Files
scummvm/engine/lua/ldo.cpp
T
Pawel Kolodziejski 08a0ad818b remove dofile,
formating code
2008-07-28 14:51:57 +00:00

452 lines
12 KiB
C++

/*
** $Id$
** Stack and Call structure of Lua
** See Copyright Notice in lua.h
*/
#include "engine/lua/ldo.h"
#include "engine/lua/lfunc.h"
#include "engine/lua/lgc.h"
#include "engine/lua/lmem.h"
#include "engine/lua/lobject.h"
#include "engine/lua/lopcodes.h"
#include "engine/lua/lparser.h"
#include "engine/lua/lstate.h"
#include "engine/lua/ltask.h"
#include "engine/lua/ltm.h"
#include "engine/lua/lua.h"
#include "engine/lua/luadebug.h"
#include "engine/lua/lundump.h"
#include "engine/lua/lvm.h"
#include "engine/lua/lzio.h"
#include "common/file.h"
#ifndef STACK_LIMIT
#define STACK_LIMIT 6000
#endif
// Extra stack size to run a function: LUA_T_LINE(1), TM calls(2), ...
#define EXTRA_STACK 5
/*
** Error messages
*/
void stderrorim() {
fprintf(stderr, "lua error: %s\n", lua_getstring(lua_getparam(1)));
}
#define STACK_UNIT 128
// Initial size for CallInfo array
#define BASIC_CI_SIZE 8
void luaD_init() {
ttype(&L->errorim) = LUA_T_CPROTO;
fvalue(&L->errorim) = stderrorim;
}
void luaD_initthr() {
L->stack.stack = luaM_newvector(STACK_UNIT, TObject);
L->stack.top = L->stack.stack;
L->stack.last = L->stack.stack + (STACK_UNIT - 1);
L->base_ci = luaM_newvector(BASIC_CI_SIZE, struct CallInfo);
memset(L->base_ci, 0, sizeof(CallInfo) * BASIC_CI_SIZE);
L->base_ci_size = sizeof(CallInfo) * BASIC_CI_SIZE;
L->ci = L->base_ci;
L->ci->tf = NULL;
L->end_ci = L->base_ci + BASIC_CI_SIZE;
}
void luaD_checkstack(int32 n) {
struct Stack *S = &L->stack;
if (S->last-S->top <= n) {
StkId top = S->top-S->stack;
int32 stacksize = (S->last-S->stack) + 1 + STACK_UNIT + n;
S->stack = luaM_reallocvector(S->stack, stacksize, TObject);
S->last = S->stack + (stacksize - 1);
S->top = S->stack + top;
if (stacksize >= STACK_LIMIT) { // stack overflow?
if (lua_stackedfunction(100) == LUA_NOOBJECT) // 100 funcs on stack?
lua_error("Lua2C - C2Lua overflow"); // doesn't look like a rec. loop
else
lua_error("stack size overflow");
}
}
}
/*
** Adjust stack. Set top to the given value, pushing NILs if needed.
*/
void luaD_adjusttop(StkId newtop) {
int32 diff = newtop-(L->stack.top-L->stack.stack);
if (diff <= 0)
L->stack.top += diff;
else {
luaD_checkstack(diff);
while (diff--)
ttype(L->stack.top++) = LUA_T_NIL;
