ref: 8070f221ed04c1e5adf9e0c2475c8ddf80ef772e
dir: /pr_edict.c/
#include "quakedef.h" const int type_size[8] = { [ev_void] = 1, [ev_string] = sizeof(string_t)/4, [ev_float] = 1, [ev_vector] = 3, [ev_entity] = 1, [ev_field] = 1, [ev_function] = sizeof(func_t)/4, [ev_pointer] = sizeof(void *)/4, }; bool ED_ParseEpair (pr_t *pr, void *base, ddef_t *key, char *s); cvar_t nomonsters = {"nomonsters", "0"}; static cvar_t scratch1 = {"scratch1", "0"}; static cvar_t scratch2 = {"scratch2", "0"}; static cvar_t scratch3 = {"scratch3", "0"}; static cvar_t scratch4 = {"scratch4", "0"}; static cvar_t saved1 = {"saved1", "0", true}; static cvar_t saved2 = {"saved2", "0", true}; static cvar_t saved3 = {"saved3", "0", true}; static cvar_t saved4 = {"saved4", "0", true}; static cvar_t gamecfg = {"gamecfg", "0"}; static cvar_t savedgamecfg = {"savedgamecfg", "0", true}; static cvar_t pr_checkextension = {"pr_checkextension", "1"}; enum { MAX_PRSTR = 1024, MAX_PRTEMPSTR = 1024, PRTEMPSTR_SIZE = 1024, MAX_FIELD_LEN = 64, GEFV_CACHESIZE = 2, }; typedef struct { ddef_t *pcache; char field[MAX_FIELD_LEN]; } gefv_cache; static gefv_cache gefvCache[GEFV_CACHESIZE] = {{nil, ""}, {nil, ""}}; char * PR_StrTmp(pr_t *pr) { return &pr->tempstr[PRTEMPSTR_SIZE * (pr->num_tempstr++ % MAX_PRTEMPSTR)]; } int PR_CopyStrTmp(pr_t *pr, char *s) { char *t = PR_StrTmp(pr); snprint(t, PRTEMPSTR_SIZE, "%s", s); return PR_SetStr(pr, t); } static int PR_StrSlot(pr_t *pr) { if(pr->num_str >= pr->max_str){ pr->str = Hunk_Double(pr->str); pr->max_str *= 2; } return pr->num_str++; } int PR_SetStr(pr_t *pr, char *s) { int i; if(s == nil || pr->strings == nil) return 0; if(s >= pr->strings && s < pr->strings+pr->strings_size-1) return s - pr->strings; for(i = 0; i < pr->num_str; i++){ if(s == pr->str[i]) return -1-i; } i = PR_StrSlot(pr); pr->str[i] = s; return -1-i; } char * PR_Str(pr_t *pr, int i) { if(i >= 0 && i < pr->strings_size) return pr->strings+i; if(i < 0 && i >= -pr->num_str && pr->str[-1-i] != nil) return pr->str[-1-i]; Con_Printf("PR_Str: invalid offset (strings=%d num_str=%d): %d", pr->strings_size, pr->num_str, i); return nil; } /* ================= ED_ClearEdict Sets everything to nil ================= */ static void ED_ClearEdict(pr_t *pr, edict_t *e) { memset(&e->v, 0, pr->entityfields * 4); e->free = false; } /* ================= ED_Alloc Either finds a free edict, or allocates a new one. Try to avoid reusing an entity that was recently freed, because it can cause the client to think the entity morphed into something else instead of being removed and recreated, which can cause interpolated angles and bad trails. ================= */ edict_t * ED_Alloc(pr_t *pr) { int i; edict_t *e; for(i = svs.maxclients+1; i<pr->num_edicts ; i++){ e = EDICT_NUM(pr, i); // the first couple seconds of server time can involve a lot of // freeing and allocating, so relax the replacement policy if(e->free && (e->freetime < 2 || sv.time - e->freetime > 0.5)){ ED_ClearEdict(pr, e); return e; } } if(i == pr->max_edicts) fatal("ED_Alloc: no free edicts"); pr->num_edicts++; e = EDICT_NUM(pr, i); ED_ClearEdict(pr, e); return e; } /* ================= ED_Free Marks the edict as free FIXME: walk all