/* 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" #define RETURN_EDICT(e) (((int *)pr_globals)[OFS_RETURN] = EDICT_TO_PROG(e)) #ifdef USEFPM #define RETURN_EDICTFPM(e) (((int *)pr_globals)[OFS_RETURN] = EDICT_TO_PROGFPM(e)) #endif /* =============================================================================== BUILT-IN FUNCTIONS =============================================================================== */ char *PF_VarString (int first) { int i; static char out[256]; out[0] = 0; for (i=first ; is_name,s); ed = PROG_TO_EDICT(pr_global_struct->self); ED_Print (ed); Host_Error ("Program error"); } #ifdef USEFPM void PF_errorFPM (void) { char *s; edict_FPM_t *ed; s = PF_VarString(0); Con_Printf ("======SERVER ERROR in %s:\n%s\n" ,pr_strings + pr_xfunction->s_name,s); ed = PROG_TO_EDICTFPM(pr_global_struct->self); ED_PrintFPM (ed); Host_Error ("Program error"); } #endif /* ================= PF_objerror Dumps out self, then an error message. The program is aborted and self is removed, but the level can continue. objerror(value) ================= */ void PF_objerror (void) { char *s; edict_t *ed; s = PF_VarString(0); Con_Printf ("======OBJECT ERROR in %s:\n%s\n" ,pr_strings + pr_xfunction->s_name,s); ed = PROG_TO_EDICT(pr_global_struct->self); ED_Print (ed); ED_Free (ed); Host_Error ("Program error"); } #ifdef USEFPM void PF_objerrorFPM (void) { char *s; edict_FPM_t *ed; s = PF_VarString(0); Con_Printf ("======OBJECT ERROR in %s:\n%s\n" ,pr_strings + pr_xfunction->s_name,s); ed = PROG_TO_EDICTFPM(pr_global_struct->self); ED_PrintFPM (ed); ED_FreeFPM (ed); Host_Error ("Program error"); } #endif /* ============== PF_makevectors Writes new values for v_forward, v_up, and v_right based on angles makevectors(vector) ============== */ void PF_makevectors (void) { AngleVectors (G_VECTOR(OFS_PARM0), pr_global_struct->v_forward, pr_global_struct->v_right, pr_global_struct->v_up); } /* ================= PF_setorigin This is the only valid way to move an object without using the physics of the world (setting velocity and waiting). Directly changing origin will not set internal links correctly, so clipping would be messed up. This should be called when an object is spawned, and then only if it is teleported. setorigin (entity, origin) ================= */ void PF_setorigin (void) { edict_t *e; float *org; e = G_EDICT(OFS_PARM0); org = G_VECTOR(OFS_PARM1); VectorCopy (org, e->v.origin); SV_LinkEdict (e, false); } #ifdef USEFPM void PF_setoriginFPM (void) { edict_FPM_t *e; float *org; e = G_EDICTFPM(OFS_PARM0); org = G_VECTOR(OFS_PARM1); VectorCopy (org, e->v.origin); SV_LinkEdictFPM (e, false); } #endif void SetMinMaxSize (edict_t *e, float *min, float *max, qboolean rotate) { float *angles; vec3_t rmin, rmax; float bounds[2][3]; float xvector[2], yvector[2]; float a; vec3_t base, transformed; int i, j, k, l; for (i=0 ; i<3 ; i++) if (min[i] > max[i]) PR_RunError ("backwards mins/maxs"); rotate = false; // FIXME: implement rotation properly again if (!rotate) { VectorCopy (min, rmin); VectorCopy (max, rmax); } else { // find min / max for rotations angles = e->v.angles; a = (float)(angles[1]/180 * M_PI); xvector[0] = (float)cos(a); xvector[1] = (float)sin(a); yvector[0] = (float)-sin(a); yvector[1] = (float)cos(a); VectorCopy (min, bounds[0]); VectorCopy (max, bounds[1]); rmin[0] = rmin[1] = rmin[2] = 9999; rmax[0] = rmax[1] = rmax[2] = -9999; for (i=0 ; i<= 1 ; i++) { base[0] = bounds[i][0]; for (j=0 ; j<= 1 ; j++) { base[1] = bounds[j][1]; for (k=0 ; k<= 1 ; k++) { base[2] = bounds[k][2]; // transform the point transformed[0] = xvector[0]*base[0] + yvector[0]*base[1]; transformed[1] = xvector[1]*base[0] + yvector[1]*base[1]; transformed[2] = base[2]; for (l=0 ; l<3 ; l++) { if (transformed[l] < rmin[l]) rmin[l] = transformed[l]; if (transformed[l] > rmax[l]) rmax[l] = transformed[l]; } } } } } // set derived values VectorCopy (rmin, e->v.mins); VectorCopy (rmax, e->v.maxs); VectorSubtract (max, min, e->v.size); SV_LinkEdict (e, false); } #ifdef USEFPM void SetMinMaxSizeFPM (edict_FPM_t *e, float *min, float *max, qboolean rotate) { float *angles; vec3_t rmin, rmax; float bounds[2][3]; float xvector[2], yvector[2]; float a; vec3_t base, transformed; int i, j, k, l; for (i=0 ; i<3 ; i++) if (min[i] > max[i]) PR_RunError ("backwards mins/maxs"); rotate = false; // FIXME: implement rotation properly again if (!rotate) { VectorCopy (min, rmin); VectorCopy (max, rmax); } else { // find min / max for rotations angles = e->v.angles; a = (float)(angles[1]/180 * M_PI); xvector[0] = (float)cos(a); xvector[1] = (float)sin(a); yvector[0] = (float)-sin(a); yvector[1] = (float)cos(a); VectorCopy (min, bounds[0]); VectorCopy (max, bounds[1]); rmin[0] = rmin[1] = rmin[2] = 9999; rmax[0] = rmax[1] = rmax[2] = -9999; for (i=0 ; i<= 1 ; i++) { base[0] = bounds[i][0]; for (j=0 ; j<= 1 ; j++) { base[1] = bounds[j][1]; for (k=0 ; k<= 1 ; k++) { base[2] = bounds[k][2]; // transform the point transformed[0] = xvector[0]*base[0] + yvector[0]*base[1]; transformed[1] = xvector[1]*base[0] + yvector[1]*base[1]; transformed[2] = base[2]; for (l=0 ; l<3 ; l++) { if (transformed[l] < rmin[l]) rmin[l] = transformed[l]; if (transformed[l] > rmax[l]) rmax[l] = transformed[l]; } } } } } // set derived values VectorCopy (rmin, e->v.mins); VectorCopy (rmax, e->v.maxs); VectorSubtract (max, min, e->v.size); SV_LinkEdictFPM (e, false); } #endif /* ================= PF_setsize the size box is rotated by the current angle setsize (entity, minvector, maxvector) ================= */ void PF_setsize (void) { edict_t *e; float *min, *max; e = G_EDICT(OFS_PARM0); min = G_VECTOR(OFS_PARM1); max = G_VECTOR(OFS_PARM2); SetMinMaxSize (e, min, max, false); } #ifdef USEFPM void PF_setsizeFPM (void) { edict_FPM_t *e; float *min, *max; e = G_EDICTFPM(OFS_PARM0); min = G_VECTOR(OFS_PARM1); max = G_VECTOR(OFS_PARM2); SetMinMaxSizeFPM (e, min, max, false); } #endif /* ================= PF_setmodel setmodel(entity, model) ================= */ void PF_setmodel (void) { edict_t *e; char *m, **check; model_t *mod; int i; e = G_EDICT(OFS_PARM0); m = G_STRING(OFS_PARM1); // check to see if model was properly precached for (i=0, check = sv.model_precache ; *check ; i++, check++) if (!strcmp(*check, m)) break; if (!*check) PR_RunError ("no precache: %s\n", m); e->v.model = m - pr_strings; e->v.modelindex = (float)i; //SV_ModelIndex (m); mod = sv.models[ (int)e->v.modelindex]; // Mod_ForName (m, true); if (mod) SetMinMaxSize (e, mod->mins, mod->maxs, true); else SetMinMaxSize (e, vec3_origin, vec3_origin, true); } #ifdef USEFPM void PF_setmodelFPM (void) { edict_FPM_t *e; char *m, **check; model_FPM_t *mod; int i; vec3_t mins, maxs; e = G_EDICTFPM(OFS_PARM0); m = G_STRING(OFS_PARM1); // check to see if model was properly precached for (i=0, check = svFPM.model_precache ; *check ; i++, check++) if (!strcmp(*check, m)) break; if (!