// HEADER FILES ------------------------------------------------------------ #include "qwsvdef.h" // MACROS ------------------------------------------------------------------ #define MAX_STACK_DEPTH 32 #define LOCALSTACK_SIZE 2048 #if defined(_MSC_VER) && defined(_WIN32) && defined(_DEBUG) // Uses the Pentium specific opcode RDTSC (ReaD TimeStamp Counter) #define TIMESNAP_ACTIVE #define TIMESNAP(clock) __asm push eax\ __asm push edx\ __asm _emit 0x0F\ __asm _emit 0x31\ __asm mov clock, eax\ __asm pop edx\ __asm pop eax #endif // TYPES ------------------------------------------------------------------- typedef struct { int s; dfunction_t *f; } prstack_t; // EXTERNAL FUNCTION PROTOTYPES -------------------------------------------- char *PR_GlobalString(int ofs); char *PR_GlobalStringNoContents(int ofs); // PUBLIC FUNCTION PROTOTYPES ---------------------------------------------- // PRIVATE FUNCTION PROTOTYPES --------------------------------------------- static int EnterFunction(dfunction_t *f); static int LeaveFunction(void); static void PrintStatement(dstatement_t *s); static void PrintCallHistory(void); #ifdef TIMESNAP_ACTIVE static unsigned int ProgsTimer(void); #endif // EXTERNAL DATA DECLARATIONS ---------------------------------------------- // PUBLIC DATA DEFINITIONS ------------------------------------------------- qboolean pr_trace; dfunction_t *pr_xfunction; int pr_xstatement; int pr_argc; // PRIVATE DATA DEFINITIONS ------------------------------------------------ static prstack_t pr_stack[MAX_STACK_DEPTH]; static int pr_depth; static int localstack[LOCALSTACK_SIZE]; static int localstack_used; static 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", "OP_MULSTORE_F", "OP_MULSTORE_V", "OP_MULSTOREP_F", "OP_MULSTOREP_V", "OP_DIVSTORE_F", "OP_DIVSTOREP_F", "OP_ADDSTORE_F", "OP_ADDSTORE_V", "OP_ADDSTOREP_F", "OP_ADDSTOREP_V", "OP_SUBSTORE_F", "OP_SUBSTORE_V", "OP_SUBSTOREP_F", "OP_SUBSTOREP_V", "OP_FETCH_GBL_F", "OP_FETCH_GBL_V", "OP_FETCH_GBL_S", "OP_FETCH_GBL_E", "OP_FETCH_GBL_FNC", "OP_CSTATE", "OP_CWSTATE", "OP_THINKTIME", "OP_BITSET", "OP_BITSETP", "OP_BITCLR", "OP_BITCLRP", "OP_RAND0", "OP_RAND1", "OP_RAND2", "OP_RANDV0", "OP_RANDV1", "OP_RANDV2", "OP_SWITCH_F", "OP_SWITCH_V", "OP_SWITCH_S", "OP_SWITCH_E", "OP_SWITCH_FNC", "OP_CASE", "OP_CASERANGE" }; // CODE -------------------------------------------------------------------- //========================================================================== // // PR_ExecuteProgram // //========================================================================== //switch types enum {SWITCH_F,SWITCH_V,SWITCH_S,SWITCH_E,SWITCH_FNC}; void PR_ExecuteProgram(func_t fnum) { int i; int s; eval_t *a, *b, *c; eval_t *ptr; dstatement_t *st; dfunction_t *f, *newf; int runaway; edict_t *ed; int exitdepth; int startFrame; int endFrame; float val; int case_type=-1; float switch_float; if(!fnum || fnum >= progs->numfunctions) { if(pr_global_struct->self) { ED_Print(PROG_TO_EDICT(pr_global_struct->self)); } SV_Error("PR_ExecuteProgram: NULL function"); } f = &pr_functions[fnum]; runaway = 100000; pr_trace = false; exitdepth = pr_depth; s = EnterFunction(f); #ifdef TIMESNAP_ACTIVE ProgsTimer(); // Init #endif while (1) { s++; // Next statement st = &pr_statements[s]; a = (eval_t *)&pr_globals[(unsigned short)st->a]; b = (eval_t *)&pr_globals[(unsigned short)st->b]; c = (eval_t *)&pr_globals[(unsigned short)st->c]; if(!