/* Expression Evaluator Library (NS-EEL) v2 Copyright (C) 2004-2008 Cockos Incorporated Copyright (C) 1999-2003 Nullsoft, Inc. nseel-compiler.c This software is provided 'as-is', without any express or implied warranty. In no event will the authors be held liable for any damages arising from the use of this software. Permission is granted to anyone to use this software for any purpose, including commercial applications, and to alter it and redistribute it freely, subject to the following restrictions: 1. The origin of this software must not be misrepresented; you must not claim that you wrote the original software. If you use this software in a product, an acknowledgment in the product documentation would be appreciated but is not required. 2. Altered source versions must be plainly marked as such, and must not be misrepresented as being the original software. 3. This notice may not be removed or altered from any source distribution. */ // for VirtualProtect #include "ns-eel-int.h" #include #include #include #include #ifndef _WIN64 #ifndef __ppc__ #include #endif #endif #ifdef __APPLE__ #ifdef __LP64__ #define EEL_USE_MPROTECT #endif #endif #ifdef EEL_USE_MPROTECT #include #include #include #endif #ifdef NSEEL_EEL1_COMPAT_MODE #ifndef EEL_NO_CHANGE_FPFLAGS #define EEL_NO_CHANGE_FPFLAGS #endif #endif #ifndef _WIN64 #if !defined(_RC_CHOP) && !defined(EEL_NO_CHANGE_FPFLAGS) #include #define _RC_CHOP _FPU_RC_ZERO #define _MCW_RC _FPU_RC_ZERO static unsigned int _controlfp(unsigned int val, unsigned int mask) { unsigned int ret; _FPU_GETCW(ret); if (mask) { ret&=~mask; ret|=val; _FPU_SETCW(ret); } return ret; } #endif #endif #ifdef __ppc__ #define GLUE_MOV_EAX_DIRECTVALUE_SIZE 8 static void GLUE_MOV_EAX_DIRECTVALUE_GEN(void *b, INT_PTR v) { unsigned int uv=(unsigned int)v; unsigned short *p=(unsigned short *)b; *p++ = 0x3C60; // addis r3, r0, hw *p++ = (uv>>16)&0xffff; *p++ = 0x6063; // ori r3, r3, lw *p++ = uv&0xffff; } // mflr r5 // stwu r5, -4(r1) const static unsigned int GLUE_FUNC_ENTER[2] = { 0x7CA802A6, 0x94A1FFFC }; // lwz r5, 0(r1) // addi r1, r1, 4 // mtlr r5 const static unsigned int GLUE_FUNC_LEAVE[3] = { 0x80A10000, 0x38210004, 0x7CA803A6 }; #define GLUE_FUNC_ENTER_SIZE sizeof(GLUE_FUNC_ENTER) #define GLUE_FUNC_LEAVE_SIZE sizeof(GLUE_FUNC_LEAVE) const static unsigned int GLUE_RET[]={0x4E800020}; // blr const static unsigned int GLUE_MOV_ESI_EDI=0x7E308B78; // mr r16, r17 static int GLUE_RESET_ESI(char *out, void *ptr) { if (out) memcpy(out,&GLUE_MOV_ESI_EDI,sizeof(GLUE_MOV_ESI_EDI)); return sizeof(GLUE_MOV_ESI_EDI); } // stwu r3, -4(r1) const static unsigned int GLUE_PUSH_EAX[1]={ 0x9461FFFC}; // lwz r14, 0(r1) // addi r1, r1, 4 const static unsigned int GLUE_POP_EBX[2]={ 0x81C10000, 0x38210004, }; // lwz r15, 0(r1) // addi r1, r1, 4 const static unsigned int GLUE_POP_ECX[2]={ 0x81E10000, 0x38210004 }; static void GLUE_CALL_CODE(INT_PTR bp, INT_PTR cp) { __asm__( "stmw r14, -80(r1)\n" "mtctr %0\n" "mr r17, %1\n" "subi r17, r17, 8\n" "mflr r5\n" "stw r5, -84(r1)\n" "subi r1, r1, 88\n" "bctrl\n" "addi r1, r1, 88\n" "lwz r5, -84(r1)\n" "lmw r14, -80(r1)\n" "mtlr r5\n" ::"r" (cp), "r" (bp)); }; INT_PTR *EEL_GLUE_set_immediate(void *_p, void *newv) { // todo 64 bit ppc will take some work unsigned int *p=(unsigned int *)_p; while ((p[0]&0x0000FFFF) != 0x0000dead && (p[1]&0x0000FFFF) != 0x0000beef) p++; p[0] = (p[0]&0xFFFF0000) | (((unsigned int)newv)>>16); p[1] = (p[1]&0xFFFF0000) | (((unsigned int)newv)&0xFFFF); return (INT_PTR*)++p; } #else //x86 specific code #define GLUE_FUNC_ENTER_SIZE 0 #define GLUE_FUNC_LEAVE_SIZE 0 const static unsigned int GLUE_FUNC_ENTER[1]; const static unsigned int GLUE_FUNC_LEAVE[1]; #if defined(_WIN64) || defined(__LP64__) #define GLUE_MOV_EAX_DIRECTVALUE_SIZE 10 static void GLUE_MOV_EAX_DIRECTVALUE_GEN(void *b, INT_PTR v) { unsigned short *bb = (unsigned short *)b; *bb++ =0xB848; *(INT_PTR *)bb = v; } const static unsigned char GLUE_PUSH_EAX[2]={ 0x50,0x50}; // push rax ; push rax (push twice to preserve alignment) const static unsigned char GLUE_POP_EBX[2]={0x5F, 0x5f}; //pop rdi ; twice const static unsigned char GLUE_POP_ECX[2]={0x59, 0x59 }; // pop rcx ; twice #else #define GLUE_MOV_EAX_DIRECTVALUE_SIZE 5 static void GLUE_MOV_EAX_DIRECTVALUE_GEN(void *b, int v) { *((unsigned char *)b) =0xB8; b= ((unsigned char *)b)+1; *(int *)b = v; } const static unsigned char GLUE_PUSH_EAX[4]={0x83, 0xEC, 12, 0x50}; // sub esp, 12, push eax const static unsigned char GLUE_POP_EBX[4]={0x5F, 0x83, 0xC4, 12}; //pop ebx, add esp, 12 // DI=5F, BX=0x5B; const static unsigned char GLUE_POP_ECX[4]={0x59, 0x83, 0xC4, 12}; // pop ecx, add esp, 12 #endif //const static unsigned short GLUE_MOV_ESI_EDI=0xF78B; const static unsigned char GLUE_RET=0xC3; static int GLUE_RESET_ESI(unsigned char *out, void *ptr) { #if defined(_WIN64) || defined(__LP64__) if (out) { *out++ = 0x48; *out++ = 0xBE; // mov rsi, constant64 *(void **)out = ptr; out+=sizeof(void *); } return 2+sizeof(void *); #else if (out) { *out++ = 0xBE; // mov esi, constant memcpy(out,&ptr,sizeof(void *)); out+=sizeof(void *); } return 1+sizeof(void *); #endif } static void GLUE_CALL_CODE(INT_PTR bp, INT_PTR cp) { #if defined(_WIN64) || defined(__LP64__) extern void win64_callcode(INT_PTR code); win64_callcode(cp); #else // non-64 bit #ifdef _MSC_VER #ifndef EEL_NO_CHANGE_FPFLAGS unsigned int