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12 Commits
nanopb-0.3 ... dynamic_al

Author SHA1 Message Date
Petteri Aimonen
c2e0b9ed5d Added note in docs that this is the dev branch. 2012-01-12 19:23:30 +02:00
Petteri Aimonen
592d4213fd Added mdpoole to LICENSE 2012-01-06 19:16:44 +02:00
Petteri Aimonen
9a0a930a18 Merge branch 'master' into dynamic_alloc_dev 2012-01-06 19:16:28 +02:00
Petteri Aimonen
a2673f24fa Merge branch 'master' into dynamic_alloc_dev 
Conflicts:
	tests/Makefile
	tests/test_encode1.c
 2012-01-05 22:10:29 +02:00
Michael Poole
accd93be8d Add an encoder optimized for in-memory buffers. 
git-svn-id: https://svn.kapsi.fi/jpa/nanopb-dev@1088 e3a754e5-d11d-0410-8d38-ebb782a927b9
 2012-01-05 22:01:48 +02:00
Michael Poole
3979f9137f Unify the non-MALLOC_HEADER tests for PB_POINTER fields. 
Rather than testing PB_POINTER once for each field type,
test it just in decode_field().

git-svn-id: https://svn.kapsi.fi/jpa/nanopb-dev@1084 e3a754e5-d11d-0410-8d38-ebb782a927b9
 2012-01-05 22:01:45 +02:00
Michael Poole
ba93b65e9f Set the defaults properly for newly allocated submessages. 
Also, pb_dec_submessage() should have used calloc() instead of malloc()
in the first place.

git-svn-id: https://svn.kapsi.fi/jpa/nanopb-dev@1083 e3a754e5-d11d-0410-8d38-ebb782a927b9
 2012-01-05 22:01:37 +02:00
Michael Poole
f7c8dd81d4 Make field decoders return false for unsupported pointer fields. 
git-svn-id: https://svn.kapsi.fi/jpa/nanopb-dev@1082 e3a754e5-d11d-0410-8d38-ebb782a927b9
 2012-01-05 22:01:33 +02:00
Michael Poole
c66c6b43c4 Support dynamic allocation for string, bytes and message fields. 
This is turned on by passing -p to nanopb_generator.py or setting the
(nanopb).pointer option for a .proto field.

git-svn-id: https://svn.kapsi.fi/jpa/nanopb-dev@1081 e3a754e5-d11d-0410-8d38-ebb782a927b9
 2012-01-05 22:01:30 +02:00
Michael Poole
8e5337e9ef Merge the generated has_<name> fields into a single one. 
git-svn-id: https://svn.kapsi.fi/jpa/nanopb-dev@1008 e3a754e5-d11d-0410-8d38-ebb782a927b9
 2012-01-05 22:01:24 +02:00
Michael Poole
43b8e20744 Create a message descriptor type. 
This replaces the sentinel at the end of the pb_field_t
array for each message type.

git-svn-id: https://svn.kapsi.fi/jpa/nanopb-dev@1007 e3a754e5-d11d-0410-8d38-ebb782a927b9
 2012-01-05 22:01:17 +02:00
Michael Poole
dcf43a6416 Convert pb_type_t to uint8_t. 
PB_HTYPE_x | PB_LTYPE_x becomes an int according to C, and
some compilers warn when assigning that to an enum value.
Also correct an associated term in reference.rst.

git-svn-id: https://svn.kapsi.fi/jpa/nanopb-dev@1006 e3a754e5-d11d-0410-8d38-ebb782a927b9
 2012-01-05 22:01:14 +02:00
158 changed files with 2976 additions and 11572 deletions
Expand all files Collapse all files

28
.gitignore vendored
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@@ -1,28 +0,0 @@
*.gcda
*.gcno
*.gcov
*.o
*.pb.c
*.pb.h
*.pb
*.pyc
*_pb2.py
*~
*.tar.gz
.sconsign.dblite
config.log
.sconf_temp
tests/build
julkaisu.txt
dist
docs/*.html
docs/generator_flow.png
examples/simple/simple
examples/network_server/client
examples/network_server/server
examples/using_double_on_avr/decode_double
examples/using_double_on_avr/encode_double
examples/using_double_on_avr/test_conversions
examples/using_union_messages/decode
examples/using_union_messages/encode
generator/nanopb_pb2.pyc

175
CHANGELOG.txt
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@@ -1,175 +0,0 @@
nanopb-0.3.0 (2014-08-26)
NOTE: See docs/migration.html or online at
http://koti.kapsi.fi/~jpa/nanopb/docs/migration.html
for changes in this version. Most importantly, you need to add
pb_common.c to the list of files to compile.
Separated field iterator logic to pb_common.c (issue 128)
Change the _count fields to use pb_size_t datatype (issue 82)
Added PB_ prefix to macro names (issue 106)
Added #if version guard to generated files (issue 129)
Added migration document
nanopb-0.2.9 (2014-08-09)
NOTE: If you are using the -e option with the generator, you have
to prepend . to the argument to get the same behaviour as before.
Do not automatically add a dot with generator -e option. (issue 122)
Fix problem with .options file and extension fields. (issue 125)
Don't use SIZE_MAX macro, as it is not in C89. (issue 120)
Generate #defines for initializing message structures. (issue 79)
Add skip_message option to generator. (issue 121)
Add PB_PACKED_STRUCT support for Keil MDK-ARM toolchain (issue 119)
Give better messages about the .options file path. (issue 124)
Improved tests
nanopb-0.2.8 (2014-05-20)
Fix security issue with PB_ENABLE_MALLOC. (issue 117)
Add option to not add timestamps to .pb.h and .pb.c preambles. (issue 115)
Documentation updates
Improved tests
nanopb-0.2.7 (2014-04-07)
Fix bug with default values for extension fields (issue 111)
Fix some MISRA-C warnings (issue 91)
Implemented optional malloc() support (issue 80)
Changed pointer-type bytes field datatype
Add a "found" field to pb_extension_t (issue 112)
Add convenience function pb_get_encoded_size() (issue 16)
nanopb-0.2.6 (2014-02-15)
Fix generator error with bytes callback fields (issue 99)
Fix warnings about large integer constants (issue 102)
Add comments to where STATIC_ASSERT is used (issue 96)
Add warning about unknown field names on .options (issue 105)
Move descriptor.proto to google/protobuf subdirectory (issue 104)
Improved tests
nanopb-0.2.5 (2014-01-01)
Fix a bug with encoding negative values in int32 fields (issue 97)
Create binary packages of the generator + dependencies (issue 47)
Add support for pointer-type fields to the encoder (part of issue 80)
Fixed path in FindNanopb.cmake (issue 94)
Improved tests
nanopb-0.2.4 (2013-11-07)
Remove the deprecated NANOPB_INTERNALS functions from public API.
Document the security model.
Check array and bytes max sizes when encoding (issue 90)
Add #defines for maximum encoded message size (issue 89)
Add #define tags for extension fields (issue 93)
Fix MISRA C violations (issue 91)
Clean up pb_field_t definition with typedefs.
nanopb-0.2.3 (2013-09-18)
Improve compatibility by removing ternary operator from initializations (issue 88)
Fix build error on Visual C++ (issue 84, patch by Markus Schwarzenberg)
Don't stop on unsupported extension fields (issue 83)
Add an example pb_syshdr.h file for non-C99 compilers
Reorganize tests and examples into subfolders (issue 63)
Switch from Makefiles to scons for building the tests
Make the tests buildable on Windows
nanopb-0.2.2 (2013-08-18)
Add support for extension fields (issue 17)
Fix unknown fields in empty message (issue 78)
Include the field tags in the generated .pb.h file.
Add pb_decode_delimited and pb_encode_delimited wrapper functions (issue 74)
Add a section in top of pb.h for changing compilation settings (issue 76)
Documentation improvements (issues 12, 77 and others)
Improved tests
nanopb-0.2.1 (2013-04-14)
NOTE: The default callback function signature has changed.
If you don't want to update your code, define PB_OLD_CALLBACK_STYLE.
Change the callback function to use void** (issue 69)
Add support for defining the nanopb options in a separate file (issue 12)
Add support for packed structs in IAR and MSVC (in addition to GCC) (issue 66)
Implement error message support for the encoder side (issue 7)
Handle unterminated strings when encoding (issue 68)
Fix bug with empty strings in repeated string callbacks (issue 73)
Fix regression in 0.2.0 with optional callback fields (issue 70)
Fix bugs with empty message types (issues 64, 65)
Fix some compiler warnings on clang (issue 67)
Some portability improvements (issues 60, 62)
Various new generator options
Improved tests
nanopb-0.2.0 (2013-03-02)
NOTE: This release requires you to regenerate all .pb.c
files. Files generated by older versions will not
compile anymore.
Reformat generated .pb.c files using macros (issue 58)
Rename PB_HTYPE_ARRAY -> PB_HTYPE_REPEATED
Separate PB_HTYPE to PB_ATYPE and PB_HTYPE
Move STATIC_ASSERTs to .pb.c file
Added CMake file (by Pavel Ilin)
Add option to give file extension to generator (by Michael Haberler)
Documentation updates
nanopb-0.1.9 (2013-02-13)
Fixed error message bugs (issues 52, 56)
Sanitize #ifndef filename (issue 50)
Performance improvements
Add compile-time option PB_BUFFER_ONLY
Add Java package name to nanopb.proto
Check for sizeof(double) == 8 (issue 54)
Added generator option to ignore some fields. (issue 51)
Added generator option to make message structs packed. (issue 49)
Add more test cases.
nanopb-0.1.8 (2012-12-13)
Fix bugs in the enum short names introduced in 0.1.7 (issues 42, 43)
Fix STATIC_ASSERT macro when using multiple .proto files. (issue 41)
Fix missing initialization of istream.errmsg
Make tests/Makefile work for non-gcc compilers (issue 40)
nanopb-0.1.7 (2012-11-11)
Remove "skip" mode from pb_istream_t callbacks. Example implementation had a bug. (issue 37)
Add option to use shorter names for enum values (issue 38)
Improve options support in generator (issues 12, 30)
Add nanopb version number to generated files (issue 36)
Add extern "C" to generated headers (issue 35)
Add names for structs to allow forward declaration (issue 39)
Add buffer size check in example (issue 34)
Fix build warnings on MS compilers (issue 33)
nanopb-0.1.6 (2012-09-02)
Reorganize the field decoder interface (issue 2)
Improve performance in submessage decoding (issue 28)
Implement error messages in the decoder side (issue 7)
Extended testcases (alltypes test is now complete).
Fix some compiler warnings (issues 25, 26, 27, 32).
nanopb-0.1.5 (2012-08-04)
Fix bug in decoder with packed arrays (issue 23).
Extended testcases.
Fix some compiler warnings.
nanopb-0.1.4 (2012-07-05)
Add compile-time options for easy-to-use >255 field support.
Improve the detection of missing required fields.
Added example on how to handle union messages.
Fix generator error with .proto without messages.
Fix problems that stopped the code from compiling with some compilers.
Fix some compiler warnings.
nanopb-0.1.3 (2012-06-12)
Refactor the field encoder interface.
Improve generator error messages (issue 5)
Add descriptor.proto into the #include exclusion list
Fix some compiler warnings.
nanopb-0.1.2 (2012-02-15)
Make the generator to generate include for other .proto files (issue 4).
Fixed generator not working on Windows (issue 3)
nanopb-0.1.1 (2012-01-14)
Fixed bug in encoder with 'bytes' fields (issue 1).
Fixed a bug in the generator that caused a compiler error on sfixed32 and sfixed64 fields.
Extended testcases.
nanopb-0.1.0 (2012-01-06)
First stable release.

1
LICENSE.txt → LICENSE
View File

@@ -1,4 +1,5 @@
Copyright (c) 2011 Petteri Aimonen <jpa at nanopb.mail.kapsi.fi>
Copyright (c) 2011 Michael Poole <mdpoole@troilus.org>
This software is provided 'as-is', without any express or
implied warranty. In no event will the authors be held liable

9
README Normal file
View File

@@ -0,0 +1,9 @@
Nanopb is a small code-size Protocol Buffers implementation.
Homepage: http://kapsi.fi/~jpa/nanopb/
To compile the library, you'll need these libraries:
protobuf-compiler python-protobuf libprotobuf-dev
To run the tests, run make under the tests folder.
If it completes without error, everything is fine.

61
README.txt
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@@ -1,61 +0,0 @@
Nanopb is a small code-size Protocol Buffers implementation in ansi C. It is
especially suitable for use in microcontrollers, but fits any memory
restricted system.
Homepage: http://kapsi.fi/~jpa/nanopb/
Using the nanopb library
========================
To use the nanopb library, you need to do two things:
1) Compile your .proto files for nanopb, using protoc.
2) Include pb_encode.c and pb_decode.c in your project.
The easiest way to get started is to study the project in "examples/simple".
It contains a Makefile, which should work directly under most Linux systems.
However, for any other kind of build system, see the manual steps in
README.txt in that folder.
Using the Protocol Buffers compiler (protoc)
============================================
The nanopb generator is implemented as a plugin for the Google's own protoc
compiler. This has the advantage that there is no need to reimplement the
basic parsing of .proto files. However, it does mean that you need the
Google's protobuf library in order to run the generator.
If you have downloaded a binary package for nanopb (either Windows, Linux or
Mac OS X version), the 'protoc' binary is included in the 'generator-bin'
folder. In this case, you are ready to go. Simply run this command:
generator-bin/protoc --nanopb_out=. myprotocol.proto
However, if you are using a git checkout or a plain source distribution, you
need to provide your own version of protoc and the Google's protobuf library.
On Linux, the necessary packages are protobuf-compiler and python-protobuf.
On Windows, you can either build Google's protobuf library from source or use
one of the binary distributions of it. In either case, if you use a separate
protoc, you need to manually give the path to nanopb generator:
protoc --plugin=protoc-gen-nanopb=nanopb/generator/protoc-gen-nanopb ...
Running the tests
=================
If you want to perform further development of the nanopb core, or to verify
its functionality using your compiler and platform, you'll want to run the
test suite. The build rules for the test suite are implemented using Scons,
so you need to have that installed. To run the tests:
cd tests
scons
This will show the progress of various test cases. If the output does not
end in an error, the test cases were successful.

2
docs/Makefile
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@@ -1,4 +1,4 @@
all: index.html concepts.html reference.html security.html migration.html \
all: index.html concepts.html reference.html \
generator_flow.png
%.png: %.svg

192
docs/concepts.rst
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@@ -10,40 +10,33 @@ The things outlined here are the underlying concepts of the nanopb design.
Proto files
===========
All Protocol Buffers implementations use .proto files to describe the message
format. The point of these files is to be a portable interface description
language.
All Protocol Buffers implementations use .proto files to describe the message format.
The point of these files is to be a portable interface description language.
Compiling .proto files for nanopb
---------------------------------
Nanopb uses the Google's protoc compiler to parse the .proto file, and then a
python script to generate the C header and source code from it::
Nanopb uses the Google's protoc compiler to parse the .proto file, and then a python script to generate the C header and source code from it::
user@host:~$ protoc -omessage.pb message.proto
user@host:~$ python ../generator/nanopb_generator.py message.pb
Writing to message.h and message.c
user@host:~$
Modifying generator behaviour
-----------------------------
Using generator options, you can set maximum sizes for fields in order to
allocate them statically. The preferred way to do this is to create an .options
file with the same name as your .proto file::
Compiling .proto files with nanopb options
------------------------------------------
Nanopb defines two extensions for message fields described in .proto files: *max_size* and *max_count*.
These are the maximum size of a string and maximum count of items in an array::
# Foo.proto
message Foo {
required string name = 1;
}
required string name = 1 [(nanopb).max_size = 40];
repeated PhoneNumber phone = 4 [(nanopb).max_count = 5];
::
To use these extensions, you need to place an import statement in the beginning of the file::
# Foo.options
Foo.name max_size:16
import "nanopb.proto";
For more information on this, see the `Proto file options`_ section in the
reference manual.
This file, in turn, requires the file *google/protobuf/descriptor.proto*. This is usually installed under */usr/include*. Therefore, to compile a .proto file which uses options, use a protoc command similar to::
.. _`Proto file options`: reference.html#proto-file-options
protoc -I/usr/include -Inanopb/generator -I. -omessage.pb message.proto
Streams
=======
@@ -57,7 +50,6 @@ There are a few generic rules for callback functions:
#) Use state to store your own data, such as a file descriptor.
#) *bytes_written* and *bytes_left* are updated by pb_write and pb_read.
#) Your callback may be used with substreams. In this case *bytes_left*, *bytes_written* and *max_size* have smaller values than the original stream. Don't use these values to calculate pointers.
#) Always read or write the full requested length of data. For example, POSIX *recv()* needs the *MSG_WAITALL* parameter to accomplish this.
Output streams
--------------
@@ -82,7 +74,7 @@ This is the way to get the size of the message without storing it anywhere::
Person myperson = ...;
pb_ostream_t sizestream = {0};
pb_encode(&sizestream, Person_fields, &myperson);
pb_encode(&sizestream, Person_msg, &myperson);
printf("Encoded size is %d\n", sizestream.bytes_written);
**Example 2:**
@@ -99,8 +91,9 @@ Writing to stdout::
Input streams
-------------
For input streams, there is one extra rule:
For input streams, there are a few extra rules:
#) If buf is NULL, read from stream but don't store the data. This is used to skip unknown input.
#) You don't need to know the length of the message in advance. After getting EOF error when reading, set bytes_left to 0 and return false. Pb_decode will detect this and if the EOF was in a proper position, it will return true.
Here is the structure::
@@ -149,6 +142,7 @@ Most Protocol Buffers datatypes have directly corresponding C datatypes, such as
1) Strings, bytes and repeated fields of any type map to callback functions by default.
2) If there is a special option *(nanopb).max_size* specified in the .proto file, string maps to null-terminated char array and bytes map to a structure containing a char array and a size field.
3) If there is a special option *(nanopb).max_count* specified on a repeated field, it maps to an array of whatever type is being repeated. Another field will be created for the actual number of entries stored.
4) The option *(nanopb).pointer* can override the default (false, unless the *-p* option is passed to *nanopb_generator.py*) behavior. If a string, byte, or submessage is generated as a pointer field, and it is repeated (with a maximum count), required, or optional, the members will be pointers rather than in-line data.
=============================================================================== =======================
field in .proto autogenerated in .h
@@ -163,20 +157,24 @@ required bytes data = 1 [(nanopb).max_size = 40];
| uint8_t bytes[40];
| } Person_data_t;
| Person_data_t data;
required string name = 1 [(nanopb).pointer = true]; char \*name;
required bytes data = 1 [(nanopb).pointer = true]; pb_bytes_t data;
required bytes data = 1 [(nanopb).pointer = true, (nanopb).max_count = 5]; | size_t data_count;
| pb_bytes_t data[5];
required Message msg = 1 [(nanopb).pointer = true]; Message \*msg;
=============================================================================== =======================
The maximum lengths are checked in runtime. If string/bytes/array exceeds the allocated length, *pb_decode* will return false.
The maximum lengths are checked in runtime. If string/bytes/array exceeds the allocated length, *pb_decode* will return false.
Note: for the *bytes* datatype, the field length checking may not be exact.
The compiler may add some padding to the *pb_bytes_t* structure, and the nanopb runtime doesn't know how much of the structure size is padding. Therefore it uses the whole length of the structure for storing data, which is not very smart but shouldn't cause problems. In practise, this means that if you specify *(nanopb).max_size=5* on a *bytes* field, you may be able to store 6 bytes there. For the *string* field type, the length limit is exact.
If a pointer-type field is not received, the field will be marked as absent, but the pointer will not be modified. This helps reduce memory fragmentation and churn, but increases worst-case memory usage and means you must use the *Message_has(object, Field)* macro rather than testing for a null pointer. You can use the `pb_clean`_ function to release unused memory in these cases.
.. _`pb_clean`: reference.html#pb-clean
Field callbacks
===============
When a field has dynamic length, nanopb cannot statically allocate storage for it. Instead, it allows you to handle the field in whatever way you want, using a callback function.
The `pb_callback_t`_ structure contains a function pointer and a *void* pointer called *arg* you can use for passing data to the callback. If the function pointer is NULL, the field will be skipped. A pointer to the *arg* is passed to the function, so that it can modify it and retrieve the value.
The actual behavior of the callback function is different in encoding and decoding modes. In encoding mode, the callback is called once and should write out everything, including field tags. In decoding mode, the callback is called repeatedly for every data item.
The `pb_callback_t`_ structure contains a function pointer and a *void* pointer you can use for passing data to the callback. If the function pointer is NULL, the field will be skipped. The actual behavior of the callback function is different in encoding and decoding modes.
.. _`pb_callback_t`: reference.html#pb-callback-t
@@ -184,21 +182,25 @@ Encoding callbacks
------------------
::
bool (*encode)(pb_ostream_t *stream, const pb_field_t *field, void * const *arg);
bool (*encode)(pb_ostream_t *stream, const pb_field_t *field, const void *arg);
bool (*encode_buffer)(pb_strstream_t *stream, const pb_field_t *field, const void *arg);
When encoding, the callback should write out complete fields, including the wire type and field number tag. It can write as many or as few fields as it likes. For example, if you want to write out an array as *repeated* field, you should do it all in a single call.
When encoding, the callbacks should write out complete fields, including the wire type and field number tag. The callback can write as many or as few fields as it likes. For example, if you want to write out an array as *repeated* field, you should do it all in a single call.
Usually you can use `pb_encode_tag_for_field`_ to encode the wire type and tag number of the field. However, if you want to encode a repeated field as a packed array, you must call `pb_encode_tag`_ instead to specify a wire type of *PB_WT_STRING*.
Usually you can use `pb_encode_tag_for_field`_ (or `pb_encbuf_tag_for_field`_ for the *encode_buffer* callback) to encode the wire type and tag number of the field. However, if you want to encode a repeated field as a packed array, you must call `pb_encode_tag`_ (respectively, `pb_encbuf_tag`_) instead to specify a wire type of *PB_WT_STRING*.
If the callback is used in a submessage, it will be called multiple times during a single call to `pb_encode`_. In this case, it must produce the same amount of data every time. If the callback is directly in the main message, it is called only once.
If the callback is used in a submessage, *encode* will be called multiple times during a single call to `pb_encode`_. In this case, it must produce the same amount of data every time. If the callback is directly in the main message, or if you are using `pb_encode_buffer`_, the callback is called only once.
.. _`pb_encode`: reference.html#pb-encode
.. _`pb_encode_buffer`: reference.html#pb-encode-buffer
.. _`pb_encode_tag_for_field`: reference.html#pb-encode-tag-for-field
.. _`pb_encbuf_tag_for_field`: reference.html#pb-encbuf-tag-for-field
.. _`pb_encode_tag`: reference.html#pb-encode-tag
.. _`pb_encbuf_tag`: reference.html#pb-encbuf-tag
This callback writes out a dynamically sized string::
bool write_string(pb_ostream_t *stream, const pb_field_t *field, void * const *arg)
bool write_string(pb_ostream_t *stream, const pb_field_t *field, const void *arg)
{
char *str = get_string_from_somewhere();
if (!pb_encode_tag_for_field(stream, field))
@@ -207,11 +209,22 @@ This callback writes out a dynamically sized string::
return pb_encode_string(stream, (uint8_t*)str, strlen(str));
}
The equivalent for in-memory buffers has to write the elements in the opposite order, because the buffer writers prepend their data::
bool write_string_buf(pb_strstream_t *stream, const pb_field_t *field, const void *arg)
{
char *str = get_string_from_somewhere();
if (!pb_encbuf_string(stream, (uint8_t*)str, strlen(str)))
return false;
return pb_encbuf_tag_for_field(stream, field));
}
Decoding callbacks
------------------
::
bool (*decode)(pb_istream_t *stream, const pb_field_t *field, void **arg);
bool (*decode)(pb_istream_t *stream, const pb_field_t *field, void *arg);
When decoding, the callback receives a length-limited substring that reads the contents of a single field. The field tag has already been read. For *string* and *bytes*, the length value has already been parsed, and is available at *stream->bytes_left*.
@@ -221,7 +234,7 @@ The callback will be called multiple times for repeated fields. For packed field
This callback reads multiple integers and prints them::
bool read_ints(pb_istream_t *stream, const pb_field_t *field, void **arg)
bool read_ints(pb_istream_t *stream, const pb_field_t *field, void *arg)
{
while (stream->bytes_left)
{
@@ -233,10 +246,10 @@ This callback reads multiple integers and prints them::
return true;
}
Field description array
=======================
Message descriptor
==================
For using the *pb_encode* and *pb_decode* functions, you need an array of pb_field_t constants describing the structure you wish to encode. This description is usually autogenerated from .proto file.
For using the *pb_encode*, *pb_encode_buffer* and *pb_decode* functions, you need a message descriptor describing the structure you wish to encode. This description is usually autogenerated from .proto file.
For example this submessage in the Person.proto file::
@@ -247,70 +260,67 @@ For example this submessage in the Person.proto file::
}
}
generates this field description array for the structure *Person_PhoneNumber*::
generates these declarations and definitions for the structure *Person_PhoneNumber*::
const pb_field_t Person_PhoneNumber_fields[3] = {
PB_FIELD( 1, STRING , REQUIRED, STATIC, Person_PhoneNumber, number, number, 0),
PB_FIELD( 2, ENUM , OPTIONAL, STATIC, Person_PhoneNumber, type, number, &Person_PhoneNumber_type_default),
PB_LAST_FIELD
typedef PB_MSG_STRUCT(2) Person_PhoneNumber_msg_t;
extern const Person_PhoneNumber_msg_t Person_PhoneNumber_real_msg;
#define Person_PhoneNumber_msg ((const pb_message_t*)&Person_PhoneNumber_real_msg)
const Person_PhoneNumber_msg_t Person_PhoneNumber_real_msg = {
2,
{
{1, PB_HTYPE_REQUIRED | PB_LTYPE_STRING,
offsetof(Person_PhoneNumber, number), 0,
pb_membersize(Person_PhoneNumber, number), 0, 0},
{2, PB_HTYPE_OPTIONAL | PB_LTYPE_VARINT,
pb_delta_end(Person_PhoneNumber, type, number), 0,
pb_membersize(Person_PhoneNumber, type), 0,
&Person_PhoneNumber_type_default},
}
};
#define Person_PhoneNumber_has(STRUCT, FIELD) PB_HAS_FIELD(STRUCT, Person_PhoneNumber, FIELD)
#define Person_PhoneNumber_set(STRUCT, FIELD) PB_SET_FIELD(STRUCT, Person_PhoneNumber, FIELD)
#define Person_PhoneNumber_clear(STRUCT, FIELD) PB_CLEAR_FIELD(STRUCT, Person_PhoneNumber, FIELD)
#define Person_PhoneNumber_number_index 0
#define Person_PhoneNumber_number_tag 1
#define Person_PhoneNumber_type_index 1
#define Person_PhoneNumber_type_tag 2
Extension fields
================
Protocol Buffers supports a concept of `extension fields`_, which are
additional fields to a message, but defined outside the actual message.
The definition can even be in a completely separate .proto file.
Optional Fields
===============
The base message is declared as extensible by keyword *extensions* in
the .proto file::
The *has_fields* member of each generated structure is an array where
each bit indicates the presence of the corresponding (optional) field.
The generated header file provides helper macros to read and update
that array; in the previous example, they are
*Person_PhoneNumber_has*, *Person_PhoneNumber_set* and
*Person_PhoneNumber_clear*.
message MyMessage {
.. fields ..
extensions 100 to 199;
}
For each extensible message, *nanopb_generator.py* declares an additional
callback field called *extensions*. The field and associated datatype
*pb_extension_t* forms a linked list of handlers. When an unknown field is
encountered, the decoder calls each handler in turn until either one of them
handles the field, or the list is exhausted.
The actual extensions are declared using the *extend* keyword in the .proto,
and are in the global namespace::
extend MyMessage {
optional int32 myextension = 100;
}
For each extension, *nanopb_generator.py* creates a constant of type
*pb_extension_type_t*. To link together the base message and the extension,
you have to:
1. Allocate storage for your field, matching the datatype in the .proto.
For example, for a *int32* field, you need a *int32_t* variable to store
the value.
2. Create a *pb_extension_t* constant, with pointers to your variable and
to the generated *pb_extension_type_t*.
3. Set the *message.extensions* pointer to point to the *pb_extension_t*.
An example of this is available in *tests/test_encode_extensions.c* and
*tests/test_decode_extensions.c*.
.. _`extension fields`: https://developers.google.com/protocol-buffers/docs/proto#extensions
For convenience, *pb_encode* and *pb_encode_buffer* only check these
bits for optional fields. *pb_decode* sets the corresponding bit for
every field it decodes, whether the field is optional or not.
.. Should there be a section here on pointer fields?
Return values and error handling
================================
Most functions in nanopb return bool: *true* means success, *false* means failure. There is also some support for error messages for debugging purposes: the error messages go in *stream->errmsg*.
Most functions in nanopb return bool: *true* means success, *false* means failure. If this is enough for you, skip this section.
The error messages help in guessing what is the underlying cause of the error. The most common error conditions are:
For simplicity, nanopb doesn't define it's own error codes. This might be added if there is a compelling need for it. You can however deduce something about the error causes:
1) Running out of memory, i.e. stack overflow.
2) Invalid field descriptors (would usually mean a bug in the generator).
3) IO errors in your own stream callbacks.
4) Errors that happen in your callback functions.
1) Running out of memory. Because everything is allocated from the stack, nanopb can't detect this itself. Encoding or decoding the same type of a message always takes the same amount of stack space. Therefore, if it works once, it works always.
2) Invalid field description. These are usually stored as constants, so if it works under the debugger, it always does.
3) IO errors in your own stream callbacks. Because encoding/decoding stops at the first error, you can overwrite the *state* field in the struct and store your own error code there.
4) Errors that happen in your callback functions. You can use the state field in the callback structure.
5) Exceeding the max_size or bytes_left of a stream.
6) Exceeding the max_size of a string or array field
7) Invalid protocol buffers binary message.
7) Invalid protocol buffers binary message. It's not like you could recover from it anyway, so a simple failure should be enough.
In my opinion, it is enough that 1. and 2. can be resolved using a debugger.
However, you may be interested which of the remaining conditions caused the error. For 3. and 4., you can set and check the state. If you have to detect 5. and 6., you should convert the fields to callback type. Any remaining problem is of type 7.

69
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@@ -14,6 +14,9 @@ Overall structure
For the runtime program, you always need *pb.h* for type declarations.
Depending on whether you want to encode, decode, or both, you also need *pb_encode.h/c* or *pb_decode.h/c*.
If you only encode into in-memory buffers, *pb_decode_buffer.h/c* should be slightly faster and smaller.
If your *.proto* file encodes submessages or other fields using pointers, you must compile *pb_decode.c* with a preprocessor macro named *MALLOC_HEADER* that is the name of a header with definitions (either as functions or macros) for *calloc()*, *realloc()* and *free()*. For a typical hosted configuration, this should be *<stdlib.h>*.
The high-level encoding and decoding functions take an array of *pb_field_t* structures, which describes the fields of a message structure. Usually you want these autogenerated from a *.proto* file. The tool script *nanopb_generator.py* accomplishes this.
@@ -25,9 +28,10 @@ So a typical project might include these files:
- pb.h
- pb_decode.h and pb_decode.c (needed for decoding messages)
- pb_encode.h and pb_encode.c (needed for encoding messages)
- pb_encode_buffer.h and pb_encode_buffer.c (for encoding specifically into in-memory buffers)
2) Protocol description (you can have many):
- person.proto (just an example)
- person.pb.c (autogenerated, contains initializers for const arrays)
- person.pb.c (autogenerated, contains initializers for message descriptors)
- person.pb.h (autogenerated, contains type declarations)
Features and limitations
@@ -36,25 +40,23 @@ Features and limitations
**Features**
#) Pure C runtime
#) Small code size (210 kB depending on processor, plus any message definitions)
#) Small ram usage (typically ~300 bytes, plus any message structs)
#) Small code size (210 kB depending on processor)
#) Small ram usage (typically 200 bytes)
#) Allows specifying maximum size for strings and arrays, so that they can be allocated statically.
#) No malloc needed: everything can be allocated statically or on the stack.
#) You can use either encoder or decoder alone to cut the code size in half.
#) Support for most protobuf features, including: all data types, nested submessages, default values, repeated and optional fields, packed arrays, extension fields.
#) Callback mechanism for handling messages larger than can fit in available RAM.
#) Extensive set of tests.
**Limitations**
#) Some speed has been sacrificed for code size.
#) User must provide callbacks when decoding arrays or strings without maximum size. Malloc support could be added as a separate module.
#) Some speed has been sacrificed for code size. For example varint calculations are always done in 64 bits.
#) Encoding is focused on writing to streams. For memory buffers only it could be made more efficient.
#) The deprecated Protocol Buffers feature called "groups" is not supported.
#) Fields in the generated structs are ordered by the tag number, instead of the natural ordering in .proto file.
#) Unknown fields are not preserved when decoding and re-encoding a message.
#) Reflection (runtime introspection) is not supported. E.g. you can't request a field by giving its name in a string.
#) Numeric arrays are always encoded as packed, even if not marked as packed in .proto. This causes incompatibility with decoders that do not support packed format.
#) Cyclic references between messages are supported only in callback mode.
#) Limited support for cyclic references between messages. (The cycle must be broken by making one of the references a pointer or callback field, and objects that have circular references are not detected when encoding.)
Getting started
===============
@@ -76,51 +78,52 @@ You should now have in *message.pb.h*::
int32_t value;
} Example;
extern const pb_field_t Example_fields[2];
typedef PB_MSG_STRUCT(1) Example_msg_t;
extern const Example_msg_t Example_real_msg;
#define Example_msg ((const pb_message_t*)&Example_real_msg)
Now in your main program do this to encode a message::
Example mymessage = {42};
uint8_t buffer[10];
pb_ostream_t stream = pb_ostream_from_buffer(buffer, sizeof(buffer));
pb_encode(&stream, Example_fields, &mymessage);
pb_encode(&stream, Example_msg, &mymessage);
After that, buffer will contain the encoded message.
The number of bytes in the message is stored in *stream.bytes_written*.
Using *pb_encode_buffer.h/c* interface is very similar::
Example mymessage = {42};
uint8_t buffer[10];
pb_strstream_t stream = pb_str_from_buffer(buffer, sizeof(buffer));
pb_encode_buffer(&stream, Example_msg, &mymessage);
The encoded message will start at *stream.last* and continue until the
end of *buffer* (that is, it has length *buffer - stream.last*).
You can feed the message to *protoc --decode=Example message.proto* to verify its validity.
For a complete example of the simple case, see *example/simple.c*.
For a more complex example with network interface, see the *example/network_server* subdirectory.
For complete examples of the simple cases, see *tests/test_decode1.c* and *tests/test_encode1.c*. For an example with network interface, see the *example* subdirectory.
Compiler requirements
=====================
Nanopb should compile with most ansi-C compatible compilers. It however
requires a few header files to be available:
Nanopb should compile with most ansi-C compatible compilers. It however requires a few header files to be available:
#) *string.h*, with these functions: *strlen*, *memcpy*, *memset*
#) *stdint.h*, for definitions of *int32_t* etc.
#) *stddef.h*, for definition of *size_t*
#) *stdbool.h*, for definition of *bool*
If these header files do not come with your compiler, you can use the
file *extra/pb_syshdr.h* instead. It contains an example of how to provide
the dependencies. You may have to edit it a bit to suit your custom platform.
If these header files do not come with your compiler, you should be able to find suitable replacements online. Mostly the requirements are very simple, just a few basic functions and typedefs.
To use the pb_syshdr.h, define *PB_SYSTEM_HEADER* as *"pb_syshdr.h"* (including the quotes).
Similarly, you can provide a custom include file, which should provide all the dependencies
listed above.
Debugging and testing
=====================
Extensive unittests are included under the *tests* folder. Just type *make* there to run the tests.
Running the test cases
======================
Extensive unittests and test cases are included under the *tests* folder.
To build the tests, you will need the `scons`__ build system. The tests should
be runnable on most platforms. Windows and Linux builds are regularly tested.
__ http://www.scons.org/
In addition to the build system, you will also need a working Google Protocol
Buffers *protoc* compiler, and the Python bindings for Protocol Buffers. On
Debian-based systems, install the following packages: *protobuf-compiler*,
*python-protobuf* and *libprotobuf-dev*.
This also generates a file called *breakpoints* which includes all lines returning *false* in nanopb. You can use this in gdb by typing *source breakpoints*, after which gdb will break on first nanopb error.
Wishlist
========
#) A cleaner rewrite of the Python-based source generator.
#) Better performance for 16- and 8-bit platforms: use smaller datatypes where possible.

11
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@@ -3,11 +3,12 @@
1) `Overview`_
2) `Concepts`_
3) `API reference`_
4) `Security model`_
5) `Migration from older versions`_
Note: This is the documentation for the *dynamic_alloc_dev* development branch. See here for the
documentation for the latest stable version:
http://koti.kapsi.fi/~jpa/nanopb/docs/index.html
.. _`Overview`: index.html
.. _`Concepts`: concepts.html
.. _`API reference`: reference.html
.. _`Security model`: security.html
.. _`Migration from older versions`: migration.html

239
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@@ -1,239 +0,0 @@
=====================================
Nanopb: Migration from older versions
=====================================
.. include :: menu.rst
This document details all the breaking changes that have been made to nanopb
since its initial release. For each change, the rationale and required
modifications of user applications are explained. Also any error indications
are included, in order to make it easier to find this document.
.. contents ::
Nanopb-0.3.0 (2014-08-26)
=========================
Separate field iterator logic to pb_common.c
--------------------------------------------
**Rationale:** Originally, the field iteration logic was simple enough to be
duplicated in *pb_decode.c* and *pb_encode.c*. New field types have made the
logic more complex, which required the creation of a new file to contain the
common functionality.
**Changes:** There is a new file, *pb_common.c*, which must be included in
builds.
**Required actions:** Add *pb_common.c* to build rules. This file is always
required. Either *pb_decode.c* or *pb_encode.c* can still be left out if some
functionality is not needed.
**Error indications:** Linker error: undefined reference to
*pb_field_iter_begin*, *pb_field_iter_next* or similar.
Change data type of field counts to pb_size_t
---------------------------------------------
**Rationale:** Often nanopb is used with small arrays, such as 255 items or
less. Using a full *size_t* field to store the array count wastes memory if
there are many arrays. There already exists parameters *PB_FIELD_16BIT* and
*PB_FIELD_32BIT* which tell nanopb what is the maximum size of arrays in use.
**Changes:** Generator will now use *pb_size_t* for the array *_count* fields.
The size of the type will be controlled by the *PB_FIELD_16BIT* and
*PB_FIELD_32BIT* compilation time options.
**Required actions:** Regenerate all *.pb.h* files. In some cases casts to the
*pb_size_t* type may need to be added in the user code when accessing the
*_count* fields.
**Error indications:** Incorrect data at runtime, crashes. But note that other
changes in the same version already require regenerating the files and have
better indications of errors, so this is only an issue for development
versions.
Renamed some macros and identifiers
-----------------------------------
**Rationale:** Some names in nanopb core were badly chosen and conflicted with
ISO C99 reserved names or lacked a prefix. While they haven't caused trouble
so far, it is reasonable to switch to non-conflicting names as these are rarely
used from user code.
**Changes:** The following identifier names have changed:
* Macros:
* STATIC_ASSERT(x) -> PB_STATIC_ASSERT(x)
* UNUSED(x) -> PB_UNUSED(x)
* Include guards:
* _PB_filename_ -> PB_filename_INCLUDED
* Structure forward declaration tags:
* _pb_field_t -> pb_field_s
* _pb_bytes_array_t -> pb_bytes_array_s
* _pb_callback_t -> pb_callback_s
* _pb_extension_type_t -> pb_extension_type_s
* _pb_extension_t -> pb_extension_s
* _pb_istream_t -> pb_istream_s
* _pb_ostream_t -> pb_ostream_s
**Required actions:** Regenerate all *.pb.c* files. If you use any of the above
identifiers in your application code, perform search-replace to the new name.
**Error indications:** Compiler errors on lines with the macro/type names.
Nanopb-0.2.9 (2014-08-09)
=========================
Change semantics of generator -e option
---------------------------------------
**Rationale:** Some compilers do not accept filenames with two dots (like
in default extension .pb.c). The *-e* option to the generator allowed changing
the extension, but not skipping the extra dot.
**Changes:** The *-e* option in generator will no longer add the prepending
dot. The default value has been adjusted accordingly to *.pb.c* to keep the
default behaviour the same as before.
**Required actions:** Only if using the generator -e option. Add dot before
the parameter value on the command line.
**Error indications:** File not found when trying to compile generated files.
Nanopb-0.2.7 (2014-04-07)
=========================
Changed pointer-type bytes field datatype
-----------------------------------------
**Rationale:** In the initial pointer encoding support since nanopb-0.2.5,
the bytes type used a separate *pb_bytes_ptr_t* type to represent *bytes*
fields. This made it easy to encode data from a separate, user-allocated
buffer. However, it made the internal logic more complex and was inconsistent
with the other types.
**Changes:** Dynamically allocated bytes fields now have the *pb_bytes_array_t*
type, just like statically allocated ones.
**Required actions:** Only if using pointer-type fields with the bytes datatype.
Change any access to *msg->field.size* to *msg->field->size*. Change any
allocation to reserve space of amount *PB_BYTES_ARRAY_T_ALLOCSIZE(n)*. If the
data pointer was begin assigned from external source, implement the field using
a callback function instead.
**Error indications:** Compiler error: unknown type name *pb_bytes_ptr_t*.
Nanopb-0.2.4 (2013-11-07)
=========================
Remove the NANOPB_INTERNALS compilation option
----------------------------------------------
**Rationale:** Having the option in the headers required the functions to
be non-static, even if the option is not used. This caused errors on some
static analysis tools.
**Changes:** The *#ifdef* and associated functions were removed from the
header.
**Required actions:** Only if the *NANOPB_INTERNALS* option was previously
used. Actions are as listed under nanopb-0.1.3 and nanopb-0.1.6.
**Error indications:** Compiler warning: implicit declaration of function
*pb_dec_string*, *pb_enc_string*, or similar.
Nanopb-0.2.1 (2013-04-14)
=========================
Callback function signature
---------------------------
**Rationale:** Previously the auxilary data to field callbacks was passed
as *void\**. This allowed passing of any data, but made it unnecessarily
complex to return a pointer from callback.
**Changes:** The callback function parameter was changed to *void\**.
**Required actions:** You can continue using the old callback style by
defining *PB_OLD_CALLBACK_STYLE*. Recommended action is to:
* Change the callback signatures to contain *void\** for decoders and
*void \* const \** for encoders.
* Change the callback function body to use *\*arg* instead of *arg*.
**Error indications:** Compiler warning: assignment from incompatible
pointer type, when initializing *funcs.encode* or *funcs.decode*.
Nanopb-0.2.0 (2013-03-02)
=========================
Reformatted generated .pb.c file using macros
---------------------------------------------
**Rationale:** Previously the generator made a list of C *pb_field_t*
initializers in the .pb.c file. This led to a need to regenerate all .pb.c
files after even small changes to the *pb_field_t* definition.
**Changes:** Macros were added to pb.h which allow for cleaner definition
of the .pb.c contents. By changing the macro definitions, changes to the
field structure are possible without breaking compatibility with old .pb.c
files.
**Required actions:** Regenerate all .pb.c files from the .proto sources.
**Error indications:** Compiler warning: implicit declaration of function
*pb_delta_end*.
Changed pb_type_t definitions
-----------------------------
**Rationale:** The *pb_type_t* was previously an enumeration type. This
caused warnings on some compilers when using bitwise operations to set flags
inside the values.
**Changes:** The *pb_type_t* was changed to *typedef uint8_t*. The values
were changed to *#define*. Some value names were changed for consistency.
**Required actions:** Only if you directly access the `pb_field_t` contents
in your own code, something which is not usually done. Needed changes:
* Change *PB_HTYPE_ARRAY* to *PB_HTYPE_REPEATED*.
* Change *PB_HTYPE_CALLBACK* to *PB_ATYPE()* and *PB_ATYPE_CALLBACK*.
**Error indications:** Compiler error: *PB_HTYPE_ARRAY* or *PB_HTYPE_CALLBACK*
undeclared.
Nanopb-0.1.6 (2012-09-02)
=========================
Refactored field decoder interface
----------------------------------
**Rationale:** Similarly to field encoders in nanopb-0.1.3.
**Changes:** New functions with names *pb_decode_\** were added.
**Required actions:** By defining NANOPB_INTERNALS, you can still keep using
the old functions. Recommended action is to replace any calls with the newer
*pb_decode_\** equivalents.
**Error indications:** Compiler warning: implicit declaration of function
*pb_dec_string*, *pb_dec_varint*, *pb_dec_submessage* or similar.
Nanopb-0.1.3 (2012-06-12)
=========================
Refactored field encoder interface
----------------------------------
**Rationale:** The old *pb_enc_\** functions were designed mostly for the
internal use by the core. Because they are internally accessed through
function pointers, their signatures had to be common. This led to a confusing
interface for external users.
**Changes:** New functions with names *pb_encode_\** were added. These have
easier to use interfaces. The old functions are now only thin wrappers for
the new interface.
**Required actions:** By defining NANOPB_INTERNALS, you can still keep using
the old functions. Recommended action is to replace any calls with the newer
*pb_encode_\** equivalents.
**Error indications:** Compiler warning: implicit declaration of function
*pb_enc_string*, *pb_enc_varint, *pb_enc_submessage* or similar.