entities and NULL out references to this entity ================= */ void ED_Free(edict_t *ed) { SV_UnlinkEdict (ed); // unlink from world bsp ed->free = true; ed->v.model = 0; ed->v.takedamage = 0; ed->v.modelindex = 0; ed->v.colormap = 0; ed->v.skin = 0; ed->v.frame = 0; VectorCopy (vec3_origin, ed->v.origin); VectorCopy (vec3_origin, ed->v.angles); ed->v.nextthink = -1; ed->v.solid = 0; ed->alpha = DEFAULT_ALPHA; ed->freetime = sv.time; } //=========================================================================== /* ============ ED_GlobalAtOfs ============ */ static ddef_t * ED_GlobalAtOfs(pr_t *pr, int ofs) { ddef_t *def; int i; for (i=0 ; i<pr->numglobaldefs ; i++) { def = &pr->globaldefs[i]; if (def->ofs == ofs) return def; } return nil; } /* ============ ED_FieldAtOfs ============ */ ddef_t * ED_FieldAtOfs(pr_t *pr, int ofs) { ddef_t *def; int i; for (i=0 ; i<pr->numfielddefs ; i++) { def = &pr->fielddefs[i]; if (def->ofs == ofs) return def; } return nil; } /* ============ ED_FindField ============ */ static ddef_t * ED_FindField(pr_t *pr, char *name) { ddef_t *def; int i; for (i=0 ; i<pr->numfielddefs ; i++) { def = &pr->fielddefs[i]; if (!strcmp(PR_Str(pr, def->s_name),name) ) return def; } return nil; } /* ============ ED_FindGlobal ============ */ static ddef_t * ED_FindGlobal(pr_t *pr, char *name) { ddef_t *def; int i; for (i=0 ; i<pr->numglobaldefs ; i++) { def = &pr->globaldefs[i]; if (!strcmp(PR_Str(pr, def->s_name),name) ) return def; } return nil; } /* ============ ED_FindFunction ============ */ dfunction_t *ED_FindFunction (pr_t *pr, char *name) { dfunction_t *func; int i; for (i=0 ; i<pr->numfunctions ; i++) { func = &pr->functions[i]; if (!strcmp(PR_Str(pr, func->s_name),name) ) return func; } return nil; } eval_t *GetEdictFieldValue(pr_t *pr, edict_t *ed, char *field) { ddef_t *def; int i; static int rep = 0; for (i=0 ; i<GEFV_CACHESIZE ; i++) { if (!strcmp(field, gefvCache[i].field)) { def = gefvCache[i].pcache; goto Done; } } def = ED_FindField (pr, field); if (strlen(field) < MAX_FIELD_LEN) { gefvCache[rep].pcache = def; strcpy (gefvCache[rep].field, field); rep ^= 1; } Done: if (def == nil) return nil; return (eval_t *)((char *)&ed->v + def->ofs*4); } /* ============ PR_ValueString Returns a string describing *data in a type specific manner ============= */ static char * PR_ValueString(pr_t *pr, etype_t type, eval_t *val) { static char line[256]; ddef_t *def; dfunction_t *f; type &= ~DEF_SAVEGLOBAL; switch (type) { case ev_string: sprint (line, "%s", PR_Str(pr, val->string)); break; case ev_entity: sprint (line, "entity %d", NUM_FOR_EDICT(pr, PROG_TO_EDICT(pr, val->edict)) ); break; case ev_function: f = pr->functions + val->function; sprint (line, "%s()", PR_Str(pr, f->s_name)); break; case ev_field: def = ED_FieldAtOfs (pr, val->_int ); sprint (line, ".