old_v=_controlfp(0,0); _controlfp(_RC_CHOP,_MCW_RC); #endif __asm { mov eax, cp pushad call eax popad }; #ifndef EEL_NO_CHANGE_FPFLAGS _controlfp(old_v,_MCW_RC); #endif #else // gcc x86 #ifndef EEL_NO_CHANGE_FPFLAGS unsigned int old_v=_controlfp(0,0); _controlfp(_RC_CHOP,_MCW_RC); #endif __asm__("call *%%eax"::"a" (cp): "%ecx","%edx","%esi","%edi"); #ifndef EEL_NO_CHANGE_FPFLAGS _controlfp(old_v,_MCW_RC); #endif #endif //gcc x86 #endif // 32bit } INT_PTR *EEL_GLUE_set_immediate(void *_p, void *newv) { char *p=(char*)_p; while (*(INT_PTR *)p != ~(INT_PTR)0) p++; *(INT_PTR *)p = (INT_PTR)newv; return ((INT_PTR*)p)+1; } #endif static void *GLUE_realAddress(void *fn, void *fn_e, int *size) { #if defined(_MSC_VER) || defined(__LP64__) unsigned char *p; #if defined(_DEBUG) && !defined(__LP64__) if (*(unsigned char *)fn == 0xE9) // this means jump to the following address { fn = ((unsigned char *)fn) + *(int *)((char *)fn+1) + 5; } #endif // this may not work in debug mode p=(unsigned char *)fn; for (;;) { int a; for (a=0;a<12;a++) { if (p[a] != (a?0x90:0x89)) break; } if (a>=12) { *size = (char *)p - (char *)fn; // if (*size<0) MessageBox(NULL,"expect poof","a",0); return fn; } p++; } #else char *p=(char *)fn_e - sizeof(GLUE_RET); if (p <= (char *)fn) *size=0; else { while (p > (char *)fn && memcmp(p,&GLUE_RET,sizeof(GLUE_RET))) p-=sizeof(GLUE_RET); *size = p - (char *)fn; } return fn; #endif } static int nseel_evallib_stats[5]; // source bytes, static code bytes, call code bytes, data bytes, segments int *NSEEL_getstats() { return nseel_evallib_stats; } EEL_F *NSEEL_getglobalregs() { return nseel_globalregs; } // this stuff almost works static int findByteOffsetInSource(compileContext *ctx, int byteoffs,int *destoffs) { int x; if (!ctx->compileLineRecs || !ctx->compileLineRecs_size) return *destoffs=0; if (byteoffs < ctx->compileLineRecs[0].destByteCount) { *destoffs=0; return 1; } for (x = 0; x < ctx->compileLineRecs_size-1; x ++) { if (byteoffs >= ctx->compileLineRecs[x].destByteCount && byteoffs < ctx->compileLineRecs[x+1].destByteCount) break; } *destoffs=ctx->compileLineRecs[(x&&x==ctx->compileLineRecs_size-1)?x-1:x].srcByteCount; return x+2; } static void onCompileNewLine(compileContext *ctx, int srcBytes, int destBytes) { if (!ctx->compileLineRecs || ctx->compileLineRecs_size >= ctx->compileLineRecs_alloc) { ctx->compileLineRecs_alloc = ctx->compileLineRecs_size+1024; ctx->compileLineRecs = (lineRecItem *)realloc(ctx->compileLineRecs,sizeof(lineRecItem)*ctx->compileLineRecs_alloc); } if (ctx->compileLineRecs) { ctx->compileLineRecs[ctx->compileLineRecs_size].srcByteCount=srcBytes; ctx->compileLineRecs[ctx->compileLineRecs_size++].destByteCount=destBytes; } } #define LLB_DSIZE (65536-64) typedef struct _llBlock { struct _llBlock *next; int sizeused; char block[LLB_DSIZE]; } llBlock; typedef struct _startPtr { struct _startPtr *next; void *startptr; } startPtr; typedef struct { void *workTable; llBlock *blocks; void *code; int code_stats[4]; } codeHandleType; #ifndef NSEEL_MAX_TEMPSPACE_ENTRIES #define NSEEL_MAX_TEMPSPACE_ENTRIES 2048 #endif static void *__newBlock(llBlock **start,int size); #define newTmpBlock(x) __newTmpBlock((llBlock **)&ctx->tmpblocks_head,x) #define newBlock(x,a) __newBlock_align(ctx,x,a) static void *__newTmpBlock(llBlock **start, int size) { void *p=__newBlock(start,size+4); if (p && size>=0) *((int *)p) = size; return p; } static void *__newBlock_align(compileContext *ctx, int size, int align) // makes sure block is aligned to 32 byte boundary, for code { int a1=align-1; char *p=(char*)__newBlock((llBlock **)&ctx->blocks_head,size+a1); return p+((align-(((INT_PTR)p)&a1))&a1); } static void freeBlocks(llBlock **start); #define DECL_ASMFUNC(x) \ void nseel_asm_##x(void); \ void nseel_asm_##x##_end(void); \ DECL_ASMFUNC(sin) DECL_ASMFUNC(cos) DECL_ASMFUNC(tan) DECL_ASMFUNC(1pdd) DECL_ASMFUNC(2pdd) DECL_ASMFUNC(2pdds) DECL_ASMFUNC(1pp) DECL_ASMFUNC(2pp) DECL_ASMFUNC(sqr) DECL_ASMFUNC(sqrt) DECL_ASMFUNC(log) DECL_ASMFUNC(log10) DECL_ASMFUNC(abs) DECL_ASMFUNC(min) DECL_ASMFUNC(max) DECL_ASMFUNC(sig) DECL_ASMFUNC(sign) DECL_ASMFUNC(band) DECL_ASMFUNC(bor) DECL_ASMFUNC(bnot) DECL_ASMFUNC(if) DECL_ASMFUNC(repeat) DECL_ASMFUNC(repeatwhile) DECL_ASMFUNC(equal) DECL_ASMFUNC(notequal) DECL_ASMFUNC(below) DECL_ASMFUNC(above) DECL_ASMFUNC(beloweq) DECL_ASMFUNC(aboveeq) DECL_ASMFUNC(assign) DECL_ASMFUNC(add) DECL_ASMFUNC(sub) DECL_ASMFUNC(add_op) DECL_ASMFUNC(sub_op) DECL_ASMFUNC(mul) DECL_ASMFUNC(div) DECL_ASMFUNC(mul_op) DECL_ASMFUNC(div_op) DECL_ASMFUNC(mod) DECL_ASMFUNC(mod_op) DECL_ASMFUNC(or) DECL_ASMFUNC(and) DECL_ASMFUNC(or_op) DECL_ASMFUNC(and_op) DECL_ASMFUNC(uplus) DECL_ASMFUNC(uminus) DECL_ASMFUNC(invsqrt) DECL_ASMFUNC(exec2) static void NSEEL_PProc_GRAM(void *data, int data_size, compileContext *ctx) { if (data_size>0) EEL_GLUE_set_immediate(data, ctx->gram_blocks); } static EEL_F g_signs[2]={1.0,-1.0}; static EEL_F negativezeropointfive=-0.5f; static EEL_F onepointfive=1.5f; static EEL_F g_closefact = NSEEL_CLOSEFACTOR; static const EEL_F eel_zero=0.0, eel_one=1.0; //#if defined(_MSC_VER) && _MSC_VER >= 1400 //static double __floor(double a) { return floor(a); } //#endif static double eel1band(double a, double b) { return (fabs(a)>g_closefact && fabs(b) > g_closefact) ? 1.0 : 0.0; } static double eel1bor(double a, double b) { return (fabs(a)>g_closefact || fabs(b) > g_closefact) ? 