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@@ -6,189 +6,6 @@ Nanopb: API reference
.. contents ::
Compilation options
===================
The following options can be specified in one of two ways:
1. Using the -D switch on the C compiler command line.
2. By #defining them at the top of pb.h.
You must have the same settings for the nanopb library and all code that
includes pb.h.
============================ ================================================
__BIG_ENDIAN__ Set this if your platform stores integers and
floats in big-endian format. Mixed-endian
systems (different layout for ints and floats)
are currently not supported.
PB_ENABLE_MALLOC Set this to enable dynamic allocation support
in the decoder.
PB_MAX_REQUIRED_FIELDS Maximum number of required fields to check for
presence. Default value is 64. Increases stack
usage 1 byte per every 8 fields. Compiler
warning will tell if you need this.
PB_FIELD_16BIT Add support for tag numbers > 255 and fields
larger than 255 bytes or 255 array entries.
Increases code size 3 bytes per each field.
Compiler error will tell if you need this.
PB_FIELD_32BIT Add support for tag numbers > 65535 and fields
larger than 65535 bytes or 65535 array entries.
Increases code size 9 bytes per each field.
Compiler error will tell if you need this.
PB_NO_ERRMSG Disables the support for error messages; only
error information is the true/false return
value. Decreases the code size by a few hundred
bytes.
PB_BUFFER_ONLY Disables the support for custom streams. Only
supports encoding and decoding with memory
buffers. Speeds up execution and decreases code
size slightly.
PB_OLD_CALLBACK_STYLE Use the old function signature (void\* instead
of void\*\*) for callback fields. This was the
default until nanopb-0.2.1.
PB_SYSTEM_HEADER Replace the standard header files with a single
header file. It should define all the required
functions and typedefs listed on the
`overview page`_. Value must include quotes,
for example *#define PB_SYSTEM_HEADER "foo.h"*.
============================ ================================================
The PB_MAX_REQUIRED_FIELDS, PB_FIELD_16BIT and PB_FIELD_32BIT settings allow
raising some datatype limits to suit larger messages. Their need is recognized
automatically by C-preprocessor #if-directives in the generated .pb.h files.
The default setting is to use the smallest datatypes (least resources used).
.. _`overview page`: index.html#compiler-requirements
Proto file options
==================
The generator behaviour can be adjusted using these options, defined in the
'nanopb.proto' file in the generator folder:
============================ ================================================
max_size Allocated size for *bytes* and *string* fields.
max_count Allocated number of entries in arrays
(*repeated* fields).
type Type of the generated field. Default value
is *FT_DEFAULT*, which selects automatically.
You can use *FT_CALLBACK*, *FT_POINTER*,
*FT_STATIC* or *FT_IGNORE* to force a callback
field, a dynamically allocated field, a static
field or to completely ignore the field.
long_names Prefix the enum name to the enum value in
definitions, i.e. *EnumName_EnumValue*. Enabled
by default.
packed_struct Make the generated structures packed.
NOTE: This cannot be used on CPUs that break
on unaligned accesses to variables.
============================ ================================================
These options can be defined for the .proto files before they are converted
using the nanopb-generatory.py. There are three ways to define the options:
1. Using a separate .options file.
This is the preferred way as of nanopb-0.2.1, because it has the best
compatibility with other protobuf libraries.
2. Defining the options on the command line of nanopb_generator.py.
This only makes sense for settings that apply to a whole file.
3. Defining the options in the .proto file using the nanopb extensions.
This is the way used in nanopb-0.1, and will remain supported in the
future. It however sometimes causes trouble when using the .proto file
with other protobuf libraries.
The effect of the options is the same no matter how they are given. The most
common purpose is to define maximum size for string fields in order to
statically allocate them.
Defining the options in a .options file
---------------------------------------
The preferred way to define options is to have a separate file
'myproto.options' in the same directory as the 'myproto.proto'. ::
# myproto.proto
message MyMessage {
required string name = 1;
repeated int32 ids = 4;
}
::
# myproto.options
MyMessage.name max_size:40
MyMessage.ids max_count:5
The generator will automatically search for this file and read the
options from it. The file format is as follows:
* Lines starting with '#' or '//' are regarded as comments.
* Blank lines are ignored.
* All other lines should start with a field name pattern, followed by one or
more options. For example: *"MyMessage.myfield max_size:5 max_count:10"*.
* The field name pattern is matched against a string of form *'Message.field'*.
For nested messages, the string is *'Message.SubMessage.field'*.
* The field name pattern may use the notation recognized by Python fnmatch():
- *\** matches any part of string, like 'Message.\*' for all fields
- *\?* matches any single character
- *[seq]* matches any of characters 's', 'e' and 'q'
- *[!seq]* matches any other character
* The options are written as *'option_name:option_value'* and several options
can be defined on same line, separated by whitespace.
* Options defined later in the file override the ones specified earlier, so
it makes sense to define wildcard options first in the file and more specific
ones later.
If preferred, the name of the options file can be set using the command line
switch *-f* to nanopb_generator.py.
Defining the options on command line
------------------------------------
The nanopb_generator.py has a simple command line option *-s OPTION:VALUE*.
The setting applies to the whole file that is being processed.
Defining the options in the .proto file
---------------------------------------
The .proto file format allows defining custom options for the fields.
The nanopb library comes with *nanopb.proto* which does exactly that, allowing
you do define the options directly in the .proto file::
import "nanopb.proto";
message MyMessage {
required string name = 1 [(nanopb).max_size = 40];
repeated int32 ids = 4 [(nanopb).max_count = 5];
}
A small complication is that you have to set the include path of protoc so that
nanopb.proto can be found. This file, in turn, requires the file
*google/protobuf/descriptor.proto*. This is usually installed under
*/usr/include*. Therefore, to compile a .proto file which uses options, use a
protoc command similar to::
protoc -I/usr/include -Inanopb/generator -I. -omessage.pb message.proto
The options can be defined in file, message and field scopes::
option (nanopb_fileopt).max_size = 20; // File scope
message Message
{
option (nanopb_msgopt).max_size = 30; // Message scope
required string fieldsize = 1 [(nanopb).max_size = 40]; // Field scope
}
pb.h
====
@@ -205,39 +22,31 @@ LTYPE identifier Value Storage format
==================== ===== ================================================
PB_LTYPE_VARINT 0x00 Integer.
PB_LTYPE_SVARINT 0x01 Integer, zigzag encoded.
PB_LTYPE_FIXED32 0x02 32-bit integer or floating point.
PB_LTYPE_FIXED64 0x03 64-bit integer or floating point.
PB_LTYPE_BYTES 0x04 Structure with *size_t* field and byte array.
PB_LTYPE_STRING 0x05 Null-terminated string.
PB_LTYPE_SUBMESSAGE 0x06 Submessage structure.
PB_LTYPE_FIXED 0x02 Integer or floating point.
PB_LTYPE_BYTES 0x03 Structure with *size_t* field and byte array.
PB_LTYPE_STRING 0x04 Null-terminated string.
PB_LTYPE_SUBMESSAGE 0x05 Submessage structure.
==================== ===== ================================================
The bits 4-5 define whether the field is required, optional or repeated:
The high-order nibble defines whether the field is required, optional, repeated or callback, and whether it is a pointer:
==================== ===== ================================================
HTYPE identifier Value Field handling
==================== ===== ================================================
PB_HTYPE_REQUIRED 0x00 Verify that field exists in decoded message.
PB_HTYPE_OPTIONAL 0x10 Use separate *has_<field>* boolean to specify
whether the field is present.
(Unless it is a callback)
PB_HTYPE_REPEATED 0x20 A repeated field with preallocated array.
PB_HTYPE_OPTIONAL 0x10 Use the structure's *has_fields* bit array to
specify whether the field is present.
PB_HTYPE_ARRAY 0x20 A repeated field with preallocated array.
Separate *<field>_count* for number of items.
(Unless it is a callback)
PB_HTYPE_CALLBACK 0x30 A field with dynamic storage size, data is
actually a pointer to a structure containing a
callback function.
PB_HTYPE_POINTER 0x80 For required, optional and array non-scalar
fields, uses a pointer type (char* for strings,
pb_bytes_t for bytes, or a pointer for
submessages).
==================== ===== ================================================
The bits 6-7 define the how the storage for the field is allocated:
==================== ===== ================================================
ATYPE identifier Value Allocation method
==================== ===== ================================================
PB_ATYPE_STATIC 0x00 Statically allocated storage in the structure.
PB_ATYPE_CALLBACK 0x40 A field with dynamic storage size. Struct field
actually contains a pointer to a callback
function.
==================== ===== ================================================
pb_field_t
----------
Describes a single structure field with memory position in relation to others. The descriptions are usually autogenerated. ::
@@ -254,14 +63,14 @@ Describes a single structure field with memory position in relation to others. T
} pb_packed;
:tag: Tag number of the field or 0 to terminate a list of fields.
:type: LTYPE, HTYPE and ATYPE of the field.
:type: LTYPE and HTYPE of the field.
:data_offset: Offset of field data, relative to the end of the previous field.
:size_offset: Offset of *bool* flag for optional fields or *size_t* count for arrays, relative to field data.
:size_offset: Offset of *size_t* count for arrays, relative to field data.
:data_size: Size of a single data entry, in bytes. For PB_LTYPE_BYTES, the size of the byte array inside the containing structure. For PB_HTYPE_CALLBACK, size of the C data type if known.
:array_size: Maximum number of entries in an array, if it is an array type.
:ptr: Pointer to default value for optional fields, or to submessage description for PB_LTYPE_SUBMESSAGE.
The *uint8_t* datatypes limit the maximum size of a single item to 255 bytes and arrays to 255 items. Compiler will give error if the values are too large. The types can be changed to larger ones by defining *PB_FIELD_16BIT*.
The *uint8_t* datatypes limit the maximum size of a single item to 255 bytes and arrays to 255 items. Compiler will warn "Initializer too large for type" if the limits are exceeded. The types can be changed to larger ones if necessary.
pb_bytes_array_t
----------------
@@ -274,6 +83,16 @@ An byte array with a field for storing the length::
In an actual array, the length of *bytes* may be different.
pb_bytes_t
----------
A byte array with fields for storing the allocated and current lengths::
typedef struct {
size_t alloced;
size_t size;
uint8_t *bytes;
} pb_bytes_array_t;
pb_callback_t
-------------
Part of a message structure, for fields with type PB_HTYPE_CALLBACK::
@@ -281,22 +100,21 @@ Part of a message structure, for fields with type PB_HTYPE_CALLBACK::
typedef struct _pb_callback_t pb_callback_t;
struct _pb_callback_t {
union {
bool (*decode)(pb_istream_t *stream, const pb_field_t *field, void **arg);
bool (*encode)(pb_ostream_t *stream, const pb_field_t *field, void * const *arg);
bool (*decode)(pb_istream_t *stream, const pb_field_t *field, void *arg);
bool (*encode)(pb_ostream_t *stream, const pb_field_t *field, const void *arg);
bool (*encode_buffer)(pb_strstream_t *stream, const pb_field_t *field, const void *arg);
} funcs;
void *arg;
};
A pointer to the *arg* is passed to the callback when calling. It can be used to store any information that the callback might need.
The *arg* is passed to the callback when calling. It can be used to store any information that the callback might need.
Previously the function received just the value of *arg* instead of a pointer to it. This old behaviour can be enabled by defining *PB_OLD_CALLBACK_STYLE*.
When calling `pb_encode`_, *funcs.encode* is used, and similarly when calling `pb_decode`_, *funcs.decode* is used. The function pointers are stored in the same memory location but are of incompatible types. You can set the function pointer to NULL to skip the field.
When calling `pb_encode`_, *funcs.encode* is used, and similarly when calling `pb_encode_buffer`_, *funcs.encode_buffer* is used, and when calling `pb_decode`_, *funcs.decode* is used. The function pointers are stored in the same memory location but are of incompatible types. You can set the function pointer to NULL to skip the field.
pb_wire_type_t
--------------
Protocol Buffers wire types. These are used with `pb_encode_tag`_. ::
Protocol Buffers wire types. These are used with `pb_encode_tag`_ and `pb_encbuf_tag`_. ::
typedef enum {
PB_WT_VARINT = 0,
@@ -305,76 +123,6 @@ Protocol Buffers wire types. These are used with `pb_encode_tag`_. ::
PB_WT_32BIT = 5
} pb_wire_type_t;
pb_extension_type_t
-------------------
Defines the handler functions and auxiliary data for a field that extends
another message. Usually autogenerated by *nanopb_generator.py*::
typedef struct {
bool (*decode)(pb_istream_t *stream, pb_extension_t *extension,
uint32_t tag, pb_wire_type_t wire_type);
bool (*encode)(pb_ostream_t *stream, const pb_extension_t *extension);
const void *arg;
} pb_extension_type_t;
In the normal case, the function pointers are *NULL* and the decoder and
encoder use their internal implementations. The internal implementations
assume that *arg* points to a *pb_field_t* that describes the field in question.
To implement custom processing of unknown fields, you can provide pointers
to your own functions. Their functionality is mostly the same as for normal
callback fields, except that they get called for any unknown field when decoding.
pb_extension_t
--------------
Ties together the extension field type and the storage for the field value::
typedef struct {
const pb_extension_type_t *type;
void *dest;
pb_extension_t *next;
} pb_extension_t;
:type: Pointer to the structure that defines the callback functions.
:dest: Pointer to the variable that stores the field value
(as used by the default extension callback functions.)
:next: Pointer to the next extension handler, or *NULL*.
PB_GET_ERROR
------------
Get the current error message from a stream, or a placeholder string if
there is no error message::
#define PB_GET_ERROR(stream) (string expression)
This should be used for printing errors, for example::
if (!pb_decode(...))
{
printf("Decode failed: %s\n", PB_GET_ERROR(stream));
}
The macro only returns pointers to constant strings (in code memory),
so that there is no need to release the returned pointer.
PB_RETURN_ERROR
---------------
Set the error message and return false::
#define PB_RETURN_ERROR(stream,msg) (sets error and returns false)
This should be used to handle error conditions inside nanopb functions
and user callback functions::
if (error_condition)
{
PB_RETURN_ERROR(stream, "something went wrong");
}
The *msg* parameter must be a constant string.
pb_encode.h
===========
@@ -407,33 +155,26 @@ pb_encode
---------
Encodes the contents of a structure as a protocol buffers message and writes it to output stream. ::
bool pb_encode(pb_ostream_t *stream, const pb_field_t fields[], const void *src_struct);
bool pb_encode(pb_ostream_t *stream, const pb_message_t *msg, const void *src_struct);
:stream: Output stream to write to.
:fields: A field description array, usually autogenerated.
:msg: A message descriptor, usually autogenerated.
:src_struct: Pointer to the data that will be serialized.
:returns: True on success, false on IO error, on detectable errors in field description, or if a field encoder returns false.
Normally pb_encode simply walks through the fields description array and serializes each field in turn. However, submessages must be serialized twice: first to calculate their size and then to actually write them to output. This causes some constraints for callback fields, which must return the same data on every call.
Normally pb_encode simply walks through the fields description array inside the message descriptor and serializes each field in turn. However, submessages must be serialized twice: first to calculate their size and then to actually write them to output. This causes some constraints for callback fields, which must return the same data on every call.
pb_encode_delimited
-------------------
Calculates the length of the message, encodes it as varint and then encodes the message. ::
pb_encode_varint
----------------
Encodes an unsigned integer in the varint_ format. ::
bool pb_encode_delimited(pb_ostream_t *stream, const pb_field_t fields[], const void *src_struct);
bool pb_encode_varint(pb_ostream_t *stream, uint64_t value);
(parameters are the same as for `pb_encode`_.)
:stream: Output stream to write to. 1-10 bytes will be written.
:value: Value to encode.
:returns: True on success, false on IO error.
A common way to indicate the message length in Protocol Buffers is to prefix it with a varint.
This function does this, and it is compatible with *parseDelimitedFrom* in Google's protobuf library.
.. sidebar:: Encoding fields manually
The functions with names *pb_encode_\** are used when dealing with callback fields. The typical reason for using callbacks is to have an array of unlimited size. In that case, `pb_encode`_ will call your callback function, which in turn will call *pb_encode_\** functions repeatedly to write out values.
The tag of a field must be encoded separately with `pb_encode_tag_for_field`_. After that, you can call exactly one of the content-writing functions to encode the payload of the field. For repeated fields, you can repeat this process multiple times.
Writing packed arrays is a little bit more involved: you need to use `pb_encode_tag` and specify `PB_WT_STRING` as the wire type. Then you need to know exactly how much data you are going to write, and use `pb_encode_varint`_ to write out the number of bytes before writing the actual data. Substreams can be used to determine the number of bytes beforehand; see `pb_encode_submessage`_ source code for an example.
.. _varint: http://code.google.com/apis/protocolbuffers/docs/encoding.html#varints
pb_encode_tag
-------------
@@ -443,7 +184,7 @@ Starts a field in the Protocol Buffers binary format: encodes the field number a
:stream: Output stream to write to. 1-5 bytes will be written.
:wiretype: PB_WT_VARINT, PB_WT_64BIT, PB_WT_STRING or PB_WT_32BIT
:field_number: Identifier for the field, defined in the .proto file. You can get it from field->tag.
:field_number: Identifier for the field, defined in the .proto file.
:returns: True on success, false on IO error.
pb_encode_tag_for_field
@@ -469,82 +210,208 @@ STRING, BYTES, SUBMESSAGE PB_WT_STRING
FIXED32 PB_WT_32BIT
========================= ============
pb_encode_varint
----------------
Encodes a signed or unsigned integer in the varint_ format. Works for fields of type `bool`, `enum`, `int32`, `int64`, `uint32` and `uint64`::
bool pb_encode_varint(pb_ostream_t *stream, uint64_t value);
:stream: Output stream to write to. 1-10 bytes will be written.
:value: Value to encode. Just cast e.g. int32_t directly to uint64_t.
:returns: True on success, false on IO error.
.. _varint: http://code.google.com/apis/protocolbuffers/docs/encoding.html#varints
pb_encode_svarint
-----------------
Encodes a signed integer in the 'zig-zagged' format. Works for fields of type `sint32` and `sint64`::
bool pb_encode_svarint(pb_ostream_t *stream, int64_t value);
(parameters are the same as for `pb_encode_varint`_
pb_encode_string
----------------
Writes the length of a string as varint and then contents of the string. Works for fields of type `bytes` and `string`::
Writes the length of a string as varint and then contents of the string. Used for writing fields with wire type PB_WT_STRING. ::
bool pb_encode_string(pb_ostream_t *stream, const uint8_t *buffer, size_t size);
:stream: Output stream to write to.
:buffer: Pointer to string data.
:size: Number of bytes in the string. Pass `strlen(s)` for strings.
:size: Number of bytes in the string.
:returns: True on success, false on IO error.
pb_encode_fixed32
-----------------
Writes 4 bytes to stream and swaps bytes on big-endian architectures. Works for fields of type `fixed32`, `sfixed32` and `float`::
.. sidebar:: Field encoders
bool pb_encode_fixed32(pb_ostream_t *stream, const void *value);
The functions with names beginning with *pb_enc_* are called field encoders. Each PB_LTYPE has an own field encoder, which handles translating from C data into Protocol Buffers data.
:stream: Output stream to write to.
:value: Pointer to a 4-bytes large C variable, for example `uint32_t foo;`.
:returns: True on success, false on IO error.
By using the *data_size* in the field description and by taking advantage of C casting rules, it has been possible to combine many data types to a single LTYPE. For example, *int32*, *uint32*, *int64*, *uint64*, *bool* and *enum* are all handled by *pb_enc_varint*.
pb_encode_fixed64
-----------------
Writes 8 bytes to stream and swaps bytes on big-endian architecture. Works for fields of type `fixed64`, `sfixed64` and `double`::
Each field encoder only encodes the contents of the field. The tag must be encoded separately with `pb_encode_tag_for_field`_.
bool pb_encode_fixed64(pb_ostream_t *stream, const void *value);
You can use the field encoders from your callbacks. Just be aware that the pb_field_t passed to the callback is not directly compatible with most of the encoders. Instead, you must create a new pb_field_t structure and set the data_size according to the data type you pass to *src*.
:stream: Output stream to write to.
:value: Pointer to a 8-bytes large C variable, for example `uint64_t foo;`.
:returns: True on success, false on IO error.
pb_enc_varint
-------------
Field encoder for PB_LTYPE_VARINT. Takes the first *field->data_size* bytes from src, casts them as *uint64_t* and calls `pb_encode_varint`_. ::
pb_encode_submessage
--------------------
Encodes a submessage field, including the size header for it. Works for fields of any message type::
bool pb_encode_submessage(pb_ostream_t *stream, const pb_field_t fields[], const void *src_struct);
bool pb_enc_varint(pb_ostream_t *stream, const pb_field_t *field, const void *src);
:stream: Output stream to write to.
:fields: Pointer to the autogenerated field description array for the submessage type, e.g. `MyMessage_fields`.
:field: Field description structure. Only *data_size* matters.
:src: Pointer to start of the field data.
:returns: True on success, false on IO error.
pb_enc_svarint
--------------
Field encoder for PB_LTYPE_SVARINT. Similar to `pb_enc_varint`_, except first zig-zag encodes the value for more efficient negative number encoding. ::
bool pb_enc_svarint(pb_ostream_t *stream, const pb_field_t *field, const void *src);
(parameters are the same as for `pb_enc_varint`_)
The number is considered negative if the high-order bit of the value is set. On big endian computers, it is the highest bit of *\*src*. On little endian computers, it is the highest bit of *\*(src + field->data_size - 1)*.
pb_enc_fixed32
--------------
Field encoder for PB_LTYPE_FIXED32. Writes the data in little endian order. On big endian computers, reverses the order of bytes. ::
bool pb_enc_fixed32(pb_ostream_t *stream, const pb_field_t *field, const void *src);
:stream: Output stream to write to.
:field: Not used.
:src: Pointer to start of the field data.
:returns: True on success, false on IO error.
pb_enc_fixed64
--------------
Field encoder for PB_LTYPE_FIXED64. Writes the data in little endian order. On big endian computers, reverses the order of bytes. ::
bool pb_enc_fixed64(pb_ostream_t *stream, const pb_field_t *field, const void *src);
(parameters are the same as for `pb_enc_fixed32`_)
The same function is used for both integers and doubles. This breaks encoding of double values on architectures where they are mixed endian (primarily some arm processors with hardware FPU).
pb_enc_bytes
------------
Field encoder for PB_LTYPE_BYTES. Just calls `pb_encode_string`_. ::
bool pb_enc_bytes(pb_ostream_t *stream, const pb_field_t *field, const void *src);
:stream: Output stream to write to.
:field: Not used.
:src: Pointer to a structure similar to pb_bytes_array_t.
:returns: True on success, false on IO error.
This function expects a pointer to a structure with a *size_t* field at start, and a variable sized byte array after it. The platform-specific field offset is inferred from *pb_bytes_array_t*, which has a byte array of size 1.
pb_enc_string
-------------
Field encoder for PB_LTYPE_STRING. Determines size of string with strlen() and then calls `pb_encode_string`_. ::
bool pb_enc_string(pb_ostream_t *stream, const pb_field_t *field, const void *src);
:stream: Output stream to write to.
:field: Not used.
:src: Pointer to a null-terminated string.
:returns: True on success, false on IO error.
pb_enc_submessage
-----------------
Field encoder for PB_LTYPE_SUBMESSAGE. Calls `pb_encode`_ to perform the actual encoding. ::
bool pb_enc_submessage(pb_ostream_t *stream, const pb_field_t *field, const void *src);
:stream: Output stream to write to.
:field: Field description structure. The *ptr* field must be a pointer to a valid *pb_message_t* descriptor for the submessage.
:src: Pointer to the structure where submessage data is.
:returns: True on success, false on IO errors, pb_encode errors or if submessage size changes between calls.
In Protocol Buffers format, the submessage size must be written before the submessage contents. Therefore, this function has to encode the submessage twice in order to know the size beforehand.
If the submessage contains callback fields, the callback function might misbehave and write out a different amount of data on the second call. This situation is recognized and *false* is returned, but garbage will be written to the output before the problem is detected.
If the submessage contains callback fields, the callback function might misbehave and write out a different amount of data on the second call. This situation is recognized and *false* is returned, but it is up to the caller to ensure that the receiver of the message does not interpret it as valid data.
pb_encode_buffer.h
==================
An important note about this module is that data is written from the
back of the buffer to the front. That is, when you call
*pb_buf_write()*, it will place the bytes (in the order you provide
them) before the data currently in the buffer.
pb_strstream_from_buffer
------------------------
Constructs a buffer descriptor. This is just a helper function, it doesn't do anything you couldn't do yourself in a callback function. ::
pb_strstream_t pb_strstream_from_buffer(uint8_t *buf, size_t bufsize);
:buf: Memory buffer to write into.
:bufsize: Maximum number of bytes to write.
:returns: The buffer descriptor.
The descriptor only tracks the amount of space left; it does not count how many bytes have been written.
pb_buf_write
------------
Prepends data to an in-memory buffer. Always use this function, instead of trying to manage the pointers inside the buffer descriptor. ::
bool pb_buf_write(pb_strstream_t *stream, const uint8_t *buf, size_t count);
:stream: Descriptor for buffer to write to.
:buf: Pointer to buffer with the data to be written.
:count: Number of bytes to write.
:returns: True on success, false if maximum length is exceeded.
If there is not enough space, *stream* is not modified.
pb_encode_buffer
----------------
Encodes the contents of a structure as a protocol buffers message and writes it to a buffer. ::
bool pb_encode_buffer(pb_strstream_t *stream, const pb_message_t *msg, const void *src_struct);
:stream: Descriptor for buffer to write to.
:msg: A message descriptor, usually autogenerated.
:src_struct: Pointer to the data that will be serialized.
:returns: True on success, false if the buffer is too small or if a field encoder returns false.
pb_encbuf_varint
----------------
Encodes an unsigned integer in the varint_ format. ::
bool pb_encbuf_varint(pb_strstream_t *stream, uint64_t value);
:stream: Descriptor for buffer to write to. 1-10 bytes will be written.
:value: Value to encode.
:returns: True on success, false on IO error.
.. _varint: http://code.google.com/apis/protocolbuffers/docs/encoding.html#varints
pb_encbuf_tag
-------------
Finishes a field in the Protocol Buffers binary format: encodes the field number and the wire type of the data. ::
bool pb_encbuf_tag(pb_strstream_t *stream, pb_wire_type_t wiretype, int field_number);
:stream: Descriptor for buffer to write to. 1-5 bytes will be written.
:wiretype: PB_WT_VARINT, PB_WT_64BIT, PB_WT_STRING or PB_WT_32BIT
:field_number: Identifier for the field, defined in the .proto file.
:returns: True on success, false on IO error.
pb_encbuf_tag_for_field
-----------------------
Same as `pb_encbuf_tag`_, except takes the parameters from a *pb_field_t* structure. ::
bool pb_encbuf_tag_for_field(pb_strstream_t *stream, const pb_field_t *field);
:stream: Descriptor for buffer to write to. 1-5 bytes will be written.
:field: Field description structure. Usually autogenerated.
:returns: True on success, false on IO error or unknown field type.
This function only considers the LTYPE of the field. You can use it from your field callbacks, because the source generator writes correct LTYPE also for callback type fields.
Wire type mapping is as follows:
========================= ============
LTYPEs Wire type
========================= ============
VARINT, SVARINT PB_WT_VARINT
FIXED64 PB_WT_64BIT
STRING, BYTES, SUBMESSAGE PB_WT_STRING
FIXED32 PB_WT_32BIT
========================= ============
pb_encbuf_string
----------------
Writes the length of a string as varint and then contents of the string. Used for writing fields with wire type PB_WT_STRING. ::
bool pb_encbuf_string(pb_strstream_t *stream, const uint8_t *buffer, size_t size);
:stream: Descriptor for buffer to write to.
:buffer: Pointer to string data.
:size: Number of bytes in the string.
:returns: True on success, false on IO error.
pb_decode.h
===========
@@ -572,65 +439,15 @@ Read data from input stream. Always use this function, don't try to call the str
End of file is signalled by *stream->bytes_left* being zero after pb_read returns false.
pb_decode
---------
Read and decode all fields of a structure. Reads until EOF on input stream. ::
bool pb_decode(pb_istream_t *stream, const pb_field_t fields[], void *dest_struct);
:stream: Input stream to read from.
:fields: A field description array. Usually autogenerated.
:dest_struct: Pointer to structure where data will be stored.
:returns: True on success, false on IO error, on detectable errors in field description, if a field encoder returns false or if a required field is missing.
In Protocol Buffers binary format, EOF is only allowed between fields. If it happens anywhere else, pb_decode will return *false*. If pb_decode returns false, you cannot trust any of the data in the structure.
In addition to EOF, the pb_decode implementation supports terminating a message with a 0 byte. This is compatible with the official Protocol Buffers because 0 is never a valid field tag.
For optional fields, this function applies the default value and sets *has_<field>* to false if the field is not present.
If *PB_ENABLE_MALLOC* is defined, this function may allocate storage for any pointer type fields.
In this case, you have to call `pb_release`_ to release the memory after you are done with the message.
On error return `pb_decode` will release the memory itself.
pb_decode_noinit
pb_decode_varint
----------------
Same as `pb_decode`_, except does not apply the default values to fields. ::
Read and decode a varint_ encoded integer. ::
bool pb_decode_noinit(pb_istream_t *stream, const pb_field_t fields[], void *dest_struct);
bool pb_decode_varint(pb_istream_t *stream, uint64_t *dest);
(parameters are the same as for `pb_decode`_.)
The destination structure should be filled with zeros before calling this function. Doing a *memset* manually can be slightly faster than using `pb_decode`_ if you don't need any default values.
In addition to decoding a single message, this function can be used to merge two messages, so that
values from previous message will remain if the new message does not contain a field.
This function *will not* release the message even on error return. If you use *PB_ENABLE_MALLOC*,
you will need to call `pb_release`_ yourself.
pb_decode_delimited
-------------------
Same as `pb_decode`_, except that it first reads a varint with the length of the message. ::
bool pb_decode_delimited(pb_istream_t *stream, const pb_field_t fields[], void *dest_struct);
(parameters are the same as for `pb_decode`_.)
A common method to indicate message size in Protocol Buffers is to prefix it with a varint.
This function is compatible with *writeDelimitedTo* in the Google's Protocol Buffers library.
pb_release
----------
Releases any dynamically allocated fields.
void pb_release(const pb_field_t fields[], void *dest_struct);
:fields: A field description array. Usually autogenerated.
:dest_struct: Pointer to structure where data will be stored.
This function is only available if *PB_ENABLE_MALLOC* is defined. It will release any
pointer type fields in the structure and set the pointers to NULL.
:stream: Input stream to read from. 1-10 bytes will be read.
:dest: Storage for the decoded integer. Value is undefined on error.
:returns: True on success, false if value exceeds uint64_t range or an IO error happens.
pb_skip_varint
--------------
@@ -650,106 +467,127 @@ Skip a varint-length-prefixed string. This means skipping a value with wire type
:stream: Input stream to read from.
:returns: True on success, false on IO error or length exceeding uint32_t.
pb_decode_tag
-------------
Decode the tag that comes before field in the protobuf encoding::
pb_decode
---------
Read and decode all fields of a structure. Reads until EOF on input stream. ::
bool pb_decode_tag(pb_istream_t *stream, pb_wire_type_t *wire_type, int *tag, bool *eof);
bool pb_decode(pb_istream_t *stream, const pb_message_t *msg, void *dest_struct);
:stream: Input stream to read from.
:wire_type: Pointer to variable where to store the wire type of the field.
:tag: Pointer to variable where to store the tag of the field.
:eof: Pointer to variable where to store end-of-file status.
:returns: True on success, false on error or EOF.
:msg: A message descriptor. Usually autogenerated.
:dest_struct: Pointer to structure where data will be stored.
:returns: True on success, false on IO error, on detectable errors in field description, if a field encoder returns false or if a required field is missing.
When the message (stream) ends, this function will return false and set *eof* to true. On other
errors, *eof* will be set to false.
In Protocol Buffers binary format, EOF is only allowed between fields. If it happens anywhere else, pb_decode will return *false*. If pb_decode returns false, you cannot trust any of the data in the structure.
pb_skip_field
-------------
Remove the data for a field from the stream, without actually decoding it::
In addition to EOF, the pb_decode implementation supports terminating a message with a 0 byte. This is compatible with the official Protocol Buffers because 0 is never a valid field tag.
bool pb_skip_field(pb_istream_t *stream, pb_wire_type_t wire_type);
For optional fields, this function applies the default value and clears the corresponding bit in *has_fields* if the field is not present.
:stream: Input stream to read from.
:wire_type: Type of field to skip.
:returns: True on success, false on IO error.
pb_clean
--------
Release and clear all the unused pointers of a structure. ::
.. sidebar:: Decoding fields manually
bool pb_clean(const pb_message_t *msg, void *dest_struct);
:msg: A message descriptor. Usually autogenerated.
:dest_struct: Pointer to structure to be cleaned.
:returns: True on success, false if one of the unused message fields has a pointer type that this function cannot handle.
For each string or submessage with pointer type, this function calls *free()* on the pointer and sets the pointer to NULL.
For bytes fields with pointer type, this function calls *free()* on the allocated data, nulls that pointer and zeros the size fields in the generated pb_bytes_t structure.
For repeated fields, it applies the corresponding operation above to each unused element of the generated array.
.. sidebar:: Field decoders
The functions with names beginning with *pb_decode_* are used when dealing with callback fields. The typical reason for using callbacks is to have an array of unlimited size. In that case, `pb_decode`_ will call your callback function repeatedly, which can then store the values into e.g. filesystem in the order received in.
The functions with names beginning with *pb_dec_* are called field decoders. Each PB_LTYPE has an own field decoder, which handles translating from Protocol Buffers data to C data.
For decoding numeric (including enumerated and boolean) values, use `pb_decode_varint`_, `pb_decode_svarint`_, `pb_decode_fixed32`_ and `pb_decode_fixed64`_. They take a pointer to a 32- or 64-bit C variable, which you may then cast to smaller datatype for storage.
Each field decoder reads and decodes a single value. For arrays, the decoder is called repeatedly.
For decoding strings and bytes fields, the length has already been decoded. You can therefore check the total length in *stream->bytes_left* and read the data using `pb_read`_.
You can use the decoders from your callbacks. Just be aware that the pb_field_t passed to the callback is not directly compatible with most of the field decoders. Instead, you must create a new pb_field_t structure and set the data_size according to the data type you pass to *dest*.
Finally, for decoding submessages in a callback, simply use `pb_decode`_ and pass it the *SubMessage_fields* descriptor array.
pb_dec_varint
-------------
Field decoder for PB_LTYPE_VARINT. ::
pb_decode_varint
----------------
Read and decode a varint_ encoded integer. ::
bool pb_decode_varint(pb_istream_t *stream, uint64_t *dest);
bool pb_dec_varint(pb_istream_t *stream, const pb_field_t *field, void *dest)
:stream: Input stream to read from. 1-10 bytes will be read.
:dest: Storage for the decoded integer. Value is undefined on error.
:returns: True on success, false if value exceeds uint64_t range or an IO error happens.
:field: Field description structure. Only *field->data_size* matters.
:dest: Pointer to destination integer. Must have size of *field->data_size* bytes.
:returns: True on success, false on IO errors or if `pb_decode_varint`_ fails.
pb_decode_svarint
-----------------
Similar to `pb_decode_varint`_, except that it performs zigzag-decoding on the value. This corresponds to the Protocol Buffers *sint32* and *sint64* datatypes. ::
This function first calls `pb_decode_varint`_. It then copies the first bytes of the 64-bit result value to *dest*, or on big endian architectures, the last bytes.
bool pb_decode_svarint(pb_istream_t *stream, int64_t *dest);
pb_dec_svarint
--------------
Field decoder for PB_LTYPE_SVARINT. Similar to `pb_dec_varint`_, except that it performs zigzag-decoding on the value. ::
(parameters are the same as `pb_decode_varint`_)
bool pb_dec_svarint(pb_istream_t *stream, const pb_field_t *field, void *dest);
pb_decode_fixed32
-----------------
Decode a *fixed32*, *sfixed32* or *float* value. ::
(parameters are the same as `pb_dec_varint`_)
bool pb_decode_fixed32(pb_istream_t *stream, void *dest);
pb_dec_fixed32
--------------
Field decoder for PB_LTYPE_FIXED32. ::
:stream: Input stream to read from. 4 bytes will be read.
:dest: Pointer to destination *int32_t*, *uint32_t* or *float*.
:returns: True on success, false on IO errors.
bool pb_dec_fixed(pb_istream_t *stream, const pb_field_t *field, void *dest);
:stream: Input stream to read from. 1-10 bytes will be read.
:field: Not used.
:dest: Pointer to destination integer. Must have size of *field->data_size* bytes.
:returns: True on success, false on IO errors or if `pb_decode_varint`_ fails.
This function reads 4 bytes from the input stream.
On big endian architectures, it then reverses the order of the bytes.
Finally, it writes the bytes to *dest*.
pb_decode_fixed64
-----------------
Decode a *fixed64*, *sfixed64* or *double* value. ::
pb_dec_fixed64
--------------
Field decoder for PB_LTYPE_FIXED64. ::
bool pb_dec_fixed(pb_istream_t *stream, const pb_field_t *field, void *dest);
:stream: Input stream to read from. 8 bytes will be read.
:field: Not used.
:dest: Pointer to destination *int64_t*, *uint64_t* or *double*.
:returns: True on success, false on IO errors.
Same as `pb_dec_fixed32`_, except this reads 8 bytes.
Same as `pb_decode_fixed32`_, except this reads 8 bytes.
pb_dec_bytes
------------
Field decoder for PB_LTYPE_BYTES. Reads a length-prefixed block of bytes. ::
pb_make_string_substream
------------------------
Decode the length for a field with wire type *PB_WT_STRING* and create a substream for reading the data. ::
bool pb_dec_bytes(pb_istream_t *stream, const pb_field_t *field, void *dest);
bool pb_make_string_substream(pb_istream_t *stream, pb_istream_t *substream);
:stream: Input stream to read from.
:field: Field description structure. Only *field->data_size* matters.
:dest: Pointer to a structure similar to pb_bytes_array_t.
:returns: True on success, false on IO error or if length exceeds the array size.
:stream: Original input stream to read the length and data from.
:substream: New substream that has limited length. Filled in by the function.
:returns: True on success, false if reading the length fails.
This function expects a pointer to a structure with a *size_t* field at start, and a variable sized byte array after it. It will deduce the maximum size of the array from *field->data_size*.
This function uses `pb_decode_varint`_ to read an integer from the stream. This is interpreted as a number of bytes, and the substream is set up so that its `bytes_left` is initially the same as the length, and its callback function and state the same as the parent stream.
pb_dec_string
-------------
Field decoder for PB_LTYPE_STRING. Reads a length-prefixed string. ::
pb_close_string_substream
-------------------------
Close the substream created with `pb_make_string_substream`_. ::
bool pb_dec_string(pb_istream_t *stream, const pb_field_t *field, void *dest);
void pb_close_string_substream(pb_istream_t *stream, pb_istream_t *substream);
:stream: Input stream to read from.
:field: Field description structure. Only *field->data_size* matters.
:dest: Pointer to a character array of size *field->data_size*.
:returns: True on success, false on IO error or if length exceeds the array size.
:stream: Original input stream to read the length and data from.
:substream: Substream to close
This function null-terminates the string when successful. On error, the contents of the destination array is undefined.
pb_dec_submessage
-----------------
Field decoder for PB_LTYPE_SUBMESSAGE. Calls `pb_decode`_ to perform the actual decoding. ::
bool pb_dec_submessage(pb_istream_t *stream, const pb_field_t *field, void *dest)
:stream: Input stream to read from.
:field: Field description structure. Only *field->ptr* matters.
:dest: Pointer to the destination structure.
:returns: True on success, false on IO error or if `pb_decode`_ fails.
The *field->ptr* should be a pointer to *pb_message_t* describing the submessage.
This function copies back the state from the substream to the parent stream.
It must be called after done with the substream.

79
docs/security.rst
View File

@@ -1,79 +0,0 @@
======================
Nanopb: Security model
======================
.. include :: menu.rst
.. contents ::
Importance of security in a Protocol Buffers library
====================================================
In the context of protocol buffers, security comes into play when decoding
untrusted data. Naturally, if the attacker can modify the contents of a
protocol buffers message, he can feed the application any values possible.
Therefore the application itself must be prepared to receive untrusted values.
Where nanopb plays a part is preventing the attacker from running arbitrary
code on the target system. Mostly this means that there must not be any
possibility to cause buffer overruns, memory corruption or invalid pointers
by the means of crafting a malicious message.
Division of trusted and untrusted data
======================================
The following data is regarded as **trusted**. It must be under the control of
the application writer. Malicious data in these structures could cause
security issues, such as execution of arbitrary code:
1. Callback and extension fields in message structures given to pb_encode()
and pb_decode(). These fields are memory pointers, and are generated
depending on the .proto file.
2. The automatically generated field definitions, i.e. *pb_field_t* lists.
3. Contents of the *pb_istream_t* and *pb_ostream_t* structures (this does not
mean the contents of the stream itself, just the stream definition).
The following data is regarded as **untrusted**. Invalid/malicious data in
these will cause "garbage in, garbage out" behaviour. It will not cause
buffer overflows, information disclosure or other security problems:
1. All data read from *pb_istream_t*.
2. All fields in message structures, except callbacks and extensions.
(Beginning with nanopb-0.2.4, in earlier versions the field sizes are partially unchecked.)
Invariants
==========
The following invariants are maintained during operation, even if the
untrusted data has been maliciously crafted:
1. Nanopb will never read more than *bytes_left* bytes from *pb_istream_t*.
2. Nanopb will never write more than *max_size* bytes to *pb_ostream_t*.
3. Nanopb will never access memory out of bounds of the message structure.
4. After pb_decode() returns successfully, the message structure will be
internally consistent:
- The *count* fields of arrays will not exceed the array size.
- The *size* field of bytes will not exceed the allocated size.
- All string fields will have null terminator.
5. After pb_encode() returns successfully, the resulting message is a valid
protocol buffers message. (Except if user-defined callbacks write incorrect
data.)
Further considerations
======================
Even if the nanopb library is free of any security issues, there are still
several possible attack vectors that the application author must consider.
The following list is not comprehensive:
1. Stack usage may depend on the contents of the message. The message
definition places an upper bound on how much stack will be used. Tests
should be run with all fields present, to record the maximum possible
stack usage.
2. Callbacks can do anything. The code for the callbacks must be carefully
checked if they are used with untrusted data.
3. If using stream input, a maximum size should be set in *pb_istream_t* to
stop a denial of service attack from using an infinite message.
4. If using network sockets as streams, a timeout should be set to stop
denial of service attacks.

14
example/Makefile Normal file
View File

@@ -0,0 +1,14 @@
CFLAGS=-ansi -Wall -Werror -I .. -g -O0
DEPS=../pb_decode.c ../pb_decode.h ../pb_encode.c ../pb_encode.h ../pb.h
all: server client
clean:
rm -f server client fileproto.pb.c fileproto.pb.h
%: %.c $(DEPS) fileproto.pb.h fileproto.pb.c
$(CC) $(CFLAGS) -o $@ $< ../pb_decode.c ../pb_encode.c fileproto.pb.c common.c
fileproto.pb.c fileproto.pb.h: fileproto.proto ../generator/nanopb_generator.py
protoc -I. -I../generator -I/usr/include -ofileproto.pb $<
python ../generator/nanopb_generator.py fileproto.pb

116
example/client.c Normal file
View File

@@ -0,0 +1,116 @@
/* This is a simple TCP client that connects to port 1234 and prints a list
* of files in a given directory.
*
* It directly deserializes and serializes messages from network, minimizing
* memory use.
*
* For flexibility, this example is implemented using posix api.
* In a real embedded system you would typically use some other kind of
* a communication and filesystem layer.
*/
#include <sys/socket.h>
#include <sys/types.h>
#include <netinet/in.h>
#include <unistd.h>
#include <dirent.h>
#include <stdio.h>
#include <string.h>
#include <pb_encode.h>
#include <pb_decode.h>
#include "fileproto.pb.h"
#include "common.h"
bool printfile_callback(pb_istream_t *stream, const pb_field_t *field, void *arg)
{
FileInfo fileinfo;
if (!pb_decode(stream, FileInfo_msg, &fileinfo))
return false;
printf("%-10lld %s\n", fileinfo.inode, fileinfo.name);
return true;
}
bool listdir(int fd, char *path)
{
ListFilesRequest request;
ListFilesResponse response;
pb_istream_t input = pb_istream_from_socket(fd);
pb_ostream_t output = pb_ostream_from_socket(fd);
uint8_t zero = 0;
if (path == NULL)
{
ListFilesRequest_clear(request, path);
}
else
{
ListFilesRequest_set(request, path);
if (strlen(path) + 1 > sizeof(request.path))
{
fprintf(stderr, "Too long path.\n");
return false;
}
strcpy(request.path, path);
}
if (!pb_encode(&output, ListFilesRequest_msg, &request))
{
fprintf(stderr, "Encoding failed.\n");
return false;
}
/* We signal the end of request with a 0 tag. */
pb_write(&output, &zero, 1);
response.file.funcs.decode = &printfile_callback;
if (!pb_decode(&input, ListFilesResponse_msg, &response))
{
fprintf(stderr, "Decoding failed.\n");
return false;
}
if (response.path_error)
{
fprintf(stderr, "Server reported error.\n");
return false;
}
return true;
}
int main(int argc, char **argv)
{
int sockfd;
struct sockaddr_in servaddr;
char *path = NULL;
if (argc > 1)
path = argv[1];
sockfd = socket(AF_INET, SOCK_STREAM, 0);
memset(&servaddr, 0, sizeof(servaddr));
servaddr.sin_family = AF_INET;
servaddr.sin_addr.s_addr = htonl(INADDR_LOOPBACK);
servaddr.sin_port = htons(1234);
if (connect(sockfd, (struct sockaddr *)&servaddr, sizeof(servaddr)) != 0)
{
perror("connect");
return 1;
}
if (!listdir(sockfd, path))
return 2;
close(sockfd);
return 0;
}

17
examples/network_server/common.c → example/common.c
View File

@@ -10,15 +10,24 @@
static bool write_callback(pb_ostream_t *stream, const uint8_t *buf, size_t count)
{
int fd = (intptr_t)stream->state;
int fd = (int)stream->state;
return send(fd, buf, count, 0) == count;
}
static bool read_callback(pb_istream_t *stream, uint8_t *buf, size_t count)
{
int fd = (intptr_t)stream->state;
int fd = (int)stream->state;
int result;
if (buf == NULL)
{
/* Well, this is a really inefficient way to skip input. */
/* It is only used when there are unknown fields. */
char dummy;
while (count-- && recv(fd, &dummy, 1, 0) == 1);
return count == 0;
}
result = recv(fd, buf, count, MSG_WAITALL);
if (result == 0)
@@ -29,12 +38,12 @@ static bool read_callback(pb_istream_t *stream, uint8_t *buf, size_t count)
pb_ostream_t pb_ostream_from_socket(int fd)
{
pb_ostream_t stream = {&write_callback, (void*)(intptr_t)fd, SIZE_MAX, 0};
pb_ostream_t stream = {&write_callback, (void*)fd, SIZE_MAX, 0};
return stream;
}
pb_istream_t pb_istream_from_socket(int fd)
{
pb_istream_t stream = {&read_callback, (void*)(intptr_t)fd, SIZE_MAX};
pb_istream_t stream = {&read_callback, (void*)fd, SIZE_MAX};
return stream;
}

0
examples/network_server/common.h → example/common.h
View File

26
example/fileproto.proto Normal file
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@@ -0,0 +1,26 @@
import "nanopb.proto";
// This defines protocol for a simple server that lists files.
//
// If you come from high-level programming background, the hardcoded
// maximum lengths may disgust you. However, if your microcontroller only
// has a few kB of ram to begin with, setting reasonable limits for
// filenames is ok.
//
// On the other hand, using the callback interface, it is not necessary
// to set a limit on the number of files in the response.
message ListFilesRequest {
optional string path = 1 [default = "/", (nanopb).max_size = 128];
}
message FileInfo {
required uint64 inode = 1;
required string name = 2 [(nanopb).max_size = 128];
}
message ListFilesResponse {
optional bool path_error = 1 [default = false];
repeated FileInfo file = 2;
}

131
example/server.c Normal file
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@@ -0,0 +1,131 @@
/* This is a simple TCP server that listens on port 1234 and provides lists
* of files to clients, using a protocol defined in file_server.proto.
*
* It directly deserializes and serializes messages from network, minimizing
* memory use.
*
* For flexibility, this example is implemented using posix api.
* In a real embedded system you would typically use some other kind of
* a communication and filesystem layer.
*/
#include <sys/socket.h>
#include <sys/types.h>
#include <netinet/in.h>
#include <unistd.h>
#include <dirent.h>
#include <stdio.h>
#include <string.h>
#include <pb_encode.h>
#include <pb_decode.h>
#include "fileproto.pb.h"
#include "common.h"
bool listdir_callback(pb_ostream_t *stream, const pb_field_t *field, const void *arg)
{
DIR *dir = (DIR*) arg;
struct dirent *file;
FileInfo fileinfo;
while ((file = readdir(dir)) != NULL)
{
fileinfo.inode = file->d_ino;
strncpy(fileinfo.name, file->d_name, sizeof(fileinfo.name));
fileinfo.name[sizeof(fileinfo.name) - 1] = '\0';
if (!pb_encode_tag_for_field(stream, field))
return false;
if (!pb_enc_submessage(stream, field, &fileinfo))
return false;
}
return true;
}
void handle_connection(int connfd)
{
ListFilesRequest request;
ListFilesResponse response;
pb_istream_t input = pb_istream_from_socket(connfd);
pb_ostream_t output = pb_ostream_from_socket(connfd);
DIR *directory;
if (!pb_decode(&input, ListFilesRequest_msg, &request))
{
printf("Decoding failed.\n");
return;
}
directory = opendir(request.path);
printf("Listing directory: %s\n", request.path);
if (directory == NULL)
{
perror("opendir");
ListFilesResponse_set(response, path_error);
response.path_error = true;
response.file.funcs.encode = NULL;
}
else
{
ListFilesResponse_clear(response, path_error);
response.file.funcs.encode = &listdir_callback;
response.file.arg = directory;
}
if (!pb_encode(&output, ListFilesResponse_msg, &response))
{
printf("Encoding failed.\n");
}
}
int main(int argc, char **argv)
{
int listenfd, connfd;
struct sockaddr_in servaddr;
int reuse = 1;
listenfd = socket(AF_INET, SOCK_STREAM, 0);
setsockopt(listenfd, SOL_SOCKET, SO_REUSEADDR, &reuse, sizeof(reuse));
memset(&servaddr, 0, sizeof(servaddr));
servaddr.sin_family = AF_INET;
servaddr.sin_addr.s_addr = htonl(INADDR_LOOPBACK);
servaddr.sin_port = htons(1234);
if (bind(listenfd, (struct sockaddr*)&servaddr, sizeof(servaddr)) != 0)
{
perror("bind");
return 1;
}
if (listen(listenfd, 5) != 0)
{
perror("listen");
return 1;
}
for(;;)
{
connfd = accept(listenfd, NULL, NULL);
if (connfd < 0)
{
perror("accept");
return 1;
}
printf("Got connection.\n");
handle_connection(connfd);
printf("Closing connection.\n");
close(connfd);
}
}

17
examples/network_server/Makefile
View File

@@ -1,17 +0,0 @@
# Include the nanopb provided Makefile rules
include ../../extra/nanopb.mk
# Compiler flags to enable all warnings & debug info
CFLAGS = -ansi -Wall -Werror -g -O0
CFLAGS += -I$(NANOPB_DIR)
all: server client
.SUFFIXES:
clean:
rm -f server client fileproto.pb.c fileproto.pb.h
%: %.c common.c fileproto.pb.c
$(CC) $(CFLAGS) -o $@ $^ $(NANOPB_CORE)

60
examples/network_server/README.txt
View File

@@ -1,60 +0,0 @@
Nanopb example "network_server"
===============================
This example demonstrates the use of nanopb to communicate over network
connections. It consists of a server that sends file listings, and of
a client that requests the file list from the server.
Example usage
-------------
user@host:~/nanopb/examples/network_server$ make # Build the example
protoc -ofileproto.pb fileproto.proto
python ../../generator/nanopb_generator.py fileproto.pb
Writing to fileproto.pb.h and fileproto.pb.c
cc -ansi -Wall -Werror -I .. -g -O0 -I../.. -o server server.c
../../pb_decode.c ../../pb_encode.c fileproto.pb.c common.c
cc -ansi -Wall -Werror -I .. -g -O0 -I../.. -o client client.c
../../pb_decode.c ../../pb_encode.c fileproto.pb.c common.c
user@host:~/nanopb/examples/network_server$ ./server & # Start the server on background
[1] 24462
petteri@oddish:~/nanopb/examples/network_server$ ./client /bin # Request the server to list /bin
Got connection.
Listing directory: /bin
1327119 bzdiff
1327126 bzless
1327147 ps
1327178 ntfsmove
1327271 mv
1327187 mount
1327259 false
1327266 tempfile
1327285 zfgrep
1327165 gzexe
1327204 nc.openbsd
1327260 uname
Details of implementation
-------------------------
fileproto.proto contains the portable Google Protocol Buffers protocol definition.
It could be used as-is to implement a server or a client in any other language, for
example Python or Java.
fileproto.options contains the nanopb-specific options for the protocol file. This
sets the amount of space allocated for file names when decoding messages.
common.c/h contains functions that allow nanopb to read and write directly from
network socket. This way there is no need to allocate a separate buffer to store
the message.
server.c contains the code to open a listening socket, to respond to clients and
to list directory contents.
client.c contains the code to connect to a server, to send a request and to print
the response message.
The code is implemented using the POSIX socket api, but it should be easy enough
to port into any other socket api, such as lwip.

142
examples/network_server/client.c
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@@ -1,142 +0,0 @@
/* This is a simple TCP client that connects to port 1234 and prints a list
* of files in a given directory.
*
* It directly deserializes and serializes messages from network, minimizing
* memory use.
*
* For flexibility, this example is implemented using posix api.
* In a real embedded system you would typically use some other kind of
* a communication and filesystem layer.
*/
#include <sys/socket.h>
#include <sys/types.h>
#include <netinet/in.h>
#include <unistd.h>
#include <dirent.h>
#include <stdio.h>
#include <string.h>
#include <pb_encode.h>
#include <pb_decode.h>
#include "fileproto.pb.h"
#include "common.h"
/* This callback function will be called once for each filename received
* from the server. The filenames will be printed out immediately, so that
* no memory has to be allocated for them.
*/
bool printfile_callback(pb_istream_t *stream, const pb_field_t *field, void **arg)
{
FileInfo fileinfo = {};
if (!pb_decode(stream, FileInfo_fields, &fileinfo))
return false;
printf("%-10lld %s\n", (long long)fileinfo.inode, fileinfo.name);
return true;
}
/* This function sends a request to socket 'fd' to list the files in
* directory given in 'path'. The results received from server will
* be printed to stdout.
*/
bool listdir(int fd, char *path)
{
/* Construct and send the request to server */
{
ListFilesRequest request = {};
pb_ostream_t output = pb_ostream_from_socket(fd);
uint8_t zero = 0;
/* In our protocol, path is optional. If it is not given,
* the server will list the root directory. */
if (path == NULL)
{
request.has_path = false;
}
else
{
request.has_path = true;
if (strlen(path) + 1 > sizeof(request.path))
{
fprintf(stderr, "Too long path.\n");
return false;
}
strcpy(request.path, path);
}
/* Encode the request. It is written to the socket immediately
* through our custom stream. */
if (!pb_encode(&output, ListFilesRequest_fields, &request))
{
fprintf(stderr, "Encoding failed: %s\n", PB_GET_ERROR(&output));
return false;
}
/* We signal the end of request with a 0 tag. */
pb_write(&output, &zero, 1);
}
/* Read back the response from server */
{
ListFilesResponse response = {};
pb_istream_t input = pb_istream_from_socket(fd);
/* Give a pointer to our callback function, which will handle the
* filenames as they arrive. */
response.file.funcs.decode = &printfile_callback;
if (!pb_decode(&input, ListFilesResponse_fields, &response))
{
fprintf(stderr, "Decode failed: %s\n", PB_GET_ERROR(&input));
return false;
}
/* If the message from server decodes properly, but directory was
* not found on server side, we get path_error == true. */
if (response.path_error)
{
fprintf(stderr, "Server reported error.\n");
return false;
}
}
return true;
}
int main(int argc, char **argv)
{
int sockfd;
struct sockaddr_in servaddr;
char *path = NULL;
if (argc > 1)
path = argv[1];
sockfd = socket(AF_INET, SOCK_STREAM, 0);
/* Connect to server running on localhost:1234 */
memset(&servaddr, 0, sizeof(servaddr));
servaddr.sin_family = AF_INET;
servaddr.sin_addr.s_addr = htonl(INADDR_LOOPBACK);
servaddr.sin_port = htons(1234);
if (connect(sockfd, (struct sockaddr *)&servaddr, sizeof(servaddr)) != 0)
{
perror("connect");
return 1;
}
/* Send the directory listing request */
if (!listdir(sockfd, path))
return 2;
/* Close connection */
close(sockfd);
return 0;
}

13
examples/network_server/fileproto.options
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@@ -1,13 +0,0 @@
# This file defines the nanopb-specific options for the messages defined
# in fileproto.proto.
#
# If you come from high-level programming background, the hardcoded
# maximum lengths may disgust you. However, if your microcontroller only
# has a few kB of ram to begin with, setting reasonable limits for
# filenames is ok.
#
# On the other hand, using the callback interface, it is not necessary
# to set a limit on the number of files in the response.
ListFilesRequest.path max_size:128
FileInfo.name max_size:128

18
examples/network_server/fileproto.proto
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@@ -1,18 +0,0 @@
// This defines protocol for a simple server that lists files.
//
// See also the nanopb-specific options in fileproto.options.
message ListFilesRequest {
optional string path = 1 [default = "/"];
}
message FileInfo {
required uint64 inode = 1;
required string name = 2;
}
message ListFilesResponse {
optional bool path_error = 1 [default = false];
repeated FileInfo file = 2;
}

158
examples/network_server/server.c
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@@ -1,158 +0,0 @@
/* This is a simple TCP server that listens on port 1234 and provides lists
* of files to clients, using a protocol defined in file_server.proto.
*
* It directly deserializes and serializes messages from network, minimizing
* memory use.
*
* For flexibility, this example is implemented using posix api.
* In a real embedded system you would typically use some other kind of
* a communication and filesystem layer.
*/
#include <sys/socket.h>
#include <sys/types.h>
#include <netinet/in.h>
#include <unistd.h>
#include <dirent.h>
#include <stdio.h>
#include <string.h>
#include <pb_encode.h>
#include <pb_decode.h>
#include "fileproto.pb.h"
#include "common.h"
/* This callback function will be called once during the encoding.
* It will write out any number of FileInfo entries, without consuming unnecessary memory.
* This is accomplished by fetching the filenames one at a time and encoding them
* immediately.
*/
bool listdir_callback(pb_ostream_t *stream, const pb_field_t *field, void * const *arg)
{
DIR *dir = (DIR*) *arg;
struct dirent *file;
FileInfo fileinfo = {};
while ((file = readdir(dir)) != NULL)
{
fileinfo.inode = file->d_ino;
strncpy(fileinfo.name, file->d_name, sizeof(fileinfo.name));
fileinfo.name[sizeof(fileinfo.name) - 1] = '\0';
/* This encodes the header for the field, based on the constant info
* from pb_field_t. */
if (!pb_encode_tag_for_field(stream, field))
return false;
/* This encodes the data for the field, based on our FileInfo structure. */
if (!pb_encode_submessage(stream, FileInfo_fields, &fileinfo))
return false;
}
return true;
}
/* Handle one arriving client connection.
* Clients are expected to send a ListFilesRequest, terminated by a '0'.
* Server will respond with a ListFilesResponse message.
*/
void handle_connection(int connfd)
{
DIR *directory = NULL;
/* Decode the message from the client and open the requested directory. */
{
ListFilesRequest request = {};
pb_istream_t input = pb_istream_from_socket(connfd);
if (!pb_decode(&input, ListFilesRequest_fields, &request))
{
printf("Decode failed: %s\n", PB_GET_ERROR(&input));
return;
}
directory = opendir(request.path);
printf("Listing directory: %s\n", request.path);
}
/* List the files in the directory and transmit the response to client */
{
ListFilesResponse response = {};
pb_ostream_t output = pb_ostream_from_socket(connfd);
if (directory == NULL)
{
perror("opendir");
/* Directory was not found, transmit error status */
response.has_path_error = true;
response.path_error = true;
response.file.funcs.encode = NULL;
}
else
{
/* Directory was found, transmit filenames */
response.has_path_error = false;
response.file.funcs.encode = &listdir_callback;
response.file.arg = directory;
}
if (!pb_encode(&output, ListFilesResponse_fields, &response))
{
printf("Encoding failed: %s\n", PB_GET_ERROR(&output));
}
}
if (directory != NULL)
closedir(directory);
}
int main(int argc, char **argv)
{
int listenfd, connfd;
struct sockaddr_in servaddr;
int reuse = 1;
/* Listen on localhost:1234 for TCP connections */
listenfd = socket(AF_INET, SOCK_STREAM, 0);
setsockopt(listenfd, SOL_SOCKET, SO_REUSEADDR, &reuse, sizeof(reuse));
memset(&servaddr, 0, sizeof(servaddr));
servaddr.sin_family = AF_INET;
servaddr.sin_addr.s_addr = htonl(INADDR_LOOPBACK);
servaddr.sin_port = htons(1234);
if (bind(listenfd, (struct sockaddr*)&servaddr, sizeof(servaddr)) != 0)
{
perror("bind");
return 1;
}
if (listen(listenfd, 5) != 0)
{
perror("listen");
return 1;
}
for(;;)
{
/* Wait for a client */
connfd = accept(listenfd, NULL, NULL);
if (connfd < 0)
{
perror("accept");
return 1;
}
printf("Got connection.\n");
handle_connection(connfd);
printf("Closing connection.\n");
close(connfd);
}
return 0;
}

22
examples/simple/Makefile
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@@ -1,22 +0,0 @@
# Include the nanopb provided Makefile rules
include ../../extra/nanopb.mk
# Compiler flags to enable all warnings & debug info
CFLAGS = -Wall -Werror -g -O0
CFLAGS += -I$(NANOPB_DIR)
# C source code files that are required
CSRC = simple.c # The main program
CSRC += simple.pb.c # The compiled protocol definition
CSRC += $(NANOPB_DIR)/pb_encode.c # The nanopb encoder
CSRC += $(NANOPB_DIR)/pb_decode.c # The nanopb decoder
CSRC += $(NANOPB_DIR)/pb_common.c # The nanopb common parts
# Build rule for the main program
simple: $(CSRC)
$(CC) $(CFLAGS) -osimple $(CSRC)
# Build rule for the protocol
simple.pb.c: simple.proto
$(PROTOC) $(PROTOC_OPTS) --nanopb_out=. simple.proto

29
examples/simple/README.txt
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@@ -1,29 +0,0 @@
Nanopb example "simple"
=======================
This example demonstrates the very basic use of nanopb. It encodes and
decodes a simple message.
The code uses four different API functions:
* pb_ostream_from_buffer() to declare the output buffer that is to be used
* pb_encode() to encode a message
* pb_istream_from_buffer() to declare the input buffer that is to be used
* pb_decode() to decode a message
Example usage
-------------
On Linux, simply type "make" to build the example. After that, you can
run it with the command: ./simple
On other platforms, you first have to compile the protocol definition using
the following command::
../../generator-bin/protoc --nanopb_out=. simple.proto
After that, add the following four files to your project and compile:
simple.c simple.pb.c pb_encode.c pb_decode.c

68
examples/simple/simple.c
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@@ -1,68 +0,0 @@
#include <stdio.h>
#include <pb_encode.h>
#include <pb_decode.h>
#include "simple.pb.h"
int main()
{
/* This is the buffer where we will store our message. */
uint8_t buffer[128];
size_t message_length;
bool status;
/* Encode our message */
{
/* Allocate space on the stack to store the message data.
*
* Nanopb generates simple struct definitions for all the messages.
* - check out the contents of simple.pb.h! */
SimpleMessage message;
/* Create a stream that will write to our buffer. */
pb_ostream_t stream = pb_ostream_from_buffer(buffer, sizeof(buffer));
/* Fill in the lucky number */
message.lucky_number = 13;
/* Now we are ready to encode the message! */
status = pb_encode(&stream, SimpleMessage_fields, &message);
message_length = stream.bytes_written;
/* Then just check for any errors.. */
if (!status)
{
printf("Encoding failed: %s\n", PB_GET_ERROR(&stream));
return 1;
}
}
/* Now we could transmit the message over network, store it in a file or
* wrap it to a pigeon's leg.
*/
/* But because we are lazy, we will just decode it immediately. */
{
/* Allocate space for the decoded message. */
SimpleMessage message;
/* Create a stream that reads from the buffer. */
pb_istream_t stream = pb_istream_from_buffer(buffer, message_length);
/* Now we are ready to decode the message. */
status = pb_decode(&stream, SimpleMessage_fields, &message);
/* Check for errors... */
if (!status)
{
printf("Decoding failed: %s\n", PB_GET_ERROR(&stream));
return 1;
}
/* Print the data contained in the message. */
printf("Your lucky number was %d!\n", message.lucky_number);
}
return 0;
}

7
examples/simple/simple.proto
View File

@@ -1,7 +0,0 @@
// A very simple protocol definition, consisting of only
// one message.
message SimpleMessage {
required int32 lucky_number = 1;
}

24
examples/using_double_on_avr/Makefile
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@@ -1,24 +0,0 @@
# Include the nanopb provided Makefile rules
include ../../extra/nanopb.mk
# Compiler flags to enable all warnings & debug info
CFLAGS = -Wall -Werror -g -O0
CFLAGS += -I$(NANOPB_DIR)
all: run_tests
.SUFFIXES:
clean:
rm -f test_conversions encode_double decode_double doubleproto.pb.c doubleproto.pb.h
test_conversions: test_conversions.c double_conversion.c
$(CC) $(CFLAGS) -o $@ $^
%: %.c double_conversion.c doubleproto.pb.c
$(CC) $(CFLAGS) -o $@ $^ $(NANOPB_CORE)
run_tests: test_conversions encode_double decode_double
./test_conversions
./encode_double | ./decode_double

25
examples/using_double_on_avr/README.txt
View File

@@ -1,25 +0,0 @@
Nanopb example "using_double_on_avr"
====================================
Some processors/compilers, such as AVR-GCC, do not support the double
datatype. Instead, they have sizeof(double) == 4. Because protocol
binary format uses the double encoding directly, this causes trouble
if the protocol in .proto requires double fields.
This directory contains a solution to this problem. It uses uint64_t
to store the raw wire values, because its size is correct on all
platforms. The file double_conversion.c provides functions that
convert these values to/from floats, without relying on compiler
support.
To use this method, you need to make some modifications to your code:
1) Change all 'double' fields into 'fixed64' in the .proto.
2) Whenever writing to a 'double' field, use float_to_double().
3) Whenever reading a 'double' field, use double_to_float().
The conversion routines are as accurate as the float datatype can
be. Furthermore, they should handle all special values (NaN, inf, denormalized
numbers) correctly. There are testcases in test_conversions.c.

