/* =========================================================================== 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 =========================================================================== */ #include "vm_local.h" #ifdef DEBUG_VM // bk001204 static char *opnames[256] = { "OP_UNDEF", "OP_IGNORE", "OP_BREAK", "OP_ENTER", "OP_LEAVE", "OP_CALL", "OP_PUSH", "OP_POP", "OP_CONST", "OP_LOCAL", "OP_JUMP", //------------------- "OP_EQ", "OP_NE", "OP_LTI", "OP_LEI", "OP_GTI", "OP_GEI", "OP_LTU", "OP_LEU", "OP_GTU", "OP_GEU", "OP_EQF", "OP_NEF", "OP_LTF", "OP_LEF", "OP_GTF", "OP_GEF", //------------------- "OP_LOAD1", "OP_LOAD2", "OP_LOAD4", "OP_STORE1", "OP_STORE2", "OP_STORE4", "OP_ARG", "OP_BLOCK_COPY", //------------------- "OP_SEX8", "OP_SEX16", "OP_NEGI", "OP_ADD", "OP_SUB", "OP_DIVI", "OP_DIVU", "OP_MODI", "OP_MODU", "OP_MULI", "OP_MULU", "OP_BAND", "OP_BOR", "OP_BXOR", "OP_BCOM", "OP_LSH", "OP_RSHI", "OP_RSHU", "OP_NEGF", "OP_ADDF", "OP_SUBF", "OP_DIVF", "OP_MULF", "OP_CVIF", "OP_CVFI" }; #endif #if idppc #if defined(__GNUC__) static inline unsigned int loadWord(void *addr) { unsigned int word; asm("lwbrx %0,0,%1" : "=r" (word) : "r" (addr)); return word; } #else #define loadWord(addr) __lwbrx(addr,0) #endif #else #define loadWord(addr) *((int *)addr) #endif char *VM_Indent( vm_t *vm ) { static char *string = " "; if ( vm->callLevel > 20 ) { return string; } return string + 2 * ( 20 - vm->callLevel ); } void VM_StackTrace( vm_t *vm, int programCounter, int programStack ) { int count; count = 0; do { Com_Printf( "%s\n", VM_ValueToSymbol( vm, programCounter ) ); programStack = *(int *)&vm->dataBase[programStack+4]; programCounter = *(int *)&vm->dataBase[programStack]; } while ( programCounter != -1 && ++count < 32 ); } /* ==================== VM_PrepareInterpreter ==================== */ void VM_PrepareInterpreter( vm_t *vm, vmHeader_t *header ) { int op; int pc; byte *code; int instruction; int *codeBase; vm->codeBase = Hunk_Alloc( vm->codeLength*4, h_high ); // we're now int aligned // memcpy( vm->codeBase, (byte *)header + header->codeOffset, vm->codeLength ); // we don't need to translate the instructions, but we still need // to find each instructions starting point for jumps pc = 0; instruction = 0; code = (byte *)header + header->codeOffset; codeBase = (int *)vm->codeBase; while ( instruction < header->instructionCount ) { vm->instructionPointers[ instruction ] = pc; instruction++; op = code[ pc ]; codeBase[pc] = op; if ( pc > header->codeLength ) { Com_Error( ERR_FATAL, "VM_PrepareInterpreter: pc > header->codeLength" ); } pc++; // these are the only opcodes that aren't a single byte switch ( op ) { case OP_ENTER: case OP_CONST: case OP_LOCAL: case OP_LEAVE: case OP_EQ: case OP_NE: case OP_LTI: case OP_LEI: case OP_GTI: case OP_GEI: case OP_LTU: case OP_LEU: case OP_GTU: case OP_GEU: case OP_EQF: case OP_NEF: case OP_LTF: case OP_LEF: case OP_GTF: case OP_GEF: case OP_BLOCK_COPY: codeBase[pc+0] = loadWord(&code[pc]); pc += 4; break; case OP_ARG: codeBase[pc+0] = code[pc]; pc += 1; break; default: break; } } pc = 0; instruction = 0; code = (byte *)header + header->codeOffset; codeBase = (int *)vm->codeBase; while ( instruction < header->instructionCount ) { op = code[ pc ]; instruction++; pc++; switch ( op ) { case OP_ENTER: case OP_CONST: case OP_LOCAL: case OP_LEAVE: case OP_EQ: case OP_NE: case OP_LTI: case OP_LEI: case OP_GTI: case OP_GEI: case OP_LTU: case OP_LEU: case OP_GTU: case OP_GEU: case OP_EQF: case OP_NEF: case OP_LTF: case OP_LEF: case OP_GTF: case OP_GEF: case OP_BLOCK_COPY: switch(op) { case OP_EQ: case OP_NE: case OP_LTI: case OP_LEI: case OP_GTI: case OP_GEI: case OP_LTU: case OP_LEU: case OP_GTU: case OP_GEU: case OP_EQF: case OP_NEF: case OP_LTF: case OP_LEF: case OP_GTF: case OP_GEF: codeBase[pc] = vm->instructionPointers[codeBase[pc]]; break; default: break; } pc += 4; break; case OP_ARG: pc += 1; break; default: break; } } } /* ============== VM_Call Upon a system call, the stack will look like: sp+32 parm1 sp+28 parm0 sp+24 return stack 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) //#define DEBUG_VM #define DEBUGSTR va("%s%i", VM_Indent(vm), opStack-stack ) int VM_CallInterpreted( vm_t *vm, int *args ) { int stack[MAX_STACK]; int *opStack; int programCounter; int programStack; int stackOnEntry; byte *image; int *codeImage; int v1; int dataMask; #ifdef DEBUG_VM vmSymbol_t *profileSymbol; #endif // interpret the code vm->currentlyInterpreting = qtrue; // we might be called recursively, so this might not be the very top programStack = stackOnEntry = vm->programStack; #ifdef DEBUG_VM profileSymbol = VM_ValueToFunctionSymbol( vm, 0 ); // uncomment this for debugging breakpoints vm->breakFunction = 0; #endif // set up the stack frame image = vm->dataBase; codeImage = (int *)vm->codeBase; dataMask = vm->dataMask; // leave a free spot at start of stack so // that as long as opStack is valid, opStack-1 will // not corrupt anything opStack = stack; programCounter = 0; programStack -= 48; *(int *)&image[ programStack + 44] = args[9]; *(int *)&image[ programStack + 40] = args[8]; *(int *)&image[ programStack + 36] = args[7]; *(int *)&image[ programStack + 32] = args[6]; *(int *)&image[ programStack + 28] = args[5]; *(int *)&image[ programStack + 24] = args[4]; *(int *)&image[ programStack + 20] = args[3]; *(int *)&image[ programStack + 16] = args[2]; *(int *)&image[ programStack + 12] = args[1]; *(int *)&image[ programStack + 8 ] = args[0]; *(int *)&image[ programStack + 4 ] = 0; // return stack *(int *)&image[ programStack ] = -1; // will terminate the loop on return vm->callLevel = 0; VM_Debug(0); // vm_debugLevel=2; // main interpreter loop, will exit when a LEAVE instruction // grabs the -1 program counter #define r2 codeImage[programCounter] while ( 1 ) { int opcode, r0, r1; // unsigned int r2; nextInstruction: r0 = ((int *)opStack)[0]; r1 = ((int *)opStack)[-1]; nextInstruction2: opcode = codeImage[ programCounter++ ]; #ifdef DEBUG_VM if ( (unsigned)programCounter > vm->codeLength ) { Com_Error( ERR_DROP, "VM pc out of range" ); } if ( opStack < stack ) { Com_Error( ERR_DROP, "VM opStack underflow" ); } if ( opStack >= stack+MAX_STACK ) { Com_Error( ERR_DROP, "VM opStack overflow" ); } if ( programStack <= vm->stackBottom ) { Com_Error( ERR_DROP, "VM stack overflow" ); } if ( programStack & 3 ) { Com_Error( ERR_DROP, "VM program stack misaligned" ); } if ( vm_debugLevel > 1 ) { Com_Printf( "%s %s\n", DEBUGSTR, opnames[opcode] ); } profileSymbol->profileCount++; #endif switch ( opcode ) { #ifdef DEBUG_VM default: Com_Error( ERR_DROP, "Bad VM