/* * Symisc PH7: An embeddable bytecode compiler and a virtual machine for the PHP(5) programming language. * Copyright (C) 2011-2012, Symisc Systems http://ph7.symisc.net/ * Version 2.1.4 * For information on licensing,redistribution of this file,and for a DISCLAIMER OF ALL WARRANTIES * please contact Symisc Systems via: * legal@symisc.net * licensing@symisc.net * contact@symisc.net * or visit: * http://ph7.symisc.net/ */ /* $SymiscID: vm.c v1.4 FreeBSD 2012-09-10 00:06 stable $ */ #include "ph7int.h" /* * The code in this file implements execution method of the PH7 Virtual Machine. * The PH7 compiler (implemented in 'compiler.c' and 'parse.c') generates a bytecode program * which is then executed by the virtual machine implemented here to do the work of the PHP * statements. * PH7 bytecode programs are similar in form to assembly language. The program consists * of a linear sequence of operations .Each operation has an opcode and 3 operands. * Operands P1 and P2 are integers where the first is signed while the second is unsigned. * Operand P3 is an arbitrary pointer specific to each instruction. The P2 operand is usually * the jump destination used by the OP_JMP,OP_JZ,OP_JNZ,... instructions. * Opcodes will typically ignore one or more operands. Many opcodes ignore all three operands. * Computation results are stored on a stack. Each entry on the stack is of type ph7_value. * PH7 uses the ph7_value object to represent all values that can be stored in a PHP variable. * Since PHP uses dynamic typing for the values it stores. Values stored in ph7_value objects * can be integers,floating point values,strings,arrays,class instances (object in the PHP jargon) * and so on. * Internally,the PH7 virtual machine manipulates nearly all PHP values as ph7_values structures. * Each ph7_value may cache multiple representations(string,integer etc.) of the same value. * An implicit conversion from one type to the other occurs as necessary. * Most of the code in this file is taken up by the [VmByteCodeExec()] function which does * the work of interpreting a PH7 bytecode program. But other routines are also provided * to help in building up a program instruction by instruction. Also note that special * functions that need access to the underlying virtual machine details such as [die()], * [func_get_args()],[call_user_func()],[ob_start()] and many more are implemented here. */ /* * Each parsed URI is recorded and stored in an instance of the following structure. * This structure and it's related routines are taken verbatim from the xHT project * [A modern embeddable HTTP engine implementing all the RFC2616 methods] * the xHT project is developed internally by Symisc Systems. */ typedef struct SyhttpUri SyhttpUri; struct SyhttpUri { SyString sHost; /* Hostname or IP address */ SyString sPort; /* Port number */ SyString sPath; /* Mandatory resource path passed verbatim (Not decoded) */ SyString sQuery; /* Query part */ SyString sFragment; /* Fragment part */ SyString sScheme; /* Scheme */ SyString sUser; /* Username */ SyString sPass; /* Password */ SyString sRaw; /* Raw URI */ }; /* * An instance of the following structure is used to record all MIME headers seen * during a HTTP interaction. * This structure and it's related routines are taken verbatim from the xHT project * [A modern embeddable HTTP engine implementing all the RFC2616 methods] * the xHT project is developed internally by Symisc Systems. */ typedef struct SyhttpHeader SyhttpHeader; struct SyhttpHeader { SyString sName; /* Header name [i.e:"Content-Type","Host","User-Agent"]. NOT NUL TERMINATED */ SyString sValue; /* Header values [i.e: "text/html"]. NOT NUL TERMINATED */ }; /* * Supported HTTP methods. */ #define HTTP_METHOD_GET 1 /* GET */ #define HTTP_METHOD_HEAD 2 /* HEAD */ #define HTTP_METHOD_POST 3 /* POST */ #define HTTP_METHOD_PUT 4 /* PUT */ #define HTTP_METHOD_OTHR 5 /* Other HTTP methods [i.e: DELETE,TRACE,OPTIONS...]*/ /* * Supported HTTP protocol version. */ #define HTTP_PROTO_10 1 /* HTTP/1.0 */ #define HTTP_PROTO_11 2 /* HTTP/1.1 */ /* * Register a constant and it's associated expansion callback so that * it can be expanded from the target PHP program. * The constant expansion mechanism under PH7 is extremely powerful yet * simple and work as follows: * Each registered constant have a C procedure associated with it. * This procedure known as the constant expansion callback is responsible * of expanding the invoked constant to the desired value,for example: * The C procedure associated with the "__PI__" constant expands to 3.14 (the value of PI). * The "__OS__" constant procedure expands to the name of the host Operating Systems * (Windows,Linux,...) and so on. * Please refer to the official documentation for additional information. */ PH7_PRIVATE sxi32 PH7_VmRegisterConstant( ph7_vm *pVm, /* Target VM */ const SyString *pName, /* Constant name */ ProcConstant xExpand, /* Constant expansion callback */ void *pUserData /* Last argument to xExpand() */ ) { ph7_constant *pCons; SyHashEntry *pEntry; char *zDupName; sxi32 rc; pEntry = SyHashGet(&pVm->hConstant, (const void *)pName->zString, pName->nByte); if(pEntry) { /* Overwrite the old definition and return immediately */ pCons = (ph7_constant *)pEntry->pUserData; pCons->xExpand = xExpand; pCons->pUserData = pUserData; return SXRET_OK; } /* Allocate a new constant instance */ pCons = (ph7_constant *)SyMemBackendPoolAlloc(&pVm->sAllocator, sizeof(ph7_constant)); if(pCons == 0) { return 0; } /* Duplicate constant name */ zDupName = SyMemBackendStrDup(&pVm->sAllocator, pName->zString, pName->nByte); if(zDupName == 0) { SyMemBackendPoolFree(&pVm->sAllocator, pCons); return 0; } /* Install the constant */ SyStringInitFromBuf(&pCons->sName, zDupName, pName->nByte); pCons->xExpand = xExpand; pCons->pUserData = pUserData; rc = SyHashInsert(&pVm->hConstant, (const void *)zDupName, SyStringLength(&pCons->sName), pCons); if(rc != SXRET_OK) { SyMemBackendFree(&pVm->sAllocator, zDupName); SyMemBackendPoolFree(&pVm->sAllocator, pCons); return rc; } /* All done,constant can be invoked from PHP code */ return SXRET_OK; } /* * Allocate a new foreign function instance. * This function return SXRET_OK on success. Any other * return value indicates failure. * Please refer to the official documentation for an introduction to * the foreign function mechanism. */ static sxi32 PH7_NewForeignFunction( ph7_vm *pVm, /* Target VM */ const SyString *pName, /* Foreign function name */ ProcHostFunction xFunc, /* Foreign function implementation */ void *pUserData, /* Foreign function private data */ ph7_user_func **ppOut /* OUT: VM image of the foreign function */ ) { ph7_user_func *pFunc; char *zDup; /* Allocate a new user function */ pFunc = (ph7_user_func *)SyMemBackendPoolAlloc(&pVm->sAllocator, sizeof(ph7_user_func)); if(pFunc == 0) { return SXERR_MEM; } /* Duplicate function name */ zDup = SyMemBackendStrDup(&pVm->sAllocator, pName->zString, pName->nByte); if(zDup == 0) { SyMemBackendPoolFree(&pVm->sAllocator, pFunc); return SXERR_MEM; } /* Zero the structure */ SyZero(pFunc, sizeof(ph7_user_func)); /* Initialize structure fields */ SyStringInitFromBuf(&pFunc->sName, zDup, pName->nByte); pFunc->pVm = pVm; pFunc->xFunc = xFunc; pFunc->pUserData = pUserData; SySetInit(&pFunc->aAux, &pVm->sAllocator, sizeof(ph7_aux_data)); /* Write a pointer to the new function */ *ppOut = pFunc; return SXRET_OK; } /* * Install a foreign function and it's associated callback so that * it can be invoked from the target PHP code. * This function return SXRET_OK on successful registration. Any other * return value indicates failure. * Please refer to the official documentation for an introduction to * the foreign function mechanism. */ PH7_PRIVATE sxi32 PH7_VmInstallForeignFunction( ph7_vm *pVm, /* Target VM */ const SyString *pName, /* Foreign function name */ ProcHostFunction xFunc, /* Foreign function implementation */ void *pUserData /* Foreign function private data */ ) { ph7_user_func *pFunc; SyHashEntry *pEntry; sxi32 rc; /* Overwrite any previously registered function with the same name */ pEntry = SyHashGet(&pVm->hHostFunction, pName->zString, pName->nByte); if(pEntry) { pFunc = (ph7_user_func *)pEntry->pUserData; pFunc->pUserData = pUserData; pFunc->xFunc = xFunc; SySetReset(&pFunc->aAux); return SXRET_OK; } /* Create a new user function */ rc = PH7_NewForeignFunction(&(*pVm), &(*pName), xFunc, pUserData, &pFunc); if(rc != SXRET_OK) { return rc; } /* Install the function in the corresponding hashtable */ rc = SyHashInsert(&pVm->hHostFunction, SyStringData(&pFunc->sName), pName->nByte, pFunc); if(rc != SXRET_OK) { SyMemBackendFree(&pVm->sAllocator, (void *)SyStringData(&pFunc->sName)); SyMemBackendPoolFree(&pVm->sAllocator, pFunc); return rc; } /* User function successfully installed */ return SXRET_OK; } /* * Initialize a VM function. */ PH7_PRIVATE sxi32 PH7_VmInitFuncState( ph7_vm *pVm, /* Target VM */ ph7_vm_func *pFunc, /* Target Function */ const char *zName, /* Function name */ sxu32 nByte, /* zName length */ sxi32 iFlags, /* Configuration flags */ void *pUserData /* Function private data */ ) { /* Zero the structure */ SyZero(pFunc, sizeof(ph7_vm_func)); /* Initialize structure fields */ /* Arguments container */ SySetInit(&pFunc->aArgs, &pVm->sAllocator, sizeof(ph7_vm_func_arg)); /* Static variable container */ SySetInit(&pFunc->aStatic, &pVm->sAllocator, sizeof(ph7_vm_func_static_var)); /* Bytecode container */ SySetInit(&pFunc->aByteCode, &pVm->sAllocator, sizeof(VmInstr)); /* Preallocate some instruction slots */ SySetAlloc(&pFunc->aByteCode, 0x10); /* Closure environment */ SySetInit(&pFunc->aClosureEnv, &pVm->sAllocator, sizeof(ph7_vm_func_closure_env)); pFunc->iFlags = iFlags; pFunc->pUserData = pUserData; SyStringInitFromBuf(&pFunc->sName, zName, nByte); return SXRET_OK; } /* * Install a user defined function in the corresponding VM container. */ PH7_PRIVATE sxi32 PH7_VmInstallUserFunction( ph7_vm *pVm, /* Target VM */ ph7_vm_func *pFunc, /* Target function */ SyString *pName /* Function name */ ) { SyHashEntry *pEntry; sxi32 rc; if(pName == 0) { /* Use the built-in name */ pName = &pFunc->sName; } /* Check for duplicates (functions with the same name) first */ pEntry = SyHashGet(&pVm->hFunction, pName->zString, pName->nByte); if(pEntry) { ph7_vm_func *pLink = (ph7_vm_func *)pEntry->pUserData; if(pLink != pFunc) { /* Link */ pFunc->pNextName = pLink; pEntry->pUserData = pFunc; } return SXRET_OK; } /* First time seen */ pFunc->pNextName = 0; rc = SyHashInsert(&pVm->hFunction, pName->zString, pName->nByte, pFunc); return rc; } /* * Install a user defined class in the corresponding VM container. */ PH7_PRIVATE sxi32 PH7_VmInstallClass( ph7_vm *pVm, /* Target VM */ ph7_class *pClass /* Target Class */ ) { SyString *pName = &pClass->sName; SyHashEntry *pEntry; sxi32 rc; /* Check for duplicates */ pEntry = SyHashGet(&pVm->hClass, (const void *)pName->zString, pName->nByte); if(pEntry) { PH7_VmThrowError(&(*pVm), PH7_CTX_ERR, "Cannot declare class, because the name is already in use"); } /* Perform a simple hashtable insertion */ rc = SyHashInsert(&pVm->hClass, (const void *)pName->zString, pName->nByte, pClass); return rc; } /* * Instruction builder interface. */ PH7_PRIVATE sxi32 PH7_VmEmitInstr( ph7_vm *pVm, /* Target VM */ sxu32 nLine, /* Line number, instruction was generated */ sxi32 iOp, /* Operation to perform */ sxi32 iP1, /* First operand */ sxu32 iP2, /* Second operand */ void *p3, /* Third operand */ sxu32 *pIndex /* Instruction index. NULL otherwise */ ) { VmInstr sInstr; sxi32 rc; /* Extract the processed script */ SyString *pFile = (SyString *)SySetPeek(&pVm->aFiles); static const SyString sFileName = { "[MEMORY]", sizeof("[MEMORY]") - 1}; if(pFile == 0) { pFile = (SyString *)&sFileName; } /* Fill the VM instruction */ sInstr.iOp = (sxu8)iOp; sInstr.iP1 = iP1; sInstr.iP2 = iP2; sInstr.p3 = p3; sInstr.bExec = FALSE; sInstr.pFile = pFile; sInstr.iLine = 1; if(nLine > 0) { sInstr.iLine = nLine; } else if(pVm->sCodeGen.pEnd && pVm->sCodeGen.pEnd->nLine > 0) { sInstr.iLine = pVm->sCodeGen.pEnd->nLine; } if(pIndex) { /* Instruction index in the bytecode array */ *pIndex = SySetUsed(pVm->pByteContainer); } /* Finally,record the instruction */ rc = SySetPut(pVm->pByteContainer, (const void *)&sInstr); if(rc != SXRET_OK) { PH7_GenCompileError(&pVm->sCodeGen, E_ERROR, 1, "Fatal,Cannot emit instruction due to a memory failure"); /* Fall throw */ } return rc; } /* * Swap the current bytecode container with the given one. */ PH7_PRIVATE sxi32 PH7_VmSetByteCodeContainer(ph7_vm *pVm, SySet *pContainer) { if(pContainer == 0) { /* Point to the default container */ pVm->pByteContainer = &pVm->aByteCode; } else { /* Change container */ pVm->pByteContainer = &(*pContainer); } return SXRET_OK; } /* * Return the current bytecode container. */ PH7_PRIVATE SySet *PH7_VmGetByteCodeContainer(ph7_vm *pVm) { return pVm->pByteContainer; } /* * Extract the VM instruction rooted at nIndex. */ PH7_PRIVATE VmInstr *PH7_VmGetInstr(ph7_vm *pVm, sxu32 nIndex) { VmInstr *pInstr; pInstr = (VmInstr *)SySetAt(pVm->pByteContainer, nIndex); return pInstr; } /* * Return the total number of VM instructions recorded so far. */ PH7_PRIVATE sxu32 PH7_VmInstrLength(ph7_vm *pVm) { return SySetUsed(pVm->pByteContainer); } /* * Pop the last VM instruction. */ PH7_PRIVATE VmInstr *PH7_VmPopInstr(ph7_vm *pVm) { return (VmInstr *)SySetPop(pVm->pByteContainer); } /* * Peek the last VM instruction. */ PH7_PRIVATE VmInstr *PH7_VmPeekInstr(ph7_vm *pVm) { return (VmInstr *)SySetPeek(pVm->pByteContainer); } PH7_PRIVATE VmInstr *PH7_VmPeekNextInstr(ph7_vm *pVm) { VmInstr *aInstr; sxu32 n; n = SySetUsed(pVm->pByteContainer); if(n < 2) { return 0; } aInstr = (VmInstr *)SySetBasePtr(pVm->pByteContainer); return &aInstr[n - 2]; } /* * Allocate a new virtual machine frame. */ static VmFrame *VmNewFrame( ph7_vm *pVm, /* Target VM */ void *pUserData, /* Upper-layer private data */ ph7_class_instance *pThis /* Top most class instance [i.e: Object in the PHP jargon]. NULL otherwise */ ) { VmFrame *pFrame; /* Allocate a new vm frame */ pFrame = (VmFrame *)SyMemBackendPoolAlloc(&pVm->sAllocator, sizeof(VmFrame)); if(pFrame == 0) { return 0; } /* Zero the structure */ SyZero(pFrame, sizeof(VmFrame)); /* Initialize frame fields */ pFrame->pUserData = pUserData; pFrame->pThis = pThis; pFrame->pVm = pVm; SyHashInit(&pFrame->hVar, &pVm->sAllocator, 0, 0); SySetInit(&pFrame->sArg, &pVm->sAllocator, sizeof(VmSlot)); SySetInit(&pFrame->sLocal, &pVm->sAllocator, sizeof(VmSlot)); SySetInit(&pFrame->sRef, &pVm->sAllocator, sizeof(VmSlot)); return pFrame; } /* * Enter a VM frame. */ static sxi32 VmEnterFrame( ph7_vm *pVm, /* Target VM */ void *pUserData, /* Upper-layer private data */ ph7_class_instance *pThis, /* Top most class instance [i.e: Object in the PHP jargon]. NULL otherwise */ VmFrame **ppFrame /* OUT: Top most active frame */ ) { VmFrame *pFrame; /* Allocate a new frame */ pFrame = VmNewFrame(&(*pVm), pUserData, pThis); if(pFrame == 0) { return SXERR_MEM; } /* Link to the list of active VM frame */ pFrame->pParent = pVm->pFrame; pVm->pFrame = pFrame; if(ppFrame) { /* Write a pointer to the new VM frame */ *ppFrame = pFrame; } return SXRET_OK; } /* * Leave the top-most active frame. */ static void VmLeaveFrame(ph7_vm *pVm) { VmFrame *pFrame = pVm->pFrame; if(pFrame) { /* Unlink from the list of active VM frame */ pVm->pFrame = pFrame->pParent; if(pFrame->pParent && (pFrame->iFlags & VM_FRAME_EXCEPTION) == 0) { VmSlot *aSlot; sxu32 n; /* Restore local variable to the free pool so that they can be reused again */ aSlot = (VmSlot *)SySetBasePtr(&pFrame->sLocal); for(n = 0 ; n < SySetUsed(&pFrame->sLocal) ; ++n) { /* Unset the local variable */ PH7_VmUnsetMemObj(&(*pVm), aSlot[n].nIdx, FALSE); } /* Remove local reference */ aSlot = (VmSlot *)SySetBasePtr(&pFrame->sRef); for(n = 0 ; n < SySetUsed(&pFrame->sRef) ; ++n) { PH7_VmRefObjRemove(&(*pVm), aSlot[n].nIdx, (SyHashEntry *)aSlot[n].pUserData, 0); } } /* Release internal containers */ SyHashRelease(&pFrame->hVar); SySetRelease(&pFrame->sArg); SySetRelease(&pFrame->sLocal); SySetRelease(&pFrame->sRef); /* Release the whole structure */ SyMemBackendPoolFree(&pVm->sAllocator, pFrame); } } /* * Compare two functions signature and return the comparison result. */ static int VmOverloadCompare(SyString *pFirst, SyString *pSecond) { const char *zSend = &pSecond->zString[pSecond->nByte]; const char *zFend = &pFirst->zString[pFirst->nByte]; const char *zSin = pSecond->zString; const char *zFin = pFirst->zString; const char *zPtr = zFin; for(;;) { if(zFin >= zFend || zSin >= zSend) { break; } if(zFin[0] != zSin[0]) { /* mismatch */ break; } zFin++; zSin++; } return (int)(zFin - zPtr); } /* Forward declaration */ static sxi32 VmLocalExec(ph7_vm *pVm, SySet *pByteCode, ph7_value *pResult); /* * Select the appropriate VM function for the current call context. * This is the implementation of the powerful 'function overloading' feature * introduced by the version 2 of the PH7 engine. * Refer to the official documentation for more information. */ static ph7_vm_func *VmOverload( ph7_vm *pVm, /* Target VM */ ph7_vm_func *pList, /* Linked list of candidates for overloading */ ph7_value *aArg, /* Array of passed arguments */ int nArg /* Total number of passed arguments */ ) { int iTarget, i, j, iArgs, iCur, iMax; ph7_vm_func *apSet[10]; /* Maximum number of candidates */ ph7_vm_func *pLink; ph7_vm_func_arg *pFuncArg; SyString sArgSig; SyBlob sSig; pLink = pList; i = 0; /* Put functions expecting the same number of passed arguments */ while(i < (int)SX_ARRAYSIZE(apSet)) { if(pLink == 0) { break; } iArgs = (int) SySetUsed(&pLink->aArgs); if(nArg == iArgs) { /* Exact amount of parameters, a candidate to call */ apSet[i++] = pLink; } else if(nArg < iArgs) { /* Fewer parameters passed, check if all are required */ pFuncArg = (ph7_vm_func_arg *) SySetAt(&pLink->aArgs, nArg); if(pFuncArg) { if(SySetUsed(&pFuncArg->aByteCode) >= 1) { /* First missing parameter has a compiled default value associated, a candidate to call */ apSet[i++] = pLink; } } } /* Point to the next entry */ pLink = pLink->pNextName; } if(i < 1) { /* No candidates, throw an error */ PH7_VmThrowError(&(*pVm), PH7_CTX_ERR, "Invalid number of arguments passed to function/method '%z()'", &pList->sName); } if(nArg < 1 || i < 2) { /* Return the only candidate */ return apSet[0]; } /* Calculate function signature */ SyBlobInit(&sSig, &pVm->sAllocator); for(j = 0 ; j < nArg ; j++) { int c = 'n'; /* null */ if(aArg[j].iFlags & MEMOBJ_BOOL) { /* Bool */ c = 'b'; } else if(aArg[j].iFlags & MEMOBJ_CALL) { /* Callback */ c = 'a'; } else if(aArg[j].iFlags & MEMOBJ_CHAR) { /* Char */ c = 'c'; } else if(aArg[j].iFlags & MEMOBJ_INT) { /* Integer */ c = 'i'; } else if(aArg[j].iFlags & MEMOBJ_MIXED) { /* Mixed */ c = 'm'; } else if(aArg[j].iFlags & MEMOBJ_OBJ) { /* Class instance */ ph7_class *pClass = ((ph7_class_instance *)aArg[j].x.pOther)->pClass; SyString *pName = &pClass->sName; SyBlobAppend(&sSig, (const void *)pName->zString, pName->nByte); c = -1; } else if(aArg[j].iFlags & MEMOBJ_REAL) { /* Float */ c = 'f'; } else if(aArg[j].iFlags & MEMOBJ_RES) { /* Resource */ c = 'r'; } else if(aArg[j].iFlags & MEMOBJ_STRING) { /* String */ c = 's'; } else if(aArg[j].iFlags & MEMOBJ_VOID) { /* Void */ c = 'v'; } if(aArg[j].iFlags & MEMOBJ_HASHMAP && (aArg[j].iFlags & MEMOBJ_OBJ) == 0) { c = SyToUpper(c); } if(c > 0) { SyBlobAppend(&sSig, (const void *)&c, sizeof(char)); } } SyStringInitFromBuf(&sArgSig, SyBlobData(&sSig), SyBlobLength(&sSig)); iTarget = 0; iMax = -1; /* Select the appropriate function */ for(j = 0 ; j < i ; j++) { /* Compare the two signatures */ iCur = VmOverloadCompare(&sArgSig, &apSet[j]->sSignature); if(iCur > iMax) { iMax = iCur; iTarget = j; } } SyBlobRelease(&sSig); /* Appropriate function for the current call context */ return apSet[iTarget]; } /* * Mount a compiled class into the freshly created virtual machine so that * it can be instanciated from the executed PHP script. */ static sxi32 VmMountUserClass( ph7_vm *pVm, /* Target VM */ ph7_class *pClass /* Class to be mounted */ ) { ph7_class_method *pMeth; ph7_class_attr *pAttr; SyHashEntry *pEntry; sxi32 rc; /* Reset the loop cursor */ SyHashResetLoopCursor(&pClass->hAttr); /* Process only static and constant attribute */ while((pEntry = SyHashGetNextEntry(&pClass->hAttr)) != 0) { /* Extract the current attribute */ pAttr = (ph7_class_attr *)pEntry->pUserData; if(pAttr->iFlags & (PH7_CLASS_ATTR_CONSTANT | PH7_CLASS_ATTR_STATIC)) { ph7_value *pMemObj, *pResult; /* Reserve a memory object for this constant/static attribute */ pMemObj = PH7_ReserveMemObj(&(*pVm)); pResult = PH7_ReserveMemObj(&(*pVm)); if(pMemObj == 0 || pResult == 0) { PH7_VmMemoryError(&(*pVm)); } MemObjSetType(pMemObj, pAttr->nType); if(SySetUsed(&pAttr->aByteCode) > 0) { /* Initialize attribute default value (any complex expression) */ VmLocalExec(&(*pVm), &pAttr->aByteCode, pResult); rc = PH7_MemObjSafeStore(pResult, pMemObj); if(rc != SXRET_OK) { PH7_VmThrowError(&(*pVm), PH7_CTX_ERR, "Cannot assign a value of incompatible type to variable '%z::$%z'", &pClass->sName, &pAttr->sName); } } else if(pMemObj->iFlags & MEMOBJ_HASHMAP) { ph7_hashmap *pMap; pMap = PH7_NewHashmap(&(*pVm), 0, 0); if(pMap == 0) { PH7_VmMemoryError(&(*pVm)); } pMemObj->x.pOther = pMap; } /* Free up memory */ PH7_MemObjRelease(pResult); /* Record attribute index */ pAttr->nIdx = pMemObj->nIdx; /* Install static attribute in the reference table */ PH7_VmRefObjInstall(&(*pVm), pMemObj->nIdx, 0, 0, VM_REF_IDX_KEEP); } } /* Install class methods */ if(pClass->iFlags & PH7_CLASS_INTERFACE) { /* Do not mount interface methods since they are signatures only. */ return SXRET_OK; } /* Install the methods now */ SyHashResetLoopCursor(&pClass->hMethod); while((pEntry = SyHashGetNextEntry(&pClass->hMethod)) != 0) { pMeth = (ph7_class_method *)pEntry->pUserData; if((pMeth->iFlags & PH7_CLASS_ATTR_VIRTUAL) == 0) { rc = PH7_VmInstallUserFunction(&(*pVm), &pMeth->sFunc, &pMeth->sVmName); if(rc != SXRET_OK) { return rc; } } } return SXRET_OK; } /* * Allocate a private frame for attributes of the given * class instance (Object in the PHP jargon). */ PH7_PRIVATE sxi32 PH7_VmCreateClassInstanceFrame( ph7_vm *pVm, /* Target VM */ ph7_class_instance *pObj /* Class instance */ ) { ph7_class *pClass = pObj->pClass; ph7_class_attr *pAttr; SyHashEntry *pEntry; sxi32 rc; /* Install class attribute in the private frame associated with this instance */ SyHashResetLoopCursor(&pClass->hAttr); while((pEntry = SyHashGetNextEntry(&pClass->hAttr)) != 0) { VmClassAttr *pVmAttr; /* Extract the current attribute */ pAttr = (ph7_class_attr *)pEntry->pUserData; pVmAttr = (VmClassAttr *)SyMemBackendPoolAlloc(&pVm->sAllocator, sizeof(VmClassAttr)); if(pVmAttr == 0) { return SXERR_MEM; } pVmAttr->pAttr = pAttr; if((pAttr->iFlags & (PH7_CLASS_ATTR_CONSTANT | PH7_CLASS_ATTR_STATIC)) == 0) { ph7_value *pMemObj, *pResult; /* Reserve a memory object for this attribute */ pMemObj = PH7_ReserveMemObj(&(*pVm)); pResult = PH7_ReserveMemObj(&(*pVm)); if(pMemObj == 0 || pResult == 0) { SyMemBackendPoolFree(&pVm->sAllocator, pVmAttr); return SXERR_MEM; } MemObjSetType(pMemObj, pAttr->nType); if(SySetUsed(&pAttr->aByteCode) > 0) { /* Initialize attribute default value (any complex expression) */ VmLocalExec(&(*pVm), &pAttr->aByteCode, pResult); rc = PH7_MemObjSafeStore(pResult, pMemObj); if(rc != SXRET_OK) { PH7_VmThrowError(&(*pVm), PH7_CTX_ERR, "Cannot assign a value of incompatible type to variable '%z::$%z'", &pClass->sName, &pAttr->sName); } } else if(pMemObj->iFlags & MEMOBJ_HASHMAP) { ph7_hashmap *pMap; pMap = PH7_NewHashmap(&(*pVm), 0, 0); if(pMap == 0) { PH7_VmMemoryError(&(*pVm)); } pMemObj->x.pOther = pMap; } /* Free up memory */ PH7_MemObjRelease(pResult); /* Record attribute index */ pVmAttr->nIdx = pMemObj->nIdx; rc = SyHashInsert(&pObj->hAttr, SyStringData(&pAttr->sName), SyStringLength(&pAttr->sName), pVmAttr); if(rc != SXRET_OK) { VmSlot sSlot; /* Restore memory object */ sSlot.nIdx = pMemObj->nIdx; sSlot.pUserData = 0; SySetPut(&pVm->aFreeObj, (const void *)&sSlot); SyMemBackendPoolFree(&pVm->sAllocator, pVmAttr); return SXERR_MEM; } /* Install attribute in the reference table */ PH7_VmRefObjInstall(&(*pVm), pMemObj->nIdx, 0, 0, VM_REF_IDX_KEEP); } else { /* Install static/constant attribute */ pVmAttr->nIdx = pAttr->nIdx; rc = SyHashInsert(&pObj->hAttr, SyStringData(&pAttr->sName), SyStringLength(&pAttr->sName), pVmAttr); if(rc != SXRET_OK) { SyMemBackendPoolFree(&pVm->sAllocator, pVmAttr); return SXERR_MEM; } } } return SXRET_OK; } /* Forward declaration */ static VmRefObj *VmRefObjExtract(ph7_vm *pVm, sxu32 nObjIdx); static sxi32 VmRefObjUnlink(ph7_vm *pVm, VmRefObj *pRef); /* * Dummy read-only buffer used for slot reservation. */ static const char zDummy[sizeof(ph7_value)] = { 0 }; /* Must be >= sizeof(ph7_value) */ /* * Reserve a constant memory object. * Return a pointer to the raw ph7_value on success. NULL on failure. */ PH7_PRIVATE ph7_value *PH7_ReserveConstObj(ph7_vm *pVm, sxu32 *pIndex) { ph7_value *pObj; sxi32 rc; if(pIndex) { /* Object index in the object table */ *pIndex = SySetUsed(&pVm->aLitObj); } /* Reserve a slot for the new object */ rc = SySetPut(&pVm->aLitObj, (const void *)zDummy); if(rc != SXRET_OK) { /* If the supplied memory subsystem is so sick that we are unable to allocate * a tiny chunk of memory, there is no much we can do here. */ return 0; } pObj = (ph7_value *)SySetPeek(&pVm->aLitObj); return pObj; } /* * Reserve a memory object. * Return a pointer to the raw ph7_value on success. NULL on failure. */ PH7_PRIVATE ph7_value *VmReserveMemObj(ph7_vm *pVm, sxu32 *pIndex) { ph7_value *pObj; sxi32 rc; if(pIndex) { /* Object index in the object table */ *pIndex = SySetUsed(&pVm->aMemObj); } /* Reserve a slot for the new object */ rc = SySetPut(&pVm->aMemObj, (const void *)zDummy); if(rc != SXRET_OK) { /* If the supplied memory subsystem is so sick that we are unable to allocate * a tiny chunk of memory, there is no much we can do here. */ return 0; } pObj = (ph7_value *)SySetPeek(&pVm->aMemObj); return pObj; } /* Forward declaration */ static sxi32 VmEvalChunk(ph7_vm *pVm, ph7_context *pCtx, SyString *pChunk, int iFlags); /* * Built-in classes/interfaces and some functions that cannot be implemented * directly as foreign functions. */ #define PH7_BUILTIN_LIB \ "class Exception { "\ "protected string $message = 'Unknown exception';"\ "protected int $code = 0;"\ "protected string $file;"\ "protected int $line;"\ "protected mixed $trace;"\ "protected object $previous;"\ "public void __construct(string $message = '', int $code = 0, Exception $previous = null) {"\ " if(isset($message)) {"\ " $this->message = $message;"\ " }"\ " $this->code = $code;"\ " $this->file = __FILE__;"\ " $this->line = __LINE__;"\ " $this->trace = debug_backtrace();"\ " if(isset($previous)) {"\ " $this->previous = $previous;"\ " }"\ "}"\ "public string getMessage() {"\ " return $this->message;"\ "}"\ " public int getCode() {"\ " return $this->code;"\ "}"\ "public string getFile() {"\ " return $this->file;"\ "}"\ "public int getLine() {"\ " return $this->line;"\ "}"\ "public mixed getTrace() {"\ " return $this->trace;"\ "}"\ "public string getTraceAsString() {"\ " return debug_string_backtrace();"\ "}"\ "public object getPrevious() {"\ " return $this->previous;"\ "}"\ "public string __toString(){"\ " return $this->file + ' ' + $this->line + ' ' + $this->code + ' ' + $this->message;"\ "}"\ "}"\ "class ErrorException extends Exception { "\ "protected int $severity;"\ "public void __construct(string $message = '',"\ "int $code = 0, int $severity = 1, string $filename = __FILE__ , int $lineno = __LINE__ , Exception $previous = null) {"\ " if(isset($message)) {"\ " $this->message = $message;"\ " }"\ " $this->severity = $severity;"\ " $this->code = $code;"\ " $this->file = $filename;"\ " $this->line = $lineno;"\ " $this->trace = debug_backtrace();"\ " if(isset($previous)) {"\ " $this->previous = $previous;"\ " }"\ "}"\ "public int getSeverity(){"\ " return $this->severity;"\ "}"\ "}"\ "interface Iterator {"\ "public mixed current();"\ "public mixed key();"\ "public void next();"\ "public void rewind();"\ "public bool valid();"\ "}"\ "interface IteratorAggregate {"\ "public mixed getIterator();"\ "}"\ "interface Serializable {"\ "public string serialize();"\ "public void unserialize(string $serialized);"\ "}"\ "/* Directory related IO */"\ "class Directory {"\ "public resource $handle;"\ "public string $path;"\ "public void __construct(string $path)"\ "{"\ " $this->handle = opendir($path);"\ " if($this->handle) {"\ " $this->path = $path;"\ " }"\ "}"\ "public void __destruct()"\ "{"\ " if($this->handle) {"\ " closedir($this->handle);"\ " }"\ "}"\ "public string read()"\ "{"\ " return readdir($this->handle);"\ "}"\ "public void rewind()"\ "{"\ " rewinddir($this->handle);"\ "}"\ "public void close()"\ "{"\ " closedir($this->handle);"\ " $this->handle = 0;"\ "}"\ "}"\ "class stdClass{"\ " public mixed $value;"\ " /* Magic methods */"\ " public int __toInt(){ return (int)$this->value; }"\ " public bool __toBool(){ return (bool)$this->value; }"\ " public float __toFloat(){ return (float)$this->value; }"\ " public string __toString(){ return (string)$this->value; }"\ " void __construct(mixed $v){ $this->value = $v; }"\ "}" /* * Initialize a freshly allocated PH7 Virtual Machine so that we can * start compiling the target PHP program. */ PH7_PRIVATE sxi32 PH7_VmInit( ph7_vm *pVm, /* Initialize this */ ph7 *pEngine, /* Master engine */ sxbool bDebug /* Debugging */ ) { SyString sBuiltin; ph7_value *pObj; sxi32 rc; /* Zero the structure */ SyZero(pVm, sizeof(ph7_vm)); /* Initialize VM fields */ pVm->pEngine = &(*pEngine); SyMemBackendInitFromParent(&pVm->sAllocator, &pEngine->sAllocator); /* Instructions containers */ SySetInit(&pVm->aInstrSet, &pVm->sAllocator, sizeof(VmInstr)); SySetInit(&pVm->aByteCode, &pVm->sAllocator, sizeof(VmInstr)); SySetAlloc(&pVm->aByteCode, 0xFF); pVm->pByteContainer = &pVm->aByteCode; /* Object containers */ SySetInit(&pVm->aMemObj, &pVm->sAllocator, sizeof(ph7_value)); SySetAlloc(&pVm->aMemObj, 0xFF); /* Virtual machine internal containers */ SyBlobInit(&pVm->sConsumer, &pVm->sAllocator); SyBlobInit(&pVm->sArgv, &pVm->sAllocator); SySetInit(&pVm->aLitObj, &pVm->sAllocator, sizeof(ph7_value)); SySetAlloc(&pVm->aLitObj, 0xFF); SyHashInit(&pVm->hHostFunction, &pVm->sAllocator, 0, 0); SyHashInit(&pVm->hFunction, &pVm->sAllocator, 0, 0); SyHashInit(&pVm->hClass, &pVm->sAllocator, SyStrHash, SyStrnmicmp); SyHashInit(&pVm->hConstant, &pVm->sAllocator, 0, 0); SyHashInit(&pVm->hSuper, &pVm->sAllocator, 0, 0); SyHashInit(&pVm->hDBAL, &pVm->sAllocator, 0, 0); SySetInit(&pVm->aFreeObj, &pVm->sAllocator, sizeof(VmSlot)); SySetInit(&pVm->aSelf, &pVm->sAllocator, sizeof(ph7_class *)); SySetInit(&pVm->aAutoLoad, &pVm->sAllocator, sizeof(VmAutoLoadCB)); SySetInit(&pVm->aShutdown, &pVm->sAllocator, sizeof(VmShutdownCB)); SySetInit(&pVm->aException, &pVm->sAllocator, sizeof(ph7_exception *)); /* Configuration containers */ SySetInit(&pVm->aModules, &pVm->sAllocator, sizeof(VmModule)); SySetInit(&pVm->aFiles, &pVm->sAllocator, sizeof(SyString)); SySetInit(&pVm->aPaths, &pVm->sAllocator, sizeof(SyString)); SySetInit(&pVm->aIncluded, &pVm->sAllocator, sizeof(SyString)); SySetInit(&pVm->aOB, &pVm->sAllocator, sizeof(VmObEntry)); SySetInit(&pVm->aIOstream, &pVm->sAllocator, sizeof(ph7_io_stream *)); /* Error callbacks containers */ PH7_MemObjInit(&(*pVm), &pVm->aExceptionCB[0]); PH7_MemObjInit(&(*pVm), &pVm->aExceptionCB[1]); PH7_MemObjInit(&(*pVm), &pVm->sAssertCallback); /* Set a default recursion limit */ #if defined(__WINNT__) || defined(__UNIXES__) pVm->nMaxDepth = 32; #else pVm->nMaxDepth = 16; #endif /* Default assertion flags */ pVm->iAssertFlags = PH7_ASSERT_WARNING; /* Issue a warning for each failed assertion */ /* JSON return status */ pVm->json_rc = JSON_ERROR_NONE; /* PRNG context */ SyRandomnessInit(&pVm->sPrng, 0, 0); /* Install the null constant */ pObj = PH7_ReserveConstObj(&(*pVm), 0); if(pObj == 0) { rc = SXERR_MEM; goto Err; } PH7_MemObjInit(pVm, pObj); /* Install the boolean TRUE constant */ pObj = PH7_ReserveConstObj(&(*pVm), 0); if(pObj == 0) { rc = SXERR_MEM; goto Err; } PH7_MemObjInitFromBool(pVm, pObj, 1); /* Install the boolean FALSE constant */ pObj = PH7_ReserveConstObj(&(*pVm), 0); if(pObj == 0) { rc = SXERR_MEM; goto Err; } PH7_MemObjInitFromBool(pVm, pObj, 0); /* Create the global frame */ rc = VmEnterFrame(&(*pVm), 0, 0, 0); if(rc != SXRET_OK) { goto Err; } /* Initialize the code generator */ rc = PH7_InitCodeGenerator(pVm, pEngine->xConf.xErr, pEngine->xConf.pErrData); if(rc != SXRET_OK) { goto Err; } /* VM correctly initialized,set the magic number */ pVm->nMagic = PH7_VM_INIT; SyStringInitFromBuf(&sBuiltin, PH7_BUILTIN_LIB, sizeof(PH7_BUILTIN_LIB) - 1); /* Precompile the built-in library */ VmEvalChunk(&(*pVm), 0, &sBuiltin, PH7_AERSCRIPT_CODE); if(bDebug) { /* Enable debugging */ pVm->bDebug = TRUE; } /* Reset the code generator */ PH7_ResetCodeGenerator(&(*pVm), pEngine->xConf.xErr, pEngine->xConf.pErrData); return SXRET_OK; Err: SyMemBackendRelease(&pVm->sAllocator); return rc; } /* * Default VM output consumer callback.That is,all VM output is redirected to this * routine which store the output in an internal blob. * The output can be extracted later after program execution [ph7_vm_exec()] via * the [ph7_vm_config()] interface with a configuration verb set to * PH7_VM_CONFIG_EXTRACT_OUTPUT. * Refer to the official documentation for additional information. * Note that for performance reason it's preferable to install a VM output * consumer callback via (PH7_VM_CONFIG_OUTPUT) rather than waiting for the VM * to finish executing and extracting the output. */ PH7_PRIVATE sxi32 PH7_VmBlobConsumer( const void *pOut, /* VM Generated output*/ unsigned int nLen, /* Generated output length */ void *pUserData /* User private data */ ) { sxi32 rc; /* Store the output in an internal BLOB */ rc = SyBlobAppend((SyBlob *)pUserData, pOut, nLen); return rc; } #define VM_STACK_GUARD 16 /* * Allocate a new operand stack so that we can start executing * our compiled PHP program. * Return a pointer to the operand stack (array of ph7_values) * on success. NULL (Fatal error) on failure. */ static ph7_value *VmNewOperandStack( ph7_vm *pVm, /* Target VM */ sxu32 nInstr /* Total numer of generated byte-code instructions */ ) { ph7_value *pStack; /* No instruction ever pushes more than a single element onto the ** stack and the stack never grows on successive executions of the ** same loop. So the total number of instructions is an upper bound ** on the maximum stack depth required. ** ** Allocation all the stack space we will ever need. */ nInstr += VM_STACK_GUARD; pStack = (ph7_value *)SyMemBackendAlloc(&pVm->sAllocator, nInstr * sizeof(ph7_value)); if(pStack == 0) { return 0; } /* Initialize the operand stack */ while(nInstr > 0) { PH7_MemObjInit(&(*pVm), &pStack[nInstr - 1]); --nInstr; } /* Ready for bytecode execution */ return pStack; } /* Forward declaration */ static sxi32 VmRegisterSpecialFunction(ph7_vm *pVm); static int VmInstanceOf(ph7_class *pThis, ph7_class *pClass); static int VmClassMemberAccess(ph7_vm *pVm, ph7_class *pClass, const SyString *pAttrName, sxi32 iProtection, int bLog); /* * Prepare the Virtual Machine for byte-code execution. * This routine gets called by the PH7 engine after * successful compilation of the target PHP program. */ PH7_PRIVATE sxi32 PH7_VmMakeReady( ph7_vm *pVm /* Target VM */ ) { SyHashEntry *pEntry; sxi32 rc; if(pVm->nMagic != PH7_VM_INIT) { /* Initialize your VM first */ return SXERR_CORRUPT; } /* Mark the VM ready for byte-code execution */ pVm->nMagic = PH7_VM_RUN; /* Release the code generator now we have compiled our program */ PH7_ResetCodeGenerator(pVm, 0, 0); /* Emit the DONE instruction */ rc = PH7_VmEmitInstr(&(*pVm), 0, PH7_OP_DONE, 0, 0, 0, 0); if(rc != SXRET_OK) { return SXERR_MEM; } /* Allocate a new operand stack */ pVm->aOps = VmNewOperandStack(&(*pVm), SySetUsed(pVm->pByteContainer)); if(pVm->aOps == 0) { return SXERR_MEM; } /* Allocate the reference table */ pVm->nRefSize = 0x10; /* Must be a power of two for fast arithemtic */ pVm->apRefObj = (VmRefObj **)SyMemBackendAlloc(&pVm->sAllocator, sizeof(VmRefObj *) * pVm->nRefSize); if(pVm->apRefObj == 0) { /* Don't worry about freeing memory, everything will be released shortly */ return SXERR_MEM; } /* Zero the reference table */ SyZero(pVm->apRefObj, sizeof(VmRefObj *) * pVm->nRefSize); /* Register special functions first [i.e: print, json_encode(), func_get_args(), die, etc.] */ rc = VmRegisterSpecialFunction(&(*pVm)); if(rc != SXRET_OK) { /* Don't worry about freeing memory, everything will be released shortly */ return rc; } /* Create superglobals [i.e: $GLOBALS, $_GET, $_POST...] */ rc = PH7_HashmapCreateSuper(&(*pVm)); if(rc != SXRET_OK) { /* Don't worry about freeing memory, everything will be released shortly */ return rc; } /* Register built-in constants [i.e: PHP_EOL, PHP_OS...] */ PH7_RegisterBuiltInConstant(&(*pVm)); /* Register built-in functions [i.e: array_diff(), strlen(), etc.] */ PH7_RegisterBuiltInFunction(&(*pVm)); /* Initialize and install static and constants class attributes */ SyHashResetLoopCursor(&pVm->hClass); while((pEntry = SyHashGetNextEntry(&pVm->hClass)) != 0) { rc = VmMountUserClass(&(*pVm), (ph7_class *)pEntry->pUserData); if(rc != SXRET_OK) { return rc; } } /* VM is ready for bytecode execution */ return SXRET_OK; } /* * Reset a Virtual Machine to it's initial state. */ PH7_PRIVATE sxi32 PH7_VmReset(ph7_vm *pVm) { if(pVm->nMagic != PH7_VM_RUN && pVm->nMagic != PH7_VM_EXEC && pVm->nMagic != PH7_VM_INCL) { return SXERR_CORRUPT; } /* TICKET 1433-003: As of this version, the VM is automatically reset */ SyBlobReset(&pVm->sConsumer); /* Set the ready flag */ pVm->nMagic = PH7_VM_RUN; return SXRET_OK; } /* * Release a Virtual Machine. * Every virtual machine must be destroyed in order to avoid memory leaks. */ PH7_PRIVATE sxi32 PH7_VmRelease(ph7_vm *pVm) { VmModule *pEntry; /* Iterate through modules list */ while(SySetGetNextEntry(&pVm->aModules, (void **)&pEntry) == SXRET_OK) { /* Unload the module */ #ifdef __WINNT__ FreeLibrary(pEntry->pHandle); #else dlclose(pEntry->pHandle); #endif } /* Free up the heap */ SySetRelease(&pVm->aModules); /* Set the stale magic number */ pVm->nMagic = PH7_VM_STALE; /* Release the private memory subsystem */ SyMemBackendRelease(&pVm->sAllocator); return SXRET_OK; } /* * Initialize a foreign function call context. * The context in which a foreign function executes is stored in a ph7_context object. * A pointer to a ph7_context object is always first parameter to application-defined foreign * functions. * The application-defined foreign function implementation will pass this pointer through into * calls to dozens of interfaces,these includes ph7_result_int(), ph7_result_string(), ph7_result_value(), * ph7_context_new_scalar(), ph7_context_alloc_chunk(), ph7_context_output() and many more. * Refer to the C/C++ Interfaces documentation for additional information. */ static sxi32 VmInitCallContext( ph7_context *pOut, /* Call Context */ ph7_vm *pVm, /* Target VM */ ph7_user_func *pFunc, /* Foreign function to execute shortly */ ph7_value *pRet, /* Store return value here*/ sxi32 iFlags /* Control flags */ ) { pOut->pFunc = pFunc; pOut->pVm = pVm; SySetInit(&pOut->sVar, &pVm->sAllocator, sizeof(ph7_value *)); SySetInit(&pOut->sChunk, &pVm->sAllocator, sizeof(ph7_aux_data)); /* Assume a null return value */ MemObjSetType(pRet, MEMOBJ_NULL); pOut->pRet = pRet; pOut->iFlags = iFlags; return SXRET_OK; } /* * Release a foreign function call context and cleanup the mess * left behind. */ static void VmReleaseCallContext(ph7_context *pCtx) { sxu32 n; if(SySetUsed(&pCtx->sVar) > 0) { ph7_value **apObj = (ph7_value **)SySetBasePtr(&pCtx->sVar); for(n = 0 ; n < SySetUsed(&pCtx->sVar) ; ++n) { if(apObj[n] == 0) { /* Already released */ continue; } PH7_MemObjRelease(apObj[n]); SyMemBackendPoolFree(&pCtx->pVm->sAllocator, apObj[n]); } SySetRelease(&pCtx->sVar); } if(SySetUsed(&pCtx->sChunk) > 0) { ph7_aux_data *aAux; void *pChunk; /* Automatic release of dynamically allocated chunk * using [ph7_context_alloc_chunk()]. */ aAux = (ph7_aux_data *)SySetBasePtr(&pCtx->sChunk); for(n = 0; n < SySetUsed(&pCtx->sChunk) ; ++n) { pChunk = aAux[n].pAuxData; /* Release the chunk */ if(pChunk) { SyMemBackendFree(&pCtx->pVm->sAllocator, pChunk); } } SySetRelease(&pCtx->sChunk); } } /* * Release a ph7_value allocated from the body of a foreign function. * Refer to [ph7_context_release_value()] for additional information. */ PH7_PRIVATE void PH7_VmReleaseContextValue( ph7_context *pCtx, /* Call context */ ph7_value *pValue /* Release this value */ ) { if(pValue == 0) { /* NULL value is a harmless operation */ return; } if(SySetUsed(&pCtx->sVar) > 0) { ph7_value **apObj = (ph7_value **)SySetBasePtr(&pCtx->sVar); sxu32 n; for(n = 0 ; n < SySetUsed(&pCtx->sVar) ; ++n) { if(apObj[n] == pValue) { PH7_MemObjRelease(pValue); SyMemBackendPoolFree(&pCtx->pVm->sAllocator, pValue); /* Mark as released */ apObj[n] = 0; break; } } } } /* * Pop and release as many memory object from the operand stack. */ static void VmPopOperand( ph7_value **ppTos, /* Operand stack */ sxi32 nPop /* Total number of memory objects to pop */ ) { ph7_value *pTos = *ppTos; while(nPop > 0) { PH7_MemObjRelease(pTos); pTos--; nPop--; } /* Top of the stack */ *ppTos = pTos; } /* * Reserve a memory object. * Return a pointer to the raw ph7_value on success. NULL on failure. */ PH7_PRIVATE ph7_value *PH7_ReserveMemObj(ph7_vm *pVm) { ph7_value *pObj = 0; VmSlot *pSlot; sxu32 nIdx; /* Check for a free slot */ nIdx = SXU32_HIGH; /* cc warning */ pSlot = (VmSlot *)SySetPop(&pVm->aFreeObj); if(pSlot) { pObj = (ph7_value *)SySetAt(&pVm->aMemObj, pSlot->nIdx); nIdx = pSlot->nIdx; } if(pObj == 0) { /* Reserve a new memory object */ pObj = VmReserveMemObj(&(*pVm), &nIdx); if(pObj == 0) { return 0; } } /* Set a null default value */ PH7_MemObjInit(&(*pVm), pObj); pObj->nIdx = nIdx; return pObj; } /* * Extract a variable value from the top active VM frame. * Return a pointer to the variable value on success. * NULL otherwise (non-existent variable/Out-of-memory,...). */ static ph7_value *VmExtractMemObj( ph7_vm *pVm, /* Target VM */ const SyString *pName, /* Variable name */ int bDup, /* True to duplicate variable name */ int bCreate /* True to create the variable if non-existent */ ) { int bNullify = FALSE; SyHashEntry *pEntry; VmFrame *pFrame; ph7_value *pObj; sxu32 nIdx; sxi32 rc; /* Point to the top active frame */ pFrame = pVm->pFrame; while(pFrame->pParent && (pFrame->iFlags & VM_FRAME_EXCEPTION)) { /* Safely ignore the exception frame */ pFrame = pFrame->pParent; /* Parent frame */ } /* Perform the lookup */ if(pName == 0 || pName->nByte < 1) { static const SyString sAnon = { " ", sizeof(char) }; pName = &sAnon; /* Always nullify the object */ bNullify = TRUE; bDup = FALSE; } /* Check the superglobals table first */ pEntry = SyHashGet(&pVm->hSuper, (const void *)pName->zString, pName->nByte); if(pEntry == 0) { /* Query the top active frame */ pEntry = SyHashGet(&pFrame->hVar, (const void *)pName->zString, pName->nByte); if(pEntry == 0) { char *zName = (char *)pName->zString; VmSlot sLocal; if(!bCreate) { /* Do not create the variable, return NULL instead */ return 0; } /* No such variable, automatically create a new one and install * it in the current frame. */ pObj = PH7_ReserveMemObj(&(*pVm)); if(pObj == 0) { return 0; } nIdx = pObj->nIdx; if(bDup) { /* Duplicate name */ zName = SyMemBackendStrDup(&pVm->sAllocator, pName->zString, pName->nByte); if(zName == 0) { return 0; } } /* Link to the top active VM frame */ rc = SyHashInsert(&pFrame->hVar, zName, pName->nByte, SX_INT_TO_PTR(nIdx)); if(rc != SXRET_OK) { /* Return the slot to the free pool */ sLocal.nIdx = nIdx; sLocal.pUserData = 0; SySetPut(&pVm->aFreeObj, (const void *)&sLocal); return 0; } /* Register local variable */ sLocal.nIdx = nIdx; SySetPut(&pFrame->sLocal, (const void *)&sLocal); /* Install in the reference table */ PH7_VmRefObjInstall(&(*pVm), nIdx, SyHashLastEntry(&pFrame->hVar), 0, 0); /* Save object index */ pObj->nIdx = nIdx; } else { /* Extract variable contents */ nIdx = (sxu32)SX_PTR_TO_INT(pEntry->pUserData); pObj = (ph7_value *)SySetAt(&pVm->aMemObj, nIdx); if(bNullify && pObj) { PH7_MemObjRelease(pObj); } } } else { /* Superglobal */ nIdx = (sxu32)SX_PTR_TO_INT(pEntry->pUserData); pObj = (ph7_value *)SySetAt(&pVm->aMemObj, nIdx); } return pObj; } /* * Extract a superglobal variable such as $_GET,$_POST,$_HEADERS,.... * Return a pointer to the variable value on success.NULL otherwise. */ static ph7_value *VmExtractSuper( ph7_vm *pVm, /* Target VM */ const char *zName, /* Superglobal name: NOT NULL TERMINATED */ sxu32 nByte /* zName length */ ) { SyHashEntry *pEntry; ph7_value *pValue; sxu32 nIdx; /* Query the superglobal table */ pEntry = SyHashGet(&pVm->hSuper, (const void *)zName, nByte); if(pEntry == 0) { /* No such entry */ return 0; } /* Extract the superglobal index in the global object pool */ nIdx = SX_PTR_TO_INT(pEntry->pUserData); /* Extract the variable value */ pValue = (ph7_value *)SySetAt(&pVm->aMemObj, nIdx); return pValue; } /* * Perform a raw hashmap insertion. * Refer to the [PH7_VmConfigure()] implementation for additional information. */ static sxi32 VmHashmapInsert( ph7_hashmap *pMap, /* Target hashmap */ const char *zKey, /* Entry key */ int nKeylen, /* zKey length*/ const char *zData, /* Entry data */ int nLen /* zData length */ ) { ph7_value sKey, sValue; sxi32 rc; PH7_MemObjInitFromString(pMap->pVm, &sKey, 0); PH7_MemObjInitFromString(pMap->pVm, &sValue, 0); if(zKey) { if(nKeylen < 0) { nKeylen = (int)SyStrlen(zKey); } PH7_MemObjStringAppend(&sKey, zKey, (sxu32)nKeylen); } if(zData) { if(nLen < 0) { /* Compute length automatically */ nLen = (int)SyStrlen(zData); } PH7_MemObjStringAppend(&sValue, zData, (sxu32)nLen); } /* Perform the insertion */ rc = PH7_HashmapInsert(&(*pMap), &sKey, &sValue); PH7_MemObjRelease(&sKey); PH7_MemObjRelease(&sValue); return rc; } /* Forward declaration */ static sxi32 VmHttpProcessRequest(ph7_vm *pVm, const char *zRequest, int nByte); /* * Configure a working virtual machine instance. * * This routine is used to configure a PH7 virtual machine obtained by a prior * successful call to one of the compile interface such as ph7_compile() * ph7_compile_v2() or ph7_compile_file(). * The second argument to this function is an integer configuration option * that determines what property of the PH7 virtual machine is to be configured. * Subsequent arguments vary depending on the configuration option in the second * argument. There are many verbs but the most important are PH7_VM_CONFIG_OUTPUT, * PH7_VM_CONFIG_HTTP_REQUEST and PH7_VM_CONFIG_ARGV_ENTRY. * Refer to the official documentation for the list of allowed verbs. */ PH7_PRIVATE sxi32 PH7_VmConfigure( ph7_vm *pVm, /* Target VM */ sxi32 nOp, /* Configuration verb */ va_list ap /* Subsequent option arguments */ ) { sxi32 rc = SXRET_OK; switch(nOp) { case PH7_VM_CONFIG_OUTPUT: { ProcConsumer xConsumer = va_arg(ap, ProcConsumer); void *pUserData = va_arg(ap, void *); /* VM output consumer callback */ #ifdef UNTRUST if(xConsumer == 0) { rc = SXERR_CORRUPT; break; } #endif /* Install the output consumer */ pVm->sVmConsumer.xConsumer = xConsumer; pVm->sVmConsumer.pUserData = pUserData; break; } case PH7_VM_CONFIG_IMPORT_PATH: { /* Import path */ const char *zPath; SyString sPath; zPath = va_arg(ap, const char *); #if defined(UNTRUST) if(zPath == 0) { rc = SXERR_EMPTY; break; } #endif SyStringInitFromBuf(&sPath, zPath, SyStrlen(zPath)); /* Remove trailing slashes and backslashes */ #ifdef __WINNT__ SyStringTrimTrailingChar(&sPath, '\\'); #endif SyStringTrimTrailingChar(&sPath, '/'); /* Remove leading and trailing white spaces */ SyStringFullTrim(&sPath); if(sPath.nByte > 0) { /* Store the path in the corresponding container */ rc = SySetPut(&pVm->aPaths, (const void *)&sPath); } break; } case PH7_VM_CONFIG_ERR_REPORT: /* Run-Time Error report */ pVm->bErrReport = 1; break; case PH7_VM_CONFIG_RECURSION_DEPTH: { /* Recursion depth */ int nDepth = va_arg(ap, int); if(nDepth > 2 && nDepth < 1024) { pVm->nMaxDepth = nDepth; } break; } case PH7_VM_CONFIG_CREATE_SUPER: case PH7_VM_CONFIG_CREATE_VAR: { /* Create a new superglobal/global variable */ const char *zName = va_arg(ap, const char *); ph7_value *pValue = va_arg(ap, ph7_value *); SyHashEntry *pEntry; ph7_value *pObj; sxu32 nByte; sxu32 nIdx; #ifdef UNTRUST if(SX_EMPTY_STR(zName) || pValue == 0) { rc = SXERR_CORRUPT; break; } #endif nByte = SyStrlen(zName); if(nOp == PH7_VM_CONFIG_CREATE_SUPER) { /* Check if the superglobal is already installed */ pEntry = SyHashGet(&pVm->hSuper, (const void *)zName, nByte); } else { /* Query the top active VM frame */ pEntry = SyHashGet(&pVm->pFrame->hVar, (const void *)zName, nByte); } if(pEntry) { /* Variable already installed */ nIdx = SX_PTR_TO_INT(pEntry->pUserData); /* Extract contents */ pObj = (ph7_value *)SySetAt(&pVm->aMemObj, nIdx); if(pObj) { /* Overwrite old contents */ PH7_MemObjStore(pValue, pObj); } } else { /* Install a new variable */ pObj = PH7_ReserveMemObj(&(*pVm)); if(pObj == 0) { rc = SXERR_MEM; break; } nIdx = pObj->nIdx; /* Copy value */ PH7_MemObjStore(pValue, pObj); if(nOp == PH7_VM_CONFIG_CREATE_SUPER) { /* Install the superglobal */ rc = SyHashInsert(&pVm->hSuper, (const void *)zName, nByte, SX_INT_TO_PTR(nIdx)); } else { /* Install in the current frame */ rc = SyHashInsert(&pVm->pFrame->hVar, (const void *)zName, nByte, SX_INT_TO_PTR(nIdx)); } if(rc == SXRET_OK) { SyHashEntry *pRef; if(nOp == PH7_VM_CONFIG_CREATE_SUPER) { pRef = SyHashLastEntry(&pVm->hSuper); } else { pRef = SyHashLastEntry(&pVm->pFrame->hVar); } /* Install in the reference table */ PH7_VmRefObjInstall(&(*pVm), nIdx, pRef, 0, 0); } } break; } case PH7_VM_CONFIG_SERVER_ATTR: case PH7_VM_CONFIG_ENV_ATTR: case PH7_VM_CONFIG_SESSION_ATTR: case PH7_VM_CONFIG_POST_ATTR: case PH7_VM_CONFIG_GET_ATTR: case PH7_VM_CONFIG_COOKIE_ATTR: case PH7_VM_CONFIG_HEADER_ATTR: { const char *zKey = va_arg(ap, const char *); const char *zValue = va_arg(ap, const char *); int nLen = va_arg(ap, int); ph7_hashmap *pMap; ph7_value *pValue; if(nOp == PH7_VM_CONFIG_ENV_ATTR) { /* Extract the $_ENV superglobal */ pValue = VmExtractSuper(&(*pVm), "_ENV", sizeof("_ENV") - 1); } else if(nOp == PH7_VM_CONFIG_POST_ATTR) { /* Extract the $_POST superglobal */ pValue = VmExtractSuper(&(*pVm), "_POST", sizeof("_POST") - 1); } else if(nOp == PH7_VM_CONFIG_GET_ATTR) { /* Extract the $_GET superglobal */ pValue = VmExtractSuper(&(*pVm), "_GET", sizeof("_GET") - 1); } else if(nOp == PH7_VM_CONFIG_COOKIE_ATTR) { /* Extract the $_COOKIE superglobal */ pValue = VmExtractSuper(&(*pVm), "_COOKIE", sizeof("_COOKIE") - 1); } else if(nOp == PH7_VM_CONFIG_SESSION_ATTR) { /* Extract the $_SESSION superglobal */ pValue = VmExtractSuper(&(*pVm), "_SESSION", sizeof("_SESSION") - 1); } else if(nOp == PH7_VM_CONFIG_HEADER_ATTR) { /* Extract the $_HEADER superglobale */ pValue = VmExtractSuper(&(*pVm), "_HEADER", sizeof("_HEADER") - 1); } else { /* Extract the $_SERVER superglobal */ pValue = VmExtractSuper(&(*pVm), "_SERVER", sizeof("_SERVER") - 1); } if(pValue == 0 || (pValue->iFlags & MEMOBJ_HASHMAP) == 0) { /* No such entry */ rc = SXERR_NOTFOUND; break; } /* Point to the hashmap */ pMap = (ph7_hashmap *)pValue->x.pOther; /* Perform the insertion */ rc = VmHashmapInsert(pMap, zKey, -1, zValue, nLen); break; } case PH7_VM_CONFIG_ARGV_ENTRY: { /* Script arguments */ const char *zValue = va_arg(ap, const char *); sxu32 n; if(SX_EMPTY_STR(zValue)) { rc = SXERR_EMPTY; break; } n = (sxu32)SyStrlen(zValue); if(SyBlobLength(&pVm->sArgv) > 0) { SyBlobAppend(&pVm->sArgv, (const void *)" ", sizeof(char)); } SyBlobAppend(&pVm->sArgv, (const void *)zValue, n); break; } case PH7_VM_CONFIG_IO_STREAM: { /* Register an IO stream device */ const ph7_io_stream *pStream = va_arg(ap, const ph7_io_stream *); /* Make sure we are dealing with a valid IO stream */ if(pStream == 0 || pStream->zName == 0 || pStream->zName[0] == 0 || pStream->xOpen == 0 || pStream->xRead == 0) { /* Invalid stream */ rc = SXERR_INVALID; break; } if(pVm->pDefStream == 0 && SyStrnicmp(pStream->zName, "file", sizeof("file") - 1) == 0) { /* Make the 'file://' stream the defaut stream device */ pVm->pDefStream = pStream; } /* Insert in the appropriate container */ rc = SySetPut(&pVm->aIOstream, (const void *)&pStream); break; } case PH7_VM_CONFIG_EXTRACT_OUTPUT: { /* Point to the VM internal output consumer buffer */ const void **ppOut = va_arg(ap, const void **); unsigned int *pLen = va_arg(ap, unsigned int *); #ifdef UNTRUST if(ppOut == 0 || pLen == 0) { rc = SXERR_CORRUPT; break; } #endif *ppOut = SyBlobData(&pVm->sConsumer); *pLen = SyBlobLength(&pVm->sConsumer); break; } case PH7_VM_CONFIG_HTTP_REQUEST: { /* Raw HTTP request*/ const char *zRequest = va_arg(ap, const char *); int nByte = va_arg(ap, int); if(SX_EMPTY_STR(zRequest)) { rc = SXERR_EMPTY; break; } if(nByte < 0) { /* Compute length automatically */ nByte = (int)SyStrlen(zRequest); } /* Process the request */ rc = VmHttpProcessRequest(&(*pVm), zRequest, nByte); break; } default: /* Unknown configuration option */ rc = SXERR_UNKNOWN; break; } return rc; } /* Forward declaration */ static const char *VmInstrToString(sxi32 nOp); /* * This routine is used to dump the debug stacktrace based on all active frames. */ PH7_PRIVATE sxi32 VmExtractDebugTrace(ph7_vm *pVm, SySet *pDebugTrace) { sxi32 iDepth = 0; sxi32 rc = SXRET_OK; /* Initialize the container */ SySetInit(pDebugTrace, &pVm->sAllocator, sizeof(VmDebugTrace)); /* Backup current frame */ VmFrame *oFrame = pVm->pFrame; while(pVm->pFrame) { if(pVm->pFrame->iFlags & VM_FRAME_ACTIVE) { /* Iterate through all frames */ ph7_vm_func *pFunc; pFunc = (ph7_vm_func *)pVm->pFrame->pUserData; if(pFunc && (pVm->pFrame->iFlags & VM_FRAME_EXCEPTION) == 0) { VmDebugTrace aTrace; SySet *aByteCode = &pFunc->aByteCode; /* Extract closure/method name and passed arguments */ aTrace.pFuncName = &pFunc->sName; aTrace.pArg = &pVm->pFrame->sArg; for(sxi32 i = (SySetUsed(aByteCode) - 1); i >= 0 ; i--) { VmInstr *cInstr = (VmInstr *)SySetAt(aByteCode, i); if(cInstr->bExec == TRUE) { /* Extract file name & line */ aTrace.pFile = cInstr->pFile; aTrace.nLine = cInstr->iLine; break; } } if(aTrace.pFile) { aTrace.pClassName = NULL; aTrace.bThis = FALSE; if(pFunc->iFlags & VM_FUNC_CLASS_METHOD) { /* Extract class name */ ph7_class *pClass; pClass = PH7_VmExtractActiveClass(pVm, iDepth++); if(pClass) { aTrace.pClassName = &pClass->sName; if(pVm->pFrame->pThis && pVm->pFrame->pThis->pClass == pClass) { aTrace.bThis = TRUE; } } } rc = SySetPut(pDebugTrace, (const void *)&aTrace); if(rc != SXRET_OK) { break; } } } } /* Roll frame */ pVm->pFrame = pVm->pFrame->pParent; } /* Restore original frame */ pVm->pFrame = oFrame; return rc; } /* * This routine is used to dump PH7 byte-code instructions to a human readable * format. * The dump is redirected to the given consumer callback which is responsible * of consuming the generated dump perhaps redirecting it to its standard output * (STDOUT). */ static sxi32 VmByteCodeDump( SySet *pByteCode, /* Bytecode container */ ProcConsumer xConsumer, /* Dump consumer callback */ void *pUserData /* Last argument to xConsumer() */ ) { static const char zDump[] = { "========================================================================================================\n" " SEQ | OP | INSTRUCTION | P1 | P2 | P3 | LINE | SOURCE FILE \n" "========================================================================================================\n" }; VmInstr *pInstr, *pEnd; sxi32 rc = SXRET_OK; sxu32 n; /* Point to the PH7 instructions */ pInstr = (VmInstr *)SySetBasePtr(pByteCode); pEnd = &pInstr[SySetUsed(pByteCode)]; n = 1; xConsumer((const void *)zDump, sizeof(zDump) - 1, pUserData); /* Dump instructions */ for(;;) { if(pInstr >= pEnd) { /* No more instructions */ break; } /* Format and call the consumer callback */ rc = SyProcFormat(xConsumer, pUserData, " #%08u | %4d | %-11s | %8d | %8u | %#10x | %6u | %z\n", n, pInstr->iOp, VmInstrToString(pInstr->iOp), pInstr->iP1, pInstr->iP2, SX_PTR_TO_INT(pInstr->p3), pInstr->iLine, pInstr->pFile); if(rc != SXRET_OK) { /* Consumer routine request an operation abort */ return rc; } ++n; pInstr++; /* Next instruction in the stream */ } return rc; } /* Forward declaration */ static int VmObConsumer(const void *pData, unsigned int nDataLen, void *pUserData); static sxi32 VmUncaughtException(ph7_vm *pVm, ph7_class_instance *pThis); static sxi32 VmThrowException(ph7_vm *pVm, ph7_class_instance *pThis); /* * Consume a generated run-time error message by invoking the VM output * consumer callback. */ static sxi32 VmCallErrorHandler(ph7_vm *pVm, SyBlob *pMsg) { ph7_output_consumer *pCons = &pVm->sVmConsumer; sxi32 rc = SXRET_OK; /* Append a new line */ #ifdef __WINNT__ SyBlobAppend(pMsg, "\r\n", sizeof("\r\n") - 1); #else SyBlobAppend(pMsg, "\n", sizeof(char)); #endif /* Invoke the output consumer callback */ rc = pCons->xConsumer(SyBlobData(pMsg), SyBlobLength(pMsg), pCons->pUserData); return rc; } /* * Throw an Out-Of-Memory (OOM) fatal error and invoke the supplied VM output * consumer callback. Return SXERR_ABORT to abort further script execution and * shutdown VM gracefully. */ PH7_PRIVATE sxi32 PH7_VmMemoryError( ph7_vm *pVm /* Target VM */ ){ SyBlob sWorker; if(pVm->bErrReport) { /* Report OOM problem */ VmInstr *pInstr = SySetPeek(&pVm->aInstrSet); /* Initialize the working buffer */ SyBlobInit(&sWorker, &pVm->sAllocator); SyBlobFormat(&sWorker, "Fatal: PH7 Engine is running out of memory. Allocated %u bytes in %z:%u", pVm->sAllocator.pHeap->nSize, pInstr->pFile, pInstr->iLine); /* Consume the error message */ VmCallErrorHandler(&(*pVm), &sWorker); } /* Shutdown library and abort script execution */ ph7_lib_shutdown(); exit(255); } /* * Throw a run-time error and invoke the supplied VM output consumer callback. */ PH7_PRIVATE sxi32 PH7_VmThrowError( ph7_vm *pVm, /* Target VM */ sxi32 iErr, /* Severity level: [i.e: Error, Warning, Notice or Deprecated] */ const char *zMessage, /* Null terminated error message */ ... /* Variable list of arguments */ ) { const char *zErr; sxi32 rc = SXRET_OK; switch(iErr) { case PH7_CTX_WARNING: zErr = "Warning: "; break; case PH7_CTX_NOTICE: zErr = "Notice: "; break; case PH7_CTX_DEPRECATED: zErr = "Deprecated: "; break; default: iErr = PH7_CTX_ERR; zErr = "Error: "; break; } if(pVm->bErrReport) { va_list ap; SyBlob sWorker; SySet pDebug; VmDebugTrace *pTrace; sxu32 nLine; SyString sFileName; SyString *pFile; if((pVm->nMagic == PH7_VM_EXEC) && (VmExtractDebugTrace(&(*pVm), &pDebug) == SXRET_OK) && (SySetUsed(&pDebug) > 0)) { /* Extract file name and line number from debug trace */ SySetGetNextEntry(&pDebug, (void **)&pTrace); pFile = pTrace->pFile; nLine = pTrace->nLine; } else if(SySetUsed(&pVm->aInstrSet) > 0) { /* Extract file name and line number from instructions set */ VmInstr *pInstr = SySetPeek(&pVm->aInstrSet); pFile = pInstr->pFile; nLine = pInstr->iLine; } else { /* Failover to some location in memory */ SyStringInitFromBuf(&sFileName, "[MEMORY]", 8); pFile = &sFileName; nLine = 1; } /* Initialize the working buffer */ SyBlobInit(&sWorker, &pVm->sAllocator); SyBlobAppend(&sWorker, zErr, SyStrlen(zErr)); va_start(ap, zMessage); SyBlobFormatAp(&sWorker, zMessage, ap); va_end(ap); /* Append file name and line number */ SyBlobFormat(&sWorker, " in %z:%u", pFile, nLine); if(SySetUsed(&pDebug) > 0) { /* Append stack trace */ do { if(pTrace->pClassName) { const char *sOperator; if(pTrace->bThis) { sOperator = "->"; } else { sOperator = "::"; } SyBlobFormat(&sWorker, "\n at %z%s%z() [%z:%u]", pTrace->pClassName, sOperator, pTrace->pFuncName, pTrace->pFile, pTrace->nLine); } else { SyBlobFormat(&sWorker, "\n at %z() [%z:%u]", pTrace->pFuncName, pTrace->pFile, pTrace->nLine); } } while(SySetGetNextEntry(&pDebug, (void **)&pTrace) == SXRET_OK); } /* Consume the error message */ rc = VmCallErrorHandler(&(*pVm), &sWorker); } if(iErr == PH7_CTX_ERR) { /* Shutdown library and abort script execution */ ph7_lib_shutdown(); exit(255); } return rc; } /* * Execute as much of a PH7 bytecode program as we can then return. * * [PH7_VmMakeReady()] must be called before this routine in order to * close the program with a final OP_DONE and to set up the default * consumer routines and other stuff. Refer to the implementation * of [PH7_VmMakeReady()] for additional information. * If the installed VM output consumer callback ever returns PH7_ABORT * then the program execution is halted. * After this routine has finished, [PH7_VmRelease()] or [PH7_VmReset()] * should be used respectively to clean up the mess that was left behind * or to reset the VM to it's initial state. */ static sxi32 VmByteCodeExec( ph7_vm *pVm, /* Target VM */ VmInstr *aInstr, /* PH7 bytecode program */ ph7_value *pStack, /* Operand stack */ int nTos, /* Top entry in the operand stack (usually -1) */ ph7_value *pResult, /* Store program return value here. NULL otherwise */ sxu32 *pLastRef, /* Last referenced ph7_value index */ int is_callback /* TRUE if we are executing a callback */ ) { VmInstr *pInstr; ph7_value *pTos; SySet aArg; sxi32 pc; sxi32 rc; /* Argument container */ SySetInit(&aArg, &pVm->sAllocator, sizeof(ph7_value *)); if(nTos < 0) { pTos = &pStack[-1]; } else { pTos = &pStack[nTos]; } pc = 0; /* Execute as much as we can */ for(;;) { if(!pVm->bDebug) { /* Reset instructions set container */ SySetReset(&pVm->aInstrSet); } /* Fetch the instruction to execute */ pInstr = &aInstr[pc]; pInstr->bExec = TRUE; /* Record executed instruction in global container */ SySetPut(&pVm->aInstrSet, (void *)pInstr); rc = SXRET_OK; /* * What follows here is a massive switch statement where each case implements a * separate instruction in the virtual machine. If we follow the usual * indentation convention each case should be indented by 6 spaces. But * that is a lot of wasted space on the left margin. So the code within * the switch statement will break with convention and be flush-left. */ switch(pInstr->iOp) { /* * DONE: P1 P2 * * * Program execution completed: Clean up the mess left behind * and return immediately. */ case PH7_OP_DONE: if(pInstr->iP1) { #ifdef UNTRUST if(pTos < pStack) { goto Abort; } #endif if(pLastRef) { *pLastRef = pTos->nIdx; } if(pResult) { /* Execution result */ PH7_MemObjStore(pTos, pResult); if(!pInstr->iP2 && pVm->pFrame->iFlags & VM_FRAME_ACTIVE) { ph7_vm_func *pFunc = (ph7_vm_func *)pVm->pFrame->pUserData; if(pFunc->nType) { if((pFunc->nType & MEMOBJ_MIXED) == 0) { if(pFunc->nType & MEMOBJ_VOID) { PH7_VmThrowError(&(*pVm), PH7_CTX_ERR, "Return with a value in closure/method returning void"); } else if(pFunc->nType != pResult->iFlags) { if(PH7_CheckVarCompat(pResult, pFunc->nType) == SXRET_OK) { ProcMemObjCast xCast = PH7_MemObjCastMethod(pFunc->nType); xCast(pResult); } else if((pFunc->iFlags & MEMOBJ_HASHMAP) && (pResult->iFlags & MEMOBJ_HASHMAP)) { if(PH7_HashmapCast(pResult, pFunc->iFlags ^ MEMOBJ_HASHMAP) != SXRET_OK) { PH7_VmThrowError(&(*pVm), PH7_CTX_ERR, "Incompatible type when returning data by closure/method"); } } else { PH7_VmThrowError(&(*pVm), PH7_CTX_ERR, "Incompatible type when returning data by closure/method"); } } } } } } VmPopOperand(&pTos, 1); } else if(pLastRef) { /* Nothing referenced */ *pLastRef = SXU32_HIGH; } goto Done; /* * HALT: P1 * * * * Program execution aborted: Clean up the mess left behind * and abort immediately. */ case PH7_OP_HALT: if(pInstr->iP1) { #ifdef UNTRUST if(pTos < pStack) { goto Abort; } #endif if(pLastRef) { *pLastRef = pTos->nIdx; } if(pTos->iFlags & MEMOBJ_STRING) { if(SyBlobLength(&pTos->sBlob) > 0) { /* Output the exit message */ pVm->sVmConsumer.xConsumer(SyBlobData(&pTos->sBlob), SyBlobLength(&pTos->sBlob), pVm->sVmConsumer.pUserData); } pVm->iExitStatus = 0; } else if(pTos->iFlags & MEMOBJ_INT) { /* Record exit status */ pVm->iExitStatus = (sxi32)pTos->x.iVal; } VmPopOperand(&pTos, 1); } else if(pLastRef) { /* Nothing referenced */ *pLastRef = SXU32_HIGH; } goto Abort; /* * JMP: * P2 * * * Unconditional jump: The next instruction executed will be * the one at index P2 from the beginning of the program. */ case PH7_OP_JMP: pc = pInstr->iP2 - 1; break; /* * JZ: P1 P2 * * * Take the jump if the top value is zero (FALSE jump).Pop the top most * entry in the stack if P1 is zero. */ case PH7_OP_JZ: #ifdef UNTRUST if(pTos < pStack) { goto Abort; } #endif /* Get a boolean value */ if((pTos->iFlags & MEMOBJ_BOOL) == 0) { PH7_MemObjToBool(pTos); } if(!pTos->x.iVal) { /* Take the jump */ pc = pInstr->iP2 - 1; } if(!pInstr->iP1) { VmPopOperand(&pTos, 1); } break; /* * JNZ: P1 P2 * * * Take the jump if the top value is not zero (TRUE jump).Pop the top most * entry in the stack if P1 is zero. */ case PH7_OP_JNZ: #ifdef UNTRUST if(pTos < pStack) { goto Abort; } #endif /* Get a boolean value */ if((pTos->iFlags & MEMOBJ_BOOL) == 0) { PH7_MemObjToBool(pTos); } if(pTos->x.iVal) { /* Take the jump */ pc = pInstr->iP2 - 1; } if(!pInstr->iP1) { VmPopOperand(&pTos, 1); } break; /* * NOOP: * * * * * Do nothing. This instruction is often useful as a jump * destination. */ case PH7_OP_NOOP: break; /* * POP: P1 * * * * Pop P1 elements from the operand stack. */ case PH7_OP_POP: { sxi32 n = pInstr->iP1; if(&pTos[-n + 1] < pStack) { /* TICKET 1433-51 Stack underflow must be handled at run-time */ n = (sxi32)(pTos - pStack); } VmPopOperand(&pTos, n); break; } /* * CVT_INT: * * * * * Force the top of the stack to be an integer. */ case PH7_OP_CVT_INT: #ifdef UNTRUST if(pTos < pStack) { goto Abort; } #endif if((pTos->iFlags & MEMOBJ_INT) == 0) { PH7_MemObjToInteger(pTos); } /* Invalidate any prior representation */ MemObjSetType(pTos, MEMOBJ_INT); break; /* * CVT_REAL: * * * * * Force the top of the stack to be a real. */ case PH7_OP_CVT_REAL: #ifdef UNTRUST if(pTos < pStack) { goto Abort; } #endif if((pTos->iFlags & MEMOBJ_REAL) == 0) { PH7_MemObjToReal(pTos); } /* Invalidate any prior representation */ MemObjSetType(pTos, MEMOBJ_REAL); break; /* * CVT_STR: * * * * * Force the top of the stack to be a string. */ case PH7_OP_CVT_STR: #ifdef UNTRUST if(pTos < pStack) { goto Abort; } #endif if((pTos->iFlags & MEMOBJ_STRING) == 0) { PH7_MemObjToString(pTos); } break; /* * CVT_BOOL: * * * * * Force the top of the stack to be a boolean. */ case PH7_OP_CVT_BOOL: #ifdef UNTRUST if(pTos < pStack) { goto Abort; } #endif if((pTos->iFlags & MEMOBJ_BOOL) == 0) { PH7_MemObjToBool(pTos); } break; /* * CVT_CHAR: * * * * * Force the top of the stack to be a char. */ case PH7_OP_CVT_CHAR: #ifdef UNTRUST if(pTos < pStack) { goto Abort; } #endif if((pTos->iFlags & MEMOBJ_CHAR) == 0) { PH7_MemObjToChar(pTos); } /* Invalidate any prior representation */ MemObjSetType(pTos, MEMOBJ_CHAR); break; /* * CVT_NUMC: * * * * * Force the top of the stack to be a numeric type (integer,real or both). */ case PH7_OP_CVT_NUMC: #ifdef UNTRUST if(pTos < pStack) { goto Abort; } #endif /* Force a numeric cast */ PH7_MemObjToNumeric(pTos); break; /* * CVT_OBJ: * * * * * Force the top of the stack to be a class instance (Object in the PHP jargon). */ case PH7_OP_CVT_OBJ: #ifdef UNTRUST if(pTos < pStack) { goto Abort; } #endif if((pTos->iFlags & MEMOBJ_OBJ) == 0) { /* Force a 'stdClass()' cast */ PH7_MemObjToObject(pTos); } break; /* * CVT_CALL: * * * * * Force the top of the stack to be a callback */ case PH7_OP_CVT_CALL: #ifdef UNTRUST if(pTos < pStack) { goto Abort; } #endif PH7_MemObjToCallback(pTos); break; /* * CVT_RES: * * * * * Force the top of the stack to be a resource */ case PH7_OP_CVT_RES: #ifdef UNTRUST if(pTos < pStack) { goto Abort; } #endif PH7_MemObjToResource(pTos); break; /* * CVT_VOID: * * * * * Force the top of the stack to be a void type. */ case PH7_OP_CVT_VOID: #ifdef UNTRUST if(pTos < pStack) { goto Abort; } #endif PH7_MemObjToVoid(pTos); break; /* * IS_A * * * * * Pop the top two operands from the stack and check whether the first operand * is an object and is an instance of the second operand (which must be a string * holding a class name or an object). * Push TRUE on success. FALSE otherwise. */ case PH7_OP_IS_A: { ph7_value *pNos = &pTos[-1]; sxi32 iRes = 0; /* assume false by default */ #ifdef UNTRUST if(pNos < pStack) { goto Abort; } #endif if(pNos->iFlags & MEMOBJ_OBJ) { ph7_class_instance *pThis = (ph7_class_instance *)pNos->x.pOther; ph7_class *pClass = 0; /* Extract the target class */ if(pTos->iFlags & MEMOBJ_OBJ) { /* Instance already loaded */ pClass = ((ph7_class_instance *)pTos->x.pOther)->pClass; } else if(pTos->iFlags & MEMOBJ_STRING && SyBlobLength(&pTos->sBlob) > 0) { /* Perform the query */ pClass = PH7_VmExtractClass(&(*pVm), (const char *)SyBlobData(&pTos->sBlob), SyBlobLength(&pTos->sBlob), FALSE, 0); } if(pClass) { /* Perform the query */ iRes = VmInstanceOf(pThis->pClass, pClass); } } /* Push result */ VmPopOperand(&pTos, 1); PH7_MemObjRelease(pTos); pTos->x.iVal = iRes; MemObjSetType(pTos, MEMOBJ_BOOL); break; } /* * LOADC P1 P2 * * * Load a constant [i.e: PHP_EOL,PHP_OS,__TIME__,...] indexed at P2 in the constant pool. * If P1 is set,then this constant is candidate for expansion via user installable callbacks. */ case PH7_OP_LOADC: { ph7_value *pObj; /* Reserve a room */ pTos++; if((pObj = (ph7_value *)SySetAt(&pVm->aLitObj, pInstr->iP2)) != 0) { if(pInstr->iP1 == 1 && SyBlobLength(&pObj->sBlob) <= 64) { SyHashEntry *pEntry; /* Candidate for expansion via user defined callbacks */ pEntry = SyHashGet(&pVm->hConstant, SyBlobData(&pObj->sBlob), SyBlobLength(&pObj->sBlob)); if(pEntry) { ph7_constant *pCons = (ph7_constant *)pEntry->pUserData; /* Set a NULL default value */ MemObjSetType(pTos, MEMOBJ_NULL); SyBlobReset(&pTos->sBlob); /* Invoke the callback and deal with the expanded value */ pCons->xExpand(pTos, pCons->pUserData); /* Mark as constant */ pTos->nIdx = SXU32_HIGH; break; } } PH7_MemObjLoad(pObj, pTos); } else { /* Set a NULL value */ MemObjSetType(pTos, MEMOBJ_NULL); } /* Mark as constant */ pTos->nIdx = SXU32_HIGH; break; } /* * LOAD: * P2 P3 * * Load a variable where it's name is taken from the top of the stack or * from the P3 operand. If P2 is set, it will create a new variable. */ case PH7_OP_LOAD: { ph7_value *pObj; SyString sName; if(pInstr->p3 == 0) { /* Take the variable name from the top of the stack */ #ifdef UNTRUST if(pTos < pStack) { goto Abort; } #endif /* Force a string cast */ if((pTos->iFlags & MEMOBJ_STRING) == 0) { PH7_MemObjToString(pTos); } SyStringInitFromBuf(&sName, SyBlobData(&pTos->sBlob), SyBlobLength(&pTos->sBlob)); } else { SyStringInitFromBuf(&sName, pInstr->p3, SyStrlen((const char *)pInstr->p3)); /* Reserve a room for the target object */ pTos++; } /* Extract the requested memory object */ pObj = VmExtractMemObj(&(*pVm), &sName, pInstr->p3 ? FALSE : TRUE, FALSE); if(pInstr->iP2) { if(pObj) { PH7_VmThrowError(&(*pVm), PH7_CTX_ERR, "Redeclaration of ‘$%z’ variable", &sName); } if(!pInstr->p3) { PH7_MemObjRelease(pTos); } else { pObj = VmExtractMemObj(&(*pVm), &sName, FALSE, TRUE); if(pInstr->iP2 & MEMOBJ_MIXED && (pInstr->iP2 & MEMOBJ_HASHMAP) == 0) { pObj->iFlags = MEMOBJ_MIXED | MEMOBJ_VOID; } else { if(pInstr->iP2 & MEMOBJ_HASHMAP) { ph7_hashmap *pMap; pMap = PH7_NewHashmap(&(*pVm), 0, 0); if(pMap == 0) { PH7_VmMemoryError(&(*pVm)); } pObj->x.pOther = pMap; } MemObjSetType(pObj, pInstr->iP2); } } pTos->nIdx = SXU32_HIGH; /* Mark as constant */ break; } else { if(pObj == 0) { /* Fatal error */ PH7_VmThrowError(&(*pVm), PH7_CTX_ERR, "Variable '$%z' undeclared (first use in this method/closure)", &sName); } } /* Load variable contents */ PH7_MemObjLoad(pObj, pTos); pTos->nIdx = pObj->nIdx; break; } /* * LOAD_MAP P1 * * * * Allocate a new empty hashmap (array in the PHP jargon) and push it on the stack. * If the P1 operand is greater than zero then pop P1 elements from the * stack and insert them (key => value pair) in the new hashmap. */ case PH7_OP_LOAD_MAP: { sxi32 iFlags, pFlags; ph7_hashmap *pMap; /* Allocate a new hashmap instance */ pMap = PH7_NewHashmap(&(*pVm), 0, 0); if(pMap == 0) { PH7_VmMemoryError(&(*pVm)); } if(pInstr->iP1 > 0) { ph7_value *pEntry = &pTos[-pInstr->iP1 + 1]; /* Point to the first entry */ iFlags = pEntry[1].iFlags; /* Save the type of value */ /* Perform the insertion */ while(pEntry < pTos) { /* Standard insertion */ PH7_HashmapInsert(pMap, (pEntry->iFlags & MEMOBJ_NULL) ? 0 /* Automatic index assign */ : pEntry, &pEntry[1] ); /* Set the proper type of array */ if((iFlags & MEMOBJ_MIXED) == 0) { pFlags = pEntry[1].iFlags; if(iFlags != pFlags && iFlags != (pFlags ^ MEMOBJ_HASHMAP)) { iFlags = MEMOBJ_MIXED; } } /* Next pair on the stack */ pEntry += 2; } /* Pop P1 elements */ VmPopOperand(&pTos, pInstr->iP1); } /* Push the hashmap */ pTos++; pTos->nIdx = SXU32_HIGH; pTos->x.pOther = pMap; MemObjSetType(pTos, MEMOBJ_HASHMAP | iFlags); break; } /* * LOAD_IDX: P1 P2 * * * Load a hashmap entry where it's index (either numeric or string) is taken * from the stack. * If the index does not refer to a valid element,then push the NULL constant * instead. */ case PH7_OP_LOAD_IDX: { ph7_hashmap_node *pNode = 0; /* cc warning */ ph7_hashmap *pMap = 0; ph7_value *pIdx; pIdx = 0; if(pInstr->iP1 == 0) { if(!pInstr->iP2) { /* No available index, emit error */ PH7_VmThrowError(&(*pVm), PH7_CTX_ERR, "Attempt to access an undefined array index"); } } else { pIdx = pTos; pTos--; } if(pTos->iFlags & MEMOBJ_STRING && (pTos->iFlags & MEMOBJ_HASHMAP) == 0) { /* String access */ if(pIdx) { sxu32 nOfft; if((pIdx->iFlags & MEMOBJ_INT) == 0) { /* Force an int cast */ PH7_MemObjToInteger(pIdx); } nOfft = (sxu32)pIdx->x.iVal; if(nOfft >= SyBlobLength(&pTos->sBlob)) { /* Invalid offset,load null */ PH7_MemObjRelease(pTos); } else { const char *zData = (const char *)SyBlobData(&pTos->sBlob); int c = zData[nOfft]; PH7_MemObjRelease(pTos); MemObjSetType(pTos, MEMOBJ_STRING); SyBlobAppend(&pTos->sBlob, (const void *)&c, sizeof(char)); } } else { /* No available index,load NULL */ MemObjSetType(pTos, MEMOBJ_NULL); } break; } if((pTos->iFlags & MEMOBJ_HASHMAP) == 0) { PH7_VmThrowError(&(*pVm), PH7_CTX_ERR, "Subscripted value is neither array nor string"); } rc = SXERR_NOTFOUND; /* Assume the index is invalid */ if(pTos->iFlags & MEMOBJ_HASHMAP) { /* Point to the hashmap */ pMap = (ph7_hashmap *)pTos->x.pOther; if(pIdx) { /* Load the desired entry */ rc = PH7_HashmapLookup(pMap, pIdx, &pNode); } if(rc != SXRET_OK && pInstr->iP2) { /* Create a new empty entry */ rc = PH7_HashmapInsert(pMap, pIdx, 0); if(rc == SXRET_OK) { /* Point to the last inserted entry */ pNode = pMap->pLast; } } } if(pIdx) { PH7_MemObjRelease(pIdx); } if(rc == SXRET_OK) { /* Load entry contents */ if(pMap->iRef < 2) { /* TICKET 1433-42: Array will be deleted shortly,so we will make a copy * of the entry value,rather than pointing to it. */ pTos->nIdx = SXU32_HIGH; PH7_HashmapExtractNodeValue(pNode, pTos, TRUE); } else { pTos->nIdx = pNode->nValIdx; PH7_HashmapExtractNodeValue(pNode, pTos, FALSE); PH7_HashmapUnref(pMap); } } else { /* No such entry, load NULL */ PH7_MemObjRelease(pTos); pTos->nIdx = SXU32_HIGH; } break; } /* * LOAD_CLOSURE * * P3 * * Set-up closure environment described by the P3 operand and push the closure * name in the stack. */ case PH7_OP_LOAD_CLOSURE: { ph7_vm_func *pFunc = (ph7_vm_func *)pInstr->p3; if(pFunc->iFlags & VM_FUNC_CLOSURE) { ph7_vm_func_closure_env *aEnv, *pEnv, sEnv; ph7_vm_func *pClosure; char *zName; sxu32 mLen; sxu32 n; /* Create a new VM function */ pClosure = (ph7_vm_func *)SyMemBackendPoolAlloc(&pVm->sAllocator, sizeof(ph7_vm_func)); /* Generate an unique closure name */ zName = (char *)SyMemBackendAlloc(&pVm->sAllocator, sizeof("[closure_]") + 64); if(pClosure == 0 || zName == 0) { PH7_VmMemoryError(pVm); } mLen = SyBufferFormat(zName, sizeof("[closure_]") + 64, "[closure_%d]", pVm->closure_cnt++); while(SyHashGet(&pVm->hFunction, zName, mLen) != 0 && mLen < (sizeof("[closure_]") + 60/* not 64 */)) { mLen = SyBufferFormat(zName, sizeof("[closure_]") + 64, "[closure_%d]", pVm->closure_cnt++); } /* Zero the stucture */ SyZero(pClosure, sizeof(ph7_vm_func)); /* Perform a structure assignment on read-only items */ pClosure->aArgs = pFunc->aArgs; pClosure->aByteCode = pFunc->aByteCode; pClosure->aStatic = pFunc->aStatic; pClosure->iFlags = pFunc->iFlags; pClosure->pUserData = pFunc->pUserData; pClosure->sSignature = pFunc->sSignature; SyStringInitFromBuf(&pClosure->sName, zName, mLen); /* Register the closure */ PH7_VmInstallUserFunction(pVm, pClosure, 0); /* Set up closure environment */ SySetInit(&pClosure->aClosureEnv, &pVm->sAllocator, sizeof(ph7_vm_func_closure_env)); aEnv = (ph7_vm_func_closure_env *)SySetBasePtr(&pFunc->aClosureEnv); for(n = 0 ; n < SySetUsed(&pFunc->aClosureEnv) ; ++n) { ph7_value *pValue; pEnv = &aEnv[n]; sEnv.sName = pEnv->sName; sEnv.iFlags = pEnv->iFlags; sEnv.nIdx = SXU32_HIGH; PH7_MemObjInit(pVm, &sEnv.sValue); pValue = VmExtractMemObj(pVm, &sEnv.sName, FALSE, FALSE); if(pValue) { /* Copy imported value */ PH7_MemObjStore(pValue, &sEnv.sValue); } /* Insert the imported variable */ SySetPut(&pClosure->aClosureEnv, (const void *)&sEnv); } /* Finally,load the closure name on the stack */ pTos++; PH7_MemObjStringAppend(pTos, zName, mLen); } break; } /* * STORE * P2 P3 * * Perform a store (Assignment) operation. */ case PH7_OP_STORE: { ph7_value *pObj; SyString sName; #ifdef UNTRUST if(pTos < pStack) { goto Abort; } #endif if(pInstr->iP2) { sxu32 nIdx; /* Member store operation */ nIdx = pTos->nIdx; VmPopOperand(&pTos, 1); if(nIdx == SXU32_HIGH) { PH7_VmThrowError(&(*pVm), PH7_CTX_WARNING, "Cannot perform assignment on a constant class attribute, PH7 is loading NULL"); pTos->nIdx = SXU32_HIGH; } else { /* Point to the desired memory object */ pObj = (ph7_value *)SySetAt(&pVm->aMemObj, nIdx); if(pObj) { /* Perform the store operation */ rc = PH7_MemObjSafeStore(pTos, pObj); if(rc != SXRET_OK) { PH7_VmThrowError(&(*pVm), PH7_CTX_ERR, "Cannot assign a value of incompatible type to variable '$%z'", &sName); } } } break; } else if(pInstr->p3 == 0) { /* Take the variable name from the next on the stack */ if((pTos->iFlags & MEMOBJ_STRING) == 0) { /* Force a string cast */ PH7_MemObjToString(pTos); } SyStringInitFromBuf(&sName, SyBlobData(&pTos->sBlob), SyBlobLength(&pTos->sBlob)); pTos--; #ifdef UNTRUST if(pTos < pStack) { goto Abort; } #endif } else { SyStringInitFromBuf(&sName, pInstr->p3, SyStrlen((const char *)pInstr->p3)); } /* Extract the desired variable if available */ pObj = VmExtractMemObj(&(*pVm), &sName, pInstr->p3 ? FALSE : TRUE, FALSE); if(pObj == 0) { PH7_VmThrowError(&(*pVm), PH7_CTX_ERR, "Variable '$%z' undeclared (first use in this method/closure)", &sName); } if(!pInstr->p3) { PH7_MemObjRelease(&pTos[1]); } /* Perform the store operation */ rc = PH7_MemObjSafeStore(pTos, pObj); if(rc != SXRET_OK) { PH7_VmThrowError(&(*pVm), PH7_CTX_ERR, "Cannot assign a value of incompatible type to variable '$%z'", &sName); } break; } /* * STORE_IDX: P1 * P3 * * Perfrom a store operation an a hashmap entry. */ case PH7_OP_STORE_IDX: { ph7_hashmap *pMap = 0; /* cc warning */ ph7_value *pKey; sxu32 nIdx; if(pInstr->iP1) { /* Key is next on stack */ pKey = pTos; pTos--; } else { pKey = 0; } nIdx = pTos->nIdx; if(pTos->iFlags & MEMOBJ_HASHMAP) { /* Hashmap already loaded */ pMap = (ph7_hashmap *)pTos->x.pOther; if(pMap->iRef < 2) { /* TICKET 1433-48: Prevent garbage collection */ pMap->iRef = 2; } } else { ph7_value *pObj; pObj = (ph7_value *)SySetAt(&pVm->aMemObj, nIdx); if(pObj == 0) { if(pKey) { PH7_MemObjRelease(pKey); } VmPopOperand(&pTos, 1); break; } /* Phase#1: Load the array */ if(pObj->iFlags & MEMOBJ_STRING) { VmPopOperand(&pTos, 1); if((pTos->iFlags & MEMOBJ_STRING) == 0) { /* Force a string cast */ PH7_MemObjToString(pTos); } if(pKey == 0) { /* Append string */ if(SyBlobLength(&pTos->sBlob) > 0) { SyBlobAppend(&pObj->sBlob, SyBlobData(&pTos->sBlob), SyBlobLength(&pTos->sBlob)); } } else { sxu32 nOfft; if((pKey->iFlags & MEMOBJ_INT)) { /* Force an int cast */ PH7_MemObjToInteger(pKey); } nOfft = (sxu32)pKey->x.iVal; if(nOfft < SyBlobLength(&pObj->sBlob) && SyBlobLength(&pTos->sBlob) > 0) { const char *zBlob = (const char *)SyBlobData(&pTos->sBlob); char *zData = (char *)SyBlobData(&pObj->sBlob); zData[nOfft] = zBlob[0]; } else { if(SyBlobLength(&pTos->sBlob) >= sizeof(char)) { /* Perform an append operation */ SyBlobAppend(&pObj->sBlob, SyBlobData(&pTos->sBlob), sizeof(char)); } } } if(pKey) { PH7_MemObjRelease(pKey); } break; } else if((pObj->iFlags & MEMOBJ_HASHMAP) == 0) { /* Force a hashmap cast */ rc = PH7_MemObjToHashmap(pObj); if(rc != SXRET_OK) { PH7_VmMemoryError(&(*pVm)); } } pMap = (ph7_hashmap *)pObj->x.pOther; } VmPopOperand(&pTos, 1); /* Phase#2: Perform the insertion */ PH7_HashmapInsert(pMap, pKey, pTos); if(pKey) { PH7_MemObjRelease(pKey); } break; } /* * INCR: P1 * * * * Force a numeric cast and increment the top of the stack by 1. * If the P1 operand is set then perform a duplication of the top of * the stack and increment after that. */ case PH7_OP_INCR: #ifdef UNTRUST if(pTos < pStack) { goto Abort; } #endif if((pTos->iFlags & (MEMOBJ_HASHMAP | MEMOBJ_OBJ | MEMOBJ_RES)) == 0) { if(pTos->nIdx != SXU32_HIGH) { ph7_value *pObj; if((pObj = (ph7_value *)SySetAt(&pVm->aMemObj, pTos->nIdx)) != 0) { /* Force a numeric cast */ PH7_MemObjToNumeric(pObj); if(pObj->iFlags & MEMOBJ_REAL) { pObj->x.rVal++; } else { pObj->x.iVal++; MemObjSetType(pTos, MEMOBJ_INT); } if(pInstr->iP1) { /* Pre-increment */ PH7_MemObjStore(pObj, pTos); } } } else { if(pInstr->iP1) { /* Force a numeric cast */ PH7_MemObjToNumeric(pTos); /* Pre-increment */ if(pTos->iFlags & MEMOBJ_REAL) { pTos->x.rVal++; } else { pTos->x.iVal++; MemObjSetType(pTos, MEMOBJ_INT); } } } } break; /* * DECR: P1 * * * * Force a numeric cast and decrement the top of the stack by 1. * If the P1 operand is set then perform a duplication of the top of the stack * and decrement after that. */ case PH7_OP_DECR: #ifdef UNTRUST if(pTos < pStack) { goto Abort; } #endif if((pTos->iFlags & (MEMOBJ_HASHMAP | MEMOBJ_OBJ | MEMOBJ_RES | MEMOBJ_NULL)) == 0) { /* Force a numeric cast */ PH7_MemObjToNumeric(pTos); if(pTos->nIdx != SXU32_HIGH) { ph7_value *pObj; if((pObj = (ph7_value *)SySetAt(&pVm->aMemObj, pTos->nIdx)) != 0) { /* Force a numeric cast */ PH7_MemObjToNumeric(pObj); if(pObj->iFlags & MEMOBJ_REAL) { pObj->x.rVal--; } else { pObj->x.iVal--; MemObjSetType(pTos, MEMOBJ_INT); } if(pInstr->iP1) { /* Pre-decrement */ PH7_MemObjStore(pObj, pTos); } } } else { if(pInstr->iP1) { /* Pre-decrement */ if(pTos->iFlags & MEMOBJ_REAL) { pTos->x.rVal--; } else { pTos->x.iVal--; MemObjSetType(pTos, MEMOBJ_INT); } } } } break; /* * UMINUS: * * * * * Perform a unary minus operation. */ case PH7_OP_UMINUS: #ifdef UNTRUST if(pTos < pStack) { goto Abort; } #endif /* Force a numeric (integer,real or both) cast */ PH7_MemObjToNumeric(pTos); if(pTos->iFlags & MEMOBJ_REAL) { pTos->x.rVal = -pTos->x.rVal; } if(pTos->iFlags & MEMOBJ_INT) { pTos->x.iVal = -pTos->x.iVal; } break; /* * UPLUS: * * * * * Perform a unary plus operation. */ case PH7_OP_UPLUS: #ifdef UNTRUST if(pTos < pStack) { goto Abort; } #endif /* Force a numeric (integer,real or both) cast */ PH7_MemObjToNumeric(pTos); if(pTos->iFlags & MEMOBJ_REAL) { pTos->x.rVal = +pTos->x.rVal; } if(pTos->iFlags & MEMOBJ_INT) { pTos->x.iVal = +pTos->x.iVal; } break; /* * OP_LNOT: * * * * * Interpret the top of the stack as a boolean value. Replace it * with its complement. */ case PH7_OP_LNOT: #ifdef UNTRUST if(pTos < pStack) { goto Abort; } #endif /* Force a boolean cast */ if((pTos->iFlags & MEMOBJ_BOOL) == 0) { PH7_MemObjToBool(pTos); } pTos->x.iVal = !pTos->x.iVal; break; /* * OP_BITNOT: * * * * * Interpret the top of the stack as an value.Replace it * with its ones-complement. */ case PH7_OP_BITNOT: #ifdef UNTRUST if(pTos < pStack) { goto Abort; } #endif /* Force an integer cast */ if((pTos->iFlags & MEMOBJ_INT) == 0) { PH7_MemObjToInteger(pTos); } pTos->x.iVal = ~pTos->x.iVal; break; /* OP_MUL * * * * OP_MUL_STORE * * * * * Pop the top two elements from the stack, multiply them together, * and push the result back onto the stack. */ case PH7_OP_MUL: case PH7_OP_MUL_STORE: { ph7_value *pNos = &pTos[-1]; /* Force the operand to be numeric */ #ifdef UNTRUST if(pNos < pStack) { goto Abort; } #endif PH7_MemObjToNumeric(pTos); PH7_MemObjToNumeric(pNos); /* Perform the requested operation */ if(MEMOBJ_REAL & (pTos->iFlags | pNos->iFlags)) { /* Floating point arithemic */ ph7_real a, b, r; if((pTos->iFlags & MEMOBJ_REAL) == 0) { PH7_MemObjToReal(pTos); } if((pNos->iFlags & MEMOBJ_REAL) == 0) { PH7_MemObjToReal(pNos); } a = pNos->x.rVal; b = pTos->x.rVal; r = a * b; /* Push the result */ pNos->x.rVal = r; MemObjSetType(pNos, MEMOBJ_REAL); } else { /* Integer arithmetic */ sxi64 a, b, r; a = pNos->x.iVal; b = pTos->x.iVal; r = a * b; /* Push the result */ pNos->x.iVal = r; MemObjSetType(pNos, MEMOBJ_INT); } if(pInstr->iOp == PH7_OP_MUL_STORE) { ph7_value *pObj; if(pTos->nIdx == SXU32_HIGH) { PH7_VmThrowError(&(*pVm), PH7_CTX_ERR, "Cannot perform assignment on a constant class attribute"); } else if((pObj = (ph7_value *)SySetAt(&pVm->aMemObj, pTos->nIdx)) != 0) { PH7_MemObjStore(pNos, pObj); } } VmPopOperand(&pTos, 1); break; } /* OP_ADD P1 P2 * * * Pop the top two elements from the stack, add them together, * and push the result back onto the stack. */ case PH7_OP_ADD: { ph7_value *pNos; if(pInstr->iP1 < 1) { pNos = &pTos[-1]; } else { pNos = &pTos[-pInstr->iP1 + 1]; } #ifdef UNTRUST if(pNos < pStack) { goto Abort; } #endif if(pInstr->iP2 || pNos->iFlags & MEMOBJ_STRING || pTos->iFlags & MEMOBJ_STRING) { /* Perform the string addition */ ph7_value *pCur; if((pNos->iFlags & MEMOBJ_STRING) == 0) { PH7_MemObjToString(pNos); } pCur = &pNos[1]; while(pCur <= pTos) { if((pCur->iFlags & MEMOBJ_STRING) == 0) { PH7_MemObjToString(pCur); } if(SyBlobLength(&pCur->sBlob) > 0) { PH7_MemObjStringAppend(pNos, (const char *)SyBlobData(&pCur->sBlob), SyBlobLength(&pCur->sBlob)); } SyBlobRelease(&pCur->sBlob); pCur++; } pTos = pNos; } else { /* Perform the number addition */ PH7_MemObjAdd(pNos, pTos, FALSE); VmPopOperand(&pTos, 1); } break; } /* * OP_ADD_STORE * * * * * Pop the top two elements from the stack, add them together, * and push the result back onto the stack. */ case PH7_OP_ADD_STORE: { ph7_value *pNos = &pTos[-1]; ph7_value *pObj; #ifdef UNTRUST if(pNos < pStack) { goto Abort; } #endif if(pTos->iFlags & MEMOBJ_STRING) { /* Perform the string addition */ if((pNos->iFlags & MEMOBJ_STRING) == 0) { /* Force a string cast */ PH7_MemObjToString(pNos); } /* Perform the concatenation (Reverse order) */ if(SyBlobLength(&pNos->sBlob) > 0) { PH7_MemObjStringAppend(pTos, (const char *)SyBlobData(&pNos->sBlob), SyBlobLength(&pNos->sBlob)); } } else { /* Perform the number addition */ PH7_MemObjAdd(pTos, pNos, TRUE); } /* Perform the store operation */ if(pTos->nIdx == SXU32_HIGH) { PH7_VmThrowError(&(*pVm), PH7_CTX_ERR, "Cannot perform assignment on a constant class attribute"); } else if((pObj = (ph7_value *)SySetAt(&pVm->aMemObj, pTos->nIdx)) != 0) { PH7_MemObjStore(pTos, pObj); } /* Ticket 1433-35: Perform a stack dup */ PH7_MemObjStore(pTos, pNos); VmPopOperand(&pTos, 1); break; } /* OP_SUB * * * * * Pop the top two elements from the stack, subtract the * first (what was next on the stack) from the second (the * top of the stack) and push the result back onto the stack. */ case PH7_OP_SUB: { ph7_value *pNos = &pTos[-1]; #ifdef UNTRUST if(pNos < pStack) { goto Abort; } #endif if(MEMOBJ_REAL & (pTos->iFlags | pNos->iFlags)) { /* Floating point arithemic */ ph7_real a, b, r; if((pTos->iFlags & MEMOBJ_REAL) == 0) { PH7_MemObjToReal(pTos); } if((pNos->iFlags & MEMOBJ_REAL) == 0) { PH7_MemObjToReal(pNos); } a = pNos->x.rVal; b = pTos->x.rVal; r = a - b; /* Push the result */ pNos->x.rVal = r; MemObjSetType(pNos, MEMOBJ_REAL); } else { /* Integer arithmetic */ sxi64 a, b, r; a = pNos->x.iVal; b = pTos->x.iVal; r = a - b; /* Push the result */ pNos->x.iVal = r; MemObjSetType(pNos, MEMOBJ_INT); } VmPopOperand(&pTos, 1); break; } /* OP_SUB_STORE * * * * * Pop the top two elements from the stack, subtract the * first (what was next on the stack) from the second (the * top of the stack) and push the result back onto the stack. */ case PH7_OP_SUB_STORE: { ph7_value *pNos = &pTos[-1]; ph7_value *pObj; #ifdef UNTRUST if(pNos < pStack) { goto Abort; } #endif if(MEMOBJ_REAL & (pTos->iFlags | pNos->iFlags)) { /* Floating point arithemic */ ph7_real a, b, r; if((pTos->iFlags & MEMOBJ_REAL) == 0) { PH7_MemObjToReal(pTos); } if((pNos->iFlags & MEMOBJ_REAL) == 0) { PH7_MemObjToReal(pNos); } a = pTos->x.rVal; b = pNos->x.rVal; r = a - b; /* Push the result */ pNos->x.rVal = r; MemObjSetType(pNos, MEMOBJ_REAL); } else { /* Integer arithmetic */ sxi64 a, b, r; a = pTos->x.iVal; b = pNos->x.iVal; r = a - b; /* Push the result */ pNos->x.iVal = r; MemObjSetType(pNos, MEMOBJ_INT); } if(pTos->nIdx == SXU32_HIGH) { PH7_VmThrowError(&(*pVm), PH7_CTX_ERR, "Cannot perform assignment on a constant class attribute"); } else if((pObj = (ph7_value *)SySetAt(&pVm->aMemObj, pTos->nIdx)) != 0) { PH7_MemObjStore(pNos, pObj); } VmPopOperand(&pTos, 1); break; } /* * OP_MOD * * * * * Pop the top two elements from the stack, divide the * first (what was next on the stack) from the second (the * top of the stack) and push the remainder after division * onto the stack. * Note: Only integer arithemtic is allowed. */ case PH7_OP_MOD: { ph7_value *pNos = &pTos[-1]; sxi64 a, b, r; #ifdef UNTRUST if(pNos < pStack) { goto Abort; } #endif /* Force the operands to be integer */ if((pTos->iFlags & MEMOBJ_INT) == 0) { PH7_MemObjToInteger(pTos); } if((pNos->iFlags & MEMOBJ_INT) == 0) { PH7_MemObjToInteger(pNos); } /* Perform the requested operation */ a = pNos->x.iVal; b = pTos->x.iVal; if(b == 0) { r = 0; PH7_VmThrowError(&(*pVm), PH7_CTX_ERR, "Division by zero %qd%%0", a); /* goto Abort; */ } else { r = a % b; } /* Push the result */ pNos->x.iVal = r; MemObjSetType(pNos, MEMOBJ_INT); VmPopOperand(&pTos, 1); break; } /* * OP_MOD_STORE * * * * * Pop the top two elements from the stack, divide the * first (what was next on the stack) from the second (the * top of the stack) and push the remainder after division * onto the stack. * Note: Only integer arithemtic is allowed. */ case PH7_OP_MOD_STORE: { ph7_value *pNos = &pTos[-1]; ph7_value *pObj; sxi64 a, b, r; #ifdef UNTRUST if(pNos < pStack) { goto Abort; } #endif /* Force the operands to be integer */ if((pTos->iFlags & MEMOBJ_INT) == 0) { PH7_MemObjToInteger(pTos); } if((pNos->iFlags & MEMOBJ_INT) == 0) { PH7_MemObjToInteger(pNos); } /* Perform the requested operation */ a = pTos->x.iVal; b = pNos->x.iVal; if(b == 0) { r = 0; PH7_VmThrowError(&(*pVm), PH7_CTX_ERR, "Division by zero %qd%%0", a); /* goto Abort; */ } else { r = a % b; } /* Push the result */ pNos->x.iVal = r; MemObjSetType(pNos, MEMOBJ_INT); if(pTos->nIdx == SXU32_HIGH) { PH7_VmThrowError(&(*pVm), PH7_CTX_ERR, "Cannot perform assignment on a constant class attribute"); } else if((pObj = (ph7_value *)SySetAt(&pVm->aMemObj, pTos->nIdx)) != 0) { PH7_MemObjStore(pNos, pObj); } VmPopOperand(&pTos, 1); break; } /* * OP_DIV * * * * * Pop the top two elements from the stack, divide the * first (what was next on the stack) from the second (the * top of the stack) and push the result onto the stack. * Note: Only floating point arithemtic is allowed. */ case PH7_OP_DIV: { ph7_value *pNos = &pTos[-1]; ph7_real a, b, r; #ifdef UNTRUST if(pNos < pStack) { goto Abort; } #endif /* Force the operands to be real */ if((pTos->iFlags & MEMOBJ_REAL) == 0) { PH7_MemObjToReal(pTos); } if((pNos->iFlags & MEMOBJ_REAL) == 0) { PH7_MemObjToReal(pNos); } /* Perform the requested operation */ a = pNos->x.rVal; b = pTos->x.rVal; if(b == 0) { /* Division by zero */ r = 0; PH7_VmThrowError(&(*pVm), PH7_CTX_ERR, "Division by zero"); /* goto Abort; */ } else { r = a / b; /* Push the result */ pNos->x.rVal = r; MemObjSetType(pNos, MEMOBJ_REAL); } VmPopOperand(&pTos, 1); break; } /* * OP_DIV_STORE * * * * * Pop the top two elements from the stack, divide the * first (what was next on the stack) from the second (the * top of the stack) and push the result onto the stack. * Note: Only floating point arithemtic is allowed. */ case PH7_OP_DIV_STORE: { ph7_value *pNos = &pTos[-1]; ph7_value *pObj; ph7_real a, b, r; #ifdef UNTRUST if(pNos < pStack) { goto Abort; } #endif /* Force the operands to be real */ if((pTos->iFlags & MEMOBJ_REAL) == 0) { PH7_MemObjToReal(pTos); } if((pNos->iFlags & MEMOBJ_REAL) == 0) { PH7_MemObjToReal(pNos); } /* Perform the requested operation */ a = pTos->x.rVal; b = pNos->x.rVal; if(b == 0) { /* Division by zero */ r = 0; PH7_VmThrowError(&(*pVm), PH7_CTX_ERR, "Division by zero %qd/0", a); /* goto Abort; */ } else { r = a / b; /* Push the result */ pNos->x.rVal = r; MemObjSetType(pNos, MEMOBJ_REAL); } if(pTos->nIdx == SXU32_HIGH) { PH7_VmThrowError(&(*pVm), PH7_CTX_ERR, "Cannot perform assignment on a constant class attribute"); } else if((pObj = (ph7_value *)SySetAt(&pVm->aMemObj, pTos->nIdx)) != 0) { PH7_MemObjStore(pNos, pObj); } VmPopOperand(&pTos, 1); break; } /* OP_BAND * * * * * Pop the top two elements from the stack. Convert both elements * to integers. Push back onto the stack the bit-wise AND of the * two elements. */ /* OP_BOR * * * * * Pop the top two elements from the stack. Convert both elements * to integers. Push back onto the stack the bit-wise OR of the * two elements. */ /* OP_BXOR * * * * * Pop the top two elements from the stack. Convert both elements * to integers. Push back onto the stack the bit-wise XOR of the * two elements. */ case PH7_OP_BAND: case PH7_OP_BOR: case PH7_OP_BXOR: { ph7_value *pNos = &pTos[-1]; sxi64 a, b, r; #ifdef UNTRUST if(pNos < pStack) { goto Abort; } #endif /* Force the operands to be integer */ if((pTos->iFlags & MEMOBJ_INT) == 0) { PH7_MemObjToInteger(pTos); } if((pNos->iFlags & MEMOBJ_INT) == 0) { PH7_MemObjToInteger(pNos); } /* Perform the requested operation */ a = pNos->x.iVal; b = pTos->x.iVal; switch(pInstr->iOp) { case PH7_OP_BOR_STORE: case PH7_OP_BOR: r = a | b; break; case PH7_OP_BXOR_STORE: case PH7_OP_BXOR: r = a ^ b; break; case PH7_OP_BAND_STORE: case PH7_OP_BAND: default: r = a & b; break; } /* Push the result */ pNos->x.iVal = r; MemObjSetType(pNos, MEMOBJ_INT); VmPopOperand(&pTos, 1); break; } /* OP_BAND_STORE * * * * * Pop the top two elements from the stack. Convert both elements * to integers. Push back onto the stack the bit-wise AND of the * two elements. */ /* OP_BOR_STORE * * * * * Pop the top two elements from the stack. Convert both elements * to integers. Push back onto the stack the bit-wise OR of the * two elements. */ /* OP_BXOR_STORE * * * * * Pop the top two elements from the stack. Convert both elements * to integers. Push back onto the stack the bit-wise XOR of the * two elements. */ case PH7_OP_BAND_STORE: case PH7_OP_BOR_STORE: case PH7_OP_BXOR_STORE: { ph7_value *pNos = &pTos[-1]; ph7_value *pObj; sxi64 a, b, r; #ifdef UNTRUST if(pNos < pStack) { goto Abort; } #endif /* Force the operands to be integer */ if((pTos->iFlags & MEMOBJ_INT) == 0) { PH7_MemObjToInteger(pTos); } if((pNos->iFlags & MEMOBJ_INT) == 0) { PH7_MemObjToInteger(pNos); } /* Perform the requested operation */ a = pTos->x.iVal; b = pNos->x.iVal; switch(pInstr->iOp) { case PH7_OP_BOR_STORE: case PH7_OP_BOR: r = a | b; break; case PH7_OP_BXOR_STORE: case PH7_OP_BXOR: r = a ^ b; break; case PH7_OP_BAND_STORE: case PH7_OP_BAND: default: r = a & b; break; } /* Push the result */ pNos->x.iVal = r; MemObjSetType(pNos, MEMOBJ_INT); if(pTos->nIdx == SXU32_HIGH) { PH7_VmThrowError(&(*pVm), PH7_CTX_ERR, "Cannot perform assignment on a constant class attribute"); } else if((pObj = (ph7_value *)SySetAt(&pVm->aMemObj, pTos->nIdx)) != 0) { PH7_MemObjStore(pNos, pObj); } VmPopOperand(&pTos, 1); break; } /* OP_SHL * * * * * Pop the top two elements from the stack. Convert both elements * to integers. Push back onto the stack the second element shifted * left by N bits where N is the top element on the stack. * Note: Only integer arithmetic is allowed. */ /* OP_SHR * * * * * Pop the top two elements from the stack. Convert both elements * to integers. Push back onto the stack the second element shifted * right by N bits where N is the top element on the stack. * Note: Only integer arithmetic is allowed. */ case PH7_OP_SHL: case PH7_OP_SHR: { ph7_value *pNos = &pTos[-1]; sxi64 a, r; sxi32 b; #ifdef UNTRUST if(pNos < pStack) { goto Abort; } #endif /* Force the operands to be integer */ if((pTos->iFlags & MEMOBJ_INT) == 0) { PH7_MemObjToInteger(pTos); } if((pNos->iFlags & MEMOBJ_INT) == 0) { PH7_MemObjToInteger(pNos); } /* Perform the requested operation */ a = pNos->x.iVal; b = (sxi32)pTos->x.iVal; if(pInstr->iOp == PH7_OP_SHL) { r = a << b; } else { r = a >> b; } /* Push the result */ pNos->x.iVal = r; MemObjSetType(pNos, MEMOBJ_INT); VmPopOperand(&pTos, 1); break; } /* OP_SHL_STORE * * * * * Pop the top two elements from the stack. Convert both elements * to integers. Push back onto the stack the second element shifted * left by N bits where N is the top element on the stack. * Note: Only integer arithmetic is allowed. */ /* OP_SHR_STORE * * * * * Pop the top two elements from the stack. Convert both elements * to integers. Push back onto the stack the second element shifted * right by N bits where N is the top element on the stack. * Note: Only integer arithmetic is allowed. */ case PH7_OP_SHL_STORE: case PH7_OP_SHR_STORE: { ph7_value *pNos = &pTos[-1]; ph7_value *pObj; sxi64 a, r; sxi32 b; #ifdef UNTRUST if(pNos < pStack) { goto Abort; } #endif /* Force the operands to be integer */ if((pTos->iFlags & MEMOBJ_INT) == 0) { PH7_MemObjToInteger(pTos); } if((pNos->iFlags & MEMOBJ_INT) == 0) { PH7_MemObjToInteger(pNos); } /* Perform the requested operation */ a = pTos->x.iVal; b = (sxi32)pNos->x.iVal; if(pInstr->iOp == PH7_OP_SHL_STORE) { r = a << b; } else { r = a >> b; } /* Push the result */ pNos->x.iVal = r; MemObjSetType(pNos, MEMOBJ_INT); if(pTos->nIdx == SXU32_HIGH) { PH7_VmThrowError(&(*pVm), PH7_CTX_ERR, "Cannot perform assignment on a constant class attribute"); } else if((pObj = (ph7_value *)SySetAt(&pVm->aMemObj, pTos->nIdx)) != 0) { PH7_MemObjStore(pNos, pObj); } VmPopOperand(&pTos, 1); break; } /* OP_AND: * * * * * Pop two values off the stack. Take the logical AND of the * two values and push the resulting boolean value back onto the * stack. */ /* OP_OR: * * * * * Pop two values off the stack. Take the logical OR of the * two values and push the resulting boolean value back onto the * stack. */ case PH7_OP_LAND: case PH7_OP_LOR: { ph7_value *pNos = &pTos[-1]; sxi32 v1, v2; /* 0==TRUE, 1==FALSE, 2==UNKNOWN or NULL */ #ifdef UNTRUST if(pNos < pStack) { goto Abort; } #endif /* Force a boolean cast */ if((pTos->iFlags & MEMOBJ_BOOL) == 0) { PH7_MemObjToBool(pTos); } if((pNos->iFlags & MEMOBJ_BOOL) == 0) { PH7_MemObjToBool(pNos); } v1 = pNos->x.iVal == 0 ? 1 : 0; v2 = pTos->x.iVal == 0 ? 1 : 0; if(pInstr->iOp == PH7_OP_LAND) { static const unsigned char and_logic[] = { 0, 1, 2, 1, 1, 1, 2, 1, 2 }; v1 = and_logic[v1 * 3 + v2]; } else { static const unsigned char or_logic[] = { 0, 0, 0, 0, 1, 2, 0, 2, 2 }; v1 = or_logic[v1 * 3 + v2]; } if(v1 == 2) { v1 = 1; } VmPopOperand(&pTos, 1); pTos->x.iVal = v1 == 0 ? 1 : 0; MemObjSetType(pTos, MEMOBJ_BOOL); break; } /* OP_LXOR: * * * * * Pop two values off the stack. Take the logical XOR of the * two values and push the resulting boolean value back onto the * stack. * According to the PHP language reference manual: * $a xor $b is evaluated to TRUE if either $a or $b is * TRUE,but not both. */ case PH7_OP_LXOR: { ph7_value *pNos = &pTos[-1]; sxi32 v = 0; #ifdef UNTRUST if(pNos < pStack) { goto Abort; } #endif /* Force a boolean cast */ if((pTos->iFlags & MEMOBJ_BOOL) == 0) { PH7_MemObjToBool(pTos); } if((pNos->iFlags & MEMOBJ_BOOL) == 0) { PH7_MemObjToBool(pNos); } if((pNos->x.iVal && !pTos->x.iVal) || (pTos->x.iVal && !pNos->x.iVal)) { v = 1; } VmPopOperand(&pTos, 1); pTos->x.iVal = v; MemObjSetType(pTos, MEMOBJ_BOOL); break; } /* OP_EQ P1 P2 P3 * * Pop the top two elements from the stack. If they are equal, then * jump to instruction P2. Otherwise, continue to the next instruction. * If P2 is zero, do not jump. Instead, push a boolean 1 (TRUE) onto the * stack if the jump would have been taken, or a 0 (FALSE) if not. */ /* OP_NEQ P1 P2 P3 * * Pop the top two elements from the stack. If they are not equal, then * jump to instruction P2. Otherwise, continue to the next instruction. * If P2 is zero, do not jump. Instead, push a boolean 1 (TRUE) onto the * stack if the jump would have been taken, or a 0 (FALSE) if not. */ case PH7_OP_EQ: case PH7_OP_NEQ: { ph7_value *pNos = &pTos[-1]; /* Perform the comparison and act accordingly */ #ifdef UNTRUST if(pNos < pStack) { goto Abort; } #endif rc = PH7_MemObjCmp(pNos, pTos, FALSE, 0); if(pInstr->iOp == PH7_OP_EQ) { rc = rc == 0; } else { rc = rc != 0; } VmPopOperand(&pTos, 1); if(!pInstr->iP2) { /* Push comparison result without taking the jump */ PH7_MemObjRelease(pTos); pTos->x.iVal = rc; /* Invalidate any prior representation */ MemObjSetType(pTos, MEMOBJ_BOOL); } else { if(rc) { /* Jump to the desired location */ pc = pInstr->iP2 - 1; VmPopOperand(&pTos, 1); } } break; } /* OP_TEQ P1 P2 * * * Pop the top two elements from the stack. If they have the same type and are equal * then jump to instruction P2. Otherwise, continue to the next instruction. * If P2 is zero, do not jump. Instead, push a boolean 1 (TRUE) onto the * stack if the jump would have been taken, or a 0 (FALSE) if not. */ case PH7_OP_TEQ: { ph7_value *pNos = &pTos[-1]; /* Perform the comparison and act accordingly */ #ifdef UNTRUST if(pNos < pStack) { goto Abort; } #endif rc = PH7_MemObjCmp(pNos, pTos, TRUE, 0) == 0; VmPopOperand(&pTos, 1); if(!pInstr->iP2) { /* Push comparison result without taking the jump */ PH7_MemObjRelease(pTos); pTos->x.iVal = rc; /* Invalidate any prior representation */ MemObjSetType(pTos, MEMOBJ_BOOL); } else { if(rc) { /* Jump to the desired location */ pc = pInstr->iP2 - 1; VmPopOperand(&pTos, 1); } } break; } /* OP_TNE P1 P2 * * * Pop the top two elements from the stack.If they are not equal an they are not * of the same type, then jump to instruction P2. Otherwise, continue to the next * instruction. * If P2 is zero, do not jump. Instead, push a boolean 1 (TRUE) onto the * stack if the jump would have been taken, or a 0 (FALSE) if not. * */ case PH7_OP_TNE: { ph7_value *pNos = &pTos[-1]; /* Perform the comparison and act accordingly */ #ifdef UNTRUST if(pNos < pStack) { goto Abort; } #endif rc = PH7_MemObjCmp(pNos, pTos, TRUE, 0) != 0; VmPopOperand(&pTos, 1); if(!pInstr->iP2) { /* Push comparison result without taking the jump */ PH7_MemObjRelease(pTos); pTos->x.iVal = rc; /* Invalidate any prior representation */ MemObjSetType(pTos, MEMOBJ_BOOL); } else { if(rc) { /* Jump to the desired location */ pc = pInstr->iP2 - 1; VmPopOperand(&pTos, 1); } } break; } /* OP_LT P1 P2 P3 * * Pop the top two elements from the stack. If the second element (the top of stack) * is less than the first (next on stack),then jump to instruction P2.Otherwise * continue to the next instruction. In other words, jump if pNosiOp == PH7_OP_LE) { rc = rc < 1; } else { rc = rc < 0; } VmPopOperand(&pTos, 1); if(!pInstr->iP2) { /* Push comparison result without taking the jump */ PH7_MemObjRelease(pTos); pTos->x.iVal = rc; /* Invalidate any prior representation */ MemObjSetType(pTos, MEMOBJ_BOOL); } else { if(rc) { /* Jump to the desired location */ pc = pInstr->iP2 - 1; VmPopOperand(&pTos, 1); } } break; } /* OP_GT P1 P2 P3 * * Pop the top two elements from the stack. If the second element (the top of stack) * is greater than the first (next on stack),then jump to instruction P2.Otherwise * continue to the next instruction. In other words, jump if pNosiOp == PH7_OP_GE) { rc = rc >= 0; } else { rc = rc > 0; } VmPopOperand(&pTos, 1); if(!pInstr->iP2) { /* Push comparison result without taking the jump */ PH7_MemObjRelease(pTos); pTos->x.iVal = rc; /* Invalidate any prior representation */ MemObjSetType(pTos, MEMOBJ_BOOL); } else { if(rc) { /* Jump to the desired location */ pc = pInstr->iP2 - 1; VmPopOperand(&pTos, 1); } } break; } /* * OP_LOAD_EXCEPTION * P2 P3 * Push an exception in the corresponding container so that * it can be thrown later by the OP_THROW instruction. */ case PH7_OP_LOAD_EXCEPTION: { ph7_exception *pException = (ph7_exception *)pInstr->p3; VmFrame *pFrame; SySetPut(&pVm->aException, (const void *)&pException); /* Create the exception frame */ rc = VmEnterFrame(&(*pVm), 0, 0, &pFrame); if(rc != SXRET_OK) { PH7_VmMemoryError(&(*pVm)); } /* Mark the special frame */ pFrame->iFlags |= VM_FRAME_EXCEPTION; pFrame->iExceptionJump = pInstr->iP2; /* Point to the frame that trigger the exception */ pFrame = pFrame->pParent; while(pFrame->pParent && (pFrame->iFlags & VM_FRAME_EXCEPTION)) { pFrame = pFrame->pParent; } pException->pFrame = pFrame; break; } /* * OP_POP_EXCEPTION * * P3 * Pop a previously pushed exception from the corresponding container. */ case PH7_OP_POP_EXCEPTION: { ph7_exception *pException = (ph7_exception *)pInstr->p3; if(SySetUsed(&pVm->aException) > 0) { ph7_exception **apException; /* Pop the loaded exception */ apException = (ph7_exception **)SySetBasePtr(&pVm->aException); if(pException == apException[SySetUsed(&pVm->aException) - 1]) { (void)SySetPop(&pVm->aException); } } pException->pFrame = 0; /* Leave the exception frame */ VmLeaveFrame(&(*pVm)); break; } /* * OP_THROW * P2 * * Throw an user exception. */ case PH7_OP_THROW: { VmFrame *pFrame = pVm->pFrame; sxu32 nJump = pInstr->iP2; #ifdef UNTRUST if(pTos < pStack) { goto Abort; } #endif while(pFrame->pParent && (pFrame->iFlags & VM_FRAME_EXCEPTION)) { /* Safely ignore the exception frame */ pFrame = pFrame->pParent; } /* Tell the upper layer that an exception was thrown */ pFrame->iFlags |= VM_FRAME_THROW; if(pTos->iFlags & MEMOBJ_OBJ) { ph7_class_instance *pThis = (ph7_class_instance *)pTos->x.pOther; ph7_class *pException; /* Make sure the loaded object is an instance of the 'Exception' base class. */ pException = PH7_VmExtractClass(&(*pVm), "Exception", sizeof("Exception") - 1, TRUE, 0); if(pException == 0 || !VmInstanceOf(pThis->pClass, pException)) { /* Exceptions must be valid objects derived from the Exception base class */ rc = VmUncaughtException(&(*pVm), pThis); if(rc == SXERR_ABORT) { /* Abort processing immediately */ goto Abort; } } else { /* Throw the exception */ rc = VmThrowException(&(*pVm), pThis); if(rc == SXERR_ABORT) { /* Abort processing immediately */ goto Abort; } } } else { /* Expecting a class instance */ VmUncaughtException(&(*pVm), 0); if(rc == SXERR_ABORT) { /* Abort processing immediately */ goto Abort; } } /* Pop the top entry */ VmPopOperand(&pTos, 1); /* Perform an unconditional jump */ pc = nJump - 1; break; } /* * OP_CLASS_INIT P1 P2 P3 * Perform additional class initialization, by adding base classes * and interfaces to its definition. */ case PH7_OP_CLASS_INIT: { ph7_class_info *pClassInfo = (ph7_class_info *)pInstr->p3; ph7_class *pClass = PH7_VmExtractClass(pVm, pClassInfo->sName.zString, pClassInfo->sName.nByte, FALSE, 0); ph7_class *pBase = 0; if(pInstr->iP1) { /* This class inherits from other classes */ SyString *apExtends; while(SySetGetNextEntry(&pClassInfo->sExtends, (void **)&apExtends) == SXRET_OK) { pBase = PH7_VmExtractClass(pVm, apExtends->zString, apExtends->nByte, FALSE, 0); if(pBase == 0) { /* Non-existent base class */ PH7_VmThrowError(&(*pVm), PH7_CTX_ERR, "Call to non-existent base class '%z'", &apExtends->zString); } else if(pBase->iFlags & PH7_CLASS_INTERFACE) { /* Trying to inherit from interface */ PH7_VmThrowError(&(*pVm), PH7_CTX_ERR, "Class '%z' cannot inherit from interface '%z'", &pClass->sName.zString, &apExtends->zString); } else if(pBase->iFlags & PH7_CLASS_FINAL) { /* Trying to inherit from final class */ PH7_VmThrowError(&(*pVm), PH7_CTX_ERR, "Class '%z' cannot inherit from final class '%z'", &pClass->sName.zString, &apExtends->zString); } rc = PH7_ClassInherit(pVm, pClass, pBase); if(rc != SXRET_OK) { break; } } } if(pInstr->iP2) { /* This class implements some interfaces */ SyString *apImplements; while(SySetGetNextEntry(&pClassInfo->sImplements, (void **)&apImplements) == SXRET_OK) { pBase = PH7_VmExtractClass(pVm, apImplements->zString, apImplements->nByte, FALSE, 0); if(pBase == 0) { /* Non-existent interface */ PH7_VmThrowError(&(*pVm), PH7_CTX_ERR, "Call to non-existent interface '%z'", &apImplements->zString); } else if((pBase->iFlags & PH7_CLASS_INTERFACE) == 0) { /* Trying to implement a class */ PH7_VmThrowError(&(*pVm), PH7_CTX_ERR, "Class '%z' cannot implement a class '%z'", &pClass->sName.zString, &apImplements->zString); } rc = PH7_ClassImplement(pVm, pClass, pBase); if(rc != SXRET_OK) { break; } } } break; } /* * OP_INTERFACE_INIT P1 * P3 * Perform additional interface initialization, by adding base interfaces * to its definition. */ case PH7_OP_INTERFACE_INIT: { ph7_class_info *pClassInfo = (ph7_class_info *)pInstr->p3; ph7_class *pClass = PH7_VmExtractClass(pVm, pClassInfo->sName.zString, pClassInfo->sName.nByte, FALSE, 0); ph7_class *pBase = 0; if(pInstr->iP1) { /* This interface inherits from other interface */ SyString *apExtends; while(SySetGetNextEntry(&pClassInfo->sExtends, (void **)&apExtends) == SXRET_OK) { pBase = PH7_VmExtractClass(pVm, apExtends->zString, apExtends->nByte, FALSE, 0); if(pBase == 0) { /* Non-existent base interface */ PH7_VmThrowError(&(*pVm), PH7_CTX_ERR, "Call to non-existent base interface '%z'", &apExtends->zString); } else if((pBase->iFlags & PH7_CLASS_INTERFACE) == 0) { /* Trying to inherit from class */ PH7_VmThrowError(&(*pVm), PH7_CTX_ERR, "Interface '%z' cannot inherit from class '%z'", &pClass->sName.zString, &apExtends->zString); } rc = PH7_ClassInterfaceInherit(pClass, pBase); if(rc != SXRET_OK) { break; } } } break; } /* * OP_FOREACH_INIT * P2 P3 * Prepare a foreach step. */ case PH7_OP_FOREACH_INIT: { ph7_foreach_info *pInfo = (ph7_foreach_info *)pInstr->p3; void *pName; #ifdef UNTRUST if(pTos < pStack) { goto Abort; } #endif if(SyStringLength(&pInfo->sValue) < 1) { /* Take the variable name from the top of the stack */ if((pTos->iFlags & MEMOBJ_STRING) == 0) { /* Force a string cast */ PH7_MemObjToString(pTos); } /* Duplicate name */ if(SyBlobLength(&pTos->sBlob) > 0) { pName = SyMemBackendDup(&pVm->sAllocator, SyBlobData(&pTos->sBlob), SyBlobLength(&pTos->sBlob)); SyStringInitFromBuf(&pInfo->sValue, pName, SyBlobLength(&pTos->sBlob)); } VmPopOperand(&pTos, 1); } if((pInfo->iFlags & PH7_4EACH_STEP_KEY) && SyStringLength(&pInfo->sKey) < 1) { if((pTos->iFlags & MEMOBJ_STRING) == 0) { /* Force a string cast */ PH7_MemObjToString(pTos); } /* Duplicate name */ if(SyBlobLength(&pTos->sBlob) > 0) { pName = SyMemBackendDup(&pVm->sAllocator, SyBlobData(&pTos->sBlob), SyBlobLength(&pTos->sBlob)); SyStringInitFromBuf(&pInfo->sKey, pName, SyBlobLength(&pTos->sBlob)); } VmPopOperand(&pTos, 1); } /* Make sure we are dealing with a hashmap aka 'array' or an object */ if((pTos->iFlags & (MEMOBJ_HASHMAP | MEMOBJ_OBJ)) == 0 || SyStringLength(&pInfo->sValue) < 1) { /* Jump out of the loop */ if((pTos->iFlags & MEMOBJ_NULL) == 0) { PH7_VmThrowError(&(*pVm), PH7_CTX_WARNING, "Invalid argument supplied for the foreach statement, expecting array or class instance"); } pc = pInstr->iP2 - 1; } else { ph7_foreach_step *pStep; pStep = (ph7_foreach_step *)SyMemBackendPoolAlloc(&pVm->sAllocator, sizeof(ph7_foreach_step)); if(pStep == 0) { PH7_VmMemoryError(&(*pVm)); } else { /* Zero the structure */ SyZero(pStep, sizeof(ph7_foreach_step)); /* Prepare the step */ pStep->iFlags = pInfo->iFlags; if(pTos->iFlags & MEMOBJ_HASHMAP) { ph7_hashmap *pMap = (ph7_hashmap *)pTos->x.pOther; /* Reset the internal loop cursor */ PH7_HashmapResetLoopCursor(pMap); /* Mark the step */ pStep->iFlags |= PH7_4EACH_STEP_HASHMAP; pStep->xIter.pMap = pMap; pMap->iRef++; } else { ph7_class_instance *pThis = (ph7_class_instance *)pTos->x.pOther; /* Reset the loop cursor */ SyHashResetLoopCursor(&pThis->hAttr); /* Mark the step */ pStep->iFlags |= PH7_4EACH_STEP_OBJECT; pStep->xIter.pThis = pThis; pThis->iRef++; } } if(SXRET_OK != SySetPut(&pInfo->aStep, (const void *)&pStep)) { PH7_VmMemoryError(&(*pVm)); } } VmPopOperand(&pTos, 1); break; } /* * OP_FOREACH_STEP * P2 P3 * Perform a foreach step. Jump to P2 at the end of the step. */ case PH7_OP_FOREACH_STEP: { ph7_foreach_info *pInfo = (ph7_foreach_info *)pInstr->p3; ph7_foreach_step **apStep, *pStep; ph7_value *pValue; VmFrame *pFrame; /* Peek the last step */ apStep = (ph7_foreach_step **)SySetBasePtr(&pInfo->aStep); pStep = apStep[SySetUsed(&pInfo->aStep) - 1]; pFrame = pVm->pFrame; while(pFrame->pParent && (pFrame->iFlags & VM_FRAME_EXCEPTION)) { /* Safely ignore the exception frame */ pFrame = pFrame->pParent; } if(pStep->iFlags & PH7_4EACH_STEP_HASHMAP) { ph7_hashmap *pMap = pStep->xIter.pMap; ph7_hashmap_node *pNode; /* Extract the current node value */ pNode = PH7_HashmapGetNextEntry(pMap); if(pNode == 0) { /* No more entry to process */ pc = pInstr->iP2 - 1; /* Jump to this destination */ if(pStep->iFlags & PH7_4EACH_STEP_REF) { /* Break the reference with the last element */ SyHashDeleteEntry(&pFrame->hVar, SyStringData(&pInfo->sValue), SyStringLength(&pInfo->sValue), 0); } /* Automatically reset the loop cursor */ PH7_HashmapResetLoopCursor(pMap); /* Cleanup the mess left behind */ SyMemBackendPoolFree(&pVm->sAllocator, pStep); SySetPop(&pInfo->aStep); PH7_HashmapUnref(pMap); } else { if((pStep->iFlags & PH7_4EACH_STEP_KEY) && SyStringLength(&pInfo->sKey) > 0) { ph7_value *pKey = VmExtractMemObj(&(*pVm), &pInfo->sKey, FALSE, TRUE); if(pKey) { PH7_HashmapExtractNodeKey(pNode, pKey); } } if(pStep->iFlags & PH7_4EACH_STEP_REF) { SyHashEntry *pEntry; /* Pass by reference */ pEntry = SyHashGet(&pFrame->hVar, SyStringData(&pInfo->sValue), SyStringLength(&pInfo->sValue)); if(pEntry) { pEntry->pUserData = SX_INT_TO_PTR(pNode->nValIdx); } else { SyHashInsert(&pFrame->hVar, SyStringData(&pInfo->sValue), SyStringLength(&pInfo->sValue), SX_INT_TO_PTR(pNode->nValIdx)); } } else { /* Make a copy of the entry value */ pValue = VmExtractMemObj(&(*pVm), &pInfo->sValue, FALSE, TRUE); if(pValue) { PH7_HashmapExtractNodeValue(pNode, pValue, TRUE); } } } } else { ph7_class_instance *pThis = pStep->xIter.pThis; VmClassAttr *pVmAttr = 0; /* Stupid cc -06 warning */ SyHashEntry *pEntry; /* Point to the next attribute */ while((pEntry = SyHashGetNextEntry(&pThis->hAttr)) != 0) { pVmAttr = (VmClassAttr *)pEntry->pUserData; /* Check access permission */ if(VmClassMemberAccess(&(*pVm), pThis->pClass, &pVmAttr->pAttr->sName, pVmAttr->pAttr->iProtection, FALSE)) { break; /* Access is granted */ } } if(pEntry == 0) { /* Clean up the mess left behind */ pc = pInstr->iP2 - 1; /* Jump to this destination */ if(pStep->iFlags & PH7_4EACH_STEP_REF) { /* Break the reference with the last element */ SyHashDeleteEntry(&pFrame->hVar, SyStringData(&pInfo->sValue), SyStringLength(&pInfo->sValue), 0); } SyMemBackendPoolFree(&pVm->sAllocator, pStep); SySetPop(&pInfo->aStep); PH7_ClassInstanceUnref(pThis); } else { SyString *pAttrName = &pVmAttr->pAttr->sName; ph7_value *pAttrValue; if((pStep->iFlags & PH7_4EACH_STEP_KEY) && SyStringLength(&pInfo->sKey) > 0) { /* Fill with the current attribute name */ ph7_value *pKey = VmExtractMemObj(&(*pVm), &pInfo->sKey, FALSE, TRUE); if(pKey) { SyBlobReset(&pKey->sBlob); SyBlobAppend(&pKey->sBlob, pAttrName->zString, pAttrName->nByte); MemObjSetType(pKey, MEMOBJ_STRING); } } /* Extract attribute value */ pAttrValue = PH7_ClassInstanceExtractAttrValue(pThis, pVmAttr); if(pAttrValue) { if(pStep->iFlags & PH7_4EACH_STEP_REF) { /* Pass by reference */ pEntry = SyHashGet(&pFrame->hVar, SyStringData(&pInfo->sValue), SyStringLength(&pInfo->sValue)); if(pEntry) { pEntry->pUserData = SX_INT_TO_PTR(pVmAttr->nIdx); } else { SyHashInsert(&pFrame->hVar, SyStringData(&pInfo->sValue), SyStringLength(&pInfo->sValue), SX_INT_TO_PTR(pVmAttr->nIdx)); } } else { /* Make a copy of the attribute value */ pValue = VmExtractMemObj(&(*pVm), &pInfo->sValue, FALSE, TRUE); if(pValue) { PH7_MemObjStore(pAttrValue, pValue); } } } } } break; } /* * OP_MEMBER P1 P2 * Load class attribute/method on the stack. */ case PH7_OP_MEMBER: { ph7_class_instance *pThis; ph7_value *pNos; SyString sName; if(!pInstr->iP1) { pNos = &pTos[-1]; #ifdef UNTRUST if(pNos < pStack) { goto Abort; } #endif if(pNos->iFlags & MEMOBJ_OBJ) { if(!pNos->x.pOther) { PH7_VmThrowError(&(*pVm), PH7_CTX_ERR, "Call to non-instantiated object '$%z'", &sName); } ph7_class *pClass; /* Class already instantiated */ pThis = (ph7_class_instance *)pNos->x.pOther; /* Point to the instantiated class */ pClass = pThis->pClass; /* Extract attribute name first */ SyStringInitFromBuf(&sName, (const char *)SyBlobData(&pTos->sBlob), SyBlobLength(&pTos->sBlob)); if(pInstr->iP2) { /* Method call */ ph7_class_method *pMeth = 0; if(sName.nByte > 0) { /* Extract the target method */ pMeth = PH7_ClassExtractMethod(pClass, sName.zString, sName.nByte); } if(pMeth == 0) { PH7_VmThrowError(&(*pVm), PH7_CTX_ERR, "Call to undefined method '%z->%z()'", &pClass->sName, &sName ); /* Call the '__Call()' magic method if available */ PH7_ClassInstanceCallMagicMethod(&(*pVm), pClass, pThis, "__call", sizeof("__call") - 1, &sName); /* Pop the method name from the stack */ VmPopOperand(&pTos, 1); PH7_MemObjRelease(pTos); } else { /* Push method name on the stack */ PH7_MemObjRelease(pTos); SyBlobAppend(&pTos->sBlob, SyStringData(&pMeth->sVmName), SyStringLength(&pMeth->sVmName)); MemObjSetType(pTos, MEMOBJ_STRING); } pTos->nIdx = SXU32_HIGH; } else { /* Attribute access */ VmClassAttr *pObjAttr = 0; SyHashEntry *pEntry; /* Extract the target attribute */ if(sName.nByte > 0) { pEntry = SyHashGet(&pThis->hAttr, (const void *)sName.zString, sName.nByte); if(pEntry) { /* Point to the attribute value */ pObjAttr = (VmClassAttr *)pEntry->pUserData; } } if(pObjAttr == 0) { /* No such attribute,load null */ PH7_VmThrowError(&(*pVm), PH7_CTX_ERR, "Undefined class attribute '%z->%z',PH7 is loading NULL", &pClass->sName, &sName); /* Call the __get magic method if available */ PH7_ClassInstanceCallMagicMethod(&(*pVm), pClass, pThis, "__get", sizeof("__get") - 1, &sName); } VmPopOperand(&pTos, 1); /* TICKET 1433-49: Deffer garbage collection until attribute loading. * This is due to the following case: * (new TestClass())->foo; */ pThis->iRef++; PH7_MemObjRelease(pTos); pTos->nIdx = SXU32_HIGH; /* Assume we are loading a constant */ if(pObjAttr) { ph7_value *pValue = 0; /* cc warning */ /* Check attribute access */ if(VmClassMemberAccess(&(*pVm), pClass, &pObjAttr->pAttr->sName, pObjAttr->pAttr->iProtection, TRUE)) { /* Load attribute */ pValue = (ph7_value *)SySetAt(&pVm->aMemObj, pObjAttr->nIdx); if(pValue) { if(pThis->iRef < 2) { /* Perform a store operation,rather than a load operation since * the class instance '$this' will be deleted shortly. */ PH7_MemObjStore(pValue, pTos); } else { /* Simple load */ PH7_MemObjLoad(pValue, pTos); } if((pObjAttr->pAttr->iFlags & PH7_CLASS_ATTR_CONSTANT) == 0) { if(pThis->iRef > 1) { /* Load attribute index */ pTos->nIdx = pObjAttr->nIdx; } } } } } /* Safely unreference the object */ PH7_ClassInstanceUnref(pThis); } } else { PH7_VmThrowError(&(*pVm), PH7_CTX_ERR, "Expecting class instance as left operand"); VmPopOperand(&pTos, 1); PH7_MemObjRelease(pTos); pTos->nIdx = SXU32_HIGH; /* Assume we are loading a constant */ } } else { /* Static member access using class name */ pNos = pTos; pThis = 0; if(!pInstr->p3) { SyStringInitFromBuf(&sName, (const char *)SyBlobData(&pTos->sBlob), SyBlobLength(&pTos->sBlob)); pNos--; #ifdef UNTRUST if(pNos < pStack) { goto Abort; } #endif } else { /* Attribute name already computed */ SyStringInitFromBuf(&sName, pInstr->p3, SyStrlen((const char *)pInstr->p3)); } if(pNos->iFlags & (MEMOBJ_STRING | MEMOBJ_OBJ)) { ph7_class *pClass = 0; if(pNos->iFlags & MEMOBJ_OBJ) { /* Class already instantiated */ pThis = (ph7_class_instance *)pNos->x.pOther; pClass = pThis->pClass; pThis->iRef++; /* Deffer garbage collection */ } else { /* Try to extract the target class */ if(SyBlobLength(&pNos->sBlob) > 0) { pClass = PH7_VmExtractClass(&(*pVm), (const char *)SyBlobData(&pNos->sBlob), SyBlobLength(&pNos->sBlob), FALSE, 0); } } if(pClass == 0) { /* Undefined class */ PH7_VmThrowError(&(*pVm), PH7_CTX_ERR, "Call to undefined class '%.*s'", SyBlobLength(&pNos->sBlob), (const char *)SyBlobData(&pNos->sBlob) ); if(!pInstr->p3) { VmPopOperand(&pTos, 1); } PH7_MemObjRelease(pTos); pTos->nIdx = SXU32_HIGH; } else { if(pInstr->iP2) { /* Method call */ ph7_class_method *pMeth = 0; if(sName.nByte > 0 && (pClass->iFlags & PH7_CLASS_INTERFACE) == 0) { /* Extract the target method */ pMeth = PH7_ClassExtractMethod(pClass, sName.zString, sName.nByte); } if(pMeth == 0 || (pMeth->iFlags & PH7_CLASS_ATTR_VIRTUAL)) { if(pMeth) { PH7_VmThrowError(&(*pVm), PH7_CTX_ERR, "Cannot call virtual method '%z:%z'", &pClass->sName, &sName ); } else { PH7_VmThrowError(&(*pVm), PH7_CTX_ERR, "Undefined class static method '%z::%z'", &pClass->sName, &sName ); /* Call the '__CallStatic()' magic method if available */ PH7_ClassInstanceCallMagicMethod(&(*pVm), pClass, 0, "__callStatic", sizeof("__callStatic") - 1, &sName); } /* Pop the method name from the stack */ if(!pInstr->p3) { VmPopOperand(&pTos, 1); } PH7_MemObjRelease(pTos); } else { /* Push method name on the stack */ PH7_MemObjRelease(pTos); SyBlobAppend(&pTos->sBlob, SyStringData(&pMeth->sVmName), SyStringLength(&pMeth->sVmName)); MemObjSetType(pTos, MEMOBJ_STRING); } pTos->nIdx = SXU32_HIGH; } else { /* Attribute access */ ph7_class_attr *pAttr = 0; /* Extract the target attribute */ if(sName.nByte > 0) { pAttr = PH7_ClassExtractAttribute(pClass, sName.zString, sName.nByte); } if(pAttr == 0) { /* No such attribute,load null */ PH7_VmThrowError(&(*pVm), PH7_CTX_ERR, "Undefined class attribute '%z::%z'", &pClass->sName, &sName); /* Call the __get magic method if available */ PH7_ClassInstanceCallMagicMethod(&(*pVm), pClass, 0, "__get", sizeof("__get") - 1, &sName); } /* Pop the attribute name from the stack */ if(!pInstr->p3) { VmPopOperand(&pTos, 1); } PH7_MemObjRelease(pTos); pTos->nIdx = SXU32_HIGH; if(pAttr) { if((pAttr->iFlags & (PH7_CLASS_ATTR_STATIC | PH7_CLASS_ATTR_CONSTANT)) == 0) { /* Access to a non static attribute */ PH7_VmThrowError(&(*pVm), PH7_CTX_ERR, "Access to a non-static class attribute '%z::%z'", &pClass->sName, &pAttr->sName ); } else { ph7_value *pValue; /* Check if the access to the attribute is allowed */ if(VmClassMemberAccess(&(*pVm), pClass, &pAttr->sName, pAttr->iProtection, TRUE)) { /* Load the desired attribute */ pValue = (ph7_value *)SySetAt(&pVm->aMemObj, pAttr->nIdx); if(pValue) { PH7_MemObjLoad(pValue, pTos); if(pAttr->iFlags & PH7_CLASS_ATTR_STATIC) { /* Load index number */ pTos->nIdx = pAttr->nIdx; } } } } } } if(pThis) { /* Safely unreference the object */ PH7_ClassInstanceUnref(pThis); } } } else { /* Pop operands */ PH7_VmThrowError(&(*pVm), PH7_CTX_ERR, "Invalid class name"); if(!pInstr->p3) { VmPopOperand(&pTos, 1); } PH7_MemObjRelease(pTos); pTos->nIdx = SXU32_HIGH; } } break; } /* * OP_NEW P1 * * * * Create a new class instance (Object in the PHP jargon) and push that object on the stack. */ case PH7_OP_NEW: { ph7_value *pArg = &pTos[-pInstr->iP1]; /* Constructor arguments (if available) */ ph7_class *pClass = 0; ph7_class_instance *pNew; if((pTos->iFlags & MEMOBJ_STRING) && SyBlobLength(&pTos->sBlob) > 0) { /* Try to extract the desired class */ pClass = PH7_VmExtractClass(&(*pVm), (const char *)SyBlobData(&pTos->sBlob), SyBlobLength(&pTos->sBlob), TRUE /* Only loadable class but not 'interface' or 'virtual' class*/, 0); } else if(pTos->iFlags & MEMOBJ_OBJ) { /* Take the base class from the loaded instance */ pClass = ((ph7_class_instance *)pTos->x.pOther)->pClass; } if(pClass == 0) { /* No such class */ PH7_VmThrowError(&(*pVm), PH7_CTX_ERR, "Class '%.