/* =========================================================================== Copyright (C) 1999-2005 Id Software, Inc. This file is part of Quake III Arena source code. Quake III Arena source code 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. Quake III Arena source code 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. You should have received a copy of the GNU General Public License along with Foobar; if not, write to the Free Software Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA =========================================================================== */ // vm.c -- virtual machine /* intermix code and data symbol table a dll has one imported function: VM_SystemCall and one exported function: Perform */ #include "vm_local.h" vm_t *currentVM = NULL; // bk001212 vm_t *lastVM = NULL; // bk001212 int vm_debugLevel; #define MAX_VM 3 vm_t vmTable[MAX_VM]; void VM_VmInfo_f( void ); void VM_VmProfile_f( void ); #if 0 // 64bit! // converts a VM pointer to a C pointer and // checks to make sure that the range is acceptable void *VM_VM2C( vmptr_t p, int length ) { return (void *)p; } #endif void VM_Debug( int level ) { vm_debugLevel = level; } /* ============== VM_Init ============== */ void VM_Init( void ) { Cvar_Get( "vm_cgame", "2", CVAR_ARCHIVE ); // !@# SHIP WITH SET TO 2 Cvar_Get( "vm_game", "2", CVAR_ARCHIVE ); // !@# SHIP WITH SET TO 2 Cvar_Get( "vm_ui", "2", CVAR_ARCHIVE ); // !@# SHIP WITH SET TO 2 Cmd_AddCommand ("vmprofile", VM_VmProfile_f ); Cmd_AddCommand ("vminfo", VM_VmInfo_f ); Com_Memset( vmTable, 0, sizeof( vmTable ) ); } /* =============== VM_ValueToSymbol Assumes a program counter value =============== */ const char *VM_ValueToSymbol( vm_t *vm, int value ) { vmSymbol_t *sym; static char text[MAX_TOKEN_CHARS]; sym = vm->symbols; if ( !sym ) { return "NO SYMBOLS"; } // find the symbol while ( sym->next && sym->next->symValue <= value ) { sym = sym->next; } if ( value == sym->symValue ) { return sym->symName; } Com_sprintf( text, sizeof( text ), "%s+%i", sym->symName, value - sym->symValue ); return text; } /* =============== VM_ValueToFunctionSymbol For profiling, find the symbol behind this value =============== */ vmSymbol_t *VM_ValueToFunctionSymbol( vm_t *vm, int value ) { vmSymbol_t *sym; static vmSymbol_t nullSym; sym = vm->symbols; if ( !sym ) { return &nullSym; } while ( sym->next && sym->next->symValue <= value ) { sym = sym->next; } return sym; } /* =============== VM_SymbolToValue =============== */ int VM_SymbolToValue( vm_t *vm, const char *symbol ) { vmSymbol_t *sym; for ( sym = vm->symbols ; sym ; sym = sym->next ) { if ( !strcmp( symbol, sym->symName ) ) { return sym->symValue; } } return 0; } /* ===================== VM_SymbolForCompiledPointer ===================== */ #if 0 // 64bit! const char *VM_SymbolForCompiledPointer( vm_t *vm, void *code ) { int i; if ( code < (void *)vm->codeBase ) { return "Before code block"; } if ( code >= (void *)(vm->codeBase + vm->codeLength) ) { return "After code block"; } // find which original instruction it is after for ( i = 0 ; i < vm->codeLength ; i++ ) { if ( (void *)vm->instructionPointers[i] > code ) { break; } } i--; // now look up the bytecode instruction pointer return VM_ValueToSymbol( vm, i ); } #endif /* =============== ParseHex =============== */ int ParseHex( const char *text ) { int value; int c; value = 0; while ( ( c = *text++ ) != 0 ) { if ( c >= '0' && c <= '9' ) { value = value * 16 + c - '0'; continue; } if ( c >= 'a' && c <= 'f' ) { value = value * 16 + 10 + c - 'a'; continue; } if ( c >= 'A' && c <= 'F' ) { value = value * 16 + 10 + c - 'A'; continue; } } return value; } /* =============== VM_LoadSymbols =============== */ void VM_LoadSymbols( vm_t *vm ) { int len; char *mapfile, *text_p, *token; char name[MAX_QPATH]; char symbols[MAX_QPATH]; vmSymbol_t **prev, *sym; int count; int value; int chars; int segment; int numInstructions; // don't load symbols if not developer if ( !com_developer->integer ) { return; } COM_StripExtension( vm->name, name ); Com_sprintf( symbols, sizeof( symbols ), "vm/%s.map", name ); len = FS_ReadFile( symbols, (void **)&mapfile ); if ( !mapfile ) { Com_Printf( "Couldn't load symbol file: %s\n", symbols ); return; } numInstructions = vm->instructionPointersLength >> 2; // parse the symbols text_p = mapfile; prev = &vm->symbols; count = 0; while ( 1 ) { token = COM_Parse( &text_p ); if ( !token[0] ) { break; } segment = ParseHex( token ); if ( segment ) { COM_Parse( &text_p ); COM_Parse( &text_p ); continue; // only load code segment values } token = COM_Parse( &text_p ); if ( !token[0] ) { Com_Printf( "WARNING: incomplete line at end of file\n" ); break; } value = ParseHex( token ); token = COM_Parse( &text_p ); if ( !token[0] ) { Com_Printf( "WARNING: incomplete line at end of file\n" ); break; } chars = strlen( token ); sym = Hunk_Alloc( sizeof( *sym ) + chars, h_high ); *prev = sym; prev = &sym->next; sym->next = NULL; // convert value from an instruction number to a code offset if ( value >= 0 && value < numInstructions ) { value = vm->instructionPointers[value]; } sym->symValue = value; Q_strncpyz( sym->symName, token, chars + 1 ); count++; } vm->numSymbols = count; Com_Printf( "%i symbols parsed from %s\n", count, symbols ); FS_FreeFile( mapfile ); } /* ============ VM_DllSyscall Dlls will call this directly rcg010206 The horror; the horror. The syscall mechanism relies on stack manipulation to get it's args. This is likely due to C's inability to pass "..." parameters to a function in one clean chunk. On PowerPC Linux, these parameters are not necessarily passed on the stack, so while (&arg[0] == arg) is true, (&arg[1] == 2nd function parameter) is not necessarily accurate, as arg's value might have been stored to the stack or other piece of scratch memory to give it a valid address, but the next parameter might still be sitting in a register. Quake's syscall system also assumes that the stack grows downward, and that any needed types can be squeezed, safely, into a signed int. This hack below copies all needed values for an argument to a array in memory, so that Quake can get the correct values. This can also be used on systems where the stack grows upwards, as the presumably standard and safe stdargs.h macros are used. As for having enough space in a signed int for your datatypes, well, it might be better to wait for DOOM 3 before you start porting. :) The original code, while probably still inherently dangerous, seems to work well enough for the platforms it already works on. Rather than add the performance hit for those platforms, the original code is still in use there. For speed, we just grab 15 arguments, and don't worry about exactly how many the syscall actually needs; the extra is thrown away. ============ */ long QDECL VM_DllSyscall( long arg, ... ) { #if ((defined __GNUC__) && !(defined __i386__)) // rcg010206 - see commentary above long args[16]; int i; va_list ap; args[0] = arg; va_start(ap, arg); for (i = 1; i < sizeof (args) / sizeof (args[i]); i++) args[i] = va_arg(ap, long); va_end(ap); return currentVM->systemCall( args ); #else // original id code return currentVM->systemCall( &arg ); #endif } /* ================= VM_LoadQVM Load a .qvm file ================= */ vmHeader_t *VM_LoadQVM( vm_t *vm, qboolean alloc ) { int length; int dataLength; int i; char filename[MAX_QPATH]; vmHeader_t *header; // load the image Com_sprintf( filename, sizeof(filename), "vm/%s.qvm", vm->name ); Com_Printf( "Loading vm file %s...