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README.md
libcow
Automatic copy-on-write semantic memory slices for use in C (and C++)
Usage
See include/cow.h
for documentation on each function.
C API
Each function, macro, and type definition in the header will be prefixed with cow_
or COW_
. Internal non-prototpyed items use the namespace _cow_
or _COW_
.
C++ wrapper API
The C++ interface defines the type Cow
, a reference-counted wrapper over cow_t
instances that supports cloning through its subtype, Cow::Fake
, and automatically ensures the originally created cow_t
is not destroyed until all its clones are, as well as the namespace _cow_util
which contains memory accessor helpers Span<T>
and Slice<T>
(aka Span<T>::Slice
).
There are also the following:
cow/area.hpp
(namespace_cow_util
) - TheArea
type is a copy-constructable wrapper around bothCow
andCow::Fake
, allowing for implicit cloning.cow/slice.hpp
(namespace_cow_util
) - Contains the definitions forSpan<T>
andSlice<T>
. Included automatically bycow.hpp
(see above).
Building
Run make
to build to build the release
(optimised) target of the library.
It will create four files: libcow-release.a
, libcow-release.so
, libcow.a
, and libcow.so
.
The latter two are just symlinks to the former two.
Run make debug
to build the debug target, which disables optimisations and includes trace messages.
It will create two files: libcow-debug.a
and libcow-debug.so
.
Each target compiles both a static and dynamic library. You may need to run make clean
before switching build targets.
To build both targets, run make all
.
To disable default target-specific (e.g. optimisation) flags, set TARGET_SPEC_FLAGS=no
when running make
.
Run sudo make install
to install the libraries (static and dynamic) and header files (C and C++).
Run sudo make uninstall
to remove the libraries and header files.
By default, the install target is /usr/local/
. Set the PREFIX
variable when running make install
/ make uninstall
to specify a different path.
Full build and installation
$ make && sudo make install
Will build with the default optimisation configuration and install the following files/directories:
- /usr/local/lib/libcow.a
- /usr/local/lib/libcow.so
- /usr/local/include/cow.h
- /usr/local/include/cow.hpp
- /usr/local/include/cow/
Notes
- The
release
target specifies-march=native
by default. This may be undesirable, if so, setTARGET_CPU=""
when runningmake
. - Many optimisation flags for the
release
configuration are specific to GCC (with graphite enabled by default), if builds on other compilers (or non-graphite enabled GCC builds) complain, either set theOPT_FLAGS
env var or remove the problem flags from the Makefile. release
builds are stripped by default. runmake STRIP=: release
to prevent stripping.- The targets are all built with
-fno-strict-aliasing
, but functions in the header file are still annotated withrestrict
needed. This is just to inform users that the function will assume the pointer is not aliased. (When included in C++, whererestrict
is not a keyword, we temporarily define it to be__restrict__
, which is the GCC equivalent for C++).
Using
Link to either libcow.a
or libcow.so
(or the debug target libraries), and include the header include/cow.h
to your project to use this library.
The header should work in C++ projects as well.
Requirements
Relying on the memfd_create()
syscall, Linux >=3.17 and glibc >=2.27 (or equivalent) are required for build.
Makefile is tuned towards gcc
but with some small modifications should work with gcc-similar compilers such as clang
, although this is unintended.
The code itself uses GCC extensions and is targeted at the gnu11
(C11 with GNU extensions) standard.
I have no plan on making this portable at all, either for non-Linux platforms or for ISO C compilers.
(GNU C is superior to ISO C and thankfully the most widely used compilers accept this).
Example
Non-propagation from clones to the origin:
#include <cow.h>
#define SIZE 4096
int main()
{
cow_t* origin = cow_create(SIZE);
strcpy(cow_ptr(origin), "Hello world");
cow_t* fake = cow_clone(origin);
printf("Fake (pre write): %s\n", cow_ptr_of(const char, fake));
strcpy(cow_ptr(fake), "Hello fake!");
printf("Real: %s\n", cow_ptr_of(const char, origin));
printf("Fake: %s\n", cow_ptr_of(const char, fake));
cow_free(fake);
cow_free(origin);
return 0;
}
Will print:
$ ./test
Fake (pre write): Hello world
Real: Hello world
Fake: Hello fake!
Notice the first read of fake
contains the data written to origin
. And that the write of Hello fake!
caused only fake
to be updated, not origin
.
What is happening here?
The cloned slice, fake
, which is created from origin
with the cow_clone()
function will contain all the information within origin
.
The cloned slice can be written to, however, those writes will only be visible to that specific instance of cow_t
, even if that cow_t*
is again cow_clone()
d.
Original or cloned ('fake') slices can be cloned to produce the same effect of a memory slice that starts out containing whatever data is in the original slice created with cow_create()
, and can be modified to produce a automatically and lazily copied slice when written to, to which that instance only will have the results of the write operation.
Each fake slice's data will first appear as the original slice that it comes from. Writing to an original slice will propagate the write to all future clones of that slice, or clones of clones of the slice.
The function cow_is_fake()
can be used to determine if a slice will not propagate its writes to its children.
License
MIT
(this code is not valuable enough to be GPL'd).