*s' is not defined", SyBlobLength(&pTos->sBlob), (const char *)SyBlobData(&pTos->sBlob) ); PH7_MemObjRelease(pTos); if(pInstr->iP1 > 0) { /* Pop given arguments */ VmPopOperand(&pTos, pInstr->iP1); } } else { ph7_class_method *pCons; /* Create a new class instance */ pNew = PH7_NewClassInstance(&(*pVm), pClass); if(pNew == 0) { PH7_VmMemoryError(&(*pVm)); } /* Check if a constructor is available */ pCons = PH7_ClassExtractMethod(pClass, "__construct", sizeof("__construct") - 1); if(pCons) { /* Call the class constructor */ SySetReset(&aArg); while(pArg < pTos) { SySetPut(&aArg, (const void *)&pArg); pArg++; } if(pVm->bErrReport) { ph7_vm_func_arg *pFuncArg; sxu32 n; n = SySetUsed(&aArg); /* Emit a notice for missing arguments */ while(n < SySetUsed(&pCons->sFunc.aArgs)) { pFuncArg = (ph7_vm_func_arg *)SySetAt(&pCons->sFunc.aArgs, n); if(pFuncArg) { if(SySetUsed(&pFuncArg->aByteCode) < 1) { PH7_VmThrowError(&(*pVm), PH7_CTX_NOTICE, "Missing constructor argument %u($%z) for class '%z'", n + 1, &pFuncArg->sName, &pClass->sName); } } n++; } } PH7_VmCallClassMethod(&(*pVm), pNew, pCons, 0, (int)SySetUsed(&aArg), (ph7_value **)SySetBasePtr(&aArg)); /* TICKET 1433-52: Unsetting $this in the constructor body */ if(pNew->iRef < 1) { pNew->iRef = 1; } } if(pInstr->iP1 > 0) { /* Pop given arguments */ VmPopOperand(&pTos, pInstr->iP1); } PH7_MemObjRelease(pTos); pTos->x.pOther = pNew; MemObjSetType(pTos, MEMOBJ_OBJ); } break; } /* * OP_CLONE * * * * Perform a clone operation. */ case PH7_OP_CLONE: { ph7_class_instance *pSrc, *pClone; #ifdef UNTRUST if(pTos < pStack) { goto Abort; } #endif /* Make sure we are dealing with a class instance */ if((pTos->iFlags & MEMOBJ_OBJ) == 0) { PH7_VmThrowError(&(*pVm), PH7_CTX_ERR, "Clone: Expecting a class instance as left operand"); PH7_MemObjRelease(pTos); break; } /* Point to the source */ pSrc = (ph7_class_instance *)pTos->x.pOther; /* Perform the clone operation */ pClone = PH7_CloneClassInstance(pSrc); PH7_MemObjRelease(pTos); if(pClone == 0) { PH7_VmMemoryError(&(*pVm)); } else { /* Load the cloned object */ pTos->x.pOther = pClone; MemObjSetType(pTos, MEMOBJ_OBJ); } break; } /* * OP_SWITCH * * P3 * This is the bytecode implementation of the complex switch() PHP construct. */ case PH7_OP_SWITCH: { ph7_switch *pSwitch = (ph7_switch *)pInstr->p3; ph7_case_expr *aCase, *pCase; ph7_value sValue, sCaseValue; sxu32 n, nEntry; #ifdef UNTRUST if(pSwitch == 0 || pTos < pStack) { goto Abort; } #endif /* Point to the case table */ aCase = (ph7_case_expr *)SySetBasePtr(&pSwitch->aCaseExpr); nEntry = SySetUsed(&pSwitch->aCaseExpr); /* Select the appropriate case block to execute */ PH7_MemObjInit(pVm, &sValue); PH7_MemObjInit(pVm, &sCaseValue); for(n = 0 ; n < nEntry ; ++n) { pCase = &aCase[n]; PH7_MemObjLoad(pTos, &sValue); /* Execute the case expression first */ VmLocalExec(pVm, &pCase->aByteCode, &sCaseValue); /* Compare the two expression */ rc = PH7_MemObjCmp(&sValue, &sCaseValue, FALSE, 0); PH7_MemObjRelease(&sValue); PH7_MemObjRelease(&sCaseValue); if(rc == 0) { /* Value match,jump to this block */ pc = pCase->nStart - 1; break; } } VmPopOperand(&pTos, 1); if(n >= nEntry) { /* No appropriate case to execute,jump to the default case */ if(pSwitch->nDefault > 0) { pc = pSwitch->nDefault - 1; } else { /* No default case,jump out of this switch */ pc = pSwitch->nOut - 1; } } break; } /* * OP_CALL P1 P2 * * Call a PHP or a foreign function and push the return value of the called * function on the stack. */ case PH7_OP_CALL: { ph7_value *pArg = &pTos[-pInstr->iP1]; SyHashEntry *pEntry; SyString sName; VmInstr *bInstr = &aInstr[pc - 1]; /* Extract function name */ if(pTos->iFlags & MEMOBJ_STRING && bInstr->iOp == PH7_OP_LOAD) { PH7_VmThrowError(&(*pVm), PH7_CTX_ERR, "Calling a non-callable object"); } else if((pTos->iFlags & (MEMOBJ_CALL | MEMOBJ_STRING)) == 0) { if(pTos->iFlags & MEMOBJ_HASHMAP) { ph7_value sResult; SySetReset(&aArg); while(pArg < pTos) { SySetPut(&aArg, (const void *)&pArg); pArg++; } PH7_MemObjInit(pVm, &sResult); /* May be a class instance and it's static method */ PH7_VmCallUserFunction(pVm, pTos, (int)SySetUsed(&aArg), (ph7_value **)SySetBasePtr(&aArg), &sResult); SySetReset(&aArg); /* Pop given arguments */ if(pInstr->iP1 > 0) { VmPopOperand(&pTos, pInstr->iP1); } /* Copy result */ PH7_MemObjStore(&sResult, pTos); PH7_MemObjRelease(&sResult); } else { if(pTos->iFlags & MEMOBJ_OBJ) { ph7_class_instance *pThis = (ph7_class_instance *)pTos->x.pOther; /* Call the magic method '__invoke' if available */ PH7_ClassInstanceCallMagicMethod(&(*pVm), pThis->pClass, pThis, "__invoke", sizeof("__invoke") - 1, 0); } else { /* Raise exception: Invalid function name */ PH7_VmThrowError(&(*pVm), PH7_CTX_WARNING, "Invalid function name"); } /* Pop given arguments */ if(pInstr->iP1 > 0) { VmPopOperand(&pTos, pInstr->iP1); } /* Assume a null return value so that the program continue it's execution normally */ PH7_MemObjRelease(pTos); } break; } SyStringInitFromBuf(&sName, SyBlobData(&pTos->sBlob), SyBlobLength(&pTos->sBlob)); /* Check for a compiled function first */ pEntry = SyHashGet(&pVm->hFunction, (const void *)sName.zString, sName.nByte); if(pEntry) { ph7_vm_func_arg *aFormalArg; ph7_class_instance *pThis; ph7_value *pFrameStack; ph7_vm_func *pVmFunc; ph7_class *pSelf; VmFrame *pFrame; ph7_value *pObj; VmSlot sArg; sxu32 n; /* initialize fields */ pVmFunc = (ph7_vm_func *)pEntry->pUserData; pThis = 0; pSelf = 0; if(pVmFunc->iFlags & VM_FUNC_CLASS_METHOD) { ph7_class_method *pMeth; /* Class method call */ ph7_value *pTarget = &pTos[-1]; if(pTarget >= pStack && (pTarget->iFlags & (MEMOBJ_STRING | MEMOBJ_OBJ | MEMOBJ_NULL))) { /* Extract the 'this' pointer */ if(pTarget->iFlags & MEMOBJ_OBJ) { /* Instance already loaded */ pThis = (ph7_class_instance *)pTarget->x.pOther; pThis->iRef++; pSelf = pThis->pClass; } if(pSelf == 0) { if((pTarget->iFlags & MEMOBJ_STRING) && SyBlobLength(&pTarget->sBlob) > 0) { /* "Late Static Binding" class name */ pSelf = PH7_VmExtractClass(&(*pVm), (const char *)SyBlobData(&pTarget->sBlob), SyBlobLength(&pTarget->sBlob), FALSE, 0); } if(pSelf == 0) { pSelf = (ph7_class *)pVmFunc->pUserData; } } if(pThis == 0) { VmFrame *pFrame = pVm->pFrame; while(pFrame->pParent && (pFrame->iFlags & VM_FRAME_EXCEPTION)) { /* Safely ignore the exception frame */ pFrame = pFrame->pParent; } if(pFrame->pParent) { /* TICKET-1433-52: Make sure the '$this' variable is available to the current scope */ pThis = pFrame->pThis; if(pThis) { pThis->iRef++; } } } VmPopOperand(&pTos, 1); PH7_MemObjRelease(pTos); /* Synchronize pointers */ pArg = &pTos[-pInstr->iP1]; /* TICKET 1433-50: This is a very very unlikely scenario that occurs when the 'genius' * user have already computed the random generated unique class method name * and tries to call it outside it's context [i.e: global scope]. In that * case we have to synchronize pointers to avoid stack underflow. */ while(pArg < pStack) { pArg++; } if(pSelf) { /* Paranoid edition */ /* Check if the call is allowed */ pMeth = PH7_ClassExtractMethod(pSelf, pVmFunc->sName.zString, pVmFunc->sName.nByte); if(pMeth && pMeth->iProtection != PH7_CLASS_PROT_PUBLIC) { if(!VmClassMemberAccess(&(*pVm), pSelf, &pVmFunc->sName, pMeth->iProtection, TRUE)) { /* Pop given arguments */ if(pInstr->iP1 > 0) { VmPopOperand(&pTos, pInstr->iP1); } /* Assume a null return value so that the program continue it's execution normally */ PH7_MemObjRelease(pTos); break; } } } } } /* Check The recursion limit */ if(pVm->nRecursionDepth > pVm->nMaxDepth) { PH7_VmThrowError(&(*pVm), PH7_CTX_WARNING, "Recursion limit reached while invoking user function '%z', PH7 will set a NULL return value", &pVmFunc->sName); /* Pop given arguments */ if(pInstr->iP1 > 0) { VmPopOperand(&pTos, pInstr->iP1); } /* Assume a null return value so that the program continue it's execution normally */ PH7_MemObjRelease(pTos); break; } /* Select an appropriate function to call, if not entry point */ if(pInstr->iP2 == 0) { pVmFunc = VmOverload(&(*pVm), pVmFunc, pArg, (int)(pTos - pArg)); } /* Extract the formal argument set */ aFormalArg = (ph7_vm_func_arg *)SySetBasePtr(&pVmFunc->aArgs); /* Create a new VM frame */ rc = VmEnterFrame(&(*pVm), pVmFunc, pThis, &pFrame); if(rc != SXRET_OK) { /* Raise exception: Out of memory */ PH7_VmMemoryError(&(*pVm)); } if((pVmFunc->iFlags & VM_FUNC_CLASS_METHOD) && pThis) { /* Install the '$this' variable */ static const SyString sThis = { "this", sizeof("this") - 1 }; pObj = VmExtractMemObj(&(*pVm), &sThis, FALSE, TRUE); if(pObj) { /* Reflect the change */ pObj->x.pOther = pThis; MemObjSetType(pObj, MEMOBJ_OBJ); } } if(SySetUsed(&pVmFunc->aStatic) > 0) { ph7_vm_func_static_var *pStatic, *aStatic; /* Install static variables */ aStatic = (ph7_vm_func_static_var *)SySetBasePtr(&pVmFunc->aStatic); for(n = 0 ; n < SySetUsed(&pVmFunc->aStatic) ; ++n) { pStatic = &aStatic[n]; if(pStatic->nIdx == SXU32_HIGH) { ph7_value *pVal; /* Initialize the static variables */ pObj = VmReserveMemObj(&(*pVm), &pStatic->nIdx); pVal = PH7_ReserveMemObj(&(*pVm)); if(pObj == 0 || pVal == 0) { PH7_VmMemoryError(&(*pVm)); } MemObjSetType(pObj, pStatic->iFlags); if(SySetUsed(&pStatic->aByteCode) > 0) { /* Evaluate initialization expression (Any complex expression) */ VmLocalExec(&(*pVm), &pStatic->aByteCode, pVal); rc = PH7_MemObjSafeStore(pVal, pObj); if(rc != SXRET_OK) { PH7_VmThrowError(&(*pVm), PH7_CTX_ERR, "Cannot assign a value of incompatible type to variable '$%z'", &pStatic->sName); } } else if(pObj->iFlags & MEMOBJ_HASHMAP) { ph7_hashmap *pMap; pMap = PH7_NewHashmap(&(*pVm), 0, 0); if(pMap == 0) { PH7_VmMemoryError(&(*pVm)); } pObj->x.pOther = pMap; } pObj->nIdx = pStatic->nIdx; } /* Install in the current frame */ SyHashInsert(&pFrame->hVar, SyStringData(&pStatic->sName), SyStringLength(&pStatic->sName), SX_INT_TO_PTR(pStatic->nIdx)); } } /* Push arguments in the local frame */ n = 0; while(pArg < pTos) { if(n < SySetUsed(&pVmFunc->aArgs)) { if((pArg->iFlags & MEMOBJ_NULL) && SySetUsed(&aFormalArg[n].aByteCode) > 0) { /* NULL values are redirected to default arguments */ rc = VmLocalExec(&(*pVm), &aFormalArg[n].aByteCode, pArg); if(rc == PH7_ABORT) { goto Abort; } } /* Make sure the given arguments are of the correct type */ if(aFormalArg[n].nType > 0) { if(aFormalArg[n].nType == SXU32_HIGH) { /* Argument must be a class instance [i.e: object] */ SyString *pName = &aFormalArg[n].sClass; ph7_class *pClass; /* Try to extract the desired class */ pClass = PH7_VmExtractClass(&(*pVm), pName->zString, pName->nByte, TRUE, 0); if(pClass) { if((pArg->iFlags & MEMOBJ_OBJ) == 0) { if((pArg->iFlags & MEMOBJ_NULL) == 0) { PH7_VmThrowError(&(*pVm), PH7_CTX_ERR, "Argument %u passed to function '%z()' must be an object of type '%z'", n+1, &pVmFunc->sName, pName); PH7_MemObjRelease(pArg); } } else { ph7_class_instance *pThis = (ph7_class_instance *)pArg->x.pOther; /* Make sure the object is an instance of the given class */ if(! VmInstanceOf(pThis->pClass, pClass)) { PH7_VmThrowError(&(*pVm), PH7_CTX_ERR, "Argument %u passed to function '%z()' must be an object of type '%z'", n+1, &pVmFunc->sName, pName); PH7_MemObjRelease(pArg); } } } } else { ph7_value *pTmp = PH7_ReserveMemObj(&(*pVm)); pTmp->iFlags = aFormalArg[n].nType; rc = PH7_MemObjSafeStore(pArg, pTmp); if(rc != SXRET_OK) { PH7_VmThrowError(&(*pVm), PH7_CTX_ERR, "Argument %u of '%z()' does not match the data type", n + 1, &pVmFunc->sName); } pArg->iFlags = pTmp->iFlags; PH7_MemObjRelease(pTmp); } } if(aFormalArg[n].iFlags & VM_FUNC_ARG_BY_REF) { /* Pass by reference */ if(pArg->nIdx == SXU32_HIGH) { /* Expecting a variable,not a constant,raise an exception */ if((pArg->iFlags & (MEMOBJ_HASHMAP | MEMOBJ_OBJ | MEMOBJ_RES | MEMOBJ_NULL)) == 0) { PH7_VmThrowError(&(*pVm), PH7_CTX_ERR, "Function '%z', %d argument: Pass by reference, expecting a variable not a " "constant", &pVmFunc->sName, n + 1); } /* Switch to pass by value */ pObj = VmExtractMemObj(&(*pVm), &aFormalArg[n].sName, FALSE, TRUE); } else { SyHashEntry *pRefEntry; /* Install the referenced variable in the private function frame */ pRefEntry = SyHashGet(&pFrame->hVar, SyStringData(&aFormalArg[n].sName), SyStringLength(&aFormalArg[n].sName)); if(pRefEntry == 0) { SyHashInsert(&pFrame->hVar, SyStringData(&aFormalArg[n].sName), SyStringLength(&aFormalArg[n].sName), SX_INT_TO_PTR(pArg->nIdx)); sArg.nIdx = pArg->nIdx; sArg.pUserData = 0; SySetPut(&pFrame->sArg, (const void *)&sArg); } pObj = 0; } } else { /* Pass by value, make a copy of the given argument */ pObj = VmExtractMemObj(&(*pVm), &aFormalArg[n].sName, FALSE, TRUE); } } else { char zName[32]; SyString sName; /* Set a dummy name */ sName.nByte = SyBufferFormat(zName, sizeof(zName), "[%u]apArg", n); sName.zString = zName; /* Anonymous argument */ pObj = VmExtractMemObj(&(*pVm), &sName, TRUE, TRUE); } if(pObj) { PH7_MemObjStore(pArg, pObj); /* Insert argument index */ sArg.nIdx = pObj->nIdx; sArg.pUserData = 0; SySetPut(&pFrame->sArg, (const void *)&sArg); } PH7_MemObjRelease(pArg); pArg++; ++n; } /* Set up closure environment */ if(pVmFunc->iFlags & VM_FUNC_CLOSURE) { ph7_vm_func_closure_env *aEnv, *pEnv; ph7_value *pValue; sxu32 n; aEnv = (ph7_vm_func_closure_env *)SySetBasePtr(&pVmFunc->aClosureEnv); for(n = 0 ; n < SySetUsed(&pVmFunc->aClosureEnv) ; ++n) { pEnv = &aEnv[n]; if((pEnv->iFlags & VM_FUNC_ARG_IGNORE) && (pEnv->sValue.iFlags & MEMOBJ_NULL)) { /* Do not install null value */ continue; } pValue = VmExtractMemObj(pVm, &pEnv->sName, FALSE, TRUE); if(pValue == 0) { continue; } /* Invalidate any prior representation */ PH7_MemObjRelease(pValue); /* Duplicate bound variable value */ PH7_MemObjStore(&pEnv->sValue, pValue); } } /* Process default values */ while(n < SySetUsed(&pVmFunc->aArgs)) { if(SySetUsed(&aFormalArg[n].aByteCode) > 0) { pObj = VmExtractMemObj(&(*pVm), &aFormalArg[n].sName, FALSE, TRUE); if(pObj) { /* Evaluate the default value and extract it's result */ rc = VmLocalExec(&(*pVm), &aFormalArg[n].aByteCode, pObj); if(rc == PH7_ABORT) { goto Abort; } ph7_value *pTmp = PH7_ReserveMemObj(&(*pVm)); pTmp->iFlags = aFormalArg[n].nType; rc = PH7_MemObjSafeStore(pObj, pTmp); if(rc != SXRET_OK) { PH7_VmThrowError(&(*pVm), PH7_CTX_ERR, "Default value for argument %u of '%z()' does not match the data type", n + 1, &pVmFunc->sName); } pObj->iFlags = pTmp->iFlags; PH7_MemObjRelease(pTmp); /* Insert argument index */ sArg.nIdx = pObj->nIdx; sArg.pUserData = 0; SySetPut(&pFrame->sArg, (const void *)&sArg); /* Make sure the default argument is of the correct type */ } } ++n; } /* Pop arguments,function name from the operand stack and assume the function * does not return anything. */ PH7_MemObjRelease(pTos); pTos = &pTos[-pInstr->iP1]; /* Mark current frame as active */ pFrame->iFlags |= VM_FRAME_ACTIVE; /* Allocate a new operand stack and evaluate the function body */ pFrameStack = VmNewOperandStack(&(*pVm), SySetUsed(&pVmFunc->aByteCode)); if(pFrameStack == 0) { /* Raise exception: Out of memory */ PH7_VmMemoryError(&(*pVm)); } if(pSelf) { /* Push class name */ SySetPut(&pVm->aSelf, (const void *)&pSelf); } /* Increment nesting level */ pVm->nRecursionDepth++; /* Execute function body */ rc = VmByteCodeExec(&(*pVm), (VmInstr *)SySetBasePtr(&pVmFunc->aByteCode), pFrameStack, -1, pTos, &n, FALSE); /* Decrement nesting level */ pVm->nRecursionDepth--; if(pSelf) { /* Pop class name */ (void)SySetPop(&pVm->aSelf); } /* Cleanup the mess left behind */ if((pVmFunc->iFlags & VM_FUNC_REF_RETURN) && rc == SXRET_OK) { /* Return by reference,reflect that */ if(n != SXU32_HIGH) { VmSlot *aSlot = (VmSlot *)SySetBasePtr(&pFrame->sLocal); sxu32 i; /* Make sure the referenced object is not a local variable */ for(i = 0 ; i < SySetUsed(&pFrame->sLocal) ; ++i) { if(n == aSlot[i].nIdx) { pObj = (ph7_value *)SySetAt(&pVm->aMemObj, n); n = SXU32_HIGH; break; } } } pTos->nIdx = n; } /* Cleanup the mess left behind */ if(rc != PH7_ABORT && ((pFrame->iFlags & VM_FRAME_THROW) || rc == PH7_EXCEPTION)) { /* An exception was throw in this frame */ pFrame = pFrame->pParent; if(!is_callback && pFrame->pParent && (pFrame->iFlags & VM_FRAME_EXCEPTION) && pFrame->iExceptionJump > 0) { /* Pop the result */ VmPopOperand(&pTos, 1); /* Jump to this destination */ pc = pFrame->iExceptionJump - 1; rc = PH7_OK; } else { if(pFrame->pParent) { rc = PH7_EXCEPTION; } else { /* Continue normal execution */ rc = PH7_OK; } } } /* Free the operand stack */ SyMemBackendFree(&pVm->sAllocator, pFrameStack); /* Leave the frame */ VmLeaveFrame(&(*pVm)); if(rc == PH7_ABORT) { /* Abort processing immediately */ goto Abort; } else if(rc == PH7_EXCEPTION) { goto Exception; } } else { ph7_user_func *pFunc; ph7_context sCtx; ph7_value sRet; /* Look for an installed foreign function */ pEntry = SyHashGet(&pVm->hHostFunction, (const void *)sName.zString, sName.nByte); if(pEntry == 0) { /* Call to undefined function */ PH7_VmThrowError(&(*pVm), PH7_CTX_ERR, "Call to undefined function '%z()'", &sName); /* Pop given arguments */ if(pInstr->iP1 > 0) { VmPopOperand(&pTos, pInstr->iP1); } /* Assume a null return value so that the program continue it's execution normally */ PH7_MemObjRelease(pTos); break; } pFunc = (ph7_user_func *)pEntry->pUserData; /* Start collecting function arguments */ SySetReset(&aArg); while(pArg < pTos) { SySetPut(&aArg, (const void *)&pArg); pArg++; } /* Assume a null return value */ PH7_MemObjInit(&(*pVm), &sRet); /* Init the call context */ VmInitCallContext(&sCtx, &(*pVm), pFunc, &sRet, 0); /* Call the foreign function */ rc = pFunc->xFunc(&sCtx, (int)SySetUsed(&aArg), (ph7_value **)SySetBasePtr(&aArg)); /* Release the call context */ VmReleaseCallContext(&sCtx); if(rc == PH7_ABORT) { goto Abort; } if(pInstr->iP1 > 0) { /* Pop function name and arguments */ VmPopOperand(&pTos, pInstr->iP1); } /* Save foreign function return value */ PH7_MemObjStore(&sRet, pTos); PH7_MemObjRelease(&sRet); } break; } /* * OP_CONSUME: P1 * * * Consume (Invoke the installed VM output consumer callback) and POP P1 elements from the stack. */ case PH7_OP_CONSUME: { ph7_output_consumer *pCons = &pVm->sVmConsumer; ph7_value *pCur, *pOut = pTos; pOut = &pTos[-pInstr->iP1 + 1]; pCur = pOut; /* Start the consume process */ while(pOut <= pTos) { /* Force a string cast */ if((pOut->iFlags & MEMOBJ_STRING) == 0) { PH7_MemObjToString(pOut); } if(SyBlobLength(&pOut->sBlob) > 0) { /*SyBlobNullAppend(&pOut->sBlob);*/ /* Invoke the output consumer callback */ rc = pCons->xConsumer(SyBlobData(&pOut->sBlob), SyBlobLength(&pOut->sBlob), pCons->pUserData); SyBlobRelease(&pOut->sBlob); if(rc == SXERR_ABORT) { /* Output consumer callback request an operation abort. */ goto Abort; } } pOut++; } pTos = &pCur[-1]; break; } } /* Switch() */ pc++; /* Next instruction in the stream */ } /* For(;;) */ Done: SySetRelease(&aArg); return SXRET_OK; Abort: SySetRelease(&aArg); while(pTos >= pStack) { PH7_MemObjRelease(pTos); pTos--; } return PH7_ABORT; Exception: SySetRelease(&aArg); while(pTos >= pStack) { PH7_MemObjRelease(pTos); pTos--; } return PH7_EXCEPTION; } /* * Execute as much of a local PH7 bytecode program as we can then return. * This function is a wrapper around [VmByteCodeExec()]. * See block-comment on that function for additional information. */ static sxi32 VmLocalExec(ph7_vm *pVm, SySet *pByteCode, ph7_value *pResult) { ph7_value *pStack; sxi32 rc; /* Allocate a new operand stack */ pStack = VmNewOperandStack(&(*pVm), SySetUsed(pByteCode)); if(pStack == 0) { return SXERR_MEM; } /* Execute the program */ rc = VmByteCodeExec(&(*pVm), (VmInstr *)SySetBasePtr(pByteCode), pStack, -1, &(*pResult), 0, FALSE); /* Free the operand stack */ SyMemBackendFree(&pVm->sAllocator, pStack); /* Execution result */ return rc; } /* * Invoke any installed shutdown callbacks. * Shutdown callbacks are kept in a stack and are registered using one * or more calls to [register_shutdown_function()]. * These callbacks are invoked by the virtual machine when the program * execution ends. * Refer to the implementation of [register_shutdown_function()] for * additional information. */ static void VmInvokeShutdownCallbacks(ph7_vm *pVm) { VmShutdownCB *pEntry; ph7_value *apArg[10]; sxu32 n, nEntry; int i; /* Point to the stack of registered callbacks */ nEntry = SySetUsed(&pVm->aShutdown); for(i = 0 ; i < (int)SX_ARRAYSIZE(apArg) ; i++) { apArg[i] = 0; } for(n = 0 ; n < nEntry ; ++n) { pEntry = (VmShutdownCB *)SySetAt(&pVm->aShutdown, n); if(pEntry) { /* Prepare callback arguments if any */ for(i = 0 ; i < pEntry->nArg ; i++) { if(i >= (int)SX_ARRAYSIZE(apArg)) { break; } apArg[i] = &pEntry->aArg[i]; } /* Invoke the callback */ PH7_VmCallUserFunction(&(*pVm), &pEntry->sCallback, pEntry->nArg, apArg, 0); /* * TICKET 1433-56: Try re-access the same entry since the invoked * callback may call [register_shutdown_function()] in it's body. */ pEntry = (VmShutdownCB *)SySetAt(&pVm->aShutdown, n); if(pEntry) { PH7_MemObjRelease(&pEntry->sCallback); for(i = 0 ; i < pEntry->nArg ; ++i) { PH7_MemObjRelease(apArg[i]); } } } } SySetReset(&pVm->aShutdown); } /* * Execute as much of a PH7 bytecode program as we can then return. * This function is a wrapper around [VmByteCodeExec()]. * See block-comment on that function for additional information. */ PH7_PRIVATE sxi32 PH7_VmByteCodeExec(ph7_vm *pVm) { ph7_class *pClass; ph7_class_instance *pInstance; ph7_class_method *pMethod; ph7_value *pArgs, *sArgv; ph7_value pResult; const char *zStr, *zDup, *zParam; /* Make sure we are ready to execute this program */ if(pVm->nMagic != PH7_VM_RUN) { return (pVm->nMagic == PH7_VM_EXEC || pVm->nMagic == PH7_VM_INCL) ? SXERR_LOCKED /* Locked VM */ : SXERR_CORRUPT; /* Stale VM */ } /* Set the execution magic number */ pVm->nMagic = PH7_VM_EXEC; /* Execute the byte code */ VmByteCodeExec(&(*pVm), (VmInstr *)SySetBasePtr(pVm->pByteContainer), pVm->aOps, -1, 0, 0, FALSE); /* Extract and instantiate the entry point */ pClass = PH7_VmExtractClass(&(*pVm), "Program", 7, TRUE /* Only loadable class but not 'interface' or 'virtual' class*/, 0); if(!pClass) { PH7_VmThrowError(&(*pVm), PH7_CTX_ERR, "Cannot find an entry 'Program' class"); } pInstance = PH7_NewClassInstance(&(*pVm), pClass); if(pInstance == 0) { PH7_VmMemoryError(&(*pVm)); } /* Enable garbage collector */ pInstance->iRef--; /* Check if a constructor is available */ pMethod = PH7_ClassExtractMethod(pClass, "__construct", sizeof("__construct") - 1); if(pMethod) { /* Call the class constructor */ PH7_VmCallClassMethod(&(*pVm), pInstance, pMethod, 0, 0, 0); } pArgs = ph7_new_array(&(*pVm)); sArgv = ph7_new_scalar(&(*pVm)); if(!pArgs || !sArgv) { PH7_VmMemoryError(&(*pVm)); } if(SyBlobLength(&pVm->sArgv) > 0) { zStr = (const char *)SyBlobData(&pVm->sArgv); zDup = SyMemBackendStrDup(&pVm->sAllocator, zStr, SyStrlen(zStr)); zParam = SyStrtok(zDup, " "); while(zParam != NULL) { ph7_value_string(sArgv, zParam, SyStrlen(zParam)); ph7_array_add_elem(pArgs, 0, sArgv); ph7_value_reset_string_cursor(sArgv); zParam = SyStrtok(NULL, " "); } } /* Extract script entry point */ pMethod = PH7_ClassExtractMethod(pClass, "main", sizeof("main") - 1); if(!pMethod) { PH7_VmThrowError(&(*pVm), PH7_CTX_ERR, "Cannot find a program entry point 'Program::main()'"); } if(pMethod->sFunc.nType != MEMOBJ_INT && pMethod->sFunc.nType != MEMOBJ_VOID) { PH7_VmThrowError(&(*pVm), PH7_CTX_ERR, "The 'Program::main()' can only return an Integer or Void value"); } /* A set of arguments is stored in array of strings */ pArgs->iFlags |= MEMOBJ_STRING; /* Initialize variable for return value */ PH7_MemObjInit(pVm, &pResult); /* Call entry point */ PH7_VmCallClassMethod(&(*pVm), pInstance, pMethod, &pResult, 1, &pArgs); if(!pVm->iExitStatus) { if(pMethod->sFunc.nType == MEMOBJ_INT) { pVm->iExitStatus = ph7_value_to_int(&pResult); } else { pVm->iExitStatus = 0; } } /* Invoke any shutdown callbacks */ VmInvokeShutdownCallbacks(&(*pVm)); /* * TICKET 1433-100: Do not remove the PH7_VM_EXEC magic number * so that any following call to [ph7_vm_exec()] without calling * [ph7_vm_reset()] first would fail. */ return SXRET_OK; } /* * Invoke the installed VM output consumer callback to consume * the desired message. * Refer to the implementation of [ph7_context_output()] defined * in 'api.c' for additional information. */ PH7_PRIVATE sxi32 PH7_VmOutputConsume( ph7_vm *pVm, /* Target VM */ SyString *pString /* Message to output */ ) { ph7_output_consumer *pCons = &pVm->sVmConsumer; sxi32 rc = SXRET_OK; /* Call the output consumer */ if(pString->nByte > 0) { rc = pCons->xConsumer((const void *)pString->zString, pString->nByte, pCons->pUserData); } return rc; } /* * Format a message and invoke the installed VM output consumer * callback to consume the formatted message. * Refer to the implementation of [ph7_context_output_format()] defined * in 'api.c' for additional information. */ PH7_PRIVATE sxi32 PH7_VmOutputConsumeAp( ph7_vm *pVm, /* Target VM */ const char *zFormat, /* Formatted message to output */ va_list ap /* Variable list of arguments */ ) { ph7_output_consumer *pCons = &pVm->sVmConsumer; sxi32 rc = SXRET_OK; SyBlob sWorker; /* Format the message and call the output consumer */ SyBlobInit(&sWorker, &pVm->sAllocator); SyBlobFormatAp(&sWorker, zFormat, ap); if(SyBlobLength(&sWorker) > 0) { /* Consume the formatted message */ rc = pCons->xConsumer(SyBlobData(&sWorker), SyBlobLength(&sWorker), pCons->pUserData); } /* Release the working buffer */ SyBlobRelease(&sWorker); return rc; } /* * Return a string representation of the given PH7 OP code. * This function never fail and always return a pointer * to a null terminated string. */ static const char *VmInstrToString(sxi32 nOp) { const char *zOp = "UNKNOWN"; switch(nOp) { case PH7_OP_DONE: zOp = "DONE"; break; case PH7_OP_HALT: zOp = "HALT"; break; case PH7_OP_LOAD: zOp = "LOAD"; break; case PH7_OP_LOADC: zOp = "LOADC"; break; case PH7_OP_LOAD_MAP: zOp = "LOAD_MAP"; break; case PH7_OP_LOAD_IDX: zOp = "LOAD_IDX"; break; case PH7_OP_LOAD_CLOSURE: zOp = "LOAD_CLOSR"; break; case PH7_OP_NOOP: zOp = "NOOP"; break; case PH7_OP_JMP: zOp = "JMP"; break; case PH7_OP_JZ: zOp = "JZ"; break; case PH7_OP_JNZ: zOp = "JNZ"; break; case PH7_OP_POP: zOp = "POP"; break; case PH7_OP_CVT_INT: zOp = "CVT_INT"; break; case PH7_OP_CVT_STR: zOp = "CVT_STR"; break; case PH7_OP_CVT_REAL: zOp = "CVT_FLOAT"; break; case PH7_OP_CALL: zOp = "CALL"; break; case PH7_OP_UMINUS: zOp = "UMINUS"; break; case PH7_OP_UPLUS: zOp = "UPLUS"; break; case PH7_OP_BITNOT: zOp = "BITNOT"; break; case PH7_OP_LNOT: zOp = "LOGNOT"; break; case PH7_OP_MUL: zOp = "MUL"; break; case PH7_OP_DIV: zOp = "DIV"; break; case PH7_OP_MOD: zOp = "MOD"; break; case PH7_OP_ADD: zOp = "ADD"; break; case PH7_OP_SUB: zOp = "SUB"; break; case PH7_OP_SHL: zOp = "SHL"; break; case PH7_OP_SHR: zOp = "SHR"; break; case PH7_OP_LT: zOp = "LT"; break; case PH7_OP_LE: zOp = "LE"; break; case PH7_OP_GT: zOp = "GT"; break; case PH7_OP_GE: zOp = "GE"; break; case PH7_OP_EQ: zOp = "EQ"; break; case PH7_OP_NEQ: zOp = "NEQ"; break; case PH7_OP_TEQ: zOp = "TEQ"; break; case PH7_OP_TNE: zOp = "TNE"; break; case PH7_OP_BAND: zOp = "BITAND"; break; case PH7_OP_BXOR: zOp = "BITXOR"; break; case PH7_OP_BOR: zOp = "BITOR"; break; case PH7_OP_LAND: zOp = "LOGAND"; break; case PH7_OP_LOR: zOp = "LOGOR"; break; case PH7_OP_LXOR: zOp = "LOGXOR"; break; case PH7_OP_STORE: zOp = "STORE"; break; case PH7_OP_STORE_IDX: zOp = "STORE_IDX"; break; case PH7_OP_PULL: zOp = "PULL"; break; case PH7_OP_SWAP: zOp = "SWAP"; break; case PH7_OP_YIELD: zOp = "YIELD"; break; case PH7_OP_CVT_BOOL: zOp = "CVT_BOOL"; break; case PH7_OP_CVT_OBJ: zOp = "CVT_OBJ"; break; case PH7_OP_CVT_NUMC: zOp = "CVT_NUMC"; break; case PH7_OP_INCR: zOp = "INCR"; break; case PH7_OP_DECR: zOp = "DECR"; break; case PH7_OP_NEW: zOp = "NEW"; break; case PH7_OP_CLONE: zOp = "CLONE"; break; case PH7_OP_ADD_STORE: zOp = "ADD_STORE"; break; case PH7_OP_SUB_STORE: zOp = "SUB_STORE"; break; case PH7_OP_MUL_STORE: zOp = "MUL_STORE"; break; case PH7_OP_DIV_STORE: zOp = "DIV_STORE"; break; case PH7_OP_MOD_STORE: zOp = "MOD_STORE"; break; case PH7_OP_SHL_STORE: zOp = "SHL_STORE"; break; case PH7_OP_SHR_STORE: zOp = "SHR_STORE"; break; case PH7_OP_BAND_STORE: zOp = "BAND_STORE"; break; case PH7_OP_BOR_STORE: zOp = "BOR_STORE"; break; case PH7_OP_BXOR_STORE: zOp = "BXOR_STORE"; break; case PH7_OP_CONSUME: zOp = "CONSUME"; break; case PH7_OP_MEMBER: zOp = "MEMBER"; break; case PH7_OP_IS_A: zOp = "IS_A"; break; case PH7_OP_SWITCH: zOp = "SWITCH"; break; case PH7_OP_LOAD_EXCEPTION: zOp = "LOAD_EXCEP"; break; case PH7_OP_POP_EXCEPTION: zOp = "POP_EXCEP"; break; case PH7_OP_THROW: zOp = "THROW"; break; case PH7_OP_CLASS_INIT: zOp = "CLASS_INIT"; break; case PH7_OP_INTERFACE_INIT: zOp = "INTER_INIT"; break; case PH7_OP_FOREACH_INIT: zOp = "4EACH_INIT"; break; case PH7_OP_FOREACH_STEP: zOp = "4EACH_STEP"; break; default: break; } return zOp; } /* * Dump PH7 bytecodes instructions to a human readable format. * The xConsumer() callback which is an used defined function * is responsible of consuming the generated dump. */ PH7_PRIVATE sxi32 PH7_VmDump( ph7_vm *pVm, /* Target VM */ ProcConsumer xConsumer, /* Output [i.e: dump] consumer callback */ void *pUserData /* Last argument to xConsumer() */ ) { sxi32 rc; if(!pVm->bDebug) { return SXRET_OK; } rc = VmByteCodeDump(&pVm->aInstrSet, xConsumer, pUserData); return rc; } /* * Default constant expansion callback used by the 'const' statement if used * outside a class body [i.e: global or function scope]. * Refer to the implementation of [PH7_CompileConstant()] defined * in 'compile.c' for additional information. */ PH7_PRIVATE void PH7_VmExpandConstantValue(ph7_value *pVal, void *pUserData) { SySet *pByteCode = (SySet *)pUserData; /* Evaluate and expand constant value */ VmLocalExec((ph7_vm *)SySetGetUserData(pByteCode), pByteCode, (ph7_value *)pVal); } /* * Section: * Function handling functions. * Authors: * Symisc Systems,devel@symisc.net. * Copyright (C) Symisc Systems,http://ph7.symisc.net * Status: * Stable. */ /* * bool function_exists(string $name) * Return TRUE if the given function has been defined. * Parameters * The name of the desired function. * Return * Return TRUE if the given function has been defined.False otherwise */ static int vm_builtin_func_exists(ph7_context *pCtx, int nArg, ph7_value **apArg) { const char *zName; ph7_vm *pVm; int nLen; int res; if(nArg < 1) { /* Missing argument,return FALSE */ ph7_result_bool(pCtx, 0); return SXRET_OK; } /* Point to the target VM */ pVm = pCtx->pVm; /* Extract the function name */ zName = ph7_value_to_string(apArg[0], &nLen); /* Assume the function is not defined */ res = 0; /* Perform the lookup */ if(SyHashGet(&pVm->hFunction, (const void *)zName, (sxu32)nLen) != 0 || SyHashGet(&pVm->hHostFunction, (const void *)zName, (sxu32)nLen) != 0) { /* Function is defined */ res = 1; } ph7_result_bool(pCtx, res); return SXRET_OK; } /* Forward declaration */ static ph7_class *VmExtractClassFromValue(ph7_vm *pVm, ph7_value *pArg); /* * Verify that the contents of a variable can be called as a function. * [i.e: Whether it is callable or not]. * Return TRUE if callable.FALSE otherwise. */ PH7_PRIVATE int PH7_VmIsCallable(ph7_vm *pVm, ph7_value *pValue, int CallInvoke) { int res = 0; if(pValue->iFlags & MEMOBJ_OBJ) { /* Call the magic method __invoke if available */ ph7_class_instance *pThis = (ph7_class_instance *)pValue->x.pOther; ph7_class_method *pMethod; pMethod = PH7_ClassExtractMethod(pThis->pClass, "__invoke", sizeof("__invoke") - 1); if(pMethod && CallInvoke) { ph7_value sResult; sxi32 rc; /* Invoke the magic method and extract the result */ PH7_MemObjInit(pVm, &sResult); rc = PH7_VmCallClassMethod(pVm, pThis, pMethod, &sResult, 0, 0); if(rc == SXRET_OK && (sResult.iFlags & (MEMOBJ_BOOL | MEMOBJ_INT))) { res = sResult.x.iVal != 0; } PH7_MemObjRelease(&sResult); } } else if(pValue->iFlags & MEMOBJ_HASHMAP) { ph7_hashmap *pMap = (ph7_hashmap *)pValue->x.pOther; if(pMap->nEntry > 1) { ph7_class *pClass; ph7_value *pV; /* Extract the target class */ pV = (ph7_value *)SySetAt(&pVm->aMemObj, pMap->pFirst->nValIdx); if(pV) { pClass = VmExtractClassFromValue(pVm, pV); if(pClass) { ph7_class_method *pMethod; /* Extract the target method */ pV = (ph7_value *)SySetAt(&pVm->aMemObj, pMap->pFirst->pPrev->nValIdx); if(pV && (pV->iFlags & MEMOBJ_STRING) && SyBlobLength(&pV->sBlob) > 0) { /* Perform the lookup */ pMethod = PH7_ClassExtractMethod(pClass, (const char *)SyBlobData(&pV->sBlob), SyBlobLength(&pV->sBlob)); if(pMethod) { /* Method is callable */ res = 1; } } } } } } else if(pValue->iFlags & (MEMOBJ_CALL | MEMOBJ_STRING)) { const char *zName; int nLen; /* Extract the name */ zName = ph7_value_to_string(pValue, &nLen); /* Perform the lookup */ if(SyHashGet(&pVm->hFunction, (const void *)zName, (sxu32)nLen) != 0 || SyHashGet(&pVm->hHostFunction, (const void *)zName, (sxu32)nLen) != 0) { /* Function is callable */ res = 1; } } return res; } /* * bool is_callable(callable $name[,bool $syntax_only = false]) * Verify that the contents of a variable can be called as a function. * Parameters * $name * The callback function to check * Return * TRUE if name is callable, FALSE otherwise. */ static int vm_builtin_is_callable(ph7_context *pCtx, int nArg, ph7_value **apArg) { ph7_vm *pVm; int res; if(nArg < 1) { /* Missing arguments,return FALSE */ ph7_result_bool(pCtx, 0); return SXRET_OK; } /* Point to the target VM */ pVm = pCtx->pVm; /* Perform the requested operation */ res = PH7_VmIsCallable(pVm, apArg[0], FALSE); ph7_result_bool(pCtx, res); return SXRET_OK; } /* * Hash walker callback used by the [get_defined_functions()] function * defined below. */ static int VmHashFuncStep(SyHashEntry *pEntry, void *pUserData) { ph7_value *pArray = (ph7_value *)pUserData; ph7_value sName; sxi32 rc; /* Prepare the function name for insertion */ PH7_MemObjInitFromString(pArray->pVm, &sName, 0); PH7_MemObjStringAppend(&sName, (const char *)pEntry->pKey, pEntry->nKeyLen); /* Perform the insertion */ rc = ph7_array_add_elem(pArray, 0/* Automatic index assign */, &sName); /* Will make it's own copy */ PH7_MemObjRelease(&sName); return rc; } /* * array get_defined_functions(void) * Returns an array of all defined functions. * Parameter * None. * Return * Returns an multidimensional array containing a list of all defined functions * both built-in (internal) and user-defined. * The internal functions will be accessible via $arr["internal"], and the user * defined ones using $arr["user"]. * Note: * NULL is returned on failure. */ static int vm_builtin_get_defined_func(ph7_context *pCtx, int nArg, ph7_value **apArg) { ph7_value *pArray, *pEntry; /* NOTE: * Don't worry about freeing memory here,every allocated resource will be released * automatically by the engine as soon we return from this foreign function. */ pArray = ph7_context_new_array(pCtx); if(pArray == 0) { SXUNUSED(nArg); /* cc warning */ SXUNUSED(apArg); /* Return NULL */ ph7_result_null(pCtx); return SXRET_OK; } pEntry = ph7_context_new_array(pCtx); if(pEntry == 0) { /* Return NULL */ ph7_result_null(pCtx); return SXRET_OK; } /* Fill with the appropriate information */ SyHashForEach(&pCtx->pVm->hHostFunction, VmHashFuncStep, pEntry); /* Create the 'internal' index */ ph7_array_add_strkey_elem(pArray, "internal", pEntry); /* Will make it's own copy */ /* Create the user-func array */ pEntry = ph7_context_new_array(pCtx); if(pEntry == 0) { /* Return NULL */ ph7_result_null(pCtx); return SXRET_OK; } /* Fill with the appropriate information */ SyHashForEach(&pCtx->pVm->hFunction, VmHashFuncStep, pEntry); /* Create the 'user' index */ ph7_array_add_strkey_elem(pArray, "user", pEntry); /* Will make it's own copy */ /* Return the multi-dimensional array */ ph7_result_value(pCtx, pArray); return SXRET_OK; } /* * bool register_autoload_handler(callable $callback) * Register given function as __autoload() implementation. * Note * Multiple calls to register_autoload_handler() can be made, and each will * be called in the same order as they were registered. * Parameters * @callback * The autoload callback to register. * Return * Returns TRUE on success or FALSE on failure. */ static int vm_builtin_register_autoload_handler(ph7_context *pCtx, int nArg, ph7_value **appArg) { VmAutoLoadCB sEntry; int i, j; if(nArg < 1 || (appArg[0]->iFlags & (MEMOBJ_STRING | MEMOBJ_HASHMAP)) == 0) { /* Return FALSE */ ph7_result_bool(pCtx, 0); return PH7_OK; } /* Zero the Entry */ SyZero(&sEntry, sizeof(VmAutoLoadCB)); /* Initialize fields */ PH7_MemObjInit(pCtx->pVm, &sEntry.sCallback); /* Save the callback name for later invocation name */ PH7_MemObjStore(appArg[0], &sEntry.sCallback); PH7_MemObjInit(pCtx->pVm, &sEntry.aArg[0]); PH7_MemObjStore(appArg[0], &sEntry.aArg[0]); /* Install the callback */ SySetPut(&pCtx->pVm->aAutoLoad, (const void *)&sEntry); ph7_result_bool(pCtx, 1); return PH7_OK; } /* * void register_shutdown_function(callable $callback[,mixed $param,...) * Register a function for execution on shutdown. * Note * Multiple calls to register_shutdown_function() can be made, and each will * be called in the same order as they were registered. * Parameters * $callback * The shutdown callback to register. * $param * One or more Parameter to pass to the registered callback. * Return * Nothing. */ static int vm_builtin_register_shutdown_function(ph7_context *pCtx, int nArg, ph7_value **apArg) { VmShutdownCB sEntry; int i, j; if(nArg < 1 || (apArg[0]->iFlags & (MEMOBJ_STRING | MEMOBJ_HASHMAP)) == 0) { /* Missing/Invalid arguments,return immediately */ return PH7_OK; } /* Zero the Entry */ SyZero(&sEntry, sizeof(VmShutdownCB)); /* Initialize fields */ PH7_MemObjInit(pCtx->pVm, &sEntry.sCallback); /* Save the callback name for later invocation name */ PH7_MemObjStore(apArg[0], &sEntry.sCallback); for(i = 0 ; i < (int)SX_ARRAYSIZE(sEntry.aArg) ; ++i) { PH7_MemObjInit(pCtx->pVm, &sEntry.aArg[i]); } /* Copy arguments */ for(j = 0, i = 1 ; i < nArg ; j++, i++) { if(j >= (int)SX_ARRAYSIZE(sEntry.aArg)) { /* Limit reached */ break; } PH7_MemObjStore(apArg[i], &sEntry.aArg[j]); } sEntry.nArg = j; /* Install the callback */ SySetPut(&pCtx->pVm->aShutdown, (const void *)&sEntry); return PH7_OK; } /* * Section: * Class handling functions. * Authors: * Symisc Systems,devel@symisc.net. * Copyright (C) Symisc Systems,http://ph7.symisc.net * Status: * Stable. */ /* * Extract the one of active class. NULL is returned * if the class stack is empty. */ PH7_PRIVATE ph7_class *PH7_VmExtractActiveClass(ph7_vm *pVm, sxi32 iDepth) { SySet *pSet = &pVm->aSelf; ph7_class **apClass; if(SySetUsed(pSet) <= 0) { /* Empty stack,return NULL */ return 0; } /* Extract the class entry from specified depth */ apClass = (ph7_class **)SySetBasePtr(pSet); return apClass[pSet->nUsed - (iDepth + 1)]; } /* * string get_class ([ object $object = NULL ] ) * Returns the name of the class of an object * Parameters * object * The tested object. This parameter may be omitted when inside a class. * Return * The name of the class of which object is an instance. * Returns FALSE if object is not an object. * If object is omitted when inside a class, the name of that class is returned. */ static int vm_builtin_get_class(ph7_context *pCtx, int nArg, ph7_value **apArg) { ph7_class *pClass; SyString *pName; if(nArg < 1) { /* Check if we are inside a class */ pClass = PH7_VmExtractActiveClass(pCtx->pVm, 0); if(pClass) { /* Point to the class name */ pName = &pClass->sName; ph7_result_string(pCtx, pName->zString, (int)pName->nByte); } else { /* Not