*check) PR_RunError ("no precache: %s\n", m); e->v.model = m - pr_strings; e->v.modelindex = (float)i; //SV_ModelIndex (m); mod = svFPM.models[ (int)e->v.modelindex]; // Mod_ForName (m, true); if (mod) { mins[0]=FPM_TOFLOAT(mod->mins[0]); mins[1]=FPM_TOFLOAT(mod->mins[1]); mins[2]=FPM_TOFLOAT(mod->mins[2]); maxs[0]=FPM_TOFLOAT(mod->maxs[0]); maxs[1]=FPM_TOFLOAT(mod->maxs[1]); maxs[2]=FPM_TOFLOAT(mod->maxs[2]); SetMinMaxSizeFPM (e, mins, maxs, true); } else { mins[0]=FPM_TOFLOAT(vec3_originFPM[0]); mins[1]=FPM_TOFLOAT(vec3_originFPM[1]); mins[2]=FPM_TOFLOAT(vec3_originFPM[2]); SetMinMaxSizeFPM (e, mins, mins, true); } } #endif /* ================= PF_bprint broadcast print to everyone on server bprint(value) ================= */ void PF_bprint (void) { char *s; s = PF_VarString(0); SV_BroadcastPrintf ("%s", s); } /* ================= PF_sprint single print to a specific client sprint(clientent, value) ================= */ void PF_sprint (void) { char *s; client_t *client; int entnum; entnum = G_EDICTNUM(OFS_PARM0); s = PF_VarString(1); if (entnum < 1 || entnum > svs.maxclients) { Con_Printf ("tried to sprint to a non-client\n"); return; } client = &svs.clients[entnum-1]; MSG_WriteChar (&client->message,svc_print); MSG_WriteString (&client->message, s ); } #ifdef USEFPM void PF_sprintFPM (void) { char *s; client_FPM_t *client; int entnum; entnum = G_EDICTNUMFPM(OFS_PARM0); s = PF_VarString(1); if (entnum < 1 || entnum > svsFPM.maxclients) { Con_Printf ("tried to sprint to a non-client\n"); return; } client = &svsFPM.clients[entnum-1]; MSG_WriteChar (&client->message,svc_print); MSG_WriteString (&client->message, s ); } #endif /* ================= PF_centerprint single print to a specific client centerprint(clientent, value) ================= */ void PF_centerprint (void) { char *s; client_t *client; int entnum; entnum = G_EDICTNUM(OFS_PARM0); s = PF_VarString(1); if (entnum < 1 || entnum > svs.maxclients) { Con_Printf ("tried to sprint to a non-client\n"); return; } client = &svs.clients[entnum-1]; MSG_WriteChar (&client->message,svc_centerprint); MSG_WriteString (&client->message, s ); } #ifdef USEFPM void PF_centerprintFPM (void) { char *s; client_FPM_t *client; int entnum; entnum = G_EDICTNUMFPM(OFS_PARM0); s = PF_VarString(1); if (entnum < 1 || entnum > svsFPM.maxclients) { Con_Printf ("tried to sprint to a non-client\n"); return; } client = &svsFPM.clients[entnum-1]; MSG_WriteChar (&client->message,svc_centerprint); MSG_WriteString (&client->message, s ); } #endif /* ================= PF_normalize vector normalize(vector) ================= */ void PF_normalize (void) { float *value1; vec3_t newvalue; float new; value1 = G_VECTOR(OFS_PARM0); new = value1[0] * value1[0] + value1[1] * value1[1] + value1[2]*value1[2]; new = (float)sqrt(new); if (new == 0) newvalue[0] = newvalue[1] = newvalue[2] = 0; else { new = 1/new; newvalue[0] = value1[0] * new; newvalue[1] = value1[1] * new; newvalue[2] = value1[2] * new; } VectorCopy (newvalue, G_VECTOR(OFS_RETURN)); } /* ================= PF_vlen scalar vlen(vector) ================= */ void PF_vlen (void) { float *value1; float new; value1 = G_VECTOR(OFS_PARM0); new = value1[0] * value1[0] + value1[1] * value1[1] + value1[2]*value1[2]; new = (float)sqrt(new); G_FLOAT(OFS_RETURN) = new; } /* ================= PF_vectoyaw float vectoyaw(vector) ================= */ void PF_vectoyaw (void) { float *value1; float yaw; value1 = G_VECTOR(OFS_PARM0); if (value1[1] == 0 && value1[0] == 0) yaw = 0; else { yaw = (float)(int) (atan2(value1[1], value1[0]) * 180 / M_PI); if (yaw < 0) yaw += 360; } G_FLOAT(OFS_RETURN) = yaw; } /* ================= PF_vectoangles vector vectoangles(vector) ================= */ void PF_vectoangles (void) { float *value1; float forward; float yaw, pitch; value1 = G_VECTOR(OFS_PARM0); if (value1[1] == 0 && value1[0] == 0) { yaw = 0; if (value1[2] > 0) pitch = 90; else pitch = 270; } else { yaw = (float)(int) (atan2(value1[1], value1[0]) * 180 / M_PI); if (yaw < 0) yaw += 360; forward = (float)sqrt (value1[0]*value1[0] + value1[1]*value1[1]); pitch = (float)(int) (atan2(value1[2], forward) * 180 / M_PI); if (pitch < 0) pitch += 360; } G_FLOAT(OFS_RETURN+0) = pitch; G_FLOAT(OFS_RETURN+1) = yaw; G_FLOAT(OFS_RETURN+2) = 0; } /* ================= PF_Random Returns a number from 0<= num < 1 random() ================= */ void PF_random (void) { float num; num = (rand ()&0x7fff) / ((float)0x7fff); G_FLOAT(OFS_RETURN) = num; } /* ================= PF_particle particle(origin, color, count) ================= */ void PF_particle (void) { float *org, *dir; float color; float count; org = G_VECTOR(OFS_PARM0); dir = G_VECTOR(OFS_PARM1); color = G_FLOAT(OFS_PARM2); count = G_FLOAT(OFS_PARM3); SV_StartParticle (org, dir, (int)color, (int)count); } #ifdef USEFPM void PF_particleFPM (void) { float *org, *dir; float color; float count; vec3_FPM_t orgFPM, dirFPM; org = G_VECTOR(OFS_PARM0); dir = G_VECTOR(OFS_PARM1); color = G_FLOAT(OFS_PARM2); count = G_FLOAT(OFS_PARM3); orgFPM[0]=FPM_FROMFLOAT(org[0]); orgFPM[1]=FPM_FROMFLOAT(org[1]); orgFPM[2]=FPM_FROMFLOAT(org[2]); dirFPM[0]=FPM_FROMFLOAT(dir[0]); dirFPM[1]=FPM_FROMFLOAT(dir[1]); dirFPM[2]=FPM_FROMFLOAT(dir[2]); SV_StartParticleFPM (orgFPM, dirFPM, (int)color, (int)count); } #endif /* ================= PF_ambientsound ================= */ void PF_ambientsound (void) { char **check; char *samp; float *pos; float vol, attenuation; int i, soundnum; pos = G_VECTOR (OFS_PARM0); samp = G_STRING(OFS_PARM1); vol = G_FLOAT(OFS_PARM2); attenuation = G_FLOAT(OFS_PARM3); // check to see if samp was properly precached for (soundnum=0, check = sv.sound_precache ; *check ; check++, soundnum++) if (!strcmp(*check,samp)) break; if (!*check) { Con_Printf ("no precache: %s\n", samp); return; } // add an svc_spawnambient command to the level signon packet MSG_WriteByte (&sv.signon,svc_spawnstaticsound); for (i=0 ; i<3 ; i++) MSG_WriteCoord(&sv.signon, pos[i]); MSG_WriteByte (&sv.signon, soundnum); MSG_WriteByte (&sv.signon, (int)(vol*255)); MSG_WriteByte (&sv.signon, (int)(attenuation*64)); } #ifdef USEFPM void PF_ambientsoundFPM (void) { char **check; char *samp; float *pos; float vol, attenuation; int i, soundnum; pos = G_VECTOR (OFS_PARM0); samp = G_STRING(OFS_PARM1); vol = G_FLOAT(OFS_PARM2); attenuation = G_FLOAT(OFS_PARM3); // check to see if samp was properly precached for (soundnum=0, check = svFPM.sound_precache ; *check ; check++, soundnum++) if (!strcmp(*check,samp)) break; if (!