}
}
/*
** Open a hole below "nelems" from the L->stack.top.
*/
void luaD_openstack(int32 nelems) {
luaO_memup(L->stack.top - nelems + 1, L->stack.top - nelems, nelems * sizeof(TObject));
incr_top;
}
void luaD_lineHook(int32 line) {
struct C_Lua_Stack oldCLS = L->Cstack;
StkId old_top = L->Cstack.lua2C = L->Cstack.base = L->stack.top-L->stack.stack;
L->Cstack.num = 0;
(*lua_linehook)(line);
L->stack.top = L->stack.stack + old_top;
L->Cstack = oldCLS;
}
void luaD_callHook(StkId base, TProtoFunc *tf, int32 isreturn) {
struct C_Lua_Stack oldCLS = L->Cstack;
StkId old_top = L->Cstack.lua2C = L->Cstack.base = L->stack.top-L->stack.stack;
L->Cstack.num = 0;
if (isreturn)
(*lua_callhook)(LUA_NOOBJECT, "(return)", 0);
else {
TObject *f = L->stack.stack + base - 1;
if (tf)
(*lua_callhook)(Ref(f), tf->fileName->str, tf->lineDefined);
else
(*lua_callhook)(Ref(f), "(C)", -1);
}
L->stack.top = L->stack.stack + old_top;
L->Cstack = oldCLS;
}
/*
** Call a C function.
** Cstack.num is the number of arguments; Cstack.lua2C points to the
** first argument. Returns an index to the first result from C.
*/
static StkId callC(lua_CFunction f, StkId base) {
struct C_Lua_Stack *CS = &L->Cstack;
struct C_Lua_Stack oldCLS = *CS;
StkId firstResult;
int32 numarg = (L->stack.top-L->stack.stack) - base;
CS->num = numarg;
CS->lua2C = base;
CS->base = base + numarg; // == top - stack
if (lua_callhook)
luaD_callHook(base, NULL, 0);
(*f)(); // do the actual call
if (lua_callhook) // func may have changed lua_callhook
luaD_callHook(base, NULL, 1);
firstResult = CS->base;
*CS = oldCLS;
return firstResult;
}
static StkId callCclosure(struct Closure *cl, lua_CFunction f, StkId base) {
TObject *pbase;
int32 nup = cl->nelems; // number of upvalues
luaD_checkstack(nup);
pbase = L->stack.stack + base; // care: previous call may change this
// open space for upvalues as extra arguments
luaO_memup(pbase+nup, pbase, (L->stack.top - pbase) * sizeof(TObject));
// copy upvalues into stack
memcpy(pbase, cl->consts + 1, nup * sizeof(TObject));
L->stack.top += nup;
return callC(f, base);
}
void luaD_callTM(TObject *f, int32 nParams, int32 nResults) {
luaD_openstack(nParams);
*(L->stack.top - nParams - 1) = *f;
luaD_call((L->stack.top - L->stack.stack) - nParams, nResults);
}
static void adjust_varargs(StkId first_extra_arg) {
TObject arg;
luaV_pack(first_extra_arg, (L->stack.top - L->stack.stack) - first_extra_arg, &arg);
luaD_adjusttop(first_extra_arg);
*L->stack.top++ = arg;
}
/*
** Prepare the stack for calling a Lua function.
*/
void luaD_precall(TObject *f, StkId base, int32 nResults) {
// Create a new CallInfo record
if (L->ci+1 == L->end_ci) {
int32 size_ci = L->end_ci - L->base_ci;
int32 index_ci = L->ci - L->base_ci;
int32 new_ci_size = size_ci * 2 * sizeof(CallInfo);
CallInfo *new_ci = (CallInfo *)luaM_malloc(new_ci_size);
memcpy(new_ci, L->base_ci, L->base_ci_size);
memset(new_ci + (L->base_ci_size / sizeof(CallInfo)), 0, (new_ci_size) - L->base_ci_size);
luaM_free(L->base_ci);
L->base_ci = new_ci;
L->base_ci_size = new_ci_size;
L->ci = L->base_ci + index_ci;
L->end_ci = L->base_ci + size_ci * 2;
}
L->ci++;
if (ttype(f) == LUA_T_CLOSURE) {
L->ci->c = clvalue(f);
f = &L->ci->c->consts[0]; // Get the actual function
} else {