33
examples/using_double_on_avr/decode_double.c
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@@ -1,33 +0,0 @@
/* Decodes a double value into a float variable.
* Used to read double values with AVR code, which doesn't support double directly.
*/
#include <stdio.h>
#include <pb_decode.h>
#include "double_conversion.h"
#include "doubleproto.pb.h"
int main()
{
uint8_t buffer[32];
size_t count = fread(buffer, 1, sizeof(buffer), stdin);
pb_istream_t stream = pb_istream_from_buffer(buffer, count);
AVRDoubleMessage message;
pb_decode(&stream, AVRDoubleMessage_fields, &message);
float v1 = double_to_float(message.field1);
float v2 = double_to_float(message.field2);
printf("Values: %f %f\n", v1, v2);
if (v1 == 1234.5678f &&
v2 == 0.00001f)
{
return 0;
}
else
{
return 1;
}
}

123
examples/using_double_on_avr/double_conversion.c
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@@ -1,123 +0,0 @@
/* Conversion routines for platforms that do not support 'double' directly. */
#include "double_conversion.h"
#include <math.h>
typedef union {
float f;
uint32_t i;
} conversion_t;
/* Note: IEE 754 standard specifies float formats as follows:
* Single precision: sign, 8-bit exp, 23-bit frac.
* Double precision: sign, 11-bit exp, 52-bit frac.
*/
uint64_t float_to_double(float value)
{
conversion_t in;
in.f = value;
uint8_t sign;
int16_t exponent;
uint64_t mantissa;
/* Decompose input value */
sign = (in.i >> 31) & 1;
exponent = ((in.i >> 23) & 0xFF) - 127;
mantissa = in.i & 0x7FFFFF;
if (exponent == 128)
{
/* Special value (NaN etc.) */
exponent = 1024;
}
else if (exponent == -127)
{
if (!mantissa)
{
/* Zero */
exponent = -1023;
}
else
{
/* Denormalized */
mantissa <<= 1;
while (!(mantissa & 0x800000))
{
mantissa <<= 1;
exponent--;
}
mantissa &= 0x7FFFFF;
}
}
/* Combine fields */
mantissa <<= 29;
mantissa |= (uint64_t)(exponent + 1023) << 52;
mantissa |= (uint64_t)sign << 63;
return mantissa;
}
float double_to_float(uint64_t value)
{
uint8_t sign;
int16_t exponent;
uint32_t mantissa;
conversion_t out;
/* Decompose input value */
sign = (value >> 63) & 1;
exponent = ((value >> 52) & 0x7FF) - 1023;
mantissa = (value >> 28) & 0xFFFFFF; /* Highest 24 bits */
/* Figure if value is in range representable by floats. */
if (exponent == 1024)
{
/* Special value */
exponent = 128;
}
else if (exponent > 127)
{
/* Too large */
if (sign)
return -INFINITY;
else
return INFINITY;
}
else if (exponent < -150)
{
/* Too small */
if (sign)
return -0.0f;
else
return 0.0f;
}
else if (exponent < -126)
{
/* Denormalized */
mantissa |= 0x1000000;
mantissa >>= (-126 - exponent);
exponent = -127;
}
/* Round off mantissa */
mantissa = (mantissa + 1) >> 1;
/* Check if mantissa went over 2.0 */
if (mantissa & 0x800000)
{
exponent += 1;
mantissa &= 0x7FFFFF;
mantissa >>= 1;
}
/* Combine fields */
out.i = mantissa;
out.i |= (uint32_t)(exponent + 127) << 23;
out.i |= (uint32_t)sign << 31;
return out.f;
}

26
examples/using_double_on_avr/double_conversion.h
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@@ -1,26 +0,0 @@
/* AVR-GCC does not have real double datatype. Instead its double
* is equal to float, i.e. 32 bit value. If you need to communicate
* with other systems that use double in their .proto files, you
* need to do some conversion.
*
* These functions use bitwise operations to mangle floats into doubles
* and then store them in uint64_t datatype.
*/
#ifndef DOUBLE_CONVERSION
#define DOUBLE_CONVERSION
#include <stdint.h>
/* Convert native 4-byte float into a 8-byte double. */
extern uint64_t float_to_double(float value);
/* Convert 8-byte double into native 4-byte float.
* Values are rounded to nearest, 0.5 away from zero.
* Overflowing values are converted to Inf or -Inf.
*/
extern float double_to_float(uint64_t value);
#endif

13
examples/using_double_on_avr/doubleproto.proto
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@@ -1,13 +0,0 @@
// A message containing doubles, as used by other applications.
message DoubleMessage {
required double field1 = 1;
required double field2 = 2;
}
// A message containing doubles, but redefined using uint64_t.
// For use in AVR code.
message AVRDoubleMessage {
required fixed64 field1 = 1;
required fixed64 field2 = 2;
}

25
examples/using_double_on_avr/encode_double.c
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@@ -1,25 +0,0 @@
/* Encodes a float value into a double on the wire.
* Used to emit doubles from AVR code, which doesn't support double directly.
*/
#include <stdio.h>
#include <pb_encode.h>
#include "double_conversion.h"
#include "doubleproto.pb.h"
int main()
{
AVRDoubleMessage message = {
float_to_double(1234.5678f),
float_to_double(0.00001f)
};
uint8_t buffer[32];
pb_ostream_t stream = pb_ostream_from_buffer(buffer, sizeof(buffer));
pb_encode(&stream, AVRDoubleMessage_fields, &message);
fwrite(buffer, 1, stream.bytes_written, stdout);
return 0;
}

56
examples/using_double_on_avr/test_conversions.c
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@@ -1,56 +0,0 @@
#include "double_conversion.h"
#include <math.h>
#include <stdio.h>
static const double testvalues[] = {
0.0, -0.0, 0.1, -0.1,
M_PI, -M_PI, 123456.789, -123456.789,
INFINITY, -INFINITY, NAN, INFINITY - INFINITY,
1e38, -1e38, 1e39, -1e39,
1e-38, -1e-38, 1e-39, -1e-39,
3.14159e-37,-3.14159e-37, 3.14159e-43, -3.14159e-43,
1e-60, -1e-60, 1e-45, -1e-45,
0.99999999999999, -0.99999999999999, 127.999999999999, -127.999999999999
};
#define TESTVALUES_COUNT (sizeof(testvalues)/sizeof(testvalues[0]))
int main()
{
int status = 0;
int i;
for (i = 0; i < TESTVALUES_COUNT; i++)
{
double orig = testvalues[i];
float expected_float = (float)orig;
double expected_double = (double)expected_float;
float got_float = double_to_float(*(uint64_t*)&orig);
uint64_t got_double = float_to_double(got_float);
uint32_t e1 = *(uint32_t*)&expected_float;
uint32_t g1 = *(uint32_t*)&got_float;
uint64_t e2 = *(uint64_t*)&expected_double;
uint64_t g2 = got_double;
if (g1 != e1)
{
printf("%3d double_to_float fail: %08x != %08x\n", i, g1, e1);
status = 1;
}
if (g2 != e2)
{
printf("%3d float_to_double fail: %016llx != %016llx\n", i,
(unsigned long long)g2,
(unsigned long long)e2);
status = 1;
}
}
return status;
}

20
examples/using_union_messages/Makefile
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@@ -1,20 +0,0 @@
# Include the nanopb provided Makefile rules
include ../../extra/nanopb.mk
# Compiler flags to enable all warnings & debug info
CFLAGS = -ansi -Wall -Werror -g -O0
CFLAGS += -I$(NANOPB_DIR)
all: encode decode
./encode 1 | ./decode
./encode 2 | ./decode
./encode 3 | ./decode
.SUFFIXES:
clean:
rm -f encode unionproto.pb.h unionproto.pb.c
%: %.c unionproto.pb.c
$(CC) $(CFLAGS) -o $@ $^ $(NANOPB_CORE)

52
examples/using_union_messages/README.txt
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@@ -1,52 +0,0 @@
Nanopb example "using_union_messages"
=====================================
Union messages is a common technique in Google Protocol Buffers used to
represent a group of messages, only one of which is passed at a time.
It is described in Google's documentation:
https://developers.google.com/protocol-buffers/docs/techniques#union
This directory contains an example on how to encode and decode union messages
with minimal memory usage. Usually, nanopb would allocate space to store
all of the possible messages at the same time, even though at most one of
them will be used at a time.
By using some of the lower level nanopb APIs, we can manually generate the
top level message, so that we only need to allocate the one submessage that
we actually want. Similarly when decoding, we can manually read the tag of
the top level message, and only then allocate the memory for the submessage
after we already know its type.
Example usage
-------------
Type `make` to run the example. It will build it and run commands like
following:
./encode 1 | ./decode
Got MsgType1: 42
./encode 2 | ./decode
Got MsgType2: true
./encode 3 | ./decode
Got MsgType3: 3 1415
This simply demonstrates that the "decode" program has correctly identified
the type of the received message, and managed to decode it.
Details of implementation
-------------------------
unionproto.proto contains the protocol used in the example. It consists of
three messages: MsgType1, MsgType2 and MsgType3, which are collected together
into UnionMessage.
encode.c takes one command line argument, which should be a number 1-3. It
then fills in and encodes the corresponding message, and writes it to stdout.
decode.c reads a UnionMessage from stdin. Then it calls the function
decode_unionmessage_type() to determine the type of the message. After that,
the corresponding message is decoded and the contents of it printed to the
screen.

96
examples/using_union_messages/decode.c
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@@ -1,96 +0,0 @@
/* This program reads a message from stdin, detects its type and decodes it.
*/
#include <stdio.h>
#include <string.h>
#include <stdlib.h>
#include <pb_decode.h>
#include "unionproto.pb.h"
/* This function reads manually the first tag from the stream and finds the
* corresponding message type. It doesn't yet decode the actual message.
*
* Returns a pointer to the MsgType_fields array, as an identifier for the
* message type. Returns null if the tag is of unknown type or an error occurs.
*/
const pb_field_t* decode_unionmessage_type(pb_istream_t *stream)
{
pb_wire_type_t wire_type;
uint32_t tag;
bool eof;
while (pb_decode_tag(stream, &wire_type, &tag, &eof))
{
if (wire_type == PB_WT_STRING)
{
const pb_field_t *field;
for (field = UnionMessage_fields; field->tag != 0; field++)
{
if (field->tag == tag && (field->type & PB_LTYPE_SUBMESSAGE))
{
/* Found our field. */
return field->ptr;
}
}
}
/* Wasn't our field.. */
pb_skip_field(stream, wire_type);
}
return NULL;
}
bool decode_unionmessage_contents(pb_istream_t *stream, const pb_field_t fields[], void *dest_struct)
{
pb_istream_t substream;
bool status;
if (!pb_make_string_substream(stream, &substream))
return false;
status = pb_decode(&substream, fields, dest_struct);
pb_close_string_substream(stream, &substream);
return status;
}
int main()
{
/* Read the data into buffer */
uint8_t buffer[512];
size_t count = fread(buffer, 1, sizeof(buffer), stdin);
pb_istream_t stream = pb_istream_from_buffer(buffer, count);
const pb_field_t *type = decode_unionmessage_type(&stream);
bool status = false;
if (type == MsgType1_fields)
{
MsgType1 msg = {};
status = decode_unionmessage_contents(&stream, MsgType1_fields, &msg);
printf("Got MsgType1: %d\n", msg.value);
}
else if (type == MsgType2_fields)
{
MsgType2 msg = {};
status = decode_unionmessage_contents(&stream, MsgType2_fields, &msg);
printf("Got MsgType2: %s\n", msg.value ? "true" : "false");
}
else if (type == MsgType3_fields)
{
MsgType3 msg = {};
status = decode_unionmessage_contents(&stream, MsgType3_fields, &msg);
printf("Got MsgType3: %d %d\n", msg.value1, msg.value2);
}
if (!status)
{
printf("Decode failed: %s\n", PB_GET_ERROR(&stream));
return 1;
}
return 0;
}

85
examples/using_union_messages/encode.c
View File

@@ -1,85 +0,0 @@
/* This program takes a command line argument and encodes a message in
* one of MsgType1, MsgType2 or MsgType3.
*/
#include <stdio.h>
#include <string.h>
#include <stdlib.h>
#include <pb_encode.h>
#include "unionproto.pb.h"
/* This function is the core of the union encoding process. It handles
* the top-level pb_field_t array manually, in order to encode a correct
* field tag before the message. The pointer to MsgType_fields array is
* used as an unique identifier for the message type.
*/
bool encode_unionmessage(pb_ostream_t *stream, const pb_field_t messagetype[], const void *message)
{
const pb_field_t *field;
for (field = UnionMessage_fields; field->tag != 0; field++)
{
if (field->ptr == messagetype)
{
/* This is our field, encode the message using it. */
if (!pb_encode_tag_for_field(stream, field))
return false;
return pb_encode_submessage(stream, messagetype, message);
}
}
/* Didn't find the field for messagetype */
return false;
}
int main(int argc, char **argv)
{
if (argc != 2)
{
fprintf(stderr, "Usage: %s (1|2|3)\n", argv[0]);
return 1;
}
uint8_t buffer[512];
pb_ostream_t stream = pb_ostream_from_buffer(buffer, sizeof(buffer));
bool status = false;
int msgtype = atoi(argv[1]);
if (msgtype == 1)
{
/* Send message of type 1 */
MsgType1 msg = {42};
status = encode_unionmessage(&stream, MsgType1_fields, &msg);
}
else if (msgtype == 2)
{
/* Send message of type 2 */
MsgType2 msg = {true};
status = encode_unionmessage(&stream, MsgType2_fields, &msg);
}
else if (msgtype == 3)
{
/* Send message of type 3 */
MsgType3 msg = {3, 1415};
status = encode_unionmessage(&stream, MsgType3_fields, &msg);
}
else
{
fprintf(stderr, "Unknown message type: %d\n", msgtype);
return 2;
}
if (!status)
{
fprintf(stderr, "Encoding failed!\n");
return 3;
}
else
{
fwrite(buffer, 1, stream.bytes_written, stdout);
return 0; /* Success */
}
}

30
examples/using_union_messages/unionproto.proto
View File

@@ -1,30 +0,0 @@
// This is an example of how to handle 'union' style messages
// with nanopb, without allocating memory for all the message types.
//
// There is no official type in Protocol Buffers for describing unions,
// but they are commonly implemented by filling out exactly one of
// several optional fields.
message MsgType1
{
required int32 value = 1;
}
message MsgType2
{
required bool value = 1;
}
message MsgType3
{
required int32 value1 = 1;
required int32 value2 = 2;
}
message UnionMessage
{
optional MsgType1 msg1 = 1;
optional MsgType2 msg2 = 2;
optional MsgType3 msg3 = 3;
}

225
extra/FindNanopb.cmake
View File

@@ -1,225 +0,0 @@
# This is an example script for use with CMake projects for locating and configuring
# the nanopb library.
#
# The following varialbes have to be set:
#
# NANOPB_SRC_ROOT_FOLDER - Path to nanopb source folder
#
# The following variables can be set and are optional:
#
#
# PROTOBUF_SRC_ROOT_FOLDER - When compiling with MSVC, if this cache variable is set
# the protobuf-default VS project build locations
# (vsprojects/Debug & vsprojects/Release) will be searched
# for libraries and binaries.
#
# NANOPB_IMPORT_DIRS - List of additional directories to be searched for
# imported .proto files.
#
# NANOPB_GENERATE_CPP_APPEND_PATH - By default -I will be passed to protoc
# for each directory where a proto file is referenced.
# Set to FALSE if you want to disable this behaviour.
#
# Defines the following variables:
#
# NANOPB_FOUND - Found the nanopb library (source&header files, generator tool, protoc compiler tool)
# NANOPB_INCLUDE_DIRS - Include directories for Google Protocol Buffers
#
# The following cache variables are also available to set or use:
# NANOPB_GENERATOR_EXECUTABLE - The nanopb generator
# PROTOBUF_PROTOC_EXECUTABLE - The protoc compiler
#
# ====================================================================
#
# NANOPB_GENERATE_CPP (public function)
# SRCS = Variable to define with autogenerated
# source files
# HDRS = Variable to define with autogenerated
# header files
# ARGN = proto files
#
# ====================================================================
# Example:
#
# set(NANOPB_SRC_ROOT_FOLDER "/path/to/nanopb")
# set(CMAKE_MODULE_PATH ${CMAKE_MODULE_PATH} ${NANOPB_SRC_ROOT_FOLDER}/cmake)
# find_package( Nanopb REQUIRED )
# include_directories(${NANOPB_INCLUDE_DIRS})
#
# NANOPB_GENERATE_CPP(PROTO_SRCS PROTO_HDRS foo.proto)
#
# include_directories(${CMAKE_CURRENT_BINARY_DIR})
# add_executable(bar bar.cc ${PROTO_SRCS} ${PROTO_HDRS})
#
# ====================================================================
#=============================================================================
# Copyright 2009 Kitware, Inc.
# Copyright 2009-2011 Philip Lowman <philip@yhbt.com>
# Copyright 2008 Esben Mose Hansen, Ange Optimization ApS
#
# Redistribution and use in source and binary forms, with or without
# modification, are permitted provided that the following conditions
# are met:
#
# * Redistributions of source code must retain the above copyright
# notice, this list of conditions and the following disclaimer.
#
# * Redistributions in binary form must reproduce the above copyright
# notice, this list of conditions and the following disclaimer in the
# documentation and/or other materials provided with the distribution.
#
# * Neither the names of Kitware, Inc., the Insight Software Consortium,
# nor the names of their contributors may be used to endorse or promote
# products derived from this software without specific prior written
# permission.
#
# THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
# "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
# LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
# A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
# HOLDER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
# SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
# LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
# DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
# THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
# (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
# OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
#
#=============================================================================
#
# Changes
# 2013.01.31 - Pavlo Ilin - used Modules/FindProtobuf.cmake from cmake 2.8.10 to
# write FindNanopb.cmake
#
#=============================================================================
function(NANOPB_GENERATE_CPP SRCS HDRS)
if(NOT ARGN)
return()
endif()
if(NANOPB_GENERATE_CPP_APPEND_PATH)
# Create an include path for each file specified
foreach(FIL ${ARGN})
get_filename_component(ABS_FIL ${FIL} ABSOLUTE)
get_filename_component(ABS_PATH ${ABS_FIL} PATH)
list(FIND _nanobp_include_path ${ABS_PATH} _contains_already)
if(${_contains_already} EQUAL -1)
list(APPEND _nanobp_include_path -I ${ABS_PATH})
endif()
endforeach()
else()
set(_nanobp_include_path -I ${CMAKE_CURRENT_SOURCE_DIR})
endif()
if(DEFINED NANOPB_IMPORT_DIRS)
foreach(DIR ${NANOPB_IMPORT_DIRS})
get_filename_component(ABS_PATH ${DIR} ABSOLUTE)
list(FIND _nanobp_include_path ${ABS_PATH} _contains_already)
if(${_contains_already} EQUAL -1)
list(APPEND _nanobp_include_path -I ${ABS_PATH})
endif()
endforeach()
endif()
set(${SRCS})
set(${HDRS})
get_filename_component(GENERATOR_PATH ${NANOPB_GENERATOR_EXECUTABLE} PATH)
foreach(FIL ${ARGN})
get_filename_component(ABS_FIL ${FIL} ABSOLUTE)
get_filename_component(FIL_WE ${FIL} NAME_WE)
list(APPEND ${SRCS} "${CMAKE_CURRENT_BINARY_DIR}/${FIL_WE}.pb.c")
list(APPEND ${HDRS} "${CMAKE_CURRENT_BINARY_DIR}/${FIL_WE}.pb.h")
add_custom_command(
OUTPUT "${CMAKE_CURRENT_BINARY_DIR}/${FIL_WE}.pb"
COMMAND ${PROTOBUF_PROTOC_EXECUTABLE}
ARGS -I${GENERATOR_PATH} -I${CMAKE_CURRENT_BINARY_DIR} ${_nanobp_include_path} -o${FIL_WE}.pb ${ABS_FIL}
DEPENDS ${ABS_FIL}
COMMENT "Running C++ protocol buffer compiler on ${FIL}"
VERBATIM )
add_custom_command(
OUTPUT "${CMAKE_CURRENT_BINARY_DIR}/${FIL_WE}.pb.c"
"${CMAKE_CURRENT_BINARY_DIR}/${FIL_WE}.pb.h"
COMMAND python
ARGS ${NANOPB_GENERATOR_EXECUTABLE} ${FIL_WE}.pb
DEPENDS "${CMAKE_CURRENT_BINARY_DIR}/${FIL_WE}.pb"
COMMENT "Running nanopb generator on ${FIL_WE}.pb"
VERBATIM )
endforeach()
set_source_files_properties(${${SRCS}} ${${HDRS}} PROPERTIES GENERATED TRUE)
set(${SRCS} ${${SRCS}} ${NANOPB_SRCS} PARENT_SCOPE)
set(${HDRS} ${${HDRS}} ${NANOPB_HDRS} PARENT_SCOPE)
endfunction()
#
# Main.
#
# By default have NANOPB_GENERATE_CPP macro pass -I to protoc
# for each directory where a proto file is referenced.
if(NOT DEFINED NANOPB_GENERATE_CPP_APPEND_PATH)
set(NANOPB_GENERATE_CPP_APPEND_PATH TRUE)
endif()
# Find the include directory
find_path(NANOPB_INCLUDE_DIRS
pb.h
PATHS ${NANOPB_SRC_ROOT_FOLDER}
)
mark_as_advanced(NANOPB_INCLUDE_DIRS)
# Find nanopb source files
set(NANOPB_SRCS)
set(NANOPB_HDRS)
list(APPEND _nanopb_srcs pb_decode.c pb_encode.c pb_common.c)
list(APPEND _nanopb_hdrs pb_decode.h pb_encode.h pb_common.h pb.h)
foreach(FIL ${_nanopb_srcs})
find_file(${FIL}__nano_pb_file NAMES ${FIL} PATHS ${NANOPB_SRC_ROOT_FOLDER} ${NANOPB_INCLUDE_DIRS})
list(APPEND NANOPB_SRCS "${${FIL}__nano_pb_file}")
mark_as_advanced(${FIL}__nano_pb_file)
endforeach()
foreach(FIL ${_nanopb_hdrs})
find_file(${FIL}__nano_pb_file NAMES ${FIL} PATHS ${NANOPB_INCLUDE_DIRS})
mark_as_advanced(${FIL}__nano_pb_file)
list(APPEND NANOPB_HDRS "${${FIL}__nano_pb_file}")
endforeach()
# Find the protoc Executable
find_program(PROTOBUF_PROTOC_EXECUTABLE
NAMES protoc
DOC "The Google Protocol Buffers Compiler"
PATHS
${PROTOBUF_SRC_ROOT_FOLDER}/vsprojects/Release
${PROTOBUF_SRC_ROOT_FOLDER}/vsprojects/Debug
)
mark_as_advanced(PROTOBUF_PROTOC_EXECUTABLE)
# Find nanopb generator
find_file(NANOPB_GENERATOR_EXECUTABLE
NAMES nanopb_generator.py
DOC "nanopb generator"
PATHS
${NANOPB_SRC_ROOT_FOLDER}/generator
)
mark_as_advanced(NANOPB_GENERATOR_EXECUTABLE)
include(FindPackageHandleStandardArgs)
FIND_PACKAGE_HANDLE_STANDARD_ARGS(NANOPB DEFAULT_MSG
NANOPB_INCLUDE_DIRS
NANOPB_SRCS NANOPB_HDRS
NANOPB_GENERATOR_EXECUTABLE
PROTOBUF_PROTOC_EXECUTABLE
)

37
extra/nanopb.mk
View File

@@ -1,37 +0,0 @@
# This is an include file for Makefiles. It provides rules for building
# .pb.c and .pb.h files out of .proto, as well the path to nanopb core.
# Path to the nanopb root directory
NANOPB_DIR := $(abspath $(dir $(lastword $(MAKEFILE_LIST)))../)
# Files for the nanopb core
NANOPB_CORE = $(NANOPB_DIR)/pb_encode.c $(NANOPB_DIR)/pb_decode.c $(NANOPB_DIR)/pb_common.c
# Check if we are running on Windows
ifdef windir
WINDOWS = 1
endif
ifdef WINDIR
WINDOWS = 1
endif
# Check whether to use binary version of nanopb_generator or the
# system-supplied python interpreter.
ifneq "$(wildcard $(NANOPB_DIR)/generator-bin)" ""
# Binary package
PROTOC = $(NANOPB_DIR)/generator-bin/protoc
PROTOC_OPTS =
else
# Source only or git checkout
PROTOC = protoc
ifdef WINDOWS
PROTOC_OPTS = --plugin=protoc-gen-nanopb=$(NANOPB_DIR)/generator/protoc-gen-nanopb.bat
else
PROTOC_OPTS = --plugin=protoc-gen-nanopb=$(NANOPB_DIR)/generator/protoc-gen-nanopb
endif
endif
# Rule for building .pb.c and .pb.h
%.pb.c %.pb.h: %.proto $(wildcard %.options)
$(PROTOC) $(PROTOC_OPTS) --nanopb_out=. $<

104
extra/pb_syshdr.h
View File

@@ -1,104 +0,0 @@
/* This is an example of a header file for platforms/compilers that do
* not come with stdint.h/stddef.h/stdbool.h/string.h. To use it, define
* PB_SYSTEM_HEADER as "pb_syshdr.h", including the quotes, and add the
* extra folder to your include path.
*
* It is very likely that you will need to customize this file to suit
* your platform. For any compiler that supports C99, this file should
* not be necessary.
*/
#ifndef _PB_SYSHDR_H_
#define _PB_SYSHDR_H_
/* stdint.h subset */
#ifdef HAVE_STDINT_H
#include <stdint.h>
#else
/* You will need to modify these to match the word size of your platform. */
typedef signed char int8_t;
typedef unsigned char uint8_t;
typedef signed short int16_t;
typedef unsigned short uint16_t;
typedef signed int int32_t;
typedef unsigned int uint32_t;
typedef signed long long int64_t;
typedef unsigned long long uint64_t;
#endif
/* stddef.h subset */
#ifdef HAVE_STDDEF_H
#include <stddef.h>
#else
typedef uint32_t size_t;
#define offsetof(st, m) ((size_t)(&((st *)0)->m))
#ifndef NULL
#define NULL 0
#endif
#endif
/* stdbool.h subset */
#ifdef HAVE_STDBOOL_H
#include <stdbool.h>
#else
#ifndef __cplusplus
typedef int bool;
#define false 0
#define true 1
#endif
#endif
/* stdlib.h subset */
#ifdef PB_ENABLE_MALLOC
#ifdef HAVE_STDLIB_H
#include <stdlib.h>
#else
void *realloc(void *ptr, size_t size);
void free(void *ptr);
#endif
#endif
/* string.h subset */
#ifdef HAVE_STRING_H
#include <string.h>
#else
/* Implementations are from the Public Domain C Library (PDCLib). */
static size_t strlen( const char * s )
{
size_t rc = 0;
while ( s[rc] )
{
++rc;
}
return rc;
}
static void * memcpy( void *s1, const void *s2, size_t n )
{
char * dest = (char *) s1;
const char * src = (const char *) s2;
while ( n-- )
{
*dest++ = *src++;
}
return s1;
}
static void * memset( void * s, int c, size_t n )
{
unsigned char * p = (unsigned char *) s;
while ( n-- )
{
*p++ = (unsigned char) c;
}
return s;
}
#endif
#endif

2
generator/Makefile Normal file
View File

@@ -0,0 +1,2 @@
nanopb_pb2.py: nanopb.proto
protoc --python_out=. -I /usr/include -I . nanopb.proto

28
generator/nanopb.proto Normal file
View File

@@ -0,0 +1,28 @@
// Custom options for defining:
// - Maximum size of string/bytes
// - Maximum number of elements in array
// - Pointer or in-line representation of non-scalar fields
//
// These are used by nanopb to generate statically allocable structures
// for memory-limited environments.
import "google/protobuf/descriptor.proto";
message NanoPBOptions {
optional int32 max_size = 1;
optional int32 max_count = 2;
optional bool pointer = 3;
}
// Protocol Buffers extension number registry
// --------------------------------
// Project: Nanopb
// Contact: Petteri Aimonen <jpa@kapsi.fi>
// Web site: http://kapsi.fi/~jpa/nanopb
// Extensions: 1010 (all types)
// --------------------------------
extend google.protobuf.FieldOptions {
optional NanoPBOptions nanopb = 1010;
}

1179
generator/nanopb_generator.py Executable file → Normal file
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File diff suppressed because it is too large Load Diff

79
generator/nanopb_pb2.py Normal file
View File

@@ -0,0 +1,79 @@
# Generated by the protocol buffer compiler. DO NOT EDIT!
from google.protobuf import descriptor
from google.protobuf import message
from google.protobuf import reflection
from google.protobuf import descriptor_pb2
# @@protoc_insertion_point(imports)
import google.protobuf.descriptor_pb2
DESCRIPTOR = descriptor.FileDescriptor(
name='nanopb.proto',
package='',
serialized_pb='\n\x0cnanopb.proto\x1a google/protobuf/descriptor.proto\"E\n\rNanoPBOptions\x12\x10\n\x08max_size\x18\x01 \x01(\x05\x12\x11\n\tmax_count\x18\x02 \x01(\x05\x12\x0f\n\x07pointer\x18\x03 \x01(\x08:>\n\x06nanopb\x12\x1d.google.protobuf.FieldOptions\x18\xf2\x07 \x01(\x0b\x32\x0e.NanoPBOptions')
NANOPB_FIELD_NUMBER = 1010
nanopb = descriptor.FieldDescriptor(
name='nanopb', full_name='nanopb', index=0,
number=1010, type=11, cpp_type=10, label=1,
has_default_value=False, default_value=None,
message_type=None, enum_type=None, containing_type=None,
is_extension=True, extension_scope=None,
options=None)
_NANOPBOPTIONS = descriptor.Descriptor(
name='NanoPBOptions',
full_name='NanoPBOptions',
filename=None,
file=DESCRIPTOR,
containing_type=None,
fields=[
descriptor.FieldDescriptor(
name='max_size', full_name='NanoPBOptions.max_size', index=0,
number=1, type=5, cpp_type=1, label=1,
has_default_value=False, default_value=0,
message_type=None, enum_type=None, containing_type=None,
is_extension=False, extension_scope=None,
options=None),
descriptor.FieldDescriptor(
name='max_count', full_name='NanoPBOptions.max_count', index=1,
number=2, type=5, cpp_type=1, label=1,
has_default_value=False, default_value=0,
message_type=None, enum_type=None, containing_type=None,
is_extension=False, extension_scope=None,
options=None),
descriptor.FieldDescriptor(
name='pointer', full_name='NanoPBOptions.pointer', index=2,
number=3, type=8, cpp_type=7, label=1,
has_default_value=False, default_value=False,
message_type=None, enum_type=None, containing_type=None,
is_extension=False, extension_scope=None,
options=None),
],
extensions=[
],
nested_types=[],
enum_types=[
],
options=None,
is_extendable=False,
extension_ranges=[],
serialized_start=50,
serialized_end=119,
)
DESCRIPTOR.message_types_by_name['NanoPBOptions'] = _NANOPBOPTIONS
class NanoPBOptions(message.Message):
__metaclass__ = reflection.GeneratedProtocolMessageType
DESCRIPTOR = _NANOPBOPTIONS
# @@protoc_insertion_point(class_scope:NanoPBOptions)
nanopb.message_type = _NANOPBOPTIONS
google.protobuf.descriptor_pb2.FieldOptions.RegisterExtension(nanopb)
# @@protoc_insertion_point(module_scope)

4
generator/proto/Makefile
View File

@@ -1,4 +0,0 @@
all: nanopb_pb2.py plugin_pb2.py
%_pb2.py: %.proto
protoc --python_out=. $<

0
generator/proto/__init__.py
View File

620
generator/proto/google/protobuf/descriptor.proto
View File

@@ -1,620 +0,0 @@
// Protocol Buffers - Google's data interchange format
// Copyright 2008 Google Inc. All rights reserved.
// http://code.google.com/p/protobuf/
//
// Redistribution and use in source and binary forms, with or without
// modification, are permitted provided that the following conditions are
// met:
//
// * Redistributions of source code must retain the above copyright
// notice, this list of conditions and the following disclaimer.
// * Redistributions in binary form must reproduce the above
// copyright notice, this list of conditions and the following disclaimer
// in the documentation and/or other materials provided with the
// distribution.
// * Neither the name of Google Inc. nor the names of its
// contributors may be used to endorse or promote products derived from
// this software without specific prior written permission.
//
// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
// "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
// LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
// A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
// OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
// SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
// LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
// DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
// THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
// (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
// OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
// Author: kenton@google.com (Kenton Varda)
// Based on original Protocol Buffers design by
// Sanjay Ghemawat, Jeff Dean, and others.
//
// The messages in this file describe the definitions found in .proto files.
// A valid .proto file can be translated directly to a FileDescriptorProto
// without any other information (e.g. without reading its imports).
package google.protobuf;
option java_package = "com.google.protobuf";
option java_outer_classname = "DescriptorProtos";
// descriptor.proto must be optimized for speed because reflection-based
// algorithms don't work during bootstrapping.
option optimize_for = SPEED;
// The protocol compiler can output a FileDescriptorSet containing the .proto
// files it parses.
message FileDescriptorSet {
repeated FileDescriptorProto file = 1;
}
// Describes a complete .proto file.
message FileDescriptorProto {
optional string name = 1; // file name, relative to root of source tree
optional string package = 2; // e.g. "foo", "foo.bar", etc.
// Names of files imported by this file.
repeated string dependency = 3;
// Indexes of the public imported files in the dependency list above.
repeated int32 public_dependency = 10;
// Indexes of the weak imported files in the dependency list.
// For Google-internal migration only. Do not use.
repeated int32 weak_dependency = 11;
// All top-level definitions in this file.
repeated DescriptorProto message_type = 4;
repeated EnumDescriptorProto enum_type = 5;
repeated ServiceDescriptorProto service = 6;
repeated FieldDescriptorProto extension = 7;
optional FileOptions options = 8;
// This field contains optional information about the original source code.
// You may safely remove this entire field whithout harming runtime
// functionality of the descriptors -- the information is needed only by
// development tools.
optional SourceCodeInfo source_code_info = 9;
}
// Describes a message type.
message DescriptorProto {
optional string name = 1;
repeated FieldDescriptorProto field = 2;
repeated FieldDescriptorProto extension = 6;
repeated DescriptorProto nested_type = 3;
repeated EnumDescriptorProto enum_type = 4;
message ExtensionRange {
optional int32 start = 1;
optional int32 end = 2;
}
repeated ExtensionRange extension_range = 5;
optional MessageOptions options = 7;
}
// Describes a field within a message.
message FieldDescriptorProto {
enum Type {
// 0 is reserved for errors.
// Order is weird for historical reasons.
TYPE_DOUBLE = 1;
TYPE_FLOAT = 2;
// Not ZigZag encoded. Negative numbers take 10 bytes. Use TYPE_SINT64 if
// negative values are likely.
TYPE_INT64 = 3;
TYPE_UINT64 = 4;
// Not ZigZag encoded. Negative numbers take 10 bytes. Use TYPE_SINT32 if
// negative values are likely.
TYPE_INT32 = 5;
TYPE_FIXED64 = 6;
TYPE_FIXED32 = 7;
TYPE_BOOL = 8;
TYPE_STRING = 9;
TYPE_GROUP = 10; // Tag-delimited aggregate.
TYPE_MESSAGE = 11; // Length-delimited aggregate.
// New in version 2.
TYPE_BYTES = 12;
TYPE_UINT32 = 13;
TYPE_ENUM = 14;
TYPE_SFIXED32 = 15;
TYPE_SFIXED64 = 16;
TYPE_SINT32 = 17; // Uses ZigZag encoding.
TYPE_SINT64 = 18; // Uses ZigZag encoding.
};
enum Label {
// 0 is reserved for errors
LABEL_OPTIONAL = 1;
LABEL_REQUIRED = 2;
LABEL_REPEATED = 3;
// TODO(sanjay): Should we add LABEL_MAP?
};
optional string name = 1;
optional int32 number = 3;
optional Label label = 4;
// If type_name is set, this need not be set. If both this and type_name
// are set, this must be either TYPE_ENUM or TYPE_MESSAGE.
optional Type type = 5;
// For message and enum types, this is the name of the type. If the name
// starts with a '.', it is fully-qualified. Otherwise, C++-like scoping
// rules are used to find the type (i.e. first the nested types within this
// message are searched, then within the parent, on up to the root
// namespace).
optional string type_name = 6;
// For extensions, this is the name of the type being extended. It is
// resolved in the same manner as type_name.
optional string extendee = 2;
// For numeric types, contains the original text representation of the value.
// For booleans, "true" or "false".
// For strings, contains the default text contents (not escaped in any way).
// For bytes, contains the C escaped value. All bytes >= 128 are escaped.
// TODO(kenton): Base-64 encode?
optional string default_value = 7;
optional FieldOptions options = 8;
}
// Describes an enum type.
message EnumDescriptorProto {
optional string name = 1;
repeated EnumValueDescriptorProto value = 2;
optional EnumOptions options = 3;
}
// Describes a value within an enum.
message EnumValueDescriptorProto {
optional string name = 1;
optional int32 number = 2;
optional EnumValueOptions options = 3;
}
// Describes a service.
message ServiceDescriptorProto {
optional string name = 1;
repeated MethodDescriptorProto method = 2;
optional ServiceOptions options = 3;
}
// Describes a method of a service.
message MethodDescriptorProto {
optional string name = 1;
// Input and output type names. These are resolved in the same way as
// FieldDescriptorProto.type_name, but must refer to a message type.
optional string input_type = 2;
optional string output_type = 3;
optional MethodOptions options = 4;
}
// ===================================================================
// Options
// Each of the definitions above may have "options" attached. These are
// just annotations which may cause code to be generated slightly differently
// or may contain hints for code that manipulates protocol messages.
//
// Clients may define custom options as extensions of the *Options messages.
// These extensions may not yet be known at parsing time, so the parser cannot
// store the values in them. Instead it stores them in a field in the *Options
// message called uninterpreted_option. This field must have the same name
// across all *Options messages. We then use this field to populate the
// extensions when we build a descriptor, at which point all protos have been
// parsed and so all extensions are known.
//
// Extension numbers for custom options may be chosen as follows:
// * For options which will only be used within a single application or
// organization, or for experimental options, use field numbers 50000
// through 99999. It is up to you to ensure that you do not use the
// same number for multiple options.
// * For options which will be published and used publicly by multiple
// independent entities, e-mail protobuf-global-extension-registry@google.com
// to reserve extension numbers. Simply provide your project name (e.g.
// Object-C plugin) and your porject website (if available) -- there's no need
// to explain how you intend to use them. Usually you only need one extension
// number. You can declare multiple options with only one extension number by
// putting them in a sub-message. See the Custom Options section of the docs
// for examples:
// http://code.google.com/apis/protocolbuffers/docs/proto.html#options
// If this turns out to be popular, a web service will be set up
// to automatically assign option numbers.
message FileOptions {
// Sets the Java package where classes generated from this .proto will be
// placed. By default, the proto package is used, but this is often
// inappropriate because proto packages do not normally start with backwards
// domain names.
optional string java_package = 1;
// If set, all the classes from the .proto file are wrapped in a single
// outer class with the given name. This applies to both Proto1
// (equivalent to the old "--one_java_file" option) and Proto2 (where
// a .proto always translates to a single class, but you may want to
// explicitly choose the class name).
optional string java_outer_classname = 8;
// If set true, then the Java code generator will generate a separate .java
// file for each top-level message, enum, and service defined in the .proto
// file. Thus, these types will *not* be nested inside the outer class
// named by java_outer_classname. However, the outer class will still be
// generated to contain the file's getDescriptor() method as well as any
// top-level extensions defined in the file.
optional bool java_multiple_files = 10 [default=false];
// If set true, then the Java code generator will generate equals() and
// hashCode() methods for all messages defined in the .proto file. This is
// purely a speed optimization, as the AbstractMessage base class includes
// reflection-based implementations of these methods.
optional bool java_generate_equals_and_hash = 20 [default=false];
// Generated classes can be optimized for speed or code size.
enum OptimizeMode {
SPEED = 1; // Generate complete code for parsing, serialization,
// etc.
CODE_SIZE = 2; // Use ReflectionOps to implement these methods.
LITE_RUNTIME = 3; // Generate code using MessageLite and the lite runtime.
}
optional OptimizeMode optimize_for = 9 [default=SPEED];
// Sets the Go package where structs generated from this .proto will be
// placed. There is no default.
optional string go_package = 11;
// Should generic services be generated in each language? "Generic" services
// are not specific to any particular RPC system. They are generated by the
// main code generators in each language (without additional plugins).
// Generic services were the only kind of service generation supported by
// early versions of proto2.
//
// Generic services are now considered deprecated in favor of using plugins
// that generate code specific to your particular RPC system. Therefore,
// these default to false. Old code which depends on generic services should
// explicitly set them to true.
optional bool cc_generic_services = 16 [default=false];
optional bool java_generic_services = 17 [default=false];
optional bool py_generic_services = 18 [default=false];
// The parser stores options it doesn't recognize here. See above.
repeated UninterpretedOption uninterpreted_option = 999;
// Clients can define custom options in extensions of this message. See above.
extensions 1000 to max;
}
message MessageOptions {
// Set true to use the old proto1 MessageSet wire format for extensions.
// This is provided for backwards-compatibility with the MessageSet wire
// format. You should not use this for any other reason: It's less
// efficient, has fewer features, and is more complicated.
//
// The message must be defined exactly as follows:
// message Foo {
// option message_set_wire_format = true;
// extensions 4 to max;
// }
// Note that the message cannot have any defined fields; MessageSets only
// have extensions.
//
// All extensions of your type must be singular messages; e.g. they cannot
// be int32s, enums, or repeated messages.
//
// Because this is an option, the above two restrictions are not enforced by
// the protocol compiler.
optional bool message_set_wire_format = 1 [default=false];
// Disables the generation of the standard "descriptor()" accessor, which can
// conflict with a field of the same name. This is meant to make migration
// from proto1 easier; new code should avoid fields named "descriptor".
optional bool no_standard_descriptor_accessor = 2 [default=false];
// The parser stores options it doesn't recognize here. See above.
repeated UninterpretedOption uninterpreted_option = 999;
// Clients can define custom options in extensions of this message. See above.
extensions 1000 to max;
}
message FieldOptions {
// The ctype option instructs the C++ code generator to use a different
// representation of the field than it normally would. See the specific
// options below. This option is not yet implemented in the open source
// release -- sorry, we'll try to include it in a future version!
optional CType ctype = 1 [default = STRING];
enum CType {
// Default mode.
STRING = 0;
CORD = 1;
STRING_PIECE = 2;
}
// The packed option can be enabled for repeated primitive fields to enable
// a more efficient representation on the wire. Rather than repeatedly
// writing the tag and type for each element, the entire array is encoded as
// a single length-delimited blob.
optional bool packed = 2;
// Should this field be parsed lazily? Lazy applies only to message-type
// fields. It means that when the outer message is initially parsed, the
// inner message's contents will not be parsed but instead stored in encoded
// form. The inner message will actually be parsed when it is first accessed.
//
// This is only a hint. Implementations are free to choose whether to use
// eager or lazy parsing regardless of the value of this option. However,
// setting this option true suggests that the protocol author believes that
// using lazy parsing on this field is worth the additional bookkeeping
// overhead typically needed to implement it.
//
// This option does not affect the public interface of any generated code;
// all method signatures remain the same. Furthermore, thread-safety of the
// interface is not affected by this option; const methods remain safe to
// call from multiple threads concurrently, while non-const methods continue
// to require exclusive access.
//
//
// Note that implementations may choose not to check required fields within
// a lazy sub-message. That is, calling IsInitialized() on the outher message
// may return true even if the inner message has missing required fields.
// This is necessary because otherwise the inner message would have to be
// parsed in order to perform the check, defeating the purpose of lazy
// parsing. An implementation which chooses not to check required fields
// must be consistent about it. That is, for any particular sub-message, the
// implementation must either *always* check its required fields, or *never*
// check its required fields, regardless of whether or not the message has
// been parsed.
optional bool lazy = 5 [default=false];
// Is this field deprecated?
// Depending on the target platform, this can emit Deprecated annotations
// for accessors, or it will be completely ignored; in the very least, this
// is a formalization for deprecating fields.
optional bool deprecated = 3 [default=false];
// EXPERIMENTAL. DO NOT USE.
// For "map" fields, the name of the field in the enclosed type that
// is the key for this map. For example, suppose we have:
// message Item {
// required string name = 1;
// required string value = 2;
// }
// message Config {
// repeated Item items = 1 [experimental_map_key="name"];
// }
// In this situation, the map key for Item will be set to "name".
// TODO: Fully-implement this, then remove the "experimental_" prefix.
optional string experimental_map_key = 9;
// For Google-internal migration only. Do not use.
optional bool weak = 10 [default=false];
// The parser stores options it doesn't recognize here. See above.
repeated UninterpretedOption uninterpreted_option = 999;
// Clients can define custom options in extensions of this message. See above.
extensions 1000 to max;
}
message EnumOptions {
// Set this option to false to disallow mapping different tag names to a same
// value.
optional bool allow_alias = 2 [default=true];
// The parser stores options it doesn't recognize here. See above.
repeated UninterpretedOption uninterpreted_option = 999;
// Clients can define custom options in extensions of this message. See above.
extensions 1000 to max;
}
message EnumValueOptions {
// The parser stores options it doesn't recognize here. See above.
repeated UninterpretedOption uninterpreted_option = 999;
// Clients can define custom options in extensions of this message. See above.
extensions 1000 to max;
}
message ServiceOptions {
// Note: Field numbers 1 through 32 are reserved for Google's internal RPC
// framework. We apologize for hoarding these numbers to ourselves, but
// we were already using them long before we decided to release Protocol
// Buffers.
// The parser stores options it doesn't recognize here. See above.
repeated UninterpretedOption uninterpreted_option = 999;
// Clients can define custom options in extensions of this message. See above.
extensions 1000 to max;
}
message MethodOptions {
// Note: Field numbers 1 through 32 are reserved for Google's internal RPC
// framework. We apologize for hoarding these numbers to ourselves, but
// we were already using them long before we decided to release Protocol
// Buffers.
// The parser stores options it doesn't recognize here. See above.
repeated UninterpretedOption uninterpreted_option = 999;
// Clients can define custom options in extensions of this message. See above.
extensions 1000 to max;
}
// A message representing a option the parser does not recognize. This only
// appears in options protos created by the compiler::Parser class.
// DescriptorPool resolves these when building Descriptor objects. Therefore,
// options protos in descriptor objects (e.g. returned by Descriptor::options(),
// or produced by Descriptor::CopyTo()) will never have UninterpretedOptions
// in them.
message UninterpretedOption {
// The name of the uninterpreted option. Each string represents a segment in
// a dot-separated name. is_extension is true iff a segment represents an
// extension (denoted with parentheses in options specs in .proto files).
// E.g.,{ ["foo", false], ["bar.baz", true], ["qux", false] } represents
// "foo.(bar.baz).qux".
message NamePart {
required string name_part = 1;
required bool is_extension = 2;
}
repeated NamePart name = 2;
// The value of the uninterpreted option, in whatever type the tokenizer
// identified it as during parsing. Exactly one of these should be set.
optional string identifier_value = 3;
optional uint64 positive_int_value = 4;
optional int64 negative_int_value = 5;
optional double double_value = 6;
optional bytes string_value = 7;
optional string aggregate_value = 8;
}
// ===================================================================
// Optional source code info
// Encapsulates information about the original source file from which a
// FileDescriptorProto was generated.
message SourceCodeInfo {
// A Location identifies a piece of source code in a .proto file which
// corresponds to a particular definition. This information is intended
// to be useful to IDEs, code indexers, documentation generators, and similar
// tools.
//
// For example, say we have a file like:
// message Foo {
// optional string foo = 1;
// }
// Let's look at just the field definition:
// optional string foo = 1;
// ^ ^^ ^^ ^ ^^^
// a bc de f ghi
// We have the following locations:
// span path represents
// [a,i) [ 4, 0, 2, 0 ] The whole field definition.
// [a,b) [ 4, 0, 2, 0, 4 ] The label (optional).
// [c,d) [ 4, 0, 2, 0, 5 ] The type (string).
// [e,f) [ 4, 0, 2, 0, 1 ] The name (foo).
// [g,h) [ 4, 0, 2, 0, 3 ] The number (1).
//
// Notes:
// - A location may refer to a repeated field itself (i.e. not to any
// particular index within it). This is used whenever a set of elements are
// logically enclosed in a single code segment. For example, an entire
// extend block (possibly containing multiple extension definitions) will
// have an outer location whose path refers to the "extensions" repeated
// field without an index.
// - Multiple locations may have the same path. This happens when a single
// logical declaration is spread out across multiple places. The most
// obvious example is the "extend" block again -- there may be multiple
// extend blocks in the same scope, each of which will have the same path.
// - A location's span is not always a subset of its parent's span. For
// example, the "extendee" of an extension declaration appears at the
// beginning of the "extend" block and is shared by all extensions within
// the block.
// - Just because a location's span is a subset of some other location's span
// does not mean that it is a descendent. For example, a "group" defines
// both a type and a field in a single declaration. Thus, the locations
// corresponding to the type and field and their components will overlap.
// - Code which tries to interpret locations should probably be designed to
// ignore those that it doesn't understand, as more types of locations could
// be recorded in the future.
repeated Location location = 1;
message Location {
// Identifies which part of the FileDescriptorProto was defined at this
// location.
//
// Each element is a field number or an index. They form a path from
// the root FileDescriptorProto to the place where the definition. For
// example, this path:
// [ 4, 3, 2, 7, 1 ]
// refers to:
// file.message_type(3) // 4, 3
// .field(7) // 2, 7
// .name() // 1
// This is because FileDescriptorProto.message_type has field number 4:
// repeated DescriptorProto message_type = 4;
// and DescriptorProto.field has field number 2:
// repeated FieldDescriptorProto field = 2;
// and FieldDescriptorProto.name has field number 1:
// optional string name = 1;
//
// Thus, the above path gives the location of a field name. If we removed
// the last element:
// [ 4, 3, 2, 7 ]
// this path refers to the whole field declaration (from the beginning
// of the label to the terminating semicolon).
repeated int32 path = 1 [packed=true];
// Always has exactly three or four elements: start line, start column,
// end line (optional, otherwise assumed same as start line), end column.
// These are packed into a single field for efficiency. Note that line
// and column numbers are zero-based -- typically you will want to add
// 1 to each before displaying to a user.
repeated int32 span = 2 [packed=true];
// If this SourceCodeInfo represents a complete declaration, these are any
// comments appearing before and after the declaration which appear to be
// attached to the declaration.
//
// A series of line comments appearing on consecutive lines, with no other
// tokens appearing on those lines, will be treated as a single comment.
//
// Only the comment content is provided; comment markers (e.g. //) are
// stripped out. For block comments, leading whitespace and an asterisk
// will be stripped from the beginning of each line other than the first.
// Newlines are included in the output.
//
// Examples:
//
// optional int32 foo = 1; // Comment attached to foo.
// // Comment attached to bar.
// optional int32 bar = 2;
//
// optional string baz = 3;
// // Comment attached to baz.
// // Another line attached to baz.
//
// // Comment attached to qux.
// //
// // Another line attached to qux.
// optional double qux = 4;
//
// optional string corge = 5;
// /* Block comment attached
// * to corge. Leading asterisks
// * will be removed. */
// /* Block comment attached to
// * grault. */
// optional int32 grault = 6;
optional string leading_comments = 3;
optional string trailing_comments = 4;
}
}

