#define PROGSUSED #include "progsint.h" #include typedef struct prmemb_s { struct prmemb_s *prev; int level; } prmemb_t; void *PRHunkAlloc(progfuncs_t *progfuncs, int ammount) { prmemb_t *mem; ammount = sizeof(prmemb_t)+((ammount + 3)&~3); mem = memalloc(ammount); memset(mem, 0, ammount); mem->prev = memb; if (!memb) mem->level = 1; else mem->level = ((prmemb_t *)memb)->level+1; memb = mem; return ((char *)mem)+sizeof(prmemb_t); } int PRHunkMark(progfuncs_t *progfuncs) { return ((prmemb_t *)memb)->level; } void PRHunkFree(progfuncs_t *progfuncs, int mark) { prmemb_t *omem; while(memb) { if (memb->level <= mark) return; omem = memb; memb = memb->prev; memfree(omem); } return; } /*if we ran out of memory, the vm can allocate a new block, but doing so requires fixing up all sorts of pointers*/ void PRAddressableRelocate(progfuncs_t *progfuncs, char *oldb, char *newb, int oldlen) { unsigned int i; edictrun_t *e; for (i=0 ; iedicttable[i]); if (e && (char*)e->fields >= oldb && (char*)e->fields < oldb+oldlen) e->fields = ((char*)e->fields - oldb) + newb; } if (progfuncs->stringtable >= oldb && progfuncs->stringtable < oldb+oldlen) progfuncs->stringtable = (progfuncs->stringtable - oldb) + newb; for (i=0; i < maxprogs; i++) { if ((char*)prinst->progstate[i].globals >= oldb && (char*)prinst->progstate[i].globals < oldb+oldlen) prinst->progstate[i].globals = (float*)(((char*)prinst->progstate[i].globals - oldb) + newb); if (prinst->progstate[i].strings >= oldb && prinst->progstate[i].strings < oldb+oldlen) prinst->progstate[i].strings = (prinst->progstate[i].strings - oldb) + newb; } for (i = 0; i < numfields; i++) { if (field[i].name >= oldb && field[i].name < oldb+oldlen) field[i].name = (field[i].name - oldb) + newb; } externs->addressablerelocated(progfuncs, oldb, newb, oldlen); } //for 64bit systems. :) //addressable memory is memory available to the vm itself for writing. //once allocated, it cannot be freed for the lifetime of the VM. void *PRAddressableExtend(progfuncs_t *progfuncs, int ammount) { ammount = (ammount + 4)&~3; //round up to 4 if (prinst->addressableused + ammount > prinst->addressablesize) { /*only do this if the caller states that it can cope with addressable-block relocations/resizes*/ if (externs->addressablerelocated) { #ifdef _WIN32 char *newblock; #if 0//def _DEBUG int oldtot = addressablesize; #endif int newsize = (prinst->addressableused + ammount + 4096) & ~(4096-1); newblock = VirtualAlloc (NULL, prinst->addressablesize, MEM_RESERVE, PAGE_NOACCESS); if (newblock) { VirtualAlloc (newblock, prinst->addressableused, MEM_COMMIT, PAGE_READWRITE); memcpy(newblock, prinst->addressablehunk, prinst->addressableused); #if 0//def _DEBUG VirtualAlloc (prinst->addressablehunk, oldtot, MEM_RESERVE, PAGE_NOACCESS); #else VirtualFree (prinst->addressablehunk, 0, MEM_RELEASE); #endif PRAddressableRelocate(progfuncs, prinst->addressablehunk, newblock, prinst->addressableused); prinst->addressablehunk = newblock; prinst->addressablesize = newsize; } #else char *newblock; int newsize = (prinst->addressableused + ammount + 1024*1024) & ~(1024*1024-1); newblock = realloc(newblock, prinst->addressablesize); if (newblock) { PRAddressableRelocate(progfuncs, prinst->addressablehunk, newblock, prinst->addressableused); prinst->addressablehunk = newblock; prinst->addressablesize = newsize; } #endif } if (prinst->addressableused + ammount > prinst->addressablesize) Sys_Error("Not enough addressable memory for progs VM"); } prinst->addressableused += ammount; #ifdef _WIN32 if (!VirtualAlloc (prinst->addressablehunk, prinst->addressableused, MEM_COMMIT, PAGE_READWRITE)) Sys_Error("VirtualAlloc failed. Blame windows."); #endif return &prinst->addressablehunk[prinst->addressableused-ammount]; } #define MARKER 0xF1E3E3E7u typedef struct { unsigned int next; unsigned int prev; unsigned int size; } qcmemfreeblock_t; typedef struct { unsigned int marker; unsigned int size; } qcmemusedblock_t; static void PF_fmem_unlink(progfuncs_t *pr, qcmemfreeblock_t *p) { qcmemfreeblock_t *np; if (p->prev) { np = (qcmemfreeblock_t*)(pr->stringtable + p->prev); np->next = p->next; } else pr->inst->mfreelist = p->next; if (p->next) { np = (qcmemfreeblock_t*)(pr->stringtable + p->next); np->prev = p->prev; } } static void *PR_memalloc (progfuncs_t *progfuncs, unsigned int size) { qcmemfreeblock_t *p, *np; qcmemusedblock_t *ub = NULL; unsigned int b,n; /*round size up*/ size = (size+sizeof(qcmemusedblock_t) + 63) & ~63; b = prinst->mfreelist; while (b) { if (b < 0 || b >= prinst->addressableused) { printf("PF_memalloc: memory corruption\n"); PR_StackTrace(progfuncs); return NULL; } p = (qcmemfreeblock_t*)(progfuncs->stringtable + b); if (p->size >= size) { if (p->next && p->next < b + p->size || p->next >= prinst->addressableused || b + p->size >= prinst->addressableused || p->prev >= b) { printf("PF_memalloc: memory corruption\n"); PR_StackTrace(progfuncs); return NULL; } ub = (qcmemusedblock_t*)p; if (p->size > size + 63) { /*make a new header just after it, with basically the same properties, and shift the important fields over*/ n = b + size; np = (qcmemfreeblock_t*)(progfuncs->stringtable + b + size); np->prev = p->prev; np->next = p->next; np->size = p->size - size; if (np->prev) { p = (qcmemfreeblock_t*)(progfuncs->stringtable + np->prev); p->next = n; } else prinst->mfreelist = n; if (p->next) { p = (qcmemfreeblock_t*)(progfuncs->stringtable + np->next); p->prev = n; } } else { size = p->size; /*alloc the entire block*/ /*unlink this entry*/ PF_fmem_unlink(progfuncs, p); } break; } } /*assign more space*/ if (!ub) { ub = PRAddressableExtend(progfuncs, size); if (!ub) { printf("PF_memalloc: memory exausted\n"); PR_StackTrace(progfuncs); return NULL; } } memset(ub, 0, size); ub->marker = MARKER; ub->size = size; return ub+1; } static void PR_memfree (progfuncs_t *progfuncs, void *memptr) { qcmemusedblock_t *ub; qcmemfreeblock_t *p, *np; unsigned int l, ln; unsigned int size; unsigned int ptr = memptr?