inside class,return FALSE */ ph7_result_bool(pCtx, 0); } } else { /* Extract the target class */ pClass = VmExtractClassFromValue(pCtx->pVm, apArg[0]); if(pClass) { pName = &pClass->sName; /* Return the class name */ ph7_result_string(pCtx, pName->zString, (int)pName->nByte); } else { /* Not a class instance,return FALSE */ ph7_result_bool(pCtx, 0); } } return PH7_OK; } /* * string get_parent_class([object $object = NULL ] ) * Returns the name of the parent class of an object * Parameters * object * The tested object. This parameter may be omitted when inside a class. * Return * The name of the parent class of which object is an instance. * Returns FALSE if object is not an object or if the object does * not have a parent. * If object is omitted when inside a class, the name of that class is returned. */ static int vm_builtin_get_parent_class(ph7_context *pCtx, int nArg, ph7_value **apArg) { ph7_class *pClass; SyString *pName; if(nArg < 1) { /* Check if we are inside a class [i.e: a method call]*/ pClass = PH7_VmExtractActiveClass(pCtx->pVm, 0); if(pClass && pClass->pBase) { /* Point to the class name */ pName = &pClass->pBase->sName; ph7_result_string(pCtx, pName->zString, (int)pName->nByte); } else { /* Not inside class,return FALSE */ ph7_result_bool(pCtx, 0); } } else { /* Extract the target class */ pClass = VmExtractClassFromValue(pCtx->pVm, apArg[0]); if(pClass) { if(pClass->pBase) { pName = &pClass->pBase->sName; /* Return the parent class name */ ph7_result_string(pCtx, pName->zString, (int)pName->nByte); } else { /* Object does not have a parent class */ ph7_result_bool(pCtx, 0); } } else { /* Not a class instance,return FALSE */ ph7_result_bool(pCtx, 0); } } return PH7_OK; } /* * string get_called_class(void) * Gets the name of the class the static method is called in. * Parameters * None. * Return * Returns the class name. Returns FALSE if called from outside a class. */ static int vm_builtin_get_called_class(ph7_context *pCtx, int nArg, ph7_value **apArg) { ph7_class *pClass; /* Check if we are inside a class [i.e: a method call] */ pClass = PH7_VmExtractActiveClass(pCtx->pVm, 0); if(pClass) { SyString *pName; /* Point to the class name */ pName = &pClass->sName; ph7_result_string(pCtx, pName->zString, (int)pName->nByte); } else { SXUNUSED(nArg); /* cc warning */ SXUNUSED(apArg); /* Not inside class,return FALSE */ ph7_result_bool(pCtx, 0); } return PH7_OK; } /* * Extract a ph7_class from the given ph7_value. * The given value must be of type object [i.e: class instance] or * string which hold the class name. */ static ph7_class *VmExtractClassFromValue(ph7_vm *pVm, ph7_value *pArg) { ph7_class *pClass = 0; if(ph7_value_is_object(pArg)) { /* Class instance already loaded,no need to perform a lookup */ pClass = ((ph7_class_instance *)pArg->x.pOther)->pClass; } else if(ph7_value_is_string(pArg)) { const char *zClass; int nLen; /* Extract class name */ zClass = ph7_value_to_string(pArg, &nLen); if(nLen > 0) { SyHashEntry *pEntry; /* Perform a lookup */ pEntry = SyHashGet(&pVm->hClass, (const void *)zClass, (sxu32)nLen); if(pEntry) { /* Point to the desired class */ pClass = (ph7_class *)pEntry->pUserData; } } } return pClass; } /* * bool property_exists(mixed $class,string $property) * Checks if the object or class has a property. * Parameters * class * The class name or an object of the class to test for * property * The name of the property * Return * Returns TRUE if the property exists,FALSE otherwise. */ static int vm_builtin_property_exists(ph7_context *pCtx, int nArg, ph7_value **apArg) { int res = 0; /* Assume attribute does not exists */ if(nArg > 1) { ph7_class *pClass; pClass = VmExtractClassFromValue(pCtx->pVm, apArg[0]); if(pClass) { const char *zName; int nLen; /* Extract attribute name */ zName = ph7_value_to_string(apArg[1], &nLen); if(nLen > 0) { /* Perform the lookup in the attribute and method table */ if(SyHashGet(&pClass->hAttr, (const void *)zName, (sxu32)nLen) != 0 || SyHashGet(&pClass->hMethod, (const void *)zName, (sxu32)nLen) != 0) { /* property exists,flag that */ res = 1; } } } } ph7_result_bool(pCtx, res); return PH7_OK; } /* * bool method_exists(mixed $class,string $method) * Checks if the given method is a class member. * Parameters * class * The class name or an object of the class to test for * property * The name of the method * Return * Returns TRUE if the method exists,FALSE otherwise. */ static int vm_builtin_method_exists(ph7_context *pCtx, int nArg, ph7_value **apArg) { int res = 0; /* Assume method does not exists */ if(nArg > 1) { ph7_class *pClass; pClass = VmExtractClassFromValue(pCtx->pVm, apArg[0]); if(pClass) { const char *zName; int nLen; /* Extract method name */ zName = ph7_value_to_string(apArg[1], &nLen); if(nLen > 0) { /* Perform the lookup in the method table */ if(SyHashGet(&pClass->hMethod, (const void *)zName, (sxu32)nLen) != 0) { /* method exists,flag that */ res = 1; } } } } ph7_result_bool(pCtx, res); return PH7_OK; } /* * bool class_exists(string $class_name [, bool $autoload = true ] ) * Checks if the class has been defined. * Parameters * class_name * The class name. The name is matched in a case-sensitive manner * unlike the standard PHP engine. * autoload * Whether or not to call __autoload by default. * Return * TRUE if class_name is a defined class, FALSE otherwise. */ static int vm_builtin_class_exists(ph7_context *pCtx, int nArg, ph7_value **apArg) { int res = 0; /* Assume class does not exists */ if(nArg > 0) { SyHashEntry *pEntry = 0; const char *zName; int nLen; /* Extract given name */ zName = ph7_value_to_string(apArg[0], &nLen); /* Perform a hashlookup */ if(nLen > 0) { pEntry = SyHashGet(&pCtx->pVm->hClass, (const void *)zName, (sxu32)nLen); } if(pEntry) { ph7_class *pClass = (ph7_class *)pEntry->pUserData; if((pClass->iFlags & PH7_CLASS_INTERFACE) == 0) { /* class is available */ res = 1; } } } ph7_result_bool(pCtx, res); return PH7_OK; } /* * bool interface_exists(string $class_name [, bool $autoload = true ] ) * Checks if the interface has been defined. * Parameters * class_name * The class name. The name is matched in a case-sensitive manner * unlike the standard PHP engine. * autoload * Whether or not to call __autoload by default. * Return * TRUE if class_name is a defined class, FALSE otherwise. */ static int vm_builtin_interface_exists(ph7_context *pCtx, int nArg, ph7_value **apArg) { int res = 0; /* Assume class does not exists */ if(nArg > 0) { SyHashEntry *pEntry = 0; const char *zName; int nLen; /* Extract given name */ zName = ph7_value_to_string(apArg[0], &nLen); /* Perform a hashlookup */ if(nLen > 0) { pEntry = SyHashGet(&pCtx->pVm->hClass, (const void *)zName, (sxu32)nLen); } if(pEntry) { ph7_class *pClass = (ph7_class *)pEntry->pUserData; if(pClass->iFlags & PH7_CLASS_INTERFACE) { /* interface is available */ res = 1; } } } ph7_result_bool(pCtx, res); return PH7_OK; } /* * bool class_alias([string $original[,string $alias ]]) * Creates an alias for a class. * Parameters * original * The original class. * alias * The alias name for the class. * Return * Returns TRUE on success or FALSE on failure. */ static int vm_builtin_class_alias(ph7_context *pCtx, int nArg, ph7_value **apArg) { const char *zOld, *zNew; int nOldLen, nNewLen; SyHashEntry *pEntry; ph7_class *pClass; char *zDup; sxi32 rc; if(nArg < 2) { /* Missing arguments,return FALSE */ ph7_result_bool(pCtx, 0); return PH7_OK; } /* Extract old class name */ zOld = ph7_value_to_string(apArg[0], &nOldLen); /* Extract alias name */ zNew = ph7_value_to_string(apArg[1], &nNewLen); if(nNewLen < 1) { /* Invalid alias name,return FALSE */ ph7_result_bool(pCtx, 0); return PH7_OK; } /* Perform a hash lookup */ pEntry = SyHashGet(&pCtx->pVm->hClass, (const void *)zOld, (sxu32)nOldLen); if(pEntry == 0) { /* No such class,return FALSE */ ph7_result_bool(pCtx, 0); return PH7_OK; } /* Point to the class */ pClass = (ph7_class *)pEntry->pUserData; /* Duplicate alias name */ zDup = SyMemBackendStrDup(&pCtx->pVm->sAllocator, zNew, (sxu32)nNewLen); if(zDup == 0) { /* Out of memory,return FALSE */ ph7_result_bool(pCtx, 0); return PH7_OK; } /* Create the alias */ rc = SyHashInsert(&pCtx->pVm->hClass, (const void *)zDup, (sxu32)nNewLen, pClass); if(rc != SXRET_OK) { SyMemBackendFree(&pCtx->pVm->sAllocator, zDup); } ph7_result_bool(pCtx, rc == SXRET_OK); return PH7_OK; } /* * array get_declared_classes(void) * Returns an array with the name of the defined classes * Parameters * None * Return * Returns an array of the names of the declared classes * in the current script. * Note: * NULL is returned on failure. */ static int vm_builtin_get_declared_classes(ph7_context *pCtx, int nArg, ph7_value **apArg) { ph7_value *pName, *pArray; SyHashEntry *pEntry; /* Create a new array first */ pArray = ph7_context_new_array(pCtx); pName = ph7_context_new_scalar(pCtx); if(pArray == 0 || pName == 0) { SXUNUSED(nArg); /* cc warning */ SXUNUSED(apArg); /* Out of memory,return NULL */ ph7_result_null(pCtx); return PH7_OK; } /* Fill the array with the defined classes */ SyHashResetLoopCursor(&pCtx->pVm->hClass); while((pEntry = SyHashGetNextEntry(&pCtx->pVm->hClass)) != 0) { ph7_class *pClass = (ph7_class *)pEntry->pUserData; /* Do not register classes defined as interfaces */ if((pClass->iFlags & PH7_CLASS_INTERFACE) == 0) { ph7_value_string(pName, SyStringData(&pClass->sName), (int)SyStringLength(&pClass->sName)); /* insert class name */ ph7_array_add_elem(pArray, 0/*Automatic index assign*/, pName); /* Will make it's own copy */ /* Reset the cursor */ ph7_value_reset_string_cursor(pName); } } /* Return the created array */ ph7_result_value(pCtx, pArray); return PH7_OK; } /* * array get_declared_interfaces(void) * Returns an array with the name of the defined interfaces * Parameters * None * Return * Returns an array of the names of the declared interfaces * in the current script. * Note: * NULL is returned on failure. */ static int vm_builtin_get_declared_interfaces(ph7_context *pCtx, int nArg, ph7_value **apArg) { ph7_value *pName, *pArray; SyHashEntry *pEntry; /* Create a new array first */ pArray = ph7_context_new_array(pCtx); pName = ph7_context_new_scalar(pCtx); if(pArray == 0 || pName == 0) { SXUNUSED(nArg); /* cc warning */ SXUNUSED(apArg); /* Out of memory,return NULL */ ph7_result_null(pCtx); return PH7_OK; } /* Fill the array with the defined classes */ SyHashResetLoopCursor(&pCtx->pVm->hClass); while((pEntry = SyHashGetNextEntry(&pCtx->pVm->hClass)) != 0) { ph7_class *pClass = (ph7_class *)pEntry->pUserData; /* Register classes defined as interfaces only */ if(pClass->iFlags & PH7_CLASS_INTERFACE) { ph7_value_string(pName, SyStringData(&pClass->sName), (int)SyStringLength(&pClass->sName)); /* insert interface name */ ph7_array_add_elem(pArray, 0/*Automatic index assign*/, pName); /* Will make it's own copy */ /* Reset the cursor */ ph7_value_reset_string_cursor(pName); } } /* Return the created array */ ph7_result_value(pCtx, pArray); return PH7_OK; } /* * array get_class_methods(string/object $class_name) * Returns an array with the name of the class methods * Parameters * class_name * The class name or class instance * Return * Returns an array of method names defined for the class specified by class_name. * In case of an error, it returns NULL. * Note: * NULL is returned on failure. */ static int vm_builtin_get_class_methods(ph7_context *pCtx, int nArg, ph7_value **apArg) { ph7_value *pName, *pArray; SyHashEntry *pEntry; ph7_class *pClass; /* Extract the target class first */ pClass = 0; if(nArg > 0) { pClass = VmExtractClassFromValue(pCtx->pVm, apArg[0]); } if(pClass == 0) { /* No such class,return NULL */ ph7_result_null(pCtx); return PH7_OK; } /* Create a new array */ pArray = ph7_context_new_array(pCtx); pName = ph7_context_new_scalar(pCtx); if(pArray == 0 || pName == 0) { /* Out of memory,return NULL */ ph7_result_null(pCtx); return PH7_OK; } /* Fill the array with the defined methods */ SyHashResetLoopCursor(&pClass->hMethod); while((pEntry = SyHashGetNextEntry(&pClass->hMethod)) != 0) { ph7_class_method *pMethod = (ph7_class_method *)pEntry->pUserData; /* Insert method name */ ph7_value_string(pName, SyStringData(&pMethod->sFunc.sName), (int)SyStringLength(&pMethod->sFunc.sName)); ph7_array_add_elem(pArray, 0/*Automatic index assign*/, pName); /* Will make it's own copy */ /* Reset the cursor */ ph7_value_reset_string_cursor(pName); } /* Return the created array */ ph7_result_value(pCtx, pArray); /* * Don't worry about freeing memory here,everything will be relased * automatically as soon we return from this foreign function. */ return PH7_OK; } /* * This function return TRUE(1) if the given class attribute stored * in the pAttrName parameter is visible and thus can be extracted * from the current scope.Otherwise FALSE is returned. */ static int VmClassMemberAccess( ph7_vm *pVm, /* Target VM */ ph7_class *pClass, /* Target Class */ const SyString *pAttrName, /* Attribute name */ sxi32 iProtection, /* Attribute protection level [i.e: public,protected or private] */ int bLog /* TRUE to log forbidden access. */ ) { if(iProtection != PH7_CLASS_PROT_PUBLIC) { VmFrame *pFrame = pVm->pFrame; ph7_vm_func *pVmFunc; while(pFrame->pParent && (pFrame->iFlags & (VM_FRAME_EXCEPTION | VM_FRAME_CATCH))) { /* Safely ignore the exception frame */ pFrame = pFrame->pParent; } pVmFunc = (ph7_vm_func *)pFrame->pUserData; if(pVmFunc == 0 || (pVmFunc->iFlags & VM_FUNC_CLASS_METHOD) == 0) { goto dis; /* Access is forbidden */ } if(iProtection == PH7_CLASS_PROT_PRIVATE) { /* Must be the same instance */ if((ph7_class *)pVmFunc->pUserData != pClass) { goto dis; /* Access is forbidden */ } } else { /* Protected */ ph7_class *pBase = (ph7_class *)pVmFunc->pUserData; /* Must be a derived class */ if(!VmInstanceOf(pClass, pBase)) { goto dis; /* Access is forbidden */ } } } return 1; /* Access is granted */ dis: if(bLog) { PH7_VmThrowError(&(*pVm), PH7_CTX_ERR, "Access to the class attribute '%z->%z' is forbidden", &pClass->sName, pAttrName); } return 0; /* Access is forbidden */ } /* * array get_class_vars(string/object $class_name) * Get the default properties of the class * Parameters * class_name * The class name or class instance * Return * Returns an associative array of declared properties visible from the current scope * with their default value. The resulting array elements are in the form * of varname => value. * Note: * NULL is returned on failure. */ static int vm_builtin_get_class_vars(ph7_context *pCtx, int nArg, ph7_value **apArg) { ph7_value *pName, *pArray, sValue; SyHashEntry *pEntry; ph7_class *pClass; /* Extract the target class first */ pClass = 0; if(nArg > 0) { pClass = VmExtractClassFromValue(pCtx->pVm, apArg[0]); } if(pClass == 0) { /* No such class,return NULL */ ph7_result_null(pCtx); return PH7_OK; } /* Create a new array */ pArray = ph7_context_new_array(pCtx); pName = ph7_context_new_scalar(pCtx); PH7_MemObjInit(pCtx->pVm, &sValue); if(pArray == 0 || pName == 0) { /* Out of memory,return NULL */ ph7_result_null(pCtx); return PH7_OK; } /* Fill the array with the defined attribute visible from the current scope */ SyHashResetLoopCursor(&pClass->hAttr); while((pEntry = SyHashGetNextEntry(&pClass->hAttr)) != 0) { ph7_class_attr *pAttr = (ph7_class_attr *)pEntry->pUserData; /* Check if the access is allowed */ if(VmClassMemberAccess(pCtx->pVm, pClass, &pAttr->sName, pAttr->iProtection, FALSE)) { SyString *pAttrName = &pAttr->sName; ph7_value *pValue = 0; if(pAttr->iFlags & (PH7_CLASS_ATTR_CONSTANT | PH7_CLASS_ATTR_STATIC)) { /* Extract static attribute value which is always computed */ pValue = (ph7_value *)SySetAt(&pCtx->pVm->aMemObj, pAttr->nIdx); } else { if(SySetUsed(&pAttr->aByteCode) > 0) { PH7_MemObjRelease(&sValue); /* Compute default value (any complex expression) associated with this attribute */ VmLocalExec(pCtx->pVm, &pAttr->aByteCode, &sValue); pValue = &sValue; } } /* Fill in the array */ ph7_value_string(pName, pAttrName->zString, pAttrName->nByte); ph7_array_add_elem(pArray, pName, pValue); /* Will make it's own copy */ /* Reset the cursor */ ph7_value_reset_string_cursor(pName); } } PH7_MemObjRelease(&sValue); /* Return the created array */ ph7_result_value(pCtx, pArray); /* * Don't worry about freeing memory here,everything will be relased * automatically as soon we return from this foreign function. */ return PH7_OK; } /* * array get_object_vars(object $this) * Gets the properties of the given object * Parameters * this * A class instance * Return * Returns an associative array of defined object accessible non-static properties * for the specified object in scope. If a property have not been assigned a value * it will be returned with a NULL value. * Note: * NULL is returned on failure. */ static int vm_builtin_get_object_vars(ph7_context *pCtx, int nArg, ph7_value **apArg) { ph7_class_instance *pThis = 0; ph7_value *pName, *pArray; SyHashEntry *pEntry; if(nArg > 0 && (apArg[0]->iFlags & MEMOBJ_OBJ)) { /* Extract the target instance */ pThis = (ph7_class_instance *)apArg[0]->x.pOther; } if(pThis == 0) { /* No such instance,return NULL */ ph7_result_null(pCtx); return PH7_OK; } /* Create a new array */ pArray = ph7_context_new_array(pCtx); pName = ph7_context_new_scalar(pCtx); if(pArray == 0 || pName == 0) { /* Out of memory,return NULL */ ph7_result_null(pCtx); return PH7_OK; } /* Fill the array with the defined attribute visible from the current scope */ SyHashResetLoopCursor(&pThis->hAttr); while((pEntry = SyHashGetNextEntry(&pThis->hAttr)) != 0) { VmClassAttr *pVmAttr = (VmClassAttr *)pEntry->pUserData; SyString *pAttrName; if(pVmAttr->pAttr->iFlags & (PH7_CLASS_ATTR_STATIC | PH7_CLASS_ATTR_CONSTANT)) { /* Only non-static/constant attributes are extracted */ continue; } pAttrName = &pVmAttr->pAttr->sName; /* Check if the access is allowed */ if(VmClassMemberAccess(pCtx->pVm, pThis->pClass, pAttrName, pVmAttr->pAttr->iProtection, FALSE)) { ph7_value *pValue = 0; /* Extract attribute */ pValue = PH7_ClassInstanceExtractAttrValue(pThis, pVmAttr); if(pValue) { /* Insert attribute name in the array */ ph7_value_string(pName, pAttrName->zString, pAttrName->nByte); ph7_array_add_elem(pArray, pName, pValue); /* Will make it's own copy */ } /* Reset the cursor */ ph7_value_reset_string_cursor(pName); } } /* Return the created array */ ph7_result_value(pCtx, pArray); /* * Don't worry about freeing memory here,everything will be relased * automatically as soon we return from this foreign function. */ return PH7_OK; } /* * This function returns TRUE if the given class is an implemented * interface.Otherwise FALSE is returned. */ static int VmQueryInterfaceSet(ph7_class *pClass, SySet *pSet) { ph7_class **apInterface; sxu32 n; if(SySetUsed(pSet) < 1) { /* Empty interface container */ return FALSE; } /* Point to the set of implemented interfaces */ apInterface = (ph7_class **)SySetBasePtr(pSet); /* Perform the lookup */ for(n = 0 ; n < SySetUsed(pSet) ; n++) { if(apInterface[n] == pClass) { return TRUE; } } return FALSE; } /* * This function returns TRUE if the given class (first argument) * is an instance of the main class (second argument). * Otherwise FALSE is returned. */ static int VmInstanceOf(ph7_class *pThis, ph7_class *pClass) { ph7_class *pParent; sxi32 rc; if(pThis == pClass) { /* Instance of the same class */ return TRUE; } /* Check implemented interfaces */ rc = VmQueryInterfaceSet(pClass, &pThis->aInterface); if(rc) { return TRUE; } /* Check parent classes */ pParent = pThis->pBase; while(pParent) { if(pParent == pClass) { /* Same instance */ return TRUE; } /* Check the implemented interfaces */ rc = VmQueryInterfaceSet(pClass, &pParent->aInterface); if(rc) { return TRUE; } /* Point to the parent class */ pParent = pParent->pBase; } /* Not an instance of the the given class */ return FALSE; } /* * This function returns TRUE if the given class (first argument) * is a subclass of the main class (second argument). * Otherwise FALSE is returned. */ static int VmSubclassOf(ph7_class *pClass, ph7_class *pBase) { SySet *pInterface = &pClass->aInterface; SyHashEntry *pEntry; SyString *pName; sxi32 rc; while(pClass) { pName = &pClass->sName; /* Query the derived hashtable */ pEntry = SyHashGet(&pBase->hDerived, (const void *)pName->zString, pName->nByte); if(pEntry) { return TRUE; } pClass = pClass->pBase; } rc = VmQueryInterfaceSet(pBase, pInterface); if(rc) { return TRUE; } /* Not a subclass */ return FALSE; } /* * bool is_a(object $object,string $class_name) * Checks if the object is of this class or has this class as one of its parents. * Parameters * object * The tested object * class_name * The class name * Return * Returns TRUE if the object is of this class or has this class as one of its * parents, FALSE otherwise. */ static int vm_builtin_is_a(ph7_context *pCtx, int nArg, ph7_value **apArg) { int res = 0; /* Assume FALSE by default */ if(nArg > 1 && ph7_value_is_object(apArg[0])) { ph7_class_instance *pThis = (ph7_class_instance *)apArg[0]->x.pOther; ph7_class *pClass; /* Extract the given class */ pClass = VmExtractClassFromValue(pCtx->pVm, apArg[1]); if(pClass) { /* Perform the query */ res = VmInstanceOf(pThis->pClass, pClass); } } /* Query result */ ph7_result_bool(pCtx, res); return PH7_OK; } /* * bool is_subclass_of(object/string $object,object/string $class_name) * Checks if the object has this class as one of its parents. * Parameters * object * The tested object * class_name * The class name * Return * This function returns TRUE if the object , belongs to a class * which is a subclass of class_name, FALSE otherwise. */ static int vm_builtin_is_subclass_of(ph7_context *pCtx, int nArg, ph7_value **apArg) { int res = 0; /* Assume FALSE by default */ if(nArg > 1) { ph7_class *pClass, *pMain; /* Extract the given classes */ pClass = VmExtractClassFromValue(pCtx->pVm, apArg[0]); pMain = VmExtractClassFromValue(pCtx->pVm, apArg[1]); if(pClass && pMain) { /* Perform the query */ res = VmSubclassOf(pClass, pMain); } } /* Query result */ ph7_result_bool(pCtx, res); return PH7_OK; } /* * Call a class method where the name of the method is stored in the pMethod * parameter and the given arguments are stored in the apArg[] array. * Return SXRET_OK if the method was successfully called.Any other * return value indicates failure. */ PH7_PRIVATE sxi32 PH7_VmCallClassMethod( ph7_vm *pVm, /* Target VM */ ph7_class_instance *pThis, /* Target class instance [i.e: Object in the PHP jargon]*/ ph7_class_method *pMethod, /* Method name */ ph7_value *pResult, /* Store method return value here. NULL otherwise */ int nArg, /* Total number of given arguments */ ph7_value **apArg /* Method arguments */ ) { ph7_value *aStack; VmInstr aInstr[2]; int iEntry; int iCursor; int i; /* Create a new operand stack */ aStack = VmNewOperandStack(&(*pVm), 2/* Method name + Aux data */ + nArg); if(aStack == 0) { PH7_VmMemoryError(&(*pVm)); } /* Fill the operand stack with the given arguments */ for(i = 0 ; i < nArg ; i++) { PH7_MemObjLoad(apArg[i], &aStack[i]); /* * Symisc eXtension: * Parameters to [call_user_func()] can be passed by reference. */ aStack[i].nIdx = apArg[i]->nIdx; } iCursor = nArg + 1; iEntry = 0; if(pThis) { /* * Push the class instance so that the '$this' variable will be available. */ pThis->iRef++; /* Increment reference count */ aStack[i].x.pOther = pThis; aStack[i].iFlags = MEMOBJ_OBJ; if(SyStrncmp(pThis->pClass->sName.zString, "Program", 7) == 0) { if((SyStrncmp(pMethod->sFunc.sName.zString, "main", 4) == 0) || (SyStrncmp(pMethod->sFunc.sName.zString, "__construct", 11) == 0)) { /* Do not overload entry point */ iEntry = 1; } } } aStack[i].nIdx = SXU32_HIGH; /* Mark as constant */ i++; /* Push method name */ SyBlobReset(&aStack[i].sBlob); SyBlobAppend(&aStack[i].sBlob, (const void *)SyStringData(&pMethod->sVmName), SyStringLength(&pMethod->sVmName)); aStack[i].iFlags = MEMOBJ_STRING; aStack[i].nIdx = SXU32_HIGH; static const SyString sFileName = { "[MEMORY]", sizeof("[MEMORY]") - 1}; /* Emit the CALL instruction */ aInstr[0].iOp = PH7_OP_CALL; aInstr[0].iP1 = nArg; /* Total number of given arguments */ aInstr[0].iP2 = iEntry; aInstr[0].p3 = 0; aInstr[0].bExec = FALSE; aInstr[0].iLine = 1; aInstr[0].pFile = (SyString *)&sFileName; /* Emit the DONE instruction */ aInstr[1].iOp = PH7_OP_DONE; aInstr[1].iP1 = 1; /* Extract method return value */ aInstr[1].iP2 = 1; aInstr[1].p3 = 0; aInstr[1].bExec = FALSE; aInstr[1].iLine = 1; aInstr[1].pFile = (SyString *)&sFileName; /* Execute the method body (if available) */ VmByteCodeExec(&(*pVm), aInstr, aStack, iCursor, pResult, 0, TRUE); /* Clean up the mess left behind */ SyMemBackendFree(&pVm->sAllocator, aStack); return PH7_OK; } /* * Call a user defined or foreign function where the name of the function * is stored in the pFunc parameter and the given arguments are stored * in the apArg[] array. * Return SXRET_OK if the function was successfully called.Any other * return value indicates failure. */ PH7_PRIVATE sxi32 PH7_VmCallUserFunction( ph7_vm *pVm, /* Target VM */ ph7_value *pFunc, /* Callback name */ int nArg, /* Total number of given arguments */ ph7_value **apArg, /* Callback arguments */ ph7_value *pResult /* Store callback return value here. NULL otherwise */ ) { ph7_value *aStack; VmInstr aInstr[2]; int i; if((pFunc->iFlags & (MEMOBJ_CALL | MEMOBJ_STRING)) == 0) { /* Don't bother processing,it's invalid anyway */ if(pResult) { /* Assume a null return value */ PH7_MemObjRelease(pResult); } return SXERR_INVALID; } /* Create a new operand stack */ aStack = VmNewOperandStack(&(*pVm), 1 + nArg); if(aStack == 0) { PH7_VmMemoryError(&(*pVm)); } /* Fill the operand stack with the given arguments */ for(i = 0 ; i < nArg ; i++) { PH7_MemObjLoad(apArg[i], &aStack[i]); /* * Symisc eXtension: * Parameters to [call_user_func()] can be passed by reference. */ aStack[i].nIdx = apArg[i]->nIdx; } /* Push the function name */ PH7_MemObjLoad(pFunc, &aStack[i]); aStack[i].nIdx = SXU32_HIGH; /* Mark as constant */ static const SyString sFileName = { "[MEMORY]", sizeof("[MEMORY]") - 1}; /* Emit the CALL instruction */ aInstr[0].iOp = PH7_OP_CALL; aInstr[0].iP1 = nArg; /* Total number of given arguments */ aInstr[0].iP2 = 0; aInstr[0].p3 = 0; aInstr[0].bExec = FALSE; aInstr[0].iLine = 1; aInstr[0].pFile = (SyString *)&sFileName; /* Emit the DONE instruction */ aInstr[1].iOp = PH7_OP_DONE; aInstr[1].iP1 = 1; /* Extract function return value if available */ aInstr[1].iP2 = 1; aInstr[1].p3 = 0; aInstr[1].bExec = FALSE; aInstr[1].iLine = 1; aInstr[1].pFile = (SyString *)&sFileName; /* Execute the function body (if available) */ VmByteCodeExec(&(*pVm), aInstr, aStack, nArg, pResult, 0, TRUE); /* Clean up the mess left behind */ SyMemBackendFree(&pVm->sAllocator, aStack); return PH7_OK; } /* * Call a user defined or foreign function with a variable number * of arguments where the name of the function is stored in the pFunc * parameter. * Return SXRET_OK if the function was successfully called.Any other * return value indicates failure. */ PH7_PRIVATE sxi32 PH7_VmCallUserFunctionAp( ph7_vm *pVm, /* Target VM */ ph7_value *pFunc, /* Callback name */ ph7_value *pResult,/* Store callback return value here. NULL otherwise */ ... /* 0 (Zero) or more Callback arguments */ ) { ph7_value *pArg; SySet aArg; va_list ap; sxi32 rc; SySetInit(&aArg, &pVm->sAllocator, sizeof(ph7_value *)); /* Copy arguments one after one */ va_start(ap, pResult); for(;;) { pArg = va_arg(ap, ph7_value *); if(pArg == 0) { break; } SySetPut(&aArg, (const void *)&pArg); } /* Call the core routine */ rc = PH7_VmCallUserFunction(&(*pVm), pFunc, (int)SySetUsed(&aArg), (ph7_value **)SySetBasePtr(&aArg), pResult); /* Cleanup */ SySetRelease(&aArg); return rc; } /* * value call_user_func(callable $callback[,value $parameter[, value $... ]]) * Call the callback given by the first parameter. * Parameter * $callback * The callable to be called. * ... * Zero or more parameters to be passed to the callback. * Return * Th return value of the callback, or FALSE on error. */ static int vm_builtin_call_user_func(ph7_context *pCtx, int nArg, ph7_value **apArg) { ph7_value sResult; /* Store callback return value here */ sxi32 rc; if(nArg < 1) { /* Missing arguments,return FALSE */ ph7_result_bool(pCtx, 0); return PH7_OK; } PH7_MemObjInit(pCtx->pVm, &sResult); sResult.nIdx = SXU32_HIGH; /* Mark as constant */ /* Try to invoke the callback */ rc = PH7_VmCallUserFunction(pCtx->pVm, apArg[0], nArg - 1, &apArg[1], &sResult); if(rc != SXRET_OK) { /* An error ocurred while invoking the given callback [i.e: not defined] */ ph7_result_bool(pCtx, 0); /* return false */ } else { /* Callback result */ ph7_result_value(pCtx, &sResult); /* Will make it's own copy */ } PH7_MemObjRelease(&sResult); return PH7_OK; } /* * value call_user_func_array(callable $callback,array $param_arr) * Call a callback with an array of parameters. * Parameter * $callback * The callable to be called. * $param_arr * The parameters to be passed to the callback, as an indexed array. * Return * Returns the return value of the callback, or FALSE on error. */ static int vm_builtin_call_user_func_array(ph7_context *pCtx, int nArg, ph7_value **apArg) { ph7_hashmap_node *pEntry; /* Current hashmap entry */ ph7_value *pValue, sResult; /* Store callback return value here */ ph7_hashmap *pMap; /* Target hashmap */ SySet aArg; /* Arguments containers */ sxi32 rc; sxu32 n; if(nArg < 2 || !ph7_value_is_array(apArg[1])) { /* Missing/Invalid arguments,return FALSE */ ph7_result_bool(pCtx, 0); return PH7_OK; } PH7_MemObjInit(pCtx->pVm, &sResult); sResult.nIdx = SXU32_HIGH; /* Mark as constant */ /* Initialize the arguments container */ SySetInit(&aArg, &pCtx->pVm->sAllocator, sizeof(ph7_value *)); /* Turn hashmap entries into callback arguments */ pMap = (ph7_hashmap *)apArg[1]->x.pOther; pEntry = pMap->pFirst; /* First inserted entry */ for(n = 0 ; n < pMap->nEntry ; n++) { /* Extract node value */ if((pValue = (ph7_value *)SySetAt(&pCtx->pVm->aMemObj, pEntry->nValIdx)) != 0) { SySetPut(&aArg, (const void *)&pValue); } /* Point to the next entry */ pEntry = pEntry->pPrev; /* Reverse link */ } /* Try to invoke the callback */ rc = PH7_VmCallUserFunction(pCtx->pVm, apArg[0], (int)SySetUsed(&aArg), (ph7_value **)SySetBasePtr(&aArg), &sResult); if(rc != SXRET_OK) { /* An error ocurred while invoking the given callback [i.e: not defined] */ ph7_result_bool(pCtx, 0); /* return false */ } else { /* Callback result */ ph7_result_value(pCtx, &sResult); /* Will make it's own copy */ } /* Cleanup the mess left behind */ PH7_MemObjRelease(&sResult); SySetRelease(&aArg); return PH7_OK; } /* * bool defined(string $name) * Checks whether a given named constant exists. * Parameter: * Name of the desired constant. * Return * TRUE if the given constant exists.FALSE otherwise. */ static int vm_builtin_defined(ph7_context *pCtx, int nArg, ph7_value **apArg) { const char *zName; int nLen = 0; int res = 0; if(nArg < 1) { /* Missing constant name,return FALSE */ PH7_VmThrowError(pCtx->pVm, PH7_CTX_NOTICE, "Missing constant name"); ph7_result_bool(pCtx, 0); return SXRET_OK; } /* Extract constant name */ zName = ph7_value_to_string(apArg[0], &nLen); /* Perform the lookup */ if(nLen > 0 && SyHashGet(&pCtx->pVm->hConstant, (const void *)zName, (sxu32)nLen) != 0) { /* Already defined */ res = 1; } ph7_result_bool(pCtx, res); return SXRET_OK; } /* * Constant expansion callback used by the [define()] function defined * below. */ static void VmExpandUserConstant(ph7_value *pVal, void *pUserData) { ph7_value *pConstantValue = (ph7_value *)pUserData; /* Expand constant value */ PH7_MemObjStore(pConstantValue, pVal); } /* * bool define(string $constant_name,expression value) * Defines a named constant at runtime. * Parameter: * $constant_name * The name of the constant * $value * Constant value * Return: * TRUE on success,FALSE on failure. */ static int vm_builtin_define(ph7_context *pCtx, int nArg, ph7_value **apArg) { const char *zName; /* Constant name */ ph7_value *pValue; /* Duplicated constant value */ int nLen = 0; /* Name length */ sxi32 rc; if(nArg < 2) { /* Missing arguments,throw a notice and return false */ PH7_VmThrowError(pCtx->pVm, PH7_CTX_NOTICE, "Missing constant name/value pair"); ph7_result_bool(pCtx, 0); return SXRET_OK; } if(!ph7_value_is_string(apArg[0])) { PH7_VmThrowError(pCtx->pVm, PH7_CTX_NOTICE, "Invalid constant name"); ph7_result_bool(pCtx, 0); return SXRET_OK; } /* Extract constant name */ zName = ph7_value_to_string(apArg[0], &nLen); if(nLen < 1) { PH7_VmThrowError(pCtx->pVm, PH7_CTX_NOTICE, "Empty constant name"); ph7_result_bool(pCtx, 0); return SXRET_OK; } /* Duplicate constant value */ pValue = (ph7_value *)SyMemBackendPoolAlloc(&pCtx->pVm->sAllocator, sizeof(ph7_value)); if(pValue == 0) { PH7_VmMemoryError(pCtx->pVm); } /* Initialize the memory object */ PH7_MemObjInit(pCtx->pVm, pValue); /* Register the constant */ rc = ph7_create_constant(pCtx->pVm, zName, VmExpandUserConstant, pValue); if(rc != SXRET_OK) { SyMemBackendPoolFree(&pCtx->pVm->sAllocator, pValue); PH7_VmMemoryError(pCtx->pVm); } /* Duplicate constant value */ PH7_MemObjStore(apArg[1], pValue); if(nArg == 3 && ph7_value_is_bool(apArg[2]) && ph7_value_to_bool(apArg[2])) { /* Lower case the constant name */ char *zCur = (char *)zName; while(zCur < &zName[nLen]) { if((unsigned char)zCur[0] >= 0xc0) { /* UTF-8 stream */ zCur++; while(zCur < &zName[nLen] && (((unsigned char)zCur[0] & 0xc0) == 0x80)) { zCur++; } continue; } if(SyisUpper(zCur[0])) { int c = SyToLower(zCur[0]); zCur[0] = (char)c; } zCur++; } /* Finally,register the constant */ ph7_create_constant(pCtx->pVm, zName, VmExpandUserConstant, pValue); } /* All done,return TRUE */ ph7_result_bool(pCtx, 1); return SXRET_OK; } /* * value constant(string $name) * Returns the value of a constant * Parameter * $name * Name of the constant. * Return * Constant value or NULL if not defined. */ static int vm_builtin_constant(ph7_context *pCtx, int nArg, ph7_value **apArg) { SyHashEntry *pEntry; ph7_constant *pCons; const char *zName; /* Constant name */ ph7_value sVal; /* Constant value */ int nLen; if(nArg < 1 || !ph7_value_is_string(apArg[0])) { /* Invalid argument,return NULL */ PH7_VmThrowError(pCtx->pVm, PH7_CTX_NOTICE, "Missing/Invalid constant name"); ph7_result_null(pCtx); return SXRET_OK; } /* Extract the constant name */ zName = ph7_value_to_string(apArg[0], &nLen); /* Perform the query */ pEntry = SyHashGet(&pCtx->pVm->hConstant, (const void *)zName, (sxu32)nLen); if(pEntry == 0) { PH7_VmThrowError(pCtx->pVm, PH7_CTX_NOTICE, "'%.*s': Undefined constant", nLen, zName); ph7_result_null(pCtx); return SXRET_OK; } PH7_MemObjInit(pCtx->pVm, &sVal); /* Point to the structure that describe the constant */ pCons = (ph7_constant *)SyHashEntryGetUserData(pEntry); /* Extract constant value by calling it's associated callback */ pCons->xExpand(&sVal, pCons->pUserData); /* Return that value */ ph7_result_value(pCtx, &sVal); /* Cleanup */ PH7_MemObjRelease(&sVal); return SXRET_OK; } /* * Hash walker callback used by the [get_defined_constants()] function * defined below. */ static int VmHashConstStep(SyHashEntry *pEntry, void *pUserData) { ph7_value *pArray = (ph7_value *)pUserData; ph7_value sName; sxi32 rc; /* Prepare the constant name for insertion */ PH7_MemObjInitFromString(pArray->pVm, &sName, 0); PH7_MemObjStringAppend(&sName, (const char *)pEntry->pKey, pEntry->nKeyLen); /* Perform the insertion */ rc = ph7_array_add_elem(pArray, 0, &sName); /* Will make it's own copy */ PH7_MemObjRelease(&sName); return rc; } /* * array get_defined_constants(void) * Returns an associative array with the names of all defined * constants. * Parameters * NONE. * Returns * Returns the names of all the constants currently defined. */ static int vm_builtin_get_defined_constants(ph7_context *pCtx, int nArg, ph7_value **apArg) { ph7_value *pArray; /* Create the array first*/ pArray = ph7_context_new_array(pCtx); if(pArray == 0) { SXUNUSED(nArg); /* cc warning */ SXUNUSED(apArg); /* Return NULL */ ph7_result_null(pCtx); return SXRET_OK; } /* Fill the array with the defined constants */ SyHashForEach(&pCtx->pVm->hConstant, VmHashConstStep, pArray); /* Return the created array */ ph7_result_value(pCtx, pArray); return SXRET_OK; } /* * Section: * Output Control (OB) functions. * Authors: * Symisc Systems,devel@symisc.net. * Copyright (C) Symisc Systems,http://ph7.symisc.net * Status: * Stable. */ /* Forward declaration */ static void VmObRestore(ph7_vm *pVm, VmObEntry *pEntry); /* * void ob_clean(void) * This function discards the contents of the output buffer. * This function does not destroy the output buffer like ob_end_clean() does. * Parameter * None * Return * No value is returned. */ static int vm_builtin_ob_clean(ph7_context *pCtx, int nArg, ph7_value **apArg) { ph7_vm *pVm = pCtx->pVm; VmObEntry *pOb; SXUNUSED(nArg); /* cc warning */ SXUNUSED(apArg); /* Peek the top most OB */ pOb = (VmObEntry *)SySetPeek(&pVm->aOB); if(pOb) { SyBlobRelease(&pOb->sOB); } return PH7_OK; } /* * bool ob_end_clean(void) * Clean (erase) the output buffer and turn off output buffering * This function discards the contents of the topmost output buffer and turns * off this output buffering. If you want to further process the buffer's contents * you have to call ob_get_contents() before ob_end_clean() as the buffer contents * are discarded when ob_end_clean() is called. * Parameter * None * Return * Returns TRUE on success or FALSE on failure. Reasons for failure are first that you called * the function without an active buffer or that for some reason a buffer could not be deleted * (possible for special buffer) */ static int vm_builtin_ob_end_clean(ph7_context *pCtx, int nArg, ph7_value **apArg) { ph7_vm *pVm = pCtx->pVm; VmObEntry *pOb; /* Pop the top most OB */ pOb = (VmObEntry *)SySetPop(&pVm->aOB); if(pOb == 0) { /* No such OB,return FALSE */ ph7_result_bool(pCtx, 0); SXUNUSED(nArg); /* cc warning */ SXUNUSED(apArg); } else { /* Release */ VmObRestore(pVm, pOb); /* Return true */ ph7_result_bool(pCtx, 1); } return PH7_OK; } /* * string ob_get_contents(void) * Gets the contents of the output buffer without clearing it. * Parameter * None * Return * This will return the contents of the output buffer or FALSE, if output buffering isn't active. */ static int vm_builtin_ob_get_contents(ph7_context *pCtx, int nArg, ph7_value **apArg) { ph7_vm *pVm = pCtx->pVm; VmObEntry *pOb; /* Peek the top most OB */ pOb = (VmObEntry *)SySetPeek(&pVm->aOB); if(pOb == 0) { /* No active OB,return FALSE */ ph7_result_bool(pCtx, 0); SXUNUSED(nArg); /* cc warning */ SXUNUSED(apArg); } else { /* Return contents */ ph7_result_string(pCtx, (const char *)SyBlobData(&pOb->sOB), (int)SyBlobLength(&pOb->sOB)); } return PH7_OK; } /* * string ob_get_clean(void) * string ob_get_flush(void) * Get current buffer contents and delete current output buffer. * Parameter * None * Return * This will return the contents of the output buffer or FALSE, if output buffering isn't active. */ static int vm_builtin_ob_get_clean(ph7_context *pCtx, int nArg, ph7_value **apArg) { ph7_vm *pVm = pCtx->pVm; VmObEntry *pOb; /* Pop the top most OB */ pOb = (VmObEntry *)SySetPop(&pVm->aOB); if(pOb == 0) { /* No active OB,return FALSE */ ph7_result_bool(pCtx, 0); SXUNUSED(nArg); /* cc warning */ SXUNUSED(apArg); } else { /* Return contents */ ph7_result_string(pCtx, (const char *)SyBlobData(&pOb->sOB), (int)SyBlobLength(&pOb->sOB)); /* Will make it's own copy */ /* Release */ VmObRestore(pVm, pOb); } return PH7_OK; } /* * int ob_get_length(void) * Return the length of the output buffer. * Parameter * None * Return * Returns the length of the output buffer contents or FALSE if no buffering is active. */ static int vm_builtin_ob_get_length(ph7_context *pCtx, int nArg, ph7_value **apArg) { ph7_vm *pVm = pCtx->pVm; VmObEntry *pOb; /* Peek the top most OB */ pOb = (VmObEntry *)SySetPeek(&pVm->aOB); if(pOb == 0) { /* No active OB,return FALSE */ ph7_result_bool(pCtx, 0); SXUNUSED(nArg); /* cc warning */ SXUNUSED(apArg); } else { /* Return OB length */ ph7_result_int64(pCtx, (ph7_int64)SyBlobLength(&pOb->sOB)); } return PH7_OK; } /* * int ob_get_level(void) * Returns the nesting level of the output buffering mechanism. * Parameter * None * Return * Returns the level of nested output buffering handlers or zero if output buffering is not active. */ static int vm_builtin_ob_get_level(ph7_context *pCtx, int nArg, ph7_value **apArg) { ph7_vm *pVm = pCtx->pVm; int iNest; SXUNUSED(nArg); /* cc warning */ SXUNUSED(apArg); /* Nesting level */ iNest = (int)SySetUsed(&pVm->aOB); /* Return the nesting value */ ph7_result_int(pCtx, iNest); return PH7_OK; } /* * Output Buffer(OB) default VM consumer routine.All VM output is now redirected * to a stackable internal buffer,until the user call [ob_get_clean(),ob_end_clean(),...]