72
generator/proto/nanopb.proto
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@@ -1,72 +0,0 @@
// Custom options for defining:
// - Maximum size of string/bytes
// - Maximum number of elements in array
//
// These are used by nanopb to generate statically allocable structures
// for memory-limited environments.
import "google/protobuf/descriptor.proto";
option java_package = "fi.kapsi.koti.jpa.nanopb";
enum FieldType {
FT_DEFAULT = 0; // Automatically decide field type, generate static field if possible.
FT_CALLBACK = 1; // Always generate a callback field.
FT_POINTER = 4; // Always generate a dynamically allocated field.
FT_STATIC = 2; // Generate a static field or raise an exception if not possible.
FT_IGNORE = 3; // Ignore the field completely.
}
// This is the inner options message, which basically defines options for
// a field. When it is used in message or file scope, it applies to all
// fields.
message NanoPBOptions {
// Allocated size for 'bytes' and 'string' fields.
optional int32 max_size = 1;
// Allocated number of entries in arrays ('repeated' fields)
optional int32 max_count = 2;
// Force type of field (callback or static allocation)
optional FieldType type = 3 [default = FT_DEFAULT];
// Use long names for enums, i.e. EnumName_EnumValue.
optional bool long_names = 4 [default = true];
// Add 'packed' attribute to generated structs.
// Note: this cannot be used on CPUs that break on unaligned
// accesses to variables.
optional bool packed_struct = 5 [default = false];
// Skip this message
optional bool skip_message = 6 [default = false];
}
// Extensions to protoc 'Descriptor' type in order to define options
// inside a .proto file.
//
// Protocol Buffers extension number registry
// --------------------------------
// Project: Nanopb
// Contact: Petteri Aimonen <jpa@kapsi.fi>
// Web site: http://kapsi.fi/~jpa/nanopb
// Extensions: 1010 (all types)
// --------------------------------
extend google.protobuf.FileOptions {
optional NanoPBOptions nanopb_fileopt = 1010;
}
extend google.protobuf.MessageOptions {
optional NanoPBOptions nanopb_msgopt = 1010;
}
extend google.protobuf.EnumOptions {
optional NanoPBOptions nanopb_enumopt = 1010;
}
extend google.protobuf.FieldOptions {
optional NanoPBOptions nanopb = 1010;
}

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generator/proto/plugin.proto
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// Protocol Buffers - Google's data interchange format
// Copyright 2008 Google Inc. All rights reserved.
// http://code.google.com/p/protobuf/
//
// Redistribution and use in source and binary forms, with or without
// modification, are permitted provided that the following conditions are
// met:
//
// * Redistributions of source code must retain the above copyright
// notice, this list of conditions and the following disclaimer.
// * Redistributions in binary form must reproduce the above
// copyright notice, this list of conditions and the following disclaimer
// in the documentation and/or other materials provided with the
// distribution.
// * Neither the name of Google Inc. nor the names of its
// contributors may be used to endorse or promote products derived from
// this software without specific prior written permission.
//
// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
// "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
// LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
// A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
// OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
// SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
// LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
// DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
// THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
// (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
// OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
// Author: kenton@google.com (Kenton Varda)
//
// WARNING: The plugin interface is currently EXPERIMENTAL and is subject to
// change.
//
// protoc (aka the Protocol Compiler) can be extended via plugins. A plugin is
// just a program that reads a CodeGeneratorRequest from stdin and writes a
// CodeGeneratorResponse to stdout.
//
// Plugins written using C++ can use google/protobuf/compiler/plugin.h instead
// of dealing with the raw protocol defined here.
//
// A plugin executable needs only to be placed somewhere in the path. The
// plugin should be named "protoc-gen-$NAME", and will then be used when the
// flag "--${NAME}_out" is passed to protoc.
package google.protobuf.compiler;
import "google/protobuf/descriptor.proto";
// An encoded CodeGeneratorRequest is written to the plugin's stdin.
message CodeGeneratorRequest {
// The .proto files that were explicitly listed on the command-line. The
// code generator should generate code only for these files. Each file's
// descriptor will be included in proto_file, below.
repeated string file_to_generate = 1;
// The generator parameter passed on the command-line.
optional string parameter = 2;
// FileDescriptorProtos for all files in files_to_generate and everything
// they import. The files will appear in topological order, so each file
// appears before any file that imports it.
//
// protoc guarantees that all proto_files will be written after
// the fields above, even though this is not technically guaranteed by the
// protobuf wire format. This theoretically could allow a plugin to stream
// in the FileDescriptorProtos and handle them one by one rather than read
// the entire set into memory at once. However, as of this writing, this
// is not similarly optimized on protoc's end -- it will store all fields in
// memory at once before sending them to the plugin.
repeated FileDescriptorProto proto_file = 15;
}
// The plugin writes an encoded CodeGeneratorResponse to stdout.
message CodeGeneratorResponse {
// Error message. If non-empty, code generation failed. The plugin process
// should exit with status code zero even if it reports an error in this way.
//
// This should be used to indicate errors in .proto files which prevent the
// code generator from generating correct code. Errors which indicate a
// problem in protoc itself -- such as the input CodeGeneratorRequest being
// unparseable -- should be reported by writing a message to stderr and
// exiting with a non-zero status code.
optional string error = 1;
// Represents a single generated file.
message File {
// The file name, relative to the output directory. The name must not
// contain "." or ".." components and must be relative, not be absolute (so,
// the file cannot lie outside the output directory). "/" must be used as
// the path separator, not "\".
//
// If the name is omitted, the content will be appended to the previous
// file. This allows the generator to break large files into small chunks,
// and allows the generated text to be streamed back to protoc so that large
// files need not reside completely in memory at one time. Note that as of
// this writing protoc does not optimize for this -- it will read the entire
// CodeGeneratorResponse before writing files to disk.
optional string name = 1;
// If non-empty, indicates that the named file should already exist, and the
// content here is to be inserted into that file at a defined insertion
// point. This feature allows a code generator to extend the output
// produced by another code generator. The original generator may provide
// insertion points by placing special annotations in the file that look
// like:
// @@protoc_insertion_point(NAME)
// The annotation can have arbitrary text before and after it on the line,
// which allows it to be placed in a comment. NAME should be replaced with
// an identifier naming the point -- this is what other generators will use
// as the insertion_point. Code inserted at this point will be placed
// immediately above the line containing the insertion point (thus multiple
// insertions to the same point will come out in the order they were added).
// The double-@ is intended to make it unlikely that the generated code
// could contain things that look like insertion points by accident.
//
// For example, the C++ code generator places the following line in the
// .pb.h files that it generates:
// // @@protoc_insertion_point(namespace_scope)
// This line appears within the scope of the file's package namespace, but
// outside of any particular class. Another plugin can then specify the
// insertion_point "namespace_scope" to generate additional classes or
// other declarations that should be placed in this scope.
//
// Note that if the line containing the insertion point begins with
// whitespace, the same whitespace will be added to every line of the
// inserted text. This is useful for languages like Python, where
// indentation matters. In these languages, the insertion point comment
// should be indented the same amount as any inserted code will need to be
// in order to work correctly in that context.
//
// The code generator that generates the initial file and the one which
// inserts into it must both run as part of a single invocation of protoc.
// Code generators are executed in the order in which they appear on the
// command line.
//
// If |insertion_point| is present, |name| must also be present.
optional string insertion_point = 2;
// The file contents.
optional string content = 15;
}
repeated File file = 15;
}

13
generator/protoc-gen-nanopb
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@@ -1,13 +0,0 @@
#!/bin/sh
# This file is used to invoke nanopb_generator.py as a plugin
# to protoc on Linux and other *nix-style systems.
# Use it like this:
# protoc --plugin=nanopb=..../protoc-gen-nanopb --nanopb_out=dir foo.proto
#
# Note that if you use the binary package of nanopb, the protoc
# path is already set up properly and there is no need to give
# --plugin= on the command line.
MYPATH=$(dirname "$0")
exec python "$MYPATH/nanopb_generator.py" --protoc-plugin

12
generator/protoc-gen-nanopb.bat
View File

@@ -1,12 +0,0 @@
@echo off
:: This file is used to invoke nanopb_generator.py as a plugin
:: to protoc on Windows.
:: Use it like this:
:: protoc --plugin=nanopb=..../protoc-gen-nanopb.bat --nanopb_out=dir foo.proto
::
:: Note that if you use the binary package of nanopb, the protoc
:: path is already set up properly and there is no need to give
:: --plugin= on the command line.
set mydir=%~dp0
python "%mydir%\nanopb_generator.py" --protoc-plugin

529
pb.h
View File

@@ -1,261 +1,161 @@
/* Common parts of the nanopb library. Most of these are quite low-level
* stuff. For the high-level interface, see pb_encode.h and pb_decode.h.
#ifndef _PB_H_
#define _PB_H_
/* pb.h: Common parts for nanopb library.
* Most of these are quite low-level stuff. For the high-level interface,
* see pb_encode.h or pb_decode.h
*/
#ifndef PB_H_INCLUDED
#define PB_H_INCLUDED
/*****************************************************************
* Nanopb compilation time options. You can change these here by *
* uncommenting the lines, or on the compiler command line. *
*****************************************************************/
/* Enable support for dynamically allocated fields */
/* #define PB_ENABLE_MALLOC 1 */
/* Define this if your CPU architecture is big endian, i.e. it
* stores the most-significant byte first. */
/* #define __BIG_ENDIAN__ 1 */
/* Increase the number of required fields that are tracked.
* A compiler warning will tell if you need this. */
/* #define PB_MAX_REQUIRED_FIELDS 256 */
/* Add support for tag numbers > 255 and fields larger than 255 bytes. */
/* #define PB_FIELD_16BIT 1 */
/* Add support for tag numbers > 65536 and fields larger than 65536 bytes. */
/* #define PB_FIELD_32BIT 1 */
/* Disable support for error messages in order to save some code space. */
/* #define PB_NO_ERRMSG 1 */
/* Disable support for custom streams (support only memory buffers). */
/* #define PB_BUFFER_ONLY 1 */
/* Switch back to the old-style callback function signature.
* This was the default until nanopb-0.2.1. */
/* #define PB_OLD_CALLBACK_STYLE */
/******************************************************************
* You usually don't need to change anything below this line. *
* Feel free to look around and use the defined macros, though. *
******************************************************************/
/* Version of the nanopb library. Just in case you want to check it in
* your own program. */
#define NANOPB_VERSION nanopb-0.3.0
/* Include all the system headers needed by nanopb. You will need the
* definitions of the following:
* - strlen, memcpy, memset functions
* - [u]int8_t, [u]int16_t, [u]int32_t, [u]int64_t
* - size_t
* - bool
*
* If you don't have the standard header files, you can instead provide
* a custom header that defines or includes all this. In that case,
* define PB_SYSTEM_HEADER to the path of this file.
*/
#ifdef PB_SYSTEM_HEADER
#include PB_SYSTEM_HEADER
#else
#include <stdint.h>
#include <stddef.h>
#include <stdbool.h>
#include <string.h>
#ifdef PB_ENABLE_MALLOC
#include <stdlib.h>
#endif
#endif
/* Macro for defining packed structures (compiler dependent).
* This just reduces memory requirements, but is not required.
*/
#if defined(__GNUC__) || defined(__clang__)
/* For GCC and clang */
# define PB_PACKED_STRUCT_START
# define PB_PACKED_STRUCT_END
# define pb_packed __attribute__((packed))
#elif defined(__ICCARM__) || defined(__CC_ARM)
/* For IAR ARM and Keil MDK-ARM compilers */
# define PB_PACKED_STRUCT_START _Pragma("pack(push, 1)")
# define PB_PACKED_STRUCT_END _Pragma("pack(pop)")
# define pb_packed
#elif defined(_MSC_VER) && (_MSC_VER >= 1500)
/* For Microsoft Visual C++ */
# define PB_PACKED_STRUCT_START __pragma(pack(push, 1))
# define PB_PACKED_STRUCT_END __pragma(pack(pop))
# define pb_packed
#ifdef __GNUC__
/* This just reduces memory requirements, but is not required. */
#define pb_packed __attribute__((packed))
#else
/* Unknown compiler */
# define PB_PACKED_STRUCT_START
# define PB_PACKED_STRUCT_END
# define pb_packed
#endif
/* Handly macro for suppressing unreferenced-parameter compiler warnings. */
#ifndef PB_UNUSED
#define PB_UNUSED(x) (void)(x)
#endif
/* Compile-time assertion, used for checking compatible compilation options.
* If this does not work properly on your compiler, use
* #define PB_NO_STATIC_ASSERT to disable it.
*
* But before doing that, check carefully the error message / place where it
* comes from to see if the error has a real cause. Unfortunately the error
* message is not always very clear to read, but you can see the reason better
* in the place where the PB_STATIC_ASSERT macro was called.
*/
#ifndef PB_NO_STATIC_ASSERT
#ifndef PB_STATIC_ASSERT
#define PB_STATIC_ASSERT(COND,MSG) typedef char PB_STATIC_ASSERT_MSG(MSG, __LINE__, __COUNTER__)[(COND)?1:-1];
#define PB_STATIC_ASSERT_MSG(MSG, LINE, COUNTER) PB_STATIC_ASSERT_MSG_(MSG, LINE, COUNTER)
#define PB_STATIC_ASSERT_MSG_(MSG, LINE, COUNTER) pb_static_assertion_##MSG##LINE##COUNTER
#endif
#else
#define PB_STATIC_ASSERT(COND,MSG)
#endif
/* Number of required fields to keep track of. */
#ifndef PB_MAX_REQUIRED_FIELDS
#define PB_MAX_REQUIRED_FIELDS 64
#endif
#if PB_MAX_REQUIRED_FIELDS < 64
#error You should not lower PB_MAX_REQUIRED_FIELDS from the default value (64).
#define pb_packed
#endif
/* List of possible field types. These are used in the autogenerated code.
* Least-significant 4 bits tell the scalar type
* Most-significant 4 bits specify repeated/required/packed etc.
*
* INT32 and UINT32 are treated the same, as are (U)INT64 and (S)FIXED*
* These types are simply casted to correct field type when they are
* assigned to the memory pointer.
* SINT* is different, though, because it is zig-zag coded.
*/
/************************
* Field contents types *
************************/
typedef uint8_t pb_type_t;
/**** Field data types ****/
/* Numeric types */
#define PB_LTYPE_VARINT 0x00 /* int32, int64, enum, bool */
#define PB_LTYPE_UVARINT 0x01 /* uint32, uint64 */
#define PB_LTYPE_SVARINT 0x02 /* sint32, sint64 */
#define PB_LTYPE_FIXED32 0x03 /* fixed32, sfixed32, float */
#define PB_LTYPE_FIXED64 0x04 /* fixed64, sfixed64, double */
#define PB_LTYPE_VARINT 0x00 /* int32, uint32, int64, uint64, bool, enum */
#define PB_LTYPE_SVARINT 0x01 /* sint32, sint64 */
#define PB_LTYPE_FIXED32 0x02 /* fixed32, sfixed32, float */
#define PB_LTYPE_FIXED64 0x03 /* fixed64, sfixed64, double */
/* Marker for last packable field type. */
#define PB_LTYPE_LAST_PACKABLE 0x04
#define PB_LTYPE_LAST_PACKABLE 0x03
/* Byte array with pre-allocated buffer.
* data_size is the length of the allocated PB_BYTES_ARRAY structure. */
#define PB_LTYPE_BYTES 0x05
#define PB_LTYPE_BYTES 0x04
/* String with pre-allocated buffer.
* data_size is the maximum length. */
#define PB_LTYPE_STRING 0x06
#define PB_LTYPE_STRING 0x05
/* Submessage
* submsg_fields is pointer to field descriptions */
#define PB_LTYPE_SUBMESSAGE 0x07
/* Extension pseudo-field
* The field contains a pointer to pb_extension_t */
#define PB_LTYPE_EXTENSION 0x08
#define PB_LTYPE_SUBMESSAGE 0x06
/* Number of declared LTYPES */
#define PB_LTYPES_COUNT 9
#define PB_LTYPE_MASK 0x0F
#define PB_LTYPES_COUNT 7
/**** Field repetition rules ****/
/******************
* Modifier flags *
******************/
/* Just the basic, write data at data_offset */
#define PB_HTYPE_REQUIRED 0x00
/* Write true at size_offset */
#define PB_HTYPE_OPTIONAL 0x10
#define PB_HTYPE_REPEATED 0x20
#define PB_HTYPE_MASK 0x30
/**** Field allocation types ****/
#define PB_ATYPE_STATIC 0x00
#define PB_ATYPE_POINTER 0x80
#define PB_ATYPE_CALLBACK 0x40
#define PB_ATYPE_MASK 0xC0
/* Read to pre-allocated array
* Maximum number of entries is array_size,
* actual number is stored at size_offset */
#define PB_HTYPE_ARRAY 0x20
#define PB_ATYPE(x) ((x) & PB_ATYPE_MASK)
#define PB_HTYPE(x) ((x) & PB_HTYPE_MASK)
#define PB_LTYPE(x) ((x) & PB_LTYPE_MASK)
/* Works for all required/optional/repeated fields.
* data_offset points to pb_callback_t structure.
* LTYPE should be 0 (it is ignored, but sometimes
* used to speculatively index an array). */
#define PB_HTYPE_CALLBACK 0x30
/* Data type used for storing sizes of struct fields
* and array counts.
/* Indicates that a string, bytes or non-repeated submessage is
* represented using a pointer (char* for string, pb_byptes_array_t
* for bytes).
*/
#if defined(PB_FIELD_32BIT)
#define PB_SIZE_MAX ((uint32_t)-1)
typedef uint32_t pb_size_t;
typedef int32_t pb_ssize_t;
#elif defined(PB_FIELD_16BIT)
#define PB_SIZE_MAX ((uint16_t)-1)
typedef uint16_t pb_size_t;
typedef int16_t pb_ssize_t;
#else
#define PB_SIZE_MAX ((uint8_t)-1)
typedef uint8_t pb_size_t;
typedef int8_t pb_ssize_t;
#endif
#define PB_HTYPE_POINTER 0x80
#define PB_POINTER(x) ((x) & PB_HTYPE_POINTER)
#define PB_HTYPE(x) ((x) & 0x70)
#define PB_LTYPE(x) ((x) & 0x0F)
/* This structure is used in auto-generated constants
* to specify struct fields.
* You can change field sizes if you need structures
* You can change field sizes here if you need structures
* larger than 256 bytes or field tags larger than 256.
* The compiler should complain if your .proto has such
* structures. Fix that by defining PB_FIELD_16BIT or
* PB_FIELD_32BIT.
* structures ("initializer too large for type").
*/
PB_PACKED_STRUCT_START
typedef struct pb_field_s pb_field_t;
struct pb_field_s {
pb_size_t tag;
typedef struct _pb_field_t pb_field_t;
struct _pb_field_t {
uint8_t tag;
pb_type_t type;
pb_size_t data_offset; /* Offset of field data, relative to previous field. */
pb_ssize_t size_offset; /* Offset of array size or has-boolean, relative to data */
pb_size_t data_size; /* Data size in bytes for a single item */
pb_size_t array_size; /* Maximum number of entries in array */
uint8_t data_offset; /* Offset of field data, relative to previous field. */
int8_t size_offset; /* Offset of array size or has-boolean, relative to data */
uint8_t data_size; /* Data size in bytes for a single item */
uint8_t array_size; /* Maximum number of entries in array */
/* Field definitions for submessage
/* Pointer to message structure for submessage
* OR default value for all other non-array, non-callback types
* If null, then field will zeroed. */
const void *ptr;
} pb_packed;
PB_PACKED_STRUCT_END
/* Make sure that the standard integer types are of the expected sizes.
* All kinds of things may break otherwise.. atleast all fixed* types.
*
* If you get errors here, it probably means that your stdint.h is not
* correct for your platform.
*/
PB_STATIC_ASSERT(sizeof(int8_t) == 1, INT8_T_WRONG_SIZE)
PB_STATIC_ASSERT(sizeof(uint8_t) == 1, UINT8_T_WRONG_SIZE)
PB_STATIC_ASSERT(sizeof(int16_t) == 2, INT16_T_WRONG_SIZE)
PB_STATIC_ASSERT(sizeof(uint16_t) == 2, UINT16_T_WRONG_SIZE)
PB_STATIC_ASSERT(sizeof(int32_t) == 4, INT32_T_WRONG_SIZE)
PB_STATIC_ASSERT(sizeof(uint32_t) == 4, UINT32_T_WRONG_SIZE)
PB_STATIC_ASSERT(sizeof(int64_t) == 8, INT64_T_WRONG_SIZE)
PB_STATIC_ASSERT(sizeof(uint64_t) == 8, UINT64_T_WRONG_SIZE)
/* This structure is used for 'bytes' arrays.
* It has the number of bytes in the beginning, and after that an array.
* Note that actual structs used will have a different length of bytes array.
*/
#define PB_BYTES_ARRAY_T(n) struct { pb_size_t size; uint8_t bytes[n]; }
#define PB_BYTES_ARRAY_T_ALLOCSIZE(n) ((size_t)n + offsetof(pb_bytes_array_t, bytes))
struct pb_bytes_array_s {
pb_size_t size;
typedef struct {
size_t size;
uint8_t bytes[1];
};
typedef struct pb_bytes_array_s pb_bytes_array_t;
} pb_bytes_array_t;
/* This structure is used for dynamically allocated 'bytes' arrays.
*/
typedef struct {
size_t size;
size_t alloced;
uint8_t *bytes;
} pb_bytes_t;
/* This macro defines the type of a structure for a message with N
* fields.
*/
#define PB_MSG_STRUCT(N) struct { \
unsigned int field_count; \
size_t size; \
pb_field_t fields[N]; \
}
/* This is the visible type for generated message structures.
* The actual number of fields at the end will vary by message type.
*/
typedef PB_MSG_STRUCT(1) pb_message_t;
/* These macros are used to manipulate the has_fields array in
* generated messages.
*/
#define PB_FIELD_INDEX(TYPE, FIELD) TYPE ## _ ## FIELD ## _index
#define PB_FIELD_BYTE(TYPE, FIELD) (PB_FIELD_INDEX(TYPE, FIELD) / 8)
#define PB_FIELD_MASK(TYPE, FIELD) (1 << (PB_FIELD_INDEX(TYPE, FIELD) & 7))
#define PB_HAS_FIELD(STRUCT, TYPE, FIELD) \
(((STRUCT).has_fields[PB_FIELD_BYTE(TYPE, FIELD)] \
& PB_FIELD_MASK(TYPE, FIELD)) != 0)
#define PB_SET_FIELD(STRUCT, TYPE, FIELD) \
((STRUCT).has_fields[PB_FIELD_BYTE(TYPE, FIELD)] \
|= PB_FIELD_MASK(TYPE, FIELD))
#define PB_CLEAR_FIELD(STRUCT, TYPE, FIELD) \
((STRUCT).has_fields[PB_FIELD_BYTE(TYPE, FIELD)] \
&= ~PB_FIELD_MASK(TYPE, FIELD))
/* This structure is used for giving the callback function.
* It is stored in the message structure and filled in by the method that
@@ -275,23 +175,16 @@ typedef struct pb_bytes_array_s pb_bytes_array_t;
*
* The callback can be null if you want to skip a field.
*/
typedef struct pb_istream_s pb_istream_t;
typedef struct pb_ostream_s pb_ostream_t;
typedef struct pb_callback_s pb_callback_t;
struct pb_callback_s {
#ifdef PB_OLD_CALLBACK_STYLE
/* Deprecated since nanopb-0.2.1 */
typedef struct _pb_istream_t pb_istream_t;
typedef struct _pb_ostream_t pb_ostream_t;
typedef struct _pb_strstream_t pb_strstream_t;
typedef struct _pb_callback_t pb_callback_t;
struct _pb_callback_t {
union {
bool (*decode)(pb_istream_t *stream, const pb_field_t *field, void *arg);
bool (*encode)(pb_ostream_t *stream, const pb_field_t *field, const void *arg);
bool (*encode_buffer)(pb_strstream_t *stream, const pb_field_t *field, const void *arg);
} funcs;
#else
/* New function signature, which allows modifying arg contents in callback. */
union {
bool (*decode)(pb_istream_t *stream, const pb_field_t *field, void **arg);
bool (*encode)(pb_ostream_t *stream, const pb_field_t *field, void * const *arg);
} funcs;
#endif
/* Free arg for use by callback */
void *arg;
@@ -305,214 +198,12 @@ typedef enum {
PB_WT_32BIT = 5
} pb_wire_type_t;
/* Structure for defining the handling of unknown/extension fields.
* Usually the pb_extension_type_t structure is automatically generated,
* while the pb_extension_t structure is created by the user. However,
* if you want to catch all unknown fields, you can also create a custom
* pb_extension_type_t with your own callback.
*/
typedef struct pb_extension_type_s pb_extension_type_t;
typedef struct pb_extension_s pb_extension_t;
struct pb_extension_type_s {
/* Called for each unknown field in the message.
* If you handle the field, read off all of its data and return true.
* If you do not handle the field, do not read anything and return true.
* If you run into an error, return false.
* Set to NULL for default handler.
*/
bool (*decode)(pb_istream_t *stream, pb_extension_t *extension,
uint32_t tag, pb_wire_type_t wire_type);
/* Called once after all regular fields have been encoded.
* If you have something to write, do so and return true.
* If you do not have anything to write, just return true.
* If you run into an error, return false.
* Set to NULL for default handler.
*/
bool (*encode)(pb_ostream_t *stream, const pb_extension_t *extension);
/* Free field for use by the callback. */
const void *arg;
};
struct pb_extension_s {
/* Type describing the extension field. Usually you'll initialize
* this to a pointer to the automatically generated structure. */
const pb_extension_type_t *type;
/* Destination for the decoded data. This must match the datatype
* of the extension field. */
void *dest;
/* Pointer to the next extension handler, or NULL.
* If this extension does not match a field, the next handler is
* automatically called. */
pb_extension_t *next;
/* The decoder sets this to true if the extension was found.
* Ignored for encoding. */
bool found;
};
/* Memory allocation functions to use. You can define pb_realloc and
* pb_free to custom functions if you want. */
#ifdef PB_ENABLE_MALLOC
# ifndef pb_realloc
# define pb_realloc(ptr, size) realloc(ptr, size)
# endif
# ifndef pb_free
# define pb_free(ptr) free(ptr)
# endif
#endif
/* This is used to inform about need to regenerate .pb.h/.pb.c files. */
#define PB_PROTO_HEADER_VERSION 30
/* These macros are used to declare pb_field_t's in the constant array. */
/* Size of a structure member, in bytes. */
#define pb_membersize(st, m) (sizeof ((st*)0)->m)
/* Number of entries in an array. */
#define pb_arraysize(st, m) (pb_membersize(st, m) / pb_membersize(st, m[0]))
/* Delta from start of one member to the start of another member. */
#define pb_delta(st, m1, m2) ((int)offsetof(st, m1) - (int)offsetof(st, m2))
/* Marks the end of the field list */
#define PB_LAST_FIELD {0,(pb_type_t) 0,0,0,0,0,0}
#define pb_delta_end(st, m1, m2) (offsetof(st, m1) - offsetof(st, m2) - pb_membersize(st, m2))
#define PB_LAST_FIELD {0,0,0,0}
/* Macros for filling in the data_offset field */
/* data_offset for first field in a message */
#define PB_DATAOFFSET_FIRST(st, m1, m2) (offsetof(st, m1))
/* data_offset for subsequent fields */
#define PB_DATAOFFSET_OTHER(st, m1, m2) (offsetof(st, m1) - offsetof(st, m2) - pb_membersize(st, m2))
/* Choose first/other based on m1 == m2 (deprecated, remains for backwards compatibility) */
#define PB_DATAOFFSET_CHOOSE(st, m1, m2) (int)(offsetof(st, m1) == offsetof(st, m2) \
? PB_DATAOFFSET_FIRST(st, m1, m2) \
: PB_DATAOFFSET_OTHER(st, m1, m2))
/* Required fields are the simplest. They just have delta (padding) from
* previous field end, and the size of the field. Pointer is used for
* submessages and default values.
*/
#define PB_REQUIRED_STATIC(tag, st, m, fd, ltype, ptr) \
{tag, PB_ATYPE_STATIC | PB_HTYPE_REQUIRED | ltype, \
fd, 0, pb_membersize(st, m), 0, ptr}
/* Optional fields add the delta to the has_ variable. */
#define PB_OPTIONAL_STATIC(tag, st, m, fd, ltype, ptr) \
{tag, PB_ATYPE_STATIC | PB_HTYPE_OPTIONAL | ltype, \
fd, \
pb_delta(st, has_ ## m, m), \
pb_membersize(st, m), 0, ptr}
/* Repeated fields have a _count field and also the maximum number of entries. */
#define PB_REPEATED_STATIC(tag, st, m, fd, ltype, ptr) \
{tag, PB_ATYPE_STATIC | PB_HTYPE_REPEATED | ltype, \
fd, \
pb_delta(st, m ## _count, m), \
pb_membersize(st, m[0]), \
pb_arraysize(st, m), ptr}
/* Allocated fields carry the size of the actual data, not the pointer */
#define PB_REQUIRED_POINTER(tag, st, m, fd, ltype, ptr) \
{tag, PB_ATYPE_POINTER | PB_HTYPE_REQUIRED | ltype, \
fd, 0, pb_membersize(st, m[0]), 0, ptr}
/* Optional fields don't need a has_ variable, as information would be redundant */
#define PB_OPTIONAL_POINTER(tag, st, m, fd, ltype, ptr) \
{tag, PB_ATYPE_POINTER | PB_HTYPE_OPTIONAL | ltype, \
fd, 0, pb_membersize(st, m[0]), 0, ptr}
/* Repeated fields have a _count field and a pointer to array of pointers */
#define PB_REPEATED_POINTER(tag, st, m, fd, ltype, ptr) \
{tag, PB_ATYPE_POINTER | PB_HTYPE_REPEATED | ltype, \
fd, pb_delta(st, m ## _count, m), \
pb_membersize(st, m[0]), 0, ptr}
/* Callbacks are much like required fields except with special datatype. */
#define PB_REQUIRED_CALLBACK(tag, st, m, fd, ltype, ptr) \
{tag, PB_ATYPE_CALLBACK | PB_HTYPE_REQUIRED | ltype, \
fd, 0, pb_membersize(st, m), 0, ptr}
#define PB_OPTIONAL_CALLBACK(tag, st, m, fd, ltype, ptr) \
{tag, PB_ATYPE_CALLBACK | PB_HTYPE_OPTIONAL | ltype, \
fd, 0, pb_membersize(st, m), 0, ptr}
#define PB_REPEATED_CALLBACK(tag, st, m, fd, ltype, ptr) \
{tag, PB_ATYPE_CALLBACK | PB_HTYPE_REPEATED | ltype, \
fd, 0, pb_membersize(st, m), 0, ptr}
/* Optional extensions don't have the has_ field, as that would be redundant. */
#define PB_OPTEXT_STATIC(tag, st, m, fd, ltype, ptr) \
{tag, PB_ATYPE_STATIC | PB_HTYPE_OPTIONAL | ltype, \
0, \
0, \
pb_membersize(st, m), 0, ptr}
#define PB_OPTEXT_CALLBACK(tag, st, m, fd, ltype, ptr) \
{tag, PB_ATYPE_CALLBACK | PB_HTYPE_OPTIONAL | ltype, \
0, 0, pb_membersize(st, m), 0, ptr}
/* The mapping from protobuf types to LTYPEs is done using these macros. */
#define PB_LTYPE_MAP_BOOL PB_LTYPE_VARINT
#define PB_LTYPE_MAP_BYTES PB_LTYPE_BYTES
#define PB_LTYPE_MAP_DOUBLE PB_LTYPE_FIXED64
#define PB_LTYPE_MAP_ENUM PB_LTYPE_VARINT
#define PB_LTYPE_MAP_FIXED32 PB_LTYPE_FIXED32
#define PB_LTYPE_MAP_FIXED64 PB_LTYPE_FIXED64
#define PB_LTYPE_MAP_FLOAT PB_LTYPE_FIXED32
#define PB_LTYPE_MAP_INT32 PB_LTYPE_VARINT
#define PB_LTYPE_MAP_INT64 PB_LTYPE_VARINT
#define PB_LTYPE_MAP_MESSAGE PB_LTYPE_SUBMESSAGE
#define PB_LTYPE_MAP_SFIXED32 PB_LTYPE_FIXED32
#define PB_LTYPE_MAP_SFIXED64 PB_LTYPE_FIXED64
#define PB_LTYPE_MAP_SINT32 PB_LTYPE_SVARINT
#define PB_LTYPE_MAP_SINT64 PB_LTYPE_SVARINT
#define PB_LTYPE_MAP_STRING PB_LTYPE_STRING
#define PB_LTYPE_MAP_UINT32 PB_LTYPE_UVARINT
#define PB_LTYPE_MAP_UINT64 PB_LTYPE_UVARINT
#define PB_LTYPE_MAP_EXTENSION PB_LTYPE_EXTENSION
/* This is the actual macro used in field descriptions.
* It takes these arguments:
* - Field tag number
* - Field type: BOOL, BYTES, DOUBLE, ENUM, FIXED32, FIXED64,
* FLOAT, INT32, INT64, MESSAGE, SFIXED32, SFIXED64
* SINT32, SINT64, STRING, UINT32, UINT64 or EXTENSION
* - Field rules: REQUIRED, OPTIONAL or REPEATED
* - Allocation: STATIC or CALLBACK
* - Placement: FIRST or OTHER, depending on if this is the first field in structure.
* - Message name
* - Field name
* - Previous field name (or field name again for first field)
* - Pointer to default value or submsg fields.
*/
#define PB_FIELD(tag, type, rules, allocation, placement, message, field, prevfield, ptr) \
PB_ ## rules ## _ ## allocation(tag, message, field, \
PB_DATAOFFSET_ ## placement(message, field, prevfield), \
PB_LTYPE_MAP_ ## type, ptr)
/* These macros are used for giving out error messages.
* They are mostly a debugging aid; the main error information
* is the true/false return value from functions.
* Some code space can be saved by disabling the error
* messages if not used.
*/
#ifdef PB_NO_ERRMSG
#define PB_RETURN_ERROR(stream,msg) \
do {\
PB_UNUSED(stream); \
return false; \
} while(0)
#define PB_GET_ERROR(stream) "(errmsg disabled)"
#else
#define PB_RETURN_ERROR(stream,msg) \
do {\
if ((stream)->errmsg == NULL) \
(stream)->errmsg = (msg); \
return false; \
} while(0)
#define PB_GET_ERROR(stream) ((stream)->errmsg ? (stream)->errmsg : "(none)")
#endif
#endif

90
pb_common.c
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@@ -1,90 +0,0 @@
/* pb_common.c: Common support functions for pb_encode.c and pb_decode.c.
*
* 2014 Petteri Aimonen <jpa@kapsi.fi>
*/
#include "pb_common.h"
bool pb_field_iter_begin(pb_field_iter_t *iter, const pb_field_t *fields, void *dest_struct)
{
iter->start = fields;
iter->pos = fields;
iter->required_field_index = 0;
iter->dest_struct = dest_struct;
iter->pData = (char*)dest_struct + iter->pos->data_offset;
iter->pSize = (char*)iter->pData + iter->pos->size_offset;
return (iter->pos->tag != 0);
}
bool pb_field_iter_next(pb_field_iter_t *iter)
{
const pb_field_t *prev_field = iter->pos;
if (prev_field->tag == 0)
{
/* Handle empty message types, where the first field is already the terminator.
* In other cases, the iter->pos never points to the terminator. */
return false;
}
iter->pos++;
if (iter->pos->tag == 0)
{
/* Wrapped back to beginning, reinitialize */
(void)pb_field_iter_begin(iter, iter->start, iter->dest_struct);
return false;
}
else
{
/* Increment the pointers based on previous field size */
size_t prev_size = prev_field->data_size;
if (PB_ATYPE(prev_field->type) == PB_ATYPE_STATIC &&
PB_HTYPE(prev_field->type) == PB_HTYPE_REPEATED)
{
/* In static arrays, the data_size tells the size of a single entry and
* array_size is the number of entries */
prev_size *= prev_field->array_size;
}
else if (PB_ATYPE(prev_field->type) == PB_ATYPE_POINTER)
{
/* Pointer fields always have a constant size in the main structure.
* The data_size only applies to the dynamically allocated area. */
prev_size = sizeof(void*);
}
if (PB_HTYPE(prev_field->type) == PB_HTYPE_REQUIRED)
{
/* Count the required fields, in order to check their presence in the
* decoder. */
iter->required_field_index++;
}
iter->pData = (char*)iter->pData + prev_size + iter->pos->data_offset;
iter->pSize = (char*)iter->pData + iter->pos->size_offset;
return true;
}
}
bool pb_field_iter_find(pb_field_iter_t *iter, uint32_t tag)
{
const pb_field_t *start = iter->pos;
do {
if (iter->pos->tag == tag &&
PB_LTYPE(iter->pos->type) != PB_LTYPE_EXTENSION)
{
/* Found the wanted field */
return true;
}
(void)pb_field_iter_next(iter);
} while (iter->pos != start);
/* Searched all the way back to start, and found nothing. */
return false;
}

42
pb_common.h
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@@ -1,42 +0,0 @@
/* pb_common.h: Common support functions for pb_encode.c and pb_decode.c.
* These functions are rarely needed by applications directly.
*/
#ifndef PB_COMMON_H_INCLUDED
#define PB_COMMON_H_INCLUDED
#include "pb.h"
#ifdef __cplusplus
extern "C" {
#endif
/* Iterator for pb_field_t list */
struct pb_field_iter_s {
const pb_field_t *start; /* Start of the pb_field_t array */
const pb_field_t *pos; /* Current position of the iterator */
unsigned required_field_index; /* Zero-based index that counts only the required fields */
void *dest_struct; /* Pointer to start of the structure */
void *pData; /* Pointer to current field value */
void *pSize; /* Pointer to count/has field */
};
typedef struct pb_field_iter_s pb_field_iter_t;
/* Initialize the field iterator structure to beginning.
* Returns false if the message type is empty. */
bool pb_field_iter_begin(pb_field_iter_t *iter, const pb_field_t *fields, void *dest_struct);
/* Advance the iterator to the next field.
* Returns false when the iterator wraps back to the first field. */
bool pb_field_iter_next(pb_field_iter_t *iter);
/* Advance the iterator until it points at a field with the given tag.
* Returns false if no such field exists. */
bool pb_field_iter_find(pb_field_iter_t *iter, uint32_t tag);
#ifdef __cplusplus
} /* extern "C" */
#endif
#endif

1254
pb_decode.c
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File diff suppressed because it is too large Load Diff

172
pb_decode.h
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@@ -1,149 +1,77 @@
#ifndef _PB_DECODE_H_
#define _PB_DECODE_H_
/* pb_decode.h: Functions to decode protocol buffers. Depends on pb_decode.c.
* The main function is pb_decode. You also need an input stream, and the
* field descriptions created by nanopb_generator.py.
* The main function is pb_decode. You will also need to create an input
* stream, which is easiest to do with pb_istream_t.
*
* You also need structures and their corresponding pb_field_t descriptions.
* These are usually generated from .proto-files with a script.
*/
#ifndef PB_DECODE_H_INCLUDED
#define PB_DECODE_H_INCLUDED
#include <stdbool.h>
#include "pb.h"
#ifdef __cplusplus
extern "C" {
#endif
/* Structure for defining custom input streams. You will need to provide
* a callback function to read the bytes from your storage, which can be
* for example a file or a network socket.
/* Lightweight input stream.
* You can provide a callback function for reading or use
* pb_istream_from_buffer.
*
* The callback must conform to these rules:
*
* Rules for callback:
* 1) Return false on IO errors. This will cause decoding to abort.
* 2) You can use state to store your own data (e.g. buffer pointer),
* and rely on pb_read to verify that no-body reads past bytes_left.
* 3) Your callback may be used with substreams, in which case bytes_left
* is different than from the main stream. Don't use bytes_left to compute
* any pointers.
*
* 2) If buf is NULL, read but don't store bytes ("skip input").
*
* 3) You can use state to store your own data (e.g. buffer pointer),
* and rely on pb_read to verify that no-body reads past bytes_left.
*
* 4) Your callback may be used with substreams, in which case bytes_left
* is different than from the main stream. Don't use bytes_left to compute
* any pointers.
*/
struct pb_istream_s
struct _pb_istream_t
{
#ifdef PB_BUFFER_ONLY
/* Callback pointer is not used in buffer-only configuration.
* Having an int pointer here allows binary compatibility but
* gives an error if someone tries to assign callback function.
*/
int *callback;
#else
bool (*callback)(pb_istream_t *stream, uint8_t *buf, size_t count);
#endif
void *state; /* Free field for use by callback implementation */
size_t bytes_left;
#ifndef PB_NO_ERRMSG
const char *errmsg;
#endif
};
/***************************
* Main decoding functions *
***************************/
/* Decode a single protocol buffers message from input stream into a C structure.
* Returns true on success, false on any failure.
* The actual struct pointed to by dest must match the description in fields.
* Callback fields of the destination structure must be initialized by caller.
* All other fields will be initialized by this function.
*
* Example usage:
* MyMessage msg = {};
* uint8_t buffer[64];
* pb_istream_t stream;
*
* // ... read some data into buffer ...
*
* stream = pb_istream_from_buffer(buffer, count);
* pb_decode(&stream, MyMessage_fields, &msg);
*/
bool pb_decode(pb_istream_t *stream, const pb_field_t fields[], void *dest_struct);
/* Same as pb_decode, except does not initialize the destination structure
* to default values. This is slightly faster if you need no default values
* and just do memset(struct, 0, sizeof(struct)) yourself.
*
* This can also be used for 'merging' two messages, i.e. update only the
* fields that exist in the new message.
*
* Note: If this function returns with an error, it will not release any
* dynamically allocated fields. You will need to call pb_release() yourself.
*/
bool pb_decode_noinit(pb_istream_t *stream, const pb_field_t fields[], void *dest_struct);
/* Same as pb_decode, except expects the stream to start with the message size
* encoded as varint. Corresponds to parseDelimitedFrom() in Google's
* protobuf API.
*/
bool pb_decode_delimited(pb_istream_t *stream, const pb_field_t fields[], void *dest_struct);
#ifdef PB_ENABLE_MALLOC
/* Release any allocated pointer fields. If you use dynamic allocation, you should
* call this for any successfully decoded message when you are done with it. If
* pb_decode() returns with an error, the message is already released.
*/
void pb_release(const pb_field_t fields[], void *dest_struct);
#endif
/**************************************
* Functions for manipulating streams *
**************************************/
/* Create an input stream for reading from a memory buffer.
*
* Alternatively, you can use a custom stream that reads directly from e.g.
* a file or a network socket.
*/
pb_istream_t pb_istream_from_buffer(uint8_t *buf, size_t bufsize);
/* Function to read from a pb_istream_t. You can use this if you need to
* read some custom header data, or to read data in field callbacks.
*/
bool pb_read(pb_istream_t *stream, uint8_t *buf, size_t count);
/* Decode from stream to destination struct.
* Returns true on success, false on any failure.
* The actual struct pointed to by dest must match the description in msg.
*/
bool pb_decode(pb_istream_t *stream, const pb_message_t *msg, void *dest_struct);
/************************************************
* Helper functions for writing field callbacks *
************************************************/
/* --- Helper functions ---
* You may want to use these from your caller or callbacks.
*/
/* Decode the tag for the next field in the stream. Gives the wire type and
* field tag. At end of the message, returns false and sets eof to true. */
bool pb_decode_tag(pb_istream_t *stream, pb_wire_type_t *wire_type, uint32_t *tag, bool *eof);
/* Skip the field payload data, given the wire type. */
bool pb_skip_field(pb_istream_t *stream, pb_wire_type_t wire_type);
/* Decode an integer in the varint format. This works for bool, enum, int32,
* int64, uint32 and uint64 field types. */
bool pb_decode_varint(pb_istream_t *stream, uint64_t *dest);
/* Decode an integer in the zig-zagged svarint format. This works for sint32
* and sint64. */
bool pb_decode_svarint(pb_istream_t *stream, int64_t *dest);
bool pb_skip_varint(pb_istream_t *stream);
bool pb_skip_string(pb_istream_t *stream);
/* Decode a fixed32, sfixed32 or float value. You need to pass a pointer to
* a 4-byte wide C variable. */
bool pb_decode_fixed32(pb_istream_t *stream, void *dest);
/* --- Field decoders ---
* Each decoder takes stream and field description, and a pointer to the field
* in the destination struct (dest = struct_addr + field->data_offset).
* For arrays, these functions are called repeatedly.
*/
/* Decode a fixed64, sfixed64 or double value. You need to pass a pointer to
* a 8-byte wide C variable. */
bool pb_decode_fixed64(pb_istream_t *stream, void *dest);
bool pb_dec_varint(pb_istream_t *stream, const pb_field_t *field, void *dest);
bool pb_dec_svarint(pb_istream_t *stream, const pb_field_t *field, void *dest);
bool pb_dec_fixed32(pb_istream_t *stream, const pb_field_t *field, void *dest);
bool pb_dec_fixed64(pb_istream_t *stream, const pb_field_t *field, void *dest);
/* Make a limited-length substream for reading a PB_WT_STRING field. */
bool pb_make_string_substream(pb_istream_t *stream, pb_istream_t *substream);
void pb_close_string_substream(pb_istream_t *stream, pb_istream_t *substream);
bool pb_dec_bytes(pb_istream_t *stream, const pb_field_t *field, void *dest);
bool pb_dec_string(pb_istream_t *stream, const pb_field_t *field, void *dest);
bool pb_dec_submessage(pb_istream_t *stream, const pb_field_t *field, void *dest);
#ifdef __cplusplus
} /* extern "C" */
#endif
/* Release memory and clear pointers for any unused elements of
* dest_struct. This function is only compiled when MALLOC_HEADER is
* defined for pb_decode.c.
*/
bool pb_clean(const pb_message_t *msg, void *dest_struct);
#endif

