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fteqw/engine/qclib/initlib.c
Spoike c1e991f31c hide console while updating packages.
fix rate indicator with http downloads.
fix gamedir change crash.
force r_shadow_realtime_world_lightmaps to 0 if there are no rtlights on the map (to work around TF/etc maps where such 'useless' entities got stripped).
tweak profile lists to be slightly more verbose.
add extra parms to fteextensions.qc, so that people realise that fte actually supports that.

git-svn-id: https://svn.code.sf.net/p/fteqw/code/trunk@4808 fc73d0e0-1445-4013-8a0c-d673dee63da5
2014-12-29 02:35:10 +00:00

1416 lines
35 KiB
C

#define PROGSUSED
#include "progsint.h"
#include <stdlib.h>
#define STRING_SPECMASK 0xc0000000 //
#define STRING_TEMP 0x80000000 //temp string, will be collected.
#define STRING_STATIC 0xc0000000 //pointer to non-qcvm string.
#define STRING_NORMAL_ 0x00000000 //stringtable/mutable. should always be a fallthrough
#define STRING_NORMAL2_ 0x40000000 //stringtable/mutable. should always be a fallthrough
typedef struct prmemb_s {
struct prmemb_s *prev;
int level;
} prmemb_t;
void *PRHunkAlloc(progfuncs_t *progfuncs, int ammount, char *name)
{
prmemb_t *mem;
ammount = sizeof(prmemb_t)+((ammount + 3)&~3);
mem = progfuncs->funcs.parms->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);
}
void *PDECL QC_HunkAlloc(pubprogfuncs_t *ppf, int ammount, char *name)
{
return PRHunkAlloc((progfuncs_t*)ppf, ammount, name);
}
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;
externs->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 ; i<maxedicts; i++)
{
e = (edictrun_t *)(prinst.edicttable[i]);
if (e && (char*)e->fields >= oldb && (char*)e->fields < oldb+oldlen)
e->fields = ((char*)e->fields - oldb) + newb;
}
if (progfuncs->funcs.stringtable >= oldb && progfuncs->funcs.stringtable < oldb+oldlen)
progfuncs->funcs.stringtable = (progfuncs->funcs.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 < prinst.numfields; i++)
{
if (prinst.field[i].name >= oldb && prinst.field[i].name < oldb+oldlen)
prinst.field[i].name = (prinst.field[i].name - oldb) + newb;
}
externs->addressablerelocated(&progfuncs->funcs, 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)
{
#if defined(_WIN32) && !defined(WINRT)
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
int newsize = (prinst.addressableused + ammount + 1024*1024) & ~(1024*1024-1);
char *newblock = malloc(newsize);
if (newblock)
{
PRAddressableRelocate(progfuncs, prinst.addressablehunk, newblock, prinst.addressableused);
free(prinst.addressablehunk);
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;
progfuncs->funcs.stringtablesize = prinst.addressableused;
#if defined(_WIN32) && !defined(WINRT)
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->funcs.stringtable + p->prev);
np->next = p->next;
}
else
pr->inst.mfreelist = p->next;
if (p->next)
{
np = (qcmemfreeblock_t*)(pr->funcs.stringtable + p->next);
np->prev = p->prev;
}
}
/*
static void PR_memvalidate (progfuncs_t *progfuncs)
{
qcmemfreeblock_t *p;
unsigned int b,l;
b = prinst.mfreelist;
l = 0;
while (b)
{
if (b < 0 || b >= prinst.addressableused)
{
printf("PF_memalloc: memory corruption\n");
PR_StackTrace(&progfuncs->funcs, false);
return;
}
p = (qcmemfreeblock_t*)(progfuncs->funcs.stringtable + b);
if (p->prev != l ||
(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->funcs, false);
return;
}
l = b;
b = p->next;
}
}
*/
static void *PDECL PR_memalloc (pubprogfuncs_t *ppf, unsigned int size)
{
progfuncs_t *progfuncs = (progfuncs_t*)ppf;
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+sizeof(qcmemfreeblock_t) >= prinst.addressableused)