L->ci->c = NULL;
}
L->ci->base = base;
L->ci->nResults = nResults;
if (ttype(f)==LUA_T_CPROTO) {
L->ci->tf = NULL;
L->ci->pc = NULL;
} else {
Byte *pc = tfvalue(f)->code;
if (lua_callhook)
luaD_callHook(base, tfvalue(f), 0);
luaD_checkstack((*pc++) + EXTRA_STACK);
if (*pc < ZEROVARARG) {
luaD_adjusttop(base + *(pc++));
} else { // varargs
luaC_checkGC();
adjust_varargs(base + (*pc++) - ZEROVARARG);
}
L->ci->tf = tfvalue(f);
L->ci->pc = pc;
}
}
/*
** Adjust the stack to the desired number of results
*/
void luaD_postret(StkId firstResult) {
int32 i;
StkId base = L->ci->base;
int32 nResults = L->ci->nResults;
if (L->ci == L->base_ci)
lua_error("call stack underflow");
// adjust the number of results
if (nResults != MULT_RET)
luaD_adjusttop(firstResult + nResults);
// move results to base - 1 (to erase parameters and function)
base--;
nResults = L->stack.top - (L->stack.stack + firstResult); // actual number of results
for (i = 0; i < nResults; i++)
*(L->stack.stack + base + i) = *(L->stack.stack + firstResult + i);
L->stack.top -= firstResult - base;
// pop off the current CallInfo
L->ci--;
}
/*
** Call a function (C or Lua). The parameters must be on the L->stack.stack,
** between [L->stack.stack+base,L->stack.top). The function to be called is at L->stack.stack+base-1.
** When returns, the results are on the L->stack.stack, between [L->stack.stack+base-1,L->stack.top).
** The number of results is nResults, unless nResults=MULT_RET.
*/
void luaD_call(StkId base, int32 nResults) {
StkId firstResult;
TObject *func = L->stack.stack + base - 1;
switch (ttype(func)) {
case LUA_T_CPROTO:
luaD_precall(func, base, nResults);
ttype(func) = LUA_T_CMARK;
firstResult = callC(fvalue(func), base);
break;
case LUA_T_PROTO:
luaD_precall(func, base, nResults);
ttype(func) = LUA_T_PMARK;
firstResult = luaV_execute(L->ci);
break;
case LUA_T_CLOSURE:
{
Closure *c = clvalue(func);
TObject *proto = &(c->consts[0]);
luaD_precall(func, base, nResults);
ttype(func) = LUA_T_CLMARK;
firstResult = (ttype(proto) == LUA_T_CPROTO) ? callCclosure(c, fvalue(proto), base) : luaV_execute(L->ci);
break;
}
default:
{ // func is not a function
// Check the tag method for invalid functions
TObject *im = luaT_getimbyObj(func, IM_FUNCTION);
if (ttype(im) == LUA_T_NIL)
lua_error("call expression not a function");
luaD_callTM(im, (L->stack.top - L->stack.stack) - (base - 1), nResults);
return;
}
}
luaD_postret(firstResult);
}
static void travstack(struct Stack *S, int32 (*fn)(TObject *)) {
StkId i;
for (i = (S->top - 1) - S->stack; i >= 0; i--)
fn(S->stack + i);
}
/*
** Traverse all objects on L->stack.stack, and all other active stacks
*/
void luaD_travstack(int32(*fn)(TObject *)) {
struct lua_Task *t;
travstack(&L->stack, fn);
for (t = L->root_task; t != NULL; t = t->next)
if (t != L->curr_task && t->Tstate != DONE)
travstack(&t->stack, fn);
}
static void message(const char *s) {
TObject im = L->errorim;
if (ttype(&im) != LUA_T_NIL) {
lua_pushstring(s);
luaD_callTM(&im, 1, 0);
}
}
/*
** Reports an error, and jumps up to the available recover label
*/
void lua_error(const char *s) {
if (s)
message(s);
if (L->errorJmp) {
longjmp(*((jmp_buf *)L->errorJmp), 1);
} else {
fprintf(stderr, "lua: exit(1). Unable to recover\n");
exit(1);
