# What does int (*ret)() = (int(*)())code mean?

Here is a copy of code from shellstorm:

``````#include <stdio.h>
/*
port 31337 (7a69)
*/
#define PORT "\x7a\x69"

unsigned char code[] =
"\x31\xc0\x31\xdb\x31\xc9\x31\xd2"
"\xb0\x66\xb3\x01\x51\x6a\x06\x6a"
"\x01\x6a\x02\x89\xe1\xcd\x80\x89"
"\xc6\xb0\x66\x31\xdb\xb3\x02\x68"
"\xc3\x89\xe1\x6a\x10\x51\x56\x89"
"\xe1\xcd\x80\x31\xc9\xb1\x03\xfe"
"\xc9\xb0\x3f\xcd\x80\x75\xf8\x31"
"\xc0\x52\x68\x6e\x2f\x73\x68\x68"
"\x2f\x2f\x62\x69\x89\xe3\x52\x53"
"\x89\xe1\x52\x89\xe2\xb0\x0b\xcd"
"\x80";

main()
{
printf("Shellcode Length: %d\n", sizeof(code)-1);
int (*ret)() = (int(*)())code;
ret();
}
``````

Could anyone help me explain this one "int (ret)() = (int()())code;" ? How does it work? Why it can make the code above run?

-
This is not kernel code. So `linux-kernel` is not appropriate tag. –  Basile Starynkevitch Feb 22 at 7:57
casting a char pointer to a function pointer! Now that's undefined behaviour. You can only assign a function pointer (any type) to a function pointer. –  ajay Feb 22 at 8:58

``````int(*ret)()
``````

declares a function pointer named `ret`; the function takes unspecified arguments and returns an integer.

``````(int(*)())code
``````

casts the `code` array to a function pointer of that same type.

So this converts the address of the `code` array to a function pointer, which then allows you to call it and execute the code.

Note that this is technically undefined behavior, so it doesn't have to work this way. But this is how practically all implementations compile this code. Shellcodes like this are not expected to be portable -- the bytes in the `code` array are dependent on the CPU architecture and stack frame layout.

-
+1 for mentioning unspecified number and type of arguments. Many people erroneously think that `int func(void)` and `int func()` are the same. They are in `C++` but not in `C`. –  ajay Feb 22 at 7:52
Also casting array to a function pointer is undefined behaviour. Don't know how I missed it. –  ajay Feb 22 at 8:58

You should read a good C programming book.

`int (*ret)()` declare a pointer to function returning an `int` -without specifying arguments (in C)

Then `= (int(*)())code;` is initializing `ret` with the casted address of `code`.

At last `ret();` is calling that function pointer, hence invoking the machine code in your `code` array.

BTW, the compiler (and the linker) might put `code` in a read-only but non-executable segment (this perhaps depends upon how your program was linked). And then your shell code might not work.

-
1+ for the essential BTW. –  alk Feb 22 at 8:04
typecasting the function pointer is redundant here because if `code` has a different signature then it will cause undefined behaviour. –  ajay Feb 22 at 8:23
It is already undefined behavior.... –  Basile Starynkevitch Feb 22 at 8:24
``````int (*ret)()
``````

defines the function pointer `ret` as function returning an `int` with an unspecified number of arguments.

``````... = (int(*)())code;
``````

casts the `unsigned char`-array `code` to the type of function `ret` would refer to and assigns it to `ret`.

This call

``````ret();
``````

then executes the op-codes stored in `code`.

All in all not a nice thing.

-
``````int (*ret)() = (int(*)())code;
``````

`int (*ret)()` defines a pointer that points to a function which returns `int` and has unspecified number of arguments; `(int(*)())code` is a type casting, let the other part could treat `code` as a function pointer, the same type as `ret`.

By the way, depends on the contents of `code`, this code may only works on a specific CPU and OS combination, if it even works and all.

-

Your program will produce undefined behaviour. C99 spec, section 6.2.5, paragraph 27 says:

A pointer to void shall have the same representation and alignment requirements as a pointer to a character type. Similarly, pointers to qualiﬁed or unqualiﬁed versions of compatible types shall have the same representation and alignment requirements. All pointers to structure types shall have the same representation and alignment requirements as each other. All pointers to union types shall have the same representation and alignment requirements as each other. Pointers to other types need not have the same representation or alignment requirements.

Further, in section 6.3.2.3, paragraph 8, it also says:

A pointer to a function of one type may be converted to a pointer to a function of another type and back again; the result shall compare equal to the original pointer.

This means that you should not assign a function pointer to a non-function pointer because the size of a function pointer is not guaranteed to be the same as that of a `char` pointer or a `void` pointer. Now these things out of the way, let's come to your code.

``````int (*ret)() = (int(*)())code;
``````

Let's first take the lhs. So it defines `ret` to be a pointer to a function which takes a fixed but unknown number and type of arguments (doesn't sound good). On the rhs, you are typecasting an array `code`, which evaluates to a pointer to its first element to the same type as `ret`. This is undefined behaviour. Only a function pointer can be assigned to a function pointer, not a pointer to any other type for reasons explained above. Also, `sizeof` operator may not be applied to a function pointer precisely because of this reason.

