/* Copyright (C) 1996-1997 Id Software, Inc. 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. You should have received a copy of the GNU General Public License along with this program; if not, write to the Free Software Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA. */ #include "quakedef.h" /* */ typedef struct { int s; dfunction_t *f; } prstack_t; #define MAX_STACK_DEPTH 32 prstack_t pr_stack[MAX_STACK_DEPTH]; int pr_depth; #define LOCALSTACK_SIZE 2048 int localstack[LOCALSTACK_SIZE]; int localstack_used; qboolean pr_trace; dfunction_t *pr_xfunction; int pr_xstatement; int pr_argc; char *pr_opnames[] = { "DONE", "MUL_F", "MUL_V", "MUL_FV", "MUL_VF", "DIV", "ADD_F", "ADD_V", "SUB_F", "SUB_V", "EQ_F", "EQ_V", "EQ_S", "EQ_E", "EQ_FNC", "NE_F", "NE_V", "NE_S", "NE_E", "NE_FNC", "LE", "GE", "LT", "GT", "INDIRECT", "INDIRECT", "INDIRECT", "INDIRECT", "INDIRECT", "INDIRECT", "ADDRESS", "STORE_F", "STORE_V", "STORE_S", "STORE_ENT", "STORE_FLD", "STORE_FNC", "STOREP_F", "STOREP_V", "STOREP_S", "STOREP_ENT", "STOREP_FLD", "STOREP_FNC", "RETURN", "NOT_F", "NOT_V", "NOT_S", "NOT_ENT", "NOT_FNC", "IF", "IFNOT", "CALL0", "CALL1", "CALL2", "CALL3", "CALL4", "CALL5", "CALL6", "CALL7", "CALL8", "STATE", "GOTO", "AND", "OR", "BITAND", "BITOR" }; char *PR_GlobalString (int ofs); char *PR_GlobalStringNoContents (int ofs); //============================================================================= /* ================= PR_PrintStatement ================= */ void PR_PrintStatement (dstatement_t *s) { int i; if ( (unsigned)s->op < sizeof(pr_opnames)/sizeof(pr_opnames[0])) { Con_Printf ("%s ", pr_opnames[s->op]); i = strlen(pr_opnames[s->op]); for ( ; i<10 ; i++) Con_Printf (" "); } if (s->op == OP_IF || s->op == OP_IFNOT) Con_Printf ("%sbranch %i",PR_GlobalString((unsigned short) s->a),s->b); else if (s->op == OP_GOTO) { Con_Printf ("branch %i",s->a); } else if ( (unsigned)(s->op - OP_STORE_F) < 6) { Con_Printf ("%s",PR_GlobalString((unsigned short) s->a)); Con_Printf ("%s", PR_GlobalStringNoContents((unsigned short) s->b)); } else { if (s->a) Con_Printf ("%s",PR_GlobalString((unsigned short) s->a)); if (s->b) Con_Printf ("%s",PR_GlobalString((unsigned short) s->b)); if (s->c) Con_Printf ("%s", PR_GlobalStringNoContents((unsigned short) s->c)); } Con_Printf ("\n"); } /* ============ PR_StackTrace ============ */ void PR_StackTrace (void) { dfunction_t *f; int i; if (pr_depth == 0) { Con_Printf ("\n"); return; } pr_stack[pr_depth].f = pr_xfunction; for (i=pr_depth ; i>=0 ; i--) { f = pr_stack[i].f; if (!f) { Con_Printf ("\n"); } else Con_Printf ("%12s : %s\n", pr_strings + f->s_file, pr_strings + f->s_name); } } /* ============ PR_Profile_f ============ */ void PR_Profile_f (void) { dfunction_t *f, *best; int max; int num; int i; num = 0; do { max = 0; best = NULL; for (i=0 ; inumfunctions ; i++) { f = &pr_functions[i]; if (f->profile > max) { max = f->profile; best = f; } } if (best) { if (num < 10) Con_Printf ("%7i %s\n", best->profile, pr_strings+best->s_name); num++; best->profile = 0; } } while (best); } /* ============ PR_RunError Aborts the currently executing function ============ */ void PR_RunError (char *error, ...) { va_list argptr; char string[1024]; va_start (argptr,error); vsprintf (string,error,argptr); va_end (argptr); PR_PrintStatement (pr_statements + pr_xstatement); PR_StackTrace (); Con_Printf ("%s\n", string); pr_depth = 0; // dump the stack so host_error can shutdown functions Host_Error ("Program error"); } /* ============================================================================ PR_ExecuteProgram The interpretation main loop ============================================================================ */ /* ==================== PR_EnterFunction Returns the new program statement counter ==================== */ int PR_EnterFunction (dfunction_t *f) { int i, j, c, o; pr_stack[pr_depth].s = pr_xstatement; pr_stack[pr_depth].f = pr_xfunction; pr_depth++; if (pr_depth >= MAX_STACK_DEPTH) PR_RunError ("stack overflow"); // save off any locals that the new function steps on c = f->locals; if (localstack_used + c > LOCALSTACK_SIZE) PR_RunError ("PR_ExecuteProgram: locals stack overflow\n"); for (i=0 ; i < c ; i++) localstack[localstack_used+i] = ((int *)pr_globals)[f->parm_start + i]; localstack_used += c; // copy parameters o = f->parm_start; for (i=0 ; inumparms ; i++) { for (j=0 ; jparm_size[i] ; j++) { ((int *)pr_globals)[o] = ((int *)pr_globals)[OFS_PARM0+i*3+j]; o++; } } pr_xfunction = f; return f->first_statement - 1; // offset the s++ } /* ==================== PR_LeaveFunction ==================== */ int PR_LeaveFunction (void) { int i, c; if (pr_depth <= 0) Host_Error ("prog stack underflow"); // restore locals from the stack c = pr_xfunction->locals; localstack_used -= c; if (localstack_used < 0) PR_RunError ("PR_ExecuteProgram: locals stack underflow\n"); for (i=0 ; i < c ; i++) ((int *)pr_globals)[pr_xfunction->parm_start + i] = localstack[localstack_used+i]; // up stack pr_depth--; pr_xfunction = pr_stack[pr_depth].f; return pr_stack[pr_depth].s; } /* ==================== PR_ExecuteProgram ==================== */ // LordHavoc: optimized #define OPA ((eval_t *)&pr_globals[(unsigned short) st->a]) #define OPB ((eval_t *)&pr_globals[(unsigned short) st->b]) #define OPC ((eval_t *)&pr_globals[(unsigned short) st->c]) extern cvar_t pr_boundscheck; void PR_ExecuteProgram (func_t fnum, char *errormessage) { dstatement_t *st; dfunction_t *f, *newf; edict_t *ed; int exitdepth; eval_t *ptr; int profile, startprofile; if (!fnum || fnum >= progs->numfunctions) { if (pr_global_struct->self) ED_Print (PROG_TO_EDICT(pr_global_struct->self)); Host_Error ("PR_ExecuteProgram: %s", errormessage); } f = &pr_functions[fnum]; pr_trace = false; // make a stack frame exitdepth = pr_depth; st = &pr_statements[PR_EnterFunction (f)]; startprofile = profile = 0; if (pr_boundscheck.value) { while (1) { st++; if (++profile > 1000000) // LordHavoc: increased runaway loop limit 10x { pr_xstatement = st - pr_statements; PR_RunError ("runaway loop error"); } if (pr_trace) PR_PrintStatement (st); switch (st->op) { case OP_ADD_F: OPC->_float = OPA->_float + OPB->_float; break; case OP_ADD_V: OPC->vector[0] = OPA->vector[0] + OPB->vector[0]; OPC->vector[1] = OPA->vector[1] + OPB->vector[1]; OPC->vector[2] = OPA->vector[2] + OPB->vector[2]; break; case OP_SUB_F: OPC->_float = OPA->_float - OPB->_float; break; case OP_SUB_V: OPC->vector[0] = OPA->vector[0] - OPB->vector[0]; OPC->vector[1] = OPA->vector[1] - OPB->vector[1]; OPC->vector[2] = OPA->vector[2] - OPB->vector[2]; break; case OP_MUL_F: OPC->_float = OPA->_float * OPB->_float; break; case OP_MUL_V: OPC->_float = OPA->vector[0]*OPB->vector[0] + OPA->vector[1]*OPB->vector[1] + OPA->vector[2]*OPB->vector[2]; break; case OP_MUL_FV: OPC->vector[0] = OPA->_float * OPB->vector[0]; OPC->vector[1] = OPA->_float * OPB->vector[1]; OPC->vector[2] = OPA->_float * OPB->vector[2]; break; case OP_MUL_VF: OPC->vector[0] = OPB->_float * OPA->vector[0]; OPC->vector[1] = OPB->_float * OPA->vector[1]; OPC->vector[2] = OPB->_float * OPA->vector[2]; break; case OP_DIV_F: OPC->_float = OPA->_float / OPB->_float; break; case OP_BITAND: OPC->_float = (int)OPA->_float & (int)OPB->_float; break; case OP_BITOR: OPC->_float = (int)OPA->_float | (int)OPB->_float; break; case OP_GE: OPC->_float = OPA->_float >= OPB->_float; break; case OP_LE: OPC->_float = OPA->_float <= OPB->_float; break; case OP_GT: OPC->_float = OPA->_float > OPB->_float; break; case OP_LT: OPC->_float = OPA->_float < OPB->_float; break; case OP_AND: OPC->_float = OPA->_float && OPB->_float; break; case OP_OR: OPC->_float = OPA->_float || OPB->_float; break; case OP_NOT_F: OPC->_float = !OPA->_float; break; case OP_NOT_V: OPC->_float = !OPA->vector[0] && !OPA->vector[1] && !OPA->vector[2]; break; case OP_NOT_S: OPC->_float = !OPA->string || !pr_strings[OPA->string]; break; case OP_NOT_FNC: OPC->_float = !OPA->function; break; case OP_NOT_ENT: OPC->_float = (PROG_TO_EDICT(OPA->edict) == sv.edicts); break; case OP_EQ_F: OPC->_float = OPA->_float == OPB->_float; break; case OP_EQ_V: OPC->_float = (OPA->vector[0] == OPB->vector[0]) && (OPA->vector[1] == OPB->vector[1]) && (OPA->vector[2] == OPB->vector[2]); break; case OP_EQ_S: OPC->_float = !strcmp(pr_strings+OPA->string,pr_strings+OPB->string); break; case OP_EQ_E: OPC->_float = OPA->_int == OPB->_int; break; case OP_EQ_FNC: OPC->_float = OPA->function == OPB->function; break; case OP_NE_F: OPC->_float = OPA->_float != OPB->_float; break; case OP_NE_V: OPC->_float = (OPA->vector[0] != OPB->vector[0]) || (OPA->vector[1] != OPB->vector[1]) || (OPA->vector[2] != OPB->vector[2]); break; case OP_NE_S: OPC->_float = strcmp(pr_strings+OPA->string,pr_strings+OPB->string); break; case OP_NE_E: OPC->_float = OPA->_int != OPB->_int; break; case OP_NE_FNC: OPC->_float = OPA->function != OPB->function; break; //================== case OP_STORE_F: case OP_STORE_ENT: case OP_STORE_FLD: // integers case OP_STORE_S: case OP_STORE_FNC: // pointers OPB->_int = OPA->_int; break; case OP_STORE_V: OPB->vector[0] = OPA->vector[0]; OPB->vector[1] = OPA->vector[1]; OPB->vector[2] = OPA->vector[2]; break; case OP_STOREP_F: case OP_STOREP_ENT: case OP_STOREP_FLD: // integers case OP_STOREP_S: case OP_STOREP_FNC: // pointers if (OPB->_int < 0 || OPB->_int + 4 > pr_edictareasize) { pr_xstatement = st - pr_statements; PR_RunError("Progs attempted to write to an out of bounds edict\n"); return; } if (OPB->_int % pr_edict_size < ((byte *)&sv.edicts->v - (byte *)sv.edicts)) { pr_xstatement = st - pr_statements; PR_RunError("Progs attempted to write to an engine edict field\n"); return; } ptr = (eval_t *)((byte *)sv.edicts + OPB->_int); ptr->_int = OPA->_int; break; case OP_STOREP_V: if (OPB->_int < 0 || OPB->_int + 12 > pr_edictareasize) { pr_xstatement = st - pr_statements; PR_RunError("Progs attempted to write to an out of bounds edict\n"); return; } ptr = (eval_t *)((byte *)sv.edicts + OPB->_int); ptr->vector[0] = OPA->vector[0]; ptr->vector[1] = OPA->vector[1]; ptr->vector[2] = OPA->vector[2]; break; case OP_ADDRESS: if (OPA->edict < 0 || OPA->edict >= pr_edictareasize) { pr_xstatement = st - pr_statements; PR_RunError("Progs attempted to address an out of bounds edict\n"); return; } if (OPA->edict == 0 && sv.state == ss_active) { pr_xstatement = st - pr_statements; PR_RunError ("assignment to world entity"); return; } if (OPB->_int < 0 || OPB->_int >= progs->entityfields) { pr_xstatement = st - pr_statements; PR_RunError("Progs attempted to address an invalid field in an edict\n"); return; } ed = PROG_TO_EDICT(OPA->edict); OPC->_int = (byte *)((int *)&ed->v + OPB->_int) - (byte *)sv.edicts; break; case OP_LOAD_F: case OP_LOAD_FLD: case OP_LOAD_ENT: case OP_LOAD_S: case OP_LOAD_FNC: if (OPA->edict < 0 || OPA->edict >= pr_edictareasize) { pr_xstatement = st - pr_statements; PR_RunError("Progs attempted to read an out of bounds edict number\n"); return; } if (OPB->_int < 0 || OPB->_int >= progs->entityfields) { pr_xstatement = st - pr_statements; PR_RunError("Progs attempted to read an invalid field in an edict\n"); return; } ed = PROG_TO_EDICT(OPA->edict); OPC->_int = ((eval_t *)((int *)&ed->v + OPB->_int))->_int; break; case OP_LOAD_V: if (OPA->edict < 0 || OPA->edict >= pr_edictareasize) { pr_xstatement = st - pr_statements; PR_RunError("Progs attempted to read an out of bounds edict number\n"); return; } if (OPB->_int < 0 || OPB->_int + 2 >= progs->entityfields) { pr_xstatement = st - pr_statements; PR_RunError("Progs attempted to read an invalid field in an edict\n"); return; } ed = PROG_TO_EDICT(OPA->edict); OPC->vector[0] = ((eval_t *)((int *)&ed->v + OPB->_int))->vector[0]; OPC->vector[1] = ((eval_t *)((int *)&ed->v + OPB->_int))->vector[1]; OPC->vector[2] = ((eval_t *)((int *)&ed->v + OPB->_int))->vector[2]; break; //================== case OP_IFNOT: if (!OPA->_int) st += st->b - 1; // offset the s++ break; case OP_IF: if (OPA->_int) st += st->b - 1; // offset the s++ break; case OP_GOTO: st += st->a - 1; // offset the s++ break; case OP_CALL0: case OP_CALL1: case OP_CALL2: case OP_CALL3: case OP_CALL4: case OP_CALL5: case OP_CALL6: case OP_CALL7: case OP_CALL8: pr_xfunction->profile += profile - startprofile; startprofile = profile; pr_xstatement = st - pr_statements; pr_argc = st->op - OP_CALL0; if (!OPA->function) PR_RunError ("NULL function"); newf = &pr_functions[OPA->function]; if (newf->first_statement < 0) { // negative statements are built in functions int i = -newf->first_statement; if (i >= pr_numbuiltins) PR_RunError ("Bad builtin call number"); pr_builtins[i] (); break; } st = &pr_statements[PR_EnterFunction (newf)]; break; case OP_DONE: case OP_RETURN: pr_globals[OFS_RETURN] = pr_globals[(unsigned short) st->a]; pr_globals[OFS_RETURN+1] = pr_globals[(unsigned short) st->a+1]; pr_globals[OFS_RETURN+2] = pr_globals[(unsigned short) st->a+2]; st = &pr_statements[PR_LeaveFunction ()]; if (pr_depth == exitdepth) return; // all done break; case OP_STATE: ed = PROG_TO_EDICT(pr_global_struct->self); ed->v.nextthink = pr_global_struct->time + 0.1; ed->v.frame = OPA->_float; ed->v.think = OPB->function; break; default: pr_xstatement = st - pr_statements; PR_RunError ("Bad opcode %i", st->op); } } } else { while (1) { st++; if (++profile > 1000000) // LordHavoc: increased runaway loop limit 10x { pr_xstatement = st - pr_statements; PR_RunError ("runaway loop error"); } if (pr_trace) PR_PrintStatement (st); switch (st->op) { case OP_ADD_F: OPC->_float = OPA->_float + OPB->_float; break; case OP_ADD_V: OPC->vector[0] = OPA->vector[0] + OPB->vector[0]; OPC->vector[1] = OPA->vector[1] + OPB->vector[1]; OPC->vector[2] = OPA->vector[2] + OPB->vector[2]; break; case OP_SUB_F: OPC->_float = OPA->_float - OPB->_float; break; case OP_SUB_V: OPC->vector[0] = OPA->vector[0] - OPB->vector[0]; OPC->vector[1] = OPA->vector[1] - OPB->vector[1]; OPC->vector[2] = OPA->vector[2] - OPB->vector[2]; break; case OP_MUL_F: OPC->_float = OPA->_float * OPB->_float; break; case OP_MUL_V: OPC->_float = OPA->vector[0]*OPB->vector[0] + OPA->vector[1]*OPB->vector[1] + OPA->vector[2]*OPB->vector[2]; break; case OP_MUL_FV: OPC->vector[0] = OPA->_float * OPB->vector[0]; OPC->vector[1] = OPA->_float * OPB->vector[1]; OPC->vector[2] = OPA->_float * OPB->vector[2]; break; case OP_MUL_VF: OPC->vector[0] = OPB->_float * OPA->vector[0]; OPC->vector[1] = OPB->_float * OPA->vector[1]; OPC->vector[2] = OPB->_float * OPA->vector[2]; break; case OP_DIV_F: OPC->_float = OPA->_float / OPB->_float; break; case OP_BITAND: OPC->_float = (int)OPA->_float & (int)OPB->_float; break; case OP_BITOR: OPC->_float = (int)OPA->_float | (int)OPB->_float; break; case OP_GE: OPC->_float = OPA->_float >= OPB->_float; break; case OP_LE: OPC->_float = OPA->_float <= OPB->_float; break; case OP_GT: OPC->_float = OPA->_float > OPB->_float; break; case OP_LT: OPC->_float = OPA->_float < OPB->_float; break; case OP_AND: OPC->_float = OPA->_float && OPB->_float; break; case OP_OR: OPC->_float = OPA->_float || OPB->_float; break; case OP_NOT_F: OPC->_float = !OPA->_float; break; case OP_NOT_V: OPC->_float = !OPA->vector[0] && !OPA->vector[1] && !OPA->vector[2]; break; case OP_NOT_S: OPC->_float = !OPA->string || !pr_strings[OPA->string]; break; case OP_NOT_FNC: OPC->_float = !OPA->function; break; case OP_NOT_ENT: OPC->_float = (PROG_TO_EDICT(OPA->edict) == sv.edicts); break; case OP_EQ_F: OPC->_float = OPA->_float == OPB->_float; break; case OP_EQ_V: OPC->_float = (OPA->vector[0] == OPB->vector[0]) && (OPA->vector[1] == OPB->vector[1]) && (OPA->vector[2] == OPB->vector[2]); break; case OP_EQ_S: OPC->_float = !strcmp(pr_strings+OPA->string,pr_strings+OPB->string); break; case OP_EQ_E: OPC->_float = OPA->_int == OPB->_int; break; case OP_EQ_FNC: OPC->_float = OPA->function == OPB->function; break; case OP_NE_F: OPC->_float = OPA->_float != OPB->_float; break; case OP_NE_V: OPC->_float = (OPA->vector[0] != OPB->vector[0]) || (OPA->vector[1] != OPB->vector[1]) || (OPA->vector[2] != OPB->vector[2]); break; case OP_NE_S: OPC->_float = strcmp(pr_strings+OPA->string,pr_strings+OPB->string); break; case OP_NE_E: OPC->_float = OPA->_int != OPB->_int; break; case OP_NE_FNC: OPC->_float = OPA->function != OPB->function; break; //================== case OP_STORE_F: case OP_STORE_ENT: case OP_STORE_FLD: // integers case OP_STORE_S: case OP_STORE_FNC: // pointers OPB->_int = OPA->_int; break; case OP_STORE_V: OPB->vector[0] = OPA->vector[0]; OPB->vector[1] = OPA->vector[1]; OPB->vector[2] = OPA->vector[2]; break; case OP_STOREP_F: case OP_STOREP_ENT: case OP_STOREP_FLD: // integers case OP_STOREP_S: case OP_STOREP_FNC: // pointers if (OPB->_int < 0 || OPB->_int + 4 > pr_edictareasize) { pr_xstatement = st - pr_statements; PR_RunError("Progs attempted to write to an out of bounds edict\n"); return; } if (OPB->_int % pr_edict_size < ((byte *)&sv.edicts->v - (byte *)sv.edicts)) { pr_xstatement = st - pr_statements; PR_RunError("Progs attempted to write to an engine edict field\n"); return; } ptr = (eval_t *)((byte *)sv.edicts + OPB->_int); ptr->_int = OPA->_int; break; case OP_STOREP_V: if (OPB->_int < 0 || OPB->_int + 12 > pr_edictareasize) { pr_xstatement = st - pr_statements; PR_RunError("Progs attempted to write to an out of bounds edict\n"); return; } ptr = (eval_t *)((byte *)sv.edicts + OPB->_int); ptr->vector[0] = OPA->vector[0]; ptr->vector[1] = OPA->vector[1]; ptr->vector[2] = OPA->vector[2]; break; case OP_ADDRESS: if (OPA->edict < 0 || OPA->edict >= pr_edictareasize) { pr_xstatement = st - pr_statements; PR_RunError("Progs attempted to address an out of bounds edict\n"); return; } if (OPA->edict == 0 && sv.state == ss_active) { pr_xstatement = st - pr_statements; PR_RunError ("assignment to world entity"); return; } if (OPB->_int < 0 || OPB->_int >= progs->entityfields) { pr_xstatement = st - pr_statements; PR_RunError("Progs attempted to address an invalid field in an edict\n"); return; } ed = PROG_TO_EDICT(OPA->edict); OPC->_int = (byte *)((int *)&ed->v + OPB->_int) - (byte *)sv.edicts; break; case OP_LOAD_F: case OP_LOAD_FLD: case OP_LOAD_ENT: case OP_LOAD_S: case OP_LOAD_FNC: if (OPA->edict < 0 || OPA->edict >= pr_edictareasize) { pr_xstatement = st - pr_statements; PR_RunError("Progs attempted to read an out of bounds edict number\n"); return; } if (OPB->_int < 0 || OPB->_int >= progs->entityfields) { pr_xstatement = st - pr_statements; PR_RunError("Progs attempted to read an invalid field in an edict\n"); return; } ed = PROG_TO_EDICT(OPA->edict); OPC->_int = ((eval_t *)((int *)&ed->v + OPB->_int))->_int; break; case OP_LOAD_V: if (OPA->edict < 0 || OPA->edict >= pr_edictareasize) { pr_xstatement = st - pr_statements; PR_RunError("Progs attempted to read an out of bounds edict number\n"); return; } if (OPB->_int < 0 || OPB->_int + 2 >= progs->entityfields) { pr_xstatement = st - pr_statements; PR_RunError("Progs attempted to read an invalid field in an edict\n"); return; } ed = PROG_TO_EDICT(OPA->edict); OPC->vector[0] = ((eval_t *)((int *)&ed->v + OPB->_int))->vector[0]; OPC->vector[1] = ((eval_t *)((int *)&ed->v + OPB->_int))->vector[1]; OPC->vector[2] = ((eval_t *)((int *)&ed->v + OPB->_int))->vector[2]; break; //================== case OP_IFNOT: if (!OPA->_int) st += st->b - 1; // offset the s++ break; case OP_IF: if (OPA->_int) st += st->b - 1; // offset the s++ break; case OP_GOTO: st += st->a - 1; // offset the s++ break; case OP_CALL0: case OP_CALL1: case OP_CALL2: case OP_CALL3: case OP_CALL4: case OP_CALL5: case OP_CALL6: case OP_CALL7: case OP_CALL8: pr_xfunction->profile += profile - startprofile; startprofile = profile; pr_xstatement = st - pr_statements; pr_argc = st->op - OP_CALL0; if (!OPA->function) PR_RunError ("NULL function"); newf = &pr_functions[OPA->function]; if (newf->first_statement < 0) { // negative statements are built in functions int i = -newf->first_statement; if (i >= pr_numbuiltins) PR_RunError ("Bad builtin call number"); pr_builtins[i] (); break; } st = &pr_statements[PR_EnterFunction (newf)]; break; case OP_DONE: case OP_RETURN: pr_globals[OFS_RETURN] = pr_globals[(unsigned short) st->a]; pr_globals[OFS_RETURN+1] = pr_globals[(unsigned short) st->a+1]; pr_globals[OFS_RETURN+2] = pr_globals[(unsigned short) st->a+2]; st = &pr_statements[PR_LeaveFunction ()]; if (pr_depth == exitdepth) return; // all done break; case OP_STATE: ed = PROG_TO_EDICT(pr_global_struct->self); ed->v.nextthink = pr_global_struct->time + 0.1; ed->v.frame = OPA->_float; ed->v.think = OPB->function; break; //================== // LordHavoc: to be enabled when Progs version 7 (or whatever it will be numbered) is finalized /* case OP_ADD_I: OPC->_int = OPA->_int + OPB->_int; break; case OP_ADD_IF: OPC->_int = OPA->_int + (int) OPB->_float; break; case OP_ADD_FI: OPC->_float = OPA->_float + (float) OPB->_int; break; case OP_SUB_I: OPC->_int = OPA->_int - OPB->_int; break; case OP_SUB_IF: OPC->_int = OPA->_int - (int) OPB->_float; break; case OP_SUB_FI: OPC->_float = OPA->_float - (float) OPB->_int; break; case OP_MUL_I: OPC->_int = OPA->_int * OPB->_int; break; case OP_MUL_IF: OPC->_int = OPA->_int * (int) OPB->_float; break; case OP_MUL_FI: OPC->_float = OPA->_float * (float) OPB->_int; break; case OP_MUL_VI: OPC->vector[0] = (float) OPB->_int * OPA->vector[0]; OPC->vector[1] = (float) OPB->_int * OPA->vector[1]; OPC->vector[2] = (float) OPB->_int * OPA->vector[2]; break; case OP_DIV_VF: { float temp = 1.0f / OPB->_float; OPC->vector[0] = temp * OPA->vector[0]; OPC->vector[1] = temp * OPA->vector[1]; OPC->vector[2] = temp * OPA->vector[2]; } break; case OP_DIV_I: OPC->_int = OPA->_int / OPB->_int; break; case OP_DIV_IF: OPC->_int = OPA->_int / (int) OPB->_float; break; case OP_DIV_FI: OPC->_float = OPA->_float / (float) OPB->_int; break; case OP_CONV_IF: OPC->_float = OPA->_int; break; case OP_CONV_FI: OPC->_int = OPA->_float; break; case OP_BITAND_I: OPC->_int = OPA->_int & OPB->_int; break; case OP_BITOR_I: OPC->_int = OPA->_int | OPB->_int; break; case OP_BITAND_IF: OPC->_int = OPA->_int & (int)OPB->_float; break; case OP_BITOR_IF: OPC->_int = OPA->_int | (int)OPB->_float; break; case OP_BITAND_FI: OPC->_float = (int)OPA->_float & OPB->_int; break; case OP_BITOR_FI: OPC->_float = (int)OPA->_float | OPB->_int; break; case OP_GE_I: OPC->_float = OPA->_int >= OPB->_int; break; case OP_LE_I: OPC->_float = OPA->_int <= OPB->_int; break; case OP_GT_I: OPC->_float = OPA->_int > OPB->_int; break; case OP_LT_I: OPC->_float = OPA->_int < OPB->_int; break; case OP_AND_I: OPC->_float = OPA->_int && OPB->_int; break; case OP_OR_I: OPC->_float = OPA->_int || OPB->_int; break; case OP_GE_IF: OPC->_float = (float)OPA->_int >= OPB->_float; break; case OP_LE_IF: OPC->_float = (float)OPA->_int <= OPB->_float; break; case OP_GT_IF: OPC->_float = (float)OPA->_int > OPB->_float; break; case OP_LT_IF: OPC->_float = (float)OPA->_int < OPB->_float; break; case OP_AND_IF: OPC->_float = (float)OPA->_int && OPB->_float; break; case OP_OR_IF: OPC->_float = (float)OPA->_int || OPB->_float; break; case OP_GE_FI: OPC->_float = OPA->_float >= (float)OPB->_int; break; case OP_LE_FI: OPC->_float = OPA->_float <= (float)OPB->_int; break; case OP_GT_FI: OPC->_float = OPA->_float > (float)OPB->_int; break; case OP_LT_FI: OPC->_float = OPA->_float < (float)OPB->_int; break; case OP_AND_FI: OPC->_float = OPA->_float && (float)OPB->_int; break; case OP_OR_FI: OPC->_float = OPA->_float || (float)OPB->_int; break; case OP_NOT_I: OPC->_float = !OPA->_int; break; case OP_EQ_I: OPC->_float = OPA->_int == OPB->_int; break; case OP_EQ_IF: OPC->_float = (float)OPA->_int == OPB->_float; break; case OP_EQ_FI: OPC->_float = OPA->_float == (float)OPB->_int; break; case OP_NE_I: OPC->_float = OPA->_int != OPB->_int; break; case OP_NE_IF: OPC->_float = (float)OPA->_int != OPB->_float; break; case OP_NE_FI: OPC->_float = OPA->_float != (float)OPB->_int; break; case OP_STORE_I: OPB->_int = OPA->_int; break; case OP_STOREP_I: if (OPB->_int < 0 || OPB->_int + 4 > pr_edictareasize) { pr_xstatement = st - pr_statements; PR_RunError("Progs attempted to write to an out of bounds edict\n"); return; } if (OPB->_int % pr_edict_size < ((byte *)&sv.edicts->v - (byte *)sv.edicts)) { pr_xstatement = st - pr_statements; PR_RunError("Progs attempted to write to an engine edict field\n"); return; } ptr = (eval_t *)((byte *)sv.edicts + OPB->_int); ptr->_int = OPA->_int; break; case OP_LOAD_I: if (OPA->edict < 0 || OPA->edict >= pr_edictareasize) { pr_xstatement = st - pr_statements; PR_RunError("Progs attempted to read an out of bounds edict number\n"); return; } if (OPB->_int < 0 || OPB->_int >= progs->entityfields) { pr_xstatement = st - pr_statements; PR_RunError("Progs attempted to read an invalid field in an edict\n"); return; } ed = PROG_TO_EDICT(OPA->edict); OPC->_int = ((eval_t *)((int *)&ed->v + OPB->_int))->_int; break; case OP_GSTOREP_I: case OP_GSTOREP_F: case OP_GSTOREP_ENT: case OP_GSTOREP_FLD: // integers case OP_GSTOREP_S: case OP_GSTOREP_FNC: // pointers if (OPB->_int < 0 || OPB->_int >= pr_globaldefs) { pr_xstatement = st - pr_statements; PR_RunError("Progs attempted to write to an invalid indexed global\n"); return; } pr_globals[OPB->_int] = OPA->_float; break; case OP_GSTOREP_V: if (OPB->_int < 0 || OPB->_int + 2 >= pr_globaldefs) { pr_xstatement = st - pr_statements; PR_RunError("Progs attempted to write to an invalid indexed global\n"); return; } pr_globals[OPB->_int ] = OPA->vector[0]; pr_globals[OPB->_int+1] = OPA->vector[1]; pr_globals[OPB->_int+2] = OPA->vector[2]; break; case OP_GADDRESS: i = OPA->_int + (int) OPB->_float; if (i < 0 || i >= pr_globaldefs) { pr_xstatement = st - pr_statements; PR_RunError("Progs attempted to address an out of bounds global\n"); return; } OPC->_float = pr_globals[i]; break; case OP_GLOAD_I: case OP_GLOAD_F: case OP_GLOAD_FLD: case OP_GLOAD_ENT: case OP_GLOAD_S: case OP_GLOAD_FNC: if (OPA->_int < 0 || OPA->_int >= pr_globaldefs) { pr_xstatement = st - pr_statements; PR_RunError("Progs attempted to read an invalid indexed global\n"); return; } OPC->_float = pr_globals[OPA->_int]; break; case OP_GLOAD_V: if (OPA->_int < 0 || OPA->_int + 2 >= pr_globaldefs) { pr_xstatement = st - pr_statements; PR_RunError("Progs attempted to read an invalid indexed global\n"); return; } OPC->vector[0] = pr_globals[OPA->_int ]; OPC->vector[1] = pr_globals[OPA->_int+1]; OPC->vector[2] = pr_globals[OPA->_int+2]; break; case OP_BOUNDCHECK: if (OPA->_int < 0 || OPA->_int >= st->b) { pr_xstatement = st - pr_statements; PR_RunError("Progs boundcheck failed at line number %d, value is < 0 or >= %d\n", st->b, st->c); return; } break; */ //================== default: pr_xstatement = st - pr_statements; PR_RunError ("Bad opcode %i", st->op); } } } }