\n", filename ); length = FS_ReadFile( filename, (void **)&header ); if ( !header ) { Com_Printf( "Failed.\n" ); VM_Free( vm ); return NULL; } if( LittleLong( header->vmMagic ) == VM_MAGIC_VER2 ) { Com_Printf( "...which has vmMagic VM_MAGIC_VER2\n" ); // byte swap the header for ( i = 0 ; i < sizeof( vmHeader_t ) / 4 ; i++ ) { ((int *)header)[i] = LittleLong( ((int *)header)[i] ); } // validate if ( header->jtrgLength < 0 || header->bssLength < 0 || header->dataLength < 0 || header->litLength < 0 || header->codeLength <= 0 ) { VM_Free( vm ); Com_Error( ERR_FATAL, "%s has bad header", filename ); } } else if( LittleLong( header->vmMagic ) == VM_MAGIC ) { // byte swap the header // sizeof( vmHeader_t ) - sizeof( int ) is the 1.32b vm header size for ( i = 0 ; i < ( sizeof( vmHeader_t ) - sizeof( int ) ) / 4 ; i++ ) { ((int *)header)[i] = LittleLong( ((int *)header)[i] ); } // validate if ( header->bssLength < 0 || header->dataLength < 0 || header->litLength < 0 || header->codeLength <= 0 ) { VM_Free( vm ); Com_Error( ERR_FATAL, "%s has bad header", filename ); } } else { VM_Free( vm ); Com_Error( ERR_FATAL, "%s does not have a recognisable " "magic number in its header", filename ); } // round up to next power of 2 so all data operations can // be mask protected dataLength = header->dataLength + header->litLength + header->bssLength; for ( i = 0 ; dataLength > ( 1 << i ) ; i++ ) { } dataLength = 1 << i; if( alloc ) { // allocate zero filled space for initialized and uninitialized data vm->dataBase = Hunk_Alloc( dataLength, h_high ); vm->dataMask = dataLength - 1; } else { // clear the data Com_Memset( vm->dataBase, 0, dataLength ); } // copy the intialized data Com_Memcpy( vm->dataBase, (byte *)header + header->dataOffset, header->dataLength + header->litLength ); // byte swap the longs for ( i = 0 ; i < header->dataLength ; i += 4 ) { *(int *)(vm->dataBase + i) = LittleLong( *(int *)(vm->dataBase + i ) ); } if( header->vmMagic == VM_MAGIC_VER2 ) { vm->numJumpTableTargets = header->jtrgLength >> 2; Com_Printf( "Loading %d jump table targets\n", vm->numJumpTableTargets ); if( alloc ) { vm->jumpTableTargets = Hunk_Alloc( header->jtrgLength, h_high ); } else { Com_Memset( vm->jumpTableTargets, 0, header->jtrgLength ); } Com_Memcpy( vm->jumpTableTargets, (byte *)header + header->dataOffset + header->dataLength + header->litLength, header->jtrgLength ); // byte swap the longs for ( i = 0 ; i < header->jtrgLength ; i += 4 ) { *(int *)(vm->jumpTableTargets + i) = LittleLong( *(int *)(vm->jumpTableTargets + i ) ); } } return header; } /* ================= VM_Restart Reload the data, but leave everything else in place This allows a server to do a map_restart without changing memory allocation ================= */ vm_t *VM_Restart( vm_t *vm ) { vmHeader_t *header; // DLL's can't be restarted in place if ( vm->dllHandle ) { char name[MAX_QPATH]; long (*systemCall)( long *parms ); systemCall = vm->systemCall; Q_strncpyz( name, vm->name, sizeof( name ) ); VM_Free( vm ); vm = VM_Create( name, systemCall, VMI_NATIVE ); return vm; } // load the image Com_Printf( "VM_Restart()\n" ); if( !( header = VM_LoadQVM( vm, qfalse ) ) ) { Com_Error( ERR_DROP, "VM_Restart failed.