In `C++`, empty parameter list means `void`, but that's not the case in `C` where it means no information is available to check against argument list provided by the caller. Hence you must explicitly mention `void`. So you should better write that statement as, assuming now that you have a function named `code` defined in your program.

``````int code(void);
int (*ret)(void) = (int(*)(void))code;
``````

To simplify things about complex `C` declarations, `typedef` might help.

``````typedef int (*myfuncptr)(void);
``````

This defines a type `myfuncptr` to be of type `pointer to a function taking no arguments and returning an int`. Next, we can define a variable of `myfuncptr` type like we define a variable of any type in `C`. However please note that `code` must have the same signature as the type of the function `ret` points to. If you cast a function pointer of any other type using `myfuncptr`, it will cause undefined behaviour. Therefore, this makes typecasting redundant.

``````int code(void);
int foo(int);

myfuncptr ret = code; // typecasting not needed. Same as- myfuncptr ret = &code;
myfuncptr bar = (myfuncptr)foo;  // undefined behaviour.
``````

A function name evaluates to a pointer when you assign it to, well, a function pointer of the same type. You don't need to use the address of operator `&`. Similarly, you can call the function pointed to by the pointer without dereferencing it first.

``````ret();     // call the function pointed to by ret
(*ret)()   // deferencing ret first.
``````

Please read this for details - Casting a function pointer to another type. Here's a good resource on how to mentally parse complex `C` declaration - Clockwise/Spiral Rule. Also note that the `C` standard lays down only two acceptable signature of `main`:

``````int main(void);
int main(int argc, char *argv[]);
``````
-

`int (*)()` is the type of a pointer to a function with the following prototype:

``````int func();
``````

Because of the way the language is parsed and the precedence of the operators, one has to put the asterisk in brackets. Also when declaring a pointer variable of that type, the name of the variable goes after the asterisk and not after the type, e.g. it is not

``````int (*)() ret;
``````

but rather

``````int (*ret)();
``````

In your case the `ret` variable is both being declared and initialised with a type cast involved.

To call a function through a function pointer, you could either use the more elaborate syntax:

``````(*ret)();
``````

or the more simple one:

``````ret();
``````

Using the former syntax is preferable since it gives indication to the reader of your code that `ret` is actually a pointer to a function and not the function itself.

Now, in principle that code should not actually work. The `code[]` array is placed in the initialised data segment, which in most modern OSes is not executable, i.e. the call `ret();` should rather produce a segmentation fault. E.g. GCC on Linux places the `code` variable in the `.data` section:

``````.globl code
.data
.align 32
.type   code, @object
.size   code, 93
code:
.string "1\3001\3331...\200"
``````

and then the `.data` section goes into a non-executable read-write segment:

``````\$ readelf --segments code.exe

Elf file type is EXEC (Executable file)
Entry point 0x4003c0
There are 8 program headers, starting at offset 64

FileSiz            MemSiz              Flags  Align
PHDR           0x0000000000000040 0x0000000000400040 0x0000000000400040
0x00000000000001c0 0x00000000000001c0  R E    8
INTERP         0x0000000000000200 0x0000000000400200 0x0000000000400200
0x000000000000001c 0x000000000000001c  R      1
[Requesting program interpreter: /lib64/ld-linux-x86-64.so.2]
0x000000000000064c 0x000000000000064c  R E    100000
vvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvvv
0x0000000000000270 0x0000000000000278  RW     100000
^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
DYNAMIC        0x0000000000000678 0x0000000000500678 0x0000000000500678
0x0000000000000190 0x0000000000000190  RW     8
NOTE           0x000000000000021c 0x000000000040021c 0x000000000040021c
0x0000000000000020 0x0000000000000020  R      4
GNU_EH_FRAME   0x0000000000000594 0x0000000000400594 0x0000000000400594
0x0000000000000024 0x0000000000000024  R      4
GNU_STACK      0x0000000000000000 0x0000000000000000 0x0000000000000000
0x0000000000000000 0x0000000000000000  RW     8

Section to Segment mapping:
Segment Sections...
00
01     .interp
02     .interp .note.ABI-tag .hash .dynsym .dynstr .gnu.version
.gnu.version_r .rela.dyn .rela.plt .init .plt .text .fini
.rodata .eh_frame_hdr .eh_frame
03     .ctors .dtors .jcr .dynamic .got .got.plt .data .bss
^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
04     .dynamic
05     .note.ABI-tag
06     .eh_frame_hdr
07
``````

The segment is missing the executable flag, i.e. it is only `RW` and not `RWE`, therefore no code could be executed from that memory. And indeed, running the program results in a fault at the very first instruction stored in `code`:

``````(gdb) run
Starting program: /tmp/code.exe
Shellcode Length: 92

Program received signal SIGSEGV, Segmentation fault.
0x0000000000500860 in code ()
(gdb) up
#1  0x00000000004004a7 in main () at code.c:27
27     ret();
(gdb) print ret
\$1 = (int (*)()) 0x500860 <code>
``````

To make it work, you could use a combination of `posix_memalign` and `mprotect` to allocate a memory page and make it executable, then copy the content of `code[]` there:

``````// For posix_memalign()
#define _XOPEN_SOURCE 600
#include <stdlib.h>
// For memcpy()
#include <string.h>
// For sysconf()
#include <unistd.h>
// For mprotect()
#include <sys/mman.h>

size_t code_size = sizeof(code) - 1;
size_t page_size = sysconf(_SC_PAGESIZE);
int (*ret)();

printf("Shellcode Length: %d\n", code_size);
posix_memalign(&ret, page_size, page_size);
Also note that the shell code uses `int 0x80` to call into the Linux kernel. This won't work out-of-the-box if the program is compiled on a 64-bit Linux system as there a different mechanism is used to make system calls. `-m32` should be specified in that case to force the compiler generate a 32-bit executable.