{
printf("PF_memalloc: memory corruption\n");
PR_StackTrace(&progfuncs->funcs, false);
return NULL;
}
p = (qcmemfreeblock_t*)(progfuncs->funcs.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->funcs, false);
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->funcs.stringtable + b + size);
np->prev = p->prev;
np->next = p->next;
np->size = p->size - size;
if (np->prev)
{
p = (qcmemfreeblock_t*)(progfuncs->funcs.stringtable + np->prev);
p->next = n;
}
else
prinst.mfreelist = n;
if (p->next)
{
p = (qcmemfreeblock_t*)(progfuncs->funcs.stringtable + np->next);
p->prev = n;
}
}
else
{
size = p->size; /*alloc the entire block*/
/*unlink this entry*/
PF_fmem_unlink(progfuncs, p);
}
break;
}
b = p->next;
}
/*assign more space*/
if (!ub)
{
ub = PRAddressableExtend(progfuncs, size);
if (!ub)
{
printf("PF_memalloc: memory exausted\n");
PR_StackTrace(&progfuncs->funcs, false);
return NULL;
}
}
memset(ub, 0, size);
ub->marker = MARKER;
ub->size = size;
// PR_memvalidate(progfuncs);
return ub+1;
}
static void PDECL PR_memfree (pubprogfuncs_t *ppf, void *memptr)
{
progfuncs_t *progfuncs = (progfuncs_t*)ppf;
qcmemusedblock_t *ub;
qcmemfreeblock_t *p, *np, *pp;
unsigned int pa, na; //prev addr, next addr
unsigned int size;
unsigned int ptr = memptr?((char*)memptr - progfuncs->funcs.stringtable):0;
/*freeing NULL is ignored*/
if (!ptr)
return;
// PR_memvalidate(progfuncs);
if (ptr < sizeof(qcmemusedblock_t) || ptr >= prinst.addressableused)
{
if (ptr < sizeof(qcmemusedblock_t) && !*(char*)memptr)
{
//the empty string is a point of contention. while we can detect it from fteqcc, its best to not give any special favours (other than nicer debugging, where possible)
//we might not actually spot it from other qccs, so warning about it where possible is probably a very good thing.
printf("PF_memfree: unable to free the non-null empty string constant at %x\n", ptr);
}
else
printf("PF_memfree: pointer invalid - out of range (%x >= %x)\n", ptr, (unsigned int)prinst.addressableused);
PR_StackTrace(&progfuncs->funcs, false);
return;
}
ub = (qcmemusedblock_t*)(progfuncs->funcs.stringtable + ptr);
ub--;
ptr = (char*)ub - progfuncs->funcs.stringtable;
if (ub->marker != MARKER || ub->size <= sizeof(*ub) || ptr + ub->size > (unsigned int)prinst.addressableused)
{
printf("PR_memfree: pointer lacks marker - double-freed?\n");
PR_StackTrace(&progfuncs->funcs, false);
return;
}
ub->marker = 0;
size = ub->size;
for (na = prinst.mfreelist, pa = 0; ;)
{
if (na < 0 || na >= prinst.addressableused)
{
printf("PF_memfree: memory corruption\n");
PR_StackTrace(&progfuncs->funcs, false);
return;
}
if (!na || na >= ptr)
{
np = (qcmemfreeblock_t*)(progfuncs->funcs.stringtable + pa);
if (pa && pa+np->size>ptr)
{
printf("PF_memfree: double free\n");
PR_StackTrace(&progfuncs->funcs, false);
return;
}
/*generate the free block, now we know its proper values*/
p = (qcmemfreeblock_t*)(progfuncs->funcs.stringtable + ptr);
np = na?(qcmemfreeblock_t*)(progfuncs->funcs.stringtable + na):NULL;
pp = pa?(qcmemfreeblock_t*)(progfuncs->funcs.stringtable + pa):NULL;
p->prev = pa;
p->next = na;
p->size = size;
/*update the next's previous*/
if (na)
{
np->prev = ptr;
/*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 (!pa)
prinst.mfreelist = ptr;
else
{
pp->next = ptr;
/*we're adjacent to the previous block, so merge them by killing the newly freed region*/
if (na && pa + np->size == ptr)
{
p->size += np->size;
PF_fmem_unlink(progfuncs, np);
}
}
break;
}
pa = na;
p = (qcmemfreeblock_t*)(progfuncs->funcs.stringtable + pa);
na = p->next;
}
// PR_memvalidate(progfuncs);
}
void PRAddressableFlush(progfuncs_t *progfuncs, size_t totalammount)
