// Windows-specific code // Copyright (c) 2003 Jan Wassenberg // // This program is free software; you can redistribute it and/or // modify it under the terms of the GNU General Public License as // published by the Free Software Foundation; either version 2 of the // License, or (at your option) any later version. // // This program is distributed in the hope that it will be useful, but // WITHOUT ANY WARRANTY; without even the implied warranty of // MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU // General Public License for more details. // // Contact info: // Jan.Wassenberg@stud.uni-karlsruhe.de // http://www.stud.uni-karlsruhe.de/~urkt/ #include "precompiled.h" #include "lib.h" #include "win_internal.h" #include // malloc debug #include #include #include // __argc #include extern HWND hWnd; void sle(int x) { SetLastError((DWORD)x); } char win_sys_dir[MAX_PATH+1]; char win_exe_dir[MAX_PATH+1]; // // these override the portable versions in sysdep.cpp // (they're more convenient) // inline void debug_check_heap() { _heapchk(); } inline int get_executable_name(char* n_path, size_t buf_size) { DWORD nbytes = GetModuleFileName(0, n_path, (DWORD)buf_size); return nbytes? 0 : -1; } void display_msg(const char* caption, const char* msg) { MessageBoxA(0, msg, caption, MB_ICONEXCLAMATION); } void wdisplay_msg(const wchar_t* caption, const wchar_t* msg) { MessageBoxW(0, msg, caption, MB_ICONEXCLAMATION); } int clipboard_set(const wchar_t* text) { int err = -1; if(!OpenClipboard( hWnd )) return err; EmptyClipboard(); err = 0; const size_t len = wcslen(text); HGLOBAL hMem = GlobalAlloc(GMEM_MOVEABLE, (len+1) * sizeof(wchar_t)); if(!hMem) goto fail; wchar_t* copy = (wchar_t*)GlobalLock(hMem); if(copy) { wcscpy(copy, text); GlobalUnlock(hMem); if(SetClipboardData(CF_UNICODETEXT, hMem) != 0) err = 0; // success } fail: CloseClipboard(); return err; } wchar_t* clipboard_get() { wchar_t* ret = 0; if(!OpenClipboard(0)) return 0; // Windows NT/2000+ auto convert UNICODETEXT <-> TEXT HGLOBAL hMem = GetClipboardData(CF_UNICODETEXT); if(hMem != 0) { wchar_t* text = (wchar_t*)GlobalLock(hMem); if(text) { SIZE_T size = GlobalSize(hMem); wchar_t* copy = (wchar_t*)malloc(size); if(copy) { wcscpy(copy, text); ret = copy; } GlobalUnlock(hMem); } } CloseClipboard(); return ret; } int clipboard_free(wchar_t* copy) { free(copy); return 0; } /////////////////////////////////////////////////////////////////////////////// // // init and shutdown mechanism // /////////////////////////////////////////////////////////////////////////////// // init and shutdown mechanism: register a function to be called at // pre-main init or shutdown. // // each module has the linker add a pointer to its init or shutdown // function to a table (at a user-defined position). // zero runtime overhead, and there's no need for a central dispatcher // that knows about all the modules. // // disadvantage: requires compiler support (MS VC-specific). // // alternatives: // - initialize via constructor. however, that would leave the problem of // shutdown order and timepoint, which is also taken care of here. // - register init/shutdown functions from a NLSO constructor: // clunky, and setting order is more difficult. // - on-demand initialization: complicated; don't know in what order // things happen. also, no way to determine how long init takes. // // the "segment name" determines when and in what order the functions are // called: "LIB$W{type}{group}", where {type} is either I for // (pre-main) initializers, or T for terminators (last of the atexit handlers). // {group} is [B, Y]; groups are called in alphabetical order, but // call order within the group itself is unspecified. // // define the segment via #pragma data_seg(name), register any functions // to be called via WIN_REGISTER_FUNC, and then restore the previous segment // with #pragma data_seg() . // // note: group must be [B, Y]. data declared in groups A or Z may // be placed beyond the table start/end by the linker, since the linker's // ordering WRT