615
pb_encode.c
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@@ -5,82 +5,49 @@
#include "pb.h"
#include "pb_encode.h"
#include "pb_common.h"
#include <string.h>
/* Use the GCC warn_unused_result attribute to check that all return values
* are propagated correctly. On other compilers and gcc before 3.4.0 just
* ignore the annotation.
*/
#if !defined(__GNUC__) || ( __GNUC__ < 3) || (__GNUC__ == 3 && __GNUC_MINOR__ < 4)
#define checkreturn
#ifdef __GNUC__
/* Verify that we remember to check all return values for proper error propagation */
#define checkreturn __attribute__((warn_unused_result))
#else
#define checkreturn __attribute__((warn_unused_result))
#define checkreturn
#endif
/**************************************
* Declarations internal to this file *
**************************************/
typedef bool (*pb_encoder_t)(pb_ostream_t *stream, const pb_field_t *field, const void *src) checkreturn;
static bool checkreturn buf_write(pb_ostream_t *stream, const uint8_t *buf, size_t count);
static bool checkreturn encode_array(pb_ostream_t *stream, const pb_field_t *field, const void *pData, size_t count, pb_encoder_t func);
static bool checkreturn encode_field(pb_ostream_t *stream, const pb_field_t *field, const void *pData);
static bool checkreturn default_extension_encoder(pb_ostream_t *stream, const pb_extension_t *extension);
static bool checkreturn encode_extension_field(pb_ostream_t *stream, const pb_field_t *field, const void *pData);
static bool checkreturn pb_enc_varint(pb_ostream_t *stream, const pb_field_t *field, const void *src);
static bool checkreturn pb_enc_uvarint(pb_ostream_t *stream, const pb_field_t *field, const void *src);
static bool checkreturn pb_enc_svarint(pb_ostream_t *stream, const pb_field_t *field, const void *src);
static bool checkreturn pb_enc_fixed32(pb_ostream_t *stream, const pb_field_t *field, const void *src);
static bool checkreturn pb_enc_fixed64(pb_ostream_t *stream, const pb_field_t *field, const void *src);
static bool checkreturn pb_enc_bytes(pb_ostream_t *stream, const pb_field_t *field, const void *src);
static bool checkreturn pb_enc_string(pb_ostream_t *stream, const pb_field_t *field, const void *src);
static bool checkreturn pb_enc_submessage(pb_ostream_t *stream, const pb_field_t *field, const void *src);
typedef bool (*pb_encoder_t)(pb_ostream_t *stream, const pb_field_t *field, const void *src) checkreturn;
/* --- Function pointers to field encoders ---
* Order in the array must match pb_action_t LTYPE numbering.
*/
static const pb_encoder_t PB_ENCODERS[PB_LTYPES_COUNT] = {
&pb_enc_varint,
&pb_enc_uvarint,
&pb_enc_svarint,
&pb_enc_fixed32,
&pb_enc_fixed64,
&pb_enc_bytes,
&pb_enc_string,
&pb_enc_submessage,
NULL /* extensions */
&pb_enc_submessage
};
/*******************************
* pb_ostream_t implementation *
*******************************/
/* pb_ostream_t implementation */
static bool checkreturn buf_write(pb_ostream_t *stream, const uint8_t *buf, size_t count)
{
uint8_t *dest = (uint8_t*)stream->state;
memcpy(dest, buf, count);
stream->state = dest + count;
while (count--)
*dest++ = *buf++;
return true;
}
pb_ostream_t pb_ostream_from_buffer(uint8_t *buf, size_t bufsize)
{
pb_ostream_t stream;
#ifdef PB_BUFFER_ONLY
stream.callback = (void*)1; /* Just a marker value */
#else
stream.callback = &buf_write;
#endif
stream.state = buf;
stream.max_size = bufsize;
stream.bytes_written = 0;
#ifndef PB_NO_ERRMSG
stream.errmsg = NULL;
#endif
return stream;
}
@@ -89,40 +56,32 @@ bool checkreturn pb_write(pb_ostream_t *stream, const uint8_t *buf, size_t count
if (stream->callback != NULL)
{
if (stream->bytes_written + count > stream->max_size)
PB_RETURN_ERROR(stream, "stream full");
#ifdef PB_BUFFER_ONLY
if (!buf_write(stream, buf, count))
PB_RETURN_ERROR(stream, "io error");
#else
return false;
if (!stream->callback(stream, buf, count))
PB_RETURN_ERROR(stream, "io error");
#endif
return false;
}
stream->bytes_written += count;
return true;
}
/*************************
* Encode a single field *
*************************/
/* Main encoding stuff */
/* Encode a static array. Handles the size calculations and possible packing. */
/* Callbacks don't need this function because they usually know the data type
* without examining the field structure.
* Therefore it is static for now.
*/
static bool checkreturn encode_array(pb_ostream_t *stream, const pb_field_t *field,
const void *pData, size_t count, pb_encoder_t func)
{
size_t i;
int i;
const void *p;
size_t size;
if (count == 0)
return true;
if (PB_ATYPE(field->type) != PB_ATYPE_POINTER && count > field->array_size)
PB_RETURN_ERROR(stream, "array max size exceeded");
/* We always pack arrays if the datatype allows it. */
if (PB_LTYPE(field->type) <= PB_LTYPE_LAST_PACKABLE)
{
if (!pb_encode_tag(stream, PB_WT_STRING, field->tag))
@@ -138,8 +97,8 @@ static bool checkreturn encode_array(pb_ostream_t *stream, const pb_field_t *fie
size = 8 * count;
}
else
{
pb_ostream_t sizestream = PB_OSTREAM_SIZING;
{
pb_ostream_t sizestream = {0};
p = pData;
for (i = 0; i < count; i++)
{
@@ -150,7 +109,7 @@ static bool checkreturn encode_array(pb_ostream_t *stream, const pb_field_t *fie
size = sizestream.bytes_written;
}
if (!pb_encode_varint(stream, (uint64_t)size))
if (!pb_encode_varint(stream, size))
return false;
if (stream->callback == NULL)
@@ -172,23 +131,8 @@ static bool checkreturn encode_array(pb_ostream_t *stream, const pb_field_t *fie
{
if (!pb_encode_tag_for_field(stream, field))
return false;
/* Normally the data is stored directly in the array entries, but
* for pointer-type string and bytes fields, the array entries are
* actually pointers themselves also. So we have to dereference once
* more to get to the actual data. */
if (PB_ATYPE(field->type) == PB_ATYPE_POINTER &&
(PB_LTYPE(field->type) == PB_LTYPE_STRING ||
PB_LTYPE(field->type) == PB_LTYPE_BYTES))
{
if (!func(stream, field, *(const void* const*)p))
return false;
}
else
{
if (!func(stream, field, p))
return false;
}
if (!func(stream, field, p))
return false;
p = (const char*)p + field->data_size;
}
}
@@ -196,210 +140,77 @@ static bool checkreturn encode_array(pb_ostream_t *stream, const pb_field_t *fie
return true;
}
/* Encode a field with static or pointer allocation, i.e. one whose data
* is available to the encoder directly. */
static bool checkreturn encode_basic_field(pb_ostream_t *stream,
const pb_field_t *field, const void *pData)
bool checkreturn pb_encode(pb_ostream_t *stream, const pb_message_t *msg, const void *src_struct)
{
pb_encoder_t func;
const void *pData = src_struct;
const void *pSize;
bool implicit_has = true;
const char *has_fields = src_struct;
unsigned int i;
size_t prev_size = 0;
func = PB_ENCODERS[PB_LTYPE(field->type)];
if (field->size_offset)
for (i = 0; i < msg->field_count; i++)
{
const pb_field_t *field = &msg->fields[i];
pb_encoder_t func = PB_ENCODERS[PB_LTYPE(field->type)];
pData = (const char*)pData + prev_size + field->data_offset;
pSize = (const char*)pData + field->size_offset;
else
pSize = &implicit_has;
if (PB_ATYPE(field->type) == PB_ATYPE_POINTER)
{
/* pData is a pointer to the field, which contains pointer to
* the data. If the 2nd pointer is NULL, it is interpreted as if
* the has_field was false.
*/
pData = *(const void* const*)pData;
implicit_has = (pData != NULL);
}
switch (PB_HTYPE(field->type))
{
case PB_HTYPE_REQUIRED:
if (!pData)
PB_RETURN_ERROR(stream, "missing required field");
if (!pb_encode_tag_for_field(stream, field))
return false;
if (!func(stream, field, pData))
return false;
break;
case PB_HTYPE_OPTIONAL:
if (*(const bool*)pSize)
{
prev_size = field->data_size;
if (PB_HTYPE(field->type) == PB_HTYPE_ARRAY)
prev_size *= field->array_size;
switch (PB_HTYPE(field->type))
{
case PB_HTYPE_OPTIONAL:
if (!(has_fields[i/8] & (1 << i%8)))
break;
if (PB_POINTER(field->type)
&& (PB_LTYPE(field->type) == PB_LTYPE_STRING
|| PB_LTYPE(field->type) == PB_LTYPE_SUBMESSAGE)
&& *(void**)pData == NULL)
break;
/* else fall through to required case */
case PB_HTYPE_REQUIRED:
if (!pb_encode_tag_for_field(stream, field))
return false;
if (!func(stream, field, pData))
return false;
break;
case PB_HTYPE_ARRAY:
if (!encode_array(stream, field, pData, *(size_t*)pSize, func))
return false;
break;
case PB_HTYPE_CALLBACK:
{
pb_callback_t *callback = (pb_callback_t*)pData;
if (callback->funcs.encode != NULL)
{
if (!callback->funcs.encode(stream, field, callback->arg))
return false;
}
break;
}
break;
case PB_HTYPE_REPEATED:
if (!encode_array(stream, field, pData, *(const pb_size_t*)pSize, func))
return false;
break;
default:
PB_RETURN_ERROR(stream, "invalid field type");
}
return true;
}
/* Encode a field with callback semantics. This means that a user function is
* called to provide and encode the actual data. */
static bool checkreturn encode_callback_field(pb_ostream_t *stream,
const pb_field_t *field, const void *pData)
{
const pb_callback_t *callback = (const pb_callback_t*)pData;
#ifdef PB_OLD_CALLBACK_STYLE
const void *arg = callback->arg;
#else
void * const *arg = &(callback->arg);
#endif
if (callback->funcs.encode != NULL)
{
if (!callback->funcs.encode(stream, field, arg))
PB_RETURN_ERROR(stream, "callback error");
}
return true;
}
/* Encode a single field of any callback or static type. */
static bool checkreturn encode_field(pb_ostream_t *stream,
const pb_field_t *field, const void *pData)
{
switch (PB_ATYPE(field->type))
{
case PB_ATYPE_STATIC:
case PB_ATYPE_POINTER:
return encode_basic_field(stream, field, pData);
case PB_ATYPE_CALLBACK:
return encode_callback_field(stream, field, pData);
default:
PB_RETURN_ERROR(stream, "invalid field type");
}
}
/* Default handler for extension fields. Expects to have a pb_field_t
* pointer in the extension->type->arg field. */
static bool checkreturn default_extension_encoder(pb_ostream_t *stream,
const pb_extension_t *extension)
{
const pb_field_t *field = (const pb_field_t*)extension->type->arg;
return encode_field(stream, field, extension->dest);
}
/* Walk through all the registered extensions and give them a chance
* to encode themselves. */
static bool checkreturn encode_extension_field(pb_ostream_t *stream,
const pb_field_t *field, const void *pData)
{
const pb_extension_t *extension = *(const pb_extension_t* const *)pData;
PB_UNUSED(field);
while (extension)
{
bool status;
if (extension->type->encode)
status = extension->type->encode(stream, extension);
else
status = default_extension_encoder(stream, extension);
if (!status)
return false;
extension = extension->next;
}
return true;
}
/*********************
* Encode all fields *
*********************/
static void *remove_const(const void *p)
{
/* Note: this casts away const, in order to use the common field iterator
* logic for both encoding and decoding. */
union {
void *p1;
const void *p2;
} t;
t.p2 = p;
return t.p1;
}
bool checkreturn pb_encode(pb_ostream_t *stream, const pb_field_t fields[], const void *src_struct)
{
pb_field_iter_t iter;
if (!pb_field_iter_begin(&iter, fields, remove_const(src_struct)))
return true; /* Empty message type */
do {
if (PB_LTYPE(iter.pos->type) == PB_LTYPE_EXTENSION)
{
/* Special case for the extension field placeholder */
if (!encode_extension_field(stream, iter.pos, iter.pData))
return false;
}
else
{
/* Regular field */
if (!encode_field(stream, iter.pos, iter.pData))
return false;
}
} while (pb_field_iter_next(&iter));
}
return true;
}
bool pb_encode_delimited(pb_ostream_t *stream, const pb_field_t fields[], const void *src_struct)
{
return pb_encode_submessage(stream, fields, src_struct);
}
bool pb_get_encoded_size(size_t *size, const pb_field_t fields[], const void *src_struct)
{
pb_ostream_t stream = PB_OSTREAM_SIZING;
if (!pb_encode(&stream, fields, src_struct))
return false;
*size = stream.bytes_written;
return true;
}
/********************
* Helper functions *
********************/
/* Helper functions */
bool checkreturn pb_encode_varint(pb_ostream_t *stream, uint64_t value)
{
uint8_t buffer[10];
size_t i = 0;
int i = 0;
if (value == 0)
return pb_write(stream, (uint8_t*)&value, 1);
while (value)
{
buffer[i] = (uint8_t)((value & 0x7F) | 0x80);
buffer[i] = (value & 0x7F) | 0x80;
value >>= 7;
i++;
}
@@ -408,54 +219,9 @@ bool checkreturn pb_encode_varint(pb_ostream_t *stream, uint64_t value)
return pb_write(stream, buffer, i);
}
bool checkreturn pb_encode_svarint(pb_ostream_t *stream, int64_t value)
bool checkreturn pb_encode_tag(pb_ostream_t *stream, pb_wire_type_t wiretype, int field_number)
{
uint64_t zigzagged;
if (value < 0)
zigzagged = ~((uint64_t)value << 1);
else
zigzagged = (uint64_t)value << 1;
return pb_encode_varint(stream, zigzagged);
}
bool checkreturn pb_encode_fixed32(pb_ostream_t *stream, const void *value)
{
#ifdef __BIG_ENDIAN__
const uint8_t *bytes = value;
uint8_t lebytes[4];
lebytes[0] = bytes[3];
lebytes[1] = bytes[2];
lebytes[2] = bytes[1];
lebytes[3] = bytes[0];
return pb_write(stream, lebytes, 4);
#else
return pb_write(stream, (const uint8_t*)value, 4);
#endif
}
bool checkreturn pb_encode_fixed64(pb_ostream_t *stream, const void *value)
{
#ifdef __BIG_ENDIAN__
const uint8_t *bytes = value;
uint8_t lebytes[8];
lebytes[0] = bytes[7];
lebytes[1] = bytes[6];
lebytes[2] = bytes[5];
lebytes[3] = bytes[4];
lebytes[4] = bytes[3];
lebytes[5] = bytes[2];
lebytes[6] = bytes[1];
lebytes[7] = bytes[0];
return pb_write(stream, lebytes, 8);
#else
return pb_write(stream, (const uint8_t*)value, 8);
#endif
}
bool checkreturn pb_encode_tag(pb_ostream_t *stream, pb_wire_type_t wiretype, uint32_t field_number)
{
uint64_t tag = ((uint64_t)field_number << 3) | wiretype;
int tag = wiretype | (field_number << 3);
return pb_encode_varint(stream, tag);
}
@@ -465,7 +231,6 @@ bool checkreturn pb_encode_tag_for_field(pb_ostream_t *stream, const pb_field_t
switch (PB_LTYPE(field->type))
{
case PB_LTYPE_VARINT:
case PB_LTYPE_UVARINT:
case PB_LTYPE_SVARINT:
wiretype = PB_WT_VARINT;
break;
@@ -485,7 +250,7 @@ bool checkreturn pb_encode_tag_for_field(pb_ostream_t *stream, const pb_field_t
break;
default:
PB_RETURN_ERROR(stream, "invalid field type");
return false;
}
return pb_encode_tag(stream, wiretype, field->tag);
@@ -493,37 +258,126 @@ bool checkreturn pb_encode_tag_for_field(pb_ostream_t *stream, const pb_field_t
bool checkreturn pb_encode_string(pb_ostream_t *stream, const uint8_t *buffer, size_t size)
{
if (!pb_encode_varint(stream, (uint64_t)size))
if (!pb_encode_varint(stream, size))
return false;
return pb_write(stream, buffer, size);
}
bool checkreturn pb_encode_submessage(pb_ostream_t *stream, const pb_field_t fields[], const void *src_struct)
/* Field encoders */
/* Copy srcsize bytes from src so that values are casted properly.
* On little endian machine, copy to start of dest
* On big endian machine, copy to end of dest
* destsize must always be larger than srcsize
*
* Note: This is the reverse of the endian_copy in pb_decode.c.
*/
static void endian_copy(void *dest, const void *src, size_t destsize, size_t srcsize)
{
/* First calculate the message size using a non-writing substream. */
pb_ostream_t substream = PB_OSTREAM_SIZING;
#ifdef __BIG_ENDIAN__
memcpy((char*)dest + (destsize - srcsize), src, srcsize);
#else
memcpy(dest, src, srcsize);
#endif
}
bool checkreturn pb_enc_varint(pb_ostream_t *stream, const pb_field_t *field, const void *src)
{
uint64_t value = 0;
endian_copy(&value, src, sizeof(value), field->data_size);
return pb_encode_varint(stream, value);
}
bool checkreturn pb_enc_svarint(pb_ostream_t *stream, const pb_field_t *field, const void *src)
{
uint64_t value = 0;
uint64_t zigzagged;
uint64_t signbitmask, xormask;
endian_copy(&value, src, sizeof(value), field->data_size);
signbitmask = (uint64_t)0x80 << (field->data_size * 8 - 8);
xormask = ((uint64_t)-1) >> (64 - field->data_size * 8);
if (value & signbitmask)
zigzagged = ((value ^ xormask) << 1) | 1;
else
zigzagged = value << 1;
return pb_encode_varint(stream, zigzagged);
}
bool checkreturn pb_enc_fixed64(pb_ostream_t *stream, const pb_field_t *field, const void *src)
{
#ifdef __BIG_ENDIAN__
uint8_t bytes[8] = {0};
memcpy(bytes, src, 8);
uint8_t lebytes[8] = {bytes[7], bytes[6], bytes[5], bytes[4],
bytes[3], bytes[2], bytes[1], bytes[0]};
return pb_write(stream, lebytes, 8);
#else
return pb_write(stream, (uint8_t*)src, 8);
#endif
}
bool checkreturn pb_enc_fixed32(pb_ostream_t *stream, const pb_field_t *field, const void *src)
{
#ifdef __BIG_ENDIAN__
uint8_t bytes[4] = {0};
memcpy(bytes, src, 4);
uint8_t lebytes[4] = {bytes[3], bytes[2], bytes[1], bytes[0]};
return pb_write(stream, lebytes, 4);
#else
return pb_write(stream, (uint8_t*)src, 4);
#endif
}
bool checkreturn pb_enc_bytes(pb_ostream_t *stream, const pb_field_t *field, const void *src)
{
if ((field != NULL) && PB_POINTER(field->type)) {
pb_bytes_t *bytes = (pb_bytes_t*)src;
return pb_encode_string(stream, bytes->bytes, bytes->size);
} else {
pb_bytes_array_t *bytes = (pb_bytes_array_t*)src;
return pb_encode_string(stream, bytes->bytes, bytes->size);
}
}
bool checkreturn pb_enc_string(pb_ostream_t *stream, const pb_field_t *field, const void *src)
{
size_t len;
if ((field != NULL) && PB_POINTER(field->type))
src = *(char**)src;
len = src ? strlen((char*)src) : 0;
return pb_encode_string(stream, (uint8_t*)src, len);
}
bool checkreturn pb_enc_submessage(pb_ostream_t *stream, const pb_field_t *field, const void *src)
{
pb_ostream_t substream = {0};
size_t size;
bool status;
if (!pb_encode(&substream, fields, src_struct))
{
#ifndef PB_NO_ERRMSG
stream->errmsg = substream.errmsg;
#endif
if (field->ptr == NULL)
return false;
if (PB_POINTER(field->type)) {
src = *(void**)src;
if (src == NULL)
return false;
}
if (!pb_encode(&substream, (const pb_message_t*)field->ptr, src))
return false;
size = substream.bytes_written;
if (!pb_encode_varint(stream, (uint64_t)size))
if (!pb_encode_varint(stream, size))
return false;
if (stream->callback == NULL)
return pb_write(stream, NULL, size); /* Just sizing */
if (stream->bytes_written + size > stream->max_size)
PB_RETURN_ERROR(stream, "stream full");
return false;
/* Use a substream to verify that a callback doesn't write more than
* what it did the first time. */
@@ -531,134 +385,15 @@ bool checkreturn pb_encode_submessage(pb_ostream_t *stream, const pb_field_t fie
substream.state = stream->state;
substream.max_size = size;
substream.bytes_written = 0;
#ifndef PB_NO_ERRMSG
substream.errmsg = NULL;
#endif
status = pb_encode(&substream, fields, src_struct);
status = pb_encode(&substream, (const pb_message_t*)field->ptr, src);
stream->bytes_written += substream.bytes_written;
stream->state = substream.state;
#ifndef PB_NO_ERRMSG
stream->errmsg = substream.errmsg;
#endif
if (substream.bytes_written != size)
PB_RETURN_ERROR(stream, "submsg size changed");
return false;
return status;
}
/* Field encoders */
static bool checkreturn pb_enc_varint(pb_ostream_t *stream, const pb_field_t *field, const void *src)
{
int64_t value = 0;
/* Cases 1 and 2 are for compilers that have smaller types for bool
* or enums. */
switch (field->data_size)
{
case 1: value = *(const int8_t*)src; break;
case 2: value = *(const int16_t*)src; break;
case 4: value = *(const int32_t*)src; break;
case 8: value = *(const int64_t*)src; break;
default: PB_RETURN_ERROR(stream, "invalid data_size");
}
return pb_encode_varint(stream, (uint64_t)value);
}
static bool checkreturn pb_enc_uvarint(pb_ostream_t *stream, const pb_field_t *field, const void *src)
{
uint64_t value = 0;
switch (field->data_size)
{
case 4: value = *(const uint32_t*)src; break;
case 8: value = *(const uint64_t*)src; break;
default: PB_RETURN_ERROR(stream, "invalid data_size");
}
return pb_encode_varint(stream, value);
}
static bool checkreturn pb_enc_svarint(pb_ostream_t *stream, const pb_field_t *field, const void *src)
{
int64_t value = 0;
switch (field->data_size)
{
case 4: value = *(const int32_t*)src; break;
case 8: value = *(const int64_t*)src; break;
default: PB_RETURN_ERROR(stream, "invalid data_size");
}
return pb_encode_svarint(stream, value);
}
static bool checkreturn pb_enc_fixed64(pb_ostream_t *stream, const pb_field_t *field, const void *src)
{
PB_UNUSED(field);
return pb_encode_fixed64(stream, src);
}
static bool checkreturn pb_enc_fixed32(pb_ostream_t *stream, const pb_field_t *field, const void *src)
{
PB_UNUSED(field);
return pb_encode_fixed32(stream, src);
}
static bool checkreturn pb_enc_bytes(pb_ostream_t *stream, const pb_field_t *field, const void *src)
{
const pb_bytes_array_t *bytes = (const pb_bytes_array_t*)src;
if (src == NULL)
{
/* Threat null pointer as an empty bytes field */
return pb_encode_string(stream, NULL, 0);
}
if (PB_ATYPE(field->type) == PB_ATYPE_STATIC &&
PB_BYTES_ARRAY_T_ALLOCSIZE(bytes->size) > field->data_size)
{
PB_RETURN_ERROR(stream, "bytes size exceeded");
}
return pb_encode_string(stream, bytes->bytes, bytes->size);
}
static bool checkreturn pb_enc_string(pb_ostream_t *stream, const pb_field_t *field, const void *src)
{
size_t size = 0;
size_t max_size = field->data_size;
const char *p = (const char*)src;
if (PB_ATYPE(field->type) == PB_ATYPE_POINTER)
max_size = (size_t)-1;
if (src == NULL)
{
size = 0; /* Threat null pointer as an empty string */
}
else
{
/* strnlen() is not always available, so just use a loop */
while (size < max_size && *p != '\0')
{
size++;
p++;
}
}
return pb_encode_string(stream, (const uint8_t*)src, size);
}
static bool checkreturn pb_enc_submessage(pb_ostream_t *stream, const pb_field_t *field, const void *src)
{
if (field->ptr == NULL)
PB_RETURN_ERROR(stream, "invalid field descriptor");
return pb_encode_submessage(stream, (const pb_field_t*)field->ptr, src);
}

174
pb_encode.h
View File

@@ -1,154 +1,72 @@
#ifndef _PB_ENCODE_H_
#define _PB_ENCODE_H_
/* pb_encode.h: Functions to encode protocol buffers. Depends on pb_encode.c.
* The main function is pb_encode. You also need an output stream, and the
* field descriptions created by nanopb_generator.py.
* The main function is pb_encode. You also need an output stream, structures
* and their field descriptions (just like with pb_decode).
*/
#ifndef PB_ENCODE_H_INCLUDED
#define PB_ENCODE_H_INCLUDED
#include <stdbool.h>
#include "pb.h"
#ifdef __cplusplus
extern "C" {
#endif
/* Structure for defining custom output streams. You will need to provide
* a callback function to write the bytes to your storage, which can be
* for example a file or a network socket.
*
* The callback must conform to these rules:
/* Lightweight output stream.
* You can provide callback for writing or use pb_ostream_from_buffer.
*
* Alternatively, callback can be NULL in which case the stream will just
* count the number of bytes that would have been written. In this case
* max_size is not checked.
*
* Rules for callback:
* 1) Return false on IO errors. This will cause encoding to abort.
*
* 2) You can use state to store your own data (e.g. buffer pointer).
*
* 3) pb_write will update bytes_written after your callback runs.
* 4) Substreams will modify max_size and bytes_written. Don't use them
* to calculate any pointers.
*
* 4) Substreams will modify max_size and bytes_written. Don't use them to
* calculate any pointers.
*/
struct pb_ostream_s
struct _pb_ostream_t
{
#ifdef PB_BUFFER_ONLY
/* Callback pointer is not used in buffer-only configuration.
* Having an int pointer here allows binary compatibility but
* gives an error if someone tries to assign callback function.
* Also, NULL pointer marks a 'sizing stream' that does not
* write anything.
*/
int *callback;
#else
bool (*callback)(pb_ostream_t *stream, const uint8_t *buf, size_t count);
#endif
void *state; /* Free field for use by callback implementation. */
size_t max_size; /* Limit number of output bytes written (or use SIZE_MAX). */
size_t bytes_written; /* Number of bytes written so far. */
#ifndef PB_NO_ERRMSG
const char *errmsg;
#endif
void *state; /* Free field for use by callback implementation */
size_t max_size; /* Limit number of output bytes written (or use SIZE_MAX). */
size_t bytes_written;
};
/***************************
* Main encoding functions *
***************************/
/* Encode a single protocol buffers message from C structure into a stream.
* Returns true on success, false on any failure.
* The actual struct pointed to by src_struct must match the description in fields.
* All required fields in the struct are assumed to have been filled in.
*
* Example usage:
* MyMessage msg = {};
* uint8_t buffer[64];
* pb_ostream_t stream;
*
* msg.field1 = 42;
* stream = pb_ostream_from_buffer(buffer, sizeof(buffer));
* pb_encode(&stream, MyMessage_fields, &msg);
*/
bool pb_encode(pb_ostream_t *stream, const pb_field_t fields[], const void *src_struct);
/* Same as pb_encode, but prepends the length of the message as a varint.
* Corresponds to writeDelimitedTo() in Google's protobuf API.
*/
bool pb_encode_delimited(pb_ostream_t *stream, const pb_field_t fields[], const void *src_struct);
/* Encode the message to get the size of the encoded data, but do not store
* the data. */
bool pb_get_encoded_size(size_t *size, const pb_field_t fields[], const void *src_struct);
/**************************************
* Functions for manipulating streams *
**************************************/
/* Create an output stream for writing into a memory buffer.
* The number of bytes written can be found in stream.bytes_written after
* encoding the message.
*
* Alternatively, you can use a custom stream that writes directly to e.g.
* a file or a network socket.
*/
pb_ostream_t pb_ostream_from_buffer(uint8_t *buf, size_t bufsize);
/* Pseudo-stream for measuring the size of a message without actually storing
* the encoded data.
*
* Example usage:
* MyMessage msg = {};
* pb_ostream_t stream = PB_OSTREAM_SIZING;
* pb_encode(&stream, MyMessage_fields, &msg);
* printf("Message size is %d\n", stream.bytes_written);
*/
#ifndef PB_NO_ERRMSG
#define PB_OSTREAM_SIZING {0,0,0,0,0}
#else
#define PB_OSTREAM_SIZING {0,0,0,0}
#endif
/* Function to write into a pb_ostream_t stream. You can use this if you need
* to append or prepend some custom headers to the message.
*/
bool pb_write(pb_ostream_t *stream, const uint8_t *buf, size_t count);
/* Encode struct to given output stream.
* Returns true on success, false on any failure.
* The actual struct pointed to by src_struct must match the description in msg.
* All required fields in the struct are assumed to have been filled in.
*/
bool pb_encode(pb_ostream_t *stream, const pb_message_t *msg, const void *src_struct);
/************************************************
* Helper functions for writing field callbacks *
************************************************/
/* --- Helper functions ---
* You may want to use these from your caller or callbacks.
*/
/* Encode field header based on type and field number defined in the field
* structure. Call this from the callback before writing out field contents. */
bool pb_encode_tag_for_field(pb_ostream_t *stream, const pb_field_t *field);
/* Encode field header by manually specifing wire type. You need to use this
* if you want to write out packed arrays from a callback field. */
bool pb_encode_tag(pb_ostream_t *stream, pb_wire_type_t wiretype, uint32_t field_number);
/* Encode an integer in the varint format.
* This works for bool, enum, int32, int64, uint32 and uint64 field types. */
bool pb_encode_varint(pb_ostream_t *stream, uint64_t value);
/* Encode an integer in the zig-zagged svarint format.
* This works for sint32 and sint64. */
bool pb_encode_svarint(pb_ostream_t *stream, int64_t value);
/* Encode a string or bytes type field. For strings, pass strlen(s) as size. */
bool pb_encode_tag(pb_ostream_t *stream, pb_wire_type_t wiretype, int field_number);
/* Encode tag based on LTYPE and field number defined in the field structure. */
bool pb_encode_tag_for_field(pb_ostream_t *stream, const pb_field_t *field);
/* Write length as varint and then the contents of buffer. */
bool pb_encode_string(pb_ostream_t *stream, const uint8_t *buffer, size_t size);
/* Encode a fixed32, sfixed32 or float value.
* You need to pass a pointer to a 4-byte wide C variable. */
bool pb_encode_fixed32(pb_ostream_t *stream, const void *value);
/* Encode a fixed64, sfixed64 or double value.
* You need to pass a pointer to a 8-byte wide C variable. */
bool pb_encode_fixed64(pb_ostream_t *stream, const void *value);
/* Encode a submessage field.
* You need to pass the pb_field_t array and pointer to struct, just like
* with pb_encode(). This internally encodes the submessage twice, first to
* calculate message size and then to actually write it out.
/* --- Field encoders ---
* Each encoder writes the content for the field.
* The tag/wire type has been written already.
*/
bool pb_encode_submessage(pb_ostream_t *stream, const pb_field_t fields[], const void *src_struct);
#ifdef __cplusplus
} /* extern "C" */
#endif
bool pb_enc_varint(pb_ostream_t *stream, const pb_field_t *field, const void *src);
bool pb_enc_svarint(pb_ostream_t *stream, const pb_field_t *field, const void *src);
bool pb_enc_fixed32(pb_ostream_t *stream, const pb_field_t *field, const void *src);
bool pb_enc_fixed64(pb_ostream_t *stream, const pb_field_t *field, const void *src);
bool pb_enc_bytes(pb_ostream_t *stream, const pb_field_t *field, const void *src);
bool pb_enc_string(pb_ostream_t *stream, const pb_field_t *field, const void *src);
bool pb_enc_submessage(pb_ostream_t *stream, const pb_field_t *field, const void *src);
#endif

362
pb_encode_buffer.c Normal file
View File

@@ -0,0 +1,362 @@
/* pb_encode_buffer.c - encode a protobuf to an in-memory array
*
* 2011 Michael Poole <mdpoole@troilus.org>
* Part of nanopb, 2011 Petteri Aimonen <jpa@kapsi.fi>
*/
#include "pb_encode_buffer.h"
#include <string.h>
#ifdef __GNUC__
/* Verify that we remember to check all return values for proper error propagation */
#define checkreturn __attribute__((warn_unused_result))
#else
#define checkreturn
#endif
typedef bool (*pb_encoder_t)(pb_strstream_t *stream, const pb_field_t *field, const void *src) checkreturn;
static bool pb_encb_varint(pb_strstream_t *stream, const pb_field_t *field, const void *src);
static bool pb_encb_svarint(pb_strstream_t *stream, const pb_field_t *field, const void *src);
static bool pb_encb_fixed32(pb_strstream_t *stream, const pb_field_t *field, const void *src);
static bool pb_encb_fixed64(pb_strstream_t *stream, const pb_field_t *field, const void *src);
static bool pb_encb_bytes(pb_strstream_t *stream, const pb_field_t *field, const void *src);
static bool pb_encb_string(pb_strstream_t *stream, const pb_field_t *field, const void *src);
static bool pb_encb_submessage(pb_strstream_t *stream, const pb_field_t *field, const void *src);
/* --- Function pointers to field encoders ---
* Order in the array must match pb_action_t LTYPE numbering.
*/
static const pb_encoder_t PB_ENCODERS[PB_LTYPES_COUNT] = {
&pb_encb_varint,
&pb_encb_svarint,
&pb_encb_fixed32,
&pb_encb_fixed64,
&pb_encb_bytes,
&pb_encb_string,
&pb_encb_submessage
};
/* pb_strstream_t implementation */
pb_strstream_t pb_strstream_from_buffer(uint8_t *buf, size_t bufsize)
{
pb_strstream_t stream;
stream.buffer = buf;
stream.last = buf + bufsize;
return stream;
}
bool pb_buf_write(pb_strstream_t *stream, const uint8_t *buf, size_t count)
{
if (stream->buffer + count > stream->last)
return false;
stream->last -= count;
memcpy(stream->last, buf, count);
return true;
}
/* Main encoding stuff */
/* This function is static for the same reason as the version in
* pb_encode.c.
*/
static bool checkreturn encode_array(pb_strstream_t *stream, const pb_field_t *field,
const void *pData, size_t count, pb_encoder_t func)
{
const void *p;
uint8_t *start;
size_t size;
int i;
if (count == 0)
return true;
start = stream->last;
p = (const char*)pData + field->data_size * count;
if (PB_LTYPE(field->type) <= PB_LTYPE_LAST_PACKABLE)
{
/* Write the data (in reverse order). */
for (i = 0; i < count; i++)
{
p = (const char*)p - field->data_size;
if (!func(stream, field, p))
return false;
}
/* Write the size. */
size = start - stream->last;
if (!pb_encbuf_varint(stream, size))
return false;
if (!pb_encbuf_tag(stream, PB_WT_STRING, field->tag))
return false;
}
else
{
for (i = 0; i < count; i++)
{
p = (const char*)p - field->data_size;
if (!func(stream, field, p))
return false;
if (!pb_encbuf_tag_for_field(stream, field))
return false;
}
}
return true;
}
bool checkreturn pb_encode_buffer(pb_strstream_t *stream, const pb_message_t *msg, const void *src_struct)
{
const char *has_fields = src_struct;
const uint8_t *pData = src_struct;
const pb_field_t *field;
pb_encoder_t func;
size_t size;
unsigned int i;
/* msg->size includes trailing padding, so we must calculate the
* offset of the last field by counting forward from the start.
*/
for (i = 0; i < msg->field_count; i++)
{
field = &msg->fields[i];
pData += field->data_offset;
size = field->data_size;
if (PB_HTYPE(field->type) == PB_HTYPE_ARRAY)
size *= field->array_size;
pData += size;
}
/* Iterate through the fields in reverse order. Because we write
* from the end of the buffer, the result is in canonical order.
*/
for (i = msg->field_count; i > 0; pData -= field->data_offset)
{
field = &msg->fields[--i];
func = PB_ENCODERS[PB_LTYPE(field->type)];
size = field->data_size;
if (PB_HTYPE(field->type) == PB_HTYPE_ARRAY)
size *= field->array_size;
pData -= size;
switch (PB_HTYPE(field->type))
{
case PB_HTYPE_OPTIONAL:
if (!(has_fields[i/8] & (1 << i%8)))
break;
if (PB_POINTER(field->type)
&& (PB_LTYPE(field->type) == PB_LTYPE_STRING
|| PB_LTYPE(field->type) == PB_LTYPE_SUBMESSAGE)
&& *(void**)pData == NULL)
break;
/* else fall through to required case */
case PB_HTYPE_REQUIRED:
if (!func(stream, field, pData))
return false;
if (!pb_encbuf_tag_for_field(stream, field))
return false;
break;
case PB_HTYPE_ARRAY:
size = *(size_t*)(pData + field->size_offset);
if (!encode_array(stream, field, pData, size, func))
return false;
break;
case PB_HTYPE_CALLBACK:
{
pb_callback_t *callback = (pb_callback_t*)pData;
if (callback->funcs.encode_buffer != NULL
&& !callback->funcs.encode_buffer(stream, field, callback->arg))
return false;
break;
}
}
}
return true;
}
/* Helper functions */
bool checkreturn pb_encbuf_varint(pb_strstream_t *stream, uint64_t value)
{
if (stream->last == stream->buffer)
{
return false;
}
else if (value < 128)
{
*--stream->last = value;
return true;
}
else
{
uint8_t buffer[10];
int i = 0;
while (value)
{
buffer[i] = (value & 0x7F) | 0x80;
value >>= 7;
i++;
}
buffer[i-1] &= 0x7F;
return pb_buf_write(stream, buffer, i);
}
}
bool checkreturn pb_encbuf_tag(pb_strstream_t *stream, pb_wire_type_t wiretype, int field_number)
{
int tag = wiretype | (field_number << 3);
return pb_encbuf_varint(stream, tag);
}
bool checkreturn pb_encbuf_tag_for_field(pb_strstream_t *stream, const pb_field_t *field)
{
pb_wire_type_t wiretype;
switch (PB_LTYPE(field->type))
{
case PB_LTYPE_VARINT:
case PB_LTYPE_SVARINT:
wiretype = PB_WT_VARINT;
break;
case PB_LTYPE_FIXED32:
wiretype = PB_WT_32BIT;
break;
case PB_LTYPE_FIXED64:
wiretype = PB_WT_64BIT;
break;
case PB_LTYPE_BYTES:
case PB_LTYPE_STRING:
case PB_LTYPE_SUBMESSAGE:
wiretype = PB_WT_STRING;
break;
default:
return false;
}
return pb_encbuf_tag(stream, wiretype, field->tag);
}
bool checkreturn pb_encbuf_string(pb_strstream_t *stream, const uint8_t *buffer, size_t size)
{
if (!pb_buf_write(stream, buffer, size))
return false;
return pb_encbuf_varint(stream, size);
}
/* Field encoders */
/* Copy srcsize bytes of integer from src so that values are casted properly.
* On little endian machine, copy to start of dest
* On big endian machine, copy to end of dest
* destsize must always be larger than srcsize
*
* Note: This is the reverse of the endian_copy in pb_decode.c.
*/
static void endian_copy(uint64_t *dest, const void *src, size_t srcsize)
{
#ifdef __BIG_ENDIAN__
memcpy((char*)dest + sizeof(*dest) - srcsize, src, srcsize);
#else
memcpy(dest, src, srcsize);
#endif
}
static bool pb_encb_varint(pb_strstream_t *stream, const pb_field_t *field, const void *src)
{
uint64_t value = 0;
endian_copy(&value, src, field->data_size);
return pb_encbuf_varint(stream, value);
}
static bool pb_encb_svarint(pb_strstream_t *stream, const pb_field_t *field, const void *src)
{
uint64_t value = 0;
uint64_t zigzagged;
uint64_t signbitmask = (uint64_t)0x80 << (field->data_size * 8 - 8);
uint64_t xormask = ((uint64_t)-1) >> (64 - field->data_size * 8);
endian_copy(&value, src, field->data_size);
if (value & signbitmask)
zigzagged = ((value ^ xormask) << 1) | 1;
else
zigzagged = value << 1;
return pb_encbuf_varint(stream, zigzagged);
}
static bool pb_encb_fixed32(pb_strstream_t *stream, const pb_field_t *field, const void *src)
{
#ifdef __BIG_ENDIAN__
const uint8_t *bytes = (const uint8_t*)src;
uint8_t lebytes[4] = {bytes[3], bytes[2], bytes[1], bytes[0]};
src = lebytes;
#endif
return pb_buf_write(stream, src, 4);
}
static bool pb_encb_fixed64(pb_strstream_t *stream, const pb_field_t *field, const void *src)
{
#ifdef __BIG_ENDIAN__
const uint8_t *bytes = (const uint8_t*)src;
uint8_t lebytes[8] = {bytes[7], bytes[6], bytes[5], bytes[4],
bytes[3], bytes[2], bytes[1], bytes[0]};
src = lebytes;
#endif
return pb_buf_write(stream, src, 8);
}
static bool pb_encb_bytes(pb_strstream_t *stream, const pb_field_t *field, const void *src)
{
if ((field != NULL) && PB_POINTER(field->type)) {
pb_bytes_t *bytes = (pb_bytes_t*)src;
return pb_encbuf_string(stream, bytes->bytes, bytes->size);
} else {
pb_bytes_array_t *bytes = (pb_bytes_array_t*)src;
return pb_encbuf_string(stream, bytes->bytes, bytes->size);
}
}
static bool pb_encb_string(pb_strstream_t *stream, const pb_field_t *field, const void *src)
{
size_t len;
if ((field != NULL) && PB_POINTER(field->type))
src = *(char**)src;
len = src ? strlen((char*)src) : 0;
return pb_encbuf_string(stream, (uint8_t*)src, len);
}
static bool pb_encb_submessage(pb_strstream_t *stream, const pb_field_t *field, const void *src)
{
uint8_t *start;
size_t size;
if (field->ptr == NULL)
return false;
if (PB_POINTER(field->type)) {
src = *(void**)src;
if (src == NULL)
return false;
}
start = stream->last;
if (!pb_encode_buffer(stream, (const pb_message_t*)field->ptr, src))
return false;
size = start - stream->last;
if (!pb_encbuf_varint(stream, size))
return false;
return true;
}

43
pb_encode_buffer.h Normal file
View File

@@ -0,0 +1,43 @@
#ifndef _PB_ENCODE_BUFFER_H_
#define _PB_ENCODE_BUFFER_H_
/* pb_encode_buffer.h: Functions to encode protocol buffers to an
* in-memory array of bytes. Depends on pb_encode_buffer.c. The main
* function is pb_encode_buffer. You also need an output buffer,
* structures and their field descriptions (just like with pb_decode
* or pb_encode).
*/
#include <stdbool.h>
#include "pb.h"
/* Output stream for an in-memory buffer.
*/
struct _pb_strstream_t
{
uint8_t *buffer;
uint8_t *last;
};
pb_strstream_t pb_strstream_from_buffer(uint8_t *buf, size_t bufsize);
bool pb_buf_write(pb_strstream_t *stream, const uint8_t *buf, size_t count);
/* --- Helper functions ---
* You may want to use these from your caller or callbacks.
*/
bool pb_encbuf_varint(pb_strstream_t *stream, uint64_t value);
bool pb_encbuf_tag(pb_strstream_t *stream, pb_wire_type_t wiretype, int field_number);
/* Encode tag based on LTYPE and field number defined in the field structure. */
bool pb_encbuf_tag_for_field(pb_strstream_t *stream, const pb_field_t *field);
/* Write length as varint and then the contents of buffer. */
bool pb_encbuf_string(pb_strstream_t *stream, const uint8_t *buffer, size_t size);
/* Encode struct to given output stream.
* Returns true on success, false on any failure.
* The actual struct pointed to by src_struct must match the description in msg.
* All required fields in the struct are assumed to have been filled in.
*/
bool pb_encode_buffer(pb_strstream_t *stream, const pb_message_t *msg, const void *src_struct);
#endif

79
tests/Makefile
View File

@@ -1,21 +1,72 @@
all:
scons
CFLAGS=-ansi -Wall -Werror -I .. -g -O0 --coverage
LDFLAGS=--coverage
DEPS=../pb_decode.h ../pb_encode.h ../pb_encode_buffer.h ../pb.h person.pb.h callbacks.pb.h unittests.h unittestproto.pb.h
TESTS=test_decode1 test_encode1 test_decode_callbacks test_encode_callbacks decode_unittests decode_ptr_unittests encode_unittests
all: breakpoints $(TESTS) run_unittests
clean:
scons -c
rm -f $(TESTS) *.pb.c *.pb.h *.o *.gcda *.gcno
coverage:
rm -rf build coverage
%.o: %.c
%.o: %.c $(DEPS)
$(CC) $(CFLAGS) -c -o $@ $<
# LCOV does not like the newer gcov format
scons CC=gcc-4.6 CXX=gcc-4.6
pb_encode.o: ../pb_encode.c $(DEPS)
$(CC) $(CFLAGS) -c -o $@ $<
pb_encode_buffer.o: ../pb_encode_buffer.c $(DEPS)
$(CC) $(CFLAGS) -c -o $@ $<
pb_decode.o: ../pb_decode.c $(DEPS)
$(CC) $(CFLAGS) -c -o $@ $<
pb_ptr_decode.o: ../pb_decode.c $(DEPS)
$(CC) $(CFLAGS) -c -o $@ $<
decode_ptr_unittests.o: decode_unittests.c $(DEPS)
$(CC) $(CFLAGS) -c -o $@ $<
# We are only interested in pb_encode.o and pb_decode.o
find build -name '*.gcda' -and \! \( -name '*pb_encode*' -or -name '*pb_decode*' \) -exec rm '{}' \;
test_decode1: test_decode1.o pb_decode.o person.pb.o
test_decode2: test_decode2.o pb_decode.o person.pb.o
test_encode1: test_encode1.o pb_encode.o person.pb.o
test_encode2: test_encode2.o pb_encode.o person.pb.o
test_decode_callbacks: test_decode_callbacks.o pb_decode.o callbacks.pb.o
test_encode_callbacks: test_encode_callbacks.o pb_encode.o callbacks.pb.o
decode_unittests: decode_unittests.o pb_decode.o unittestproto.pb.o
pb_ptr_decode.o decode_ptr_unittests.o: CFLAGS += -DMALLOC_HEADER="<stdlib.h>"
decode_ptr_unittests: decode_ptr_unittests.o pb_ptr_decode.o unittestproto.pb.o
encode_unittests: encode_unittests.o pb_encode.o pb_encode_buffer.o unittestproto.pb.o
# Collect the data
mkdir build/coverage
lcov --base-directory . --directory build/ --gcov-tool gcov-4.6 -c -o build/coverage/nanopb.info
%.pb: %.proto
protoc -I. -I../generator -I/usr/include -o$@ $<
# Generate HTML
genhtml -o build/coverage build/coverage/nanopb.info
%.pb.c %.pb.h: %.pb ../generator/nanopb_generator.py
python ../generator/nanopb_generator.py $<
breakpoints: ../*.c *.c
grep -n 'return false;' $^ | cut -d: -f-2 | xargs -n 1 echo b > $@
coverage: run_unittests
gcov pb_encode.gcda
gcov pb_encode_buffer.gcda
gcov pb_decode.gcda
gcov pb_ptr_decode.gcda
run_unittests: decode_unittests decode_ptr_unittests encode_unittests test_encode1 test_encode2 test_decode1 test_decode2 test_encode_callbacks test_decode_callbacks
rm -f *.gcda
./decode_unittests > /dev/null
./decode_ptr_unittests > /dev/null
./encode_unittests > /dev/null
[ "`./test_encode1 | ./test_decode1`" = \
"`./test_encode1 | protoc --decode=Person -I. -I../generator -I/usr/include person.proto`" ]
[ "`./test_encode2 | ./test_decode1`" = \
"`./test_encode2 | protoc --decode=Person -I. -I../generator -I/usr/include person.proto`" ]
[ "`./test_encode2 | ./test_decode2`" = \
"`./test_encode2 | protoc --decode=Person -I. -I../generator -I/usr/include person.proto`" ]
[ "`./test_encode_callbacks | ./test_decode_callbacks`" = \
"`./test_encode_callbacks | protoc --decode=TestMessage callbacks.proto`" ]
run_fuzztest: test_decode2
bash -c 'I=1; while true; do cat /dev/urandom | ./test_decode2 > /dev/null; I=$$(($$I+1)); echo -en "\r$$I"; done'

146
tests/SConstruct
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@@ -1,146 +0,0 @@
Help('''
Type 'scons' to build and run all the available test cases.
It will automatically detect your platform and C compiler and
build appropriately.
You can modify the behavious using following options:
CC Name of C compiler
CXX Name of C++ compiler
CCFLAGS Flags to pass to the C compiler
CXXFLAGS Flags to pass to the C++ compiler
For example, for a clang build, use:
scons CC=clang CXX=clang++
''')
import os
env = Environment(ENV = os.environ, tools = ['default', 'nanopb'])
# Allow overriding the compiler with scons CC=???
if 'CC' in ARGUMENTS: env.Replace(CC = ARGUMENTS['CC'])
if 'CXX' in ARGUMENTS: env.Replace(CXX = ARGUMENTS['CXX'])
if 'CCFLAGS' in ARGUMENTS: env.Append(CCFLAGS = ARGUMENTS['CCFLAGS'])
if 'CXXFLAGS' in ARGUMENTS: env.Append(CXXFLAGS = ARGUMENTS['CXXFLAGS'])
# Add the builders defined in site_init.py
add_nanopb_builders(env)
# Path to the files shared by tests, and to the nanopb core.
env.Append(CPPPATH = ["#../", "$COMMON"])
# Path for finding nanopb.proto
env.Append(PROTOCPATH = '#../generator')
# Check the compilation environment, unless we are just cleaning up.
if not env.GetOption('clean'):
def check_ccflags(context, flags, linkflags = ''):
'''Check if given CCFLAGS are supported'''
context.Message('Checking support for CCFLAGS="%s"... ' % flags)
oldflags = context.env['CCFLAGS']
oldlinkflags = context.env['CCFLAGS']
context.env.Append(CCFLAGS = flags)
context.env.Append(LINKFLAGS = linkflags)
result = context.TryCompile("int main() {return 0;}", '.c')
context.env.Replace(CCFLAGS = oldflags)
context.env.Replace(LINKFLAGS = oldlinkflags)
context.Result(result)
return result
conf = Configure(env, custom_tests = {'CheckCCFLAGS': check_ccflags})
# If the platform doesn't support C99, use our own header file instead.
stdbool = conf.CheckCHeader('stdbool.h')
stdint = conf.CheckCHeader('stdint.h')
stddef = conf.CheckCHeader('stddef.h')
string = conf.CheckCHeader('string.h')
stdlib = conf.CheckCHeader('stdlib.h')
if not stdbool or not stdint or not stddef or not string:
conf.env.Append(CPPDEFINES = {'PB_SYSTEM_HEADER': '\\"pb_syshdr.h\\"'})
conf.env.Append(CPPPATH = "#../extra")
if stdbool: conf.env.Append(CPPDEFINES = {'HAVE_STDBOOL_H': 1})
if stdint: conf.env.Append(CPPDEFINES = {'HAVE_STDINT_H': 1})
if stddef: conf.env.Append(CPPDEFINES = {'HAVE_STDDEF_H': 1})
if string: conf.env.Append(CPPDEFINES = {'HAVE_STRING_H': 1})
if stdlib: conf.env.Append(CPPDEFINES = {'HAVE_STDLIB_H': 1})
# Check if we can use pkg-config to find protobuf include path
status, output = conf.TryAction('pkg-config protobuf --variable=includedir > $TARGET')
if status:
conf.env.Append(PROTOCPATH = output.strip())
else:
conf.env.Append(PROTOCPATH = '/usr/include')
# Check if libmudflap is available (only with GCC)
if 'gcc' in env['CC']:
if conf.CheckLib('mudflap'):
conf.env.Append(CCFLAGS = '-fmudflap')
conf.env.Append(LINKFLAGS = '-fmudflap')
# Check if we can use extra strict warning flags (only with GCC)
extra = '-Wcast-qual -Wlogical-op -Wconversion'
extra += ' -fstrict-aliasing -Wstrict-aliasing=1'
extra += ' -Wmissing-prototypes -Wmissing-declarations -Wredundant-decls'
extra += ' -Wstack-protector '
if 'gcc' in env['CC']:
if conf.CheckCCFLAGS(extra):
conf.env.Append(CORECFLAGS = extra)
# Check if we can use undefined behaviour sanitizer (only with clang)
extra = '-fsanitize=undefined '
if 'clang' in env['CC']:
if conf.CheckCCFLAGS(extra, linkflags = extra):
conf.env.Append(CORECFLAGS = extra)
conf.env.Append(LINKFLAGS = extra)
# End the config stuff
env = conf.Finish()
# Initialize the CCFLAGS according to the compiler
if 'gcc' in env['CC']:
# GNU Compiler Collection
# Debug info, warnings as errors
env.Append(CFLAGS = '-ansi -pedantic -g -Wall -Werror -fprofile-arcs -ftest-coverage -fstack-protector-all')
env.Append(CORECFLAGS = '-Wextra')
env.Append(LINKFLAGS = '-g --coverage')
# We currently need uint64_t anyway, even though ANSI C90 otherwise..
env.Append(CFLAGS = '-Wno-long-long')
elif 'clang' in env['CC']:
# CLang
env.Append(CFLAGS = '-ansi -g -Wall -Werror')
env.Append(CORECFLAGS = ' -Wextra -Wcast-qual -Wconversion')
elif 'cl' in env['CC']:
# Microsoft Visual C++
# Debug info on, warning level 2 for tests, warnings as errors
env.Append(CFLAGS = '/Zi /W2 /WX')
env.Append(LINKFLAGS = '/DEBUG')
# More strict checks on the nanopb core
env.Append(CORECFLAGS = '/W4')
# PB_RETURN_ERROR triggers C4127 because of while(0)
env.Append(CFLAGS = '/wd4127')
elif 'tcc' in env['CC']:
# Tiny C Compiler
env.Append(CFLAGS = '-Wall -Werror -g')
env.SetDefault(CORECFLAGS = '')
if 'clang' in env['CXX']:
env.Append(CXXFLAGS = '-g -Wall -Werror -Wextra -Wno-missing-field-initializers')
elif 'g++' in env['CXX'] or 'gcc' in env['CXX']:
env.Append(CXXFLAGS = '-g -Wall -Werror -Wextra -Wno-missing-field-initializers')
elif 'cl' in env['CXX']:
env.Append(CXXFLAGS = '/Zi /W2 /WX')
# Now include the SConscript files from all subdirectories
import os.path
env['VARIANT_DIR'] = 'build'
env['BUILD'] = '#' + env['VARIANT_DIR']
env['COMMON'] = '#' + env['VARIANT_DIR'] + '/common'
for subdir in Glob('*/SConscript') + Glob('regression/*/SConscript'):
SConscript(subdir, exports = 'env', variant_dir = env['VARIANT_DIR'] + '/' + os.path.dirname(str(subdir)))

35
tests/alltypes/SConscript
View File

@@ -1,35 +0,0 @@
# Build and run a test that encodes and decodes a message that contains
# all of the Protocol Buffers data types.
Import("env")
env.NanopbProto(["alltypes", "alltypes.options"])
enc = env.Program(["encode_alltypes.c", "alltypes.pb.c", "$COMMON/pb_encode.o", "$COMMON/pb_common.o"])
dec = env.Program(["decode_alltypes.c", "alltypes.pb.c", "$COMMON/pb_decode.o", "$COMMON/pb_common.o"])
# Test the round-trip from nanopb encoder to nanopb decoder
env.RunTest(enc)
env.RunTest([dec, "encode_alltypes.output"])
# Re-encode the data using protoc, and check that the results from nanopb
# match byte-per-byte to the protoc output.
env.Decode("encode_alltypes.output.decoded",
["encode_alltypes.output", "alltypes.proto"],
MESSAGE='AllTypes')
env.Encode("encode_alltypes.output.recoded",
["encode_alltypes.output.decoded", "alltypes.proto"],
MESSAGE='AllTypes')
env.Compare(["encode_alltypes.output", "encode_alltypes.output.recoded"])
# Do the same checks with the optional fields present.
env.RunTest("optionals.output", enc, ARGS = ['1'])
env.RunTest("optionals.decout", [dec, "optionals.output"], ARGS = ['1'])
env.Decode("optionals.output.decoded",
["optionals.output", "alltypes.proto"],
MESSAGE='AllTypes')
env.Encode("optionals.output.recoded",
["optionals.output.decoded", "alltypes.proto"],
MESSAGE='AllTypes')
env.Compare(["optionals.output", "optionals.output.recoded"])

