mirror of
https://github.com/KolibriOS/kolibrios.git
synced 2024-12-03 22:01:55 +03:00
a5d8ff9f45
git-svn-id: svn://kolibrios.org@6767 a494cfbc-eb01-0410-851d-a64ba20cac60
611 lines
21 KiB
PHP
611 lines
21 KiB
PHP
; Module management, non-PE-specific code.
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; Works in conjuction with peloader.inc for PE-specific code.
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; void* dlopen(const char* filename, int mode)
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; Opens the module named filename and maps it in; returns a handle that can be
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; passed to dlsym to get symbol values from it.
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;
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; If filename starts with '/', it is treated as an absolute file name.
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; Otherwise, dlopen searches for filename in predefined locations:
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; /rd/1/lib, /kolibrios/lib, directory of the executable file.
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; The current directory is *not* searched.
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;
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; If the same module is loaded again with dlopen(), the same
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; handle is returned. The loader maintains reference
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; counts for loaded modules, so a dynamically loaded module is
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; not deallocated until dlclose() has been called on it as many times
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; as dlopen() has succeeded on it. Any initialization functions
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; are called just once.
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;
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; If dlopen() fails for any reason, it returns NULL.
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;
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; mode is reserved and should be zero.
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proc dlopen stdcall uses esi edi, file, mode
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; find_module_by_name and load_module do all the work.
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; We just need to acquire/release the mutex and adjust input/output.
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cmp [mode], 0
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jnz .invalid_mode
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mutex_lock modules_mutex
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mov edi, [file]
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call find_module_by_name
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test esi, esi
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jnz .inc_refcount
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call load_module
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xor edi, edi
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test eax, eax
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jz .unlock_return
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; The handle returned on success is module base address.
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; Unlike pointer to MODULE struct, it can be actually useful
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; for the caller as is.
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mov edi, [eax+MODULE.base]
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jmp .unlock_return
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.inc_refcount:
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inc [esi+MODULE.refcount]
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mov edi, [esi+MODULE.base]
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.unlock_return:
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mutex_unlock modules_mutex
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mov eax, edi
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ret
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.invalid_mode:
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xor eax, eax
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ret
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endp
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; int dlclose(void* handle)
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; Decrements the reference count on the dynamically loaded module
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; referred to by handle. If the reference count drops to zero,
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; then the module is unloaded. All modules that were automatically loaded
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; when dlopen() was invoked on the module referred to by handle are
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; recursively closed in the same manner.
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;
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; A successful return from dlclose() does not guarantee that the
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; module has been actually removed from the caller's address space.
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; In addition to references resulting from explicit dlopen() calls,
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; a module may have been implicitly loaded (and reference counted)
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; because of dependencies in other shared objects.
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; Only when all references have been released can the module be removed
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; from the address space.
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; On success, dlclose() returns 0; on error, it returns a nonzero value.
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proc dlclose stdcall uses esi, handle
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; This function uses two worker functions:
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; find_module_by_addr to map handle -> MODULE,
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; dereference_module for the main work.
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; Aside of calling these, we should only acquire/release the mutex.
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mutex_lock modules_mutex
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mov ecx, [handle]
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call find_module_by_addr
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test esi, esi
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jz .invalid_handle
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call dereference_module
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mutex_unlock modules_mutex
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xor eax, eax
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ret
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.invalid_handle:
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mutex_unlock modules_mutex
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xor eax, eax
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inc eax
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ret
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endp
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; void* dlsym(void* handle, const char* symbol)
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; Obtains address of a symbol in a module.
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; On failure, returns NULL.
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;
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; symbol can also be a number between 0 and 0xFFFF;
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; it is interpreted as an ordinal of a symbol.
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; Low 64K of address space are blocked for the allocation,
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; so a valid pointer cannot be less than 0x10000.
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;
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; handle is not validated. Passing an invalid handle can result in a crash.
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proc dlsym stdcall, handle, symbol
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locals
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export_base dd ?
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export_ptr dd ?
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export_size dd ?
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import_module dd 0
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endl
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; Again, helper functions do all the work.
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; We don't need to browse list of MODULEs,
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; so we don't need to acquire/release the mutex.
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; Unless the function is forwarded or module name is required for error message,
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; but this should be processed by get_exported_function_*.