%s", PR_Str(pr, def->s_name)); break; case ev_void: sprint (line, "void"); break; case ev_float: sprint (line, "%5.1f", val->_float); break; case ev_vector: sprint (line, "'%5.1f %5.1f %5.1f'", val->vector[0], val->vector[1], val->vector[2]); break; case ev_pointer: sprint (line, "pointer"); break; default: sprint (line, "bad type %d", type); break; } return line; } /* ============ PR_UglyValueString Returns a string describing *data in a type specific manner Easier to parse than PR_ValueString ============= */ char *PR_UglyValueString (pr_t *pr, etype_t type, eval_t *val) { static char line[256]; ddef_t *def; dfunction_t *f; type &= ~DEF_SAVEGLOBAL; switch (type) { case ev_string: sprint (line, "%s", PR_Str(pr, val->string)); break; case ev_entity: sprint (line, "%d", NUM_FOR_EDICT(pr, PROG_TO_EDICT(pr, val->edict))); break; case ev_function: f = pr->functions + val->function; sprint (line, "%s", PR_Str(pr, f->s_name)); break; case ev_field: def = ED_FieldAtOfs (pr, val->_int ); sprint (line, "%s", PR_Str(pr, def->s_name)); break; case ev_void: sprint (line, "void"); break; case ev_float: sprint (line, "%f", val->_float); break; case ev_vector: sprint (line, "%f %f %f", val->vector[0], val->vector[1], val->vector[2]); break; default: sprint (line, "bad type %d", type); break; } return line; } /* ============ PR_GlobalString Returns a string with a description and the contents of a global, padded to 20 field width ============ */ char * PR_GlobalString(pr_t *pr, int ofs) { char *s; int i; ddef_t *def; void *val; static char line[128]; val = (void *)&pr->globals[ofs]; def = ED_GlobalAtOfs(pr, ofs); if (!def) sprint (line,"%d(?)", ofs); else { s = PR_ValueString(pr, def->type, val); sprint(line,"%d(%s)%s", ofs, PR_Str(pr, def->s_name), s); } i = strlen(line); for ( ; i<20 ; i++) strcat (line," "); strcat (line," "); return line; } char * PR_GlobalStringNoContents(pr_t *pr, int ofs) { int i; ddef_t *def; static char line[128]; def = ED_GlobalAtOfs(pr, ofs); if (!def) sprint (line,"%d(?)", ofs); else sprint (line,"%d(%s)", ofs, PR_Str(pr, def->s_name)); i = strlen(line); for ( ; i<20 ; i++) strcat (line," "); strcat (line," "); return line; } /* ============= ED_Print For debugging ============= */ void ED_Print (pr_t *pr, edict_t *ed) { int l; ddef_t *d; int *v; int i, j; char *name; int type; if (ed->free) { Con_Printf ("FREE\n"); return; } Con_Printf("\nEDICT %d:\n", NUM_FOR_EDICT(pr, ed)); for (i=1 ; i<pr->numfielddefs ; i++) { d = &pr->fielddefs[i]; name = PR_Str(pr, d->s_name); if (name[strlen(name)-2] == '_') continue; // skip _x, _y, _z vars v = (int *)((char *)&ed->v + d->ofs*4); // if the value is still all 0, skip the field if((type = d->type & ~DEF_SAVEGLOBAL) >= nelem(type_size)) continue; for (j=0 ; j<type_size[type] ; j++) if (v[j]) break; if (j == type_size[type]) continue; Con_Printf ("%s",name); l = strlen (name); while (l++ < 15) Con_Printf (" "); Con_Printf ("%s\n", PR_ValueString(pr, d->type, (eval_t *)v)); } } void ED_PrintNum (pr_t *pr, int ent) { ED_Print (pr, EDICT_NUM(pr, ent)); } /* ============= ED_PrintEdicts For debugging, prints all the entities in the current server ============= */ void ED_PrintEdicts(cmd_t *c) { int i; USED(c); Con_Printf ("%d entities\n", sv.pr->num_edicts); for (i=0 ; i<sv.pr->num_edicts ; i++) ED_PrintNum(sv.pr, i); } /* ============= ED_PrintEdict_f For debugging, prints a single edicy ============= */ static void ED_PrintEdict_f(cmd_t *c) { int i; USED(c); i = atoi(Cmd_Argv(1)); if (i >= sv.pr->num_edicts) { Con_Printf("Bad edict