3
tests/alltypes/alltypes.options
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@@ -1,3 +0,0 @@
* max_size:16
* max_count:5

114
tests/alltypes/alltypes.proto
View File

@@ -1,114 +0,0 @@
message SubMessage {
required string substuff1 = 1 [default = "1"];
required int32 substuff2 = 2 [default = 2];
optional fixed32 substuff3 = 3 [default = 3];
}
message EmptyMessage {
}
enum HugeEnum {
Negative = -2147483647; /* protoc doesn't accept -2147483648 here */
Positive = 2147483647;
}
message Limits {
required int32 int32_min = 1 [default = 2147483647];
required int32 int32_max = 2 [default = -2147483647];
required uint32 uint32_min = 3 [default = 4294967295];
required uint32 uint32_max = 4 [default = 0];
required int64 int64_min = 5 [default = 9223372036854775807];
required int64 int64_max = 6 [default = -9223372036854775807];
required uint64 uint64_min = 7 [default = 18446744073709551615];
required uint64 uint64_max = 8 [default = 0];
required HugeEnum enum_min = 9 [default = Positive];
required HugeEnum enum_max = 10 [default = Negative];
}
enum MyEnum {
Zero = 0;
First = 1;
Second = 2;
Truth = 42;
}
message AllTypes {
required int32 req_int32 = 1;
required int64 req_int64 = 2;
required uint32 req_uint32 = 3;
required uint64 req_uint64 = 4;
required sint32 req_sint32 = 5;
required sint64 req_sint64 = 6;
required bool req_bool = 7;
required fixed32 req_fixed32 = 8;
required sfixed32 req_sfixed32= 9;
required float req_float = 10;
required fixed64 req_fixed64 = 11;
required sfixed64 req_sfixed64= 12;
required double req_double = 13;
required string req_string = 14;
required bytes req_bytes = 15;
required SubMessage req_submsg = 16;
required MyEnum req_enum = 17;
required EmptyMessage req_emptymsg = 18;
repeated int32 rep_int32 = 21 [packed = true];
repeated int64 rep_int64 = 22 [packed = true];
repeated uint32 rep_uint32 = 23 [packed = true];
repeated uint64 rep_uint64 = 24 [packed = true];
repeated sint32 rep_sint32 = 25 [packed = true];
repeated sint64 rep_sint64 = 26 [packed = true];
repeated bool rep_bool = 27 [packed = true];
repeated fixed32 rep_fixed32 = 28 [packed = true];
repeated sfixed32 rep_sfixed32= 29 [packed = true];
repeated float rep_float = 30 [packed = true];
repeated fixed64 rep_fixed64 = 31 [packed = true];
repeated sfixed64 rep_sfixed64= 32 [packed = true];
repeated double rep_double = 33 [packed = true];
repeated string rep_string = 34;
repeated bytes rep_bytes = 35;
repeated SubMessage rep_submsg = 36;
repeated MyEnum rep_enum = 37 [packed = true];
repeated EmptyMessage rep_emptymsg = 38;
optional int32 opt_int32 = 41 [default = 4041];
optional int64 opt_int64 = 42 [default = 4042];
optional uint32 opt_uint32 = 43 [default = 4043];
optional uint64 opt_uint64 = 44 [default = 4044];
optional sint32 opt_sint32 = 45 [default = 4045];
optional sint64 opt_sint64 = 46 [default = 4046];
optional bool opt_bool = 47 [default = false];
optional fixed32 opt_fixed32 = 48 [default = 4048];
optional sfixed32 opt_sfixed32= 49 [default = 4049];
optional float opt_float = 50 [default = 4050];
optional fixed64 opt_fixed64 = 51 [default = 4051];
optional sfixed64 opt_sfixed64= 52 [default = 4052];
optional double opt_double = 53 [default = 4053];
optional string opt_string = 54 [default = "4054"];
optional bytes opt_bytes = 55 [default = "4055"];
optional SubMessage opt_submsg = 56;
optional MyEnum opt_enum = 57 [default = Second];
optional EmptyMessage opt_emptymsg = 58;
// Check that extreme integer values are handled correctly
required Limits req_limits = 98;
// Just to make sure that the size of the fields has been calculated
// properly, i.e. otherwise a bug in last field might not be detected.
required int32 end = 99;
extensions 200 to 255;
}

215
tests/alltypes/decode_alltypes.c
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@@ -1,215 +0,0 @@
/* Tests the decoding of all types.
* This is the counterpart of test_encode3.
* Run e.g. ./test_encode3 | ./test_decode3
*/
#include <stdio.h>
#include <string.h>
#include <stdlib.h>
#include <pb_decode.h>
#include "alltypes.pb.h"
#include "test_helpers.h"
#define TEST(x) if (!(x)) { \
printf("Test " #x " failed.\n"); \
return false; \
}
/* This function is called once from main(), it handles
the decoding and checks the fields. */
bool check_alltypes(pb_istream_t *stream, int mode)
{
/* Uses _init_default to just make sure that it works. */
AllTypes alltypes = AllTypes_init_default;
/* Fill with garbage to better detect initialization errors */
memset(&alltypes, 0xAA, sizeof(alltypes));
alltypes.extensions = 0;
if (!pb_decode(stream, AllTypes_fields, &alltypes))
return false;
TEST(alltypes.req_int32 == -1001);
TEST(alltypes.req_int64 == -1002);
TEST(alltypes.req_uint32 == 1003);
TEST(alltypes.req_uint64 == 1004);
TEST(alltypes.req_sint32 == -1005);
TEST(alltypes.req_sint64 == -1006);
TEST(alltypes.req_bool == true);
TEST(alltypes.req_fixed32 == 1008);
TEST(alltypes.req_sfixed32 == -1009);
TEST(alltypes.req_float == 1010.0f);
TEST(alltypes.req_fixed64 == 1011);
TEST(alltypes.req_sfixed64 == -1012);
TEST(alltypes.req_double == 1013.0f);
TEST(strcmp(alltypes.req_string, "1014") == 0);
TEST(alltypes.req_bytes.size == 4);
TEST(memcmp(alltypes.req_bytes.bytes, "1015", 4) == 0);
TEST(strcmp(alltypes.req_submsg.substuff1, "1016") == 0);
TEST(alltypes.req_submsg.substuff2 == 1016);
TEST(alltypes.req_submsg.substuff3 == 3);
TEST(alltypes.req_enum == MyEnum_Truth);
TEST(alltypes.rep_int32_count == 5 && alltypes.rep_int32[4] == -2001 && alltypes.rep_int32[0] == 0);
TEST(alltypes.rep_int64_count == 5 && alltypes.rep_int64[4] == -2002 && alltypes.rep_int64[0] == 0);
TEST(alltypes.rep_uint32_count == 5 && alltypes.rep_uint32[4] == 2003 && alltypes.rep_uint32[0] == 0);
TEST(alltypes.rep_uint64_count == 5 && alltypes.rep_uint64[4] == 2004 && alltypes.rep_uint64[0] == 0);
TEST(alltypes.rep_sint32_count == 5 && alltypes.rep_sint32[4] == -2005 && alltypes.rep_sint32[0] == 0);
TEST(alltypes.rep_sint64_count == 5 && alltypes.rep_sint64[4] == -2006 && alltypes.rep_sint64[0] == 0);
TEST(alltypes.rep_bool_count == 5 && alltypes.rep_bool[4] == true && alltypes.rep_bool[0] == false);
TEST(alltypes.rep_fixed32_count == 5 && alltypes.rep_fixed32[4] == 2008 && alltypes.rep_fixed32[0] == 0);
TEST(alltypes.rep_sfixed32_count == 5 && alltypes.rep_sfixed32[4] == -2009 && alltypes.rep_sfixed32[0] == 0);
TEST(alltypes.rep_float_count == 5 && alltypes.rep_float[4] == 2010.0f && alltypes.rep_float[0] == 0.0f);
TEST(alltypes.rep_fixed64_count == 5 && alltypes.rep_fixed64[4] == 2011 && alltypes.rep_fixed64[0] == 0);
TEST(alltypes.rep_sfixed64_count == 5 && alltypes.rep_sfixed64[4] == -2012 && alltypes.rep_sfixed64[0] == 0);
TEST(alltypes.rep_double_count == 5 && alltypes.rep_double[4] == 2013.0 && alltypes.rep_double[0] == 0.0);
TEST(alltypes.rep_string_count == 5 && strcmp(alltypes.rep_string[4], "2014") == 0 && alltypes.rep_string[0][0] == '\0');
TEST(alltypes.rep_bytes_count == 5 && alltypes.rep_bytes[4].size == 4 && alltypes.rep_bytes[0].size == 0);
TEST(memcmp(alltypes.rep_bytes[4].bytes, "2015", 4) == 0);
TEST(alltypes.rep_submsg_count == 5);
TEST(strcmp(alltypes.rep_submsg[4].substuff1, "2016") == 0 && alltypes.rep_submsg[0].substuff1[0] == '\0');
TEST(alltypes.rep_submsg[4].substuff2 == 2016 && alltypes.rep_submsg[0].substuff2 == 0);
TEST(alltypes.rep_submsg[4].substuff3 == 2016 && alltypes.rep_submsg[0].substuff3 == 3);
TEST(alltypes.rep_enum_count == 5 && alltypes.rep_enum[4] == MyEnum_Truth && alltypes.rep_enum[0] == MyEnum_Zero);
TEST(alltypes.rep_emptymsg_count == 5);
if (mode == 0)
{
/* Expect default values */
TEST(alltypes.has_opt_int32 == false);
TEST(alltypes.opt_int32 == 4041);
TEST(alltypes.has_opt_int64 == false);
TEST(alltypes.opt_int64 == 4042);
TEST(alltypes.has_opt_uint32 == false);
TEST(alltypes.opt_uint32 == 4043);
TEST(alltypes.has_opt_uint64 == false);
TEST(alltypes.opt_uint64 == 4044);
TEST(alltypes.has_opt_sint32 == false);
TEST(alltypes.opt_sint32 == 4045);
TEST(alltypes.has_opt_sint64 == false);
TEST(alltypes.opt_sint64 == 4046);
TEST(alltypes.has_opt_bool == false);
TEST(alltypes.opt_bool == false);
TEST(alltypes.has_opt_fixed32 == false);
TEST(alltypes.opt_fixed32 == 4048);
TEST(alltypes.has_opt_sfixed32 == false);
TEST(alltypes.opt_sfixed32 == 4049);
TEST(alltypes.has_opt_float == false);
TEST(alltypes.opt_float == 4050.0f);
TEST(alltypes.has_opt_fixed64 == false);
TEST(alltypes.opt_fixed64 == 4051);
TEST(alltypes.has_opt_sfixed64 == false);
TEST(alltypes.opt_sfixed64 == 4052);
TEST(alltypes.has_opt_double == false);
TEST(alltypes.opt_double == 4053.0);
TEST(alltypes.has_opt_string == false);
TEST(strcmp(alltypes.opt_string, "4054") == 0);
TEST(alltypes.has_opt_bytes == false);
TEST(alltypes.opt_bytes.size == 4);
TEST(memcmp(alltypes.opt_bytes.bytes, "4055", 4) == 0);
TEST(alltypes.has_opt_submsg == false);
TEST(strcmp(alltypes.opt_submsg.substuff1, "1") == 0);
TEST(alltypes.opt_submsg.substuff2 == 2);
TEST(alltypes.opt_submsg.substuff3 == 3);
TEST(alltypes.has_opt_enum == false);
TEST(alltypes.opt_enum == MyEnum_Second);
TEST(alltypes.has_opt_emptymsg == false);
}
else
{
/* Expect filled-in values */
TEST(alltypes.has_opt_int32 == true);
TEST(alltypes.opt_int32 == 3041);
TEST(alltypes.has_opt_int64 == true);
TEST(alltypes.opt_int64 == 3042);
TEST(alltypes.has_opt_uint32 == true);
TEST(alltypes.opt_uint32 == 3043);
TEST(alltypes.has_opt_uint64 == true);
TEST(alltypes.opt_uint64 == 3044);
TEST(alltypes.has_opt_sint32 == true);
TEST(alltypes.opt_sint32 == 3045);
TEST(alltypes.has_opt_sint64 == true);
TEST(alltypes.opt_sint64 == 3046);
TEST(alltypes.has_opt_bool == true);
TEST(alltypes.opt_bool == true);
TEST(alltypes.has_opt_fixed32 == true);
TEST(alltypes.opt_fixed32 == 3048);
TEST(alltypes.has_opt_sfixed32 == true);
TEST(alltypes.opt_sfixed32 == 3049);
TEST(alltypes.has_opt_float == true);
TEST(alltypes.opt_float == 3050.0f);
TEST(alltypes.has_opt_fixed64 == true);
TEST(alltypes.opt_fixed64 == 3051);
TEST(alltypes.has_opt_sfixed64 == true);
TEST(alltypes.opt_sfixed64 == 3052);
TEST(alltypes.has_opt_double == true);
TEST(alltypes.opt_double == 3053.0);
TEST(alltypes.has_opt_string == true);
TEST(strcmp(alltypes.opt_string, "3054") == 0);
TEST(alltypes.has_opt_bytes == true);
TEST(alltypes.opt_bytes.size == 4);
TEST(memcmp(alltypes.opt_bytes.bytes, "3055", 4) == 0);
TEST(alltypes.has_opt_submsg == true);
TEST(strcmp(alltypes.opt_submsg.substuff1, "3056") == 0);
TEST(alltypes.opt_submsg.substuff2 == 3056);
TEST(alltypes.opt_submsg.substuff3 == 3);
TEST(alltypes.has_opt_enum == true);
TEST(alltypes.opt_enum == MyEnum_Truth);
TEST(alltypes.has_opt_emptymsg == true);
}
TEST(alltypes.req_limits.int32_min == INT32_MIN);
TEST(alltypes.req_limits.int32_max == INT32_MAX);
TEST(alltypes.req_limits.uint32_min == 0);
TEST(alltypes.req_limits.uint32_max == UINT32_MAX);
TEST(alltypes.req_limits.int64_min == INT64_MIN);
TEST(alltypes.req_limits.int64_max == INT64_MAX);
TEST(alltypes.req_limits.uint64_min == 0);
TEST(alltypes.req_limits.uint64_max == UINT64_MAX);
TEST(alltypes.req_limits.enum_min == HugeEnum_Negative);
TEST(alltypes.req_limits.enum_max == HugeEnum_Positive);
TEST(alltypes.end == 1099);
return true;
}
int main(int argc, char **argv)
{
uint8_t buffer[1024];
size_t count;
pb_istream_t stream;
/* Whether to expect the optional values or the default values. */
int mode = (argc > 1) ? atoi(argv[1]) : 0;
/* Read the data into buffer */
SET_BINARY_MODE(stdin);
count = fread(buffer, 1, sizeof(buffer), stdin);
/* Construct a pb_istream_t for reading from the buffer */
stream = pb_istream_from_buffer(buffer, count);
/* Decode and print out the stuff */
if (!check_alltypes(&stream, mode))
{
printf("Parsing failed: %s\n", PB_GET_ERROR(&stream));
return 1;
} else {
return 0;
}
}

145
tests/alltypes/encode_alltypes.c
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@@ -1,145 +0,0 @@
/* Attempts to test all the datatypes supported by ProtoBuf.
*/
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <pb_encode.h>
#include "alltypes.pb.h"
#include "test_helpers.h"
int main(int argc, char **argv)
{
int mode = (argc > 1) ? atoi(argv[1]) : 0;
/* Initialize the structure with constants */
AllTypes alltypes = AllTypes_init_zero;
alltypes.req_int32 = -1001;
alltypes.req_int64 = -1002;
alltypes.req_uint32 = 1003;
alltypes.req_uint64 = 1004;
alltypes.req_sint32 = -1005;
alltypes.req_sint64 = -1006;
alltypes.req_bool = true;
alltypes.req_fixed32 = 1008;
alltypes.req_sfixed32 = -1009;
alltypes.req_float = 1010.0f;
alltypes.req_fixed64 = 1011;
alltypes.req_sfixed64 = -1012;
alltypes.req_double = 1013.0;
strcpy(alltypes.req_string, "1014");
alltypes.req_bytes.size = 4;
memcpy(alltypes.req_bytes.bytes, "1015", 4);
strcpy(alltypes.req_submsg.substuff1, "1016");
alltypes.req_submsg.substuff2 = 1016;
alltypes.req_enum = MyEnum_Truth;
alltypes.rep_int32_count = 5; alltypes.rep_int32[4] = -2001;
alltypes.rep_int64_count = 5; alltypes.rep_int64[4] = -2002;
alltypes.rep_uint32_count = 5; alltypes.rep_uint32[4] = 2003;
alltypes.rep_uint64_count = 5; alltypes.rep_uint64[4] = 2004;
alltypes.rep_sint32_count = 5; alltypes.rep_sint32[4] = -2005;
alltypes.rep_sint64_count = 5; alltypes.rep_sint64[4] = -2006;
alltypes.rep_bool_count = 5; alltypes.rep_bool[4] = true;
alltypes.rep_fixed32_count = 5; alltypes.rep_fixed32[4] = 2008;
alltypes.rep_sfixed32_count = 5; alltypes.rep_sfixed32[4] = -2009;
alltypes.rep_float_count = 5; alltypes.rep_float[4] = 2010.0f;
alltypes.rep_fixed64_count = 5; alltypes.rep_fixed64[4] = 2011;
alltypes.rep_sfixed64_count = 5; alltypes.rep_sfixed64[4] = -2012;
alltypes.rep_double_count = 5; alltypes.rep_double[4] = 2013.0;
alltypes.rep_string_count = 5; strcpy(alltypes.rep_string[4], "2014");
alltypes.rep_bytes_count = 5; alltypes.rep_bytes[4].size = 4;
memcpy(alltypes.rep_bytes[4].bytes, "2015", 4);
alltypes.rep_submsg_count = 5;
strcpy(alltypes.rep_submsg[4].substuff1, "2016");
alltypes.rep_submsg[4].substuff2 = 2016;
alltypes.rep_submsg[4].has_substuff3 = true;
alltypes.rep_submsg[4].substuff3 = 2016;
alltypes.rep_enum_count = 5; alltypes.rep_enum[4] = MyEnum_Truth;
alltypes.rep_emptymsg_count = 5;
alltypes.req_limits.int32_min = INT32_MIN;
alltypes.req_limits.int32_max = INT32_MAX;
alltypes.req_limits.uint32_min = 0;
alltypes.req_limits.uint32_max = UINT32_MAX;
alltypes.req_limits.int64_min = INT64_MIN;
alltypes.req_limits.int64_max = INT64_MAX;
alltypes.req_limits.uint64_min = 0;
alltypes.req_limits.uint64_max = UINT64_MAX;
alltypes.req_limits.enum_min = HugeEnum_Negative;
alltypes.req_limits.enum_max = HugeEnum_Positive;
if (mode != 0)
{
/* Fill in values for optional fields */
alltypes.has_opt_int32 = true;
alltypes.opt_int32 = 3041;
alltypes.has_opt_int64 = true;
alltypes.opt_int64 = 3042;
alltypes.has_opt_uint32 = true;
alltypes.opt_uint32 = 3043;
alltypes.has_opt_uint64 = true;
alltypes.opt_uint64 = 3044;
alltypes.has_opt_sint32 = true;
alltypes.opt_sint32 = 3045;
alltypes.has_opt_sint64 = true;
alltypes.opt_sint64 = 3046;
alltypes.has_opt_bool = true;
alltypes.opt_bool = true;
alltypes.has_opt_fixed32 = true;
alltypes.opt_fixed32 = 3048;
alltypes.has_opt_sfixed32 = true;
alltypes.opt_sfixed32 = 3049;
alltypes.has_opt_float = true;
alltypes.opt_float = 3050.0f;
alltypes.has_opt_fixed64 = true;
alltypes.opt_fixed64 = 3051;
alltypes.has_opt_sfixed64 = true;
alltypes.opt_sfixed64 = 3052;
alltypes.has_opt_double = true;
alltypes.opt_double = 3053.0;
alltypes.has_opt_string = true;
strcpy(alltypes.opt_string, "3054");
alltypes.has_opt_bytes = true;
alltypes.opt_bytes.size = 4;
memcpy(alltypes.opt_bytes.bytes, "3055", 4);
alltypes.has_opt_submsg = true;
strcpy(alltypes.opt_submsg.substuff1, "3056");
alltypes.opt_submsg.substuff2 = 3056;
alltypes.has_opt_enum = true;
alltypes.opt_enum = MyEnum_Truth;
alltypes.has_opt_emptymsg = true;
}
alltypes.end = 1099;
{
uint8_t buffer[AllTypes_size];
pb_ostream_t stream = pb_ostream_from_buffer(buffer, sizeof(buffer));
/* Now encode it and check if we succeeded. */
if (pb_encode(&stream, AllTypes_fields, &alltypes))
{
SET_BINARY_MODE(stdout);
fwrite(buffer, 1, stream.bytes_written, stdout);
return 0; /* Success */
}
else
{
fprintf(stderr, "Encoding failed: %s\n", PB_GET_ERROR(&stream));
return 1; /* Failure */
}
}
}

23
tests/alltypes_callback/SConscript
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@@ -1,23 +0,0 @@
# Test the AllTypes encoding & decoding using callbacks for all fields.
Import("env")
c = Copy("$TARGET", "$SOURCE")
env.Command("alltypes.proto", "#alltypes/alltypes.proto", c)
env.NanopbProto(["alltypes", "alltypes.options"])
enc = env.Program(["encode_alltypes_callback.c", "alltypes.pb.c", "$COMMON/pb_encode.o", "$COMMON/pb_common.o"])
dec = env.Program(["decode_alltypes_callback.c", "alltypes.pb.c", "$COMMON/pb_decode.o", "$COMMON/pb_common.o"])
refdec = "$BUILD/alltypes/decode_alltypes$PROGSUFFIX"
# Encode and compare results
env.RunTest(enc)
env.RunTest("decode_alltypes.output", [refdec, "encode_alltypes_callback.output"])
env.RunTest("decode_alltypes_callback.output", [dec, "encode_alltypes_callback.output"])
# Do the same thing with the optional fields present
env.RunTest("optionals.output", enc, ARGS = ['1'])
env.RunTest("optionals.refdecout", [refdec, "optionals.output"], ARGS = ['1'])
env.RunTest("optionals.decout", [dec, "optionals.output"], ARGS = ['1'])

3
tests/alltypes_callback/alltypes.options
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@@ -1,3 +0,0 @@
# Generate all fields as callbacks.
AllTypes.* type:FT_CALLBACK
SubMessage.substuff1 max_size:16

424
tests/alltypes_callback/decode_alltypes_callback.c
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@@ -1,424 +0,0 @@
/* Attempts to test all the datatypes supported by ProtoBuf when used as callback fields.
* Note that normally there would be no reason to use callback fields for this,
* because each encoder defined here only gives a single field.
*/
#include <stdio.h>
#include <string.h>
#include <stdlib.h>
#include <pb_decode.h>
#include "alltypes.pb.h"
#include "test_helpers.h"
#define TEST(x) if (!(x)) { \
printf("Test " #x " failed (in field %d).\n", field->tag); \
return false; \
}
static bool read_varint(pb_istream_t *stream, const pb_field_t *field, void **arg)
{
uint64_t value;
if (!pb_decode_varint(stream, &value))
return false;
TEST((int64_t)value == (long)*arg);
return true;
}
static bool read_svarint(pb_istream_t *stream, const pb_field_t *field, void **arg)
{
int64_t value;
if (!pb_decode_svarint(stream, &value))
return false;
TEST(value == (long)*arg);
return true;
}
static bool read_fixed32(pb_istream_t *stream, const pb_field_t *field, void **arg)
{
uint32_t value;
if (!pb_decode_fixed32(stream, &value))
return false;
TEST(value == *(uint32_t*)*arg);
return true;
}
static bool read_fixed64(pb_istream_t *stream, const pb_field_t *field, void **arg)
{
uint64_t value;
if (!pb_decode_fixed64(stream, &value))
return false;
TEST(value == *(uint64_t*)*arg);
return true;
}
static bool read_string(pb_istream_t *stream, const pb_field_t *field, void **arg)
{
uint8_t buf[16] = {0};
size_t len = stream->bytes_left;
if (len > sizeof(buf) - 1 || !pb_read(stream, buf, len))
return false;
TEST(strcmp((char*)buf, *arg) == 0);
return true;
}
static bool read_submsg(pb_istream_t *stream, const pb_field_t *field, void **arg)
{
SubMessage submsg = {""};
if (!pb_decode(stream, SubMessage_fields, &submsg))
return false;
TEST(memcmp(&submsg, *arg, sizeof(submsg)));
return true;
}
static bool read_emptymsg(pb_istream_t *stream, const pb_field_t *field, void **arg)
{
EmptyMessage emptymsg = {0};
return pb_decode(stream, EmptyMessage_fields, &emptymsg);
}
static bool read_repeated_varint(pb_istream_t *stream, const pb_field_t *field, void **arg)
{
int32_t** expected = (int32_t**)arg;
uint64_t value;
if (!pb_decode_varint(stream, &value))
return false;
TEST(*(*expected)++ == value);
return true;
}
static bool read_repeated_svarint(pb_istream_t *stream, const pb_field_t *field, void **arg)
{
int32_t** expected = (int32_t**)arg;
int64_t value;
if (!pb_decode_svarint(stream, &value))
return false;
TEST(*(*expected)++ == value);
return true;
}
static bool read_repeated_fixed32(pb_istream_t *stream, const pb_field_t *field, void **arg)
{
uint32_t** expected = (uint32_t**)arg;
uint32_t value;
if (!pb_decode_fixed32(stream, &value))
return false;
TEST(*(*expected)++ == value);
return true;
}
static bool read_repeated_fixed64(pb_istream_t *stream, const pb_field_t *field, void **arg)
{
uint64_t** expected = (uint64_t**)arg;
uint64_t value;
if (!pb_decode_fixed64(stream, &value))
return false;
TEST(*(*expected)++ == value);
return true;
}
static bool read_repeated_string(pb_istream_t *stream, const pb_field_t *field, void **arg)
{
uint8_t*** expected = (uint8_t***)arg;
uint8_t buf[16] = {0};
size_t len = stream->bytes_left;
if (len > sizeof(buf) - 1 || !pb_read(stream, buf, len))
return false;
TEST(strcmp((char*)*(*expected)++, (char*)buf) == 0);
return true;
}
static bool read_repeated_submsg(pb_istream_t *stream, const pb_field_t *field, void **arg)
{
SubMessage** expected = (SubMessage**)arg;
SubMessage decoded = {""};
if (!pb_decode(stream, SubMessage_fields, &decoded))
return false;
TEST(memcmp((*expected)++, &decoded, sizeof(decoded)) == 0);
return true;
}
static bool read_limits(pb_istream_t *stream, const pb_field_t *field, void **arg)
{
Limits decoded = {0};
if (!pb_decode(stream, Limits_fields, &decoded))
return false;
TEST(decoded.int32_min == INT32_MIN);
TEST(decoded.int32_max == INT32_MAX);
TEST(decoded.uint32_min == 0);
TEST(decoded.uint32_max == UINT32_MAX);
TEST(decoded.int64_min == INT64_MIN);
TEST(decoded.int64_max == INT64_MAX);
TEST(decoded.uint64_min == 0);
TEST(decoded.uint64_max == UINT64_MAX);
TEST(decoded.enum_min == HugeEnum_Negative);
TEST(decoded.enum_max == HugeEnum_Positive);
return true;
}
/* This function is called once from main(), it handles
the decoding and checks the fields. */
bool check_alltypes(pb_istream_t *stream, int mode)
{
/* Values for use from callbacks through pointers. */
uint32_t req_fixed32 = 1008;
int32_t req_sfixed32 = -1009;
float req_float = 1010.0f;
uint64_t req_fixed64 = 1011;
int64_t req_sfixed64 = -1012;
double req_double = 1013.0;
SubMessage req_submsg = {"1016", 1016};
int32_t rep_int32[5] = {0, 0, 0, 0, -2001};
int32_t rep_int64[5] = {0, 0, 0, 0, -2002};
int32_t rep_uint32[5] = {0, 0, 0, 0, 2003};
int32_t rep_uint64[5] = {0, 0, 0, 0, 2004};
int32_t rep_sint32[5] = {0, 0, 0, 0, -2005};
int32_t rep_sint64[5] = {0, 0, 0, 0, -2006};
int32_t rep_bool[5] = {false, false, false, false, true};
uint32_t rep_fixed32[5] = {0, 0, 0, 0, 2008};
int32_t rep_sfixed32[5] = {0, 0, 0, 0, -2009};
float rep_float[5] = {0, 0, 0, 0, 2010.0f};
uint64_t rep_fixed64[5] = {0, 0, 0, 0, 2011};
int64_t rep_sfixed64[5] = {0, 0, 0, 0, -2012};
double rep_double[5] = {0, 0, 0, 0, 2013.0};
char* rep_string[5] = {"", "", "", "", "2014"};
char* rep_bytes[5] = {"", "", "", "", "2015"};
SubMessage rep_submsg[5] = {{"", 0, 0, 3},
{"", 0, 0, 3},
{"", 0, 0, 3},
{"", 0, 0, 3},
{"2016", 2016, true, 2016}};
int32_t rep_enum[5] = {0, 0, 0, 0, MyEnum_Truth};
uint32_t opt_fixed32 = 3048;
int32_t opt_sfixed32 = 3049;
float opt_float = 3050.0f;
uint64_t opt_fixed64 = 3051;
int64_t opt_sfixed64 = 3052;
double opt_double = 3053.0f;
SubMessage opt_submsg = {"3056", 3056};
/* Bind callbacks for required fields */
AllTypes alltypes;
/* Fill with garbage to better detect initialization errors */
memset(&alltypes, 0xAA, sizeof(alltypes));
alltypes.extensions = 0;
alltypes.req_int32.funcs.decode = &read_varint;
alltypes.req_int32.arg = (void*)-1001;
alltypes.req_int64.funcs.decode = &read_varint;
alltypes.req_int64.arg = (void*)-1002;
alltypes.req_uint32.funcs.decode = &read_varint;
alltypes.req_uint32.arg = (void*)1003;
alltypes.req_uint32.funcs.decode = &read_varint;
alltypes.req_uint32.arg = (void*)1003;
alltypes.req_uint64.funcs.decode = &read_varint;
alltypes.req_uint64.arg = (void*)1004;
alltypes.req_sint32.funcs.decode = &read_svarint;
alltypes.req_sint32.arg = (void*)-1005;
alltypes.req_sint64.funcs.decode = &read_svarint;
alltypes.req_sint64.arg = (void*)-1006;
alltypes.req_bool.funcs.decode = &read_varint;
alltypes.req_bool.arg = (void*)true;
alltypes.req_fixed32.funcs.decode = &read_fixed32;
alltypes.req_fixed32.arg = &req_fixed32;
alltypes.req_sfixed32.funcs.decode = &read_fixed32;
alltypes.req_sfixed32.arg = &req_sfixed32;
alltypes.req_float.funcs.decode = &read_fixed32;
alltypes.req_float.arg = &req_float;
alltypes.req_fixed64.funcs.decode = &read_fixed64;
alltypes.req_fixed64.arg = &req_fixed64;
alltypes.req_sfixed64.funcs.decode = &read_fixed64;
alltypes.req_sfixed64.arg = &req_sfixed64;
alltypes.req_double.funcs.decode = &read_fixed64;
alltypes.req_double.arg = &req_double;
alltypes.req_string.funcs.decode = &read_string;
alltypes.req_string.arg = "1014";
alltypes.req_bytes.funcs.decode = &read_string;
alltypes.req_bytes.arg = "1015";
alltypes.req_submsg.funcs.decode = &read_submsg;
alltypes.req_submsg.arg = &req_submsg;
alltypes.req_enum.funcs.decode = &read_varint;
alltypes.req_enum.arg = (void*)MyEnum_Truth;
alltypes.req_emptymsg.funcs.decode = &read_emptymsg;
/* Bind callbacks for repeated fields */
alltypes.rep_int32.funcs.decode = &read_repeated_varint;
alltypes.rep_int32.arg = rep_int32;
alltypes.rep_int64.funcs.decode = &read_repeated_varint;
alltypes.rep_int64.arg = rep_int64;
alltypes.rep_uint32.funcs.decode = &read_repeated_varint;
alltypes.rep_uint32.arg = rep_uint32;
alltypes.rep_uint64.funcs.decode = &read_repeated_varint;
alltypes.rep_uint64.arg = rep_uint64;
alltypes.rep_sint32.funcs.decode = &read_repeated_svarint;
alltypes.rep_sint32.arg = rep_sint32;
alltypes.rep_sint64.funcs.decode = &read_repeated_svarint;
alltypes.rep_sint64.arg = rep_sint64;
alltypes.rep_bool.funcs.decode = &read_repeated_varint;
alltypes.rep_bool.arg = rep_bool;
alltypes.rep_fixed32.funcs.decode = &read_repeated_fixed32;
alltypes.rep_fixed32.arg = rep_fixed32;
alltypes.rep_sfixed32.funcs.decode = &read_repeated_fixed32;
alltypes.rep_sfixed32.arg = rep_sfixed32;
alltypes.rep_float.funcs.decode = &read_repeated_fixed32;
alltypes.rep_float.arg = rep_float;
alltypes.rep_fixed64.funcs.decode = &read_repeated_fixed64;
alltypes.rep_fixed64.arg = rep_fixed64;
alltypes.rep_sfixed64.funcs.decode = &read_repeated_fixed64;
alltypes.rep_sfixed64.arg = rep_sfixed64;
alltypes.rep_double.funcs.decode = &read_repeated_fixed64;
alltypes.rep_double.arg = rep_double;
alltypes.rep_string.funcs.decode = &read_repeated_string;
alltypes.rep_string.arg = rep_string;
alltypes.rep_bytes.funcs.decode = &read_repeated_string;
alltypes.rep_bytes.arg = rep_bytes;
alltypes.rep_submsg.funcs.decode = &read_repeated_submsg;
alltypes.rep_submsg.arg = rep_submsg;
alltypes.rep_enum.funcs.decode = &read_repeated_varint;
alltypes.rep_enum.arg = rep_enum;
alltypes.rep_emptymsg.funcs.decode = &read_emptymsg;
alltypes.req_limits.funcs.decode = &read_limits;
alltypes.end.funcs.decode = &read_varint;
alltypes.end.arg = (void*)1099;
/* Bind callbacks for optional fields */
if (mode == 1)
{
alltypes.opt_int32.funcs.decode = &read_varint;
alltypes.opt_int32.arg = (void*)3041;
alltypes.opt_int64.funcs.decode = &read_varint;
alltypes.opt_int64.arg = (void*)3042;
alltypes.opt_uint32.funcs.decode = &read_varint;
alltypes.opt_uint32.arg = (void*)3043;
alltypes.opt_uint64.funcs.decode = &read_varint;
alltypes.opt_uint64.arg = (void*)3044;
alltypes.opt_sint32.funcs.decode = &read_svarint;
alltypes.opt_sint32.arg = (void*)3045;
alltypes.opt_sint64.funcs.decode = &read_svarint;
alltypes.opt_sint64.arg = (void*)3046;
alltypes.opt_bool.funcs.decode = &read_varint;
alltypes.opt_bool.arg = (void*)true;
alltypes.opt_fixed32.funcs.decode = &read_fixed32;
alltypes.opt_fixed32.arg = &opt_fixed32;
alltypes.opt_sfixed32.funcs.decode = &read_fixed32;
alltypes.opt_sfixed32.arg = &opt_sfixed32;
alltypes.opt_float.funcs.decode = &read_fixed32;
alltypes.opt_float.arg = &opt_float;
alltypes.opt_fixed64.funcs.decode = &read_fixed64;
alltypes.opt_fixed64.arg = &opt_fixed64;
alltypes.opt_sfixed64.funcs.decode = &read_fixed64;
alltypes.opt_sfixed64.arg = &opt_sfixed64;
alltypes.opt_double.funcs.decode = &read_fixed64;
alltypes.opt_double.arg = &opt_double;
alltypes.opt_string.funcs.decode = &read_string;
alltypes.opt_string.arg = "3054";
alltypes.opt_bytes.funcs.decode = &read_string;
alltypes.opt_bytes.arg = "3055";
alltypes.opt_submsg.funcs.decode = &read_submsg;
alltypes.opt_submsg.arg = &opt_submsg;
alltypes.opt_enum.funcs.decode = &read_varint;
alltypes.opt_enum.arg = (void*)MyEnum_Truth;
alltypes.opt_emptymsg.funcs.decode = &read_emptymsg;
}
return pb_decode(stream, AllTypes_fields, &alltypes);
}
int main(int argc, char **argv)
{
uint8_t buffer[1024];
size_t count;
pb_istream_t stream;
/* Whether to expect the optional values or the default values. */
int mode = (argc > 1) ? atoi(argv[1]) : 0;
/* Read the data into buffer */
SET_BINARY_MODE(stdin);
count = fread(buffer, 1, sizeof(buffer), stdin);
/* Construct a pb_istream_t for reading from the buffer */
stream = pb_istream_from_buffer(buffer, count);
/* Decode and print out the stuff */
if (!check_alltypes(&stream, mode))
{
printf("Parsing failed: %s\n", PB_GET_ERROR(&stream));
return 1;
} else {
return 0;
}
}

397
tests/alltypes_callback/encode_alltypes_callback.c
View File

@@ -1,397 +0,0 @@
/* Attempts to test all the datatypes supported by ProtoBuf when used as callback fields.
* Note that normally there would be no reason to use callback fields for this,
* because each encoder defined here only gives a single field.
*/
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <pb_encode.h>
#include "alltypes.pb.h"
#include "test_helpers.h"
static bool write_varint(pb_ostream_t *stream, const pb_field_t *field, void * const *arg)
{
return pb_encode_tag_for_field(stream, field) &&
pb_encode_varint(stream, (long)*arg);
}
static bool write_svarint(pb_ostream_t *stream, const pb_field_t *field, void * const *arg)
{
return pb_encode_tag_for_field(stream, field) &&
pb_encode_svarint(stream, (long)*arg);
}
static bool write_fixed32(pb_ostream_t *stream, const pb_field_t *field, void * const *arg)
{
return pb_encode_tag_for_field(stream, field) &&
pb_encode_fixed32(stream, *arg);
}
static bool write_fixed64(pb_ostream_t *stream, const pb_field_t *field, void * const *arg)
{
return pb_encode_tag_for_field(stream, field) &&
pb_encode_fixed64(stream, *arg);
}
static bool write_string(pb_ostream_t *stream, const pb_field_t *field, void * const *arg)
{
return pb_encode_tag_for_field(stream, field) &&
pb_encode_string(stream, *arg, strlen(*arg));
}
static bool write_submsg(pb_ostream_t *stream, const pb_field_t *field, void * const *arg)
{
return pb_encode_tag_for_field(stream, field) &&
pb_encode_submessage(stream, SubMessage_fields, *arg);
}
static bool write_emptymsg(pb_ostream_t *stream, const pb_field_t *field, void * const *arg)
{
EmptyMessage emptymsg = {0};
return pb_encode_tag_for_field(stream, field) &&
pb_encode_submessage(stream, EmptyMessage_fields, &emptymsg);
}
static bool write_repeated_varint(pb_ostream_t *stream, const pb_field_t *field, void * const *arg)
{
return pb_encode_tag_for_field(stream, field) &&
pb_encode_varint(stream, 0) &&
pb_encode_tag_for_field(stream, field) &&
pb_encode_varint(stream, 0) &&
pb_encode_tag_for_field(stream, field) &&
pb_encode_varint(stream, 0) &&
pb_encode_tag_for_field(stream, field) &&
pb_encode_varint(stream, 0) &&
pb_encode_tag_for_field(stream, field) &&
pb_encode_varint(stream, (long)*arg);
}
static bool write_repeated_svarint(pb_ostream_t *stream, const pb_field_t *field, void * const *arg)
{
return pb_encode_tag_for_field(stream, field) &&
pb_encode_svarint(stream, 0) &&
pb_encode_tag_for_field(stream, field) &&
pb_encode_svarint(stream, 0) &&
pb_encode_tag_for_field(stream, field) &&
pb_encode_svarint(stream, 0) &&
pb_encode_tag_for_field(stream, field) &&
pb_encode_svarint(stream, 0) &&
pb_encode_tag_for_field(stream, field) &&
pb_encode_svarint(stream, (long)*arg);
}
static bool write_repeated_fixed32(pb_ostream_t *stream, const pb_field_t *field, void * const *arg)
{
uint32_t dummy = 0;
/* Make it a packed field */
return pb_encode_tag(stream, PB_WT_STRING, field->tag) &&
pb_encode_varint(stream, 5 * 4) && /* Number of bytes */
pb_encode_fixed32(stream, &dummy) &&
pb_encode_fixed32(stream, &dummy) &&
pb_encode_fixed32(stream, &dummy) &&
pb_encode_fixed32(stream, &dummy) &&
pb_encode_fixed32(stream, *arg);
}
static bool write_repeated_fixed64(pb_ostream_t *stream, const pb_field_t *field, void * const *arg)
{
uint64_t dummy = 0;
/* Make it a packed field */
return pb_encode_tag(stream, PB_WT_STRING, field->tag) &&
pb_encode_varint(stream, 5 * 8) && /* Number of bytes */
pb_encode_fixed64(stream, &dummy) &&
pb_encode_fixed64(stream, &dummy) &&
pb_encode_fixed64(stream, &dummy) &&
pb_encode_fixed64(stream, &dummy) &&
pb_encode_fixed64(stream, *arg);
}
static bool write_repeated_string(pb_ostream_t *stream, const pb_field_t *field, void * const *arg)
{
return pb_encode_tag_for_field(stream, field) &&
pb_encode_string(stream, 0, 0) &&
pb_encode_tag_for_field(stream, field) &&
pb_encode_string(stream, 0, 0) &&
pb_encode_tag_for_field(stream, field) &&
pb_encode_string(stream, 0, 0) &&
pb_encode_tag_for_field(stream, field) &&
pb_encode_string(stream, 0, 0) &&
pb_encode_tag_for_field(stream, field) &&
pb_encode_string(stream, *arg, strlen(*arg));
}
static bool write_repeated_submsg(pb_ostream_t *stream, const pb_field_t *field, void * const *arg)
{
SubMessage dummy = {""};
return pb_encode_tag_for_field(stream, field) &&
pb_encode_submessage(stream, SubMessage_fields, &dummy) &&
pb_encode_tag_for_field(stream, field) &&
pb_encode_submessage(stream, SubMessage_fields, &dummy) &&
pb_encode_tag_for_field(stream, field) &&
pb_encode_submessage(stream, SubMessage_fields, &dummy) &&
pb_encode_tag_for_field(stream, field) &&
pb_encode_submessage(stream, SubMessage_fields, &dummy) &&
pb_encode_tag_for_field(stream, field) &&
pb_encode_submessage(stream, SubMessage_fields, *arg);
}
static bool write_limits(pb_ostream_t *stream, const pb_field_t *field, void * const *arg)
{
Limits limits = {0};
limits.int32_min = INT32_MIN;
limits.int32_max = INT32_MAX;
limits.uint32_min = 0;
limits.uint32_max = UINT32_MAX;
limits.int64_min = INT64_MIN;
limits.int64_max = INT64_MAX;
limits.uint64_min = 0;
limits.uint64_max = UINT64_MAX;
limits.enum_min = HugeEnum_Negative;
limits.enum_max = HugeEnum_Positive;
return pb_encode_tag_for_field(stream, field) &&
pb_encode_submessage(stream, Limits_fields, &limits);
}
static bool write_repeated_emptymsg(pb_ostream_t *stream, const pb_field_t *field, void * const *arg)
{
EmptyMessage emptymsg = {0};
return pb_encode_tag_for_field(stream, field) &&
pb_encode_submessage(stream, EmptyMessage_fields, &emptymsg) &&
pb_encode_tag_for_field(stream, field) &&
pb_encode_submessage(stream, EmptyMessage_fields, &emptymsg) &&
pb_encode_tag_for_field(stream, field) &&
pb_encode_submessage(stream, EmptyMessage_fields, &emptymsg) &&
pb_encode_tag_for_field(stream, field) &&
pb_encode_submessage(stream, EmptyMessage_fields, &emptymsg) &&
pb_encode_tag_for_field(stream, field) &&
pb_encode_submessage(stream, EmptyMessage_fields, &emptymsg);
}
int main(int argc, char **argv)
{
int mode = (argc > 1) ? atoi(argv[1]) : 0;
/* Values for use from callbacks through pointers. */
uint32_t req_fixed32 = 1008;
int32_t req_sfixed32 = -1009;
float req_float = 1010.0f;
uint64_t req_fixed64 = 1011;
int64_t req_sfixed64 = -1012;
double req_double = 1013.0;
SubMessage req_submsg = {"1016", 1016};
uint32_t rep_fixed32 = 2008;
int32_t rep_sfixed32 = -2009;
float rep_float = 2010.0f;
uint64_t rep_fixed64 = 2011;
int64_t rep_sfixed64 = -2012;
double rep_double = 2013.0;
SubMessage rep_submsg = {"2016", 2016, true, 2016};
uint32_t opt_fixed32 = 3048;
int32_t opt_sfixed32 = 3049;
float opt_float = 3050.0f;
uint64_t opt_fixed64 = 3051;
int64_t opt_sfixed64 = 3052;
double opt_double = 3053.0f;
SubMessage opt_submsg = {"3056", 3056};
/* Bind callbacks for required fields */
AllTypes alltypes = {{{0}}};
alltypes.req_int32.funcs.encode = &write_varint;
alltypes.req_int32.arg = (void*)-1001;
alltypes.req_int64.funcs.encode = &write_varint;
alltypes.req_int64.arg = (void*)-1002;
alltypes.req_uint32.funcs.encode = &write_varint;
alltypes.req_uint32.arg = (void*)1003;
alltypes.req_uint32.funcs.encode = &write_varint;
alltypes.req_uint32.arg = (void*)1003;
alltypes.req_uint64.funcs.encode = &write_varint;
alltypes.req_uint64.arg = (void*)1004;
alltypes.req_sint32.funcs.encode = &write_svarint;
alltypes.req_sint32.arg = (void*)-1005;
alltypes.req_sint64.funcs.encode = &write_svarint;
alltypes.req_sint64.arg = (void*)-1006;
alltypes.req_bool.funcs.encode = &write_varint;
alltypes.req_bool.arg = (void*)true;
alltypes.req_fixed32.funcs.encode = &write_fixed32;
alltypes.req_fixed32.arg = &req_fixed32;
alltypes.req_sfixed32.funcs.encode = &write_fixed32;
alltypes.req_sfixed32.arg = &req_sfixed32;
alltypes.req_float.funcs.encode = &write_fixed32;
alltypes.req_float.arg = &req_float;
alltypes.req_fixed64.funcs.encode = &write_fixed64;
alltypes.req_fixed64.arg = &req_fixed64;
alltypes.req_sfixed64.funcs.encode = &write_fixed64;
alltypes.req_sfixed64.arg = &req_sfixed64;
alltypes.req_double.funcs.encode = &write_fixed64;
alltypes.req_double.arg = &req_double;
alltypes.req_string.funcs.encode = &write_string;
alltypes.req_string.arg = "1014";
alltypes.req_bytes.funcs.encode = &write_string;
alltypes.req_bytes.arg = "1015";
alltypes.req_submsg.funcs.encode = &write_submsg;
alltypes.req_submsg.arg = &req_submsg;
alltypes.req_enum.funcs.encode = &write_varint;
alltypes.req_enum.arg = (void*)MyEnum_Truth;
alltypes.req_emptymsg.funcs.encode = &write_emptymsg;
/* Bind callbacks for repeated fields */
alltypes.rep_int32.funcs.encode = &write_repeated_varint;
alltypes.rep_int32.arg = (void*)-2001;
alltypes.rep_int64.funcs.encode = &write_repeated_varint;
alltypes.rep_int64.arg = (void*)-2002;
alltypes.rep_uint32.funcs.encode = &write_repeated_varint;
alltypes.rep_uint32.arg = (void*)2003;
alltypes.rep_uint64.funcs.encode = &write_repeated_varint;
alltypes.rep_uint64.arg = (void*)2004;
alltypes.rep_sint32.funcs.encode = &write_repeated_svarint;
alltypes.rep_sint32.arg = (void*)-2005;
alltypes.rep_sint64.funcs.encode = &write_repeated_svarint;
alltypes.rep_sint64.arg = (void*)-2006;
alltypes.rep_bool.funcs.encode = &write_repeated_varint;
alltypes.rep_bool.arg = (void*)true;
alltypes.rep_fixed32.funcs.encode = &write_repeated_fixed32;
alltypes.rep_fixed32.arg = &rep_fixed32;
alltypes.rep_sfixed32.funcs.encode = &write_repeated_fixed32;
alltypes.rep_sfixed32.arg = &rep_sfixed32;
alltypes.rep_float.funcs.encode = &write_repeated_fixed32;
alltypes.rep_float.arg = &rep_float;
alltypes.rep_fixed64.funcs.encode = &write_repeated_fixed64;
alltypes.rep_fixed64.arg = &rep_fixed64;
alltypes.rep_sfixed64.funcs.encode = &write_repeated_fixed64;
alltypes.rep_sfixed64.arg = &rep_sfixed64;
alltypes.rep_double.funcs.encode = &write_repeated_fixed64;
alltypes.rep_double.arg = &rep_double;
alltypes.rep_string.funcs.encode = &write_repeated_string;
alltypes.rep_string.arg = "2014";
alltypes.rep_bytes.funcs.encode = &write_repeated_string;
alltypes.rep_bytes.arg = "2015";
alltypes.rep_submsg.funcs.encode = &write_repeated_submsg;
alltypes.rep_submsg.arg = &rep_submsg;
alltypes.rep_enum.funcs.encode = &write_repeated_varint;
alltypes.rep_enum.arg = (void*)MyEnum_Truth;
alltypes.rep_emptymsg.funcs.encode = &write_repeated_emptymsg;
alltypes.req_limits.funcs.encode = &write_limits;
/* Bind callbacks for optional fields */
if (mode != 0)
{
alltypes.opt_int32.funcs.encode = &write_varint;
alltypes.opt_int32.arg = (void*)3041;
alltypes.opt_int64.funcs.encode = &write_varint;
alltypes.opt_int64.arg = (void*)3042;
alltypes.opt_uint32.funcs.encode = &write_varint;
alltypes.opt_uint32.arg = (void*)3043;
alltypes.opt_uint64.funcs.encode = &write_varint;
alltypes.opt_uint64.arg = (void*)3044;
alltypes.opt_sint32.funcs.encode = &write_svarint;
alltypes.opt_sint32.arg = (void*)3045;
alltypes.opt_sint64.funcs.encode = &write_svarint;
alltypes.opt_sint64.arg = (void*)3046;
alltypes.opt_bool.funcs.encode = &write_varint;
alltypes.opt_bool.arg = (void*)true;
alltypes.opt_fixed32.funcs.encode = &write_fixed32;
alltypes.opt_fixed32.arg = &opt_fixed32;
alltypes.opt_sfixed32.funcs.encode = &write_fixed32;
alltypes.opt_sfixed32.arg = &opt_sfixed32;
alltypes.opt_float.funcs.encode = &write_fixed32;
alltypes.opt_float.arg = &opt_float;
alltypes.opt_fixed64.funcs.encode = &write_fixed64;
alltypes.opt_fixed64.arg = &opt_fixed64;
alltypes.opt_sfixed64.funcs.encode = &write_fixed64;
alltypes.opt_sfixed64.arg = &opt_sfixed64;
alltypes.opt_double.funcs.encode = &write_fixed64;
alltypes.opt_double.arg = &opt_double;
alltypes.opt_string.funcs.encode = &write_string;
alltypes.opt_string.arg = "3054";
alltypes.opt_bytes.funcs.encode = &write_string;
alltypes.opt_bytes.arg = "3055";
alltypes.opt_submsg.funcs.encode = &write_submsg;
alltypes.opt_submsg.arg = &opt_submsg;
alltypes.opt_enum.funcs.encode = &write_varint;
alltypes.opt_enum.arg = (void*)MyEnum_Truth;
alltypes.opt_emptymsg.funcs.encode = &write_emptymsg;
}
alltypes.end.funcs.encode = &write_varint;
alltypes.end.arg = (void*)1099;
{
uint8_t buffer[2048];
pb_ostream_t stream = pb_ostream_from_buffer(buffer, sizeof(buffer));
/* Now encode it and check if we succeeded. */
if (pb_encode(&stream, AllTypes_fields, &alltypes))
{
SET_BINARY_MODE(stdout);
fwrite(buffer, 1, stream.bytes_written, stdout);
return 0; /* Success */
}
else
{
fprintf(stderr, "Encoding failed: %s\n", PB_GET_ERROR(&stream));
return 1; /* Failure */
}
}
}