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mov eax, [handle]
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call prepare_import_from_module
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mov ecx, [symbol]
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cmp ecx, 0x10000
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jb .ordinal
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mov edx, -1 ; no hint for lookup in name table
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call get_exported_function_by_name
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ret
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.ordinal:
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call get_exported_function_by_ordinal
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ret
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endp
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; Errors happen.
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; Some errors should be reported to the user. Some errors are normal.
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; After the process has been initialized, we don't know what an error
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; should mean - is the failed DLL absolutely required or unimportant enhancement?
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; So we report an error to the caller and let it decide how to handle it.
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; However, when the process is initializing, there is no one to report to,
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; so we must inform the user ourselves.
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; In any case, write to the debug board - it is *debug* board, after all.
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;
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; This function is called whenever an error occurs in the loader.
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; Except errors in malloc/realloc - they shouldn't happen anyway,
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; and if they happened after all, we are screwed and likely will fail anyway,
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; so don't bother.
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; Variable number of arguments: strings to be concatenated, end with NULL.
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proc loader_say_error c uses ebx esi, first_msg, ...
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; 1. Concatenate all given strings to the final error message.
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; 1a. Calculate the total length.
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xor ebx, ebx
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lea edx, [first_msg]
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.get_length:
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mov ecx, [edx]
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test ecx, ecx
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jz .length_done
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@@:
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inc ebx
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inc ecx
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cmp byte [ecx-1], 0
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jnz @b
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dec ebx
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add edx, 4
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jmp .get_length
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.length_done:
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inc ebx ; terminating zero
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; 1b. Allocate memory. Exit if failed.
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stdcall malloc, ebx
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test eax, eax
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jz .nothing
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mov esi, eax
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; 1c. Copy data.
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lea edx, [first_msg]
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.copy_data:
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mov ecx, [edx]
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test ecx, ecx
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jz .data_done
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@@:
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mov bl, [ecx]
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test bl, bl
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jz @f
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mov [eax], bl
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inc ecx
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inc eax
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jmp @b
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@@:
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add edx, 4
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jmp .copy_data
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.data_done:
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mov byte [eax], 0 ; terminating zero
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; 2. Print to the debug board.
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mov ecx, loader_debugboard_prefix
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call sys_msg_board_str
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mov ecx, esi
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call sys_msg_board_str
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mov ecx, msg_newline
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call sys_msg_board_str
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; 3. If the initialization is in process, report to the user.
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xor eax, eax
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cmp [process_initialized], al
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jnz .no_report
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; Use @notify. Create structure for function 70.7 on the stack.
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push eax ; to be rewritten with part of path
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push eax ; to be rewritten with part of path
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push eax ; reserved
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push eax ; reserved
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push esi ; command line
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push eax ; flags: none
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push 7
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mov eax, 70
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mov ebx, esp
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mov dword [ebx+21], notify_program
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call FS_SYSCALL_PTR
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add esp, 28
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; Ignore any errors. We can't do anything with them anyway.
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.no_report:
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stdcall free, esi
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.nothing:
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ret
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endp
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; When the loader is initializing the process, errors can happen.
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; They should be reported to the user.
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; The main executable cannot do this, it is not initialized yet.
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; So we should do it ourselves.
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; However, after the process has been initialized, the main
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;
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; Helper function that is called whenever an error is occured.
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; For now, we don't expect many modules in one process.
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; So, all modules are linked into a single list,
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; and lookup functions simply walk the entire list.
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; This should be revisited if dozens of modules would be typical.
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; This structure describes one loaded PE module.
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; malloc'd from the default heap,
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; includes variable-sized module path in the end.
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struct MODULE
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; All modules are linked in the global list with head at modules_list.
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next dd ?
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prev dd ?
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base dd ? ; base address
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size dd ? ; size in memory
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refcount dd ? ; reference counter
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timestamp dd ? ; for bound imports
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basedelta dd ? ; base address - preferred address, for bound imports
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num_imports dd ? ; size of imports array
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imports dd ?
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; Pointer to array of pointers to MODULEs containing imported functions.
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; Used to unload all dependencies when the module is unloaded.
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; Contains all modules referenced by import table;
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; if the module forwards some export to another module,
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; then forward target is added to this array when forward source is requested.
