docs/syscall_descriptions.md - third_party/syzkaller - Git at Google

 # Syscall descriptions

 `syzkaller` uses declarative description of syscalls to generate, mutate, minimize, serialize and deserialize programs (sequences of syscalls).
 Below you can see (hopefully self-explanatory) excerpt from the description:

 ```
 open(file filename, flags flags[open_flags], mode flags[open_mode]) fd
 read(fd fd, buf buffer[out], count len[buf]) len[buf]
 close(fd fd)
 open_mode = S_IRUSR, S_IWUSR, S_IXUSR, S_IRGRP, S_IWGRP, S_IXGRP, S_IROTH, S_IWOTH, S_IXOTH
 ```

 The description is contained in `sys/linux/*.txt` files.
 For example see the [sys/linux/sys.txt](/sys/linux/sys.txt) file.

 ## Syntax

 The description of the syntax can be found [here](syscall_descriptions_syntax.md).

 ## Code generation

 Textual syscall descriptions are translated into code used by `syzkaller`.
 This process consists of 2 steps.
 The first step is extraction of values of symbolic constants from Linux sources using `syz-extract` utility.
 `syz-extract` generates a small C program that includes kernel headers referenced by `include` directives,
 defines macros as specified by `define` directives and prints values of symbolic constants.
 Results are stored in `.const` files, one per arch.
 For example, [sys/linux/tty.txt](/sys/linux/tty.txt) is translated into [sys/linux/tty_amd64.const](/sys/linux/tty_amd64.const).

 The second step is generation of Go code for syzkaller.
 This step uses syscall descriptions and the const files generated during the first step.
 You can see a result in [sys/linux/gen/amd64.go](/sys/linux/gen/amd64.go) and in [executor/syscalls_linux.h](/executor/syscalls_linux.h).

 ## Describing new system calls

 This section describes how to extend syzkaller to allow fuzz testing of a new system call;
 this is particularly useful for kernel developers who are proposing new system calls.

 First, add a declarative description of the new system call to the appropriate file:
  - Various `sys/linux/<subsystem>.txt` files hold system calls for particular kernel
    subsystems, for example `bpf` or `socket`.
  - [sys/linux/sys.txt](/sys/linux/sys.txt) holds descriptions for more general system calls.
  - An entirely new subsystem can be added as a new `sys/linux/<new>.txt` file.

 The description of the syntax can be found [here](syscall_descriptions_syntax.md).

 If the subsystem is present in the mainline kernel, run `make extract TARGETOS=linux SOURCEDIR=$KSRC`
 with `$KSRC` set to the location of a kernel source tree. This will generate const files.
 Not, that this will overwrite `.config` file you have in `$KSRC`.

 If the subsystem is not present in the mainline kernel, then you need to manually run `syz-extract` binary:
 ```
 make bin/syz-extract
 bin/syz-extract -os linux -arch $ARCH -sourcedir "$LINUX" -builddir "$LINUXBLD" <new>.txt
 ```
 `$ARCH` is one of `amd64`, `386` `arm64`, `arm`, `ppc64le`.
 If the subsystem is supported on several architectures, then run `syz-extract` for each arch.
 `$LINUX` should point to kernel source checkout, which is configured for the corresponding arch (i.e. you need to run `make someconfig && make` there first).
 If the kernel was built into a separate directory (with `make O=...`) then also set `$LINUXBLD` to the location of the build directory.

 Then, run `make generate` which will update generated code.

 Rebuild syzkaller (`make clean all`) to force use of the new system call definitions.

 Optionally, adjust the `enable_syscalls` configuration value for syzkaller to specifically target the new system calls.

 In order to partially auto-generate system call descriptions you can use [headerparser](headerparser_usage.md).
	# Syscall descriptions

	`syzkaller` uses declarative description of syscalls to generate, mutate, minimize, serialize and deserialize programs (sequences of syscalls).
	Below you can see (hopefully self-explanatory) excerpt from the description:

	```
	open(file filename, flags flags[open_flags], mode flags[open_mode]) fd
	read(fd fd, buf buffer[out], count len[buf]) len[buf]
	close(fd fd)
	open_mode = S_IRUSR, S_IWUSR, S_IXUSR, S_IRGRP, S_IWGRP, S_IXGRP, S_IROTH, S_IWOTH, S_IXOTH
	```

	The description is contained in `sys/linux/*.txt` files.
	For example see the [sys/linux/sys.txt](/sys/linux/sys.txt) file.

	## Syntax

	The description of the syntax can be found [here](syscall_descriptions_syntax.md).

	## Code generation

	Textual syscall descriptions are translated into code used by `syzkaller`.
	This process consists of 2 steps.
	The first step is extraction of values of symbolic constants from Linux sources using `syz-extract` utility.
	`syz-extract` generates a small C program that includes kernel headers referenced by `include` directives,
	defines macros as specified by `define` directives and prints values of symbolic constants.
	Results are stored in `.const` files, one per arch.
	For example, [sys/linux/tty.txt](/sys/linux/tty.txt) is translated into [sys/linux/tty_amd64.const](/sys/linux/tty_amd64.const).

	The second step is generation of Go code for syzkaller.
	This step uses syscall descriptions and the const files generated during the first step.
	You can see a result in [sys/linux/gen/amd64.go](/sys/linux/gen/amd64.go) and in [executor/syscalls_linux.h](/executor/syscalls_linux.h).

	## Describing new system calls

	This section describes how to extend syzkaller to allow fuzz testing of a new system call;
	this is particularly useful for kernel developers who are proposing new system calls.

	First, add a declarative description of the new system call to the appropriate file:
	- Various `sys/linux/<subsystem>.txt` files hold system calls for particular kernel
	subsystems, for example `bpf` or `socket`.
	- [sys/linux/sys.txt](/sys/linux/sys.txt) holds descriptions for more general system calls.
	- An entirely new subsystem can be added as a new `sys/linux/<new>.txt` file.

	The description of the syntax can be found [here](syscall_descriptions_syntax.md).

	If the subsystem is present in the mainline kernel, run `make extract TARGETOS=linux SOURCEDIR=$KSRC`
	with `$KSRC` set to the location of a kernel source tree. This will generate const files.
	Not, that this will overwrite `.config` file you have in `$KSRC`.

	If the subsystem is not present in the mainline kernel, then you need to manually run `syz-extract` binary:
	```
	make bin/syz-extract
	bin/syz-extract -os linux -arch $ARCH -sourcedir "$LINUX" -builddir "$LINUXBLD" <new>.txt
	```
	`$ARCH` is one of `amd64`, `386` `arm64`, `arm`, `ppc64le`.
	If the subsystem is supported on several architectures, then run `syz-extract` for each arch.
	`$LINUX` should point to kernel source checkout, which is configured for the corresponding arch (i.e. you need to run `make someconfig && make` there first).
	If the kernel was built into a separate directory (with `make O=...`) then also set `$LINUXBLD` to the location of the build directory.

	Then, run `make generate` which will update generated code.

	Rebuild syzkaller (`make clean all`) to force use of the new system call definitions.

	Optionally, adjust the `enable_syscalls` configuration value for syzkaller to specifically target the new system calls.

	In order to partially auto-generate system call descriptions you can use [headerparser](headerparser_usage.md).