instruction" ); // this should be scanned on load! #endif case OP_BREAK: vm->breakCount++; goto nextInstruction2; case OP_CONST: opStack++; r1 = r0; r0 = *opStack = r2; programCounter += 4; goto nextInstruction2; case OP_LOCAL: opStack++; r1 = r0; r0 = *opStack = r2+programStack; programCounter += 4; goto nextInstruction2; case OP_LOAD4: #ifdef DEBUG_VM if ( *opStack & 3 ) { Com_Error( ERR_DROP, "OP_LOAD4 misaligned" ); } #endif r0 = *opStack = *(int *)&image[ r0&dataMask ]; goto nextInstruction2; case OP_LOAD2: r0 = *opStack = *(unsigned short *)&image[ r0&dataMask ]; goto nextInstruction2; case OP_LOAD1: r0 = *opStack = image[ r0&dataMask ]; goto nextInstruction2; case OP_STORE4: *(int *)&image[ r1&(dataMask & ~3) ] = r0; opStack -= 2; goto nextInstruction; case OP_STORE2: *(short *)&image[ r1&(dataMask & ~1) ] = r0; opStack -= 2; goto nextInstruction; case OP_STORE1: image[ r1&dataMask ] = r0; opStack -= 2; goto nextInstruction; case OP_ARG: // single byte offset from programStack *(int *)&image[ codeImage[programCounter] + programStack ] = r0; opStack--; programCounter += 1; goto nextInstruction; case OP_BLOCK_COPY: { int *src, *dest; int i, count, srci, desti; count = r2; // MrE: copy range check srci = r0 & dataMask; desti = r1 & dataMask; count = ((srci + count) & dataMask) - srci; count = ((desti + count) & dataMask) - desti; src = (int *)&image[ r0&dataMask ]; dest = (int *)&image[ r1&dataMask ]; if ( ( (long)src | (long)dest | count ) & 3 ) { Com_Error( ERR_DROP, "OP_BLOCK_COPY not dword aligned" ); } count >>= 2; for ( i = count-1 ; i>= 0 ; i-- ) { dest[i] = src[i]; } programCounter += 4; opStack -= 2; } goto nextInstruction; case OP_CALL: // save current program counter *(int *)&image[ programStack ] = programCounter; // jump to the location on the stack programCounter = r0; opStack--; if ( programCounter < 0 ) { // system call int r; int temp; #ifdef DEBUG_VM int stomped; if ( vm_debugLevel ) { Com_Printf( "%s---> systemcall(%i)\n", DEBUGSTR, -1 - programCounter ); } #endif // save the stack to allow recursive VM entry temp = vm->callLevel; vm->programStack = programStack - 4; #ifdef DEBUG_VM stomped = *(int *)&image[ programStack + 4 ]; #endif *(int *)&image[ programStack + 4 ] = -1 - programCounter; //VM_LogSyscalls( (int *)&image[ programStack + 4 ] ); r = vm->systemCall( (int *)&image[ programStack + 4 ] ); #ifdef DEBUG_VM // this is just our stack frame pointer, only needed // for debugging *(int *)&image[ programStack + 4 ] = stomped; #endif // save return value opStack++; *opStack = r; programCounter = *(int *)&image[ programStack ]; vm->callLevel = temp; #ifdef DEBUG_VM if ( vm_debugLevel ) { Com_Printf( "%s<--- %s\n", DEBUGSTR, VM_ValueToSymbol( vm, programCounter ) ); } #endif } else { programCounter = vm->instructionPointers[ programCounter ]; } goto nextInstruction; // push and pop are only needed for discarded or bad function return values case OP_PUSH: opStack++; goto nextInstruction; case OP_POP: opStack--; goto nextInstruction; case OP_ENTER: #ifdef DEBUG_VM profileSymbol = VM_ValueToFunctionSymbol( vm, programCounter ); #endif // get size of stack frame v1 = r2; programCounter += 4; programStack -= v1; #ifdef DEBUG_VM // save old stack frame for debugging traces *(int *)&image[programStack+4] = programStack + v1; if ( vm_debugLevel ) { Com_Printf( "%s---> %s\n", DEBUGSTR, VM_ValueToSymbol( vm, programCounter - 5 ) ); if ( vm->breakFunction && programCounter - 5 == vm->breakFunction ) { // this is to allow setting breakpoints here in the debugger vm->breakCount++; // vm_debugLevel = 2; // VM_StackTrace( vm, programCounter, programStack ); } vm->callLevel++; } #endif goto nextInstruction; case OP_LEAVE: // remove our stack frame v1 = r2; programStack += v1; // grab the saved program counter programCounter = *(int *)&image[ programStack ]; #ifdef DEBUG_VM profileSymbol = VM_ValueToFunctionSymbol( vm, programCounter ); if ( vm_debugLevel ) { vm->callLevel--; Com_Printf( "%s<--- %s\n", DEBUGSTR, VM_ValueToSymbol( vm, programCounter ) ); } #endif // check for leaving the VM if ( programCounter == -1 ) { goto done; } goto nextInstruction; /* =================================================================== BRANCHES =================================================================== */ case OP_JUMP: programCounter = r0; programCounter = vm->instructionPointers[ programCounter ]; opStack--; goto nextInstruction; case OP_EQ: opStack -= 2; if ( r1 == r0 ) { programCounter = r2; //vm->instructionPointers[r2]; goto nextInstruction; } else { programCounter += 4; goto nextInstruction; } case OP_NE: opStack -= 2; if ( r1 != r0 ) { programCounter = r2; //vm->instructionPointers[r2]; goto nextInstruction; } else { programCounter += 4; goto nextInstruction; } case OP_LTI: opStack -= 2; if ( r1 < r0 ) { programCounter = r2; //vm->instructionPointers[r2]; goto nextInstruction; } else { programCounter += 4; goto nextInstruction; } case OP_LEI: opStack -= 2; if ( r1 <= r0 ) { programCounter = r2; //vm->instructionPointers[r2]; goto nextInstruction; } else { programCounter += 4; goto nextInstruction; } case OP_GTI: opStack -= 2; if ( r1 > r0 ) { programCounter = r2; //vm->instructionPointers[r2]; goto nextInstruction; } else { programCounter += 4; goto nextInstruction; } case OP_GEI: opStack -= 2; if ( r1 >= r0 ) { programCounter = r2; //vm->instructionPointers[r2]; goto nextInstruction; } else { programCounter += 4; goto nextInstruction; } case OP_LTU: opStack -= 2; if ( ((unsigned)r1) < ((unsigned)r0) ) { programCounter = r2; //vm->instructionPointers[r2]; goto nextInstruction; } else { programCounter += 4; goto nextInstruction; } case OP_LEU: opStack -= 2; if ( ((unsigned)r1) <= ((unsigned)r0) ) { programCounter = r2; //vm->instructionPointers[r2]; goto nextInstruction; } else { programCounter += 4; goto nextInstruction; } case OP_GTU: opStack -= 2; if ( ((unsigned)r1) > ((unsigned)r0) ) { programCounter = r2; //vm->instructionPointers[r2]; goto nextInstruction; } else { programCounter += 4; goto nextInstruction; } case OP_GEU: opStack -= 2; if ( ((unsigned)r1) >= ((unsigned)r0) ) { programCounter = r2; //vm->instructionPointers[r2]; goto nextInstruction; } else { programCounter += 4; goto nextInstruction; } case OP_EQF: if ( ((float *)opStack)[-1] == *(float *)opStack ) { programCounter = r2; //vm->instructionPointers[r2]; opStack -= 2; goto nextInstruction; } else { programCounter += 4; opStack -= 2; goto nextInstruction; } case OP_NEF: if ( ((float *)opStack)[-1] != *(float *)opStack ) { programCounter = r2; //vm->instructionPointers[r2]; opStack -= 2; goto nextInstruction; } else { programCounter += 4; opStack -= 2; goto nextInstruction; } case OP_LTF: if ( ((float *)opStack)[-1] < *(float *)opStack ) { programCounter = r2; //vm->instructionPointers[r2]; opStack -= 2; goto nextInstruction; } else { programCounter += 4; opStack -= 2; goto nextInstruction; } case OP_LEF: if ( ((float *)opStack)[-1] <= *(float *)opStack ) { programCounter = r2; //vm->instructionPointers[r2]; opStack -= 2; goto nextInstruction; } else { programCounter += 4; opStack -= 2; goto nextInstruction; } case OP_GTF: if ( ((float *)opStack)[-1] > *(float *)opStack ) { programCounter = r2; //vm->instructionPointers[r2]; opStack -= 2; goto nextInstruction; } else { programCounter += 4; opStack -= 2; goto nextInstruction; } case OP_GEF: if ( ((float *)opStack)[-1] >= *(float *)opStack ) { programCounter = r2; //vm->instructionPointers[r2]; opStack -= 2; goto nextInstruction; } else { programCounter += 4; opStack -= 2; goto nextInstruction; } //=================================================================== case OP_NEGI: *opStack = -r0; goto nextInstruction; case OP_ADD: opStack[-1] = r1 + r0; opStack--; goto nextInstruction; case OP_SUB: opStack[-1] = r1 - r0; opStack--; goto nextInstruction; case OP_DIVI: opStack[-1] = r1 / r0; opStack--; goto nextInstruction; case OP_DIVU: opStack[-1] = ((unsigned)r1) / ((unsigned)r0); opStack--; goto nextInstruction; case OP_MODI: opStack[-1] = r1 % r0; opStack--; goto nextInstruction; case OP_MODU: opStack[-1] = ((unsigned)r1) % (unsigned)r0; opStack--; goto nextInstruction; case OP_MULI: opStack[-1] = r1 * r0; opStack--; goto nextInstruction; case OP_MULU: opStack[-1] = ((unsigned)r1) * ((unsigned)r0); opStack--; goto nextInstruction; case OP_BAND: opStack[-1] = ((unsigned)r1) & ((unsigned)r0); opStack--; goto nextInstruction; case OP_BOR: opStack[-1] = ((unsigned)r1) | ((unsigned)r0); opStack--; goto nextInstruction; case OP_BXOR: opStack[-1] = ((unsigned)r1) ^ ((unsigned)r0); opStack--; goto nextInstruction; case OP_BCOM: opStack[-1] = ~ ((unsigned)r0); goto nextInstruction; case OP_LSH: opStack[-1] = r1 << r0; opStack--; goto nextInstruction; case OP_RSHI: opStack[-1] = r1 >> r0; opStack--; goto nextInstruction; case OP_RSHU: opStack[-1] = ((unsigned)r1) >> r0; opStack--; goto nextInstruction; case OP_NEGF: *(float *)opStack = -*(float *)opStack; goto nextInstruction; case OP_ADDF: *(float *)(opStack-1) = *(float *)(opStack-1) + *(float *)opStack; opStack--; goto nextInstruction; case OP_SUBF: *(float *)(opStack-1) = *(float *)(opStack-1) - *(float *)opStack; opStack--; goto nextInstruction; case OP_DIVF: *(float *)(opStack-1) = *(float *)(opStack-1) / *(float *)opStack; opStack--; goto nextInstruction; case OP_MULF: *(float *)(opStack-1) = *(float *)(opStack-1) * *(float *)opStack; opStack--; goto nextInstruction; case OP_CVIF: *(float *)opStack = (float)*opStack; goto nextInstruction; case OP_CVFI: *opStack = (int) *(float *)opStack; goto nextInstruction; case OP_SEX8: *opStack = (signed char)*opStack; goto nextInstruction; case OP_SEX16: *opStack = (short)*opStack; goto nextInstruction; } } done: vm->currentlyInterpreting = qfalse; if ( opStack != &stack[1] ) { Com_Error( ERR_DROP, "Interpreter error: opStack = %i", opStack - stack ); } vm->programStack = stackOnEntry; // return the result return *opStack; }