react-native-macos/Libraries/fishhook/README.md

# fishhook

__fishhook__ is a very simple library that enables dynamically rebinding symbols in Mach-O binaries running on iOS in the simulator and on device. This provides functionality that is similar to using [`DYLD_INTERPOSE`][interpose] on OS X. At Facebook, we've found it useful as a way to hook calls in libSystem for debugging/tracing purposes (for example, auditing for double-close issues with file descriptors).

[interpose]: http://opensource.apple.com/source/dyld/dyld-210.2.3/include/mach-o/dyld-interposing.h "<mach-o/dyld-interposing.h>"

## Usage

Once you add `fishhook.h`/`fishhook.c` to your project, you can rebind symbols as follows:
```Objective-C
#import <dlfcn.h>

#import <UIKit/UIKit.h>

#import "AppDelegate.h"
#import "fishhook.h"
 
static int (*orig_close)(int);
static int (*orig_open)(const char *, int, ...);
 
int my_close(int fd) {
  printf("Calling real close(%d)\n", fd);
  return orig_close(fd);
}
 
int my_open(const char *path, int oflag, ...) {
  va_list ap = {0};
  mode_t mode = 0;
 
  if ((oflag & O_CREAT) != 0) {
    // mode only applies to O_CREAT
    va_start(ap, oflag);
    mode = va_arg(ap, int);
    va_end(ap);
    printf("Calling real open('%s', %d, %d)\n", path, oflag, mode);
    return orig_open(path, oflag, mode);
  } else {
    printf("Calling real open('%s', %d)\n", path, oflag);
    return orig_open(path, oflag, mode);
  }
}
 
int main(int argc, char * argv[])
{
  @autoreleasepool {
    rebind_symbols((struct rebinding[2]){{"close", my_close, (void *)&orig_close}, {"open", my_open, (void *)&orig_open}}, 2);
 
    // Open our own binary and print out first 4 bytes (which is the same
    // for all Mach-O binaries on a given architecture)
    int fd = open(argv[0], O_RDONLY);
    uint32_t magic_number = 0;
    read(fd, &magic_number, 4);
    printf("Mach-O Magic Number: %x \n", magic_number);
    close(fd);
 
    return UIApplicationMain(argc, argv, nil, NSStringFromClass([AppDelegate class]));
  }
}
```
### Sample output
```
Calling real open('/var/mobile/Applications/161DA598-5B83-41F5-8A44-675491AF6A2C/Test.app/Test', 0)
Mach-O Magic Number: feedface 
Calling real close(3)
...
```

## How it works

`dyld` binds lazy and non-lazy symbols by updating pointers in particular sections of the `__DATA` segment of a Mach-O binary. __fishhook__ re-binds these symbols by determining the locations to update for each of the symbol names passed to `rebind_symbols` and then writing out the corresponding replacements.

For a given image, the `__DATA` segment may contain two sections that are relevant for dynamic symbol bindings: `__nl_symbol_ptr` and `__la_symbol_ptr`. `__nl_symbol_ptr` is an array of pointers to non-lazily bound data (these are bound at the time a library is loaded) and `__la_symbol_ptr` is an array of pointers to imported functions that is generally filled by a routine called `dyld_stub_binder` during the first call to that symbol (it's also possible to tell `dyld` to bind these at launch). In order to find the name of the symbol that corresponds to a particular location in one of these sections, we have to jump through several layers of indirection. For the two relevant sections, the section headers (`struct section`s from `<mach-o/loader.h>`) provide an offset (in the `reserved1` field) into what is known as the indirect symbol table. The indirect symbol table, which is located in the `__LINKEDIT` segment of the binary, is just an array of indexes into the symbol table (also in `__LINKEDIT`) whose order is identical to that of the pointers in the non-lazy and lazy symbol sections. So, given `struct section nl_symbol_ptr`, the corresponding index in the symbol table of the first address in that section is `indirect_symbol_table[nl_symbol_ptr->reserved1]`. The symbol table itself is an array of `struct nlist`s (see `<mach-o/nlist.h>`), and each `nlist` contains an index into the string table in `__LINKEDIT` which where the actual symbol names are stored. So, for each pointer `__nl_symbol_ptr` and `__la_symbol_ptr`, we are able to find the corresponding symbol and then the corresponding string to compare against the requested symbol names, and if there is a match, we replace the pointer in the section with the replacement.

The process of looking up the name of a given entry in the lazy or non-lazy pointer tables looks like this:
![Visual explanation](http://i.imgur.com/HVXqHCz.png)
fishhook nwlog_legacy_v to avoid log spam on websocket reconnect Reviewed By: mmmulani, javache Differential Revision: D5570896 fbshipit-source-id: be98f500434bd2a0113b9abca20c9f21102c09d1 2017-08-08 18:10:51 +03:00			`# fishhook`

			__fishhook__ is a very simple library that enables dynamically rebinding symbols in Mach-O binaries running on iOS in the simulator and on device. This provides functionality that is similar to using [`DYLD_INTERPOSE`][interpose] on OS X. At Facebook, we've found it useful as a way to hook calls in libSystem for debugging/tracing purposes (for example, auditing for double-close issues with file descriptors).