*check) { Con_Printf ("no precache: %s\n", samp); return; } // add an svc_spawnambient command to the level signon packet MSG_WriteByte (&svFPM.signon,svc_spawnstaticsound); for (i=0 ; i<3 ; i++) MSG_WriteCoord(&svFPM.signon, pos[i]); MSG_WriteByte (&svFPM.signon, soundnum); MSG_WriteByte (&svFPM.signon, (int)(vol*255)); MSG_WriteByte (&svFPM.signon, (int)(attenuation*64)); } #endif /* ================= PF_sound Each entity can have eight independant sound sources, like voice, weapon, feet, etc. Channel 0 is an auto-allocate channel, the others override anything allready running on that entity/channel pair. An attenuation of 0 will play full volume everywhere in the level. Larger attenuations will drop off. ================= */ void PF_sound (void) { char *sample; int channel; edict_t *entity; int volume; float attenuation; entity = G_EDICT(OFS_PARM0); channel = (int)G_FLOAT(OFS_PARM1); sample = G_STRING(OFS_PARM2); volume = (int)G_FLOAT(OFS_PARM3) * 255; attenuation = G_FLOAT(OFS_PARM4); if (volume < 0 || volume > 255) Sys_Error ("SV_StartSound: volume = %i", volume); if (attenuation < 0 || attenuation > 4) Sys_Error ("SV_StartSound: attenuation = %f", attenuation); if (channel < 0 || channel > 7) Sys_Error ("SV_StartSound: channel = %i", channel); SV_StartSound (entity, channel, sample, volume, attenuation); } #ifdef USEFPM void PF_soundFPM (void) { char *sample; int channel; edict_FPM_t *entity; int volume; float attenuation; entity = G_EDICTFPM(OFS_PARM0); channel = (int)G_FLOAT(OFS_PARM1); sample = G_STRING(OFS_PARM2); volume = (int)G_FLOAT(OFS_PARM3) * 255; attenuation = G_FLOAT(OFS_PARM4); if (volume < 0 || volume > 255) Sys_Error ("SV_StartSound: volume = %i", volume); if (attenuation < 0 || attenuation > 4) Sys_Error ("SV_StartSound: attenuation = %f", attenuation); if (channel < 0 || channel > 7) Sys_Error ("SV_StartSound: channel = %i", channel); SV_StartSoundFPM (entity, channel, sample, volume, attenuation); } #endif /* ================= PF_break break() ================= */ void PF_break (void) { Con_Printf ("break statement\n"); *(int *)-4 = 0; // dump to debugger // PR_RunError ("break statement"); } /* ================= PF_traceline Used for use tracing and shot targeting Traces are blocked by bbox and exact bsp entityes, and also slide box entities if the tryents flag is set. traceline (vector1, vector2, tryents) ================= */ void PF_traceline (void) { float *v1, *v2; trace_t trace; int nomonsters; edict_t *ent; v1 = G_VECTOR(OFS_PARM0); v2 = G_VECTOR(OFS_PARM1); nomonsters = (int)G_FLOAT(OFS_PARM2); ent = G_EDICT(OFS_PARM3); trace = SV_Move (v1, vec3_origin, vec3_origin, v2, nomonsters, ent); pr_global_struct->trace_allsolid = (float)trace.allsolid; pr_global_struct->trace_startsolid = (float)trace.startsolid; pr_global_struct->trace_fraction = trace.fraction; pr_global_struct->trace_inwater = (float)trace.inwater; pr_global_struct->trace_inopen = (float)trace.inopen; VectorCopy (trace.endpos, pr_global_struct->trace_endpos); VectorCopy (trace.plane.normal, pr_global_struct->trace_plane_normal); pr_global_struct->trace_plane_dist = trace.plane.dist; if (trace.ent) pr_global_struct->trace_ent = EDICT_TO_PROG(trace.ent); else pr_global_struct->trace_ent = EDICT_TO_PROG(sv.edicts); } #ifdef USEFPM void PF_tracelineFPM (void) { float *v1, *v2; trace_FPM_t trace; int nomonsters; edict_FPM_t *ent; vec3_FPM_t v1FPM, v2FPM; v1 = G_VECTOR(OFS_PARM0); v2 = G_VECTOR(OFS_PARM1); nomonsters = (int)G_FLOAT(OFS_PARM2); ent = G_EDICTFPM(OFS_PARM3); v1FPM[0]=FPM_FROMFLOAT(v1[0]); v1FPM[1]=FPM_FROMFLOAT(v1[1]); v1FPM[2]=FPM_FROMFLOAT(v1[2]); v2FPM[0]=FPM_FROMFLOAT(v2[0]); v2FPM[1]=FPM_FROMFLOAT(v2[1]); v2FPM[2]=FPM_FROMFLOAT(v2[2]); trace = SV_MoveFPM (v1FPM, vec3_originFPM, vec3_originFPM, v2FPM, nomonsters, ent); pr_global_struct->trace_allsolid = (float)trace.allsolid; pr_global_struct->trace_startsolid = (float)trace.startsolid; pr_global_struct->trace_fraction = FPM_TOFLOAT(trace.fraction); pr_global_struct->trace_inwater = (float)trace.inwater; pr_global_struct->trace_inopen = (float)trace.inopen; pr_global_struct->trace_endpos[0]=FPM_TOFLOAT(trace.endpos[0]); pr_global_struct->trace_endpos[1]=FPM_TOFLOAT(trace.endpos[1]); pr_global_struct->trace_endpos[2]=FPM_TOFLOAT(trace.endpos[2]); pr_global_struct->trace_plane_normal[0]=FPM_TOFLOAT(trace.plane.normal[0]); pr_global_struct->trace_plane_normal[1]=FPM_TOFLOAT(trace.plane.normal[1]); pr_global_struct->trace_plane_normal[2]=FPM_TOFLOAT(trace.plane.normal[2]); //VectorCopy (trace.endpos, pr_global_struct->trace_endpos); //VectorCopy (trace.plane.normal, pr_global_struct->trace_plane_normal); pr_global_struct->trace_plane_dist = FPM_TOFLOAT(trace.plane.dist); if (trace.ent) pr_global_struct->trace_ent = EDICT_TO_PROGFPM(trace.ent); else pr_global_struct->trace_ent = EDICT_TO_PROGFPM(svFPM.edicts); } #endif #ifdef QUAKE2 extern trace_t SV_Trace_Toss (edict_t *ent, edict_t *ignore); void PF_TraceToss (void) { trace_t trace; edict_t *ent; edict_t *ignore; ent = G_EDICT(OFS_PARM0); ignore = G_EDICT(OFS_PARM1); trace = SV_Trace_Toss (ent, ignore); pr_global_struct->trace_allsolid = trace.allsolid; pr_global_struct->trace_startsolid = trace.startsolid; pr_global_struct->trace_fraction = trace.fraction; pr_global_struct->trace_inwater = trace.inwater; pr_global_struct->trace_inopen = trace.inopen; VectorCopy (trace.endpos, pr_global_struct->trace_endpos); VectorCopy (trace.plane.normal, pr_global_struct->trace_plane_normal); pr_global_struct->trace_plane_dist = trace.plane.dist; if (trace.ent) pr_global_struct->trace_ent = EDICT_TO_PROG(trace.ent); else pr_global_struct->trace_ent = EDICT_TO_PROG(sv.edicts); } #endif /* ================= PF_checkpos Returns true if the given entity can move to the given position from it's current position by walking or rolling. FIXME: make work... scalar checkpos (entity, vector) ================= */ void PF_checkpos (void) { } //============================================================================ byte checkpvs[MAX_MAP_LEAFS/8]; int PF_newcheckclient (int check) { int i; byte *pvs; edict_t *ent; mleaf_t *leaf; vec3_t org; // cycle to the next one if (check < 1) check = 1; if (check > svs.maxclients) check = svs.maxclients; if (check == svs.maxclients) i = 1; else i = check + 1; for ( ; ; i++) { if (i == svs.maxclients+1) i = 1; ent = EDICT_NUM(i); if (i == check) break; // didn't find anything else if (ent->free) continue; if (ent->v.health <= 0) continue; if ((int)ent->v.flags & FL_NOTARGET) continue; // anything that is a client, or has a client as an enemy break; } // get the PVS for the entity VectorAdd (ent->v.origin, ent->v.view_ofs, org); leaf = Mod_PointInLeaf (org, sv.worldmodel); pvs = Mod_LeafPVS (leaf, sv.worldmodel); Q_memcpy (checkpvs, pvs, (sv.worldmodel->numleafs+7)>>3 ); return i; } #ifdef USEFPM int PF_newcheckclientFPM (int check) { int i; byte *pvs; edict_FPM_t *ent; mleaf_FPM_t *leaf; vec3_FPM_t org; vec3_t tmp; // cycle to the next one if (check < 1) check = 1; if (check > svsFPM.maxclients) check = svsFPM.maxclients; if (check == svsFPM.maxclients) i = 1; else i = check + 1; for ( ; ; i++) { if (i == svsFPM.maxclients+1) i = 1; ent = EDICT_NUMFPM(i); if (i == check) break; // didn't find anything else if (ent->free) continue; if (ent->v.health <= 0) continue; if ((int)ent->v.flags & FL_NOTARGET) continue; // anything that is a client, or has a client as an enemy break; } // get the PVS for the entity VectorAdd (ent->v.origin, ent->v.view_ofs, tmp); VectorToFPM(tmp, org); leaf = Mod_PointInLeafFPM (org, svFPM.worldmodel); pvs = Mod_LeafPVSFPM (leaf, svFPM.worldmodel); Q_memcpy (checkpvs, pvs, (svFPM.worldmodel->numleafs+7)>>3 ); return i; } #endif /* ================= PF_checkclient Returns a client (or object that has a client enemy) that would be a valid target. If there are more than one valid options, they are cycled each frame If (self.origin + self.viewofs) is not in the PVS of the current target, it is not returned at all. name checkclient () ================= */ #define MAX_CHECK 16 int c_invis, c_notvis; void PF_checkclient (void) { edict_t *ent, *self; mleaf_t *leaf; int l; vec3_t view; // find a new check if on a new frame if (sv.time - sv.lastchecktime >= 0.1) { sv.lastcheck = PF_newcheckclient (sv.lastcheck); sv.lastchecktime = sv.time; } // return check if it might be visible ent = EDICT_NUM(sv.lastcheck); if (ent->free || ent->v.health <= 0) { RETURN_EDICT(sv.edicts); return; } // if current entity can't possibly see the check entity, return 0 self = PROG_TO_EDICT(pr_global_struct->self); VectorAdd (self->v.origin, self->v.view_ofs, view); leaf = Mod_PointInLeaf (view, sv.worldmodel); l = (leaf - sv.worldmodel->leafs) - 1; if ( (l<0) || !