{
prinst.addressableused = 0;
if (totalammount <= 0) //flush
{
totalammount = prinst.addressablesize;
// return;
}
#if defined(_WIN32) && !defined(WINRT)
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;
progfuncs->funcs.stringtablemaxsize = totalammount;
}
int PDECL PR_InitEnts(pubprogfuncs_t *ppf, int max_ents)
{
progfuncs_t *progfuncs = (progfuncs_t*)ppf;
maxedicts = max_ents;
sv_num_edicts = 0;
#if 0
{
int i;
for (i = 0; i < prinst.numfields; i++)
{
printf("%s(%i) %i -> %i\n", prinst.field[i].name, prinst.field[i].type, prinst.field[i].progsofs, prinst.field[i].ofs);
}
}
#endif
max_fields_size = fields_size;
prinst.edicttable = PRHunkAlloc(progfuncs, maxedicts*sizeof(struct edicts_s *), "edicttable");
sv_edicts = PRHunkAlloc(progfuncs, externs->edictsize, "edict0");
prinst.edicttable[0] = sv_edicts;
((edictrun_t*)prinst.edicttable[0])->fields = PRAddressableExtend(progfuncs, max_fields_size);
QC_ClearEdict(&progfuncs->funcs, 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
static float tempedictfields[2048];
static void PDECL PR_Configure (pubprogfuncs_t *ppf, size_t addressable_size, int max_progs, pbool profiling) //can be used to wipe all memory
{
progfuncs_t *progfuncs = (progfuncs_t*)ppf;
unsigned int i;
edictrun_t *e;
max_fields_size=0;
fields_size = 0;
progfuncs->funcs.stringtable = 0;
QC_StartShares(progfuncs);
QC_InitShares(progfuncs);
for ( i=1 ; i<maxedicts; i++)
{
e = (edictrun_t *)(prinst.edicttable[i]);
prinst.edicttable[i] = NULL;
// e->entnum = i;
if (e)
externs->memfree(e);
}
PRHunkFree(progfuncs, 0); //clear mem - our hunk may not be a real hunk.
if (addressable_size<0 || addressable_size == (size_t)-1)
{
#if defined(_WIN64) && !defined(WINRT)
addressable_size = 0x80000000; //use of virtual address space rather than physical memory means we can just go crazy and use the max of 2gb.
#else
addressable_size = 32*1024*1024;
#endif
}
if (addressable_size > 0x80000000)
addressable_size = 0x80000000;
PRAddressableFlush(progfuncs, addressable_size);
pr_progstate = PRHunkAlloc(progfuncs, sizeof(progstate_t) * max_progs, "progstatetable");
/* for(a = 0; a < max_progs; a++)
{
pr_progstate[a].progs = NULL;
}
*/
maxprogs = max_progs;
pr_typecurrent=-1;
prinst.reorganisefields = false;
prinst.profiling = profiling;
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 *PDECL PR_globals (pubprogfuncs_t *ppf, progsnum_t pnum)
{
progfuncs_t *progfuncs = (progfuncs_t*)ppf;
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 *PDECL PR_entvars (pubprogfuncs_t *ppf, struct edict_s *ed)
{
// progfuncs_t *progfuncs = (progfuncs_t*)ppf;
if (((edictrun_t *)ed)->isfree)
return NULL;
return (struct entvars_s *)edvars(ed);
}
int PDECL PR_GetFuncArgCount(pubprogfuncs_t *ppf, func_t func)
{
progfuncs_t *progfuncs = (progfuncs_t*)ppf;
unsigned int pnum;
unsigned int fnum;
mfunction_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 PDECL PR_FindFunc(pubprogfuncs_t *ppf, const char *funcname, progsnum_t pnum)
{
progfuncs_t *progfuncs = (progfuncs_t*)ppf;
mfunction_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 PDECL QC_FindPrefixedGlobals(pubprogfuncs_t *ppf, int pnum, char *prefix, void (PDECL *found) (pubprogfuncs_t *progfuncs, char *name, union eval_s *val, etype_t type, void *ctx), void *ctx)
{
progfuncs_t *progfuncs = (progfuncs_t*)ppf;
unsigned int i;
ddef16_t *def16;
ddef32_t *def32;
int len = strlen(prefix);
if (pnum == PR_CURRENT)
pnum = pr_typecurrent;
if (pnum == PR_ANY)
{
for (pnum = 0; (unsigned)pnum < maxprogs; pnum++)
{
if (!pr_progstate[pnum].progs)
continue;
QC_FindPrefixedGlobals(ppf, pnum, prefix, found, ctx);
}
return;
}
if (!pr_progstate[pnum].progs)