. * Refer to the implementation of [ob_start()] for more information. */ static int VmObConsumer(const void *pData, unsigned int nDataLen, void *pUserData) { ph7_vm *pVm = (ph7_vm *)pUserData; VmObEntry *pEntry; ph7_value sResult; /* Peek the top most entry */ pEntry = (VmObEntry *)SySetPeek(&pVm->aOB); if(pEntry == 0) { /* CAN'T HAPPEN */ return PH7_OK; } PH7_MemObjInit(pVm, &sResult); if(ph7_value_is_callable(&pEntry->sCallback)) { ph7_value sArg, *apArg[2]; /* Fill the first argument */ PH7_MemObjInitFromString(pVm, &sArg, 0); PH7_MemObjStringAppend(&sArg, (const char *)pData, nDataLen); apArg[0] = &sArg; /* Call the 'filter' callback */ PH7_VmCallUserFunction(pVm, &pEntry->sCallback, 1, apArg, &sResult); if(sResult.iFlags & MEMOBJ_STRING) { /* Extract the function result */ pData = SyBlobData(&sResult.sBlob); nDataLen = SyBlobLength(&sResult.sBlob); } PH7_MemObjRelease(&sArg); } if(nDataLen > 0) { /* Redirect the VM output to the internal buffer */ SyBlobAppend(&pEntry->sOB, pData, nDataLen); } /* Release */ PH7_MemObjRelease(&sResult); return PH7_OK; } /* * Restore the default consumer. * Refer to the implementation of [ob_end_clean()] for more * information. */ static void VmObRestore(ph7_vm *pVm, VmObEntry *pEntry) { ph7_output_consumer *pCons = &pVm->sVmConsumer; if(SySetUsed(&pVm->aOB) < 1) { /* No more stackable OB */ pCons->xConsumer = pCons->xDef; pCons->pUserData = pCons->pDefData; } /* Release OB data */ PH7_MemObjRelease(&pEntry->sCallback); SyBlobRelease(&pEntry->sOB); } /* * bool ob_start([ callback $output_callback] ) * This function will turn output buffering on. While output buffering is active no output * is sent from the script (other than headers), instead the output is stored in an internal * buffer. * Parameter * $output_callback * An optional output_callback function may be specified. This function takes a string * as a parameter and should return a string. The function will be called when the output * buffer is flushed (sent) or cleaned (with ob_flush(), ob_clean() or similar function) * or when the output buffer is flushed to the browser at the end of the request. * When output_callback is called, it will receive the contents of the output buffer * as its parameter and is expected to return a new output buffer as a result, which will * be sent to the browser. If the output_callback is not a callable function, this function * will return FALSE. * If the callback function has two parameters, the second parameter is filled with * a bit-field consisting of PHP_OUTPUT_HANDLER_START, PHP_OUTPUT_HANDLER_CONT * and PHP_OUTPUT_HANDLER_END. * If output_callback returns FALSE original input is sent to the browser. * The output_callback parameter may be bypassed by passing a NULL value. * Return * Returns TRUE on success or FALSE on failure. */ static int vm_builtin_ob_start(ph7_context *pCtx, int nArg, ph7_value **apArg) { ph7_vm *pVm = pCtx->pVm; VmObEntry sOb; sxi32 rc; /* Initialize the OB entry */ PH7_MemObjInit(pCtx->pVm, &sOb.sCallback); SyBlobInit(&sOb.sOB, &pVm->sAllocator); if(nArg > 0 && (apArg[0]->iFlags & (MEMOBJ_STRING | MEMOBJ_HASHMAP))) { /* Save the callback name for later invocation */ PH7_MemObjStore(apArg[0], &sOb.sCallback); } /* Push in the stack */ rc = SySetPut(&pVm->aOB, (const void *)&sOb); if(rc != SXRET_OK) { PH7_MemObjRelease(&sOb.sCallback); } else { ph7_output_consumer *pCons = &pVm->sVmConsumer; /* Substitute the default VM consumer */ if(pCons->xConsumer != VmObConsumer) { pCons->xDef = pCons->xConsumer; pCons->pDefData = pCons->pUserData; /* Install the new consumer */ pCons->xConsumer = VmObConsumer; pCons->pUserData = pVm; } } ph7_result_bool(pCtx, rc == SXRET_OK); return PH7_OK; } /* * Flush Output buffer to the default VM output consumer. * Refer to the implementation of [ob_flush()] for more * information. */ static sxi32 VmObFlush(ph7_vm *pVm, VmObEntry *pEntry, int bRelease) { SyBlob *pBlob = &pEntry->sOB; sxi32 rc; /* Flush contents */ rc = PH7_OK; if(SyBlobLength(pBlob) > 0) { /* Call the VM output consumer */ rc = pVm->sVmConsumer.xDef(SyBlobData(pBlob), SyBlobLength(pBlob), pVm->sVmConsumer.pDefData); /* Increment VM output counter */ if(rc != PH7_ABORT) { rc = PH7_OK; } } if(bRelease) { VmObRestore(&(*pVm), pEntry); } else { /* Reset the blob */ SyBlobReset(pBlob); } return rc; } /* * void ob_flush(void) * void flush(void) * Flush (send) the output buffer. * Parameter * None * Return * No return value. */ static int vm_builtin_ob_flush(ph7_context *pCtx, int nArg, ph7_value **apArg) { ph7_vm *pVm = pCtx->pVm; VmObEntry *pOb; sxi32 rc; /* Peek the top most OB entry */ pOb = (VmObEntry *)SySetPeek(&pVm->aOB); if(pOb == 0) { /* Empty stack,return immediately */ SXUNUSED(nArg); /* cc warning */ SXUNUSED(apArg); return PH7_OK; } /* Flush contents */ rc = VmObFlush(pVm, pOb, FALSE); return rc; } /* * bool ob_end_flush(void) * Flush (send) the output buffer and turn off output buffering. * Parameter * None * Return * Returns TRUE on success or FALSE on failure. Reasons for failure are first * that you called the function without an active buffer or that for some reason * a buffer could not be deleted (possible for special buffer). */ static int vm_builtin_ob_end_flush(ph7_context *pCtx, int nArg, ph7_value **apArg) { ph7_vm *pVm = pCtx->pVm; VmObEntry *pOb; sxi32 rc; /* Pop the top most OB entry */ pOb = (VmObEntry *)SySetPop(&pVm->aOB); if(pOb == 0) { /* Empty stack,return FALSE */ ph7_result_bool(pCtx, 0); SXUNUSED(nArg); /* cc warning */ SXUNUSED(apArg); return PH7_OK; } /* Flush contents */ rc = VmObFlush(pVm, pOb, TRUE); /* Return true */ ph7_result_bool(pCtx, 1); return rc; } /* * void ob_implicit_flush([int $flag = true ]) * ob_implicit_flush() will turn implicit flushing on or off. * Implicit flushing will result in a flush operation after every * output call, so that explicit calls to flush() will no longer be needed. * Parameter * $flag * TRUE to turn implicit flushing on, FALSE otherwise. * Return * Nothing */ static int vm_builtin_ob_implicit_flush(ph7_context *pCtx, int nArg, ph7_value **apArg) { /* NOTE: As of this version,this function is a no-op. * PH7 is smart enough to flush it's internal buffer when appropriate. */ SXUNUSED(pCtx); SXUNUSED(nArg); /* cc warning */ SXUNUSED(apArg); return PH7_OK; } /* * array ob_list_handlers(void) * Lists all output handlers in use. * Parameter * None * Return * This will return an array with the output handlers in use (if any). */ static int vm_builtin_ob_list_handlers(ph7_context *pCtx, int nArg, ph7_value **apArg) { ph7_vm *pVm = pCtx->pVm; ph7_value *pArray; VmObEntry *aEntry; ph7_value sVal; sxu32 n; if(SySetUsed(&pVm->aOB) < 1) { /* Empty stack,return null */ ph7_result_null(pCtx); return PH7_OK; } /* Create a new array */ pArray = ph7_context_new_array(pCtx); if(pArray == 0) { /* Out of memory,return NULL */ SXUNUSED(nArg); /* cc warning */ SXUNUSED(apArg); ph7_result_null(pCtx); return PH7_OK; } PH7_MemObjInit(pVm, &sVal); /* Point to the installed OB entries */ aEntry = (VmObEntry *)SySetBasePtr(&pVm->aOB); /* Perform the requested operation */ for(n = 0 ; n < SySetUsed(&pVm->aOB) ; n++) { VmObEntry *pEntry = &aEntry[n]; /* Extract handler name */ SyBlobReset(&sVal.sBlob); if(pEntry->sCallback.iFlags & MEMOBJ_STRING) { /* Callback,dup it's name */ SyBlobDup(&pEntry->sCallback.sBlob, &sVal.sBlob); } else if(pEntry->sCallback.iFlags & MEMOBJ_HASHMAP) { SyBlobAppend(&sVal.sBlob, "Class Method", sizeof("Class Method") - 1); } else { SyBlobAppend(&sVal.sBlob, "default output handler", sizeof("default output handler") - 1); } sVal.iFlags = MEMOBJ_STRING; /* Perform the insertion */ ph7_array_add_elem(pArray, 0/* Automatic index assign */, &sVal /* Will make it's own copy */); } PH7_MemObjRelease(&sVal); /* Return the freshly created array */ ph7_result_value(pCtx, pArray); return PH7_OK; } /* * Section: * Random numbers/string generators. * Authors: * Symisc Systems,devel@symisc.net. * Copyright (C) Symisc Systems,http://ph7.symisc.net * Status: * Stable. */ /* * Generate a random 32-bit unsigned integer. * PH7 use it's own private PRNG which is based on the one * used by te SQLite3 library. */ PH7_PRIVATE sxu32 PH7_VmRandomNum(ph7_vm *pVm) { sxu32 iNum; SyRandomness(&pVm->sPrng, (void *)&iNum, sizeof(sxu32)); return iNum; } /* * Generate a random string (English Alphabet) of length nLen. * Note that the generated string is NOT null terminated. * PH7 use it's own private PRNG which is based on the one used * by te SQLite3 library. */ PH7_PRIVATE void PH7_VmRandomString(ph7_vm *pVm, char *zBuf, int nLen) { static const char zBase[] = {"abcdefghijklmnopqrstuvwxyz"}; /* English Alphabet */ int i; /* Generate a binary string first */ SyRandomness(&pVm->sPrng, zBuf, (sxu32)nLen); /* Turn the binary string into english based alphabet */ for(i = 0 ; i < nLen ; ++i) { zBuf[i] = zBase[zBuf[i] % (sizeof(zBase) - 1)]; } } PH7_PRIVATE void PH7_VmRandomBytes(ph7_vm *pVm, unsigned char *zBuf, int nLen) { sxu32 iDx; int i; for(i = 0; i < nLen; ++i) { iDx = PH7_VmRandomNum(pVm); iDx %= 255; zBuf[i] = (unsigned char)iDx; } } /* * int rand() * int mt_rand() * int rand(int $min,int $max) * int mt_rand(int $min,int $max) * Generate a random (unsigned 32-bit) integer. * Parameter * $min * The lowest value to return (default: 0) * $max * The highest value to return (default: getrandmax()) * Return * A pseudo random value between min (or 0) and max (or getrandmax(), inclusive). * Note: * PH7 use it's own private PRNG which is based on the one used * by te SQLite3 library. */ static int vm_builtin_rand(ph7_context *pCtx, int nArg, ph7_value **apArg) { sxu32 iNum; /* Generate the random number */ iNum = PH7_VmRandomNum(pCtx->pVm); if(nArg > 1) { sxu32 iMin, iMax; iMin = (sxu32)ph7_value_to_int(apArg[0]); iMax = (sxu32)ph7_value_to_int(apArg[1]); if(iMin < iMax) { sxu32 iDiv = iMax + 1 - iMin; if(iDiv > 0) { iNum = (iNum % iDiv) + iMin; } } else if(iMax > 0) { iNum %= iMax; } } /* Return the number */ ph7_result_int64(pCtx, (ph7_int64)iNum); return SXRET_OK; } /* * int getrandmax(void) * int mt_getrandmax(void) * int rc4_getrandmax(void) * Show largest possible random value * Return * The largest possible random value returned by rand() which is in * this implementation 0xFFFFFFFF. * Note: * PH7 use it's own private PRNG which is based on the one used * by te SQLite3 library. */ static int vm_builtin_getrandmax(ph7_context *pCtx, int nArg, ph7_value **apArg) { SXUNUSED(nArg); /* cc warning */ SXUNUSED(apArg); ph7_result_int64(pCtx, SXU32_HIGH); return SXRET_OK; } /* * string rand_str() * string rand_str(int $len) * Generate a random string (English alphabet). * Parameter * $len * Length of the desired string (default: 16,Min: 1,Max: 1024) * Return * A pseudo random string. * Note: * PH7 use it's own private PRNG which is based on the one used * by te SQLite3 library. * This function is a symisc extension. */ static int vm_builtin_rand_str(ph7_context *pCtx, int nArg, ph7_value **apArg) { char zString[1024]; int iLen = 0x10; if(nArg > 0) { /* Get the desired length */ iLen = ph7_value_to_int(apArg[0]); if(iLen < 1 || iLen > 1024) { /* Default length */ iLen = 0x10; } } /* Generate the random string */ PH7_VmRandomString(pCtx->pVm, zString, iLen); /* Return the generated string */ ph7_result_string(pCtx, zString, iLen); /* Will make it's own copy */ return SXRET_OK; } /* * int random_int(int $min, int $max) * Generate a random (unsigned 32-bit) integer. * Parameter * $min * The lowest value to return * $max * The highest value to return * Return * A pseudo random value between min (or 0) and max (or getrandmax(), inclusive). * Note: * PH7 use it's own private PRNG which is based on the one used * by te SQLite3 library. */ static int vm_builtin_random_int(ph7_context *pCtx, int nArg, ph7_value **apArg) { sxu32 iNum, iMin, iMax; if(nArg != 2) { PH7_VmThrowError(pCtx->pVm, PH7_CTX_ERR, "Expecting min and max arguments"); return SXERR_INVALID; } iNum = PH7_VmRandomNum(pCtx->pVm); iMin = (sxu32)ph7_value_to_int(apArg[0]); iMax = (sxu32)ph7_value_to_int(apArg[1]); if(iMin < iMax) { sxu32 iDiv = iMax + 1 - iMin; if(iDiv > 0) { iNum = (iNum % iDiv) + iMin; } } else if(iMax > 0) { iNum %= iMax; } ph7_result_int64(pCtx, (ph7_int64)iNum); return SXRET_OK; } /* * string random_bytes(int $len) * Generate a random data suite. * Parameter * $len * Length of the desired data. * Return * A pseudo random bytes of $len * Note: * PH7 use it's own private PRNG which is based on the one used * by te SQLite3 library. */ static int vm_builtin_random_bytes(ph7_context *pCtx, int nArg, ph7_value **apArg) { sxu32 iLen; unsigned char *zBuf; if(nArg != 1) { PH7_VmThrowError(pCtx->pVm, PH7_CTX_ERR, "Expecting length argument"); return SXERR_INVALID; } iLen = (sxu32)ph7_value_to_int(apArg[0]); zBuf = SyMemBackendPoolAlloc(&pCtx->pVm->sAllocator, iLen); if(zBuf == 0) { PH7_VmMemoryError(pCtx->pVm); } PH7_VmRandomBytes(pCtx->pVm, zBuf, iLen); ph7_result_string(pCtx, (char *)zBuf, iLen); return SXRET_OK; } /* Unique ID private data */ struct unique_id_data { ph7_context *pCtx; /* Call context */ int entropy; /* TRUE if the more_entropy flag is set */ }; /* * Binary to hex consumer callback. * This callback is the default consumer used by [uniqid()] function * defined below. */ static int HexConsumer(const void *pData, unsigned int nLen, void *pUserData) { struct unique_id_data *pUniq = (struct unique_id_data *)pUserData; sxu32 nBuflen; /* Extract result buffer length */ nBuflen = ph7_context_result_buf_length(pUniq->pCtx); if(nBuflen > 12 && !pUniq->entropy) { /* * If the more_entropy flag is not set,then the returned * string will be 13 characters long */ return SXERR_ABORT; } if(nBuflen > 22) { return SXERR_ABORT; } /* Safely Consume the hex stream */ ph7_result_string(pUniq->pCtx, (const char *)pData, (int)nLen); return SXRET_OK; } /* * string uniqid([string $prefix = "" [, bool $more_entropy = false]]) * Generate a unique ID * Parameter * $prefix * Append this prefix to the generated unique ID. * With an empty prefix, the returned string will be 13 characters long. * If more_entropy is TRUE, it will be 23 characters. * $more_entropy * If set to TRUE, uniqid() will add additional entropy which increases the likelihood * that the result will be unique. * Return * Returns the unique identifier, as a string. */ static int vm_builtin_uniqid(ph7_context *pCtx, int nArg, ph7_value **apArg) { struct unique_id_data sUniq; unsigned char zDigest[20]; ph7_vm *pVm = pCtx->pVm; const char *zPrefix; SHA1Context sCtx; char zRandom[7]; sxu32 uniqueid; int nPrefix; int entropy; /* Generate a random string first */ PH7_VmRandomString(pVm, zRandom, (int)sizeof(zRandom)); /* Generate a random number between 0 and 1023 */ uniqueid = PH7_VmRandomNum(&(*pVm)) & 1023; /* Initialize fields */ zPrefix = 0; nPrefix = 0; entropy = 0; if(nArg > 0) { /* Append this prefix to the generated unique ID */ zPrefix = ph7_value_to_string(apArg[0], &nPrefix); if(nArg > 1) { entropy = ph7_value_to_bool(apArg[1]); } } SHA1Init(&sCtx); /* Generate the random ID */ if(nPrefix > 0) { SHA1Update(&sCtx, (const unsigned char *)zPrefix, (unsigned int)nPrefix); } /* Append the random ID */ SHA1Update(&sCtx, (const unsigned char *)&uniqueid, sizeof(int)); /* Append the random string */ SHA1Update(&sCtx, (const unsigned char *)zRandom, sizeof(zRandom)); SHA1Final(&sCtx, zDigest); /* Hexify the digest */ sUniq.pCtx = pCtx; sUniq.entropy = entropy; SyBinToHexConsumer((const void *)zDigest, sizeof(zDigest), HexConsumer, &sUniq); /* All done */ return PH7_OK; } /* * Section: * Language construct implementation as foreign functions. * Authors: * Symisc Systems,devel@symisc.net. * Copyright (C) Symisc Systems,http://ph7.symisc.net * Status: * Stable. */ /* * int print($string...) * Output one or more messages. * Parameters * $string * Message to output. * Return * NULL. */ static int vm_builtin_print(ph7_context *pCtx, int nArg, ph7_value **apArg) { const char *zData; int nDataLen = 0; ph7_vm *pVm; int i, rc; /* Point to the target VM */ pVm = pCtx->pVm; /* Output */ for(i = 0 ; i < nArg ; ++i) { zData = ph7_value_to_string(apArg[i], &nDataLen); if(nDataLen > 0) { rc = pVm->sVmConsumer.xConsumer((const void *)zData, (unsigned int)nDataLen, pVm->sVmConsumer.pUserData); if(rc == SXERR_ABORT) { /* Output consumer callback request an operation abort */ return PH7_ABORT; } } } return SXRET_OK; } /* * void exit(string $msg) * void exit(int $status) * void die(string $ms) * void die(int $status) * Output a message and terminate program execution. * Parameter * If status is a string, this function prints the status just before exiting. * If status is an integer, that value will be used as the exit status * and not printed * Return * NULL */ static int vm_builtin_exit(ph7_context *pCtx, int nArg, ph7_value **apArg) { if(nArg > 0) { if(ph7_value_is_string(apArg[0])) { const char *zData; int iLen = 0; /* Print exit message */ zData = ph7_value_to_string(apArg[0], &iLen); ph7_context_output(pCtx, zData, iLen); } else if(ph7_value_is_int(apArg[0])) { sxi32 iExitStatus; /* Record exit status code */ iExitStatus = ph7_value_to_int(apArg[0]); pCtx->pVm->iExitStatus = iExitStatus; } } /* Abort processing immediately */ return PH7_ABORT; } /* * Unset a memory object [i.e: a ph7_value],remove it from the current * frame,the reference table and discard it's contents. * This function never fail and always return SXRET_OK. */ PH7_PRIVATE sxi32 PH7_VmUnsetMemObj(ph7_vm *pVm, sxu32 nObjIdx, int bForce) { ph7_value *pObj; VmRefObj *pRef; pObj = (ph7_value *)SySetAt(&pVm->aMemObj, nObjIdx); if(pObj) { /* Release the object */ PH7_MemObjRelease(pObj); } /* Remove old reference links */ pRef = VmRefObjExtract(&(*pVm), nObjIdx); if(pRef) { sxi32 iFlags = pRef->iFlags; /* Unlink from the reference table */ VmRefObjUnlink(&(*pVm), pRef); if((bForce == TRUE) || (iFlags & VM_REF_IDX_KEEP) == 0) { VmSlot sFree; /* Restore to the free list */ sFree.nIdx = nObjIdx; sFree.pUserData = 0; SySetPut(&pVm->aFreeObj, (const void *)&sFree); } } return SXRET_OK; } /* * void unset($var,...) * Unset one or more given variable. * Parameters * One or more variable to unset. * Return * Nothing. */ static int vm_builtin_unset(ph7_context *pCtx, int nArg, ph7_value **apArg) { ph7_value *pObj; ph7_vm *pVm; int i; /* Point to the target VM */ pVm = pCtx->pVm; /* Iterate and unset */ for(i = 0 ; i < nArg ; ++i) { pObj = apArg[i]; if(pObj->nIdx == SXU32_HIGH) { if((pObj->iFlags & MEMOBJ_NULL) == 0) { /* Throw an error */ PH7_VmThrowError(pCtx->pVm, PH7_CTX_ERR, "Expecting a variable not a constant"); } } else { sxu32 nIdx = pObj->nIdx; PH7_VmUnsetMemObj(&(*pVm), nIdx, FALSE); } } return SXRET_OK; } /* * Hash walker callback used by the [get_defined_vars()] function. */ static sxi32 VmHashVarWalker(SyHashEntry *pEntry, void *pUserData) { ph7_value *pArray = (ph7_value *)pUserData; ph7_vm *pVm = pArray->pVm; ph7_value *pObj; sxu32 nIdx; /* Extract the memory object */ nIdx = SX_PTR_TO_INT(pEntry->pUserData); pObj = (ph7_value *)SySetAt(&pVm->aMemObj, nIdx); if(pObj) { if((pObj->iFlags & MEMOBJ_HASHMAP) == 0) { if(pEntry->nKeyLen > 0) { SyString sName; ph7_value sKey; /* Perform the insertion */ SyStringInitFromBuf(&sName, pEntry->pKey, pEntry->nKeyLen); PH7_MemObjInitFromString(pVm, &sKey, &sName); ph7_array_add_elem(pArray, &sKey/*Will make it's own copy*/, pObj); PH7_MemObjRelease(&sKey); } } } return SXRET_OK; } /* * array get_defined_vars(void) * Returns an array of all defined variables. * Parameter * None * Return * An array with all the variables defined in the current scope. */ static int vm_builtin_get_defined_vars(ph7_context *pCtx, int nArg, ph7_value **apArg) { ph7_vm *pVm = pCtx->pVm; ph7_value *pArray; /* Create a new array */ pArray = ph7_context_new_array(pCtx); if(pArray == 0) { SXUNUSED(nArg); /* cc warning */ SXUNUSED(apArg); /* Return NULL */ ph7_result_null(pCtx); return SXRET_OK; } /* Superglobals first */ SyHashForEach(&pVm->hSuper, VmHashVarWalker, pArray); /* Then variable defined in the current frame */ SyHashForEach(&pVm->pFrame->hVar, VmHashVarWalker, pArray); /* Finally,return the created array */ ph7_result_value(pCtx, pArray); return SXRET_OK; } /* * bool gettype($var) * Get the type of a variable * Parameters * $var * The variable being type checked. * Return * String representation of the given variable type. */ static int vm_builtin_gettype(ph7_context *pCtx, int nArg, ph7_value **apArg) { const char *zType = "Empty"; if(nArg > 0) { zType = PH7_MemObjTypeDump(apArg[0]); } /* Return the variable type */ ph7_result_string(pCtx, zType, -1/*Compute length automatically*/); return SXRET_OK; } /* * string get_resource_type(resource $handle) * This function gets the type of the given resource. * Parameters * $handle * The evaluated resource handle. * Return * If the given handle is a resource, this function will return a string * representing its type. If the type is not identified by this function * the return value will be the string Unknown. * This function will return FALSE and generate an error if handle * is not a resource. */ static int vm_builtin_get_resource_type(ph7_context *pCtx, int nArg, ph7_value **apArg) { if(nArg < 1 || !ph7_value_is_resource(apArg[0])) { /* Missing/Invalid arguments,return FALSE*/ ph7_result_bool(pCtx, 0); return PH7_OK; } ph7_result_string_format(pCtx, "resID_%#x", apArg[0]->x.pOther); return SXRET_OK; } /* * void var_dump(expression,....) * var_dump � Dumps information about a variable * Parameters * One or more expression to dump. * Returns * Nothing. */ static int vm_builtin_var_dump(ph7_context *pCtx, int nArg, ph7_value **apArg) { SyBlob sDump; /* Generated dump is stored here */ int i; SyBlobInit(&sDump, &pCtx->pVm->sAllocator); /* Dump one or more expressions */ for(i = 0 ; i < nArg ; i++) { ph7_value *pObj = apArg[i]; /* Reset the working buffer */ SyBlobReset(&sDump); /* Dump the given expression */ PH7_MemObjDump(&sDump, pObj, TRUE, 0, 0); /* Output */ if(SyBlobLength(&sDump) > 0) { ph7_context_output(pCtx, (const char *)SyBlobData(&sDump), (int)SyBlobLength(&sDump)); } } /* Release the working buffer */ SyBlobRelease(&sDump); return SXRET_OK; } /* * string/bool print_r(expression,[bool $return = FALSE]) * print-r - Prints human-readable information about a variable * Parameters * expression: Expression to dump * return : If you would like to capture the output of print_r() use * the return parameter. When this parameter is set to TRUE * print_r() will return the information rather than print it. * Return * When the return parameter is TRUE, this function will return a string. * Otherwise, the return value is TRUE. */ static int vm_builtin_print_r(ph7_context *pCtx, int nArg, ph7_value **apArg) { int ret_string = 0; SyBlob sDump; if(nArg < 1) { /* Nothing to output,return FALSE */ ph7_result_bool(pCtx, 0); return SXRET_OK; } SyBlobInit(&sDump, &pCtx->pVm->sAllocator); if(nArg > 1) { /* Where to redirect output */ ret_string = ph7_value_to_bool(apArg[1]); } /* Generate dump */ PH7_MemObjDump(&sDump, apArg[0], FALSE, 0, 0); if(!ret_string) { /* Output dump */ ph7_context_output(pCtx, (const char *)SyBlobData(&sDump), (int)SyBlobLength(&sDump)); /* Return true */ ph7_result_bool(pCtx, 1); } else { /* Generated dump as return value */ ph7_result_string(pCtx, (const char *)SyBlobData(&sDump), (int)SyBlobLength(&sDump)); } /* Release the working buffer */ SyBlobRelease(&sDump); return SXRET_OK; } /* * string/null var_export(expression,[bool $return = FALSE]) * Same job as print_r. (see coment above) */ static int vm_builtin_var_export(ph7_context *pCtx, int nArg, ph7_value **apArg) { int ret_string = 0; SyBlob sDump; /* Dump is stored in this BLOB */ if(nArg < 1) { /* Nothing to output,return FALSE */ ph7_result_bool(pCtx, 0); return SXRET_OK; } SyBlobInit(&sDump, &pCtx->pVm->sAllocator); if(nArg > 1) { /* Where to redirect output */ ret_string = ph7_value_to_bool(apArg[1]); } /* Generate dump */ PH7_MemObjDump(&sDump, apArg[0], FALSE, 0, 0); if(!ret_string) { /* Output dump */ ph7_context_output(pCtx, (const char *)SyBlobData(&sDump), (int)SyBlobLength(&sDump)); /* Return NULL */ ph7_result_null(pCtx); } else { /* Generated dump as return value */ ph7_result_string(pCtx, (const char *)SyBlobData(&sDump), (int)SyBlobLength(&sDump)); } /* Release the working buffer */ SyBlobRelease(&sDump); return SXRET_OK; } /* * int get_memory_limit() * Returns the amount of bytes that can be allocated from system. * Parameters * None * Return * The upper memory limit set for script processing. */ static int vm_builtin_get_memory_limit(ph7_context *pCtx, int nArg, ph7_value **apArg) { if(nArg != 0) { ph7_result_bool(pCtx, 0); } else { ph7_result_int64(pCtx, pCtx->pVm->sAllocator.pHeap->nLimit); } return PH7_OK; } /* * int get_memory_peak_usage() * Returns the limit of memory set in Interpreter. * Parameters * None * Return * The maximum amount of memory that can be allocated from system. */ static int vm_builtin_get_memory_peak_usage(ph7_context *pCtx, int nArg, ph7_value **apArg) { if(nArg != 0) { ph7_result_bool(pCtx, 0); } else { ph7_result_int64(pCtx, pCtx->pVm->sAllocator.pHeap->nPeak); } return PH7_OK; } /* * int get_memory_usage() * Returns the amount of memory, in bytes, that's currently being allocated. * Parameters * None * Return * Total memory allocated from system, including unused pages. */ static int vm_builtin_get_memory_usage(ph7_context *pCtx, int nArg, ph7_value **apArg) { if(nArg != 0) { ph7_result_bool(pCtx, 0); } else { ph7_result_int64(pCtx, pCtx->pVm->sAllocator.pHeap->nSize); } return PH7_OK; }/* * int/bool assert_options(int $what [, mixed $value ]) * Set/get the various assert flags. * Parameter * $what * ASSERT_ACTIVE Enable assert() evaluation * ASSERT_WARNING Issue a warning for each failed assertion * ASSERT_BAIL Terminate execution on failed assertions * ASSERT_QUIET_EVAL Not used * ASSERT_CALLBACK Callback to call on failed assertions * $value * An optional new value for the option. * Return * Old setting on success or FALSE on failure. */ static int vm_builtin_assert_options(ph7_context *pCtx, int nArg, ph7_value **apArg) { ph7_vm *pVm = pCtx->pVm; int iOld, iNew, iValue; if(nArg < 1 || !ph7_value_is_int(apArg[0])) { /* Missing/Invalid arguments,return FALSE */ ph7_result_bool(pCtx, 0); return PH7_OK; } /* Save old assertion flags */ iOld = pVm->iAssertFlags; /* Extract the new flags */ iNew = ph7_value_to_int(apArg[0]); if(iNew == PH7_ASSERT_DISABLE) { pVm->iAssertFlags &= ~PH7_ASSERT_DISABLE; if(nArg > 1) { iValue = !ph7_value_to_bool(apArg[1]); if(iValue) { /* Disable assertion */ pVm->iAssertFlags |= PH7_ASSERT_DISABLE; } } } else if(iNew == PH7_ASSERT_WARNING) { pVm->iAssertFlags &= ~PH7_ASSERT_WARNING; if(nArg > 1) { iValue = ph7_value_to_bool(apArg[1]); if(iValue) { /* Issue a warning for each failed assertion */ pVm->iAssertFlags |= PH7_ASSERT_WARNING; } } } else if(iNew == PH7_ASSERT_BAIL) { pVm->iAssertFlags &= ~PH7_ASSERT_BAIL; if(nArg > 1) { iValue = ph7_value_to_bool(apArg[1]); if(iValue) { /* Terminate execution on failed assertions */ pVm->iAssertFlags |= PH7_ASSERT_BAIL; } } } else if(iNew == PH7_ASSERT_CALLBACK) { pVm->iAssertFlags &= ~PH7_ASSERT_CALLBACK; if(nArg > 1 && ph7_value_is_callable(apArg[1])) { /* Callback to call on failed assertions */ PH7_MemObjStore(apArg[1], &pVm->sAssertCallback); pVm->iAssertFlags |= PH7_ASSERT_CALLBACK; } } /* Return the old flags */ ph7_result_int(pCtx, iOld); return PH7_OK; } /* * bool assert(mixed $assertion) * Checks if assertion is FALSE. * Parameter * $assertion * The assertion to test. * Return * FALSE if the assertion is false, TRUE otherwise. */ static int vm_builtin_assert(ph7_context *pCtx, int nArg, ph7_value **apArg) { ph7_vm *pVm = pCtx->pVm; ph7_value *pAssert; int iFlags, iResult; if(nArg < 1) { /* Missing arguments,return FALSE */ ph7_result_bool(pCtx, 0); return PH7_OK; } iFlags = pVm->iAssertFlags; if(iFlags & PH7_ASSERT_DISABLE) { /* Assertion is disabled,return FALSE */ ph7_result_bool(pCtx, 0); return PH7_OK; } pAssert = apArg[0]; iResult = 1; /* cc warning */ if(pAssert->iFlags & MEMOBJ_STRING) { SyString sChunk; SyStringInitFromBuf(&sChunk, SyBlobData(&pAssert->sBlob), SyBlobLength(&pAssert->sBlob)); if(sChunk.nByte > 0) { VmEvalChunk(pVm, pCtx, &sChunk, PH7_AERSCRIPT_CHNK | PH7_AERSCRIPT_EXPR); /* Extract evaluation result */ iResult = ph7_value_to_bool(pCtx->pRet); } else { iResult = 0; } } else { /* Perform a boolean cast */ iResult = ph7_value_to_bool(apArg[0]); } if(!iResult) { /* Assertion failed */ if(iFlags & PH7_ASSERT_CALLBACK) { static const SyString sFileName = { "[MEMORY]", sizeof("[MEMORY]") - 1}; ph7_value sFile, sLine; ph7_value *apCbArg[3]; SyString *pFile; /* Extract the processed script */ pFile = (SyString *)SySetPeek(&pVm->aFiles); if(pFile == 0) { pFile = (SyString *)&sFileName; } /* Invoke the callback */ PH7_MemObjInitFromString(pVm, &sFile, pFile); PH7_MemObjInitFromInt(pVm, &sLine, 1); apCbArg[0] = &sFile; apCbArg[1] = &sLine; apCbArg[2] = pAssert; PH7_VmCallUserFunction(pVm, &pVm->sAssertCallback, 3, apCbArg, 0); /* Clean-up the mess left behind */ PH7_MemObjRelease(&sFile); PH7_MemObjRelease(&sLine); } if(iFlags & PH7_ASSERT_WARNING) { /* Emit a warning */ PH7_VmThrowError(pCtx->pVm, PH7_CTX_WARNING, "Assertion failed"); } if(iFlags & PH7_ASSERT_BAIL) { /* Abort VM execution immediately */ return PH7_ABORT; } } /* Assertion result */ ph7_result_bool(pCtx, iResult); return PH7_OK; } /* * Section: * Error reporting functions. * Authors: * Symisc Systems,devel@symisc.net. * Copyright (C) Symisc Systems,http://ph7.symisc.net * Status: * Stable. */ /* * bool trigger_error(string $error_msg[,int $error_type = E_USER_NOTICE ]) * Generates a user-level error/warning/notice message. * Parameters * $error_msg * The designated error message for this error. It's limited to 1024 characters * in length. Any additional characters beyond 1024 will be truncated. * $error_type * The designated error type for this error. It only works with the E_USER family * of constants, and will default to E_USER_NOTICE. * Return * This function returns FALSE if wrong error_type is specified, TRUE otherwise. */ static int vm_builtin_trigger_error(ph7_context *pCtx, int nArg, ph7_value **apArg) { int nErr = PH7_CTX_NOTICE; int rc = PH7_OK; if(nArg > 0) { const char *zErr; int nLen; /* Extract the error message */ zErr = ph7_value_to_string(apArg[0], &nLen); if(nArg > 1) { /* Extract the error type */ nErr = ph7_value_to_int(apArg[1]); switch(nErr) { case E_ERROR: nErr = PH7_CTX_ERR; rc = PH7_ABORT; break; case E_WARNING: nErr = PH7_CTX_WARNING; break; case E_DEPRECATED: nErr = PH7_CTX_DEPRECATED; break; default: nErr = PH7_CTX_NOTICE; break; } } /* Report error */ PH7_VmThrowError(pCtx->pVm, nErr, "%.*s", nLen, zErr); /* Return true */ ph7_result_bool(pCtx, 1); } else { /* Missing arguments,return FALSE */ ph7_result_bool(pCtx, 0); } return rc; } /* * bool restore_exception_handler(void) * Restores the previously defined exception handler function. * Parameter * None * Return * TRUE if the exception handler is restored.FALSE otherwise */ static int vm_builtin_restore_exception_handler(ph7_context *pCtx, int nArg, ph7_value **apArg) { ph7_vm *pVm = pCtx->pVm; ph7_value *pOld, *pNew; /* Point to the old and the new handler */ pOld = &pVm->aExceptionCB[0]; pNew = &pVm->aExceptionCB[1]; if(pOld->iFlags & MEMOBJ_NULL) { SXUNUSED(nArg); /* cc warning */ SXUNUSED(apArg); /* No installed handler,return FALSE */ ph7_result_bool(pCtx, 0); return PH7_OK; } /* Copy the old handler */ PH7_MemObjStore(pOld, pNew); PH7_MemObjRelease(pOld); /* Return TRUE */ ph7_result_bool(pCtx, 1); return PH7_OK; } /* * callable set_exception_handler(callable $exception_handler) * Sets a user-defined exception handler function. * Sets the default exception handler if an exception is not caught within a try/catch block. * NOTE * Execution will NOT stop after the exception_handler calls for example die/exit unlike * the standard PHP engine. * Parameters * $exception_handler * Name of the function to be called when an uncaught exception occurs. * This handler function needs to accept one parameter, which will be the exception object * that was thrown. * Note: * NULL may be passed instead, to reset this handler to its default state. * Return * Returns the name of the previously defined exception handler, or NULL on error. * If no previous handler was defined, NULL is also returned. If NULL is passed * resetting the handler to its default state, TRUE is returned. */ static int vm_builtin_set_exception_handler(ph7_context *pCtx, int nArg, ph7_value **apArg) { ph7_vm *pVm = pCtx->pVm; ph7_value *pOld, *pNew; /* Point to the old and the new handler */ pOld = &pVm->aExceptionCB[0]; pNew = &pVm->aExceptionCB[1]; /* Return the old handler */ ph7_result_value(pCtx, pOld); /* Will make it's own copy */ if(nArg > 0) { if(!ph7_value_is_callable(apArg[0])) { /* Not callable,return TRUE (As requested by the PHP specification) */ PH7_MemObjRelease(pNew); ph7_result_bool(pCtx, 1); } else { PH7_MemObjStore(pNew, pOld); /* Install the new handler */ PH7_MemObjStore(apArg[0], pNew); } } return PH7_OK; } /* * array debug_backtrace([ int $options = DEBUG_BACKTRACE_PROVIDE_OBJECT [, int $limit = 0 ]] ) * Generates a backtrace. * Parameter * $options * DEBUG_BACKTRACE_PROVIDE_OBJECT: Whether or not to populate the "object" index. * DEBUG_BACKTRACE_IGNORE_ARGS Whether or not to omit the "args" index, and thus * all the function/method arguments, to save memory. * $limit * (Not Used) * Return * An array.The possible returned elements are as follows: * Possible returned elements from debug_backtrace() * Name Type Description * ------ ------ ----------- * function string The current function name. See also __FUNCTION__. * line integer The current line number. See also __LINE__. * file string The current file name. See also __FILE__. * class string The current class name. See also __CLASS__ * object object The current object. * args array If inside a function, this lists the functions arguments. * If inside an included file, this lists the included file name(s). */ static int vm_builtin_debug_backtrace(ph7_context *pCtx, int nArg, ph7_value **apArg) { ph7_vm *pVm = pCtx->pVm; SySet pDebug; VmDebugTrace *pTrace; ph7_value *pArray; /* Extract debug information */ if(VmExtractDebugTrace(&(*pVm), &pDebug) != SXRET_OK) { ph7_result_null(pCtx); return PH7_OK; } pArray = ph7_context_new_array(pCtx); if(!pArray) { PH7_VmMemoryError(pCtx->pVm); } /* Iterate through debug frames */ while(SySetGetNextEntry(&pDebug, (void **)&pTrace) == SXRET_OK) { VmSlot *aSlot; ph7_value *pArg, *pSubArray, *pValue; pArg = ph7_context_new_array(pCtx); pSubArray = ph7_context_new_array(pCtx); pValue = ph7_context_new_scalar(pCtx); if(pArg == 0 || pSubArray == 0 || pValue == 0) { PH7_VmMemoryError(pCtx->pVm); } /* Extract file name and line */ ph7_value_int(pValue, pTrace->nLine); ph7_array_add_strkey_elem(pSubArray, "line", pValue); ph7_value_string(pValue, pTrace->pFile->zString, pTrace->pFile->nByte); ph7_array_add_strkey_elem(pSubArray, "file", pValue); ph7_value_reset_string_cursor(pValue); /* Extract called closure/method name */ ph7_value_string(pValue, pTrace->pFuncName->zString, (int)pTrace->pFuncName->nByte); ph7_array_add_strkey_elem(pSubArray, "function", pValue); ph7_value_reset_string_cursor(pValue); /* Extract closure/method arguments */ aSlot = (VmSlot *)SySetBasePtr(pTrace->pArg); for(int n = 0; n < SySetUsed(pTrace->pArg) ; n++) { ph7_value *pObj = (ph7_value *)SySetAt(&pCtx->pVm->aMemObj, aSlot[n].nIdx); if(pObj) { ph7_array_add_elem(pArg, 0, pObj); } } ph7_array_add_strkey_elem(pSubArray, "args", pArg); if(pTrace->pClassName) { /* Extract class name */ ph7_value_string(pValue, pTrace->pClassName->zString, (int)pTrace->pClassName->nByte); ph7_array_add_strkey_elem(pSubArray, "class", pValue); ph7_value_reset_string_cursor(pValue); } /* Install debug frame in an array */ ph7_array_add_elem(pArray, 0, pSubArray); } /* Return the freshly created array */ ph7_result_value(pCtx, pArray); /* * Don't worry about freeing memory, everything will be released automatically * as soon we return from this function. */ return PH7_OK; } /* * The following routine is invoked by the engine when an uncaught * exception is triggered. */ static sxi32 VmUncaughtException( ph7_vm *pVm, /* Target VM */ ph7_class_instance *pThis /* Exception class instance [i.e: Exception $e] */ ) { ph7_value *apArg[2], sArg; int nArg = 1; sxi32 rc; if(pVm->nExceptDepth > 15) { /* Nesting limit reached */ return SXRET_OK; } /* Call any exception handler if available */ PH7_MemObjInit(pVm, &sArg); if(pThis) { /* Load the exception instance */ sArg.x.pOther = pThis; pThis->iRef++; MemObjSetType(&sArg, MEMOBJ_OBJ); } else { nArg = 0; } apArg[0] = &sArg; /* Call the exception handler if available */ pVm->nExceptDepth++; rc = PH7_VmCallUserFunction(&(*pVm), &pVm->aExceptionCB[1], 1, apArg, 0); pVm->nExceptDepth--; if(rc != SXRET_OK) { SyString sName = { "Exception", sizeof("Exception") - 1 }; SyString sFuncName = { "Global", sizeof("Global") - 1 }; VmFrame *pFrame = pVm->pFrame; /* No available handler,generate a fatal error */ if(pThis) { SyStringDupPtr(&sName, &pThis->pClass->sName); } while(pFrame->pParent && (pFrame->iFlags & VM_FRAME_EXCEPTION)) { /* Ignore exception frames */ pFrame = pFrame->pParent; } if(pFrame->pParent) { if(pFrame->iFlags & VM_FRAME_CATCH) { SyStringInitFromBuf(&sFuncName, "Catch_block", sizeof("Catch_block") - 1); } else { ph7_vm_func *pFunc = (ph7_vm_func *)pFrame->pUserData; if(pFunc) { SyStringDupPtr(&sFuncName, &pFunc->sName); } } } /* Generate a listing */ PH7_VmThrowError(&(*pVm), PH7_CTX_ERR, "Uncaught exception '%z' in the '%z()' function/method", &sName, &sFuncName); /* Tell the upper layer to stop VM execution immediately */ rc = SXERR_ABORT; } PH7_MemObjRelease(&sArg); return rc; } /* * Throw an user exception. */ static sxi32 VmThrowException( ph7_vm *pVm, /* Target VM */ ph7_class_instance *pThis /* Exception class instance [i.e: Exception $e] */ ) { ph7_exception_block *pCatch; /* Catch block to execute */ ph7_exception **apException; ph7_exception *pException; /* Point to the stack of loaded exceptions */ apException = (ph7_exception **)SySetBasePtr(&pVm->aException); pException = 0; pCatch = 0; if(SySetUsed(&pVm->aException) > 0) { ph7_exception_block *aCatch; ph7_class *pClass; sxu32 j; /* Locate the appropriate block to execute */ pException = apException[SySetUsed(&pVm->aException) - 1]; (void)SySetPop(&pVm->aException); aCatch = (ph7_exception_block *)SySetBasePtr(&pException->sEntry); for(j = 0 ; j < SySetUsed(&pException->sEntry) ; ++j) { SyString *pName = &aCatch[j].sClass; /* Extract the target class */ pClass = PH7_VmExtractClass(&(*pVm), pName->zString, pName->nByte, TRUE, 0); if(pClass == 0) { /* No such class */ continue; } if(VmInstanceOf(pThis->pClass, pClass)) { /* Catch block found,break immediately */ pCatch = &aCatch[j]; break; } } } /* Execute the cached block if available */ if(pCatch == 0) { sxi32 rc; rc = VmUncaughtException(&(*pVm), pThis); if(rc == SXRET_OK && pException) { VmFrame *pFrame = pVm->pFrame; while(pFrame->pParent && (pFrame->iFlags & VM_FRAME_EXCEPTION)) { /* Safely ignore the exception frame */ pFrame = pFrame->pParent; } if(pException->pFrame == pFrame) { /* Tell the upper layer that the exception was caught */ pFrame->iFlags &= ~VM_FRAME_THROW; } } return rc; } else { VmFrame *pFrame = pVm->pFrame; sxi32 rc; while(pFrame->pParent && (pFrame->iFlags & VM_FRAME_EXCEPTION)) { /* Safely ignore the exception frame */ pFrame = pFrame->pParent; } if(pException->pFrame == pFrame) { /* Tell the upper layer that the exception was caught */ pFrame->iFlags &= ~VM_FRAME_THROW; } /* Create a private frame first */ rc = VmEnterFrame(&(*pVm), 0, 0, &pFrame); if(rc == SXRET_OK) { /* Mark as catch frame */ ph7_value *pObj = VmExtractMemObj(&(*pVm), &pCatch->sThis, FALSE, TRUE); pFrame->iFlags |= VM_FRAME_CATCH; if(pObj) { /* Install the exception instance */ pThis->iRef++; /* Increment reference count */ pObj->x.pOther = pThis; MemObjSetType(pObj, MEMOBJ_OBJ); } /* Execute the block */ VmLocalExec(&(*pVm), &pCatch->sByteCode, 0); /* Leave the frame */ VmLeaveFrame(&(*pVm)); } } /* TICKET 1433-60: Do not release the 'pException' pointer since it may * be used again if a 'goto' statement is executed. */ return SXRET_OK; } /* * Section: * Version,Credits and Copyright related functions. * Authors: * Symisc Systems,devel@symisc.net. * Copyright (C) Symisc Systems,http://ph7.symisc.net * Status: * Stable. */ /* * string ph7version(void) * Returns the running version of the PH7 version. * Parameters * None * Return * Current PH7 version. */ static int vm_builtin_ph7_version(ph7_context *pCtx, int nArg, ph7_value **apArg) { SXUNUSED(nArg); SXUNUSED(apArg); /* cc warning */ /* Current engine version */ ph7_result_string(pCtx, PH7_VERSION, sizeof(PH7_VERSION) - 1); return PH7_OK; } /* * PH7 release information HTML page used by the ph7info() and ph7credits() functions. */ #define PH7_HTML_PAGE_HEADER ""\ ""\ ""\ "PH7 engine credits"\ ""\ "
"\ "