--runaway) { PR_RunError("runaway loop error"); } #ifndef TIMESNAP_ACTIVE pr_xfunction->profile++; #endif pr_xstatement = s; if(pr_trace) { PrintStatement(st); } switch(st->op) { case OP_ADD_F: c->_float = a->_float + b->_float; break; case OP_ADD_V: c->vector[0] = a->vector[0] + b->vector[0]; c->vector[1] = a->vector[1] + b->vector[1]; c->vector[2] = a->vector[2] + b->vector[2]; break; case OP_SUB_F: c->_float = a->_float - b->_float; break; case OP_SUB_V: c->vector[0] = a->vector[0] - b->vector[0]; c->vector[1] = a->vector[1] - b->vector[1]; c->vector[2] = a->vector[2] - b->vector[2]; break; case OP_MUL_F: c->_float = a->_float * b->_float; break; case OP_MUL_V: c->_float = a->vector[0]*b->vector[0] + a->vector[1]*b->vector[1] + a->vector[2]*b->vector[2]; break; case OP_MUL_FV: c->vector[0] = a->_float * b->vector[0]; c->vector[1] = a->_float * b->vector[1]; c->vector[2] = a->_float * b->vector[2]; break; case OP_MUL_VF: c->vector[0] = b->_float * a->vector[0]; c->vector[1] = b->_float * a->vector[1]; c->vector[2] = b->_float * a->vector[2]; break; case OP_DIV_F: c->_float = a->_float / b->_float; break; case OP_BITAND: c->_float = (int)a->_float & (int)b->_float; break; case OP_BITOR: c->_float = (int)a->_float | (int)b->_float; break; case OP_GE: c->_float = a->_float >= b->_float; break; case OP_LE: c->_float = a->_float <= b->_float; break; case OP_GT: c->_float = a->_float > b->_float; break; case OP_LT: c->_float = a->_float < b->_float; break; case OP_AND: c->_float = a->_float && b->_float; break; case OP_OR: c->_float = a->_float || b->_float; break; case OP_NOT_F: c->_float = !a->_float; break; case OP_NOT_V: c->_float = !a->vector[0] && !a->vector[1] && !a->vector[2]; break; case OP_NOT_S: c->_float = !a->string || !pr_strings[a->string]; break; case OP_NOT_FNC: c->_float = !a->function; break; case OP_NOT_ENT: c->_float = (PROG_TO_EDICT(a->edict) == sv.edicts); break; case OP_EQ_F: c->_float = a->_float == b->_float; break; case OP_EQ_V: c->_float = (a->vector[0] == b->vector[0]) && (a->vector[1] == b->vector[1]) && (a->vector[2] == b->vector[2]); break; case OP_EQ_S: c->_float = !strcmp(pr_strings+a->string,pr_strings+b->string); break; case OP_EQ_E: c->_float = a->_int == b->_int; break; case OP_EQ_FNC: c->_float = a->function == b->function; break; case OP_NE_F: c->_float = a->_float != b->_float; break; case OP_NE_V: c->_float = (a->vector[0] != b->vector[0]) || (a->vector[1] != b->vector[1]) || (a->vector[2] != b->vector[2]); break; case OP_NE_S: c->_float = strcmp(pr_strings+a->string,pr_strings+b->string); break; case OP_NE_E: c->_float = a->_int != b->_int; break; case OP_NE_FNC: c->_float = a->function != b->function; break; case OP_STORE_F: case OP_STORE_ENT: case OP_STORE_FLD: // integers case OP_STORE_S: case OP_STORE_FNC: // pointers b->_int = a->_int; break; case OP_STORE_V: b->vector[0] = a->vector[0]; b->vector[1] = a->vector[1]; b->vector[2] = a->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 ptr = (eval_t *)((byte *)sv.edicts + b->_int); ptr->_int = a->_int; break; case OP_STOREP_V: ptr = (eval_t *)((byte *)sv.edicts + b->_int); ptr->vector[0] = a->vector[0]; ptr->vector[1] = a->vector[1]; ptr->vector[2] = a->vector[2]; break; case OP_MULSTORE_F: // f *= f b->_float *= a->_float; break; case OP_MULSTORE_V: // v *= f b->vector[0] *= a->_float; b->vector[1] *= a->_float; b->vector[2] *= a->_float; break; case OP_MULSTOREP_F: // e.f *= f ptr = (eval_t *)((byte *)sv.edicts+b->_int); c->_float = (ptr->_float *= a->_float); break; case OP_MULSTOREP_V: // e.v *= f ptr = (eval_t *)((byte *)sv.edicts+b->_int); c->vector[0] = (ptr->vector[0] *= a->_float); c->vector[0] = (ptr->vector[1] *= a->_float); c->vector[0] = (ptr->vector[2] *= a->_float); break; case OP_DIVSTORE_F: // f /= f b->_float /= a->_float; break; case OP_DIVSTOREP_F: // e.f /= f ptr = (eval_t *)((byte *)sv.edicts+b->_int); c->_float = (ptr->_float /= a->_float); break; case OP_ADDSTORE_F: // f += f b->_float += a->_float; break; case OP_ADDSTORE_V: // v += v b->vector[0] += a->vector[0]; b->vector[1] += a->vector[1]; b->vector[2] += a->vector[2]; break; case OP_ADDSTOREP_F: // e.f += f ptr = (eval_t *)((byte *)sv.edicts+b->_int); c->_float = (ptr->_float += a->_float); break; case OP_ADDSTOREP_V: // e.v += v ptr = (eval_t *)((byte *)sv.edicts+b->_int); c->vector[0] = (ptr->vector[0] += a->vector[0]); c->vector[1] = (ptr->vector[1] += a->vector[1]); c->vector[2] = (ptr->vector[2] += a->vector[2]); break; case OP_SUBSTORE_F: // f -= f b->_float -= a->_float; break; case OP_SUBSTORE_V: // v -= v b->vector[0] -= a->vector[0]; b->vector[1] -= a->vector[1]; b->vector[2] -= a->vector[2]; break; case OP_SUBSTOREP_F: // e.f -= f ptr = (eval_t *)((byte *)sv.edicts+b->_int); c->_float = (ptr->_float -= a->_float); break; case OP_SUBSTOREP_V: // e.v -= v ptr = (eval_t *)((byte *)sv.edicts+b->_int); c->vector[0] = (ptr->vector[0] -= a->vector[0]); c->vector[1] = (ptr->vector[1] -= a->vector[1]); c->vector[2] = (ptr->vector[2] -= a->vector[2]); break; case OP_ADDRESS: ed = PROG_TO_EDICT(a->edict); #ifdef PARANOID NUM_FOR_EDICT(ed); // Make sure it's in range #endif if(ed == (edict_t *)sv.edicts && sv.state == ss_active) { PR_RunError("assignment to world entity"); } c->_int = (byte *)((int *)&ed->v + b->_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: ed = PROG_TO_EDICT(a->edict); #ifdef PARANOID NUM_FOR_EDICT(ed); // Make sure it's in range #endif a = (eval_t *)((int *)&ed->v+b->_int); c->_int = a->_int; break; case OP_LOAD_V: ed = PROG_TO_EDICT(a->edict); #ifdef PARANOID NUM_FOR_EDICT(ed); // Make sure it's in range #endif a = (eval_t *)((int *)&ed->v + b->_int); c->vector[0] = a->vector[0]; c->vector[1] = a->vector[1]; c->vector[2] = a->vector[2]; break; case OP_FETCH_GBL_F: case OP_FETCH_GBL_S: case OP_FETCH_GBL_E: case OP_FETCH_GBL_FNC: i = (int)b->_float; if(i < 0 || i > G_INT((unsigned short)st->a - 1)) { PR_RunError("array index out of bounds: %d", i); } a = (eval_t *)&pr_globals[(unsigned short)st->a + i]; c->_int = a->_int; break; case OP_FETCH_GBL_V: i = (int)b->_float; if(i < 0 || i > G_INT((unsigned short)st->a - 1)) { PR_RunError("array index out of bounds: %d", i); } a = (eval_t *)&pr_globals[(unsigned short)st->a +((int)b->_float)*3]; c->vector[0] = a->vector[0]; c->vector[1] = a->vector[1]; c->vector[2] = a->vector[2]; break; case OP_IFNOT: if(!a->_int) { s += st->b-1; // -1 to offset the s++ } break; case OP_IF: if(a->_int) { s += st->b-1; // -1 to offset the s++ } break; case OP_GOTO: s += st->a-1; // -1 to offset the s++ break; case OP_CALL8: case OP_CALL7: case OP_CALL6: case OP_CALL5: case OP_CALL4: case OP_CALL3: case OP_CALL2: // Copy second arg to shared space VectorCopy(c->vector, G_VECTOR(OFS_PARM1)); case OP_CALL1: // Copy first arg to shared space VectorCopy(b->vector, G_VECTOR(OFS_PARM0)); case OP_CALL0: pr_argc = st->op-OP_CALL0; if(!a->function) { PR_RunError("NULL function"); } newf = &pr_functions[a->function]; if(newf->first_statement < 0) { // Built-in function i = -newf->first_statement; if(i >= pr_numbuiltins) { PR_RunError("Bad builtin call number"); } pr_builtins[i](); break; } // Normal function #ifdef TIMESNAP_ACTIVE pr_xfunction->profile += ProgsTimer(); #endif s = 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]; #ifdef TIMESNAP_ACTIVE pr_xfunction->profile += ProgsTimer(); #endif s = LeaveFunction(); if(pr_depth == exitdepth) { // Done return; } break; case OP_STATE: ed = PROG_TO_EDICT(pr_global_struct->self); /* Id 1.07 changes #ifdef FPS_20 ed->v.nextthink = pr_global_struct->time + 0.05; #else ed->v.nextthink = pr_global_struct->time + 0.1; #endif */ ed->v.nextthink = pr_global_struct->time+HX_FRAME_TIME; if(a->_float != ed->v.frame) { ed->v.frame = a->_float; } ed->v.think = b->function; break; case OP_CSTATE: // Cycle state ed = PROG_TO_EDICT(pr_global_struct->self); ed->v.nextthink = pr_global_struct->time+HX_FRAME_TIME; ed->v.think = pr_xfunction-pr_functions; pr_global_struct->cycle_wrapped = false; startFrame = (int)a->_float; endFrame = (int)b->_float; if(startFrame <= endFrame) { // Increment if(ed->v.frame < startFrame || ed->v.frame > endFrame) { ed->v.frame = startFrame; break; } ed->v.frame++; if(ed->v.frame > endFrame) { pr_global_struct->cycle_wrapped = true; ed->v.frame = startFrame; } break; } // Decrement if(ed->v.frame > startFrame || ed->v.frame < endFrame) { ed->v.frame = startFrame; break; } ed->v.frame--; if(ed->v.frame < endFrame) { pr_global_struct->cycle_wrapped = true; ed->v.frame = startFrame; } break; case OP_CWSTATE: // Cycle weapon state ed = PROG_TO_EDICT(pr_global_struct->self); ed->v.nextthink = pr_global_struct->time+HX_FRAME_TIME; ed->v.think = pr_xfunction-pr_functions; pr_global_struct->cycle_wrapped = false; startFrame = (int)a->_float; endFrame = (int)b->_float; if(startFrame <= endFrame) { // Increment if(ed->v.weaponframe < startFrame || ed->v.weaponframe > endFrame) { ed->v.weaponframe = startFrame; break; } ed->v.weaponframe++; if(ed->v.weaponframe > endFrame) { pr_global_struct->cycle_wrapped = true; ed->v.weaponframe = startFrame; } break; } // Decrement if(ed->v.weaponframe > startFrame || ed->v.weaponframe < endFrame) { ed->v.weaponframe = startFrame; break; } ed->v.weaponframe--; if(ed->v.weaponframe < endFrame) { pr_global_struct->cycle_wrapped = true; ed->v.weaponframe = startFrame; } break; case OP_THINKTIME: ed = PROG_TO_EDICT(a->edict); #ifdef PARANOID NUM_FOR_EDICT(ed); // Make sure it's in range #endif if(ed == (edict_t *)sv.edicts && sv.state == ss_active) { PR_RunError("assignment to world entity"); } ed->v.nextthink = pr_global_struct->time+b->_float; break; case OP_BITSET: // f (+) f b->_float = (int)b->_float | (int)a->_float; break; case OP_BITSETP: // e.f (+) f ptr = (eval_t *)((byte *)sv.edicts+b->_int); ptr->_float = (int)ptr->_float | (int)a->_float; break; case OP_BITCLR: // f (-) f b->_float = (int)b->_float & ~((int)a->_float); break; case OP_BITCLRP: // e.f (-) f ptr = (eval_t *)((byte *)sv.edicts+b->_int); ptr->_float = (int)ptr->_float & ~((int)a->_float); break; case OP_RAND0: val = (rand()&0x7fff)/((float)0x7fff); G_FLOAT(OFS_RETURN) = val; break; case OP_RAND1: val = (rand()&0x7fff)/((float)0x7fff)*a->_float; G_FLOAT(OFS_RETURN) = val; break; case OP_RAND2: if(a->_float < b->_float) { val = a->_float+((rand()&0x7fff)/((float)0x7fff) *(b->_float-a->_float)); } else { val = b->_float+((rand()&0x7fff)/((float)0x7fff) *(a->_float-b->_float)); } G_FLOAT(OFS_RETURN) = val; break; case OP_RANDV0: val = (rand()&0x7fff)/((float)0x7fff); G_FLOAT(OFS_RETURN+0) = val; val = (rand()&0x7fff)/((float)0x7fff); G_FLOAT(OFS_RETURN+1) = val; val = (rand()&0x7fff)/((float)0x7fff); G_FLOAT(OFS_RETURN+2) = val; break; case OP_RANDV1: val = (rand()&0x7fff)/((float)0x7fff)*a->vector[0]; G_FLOAT(OFS_RETURN+0) = val; val = (rand()&0x7fff)/((float)0x7fff)*a->vector[1]; G_FLOAT(OFS_RETURN+1) = val; val = (rand()&0x7fff)/((float)0x7fff)*a->vector[2]; G_FLOAT(OFS_RETURN+2) = val; break; case OP_RANDV2: for(i = 0; i < 3; i++) { if(a->vector[i] < b->vector[i]) { val = a->vector[i]+((rand()&0x7fff)/((float)0x7fff) *(b->vector[i]-a->vector[i])); } else { val = b->vector[i]+(rand()*(1.0/RAND_MAX) *(a->vector[i]-b->vector[i])); } G_FLOAT(OFS_RETURN+i) = val; } break; case OP_SWITCH_F: case_type = SWITCH_F; switch_float = a->_float; s += st->b-1; // -1 to offset the s++ break; case OP_SWITCH_V: PR_RunError("switch v not done yet!"); break; case OP_SWITCH_S: PR_RunError("switch s not done yet!"); break; case OP_SWITCH_E: PR_RunError("switch e not done yet!"); break; case OP_SWITCH_FNC: PR_RunError("switch fnc not done yet!"); break; case OP_CASERANGE: if (case_type!=SWITCH_F) PR_RunError("caserange fucked!"); if((switch_float >= a->_float) && (switch_float <= b->_float)) { s += st->c-1; // -1 to offset the s++ } break; case OP_CASE: switch (case_type) { case SWITCH_F: if(switch_float == a->_float) { s += st->b-1; // -1 to offset the s++ } break; case SWITCH_V: case SWITCH_S: case SWITCH_E: case SWITCH_FNC: PR_RunError("case not done yet!"); break; default: PR_RunError("fucked case!"); } break; default: PR_RunError("Bad opcode %i", st->op); } } } //========================================================================== // // EnterFunction // //========================================================================== static int 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; i < f->numparms; i++) { for(j = 0; j < f->parm_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++ } //========================================================================== // // LeaveFunction // //========================================================================== static int LeaveFunction(void) { int i, c; if(pr_depth <= 0) { Sys_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_RunError // //========================================================================== void PR_RunError(char *error, ...) { va_list argptr; char string[1024]; va_start(argptr,error); vsprintf(string,error,argptr); va_end(argptr); PrintStatement(pr_statements + pr_xstatement); PrintCallHistory(); Con_Printf("%s\n", string); pr_depth = 0; // dump the stack so sv_error can shutdown functions SV_Error("Program error"); } //========================================================================== // // PrintCallHistory // //========================================================================== static void PrintCallHistory(void) { int i; dfunction_t *f; 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); } } } //========================================================================== // // PrintStatement // //========================================================================== static void 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(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(s->a)); Con_Printf("%s", PR_GlobalStringNoContents(s->b)); } else { if(s->a) { Con_Printf("%s", PR_GlobalString(s->a)); } if(s->b) { Con_Printf("%s", PR_GlobalString(s->b)); } if(s->c) { Con_Printf("%s", PR_GlobalStringNoContents(s->c)); } } Con_Printf("\n"); } //========================================================================== // // PR_Profile_f // //========================================================================== void PR_Profile_f(void) { int i, j; int max; dfunction_t *f, *bestFunc; int total; int funcCount; qboolean byHC; char saveName[128]; FILE *saveFile; int currentFile; int bestFile; int tally; char *s; byHC = false; funcCount = 10; *saveName = 0; for(i = 1; i < Cmd_Argc(); i++) { s = Cmd_Argv(i); if(tolower(*s) == 'h') { // Sort by HC source file byHC = true; } else if(tolower(*s) == 's') { // Save to file if(i+1 < Cmd_Argc() && !isdigit(*Cmd_Argv(i+1))) { i++; sprintf(saveName, "%s/%s", com_gamedir, Cmd_Argv(i)); } else { sprintf(saveName, "%s/profile.txt", com_gamedir); } } else if(isdigit(*s)) { // Specify function count funcCount = atoi(Cmd_Argv(i)); if(funcCount < 1) { funcCount = 1; } } } total = 0; for(i = 0; i < progs->numfunctions; i++) { total += pr_functions[i].profile; } if(*saveName) { // Create the output file if((saveFile = fopen(saveName, "w")) == NULL) { Con_Printf("Could not open %s\n", saveName); return; } } #ifdef TIMESNAP_ACTIVE if(*saveName) { fprintf(saveFile, "(Timesnap Profile)\n"); } else { Con_Printf("(Timesnap Profile)\n"); } #endif if(byHC == false) { j = 0; do { max = 0; bestFunc = NULL; for(i = 0; i < progs->numfunctions; i++) { f = &pr_functions[i]; if(f->profile > max) { max = f->profile; bestFunc = f; } } if(bestFunc) { if(j < funcCount) { if(*saveName) { fprintf(saveFile, "%05.2f %s\n", ((float)bestFunc->profile/(float)total)*100.0, pr_strings+bestFunc->s_name); } else { Con_Printf("%05.2f %s\n", ((float)bestFunc->profile/(float)total)*100.0, pr_strings+bestFunc->s_name); } } j++; bestFunc->profile = 0; } } while(bestFunc); if(*saveName) { fclose(saveFile); } return; } currentFile = -1; do { tally = 0; bestFile = Q_MAXINT; for(i = 0; i < progs->numfunctions; i++) { if(pr_functions[i].s_file > currentFile && pr_functions[i].s_file < bestFile) { bestFile = pr_functions[i].s_file; tally = pr_functions[i].profile; continue; } if(pr_functions[i].s_file == bestFile) { tally += pr_functions[i].profile; } } currentFile = bestFile; if(tally && currentFile != Q_MAXINT) { if(*saveName) { fprintf(saveFile, "\"%s\"\n", pr_strings+currentFile); } else { Con_Printf("\"%s\"\n", pr_strings+currentFile); } j = 0; do { max = 0; bestFunc = NULL; for(i = 0; i < progs->numfunctions; i++) { f = &pr_functions[i]; if(f->s_file == currentFile && f->profile > max) { max = f->profile; bestFunc = f; } } if(bestFunc) { if(j < funcCount) { if(*saveName) { fprintf(saveFile, " %05.2f %s\n", ((float)bestFunc->profile /(float)total)*100.0, pr_strings+bestFunc->s_name); } else { Con_Printf(" %05.2f %s\n", ((float)bestFunc->profile /(float)total)*100.0, pr_strings+bestFunc->s_name); } } j++; bestFunc->profile = 0; } } while(bestFunc); } } while(currentFile != Q_MAXINT); if(*saveName) { fclose(saveFile); } } //========================================================================== // // ProgsTimer // //========================================================================== #ifdef TIMESNAP_ACTIVE static unsigned int ProgsTimer(void) { unsigned int c; unsigned int cycleCount; static unsigned int cycleTimer; TIMESNAP(c); if(cycleTimer > c) { cycleCount = ((unsigned int)0xffffffff-(cycleTimer-c)); } else { cycleCount = c-cycleTimer; } cycleTimer = c; return cycleCount>>8; } #endif