return;
switch(pr_progstate[pnum].structtype)
{
case PST_DEFAULT:
case PST_KKQWSV:
for (i=1 ; i<pr_progstate[pnum].progs->numglobaldefs ; i++)
{
def16 = &pr_progstate[pnum].globaldefs16[i];
if (!strncmp(def16->s_name+progfuncs->funcs.stringtable,prefix, len))
found(&progfuncs->funcs, def16->s_name+progfuncs->funcs.stringtable, (eval_t *)&pr_progstate[pnum].globals[def16->ofs], def16->type, ctx);
}
break;
case PST_QTEST:
case PST_FTE32:
for (i=1 ; i<pr_progstate[pnum].progs->numglobaldefs ; i++)
{
def32 = &pr_progstate[pnum].globaldefs32[i];
if (!strncmp(def32->s_name+progfuncs->funcs.stringtable,prefix, len))
found(&progfuncs->funcs, def32->s_name+progfuncs->funcs.stringtable, (eval_t *)&pr_progstate[pnum].globals[def32->ofs], def32->type, ctx);
}
break;
}
}
eval_t *PDECL PR_FindGlobal(pubprogfuncs_t *ppf, const char *globname, progsnum_t pnum, etype_t *type)
{
progfuncs_t *progfuncs = (progfuncs_t*)ppf;
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->funcs, 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 PDECL SetGlobalEdict(pubprogfuncs_t *ppf, struct edict_s *ed, int ofs)
{
progfuncs_t *progfuncs = (progfuncs_t*)ppf;
((int*)pr_globals)[ofs] = EDICT_TO_PROG(progfuncs, ed);
}
char *PDECL PR_VarString (pubprogfuncs_t *ppf, int first)
{
progfuncs_t *progfuncs = (progfuncs_t*)ppf;
int i;
static char out[1024];
char *s;
out[0] = 0;
for (i=first ; i<progfuncs->funcs.callargc ; i++)
{
if (G_STRING(OFS_PARM0+i*3))
{
s=G_STRING((OFS_PARM0+i*3)) + progfuncs->funcs.stringtable;
if (strlen(out) + strlen(s) + 1 >= sizeof(out))
return out;
strcat (out, s);
}
}
return out;
}
int PDECL PR_QueryField (pubprogfuncs_t *ppf, unsigned int fieldoffset, etype_t *type, char **name, evalc_t *fieldcache)
{
progfuncs_t *progfuncs = (progfuncs_t*)ppf;
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 *PDECL QC_GetEdictFieldValue(pubprogfuncs_t *ppf, struct edict_s *ed, char *name, evalc_t *cache)
{
progfuncs_t *progfuncs = (progfuncs_t*)ppf;
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 *PDECL ProgsToEdict (pubprogfuncs_t *ppf, int progs)
{
progfuncs_t *progfuncs = (progfuncs_t*)ppf;
if ((unsigned)progs >= (unsigned)maxedicts)
{
printf("Bad entity index %i\n", progs);
if (pr_depth)
{
PR_StackTrace (ppf, false);
// progfuncs->funcs.pr_trace += 1;
}
progs = 0;
}
return (struct edict_s *)PROG_TO_EDICT(progfuncs.inst, progs);
}
int PDECL EdictToProgs (pubprogfuncs_t *ppf, struct edict_s *ed)
{
// progfuncs_t *progfuncs = (progfuncs_t*)ppf;
return EDICT_TO_PROG(progfuncs, ed);
}
string_t PDECL PR_StringToProgs (pubprogfuncs_t *ppf, const char *str)
{
progfuncs_t *progfuncs = (progfuncs_t*)ppf;
char **ntable;
int i, free=-1;
if (!str)
return 0;
if (str >= progfuncs->funcs.stringtable && str < progfuncs->funcs.stringtable + prinst.addressableused)
return str - progfuncs->funcs.stringtable;
for (i = prinst.numallocedstrings-1; i >= 0; i--)
{
if (prinst.allocedstrings[i] == str)
return (string_t)((unsigned int)i | STRING_STATIC);
if (!prinst.allocedstrings[i])
free = i;
}
if (free != -1)
{
i = free;
prinst.allocedstrings[i] = (char*)str;
return (string_t)((unsigned int)i | STRING_STATIC);
}
prinst.maxallocedstrings += 1024;
ntable = progfuncs->funcs.parms->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)
progfuncs->funcs.parms->memfree(prinst.allocedstrings);
prinst.allocedstrings = ntable;
for (i = prinst.numallocedstrings-1; i >= 0; i--)
{
if (!prinst.allocedstrings[i])
{
prinst.allocedstrings[i] = (char*)str;
return (string_t)((unsigned int)i | STRING_STATIC);
}
}
return 0;
}
//if ed is null, fld points to a global. if str_is_static, then s doesn't need its own memory allocated.