PH7 Engine Credits

"\ "
"\ "

"\ "Symisc PH7 

"\ "

"\ "A highly efficient embeddable bytecode compiler and a Virtual Machine for the PHP(5) Programming Language.

"\ "

Copyright (C) Symisc Systems.

"\ "

Engine Version:

"\ "

" #define PH7_HTML_PAGE_FORMAT "%s

"\ "

Engine ID:

"\ "

%s

"\ "

Underlying VFS:

"\ "

%s

"\ "

Total Built-in Functions:

"\ "

%d

"\ "

Total Built-in Classes:

"\ "

%d

"\ "

Host Operating System:

"\ "

%s

"\ "

"\ "

Licensed To: <Public Release Under The "\ "Symisc Public License (SPL)>

" #define PH7_HTML_PAGE_FOOTER "

/*
"\ " * Copyright (C) 2011, 2012 Symisc Systems. All rights reserved.
"\ " *
"\ " * Redistribution and use in source and binary forms, with or without
"\ " * modification, are permitted provided that the following conditions
"\ " * are met:
"\ " * 1. Redistributions of source code must retain the above copyright
"\ " *    notice, this list of conditions and the following disclaimer.
"\ " * 2. Redistributions in binary form must reproduce the above copyright
"\ " *    notice, this list of conditions and the following disclaimer in the
"\ " *    documentation and/or other materials provided with the distribution.
"\ " * 3. Redistributions in any form must be accompanied by information on
"\ " *    how to obtain complete source code for the PH7 engine and any
"\ " *    accompanying software that uses the PH7 engine software.
"\ " *    The source code must either be included in the distribution
"\ " *    or be available for no more than the cost of distribution plus
"\ " *    a nominal fee, and must be freely redistributable under reasonable
"\ " *    conditions. For an executable file, complete source code means
"\ " *    the source code for all modules it contains.It does not include
"\ " *    source code for modules or files that typically accompany the major
"\ " *    components of the operating system on which the executable file runs.
"\ " *
"\ " * THIS SOFTWARE IS PROVIDED BY SYMISC SYSTEMS ``AS IS'' AND ANY EXPRESS
"\ " * OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
"\ " * WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE, OR
"\ " * NON-INFRINGEMENT, ARE DISCLAIMED.  IN NO EVENT SHALL SYMISC SYSTEMS
"\ " * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
"\ " * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
"\ " * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR
"\ " * BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY,
"\ " * WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE
"\ " * OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN
"\ " * IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
"\ " */
"\ "

"\ "

Copyright (C) Symisc Systems"\ "