1.0 : 0.0; } static double eel1sigmoid(double x, double constraint) { double t = (1+exp(-x * (constraint))); return fabs(t)>g_closefact ? 1.0/t : 0; } EEL_F NSEEL_CGEN_CALL nseel_int_rand(EEL_F *f); static functionType fnTable1[] = { { "_if", nseel_asm_if,nseel_asm_if_end, 3, {&g_closefact} }, { "_and", nseel_asm_band,nseel_asm_band_end, 2 } , { "_or", nseel_asm_bor,nseel_asm_bor_end, 2 } , { "loop", nseel_asm_repeat,nseel_asm_repeat_end, 2 }, { "while", nseel_asm_repeatwhile,nseel_asm_repeatwhile_end, 1 }, #ifdef __ppc__ { "_not", nseel_asm_bnot,nseel_asm_bnot_end, 1, {&g_closefact,&eel_zero,&eel_one} } , { "_equal", nseel_asm_equal,nseel_asm_equal_end, 2, {&g_closefact,&eel_zero, &eel_one} }, { "_noteq", nseel_asm_notequal,nseel_asm_notequal_end, 2, {&g_closefact,&eel_one,&eel_zero} }, { "_below", nseel_asm_below,nseel_asm_below_end, 2, {&eel_zero, &eel_one} }, { "_above", nseel_asm_above,nseel_asm_above_end, 2, {&eel_zero, &eel_one} }, { "_beleq", nseel_asm_beloweq,nseel_asm_beloweq_end, 2, {&eel_zero, &eel_one} }, { "_aboeq", nseel_asm_aboveeq,nseel_asm_aboveeq_end, 2, {&eel_zero, &eel_one} }, #else { "_not", nseel_asm_bnot,nseel_asm_bnot_end, 1, {&g_closefact} } , { "_equal", nseel_asm_equal,nseel_asm_equal_end, 2, {&g_closefact} }, { "_noteq", nseel_asm_notequal,nseel_asm_notequal_end, 2, {&g_closefact} }, { "_below", nseel_asm_below,nseel_asm_below_end, 2 }, { "_above", nseel_asm_above,nseel_asm_above_end, 2 }, { "_beleq", nseel_asm_beloweq,nseel_asm_beloweq_end, 2 }, { "_aboeq", nseel_asm_aboveeq,nseel_asm_aboveeq_end, 2 }, #endif { "_set",nseel_asm_assign,nseel_asm_assign_end,2}, { "_mod",nseel_asm_mod,nseel_asm_mod_end,2}, { "_mulop",nseel_asm_mul_op,nseel_asm_mul_op_end,2}, { "_divop",nseel_asm_div_op,nseel_asm_div_op_end,2}, { "_orop",nseel_asm_or_op,nseel_asm_or_op_end,2}, { "_andop",nseel_asm_and_op,nseel_asm_and_op_end,2}, { "_addop",nseel_asm_add_op,nseel_asm_add_op_end,2}, { "_subop",nseel_asm_sub_op,nseel_asm_sub_op_end,2}, { "_modop",nseel_asm_mod_op,nseel_asm_mod_op_end,2}, #ifdef __ppc__ { "sin", nseel_asm_1pdd,nseel_asm_1pdd_end, 1, {&sin} }, { "cos", nseel_asm_1pdd,nseel_asm_1pdd_end, 1, {&cos} }, { "tan", nseel_asm_1pdd,nseel_asm_1pdd_end, 1, {&tan} }, #else { "sin", nseel_asm_sin,nseel_asm_sin_end, 1 }, { "cos", nseel_asm_cos,nseel_asm_cos_end, 1 }, { "tan", nseel_asm_tan,nseel_asm_tan_end, 1 }, #endif { "asin", nseel_asm_1pdd,nseel_asm_1pdd_end, 1, {&asin}, }, { "acos", nseel_asm_1pdd,nseel_asm_1pdd_end, 1, {&acos}, }, { "atan", nseel_asm_1pdd,nseel_asm_1pdd_end, 1, {&atan}, }, { "atan2", nseel_asm_2pdd,nseel_asm_2pdd_end, 2, {&atan2}, }, { "sqr", nseel_asm_sqr,nseel_asm_sqr_end, 1 }, #ifdef __ppc__ { "sqrt", nseel_asm_1pdd,nseel_asm_1pdd_end, 1, {&sqrt}, }, #else { "sqrt", nseel_asm_sqrt,nseel_asm_sqrt_end, 1 }, #endif { "pow", nseel_asm_2pdd,nseel_asm_2pdd_end, 2, {&pow}, }, { "_powop", nseel_asm_2pdds,nseel_asm_2pdds_end, 2, {&pow}, }, { "exp", nseel_asm_1pdd,nseel_asm_1pdd_end, 1, {&exp}, }, #ifdef __ppc__ { "log", nseel_asm_1pdd,nseel_asm_1pdd_end, 1, {&log} }, { "log10", nseel_asm_1pdd,nseel_asm_1pdd_end, 1, {&log10} }, #else { "log", nseel_asm_log,nseel_asm_log_end, 1, }, { "log10", nseel_asm_log10,nseel_asm_log10_end, 1, }, #endif { "abs", nseel_asm_abs,nseel_asm_abs_end, 1 }, { "min", nseel_asm_min,nseel_asm_min_end, 2 }, { "max", nseel_asm_max,nseel_asm_max_end, 2 }, #ifdef __ppc__ { "sign", nseel_asm_sign,nseel_asm_sign_end, 1, {&eel_zero}} , #else { "sign", nseel_asm_sign,nseel_asm_sign_end, 1, {&g_signs}} , #endif { "rand", nseel_asm_1pp,nseel_asm_1pp_end, 1, {&nseel_int_rand}, } , //#if defined(_MSC_VER) && _MSC_VER >= 1400 // { "floor", nseel_asm_1pdd,nseel_asm_1pdd_end, 1, {&__floor} }, //#else // { "floor", nseel_asm_1pdd,nseel_asm_1pdd_end, 1, {&floor} }, //#endif { "ceil", nseel_asm_1pdd,nseel_asm_1pdd_end, 1, {&ceil} }, #ifdef __ppc__ { "invsqrt", nseel_asm_invsqrt,nseel_asm_invsqrt_end, 1, }, #else { "invsqrt", nseel_asm_invsqrt,nseel_asm_invsqrt_end, 1, {&negativezeropointfive, &onepointfive} }, #endif { "sigmoid", nseel_asm_2pdd,nseel_asm_2pdd_end, 2, {&eel1sigmoid}, }, // these differ from _and/_or, they always evaluate both... { "band", nseel_asm_2pdd,nseel_asm_2pdd_end, 2, {&eel1band}, }, { "bor", nseel_asm_2pdd,nseel_asm_2pdd_end, 2, {&eel1bor}, }, {"exec2",nseel_asm_exec2,nseel_asm_exec2_end,2}, {"exec3",nseel_asm_exec2,nseel_asm_exec2_end,3}, {"_mem",_asm_megabuf,_asm_megabuf_end,1,{&g_closefact,&__NSEEL_RAMAlloc},NSEEL_PProc_RAM}, {"_gmem",_asm_megabuf,_asm_megabuf_end,1,{&g_closefact,&__NSEEL_RAMAllocGMEM},NSEEL_PProc_GRAM}, {"freembuf",_asm_generic1parm,_asm_generic1parm_end,1,{&__NSEEL_RAM_MemFree},NSEEL_PProc_RAM}, {"memcpy",_asm_generic3parm,_asm_generic3parm_end,3,{&__NSEEL_RAM_MemCpy},NSEEL_PProc_RAM}, {"memset",_asm_generic3parm,_asm_generic3parm_end,3,{&__NSEEL_RAM_MemSet},NSEEL_PProc_RAM}, }; static functionType *fnTableUser; static int fnTableUser_size; functionType *nseel_getFunctionFromTable(int idx) { if (idx<0) return 0; if (idx>=sizeof(fnTable1)/sizeof(fnTable1[0])) { idx -= sizeof(fnTable1)/sizeof(fnTable1[0]); if (!fnTableUser || idx >= fnTableUser_size) return 0; return fnTableUser+idx; } return fnTable1+idx; } int NSEEL_init() // returns 0 on success { NSEEL_quit(); return 0; } void NSEEL_addfunctionex2(const char *name, int nparms, char *code_startaddr, int code_len, void *pproc, void *fptr, void *fptr2) { if (!fnTableUser || !