(checkpvs[l>>3] & (1<<(l&7)) ) ) { c_notvis++; RETURN_EDICT(sv.edicts); return; } // might be able to see it c_invis++; RETURN_EDICT(ent); } #ifdef USEFPM void PF_checkclientFPM (void) { edict_FPM_t *ent, *self; mleaf_FPM_t *leaf; int l; vec3_FPM_t view; vec3_t tmp; // find a new check if on a new frame if (svFPM.time - svFPM.lastchecktime >= 0.1) { svFPM.lastcheck = PF_newcheckclientFPM (svFPM.lastcheck); svFPM.lastchecktime = svFPM.time; } // return check if it might be visible ent = EDICT_NUMFPM(svFPM.lastcheck); if (ent->free || ent->v.health <= 0) { RETURN_EDICTFPM(svFPM.edicts); return; } // if current entity can't possibly see the check entity, return 0 self = PROG_TO_EDICTFPM(pr_global_struct->self); VectorAdd (self->v.origin, self->v.view_ofs, tmp); VectorToFPM(tmp, view); leaf = Mod_PointInLeafFPM (view, svFPM.worldmodel); l = (leaf - svFPM.worldmodel->leafs) - 1; if ( (l<0) || !(checkpvs[l>>3] & (1<<(l&7)) ) ) { c_notvis++; RETURN_EDICTFPM(svFPM.edicts); return; } // might be able to see it c_invis++; RETURN_EDICTFPM(ent); } #endif //============================================================================ /* ================= PF_stuffcmd Sends text over to the client's execution buffer stuffcmd (clientent, value) ================= */ void PF_stuffcmd (void) { int entnum; char *str; client_t *old; entnum = G_EDICTNUM(OFS_PARM0); if (entnum < 1 || entnum > svs.maxclients) PR_RunError ("Parm 0 not a client"); str = G_STRING(OFS_PARM1); old = host_client; host_client = &svs.clients[entnum-1]; Host_ClientCommands ("%s", str); host_client = old; } #ifdef USEFPM void PF_stuffcmdFPM (void) { int entnum; char *str; client_FPM_t *old; entnum = G_EDICTNUMFPM(OFS_PARM0); if (entnum < 1 || entnum > svsFPM.maxclients) PR_RunError ("Parm 0 not a client"); str = G_STRING(OFS_PARM1); old = host_clientFPM; host_clientFPM = &svsFPM.clients[entnum-1]; Host_ClientCommandsFPM ("%s", str); host_clientFPM = old; } #endif /* ================= PF_localcmd Sends text over to the client's execution buffer localcmd (string) ================= */ void PF_localcmd (void) { char *str; str = G_STRING(OFS_PARM0); Cbuf_AddText (str); } #ifdef USEFPM void PF_localcmdFPM (void) { char *str; str = G_STRING(OFS_PARM0); Cbuf_AddText (str); } #endif /* ================= PF_cvar float cvar (string) ================= */ void PF_cvar (void) { char *str; str = G_STRING(OFS_PARM0); G_FLOAT(OFS_RETURN) = Cvar_VariableValue (str); } #ifdef USEFPM void PF_cvarFPM (void) { char *str; str = G_STRING(OFS_PARM0); G_FLOAT(OFS_RETURN) = Cvar_VariableValue (str); } #endif /* ================= PF_cvar_set float cvar (string) ================= */ void PF_cvar_set (void) { char *var, *val; var = G_STRING(OFS_PARM0); val = G_STRING(OFS_PARM1); Cvar_Set (var, val); } #ifdef USEFPM void PF_cvar_setFPM (void) { char *var, *val; var = G_STRING(OFS_PARM0); val = G_STRING(OFS_PARM1); Cvar_Set (var, val); } #endif /* ================= PF_findradius Returns a chain of entities that have origins within a spherical area findradius (origin, radius) ================= */ void PF_findradius (void) { edict_t *ent, *chain; float rad; float *org; vec3_t eorg; int i, j; chain = (edict_t *)sv.edicts; org = G_VECTOR(OFS_PARM0); rad = G_FLOAT(OFS_PARM1); ent = NEXT_EDICT(sv.edicts); for (i=1 ; ifree) continue; if (ent->v.solid == SOLID_NOT) continue; for (j=0 ; j<3 ; j++) eorg[j] = (float)(org[j] - (ent->v.origin[j] + (ent->v.mins[j] + ent->v.maxs[j])*0.5)); if (Length(eorg) > rad) continue; ent->v.chain = EDICT_TO_PROG(chain); chain = ent; } RETURN_EDICT(chain); } #ifdef USEFPM void PF_findradiusFPM (void) { edict_FPM_t *ent, *chain; float rad; float *org; vec3_t eorg; int i, j; chain = (edict_FPM_t *)svFPM.edicts; org = G_VECTOR(OFS_PARM0); rad = G_FLOAT(OFS_PARM1); ent = NEXT_EDICTFPM(svFPM.edicts); for (i=1 ; ifree) continue; if (ent->v.solid == SOLID_NOT) continue; for (j=0 ; j<3 ; j++) eorg[j] = (float)(org[j] - (ent->v.origin[j] + (ent->v.mins[j] + ent->v.maxs[j])*0.5)); if (Length(eorg) > rad) continue; ent->v.chain = EDICT_TO_PROGFPM(chain); chain = ent; } RETURN_EDICTFPM(chain); } #endif /* ========= PF_dprint ========= */ void PF_dprint (void) { Con_DPrintf ("%s",PF_VarString(0)); } #ifdef USEFPM void PF_dprintFPM (void) { Con_DPrintf ("%s",PF_VarString(0)); } #endif char pr_string_temp[128]; void PF_ftos (void) { float v; v = G_FLOAT(OFS_PARM0); if (v == (int)v) sprintf (pr_string_temp, "%d",(int)v); else sprintf (pr_string_temp, "%5.1f",v); G_INT(OFS_RETURN) = pr_string_temp - pr_strings; } #ifdef USEFPM void PF_ftosFPM (void) { float v; v = G_FLOAT(OFS_PARM0); if (v == (int)v) sprintf (pr_string_temp, "%d",(int)v); else sprintf (pr_string_temp, "%5.1f",v); G_INT(OFS_RETURN) = pr_string_temp - pr_strings; } #endif void PF_fabs (void) { float v; v = G_FLOAT(OFS_PARM0); G_FLOAT(OFS_RETURN) = (float)fabs(v); } #ifdef USEFPM void PF_fabsFPM (void) { float v; v = G_FLOAT(OFS_PARM0); G_FLOAT(OFS_RETURN) = (float)fabs(v); } #endif //USEFPM void PF_vtos (void) { sprintf (pr_string_temp, "'%5.1f %5.1f %5.1f'", G_VECTOR(OFS_PARM0)[0], G_VECTOR(OFS_PARM0)[1], G_VECTOR(OFS_PARM0)[2]); G_INT(OFS_RETURN) = pr_string_temp - pr_strings; } #ifdef USEFPM void PF_vtosFPM (void) { sprintf (pr_string_temp, "'%5.1f %5.1f %5.1f'", G_VECTOR(OFS_PARM0)[0], G_VECTOR(OFS_PARM0)[1], G_VECTOR(OFS_PARM0)[2]); G_INT(OFS_RETURN) = pr_string_temp - pr_strings; } #endif //USEFPM #ifdef QUAKE2 void PF_etos (void) { sprintf (pr_string_temp, "entity %i", G_EDICTNUM(OFS_PARM0)); G_INT(OFS_RETURN) = pr_string_temp - pr_strings; } #ifdef USEFPM void PF_etosFPM (void) { sprintf (pr_string_temp, "entity %i", G_EDICTNUMFPM(OFS_PARM0)); G_INT(OFS_RETURN) = pr_string_temp - pr_strings; } #endif //USEFPM #endif void PF_Spawn (void) { edict_t *ed; ed = ED_Alloc(); RETURN_EDICT(ed); } #ifdef USEFPM void PF_SpawnFPM (void) { edict_FPM_t *ed; ed = ED_AllocFPM(); RETURN_EDICTFPM(ed); } #endif //USEFPM void PF_Remove (void) { edict_t *ed; ed = G_EDICT(OFS_PARM0); ED_Free (ed); } #ifdef USEFPM void PF_RemoveFPM (void) { edict_FPM_t *ed; ed = G_EDICTFPM(OFS_PARM0); ED_FreeFPM (ed); } #endif //USEFPM // entity (entity start, .string field, string match) find = #5; void PF_Find (void) #ifdef QUAKE2 { int e; int f; char *s, *t; edict_t *ed; edict_t *first; edict_t *second; edict_t *last; first = second = last = (edict_t *)sv.edicts; e = G_EDICTNUM(OFS_PARM0); f = G_INT(OFS_PARM1); s = G_STRING(OFS_PARM2); if (!s) PR_RunError ("PF_Find: bad search string"); for (e++ ; e < sv.num_edicts ; e++) { ed = EDICT_NUM(e); if (ed->free) continue; t = E_STRING(ed,f); if (!t) continue; if (!strcmp(t,s)) { if (first == (edict_t *)sv.edicts) first = ed; else if (second == (edict_t *)sv.edicts) second = ed; ed->v.chain = EDICT_TO_PROG(last); last = ed; } } if (first != last) { if (last != second) first->v.chain = last->v.chain; else first->v.chain = EDICT_TO_PROG(last); last->v.chain = EDICT_TO_PROG((edict_t *)sv.edicts); if (second && second != last) second->v.chain = EDICT_TO_PROG(last); } RETURN_EDICT(first); } #else { int e; int f; char *s, *t; edict_t *ed; e = G_EDICTNUM(OFS_PARM0); f = G_INT(OFS_PARM1); s = G_STRING(OFS_PARM2); if (!s) PR_RunError ("PF_Find: bad search string"); for (e++ ; e < sv.num_edicts ; e++) { ed = EDICT_NUM(e); if (ed->free) continue; t = E_STRING(ed,f); if (!t) continue; if (!strcmp(t,s)) { RETURN_EDICT(ed); return; } } RETURN_EDICT(sv.edicts); } #endif #ifdef USEFPM void PF_FindFPM (void) #ifdef QUAKE2 { int e; int f; char *s, *t; edict_FPM_t *ed; edict_FPM_t *first; edict_FPM_t *second; edict_FPM_t *last; first = second = last = (edict_FPM_t *)svFPM.edicts; e = G_EDICTNUMFPM(OFS_PARM0); f = G_INT(OFS_PARM1); s = G_STRING(OFS_PARM2); if (!s) PR_RunError ("PF_Find: bad search string"); for (e++ ; e < svFPM.num_edicts ; e++) { ed = EDICT_NUMFPM(e); if (ed->free) continue; t = E_STRING(ed,f); if (!t) continue; if (!strcmp(t,s)) { if (first == (edict_FPM_t *)svFPM.edicts) first = ed; else if (second == (edict_t *)svFPM.edicts) second = ed; ed->v.chain = EDICT_TO_PROGFPM(last); last = ed; } } if (first != last) { if (last != second) first->v.chain = last->v.chain; else first->v.chain = EDICT_TO_PROGFPM(last); last->v.chain = EDICT_TO_PROGFPM((edict_FPM_t *)svFPM.edicts); if (second && second != last) second->v.chain = EDICT_TO_PROGFPM(last); } RETURN_EDICTFPM(first); } #else { int e; int f; char *s, *t; edict_FPM_t *ed; e = G_EDICTNUMFPM(OFS_PARM0); f = G_INT(OFS_PARM1); s = G_STRING(OFS_PARM2); if (!s) PR_RunError ("PF_Find: bad search string"); for (e++ ; e < svFPM.num_edicts ; e++) { ed = EDICT_NUMFPM(e); if (ed->free) continue; t = E_STRING(ed,f); if (!t) continue; if (!strcmp(t,s)) { RETURN_EDICTFPM(ed); return; } } RETURN_EDICTFPM(svFPM.edicts); } #endif #endif //USEFPM void PR_CheckEmptyString (char *s) { if (s[0] <= ' ') PR_RunError ("Bad string"); } #ifdef USEFPM void PR_CheckEmptyStringFPM (char *s) { if (s[0] <= ' ') PR_RunError ("Bad string"); } #endif //USEFPM void PF_precache_file (void) { // precache_file is only used to copy files with qcc, it does nothing G_INT(OFS_RETURN) = G_INT(OFS_PARM0); } #ifdef USEFPM void PF_precache_fileFPM (void) { // precache_file is only used to copy files with qcc, it does nothing G_INT(OFS_RETURN) = G_INT(OFS_PARM0); } #endif //USEFPM void PF_precache_sound (void) { char *s; int i; if (sv.state != ss_loading) PR_RunError ("PF_Precache_*: Precache can only be done in spawn functions"); s = G_STRING(OFS_PARM0); G_INT(OFS_RETURN) = G_INT(OFS_PARM0); PR_CheckEmptyString (s); for (i=0 ; iself); yaw = G_FLOAT(OFS_PARM0); dist = G_FLOAT(OFS_PARM1); if ( !( (int)ent->v.flags & (FL_ONGROUND|FL_FLY|FL_SWIM) ) ) { G_FLOAT(OFS_RETURN) = 0; return; } yaw = (float)(yaw*M_PI*2 / 360); move[0] = (float)(cos(yaw)*dist); move[1] = (float)(sin(yaw)*dist); move[2] = 0; // save program state, because SV_movestep may call other progs oldf = pr_xfunction; oldself = pr_global_struct->self; G_FLOAT(OFS_RETURN) = (float)SV_movestep(ent, move, true); // restore program state pr_xfunction = oldf; pr_global_struct->self = oldself; } #ifdef USEFPM void PF_walkmoveFPM (void) { edict_FPM_t *ent; fixedpoint_t yaw, dist; vec3_FPM_t move; dfunction_t *oldf; int oldself; ent = PROG_TO_EDICTFPM(pr_global_struct->self); yaw = FPM_FROMFLOAT(G_FLOAT(OFS_PARM0)); dist = FPM_FROMFLOAT(G_FLOAT(OFS_PARM1)); if ( !( (int)ent->v.flags & (FL_ONGROUND|FL_FLY|FL_SWIM) ) ) { G_FLOAT(OFS_RETURN) = 0; return; } yaw = FPM_MUL(FPM_MUL(yaw,FPM_PI),FPM_FROMLONGC(180)); move[0] = FPM_MUL(FPM_COS(yaw),dist); move[1] = FPM_MUL(FPM_SIN(yaw),dist); move[2] = 0; // save program state, because SV_movestep may call other progs oldf = pr_xfunction; oldself = pr_global_struct->self; G_FLOAT(OFS_RETURN) = (float)SV_movestepFPM(ent, move, true); // restore program state pr_xfunction = oldf; pr_global_struct->self = oldself; } #endif //USEFPM /* =============== PF_droptofloor void() droptofloor =============== */ void PF_droptofloor (void) { edict_t *ent; vec3_t end; trace_t trace; ent = PROG_TO_EDICT(pr_global_struct->self); VectorCopy (ent->v.origin, end); end[2] -= 256; trace = SV_Move (ent->v.origin, ent->v.mins, ent->v.maxs, end, false, ent); if (trace.fraction == 1 || trace.allsolid) G_FLOAT(OFS_RETURN) = 0; else { VectorCopy (trace.endpos, ent->v.origin); SV_LinkEdict (ent, false); ent->v.flags = (float)((int)ent->v.flags | FL_ONGROUND); ent->v.groundentity = EDICT_TO_PROG(trace.ent); G_FLOAT(OFS_RETURN) = 1; } } #ifdef USEFPM void PF_droptofloorFPM (void) { edict_FPM_t *ent; vec3_FPM_t end, vmins, vmaxs; trace_FPM_t trace; ent = PROG_TO_EDICTFPM(pr_global_struct->self); VectorToFPM(ent->v.origin, end); //VectorCopy (ent->v.origin, end); end[2] = FPM_SUB(end[2], FPM_FROMLONGC(256)); VectorToFPM(ent->v.mins, vmins); VectorToFPM(ent->v.maxs, vmaxs); trace = SV_MoveFPM (end, vmins, vmaxs, end, false, ent); if (trace.fraction == 1 || trace.allsolid) G_FLOAT(OFS_RETURN) = 0; else { FPMToVector(trace.endpos, ent->v.origin); //VectorCopy (trace.endpos, ent->v.origin); SV_LinkEdictFPM (ent, false); ent->v.flags = (float)((int)ent->v.flags | FL_ONGROUND); ent->v.groundentity = EDICT_TO_PROGFPM(trace.ent); G_FLOAT(OFS_RETURN) = 1; } } #endif //USEFPM /* =============== PF_lightstyle void(float style, string value) lightstyle =============== */ void PF_lightstyle (void) { int style; char *val; client_t *client; int j; style = (int)G_FLOAT(OFS_PARM0); val = G_STRING(OFS_PARM1); // change the string in sv sv.lightstyles[style] = val; // send message to all clients on this server if (sv.state != ss_active) return; for (j=0, client = svs.clients ; jactive || client->spawned) { MSG_WriteChar (&client->message, svc_lightstyle); MSG_WriteChar (&client->message,style); MSG_WriteString (&client->message, val); } } #ifdef USEFPM void PF_lightstyleFPM (void) { int style; char *val; client_FPM_t *client; int j; style = (int)G_FLOAT(OFS_PARM0); val = G_STRING(OFS_PARM1); // change the string in sv svFPM.lightstyles[style] = val; // send message to all clients on this server if (svFPM.state != ss_active) return; for (j=0, client = svsFPM.clients ; jactive || client->spawned) { MSG_WriteChar (&client->message, svc_lightstyle); MSG_WriteChar (&client->message,style); MSG_WriteString (&client->message, val); } } #endif //USEFPM void PF_rint (void) { float f; f = G_FLOAT(OFS_PARM0); if (f > 0) G_FLOAT(OFS_RETURN) = (float)(int)(f + 0.5); else G_FLOAT(OFS_RETURN) = (float)(int)(f - 0.5); } void PF_floor (void) { G_FLOAT(OFS_RETURN) = (float)floor(G_FLOAT(OFS_PARM0)); } void PF_ceil (void) { G_FLOAT(OFS_RETURN) = (float)ceil(G_FLOAT(OFS_PARM0)); } /* ============= PF_checkbottom ============= */ void PF_checkbottom (void) { edict_t *ent; ent = G_EDICT(OFS_PARM0); G_FLOAT(OFS_RETURN) = (float)SV_CheckBottom (ent); } #ifdef USEFPM void PF_checkbottomFPM (void) { edict_FPM_t *ent; ent = G_EDICTFPM(OFS_PARM0); G_FLOAT(OFS_RETURN) = (float)SV_CheckBottomFPM (ent); } #endif //USEFPM /* ============= PF_pointcontents ============= */ void PF_pointcontents (void) { float *v; v = G_VECTOR(OFS_PARM0); G_FLOAT(OFS_RETURN) = (float)SV_PointContents (v); } #ifdef USEFPM void PF_pointcontentsFPM (void) { fixedpoint_t v; v = FPM_FROMFLOAT(*G_VECTOR(OFS_PARM0)); G_FLOAT(OFS_RETURN) = (float)SV_PointContentsFPM (&v); } #endif //USEFPM /* ============= PF_nextent entity nextent(entity) ============= */ void PF_nextent (void) { int i; edict_t *ent; i = G_EDICTNUM(OFS_PARM0); while (1) { i++; if (i == sv.num_edicts) { RETURN_EDICT(sv.edicts); return; } ent = EDICT_NUM(i); if (!ent->free) { RETURN_EDICT(ent); return; } } } #ifdef USEFPM void PF_nextentFPM (void) { int i; edict_FPM_t *ent; i = G_EDICTNUMFPM(OFS_PARM0); while (1) { i++; if (i == svFPM.num_edicts) { RETURN_EDICTFPM(svFPM.edicts); return; } ent = EDICT_NUMFPM(i); if (!ent->free) { RETURN_EDICTFPM(ent); return; } } } #endif //USEFPM /* ============= PF_aim Pick a vector for the player to shoot along vector aim(entity, missilespeed) ============= */ cvar_t sv_aim = {"sv_aim", "0.93"}; void PF_aim (void) { edict_t *ent, *check, *bestent; vec3_t start, dir, end, bestdir; int i, j; trace_t tr; float dist, bestdist; float speed; ent = G_EDICT(OFS_PARM0); speed = G_FLOAT(OFS_PARM1); VectorCopy (ent->v.origin, start); start[2] += 20; // try sending a trace straight VectorCopy (pr_global_struct->v_forward, dir); VectorMA (start, 2048, dir, end); tr = SV_Move (start, vec3_origin, vec3_origin, end, false, ent); if (tr.ent && tr.ent->v.takedamage == DAMAGE_AIM && (!teamplay.value || ent->v.team <=0 || ent->v.team != tr.ent->v.team) ) { VectorCopy (pr_global_struct->v_forward, G_VECTOR(OFS_RETURN)); return; } // try all possible entities VectorCopy (dir, bestdir); bestdist = sv_aim.value; bestent = NULL; check = NEXT_EDICT(sv.edicts); for (i=1 ; iv.takedamage != DAMAGE_AIM) continue; if (check == ent) continue; if (teamplay.value && ent->v.team > 0 && ent->v.team == check->v.team) continue; // don't aim at teammate for (j=0 ; j<3 ; j++) end[j] = (float)(check->v.origin[j] + 0.5*(check->v.mins[j] + check->v.maxs[j])); VectorSubtract (end, start, dir); VectorNormalize (dir); dist = DotProduct (dir, pr_global_struct->v_forward); if (dist < bestdist) continue; // to far to turn tr = SV_Move (start, vec3_origin, vec3_origin, end, false, ent); if (tr.ent == check) { // can shoot at this one bestdist = dist; bestent = check; } } if (bestent) { VectorSubtract (bestent->v.origin, ent->v.origin, dir); dist = DotProduct (dir, pr_global_struct->v_forward); VectorScale (pr_global_struct->v_forward, dist, end); end[2] = dir[2]; VectorNormalize (end); VectorCopy (end, G_VECTOR(OFS_RETURN)); } else { VectorCopy (bestdir, G_VECTOR(OFS_RETURN)); } } #ifdef USEFPM void PF_aimFPM (void) { edict_FPM_t *ent, *check, *bestent; vec3_FPM_t start, dir, end, bestdir; vec3_FPM_t vforward, vorigin1, vorigin2; int i, j; trace_FPM_t tr; fixedpoint_t dist, bestdist; fixedpoint_t speed; ent = G_EDICTFPM(OFS_PARM0); speed = FPM_FROMFLOAT(G_FLOAT(OFS_PARM1)); VectorToFPM(ent->v.origin, start); //VectorCopy (ent->v.origin, start); start[2] = FPM_ADD(start[2], FPM_FROMLONGC(20)); // try sending a trace straight VectorToFPM(pr_global_struct->v_forward, dir); //VectorCopy (pr_global_struct->v_forward, dir); VectorMAFPM (start, FPM_FROMLONG(2048), dir, end); tr = SV_MoveFPM (start, vec3_originFPM, vec3_originFPM, end, false, ent); if (tr.ent && tr.ent->v.takedamage == DAMAGE_AIM && (!teamplay.value || ent->v.team <=0 || ent->v.team != tr.ent->v.team) ) { VectorCopy (pr_global_struct->v_forward, G_VECTOR(OFS_RETURN)); return; } // try all possible entities VectorCopy (dir, bestdir); bestdist = FPM_FROMFLOAT(sv_aim.value); bestent = NULL; VectorToFPM(pr_global_struct->v_forward, vforward); check = NEXT_EDICTFPM(svFPM.edicts); for (i=1 ; iv.takedamage != DAMAGE_AIM) continue; if (check == ent) continue; if (teamplay.value && ent->v.team > 0 && ent->v.team == check->v.team) continue; // don't aim at teammate for (j=0 ; j<3 ; j++) end[j] = FPM_ADD(FPM_FROMFLOATC(check->v.origin[j]), FPM_MUL(FPM_FROMFLOATC(0.5),FPM_ADD(FPM_FROMFLOAT(check->v.mins[j]), FPM_FROMFLOAT(check->v.maxs[j])))); VectorSubtractFPM (end, start, dir); VectorNormalizeFPM (dir); dist = DotProductFPM (dir, vforward); if (dist < bestdist) continue; // to far to turn tr = SV_MoveFPM (start, vec3_originFPM, vec3_originFPM, end, false, ent); if (tr.ent == check) { // can shoot at this one bestdist = dist; bestent = check; } } if (bestent) { VectorToFPM(bestent->v.origin, vorigin1); VectorToFPM(ent->v.origin, vorigin2); VectorSubtractFPM (vorigin1, vorigin2, dir); dist = DotProductFPM (dir, vforward); VectorScaleFPM (vforward, dist, end); end[2] = dir[2]; VectorNormalizeFPM (end); FPMToVector(end, G_VECTOR(OFS_RETURN)); //VectorCopy (end, G_VECTOR(OFS_RETURN)); } else { FPMToVector(bestdir, G_VECTOR(OFS_RETURN)); //VectorCopy (bestdir, G_VECTOR(OFS_RETURN)); } } #endif //USEFPM /* ============== PF_changeyaw This was a major timewaster in progs, so it was converted to C ============== */ void PF_changeyaw (void) { edict_t *ent; float ideal, current, move, speed; ent = PROG_TO_EDICT(pr_global_struct->self); current = anglemod( ent->v.angles[1] ); ideal = ent->v.ideal_yaw; speed = ent->v.yaw_speed; if (current == ideal) return; move = ideal - current; if (ideal > current) { if (move >= 180) move = move - 360; } else { if (move <= -180) move = move + 360; } if (move > 0) { if (move > speed) move = speed; } else { if (move < -speed) move = -speed; } ent->v.angles[1] = anglemod (current + move); } #ifdef USEFPM void PF_changeyawFPM (void) { edict_FPM_t *ent; fixedpoint_t ideal, current, move, speed; ent = PROG_TO_EDICTFPM(pr_global_struct->self); current = anglemodFPM( FPM_FROMFLOAT(ent->v.angles[1]) ); ideal = FPM_FROMFLOAT(ent->v.ideal_yaw); speed = FPM_FROMFLOAT(ent->v.yaw_speed); if (current == ideal) return; move = ideal - current; if (ideal > current) { if (move >= FPM_FROMLONGC(180)) move = FPM_SUB(move, FPM_FROMLONGC(360)); } else { if (move <= FPM_FROMLONGC(-180)) move = FPM_ADD(move, FPM_FROMLONGC(360)); } if (move > 0) { if (move > speed) move = speed; } else { if (move < -speed) move = -speed; } ent->v.angles[1] = FPM_TOFLOAT(anglemodFPM (FPM_ADD(current, move))); } #endif //USEFPM #ifdef QUAKE2 /* ============== PF_changepitch ============== */ void PF_changepitch (void) { edict_t *ent; float ideal, current, move, speed; ent = G_EDICT(OFS_PARM0); current = anglemod( ent->v.angles[0] ); ideal = ent->v.idealpitch; speed = ent->v.pitch_speed; if (current == ideal) return; move = ideal - current; if (ideal > current) { if (move >= 180) move = move - 360; } else { if (move <= -180) move = move + 360; } if (move > 0) { if (move > speed) move = speed; } else { if (move < -speed) move = -speed; } ent->v.angles[0] = anglemod (current + move); } #endif /* =============================================================================== MESSAGE WRITING =============================================================================== */ #define MSG_BROADCAST 0 // unreliable to all #define MSG_ONE 1 // reliable to one (msg_entity) #define MSG_ALL 2 // reliable to all #define MSG_INIT 3 // write to the init string sizebuf_t *WriteDest (void) { int entnum; int dest; edict_t *ent; dest = (int)G_FLOAT(OFS_PARM0); switch (dest) { case MSG_BROADCAST: return &sv.datagram; case MSG_ONE: ent = PROG_TO_EDICT(pr_global_struct->msg_entity); entnum = NUM_FOR_EDICT(ent); if (entnum < 1 || entnum > svs.maxclients) PR_RunError ("WriteDest: not a client"); return &svs.clients[entnum-1].message; case MSG_ALL: return &sv.reliable_datagram; case MSG_INIT: return &sv.signon; default: PR_RunError ("WriteDest: bad destination"); break; } return NULL; } #ifdef USEFPM sizebuf_t *WriteDestFPM (void) { int entnum; int dest; edict_FPM_t *ent; dest = (int)G_FLOAT(OFS_PARM0); switch (dest) { case MSG_BROADCAST: return &svFPM.datagram; case MSG_ONE: ent = PROG_TO_EDICTFPM(pr_global_struct->msg_entity); entnum = NUM_FOR_EDICTFPM(ent); if (entnum < 1 || entnum > svsFPM.maxclients) PR_RunError ("WriteDest: not a client"); return &svsFPM.clients[entnum-1].message; case MSG_ALL: return &svFPM.reliable_datagram; case MSG_INIT: return &svFPM.signon; default: PR_RunError ("WriteDest: bad destination"); break; } return NULL; } #endif //USEFPM void PF_WriteByte (void) { MSG_WriteByte (WriteDest(), (int)G_FLOAT(OFS_PARM1)); } void PF_WriteChar (void) { MSG_WriteChar (WriteDest(), (int)G_FLOAT(OFS_PARM1)); } void PF_WriteShort (void) { MSG_WriteShort (WriteDest(), (int)G_FLOAT(OFS_PARM1)); } void PF_WriteLong (void) { MSG_WriteLong (WriteDest(), (int)G_FLOAT(OFS_PARM1)); } void PF_WriteAngle (void) { MSG_WriteAngle (WriteDest(), G_FLOAT(OFS_PARM1)); } void PF_WriteCoord (void) { MSG_WriteCoord (WriteDest(), G_FLOAT(OFS_PARM1)); } void PF_WriteString (void) { MSG_WriteString (WriteDest(), G_STRING(OFS_PARM1)); } void PF_WriteEntity (void) { MSG_WriteShort (WriteDest(), G_EDICTNUM(OFS_PARM1)); } //============================================================================= int SV_ModelIndex (char *name); void PF_makestatic (void) { edict_t *ent; int i; ent = G_EDICT(OFS_PARM0); MSG_WriteByte (&sv.signon,svc_spawnstatic); MSG_WriteByte (&sv.signon, SV_ModelIndex(pr_strings + ent->v.model)); MSG_WriteByte (&sv.signon, (int)ent->v.frame); MSG_WriteByte (&sv.signon, (int)ent->v.colormap); MSG_WriteByte (&sv.signon, (int)ent->v.skin); for (i=0 ; i<3 ; i++) { MSG_WriteCoord(&sv.signon, ent->v.origin[i]); MSG_WriteAngle(&sv.signon, ent->v.angles[i]); } // throw the entity away now ED_Free (ent); } #ifdef USEFPM void PF_makestaticFPM (void) { edict_FPM_t *ent; int i; ent = G_EDICTFPM(OFS_PARM0); MSG_WriteByte (&svFPM.signon,svc_spawnstatic); MSG_WriteByte (&svFPM.signon, SV_ModelIndexFPM(pr_strings + ent->v.model)); MSG_WriteByte (&svFPM.signon, (int)ent->v.frame); MSG_WriteByte (&svFPM.signon, (int)ent->v.colormap); MSG_WriteByte (&svFPM.signon, (int)ent->v.skin); for (i=0 ; i<3 ; i++) { MSG_WriteCoord(&svFPM.signon, ent->v.origin[i]); MSG_WriteAngle(&svFPM.signon, ent->v.angles[i]); } // throw the entity away now ED_FreeFPM (ent); } #endif //USEFPM //============================================================================= /* ============== PF_setspawnparms ============== */ void PF_setspawnparms (void) { edict_t *ent; int i; client_t *client; ent = G_EDICT(OFS_PARM0); i = NUM_FOR_EDICT(ent); if (i < 1 || i > svs.maxclients) PR_RunError ("Entity is not a client"); // copy spawn parms out of the client_t client = svs.clients + (i-1); for (i=0 ; i< NUM_SPAWN_PARMS ; i++) (&pr_global_struct->parm1)[i] = client->spawn_parms[i]; } #ifdef USEFPM void PF_setspawnparmsFPM (void) { edict_FPM_t *ent; int i; client_FPM_t *client; ent = G_EDICTFPM(OFS_PARM0); i = NUM_FOR_EDICTFPM(ent); if (i < 1 || i > svsFPM.maxclients) PR_RunError ("Entity is not a client"); // copy spawn parms out of the client_t client = svsFPM.clients + (i-1); for (i=0 ; i< NUM_SPAWN_PARMS ; i++) (&pr_global_struct->parm1)[i] = client->spawn_parms[i]; } #endif //USEFPM /* ============== PF_changelevel ============== */ void PF_changelevel (void) { #ifdef QUAKE2 char *s1, *s2; if (svs.changelevel_issued) return; svs.changelevel_issued = true; s1 = G_STRING(OFS_PARM0); s2 = G_STRING(OFS_PARM1); if ((int)pr_global_struct->serverflags & (SFL_NEW_UNIT | SFL_NEW_EPISODE)) Cbuf_AddText (va("changelevel %s %s\n",s1, s2)); else Cbuf_AddText (va("changelevel2 %s %s\n",s1, s2)); #else char *s; // make sure we don't issue two changelevels if (svs.changelevel_issued) return; svs.changelevel_issued = true; s = G_STRING(OFS_PARM0); Cbuf_AddText (va("changelevel %s\n",s)); #endif } #ifdef USEFPM void PF_changelevelFPM (void) { #ifdef QUAKE2 char *s1, *s2; if (svsFPM.changelevel_issued) return; svsFPM.changelevel_issued = true; s1 = G_STRING(OFS_PARM0); s2 = G_STRING(OFS_PARM1); if ((int)pr_global_struct->serverflags & (SFL_NEW_UNIT | SFL_NEW_EPISODE)) Cbuf_AddText (va("changelevel %s %s\n",s1, s2)); else Cbuf_AddText (va("changelevel2 %s %s\n",s1, s2)); #else char *s; // make sure we don't issue two changelevels if (svsFPM.changelevel_issued) return; svsFPM.changelevel_issued = true; s = G_STRING(OFS_PARM0); Cbuf_AddText (va("changelevel %s\n",s)); #endif } #endif //USEFPM #ifdef QUAKE2 #define CONTENT_WATER -3 #define CONTENT_SLIME -4 #define CONTENT_LAVA -5 #define FL_IMMUNE_WATER 131072 #define FL_IMMUNE_SLIME 262144 #define FL_IMMUNE_LAVA 524288 #define CHAN_VOICE 2 #define CHAN_BODY 4 #define ATTN_NORM 1 void PF_WaterMove (void) { edict_t *self; int flags; int waterlevel; int watertype; float drownlevel; float damage = 0.0; self = PROG_TO_EDICT(pr_global_struct->self); if (self->v.movetype == MOVETYPE_NOCLIP) { self->v.air_finished = sv.time + 12; G_FLOAT(OFS_RETURN) = damage; return; } if (self->v.health < 0) { G_FLOAT(OFS_RETURN) = damage; return; } if (self->v.deadflag == DEAD_NO) drownlevel = 3; else drownlevel = 1; flags = (int)self->v.flags; waterlevel = (int)self->v.waterlevel; watertype = (int)self->v.watertype; if (!(flags & (FL_IMMUNE_WATER + FL_GODMODE))) if (((flags & FL_SWIM) && (waterlevel < drownlevel)) || (waterlevel >= drownlevel)) { if (self->v.air_finished < sv.time) if (self->v.pain_finished < sv.time) { self->v.dmg = self->v.dmg + 2; if (self->v.dmg > 15) self->v.dmg = 10; // T_Damage (self, world, world, self.dmg, 0, FALSE); damage = self->v.dmg; self->v.pain_finished = sv.time + 1.0; } } else { if (self->v.air_finished < sv.time) // sound (self, CHAN_VOICE, "player/gasp2.wav", 1, ATTN_NORM); SV_StartSound (self, CHAN_VOICE, "player/gasp2.wav", 255, ATTN_NORM); else if (self->v.air_finished < sv.time + 9) // sound (self, CHAN_VOICE, "player/gasp1.wav", 1, ATTN_NORM); SV_StartSound (self, CHAN_VOICE, "player/gasp1.wav", 255, ATTN_NORM); self->v.air_finished = sv.time + 12.0; self->v.dmg = 2; } if (!waterlevel) { if (flags & FL_INWATER) { // play leave water sound // sound (self, CHAN_BODY, "misc/outwater.wav", 1, ATTN_NORM); SV_StartSound (self, CHAN_BODY, "misc/outwater.wav", 255, ATTN_NORM); self->v.flags = (float)(flags &~FL_INWATER); } self->v.air_finished = sv.time + 12.0; G_FLOAT(OFS_RETURN) = damage; return; } if (watertype == CONTENT_LAVA) { // do damage if (!