((char*)memptr - progfuncs->stringtable):0; /*freeing NULL is ignored*/ if (!ptr) return; if (ptr < sizeof(qcmemusedblock_t) || ptr >= prinst->addressableused) { printf("PF_memfree: pointer invalid - out of range (%u >= %u)\n", ptr, prinst->addressableused); PR_StackTrace(progfuncs); return; } ub = (qcmemusedblock_t*)(progfuncs->stringtable + ptr); ub--; ptr = (char*)ub - progfuncs->stringtable; if (ub->marker != MARKER || ub->size <= sizeof(*ub) || ptr + ub->size > (unsigned int)prinst->addressableused) { printf("PF_memfree: memory corruption or double free\n"); PR_StackTrace(progfuncs); return; } ub->marker = 0; size = ub->size; for (ln = prinst->mfreelist, l = 0; ;) { if (ln < 0 || ln >= prinst->addressableused) { printf("PF_memfree: memory corruption\n"); PR_StackTrace(progfuncs); return; } if (!ln || ln >= ptr) { np = (qcmemfreeblock_t*)(progfuncs->stringtable + l); if (l && l+np->size>ptr) { printf("PF_memfree: double free\n"); PR_StackTrace(progfuncs); return; } /*generate the free block, now we know its proper values*/ p = (qcmemfreeblock_t*)(progfuncs->stringtable + ptr); p->prev = l; p->next = ln; p->size = size; /*update the next's previous*/ if (p->next) { np = (qcmemfreeblock_t*)(progfuncs->stringtable + p->next); np->prev = p->prev; /*extend this block and kill the next if they are adjacent*/ if (p->next == ptr + size) { p->size += np->size; PF_fmem_unlink(progfuncs, np); } } /*update the link to get here*/ if (!l) prinst->mfreelist = ptr; else { np = (qcmemfreeblock_t*)(progfuncs->stringtable + l); np->next = ptr; /*we're adjacent to the previous block, so merge them by killing the newly freed region*/ if (l + np->size == ptr) { np->size += size; PF_fmem_unlink(progfuncs, p); } } break; } l = ln; p = (qcmemfreeblock_t*)(progfuncs->stringtable + l); ln = p->next; } } void PRAddressableFlush(progfuncs_t *progfuncs, int totalammount) { prinst->addressableused = 0; if (totalammount < 0) //flush { totalammount = prinst->addressablesize; // return; } #ifdef _WIN32 if (prinst->addressablehunk && prinst->addressablesize != totalammount) { VirtualFree(prinst->addressablehunk, 0, MEM_RELEASE); //doesn't this look complicated? :p prinst->addressablehunk = NULL; } if (!prinst->addressablehunk) prinst->addressablehunk = VirtualAlloc (prinst->addressablehunk, totalammount, MEM_RESERVE, PAGE_NOACCESS); #else if (prinst->addressablehunk && prinst->addressablesize != totalammount) { free(prinst->addressablehunk); prinst->addressablehunk = NULL; } if (!prinst->addressablehunk) prinst->addressablehunk = malloc(totalammount); //linux will allocate-on-use anyway, which is handy. // memset(prinst->addressablehunk, 0xff, totalammount); #endif if (!prinst->addressablehunk) Sys_Error("Out of memory\n"); prinst->addressablesize = totalammount; } int PR_InitEnts(progfuncs_t *progfuncs, int max_ents) { maxedicts = max_ents; sv_num_edicts = 0; max_fields_size = fields_size; prinst->edicttable = PRHunkAlloc(progfuncs, maxedicts*sizeof(struct edicts_s *)); sv_edicts = PRHunkAlloc(progfuncs, externs->edictsize); prinst->edicttable[0] = sv_edicts; ((edictrun_t*)prinst->edicttable[0])->fields = PRAddressableExtend(progfuncs, max_fields_size); QC_ClearEdict(progfuncs, sv_edicts); sv_num_edicts = 1; if (externs->entspawn) externs->entspawn((struct edict_s *)sv_edicts, false); return max_fields_size; } edictrun_t tempedict; //used as a safty buffer float tempedictfields[2048]; void PR_Configure (progfuncs_t *progfuncs, int addressable_size, int max_progs) //can be used to wipe all memory { unsigned int i; edictrun_t *e; max_fields_size=0; fields_size = 0; progfuncs->stringtable = 0; QC_StartShares(progfuncs); QC_InitShares(progfuncs); for ( i=1 ; iedicttable[i]); prinst->edicttable[i] = NULL; // e->entnum = i; if (e) memfree(e); } PRHunkFree(progfuncs, 0); //clear mem - our hunk may not be a real hunk. if (addressable_size<0) addressable_size = 8*1024*1024; PRAddressableFlush(progfuncs, addressable_size); pr_progstate = PRHunkAlloc(progfuncs, sizeof(progstate_t) * max_progs); /* for(a = 0; a < max_progs; a++) { pr_progstate[a].progs = NULL; } */ maxprogs = max_progs; pr_typecurrent=-1; prinst->reorganisefields = false; maxedicts = 1; prinst->edicttable = &sv_edicts; sv_num_edicts = 1; //set up a safty buffer so things won't go horribly wrong too often sv_edicts=(struct edict_s *)&tempedict; tempedict.readonly = true; tempedict.fields = tempedictfields; tempedict.isfree = false; } struct globalvars_s *PR_globals (progfuncs_t *progfuncs, progsnum_t pnum) { if (pnum < 0) { if (!current_progstate) { static float fallback[RESERVED_OFS]; return (struct globalvars_s *)fallback; //err.. you've not loaded one yet. } return (struct globalvars_s *)current_progstate->globals; } return (struct globalvars_s *)pr_progstate[pnum].globals; } struct entvars_s *PR_entvars (progfuncs_t *progfuncs, struct edict_s *ed) { if (((edictrun_t *)ed)->isfree) return NULL; return (struct entvars_s *)edvars(ed); } int PR_GetFuncArgCount(progfuncs_t *progfuncs, func_t func) { unsigned int pnum; unsigned int fnum; dfunction_t *f; pnum = (func & 0xff000000)>>24; fnum = (func & 0x00ffffff); if (pnum >= (unsigned)maxprogs || !pr_progstate[pnum].functions) return -1; else if (fnum >= pr_progstate[pnum].progs->numfunctions) return -1; else { f = pr_progstate[pnum].functions + fnum; return f->numparms; } } func_t PR_FindFunc(progfuncs_t *progfuncs, char *funcname, progsnum_t pnum) { dfunction_t *f=NULL; if (pnum == PR_ANY) { for (pnum = 0; (unsigned)pnum < maxprogs; pnum++) { if (!pr_progstate[pnum].progs) continue; f = ED_FindFunction(progfuncs, funcname, &pnum, pnum); if (f) break; } } else if (pnum == PR_ANYBACK) //run backwards { for (pnum = maxprogs-1; pnum >= 0; pnum--) { if (!pr_progstate[pnum].progs) continue; f = ED_FindFunction(progfuncs, funcname, &pnum, pnum); if (f) break; } } else f = ED_FindFunction(progfuncs, funcname, &pnum, pnum); if (!f) return 0; { ddef16_t *var16; ddef32_t *var32; switch(pr_progstate[pnum].structtype) { case PST_KKQWSV: case PST_DEFAULT: var16 = ED_FindTypeGlobalFromProgs16(progfuncs, funcname, pnum, ev_function); //we must make sure we actually have a function def - 'light' is defined as a field before it is defined as a function. if (!var16) return (f - pr_progstate[pnum].functions) | (pnum << 24); return *(int *)&pr_progstate[pnum].globals[var16->ofs]; case PST_QTEST: case PST_FTE32: var32 = ED_FindTypeGlobalFromProgs32(progfuncs, funcname, pnum, ev_function); //we must make sure we actually have a function def - 'light' is defined as a field before it is defined as a function. if (!var32) return (f - pr_progstate[pnum].functions) | (pnum << 24); return *(int *)&pr_progstate[pnum].globals[var32->ofs]; } Sys_Error("Error with def size (PR_FindFunc)"); } return 0; } void QC_FindPrefixedGlobals(progfuncs_t *progfuncs, char *prefix, void (*found) (progfuncs_t *progfuncs, char *name, union eval_s *val, etype_t type) ) { unsigned int i; ddef16_t *def16; ddef32_t *def32; int len = strlen(prefix); unsigned int pnum; for (pnum = 0; pnum < maxprogs; pnum++) { if (!pr_progstate[pnum].progs) continue; switch(pr_progstate[pnum].structtype) { case PST_DEFAULT: case PST_KKQWSV: for (i=1 ; inumglobaldefs ; i++) { def16 = &pr_progstate[pnum].globaldefs16[i]; if (!strncmp(def16->s_name+progfuncs->stringtable,prefix, len)) found(progfuncs, def16->s_name+progfuncs->stringtable, (eval_t *)&pr_progstate[pnum].globals[def16->ofs], def16->type); } break; case PST_QTEST: case PST_FTE32: for (i=1 ; inumglobaldefs ; i++) { def32 = &pr_progstate[pnum].globaldefs32[i]; if (!strncmp(def32->s_name+progfuncs->stringtable,prefix, len)) found(progfuncs, def32->s_name+progfuncs->stringtable, (eval_t *)&pr_progstate[pnum].globals[def32->ofs], def32->type); } break; } } } eval_t *PR_FindGlobal(progfuncs_t *progfuncs, char *globname, progsnum_t pnum, etype_t *type) { unsigned int i; ddef16_t *var16; ddef32_t *var32; if (pnum == PR_CURRENT) pnum = pr_typecurrent; if (pnum == PR_ANY) { eval_t *ev; for (i = 0; i < maxprogs; i++) { if (!pr_progstate[i].progs) continue; ev = PR_FindGlobal(progfuncs, globname, i, type); if (ev) return ev; } return NULL; } if (pnum < 0 || (unsigned)pnum >= maxprogs || !pr_progstate[pnum].progs) return NULL; switch(pr_progstate[pnum].structtype) { case PST_DEFAULT: case PST_KKQWSV: if (!(var16 = ED_FindGlobalFromProgs16(progfuncs, globname, pnum))) return NULL; if (type) *type = var16->type; return (eval_t *)&pr_progstate[pnum].globals[var16->ofs]; case PST_QTEST: case PST_FTE32: if (!(var32 = ED_FindGlobalFromProgs32(progfuncs, globname, pnum))) return NULL; if (type) *type = var32->type; return (eval_t *)&pr_progstate[pnum].globals[var32->ofs]; } Sys_Error("Error with def size (PR_FindGlobal)"); return NULL; } void SetGlobalEdict(progfuncs_t *progfuncs, struct edict_s *ed, int ofs) { ((int*)pr_globals)[ofs] = EDICT_TO_PROG(progfuncs, ed); } char *PR_VarString (progfuncs_t *progfuncs, int first) { int i; static char out[1024]; char *s; out[0] = 0; for (i=first ; istringtable; if (strlen(out) + strlen(s) + 1 >= sizeof(out)) return out; strcat (out, s); } } return out; } int PR_QueryField (progfuncs_t *progfuncs, unsigned int fieldoffset, etype_t *type, char **name, evalc_t *fieldcache) { fdef_t *var; var = ED_FieldAtOfs(progfuncs, fieldoffset); if (!var) return false; if (type) *type = var->type & ~(DEF_SAVEGLOBAL|DEF_SHARED); if (name) *name = var->name; if (fieldcache) { fieldcache->ofs32 = var; fieldcache->varname = var->name; } return true; } eval_t *GetEdictFieldValue(progfuncs_t *progfuncs, struct edict_s *ed, char *name, evalc_t *cache) { fdef_t *var; if (!cache) { var = ED_FindField(progfuncs, name); if (!var) return NULL; return (eval_t *) &(((int*)(((edictrun_t*)ed)->fields))[var->ofs]); } if (!cache->varname) { cache->varname = name; var = ED_FindField(progfuncs, name); if (!var) { cache->ofs32 = NULL; return NULL; } cache->ofs32 = var; cache->varname = var->name; if (!ed) return (void*)~0; //something not null return (eval_t *) &(((int*)(((edictrun_t*)ed)->fields))[var->ofs]); } if (cache->ofs32 == NULL) return NULL; return (eval_t *) &(((int*)(((edictrun_t*)ed)->fields))[cache->ofs32->ofs]); } struct edict_s *ProgsToEdict (progfuncs_t *progfuncs, int progs) { if ((unsigned)progs >= (unsigned)maxedicts) { printf("Bad entity index %i\n", progs); progs = 0; } return (struct edict_s *)PROG_TO_EDICT(progfuncs, progs); } int EdictToProgs (progfuncs_t *progfuncs, struct edict_s *ed) { return EDICT_TO_PROG(progfuncs, ed); } string_t PR_StringToProgs (progfuncs_t *progfuncs, char *str) { char **ntable; int i, free=-1; if (!str) return 0; if (str >= progfuncs->stringtable && str < progfuncs->stringtable + prinst->addressableused) return str - progfuncs->stringtable; for (i = prinst->numallocedstrings-1; i >= 0; i--) { if (prinst->allocedstrings[i] == str) return (string_t)((unsigned int)i | 0x80000000); if (!prinst->allocedstrings[i]) free = i; } if (free != -1) { i = free; prinst->allocedstrings[i] = str; return (string_t)((unsigned int)i | 0x80000000); } prinst->maxallocedstrings += 1024; ntable = memalloc(sizeof(char*) * prinst->maxallocedstrings); memcpy(ntable, prinst->allocedstrings, sizeof(char*) * prinst->numallocedstrings); memset(ntable + prinst->numallocedstrings, 0, sizeof(char*) * (prinst->maxallocedstrings - prinst->numallocedstrings)); prinst->numallocedstrings = prinst->maxallocedstrings; if (prinst->allocedstrings) memfree(prinst->allocedstrings); prinst->allocedstrings = ntable; for (i = prinst->numallocedstrings-1; i >= 0; i--) { if (!prinst->allocedstrings[i]) { prinst->allocedstrings[i] = str; return (string_t)((unsigned int)i | 0x80000000); } } return 0; } char *PR_RemoveProgsString (progfuncs_t *progfuncs, string_t str) { char *ret; //input string is expected to be an allocated string //if its a temp, or a constant, just return NULL. if ((unsigned int)str & 0xc0000000) { if ((unsigned int)str & 0x80000000) { int i = str & ~0x80000000; if (i >= prinst->numallocedstrings) { pr_trace = 1; return NULL; } if (prinst->allocedstrings[i]) { ret = prinst->allocedstrings[i]; prinst->allocedstrings[i] = NULL; //remove it return ret; } else { pr_trace = 1; return NULL; //urm, was freed... } } } pr_trace = 1; return NULL; } char *ASMCALL PR_StringToNative (progfuncs_t *progfuncs, string_t str) { if ((unsigned int)str & 0xc0000000) { if ((unsigned int)str & 0x80000000) { int i = str & ~0x80000000; if (i >= prinst->numallocedstrings) { printf("invalid string %x\n", str); PR_StackTrace(progfuncs); pr_trace = 1; return ""; } if (prinst->allocedstrings[i]) return prinst->allocedstrings[i]; else { printf("invalid string %x\n", str); PR_StackTrace(progfuncs); pr_trace = 1; return ""; //urm, was freed... } } if ((unsigned int)str & 0x40000000) { int i = str & ~0x40000000; if (i >= prinst->numtempstrings) { printf("invalid temp string %x\n", str); PR_StackTrace(progfuncs); pr_trace = 1; return ""; } return prinst->tempstrings[i]; } } if ((unsigned int)str >= (unsigned int)prinst->addressableused) { printf("invalid string offset %x\n", str); PR_StackTrace(progfuncs); pr_trace = 1; return ""; } return progfuncs->stringtable + str; } string_t PR_AllocTempString (progfuncs_t *progfuncs, char *str) { char **ntable; int newmax; int i; if (!str) return 0; if (prinst->numtempstrings == prinst->maxtempstrings) { newmax = prinst->maxtempstrings += 1024; prinst->maxtempstrings += 1024; ntable = memalloc(sizeof(char*) * newmax); memcpy(ntable, prinst->tempstrings, sizeof(char*) * prinst->numtempstrings); prinst->maxtempstrings = newmax; if (prinst->tempstrings) memfree(prinst->tempstrings); prinst->tempstrings = ntable; } i = prinst->numtempstrings; if (i == 0x10000000) return 0; prinst->numtempstrings++; prinst->tempstrings[i] = memalloc(strlen(str)+1); strcpy(prinst->tempstrings[i], str); return (string_t)((unsigned int)i | 0x40000000); } string_t PR_AllocTempStringLen (progfuncs_t *progfuncs, char **str, unsigned int len) { char **ntable; int newmax; int i; if (!str) return 0; if (prinst->numtempstrings == prinst->maxtempstrings) { newmax = prinst->maxtempstrings += 1024; prinst->maxtempstrings += 1024; ntable = memalloc(sizeof(char*) * newmax); memcpy(ntable, prinst->tempstrings, sizeof(char*) * prinst->numtempstrings); prinst->maxtempstrings = newmax; if (prinst->tempstrings) memfree(prinst->tempstrings); prinst->tempstrings = ntable; } i = prinst->numtempstrings; if (i == 0x10000000) return 0; prinst->numtempstrings++; prinst->tempstrings[i] = memalloc(len); *str = prinst->tempstrings[i]; return (string_t)((unsigned int)i | 0x40000000); } void PR_FreeTemps (progfuncs_t *progfuncs, int depth) { int i; if (depth > prinst->numtempstrings) { Sys_Error("QC Temp stack inverted\n"); return; } for (i = depth; i < prinst->numtempstrings; i++) { memfree(prinst->tempstrings[i]); } prinst->numtempstrings = depth; } struct qcthread_s *PR_ForkStack (progfuncs_t *progfuncs); void PR_ResumeThread (progfuncs_t *progfuncs, struct qcthread_s *thread); void PR_AbortStack (progfuncs_t *progfuncs); void RegisterBuiltin(progfuncs_t *progfncs, char *name, builtin_t func); progfuncs_t deffuncs = { PROGSTRUCT_VERSION, PR_Configure, PR_LoadProgs, PR_InitEnts, PR_ExecuteProgram, PR_SwitchProgs, PR_globals, PR_entvars, PR_RunError, ED_Print, ED_Alloc, ED_Free, EDICT_NUM, NUM_FOR_EDICT, SetGlobalEdict, PR_VarString, NULL, PR_FindFunc, #ifdef MINIMAL NULL, NULL, #else Comp_Begin, Comp_Continue, #endif filefromprogs, NULL,//filefromnewprogs, SaveEnts, LoadEnts, SaveEnt, RestoreEnt, PR_FindGlobal, ED_NewString, (void*)PRHunkAlloc, GetEdictFieldValue, ProgsToEdict, EdictToProgs, EvaluateDebugString, NULL, PR_StackTrace, PR_ToggleBreakpoint, 0, NULL, #ifdef MINIMAL NULL, #else Decompile, #endif NULL, NULL, RegisterBuiltin, 0, 0, PR_ForkStack, PR_ResumeThread, PR_AbortStack, 0, QC_RegisterFieldVar, 0, 0, PR_AllocTempString, PR_StringToProgs, PR_StringToNative, 0, PR_QueryField, QC_ClearEdict, QC_FindPrefixedGlobals, PR_memalloc, PR_AllocTempStringLen, PR_memfree, }; #undef printf //defs incase following structure is not passed. struct edict_s *safesv_edicts; int safesv_num_edicts; double safetime=0; progexterns_t defexterns = { PROGSTRUCT_VERSION, NULL, //char *(*ReadFile) (char *fname, void *buffer, int len); NULL, //int (*FileSize) (char *fname); //-1 if file does not exist NULL, //bool (*WriteFile) (char *name, void *data, int len); printf, //void (*printf) (char *, ...); (void*)exit, //void (*Sys_Error) (char *, ...); NULL, //void (*Abort) (char *, ...); sizeof(edictrun_t), //int edictsize; //size of edict_t NULL, //void (*entspawn) (struct edict_s *ent); //ent has been spawned, but may not have