(fnTableUser_size&7)) { fnTableUser=(functionType *)realloc(fnTableUser,(fnTableUser_size+8)*sizeof(functionType)); } if (fnTableUser) { memset(&fnTableUser[fnTableUser_size],0,sizeof(functionType)); fnTableUser[fnTableUser_size].nParams = nparms; fnTableUser[fnTableUser_size].name = name; fnTableUser[fnTableUser_size].afunc = code_startaddr; fnTableUser[fnTableUser_size].func_e = code_startaddr + code_len; fnTableUser[fnTableUser_size].pProc = (NSEEL_PPPROC) pproc; fnTableUser[fnTableUser_size].replptrs[0]=fptr; fnTableUser[fnTableUser_size].replptrs[1]=fptr2; fnTableUser_size++; } } void NSEEL_quit() { free(fnTableUser); fnTableUser_size=0; fnTableUser=0; } //--------------------------------------------------------------------------------------------------------------- static void freeBlocks(llBlock **start) { llBlock *s=*start; *start=0; while (s) { llBlock *llB = s->next; #ifdef _WIN32 VirtualFree(s, 0 /*LLB_DSIZE*/, MEM_RELEASE); #else free(s); #endif s=llB; } } //--------------------------------------------------------------------------------------------------------------- static void *__newBlock(llBlock **start, int size) { llBlock *llb; int alloc_size; if (*start && (LLB_DSIZE - (*start)->sizeused) >= size) { void *t=(*start)->block+(*start)->sizeused; (*start)->sizeused+=(size+7)&~7; return t; } alloc_size=sizeof(llBlock); if ((int)size > LLB_DSIZE) alloc_size += size - LLB_DSIZE; #ifdef _WIN32 llb = (llBlock *)VirtualAlloc(NULL, alloc_size, MEM_COMMIT, PAGE_EXECUTE_READWRITE); #else llb = (llBlock *)malloc(alloc_size); // grab bigger block if absolutely necessary (heh) #endif #if defined(EEL_USE_MPROTECT) { static int pagesize = 0; if (!pagesize) { pagesize=sysconf(_SC_PAGESIZE); if (!pagesize) pagesize=4096; } uintptr_t offs,eoffs; offs=((uintptr_t)llb)&~(pagesize-1); eoffs=((uintptr_t)llb + alloc_size + pagesize-1)&~(pagesize-1); mprotect((void*)offs,eoffs-offs,PROT_WRITE|PROT_READ|PROT_EXEC); } #endif llb->sizeused=(size+7)&~7; llb->next = *start; *start = llb; return llb->block; } //--------------------------------------------------------------------------------------------------------------- INT_PTR nseel_createCompiledValue(compileContext *ctx, EEL_F value, EEL_F *addrValue) { unsigned char *block; block=(unsigned char *)newTmpBlock(GLUE_MOV_EAX_DIRECTVALUE_SIZE); if (addrValue == NULL) { *(addrValue = (EEL_F *)newBlock(sizeof(EEL_F),sizeof(EEL_F))) = value; ctx->l_stats[3]+=sizeof(EEL_F); } GLUE_MOV_EAX_DIRECTVALUE_GEN(block+4,(INT_PTR)addrValue); return ((INT_PTR)(block)); } //--------------------------------------------------------------------------------------------------------------- static void *nseel_getFunctionAddress(int fntype, int fn, int *size, NSEEL_PPPROC *pProc, void ***replList) { *replList=0; switch (fntype) { case MATH_SIMPLE: switch (fn) { case FN_ASSIGN: return GLUE_realAddress(nseel_asm_assign,nseel_asm_assign_end,size); case FN_ADD: return GLUE_realAddress(nseel_asm_add,nseel_asm_add_end,size); case FN_SUB: return GLUE_realAddress(nseel_asm_sub,nseel_asm_sub_end,size); case FN_MULTIPLY: return GLUE_realAddress(nseel_asm_mul,nseel_asm_mul_end,size); case FN_DIVIDE: return GLUE_realAddress(nseel_asm_div,nseel_asm_div_end,size); case FN_MODULO: return GLUE_realAddress(nseel_asm_exec2,nseel_asm_exec2_end,size); case FN_AND: return GLUE_realAddress(nseel_asm_and,nseel_asm_and_end,size); case FN_OR: return GLUE_realAddress(nseel_asm_or,nseel_asm_or_end,size); case FN_UPLUS: return GLUE_realAddress(nseel_asm_uplus,nseel_asm_uplus_end,size); case FN_UMINUS: return GLUE_realAddress(nseel_asm_uminus,nseel_asm_uminus_end,size); } case MATH_FN: { functionType *p=nseel_getFunctionFromTable(fn); if (p) { *replList=p->replptrs; *pProc=p->pProc; return GLUE_realAddress(p->afunc,p->func_e,size); } } } *size=0; return 0; } //--------------------------------------------------------------------------------------------------------------- INT_PTR nseel_createCompiledFunction3(compileContext *ctx, int fntype, INT_PTR fn, INT_PTR code1, INT_PTR code2, INT_PTR code3) { int sizes1=((int *)code1)[0]; int sizes2=((int *)code2)[0]; int sizes3=((int *)code3)[0]; if (fntype == MATH_FN && fn == 0) // special case: IF { void *func3; int size; INT_PTR *ptr; char *block; unsigned char *newblock2,*newblock3; unsigned char *p; p=newblock2=newBlock(sizes2+sizeof(GLUE_RET)+GLUE_FUNC_ENTER_SIZE+GLUE_FUNC_LEAVE_SIZE,32); memcpy(p,&GLUE_FUNC_ENTER,GLUE_FUNC_ENTER_SIZE); p+=GLUE_FUNC_ENTER_SIZE; memcpy(p,(char*)code2+4,sizes2); p+=sizes2; memcpy(p,&GLUE_FUNC_LEAVE,GLUE_FUNC_LEAVE_SIZE); p+=GLUE_FUNC_LEAVE_SIZE; memcpy(p,&GLUE_RET,sizeof(GLUE_RET)); p+=sizeof(GLUE_RET); p=newblock3=newBlock(sizes3+sizeof(GLUE_RET)+GLUE_FUNC_ENTER_SIZE+GLUE_FUNC_LEAVE_SIZE,32); memcpy(p,&GLUE_FUNC_ENTER,GLUE_FUNC_ENTER_SIZE); p+=GLUE_FUNC_ENTER_SIZE; memcpy(p,(char*)code3+4,sizes3); p+=sizes3; memcpy(p,&GLUE_FUNC_LEAVE,GLUE_FUNC_LEAVE_SIZE); p+=GLUE_FUNC_LEAVE_SIZE; memcpy(p,&GLUE_RET,sizeof(GLUE_RET)); p+=sizeof(GLUE_RET); ctx->l_stats[2]+=sizes2+sizes3+sizeof(GLUE_RET)*2; func3 = GLUE_realAddress(nseel_asm_if,nseel_asm_if_end,&size); block=(char *)newTmpBlock(sizes1+size); memcpy(block+4,(char*)code1+4,sizes1); ptr=(INT_PTR *)(block+4+sizes1); memcpy(ptr,func3,size); ptr=EEL_GLUE_set_immediate(ptr,&g_closefact); ptr=EEL_GLUE_set_immediate(ptr,newblock2); EEL_GLUE_set_immediate(ptr,newblock3); ctx->computTableTop++; return (INT_PTR)block; } else { int size2; unsigned char *block; unsigned char *outp; void *myfunc; NSEEL_PPPROC preProc=0; void **repl; myfunc = nseel_getFunctionAddress(fntype, fn, &size2, &preProc,&repl); block=(unsigned char *)newTmpBlock(size2+sizes1+sizes2+sizes3+ sizeof(GLUE_PUSH_EAX) + sizeof(GLUE_PUSH_EAX) + sizeof(GLUE_POP_EBX) + sizeof(GLUE_POP_ECX)); outp=block+4; memcpy(outp,(char*)code1+4,sizes1); outp+=sizes1; memcpy(outp,&GLUE_PUSH_EAX,sizeof(GLUE_PUSH_EAX)); outp+=sizeof(GLUE_PUSH_EAX); memcpy(outp,(char*)code2+4,sizes2); outp+=sizes2; memcpy(outp,&GLUE_PUSH_EAX,sizeof(GLUE_PUSH_EAX)); outp+=sizeof(GLUE_PUSH_EAX); memcpy(outp,(char*)code3+4,sizes3); outp+=sizes3; memcpy(outp,&GLUE_POP_EBX,sizeof(GLUE_POP_EBX)); outp+=sizeof(GLUE_POP_EBX); memcpy(outp,&GLUE_POP_ECX,sizeof(GLUE_POP_ECX)); outp+=sizeof(GLUE_POP_ECX); memcpy(outp,myfunc,size2); if (preProc) preProc(outp,size2,ctx); if (repl) { if (repl[0]) outp=(unsigned char *)EEL_GLUE_set_immediate(outp,repl[0]); if (repl[1]) outp=(unsigned char *)EEL_GLUE_set_immediate(outp,repl[1]); if (repl[2]) outp=(unsigned char *)EEL_GLUE_set_immediate(outp,repl[2]); if (repl[3]) outp=(unsigned char *)EEL_GLUE_set_immediate(outp,repl[3]); } ctx->computTableTop++; return ((INT_PTR)(block)); } } //--------------------------------------------------------------------------------------------------------------- INT_PTR nseel_createCompiledFunction2(compileContext *ctx, int fntype, INT_PTR fn, INT_PTR code1, INT_PTR code2) { int size2; unsigned char *outp; void *myfunc; int sizes1=((int *)code1)[0]; int sizes2=((int *)code2)[0]; if (fntype == MATH_FN && (fn == 1 || fn == 2 || fn == 3)) // special case: LOOP/BOR/BAND { void *func3; int size; INT_PTR *ptr; char *block; unsigned char *newblock2, *p; p=newblock2=newBlock(sizes2+sizeof(GLUE_RET)+GLUE_FUNC_ENTER_SIZE+GLUE_FUNC_LEAVE_SIZE,32); memcpy(p,&GLUE_FUNC_ENTER,GLUE_FUNC_ENTER_SIZE); p+=GLUE_FUNC_ENTER_SIZE; memcpy(p,(char*)code2+4,sizes2); p+=sizes2; memcpy(p,&GLUE_FUNC_LEAVE,GLUE_FUNC_LEAVE_SIZE); p+=GLUE_FUNC_LEAVE_SIZE; memcpy(p,&GLUE_RET,sizeof(GLUE_RET)); p+=sizeof(GLUE_RET); ctx->l_stats[2]+=sizes2+2; if (fn == 1) func3 = GLUE_realAddress(nseel_asm_band,nseel_asm_band_end,&size); else if (fn == 3) func3 = GLUE_realAddress(nseel_asm_repeat,nseel_asm_repeat_end,&size); else func3 = GLUE_realAddress(nseel_asm_bor,nseel_asm_bor_end,&size); block=(char *)newTmpBlock(sizes1+size); memcpy(block+4,(char*)code1+4,sizes1); ptr=(INT_PTR *)(block+4+sizes1); memcpy(ptr,func3,size); if (fn!=3) ptr=EEL_GLUE_set_immediate(ptr,&g_closefact); // for or/and ptr=EEL_GLUE_set_immediate(ptr,newblock2); if (fn!=3) ptr=EEL_GLUE_set_immediate(ptr,&g_closefact); // for or/and #ifdef __ppc__ if (fn!=3) // for or/and on ppc we need a one { ptr=EEL_GLUE_set_immediate(ptr,&eel_one); } #endif ctx->computTableTop++; return (INT_PTR)block; } { NSEEL_PPPROC preProc=0; unsigned char *block; void **repl; myfunc = nseel_getFunctionAddress(fntype, fn, &size2,&preProc,&repl); block=(unsigned char *)newTmpBlock(size2+sizes1+sizes2+sizeof(GLUE_PUSH_EAX)+sizeof(GLUE_POP_EBX)); outp=block+4; memcpy(outp,(char*)code1+4,sizes1); outp+=sizes1; memcpy(outp,&GLUE_PUSH_EAX,sizeof(GLUE_PUSH_EAX)); outp+=sizeof(GLUE_PUSH_EAX); memcpy(outp,(char*)code2+4,sizes2); outp+=sizes2; memcpy(outp,&GLUE_POP_EBX,sizeof(GLUE_POP_EBX)); outp+=sizeof(GLUE_POP_EBX); memcpy(outp,myfunc,size2); if (preProc) preProc(outp,size2,ctx); if (repl) { if (repl[0]) outp=(unsigned char *)EEL_GLUE_set_immediate(outp,repl[0]); if (repl[1]) outp=(unsigned char *)EEL_GLUE_set_immediate(outp,repl[1]); if (repl[2]) outp=(unsigned char *)EEL_GLUE_set_immediate(outp,repl[2]); if (repl[3]) outp=(unsigned char *)EEL_GLUE_set_immediate(outp,repl[3]); } ctx->computTableTop++; return ((INT_PTR)(block)); } } //--------------------------------------------------------------------------------------------------------------- INT_PTR nseel_createCompiledFunction1(compileContext *ctx, int fntype, INT_PTR fn, INT_PTR code) { NSEEL_PPPROC preProc=0; int size,size2; char *block; void *myfunc; void *func1; size =((int *)code)[0]; func1 = (void *)(code+4); if (fntype == MATH_FN && fn == 4) // special case: while { void *func3; INT_PTR *ptr; unsigned char *newblock2, *p; p=newblock2=newBlock(size+sizeof(GLUE_RET)+GLUE_FUNC_ENTER_SIZE+GLUE_FUNC_LEAVE_SIZE,32); memcpy(p,&GLUE_FUNC_ENTER,GLUE_FUNC_ENTER_SIZE); p+=GLUE_FUNC_ENTER_SIZE; memcpy(p,func1,size); p+=size; memcpy(p,&GLUE_FUNC_LEAVE,GLUE_FUNC_LEAVE_SIZE); p+=GLUE_FUNC_LEAVE_SIZE; memcpy(p,&GLUE_RET,sizeof(GLUE_RET)); p+=sizeof(GLUE_RET); ctx->l_stats[2]+=size+2; func3 = GLUE_realAddress(nseel_asm_repeatwhile,nseel_asm_repeatwhile_end,&size); block=(char *)newTmpBlock(size); ptr = (INT_PTR *)(block+4); memcpy(ptr,func3,size); ptr=EEL_GLUE_set_immediate(ptr,newblock2); EEL_GLUE_set_immediate(ptr,&g_closefact); ctx->computTableTop++; return (INT_PTR)block; } { void **repl; myfunc = nseel_getFunctionAddress(fntype, fn, &size2,&preProc,&repl); block=(char *)newTmpBlock(size+size2); memcpy(block+4, func1, size); memcpy(block+size+4,myfunc,size2); if (preProc) preProc(block+size+4,size2,ctx); if (repl) { unsigned char *outp=(unsigned char *)block+size+4; if (repl[0]) outp=(unsigned char *)EEL_GLUE_set_immediate(outp,repl[0]); if (repl[1]) outp=(unsigned char *)EEL_GLUE_set_immediate(outp,repl[1]); if (repl[2]) outp=(unsigned char *)EEL_GLUE_set_immediate(outp,repl[2]); if (repl[3]) outp=(unsigned char *)EEL_GLUE_set_immediate(outp,repl[3]); } ctx->computTableTop++; return ((INT_PTR)(block)); } } static char *preprocessCode(compileContext *ctx, char *expression) { char *expression_start=expression; int len=0; int alloc_len=strlen(expression)+1+64; char *buf=(char *)malloc(alloc_len); int semicnt=0; // we need to call onCompileNewLine for each new line we get //onCompileNewLine(ctx, while (*expression) { if (len > alloc_len-64) { alloc_len = len+128; buf=(char*)realloc(buf,alloc_len); } if (expression[0] == '/') { if (expression[1] == '/') { expression+=2; while (expression[0] && expression[0] != '\n') expression++; continue; } else if (expression[1] == '*') { expression+=2; while (expression[0] && (expression[0] != '*' || expression[1] != '/')) { if (expression[0] == '\n') onCompileNewLine(ctx,expression+1-expression_start,len); expression++; } if (expression[0]) expression+=2; // at this point we KNOW expression[0]=* and expression[1]=/ continue; } } if (expression[0] == '$') { if (toupper(expression[1]) == 'X') { char *p=expression+2; unsigned int v=strtoul(expression+2,&p,16); char tmp[64]; expression=p; sprintf(tmp,"%u",v); memcpy(buf+len,tmp,strlen(tmp)); len+=strlen(tmp); ctx->l_stats[0]+=strlen(tmp); continue; } if (expression[1]=='\'' && expression[2] && expression[3]=='\'') { char tmp[64]; sprintf(tmp,"%u",((unsigned char *)expression)[2]); expression+=4; memcpy(buf+len,tmp,strlen(tmp)); len+=strlen(tmp); ctx->l_stats[0]+=strlen(tmp); continue; } if (toupper(expression[1]) == 'P' && toupper(expression[2]) == 'I') { static char *str="3.141592653589793"; expression+=3; memcpy(buf+len,str,17); len+=17; //strlen(str); ctx->l_stats[0]+=17; continue; } if (toupper(expression[1]) == 'E') { static char *str="2.71828183"; expression+=2; memcpy(buf+len,str,10); len+=10; //strlen(str); ctx->l_stats[0]+=10; continue; } if (toupper(expression[1]) == 'P' && toupper(expression[2]) == 'H' && toupper(expression[3]) == 'I') { static char *str="1.61803399"; expression+=4; memcpy(buf+len,str,10); len+=10; //strlen(str); ctx->l_stats[0]+=10; continue; } } { char c=*expression++; if (c == '\n') onCompileNewLine(ctx,expression-expression_start,len); if (isspace(c)) c=' '; if (c == '(') semicnt++; else if (c == ')') { semicnt--; if (semicnt < 0) semicnt=0; } else if (c == ';' && semicnt > 0) { // convert ; to % if next nonwhitespace char is alnum, otherwise convert to space int p=0; int nc; int commentstate=0; while ((nc=expression[p])) { if (!commentstate && nc == '/') { if (expression[p+1] == '/') commentstate=1; else if (expression[p+1] == '*') commentstate=2; } if (commentstate == 1 && nc == '\n') commentstate=0; else if (commentstate == 2 && nc == '*' && expression[p+1]=='/') { p++; // skip * commentstate=0; } else if (!commentstate && !isspace(nc)) break; p++; } // fucko, we should look for even more chars, me thinks if (nc && (isalnum(nc) #if 1 || nc == '(' || nc == '_' || nc == '!' || nc == '$' #endif )) c='%'; else c = ' '; // stray ; } #if 0 else if (semicnt > 0 && c == ',') { int p=0; int nc; while ((nc=expression[p]) && isspace(nc)) p++; if (nc == ',' || nc == ')') { expression += p+1; buf[len++]=','; buf[len++]='0'; c=nc; // append this char } } #endif // list of operators else if (!isspace(c) && !isalnum(c)) // check to see if this operator is ours { static char *symbollists[]= { "", // or any control char that is not parenthed ":(,;?%", ",):?;", // or || or && ",);", // jf> removed :? from this, for = ",);", "", // only scans for a negative ] level }; static struct { char op[2]; char lscan,rscan; char *func; } preprocSymbols[] = { {{'+','='}, 0, 3, "_addop" }, {{'-','='}, 0, 3, "_subop" }, {{'%','='}, 0, 3, "_modop" }, {{'|','='}, 0, 3, "_orop" }, {{'&','='}, 0, 3, "_andop"}, {{'/','='}, 0, 3, "_divop"}, {{'*','='}, 0, 3, "_mulop"}, {{'^','='}, 0, 3, "_powop"}, {{'=','='}, 1, 2, "_equal" }, {{'<','='}, 1, 2, "_beleq" }, {{'>','='}, 1, 2, "_aboeq" }, {{'<',0 }, 1, 2, "_below" }, {{'>',0 }, 1, 2, "_above" }, {{'!','='}, 1, 2, "_noteq" }, {{'|','|'}, 1, 2, "_or" }, {{'&','&'}, 1, 2, "_and" }, {{'=',0 }, 0, 3, "_set" }, {{'%',0}, 0, 0, "_mod" }, {{'^',0}, 0, 0, "pow" }, {{'[',0 }, 0, 5, }, {{'!',0 },-1, 0, }, // this should also ignore any leading +- {{'?',0 }, 1, 4, }, }; int n; int ns=sizeof(preprocSymbols)/sizeof(preprocSymbols[0]); for (n = 0; n < ns; n++) { if (c == preprocSymbols[n].op[0] && (!preprocSymbols[n].op[1] || expression[0] == preprocSymbols[n].op[1])) { break; } } if (n < ns) { int lscan=preprocSymbols[n].lscan; int rscan=preprocSymbols[n].rscan; // parse left side of =, scanning back for an unparenthed nonwhitespace nonalphanumeric nonparenth? // so megabuf(x+y)= would be fine, x=, but +x= would do +set(x,) char *l_ptr=0; char *r_ptr=0; if (lscan >= 0) { char *scan=symbollists[lscan]; int l_semicnt=0; l_ptr=buf + len - 1; while (l_ptr >= buf) { if (*l_ptr == ')') l_semicnt++; else if (*l_ptr == '(') { l_semicnt--; if (l_semicnt < 0) break; } else if (!l_semicnt) { if (!