void PDECL PR_SetStringField(pubprogfuncs_t *progfuncs, struct edict_s *ed, string_t *fld, const char *str, pbool str_is_static)
{
*fld = PR_StringToProgs(progfuncs, str);
}
char *PDECL PR_RemoveProgsString (pubprogfuncs_t *ppf, string_t str)
{
progfuncs_t *progfuncs = (progfuncs_t*)ppf;
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 & STRING_SPECMASK) == STRING_STATIC)
{
int i = str & ~STRING_SPECMASK;
if (i >= prinst.numallocedstrings)
{
progfuncs->funcs.pr_trace = 1;
return NULL;
}
if (prinst.allocedstrings[i])
{
ret = prinst.allocedstrings[i];
prinst.allocedstrings[i] = NULL; //remove it
return ret;
}
else
{
progfuncs->funcs.pr_trace = 1;
return NULL; //urm, was freed...
}
}
printf("invalid static string %x\n", str);
progfuncs->funcs.pr_trace = 1;
return NULL;
}
const char *ASMCALL PR_StringToNative (pubprogfuncs_t *ppf, string_t str)
{
progfuncs_t *progfuncs = (progfuncs_t*)ppf;
if (((unsigned int)str & STRING_SPECMASK) == STRING_STATIC)
{
int i = str & ~STRING_SPECMASK;
if (i >= prinst.numallocedstrings)
{
if (!progfuncs->funcs.pr_trace)
{
printf("invalid string %x\n", str);
progfuncs->funcs.pr_trace = 1;
PR_StackTrace(&progfuncs->funcs, false);
}
return "";
}
if (prinst.allocedstrings[i])
return prinst.allocedstrings[i];
else
{
if (!progfuncs->funcs.pr_trace)
{
printf("invalid string %x\n", str);
progfuncs->funcs.pr_trace = 1;
PR_StackTrace(&progfuncs->funcs, false);
}
return ""; //urm, was freed...
}
}
if (((unsigned int)str & STRING_SPECMASK) == STRING_TEMP)
{
int i = str & ~STRING_SPECMASK;
if (i >= prinst.numtempstrings)
{
if (!progfuncs->funcs.pr_trace)
{
printf("invalid temp string %x\n", str);
progfuncs->funcs.pr_trace = 1;
PR_StackTrace(&progfuncs->funcs, false);
}
return "";
}
return prinst.tempstrings[i];
}
if ((unsigned int)str >= (unsigned int)prinst.addressableused)
{
if (!progfuncs->funcs.pr_trace)
{
printf("invalid string offset %x\n", str);
progfuncs->funcs.pr_trace = 1;
PR_StackTrace(&progfuncs->funcs, false);
}
return "";
}
return progfuncs->funcs.stringtable + str;
}
string_t PDECL PR_AllocTempString (pubprogfuncs_t *ppf, const char *str)
{
progfuncs_t *progfuncs = (progfuncs_t*)ppf;
char **ntable;
int newmax;
int i;
if (!str)
return 0;
if (prinst.numtempstrings == prinst.maxtempstrings)
{
newmax = prinst.maxtempstrings += 1024;
prinst.maxtempstrings += 1024;
ntable = progfuncs->funcs.parms->memalloc(sizeof(char*) * newmax);
memcpy(ntable, prinst.tempstrings, sizeof(char*) * prinst.numtempstrings);
prinst.maxtempstrings = newmax;
if (prinst.tempstrings)
progfuncs->funcs.parms->memfree(prinst.tempstrings);
prinst.tempstrings = ntable;
}
i = prinst.numtempstrings;
if (i == 0x10000000)
return 0;
prinst.numtempstrings++;
prinst.tempstrings[i] = progfuncs->funcs.parms->memalloc(strlen(str)+1);
strcpy(prinst.tempstrings[i], str);
return (string_t)((unsigned int)i | STRING_TEMP);
}
string_t PDECL PR_AllocTempStringLen (pubprogfuncs_t *ppf, char **str, unsigned int len)
{
progfuncs_t *progfuncs = (progfuncs_t*)ppf;
char **ntable;
int newmax;
int i;
if (!str)
return 0;
if (prinst.numtempstrings == prinst.maxtempstrings)
{
newmax = prinst.maxtempstrings += 1024;
prinst.maxtempstrings += 1024;