			`[interpose]: http://opensource.apple.com/source/dyld/dyld-210.2.3/include/mach-o/dyld-interposing.h "<mach-o/dyld-interposing.h>"`

			`## Usage`

			Once you add `fishhook.h`/`fishhook.c` to your project, you can rebind symbols as follows:
			```Objective-C
			`#import <dlfcn.h>`

			`#import <UIKit/UIKit.h>`

			`#import "AppDelegate.h"`
			`#import "fishhook.h"`

			`static int (*orig_close)(int);`
			`static int (orig_open)(const char , int, ...);`

			`int my_close(int fd) {`
			`printf("Calling real close(%d)\n", fd);`
			`return orig_close(fd);`
			`}`

			`int my_open(const char *path, int oflag, ...) {`
			`va_list ap = {0};`
			`mode_t mode = 0;`

			`if ((oflag & O_CREAT) != 0) {`
			`// mode only applies to O_CREAT`
			`va_start(ap, oflag);`
			`mode = va_arg(ap, int);`
			`va_end(ap);`
			`printf("Calling real open('%s', %d, %d)\n", path, oflag, mode);`
			`return orig_open(path, oflag, mode);`
			`} else {`
			`printf("Calling real open('%s', %d)\n", path, oflag);`
			`return orig_open(path, oflag, mode);`
			`}`
			`}`

			`int main(int argc, char * argv[])`
			`{`
			`@autoreleasepool {`
			`rebind_symbols((struct rebinding[2]){{"close", my_close, (void )&orig_close}, {"open", my_open, (void )&orig_open}}, 2);`

			`// Open our own binary and print out first 4 bytes (which is the same`
			`// for all Mach-O binaries on a given architecture)`
			`int fd = open(argv[0], O_RDONLY);`
			`uint32_t magic_number = 0;`
			`read(fd, &magic_number, 4);`
			`printf("Mach-O Magic Number: %x \n", magic_number);`
			`close(fd);`

			`return UIApplicationMain(argc, argv, nil, NSStringFromClass([AppDelegate class]));`
			`}`
			`}`
			```
			`### Sample output`
			```
			`Calling real open('/var/mobile/Applications/161DA598-5B83-41F5-8A44-675491AF6A2C/Test.app/Test', 0)`
			`Mach-O Magic Number: feedface`
			`Calling real close(3)`
			`...`
			```

			`## How it works`

			`dyld` binds lazy and non-lazy symbols by updating pointers in particular sections of the `__DATA` segment of a Mach-O binary. __fishhook__ re-binds these symbols by determining the locations to update for each of the symbol names passed to `rebind_symbols` and then writing out the corresponding replacements.

			For a given image, the `__DATA` segment may contain two sections that are relevant for dynamic symbol bindings: `__nl_symbol_ptr` and `__la_symbol_ptr`. `__nl_symbol_ptr` is an array of pointers to non-lazily bound data (these are bound at the time a library is loaded) and `__la_symbol_ptr` is an array of pointers to imported functions that is generally filled by a routine called `dyld_stub_binder` during the first call to that symbol (it's also possible to tell `dyld` to bind these at launch). In order to find the name of the symbol that corresponds to a particular location in one of these sections, we have to jump through several layers of indirection. For the two relevant sections, the section headers (`struct section`s from `<mach-o/loader.h>`) provide an offset (in the `reserved1` field) into what is known as the indirect symbol table. The indirect symbol table, which is located in the `__LINKEDIT` segment of the binary, is just an array of indexes into the symbol table (also in `__LINKEDIT`) whose order is identical to that of the pointers in the non-lazy and lazy symbol sections. So, given `struct section nl_symbol_ptr`, the corresponding index in the symbol table of the first address in that section is `indirect_symbol_table[nl_symbol_ptr->reserved1]`. The symbol table itself is an array of `struct nlist`s (see `<mach-o/nlist.h>`), and each `nlist` contains an index into the string table in `__LINKEDIT` which where the actual symbol names are stored. So, for each pointer `__nl_symbol_ptr` and `__la_symbol_ptr`, we are able to find the corresponding symbol and then the corresponding string to compare against the requested symbol names, and if there is a match, we replace the pointer in the section with the replacement.

			`The process of looking up the name of a given entry in the lazy or non-lazy pointer tables looks like this:`
			`![Visual explanation](http://i.imgur.com/HVXqHCz.png)`