(flags & (FL_IMMUNE_LAVA + FL_GODMODE))) if (self->v.dmgtime < sv.time) { if (self->v.radsuit_finished < sv.time) self->v.dmgtime = sv.time + 0.2; else self->v.dmgtime = sv.time + 1.0; // T_Damage (self, world, world, 10*self.waterlevel, 0, TRUE); damage = (float)(10*waterlevel); } } else if (watertype == CONTENT_SLIME) { // do damage if (!(flags & (FL_IMMUNE_SLIME + FL_GODMODE))) if (self->v.dmgtime < sv.time && self->v.radsuit_finished < sv.time) { self->v.dmgtime = sv.time + 1.0; // T_Damage (self, world, world, 4*self.waterlevel, 0, TRUE); damage = (float)(4*waterlevel); } } if ( !(flags & FL_INWATER) ) { // player enter water sound if (watertype == CONTENT_LAVA) // sound (self, CHAN_BODY, "player/inlava.wav", 1, ATTN_NORM); SV_StartSound (self, CHAN_BODY, "player/inlava.wav", 255, ATTN_NORM); if (watertype == CONTENT_WATER) // sound (self, CHAN_BODY, "player/inh2o.wav", 1, ATTN_NORM); SV_StartSound (self, CHAN_BODY, "player/inh2o.wav", 255, ATTN_NORM); if (watertype == CONTENT_SLIME) // sound (self, CHAN_BODY, "player/slimbrn2.wav", 1, ATTN_NORM); SV_StartSound (self, CHAN_BODY, "player/slimbrn2.wav", 255, ATTN_NORM); self->v.flags = (float)(flags | FL_INWATER); self->v.dmgtime = 0; } if (! (flags & FL_WATERJUMP) ) { // self.velocity = self.velocity - 0.8*self.waterlevel*frametime*self.velocity; VectorMA (self->v.velocity, -0.8 * self->v.waterlevel * host_frametime, self->v.velocity, self->v.velocity); } G_FLOAT(OFS_RETURN) = damage; } void PF_sin (void) { G_FLOAT(OFS_RETURN) = sin(G_FLOAT(OFS_PARM0)); } void PF_cos (void) { G_FLOAT(OFS_RETURN) = cos(G_FLOAT(OFS_PARM0)); } void PF_sqrt (void) { G_FLOAT(OFS_RETURN) = sqrt(G_FLOAT(OFS_PARM0)); } #endif //QUAKE2 void PF_Fixme (void) { PR_RunError ("unimplemented bulitin"); } #ifdef USEFPM void PF_FixmeFPM (void) { PR_RunError ("unimplemented bulitin"); } #endif //USEFPM builtin_t pr_builtin[] = { PF_Fixme, PF_makevectors, // void(entity e) makevectors = #1; PF_setorigin, // void(entity e, vector o) setorigin = #2; PF_setmodel, // void(entity e, string m) setmodel = #3; PF_setsize, // void(entity e, vector min, vector max) setsize = #4; PF_Fixme, // void(entity e, vector min, vector max) setabssize = #5; PF_break, // void() break = #6; PF_random, // float() random = #7; PF_sound, // void(entity e, float chan, string samp) sound = #8; PF_normalize, // vector(vector v) normalize = #9; PF_error, // void(string e) error = #10; PF_objerror, // void(string e) objerror = #11; PF_vlen, // float(vector v) vlen = #12; PF_vectoyaw, // float(vector v) vectoyaw = #13; PF_Spawn, // entity() spawn = #14; PF_Remove, // void(entity e) remove = #15; PF_traceline, // float(vector v1, vector v2, float tryents) traceline = #16; PF_checkclient, // entity() clientlist = #17; PF_Find, // entity(entity start, .string fld, string match) find = #18; PF_precache_sound, // void(string s) precache_sound = #19; PF_precache_model, // void(string s) precache_model = #20; PF_stuffcmd, // void(entity client, string s)stuffcmd = #21; PF_findradius, // entity(vector org, float rad) findradius = #22; PF_bprint, // void(string s) bprint = #23; PF_sprint, // void(entity client, string s) sprint = #24; PF_dprint, // void(string s) dprint = #25; PF_ftos, // void(string s) ftos = #26; PF_vtos, // void(string s) vtos = #27; PF_coredump, PF_traceon, PF_traceoff, PF_eprint, // void(entity e) debug print an entire entity PF_walkmove, // float(float yaw, float dist) walkmove PF_Fixme, // float(float yaw, float dist) walkmove PF_droptofloor, PF_lightstyle, PF_rint, PF_floor, PF_ceil, PF_Fixme, PF_checkbottom, PF_pointcontents, PF_Fixme, PF_fabs, PF_aim, PF_cvar, PF_localcmd, PF_nextent, PF_particle, PF_changeyaw, PF_Fixme, PF_vectoangles, PF_WriteByte, PF_WriteChar, PF_WriteShort, PF_WriteLong, PF_WriteCoord, PF_WriteAngle, PF_WriteString, PF_WriteEntity, #ifdef QUAKE2 PF_sin, PF_cos, PF_sqrt, PF_changepitch, PF_TraceToss, PF_etos, PF_WaterMove, #else PF_Fixme, PF_Fixme, PF_Fixme, PF_Fixme, PF_Fixme, PF_Fixme, PF_Fixme, #endif SV_MoveToGoal, PF_precache_file, PF_makestatic, PF_changelevel, PF_Fixme, PF_cvar_set, PF_centerprint, PF_ambientsound, PF_precache_model, PF_precache_sound, // precache_sound2 is different only for qcc PF_precache_file, PF_setspawnparms }; #ifdef USEFPM builtin_t pr_builtinFPM[] = { PF_FixmeFPM, PF_makevectors, // void(entity e) makevectors = #1; PF_setoriginFPM, // void(entity e, vector o) setorigin = #2; PF_setmodelFPM, // void(entity e, string m) setmodel = #3; PF_setsizeFPM, // void(entity e, vector min, vector max) setsize = #4; PF_FixmeFPM, // void(entity e, vector min, vector max) setabssize = #5; PF_break, // void() break = #6; PF_random, // float() random = #7; PF_soundFPM, // void(entity e, float chan, string samp) sound = #8; PF_normalize, // vector(vector v) normalize = #9; PF_errorFPM, // void(string e) error = #10; PF_objerrorFPM, // void(string e) objerror = #11; PF_vlen, // float(vector v) vlen = #12; PF_vectoyaw, // float(vector v) vectoyaw = #13; PF_SpawnFPM, // entity() spawn = #14; PF_RemoveFPM, // void(entity e) remove = #15; PF_tracelineFPM, // float(vector v1, vector v2, float tryents) traceline = #16; PF_checkclientFPM, // entity() clientlist = #17; PF_FindFPM, // entity(entity start, .string fld, string match) find = #18; PF_precache_soundFPM, // void(string s) precache_sound = #19; PF_precache_modelFPM, // void(string s) precache_model = #20; PF_stuffcmdFPM, // void(entity client, string s)stuffcmd = #21; PF_findradiusFPM, // entity(vector org, float rad) findradius = #22; PF_bprint, // void(string s) bprint = #23; PF_sprintFPM, // void(entity client, string s) sprint = #24; PF_dprintFPM, // void(string s) dprint = #25; PF_ftosFPM, // void(string s) ftos = #26; PF_vtosFPM, // void(string s) vtos = #27; PF_coredumpFPM, PF_traceonFPM, PF_traceoffFPM, PF_eprintFPM, // void(entity e) debug print an entire entity PF_walkmoveFPM, // float(float yaw, float dist) walkmove PF_FixmeFPM, // float(float yaw, float dist) walkmove PF_droptofloorFPM, PF_lightstyleFPM, PF_rint, PF_floor, PF_ceil, PF_FixmeFPM, PF_checkbottomFPM, PF_pointcontentsFPM, PF_FixmeFPM, PF_fabsFPM, PF_aimFPM, PF_cvarFPM, PF_localcmdFPM, PF_nextentFPM, PF_particleFPM, PF_changeyawFPM, PF_FixmeFPM, PF_vectoangles, PF_WriteByte, PF_WriteChar, PF_WriteShort, PF_WriteLong, PF_WriteCoord, PF_WriteAngle, PF_WriteString, PF_WriteEntity, #ifdef QUAKE2 PF_sin, PF_cos, PF_sqrt, PF_changepitchFPM, PF_TraceTossFPM, PF_etosFPM, PF_WaterMoveFPM, #else PF_FixmeFPM, PF_FixmeFPM, PF_FixmeFPM, PF_FixmeFPM, PF_FixmeFPM, PF_FixmeFPM, PF_FixmeFPM, #endif SV_MoveToGoalFPM, PF_precache_fileFPM, PF_makestaticFPM, PF_changelevelFPM, PF_FixmeFPM, PF_cvar_setFPM, PF_centerprintFPM, PF_ambientsoundFPM, PF_precache_modelFPM, PF_precache_soundFPM, // precache_sound2 is different only for qcc PF_precache_fileFPM, PF_setspawnparms }; #endif builtin_t *pr_builtins = pr_builtin; int pr_numbuiltins = sizeof(pr_builtin)/sizeof(pr_builtin[0]); #ifdef USEFPM builtin_t *pr_builtinsFPM = pr_builtinFPM; int pr_numbuiltinsFPM = sizeof(pr_builtinFPM)/sizeof(pr_builtinFPM[0]); #endif