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filename dd ? ; pointer inside path array after dirname
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filenamelen dd ? ; strlen(filename) + 1
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path rb 0
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ends
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; Fills some fields in a new MODULE struct based on given PE image.
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; Assumes that MODULE.path has been filled during the allocation,
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; does not insert the structure in the common list, fills everything else.
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; in: eax -> MODULE
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; in: esi = module base
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proc init_module_struct
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; Straightforward initialization of all non-PE-specific fields.
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lea edx, [eax+MODULE.path]
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mov [eax+MODULE.filename], edx
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@@:
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inc edx
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cmp byte [edx-1], 0
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jz @f
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cmp byte [edx-1], '/'
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jnz @b
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mov [eax+MODULE.filename], edx
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jmp @b
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@@:
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sub edx, [eax+MODULE.filename]
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mov [eax+MODULE.filenamelen], edx
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xor edx, edx
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mov [eax+MODULE.base], esi
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mov [eax+MODULE.refcount], 1
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mov [eax+MODULE.num_imports], edx
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mov [eax+MODULE.imports], edx
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; Let the PE-specific part do its job.
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init_module_struct_pe_specific
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endp
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; Helper function for dlclose and resolving forwarded exports from dlsym.
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; in: ecx = module base address
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; out: esi -> MODULE or esi = NULL
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; modules_mutex should be locked
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proc find_module_by_addr
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; Simple linear lookup in the list.
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mov esi, [modules_list + MODULE.next]
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.scan:
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cmp esi, modules_list
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jz .notfound
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cmp ecx, [esi+MODULE.base]
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jz .found
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mov esi, [esi+MODULE.next]
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jmp .scan
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.notfound:
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xor esi, esi
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.found:
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ret
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endp
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; Helper function for whenever we have a module name
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; and want to check whether it is already loaded.
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; in: edi -> name with or without a path
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; out: esi -> MODULE or esi = NULL
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; modules_mutex should be locked
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proc find_module_by_name uses edi
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; 1. Skip the path, if it is present.
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; eax = current pointer,
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; edi is updated whenever the previous character is '/'
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mov eax, edi
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.find_basename:
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cmp byte [eax], 0
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jz .found_basename
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inc eax
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cmp byte [eax-1], '/'
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jnz .find_basename
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mov edi, eax
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jmp .find_basename
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.found_basename:
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; 2. Simple linear lookup in the list.
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mov eax, [modules_list + MODULE.next]
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.scan:
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cmp eax, modules_list
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jz .notfound
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; For every module, compare base names ignoring paths.
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push edi
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mov esi, [eax+MODULE.filename]
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mov ecx, [eax+MODULE.filenamelen]
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repz cmpsb
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pop edi
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jz .found
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mov eax, [eax+MODULE.next]
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jmp .scan
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.found:
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mov esi, eax
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ret
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.notfound:
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xor esi, esi
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ret
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endp
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; Called when some module is implicitly loaded by another module,
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; either due to a record in import table,
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; or because some exported function forwards to another module.
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; Checks whether the target module has already been referenced
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; by the source module. The first reference is passed down
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; to load_module increasing refcount of the target and possibly
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; loading it if not yet, subsequent references just return
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; without modifying refcount.
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; We don't actually need to deduplicate DLLs from import table
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; as long as we decrement refcount on unload the same number of times
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; that we have incremented it on load.
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; However, we need to keep track of references to forward targets,
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; and we don't want to scan the entire export table and load all forward
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; targets just in case some of those would be useful,
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; so load them on-demand first time and ignore subsequential references.
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; To be consistent, do the same for import table too.
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;
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; in: esi -> source MODULE struct
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; in: edi -> target module name
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; out: eax -> imported MODULE, 0 on error
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; modules_mutex should be locked
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proc load_imported_module uses edi
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; 1. Find the target module in the loaded modules list.
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; If not found, go to 5.
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push esi
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call find_module_by_name
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test esi, esi
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mov eax, esi
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pop esi
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jz .load
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; 2. The module has been already loaded.
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; Now check whether it is already stored in imports array.
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; If yes, just return without doing anything.
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mov edi, [esi+MODULE.imports]
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mov ecx, [esi+MODULE.num_imports]
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test ecx, ecx
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jz .newref
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repnz scasd
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jz .nothing
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.newref:
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; The module is loaded, but not by us.
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; 3. Increment the reference counter of the target.