*scan) { if (!isspace(*l_ptr) && !isalnum(*l_ptr) && *l_ptr != '_' && *l_ptr != '.') break; } else { char *sc=scan; if (lscan == 2 && ( // not currently used, even (l_ptr[0]=='|' && l_ptr[1] == '|')|| (l_ptr[0]=='&' && l_ptr[1] == '&') ) ) break; while (*sc && *l_ptr != *sc) sc++; if (*sc) break; } } l_ptr--; } buf[len]=0; l_ptr++; len = l_ptr - buf; l_ptr = strdup(l_ptr); // doesn't need to be preprocessed since it just was } if (preprocSymbols[n].op[1]) expression++; r_ptr=expression; { // scan forward to an uncommented, unparenthed semicolon, comma, or ) int r_semicnt=0; int r_qcnt=0; char *scan=symbollists[rscan]; int commentstate=0; int hashadch=0; int bracketcnt=0; while (*r_ptr) { if (!commentstate && *r_ptr == '/') { if (r_ptr[1] == '/') commentstate=1; else if (r_ptr[1] == '*') commentstate=2; } if (commentstate == 1 && *r_ptr == '\n') commentstate=0; else if (commentstate == 2 && *r_ptr == '*' && r_ptr[1]=='/') { r_ptr++; // skip * commentstate=0; } else if (!commentstate) { if (*r_ptr == '(') {hashadch=1; r_semicnt++; } else if (*r_ptr == ')') { r_semicnt--; if (r_semicnt < 0) break; } else if (!r_semicnt) { char *sc=scan; if (*r_ptr == ';' || *r_ptr == ',') break; if (!rscan) { if (*r_ptr == ':') break; if (!isspace(*r_ptr) && !isalnum(*r_ptr) && *r_ptr != '_' && *r_ptr != '.' && hashadch) break; if (isalnum(*r_ptr) || *r_ptr == '_')hashadch=1; } else if (rscan == 2 && ((r_ptr[0]=='|' && r_ptr[1] == '|')|| (r_ptr[0]=='&' && r_ptr[1] == '&') ) ) break; else if (rscan == 3 || rscan == 4) { if (*r_ptr == ':') r_qcnt--; else if (*r_ptr == '?') r_qcnt++; if (r_qcnt < 3-rscan) break; } else if (rscan == 5) { if (*r_ptr == '[') bracketcnt++; else if (*r_ptr == ']') bracketcnt--; if (bracketcnt < 0) break; } while (*sc && *r_ptr != *sc) sc++; if (*sc) break; } } r_ptr++; } // expression -> r_ptr is our string (not including r_ptr) { char *orp=r_ptr; char rps=*orp; *orp=0; // temporarily terminate r_ptr=preprocessCode(ctx,expression); expression=orp; *orp = rps; // fix termination(restore string) } } if (r_ptr) { int thisl = strlen(l_ptr?l_ptr:"") + strlen(r_ptr) + 32; if (len+thisl > alloc_len-64) { alloc_len = len+thisl+128; buf=(char*)realloc(buf,alloc_len); } if (n == ns-3) { char *lp = l_ptr; char *rp = r_ptr; while (lp && *lp && isspace(*lp)) lp++; while (rp && *rp && isspace(*rp)) rp++; if (lp && !strncasecmp(lp,"gmem",4) && (!lp[4] || isspace(lp[4]))) { len+=sprintf(buf+len,"_gmem(%s",r_ptr && *r_ptr ? r_ptr : "0"); ctx->l_stats[0]+=strlen(l_ptr)+4; } else if (rp && *rp && strcmp(rp,"0")) { len+=sprintf(buf+len,"_mem((%s)+(%s)",lp,rp); ctx->l_stats[0]+=strlen(lp)+strlen(rp)+8; } else { len+=sprintf(buf+len,"_mem(%s",lp); ctx->l_stats[0]+=strlen(lp)+4; } // skip the ] if (*expression == ']') expression++; } else if (n == ns-2) { len+=sprintf(buf+len,"_not(%s", r_ptr); ctx->l_stats[0]+=4; } else if (n == ns-1)// if (l_ptr,r_ptr1,r_ptr2) { char *rptr2=r_ptr; char *tmp=r_ptr; int parcnt=0; int qcnt=1; while (*rptr2) { if (*rptr2 == '?') qcnt++; else if (*rptr2 == ':') qcnt--; else if (*rptr2 == '(') parcnt++; else if (*rptr2 == ')') parcnt--; if (parcnt < 0) break; if (!parcnt && !qcnt && *rptr2 == ':') break; rptr2++; } if (*rptr2) *rptr2++=0; while (isspace(*rptr2)) rptr2++; while (isspace(*tmp)) tmp++; len+=sprintf(buf+len,"_if(%s,%s,%s",l_ptr,*tmp?tmp:"0",*rptr2?rptr2:"0"); ctx->l_stats[0]+=6; } else { len+=sprintf(buf+len,"%s(%s,%s",preprocSymbols[n].func,l_ptr?l_ptr:"",r_ptr); ctx->l_stats[0]+=strlen(preprocSymbols[n].func)+2; } } free(r_ptr); free(l_ptr); c = ')'; // close parenth below } } // if (c != ' ' || (len && buf[len-1] != ' ')) // don't bother adding multiple spaces { buf[len++]=c; if (c != ' ') ctx->l_stats[0]++; } } } buf[len]=0; return buf; } #ifdef PPROC_TEST int main(int argc, char* argv[]) { compileContext ctx={0}; char *p=preprocessCode(&ctx,argv[1]); if (p)printf("%s\n",p); free(p); return 0; } #endif #if 0 static void movestringover(char *str, int amount) { char tmp[1024+8]; int l=(int)strlen(str); l=min(1024-amount-1,l); memcpy(tmp,str,l+1); while (l >= 0 && tmp[l]!='\n') l--; l++; tmp[l]=0;//ensure we null terminate memcpy(str+amount,tmp,l+1); } #endif //------------------------------------------------------------------------------ NSEEL_CODEHANDLE NSEEL_code_compile(NSEEL_VMCTX _ctx, char *_expression, int lineoffs) { compileContext *ctx = (compileContext *)_ctx; char *expression,*expression_start; int computable_size=0; codeHandleType *handle; startPtr *scode=NULL; startPtr *startpts=NULL; if (!ctx) return 0; ctx->last_error_string[0]=0; if (!_expression || !*_expression) return 0; freeBlocks((llBlock **)&ctx->tmpblocks_head); // free blocks freeBlocks((llBlock **)&ctx->blocks_head); // free blocks memset(ctx->l_stats,0,sizeof(ctx->l_stats)); free(ctx->compileLineRecs); ctx->compileLineRecs=0; ctx->compileLineRecs_size=0; ctx->compileLineRecs_alloc=0; handle = (codeHandleType*)newBlock(sizeof(codeHandleType),8); if (!handle) { return 0; } memset(handle,0,sizeof(codeHandleType)); expression_start=expression=preprocessCode(ctx,_expression); while (*expression) { void *startptr; char *expr; ctx->colCount=0; ctx->computTableTop=0; // single out segment while (*expression == ';' || isspace(*expression)) expression++; if (!*expression) break; expr=expression; while (*expression && *expression != ';') expression++; if (*expression) *expression++ = 0; // parse startptr=nseel_compileExpression(ctx,expr); if (ctx->computTableTop > NSEEL_MAX_TEMPSPACE_ENTRIES- /* safety */ 16 - /* alignment */4 || !startptr) { int byteoffs = expr - expression_start; int destoffs,linenumber; char buf[21], *p; int x,le; #ifdef NSEEL_EEL1_COMPAT_MODE if (!startptr) continue; #endif if (ctx->errVar > 0) byteoffs += ctx->errVar; linenumber=findByteOffsetInSource(ctx,byteoffs,&destoffs); if (destoffs < 0) destoffs=0; le=strlen(_expression); if (destoffs >= le) destoffs=le; p= _expression + destoffs; for (x = 0;x < 20; x ++) { if (!