\n" ); return NULL; } // free the original file FS_FreeFile( header ); return vm; } /* ================ VM_Create If image ends in .qvm it will be interpreted, otherwise it will attempt to load as a system dll ================ */ #define STACK_SIZE 0x20000 vm_t *VM_Create( const char *module, long (*systemCalls)(long *), vmInterpret_t interpret ) { vm_t *vm; vmHeader_t *header; int i, remaining; if ( !module || !module[0] || !systemCalls ) { Com_Error( ERR_FATAL, "VM_Create: bad parms" ); } remaining = Hunk_MemoryRemaining(); // see if we already have the VM for ( i = 0 ; i < MAX_VM ; i++ ) { if (!Q_stricmp(vmTable[i].name, module)) { vm = &vmTable[i]; return vm; } } // find a free vm for ( i = 0 ; i < MAX_VM ; i++ ) { if ( !vmTable[i].name[0] ) { break; } } if ( i == MAX_VM ) { Com_Error( ERR_FATAL, "VM_Create: no free vm_t" ); } vm = &vmTable[i]; Q_strncpyz( vm->name, module, sizeof( vm->name ) ); vm->systemCall = systemCalls; #if defined(HAVE_VM_NATIVE) // never allow dll loading with a demo if ( interpret == VMI_NATIVE ) { if ( Cvar_VariableValue( "fs_restrict" ) ) { interpret = VMI_COMPILED; } } if ( interpret == VMI_NATIVE ) { // try to load as a system dll Com_Printf( "Loading dll file %s.\n", vm->name ); vm->dllHandle = Sys_LoadDll( module, vm->fqpath , &vm->entryPoint, VM_DllSyscall ); if ( vm->dllHandle ) { return vm; } Com_Printf( "Failed to load dll, looking for qvm.\n" ); interpret = VMI_COMPILED; } #else if ( interpret == VMI_NATIVE ) { Com_Printf("Architecture doesn't support native dll's, using qvm\n"); interpret = VMI_COMPILED; } #endif // load the image if( !( header = VM_LoadQVM( vm, qtrue ) ) ) { return NULL; } // allocate space for the jump targets, which will be filled in by the compile/prep functions vm->instructionPointersLength = header->instructionCount * 4; vm->instructionPointers = Hunk_Alloc( vm->instructionPointersLength, h_high ); // copy or compile the instructions vm->codeLength = header->codeLength; #if !defined(HAVE_VM_COMPILED) if(interpret >= VMI_COMPILED) { Com_Printf("Architecture doesn't have a bytecode compiler, using interpreter\n"); interpret = VMI_BYTECODE; } #else if ( interpret >= VMI_COMPILED ) { vm->compiled = qtrue; VM_Compile( vm, header ); } else #endif { vm->compiled = qfalse; VM_PrepareInterpreter( vm, header ); } // free the original file FS_FreeFile( header ); // load the map file VM_LoadSymbols( vm ); // the stack is implicitly at the end of the image vm->programStack = vm->dataMask + 1; vm->stackBottom = vm->programStack - STACK_SIZE; Com_Printf("%s loaded in %d bytes on the hunk\n", module, remaining - Hunk_MemoryRemaining()); return vm; } /* ============== VM_Free ============== */ void VM_Free( vm_t *vm ) { if ( vm->dllHandle ) { Sys_UnloadDll( vm->dllHandle ); Com_Memset( vm, 0, sizeof( *vm ) ); } #if 0 // now automatically freed by hunk if ( vm->codeBase ) { Z_Free( vm->codeBase ); } if ( vm->dataBase ) { Z_Free( vm->dataBase ); } if ( vm->instructionPointers ) { Z_Free( vm->instructionPointers ); } #endif Com_Memset( vm, 0, sizeof( *vm ) ); currentVM = NULL; lastVM = NULL; } void VM_Clear(void) { int i; for (i=0;ientryPoint ) { return (void *)(currentVM->dataBase + intValue); } else { return (void *)(currentVM->dataBase + (intValue & currentVM->dataMask)); } } void *VM_ExplicitArgPtr( vm_t *vm, long intValue ) { if ( !intValue ) { return NULL; } // bk010124 - currentVM is missing on reconnect here as well? if ( currentVM==NULL ) return NULL; // if ( vm->entryPoint ) { return (void *)(vm->dataBase + intValue); } else { return (void *)(vm->dataBase + (intValue & vm->dataMask)); } } /* ============== VM_Call Upon a system call, the stack will look like: sp+32 parm1 sp+28 parm0 sp+24 return value sp+20 return address sp+16 local1 sp+14 local0 sp+12 arg1 sp+8 arg0 sp+4 return stack sp return address An interpreted function will immediately execute an OP_ENTER instruction, which will subtract space for locals from sp ============== */ #define MAX_STACK 256 #define STACK_MASK (MAX_STACK-1) long QDECL VM_Call( vm_t *vm, long callnum, ... ) { vm_t *oldVM; int r; int i; if ( !vm ) { Com_Error( ERR_FATAL, "VM_Call with NULL vm" ); } oldVM = currentVM; currentVM = vm; lastVM = vm; if ( vm_debugLevel ) { Com_Printf( "VM_Call( %ld )\n", callnum ); } // if we have a dll loaded, call it directly if ( vm->entryPoint ) { //rcg010207 - see dissertation at top of VM_DllSyscall() in this file. long args[16]; va_list ap; va_start(ap, callnum); for (i = 0; i < sizeof (args) / sizeof (args[i]); i++) { args[i] = va_arg(ap, long); } va_end(ap); r = vm->entryPoint( callnum, args[0], args[1], args[2], args[3], args[4], args[5], args[6], args[7], args[8], args[9], args[10], args[11], args[12], args[13], args[14], args[15]); } else { #ifdef __i386__ // i386 calling convention doesn't need conversion #if defined(HAVE_VM_COMPILED) if ( vm->compiled ) r = VM_CallCompiled( vm, (int*)&callnum ); else #endif r = VM_CallInterpreted( vm, (int*)&callnum ); #else struct { int callnum; int args[16]; } a; va_list ap; a.callnum = callnum; va_start(ap, callnum); for (i = 0; i < sizeof (a.args) / sizeof (a.args[0]); i++) { a.args[i] = va_arg(ap, long); } va_end(ap); #if defined(HAVE_VM_COMPILED) if ( vm->compiled ) r = VM_CallCompiled( vm, &a.callnum ); else #endif r = VM_CallInterpreted( vm, &a.callnum ); #endif } if ( oldVM != NULL ) // bk001220 - assert(currentVM!=NULL) for oldVM==NULL currentVM = oldVM; return r; } //================================================================= static int QDECL VM_ProfileSort( const void *a, const void *b ) { vmSymbol_t *sa, *sb; sa = *(vmSymbol_t **)a; sb = *(vmSymbol_t **)b; if ( sa->profileCount < sb->profileCount ) { return -1; } if ( sa->profileCount > sb->profileCount ) { return 1; } return 0; } /* ============== VM_VmProfile_f ============== */ void VM_VmProfile_f( void ) { vm_t *vm; vmSymbol_t **sorted, *sym; int i; double total; if ( !lastVM ) { return; } vm = lastVM; if ( !vm->numSymbols ) { return; } sorted = Z_Malloc( vm->numSymbols * sizeof( *sorted ) ); sorted[0] = vm->symbols; total = sorted[0]->profileCount; for ( i = 1 ; i < vm->numSymbols ; i++ ) { sorted[i] = sorted[i-1]->next; total += sorted[i]->profileCount; } qsort( sorted, vm->numSymbols, sizeof( *sorted ), VM_ProfileSort ); for ( i = 0 ; i < vm->numSymbols ; i++ ) { int perc; sym = sorted[i]; perc = 100 * (float) sym->profileCount / total; Com_Printf( "%2i%% %9i %s\n", perc, sym->profileCount, sym->symName ); sym->profileCount = 0; } Com_Printf(" %9.0f total\n", total ); Z_Free( sorted ); } /* ============== VM_VmInfo_f ============== */ void VM_VmInfo_f( void ) { vm_t *vm; int i; Com_Printf( "Registered virtual machines:\n" ); for ( i = 0 ; i < MAX_VM ; i++ ) { vm = &vmTable[i]; if ( !vm->name[0] ) { break; } Com_Printf( "%s : ", vm->name ); if ( vm->dllHandle ) { Com_Printf( "native\n" ); continue; } if ( vm->compiled ) { Com_Printf( "compiled on load\n" ); } else { Com_Printf( "interpreted\n" ); } Com_Printf( " code length : %7i\n", vm->codeLength ); Com_Printf( " table length: %7i\n", vm->instructionPointersLength ); Com_Printf( " data length : %7i\n", vm->dataMask + 1 ); } } /* =============== VM_LogSyscalls Insert calls to this while debugging the vm compiler =============== */ void VM_LogSyscalls( int *args ) { static int callnum; static FILE *f; if ( !f ) { f = fopen("syscalls.log", "w" ); } callnum++; fprintf(f, "%i: %li (%i) = %i %i %i %i\n", callnum, (long)(args - (int *)currentVM->dataBase), args[0], args[1], args[2], args[3], args[4] ); } #ifdef DLL_ONLY // bk010215 - for DLL_ONLY dedicated servers/builds w/o VM int VM_CallCompiled( vm_t *vm, int *args ) { return(0); } void VM_Compile( vm_t *vm, vmHeader_t *header ) {} #endif // DLL_ONLY