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inc [eax+MODULE.refcount]
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.add_to_imports:
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; 4. Add the new pointer to the imports array.
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; 4a. Check whether there is place in the array.
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; If so, go to 4c.
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; We don't want to reallocate too often, since reallocation
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; may involve copying our data to a new place.
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; We always reserve space that is a power of two; in this way,
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; the wasted space is never greater than the used space,
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; and total time of copying the data is O(number of modules).
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; The last fact is not really important right now,
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; since the current implementation of step 2 makes everything
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; quadratic and the number of modules is very small anyway,
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; but since this enhancement costs only a few instructions, why not?
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mov edi, eax
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; X is a power of two or zero if and only if (X and (X - 1)) is zero
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mov ecx, [esi+MODULE.num_imports]
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lea edx, [ecx-1]
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test ecx, edx
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jnz .has_space
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; 4b. Reallocate the imports array:
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; if the current size is zero, allocate 1 item,
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; otherwise double number of items.
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; Item size is 4 bytes.
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lea ecx, [ecx*8]
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test ecx, ecx
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jnz @f
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mov ecx, 4
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@@:
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stdcall realloc, [esi+MODULE.imports], ecx
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test eax, eax
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jz .realloc_failed
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mov [esi+MODULE.imports], eax
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mov ecx, [esi+MODULE.num_imports]
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.has_space:
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; 4c. Append pointer to the target MODULE to imports array.
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mov eax, [esi+MODULE.imports]
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mov [eax+ecx*4], edi
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inc [esi+MODULE.num_imports]
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mov eax, edi
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.nothing:
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ret
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.load:
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; 5. This is a totally new module. Load it.
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call load_module
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; On error, return it to the caller. On success, go to 4.
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test eax, eax
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jz .nothing
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jmp .add_to_imports
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.realloc_failed:
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; Out of memory for a couple of dwords? Should not happen.
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; Dereference the target referenced by step 3 or 5
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; and return error to the caller.
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push esi
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mov esi, edi
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call dereference_module
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pop esi
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xor eax, eax
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ret
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endp
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; Helper procedure for load_module.
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; Allocates MODULE structure for (given path) + (module name),
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; calls the kernel to map it,
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; on success, fills the MODULE structure.
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; in: edi -> module name
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; in: ebx = strlen(filename) + 1
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proc try_map_module uses ebx esi, path_ptr, path_len
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; 1. Allocate MODULE structure.
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mov eax, [path_len]
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lea eax, [eax+ebx+MODULE.path]
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stdcall malloc, eax
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test eax, eax
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jz .nothing
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; 2. Create the full name of module in MODULE structure:
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; concatenate module path, if given, and module name.
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mov ecx, [path_len]
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mov esi, [path_ptr]
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push edi
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lea edi, [eax+MODULE.path]
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rep movsb
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mov ecx, ebx
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mov esi, [esp]
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rep movsb
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pop edi
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mov esi, eax
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; 3. Call the kernel to map the module.
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lea ecx, [eax+MODULE.path]
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mov eax, 68
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mov ebx, 28
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call FS_SYSCALL_PTR
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cmp eax, -0x1000
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ja .failed
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; 4. On success, fill the rest of MODULE structure and return it.
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xchg eax, esi
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call init_module_struct
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ret
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.failed:
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; On failure, undo allocation at step 1 and return zero.
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stdcall free, esi
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xor eax, eax
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.nothing:
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ret
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endp
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; Worker procedure for loading a new module.
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; Does not check whether the module has been already loaded;
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; find_module_by_name should be called beforehand.
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; in: edi -> filename
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; out: eax -> MODULE or 0
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; modules_mutex should be locked
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proc load_module uses ebx esi ebp
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; 1. Map the module.
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; 1a. Prepare for try_map_module: calculate length of the name.