*p || *p == '\r' || *p == '\n') break; buf[x]=*p++; } buf[x]=0; sprintf(ctx->last_error_string,"Around line %d '%s'",linenumber+lineoffs,buf); ctx->last_error_string[sizeof(ctx->last_error_string)-1]=0; scode=NULL; break; } if (computable_size < ctx->computTableTop) { computable_size=ctx->computTableTop; } { startPtr *tmp=(startPtr*) __newBlock((llBlock **)&ctx->tmpblocks_head,sizeof(startPtr)); if (!tmp) break; tmp->startptr = startptr; tmp->next=NULL; if (!scode) scode=startpts=tmp; else { scode->next=tmp; scode=tmp; } } } free(ctx->compileLineRecs); ctx->compileLineRecs=0; ctx->compileLineRecs_size=0; ctx->compileLineRecs_alloc=0; // check to see if failed on the first startingCode if (!scode) { handle=NULL; // return NULL (after resetting blocks_head) } else { char *tabptr = (char *)(handle->workTable=calloc(computable_size+64, sizeof(EEL_F))); unsigned char *writeptr; startPtr *p=startpts; int size=sizeof(GLUE_RET)+GLUE_FUNC_ENTER_SIZE+GLUE_FUNC_LEAVE_SIZE; // for ret at end :) if (((INT_PTR)tabptr)&31) tabptr += 32-(((INT_PTR)tabptr)&31); // now we build one big code segment out of our list of them, inserting a mov esi, computable before each item while (p) { size += GLUE_RESET_ESI(NULL,0); size+=*(int *)p->startptr; p=p->next; } handle->code = newBlock(size,32); if (handle->code) { writeptr=(unsigned char *)handle->code; memcpy(writeptr,&GLUE_FUNC_ENTER,GLUE_FUNC_ENTER_SIZE); writeptr += GLUE_FUNC_ENTER_SIZE; p=startpts; while (p) { int thissize=*(int *)p->startptr; writeptr+=GLUE_RESET_ESI(writeptr,tabptr); //memcpy(writeptr,&GLUE_MOV_ESI_EDI,sizeof(GLUE_MOV_ESI_EDI)); //writeptr+=sizeof(GLUE_MOV_ESI_EDI); memcpy(writeptr,(char*)p->startptr + 4,thissize); writeptr += thissize; p=p->next; } memcpy(writeptr,&GLUE_FUNC_LEAVE,GLUE_FUNC_LEAVE_SIZE); writeptr += GLUE_FUNC_LEAVE_SIZE; memcpy(writeptr,&GLUE_RET,sizeof(GLUE_RET)); writeptr += sizeof(GLUE_RET); ctx->l_stats[1]=size; } handle->blocks = ctx->blocks_head; ctx->blocks_head=0; } freeBlocks((llBlock **)&ctx->tmpblocks_head); // free blocks freeBlocks((llBlock **)&ctx->blocks_head); // free blocks if (handle) { memcpy(handle->code_stats,ctx->l_stats,sizeof(ctx->l_stats)); nseel_evallib_stats[0]+=ctx->l_stats[0]; nseel_evallib_stats[1]+=ctx->l_stats[1]; nseel_evallib_stats[2]+=ctx->l_stats[2]; nseel_evallib_stats[3]+=ctx->l_stats[3]; nseel_evallib_stats[4]++; } memset(ctx->l_stats,0,sizeof(ctx->l_stats)); free(expression_start); return (NSEEL_CODEHANDLE)handle; } //------------------------------------------------------------------------------ void NSEEL_code_execute(NSEEL_CODEHANDLE code) { INT_PTR tabptr; INT_PTR codeptr; codeHandleType *h = (codeHandleType *)code; if (!h || !h->code) return; codeptr = (INT_PTR) h->code; #if 0 { unsigned int *p=(unsigned int *)codeptr; while (*p != GLUE_RET[0]) { printf("instr:%04X:%04X\n",*p>>16,*p&0xffff); p++; } } #endif tabptr=(INT_PTR)h->workTable; if (tabptr&31) tabptr += 32-((tabptr)&31); //printf("calling code!\n"); GLUE_CALL_CODE(tabptr,codeptr); } char *NSEEL_code_getcodeerror(NSEEL_VMCTX ctx) { compileContext *c=(compileContext *)ctx; if (ctx && c->last_error_string[0]) return c->last_error_string; return 0; } //------------------------------------------------------------------------------ void NSEEL_code_free(NSEEL_CODEHANDLE code) { codeHandleType *h = (codeHandleType *)code; if (h != NULL) { free(h->workTable); nseel_evallib_stats[0]-=h->code_stats[0]; nseel_evallib_stats[1]-=h->code_stats[1]; nseel_evallib_stats[2]-=h->code_stats[2]; nseel_evallib_stats[3]-=h->code_stats[3]; nseel_evallib_stats[4]--; freeBlocks(&h->blocks); } } //------------------------------------------------------------------------------ void NSEEL_VM_resetvars(NSEEL_VMCTX _ctx) { if (_ctx) { compileContext *ctx=(compileContext *)_ctx; int x; if (ctx->varTable_Names || ctx->varTable_Values) for (x = 0; x < ctx->varTable_numBlocks; x ++) { if (ctx->varTable_Names) free(ctx->varTable_Names[x]); if (ctx->varTable_Values) free(ctx->varTable_Values[x]); } free(ctx->varTable_Values); free(ctx->varTable_Names); ctx->varTable_Values=0; ctx->varTable_Names=0; ctx->varTable_numBlocks=0; } } NSEEL_VMCTX NSEEL_VM_alloc() // return a handle { compileContext *ctx=calloc(1,sizeof(compileContext)); return ctx; } void NSEEL_VM_free(NSEEL_VMCTX _ctx) // free when done with a VM and ALL of its code have been freed, as well { if (_ctx) { compileContext *ctx=(compileContext *)_ctx; NSEEL_VM_resetvars(_ctx); NSEEL_VM_freeRAM(_ctx); freeBlocks((llBlock **)&ctx->tmpblocks_head); // free blocks freeBlocks((llBlock **)&ctx->blocks_head); // free blocks free(ctx->compileLineRecs); free(ctx); } } int *NSEEL_code_getstats(NSEEL_CODEHANDLE code) { codeHandleType *h = (codeHandleType *)code; if (h) { return h->code_stats; } return 0; } void NSEEL_VM_SetCustomFuncThis(NSEEL_VMCTX ctx, void *thisptr) { if (ctx) { compileContext *c=(compileContext*)ctx; c->caller_this=thisptr; } } void NSEEL_PProc_RAM(void *data, int data_size, compileContext *ctx) { if (data_size>0) EEL_GLUE_set_immediate(data, &ctx->ram_blocks); } void NSEEL_PProc_THIS(void *data, int data_size, compileContext *ctx) { if (data_size>0) EEL_GLUE_set_immediate(data, ctx->caller_this); }