number\n"); return; } ED_PrintNum (sv.pr, i); } /* ============= ED_Count For debugging ============= */ static void ED_Count(cmd_t *c) { int i; edict_t *ent; int active, models, solid, step; USED(c); active = models = solid = step = 0; for (i=0 ; i<sv.pr->num_edicts ; i++) { ent = EDICT_NUM(sv.pr, i); if (ent->free) continue; active++; if (ent->v.solid) solid++; if (ent->v.model) models++; if (ent->v.movetype == MOVETYPE_STEP) step++; } Con_Printf ("num_edicts:%3d\n", sv.pr->num_edicts); Con_Printf ("active :%3d\n", active); Con_Printf ("view :%3d\n", models); Con_Printf ("touch :%3d\n", solid); Con_Printf ("step :%3d\n", step); } /* ============================================================================== ARCHIVING GLOBALS FIXME: need to tag constants, doesn't really work ============================================================================== */ /* ============= ED_ParseGlobals ============= */ void ED_ParseGlobals (pr_t *pr, char *data) { char keyname[64]; ddef_t *key; while (1) { // parse key data = COM_Parse (data); if (com_token[0] == '}') break; if (!data) fatal ("ED_ParseGlobals: EOF without closing brace"); strcpy (keyname, com_token); // parse value data = COM_Parse (data); if (!data) fatal ("ED_ParseGlobals: EOF without closing brace"); if (com_token[0] == '}') fatal ("ED_ParseGlobals: closing brace without data"); key = ED_FindGlobal (pr, keyname); if (!key) { Con_Printf ("ED_ParseGlobals: '%s' is not a global\n", keyname); continue; } if (!ED_ParseEpair (pr, (void *)pr->globals, key, com_token)) Host_Error ("ED_ParseGlobals: parse error"); } } //============================================================================ /* ============= ED_NewString ============= */ string_t ED_NewString (pr_t *pr, char *string) { char *new, *new_p; int i,l, slot; l = strlen(string) + 1; new = Hunk_Alloc(l); new_p = new; slot = PR_StrSlot(pr); for (i=0 ; i< l ; i++) { if (string[i] == '\\' && i < l-1) { i++; if (string[i] == 'n') *new_p++ = '\n'; else *new_p++ = '\\'; } else *new_p++ = string[i]; } pr->str[slot] = new; return -1-slot; } /* ============= ED_ParseEval Can parse either fields or globals returns false if error ============= */ bool ED_ParseEpair (pr_t *pr, void *base, ddef_t *key, char *s) { ddef_t *def; char *v, *w; void *d; dfunction_t *func; int i; d = (void *)((int *)base + key->ofs); switch (key->type & ~DEF_SAVEGLOBAL) { case ev_string: *(string_t *)d = ED_NewString(pr, s); break; case ev_float: *(float *)d = atof(s); break; case ev_vector: memset(d, 0, sizeof(float)*3); w = s; for(i = 0; i < 3; i++, w = v){ ((float*)d)[i] = strtod(w, &v); if(w == v) break; while(*v == ',' || *v == ' ') v++; } for(; i < 3; i++) ((float*)d)[i] = 0; break; case ev_entity: *(int *)d = EDICT_TO_PROG(pr, EDICT_NUM(pr, atoi (s))); break; case ev_field: def = ED_FindField (pr, s); if (!def) { Con_Printf ("Can't find field %s\n", s); return false; } *(int *)d = G_INT(pr, def->ofs); break; case ev_function: func = ED_FindFunction (pr, s); if (!func) { Con_Printf ("Can't find function %s\n", s); return false; } *(func_t *)d = func - pr->functions; break; default: break; } return true; } /* ==================== ED_ParseEdict Parses an edict out of the