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mov ebx, edi
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@@:
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inc ebx
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cmp byte [ebx-1], 0
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jnz @b
|
|
sub ebx, edi
|
|
; 1b. Check whether the given path is absolute.
|
|
; If so, proceed to 1c. If not, go to 1d.
|
|
cmp byte [edi], '/'
|
|
jnz .relative
|
|
; 1c. The given path is absolute. Use it as is. Don't try any other paths.
|
|
stdcall try_map_module, 0, 0
|
|
test eax, eax
|
|
jnz .loaded_ok
|
|
ccall loader_say_error, msg_cannot_open, edi, 0
|
|
jmp .load_failed
|
|
.relative:
|
|
; 1d. The given path is relative.
|
|
; Try /rd/1/lib/, /kolibrios/lib/ and path to executable
|
|
; in this order.
|
|
stdcall try_map_module, module_path1, module_path1.size
|
|
test eax, eax
|
|
jnz .loaded_ok
|
|
stdcall try_map_module, module_path2, module_path2.size
|
|
test eax, eax
|
|
jnz .loaded_ok
|
|
; Note: we assume that the executable is always the first module in the list.
|
|
mov eax, [modules_list + MODULE.next]
|
|
mov ecx, [eax+MODULE.filename]
|
|
add eax, MODULE.path
|
|
mov esi, eax
|
|
sub ecx, eax
|
|
stdcall try_map_module, eax, ecx
|
|
test eax, eax
|
|
jnz .loaded_ok
|
|
mov ebx, dword [esi+MODULE.filename-MODULE.path]
|
|
movzx eax, byte [ebx]
|
|
mov byte [ebx], 0
|
|
push eax
|
|
ccall loader_say_error, msg_cannot_open, edi, msg_paths_begin, esi, 0
|
|
pop eax
|
|
mov byte [ebx], al
|
|
.load_failed:
|
|
xor eax, eax
|
|
ret
|
|
.loaded_ok:
|
|
; Module has been mapped.
|
|
; MODULE structure has been initialized, but not yet inserted in the common list.
|
|
; 2. Insert the MODULE structure in the end of the common list.
|
|
mov esi, eax
|
|
mov eax, [modules_list+MODULE.prev]
|
|
mov [eax+MODULE.next], esi
|
|
mov [esi+MODULE.prev], eax
|
|
mov [modules_list+MODULE.prev], esi
|
|
mov [esi+MODULE.next], modules_list
|
|
; 3. Call PE-specific code to initialize the mapped module.
|
|
push esi
|
|
push edi ; for messages in fixup_pe_relocations
|
|
mov esi, [esi+MODULE.base]
|
|
call fixup_pe_relocations
|
|
pop ecx
|
|
pop esi
|
|
jc .fail_unload
|
|
call resolve_pe_imports
|
|
test eax, eax
|
|
jnz .fail_unload
|
|
mov eax, esi
|
|
ret
|
|
.fail_unload:
|
|
call dereference_module
|
|
xor eax, eax
|
|
ret
|
|
endp
|
|
|
|
; Worker procedure for unloading a module.
|
|
; Drops one reference to the module; if it was the last one,
|
|
; unloads the module and all referenced modules recursively.
|
|
; in: esi -> MODULE struct
|
|
; modules_mutex should be locked
|
|
proc dereference_module
|
|
; 1. Decrement reference counter.
|
|
; If the decremented value is nonzero, exit.
|
|
dec [esi+MODULE.refcount]
|
|
jnz .nothing
|
|
; 2. Remove the module from the common list.
|
|
mov eax, [esi+MODULE.prev]
|
|
mov edx, [esi+MODULE.next]
|
|
mov [eax+MODULE.next], edx
|
|
mov [edx+MODULE.prev], eax
|
|
; 3. Recursively unload dependencies.
|
|
cmp [esi+MODULE.num_imports], 0
|
|
jz .import_deref_done
|
|
.import_deref_loop:
|
|
mov eax, [esi+MODULE.num_imports]
|
|
push esi
|
|
mov esi, [esi+MODULE.imports]
|
|
mov esi, [esi+(eax-1)*4]
|
|
call dereference_module
|
|
pop esi
|
|
dec [esi+MODULE.num_imports]
|
|
jnz .import_deref_loop
|
|
.import_deref_done:
|
|
stdcall free, [esi+MODULE.imports] ; free(NULL) is ok
|
|
; 4. Unmap the module.
|
|
push ebx
|
|
mov eax, 68
|
|
mov ebx, 29
|
|
mov ecx, [esi+MODULE.base]
|
|
call FS_SYSCALL_PTR
|
|
pop ebx
|
|
; 5. Free the MODULE struct.
|
|
stdcall free, esi
|
|
.nothing:
|
|
ret
|
|
endp
|