ntable = progfuncs->funcs.parms->memalloc(sizeof(char*) * newmax);
memcpy(ntable, prinst.tempstrings, sizeof(char*) * prinst.numtempstrings);
prinst.maxtempstrings = newmax;
if (prinst.tempstrings)
progfuncs->funcs.parms->memfree(prinst.tempstrings);
prinst.tempstrings = ntable;
}
i = prinst.numtempstrings;
if (i == 0x10000000)
return 0;
prinst.numtempstrings++;
prinst.tempstrings[i] = progfuncs->funcs.parms->memalloc(len);
*str = prinst.tempstrings[i];
return (string_t)((unsigned int)i | STRING_TEMP);
}
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++)
{
externs->memfree(prinst.tempstrings[i]);
}
prinst.numtempstrings = depth;
}
pbool PDECL PR_DumpProfiles (pubprogfuncs_t *ppf)
{
progfuncs_t *progfuncs = (progfuncs_t*)ppf;
struct progstate_s *ps;
unsigned int i, f, j, s;
unsigned long long cpufrequency;
struct
{
char *fname;
int profile;
unsigned long long profiletime;
unsigned long long totaltime;
} *sorted, t;
if (!prinst.profiling)
{
printf("Enabling profiling\n");
prinst.profiling = true;
return true;
}
cpufrequency = Sys_GetClockRate();
for (i = 0; i < maxprogs; i++)
{
ps = &pr_progstate[i];
if (ps->progs == NULL) //we havn't loaded it yet, for some reason
continue;
printf("%s:\n", ps->filename);
sorted = malloc(sizeof(*sorted) * ps->progs->numfunctions);
//pull out the functions in order to sort them
for (s = 0, f = 0; f < ps->progs->numfunctions; f++)
{
if (!ps->functions[f].profile)
continue;
sorted[s].fname = ps->functions[f].s_name+progfuncs->funcs.stringtable;
sorted[s].profile = ps->functions[f].profile;
sorted[s].profiletime = ps->functions[f].profiletime - ps->functions[f].profilechildtime;
sorted[s].totaltime = ps->functions[f].profiletime;
ps->functions[f].profile = 0;
ps->functions[f].profiletime = 0;
s++;
}
// good 'ol bubble sort
for (f = 0; f < s; f++)
{
for (j = f; j < s; j++)
if (sorted[f].profiletime > sorted[j].profiletime)
{
t = sorted[f];
sorted[f] = sorted[j];
sorted[j] = t;
}
}
//print it out
printf("%5s %5s %5s: %s\n", "ops", "self-time", "total-time", "function");
for (f = 0; f < s; f++)
printf("%5u %5g %5g: %s\n", sorted[f].profile, (float)(((double)sorted[f].profiletime) / cpufrequency), (float)(((double)sorted[f].totaltime) / cpufrequency), sorted[f].fname);
free(sorted);
}
return true;
}
static void PDECL PR_CloseProgs(pubprogfuncs_t *ppf);
static void PDECL RegisterBuiltin(pubprogfuncs_t *progfncs, char *name, builtin_t func);
pubprogfuncs_t deffuncs = {
PROGSTRUCT_VERSION,
PR_CloseProgs,
PR_Configure,
PR_LoadProgs,
PR_InitEnts,
PR_ExecuteProgram,
PR_globals,
PR_entvars,
PR_RunError,
ED_Print,
ED_Alloc,
ED_Free,
QC_EDICT_NUM,
QC_NUM_FOR_EDICT,
SetGlobalEdict,
PR_VarString,
NULL, //progstate
PR_FindFunc,
#if defined(MINIMAL) || defined(OMIT_QCC)
NULL,
NULL,
#else
Comp_Begin,
Comp_Continue,
#endif
filefromprogs,
NULL,//filefromnewprogs,
ED_Print,
PR_SaveEnts,
PR_LoadEnts,
PR_SaveEnt,
PR_RestoreEnt,
PR_FindGlobal,
ED_NewString,
QC_HunkAlloc,
QC_GetEdictFieldValue,
ProgsToEdict,
EdictToProgs,
PR_EvaluateDebugString,
0,//trace
PR_StackTrace,
PR_ToggleBreakpoint,
0, //numprogs
NULL, //parms
#if 1//defined(MINIMAL) || defined(OMIT_QCC)
NULL, //decompile
#else