49
tests/alltypes_pointer/SConscript
View File

@@ -1,49 +0,0 @@
# Encode the AllTypes message using pointers for all fields, and verify the
# output against the normal AllTypes test case.
Import("env")
# We need our own pb_decode.o for the malloc support
env = env.Clone()
env.Append(CPPDEFINES = {'PB_ENABLE_MALLOC': 1});
# Disable libmudflap, because it will confuse valgrind
# and other memory leak detection tools.
if '-fmudflap' in env["CCFLAGS"]:
env["CCFLAGS"].remove("-fmudflap")
env["LINKFLAGS"].remove("-fmudflap")
env["LIBS"].remove("mudflap")
strict = env.Clone()
strict.Append(CFLAGS = strict['CORECFLAGS'])
strict.Object("pb_decode_with_malloc.o", "$NANOPB/pb_decode.c")
strict.Object("pb_encode_with_malloc.o", "$NANOPB/pb_encode.c")
strict.Object("pb_common_with_malloc.o", "$NANOPB/pb_common.c")
c = Copy("$TARGET", "$SOURCE")
env.Command("alltypes.proto", "#alltypes/alltypes.proto", c)
env.NanopbProto(["alltypes", "alltypes.options"])
enc = env.Program(["encode_alltypes_pointer.c", "alltypes.pb.c", "pb_encode_with_malloc.o", "pb_common_with_malloc.o"])
dec = env.Program(["decode_alltypes_pointer.c", "alltypes.pb.c", "pb_decode_with_malloc.o", "pb_common_with_malloc.o"])
# Encode and compare results to non-pointer alltypes test case
env.RunTest(enc)
env.Compare(["encode_alltypes_pointer.output", "$BUILD/alltypes/encode_alltypes.output"])
# Decode (under valgrind if available)
valgrind = env.WhereIs('valgrind')
kwargs = {}
if valgrind:
kwargs['COMMAND'] = valgrind
kwargs['ARGS'] = ["-q", dec[0].abspath]
env.RunTest("decode_alltypes.output", [dec, "encode_alltypes_pointer.output"], **kwargs)
# Do the same thing with the optional fields present
env.RunTest("optionals.output", enc, ARGS = ['1'])
env.Compare(["optionals.output", "$BUILD/alltypes/optionals.output"])
kwargs['ARGS'] = kwargs.get('ARGS', []) + ['1']
env.RunTest("optionals.decout", [dec, "optionals.output"], **kwargs)

3
tests/alltypes_pointer/alltypes.options
View File

@@ -1,3 +0,0 @@
# Generate all fields as pointers.
* type:FT_POINTER

174
tests/alltypes_pointer/decode_alltypes_pointer.c
View File

@@ -1,174 +0,0 @@
#include <stdio.h>
#include <string.h>
#include <stdlib.h>
#include <pb_decode.h>
#include "alltypes.pb.h"
#include "test_helpers.h"
#define TEST(x) if (!(x)) { \
fprintf(stderr, "Test " #x " failed.\n"); \
status = false; \
}
/* This function is called once from main(), it handles
the decoding and checks the fields. */
bool check_alltypes(pb_istream_t *stream, int mode)
{
bool status = true;
AllTypes alltypes;
/* Fill with garbage to better detect initialization errors */
memset(&alltypes, 0xAA, sizeof(alltypes));
alltypes.extensions = 0;
if (!pb_decode(stream, AllTypes_fields, &alltypes))
return false;
TEST(alltypes.req_int32 && *alltypes.req_int32 == -1001);
TEST(alltypes.req_int64 && *alltypes.req_int64 == -1002);
TEST(alltypes.req_uint32 && *alltypes.req_uint32 == 1003);
TEST(alltypes.req_uint64 && *alltypes.req_uint64 == 1004);
TEST(alltypes.req_sint32 && *alltypes.req_sint32 == -1005);
TEST(alltypes.req_sint64 && *alltypes.req_sint64 == -1006);
TEST(alltypes.req_bool && *alltypes.req_bool == true);
TEST(alltypes.req_fixed32 && *alltypes.req_fixed32 == 1008);
TEST(alltypes.req_sfixed32 && *alltypes.req_sfixed32 == -1009);
TEST(alltypes.req_float && *alltypes.req_float == 1010.0f);
TEST(alltypes.req_fixed64 && *alltypes.req_fixed64 == 1011);
TEST(alltypes.req_sfixed64 && *alltypes.req_sfixed64 == -1012);
TEST(alltypes.req_double && *alltypes.req_double == 1013.0f);
TEST(alltypes.req_string && strcmp(alltypes.req_string, "1014") == 0);
TEST(alltypes.req_bytes && alltypes.req_bytes->size == 4);
TEST(alltypes.req_bytes && memcmp(&alltypes.req_bytes->bytes, "1015", 4) == 0);
TEST(alltypes.req_submsg && alltypes.req_submsg->substuff1
&& strcmp(alltypes.req_submsg->substuff1, "1016") == 0);
TEST(alltypes.req_submsg && alltypes.req_submsg->substuff2
&& *alltypes.req_submsg->substuff2 == 1016);
TEST(*alltypes.req_enum == MyEnum_Truth);
TEST(alltypes.rep_int32_count == 5 && alltypes.rep_int32[4] == -2001 && alltypes.rep_int32[0] == 0);
TEST(alltypes.rep_int64_count == 5 && alltypes.rep_int64[4] == -2002 && alltypes.rep_int64[0] == 0);
TEST(alltypes.rep_uint32_count == 5 && alltypes.rep_uint32[4] == 2003 && alltypes.rep_uint32[0] == 0);
TEST(alltypes.rep_uint64_count == 5 && alltypes.rep_uint64[4] == 2004 && alltypes.rep_uint64[0] == 0);
TEST(alltypes.rep_sint32_count == 5 && alltypes.rep_sint32[4] == -2005 && alltypes.rep_sint32[0] == 0);
TEST(alltypes.rep_sint64_count == 5 && alltypes.rep_sint64[4] == -2006 && alltypes.rep_sint64[0] == 0);
TEST(alltypes.rep_bool_count == 5 && alltypes.rep_bool[4] == true && alltypes.rep_bool[0] == false);
TEST(alltypes.rep_fixed32_count == 5 && alltypes.rep_fixed32[4] == 2008 && alltypes.rep_fixed32[0] == 0);
TEST(alltypes.rep_sfixed32_count == 5 && alltypes.rep_sfixed32[4] == -2009 && alltypes.rep_sfixed32[0] == 0);
TEST(alltypes.rep_float_count == 5 && alltypes.rep_float[4] == 2010.0f && alltypes.rep_float[0] == 0.0f);
TEST(alltypes.rep_fixed64_count == 5 && alltypes.rep_fixed64[4] == 2011 && alltypes.rep_fixed64[0] == 0);
TEST(alltypes.rep_sfixed64_count == 5 && alltypes.rep_sfixed64[4] == -2012 && alltypes.rep_sfixed64[0] == 0);
TEST(alltypes.rep_double_count == 5 && alltypes.rep_double[4] == 2013.0 && alltypes.rep_double[0] == 0.0);
TEST(alltypes.rep_string_count == 5 && strcmp(alltypes.rep_string[4], "2014") == 0 && alltypes.rep_string[0][0] == '\0');
TEST(alltypes.rep_bytes_count == 5 && alltypes.rep_bytes[4]->size == 4 && alltypes.rep_bytes[0]->size == 0);
TEST(memcmp(&alltypes.rep_bytes[4]->bytes, "2015", 4) == 0);
TEST(alltypes.rep_submsg_count == 5);
TEST(strcmp(alltypes.rep_submsg[4].substuff1, "2016") == 0 && alltypes.rep_submsg[0].substuff1[0] == '\0');
TEST(*alltypes.rep_submsg[4].substuff2 == 2016 && *alltypes.rep_submsg[0].substuff2 == 0);
TEST(*alltypes.rep_submsg[4].substuff3 == 2016 && alltypes.rep_submsg[0].substuff3 == NULL);
TEST(alltypes.rep_enum_count == 5 && alltypes.rep_enum[4] == MyEnum_Truth && alltypes.rep_enum[0] == MyEnum_Zero);
TEST(alltypes.rep_emptymsg_count == 5);
if (mode == 0)
{
/* Expect that optional values are not present */
TEST(alltypes.opt_int32 == NULL);
TEST(alltypes.opt_int64 == NULL);
TEST(alltypes.opt_uint32 == NULL);
TEST(alltypes.opt_uint64 == NULL);
TEST(alltypes.opt_sint32 == NULL);
TEST(alltypes.opt_sint64 == NULL);
TEST(alltypes.opt_bool == NULL);
TEST(alltypes.opt_fixed32 == NULL);
TEST(alltypes.opt_sfixed32 == NULL);
TEST(alltypes.opt_float == NULL);
TEST(alltypes.opt_fixed64 == NULL);
TEST(alltypes.opt_sfixed64 == NULL);
TEST(alltypes.opt_double == NULL);
TEST(alltypes.opt_string == NULL);
TEST(alltypes.opt_bytes == NULL);
TEST(alltypes.opt_submsg == NULL);
TEST(alltypes.opt_enum == NULL);
}
else
{
/* Expect filled-in values */
TEST(alltypes.opt_int32 && *alltypes.opt_int32 == 3041);
TEST(alltypes.opt_int64 && *alltypes.opt_int64 == 3042);
TEST(alltypes.opt_uint32 && *alltypes.opt_uint32 == 3043);
TEST(alltypes.opt_uint64 && *alltypes.opt_uint64 == 3044);
TEST(alltypes.opt_sint32 && *alltypes.opt_sint32 == 3045);
TEST(alltypes.opt_sint64 && *alltypes.opt_sint64 == 3046);
TEST(alltypes.opt_bool && *alltypes.opt_bool == true);
TEST(alltypes.opt_fixed32 && *alltypes.opt_fixed32 == 3048);
TEST(alltypes.opt_sfixed32 && *alltypes.opt_sfixed32== 3049);
TEST(alltypes.opt_float && *alltypes.opt_float == 3050.0f);
TEST(alltypes.opt_fixed64 && *alltypes.opt_fixed64 == 3051);
TEST(alltypes.opt_sfixed64 && *alltypes.opt_sfixed64== 3052);
TEST(alltypes.opt_double && *alltypes.opt_double == 3053.0);
TEST(alltypes.opt_string && strcmp(alltypes.opt_string, "3054") == 0);
TEST(alltypes.opt_bytes && alltypes.opt_bytes->size == 4);
TEST(alltypes.opt_bytes && memcmp(&alltypes.opt_bytes->bytes, "3055", 4) == 0);
TEST(alltypes.opt_submsg && strcmp(alltypes.opt_submsg->substuff1, "3056") == 0);
TEST(alltypes.opt_submsg && *alltypes.opt_submsg->substuff2 == 3056);
TEST(alltypes.opt_enum && *alltypes.opt_enum == MyEnum_Truth);
TEST(alltypes.opt_emptymsg);
}
TEST(alltypes.req_limits->int32_min && *alltypes.req_limits->int32_min == INT32_MIN);
TEST(alltypes.req_limits->int32_max && *alltypes.req_limits->int32_max == INT32_MAX);
TEST(alltypes.req_limits->uint32_min && *alltypes.req_limits->uint32_min == 0);
TEST(alltypes.req_limits->uint32_max && *alltypes.req_limits->uint32_max == UINT32_MAX);
TEST(alltypes.req_limits->int64_min && *alltypes.req_limits->int64_min == INT64_MIN);
TEST(alltypes.req_limits->int64_max && *alltypes.req_limits->int64_max == INT64_MAX);
TEST(alltypes.req_limits->uint64_min && *alltypes.req_limits->uint64_min == 0);
TEST(alltypes.req_limits->uint64_max && *alltypes.req_limits->uint64_max == UINT64_MAX);
TEST(alltypes.req_limits->enum_min && *alltypes.req_limits->enum_min == HugeEnum_Negative);
TEST(alltypes.req_limits->enum_max && *alltypes.req_limits->enum_max == HugeEnum_Positive);
TEST(alltypes.end && *alltypes.end == 1099);
pb_release(AllTypes_fields, &alltypes);
return status;
}
int main(int argc, char **argv)
{
uint8_t buffer[1024];
size_t count;
pb_istream_t stream;
/* Whether to expect the optional values or the default values. */
int mode = (argc > 1) ? atoi(argv[1]) : 0;
/* Read the data into buffer */
SET_BINARY_MODE(stdin);
count = fread(buffer, 1, sizeof(buffer), stdin);
/* Construct a pb_istream_t for reading from the buffer */
stream = pb_istream_from_buffer(buffer, count);
/* Decode and verify the message */
if (!check_alltypes(&stream, mode))
{
fprintf(stderr, "Test failed: %s\n", PB_GET_ERROR(&stream));
return 1;
}
else
{
return 0;
}
}

188
tests/alltypes_pointer/encode_alltypes_pointer.c
View File

@@ -1,188 +0,0 @@
/* Attempts to test all the datatypes supported by ProtoBuf.
*/
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <pb_encode.h>
#include "alltypes.pb.h"
#include "test_helpers.h"
int main(int argc, char **argv)
{
int mode = (argc > 1) ? atoi(argv[1]) : 0;
/* Values for required fields */
int32_t req_int32 = -1001;
int64_t req_int64 = -1002;
uint32_t req_uint32 = 1003;
uint64_t req_uint64 = 1004;
int32_t req_sint32 = -1005;
int64_t req_sint64 = -1006;
bool req_bool = true;
uint32_t req_fixed32 = 1008;
int32_t req_sfixed32 = -1009;
float req_float = 1010.0f;
uint64_t req_fixed64 = 1011;
int64_t req_sfixed64 = -1012;
double req_double = 1013.0;
char* req_string = "1014";
PB_BYTES_ARRAY_T(4) req_bytes = {4, {'1', '0', '1', '5'}};
static int32_t req_substuff = 1016;
SubMessage req_submsg = {"1016", &req_substuff};
MyEnum req_enum = MyEnum_Truth;
EmptyMessage req_emptymsg = {0};
int32_t end = 1099;
/* Values for repeated fields */
int32_t rep_int32[5] = {0, 0, 0, 0, -2001};
int64_t rep_int64[5] = {0, 0, 0, 0, -2002};
uint32_t rep_uint32[5] = {0, 0, 0, 0, 2003};
uint64_t rep_uint64[5] = {0, 0, 0, 0, 2004};
int32_t rep_sint32[5] = {0, 0, 0, 0, -2005};
int64_t rep_sint64[5] = {0, 0, 0, 0, -2006};
bool rep_bool[5] = {false, false, false, false, true};
uint32_t rep_fixed32[5] = {0, 0, 0, 0, 2008};
int32_t rep_sfixed32[5] = {0, 0, 0, 0, -2009};
float rep_float[5] = {0, 0, 0, 0, 2010.0f};
uint64_t rep_fixed64[5] = {0, 0, 0, 0, 2011};
int64_t rep_sfixed64[5] = {0, 0, 0, 0, -2012};
double rep_double[5] = {0, 0, 0, 0, 2013.0f};
char* rep_string[5] = {"", "", "", "", "2014"};
static PB_BYTES_ARRAY_T(4) rep_bytes_4 = {4, {'2', '0', '1', '5'}};
pb_bytes_array_t *rep_bytes[5]= {NULL, NULL, NULL, NULL, (pb_bytes_array_t*)&rep_bytes_4};
static int32_t rep_sub2zero = 0;
static int32_t rep_substuff2 = 2016;
static uint32_t rep_substuff3 = 2016;
SubMessage rep_submsg[5] = {{"", &rep_sub2zero},
{"", &rep_sub2zero},
{"", &rep_sub2zero},
{"", &rep_sub2zero},
{"2016", &rep_substuff2, &rep_substuff3}};
MyEnum rep_enum[5] = {0, 0, 0, 0, MyEnum_Truth};
EmptyMessage rep_emptymsg[5] = {{0}, {0}, {0}, {0}, {0}};
/* Values for optional fields */
int32_t opt_int32 = 3041;
int64_t opt_int64 = 3042;
uint32_t opt_uint32 = 3043;
uint64_t opt_uint64 = 3044;
int32_t opt_sint32 = 3045;
int64_t opt_sint64 = 3046;
bool opt_bool = true;
uint32_t opt_fixed32 = 3048;
int32_t opt_sfixed32 = 3049;
float opt_float = 3050.0f;
uint64_t opt_fixed64 = 3051;
int64_t opt_sfixed64 = 3052;
double opt_double = 3053.0;
char* opt_string = "3054";
PB_BYTES_ARRAY_T(4) opt_bytes = {4, {'3', '0', '5', '5'}};
static int32_t opt_substuff = 3056;
SubMessage opt_submsg = {"3056", &opt_substuff};
MyEnum opt_enum = MyEnum_Truth;
EmptyMessage opt_emptymsg = {0};
/* Values for the Limits message. */
static int32_t int32_min = INT32_MIN;
static int32_t int32_max = INT32_MAX;
static uint32_t uint32_min = 0;
static uint32_t uint32_max = UINT32_MAX;
static int64_t int64_min = INT64_MIN;
static int64_t int64_max = INT64_MAX;
static uint64_t uint64_min = 0;
static uint64_t uint64_max = UINT64_MAX;
static HugeEnum enum_min = HugeEnum_Negative;
static HugeEnum enum_max = HugeEnum_Positive;
Limits req_limits = {&int32_min, &int32_max,
&uint32_min, &uint32_max,
&int64_min, &int64_max,
&uint64_min, &uint64_max,
&enum_min, &enum_max};
/* Initialize the message struct with pointers to the fields. */
AllTypes alltypes = {0};
alltypes.req_int32 = &req_int32;
alltypes.req_int64 = &req_int64;
alltypes.req_uint32 = &req_uint32;
alltypes.req_uint64 = &req_uint64;
alltypes.req_sint32 = &req_sint32;
alltypes.req_sint64 = &req_sint64;
alltypes.req_bool = &req_bool;
alltypes.req_fixed32 = &req_fixed32;
alltypes.req_sfixed32 = &req_sfixed32;
alltypes.req_float = &req_float;
alltypes.req_fixed64 = &req_fixed64;
alltypes.req_sfixed64 = &req_sfixed64;
alltypes.req_double = &req_double;
alltypes.req_string = req_string;
alltypes.req_bytes = (pb_bytes_array_t*)&req_bytes;
alltypes.req_submsg = &req_submsg;
alltypes.req_enum = &req_enum;
alltypes.req_emptymsg = &req_emptymsg;
alltypes.req_limits = &req_limits;
alltypes.rep_int32_count = 5; alltypes.rep_int32 = rep_int32;
alltypes.rep_int64_count = 5; alltypes.rep_int64 = rep_int64;
alltypes.rep_uint32_count = 5; alltypes.rep_uint32 = rep_uint32;
alltypes.rep_uint64_count = 5; alltypes.rep_uint64 = rep_uint64;
alltypes.rep_sint32_count = 5; alltypes.rep_sint32 = rep_sint32;
alltypes.rep_sint64_count = 5; alltypes.rep_sint64 = rep_sint64;
alltypes.rep_bool_count = 5; alltypes.rep_bool = rep_bool;
alltypes.rep_fixed32_count = 5; alltypes.rep_fixed32 = rep_fixed32;
alltypes.rep_sfixed32_count = 5; alltypes.rep_sfixed32 = rep_sfixed32;
alltypes.rep_float_count = 5; alltypes.rep_float = rep_float;
alltypes.rep_fixed64_count = 5; alltypes.rep_fixed64 = rep_fixed64;
alltypes.rep_sfixed64_count = 5; alltypes.rep_sfixed64 = rep_sfixed64;
alltypes.rep_double_count = 5; alltypes.rep_double = rep_double;
alltypes.rep_string_count = 5; alltypes.rep_string = rep_string;
alltypes.rep_bytes_count = 5; alltypes.rep_bytes = rep_bytes;
alltypes.rep_submsg_count = 5; alltypes.rep_submsg = rep_submsg;
alltypes.rep_enum_count = 5; alltypes.rep_enum = rep_enum;
alltypes.rep_emptymsg_count = 5; alltypes.rep_emptymsg = rep_emptymsg;
if (mode != 0)
{
/* Fill in values for optional fields */
alltypes.opt_int32 = &opt_int32;
alltypes.opt_int64 = &opt_int64;
alltypes.opt_uint32 = &opt_uint32;
alltypes.opt_uint64 = &opt_uint64;
alltypes.opt_sint32 = &opt_sint32;
alltypes.opt_sint64 = &opt_sint64;
alltypes.opt_bool = &opt_bool;
alltypes.opt_fixed32 = &opt_fixed32;
alltypes.opt_sfixed32 = &opt_sfixed32;
alltypes.opt_float = &opt_float;
alltypes.opt_fixed64 = &opt_fixed64;
alltypes.opt_sfixed64 = &opt_sfixed64;
alltypes.opt_double = &opt_double;
alltypes.opt_string = opt_string;
alltypes.opt_bytes = (pb_bytes_array_t*)&opt_bytes;
alltypes.opt_submsg = &opt_submsg;
alltypes.opt_enum = &opt_enum;
alltypes.opt_emptymsg = &opt_emptymsg;
}
alltypes.end = &end;
{
uint8_t buffer[4096];
pb_ostream_t stream = pb_ostream_from_buffer(buffer, sizeof(buffer));
/* Now encode it and check if we succeeded. */
if (pb_encode(&stream, AllTypes_fields, &alltypes))
{
SET_BINARY_MODE(stdout);
fwrite(buffer, 1, stream.bytes_written, stdout);
return 0; /* Success */
}
else
{
fprintf(stderr, "Encoding failed: %s\n", PB_GET_ERROR(&stream));
return 1; /* Failure */
}
}
}

11
tests/backwards_compatibility/SConscript
View File

@@ -1,11 +0,0 @@
# Check that the old generated .pb.c/.pb.h files are still compatible with the
# current version of nanopb.
Import("env")
enc = env.Program(["encode_legacy.c", "alltypes_legacy.c", "$COMMON/pb_encode.o", "$COMMON/pb_common.o"])
dec = env.Program(["decode_legacy.c", "alltypes_legacy.c", "$COMMON/pb_decode.o", "$COMMON/pb_common.o"])
env.RunTest(enc)
env.RunTest([dec, "encode_legacy.output"])

153
tests/backwards_compatibility/alltypes_legacy.c
View File

@@ -1,153 +0,0 @@
/* Automatically generated nanopb constant definitions */
/* Generated by nanopb-0.3.0-dev at Tue Aug 19 17:53:24 2014. */
#include "alltypes_legacy.h"
#if PB_PROTO_HEADER_VERSION != 30
#error Regenerate this file with the current version of nanopb generator.
#endif
const char SubMessage_substuff1_default[16] = "1";
const int32_t SubMessage_substuff2_default = 2;
const uint32_t SubMessage_substuff3_default = 3u;
const int32_t Limits_int32_min_default = 2147483647;
const int32_t Limits_int32_max_default = -2147483647;
const uint32_t Limits_uint32_min_default = 4294967295u;
const uint32_t Limits_uint32_max_default = 0u;
const int64_t Limits_int64_min_default = 9223372036854775807ll;
const int64_t Limits_int64_max_default = -9223372036854775807ll;
const uint64_t Limits_uint64_min_default = 18446744073709551615ull;
const uint64_t Limits_uint64_max_default = 0ull;
const HugeEnum Limits_enum_min_default = HugeEnum_Positive;
const HugeEnum Limits_enum_max_default = HugeEnum_Negative;
const int32_t AllTypes_opt_int32_default = 4041;
const int64_t AllTypes_opt_int64_default = 4042ll;
const uint32_t AllTypes_opt_uint32_default = 4043u;
const uint64_t AllTypes_opt_uint64_default = 4044ull;
const int32_t AllTypes_opt_sint32_default = 4045;
const int64_t AllTypes_opt_sint64_default = 4046;
const bool AllTypes_opt_bool_default = false;
const uint32_t AllTypes_opt_fixed32_default = 4048u;
const int32_t AllTypes_opt_sfixed32_default = 4049;
const float AllTypes_opt_float_default = 4050;
const uint64_t AllTypes_opt_fixed64_default = 4051ull;
const int64_t AllTypes_opt_sfixed64_default = 4052ll;
const double AllTypes_opt_double_default = 4053;
const char AllTypes_opt_string_default[16] = "4054";
const AllTypes_opt_bytes_t AllTypes_opt_bytes_default = {4, {0x34,0x30,0x35,0x35}};
const MyEnum AllTypes_opt_enum_default = MyEnum_Second;
const pb_field_t SubMessage_fields[4] = {
PB_FIELD( 1, STRING , REQUIRED, STATIC , FIRST, SubMessage, substuff1, substuff1, &SubMessage_substuff1_default),
PB_FIELD( 2, INT32 , REQUIRED, STATIC , OTHER, SubMessage, substuff2, substuff1, &SubMessage_substuff2_default),
PB_FIELD( 3, FIXED32 , OPTIONAL, STATIC , OTHER, SubMessage, substuff3, substuff2, &SubMessage_substuff3_default),
PB_LAST_FIELD
};
const pb_field_t EmptyMessage_fields[1] = {
PB_LAST_FIELD
};
const pb_field_t Limits_fields[11] = {
PB_FIELD( 1, INT32 , REQUIRED, STATIC , FIRST, Limits, int32_min, int32_min, &Limits_int32_min_default),
PB_FIELD( 2, INT32 , REQUIRED, STATIC , OTHER, Limits, int32_max, int32_min, &Limits_int32_max_default),
PB_FIELD( 3, UINT32 , REQUIRED, STATIC , OTHER, Limits, uint32_min, int32_max, &Limits_uint32_min_default),
PB_FIELD( 4, UINT32 , REQUIRED, STATIC , OTHER, Limits, uint32_max, uint32_min, &Limits_uint32_max_default),
PB_FIELD( 5, INT64 , REQUIRED, STATIC , OTHER, Limits, int64_min, uint32_max, &Limits_int64_min_default),
PB_FIELD( 6, INT64 , REQUIRED, STATIC , OTHER, Limits, int64_max, int64_min, &Limits_int64_max_default),
PB_FIELD( 7, UINT64 , REQUIRED, STATIC , OTHER, Limits, uint64_min, int64_max, &Limits_uint64_min_default),
PB_FIELD( 8, UINT64 , REQUIRED, STATIC , OTHER, Limits, uint64_max, uint64_min, &Limits_uint64_max_default),
PB_FIELD( 9, ENUM , REQUIRED, STATIC , OTHER, Limits, enum_min, uint64_max, &Limits_enum_min_default),
PB_FIELD( 10, ENUM , REQUIRED, STATIC , OTHER, Limits, enum_max, enum_min, &Limits_enum_max_default),
PB_LAST_FIELD
};
const pb_field_t AllTypes_fields[54] = {
PB_FIELD( 1, INT32 , REQUIRED, STATIC , FIRST, AllTypes, req_int32, req_int32, 0),
PB_FIELD( 2, INT64 , REQUIRED, STATIC , OTHER, AllTypes, req_int64, req_int32, 0),
PB_FIELD( 3, UINT32 , REQUIRED, STATIC , OTHER, AllTypes, req_uint32, req_int64, 0),
PB_FIELD( 4, UINT64 , REQUIRED, STATIC , OTHER, AllTypes, req_uint64, req_uint32, 0),
PB_FIELD( 5, SINT32 , REQUIRED, STATIC , OTHER, AllTypes, req_sint32, req_uint64, 0),
PB_FIELD( 6, SINT64 , REQUIRED, STATIC , OTHER, AllTypes, req_sint64, req_sint32, 0),
PB_FIELD( 7, BOOL , REQUIRED, STATIC , OTHER, AllTypes, req_bool, req_sint64, 0),
PB_FIELD( 8, FIXED32 , REQUIRED, STATIC , OTHER, AllTypes, req_fixed32, req_bool, 0),
PB_FIELD( 9, SFIXED32, REQUIRED, STATIC , OTHER, AllTypes, req_sfixed32, req_fixed32, 0),
PB_FIELD( 10, FLOAT , REQUIRED, STATIC , OTHER, AllTypes, req_float, req_sfixed32, 0),
PB_FIELD( 11, FIXED64 , REQUIRED, STATIC , OTHER, AllTypes, req_fixed64, req_float, 0),
PB_FIELD( 12, SFIXED64, REQUIRED, STATIC , OTHER, AllTypes, req_sfixed64, req_fixed64, 0),
PB_FIELD( 13, DOUBLE , REQUIRED, STATIC , OTHER, AllTypes, req_double, req_sfixed64, 0),
PB_FIELD( 14, STRING , REQUIRED, STATIC , OTHER, AllTypes, req_string, req_double, 0),
PB_FIELD( 15, BYTES , REQUIRED, STATIC , OTHER, AllTypes, req_bytes, req_string, 0),
PB_FIELD( 16, MESSAGE , REQUIRED, STATIC , OTHER, AllTypes, req_submsg, req_bytes, &SubMessage_fields),
PB_FIELD( 17, ENUM , REQUIRED, STATIC , OTHER, AllTypes, req_enum, req_submsg, 0),
PB_FIELD( 21, INT32 , REPEATED, STATIC , OTHER, AllTypes, rep_int32, req_enum, 0),
PB_FIELD( 22, INT64 , REPEATED, STATIC , OTHER, AllTypes, rep_int64, rep_int32, 0),
PB_FIELD( 23, UINT32 , REPEATED, STATIC , OTHER, AllTypes, rep_uint32, rep_int64, 0),
PB_FIELD( 24, UINT64 , REPEATED, STATIC , OTHER, AllTypes, rep_uint64, rep_uint32, 0),
PB_FIELD( 25, SINT32 , REPEATED, STATIC , OTHER, AllTypes, rep_sint32, rep_uint64, 0),
PB_FIELD( 26, SINT64 , REPEATED, STATIC , OTHER, AllTypes, rep_sint64, rep_sint32, 0),
PB_FIELD( 27, BOOL , REPEATED, STATIC , OTHER, AllTypes, rep_bool, rep_sint64, 0),
PB_FIELD( 28, FIXED32 , REPEATED, STATIC , OTHER, AllTypes, rep_fixed32, rep_bool, 0),
PB_FIELD( 29, SFIXED32, REPEATED, STATIC , OTHER, AllTypes, rep_sfixed32, rep_fixed32, 0),
PB_FIELD( 30, FLOAT , REPEATED, STATIC , OTHER, AllTypes, rep_float, rep_sfixed32, 0),
PB_FIELD( 31, FIXED64 , REPEATED, STATIC , OTHER, AllTypes, rep_fixed64, rep_float, 0),
PB_FIELD( 32, SFIXED64, REPEATED, STATIC , OTHER, AllTypes, rep_sfixed64, rep_fixed64, 0),
PB_FIELD( 33, DOUBLE , REPEATED, STATIC , OTHER, AllTypes, rep_double, rep_sfixed64, 0),
PB_FIELD( 34, STRING , REPEATED, STATIC , OTHER, AllTypes, rep_string, rep_double, 0),
PB_FIELD( 35, BYTES , REPEATED, STATIC , OTHER, AllTypes, rep_bytes, rep_string, 0),
PB_FIELD( 36, MESSAGE , REPEATED, STATIC , OTHER, AllTypes, rep_submsg, rep_bytes, &SubMessage_fields),
PB_FIELD( 37, ENUM , REPEATED, STATIC , OTHER, AllTypes, rep_enum, rep_submsg, 0),
PB_FIELD( 41, INT32 , OPTIONAL, STATIC , OTHER, AllTypes, opt_int32, rep_enum, &AllTypes_opt_int32_default),
PB_FIELD( 42, INT64 , OPTIONAL, STATIC , OTHER, AllTypes, opt_int64, opt_int32, &AllTypes_opt_int64_default),
PB_FIELD( 43, UINT32 , OPTIONAL, STATIC , OTHER, AllTypes, opt_uint32, opt_int64, &AllTypes_opt_uint32_default),
PB_FIELD( 44, UINT64 , OPTIONAL, STATIC , OTHER, AllTypes, opt_uint64, opt_uint32, &AllTypes_opt_uint64_default),
PB_FIELD( 45, SINT32 , OPTIONAL, STATIC , OTHER, AllTypes, opt_sint32, opt_uint64, &AllTypes_opt_sint32_default),
PB_FIELD( 46, SINT64 , OPTIONAL, STATIC , OTHER, AllTypes, opt_sint64, opt_sint32, &AllTypes_opt_sint64_default),
PB_FIELD( 47, BOOL , OPTIONAL, STATIC , OTHER, AllTypes, opt_bool, opt_sint64, &AllTypes_opt_bool_default),
PB_FIELD( 48, FIXED32 , OPTIONAL, STATIC , OTHER, AllTypes, opt_fixed32, opt_bool, &AllTypes_opt_fixed32_default),
PB_FIELD( 49, SFIXED32, OPTIONAL, STATIC , OTHER, AllTypes, opt_sfixed32, opt_fixed32, &AllTypes_opt_sfixed32_default),
PB_FIELD( 50, FLOAT , OPTIONAL, STATIC , OTHER, AllTypes, opt_float, opt_sfixed32, &AllTypes_opt_float_default),
PB_FIELD( 51, FIXED64 , OPTIONAL, STATIC , OTHER, AllTypes, opt_fixed64, opt_float, &AllTypes_opt_fixed64_default),
PB_FIELD( 52, SFIXED64, OPTIONAL, STATIC , OTHER, AllTypes, opt_sfixed64, opt_fixed64, &AllTypes_opt_sfixed64_default),
PB_FIELD( 53, DOUBLE , OPTIONAL, STATIC , OTHER, AllTypes, opt_double, opt_sfixed64, &AllTypes_opt_double_default),
PB_FIELD( 54, STRING , OPTIONAL, STATIC , OTHER, AllTypes, opt_string, opt_double, &AllTypes_opt_string_default),
PB_FIELD( 55, BYTES , OPTIONAL, STATIC , OTHER, AllTypes, opt_bytes, opt_string, &AllTypes_opt_bytes_default),
PB_FIELD( 56, MESSAGE , OPTIONAL, STATIC , OTHER, AllTypes, opt_submsg, opt_bytes, &SubMessage_fields),
PB_FIELD( 57, ENUM , OPTIONAL, STATIC , OTHER, AllTypes, opt_enum, opt_submsg, &AllTypes_opt_enum_default),
PB_FIELD( 99, INT32 , REQUIRED, STATIC , OTHER, AllTypes, end, opt_enum, 0),
PB_FIELD(200, EXTENSION, OPTIONAL, CALLBACK, OTHER, AllTypes, extensions, end, 0),
PB_LAST_FIELD
};
/* Check that field information fits in pb_field_t */
#if !defined(PB_FIELD_32BIT)
/* If you get an error here, it means that you need to define PB_FIELD_32BIT
* compile-time option. You can do that in pb.h or on compiler command line.
*
* The reason you need to do this is that some of your messages contain tag
* numbers or field sizes that are larger than what can fit in 8 or 16 bit
* field descriptors.
*/
PB_STATIC_ASSERT((pb_membersize(AllTypes, req_submsg) < 65536 && pb_membersize(AllTypes, rep_submsg[0]) < 65536 && pb_membersize(AllTypes, opt_submsg) < 65536), YOU_MUST_DEFINE_PB_FIELD_32BIT_FOR_MESSAGES_SubMessage_EmptyMessage_Limits_AllTypes)
#endif
#if !defined(PB_FIELD_16BIT) && !defined(PB_FIELD_32BIT)
/* If you get an error here, it means that you need to define PB_FIELD_16BIT
* compile-time option. You can do that in pb.h or on compiler command line.
*
* The reason you need to do this is that some of your messages contain tag
* numbers or field sizes that are larger than what can fit in the default
* 8 bit descriptors.
*/
PB_STATIC_ASSERT((pb_membersize(AllTypes, req_submsg) < 256 && pb_membersize(AllTypes, rep_submsg[0]) < 256 && pb_membersize(AllTypes, opt_submsg) < 256), YOU_MUST_DEFINE_PB_FIELD_16BIT_FOR_MESSAGES_SubMessage_EmptyMessage_Limits_AllTypes)
#endif
/* On some platforms (such as AVR), double is really float.
* These are not directly supported by nanopb, but see example_avr_double.
* To get rid of this error, remove any double fields from your .proto.
*/
PB_STATIC_ASSERT(sizeof(double) == 8, DOUBLE_MUST_BE_8_BYTES)

274
tests/backwards_compatibility/alltypes_legacy.h
View File

@@ -1,274 +0,0 @@
/* Automatically generated nanopb header */
/* Generated by nanopb-0.3.0-dev at Tue Aug 19 17:53:24 2014. */
#ifndef PB_ALLTYPES_LEGACY_H_INCLUDED
#define PB_ALLTYPES_LEGACY_H_INCLUDED
#include <pb.h>
#if PB_PROTO_HEADER_VERSION != 30
#error Regenerate this file with the current version of nanopb generator.
#endif
#ifdef __cplusplus
extern "C" {
#endif
/* Enum definitions */
typedef enum _HugeEnum {
HugeEnum_Negative = -2147483647,
HugeEnum_Positive = 2147483647
} HugeEnum;
typedef enum _MyEnum {
MyEnum_Zero = 0,
MyEnum_First = 1,
MyEnum_Second = 2,
MyEnum_Truth = 42
} MyEnum;
/* Struct definitions */
typedef struct _EmptyMessage {
uint8_t dummy_field;
} EmptyMessage;
typedef struct _Limits {
int32_t int32_min;
int32_t int32_max;
uint32_t uint32_min;
uint32_t uint32_max;
int64_t int64_min;
int64_t int64_max;
uint64_t uint64_min;
uint64_t uint64_max;
HugeEnum enum_min;
HugeEnum enum_max;
} Limits;
typedef struct _SubMessage {
char substuff1[16];
int32_t substuff2;
bool has_substuff3;
uint32_t substuff3;
} SubMessage;
typedef PB_BYTES_ARRAY_T(16) AllTypes_req_bytes_t;
typedef PB_BYTES_ARRAY_T(16) AllTypes_rep_bytes_t;
typedef PB_BYTES_ARRAY_T(16) AllTypes_opt_bytes_t;
typedef struct _AllTypes {
int32_t req_int32;
int64_t req_int64;
uint32_t req_uint32;
uint64_t req_uint64;
int32_t req_sint32;
int64_t req_sint64;
bool req_bool;
uint32_t req_fixed32;
int32_t req_sfixed32;
float req_float;
uint64_t req_fixed64;
int64_t req_sfixed64;
double req_double;
char req_string[16];
AllTypes_req_bytes_t req_bytes;
SubMessage req_submsg;
MyEnum req_enum;
pb_size_t rep_int32_count;
int32_t rep_int32[5];
pb_size_t rep_int64_count;
int64_t rep_int64[5];
pb_size_t rep_uint32_count;
uint32_t rep_uint32[5];
pb_size_t rep_uint64_count;
uint64_t rep_uint64[5];
pb_size_t rep_sint32_count;
int32_t rep_sint32[5];
pb_size_t rep_sint64_count;
int64_t rep_sint64[5];
pb_size_t rep_bool_count;
bool rep_bool[5];
pb_size_t rep_fixed32_count;
uint32_t rep_fixed32[5];
pb_size_t rep_sfixed32_count;
int32_t rep_sfixed32[5];
pb_size_t rep_float_count;
float rep_float[5];
pb_size_t rep_fixed64_count;
uint64_t rep_fixed64[5];
pb_size_t rep_sfixed64_count;
int64_t rep_sfixed64[5];
pb_size_t rep_double_count;
double rep_double[5];
pb_size_t rep_string_count;
char rep_string[5][16];
pb_size_t rep_bytes_count;
AllTypes_rep_bytes_t rep_bytes[5];
pb_size_t rep_submsg_count;
SubMessage rep_submsg[5];
pb_size_t rep_enum_count;
MyEnum rep_enum[5];
bool has_opt_int32;
int32_t opt_int32;
bool has_opt_int64;
int64_t opt_int64;
bool has_opt_uint32;
uint32_t opt_uint32;
bool has_opt_uint64;
uint64_t opt_uint64;
bool has_opt_sint32;
int32_t opt_sint32;
bool has_opt_sint64;
int64_t opt_sint64;
bool has_opt_bool;
bool opt_bool;
bool has_opt_fixed32;
uint32_t opt_fixed32;
bool has_opt_sfixed32;
int32_t opt_sfixed32;
bool has_opt_float;
float opt_float;
bool has_opt_fixed64;
uint64_t opt_fixed64;
bool has_opt_sfixed64;
int64_t opt_sfixed64;
bool has_opt_double;
double opt_double;
bool has_opt_string;
char opt_string[16];
bool has_opt_bytes;
AllTypes_opt_bytes_t opt_bytes;
bool has_opt_submsg;
SubMessage opt_submsg;
bool has_opt_enum;
MyEnum opt_enum;
int32_t end;
pb_extension_t *extensions;
} AllTypes;
/* Default values for struct fields */
extern const char SubMessage_substuff1_default[16];
extern const int32_t SubMessage_substuff2_default;
extern const uint32_t SubMessage_substuff3_default;
extern const int32_t Limits_int32_min_default;
extern const int32_t Limits_int32_max_default;
extern const uint32_t Limits_uint32_min_default;
extern const uint32_t Limits_uint32_max_default;
extern const int64_t Limits_int64_min_default;
extern const int64_t Limits_int64_max_default;
extern const uint64_t Limits_uint64_min_default;
extern const uint64_t Limits_uint64_max_default;
extern const HugeEnum Limits_enum_min_default;
extern const HugeEnum Limits_enum_max_default;
extern const int32_t AllTypes_opt_int32_default;
extern const int64_t AllTypes_opt_int64_default;
extern const uint32_t AllTypes_opt_uint32_default;
extern const uint64_t AllTypes_opt_uint64_default;
extern const int32_t AllTypes_opt_sint32_default;
extern const int64_t AllTypes_opt_sint64_default;
extern const bool AllTypes_opt_bool_default;
extern const uint32_t AllTypes_opt_fixed32_default;
extern const int32_t AllTypes_opt_sfixed32_default;
extern const float AllTypes_opt_float_default;
extern const uint64_t AllTypes_opt_fixed64_default;
extern const int64_t AllTypes_opt_sfixed64_default;
extern const double AllTypes_opt_double_default;
extern const char AllTypes_opt_string_default[16];
extern const AllTypes_opt_bytes_t AllTypes_opt_bytes_default;
extern const MyEnum AllTypes_opt_enum_default;
/* Initializer values for message structs */
#define SubMessage_init_default {"1", 2, false, 3u}
#define EmptyMessage_init_default {0}
#define Limits_init_default {2147483647, -2147483647, 4294967295u, 0u, 9223372036854775807ll, -9223372036854775807ll, 18446744073709551615ull, 0ull, HugeEnum_Positive, HugeEnum_Negative}
#define AllTypes_init_default {0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, "", {0, {0}}, SubMessage_init_default, (MyEnum)0, 0, {0, 0, 0, 0, 0}, 0, {0, 0, 0, 0, 0}, 0, {0, 0, 0, 0, 0}, 0, {0, 0, 0, 0, 0}, 0, {0, 0, 0, 0, 0}, 0, {0, 0, 0, 0, 0}, 0, {0, 0, 0, 0, 0}, 0, {0, 0, 0, 0, 0}, 0, {0, 0, 0, 0, 0}, 0, {0, 0, 0, 0, 0}, 0, {0, 0, 0, 0, 0}, 0, {0, 0, 0, 0, 0}, 0, {0, 0, 0, 0, 0}, 0, {"", "", "", "", ""}, 0, {{0, {0}}, {0, {0}}, {0, {0}}, {0, {0}}, {0, {0}}}, 0, {SubMessage_init_default, SubMessage_init_default, SubMessage_init_default, SubMessage_init_default, SubMessage_init_default}, 0, {(MyEnum)0, (MyEnum)0, (MyEnum)0, (MyEnum)0, (MyEnum)0}, false, 4041, false, 4042ll, false, 4043u, false, 4044ull, false, 4045, false, 4046, false, false, false, 4048u, false, 4049, false, 4050, false, 4051ull, false, 4052ll, false, 4053, false, "4054", false, {4, {0x34,0x30,0x35,0x35}}, false, SubMessage_init_default, false, MyEnum_Second, 0, NULL}
#define SubMessage_init_zero {"", 0, false, 0}
#define EmptyMessage_init_zero {0}
#define Limits_init_zero {0, 0, 0, 0, 0, 0, 0, 0, (HugeEnum)0, (HugeEnum)0}
#define AllTypes_init_zero {0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, "", {0, {0}}, SubMessage_init_zero, (MyEnum)0, 0, {0, 0, 0, 0, 0}, 0, {0, 0, 0, 0, 0}, 0, {0, 0, 0, 0, 0}, 0, {0, 0, 0, 0, 0}, 0, {0, 0, 0, 0, 0}, 0, {0, 0, 0, 0, 0}, 0, {0, 0, 0, 0, 0}, 0, {0, 0, 0, 0, 0}, 0, {0, 0, 0, 0, 0}, 0, {0, 0, 0, 0, 0}, 0, {0, 0, 0, 0, 0}, 0, {0, 0, 0, 0, 0}, 0, {0, 0, 0, 0, 0}, 0, {"", "", "", "", ""}, 0, {{0, {0}}, {0, {0}}, {0, {0}}, {0, {0}}, {0, {0}}}, 0, {SubMessage_init_zero, SubMessage_init_zero, SubMessage_init_zero, SubMessage_init_zero, SubMessage_init_zero}, 0, {(MyEnum)0, (MyEnum)0, (MyEnum)0, (MyEnum)0, (MyEnum)0}, false, 0, false, 0, false, 0, false, 0, false, 0, false, 0, false, 0, false, 0, false, 0, false, 0, false, 0, false, 0, false, 0, false, "", false, {0, {0}}, false, SubMessage_init_zero, false, (MyEnum)0, 0, NULL}
/* Field tags (for use in manual encoding/decoding) */
#define Limits_int32_min_tag 1
#define Limits_int32_max_tag 2
#define Limits_uint32_min_tag 3
#define Limits_uint32_max_tag 4
#define Limits_int64_min_tag 5
#define Limits_int64_max_tag 6
#define Limits_uint64_min_tag 7
#define Limits_uint64_max_tag 8
#define Limits_enum_min_tag 9
#define Limits_enum_max_tag 10
#define SubMessage_substuff1_tag 1
#define SubMessage_substuff2_tag 2
#define SubMessage_substuff3_tag 3
#define AllTypes_req_int32_tag 1
#define AllTypes_req_int64_tag 2
#define AllTypes_req_uint32_tag 3
#define AllTypes_req_uint64_tag 4
#define AllTypes_req_sint32_tag 5
#define AllTypes_req_sint64_tag 6
#define AllTypes_req_bool_tag 7
#define AllTypes_req_fixed32_tag 8
#define AllTypes_req_sfixed32_tag 9
#define AllTypes_req_float_tag 10
#define AllTypes_req_fixed64_tag 11
#define AllTypes_req_sfixed64_tag 12
#define AllTypes_req_double_tag 13
#define AllTypes_req_string_tag 14
#define AllTypes_req_bytes_tag 15
#define AllTypes_req_submsg_tag 16
#define AllTypes_req_enum_tag 17
#define AllTypes_rep_int32_tag 21
#define AllTypes_rep_int64_tag 22
#define AllTypes_rep_uint32_tag 23
#define AllTypes_rep_uint64_tag 24
#define AllTypes_rep_sint32_tag 25
#define AllTypes_rep_sint64_tag 26
#define AllTypes_rep_bool_tag 27
#define AllTypes_rep_fixed32_tag 28
#define AllTypes_rep_sfixed32_tag 29
#define AllTypes_rep_float_tag 30
#define AllTypes_rep_fixed64_tag 31
#define AllTypes_rep_sfixed64_tag 32
#define AllTypes_rep_double_tag 33
#define AllTypes_rep_string_tag 34
#define AllTypes_rep_bytes_tag 35
#define AllTypes_rep_submsg_tag 36
#define AllTypes_rep_enum_tag 37
#define AllTypes_opt_int32_tag 41
#define AllTypes_opt_int64_tag 42
#define AllTypes_opt_uint32_tag 43
#define AllTypes_opt_uint64_tag 44
#define AllTypes_opt_sint32_tag 45
#define AllTypes_opt_sint64_tag 46
#define AllTypes_opt_bool_tag 47
#define AllTypes_opt_fixed32_tag 48
#define AllTypes_opt_sfixed32_tag 49
#define AllTypes_opt_float_tag 50
#define AllTypes_opt_fixed64_tag 51
#define AllTypes_opt_sfixed64_tag 52
#define AllTypes_opt_double_tag 53
#define AllTypes_opt_string_tag 54
#define AllTypes_opt_bytes_tag 55
#define AllTypes_opt_submsg_tag 56
#define AllTypes_opt_enum_tag 57
#define AllTypes_end_tag 99
/* Struct field encoding specification for nanopb */
extern const pb_field_t SubMessage_fields[4];
extern const pb_field_t EmptyMessage_fields[1];
extern const pb_field_t Limits_fields[11];
extern const pb_field_t AllTypes_fields[54];
/* Maximum encoded size of messages (where known) */
#define SubMessage_size 34
#define EmptyMessage_size 0
#define Limits_size 90
#define AllTypes_size 1362
#ifdef __cplusplus
} /* extern "C" */
#endif
#endif

3
tests/backwards_compatibility/alltypes_legacy.options
View File

@@ -1,3 +0,0 @@
* max_size:16
* max_count:5

108
tests/backwards_compatibility/alltypes_legacy.proto
View File

@@ -1,108 +0,0 @@
message SubMessage {
required string substuff1 = 1 [default = "1"];
required int32 substuff2 = 2 [default = 2];
optional fixed32 substuff3 = 3 [default = 3];
}
message EmptyMessage {
}
enum HugeEnum {
Negative = -2147483647; /* protoc doesn't accept -2147483648 here */
Positive = 2147483647;
}
message Limits {
required int32 int32_min = 1 [default = 2147483647];
required int32 int32_max = 2 [default = -2147483647];
required uint32 uint32_min = 3 [default = 4294967295];
required uint32 uint32_max = 4 [default = 0];
required int64 int64_min = 5 [default = 9223372036854775807];
required int64 int64_max = 6 [default = -9223372036854775807];
required uint64 uint64_min = 7 [default = 18446744073709551615];
required uint64 uint64_max = 8 [default = 0];
required HugeEnum enum_min = 9 [default = Positive];
required HugeEnum enum_max = 10 [default = Negative];
}
enum MyEnum {
Zero = 0;
First = 1;
Second = 2;
Truth = 42;
}
message AllTypes {
required int32 req_int32 = 1;
required int64 req_int64 = 2;
required uint32 req_uint32 = 3;
required uint64 req_uint64 = 4;
required sint32 req_sint32 = 5;
required sint64 req_sint64 = 6;
required bool req_bool = 7;
required fixed32 req_fixed32 = 8;
required sfixed32 req_sfixed32= 9;
required float req_float = 10;
required fixed64 req_fixed64 = 11;
required sfixed64 req_sfixed64= 12;
required double req_double = 13;
required string req_string = 14;
required bytes req_bytes = 15;
required SubMessage req_submsg = 16;
required MyEnum req_enum = 17;
repeated int32 rep_int32 = 21 [packed = true];
repeated int64 rep_int64 = 22 [packed = true];
repeated uint32 rep_uint32 = 23 [packed = true];
repeated uint64 rep_uint64 = 24 [packed = true];
repeated sint32 rep_sint32 = 25 [packed = true];
repeated sint64 rep_sint64 = 26 [packed = true];
repeated bool rep_bool = 27 [packed = true];
repeated fixed32 rep_fixed32 = 28 [packed = true];
repeated sfixed32 rep_sfixed32= 29 [packed = true];
repeated float rep_float = 30 [packed = true];
repeated fixed64 rep_fixed64 = 31 [packed = true];
repeated sfixed64 rep_sfixed64= 32 [packed = true];
repeated double rep_double = 33 [packed = true];
repeated string rep_string = 34;
repeated bytes rep_bytes = 35;
repeated SubMessage rep_submsg = 36;
repeated MyEnum rep_enum = 37 [packed = true];
optional int32 opt_int32 = 41 [default = 4041];
optional int64 opt_int64 = 42 [default = 4042];
optional uint32 opt_uint32 = 43 [default = 4043];
optional uint64 opt_uint64 = 44 [default = 4044];
optional sint32 opt_sint32 = 45 [default = 4045];
optional sint64 opt_sint64 = 46 [default = 4046];
optional bool opt_bool = 47 [default = false];
optional fixed32 opt_fixed32 = 48 [default = 4048];
optional sfixed32 opt_sfixed32= 49 [default = 4049];
optional float opt_float = 50 [default = 4050];
optional fixed64 opt_fixed64 = 51 [default = 4051];
optional sfixed64 opt_sfixed64= 52 [default = 4052];
optional double opt_double = 53 [default = 4053];
optional string opt_string = 54 [default = "4054"];
optional bytes opt_bytes = 55 [default = "4055"];
optional SubMessage opt_submsg = 56;
optional MyEnum opt_enum = 57 [default = Second];
// Just to make sure that the size of the fields has been calculated
// properly, i.e. otherwise a bug in last field might not be detected.
required int32 end = 99;
extensions 200 to 255;
}

