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CMakeLists.txt | 1 год назад | |
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Core c99 package for AWS SDK for C. Includes cross-platform primitives, configuration, data structures, and error handling.
This library is licensed under the Apache 2.0 License.
aws-c-common uses CMake for setting up build environments. This library has no non-kernel dependencies so the build is quite simple.
For example:
git clone git@github.com:awslabs/aws-c-common.git aws-c-common
mkdir aws-c-common-build
cd aws-c-common-build
cmake ../aws-c-common
make -j 12
make test
sudo make install
Keep in mind that CMake supports multiple build systems, so for each platform you can pass your own build system
as the -G
option. For example:
cmake -GNinja ../aws-c-common
ninja build
ninja test
sudo ninja install
Or on windows,
cmake -G "Visual Studio 14 2015 Win64" ../aws-c-common
msbuild.exe ALL_BUILD.vcproj
Every API has a specific set of styles and conventions. We'll outline them here. These conventions are followed in every library in the AWS C SDK ecosystem.
Every function that returns an int
type, returns AWS_OP_SUCCESS
( 0 ) or AWS_OP_ERR
(-1) on failure. To retrieve
the error code, use the function aws_last_error()
. Each error code also has a corresponding error string that can be
accessed via the aws_error_str()
function.
In addition, you can install both a global and a thread local error handler by using the aws_set_global_error_handler_fn()
and aws_set_thread_local_error_handler_fn()
functions.
All error functions are in the include/aws/common/error.h
header file.
Any function that allocates and initializes an object will be suffixed with new
(e.g. aws_myobj_new()
). Similarly, these objects will always
have a corresponding function with a destroy
suffix. The new
functions will return the allocated object
on success and NULL
on failure. To respond to the error, call aws_last_error()
. If several new
or destroy
functions are available, the variants should be named like new_x
or destroy_x
(e.g. aws_myobj_new_copy()
or aws_myobj_destroy_secure()
).
Any function that initializes an existing object will be suffixed with init
(e.g. aws_myobj_init()
. These objects will have a corresponding
clean_up
function if necessary. In these cases, you are responsible for making the decisions for how your object is
allocated. The init
functions return AWS_OP_SUCCESS
( 0 ) or AWS_OP_ERR
(-1) on failure. If several init
or
clean_up
functions are available, they should be named like init_x
or clean_up_x
(e.g. aws_myobj_init_static()
or
aws_myobj_clean_up_secure()
).
If you are contributing to this code-base, first off, THANK YOU!. There are a few things to keep in mind to minimize the pull request turn around time.
These "guidelines" are followed in every library in the AWS C SDK ecosystem.
aws_allocator
and use that. No malloc()
or
free()
calls should be made directly.AWS_ERROR_OOM
error code upon allocation failures. If it is a new()
function
it should return NULL. If it is an init()
function, it should return AWS_OP_ERR
.int
error code. The only acceptable return types are AWS_OP_SUCCESS
and AWS_OP_ERR
. Before
returning control to the caller, if you have an error to raise, use the aws_raise_error()
function.NULL
on failure. Before
returning control to the caller, if you have an error to raise, use the aws_raise_error()
function.The logging & error handling infrastructure is designed to support multiple libraries. For this to work, AWS maintained libraries have pre-slotted log subjects & error codes for each library. The currently allocated ranges are:
Range | Library Name |
---|---|
[0x0000, 0x0400) | aws-c-common |
[0x0400, 0x0800) | aws-c-io |
[0x0800, 0x0C00) | aws-c-http |
[0x0C00, 0x1000) | aws-c-compression |
[0x1000, 0x1400) | aws-c-eventstream |
[0x1400, 0x1800) | aws-c-mqtt |
[0x1800, 0x1C00) | aws-c-auth |
[0x1C00, 0x2000) | aws-c-cal |
[0x2000, 0x2400) | aws-crt-cpp |
[0x2400, 0x2800) | aws-crt-java |
[0x2800, 0x2C00) | aws-crt-python |
[0x2C00, 0x3000) | aws-crt-nodejs |
[0x3000, 0x3400) | aws-crt-dotnet |
[0x3400, 0x3800) | aws-c-iot |
[0x3800, 0x3C00) | aws-c-s3 |
[0x3C00, 0x4000) | aws-c-sdkutils |
[0x4000, 0x4400) | (reserved for future project) |
[0x4400, 0x4800) | (reserved for future project) |
Each library should begin its error and log subject values at the beginning of its range and follow in sequence (don't skip codes). Upon adding an AWS maintained library, a new enum range must be approved and added to the above table.
We have a high bar for test coverage, and PRs fixing bugs or introducing new functionality need to have tests before they will be accepted. A couple of tips:
We provide a test harness for writing unit tests. This includes an allocator that will fail your test if you have any
memory leaks, as well as some ASSERT
macros. To write a test:
int test_case_name(struct aws_allocator *, void *ctx)
AWS_TEST_CASE
macro to declare the test.tests/main.c
file.tests/CMakeLists.txt
file.(
.else
and else if
stay on the same line as the closing brace.Example:
if (condition) {
do_something();
} else {
do_something_else();
}
aws/common/common.h
, so feel free to use them.//
.void *impl
pattern. v-tables
should be the last member in the struct.Example:
#ifdef FOO
do_something();
# ifdef BAR
do_something_else();
# endif
#endif
AWS_ERROR_<lib name>_<error name>
.static
(local file scope) variables that are not const
are prefixed by s_
and lower snake case.const
are prefixed by g_
and lower snake case.tl_
and lower snake case.const
variables are upper snake case.Example:
typedef int(fn_name_fn)(void *);
Not:
typedef int(*fn_name_fn)(void *);
extern inline
. It's too unpredictable between compiler versions and language standards.aws_<libname>?_<api>_<what it does>
. Lib name is
not always required if a conflict is not likely and it provides better ergonomics.init
, clean_up
, new
, destroy
are suffixed to the function names for their object.Example:
AWS_COMMON_API
int aws_module_init(aws_module_t *module);
AWS_COMMON_API
void aws_module_clean_up(aws_module_t *module);
AWS_COMMON_API
aws_module_t *aws_module_new(aws_allocator_t *allocator);
AWS_COMMON_API
void aws_module_destroy(aws_module_t *module);
NULL
terminators. Expose struct aws_byte_buf
APIs
and let the user figure it out.Example:
if (options->callback == NULL) {
AWS_LOGF_ERROR(AWS_LS_SOME_SUBJECT, "Invalid options - callback is null");
return aws_raise_error(AWS_ERROR_INVALID_ARGUMENT);
}
if (options->allocator == NULL) {
AWS_LOGF_ERROR(AWS_LS_SOME_SUBJECT, "Invalid options - allocator is null");
return aws_raise_error(AWS_ERROR_INVALID_ARGUMENT);
}
Not:
if (options->callback == NULL || options->allocator == NULL) {
AWS_LOGF_ERROR(AWS_LS_SOME_SUBJECT, "Invalid options - something is null");
return aws_raise_error(AWS_ERROR_INVALID_ARGUMENT);
}
To learn more about CBMC and proofs specifically, review the training material here.
The verification/cbmc/proofs
directory contains CBMC proofs.
In order to run these proofs you will need to install CBMC and other tools by following the instructions here.