QC_Decompile,
#endif
0, //callargc
RegisterBuiltin,
0, //string table(pointer base address)
0, //string table size
0, //max size
0, //field adjust(aditional field offset)
PR_ForkStack,
PR_ResumeThread,
PR_AbortStack,
0, //called builtin number
QC_RegisterFieldVar,
NULL, //user tempstringbase
0, //user tempstringnum
PR_AllocTempString,
PR_StringToProgs,
PR_StringToNative,
PR_QueryField,
QC_ClearEdict,
QC_FindPrefixedGlobals,
PR_memalloc,
PR_AllocTempStringLen,
PR_memfree,
PR_SetWatchPoint,
QC_AddSharedVar,
QC_AddSharedFieldVar,
PR_RemoveProgsString,
PR_GetFuncArgCount,
PR_GenerateStatementString,
ED_FieldInfo,
PR_UglyValueString,
ED_ParseEval,
PR_SetStringField,
PR_DumpProfiles
};
static int PDECL qclib_null_printf(const char *s, ...)
{
return 0;
}
static void *PDECL qclib_malloc(int size)
{
return malloc(size);
}
static void PDECL qclib_free(void *ptr)
{
free(ptr);
}
#ifdef FTE_TARGET_WEB
#undef printf
#define printf NULL //should be some null wrapper instead
#endif
//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);
qclib_null_printf, //void (*printf) (char *, ...);
(void*)exit, //void (*Sys_Error) (char *, ...);
NULL, //void (*Abort) (char *, ...);
NULL,
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,
qclib_malloc, //void *(*memalloc) (int size); //small string allocation malloced and freed randomly by the executor. (use memalloc if you want)
qclib_free, //void (*memfree) (void * mem);
NULL, //int (*useeditor) (char *filename, int line, int nump, char **parms);
NULL, //relocated
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;
sizeof(edictrun_t), //int edictsize; //size of edict_t
};
//progfuncs_t *progfuncs = NULL;
#undef memfree
#undef prinst
#undef extensionbuiltin
#undef field
#undef shares
#undef maxedicts
#undef sv_num_edicts
static void PDECL PR_CloseProgs(pubprogfuncs_t *ppf)
{
// extensionbuiltin_t *eb;
void (VARGS *f) (void *);
progfuncs_t *inst = (progfuncs_t*)ppf;
unsigned int i;
edictrun_t *e;
f = inst->funcs.parms->memfree;
for ( i=1 ; i<inst->inst.maxedicts; i++)
{
e = (edictrun_t *)(inst->inst.edicttable[i]);
inst->inst.edicttable[i] = NULL;
if (e)
{
// e->entnum = i;
f(e);
}
}
PRHunkFree(inst, 0);
#if defined(_WIN32) && !defined(WINRT)
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;
free(inst->inst.watch_name);
/*
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);
}
static void PDECL RegisterBuiltin(pubprogfuncs_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
pubprogfuncs_t * PDECL InitProgs(progexterns_t *ext)
{
progfuncs_t *funcs;
if (!ext)
ext = &defexterns;
else
{
int i;
if (ext->progsversion > PROGSTRUCT_VERSION)
return NULL;
for (i=0;i<sizeof(progexterns_t); i+=4) //make sure there are no items left out.
if (!*(int *)((char *)ext+i))
*(int *)((char *)ext+i) = *(int *)((char *)&defexterns+i);
}
#undef memalloc
#undef pr_progstate
#undef pr_argc
funcs = ext->memalloc(sizeof(progfuncs_t));
memcpy(&funcs->funcs, &deffuncs, sizeof(pubprogfuncs_t));
memset(&funcs->inst, 0, sizeof(funcs->inst));
funcs->funcs.progstate = &funcs->inst.progstate;
funcs->funcs.parms = ext;
SetEndian();
return &funcs->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