given string, returning the new position ed should be a properly initialized empty edict. Used for initial level load and for savegames. ==================== */ char *ED_ParseEdict (pr_t *pr, char *data, edict_t *ent) { ddef_t *key; bool anglehack; bool init; char keyname[256]; int n; init = false; // clear it if (ent != pr->edicts) // hack memset (&ent->v, 0, pr->entityfields * 4); // go through all the dictionary pairs while (1) { // parse key data = COM_Parse (data); if (com_token[0] == '}') break; if (!data) fatal ("ED_ParseEdict: EOF without closing brace"); // anglehack is to allow QuakeEd to write single scalar angles // and allow them to be turned into vectors. (FIXME...) if (!strcmp(com_token, "angle")) { strcpy (com_token, "angles"); anglehack = true; } else anglehack = false; // FIXME: change light to _light to get rid of this hack if (!strcmp(com_token, "light")) strcpy (com_token, "light_lev"); // hack for single light def strcpy (keyname, com_token); // another hack to fix heynames with trailing spaces n = strlen(keyname); while (n && keyname[n-1] == ' ') { keyname[n-1] = 0; n--; } // parse value data = COM_Parse (data); if (!data) fatal ("ED_ParseEdict: EOF without closing brace"); if (com_token[0] == '}') fatal ("ED_ParseEdict: closing brace without data"); init = true; // keynames with a leading underscore are used for utility comments, // and are immediately discarded by quake if (keyname[0] == '_') continue; if(strcmp(keyname, "taregtname") == 0) // you'd be surprised (rrp) strcpy(keyname, "targetname"); key = ED_FindField (pr, keyname); if (!key) { if(strcmp(keyname, "alpha") == 0){ ent->alpha = f2alpha(atof(com_token)); }else if(strcmp(keyname, "renderamt") == 0){ ent->alpha = atoi(com_token); if(ent->alpha == ZERO_ALPHA) ent->alpha++; else if(ent->alpha == 0) ent->alpha = ZERO_ALPHA; }else if(strcmp(keyname, "rendermode") == 0){ switch(atoi(com_token)){ case 5: ent->v.effects = (int)ent->v.effects | EF_ADDITIVE; break; default: /* FIXME(sigrid): support more? */ break; } }else{ Con_Printf ("ED_ParseEdict: '%s' is not a field\n", keyname); } continue; } if (anglehack){ char temp[32]; strcpy (temp, com_token); sprint (com_token, "0 %s 0", temp); } if (!ED_ParseEpair (pr, (void *)&ent->v, key, com_token)) Host_Error ("ED_ParseEdict: parse error"); } if (!init) ent->free = true; return data; } /* ================ ED_LoadFromFile The entities are directly placed in the array, rather than allocated with ED_Alloc, because otherwise an error loading the map would have entity number references out of order. Creates a server's entity / program execution context by parsing textual entity definitions out of an ent file. Used for both fresh maps and savegame loads. A fresh map would also need to call ED_CallSpawnFunctions () to let the objects initialize themselves. ================ */ void ED_LoadFromFile (pr_t *pr, char *data) { edict_t *ent; int inhibit; dfunction_t *func; ent = nil; inhibit = 0; pr->global_struct->time = sv.time; // parse ents while (1) { // parse the opening brace data = COM_Parse (data); if (!data) break; if (com_token[0] != '{') fatal ("ED_LoadFromFile: found %s when expecting {", com_token); if (!ent) ent = EDICT_NUM(pr, 0); else ent = ED_Alloc(pr); data = ED_ParseEdict (pr, data, ent); // remove things from different skill levels or deathmatch if (deathmatch.value) { if (((int)ent->v.spawnflags & SPAWNFLAG_NOT_DEATHMATCH)) { ED_Free (ent); inhibit++; continue; } } else if ((current_skill == 0 && ((int)ent->v.spawnflags & SPAWNFLAG_NOT_EASY)) || (current_skill == 1 && ((int)ent->v.spawnflags & SPAWNFLAG_NOT_MEDIUM)) || (current_skill >= 2 && ((int)ent->v.spawnflags & SPAWNFLAG_NOT_HARD)) ) { ED_Free (ent); inhibit++; continue; } // immediately call spawn function if (!ent->v.classname) { Con_Printf ("No classname for:\n"); ED_Print (pr, ent); ED_Free (ent); continue; } // look for the spawn function func = ED_FindFunction (pr, PR_Str(pr, ent->v.classname) ); if (!func) { Con_Printf ("No spawn function for:\n"); ED_Print (pr, ent); ED_Free (ent); continue; } SV_SignonFrame(); pr->global_struct->self = EDICT_TO_PROG(pr, ent); PR_ExecuteProgram (pr, func - pr->functions); } Con_DPrintf("%d entities inhibited\n", inhibit); } typedef struct extra_field_t extra_field_t; struct extra_field_t { int type; char *name; }; static extra_field_t extra_fields[] = { {ev_float, "alpha"}, }; static void PR_FieldDefs(pr_t *pr, byte *in, int num) { extra_field_t *e; ddef_t *d; int i, n; // allocate to fit *all* extra fields, if needed, and copy over pr->numfielddefs = n = num; for(i = 0; i < nelem(extra_fields); i++) n += extra_fields[i].type == ev_vector ? 4 : 1; pr->fielddefs = d = Hunk_Alloc(n * sizeof(*d)); for(i = 0; i < pr->numfielddefs; i++){ d[i].type = le16u(in); d[i].ofs = le16u(in); d[i].s_name = le32(in); } // add missing extra fields d += pr->numfielddefs; for(i = 0, e = extra_fields; i < nelem(extra_fields); i++, e++){ if(ED_FindField(pr, e->name) != nil) continue; d->type = e->type; d->s_name = ED_NewString(pr, e->name); d->ofs = pr->numfielddefs++; d++; if(e->type == ev_vector){ for(n = 0; n < 3; n++){ d->type = ev_float; d->s_name = ED_NewString(pr, va("%s_%c", e->name, 'x'+n)); d->ofs = pr->numfielddefs++; d++; } } pr->entityfields += type_size[e->type]; } } /* =============== PR_LoadProgs =============== */ pr_t *PR_LoadProgs (char *name) { int i, n, version, hdrcrc; byte *in, *in0; dfunction_t *f; dproglump_t *pl; pr_t *pr; static const int elsz[NUM_PR_LUMPS] = { [PR_LUMP_STATEMENTS] = 4*2, [PR_LUMP_GLOBALDEFS] = 2*2+1*4, [PR_LUMP_FIELDDEFS] = 2*2+1*4, [PR_LUMP_FUNCTIONS] = 7*4+MAX_PARMS*1, [PR_LUMP_STRINGS] = 1, [PR_LUMP_GLOBALS] = 4, }; dproglump_t lumps[NUM_PR_LUMPS]; // flush the non-C variable lookup cache for (i=0 ; i<GEFV_CACHESIZE ; i++) gefvCache[i].field[0] = 0; pr = Hunk_Alloc(sizeof(*pr)); pr->max_str = MAX_PRSTR; pr->str = Hunk_Alloc(pr->max_str*sizeof(*pr->str)); pr->num_str = 0; pr->tempstr = Hunk_Alloc(MAX_PRTEMPSTR*PRTEMPSTR_SIZE); pr->num_tempstr = 0; PR_SetStr(pr, ""); in = in0 = loadhunklmp(name, &n); if(in == nil){ err: fatal("PR_LoadProgs: %s", lerr()); } if(n < 15*4){ werrstr("too small"); goto err; } version = le32(in); if(version != PROG_VERSION){ werrstr("wrong version number (%d should be %d)", version, PROG_VERSION); goto err; } hdrcrc = le32(in); initcrc(); for(i = 0; i < n; i++) crc(in0[i]); if(hdrcrc != PROGHEADER_CRC){ werrstr("system vars have been modified, progdefs.h is out of date"); goto err; } for(i = 0, pl = lumps; i < nelem(lumps); i++, pl++){ pl->off = le32(in); pl->num = le32(in); if(pl->num <= 0 || pl->off < 2*4+nelem(lumps)*2*4+4 || pl->off+pl->num*elsz[i] > n){ werrstr("invalid lump: off=%d num=%d elsz=%d total=%d", pl->off, pl->num, elsz[i], n); goto err; } } if((pr->entityfields = le32(in)) <= 0){ werrstr("invalid entityfields"); goto err; } pl = &lumps[PR_LUMP_FUNCTIONS]; pr->functions = f = Hunk_Alloc(pl->num * sizeof(*f)); pr->numfunctions = pl->num; for(i = 0, in = in0 + pl->off; i < pl->num; i++, f++){ f->first_statement = le32(in); f->parm_start = le32(in); f->locals = le32(in); f->profile = le32(in); f->s_name = le32(in); f->s_file = le32(in); f->numparms = le32(in); memmove(f->parm_size, in, MAX_PARMS); in += MAX_PARMS; } pl = &lumps[PR_LUMP_STATEMENTS]; pr->statements = Hunk_Alloc(pl->num * sizeof(*pr->statements)); for(i = 0, in = in0 + pl->off; i < pl->num; i++){ pr->statements[i].op = le16u(in); pr->statements[i].a = le16(in); pr->statements[i].b = le16(in); pr->statements[i].c = le16(in); } pl = &lumps[PR_LUMP_STRINGS]; pr->strings = Hunk_Alloc(pl->num + 1); memmove(pr->strings, in0 + pl->off, pl->num); pr->strings[pr->strings_size = pl->num] = 0; pl = &lumps[PR_LUMP_GLOBALDEFS]; pr->globaldefs = Hunk_Alloc(pl->num * sizeof(*pr->globaldefs)); pr->numglobaldefs = pl->num; for(i = 0, in = in0 + pl->off; i < pl->num; i++){ // FIXME(sigrid): verify all of these as well pr->globaldefs[i].type = le16u(in); pr->globaldefs[i].ofs = le16u(in); pr->globaldefs[i].s_name = le32(in); } pl = &lumps[PR_LUMP_GLOBALS]; pr->globals = (float *)(pr->global_struct = Hunk_Alloc(pl->num * 4)); for(i = 0, in = in0 + pl->off; i < pl->num; i++) ((int*)pr->globals)[i] = le32(in); pl = &lumps[PR_LUMP_FIELDDEFS]; PR_FieldDefs(pr, in0 + pl->off, pl->num); pr->edict_size = pr->entityfields*4 + sizeof(edict_t) - sizeof(entvars_t); // pr->edict_size = (pr->edict_size + 7) & ~7; Con_DPrintf("Programs occupy %dK.\n", n/1024); pr->max_edicts = MAX_EDICTS; pr->edicts = Hunk_Alloc(pr->max_edicts*pr->edict_size); PR_InitSV(pr); return pr; } /* =============== PR_Init =============== */ void PR_Init (void) { Cmd_AddCommand ("edict", ED_PrintEdict_f); Cmd_AddCommand ("edicts", ED_PrintEdicts); Cmd_AddCommand ("edictcount", ED_Count); Cmd_AddCommand ("profile", PR_Profile_f); Cvar_RegisterVariable (&nomonsters); Cvar_RegisterVariable (&gamecfg); Cvar_RegisterVariable (&scratch1); Cvar_RegisterVariable (&scratch2); Cvar_RegisterVariable (&scratch3); Cvar_RegisterVariable (&scratch4); Cvar_RegisterVariable (&savedgamecfg); Cvar_RegisterVariable (&saved1); Cvar_RegisterVariable (&saved2); Cvar_RegisterVariable (&saved3); Cvar_RegisterVariable (&saved4); Cvar_RegisterVariable (&pr_checkextension); } edict_t *EDICT_NUM(pr_t *pr, int n) { if (n < 0 || n >= pr->max_edicts) fatal ("EDICT_NUM: bad number %d", n); return (edict_t *)((byte *)pr->edicts+ (n)*pr->edict_size); } int NUM_FOR_EDICT(pr_t *pr, edict_t *e) { int b; b = (byte *)e - (byte *)pr->edicts; b = b / pr->edict_size; if (b < 0 || b >= pr->num_edicts) fatal ("NUM_FOR_EDICT: bad pointer"); return b; }