202
tests/backwards_compatibility/decode_legacy.c
View File

@@ -1,202 +0,0 @@
/* Tests the decoding of all types.
* This is a backwards-compatibility test, using alltypes_legacy.h.
* It is similar to decode_alltypes, but duplicated in order to allow
* decode_alltypes to test any new features introduced later.
*
* Run e.g. ./encode_legacy | ./decode_legacy
*/
#include <stdio.h>
#include <string.h>
#include <stdlib.h>
#include <pb_decode.h>
#include "alltypes_legacy.h"
#include "test_helpers.h"
#define TEST(x) if (!(x)) { \
printf("Test " #x " failed.\n"); \
return false; \
}
/* This function is called once from main(), it handles
the decoding and checks the fields. */
bool check_alltypes(pb_istream_t *stream, int mode)
{
AllTypes alltypes;
/* Fill with garbage to better detect initialization errors */
memset(&alltypes, 0xAA, sizeof(alltypes));
if (!pb_decode(stream, AllTypes_fields, &alltypes))
return false;
TEST(alltypes.req_int32 == -1001);
TEST(alltypes.req_int64 == -1002);
TEST(alltypes.req_uint32 == 1003);
TEST(alltypes.req_uint64 == 1004);
TEST(alltypes.req_sint32 == -1005);
TEST(alltypes.req_sint64 == -1006);
TEST(alltypes.req_bool == true);
TEST(alltypes.req_fixed32 == 1008);
TEST(alltypes.req_sfixed32 == -1009);
TEST(alltypes.req_float == 1010.0f);
TEST(alltypes.req_fixed64 == 1011);
TEST(alltypes.req_sfixed64 == -1012);
TEST(alltypes.req_double == 1013.0f);
TEST(strcmp(alltypes.req_string, "1014") == 0);
TEST(alltypes.req_bytes.size == 4);
TEST(memcmp(alltypes.req_bytes.bytes, "1015", 4) == 0);
TEST(strcmp(alltypes.req_submsg.substuff1, "1016") == 0);
TEST(alltypes.req_submsg.substuff2 == 1016);
TEST(alltypes.req_submsg.substuff3 == 3);
TEST(alltypes.req_enum == MyEnum_Truth);
TEST(alltypes.rep_int32_count == 5 && alltypes.rep_int32[4] == -2001 && alltypes.rep_int32[0] == 0);
TEST(alltypes.rep_int64_count == 5 && alltypes.rep_int64[4] == -2002 && alltypes.rep_int64[0] == 0);
TEST(alltypes.rep_uint32_count == 5 && alltypes.rep_uint32[4] == 2003 && alltypes.rep_uint32[0] == 0);
TEST(alltypes.rep_uint64_count == 5 && alltypes.rep_uint64[4] == 2004 && alltypes.rep_uint64[0] == 0);
TEST(alltypes.rep_sint32_count == 5 && alltypes.rep_sint32[4] == -2005 && alltypes.rep_sint32[0] == 0);
TEST(alltypes.rep_sint64_count == 5 && alltypes.rep_sint64[4] == -2006 && alltypes.rep_sint64[0] == 0);
TEST(alltypes.rep_bool_count == 5 && alltypes.rep_bool[4] == true && alltypes.rep_bool[0] == false);
TEST(alltypes.rep_fixed32_count == 5 && alltypes.rep_fixed32[4] == 2008 && alltypes.rep_fixed32[0] == 0);
TEST(alltypes.rep_sfixed32_count == 5 && alltypes.rep_sfixed32[4] == -2009 && alltypes.rep_sfixed32[0] == 0);
TEST(alltypes.rep_float_count == 5 && alltypes.rep_float[4] == 2010.0f && alltypes.rep_float[0] == 0.0f);
TEST(alltypes.rep_fixed64_count == 5 && alltypes.rep_fixed64[4] == 2011 && alltypes.rep_fixed64[0] == 0);
TEST(alltypes.rep_sfixed64_count == 5 && alltypes.rep_sfixed64[4] == -2012 && alltypes.rep_sfixed64[0] == 0);
TEST(alltypes.rep_double_count == 5 && alltypes.rep_double[4] == 2013.0 && alltypes.rep_double[0] == 0.0);
TEST(alltypes.rep_string_count == 5 && strcmp(alltypes.rep_string[4], "2014") == 0 && alltypes.rep_string[0][0] == '\0');
TEST(alltypes.rep_bytes_count == 5 && alltypes.rep_bytes[4].size == 4 && alltypes.rep_bytes[0].size == 0);
TEST(memcmp(alltypes.rep_bytes[4].bytes, "2015", 4) == 0);
TEST(alltypes.rep_submsg_count == 5);
TEST(strcmp(alltypes.rep_submsg[4].substuff1, "2016") == 0 && alltypes.rep_submsg[0].substuff1[0] == '\0');
TEST(alltypes.rep_submsg[4].substuff2 == 2016 && alltypes.rep_submsg[0].substuff2 == 0);
TEST(alltypes.rep_submsg[4].substuff3 == 2016 && alltypes.rep_submsg[0].substuff3 == 3);
TEST(alltypes.rep_enum_count == 5 && alltypes.rep_enum[4] == MyEnum_Truth && alltypes.rep_enum[0] == MyEnum_Zero);
if (mode == 0)
{
/* Expect default values */
TEST(alltypes.has_opt_int32 == false);
TEST(alltypes.opt_int32 == 4041);
TEST(alltypes.has_opt_int64 == false);
TEST(alltypes.opt_int64 == 4042);
TEST(alltypes.has_opt_uint32 == false);
TEST(alltypes.opt_uint32 == 4043);
TEST(alltypes.has_opt_uint64 == false);
TEST(alltypes.opt_uint64 == 4044);
TEST(alltypes.has_opt_sint32 == false);
TEST(alltypes.opt_sint32 == 4045);
TEST(alltypes.has_opt_sint64 == false);
TEST(alltypes.opt_sint64 == 4046);
TEST(alltypes.has_opt_bool == false);
TEST(alltypes.opt_bool == false);
TEST(alltypes.has_opt_fixed32 == false);
TEST(alltypes.opt_fixed32 == 4048);
TEST(alltypes.has_opt_sfixed32 == false);
TEST(alltypes.opt_sfixed32 == 4049);
TEST(alltypes.has_opt_float == false);
TEST(alltypes.opt_float == 4050.0f);
TEST(alltypes.has_opt_fixed64 == false);
TEST(alltypes.opt_fixed64 == 4051);
TEST(alltypes.has_opt_sfixed64 == false);
TEST(alltypes.opt_sfixed64 == 4052);
TEST(alltypes.has_opt_double == false);
TEST(alltypes.opt_double == 4053.0);
TEST(alltypes.has_opt_string == false);
TEST(strcmp(alltypes.opt_string, "4054") == 0);
TEST(alltypes.has_opt_bytes == false);
TEST(alltypes.opt_bytes.size == 4);
TEST(memcmp(alltypes.opt_bytes.bytes, "4055", 4) == 0);
TEST(alltypes.has_opt_submsg == false);
TEST(strcmp(alltypes.opt_submsg.substuff1, "1") == 0);
TEST(alltypes.opt_submsg.substuff2 == 2);
TEST(alltypes.opt_submsg.substuff3 == 3);
TEST(alltypes.has_opt_enum == false);
TEST(alltypes.opt_enum == MyEnum_Second);
}
else
{
/* Expect filled-in values */
TEST(alltypes.has_opt_int32 == true);
TEST(alltypes.opt_int32 == 3041);
TEST(alltypes.has_opt_int64 == true);
TEST(alltypes.opt_int64 == 3042);
TEST(alltypes.has_opt_uint32 == true);
TEST(alltypes.opt_uint32 == 3043);
TEST(alltypes.has_opt_uint64 == true);
TEST(alltypes.opt_uint64 == 3044);
TEST(alltypes.has_opt_sint32 == true);
TEST(alltypes.opt_sint32 == 3045);
TEST(alltypes.has_opt_sint64 == true);
TEST(alltypes.opt_sint64 == 3046);
TEST(alltypes.has_opt_bool == true);
TEST(alltypes.opt_bool == true);
TEST(alltypes.has_opt_fixed32 == true);
TEST(alltypes.opt_fixed32 == 3048);
TEST(alltypes.has_opt_sfixed32 == true);
TEST(alltypes.opt_sfixed32 == 3049);
TEST(alltypes.has_opt_float == true);
TEST(alltypes.opt_float == 3050.0f);
TEST(alltypes.has_opt_fixed64 == true);
TEST(alltypes.opt_fixed64 == 3051);
TEST(alltypes.has_opt_sfixed64 == true);
TEST(alltypes.opt_sfixed64 == 3052);
TEST(alltypes.has_opt_double == true);
TEST(alltypes.opt_double == 3053.0);
TEST(alltypes.has_opt_string == true);
TEST(strcmp(alltypes.opt_string, "3054") == 0);
TEST(alltypes.has_opt_bytes == true);
TEST(alltypes.opt_bytes.size == 4);
TEST(memcmp(alltypes.opt_bytes.bytes, "3055", 4) == 0);
TEST(alltypes.has_opt_submsg == true);
TEST(strcmp(alltypes.opt_submsg.substuff1, "3056") == 0);
TEST(alltypes.opt_submsg.substuff2 == 3056);
TEST(alltypes.opt_submsg.substuff3 == 3);
TEST(alltypes.has_opt_enum == true);
TEST(alltypes.opt_enum == MyEnum_Truth);
}
TEST(alltypes.end == 1099);
return true;
}
int main(int argc, char **argv)
{
uint8_t buffer[1024];
size_t count;
pb_istream_t stream;
/* Whether to expect the optional values or the default values. */
int mode = (argc > 1) ? atoi(argv[1]) : 0;
/* Read the data into buffer */
SET_BINARY_MODE(stdin);
count = fread(buffer, 1, sizeof(buffer), stdin);
/* Construct a pb_istream_t for reading from the buffer */
stream = pb_istream_from_buffer(buffer, count);
/* Decode and print out the stuff */
if (!check_alltypes(&stream, mode))
{
printf("Parsing failed: %s\n", PB_GET_ERROR(&stream));
return 1;
} else {
return 0;
}
}

135
tests/backwards_compatibility/encode_legacy.c
View File

@@ -1,135 +0,0 @@
/* Attempts to test all the datatypes supported by ProtoBuf.
* This is a backwards-compatibility test, using alltypes_legacy.h.
* It is similar to encode_alltypes, but duplicated in order to allow
* encode_alltypes to test any new features introduced later.
*/
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <pb_encode.h>
#include "alltypes_legacy.h"
#include "test_helpers.h"
int main(int argc, char **argv)
{
int mode = (argc > 1) ? atoi(argv[1]) : 0;
/* Initialize the structure with constants */
AllTypes alltypes = {0};
alltypes.req_int32 = -1001;
alltypes.req_int64 = -1002;
alltypes.req_uint32 = 1003;
alltypes.req_uint64 = 1004;
alltypes.req_sint32 = -1005;
alltypes.req_sint64 = -1006;
alltypes.req_bool = true;
alltypes.req_fixed32 = 1008;
alltypes.req_sfixed32 = -1009;
alltypes.req_float = 1010.0f;
alltypes.req_fixed64 = 1011;
alltypes.req_sfixed64 = -1012;
alltypes.req_double = 1013.0;
strcpy(alltypes.req_string, "1014");
alltypes.req_bytes.size = 4;
memcpy(alltypes.req_bytes.bytes, "1015", 4);
strcpy(alltypes.req_submsg.substuff1, "1016");
alltypes.req_submsg.substuff2 = 1016;
alltypes.req_enum = MyEnum_Truth;
alltypes.rep_int32_count = 5; alltypes.rep_int32[4] = -2001;
alltypes.rep_int64_count = 5; alltypes.rep_int64[4] = -2002;
alltypes.rep_uint32_count = 5; alltypes.rep_uint32[4] = 2003;
alltypes.rep_uint64_count = 5; alltypes.rep_uint64[4] = 2004;
alltypes.rep_sint32_count = 5; alltypes.rep_sint32[4] = -2005;
alltypes.rep_sint64_count = 5; alltypes.rep_sint64[4] = -2006;
alltypes.rep_bool_count = 5; alltypes.rep_bool[4] = true;
alltypes.rep_fixed32_count = 5; alltypes.rep_fixed32[4] = 2008;
alltypes.rep_sfixed32_count = 5; alltypes.rep_sfixed32[4] = -2009;
alltypes.rep_float_count = 5; alltypes.rep_float[4] = 2010.0f;
alltypes.rep_fixed64_count = 5; alltypes.rep_fixed64[4] = 2011;
alltypes.rep_sfixed64_count = 5; alltypes.rep_sfixed64[4] = -2012;
alltypes.rep_double_count = 5; alltypes.rep_double[4] = 2013.0;
alltypes.rep_string_count = 5; strcpy(alltypes.rep_string[4], "2014");
alltypes.rep_bytes_count = 5; alltypes.rep_bytes[4].size = 4;
memcpy(alltypes.rep_bytes[4].bytes, "2015", 4);
alltypes.rep_submsg_count = 5;
strcpy(alltypes.rep_submsg[4].substuff1, "2016");
alltypes.rep_submsg[4].substuff2 = 2016;
alltypes.rep_submsg[4].has_substuff3 = true;
alltypes.rep_submsg[4].substuff3 = 2016;
alltypes.rep_enum_count = 5; alltypes.rep_enum[4] = MyEnum_Truth;
if (mode != 0)
{
/* Fill in values for optional fields */
alltypes.has_opt_int32 = true;
alltypes.opt_int32 = 3041;
alltypes.has_opt_int64 = true;
alltypes.opt_int64 = 3042;
alltypes.has_opt_uint32 = true;
alltypes.opt_uint32 = 3043;
alltypes.has_opt_uint64 = true;
alltypes.opt_uint64 = 3044;
alltypes.has_opt_sint32 = true;
alltypes.opt_sint32 = 3045;
alltypes.has_opt_sint64 = true;
alltypes.opt_sint64 = 3046;
alltypes.has_opt_bool = true;
alltypes.opt_bool = true;
alltypes.has_opt_fixed32 = true;
alltypes.opt_fixed32 = 3048;
alltypes.has_opt_sfixed32 = true;
alltypes.opt_sfixed32 = 3049;
alltypes.has_opt_float = true;
alltypes.opt_float = 3050.0f;
alltypes.has_opt_fixed64 = true;
alltypes.opt_fixed64 = 3051;
alltypes.has_opt_sfixed64 = true;
alltypes.opt_sfixed64 = 3052;
alltypes.has_opt_double = true;
alltypes.opt_double = 3053.0;
alltypes.has_opt_string = true;
strcpy(alltypes.opt_string, "3054");
alltypes.has_opt_bytes = true;
alltypes.opt_bytes.size = 4;
memcpy(alltypes.opt_bytes.bytes, "3055", 4);
alltypes.has_opt_submsg = true;
strcpy(alltypes.opt_submsg.substuff1, "3056");
alltypes.opt_submsg.substuff2 = 3056;
alltypes.has_opt_enum = true;
alltypes.opt_enum = MyEnum_Truth;
}
alltypes.end = 1099;
{
uint8_t buffer[1024];
pb_ostream_t stream = pb_ostream_from_buffer(buffer, sizeof(buffer));
/* Now encode it and check if we succeeded. */
if (pb_encode(&stream, AllTypes_fields, &alltypes))
{
SET_BINARY_MODE(stdout);
fwrite(buffer, 1, stream.bytes_written, stdout);
return 0; /* Success */
}
else
{
fprintf(stderr, "Encoding failed!\n");
return 1; /* Failure */
}
}
}

12
tests/basic_buffer/SConscript
View File

@@ -1,12 +0,0 @@
# Build and run a basic round-trip test using memory buffer encoding.
Import("env")
enc = env.Program(["encode_buffer.c", "$COMMON/person.pb.c", "$COMMON/pb_encode.o", "$COMMON/pb_common.o"])
dec = env.Program(["decode_buffer.c", "$COMMON/person.pb.c", "$COMMON/pb_decode.o", "$COMMON/pb_common.o"])
env.RunTest(enc)
env.RunTest([dec, "encode_buffer.output"])
env.Decode(["encode_buffer.output", "$COMMON/person.proto"], MESSAGE = "Person")
env.Compare(["decode_buffer.output", "encode_buffer.decoded"])

38
tests/basic_buffer/encode_buffer.c
View File

@@ -1,38 +0,0 @@
/* A very simple encoding test case using person.proto.
* Just puts constant data in the fields and encodes into
* buffer, which is then written to stdout.
*/
#include <stdio.h>
#include <pb_encode.h>
#include "person.pb.h"
#include "test_helpers.h"
int main()
{
uint8_t buffer[Person_size];
pb_ostream_t stream;
/* Initialize the structure with constants */
Person person = {"Test Person 99", 99, true, "test@person.com",
3, {{"555-12345678", true, Person_PhoneType_MOBILE},
{"99-2342", false, 0},
{"1234-5678", true, Person_PhoneType_WORK},
}};
stream = pb_ostream_from_buffer(buffer, sizeof(buffer));
/* Now encode it and check if we succeeded. */
if (pb_encode(&stream, Person_fields, &person))
{
/* Write the result data to stdout */
SET_BINARY_MODE(stdout);
fwrite(buffer, 1, stream.bytes_written, stdout);
return 0; /* Success */
}
else
{
fprintf(stderr, "Encoding failed: %s\n", PB_GET_ERROR(&stream));
return 1; /* Failure */
}
}

12
tests/basic_stream/SConscript
View File

@@ -1,12 +0,0 @@
# Build and run a basic round-trip test using direct stream encoding.
Import("env")
enc = env.Program(["encode_stream.c", "$COMMON/person.pb.c", "$COMMON/pb_encode.o", "$COMMON/pb_common.o"])
dec = env.Program(["decode_stream.c", "$COMMON/person.pb.c", "$COMMON/pb_decode.o", "$COMMON/pb_common.o"])
env.RunTest(enc)
env.RunTest([dec, "encode_stream.output"])
env.Decode(["encode_stream.output", "$COMMON/person.proto"], MESSAGE = "Person")
env.Compare(["decode_stream.output", "encode_stream.decoded"])

28
tests/buffer_only/SConscript
View File

@@ -1,28 +0,0 @@
# Run the alltypes test case, but compile with PB_BUFFER_ONLY=1
Import("env")
# Take copy of the files for custom build.
c = Copy("$TARGET", "$SOURCE")
env.Command("alltypes.pb.h", "$BUILD/alltypes/alltypes.pb.h", c)
env.Command("alltypes.pb.c", "$BUILD/alltypes/alltypes.pb.c", c)
env.Command("encode_alltypes.c", "$BUILD/alltypes/encode_alltypes.c", c)
env.Command("decode_alltypes.c", "$BUILD/alltypes/decode_alltypes.c", c)
# Define the compilation options
opts = env.Clone()
opts.Append(CPPDEFINES = {'PB_BUFFER_ONLY': 1})
# Build new version of core
strict = opts.Clone()
strict.Append(CFLAGS = strict['CORECFLAGS'])
strict.Object("pb_decode_bufonly.o", "$NANOPB/pb_decode.c")
strict.Object("pb_encode_bufonly.o", "$NANOPB/pb_encode.c")
strict.Object("pb_common_bufonly.o", "$NANOPB/pb_common.c")
# Now build and run the test normally.
enc = opts.Program(["encode_alltypes.c", "alltypes.pb.c", "pb_encode_bufonly.o", "pb_common_bufonly.o"])
dec = opts.Program(["decode_alltypes.c", "alltypes.pb.c", "pb_decode_bufonly.o", "pb_common_bufonly.o"])
env.RunTest(enc)
env.RunTest([dec, "encode_alltypes.output"])

1
tests/callbacks/callbacks.proto → tests/callbacks.proto
View File

@@ -11,6 +11,5 @@ message TestMessage {
repeated fixed32 fixed32value = 3;
repeated fixed64 fixed64value = 4;
optional SubMessage submsg = 5;
repeated string repeatedstring = 6;
}

14
tests/callbacks/SConscript
View File

@@ -1,14 +0,0 @@
# Test the functionality of the callback fields.
Import("env")
env.NanopbProto("callbacks")
enc = env.Program(["encode_callbacks.c", "callbacks.pb.c", "$COMMON/pb_encode.o", "$COMMON/pb_common.o"])
dec = env.Program(["decode_callbacks.c", "callbacks.pb.c", "$COMMON/pb_decode.o", "$COMMON/pb_common.o"])
env.RunTest(enc)
env.RunTest([dec, "encode_callbacks.output"])
env.Decode(["encode_callbacks.output", "callbacks.proto"], MESSAGE = "TestMessage")
env.Compare(["decode_callbacks.output", "encode_callbacks.decoded"])

17
tests/common/SConscript
View File

@@ -1,17 +0,0 @@
# Build the common files needed by multiple test cases
Import('env')
# Protocol definitions for the encode/decode_unittests
env.NanopbProto("unittestproto")
# Protocol definitions for basic_buffer/stream tests
env.NanopbProto("person")
# Binaries of the pb_decode.c and pb_encode.c
# These are built using more strict warning flags.
strict = env.Clone()
strict.Append(CFLAGS = strict['CORECFLAGS'])
strict.Object("pb_decode.o", "$NANOPB/pb_decode.c")
strict.Object("pb_encode.o", "$NANOPB/pb_encode.c")
strict.Object("pb_common.o", "$NANOPB/pb_common.c")

17
tests/common/test_helpers.h
View File

@@ -1,17 +0,0 @@
/* Compatibility helpers for the test programs. */
#ifndef _TEST_HELPERS_H_
#define _TEST_HELPERS_H_
#ifdef _WIN32
#include <io.h>
#include <fcntl.h>
#define SET_BINARY_MODE(file) setmode(fileno(file), O_BINARY)
#else
#define SET_BINARY_MODE(file)
#endif
#endif

36
tests/common/unittestproto.proto
View File

@@ -1,36 +0,0 @@
import 'nanopb.proto';
message IntegerArray {
repeated int32 data = 1 [(nanopb).max_count = 10];
}
message FloatArray {
repeated float data = 1 [(nanopb).max_count = 10];
}
message StringMessage {
required string data = 1 [(nanopb).max_size = 10];
}
message BytesMessage {
required bytes data = 1 [(nanopb).max_size = 16];
}
message CallbackArray {
// We cheat a bit and use this message for testing other types, too.
// Nanopb does not care about the actual defined data type for callback
// fields.
repeated int32 data = 1;
}
message IntegerContainer {
required IntegerArray submsg = 1;
}
message CallbackContainer {
required CallbackArray submsg = 1;
}
message CallbackContainerContainer {
required CallbackContainer submsg = 1;
}

25
tests/cxx_main_program/SConscript
View File

@@ -1,25 +0,0 @@
# Run the alltypes test case, but compile it as C++ instead.
# In fact, compile the entire nanopb using C++ compiler.
Import("env")
# This is needed to get INT32_MIN etc. macros defined
env = env.Clone()
env.Append(CPPDEFINES = ['__STDC_LIMIT_MACROS'])
# Copy the files to .cxx extension in order to force C++ build.
c = Copy("$TARGET", "$SOURCE")
env.Command("pb_encode.cxx", "#../pb_encode.c", c)
env.Command("pb_decode.cxx", "#../pb_decode.c", c)
env.Command("pb_common.cxx", "#../pb_common.c", c)
env.Command("alltypes.pb.h", "$BUILD/alltypes/alltypes.pb.h", c)
env.Command("alltypes.pb.cxx", "$BUILD/alltypes/alltypes.pb.c", c)
env.Command("encode_alltypes.cxx", "$BUILD/alltypes/encode_alltypes.c", c)
env.Command("decode_alltypes.cxx", "$BUILD/alltypes/decode_alltypes.c", c)
# Now build and run the test normally.
enc = env.Program(["encode_alltypes.cxx", "alltypes.pb.cxx", "pb_encode.cxx", "pb_common.cxx"])
dec = env.Program(["decode_alltypes.cxx", "alltypes.pb.cxx", "pb_decode.cxx", "pb_common.cxx"])
env.RunTest(enc)
env.RunTest([dec, "encode_alltypes.output"])

128
tests/decode_unittests/decode_unittests.c → tests/decode_unittests.c
View File

@@ -1,10 +1,6 @@
/* This includes the whole .c file to get access to static functions. */
#define PB_ENABLE_MALLOC
#include "pb_common.c"
#include "pb_decode.c"
#include <stdio.h>
#include <string.h>
#include "pb_decode.h"
#include "unittests.h"
#include "unittestproto.pb.h"
@@ -21,11 +17,11 @@ bool stream_callback(pb_istream_t *stream, uint8_t *buf, size_t count)
}
/* Verifies that the stream passed to callback matches the byte array pointed to by arg. */
bool callback_check(pb_istream_t *stream, const pb_field_t *field, void **arg)
bool callback_check(pb_istream_t *stream, const pb_field_t *field, void *arg)
{
int i;
uint8_t byte;
pb_bytes_array_t *ref = (pb_bytes_array_t*) *arg;
pb_bytes_array_t *ref = (pb_bytes_array_t*) arg;
for (i = 0; i < ref->size; i++)
{
@@ -170,23 +166,15 @@ int main()
{
pb_istream_t s;
struct { pb_size_t size; uint8_t bytes[5]; } d;
pb_field_t f = {1, PB_LTYPE_BYTES, 0, 0, sizeof(d), 0, 0};
struct { size_t size; uint8_t bytes[5]; } d;
pb_field_t f = {1, PB_LTYPE_BYTES, 0, 0, 5, 0, 0};
COMMENT("Test pb_dec_bytes")
TEST((s = S("\x00"), pb_dec_bytes(&s, &f, &d) && d.size == 0))
TEST((s = S("\x01\xFF"), pb_dec_bytes(&s, &f, &d) && d.size == 1 && d.bytes[0] == 0xFF))
TEST((s = S("\x06xxxxxx"), !pb_dec_bytes(&s, &f, &d)))
TEST((s = S("\x05xxxxx"), pb_dec_bytes(&s, &f, &d) && d.size == 5))
TEST((s = S("\x05xxxx"), !pb_dec_bytes(&s, &f, &d)))
/* Note: the size limit on bytes-fields is not strictly obeyed, as
* the compiler may add some padding to the struct. Using this padding
* is not a very good thing to do, but it is difficult to avoid when
* we use only a single uint8_t to store the size of the field.
* Therefore this tests against a 10-byte string, while otherwise even
* 6 bytes should error out.
*/
TEST((s = S("\x10xxxxxxxxxx"), !pb_dec_bytes(&s, &f, &d)))
}
{
@@ -205,13 +193,13 @@ int main()
IntegerArray dest;
COMMENT("Testing pb_decode with repeated int32 field")
TEST((s = S(""), pb_decode(&s, IntegerArray_fields, &dest) && dest.data_count == 0))
TEST((s = S("\x08\x01\x08\x02"), pb_decode(&s, IntegerArray_fields, &dest)
TEST((s = S(""), pb_decode(&s, IntegerArray_msg, &dest) && dest.data_count == 0))
TEST((s = S("\x08\x01\x08\x02"), pb_decode(&s, IntegerArray_msg, &dest)
&& dest.data_count == 2 && dest.data[0] == 1 && dest.data[1] == 2))
s = S("\x08\x01\x08\x02\x08\x03\x08\x04\x08\x05\x08\x06\x08\x07\x08\x08\x08\x09\x08\x0A");
TEST(pb_decode(&s, IntegerArray_fields, &dest) && dest.data_count == 10 && dest.data[9] == 10)
TEST(pb_decode(&s, IntegerArray_msg, &dest) && dest.data_count == 10 && dest.data[9] == 10)
s = S("\x08\x01\x08\x02\x08\x03\x08\x04\x08\x05\x08\x06\x08\x07\x08\x08\x08\x09\x08\x0A\x08\x0B");
TEST(!pb_decode(&s, IntegerArray_fields, &dest))
TEST(!pb_decode(&s, IntegerArray_msg, &dest))
}
{
@@ -219,17 +207,17 @@ int main()
IntegerArray dest;
COMMENT("Testing pb_decode with packed int32 field")
TEST((s = S("\x0A\x00"), pb_decode(&s, IntegerArray_fields, &dest)
TEST((s = S("\x0A\x00"), pb_decode(&s, IntegerArray_msg, &dest)
&& dest.data_count == 0))
TEST((s = S("\x0A\x01\x01"), pb_decode(&s, IntegerArray_fields, &dest)
TEST((s = S("\x0A\x01\x01"), pb_decode(&s, IntegerArray_msg, &dest)
&& dest.data_count == 1 && dest.data[0] == 1))
TEST((s = S("\x0A\x0A\x01\x02\x03\x04\x05\x06\x07\x08\x09\x0A"), pb_decode(&s, IntegerArray_fields, &dest)
TEST((s = S("\x0A\x0A\x01\x02\x03\x04\x05\x06\x07\x08\x09\x0A"), pb_decode(&s, IntegerArray_msg, &dest)
&& dest.data_count == 10 && dest.data[0] == 1 && dest.data[9] == 10))
TEST((s = S("\x0A\x0B\x01\x02\x03\x04\x05\x06\x07\x08\x09\x0A\x0B"), !pb_decode(&s, IntegerArray_fields, &dest)))
TEST((s = S("\x0A\x0B\x01\x02\x03\x04\x05\x06\x07\x08\x09\x0A\x0B"), !pb_decode(&s, IntegerArray_msg, &dest)))
/* Test invalid wire data */
TEST((s = S("\x0A\xFF"), !pb_decode(&s, IntegerArray_fields, &dest)))
TEST((s = S("\x0A\x01"), !pb_decode(&s, IntegerArray_fields, &dest)))
TEST((s = S("\x0A\xFF"), !pb_decode(&s, IntegerArray_msg, &dest)))
TEST((s = S("\x0A\x01"), !pb_decode(&s, IntegerArray_msg, &dest)))
}
{
@@ -237,46 +225,46 @@ int main()
IntegerArray dest;
COMMENT("Testing pb_decode with unknown fields")
TEST((s = S("\x18\x0F\x08\x01"), pb_decode(&s, IntegerArray_fields, &dest)
TEST((s = S("\x18\x0F\x08\x01"), pb_decode(&s, IntegerArray_msg, &dest)
&& dest.data_count == 1 && dest.data[0] == 1))
TEST((s = S("\x19\x00\x00\x00\x00\x00\x00\x00\x00\x08\x01"), pb_decode(&s, IntegerArray_fields, &dest)
TEST((s = S("\x19\x00\x00\x00\x00\x00\x00\x00\x00\x08\x01"), pb_decode(&s, IntegerArray_msg, &dest)
&& dest.data_count == 1 && dest.data[0] == 1))
TEST((s = S("\x1A\x00\x08\x01"), pb_decode(&s, IntegerArray_fields, &dest)
TEST((s = S("\x1A\x00\x08\x01"), pb_decode(&s, IntegerArray_msg, &dest)
&& dest.data_count == 1 && dest.data[0] == 1))
TEST((s = S("\x1B\x08\x01"), !pb_decode(&s, IntegerArray_fields, &dest)))
TEST((s = S("\x1D\x00\x00\x00\x00\x08\x01"), pb_decode(&s, IntegerArray_fields, &dest)
TEST((s = S("\x1B\x08\x01"), !pb_decode(&s, IntegerArray_msg, &dest)))
TEST((s = S("\x1D\x00\x00\x00\x00\x08\x01"), pb_decode(&s, IntegerArray_msg, &dest)
&& dest.data_count == 1 && dest.data[0] == 1))
}
{
pb_istream_t s;
CallbackArray dest;
struct { pb_size_t size; uint8_t bytes[10]; } ref;
struct { size_t size; uint8_t bytes[10]; } ref;
dest.data.funcs.decode = &callback_check;
dest.data.arg = &ref;
COMMENT("Testing pb_decode with callbacks")
/* Single varint */
ref.size = 1; ref.bytes[0] = 0x55;
TEST((s = S("\x08\x55"), pb_decode(&s, CallbackArray_fields, &dest)))
TEST((s = S("\x08\x55"), pb_decode(&s, CallbackArray_msg, &dest)))
/* Packed varint */
ref.size = 3; ref.bytes[0] = ref.bytes[1] = ref.bytes[2] = 0x55;
TEST((s = S("\x0A\x03\x55\x55\x55"), pb_decode(&s, CallbackArray_fields, &dest)))
TEST((s = S("\x0A\x03\x55\x55\x55"), pb_decode(&s, CallbackArray_msg, &dest)))
/* Packed varint with loop */
ref.size = 1; ref.bytes[0] = 0x55;
TEST((s = S("\x0A\x03\x55\x55\x55"), pb_decode(&s, CallbackArray_fields, &dest)))
TEST((s = S("\x0A\x03\x55\x55\x55"), pb_decode(&s, CallbackArray_msg, &dest)))
/* Single fixed32 */
ref.size = 4; ref.bytes[0] = ref.bytes[1] = ref.bytes[2] = ref.bytes[3] = 0xAA;
TEST((s = S("\x0D\xAA\xAA\xAA\xAA"), pb_decode(&s, CallbackArray_fields, &dest)))
TEST((s = S("\x0D\xAA\xAA\xAA\xAA"), pb_decode(&s, CallbackArray_msg, &dest)))
/* Single fixed64 */
ref.size = 8; memset(ref.bytes, 0xAA, 8);
TEST((s = S("\x09\xAA\xAA\xAA\xAA\xAA\xAA\xAA\xAA"), pb_decode(&s, CallbackArray_fields, &dest)))
TEST((s = S("\x09\xAA\xAA\xAA\xAA\xAA\xAA\xAA\xAA"), pb_decode(&s, CallbackArray_msg, &dest)))
/* Unsupported field type */
TEST((s = S("\x0B\x00"), !pb_decode(&s, CallbackArray_fields, &dest)))
TEST((s = S("\x0B\x00"), !pb_decode(&s, CallbackArray_msg, &dest)))
/* Just make sure that our test function works */
ref.size = 1; ref.bytes[0] = 0x56;
TEST((s = S("\x08\x55"), !pb_decode(&s, CallbackArray_fields, &dest)))
TEST((s = S("\x08\x55"), !pb_decode(&s, CallbackArray_msg, &dest)))
}
{
@@ -284,43 +272,39 @@ int main()
IntegerArray dest;
COMMENT("Testing pb_decode message termination")
TEST((s = S(""), pb_decode(&s, IntegerArray_fields, &dest)))
TEST((s = S("\x00"), pb_decode(&s, IntegerArray_fields, &dest)))
TEST((s = S("\x08\x01"), pb_decode(&s, IntegerArray_fields, &dest)))
TEST((s = S("\x08\x01\x00"), pb_decode(&s, IntegerArray_fields, &dest)))
TEST((s = S("\x08"), !pb_decode(&s, IntegerArray_fields, &dest)))
TEST((s = S(""), pb_decode(&s, IntegerArray_msg, &dest)))
TEST((s = S("\x00"), pb_decode(&s, IntegerArray_msg, &dest)))
TEST((s = S("\x08\x01"), pb_decode(&s, IntegerArray_msg, &dest)))
TEST((s = S("\x08\x01\x00"), pb_decode(&s, IntegerArray_msg, &dest)))
TEST((s = S("\x08"), !pb_decode(&s, IntegerArray_msg, &dest)))
}
{
pb_istream_t s;
IntegerContainer dest = {{0}};
PointerContainer dest;
COMMENT("Testing pb_decode_delimited")
TEST((s = S("\x09\x0A\x07\x0A\x05\x01\x02\x03\x04\x05"),
pb_decode_delimited(&s, IntegerContainer_fields, &dest)) &&
dest.submsg.data_count == 5)
}
{
pb_istream_t s = {0};
void *data = NULL;
COMMENT("Testing pb_decode with pointer fields")
COMMENT("Testing allocate_field")
TEST(allocate_field(&s, &data, 10, 10) && data != NULL);
TEST(allocate_field(&s, &data, 10, 20) && data != NULL);
{
void *oldvalue = data;
size_t very_big = (size_t)-1;
size_t somewhat_big = very_big / 2 + 1;
size_t not_so_big = (size_t)1 << (4 * sizeof(size_t));
TEST(!allocate_field(&s, &data, very_big, 2) && data == oldvalue);
TEST(!allocate_field(&s, &data, somewhat_big, 2) && data == oldvalue);
TEST(!allocate_field(&s, &data, not_so_big, not_so_big) && data == oldvalue);
}
pb_free(data);
memset(&dest, 0, sizeof(dest));
#ifdef MALLOC_HEADER
TEST((s = S("\x0A\x01\x61\x12\x01\x62\x1A\x00\x2A\x01\x65\x32\x01\x66"
"\x3A\x00\x42\x01\x63\x4A\x01\x64"),
pb_decode(&s, PointerContainer_msg, &dest)))
TEST(0 == strcmp(dest.text, "a"))
TEST(dest.blob.size == 1 && dest.blob.bytes[0] == 'b')
TEST(dest.submsg != NULL && dest.submsg->data == 10)
TEST(dest.rtext_count == 1 && (0 == strcmp(dest.rtext[0], "e")))
TEST(dest.rblob_count == 1 && dest.rblob[0].size == 1 &&
dest.rblob[0].bytes[0] == 'f')
TEST(dest.rsubmsg_count == 1)
TEST(0 == strcmp(dest.otext, "c"))
TEST(dest.oblob.size == 1 && dest.oblob.bytes[0] == 'd')
TEST(pb_clean(PointerContainer_msg, &dest));
#else
TEST((s = S("\x0A\x01\x61\x12\x01\x62\x2A\x01\x65\x32\x01\x66\x01\x66"
"\x3A\x00\x42\x01\x63\x4A\x01\x64"),
!pb_decode(&s, PointerContainer_msg, &dest)))
#endif
}
if (status != 0)

4
tests/decode_unittests/SConscript
View File

@@ -1,4 +0,0 @@
Import('env')
p = env.Program(["decode_unittests.c", "$COMMON/unittestproto.pb.c"])
env.RunTest(p)

405
tests/encode_unittests.c Normal file
View File

@@ -0,0 +1,405 @@
#include <stdio.h>
#include <string.h>
#include "pb_encode.h"
#include "pb_encode_buffer.h"
#include "unittests.h"
#include "unittestproto.pb.h"
bool streamcallback(pb_ostream_t *stream, const uint8_t *buf, size_t count)
{
/* Allow only 'x' to be written */
while (count--)
{
if (*buf++ != 'x')
return false;
}
return true;
}
bool fieldcallback(pb_ostream_t *stream, const pb_field_t *field, const void *arg)
{
int value = 0x55;
if (!pb_encode_tag_for_field(stream, field))
return false;
return pb_encode_varint(stream, value);
}
bool fieldcallback_buf(pb_strstream_t *stream, const pb_field_t *field, const void *arg)
{
int value = 0x55;
if (!pb_encbuf_varint(stream, value))
return false;
return pb_encbuf_tag_for_field(stream, field);
}
bool crazyfieldcallback(pb_ostream_t *stream, const pb_field_t *field, const void *arg)
{
/* This callback writes different amount of data the second time. */
uint32_t *state = (uint32_t*)arg;
*state <<= 8;
if (!pb_encode_tag_for_field(stream, field))
return false;
return pb_encode_varint(stream, *state);
}
bool crazyfieldcallback_buf(pb_strstream_t *stream, const pb_field_t *field, const void *arg)
{
/* This callback writes different amount of data the second time. */
uint32_t *state = (uint32_t*)arg;
*state <<= 8;
if (!pb_encbuf_varint(stream, *state))
return false;
return pb_encbuf_tag_for_field(stream, field);
}
/* Check that expression x writes data y.
* Y is a string, which may contain null bytes. Null terminator is ignored.
*/
#define WRITES(x, y) \
memset(buffer, 0xAA, sizeof(buffer)), \
s = pb_ostream_from_buffer(buffer, sizeof(buffer)), \
(x) && \
memcmp(buffer, y, sizeof(y) - 1) == 0 && \
buffer[sizeof(y) - 1] == 0xAA
/* Check that expression x writes data y into s2.
* Y is a string, which may contain null bytes. Null terminator is ignored.
*/
#define WRITES_BUF(x, y) \
memset(buffer, 0xAA, sizeof(buffer)), \
s2 = pb_strstream_from_buffer(buffer, sizeof(buffer)), \
(x) && \
memcmp(s2.last, y, sizeof(y) - 1) == 0 && \
s2.last - buffer == sizeof(buffer) - (sizeof(y) - 1)
/* Check that expression x and y write data z into s and s2, respectively.
*/
#define WRITES_BOTH(x, y, z) (WRITES(x, z)) && (WRITES_BUF(y, z))
int main()
{
int status = 0;
{
uint8_t buffer1[] = "foobartest1234";
uint8_t buffer2[sizeof(buffer1)];
pb_ostream_t stream = pb_ostream_from_buffer(buffer2, sizeof(buffer1));
COMMENT("Test pb_write and pb_ostream_t");
TEST(pb_write(&stream, buffer1, sizeof(buffer1)));
TEST(memcmp(buffer1, buffer2, sizeof(buffer1)) == 0);
TEST(!pb_write(&stream, buffer1, 1));
TEST(stream.bytes_written == sizeof(buffer1));
}
{
uint8_t buffer1[] = "xxxxxxx";
pb_ostream_t stream = {&streamcallback, 0, SIZE_MAX, 0};
COMMENT("Test pb_write with custom callback");
TEST(pb_write(&stream, buffer1, 5));
buffer1[0] = 'a';
TEST(!pb_write(&stream, buffer1, 5));
}
{
uint8_t buffer[30];
pb_ostream_t s;
pb_strstream_t s2;
COMMENT("Test pb_encode_varint")
TEST(WRITES_BOTH(pb_encode_varint(&s, 0),
pb_encbuf_varint(&s2, 0), "\0"));
TEST(WRITES_BOTH(pb_encode_varint(&s, 1),
pb_encbuf_varint(&s2, 1), "\1"));
TEST(WRITES_BOTH(pb_encode_varint(&s, 0x7F),
pb_encbuf_varint(&s2, 0x7F), "\x7F"));
TEST(WRITES_BOTH(pb_encode_varint(&s, 0x80),
pb_encbuf_varint(&s2, 0x80), "\x80\x01"));
TEST(WRITES_BOTH(pb_encode_varint(&s, UINT32_MAX),
pb_encbuf_varint(&s2, UINT32_MAX),
"\xFF\xFF\xFF\xFF\x0F"));
TEST(WRITES_BOTH(pb_encode_varint(&s, UINT64_MAX),
pb_encbuf_varint(&s2, UINT64_MAX),
"\xFF\xFF\xFF\xFF\xFF\xFF\xFF\xFF\xFF\x01"));
}
{
uint8_t buffer[30];
pb_ostream_t s;
pb_strstream_t s2;
COMMENT("Test pb_encode_tag")
TEST(WRITES_BOTH(pb_encode_tag(&s, PB_WT_STRING, 5),
pb_encbuf_tag(&s2, PB_WT_STRING, 5), "\x2A"));
TEST(WRITES_BOTH(pb_encode_tag(&s, PB_WT_VARINT, 99),
pb_encbuf_tag(&s2, PB_WT_VARINT, 99), "\x98\x06"));
}
{
uint8_t buffer[30];
pb_ostream_t s;
pb_strstream_t s2;
pb_field_t field = {10, PB_LTYPE_SVARINT};
COMMENT("Test pb_encode_tag_for_field")
TEST(WRITES_BOTH(pb_encode_tag_for_field(&s, &field),
pb_encbuf_tag_for_field(&s2, &field), "\x50"));
field.type = PB_LTYPE_FIXED64;
TEST(WRITES_BOTH(pb_encode_tag_for_field(&s, &field),
pb_encbuf_tag_for_field(&s2, &field), "\x51"));
field.type = PB_LTYPE_STRING;
TEST(WRITES_BOTH(pb_encode_tag_for_field(&s, &field),
pb_encbuf_tag_for_field(&s2, &field), "\x52"));
field.type = PB_LTYPE_FIXED32;
TEST(WRITES_BOTH(pb_encode_tag_for_field(&s, &field),
pb_encbuf_tag_for_field(&s2, &field), "\x55"));
}
{
uint8_t buffer[30];
pb_ostream_t s;
pb_strstream_t s2;
COMMENT("Test pb_encode_string")
TEST(WRITES_BOTH(pb_encode_string(&s, (const uint8_t*)"abcd", 4),
pb_encbuf_string(&s2, (const uint8_t*)"abcd", 4),
"\x04""abcd"));
TEST(WRITES_BOTH(pb_encode_string(&s, (const uint8_t*)"abcd\x00", 5),
pb_encbuf_string(&s2, (const uint8_t*)"abcd\x00", 5),
"\x05""abcd\x00"));
TEST(WRITES_BOTH(pb_encode_string(&s, (const uint8_t*)"", 0),
pb_encbuf_string(&s2, (const uint8_t*)"", 0), "\x00"));
}
{
uint8_t buffer[30];
pb_ostream_t s;
uint8_t value = 1;
int8_t svalue = -1;
int32_t max = INT32_MAX;
int32_t min = INT32_MIN;
int64_t lmax = INT64_MAX;
int64_t lmin = INT64_MIN;
pb_field_t field = {1, PB_LTYPE_VARINT, 0, 0, sizeof(value)};
COMMENT("Test pb_enc_varint and pb_enc_svarint")
TEST(WRITES(pb_enc_varint(&s, &field, &value), "\x01"));
TEST(WRITES(pb_enc_svarint(&s, &field, &svalue), "\x01"));
TEST(WRITES(pb_enc_svarint(&s, &field, &value), "\x02"));
field.data_size = sizeof(max);
TEST(WRITES(pb_enc_svarint(&s, &field, &max), "\xfe\xff\xff\xff\x0f"));
TEST(WRITES(pb_enc_svarint(&s, &field, &min), "\xff\xff\xff\xff\x0f"));
field.data_size = sizeof(lmax);
TEST(WRITES(pb_enc_svarint(&s, &field, &lmax), "\xFE\xFF\xFF\xFF\xFF\xFF\xFF\xFF\xFF\x01"));
TEST(WRITES(pb_enc_svarint(&s, &field, &lmin), "\xFF\xFF\xFF\xFF\xFF\xFF\xFF\xFF\xFF\x01"));
}
{
uint8_t buffer[30];
pb_ostream_t s;
float fvalue;
double dvalue;
COMMENT("Test pb_enc_fixed32 using float")
fvalue = 0.0f;
TEST(WRITES(pb_enc_fixed32(&s, NULL, &fvalue), "\x00\x00\x00\x00"))
fvalue = 99.0f;
TEST(WRITES(pb_enc_fixed32(&s, NULL, &fvalue), "\x00\x00\xc6\x42"))
fvalue = -12345678.0f;
TEST(WRITES(pb_enc_fixed32(&s, NULL, &fvalue), "\x4e\x61\x3c\xcb"))
COMMENT("Test pb_enc_fixed64 using double")
dvalue = 0.0;
TEST(WRITES(pb_enc_fixed64(&s, NULL, &dvalue), "\x00\x00\x00\x00\x00\x00\x00\x00"))
dvalue = 99.0;
TEST(WRITES(pb_enc_fixed64(&s, NULL, &dvalue), "\x00\x00\x00\x00\x00\xc0\x58\x40"))
dvalue = -12345678.0;
TEST(WRITES(pb_enc_fixed64(&s, NULL, &dvalue), "\x00\x00\x00\xc0\x29\x8c\x67\xc1"))
}
{
uint8_t buffer[30];
pb_ostream_t s;
struct { size_t size; uint8_t bytes[5]; } value = {5, {'x', 'y', 'z', 'z', 'y'}};
COMMENT("Test pb_enc_bytes")
TEST(WRITES(pb_enc_bytes(&s, NULL, &value), "\x05xyzzy"))
value.size = 0;
TEST(WRITES(pb_enc_bytes(&s, NULL, &value), "\x00"))
}
{
uint8_t buffer[30];
pb_ostream_t s;
char value[] = "xyzzy";
COMMENT("Test pb_enc_string")
TEST(WRITES(pb_enc_string(&s, NULL, &value), "\x05xyzzy"))
value[0] = '\0';
TEST(WRITES(pb_enc_string(&s, NULL, &value), "\x00"))
}
{
uint8_t buffer[10];
pb_ostream_t s;
pb_strstream_t s2;
IntegerArray msg = {{0}, 5, {1, 2, 3, 4, 5}};
COMMENT("Test pb_encode with int32 array")
TEST(WRITES_BOTH(pb_encode(&s, IntegerArray_msg, &msg),
pb_encode_buffer(&s2, IntegerArray_msg, &msg),
"\x0A\x05\x01\x02\x03\x04\x05"))
msg.data_count = 0;
TEST(WRITES_BOTH(pb_encode(&s, IntegerArray_msg, &msg),
pb_encode_buffer(&s2, IntegerArray_msg, &msg), ""))
msg.data_count = 10;
TEST(!pb_encode(&s, IntegerArray_msg, &msg))
TEST(!pb_encode_buffer(&s2, IntegerArray_msg, &msg))
}
{
uint8_t buffer[10];
pb_ostream_t s;
pb_strstream_t s2;
FloatArray msg = {{0}, 1, {99.0f}};
COMMENT("Test pb_encode with float array")
TEST(WRITES_BOTH(pb_encode(&s, FloatArray_msg, &msg),
pb_encode_buffer(&s2, FloatArray_msg, &msg),
"\x0A\x04\x00\x00\xc6\x42"))
msg.data_count = 0;
TEST(WRITES_BOTH(pb_encode(&s, FloatArray_msg, &msg),
pb_encode_buffer(&s2, FloatArray_msg, &msg), ""))
msg.data_count = 3;
TEST(!pb_encode(&s, FloatArray_msg, &msg))
TEST(!pb_encode_buffer(&s2, FloatArray_msg, &msg))
}
{
uint8_t buffer[10];
pb_ostream_t s;
pb_strstream_t s2;
CallbackArray msg;
COMMENT("Test pb_encode with callback field.")
msg.data.funcs.encode = &fieldcallback;
TEST(WRITES(pb_encode(&s, CallbackArray_msg, &msg), "\x08\x55"))
msg.data.funcs.encode_buffer = &fieldcallback_buf;
TEST(WRITES_BUF(pb_encode_buffer(&s2, CallbackArray_msg, &msg), "\x08\x55"))
}
{
uint8_t buffer[10];
pb_ostream_t s;
pb_strstream_t s2;
IntegerContainer msg = {{0}, {{0}, 5, {1,2,3,4,5}}};
COMMENT("Test pb_encode with packed array in a submessage.")
TEST(WRITES_BOTH(pb_encode(&s, IntegerContainer_msg, &msg),
pb_encode_buffer(&s2, IntegerContainer_msg, &msg),
"\x0A\x07\x0A\x05\x01\x02\x03\x04\x05"))
}
{
uint8_t buffer[10];
pb_ostream_t s;
pb_strstream_t s2;
CallbackContainer msg;
CallbackContainerContainer msg2;
uint32_t state = 1;
COMMENT("Test pb_encode with callback field in a submessage.")
msg.submsg.data.funcs.encode = &fieldcallback;
msg2.submsg.submsg.data.funcs.encode = &fieldcallback;
TEST(WRITES(pb_encode(&s, CallbackContainer_msg, &msg), "\x0A\x02\x08\x55"))
TEST(WRITES(pb_encode(&s, CallbackContainerContainer_msg, &msg2),
"\x0A\x04\x0A\x02\x08\x55"))
msg.submsg.data.funcs.encode_buffer = &fieldcallback_buf;
msg2.submsg.submsg.data.funcs.encode_buffer = &fieldcallback_buf;
TEST(WRITES_BUF(pb_encode_buffer(&s2, CallbackContainer_msg, &msg), "\x0A\x02\x08\x55"))
TEST(WRITES_BUF(pb_encode_buffer(&s2, CallbackContainerContainer_msg, &msg2),
"\x0A\x04\x0A\x02\x08\x55"))
/* Misbehaving callback: varying output between calls */
msg.submsg.data.funcs.encode = &crazyfieldcallback;
msg.submsg.data.arg = &state;
msg2.submsg.submsg.data.funcs.encode = &crazyfieldcallback;
msg2.submsg.submsg.data.arg = &state;
TEST(!pb_encode(&s, CallbackContainer_msg, &msg))
state = 1;
TEST(!pb_encode(&s, CallbackContainerContainer_msg, &msg2))
msg.submsg.data.funcs.encode_buffer = &crazyfieldcallback_buf;
msg.submsg.data.arg = &state;
msg2.submsg.submsg.data.funcs.encode_buffer = &crazyfieldcallback_buf;
msg2.submsg.submsg.data.arg = &state;
TEST(!pb_encode_buffer(&s2, CallbackContainer_msg, &msg))
state = 1;
TEST(!pb_encode_buffer(&s2, CallbackContainerContainer_msg, &msg2))
}
{
uint8_t buffer[30];
pb_ostream_t s;
pb_strstream_t s2;
PointerContainer msg;
DefaultContainer msg2;
IntegerArray msg3;
COMMENT("Test pb_encode with pointer fields.")
memset(&msg, 0, sizeof(msg));
memset(&msg2, 0, sizeof(msg2));
msg.text = "a";
msg.blob.size = 1;
msg.blob.bytes = (uint8_t*)"b";
msg.submsg = &msg2;
TEST(WRITES_BOTH(pb_encode(&s, PointerContainer_msg, &msg),
pb_encode_buffer(&s2, PointerContainer_msg, &msg),
"\x0A\x01\x61\x12\x01\x62\x1A\x00"))
memset(&msg3, 0, sizeof(msg3));
msg.rtext_count = 1;
msg.rtext[0] = "e";
msg.rblob_count = 1;
msg.rblob[0].size = 1;
msg.rblob[0].bytes = (uint8_t*)"f";
msg.rsubmsg_count = 1;
msg.rsubmsg[0] = &msg3;
TEST(WRITES_BOTH(pb_encode(&s, PointerContainer_msg, &msg),
pb_encode_buffer(&s2, PointerContainer_msg, &msg),
"\x0A\x01\x61\x12\x01\x62\x1A\x00"
"\x2A\x01\x65\x32\x01\x66\x3A\x00"));
PointerContainer_set(msg, otext);
msg.otext = "c";
PointerContainer_set(msg, oblob);
msg.oblob.size = 1;
msg.oblob.bytes = (uint8_t*)"d";
TEST(WRITES_BOTH(pb_encode(&s, PointerContainer_msg, &msg),
pb_encode_buffer(&s2, PointerContainer_msg, &msg),
"\x0A\x01\x61\x12\x01\x62\x1A\x00"
"\x2A\x01\x65\x32\x01\x66\x3A\x00"
"\x42\x01\x63\x4A\x01\x64"));
}
if (status != 0)
fprintf(stdout, "\n\nSome tests FAILED!\n");
return status;
}

5
tests/encode_unittests/SConscript
View File

@@ -1,5 +0,0 @@
# Build and run the stand-alone unit tests for the nanopb encoder part.
Import('env')
p = env.Program(["encode_unittests.c", "$COMMON/unittestproto.pb.c"])
env.RunTest(p)

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