}
}
/*
** Call the function at L->Cstack.base, and incorporate results on
** the Lua2C structure.
*/
static void do_callinc(int32 nResults) {
StkId base = L->Cstack.base;
luaD_call(base + 1, nResults);
L->Cstack.lua2C = base; // position of the luaM_new results
L->Cstack.num = (L->stack.top - L->stack.stack) - base; // number of results
L->Cstack.base = base + L->Cstack.num; // incorporate results on L->stack.stack/
}
/*
** Execute a protected call. Assumes that function is at L->Cstack.base and
** parameters are on top of it. Leave nResults on the stack.
*/
int32 luaD_protectedrun(int32 nResults) {
jmp_buf myErrorJmp;
int32 status;
struct C_Lua_Stack oldCLS = L->Cstack;
jmp_buf *oldErr = L->errorJmp;
int32 ci_len = L->ci - L->base_ci;
L->errorJmp = &myErrorJmp;
if (setjmp(myErrorJmp) == 0) {
do_callinc(nResults);
status = 0;
} else { // an error occurred: restore L->Cstack and L->stack.top
L->Cstack = oldCLS;
L->stack.top = L->stack.stack + L->Cstack.base;
L->ci = L->base_ci + ci_len;
status = 1;
}
L->errorJmp = oldErr;
return status;
}
/*
** returns 0 = chunk loaded; 1 = error; 2 = no more chunks to load
*/
static int32 protectedparser(ZIO *z, int32 bin) {
volatile int32 status;
TProtoFunc *volatile tf;
jmp_buf myErrorJmp;
jmp_buf *volatile oldErr = L->errorJmp;
L->errorJmp = &myErrorJmp;
if (setjmp(myErrorJmp) == 0) {
tf = bin ? luaU_undump1(z) : luaY_parser(z);
status = 0;
} else {
tf = NULL;
status = 1;
}
L->errorJmp = oldErr;
if (status)
return 1; // error code
if (tf == NULL)
return 2; // 'natural' end
luaD_adjusttop(L->Cstack.base + 1); // one slot for the pseudo-function
L->stack.stack[L->Cstack.base].ttype = LUA_T_PROTO;
L->stack.stack[L->Cstack.base].value.tf = tf;
luaV_closure(0);
return 0;
}
static int32 do_main(ZIO *z, int32 bin) {
int32 status;
do {
int32 old_blocks = (luaC_checkGC(), L->nblocks);
status = protectedparser(z, bin);
if (status == 1)
return 1; // error
else if (status == 2)
return 0; // 'natural' end
else {
int32 newelems2 = 2 * (L->nblocks - old_blocks);
L->GCthreshold += newelems2;
status = luaD_protectedrun(MULT_RET);
L->GCthreshold -= newelems2;
}
} while (bin && status == 0);
return status;
}
void luaD_gcIM(TObject *o) {
TObject *im = luaT_getimbyObj(o, IM_GC);
if (ttype(im) != LUA_T_NIL) {
*L->stack.top = *o;
incr_top;
luaD_callTM(im, 1, 0);
}
}
#define SIZE_PREF 20 // size of string prefix to appear in error messages
#define SSIZE_PREF "20"
static void build_name (const char *str, char *name) {
if (str == NULL || *str == ID_CHUNK)
strcpy(name, "(buffer)");
else {
char *temp;
sprintf(name, "(dostring) >> \"%." SSIZE_PREF "s\"", str);
temp = strchr(name, '\n');
if (temp) { // end string after first line
*temp = '"';
*(temp + 1) = 0;
}
}
}
int32 lua_dostring(const char *str) {
return lua_dobuffer(str, strlen(str), NULL);
}
int32 lua_dobuffer(const char *buff, int32 size, const char *name) {
char newname[SIZE_PREF + 25];
ZIO z;
int32 status;
if (!name) {
build_name(buff, newname);
name = newname;
}
luaZ_mopen(&z, buff, size, name);
status = do_main(&z, buff[0] == ID_CHUNK);
return status;
}