other source files' data is undefined within a segment. typedef int(*_PIFV)(void); // pointers to start and end of function tables. // note: COFF throws out empty segments, so we have to put in one value // (zero, because call_func_tbl has to ignore NULL entries anyway). #pragma data_seg(".LIB$WIA") _PIFV init_begin[] = { 0 }; #pragma data_seg(".LIB$WIZ") _PIFV init_end[] = { 0 }; #pragma data_seg(".LIB$WTA") _PIFV shutdown_begin[] = { 0 }; #pragma data_seg(".LIB$WTZ") _PIFV shutdown_end[] = { 0 }; #pragma data_seg() #pragma comment(linker, "/merge:.LIB=.data") // call all non-NULL function pointers in [begin, end). // note: the range may be larger than expected due to section padding. // that (and the COFF empty section problem) is why we need to ignore zeroes. static void call_func_tbl(_PIFV* begin, _PIFV* end) { for(_PIFV* p = begin; p < end; p++) if(*p) (*p)(); } /////////////////////////////////////////////////////////////////////////////// // locking for win-specific code // several init functions are called on-demand, possibly from constructors. // can't guarantee POSIX static mutex init has been done by then. static CRITICAL_SECTION cs[NUM_CS]; void win_lock(uint idx) { assert(idx < NUM_CS && "win_lock: invalid critical section index"); EnterCriticalSection(&cs[idx]); } void win_unlock(uint idx) { assert(idx < NUM_CS && "win_unlock: invalid critical section index"); LeaveCriticalSection(&cs[idx]); } /////////////////////////////////////////////////////////////////////////////// // entry -> pre_libc -> WinMainCRTStartup -> WinMain -> pre_main -> main // at_exit is called as the last of the atexit handlers // (assuming, as documented in lib.cpp, constructors don't use atexit!) // // note: this way of getting control before main adds overhead // (setting up the WinMain parameters), but is simpler and safer than // SDL-style #define main SDL_main. static void at_exit(void) { call_func_tbl(shutdown_begin, shutdown_end); for(int i = 0; i < NUM_CS; i++) DeleteCriticalSection(&cs[i]); } // be very careful to avoid non-stateless libc functions! static inline void pre_libc_init() { for(int i = 0; i < NUM_CS; i++) InitializeCriticalSection(&cs[i]); GetSystemDirectory(win_sys_dir, sizeof(win_sys_dir)); if(GetModuleFileName(GetModuleHandle(0), win_exe_dir, MAX_PATH) != 0) { char* slash = strrchr(win_exe_dir, '\\'); if(slash) *slash = '\0'; } } static inline void pre_main_init() { #ifdef HAVE_DEBUGALLOC uint flags = _CrtSetDbgFlag(_CRTDBG_REPORT_FLAG); // Always enable leak detection in debug builds flags |= _CRTDBG_LEAK_CHECK_DF; #ifdef PARANOIA // force malloc et al. to check the heap every call. // slower, but reports errors closer to where they occur. flags |= _CRTDBG_CHECK_ALWAYS_DF | _CRTDBG_DELAY_FREE_MEM_DF; #endif // PARANOIA _CrtSetDbgFlag(flags); #endif // HAVE_DEBUGALLOC call_func_tbl(init_begin, init_end); atexit(at_exit); // no point redirecting stdout yet - the current directory // may be incorrect (file_set_root not yet called). // (w)sdl will take care of it anyway. } // Enable heap corruption checking after every allocation. Has the same // effect as PARANOIA in pre_main_init, but lets you switch it on anywhere // so that you can skip checking the whole of the initialisation code. // The debugger will break in the allocation just after the one that // corrupted the heap, so check its ID and then _CrtSetBreakAlloc(...) // on the previous one and try again. // Warning: This makes things rather slow. void memory_debug_extreme_turbo_plus() { _CrtSetDbgFlag( _CrtSetDbgFlag(_CRTDBG_REPORT_FLAG) | _CRTDBG_CHECK_ALWAYS_DF | _CRTDBG_DELAY_FREE_MEM_DF ); } extern u64 rdtsc(); extern u64 PREVTSC; u64 PREVTSC; int entry() { #ifdef _MSC_VER u64 TSC=rdtsc(); debug_out( "----------------------------------------\n"\ "ENTRY\n"\ "----------------------------------------\n"); PREVTSC=TSC; #endif pre_libc_init(); return WinMainCRTStartup(); // calls _cinit, and then WinMain } int WINAPI WinMain(HINSTANCE, HINSTANCE, LPSTR, int) { pre_main_init(); return main(__argc, __argv); }