all the extra variables (that may need to be set) set NULL, //bool (*entcanfree) (struct edict_s *ent); //return true to stop ent from being freed NULL, //void (*stateop) (float var, func_t func); NULL, NULL, NULL, //used when loading a game NULL, //builtin_t *(*builtinsfor) (int num); //must return a pointer to the builtins that were used before the state was saved. NULL, //void (*loadcompleate) (int edictsize); //notification to reset any pointers. NULL, (void*)malloc, //void *(*memalloc) (int size); //small string allocation malloced and freed randomly by the executor. (use memalloc if you want) free, //void (*memfree) (void * mem); NULL, //builtin_t *globalbuiltins; //these are available to all progs 0, //int numglobalbuiltins; PR_NOCOMPILE, &safetime, //double *gametime; &safesv_edicts, //struct edict_s **sv_edicts; &safesv_num_edicts, //int *sv_num_edicts; NULL, //int (*useeditor) (char *filename, int line, int nump, char **parms); }; //progfuncs_t *progfuncs = NULL; #undef memfree #undef prinst #undef extensionbuiltin #undef field #undef shares #undef maxedicts #undef sv_num_edicts #ifdef QCLIBDLL_EXPORTS __declspec(dllexport) #endif void CloseProgs(progfuncs_t *inst) { // extensionbuiltin_t *eb; void (VARGS *f) (void *); unsigned int i; edictrun_t *e; f = inst->parms->memfree; for ( i=1 ; iinst->maxedicts; i++) { e = (edictrun_t *)(inst->inst->edicttable[i]); inst->inst->edicttable[i] = NULL; if (e) { // e->entnum = i; f(e); } } PRHunkFree(inst, 0); #ifdef _WIN32 VirtualFree(inst->inst->addressablehunk, 0, MEM_RELEASE); //doesn't this look complicated? :p #else free(inst->inst->addressablehunk); #endif if (inst->inst->allocedstrings) f(inst->inst->allocedstrings); inst->inst->allocedstrings = NULL; if (inst->inst->tempstrings) f(inst->inst->tempstrings); inst->inst->tempstrings = NULL; /* while(inst->prinst->extensionbuiltin) { eb = inst->prinst->extensionbuiltin->prev; f(inst->prinst->extensionbuiltin); inst->prinst->extensionbuiltin = eb; } */ if (inst->inst->field) f(inst->inst->field); if (inst->inst->shares) f(inst->inst->shares); //free memory f(inst->inst); f(inst); } void RegisterBuiltin(progfuncs_t *progfuncs, char *name, builtin_t func) { /* extensionbuiltin_t *eb; eb = memalloc(sizeof(extensionbuiltin_t)); eb->prev = progfuncs->prinst->extensionbuiltin; progfuncs->prinst->extensionbuiltin = eb; eb->name = name; eb->func = func; */ } #ifndef WIN32 #define QCLIBINT //don't use dllspecifications #endif #if defined(QCLIBDLL_EXPORTS) __declspec(dllexport) #endif progfuncs_t * InitProgs(progexterns_t *ext) { progfuncs_t *funcs; if (!ext) ext = &defexterns; else { int i; if (ext->progsversion > PROGSTRUCT_VERSION) return NULL; for (i=0;imemalloc(sizeof(progfuncs_t)); memcpy(funcs, &deffuncs, sizeof(progfuncs_t)); funcs->inst = ext->memalloc(sizeof(prinst_t)); memset(funcs->inst,0, sizeof(prinst_t)); funcs->pr_trace = &funcs->inst->pr_trace; funcs->progstate = &funcs->inst->progstate; funcs->callargc = &funcs->inst->pr_argc; funcs->parms = ext; SetEndian(); return funcs; } #ifdef QCC void main (int argc, char **argv) { progexterns_t ext; progfuncs_t *funcs; funcs = InitProgs(&ext); if (funcs->PR_StartCompile(argc, argv)) while(funcs->PR_ContinueCompile()); } #endif