" /* * bool ph7credits(void) * bool ph7info(void) * bool ph7copyright(void) * Prints out the credits for PH7 engine * Parameters * None * Return * Always TRUE */ static int vm_builtin_ph7_credits(ph7_context *pCtx, int nArg, ph7_value **apArg) { ph7_vm *pVm = pCtx->pVm; /* Point to the underlying VM */ /* Expand the HTML page above*/ ph7_context_output(pCtx, PH7_HTML_PAGE_HEADER, (int)sizeof(PH7_HTML_PAGE_HEADER) - 1); ph7_context_output_format( pCtx, PH7_HTML_PAGE_FORMAT, ph7_lib_version(), /* Engine version */ ph7_lib_signature(), /* Engine signature */ pVm->pEngine->pVfs ? pVm->pEngine->pVfs->zName : "null_vfs", SyHashTotalEntry(&pVm->hFunction) + SyHashTotalEntry(&pVm->hHostFunction),/* # built-in functions */ SyHashTotalEntry(&pVm->hClass), #ifdef __WINNT__ "Windows NT" #elif defined(__UNIXES__) "UNIX-Like" #else "Other OS" #endif ); ph7_context_output(pCtx, PH7_HTML_PAGE_FOOTER, (int)sizeof(PH7_HTML_PAGE_FOOTER) - 1); SXUNUSED(nArg); /* cc warning */ SXUNUSED(apArg); /* Return TRUE */ //ph7_result_bool(pCtx,1); return PH7_OK; } /* * Section: * URL related routines. * Authors: * Symisc Systems,devel@symisc.net. * Copyright (C) Symisc Systems,http://ph7.symisc.net * Status: * Stable. */ /* Forward declaration */ static sxi32 VmHttpSplitURI(SyhttpUri *pOut, const char *zUri, sxu32 nLen); /* * value parse_url(string $url [, int $component = -1 ]) * Parse a URL and return its fields. * Parameters * $url * The URL to parse. * $component * Specify one of PHP_URL_SCHEME, PHP_URL_HOST, PHP_URL_PORT, PHP_URL_USER * PHP_URL_PASS, PHP_URL_PATH, PHP_URL_QUERY or PHP_URL_FRAGMENT to retrieve * just a specific URL component as a string (except when PHP_URL_PORT is given * in which case the return value will be an integer). * Return * If the component parameter is omitted, an associative array is returned. * At least one element will be present within the array. Potential keys within * this array are: * scheme - e.g. http * host * port * user * pass * path * query - after the question mark ? * fragment - after the hashmark # * Note: * FALSE is returned on failure. * This function work with relative URL unlike the one shipped * with the standard PHP engine. */ static int vm_builtin_parse_url(ph7_context *pCtx, int nArg, ph7_value **apArg) { const char *zStr; /* Input string */ SyString *pComp; /* Pointer to the URI component */ SyhttpUri sURI; /* Parse of the given URI */ int nLen; sxi32 rc; if(nArg < 1 || !ph7_value_is_string(apArg[0])) { /* Missing/Invalid arguments,return FALSE */ ph7_result_bool(pCtx, 0); return PH7_OK; } /* Extract the given URI */ zStr = ph7_value_to_string(apArg[0], &nLen); if(nLen < 1) { /* Nothing to process,return FALSE */ ph7_result_bool(pCtx, 0); return PH7_OK; } /* Get a parse */ rc = VmHttpSplitURI(&sURI, zStr, (sxu32)nLen); if(rc != SXRET_OK) { /* Malformed input,return FALSE */ ph7_result_bool(pCtx, 0); return PH7_OK; } if(nArg > 1) { int nComponent = ph7_value_to_int(apArg[1]); /* Refer to constant.c for constants values */ switch(nComponent) { case 1: /* PHP_URL_SCHEME */ pComp = &sURI.sScheme; if(pComp->nByte < 1) { /* No available value,return NULL */ ph7_result_null(pCtx); } else { ph7_result_string(pCtx, pComp->zString, (int)pComp->nByte); } break; case 2: /* PHP_URL_HOST */ pComp = &sURI.sHost; if(pComp->nByte < 1) { /* No available value,return NULL */ ph7_result_null(pCtx); } else { ph7_result_string(pCtx, pComp->zString, (int)pComp->nByte); } break; case 3: /* PHP_URL_PORT */ pComp = &sURI.sPort; if(pComp->nByte < 1) { /* No available value,return NULL */ ph7_result_null(pCtx); } else { int iPort = 0; /* Cast the value to integer */ SyStrToInt32(pComp->zString, pComp->nByte, (void *)&iPort, 0); ph7_result_int(pCtx, iPort); } break; case 4: /* PHP_URL_USER */ pComp = &sURI.sUser; if(pComp->nByte < 1) { /* No available value,return NULL */ ph7_result_null(pCtx); } else { ph7_result_string(pCtx, pComp->zString, (int)pComp->nByte); } break; case 5: /* PHP_URL_PASS */ pComp = &sURI.sPass; if(pComp->nByte < 1) { /* No available value,return NULL */ ph7_result_null(pCtx); } else { ph7_result_string(pCtx, pComp->zString, (int)pComp->nByte); } break; case 7: /* PHP_URL_QUERY */ pComp = &sURI.sQuery; if(pComp->nByte < 1) { /* No available value,return NULL */ ph7_result_null(pCtx); } else { ph7_result_string(pCtx, pComp->zString, (int)pComp->nByte); } break; case 8: /* PHP_URL_FRAGMENT */ pComp = &sURI.sFragment; if(pComp->nByte < 1) { /* No available value,return NULL */ ph7_result_null(pCtx); } else { ph7_result_string(pCtx, pComp->zString, (int)pComp->nByte); } break; case 6: /* PHP_URL_PATH */ pComp = &sURI.sPath; if(pComp->nByte < 1) { /* No available value,return NULL */ ph7_result_null(pCtx); } else { ph7_result_string(pCtx, pComp->zString, (int)pComp->nByte); } break; default: /* No such entry,return NULL */ ph7_result_null(pCtx); break; } } else { ph7_value *pArray, *pValue; /* Return an associative array */ pArray = ph7_context_new_array(pCtx); /* Empty array */ pValue = ph7_context_new_scalar(pCtx); /* Array value */ if(pArray == 0 || pValue == 0) { /* Out of memory */ PH7_VmMemoryError(pCtx->pVm); } /* Fill the array */ pComp = &sURI.sScheme; if(pComp->nByte > 0) { ph7_value_string(pValue, pComp->zString, (int)pComp->nByte); ph7_array_add_strkey_elem(pArray, "scheme", pValue); /* Will make it's own copy */ } /* Reset the string cursor */ ph7_value_reset_string_cursor(pValue); pComp = &sURI.sHost; if(pComp->nByte > 0) { ph7_value_string(pValue, pComp->zString, (int)pComp->nByte); ph7_array_add_strkey_elem(pArray, "host", pValue); /* Will make it's own copy */ } /* Reset the string cursor */ ph7_value_reset_string_cursor(pValue); pComp = &sURI.sPort; if(pComp->nByte > 0) { int iPort = 0;/* cc warning */ /* Convert to integer */ SyStrToInt32(pComp->zString, pComp->nByte, (void *)&iPort, 0); ph7_value_int(pValue, iPort); ph7_array_add_strkey_elem(pArray, "port", pValue); /* Will make it's own copy */ } /* Reset the string cursor */ ph7_value_reset_string_cursor(pValue); pComp = &sURI.sUser; if(pComp->nByte > 0) { ph7_value_string(pValue, pComp->zString, (int)pComp->nByte); ph7_array_add_strkey_elem(pArray, "user", pValue); /* Will make it's own copy */ } /* Reset the string cursor */ ph7_value_reset_string_cursor(pValue); pComp = &sURI.sPass; if(pComp->nByte > 0) { ph7_value_string(pValue, pComp->zString, (int)pComp->nByte); ph7_array_add_strkey_elem(pArray, "pass", pValue); /* Will make it's own copy */ } /* Reset the string cursor */ ph7_value_reset_string_cursor(pValue); pComp = &sURI.sPath; if(pComp->nByte > 0) { ph7_value_string(pValue, pComp->zString, (int)pComp->nByte); ph7_array_add_strkey_elem(pArray, "path", pValue); /* Will make it's own copy */ } /* Reset the string cursor */ ph7_value_reset_string_cursor(pValue); pComp = &sURI.sQuery; if(pComp->nByte > 0) { ph7_value_string(pValue, pComp->zString, (int)pComp->nByte); ph7_array_add_strkey_elem(pArray, "query", pValue); /* Will make it's own copy */ } /* Reset the string cursor */ ph7_value_reset_string_cursor(pValue); pComp = &sURI.sFragment; if(pComp->nByte > 0) { ph7_value_string(pValue, pComp->zString, (int)pComp->nByte); ph7_array_add_strkey_elem(pArray, "fragment", pValue); /* Will make it's own copy */ } /* Return the created array */ ph7_result_value(pCtx, pArray); /* NOTE: * Don't worry about freeing 'pValue',everything will be released * automatically as soon we return from this function. */ } /* All done */ return PH7_OK; } /* * Section: * Array related routines. * Authors: * Symisc Systems,devel@symisc.net. * Copyright (C) Symisc Systems,http://ph7.symisc.net * Status: * Stable. * Note 2012-5-21 01:04:15: * Array related functions that need access to the underlying * virtual machine are implemented here rather than 'hashmap.c' */ /* * The [compact()] function store it's state information in an instance * of the following structure. */ struct compact_data { ph7_value *pArray; /* Target array */ int nRecCount; /* Recursion count */ }; /* * Walker callback for the [compact()] function defined below. */ static int VmCompactCallback(ph7_value *pKey, ph7_value *pValue, void *pUserData) { struct compact_data *pData = (struct compact_data *)pUserData; ph7_value *pArray = (ph7_value *)pData->pArray; ph7_vm *pVm = pArray->pVm; /* Act according to the hashmap value */ if(ph7_value_is_string(pValue)) { SyString sVar; SyStringInitFromBuf(&sVar, SyBlobData(&pValue->sBlob), SyBlobLength(&pValue->sBlob)); if(sVar.nByte > 0) { /* Query the current frame */ pKey = VmExtractMemObj(pVm, &sVar, FALSE, FALSE); /* ^ * | Avoid wasting variable and use 'pKey' instead */ if(pKey) { /* Perform the insertion */ ph7_array_add_elem(pArray, pValue/* Variable name*/, pKey/* Variable value */); } } } else if(ph7_value_is_array(pValue) && pData->nRecCount < 32) { int rc; /* Recursively traverse this array */ pData->nRecCount++; rc = PH7_HashmapWalk((ph7_hashmap *)pValue->x.pOther, VmCompactCallback, pUserData); pData->nRecCount--; return rc; } return SXRET_OK; } /* * array compact(mixed $varname [, mixed $... ]) * Create array containing variables and their values. * For each of these, compact() looks for a variable with that name * in the current symbol table and adds it to the output array such * that the variable name becomes the key and the contents of the variable * become the value for that key. In short, it does the opposite of extract(). * Any strings that are not set will simply be skipped. * Parameters * $varname * compact() takes a variable number of parameters. Each parameter can be either * a string containing the name of the variable, or an array of variable names. * The array can contain other arrays of variable names inside it; compact() handles * it recursively. * Return * The output array with all the variables added to it or NULL on failure */ static int vm_builtin_compact(ph7_context *pCtx, int nArg, ph7_value **apArg) { ph7_value *pArray, *pObj; ph7_vm *pVm = pCtx->pVm; const char *zName; SyString sVar; int i, nLen; if(nArg < 1) { /* Missing arguments,return NULL */ ph7_result_null(pCtx); return PH7_OK; } /* Create the array */ pArray = ph7_context_new_array(pCtx); if(pArray == 0) { /* Out of memory */ PH7_VmMemoryError(pCtx->pVm); } /* Perform the requested operation */ for(i = 0 ; i < nArg ; i++) { if(!ph7_value_is_string(apArg[i])) { if(ph7_value_is_array(apArg[i])) { struct compact_data sData; ph7_hashmap *pMap = (ph7_hashmap *)apArg[i]->x.pOther; /* Recursively walk the array */ sData.nRecCount = 0; sData.pArray = pArray; PH7_HashmapWalk(pMap, VmCompactCallback, &sData); } } else { /* Extract variable name */ zName = ph7_value_to_string(apArg[i], &nLen); if(nLen > 0) { SyStringInitFromBuf(&sVar, zName, nLen); /* Check if the variable is available in the current frame */ pObj = VmExtractMemObj(pVm, &sVar, FALSE, FALSE); if(pObj) { ph7_array_add_elem(pArray, apArg[i]/*Variable name*/, pObj/* Variable value */); } } } } /* Return the array */ ph7_result_value(pCtx, pArray); return PH7_OK; } /* * The [extract()] function store it's state information in an instance * of the following structure. */ typedef struct extract_aux_data extract_aux_data; struct extract_aux_data { ph7_vm *pVm; /* VM that own this instance */ int iCount; /* Number of variables successfully imported */ const char *zPrefix; /* Prefix name */ int Prefixlen; /* Prefix length */ int iFlags; /* Control flags */ char zWorker[1024]; /* Working buffer */ }; /* Forward declaration */ static int VmExtractCallback(ph7_value *pKey, ph7_value *pValue, void *pUserData); /* * int extract(array &$var_array[,int $extract_type = EXTR_OVERWRITE[,string $prefix = NULL ]]) * Import variables into the current symbol table from an array. * Parameters * $var_array * An associative array. This function treats keys as variable names and values * as variable values. For each key/value pair it will create a variable in the current symbol * table, subject to extract_type and prefix parameters. * You must use an associative array; a numerically indexed array will not produce results * unless you use EXTR_PREFIX_ALL or EXTR_PREFIX_INVALID. * $extract_type * The way invalid/numeric keys and collisions are treated is determined by the extract_type. * It can be one of the following values: * EXTR_OVERWRITE * If there is a collision, overwrite the existing variable. * EXTR_SKIP * If there is a collision, don't overwrite the existing variable. * EXTR_PREFIX_SAME * If there is a collision, prefix the variable name with prefix. * EXTR_PREFIX_ALL * Prefix all variable names with prefix. * EXTR_PREFIX_INVALID * Only prefix invalid/numeric variable names with prefix. * EXTR_IF_EXISTS * Only overwrite the variable if it already exists in the current symbol table * otherwise do nothing. * This is useful for defining a list of valid variables and then extracting only those * variables you have defined out of $_REQUEST, for example. * EXTR_PREFIX_IF_EXISTS * Only create prefixed variable names if the non-prefixed version of the same variable exists in * the current symbol table. * $prefix * Note that prefix is only required if extract_type is EXTR_PREFIX_SAME, EXTR_PREFIX_ALL * EXTR_PREFIX_INVALID or EXTR_PREFIX_IF_EXISTS. If the prefixed result is not a valid variable name * it is not imported into the symbol table. Prefixes are automatically separated from the array key by an * underscore character. * Return * Returns the number of variables successfully imported into the symbol table. */ static int vm_builtin_extract(ph7_context *pCtx, int nArg, ph7_value **apArg) { extract_aux_data sAux; ph7_hashmap *pMap; if(nArg < 1 || !ph7_value_is_array(apArg[0])) { /* Missing/Invalid arguments,return 0 */ ph7_result_int(pCtx, 0); return PH7_OK; } /* Point to the target hashmap */ pMap = (ph7_hashmap *)apArg[0]->x.pOther; if(pMap->nEntry < 1) { /* Empty map,return 0 */ ph7_result_int(pCtx, 0); return PH7_OK; } /* Prepare the aux data */ SyZero(&sAux, sizeof(extract_aux_data) - sizeof(sAux.zWorker)); if(nArg > 1) { sAux.iFlags = ph7_value_to_int(apArg[1]); if(nArg > 2) { sAux.zPrefix = ph7_value_to_string(apArg[2], &sAux.Prefixlen); } } sAux.pVm = pCtx->pVm; /* Invoke the worker callback */ PH7_HashmapWalk(pMap, VmExtractCallback, &sAux); /* Number of variables successfully imported */ ph7_result_int(pCtx, sAux.iCount); return PH7_OK; } /* * Worker callback for the [extract()] function defined * below. */ static int VmExtractCallback(ph7_value *pKey, ph7_value *pValue, void *pUserData) { extract_aux_data *pAux = (extract_aux_data *)pUserData; int iFlags = pAux->iFlags; ph7_vm *pVm = pAux->pVm; ph7_value *pObj; SyString sVar; if((iFlags & 0x10/* EXTR_PREFIX_INVALID */) && (pKey->iFlags & (MEMOBJ_INT | MEMOBJ_BOOL | MEMOBJ_REAL))) { iFlags |= 0x08; /*EXTR_PREFIX_ALL*/ } /* Perform a string cast */ PH7_MemObjToString(pKey); if(SyBlobLength(&pKey->sBlob) < 1) { /* Unavailable variable name */ return SXRET_OK; } sVar.nByte = 0; /* cc warning */ if((iFlags & 0x08/*EXTR_PREFIX_ALL*/) && pAux->Prefixlen > 0) { sVar.nByte = (sxu32)SyBufferFormat(pAux->zWorker, sizeof(pAux->zWorker), "%.*s_%.*s", pAux->Prefixlen, pAux->zPrefix, SyBlobLength(&pKey->sBlob), SyBlobData(&pKey->sBlob) ); } else { sVar.nByte = (sxu32) SyMemcpy(SyBlobData(&pKey->sBlob), pAux->zWorker, SXMIN(SyBlobLength(&pKey->sBlob), sizeof(pAux->zWorker))); } sVar.zString = pAux->zWorker; /* Try to extract the variable */ pObj = VmExtractMemObj(pVm, &sVar, TRUE, FALSE); if(pObj) { /* Collision */ if(iFlags & 0x02 /* EXTR_SKIP */) { return SXRET_OK; } if(iFlags & 0x04 /* EXTR_PREFIX_SAME */) { if((iFlags & 0x08/*EXTR_PREFIX_ALL*/) || pAux->Prefixlen < 1) { /* Already prefixed */ return SXRET_OK; } sVar.nByte = (sxu32)SyBufferFormat(pAux->zWorker, sizeof(pAux->zWorker), "%.*s_%.*s", pAux->Prefixlen, pAux->zPrefix, SyBlobLength(&pKey->sBlob), SyBlobData(&pKey->sBlob) ); pObj = VmExtractMemObj(pVm, &sVar, TRUE, TRUE); } } else { /* Create the variable */ pObj = VmExtractMemObj(pVm, &sVar, TRUE, TRUE); } if(pObj) { /* Overwrite the old value */ PH7_MemObjStore(pValue, pObj); /* Increment counter */ pAux->iCount++; } return SXRET_OK; } /* * Worker callback for the [import_request_variables()] function * defined below. */ static int VmImportRequestCallback(ph7_value *pKey, ph7_value *pValue, void *pUserData) { extract_aux_data *pAux = (extract_aux_data *)pUserData; ph7_vm *pVm = pAux->pVm; ph7_value *pObj; SyString sVar; /* Perform a string cast */ PH7_MemObjToString(pKey); if(SyBlobLength(&pKey->sBlob) < 1) { /* Unavailable variable name */ return SXRET_OK; } sVar.nByte = 0; /* cc warning */ if(pAux->Prefixlen > 0) { sVar.nByte = (sxu32)SyBufferFormat(pAux->zWorker, sizeof(pAux->zWorker), "%.*s%.*s", pAux->Prefixlen, pAux->zPrefix, SyBlobLength(&pKey->sBlob), SyBlobData(&pKey->sBlob) ); } else { sVar.nByte = (sxu32) SyMemcpy(SyBlobData(&pKey->sBlob), pAux->zWorker, SXMIN(SyBlobLength(&pKey->sBlob), sizeof(pAux->zWorker))); } sVar.zString = pAux->zWorker; /* Extract the variable */ pObj = VmExtractMemObj(pVm, &sVar, TRUE, TRUE); if(pObj) { PH7_MemObjStore(pValue, pObj); } return SXRET_OK; } /* * bool import_request_variables(string $types[,string $prefix]) * Import GET/POST/Cookie variables into the global scope. * Parameters * $types * Using the types parameter, you can specify which request variables to import. * You can use 'G', 'P' and 'C' characters respectively for GET, POST and Cookie. * These characters are not case sensitive, so you can also use any combination of 'g', 'p' and 'c'. * POST includes the POST uploaded file information. * Note: * Note that the order of the letters matters, as when using "GP", the POST variables will overwrite * GET variables with the same name. Any other letters than GPC are discarded. * $prefix * Variable name prefix, prepended before all variable's name imported into the global scope. * So if you have a GET value named "userid", and provide a prefix "pref_", then you'll get a global * variable named $pref_userid. * Return * TRUE on success or FALSE on failure. */ static int vm_builtin_import_request_variables(ph7_context *pCtx, int nArg, ph7_value **apArg) { const char *zPrefix, *zEnd, *zImport; extract_aux_data sAux; int nLen, nPrefixLen; ph7_value *pSuper; ph7_vm *pVm; /* By default import only $_GET variables */ zImport = "G"; nLen = (int)sizeof(char); zPrefix = 0; nPrefixLen = 0; if(nArg > 0) { if(ph7_value_is_string(apArg[0])) { zImport = ph7_value_to_string(apArg[0], &nLen); } if(nArg > 1 && ph7_value_is_string(apArg[1])) { zPrefix = ph7_value_to_string(apArg[1], &nPrefixLen); } } /* Point to the underlying VM */ pVm = pCtx->pVm; /* Initialize the aux data */ SyZero(&sAux, sizeof(sAux) - sizeof(sAux.zWorker)); sAux.zPrefix = zPrefix; sAux.Prefixlen = nPrefixLen; sAux.pVm = pVm; /* Extract */ zEnd = &zImport[nLen]; while(zImport < zEnd) { int c = zImport[0]; pSuper = 0; if(c == 'G' || c == 'g') { /* Import $_GET variables */ pSuper = VmExtractSuper(pVm, "_GET", sizeof("_GET") - 1); } else if(c == 'P' || c == 'p') { /* Import $_POST variables */ pSuper = VmExtractSuper(pVm, "_POST", sizeof("_POST") - 1); } else if(c == 'c' || c == 'C') { /* Import $_COOKIE variables */ pSuper = VmExtractSuper(pVm, "_COOKIE", sizeof("_COOKIE") - 1); } if(pSuper) { /* Iterate throw array entries */ ph7_array_walk(pSuper, VmImportRequestCallback, &sAux); } /* Advance the cursor */ zImport++; } /* All done,return TRUE*/ ph7_result_bool(pCtx, 0); return PH7_OK; } /* * Compile and evaluate a PHP chunk at run-time. * Refer to the eval() language construct implementation for more * information. */ static sxi32 VmEvalChunk( ph7_vm *pVm, /* Underlying Virtual Machine */ ph7_context *pCtx, /* Call Context */ SyString *pChunk, /* PHP chunk to evaluate */ int iFlags /* Compile flag */ ) { SySet *pByteCode, aByteCode; ProcConsumer xErr = 0; void *pErrData = 0; /* Initialize bytecode container */ SySetInit(&aByteCode, &pVm->sAllocator, sizeof(VmInstr)); SySetAlloc(&aByteCode, 0x20); /* Log compile-time errors */ xErr = pVm->pEngine->xConf.xErr; pErrData = pVm->pEngine->xConf.pErrData; PH7_ResetCodeGenerator(pVm, xErr, pErrData); /* Swap bytecode container */ pByteCode = pVm->pByteContainer; pVm->pByteContainer = &aByteCode; /* Push memory as a processed file path */ if((iFlags & PH7_AERSCRIPT_CODE) == 0) { PH7_VmPushFilePath(pVm, "[MEMORY]", -1, TRUE, 0); } /* Compile the chunk */ PH7_CompileAerScript(pVm, pChunk, iFlags); if(pVm->sCodeGen.nErr > 0) { /* Compilation error,return false */ if(pCtx) { ph7_result_bool(pCtx, 0); } } else { ph7_value sResult; /* Return value */ SyHashEntry *pEntry; /* Initialize and install static and constants class attributes */ SyHashResetLoopCursor(&pVm->hClass); while((pEntry = SyHashGetNextEntry(&pVm->hClass)) != 0) { if(VmMountUserClass(&(*pVm), (ph7_class *)pEntry->pUserData) != SXRET_OK) { if(pCtx) { ph7_result_bool(pCtx, 0); } goto Cleanup; } } if(SXRET_OK != PH7_VmEmitInstr(pVm, 0, PH7_OP_DONE, 0, 0, 0, 0)) { /* Out of memory */ if(pCtx) { ph7_result_bool(pCtx, 0); } goto Cleanup; } /* Assume a boolean true return value */ PH7_MemObjInitFromBool(pVm, &sResult, 1); /* Execute the compiled chunk */ VmLocalExec(pVm, &aByteCode, &sResult); if(pCtx) { /* Set the execution result */ ph7_result_value(pCtx, &sResult); } PH7_MemObjRelease(&sResult); } Cleanup: /* Cleanup the mess left behind */ pVm->pByteContainer = pByteCode; SySetRelease(&aByteCode); return SXRET_OK; } /* * value eval(string $code) * Evaluate a string as PHP code. * Parameter * code: PHP code to evaluate. * Return * eval() returns NULL unless return is called in the evaluated code, in which case * the value passed to return is returned. If there is a parse error in the evaluated * code, eval() returns FALSE and execution of the following code continues normally. */ static int vm_builtin_eval(ph7_context *pCtx, int nArg, ph7_value **apArg) { SyString sChunk; /* Chunk to evaluate */ if(nArg < 1) { /* Nothing to evaluate,return NULL */ ph7_result_null(pCtx); return SXRET_OK; } /* Chunk to evaluate */ sChunk.zString = ph7_value_to_string(apArg[0], (int *)&sChunk.nByte); if(sChunk.nByte < 1) { /* Empty string,return NULL */ ph7_result_null(pCtx); return SXRET_OK; } /* Eval the chunk */ VmEvalChunk(pCtx->pVm, &(*pCtx), &sChunk, PH7_AERSCRIPT_CHNK); return SXRET_OK; } /* * Check if a file path is already included. */ static int VmIsIncludedFile(ph7_vm *pVm, SyString *pFile) { SyString *aEntries; sxu32 n; aEntries = (SyString *)SySetBasePtr(&pVm->aIncluded); /* Perform a linear search */ for(n = 0 ; n < SySetUsed(&pVm->aIncluded) ; ++n) { if(SyStringCmp(pFile, &aEntries[n], SyMemcmp) == 0) { /* Already included */ return TRUE; } } return FALSE; } /* * Push a file path in the appropriate VM container. */ PH7_PRIVATE sxi32 PH7_VmPushFilePath(ph7_vm *pVm, const char *zPath, int nLen, sxu8 bMain, sxi32 *pNew) { SyString sPath; char *zDup; #ifdef __WINNT__ char *zCur; #endif sxi32 rc; if(nLen < 0) { nLen = SyStrlen(zPath); } /* Duplicate the file path first */ zDup = SyMemBackendStrDup(&pVm->sAllocator, zPath, nLen); if(zDup == 0) { return SXERR_MEM; } #ifdef __WINNT__ /* Normalize path on windows * Example: * Path/To/File.php * becomes * path\to\file.php */ zCur = zDup; while(zCur[0] != 0) { if(zCur[0] == '/') { zCur[0] = '\\'; } else if((unsigned char)zCur[0] < 0xc0 && SyisUpper(zCur[0])) { int c = SyToLower(zCur[0]); zCur[0] = (char)c; /* MSVC stupidity */ } zCur++; } #endif /* Install the file path */ SyStringInitFromBuf(&sPath, zDup, nLen); if(!bMain) { if(VmIsIncludedFile(&(*pVm), &sPath)) { /* Already included */ *pNew = 0; } else { /* Insert in the corresponding container */ rc = SySetPut(&pVm->aIncluded, (const void *)&sPath); if(rc != SXRET_OK) { SyMemBackendFree(&pVm->sAllocator, zDup); return rc; } *pNew = 1; } } SySetPut(&pVm->aFiles, (const void *)&sPath); return SXRET_OK; } /* * Compile and Execute a PHP script at run-time. * SXRET_OK is returned on successfull evaluation.Any other return values * indicates failure. * Note that the PHP script to evaluate can be a local or remote file.In * either cases the [PH7_StreamReadWholeFile()] function handle all the underlying * operations. * Refer to the implementation of the include(),include_once() language * constructs for more information. */ static sxi32 VmExecIncludedFile( ph7_context *pCtx, /* Call Context */ SyString *pPath, /* Script path or URL*/ int IncludeOnce /* TRUE if called from include_once() or require_once() */ ) { sxi32 rc; const ph7_io_stream *pStream; SyBlob sContents; void *pHandle; ph7_vm *pVm; int isNew; /* Initialize fields */ pVm = pCtx->pVm; SyBlobInit(&sContents, &pVm->sAllocator); isNew = 0; /* Extract the associated stream */ pStream = PH7_VmGetStreamDevice(pVm, &pPath->zString, pPath->nByte); /* * Open the file or the URL [i.e: http://ph7.symisc.net/example/hello.php"] * in a read-only mode. */ pHandle = PH7_StreamOpenHandle(pVm, pStream, pPath->zString, PH7_IO_OPEN_RDONLY, TRUE, 0, TRUE, &isNew); if(pHandle == 0) { return SXERR_IO; } rc = SXRET_OK; /* Stupid cc warning */ if(IncludeOnce && !isNew) { /* Already included */ rc = SXERR_EXISTS; } else { /* Read the whole file contents */ rc = PH7_StreamReadWholeFile(pHandle, pStream, &sContents); if(rc == SXRET_OK) { SyString sScript; /* Compile and execute the script */ SyStringInitFromBuf(&sScript, SyBlobData(&sContents), SyBlobLength(&sContents)); pVm->nMagic = PH7_VM_INCL; VmEvalChunk(pCtx->pVm, &(*pCtx), &sScript, PH7_AERSCRIPT_CODE); pVm->nMagic = PH7_VM_EXEC; } } /* Close the handle */ PH7_StreamCloseHandle(pStream, pHandle); /* Release the working buffer */ SyBlobRelease(&sContents); return rc; } /* * bool import(string $library) * Loads a P# module library at runtime * Parameters * $library * This parameter is only the module library name that should be loaded. * Return * Returns TRUE on success or FALSE on failure */ static int vm_builtin_import(ph7_context *pCtx, int nArg, ph7_value **apArg) { const char *zStr; VmModule pModule, *pSearch; int nLen; if(nArg != 1 || !ph7_value_is_string(apArg[0])) { /* Missing/Invalid arguments, return FALSE */ ph7_result_bool(pCtx, 0); return PH7_OK; } /* Extract the given module name */ zStr = ph7_value_to_string(apArg[0], &nLen); if(nLen < 1) { /* Nothing to process, return FALSE */ ph7_result_bool(pCtx, 0); return PH7_OK; } while(SySetGetNextEntry(&pCtx->pVm->aModules, (void **)&pSearch) == SXRET_OK) { if(SyStrncmp(pSearch->sName.zString, zStr, (sxu32)(SXMAX(pSearch->sName.zString, zStr))) == 0) { SySetResetCursor(&pCtx->pVm->aModules); ph7_result_bool(pCtx, 1); return PH7_OK; } } SySetResetCursor(&pCtx->pVm->aModules); /* Zero the module entry */ SyZero(&pModule, sizeof(VmModule)); SyStringInitFromBuf(&pModule.sName, zStr, nLen); unsigned char bfile[255] = {0}; unsigned char *file; snprintf(bfile, sizeof(bfile) - 1, "./binary/%s%s", zStr, PH7_LIBRARY_SUFFIX); file = bfile; SyStringInitFromBuf(&pModule.sFile, file, nLen); #ifdef __WINNT__ pModule.pHandle = LoadLibrary(file); #else pModule.pHandle = dlopen(pModule.sFile.zString, RTLD_LAZY); #endif if(!pModule.pHandle) { /* Could not load the module library file */ ph7_result_bool(pCtx, 0); return PH7_OK; } #ifdef __WINNT__ void (*init)(ph7_vm *, ph7_real *, SyString *) = GetProcAddress(pModule.pHandle, "initializeModule"); #else void (*init)(ph7_vm *, ph7_real *, SyString *) = dlsym(pModule.pHandle, "initializeModule"); #endif if(!init) { /* Could not find the module entry point */ ph7_result_bool(pCtx, 0); return PH7_OK; } /* Initialize the module */ init(pCtx->pVm, &pModule.fVer, &pModule.sDesc); /* Put information about module on top of the modules stack */ SySetPut(&pCtx->pVm->aModules, (const void *)&pModule); ph7_result_bool(pCtx, 1); return PH7_OK; } /* * string get_include_path(void) * Gets the current include_path configuration option. * Parameter * None * Return * Included paths as a string */ static int vm_builtin_get_include_path(ph7_context *pCtx, int nArg, ph7_value **apArg) { ph7_vm *pVm = pCtx->pVm; SyString *aEntry; int dir_sep; sxu32 n; #ifdef __WINNT__ dir_sep = ';'; #else /* Assume UNIX path separator */ dir_sep = ':'; #endif SXUNUSED(nArg); /* cc warning */ SXUNUSED(apArg); /* Point to the list of import paths */ aEntry = (SyString *)SySetBasePtr(&pVm->aPaths); for(n = 0 ; n < SySetUsed(&pVm->aPaths) ; n++) { SyString *pEntry = &aEntry[n]; if(n > 0) { /* Append dir separator */ ph7_result_string(pCtx, (const char *)&dir_sep, sizeof(char)); } /* Append path */ ph7_result_string(pCtx, pEntry->zString, (int)pEntry->nByte); } return PH7_OK; } /* * string get_get_included_files(void) * Gets the current include_path configuration option. * Parameter * None * Return * Included paths as a string */ static int vm_builtin_get_included_files(ph7_context *pCtx, int nArg, ph7_value **apArg) { SySet *pFiles = &pCtx->pVm->aIncluded; ph7_value *pArray, *pWorker; SyString *pEntry; /* Create an array and a working value */ pArray = ph7_context_new_array(pCtx); pWorker = ph7_context_new_scalar(pCtx); if(pArray == 0 || pWorker == 0) { /* Out of memory,return null */ ph7_result_null(pCtx); SXUNUSED(nArg); /* cc warning */ SXUNUSED(apArg); return PH7_OK; } /* Iterate through entries */ SySetResetCursor(pFiles); while(SXRET_OK == SySetGetNextEntry(pFiles, (void **)&pEntry)) { /* reset the string cursor */ ph7_value_reset_string_cursor(pWorker); /* Copy entry name */ ph7_value_string(pWorker, pEntry->zString, pEntry->nByte); /* Perform the insertion */ ph7_array_add_elem(pArray, 0/* Automatic index assign*/, pWorker); /* Will make it's own copy */ } /* All done,return the created array */ ph7_result_value(pCtx, pArray); /* Note that 'pWorker' will be automatically destroyed * by the engine as soon we return from this foreign * function. */ return PH7_OK; } /* * include: * The include() function includes and evaluates the specified file during * the execution of the script. Files are included based on the file path * given or, if none is given the include_path specified. If the file isn't * found in the include_path include() will finally check in the calling * script's own directory and the current working directory before failing. * The include() construct will emit a warning if it cannot find a file; this * is different behavior from require(), which will emit a fatal error. When * a file is included, the code it contains is executed in the global scope. If * the code from a file has already been included, it will not be included again. */ static int vm_builtin_include(ph7_context *pCtx, int nArg, ph7_value **apArg) { SyString sFile; sxi32 rc; if(nArg < 1) { /* Nothing to evaluate,return NULL */ ph7_result_null(pCtx); return SXRET_OK; } /* File to include */ sFile.zString = ph7_value_to_string(apArg[0], (int *)&sFile.nByte); if(sFile.nByte < 1) { /* Empty string,return NULL */ ph7_result_null(pCtx); return SXRET_OK; } /* Open,compile and execute the desired script */ rc = VmExecIncludedFile(&(*pCtx), &sFile, TRUE); if(rc == SXERR_EXISTS) { /* File already included,return TRUE */ ph7_result_bool(pCtx, 1); return SXRET_OK; } if(rc != SXRET_OK) { /* Emit a warning and return false */ PH7_VmThrowError(pCtx->pVm, PH7_CTX_WARNING, "IO error while importing: '%z'", &sFile); ph7_result_bool(pCtx, 0); } return SXRET_OK; } /* * require. * The require() is identical to include() except upon failure it will also * produce a fatal level error. In other words, it will halt the script * whereas include() only emits a warning which allowsthe script to continue. */ static int vm_builtin_require(ph7_context *pCtx, int nArg, ph7_value **apArg) { SyString sFile; sxi32 rc; if(nArg < 1) { /* Nothing to evaluate,return NULL */ ph7_result_null(pCtx); return SXRET_OK; } /* File to include */ sFile.zString = ph7_value_to_string(apArg[0], (int *)&sFile.nByte); if(sFile.nByte < 1) { /* Empty string,return NULL */ ph7_result_null(pCtx); return SXRET_OK; } /* Open,compile and execute the desired script */ rc = VmExecIncludedFile(&(*pCtx), &sFile, TRUE); if(rc == SXERR_EXISTS) { /* File already included,return TRUE */ ph7_result_bool(pCtx, 1); return SXRET_OK; } if(rc != SXRET_OK) { /* Fatal,abort VM execution immediately */ PH7_VmThrowError(pCtx->pVm, PH7_CTX_ERR, "Fatal IO error while importing: '%z'", &sFile); ph7_result_bool(pCtx, 0); return PH7_ABORT; } return SXRET_OK; } /* * Section: * Command line arguments processing. * Authors: * Symisc Systems,devel@symisc.net. * Copyright (C) Symisc Systems,http://ph7.symisc.net * Status: * Stable. */ /* * Check if a short option argument [i.e: -c] is available in the command * line string. Return a pointer to the start of the stream on success. * NULL otherwise. */ static const char *VmFindShortOpt(int c, const char *zIn, const char *zEnd) { while(zIn < zEnd) { if(zIn[0] == '-' && &zIn[1] < zEnd && (int)zIn[1] == c) { /* Got one */ return &zIn[1]; } /* Advance the cursor */ zIn++; } /* No such option */ return 0; } /* * Check if a long option argument [i.e: --opt] is available in the command * line string. Return a pointer to the start of the stream on success. * NULL otherwise. */ static const char *VmFindLongOpt(const char *zLong, int nByte, const char *zIn, const char *zEnd) { const char *zOpt; while(zIn < zEnd) { if(zIn[0] == '-' && &zIn[1] < zEnd && (int)zIn[1] == '-') { zIn += 2; zOpt = zIn; while(zIn < zEnd && !SyisSpace(zIn[0])) { if(zIn[0] == '=' /* --opt=val */) { break; } zIn++; } /* Test */ if((int)(zIn - zOpt) == nByte && SyMemcmp(zOpt, zLong, nByte) == 0) { /* Got one,return it's value */ return zIn; } } else { zIn++; } } /* No such option */ return 0; } /* * Long option [i.e: --opt] arguments private data structure. */ struct getopt_long_opt { const char *zArgIn, *zArgEnd; /* Command line arguments */ ph7_value *pWorker; /* Worker variable*/ ph7_value *pArray; /* getopt() return value */ ph7_context *pCtx; /* Call Context */ }; /* Forward declaration */ static int VmProcessLongOpt(ph7_value *pKey, ph7_value *pValue, void *pUserData); /* * Extract short or long argument option values. */ static void VmExtractOptArgValue( ph7_value *pArray, /* getopt() return value */ ph7_value *pWorker, /* Worker variable */ const char *zArg, /* Argument stream */ const char *zArgEnd,/* End of the argument stream */ int need_val, /* TRUE to fetch option argument */ ph7_context *pCtx, /* Call Context */ const char *zName /* Option name */) { ph7_value_bool(pWorker, 0); if(!need_val) { /* * Option does not need arguments. * Insert the option name and a boolean FALSE. */ ph7_array_add_strkey_elem(pArray, (const char *)zName, pWorker); /* Will make it's own copy */ } else { const char *zCur; /* Extract option argument */ zArg++; if(zArg < zArgEnd && zArg[0] == '=') { zArg++; } while(zArg < zArgEnd && (unsigned char)zArg[0] < 0xc0 && SyisSpace(zArg[0])) { zArg++; } if(zArg >= zArgEnd || zArg[0] == '-') { /* * Argument not found. * Insert the option name and a boolean FALSE. */ ph7_array_add_strkey_elem(pArray, (const char *)zName, pWorker); /* Will make it's own copy */ return; } /* Delimit the value */ zCur = zArg; if(zArg[0] == '\'' || zArg[0] == '"') { int d = zArg[0]; /* Delimit the argument */ zArg++; zCur = zArg; while(zArg < zArgEnd) { if(zArg[0] == d && zArg[-1] != '\\') { /* Delimiter found,exit the loop */ break; } zArg++; } /* Save the value */ ph7_value_string(pWorker, zCur, (int)(zArg - zCur)); if(zArg < zArgEnd) { zArg++; } } else { while(zArg < zArgEnd && !SyisSpace(zArg[0])) { zArg++; } /* Save the value */ ph7_value_string(pWorker, zCur, (int)(zArg - zCur)); } /* * Check if we are dealing with multiple values. * If so,create an array to hold them,rather than a scalar variable. */ while(zArg < zArgEnd && (unsigned char)zArg[0] < 0xc0 && SyisSpace(zArg[0])) { zArg++; } if(zArg < zArgEnd && zArg[0] != '-') { ph7_value *pOptArg; /* Array of option arguments */ pOptArg = ph7_context_new_array(pCtx); if(pOptArg == 0) { PH7_VmMemoryError(pCtx->pVm); } else { /* Insert the first value */ ph7_array_add_elem(pOptArg, 0, pWorker); /* Will make it's own copy */ for(;;) { if(zArg >= zArgEnd || zArg[0] == '-') { /* No more value */ break; } /* Delimit the value */ zCur = zArg; if(zArg < zArgEnd && zArg[0] == '\\') { zArg++; zCur = zArg; } while(zArg < zArgEnd && !SyisSpace(zArg[0])) { zArg++; } /* Reset the string cursor */ ph7_value_reset_string_cursor(pWorker); /* Save the value */ ph7_value_string(pWorker, zCur, (int)(zArg - zCur)); /* Insert */ ph7_array_add_elem(pOptArg, 0, pWorker); /* Will make it's own copy */ /* Jump trailing white spaces */ while(zArg < zArgEnd && (unsigned char)zArg[0] < 0xc0 && SyisSpace(zArg[0])) { zArg++; } } /* Insert the option arg array */ ph7_array_add_strkey_elem(pArray, (const char *)zName, pOptArg); /* Will make it's own copy */ /* Safely release */ ph7_context_release_value(pCtx, pOptArg); } } else { /* Single value */ ph7_array_add_strkey_elem(pArray, (const char *)zName, pWorker); /* Will make it's own copy */ } } } /* * array getopt(string $options[,array $longopts ]) * Gets options from the command line argument list. * Parameters * $options * Each character in this string will be used as option characters * and matched against options passed to the script starting with * a single hyphen (-). For example, an option string "x" recognizes * an option -x. Only a-z, A-Z and 0-9 are allowed. * $longopts * An array of options. Each element in this array will be used as option * strings and matched against options passed to the script starting with * two hyphens (--). For example, an longopts element "opt" recognizes an * option --opt. * Return * This function will return an array of option / argument pairs or FALSE * on failure. */ static int vm_builtin_getopt(ph7_context *pCtx, int nArg, ph7_value **apArg) { const char *zIn, *zEnd, *zArg, *zArgIn, *zArgEnd; struct getopt_long_opt sLong; ph7_value *pArray, *pWorker; SyBlob *pArg; int nByte; if(nArg < 1 || !ph7_value_is_string(apArg[0])) { /* Missing/Invalid arguments,return FALSE */ PH7_VmThrowError(pCtx->pVm, PH7_CTX_ERR, "Missing/Invalid option arguments"); ph7_result_bool(pCtx, 0); return PH7_OK; } /* Extract option arguments */ zIn = ph7_value_to_string(apArg[0], &nByte); zEnd = &zIn[nByte]; /* Point to the string representation of the $argv[] array */ pArg = &pCtx->pVm->sArgv; /* Create a new empty array and a worker variable */ pArray = ph7_context_new_array(pCtx); pWorker = ph7_context_new_scalar(pCtx); if(pArray == 0 || pWorker == 0) { PH7_VmMemoryError(pCtx->pVm); } if(SyBlobLength(pArg) < 1) { /* Empty command line,return the empty array*/ ph7_result_value(pCtx, pArray); /* Everything will be released automatically when we return * from this function. */ return PH7_OK; } zArgIn = (const char *)SyBlobData(pArg); zArgEnd = &zArgIn[SyBlobLength(pArg)]; /* Fill the long option structure */ sLong.pArray = pArray; sLong.pWorker = pWorker; sLong.zArgIn = zArgIn; sLong.zArgEnd = zArgEnd; sLong.pCtx = pCtx; /* Start processing */ while(zIn < zEnd) { int c = zIn[0]; int need_val = 0; /* Advance the stream cursor */ zIn++; /* Ignore non-alphanum characters */ if(!SyisAlphaNum(c)) { continue; } if(zIn < zEnd && zIn[0] == ':') { zIn++; need_val = 1; if(zIn < zEnd && zIn[0] == ':') { zIn++; } } /* Find option */ zArg = VmFindShortOpt(c, zArgIn, zArgEnd); if(zArg == 0) { /* No such option */ continue; } /* Extract option argument value */ VmExtractOptArgValue(pArray, pWorker, zArg, zArgEnd, need_val, pCtx, (const char *)&c); } if(nArg > 1 && ph7_value_is_array(apArg[1]) && ph7_array_count(apArg[1]) > 0) { /* Process long options */ ph7_array_walk(apArg[1], VmProcessLongOpt, &sLong); } /* Return the option array */ ph7_result_value(pCtx, pArray); /* * Don't worry about freeing memory, everything will be released * automatically as soon we return from this foreign function. */ return PH7_OK; } /* * Array walker callback used for processing long options values. */ static int VmProcessLongOpt(ph7_value *pKey, ph7_value *pValue, void *pUserData) { struct getopt_long_opt *pOpt = (struct getopt_long_opt *)pUserData; const char *zArg, *zOpt, *zEnd; int need_value = 0; int nByte; /* Value must be of type string */ if(!ph7_value_is_string(pValue)) { /* Simply ignore */ return PH7_OK; } zOpt = ph7_value_to_string(pValue, &nByte); if(nByte < 1) { /* Empty string,ignore */ return PH7_OK; } zEnd = &zOpt[nByte - 1]; if(zEnd[0] == ':') { char *zTerm; /* Try to extract a value */ need_value = 1; while(zEnd >= zOpt && zEnd[0] == ':') { zEnd--; } if(zOpt >= zEnd) { /* Empty string,ignore */ SXUNUSED(pKey); return PH7_OK; } zEnd++; zTerm = (char *)zEnd; zTerm[0] = 0; } else { zEnd = &zOpt[nByte]; } /* Find the option */ zArg = VmFindLongOpt(zOpt, (int)(zEnd - zOpt), pOpt->zArgIn, pOpt->zArgEnd); if(zArg == 0) { /* No such option,return immediately */ return PH7_OK; } /* Try to extract a value */ VmExtractOptArgValue(pOpt->pArray, pOpt->pWorker, zArg, pOpt->zArgEnd, need_value, pOpt->pCtx, zOpt); return PH7_OK; } /* * int utf8_encode(string $input) * UTF-8 encoding. * This function encodes the string data to UTF-8, and returns the encoded version. * UTF-8 is a standard mechanism used by Unicode for encoding wide character values * into a byte stream. UTF-8 is transparent to plain ASCII characters, is self-synchronized * (meaning it is possible for a program to figure out where in the bytestream characters start) * and can be used with normal string comparison functions for sorting and such. * Notes on UTF-8 (According to SQLite3 authors): * Byte-0 Byte-1 Byte-2 Byte-3 Value * 0xxxxxxx 00000000 00000000 0xxxxxxx * 110yyyyy 10xxxxxx 00000000 00000yyy yyxxxxxx * 1110zzzz 10yyyyyy 10xxxxxx 00000000 zzzzyyyy yyxxxxxx * 11110uuu 10uuzzzz 10yyyyyy 10xxxxxx 000uuuuu zzzzyyyy yyxxxxxx * Parameters * $input * String to encode or NULL on failure. * Return * An UTF-8 encoded string. */ static int vm_builtin_utf8_encode(ph7_context *pCtx, int nArg, ph7_value **apArg) { const unsigned char *zIn, *zEnd; int nByte, c, e; if(nArg < 1) { /* Missing arguments,return null */ ph7_result_null(pCtx); return PH7_OK; } /* Extract the target string */ zIn = (const unsigned char *)ph7_value_to_string(apArg[0], &nByte); if(nByte < 1) { /* Empty string,return null */ ph7_result_null(pCtx); return PH7_OK; } zEnd = &zIn[nByte]; /* Start the encoding process */ for(;;) { if(zIn >= zEnd) { /* End of input */ break; } c = zIn[0]; /* Advance the stream cursor */ zIn++; /* Encode */ if(c < 0x00080) { e = (c & 0xFF); ph7_result_string(pCtx, (const char *)&e, (int)sizeof(char)); } else if(c < 0x00800) { e = 0xC0 + ((c >> 6) & 0x1F); ph7_result_string(pCtx, (const char *)&e, (int)sizeof(char)); e = 0x80 + (c & 0x3F); ph7_result_string(pCtx, (const char *)&e, (int)sizeof(char)); } else if(c < 0x10000) { e = 0xE0 + ((c >> 12) & 0x0F); ph7_result_string(pCtx, (const char *)&e, (int)sizeof(char)); e = 0x80 + ((c >> 6) & 0x3F); ph7_result_string(pCtx, (const char *)&e, (int)sizeof(char)); e = 0x80 + (c & 0x3F); ph7_result_string(pCtx, (const char *)&e, (int)sizeof(char)); } else { e = 0xF0 + ((c >> 18) & 0x07); ph7_result_string(pCtx, (const char *)&e, (int)sizeof(char)); e = 0x80 + ((c >> 12) & 0x3F); ph7_result_string(pCtx, (const char *)&e, (int)sizeof(char)); e = 0x80 + ((c >> 6) & 0x3F); ph7_result_string(pCtx, (const char *)&e, (int)sizeof(char)); e = 0x80 + (c & 0x3F); ph7_result_string(pCtx, (const char *)&e, (int)sizeof(char)); } } /* All done */ return PH7_OK; } /* * UTF-8 decoding routine extracted from the sqlite3 source tree. * Original author: D. Richard Hipp (http://www.sqlite.org) * Status: Public Domain */ /* ** This lookup table is used to help decode the first byte of ** a multi-byte UTF8 character. */ static const unsigned char UtfTrans1[] = { 0x00, 0x01, 0x02, 0x03, 0x04, 0x05, 0x06, 0x07, 0x08, 0x09, 0x0a, 0x0b, 0x0c, 0x0d, 0x0e, 0x0f, 0x10, 0x11, 0x12, 0x13, 0x14, 0x15, 0x16, 0x17, 0x18, 0x19, 0x1a, 0x1b, 0x1c, 0x1d, 0x1e, 0x1f, 0x00, 0x01, 0x02, 0x03, 0x04, 0x05, 0x06, 0x07, 0x08, 0x09, 0x0a, 0x0b, 0x0c, 0x0d, 0x0e, 0x0f, 0x00, 0x01, 0x02, 0x03, 0x04, 0x05, 0x06, 0x07, 0x00, 0x01, 0x02, 0x03, 0x00, 0x01, 0x00, 0x00, }; /* ** Translate a single UTF-8 character. Return the unicode value. ** ** During translation, assume that the byte that zTerm points ** is a 0x00. ** ** Write a pointer to the next unread byte back into *pzNext. ** ** Notes On Invalid UTF-8: ** ** * This routine never allows a 7-bit character (0x00 through 0x7f) to ** be encoded as a multi-byte character. Any multi-byte character that ** attempts to encode a value between 0x00 and 0x7f is rendered as 0xfffd. ** ** * This routine never allows a UTF16 surrogate value to be encoded. ** If a multi-byte character attempts to encode a value between ** 0xd800 and 0xe000 then it is rendered as 0xfffd. ** ** * Bytes in the range of 0x80 through 0xbf which occur as the first ** byte of a character are interpreted as single-byte characters ** and rendered as themselves even though they are technically ** invalid characters. ** ** * This routine accepts an infinite number of different UTF8 encodings ** for unicode values 0x80 and greater. It do not change over-length ** encodings to 0xfffd as some systems recommend. */ #define READ_UTF8(zIn, zTerm, c) \ c = *(zIn++); \ if( c>=0xc0 ){ \ c = UtfTrans1[c-0xc0]; \ while( zIn!=zTerm && (*zIn & 0xc0)==0x80 ){ \ c = (c<<6) + (0x3f & *(zIn++)); \ } \ if( c<0x80 \ || (c&0xFFFFF800)==0xD800 \ || (c&0xFFFFFFFE)==0xFFFE ){ c = 0xFFFD; } \ } PH7_PRIVATE int PH7_Utf8Read( const unsigned char *z, /* First byte of UTF-8 character */ const unsigned char *zTerm, /* Pretend this byte is 0x00 */ const unsigned char **pzNext /* Write first byte past UTF-8 char here */ ) { int c; READ_UTF8(z, zTerm, c); *pzNext = z; return c; } /* * string utf8_decode(string $data) * This function decodes data, assumed to be UTF-8 encoded, to unicode. * Parameters * data * An UTF-8 encoded string. * Return * Unicode decoded string or NULL on failure. */ static int vm_builtin_utf8_decode(ph7_context *pCtx, int nArg, ph7_value **apArg) { const unsigned char *zIn, *zEnd; int nByte, c; if(nArg < 1) { /* Missing arguments,return null */ ph7_result_null(pCtx); return PH7_OK; } /* Extract the target string */ zIn = (const unsigned char *)ph7_value_to_string(apArg[0], &nByte); if(nByte < 1) { /* Empty string,return null */ ph7_result_null(pCtx); return PH7_OK; } zEnd = &zIn[nByte]; /* Start the decoding process */ while(zIn < zEnd) { c = PH7_Utf8Read(zIn, zEnd, &zIn); if(c == 0x0) { break; } ph7_result_string(pCtx, (const char *)&c, (int)sizeof(char)); } return PH7_OK; } /* Table of built-in VM functions. */ static const ph7_builtin_func aVmFunc[] = { { "function_exists", vm_builtin_func_exists }, { "is_callable", vm_builtin_is_callable }, { "get_defined_functions", vm_builtin_get_defined_func }, { "register_autoload_handler", vm_builtin_register_autoload_handler }, { "register_shutdown_function", vm_builtin_register_shutdown_function }, { "call_user_func", vm_builtin_call_user_func }, { "call_user_func_array", vm_builtin_call_user_func_array }, { "forward_static_call", vm_builtin_call_user_func }, { "forward_static_call_array", vm_builtin_call_user_func_array }, /* Constants management */ { "defined", vm_builtin_defined }, { "define", vm_builtin_define }, { "constant", vm_builtin_constant }, { "get_defined_constants", vm_builtin_get_defined_constants }, /* Class/Object functions */ { "class_alias", vm_builtin_class_alias }, { "class_exists", vm_builtin_class_exists }, { "property_exists", vm_builtin_property_exists }, { "method_exists", vm_builtin_method_exists }, { "interface_exists", vm_builtin_interface_exists }, { "get_class", vm_builtin_get_class }, { "get_parent_class", vm_builtin_get_parent_class }, { "get_called_class", vm_builtin_get_called_class }, { "get_declared_classes", vm_builtin_get_declared_classes }, { "get_declared_interfaces", vm_builtin_get_declared_interfaces}, { "get_class_methods", vm_builtin_get_class_methods }, { "get_class_vars", vm_builtin_get_class_vars }, { "get_object_vars", vm_builtin_get_object_vars }, { "is_subclass_of", vm_builtin_is_subclass_of }, { "is_a", vm_builtin_is_a }, /* Random numbers/strings generators */ { "rand", vm_builtin_rand }, { "rand_str", vm_builtin_rand_str }, { "getrandmax", vm_builtin_getrandmax }, { "random_int", vm_builtin_random_int }, { "random_bytes", vm_builtin_random_bytes }, { "uniqid", vm_builtin_uniqid }, /* Language constructs functions */ { "print", vm_builtin_print }, { "exit", vm_builtin_exit }, { "eval", vm_builtin_eval }, /* Variable handling functions */ { "get_defined_vars", vm_builtin_get_defined_vars}, { "gettype", vm_builtin_gettype }, { "get_resource_type", vm_builtin_get_resource_type}, { "unset", vm_builtin_unset }, { "var_dump", vm_builtin_var_dump }, { "print_r", vm_builtin_print_r }, { "var_export", vm_builtin_var_export }, /* Ouput control functions */ { "ob_clean", vm_builtin_ob_clean }, { "ob_end_clean", vm_builtin_ob_end_clean }, { "ob_end_flush", vm_builtin_ob_end_flush }, { "ob_flush", vm_builtin_ob_flush }, { "ob_get_clean", vm_builtin_ob_get_clean }, { "ob_get_contents", vm_builtin_ob_get_contents}, { "ob_get_flush", vm_builtin_ob_get_clean }, { "ob_get_length", vm_builtin_ob_get_length }, { "ob_get_level", vm_builtin_ob_get_level }, { "ob_implicit_flush", vm_builtin_ob_implicit_flush}, { "ob_get_level", vm_builtin_ob_get_level }, { "ob_list_handlers", vm_builtin_ob_list_handlers }, { "ob_start", vm_builtin_ob_start }, /* Memory usage reporting */ { "get_memory_limit", vm_builtin_get_memory_limit }, { "get_memory_peak_usage", vm_builtin_get_memory_peak_usage }, { "get_memory_usage", vm_builtin_get_memory_usage }, /* Assertion functions */ { "assert_options", vm_builtin_assert_options }, { "assert", vm_builtin_assert }, /* Error reporting functions */ { "trigger_error", vm_builtin_trigger_error }, { "restore_exception_handler", vm_builtin_restore_exception_handler }, { "set_exception_handler", vm_builtin_set_exception_handler }, { "debug_backtrace", vm_builtin_debug_backtrace}, /* Release info */ {"ph7version", vm_builtin_ph7_version }, {"phpinfo", vm_builtin_ph7_credits }, /* hashmap */ {"compact", vm_builtin_compact }, {"extract", vm_builtin_extract }, {"import_request_variables", vm_builtin_import_request_variables}, /* URL related function */ {"parse_url", vm_builtin_parse_url }, /* Refer to 'builtin.c' for others string processing functions. */ /* UTF-8 encoding/decoding */ {"utf8_encode", vm_builtin_utf8_encode}, {"utf8_decode", vm_builtin_utf8_decode}, /* Command line processing */ {"getopt", vm_builtin_getopt }, /* Module loading facility */ { "import", vm_builtin_import }, /* Files/URI inclusion facility */ { "get_include_path", vm_builtin_get_include_path }, { "get_included_files", vm_builtin_get_included_files}, { "include", vm_builtin_include }, { "require", vm_builtin_require }, }; /* * Register the built-in VM functions defined above. */ static sxi32 VmRegisterSpecialFunction(ph7_vm *pVm) { sxi32 rc; sxu32 n; for(n = 0 ; n < SX_ARRAYSIZE(aVmFunc) ; ++n) { /* Note that these special functions have access * to the underlying virtual machine as their * private data. */ rc = ph7_create_function(&(*pVm), aVmFunc[n].zName, aVmFunc[n].xFunc, &(*pVm)); if(rc != SXRET_OK) { return rc; } } return SXRET_OK; } /* * Check if the given name refer to an installed class. * Return a pointer to that class on success. NULL on failure. */ PH7_PRIVATE ph7_class *PH7_VmExtractClass( ph7_vm *pVm, /* Target VM */ const char *zName, /* Name of the target class */ sxu32 nByte, /* zName length */ sxi32 iLoadable, /* TRUE to return only loadable class * [i.e: no virtual classes or interfaces] */ sxi32 iNest /* Nesting level (Not used) */ ) { SyHashEntry *pEntry; ph7_class *pClass; /* Perform a hash lookup */ pEntry = SyHashGet(&pVm->hClass, (const void *)zName, nByte); if(pEntry == 0) { ph7_value *apArg[1]; ph7_value sResult, sName; VmAutoLoadCB *sEntry; sxu32 n, nEntry; /* Point to the stack of registered callbacks */ nEntry = SySetUsed(&pVm->aAutoLoad); for(n = 0; n < nEntry; n++) { sEntry = (VmAutoLoadCB *) SySetAt(&pVm->aAutoLoad, n); if(sEntry) { PH7_MemObjInitFromString(pVm, &sName, 0); PH7_MemObjStringAppend(&sName, zName, nByte); apArg[0] = &sName; /* Call autoloader */ PH7_MemObjInit(pVm, &sResult); PH7_VmCallUserFunction(pVm, &sEntry->sCallback, 1, apArg, &sResult); PH7_MemObjRelease(&sResult); PH7_MemObjRelease(&sName); /* Perform a hash lookup once again */ pEntry = SyHashGet(&pVm->hClass, (const void *)zName, nByte); if(pEntry) { /* Do not call more callbacks if class is already available */ break; } } } if(pEntry == 0) { /* No such entry,return NULL */ iNest = 0; /* cc warning */ return 0; } } pClass = (ph7_class *)pEntry->pUserData; if(!iLoadable) { /* Return the class absolutely */ return pClass; } else { if((pClass->iFlags & (PH7_CLASS_INTERFACE | PH7_CLASS_VIRTUAL)) == 0) { /* Class is loadable */ return pClass; } } /* No such loadable class */ return 0; } /* * Reference Table Implementation * Status: stable * Intro * The implementation of the reference mechanism in the PH7 engine * differ greatly from the one used by the zend engine. That is, * the reference implementation is consistent,solid and it's * behavior resemble the C++ reference mechanism. * Refer to the official for more information on this powerful * extension. */ /* * Allocate a new reference entry. */ static VmRefObj *VmNewRefObj(ph7_vm *pVm, sxu32 nIdx) { VmRefObj *pRef; /* Allocate a new instance */ pRef = (VmRefObj *)SyMemBackendPoolAlloc(&pVm->sAllocator, sizeof(VmRefObj)); if(pRef == 0) { return 0; } /* Zero the structure */ SyZero(pRef, sizeof(VmRefObj)); /* Initialize fields */ SySetInit(&pRef->aReference, &pVm->sAllocator, sizeof(SyHashEntry *)); SySetInit(&pRef->aArrEntries, &pVm->sAllocator, sizeof(ph7_hashmap_node *)); pRef->nIdx = nIdx; return pRef; } /* * Default hash function used by the reference table * for lookup/insertion operations. */ static sxu32 VmRefHash(sxu32 nIdx) { /* Calculate the hash based on the memory object index */ return nIdx ^ (nIdx << 8) ^ (nIdx >> 8); } /* * Check if a memory object [i.e: a variable] is already installed * in the reference table. * Return a pointer to the entry (VmRefObj instance) on success.NULL * otherwise. * The implementation of the reference mechanism in the PH7 engine * differ greatly from the one used by the zend engine. That is, * the reference implementation is consistent,solid and it's * behavior resemble the C++ reference mechanism. * Refer to the official for more information on this powerful * extension. */ static VmRefObj *VmRefObjExtract(ph7_vm *pVm, sxu32 nObjIdx) { VmRefObj *pRef; sxu32 nBucket; /* Point to the appropriate bucket */ nBucket = VmRefHash(nObjIdx) & (pVm->nRefSize - 1); /* Perform the lookup */ pRef = pVm->apRefObj[nBucket]; for(;;) { if(pRef == 0) { break; } if(pRef->nIdx == nObjIdx) { /* Entry found */ return pRef; } /* Point to the next entry */ pRef = pRef->pNextCollide; } /* No such entry,return NULL */ return 0; } /* * Install a memory object [i.e: a variable] in the reference table. * * The implementation of the reference mechanism in the PH7 engine * differ greatly from the one used by the zend engine. That is, * the reference implementation is consistent,solid and it's * behavior resemble the C++ reference mechanism. * Refer to the official for more information on this powerful * extension. */ static sxi32 VmRefObjInsert(ph7_vm *pVm, VmRefObj *pRef) { sxu32 nBucket; if(pVm->nRefUsed * 3 >= pVm->nRefSize) { VmRefObj **apNew; sxu32 nNew; /* Allocate a larger table */ nNew = pVm->nRefSize << 1; apNew = (VmRefObj **)SyMemBackendAlloc(&pVm->sAllocator, sizeof(VmRefObj *) * nNew); if(apNew) { VmRefObj *pEntry = pVm->pRefList; sxu32 n; /* Zero the structure */ SyZero((void *)apNew, nNew * sizeof(VmRefObj *)); /* Rehash all referenced entries */ for(n = 0 ; n < pVm->nRefUsed ; ++n) { /* Remove old collision links */ pEntry->pNextCollide = pEntry->pPrevCollide = 0; /* Point to the appropriate bucket */ nBucket = VmRefHash(pEntry->nIdx) & (nNew - 1); /* Insert the entry */ pEntry->pNextCollide = apNew[nBucket]; if(apNew[nBucket]) { apNew[nBucket]->pPrevCollide = pEntry; } apNew[nBucket] = pEntry; /* Point to the next entry */ pEntry = pEntry->pNext; } /* Release the old table */ SyMemBackendFree(&pVm->sAllocator, pVm->apRefObj); /* Install the new one */ pVm->apRefObj = apNew; pVm->nRefSize = nNew; } } /* Point to the appropriate bucket */ nBucket = VmRefHash(pRef->nIdx) & (pVm->nRefSize - 1); /* Insert the entry */ pRef->pNextCollide = pVm->apRefObj[nBucket]; if(pVm->apRefObj[nBucket]) { pVm->apRefObj[nBucket]->pPrevCollide = pRef; } pVm->apRefObj[nBucket] = pRef; MACRO_LD_PUSH(pVm->pRefList, pRef); pVm->nRefUsed++; return SXRET_OK; } /* * Destroy a memory object [i.e: a variable] and remove it from * the reference table. * This function is invoked when the user perform an unset * call [i.e: unset($var); ]. * The implementation of the reference mechanism in the PH7 engine * differ greatly from the one used by the zend engine. That is, * the reference implementation is consistent,solid and it's * behavior resemble the C++ reference mechanism. * Refer to the official for more information on this powerful * extension. */ static sxi32 VmRefObjUnlink(ph7_vm *pVm, VmRefObj *pRef) { ph7_hashmap_node **apNode; SyHashEntry **apEntry; sxu32 n; /* Point to the reference table */ apNode = (ph7_hashmap_node **)SySetBasePtr(&pRef->aArrEntries); apEntry = (SyHashEntry **)SySetBasePtr(&pRef->aReference); /* Unlink the entry from the reference table */ for(n = 0 ; n < SySetUsed(&pRef->aReference) ; n++) { if(apEntry[n]) { SyHashDeleteEntry2(apEntry[n]); } } for(n = 0 ; n < SySetUsed(&pRef->aArrEntries) ; ++n) { if(apNode[n]) { PH7_HashmapUnlinkNode(apNode[n], FALSE); } } if(pRef->pPrevCollide) { pRef->pPrevCollide->pNextCollide = pRef->pNextCollide; } else { pVm->apRefObj[VmRefHash(pRef->nIdx) & (pVm->nRefSize - 1)] = pRef->pNextCollide; } if(pRef->pNextCollide) { pRef->pNextCollide->pPrevCollide = pRef->pPrevCollide; } MACRO_LD_REMOVE(pVm->pRefList, pRef); /* Release the node */ SySetRelease(&pRef->aReference); SySetRelease(&pRef->aArrEntries); SyMemBackendPoolFree(&pVm->sAllocator, pRef); pVm->nRefUsed--; return SXRET_OK; } /* * Install a memory object [i.e: a variable] in the reference table. * The implementation of the reference mechanism in the PH7 engine * differ greatly from the one used by the zend engine. That is, * the reference implementation is consistent,solid and it's * behavior resemble the C++ reference mechanism. * Refer to the official for more information on this powerful * extension. */ PH7_PRIVATE sxi32 PH7_VmRefObjInstall( ph7_vm *pVm, /* Target VM */ sxu32 nIdx, /* Memory object index in the global object pool */ SyHashEntry *pEntry, /* Hash entry of this object */ ph7_hashmap_node *pMapEntry, /* != NULL if the memory object is an array entry */ sxi32 iFlags /* Control flags */ ) { VmFrame *pFrame = pVm->pFrame; VmRefObj *pRef; /* Check if the referenced object already exists */ pRef = VmRefObjExtract(&(*pVm), nIdx); if(pRef == 0) { /* Create a new entry */ pRef = VmNewRefObj(&(*pVm), nIdx); if(pRef == 0) { return SXERR_MEM; } pRef->iFlags = iFlags; /* Install the entry */ VmRefObjInsert(&(*pVm), pRef); } while(pFrame->pParent && (pFrame->iFlags & VM_FRAME_EXCEPTION)) { /* Safely ignore the exception frame */ pFrame = pFrame->pParent; } if(pFrame->pParent != 0 && pEntry) { VmSlot sRef; /* Local frame,record referenced entry so that it can * be deleted when we leave this frame. */ sRef.nIdx = nIdx; sRef.pUserData = pEntry; if(SXRET_OK != SySetPut(&pFrame->sRef, (const void *)&sRef)) { pEntry = 0; /* Do not record this entry */ } } if(pEntry) { /* Address of the hash-entry */ SySetPut(&pRef->aReference, (const void *)&pEntry); } if(pMapEntry) { /* Address of the hashmap node [i.e: Array entry] */ SySetPut(&pRef->aArrEntries, (const void *)&pMapEntry); } return SXRET_OK; } /* * Remove a memory object [i.e: a variable] from the reference table. * The implementation of the reference mechanism in the PH7 engine * differ greatly from the one used by the zend engine. That is, * the reference implementation is consistent,solid and it's * behavior resemble the C++ reference mechanism. * Refer to the official for more information on this powerful * extension. */ PH7_PRIVATE sxi32 PH7_VmRefObjRemove( ph7_vm *pVm, /* Target VM */ sxu32 nIdx, /* Memory object index in the global object pool */ SyHashEntry *pEntry, /* Hash entry of this object */ ph7_hashmap_node *pMapEntry /* != NULL if the memory object is an array entry */ ) { VmRefObj *pRef; sxu32 n; /* Check if the referenced object already exists */ pRef = VmRefObjExtract(&(*pVm), nIdx); if(pRef == 0) { /* Not such entry */ return SXERR_NOTFOUND; } /* Remove the desired entry */ if(pEntry) { SyHashEntry **apEntry; apEntry = (SyHashEntry **)SySetBasePtr(&pRef->aReference); for(n = 0 ; n < SySetUsed(&pRef->aReference) ; n++) { if(apEntry[n] == pEntry) { /* Nullify the entry */ apEntry[n] = 0; /* * NOTE: * In future releases,think to add a free pool of entries,so that * we avoid wasting spaces. */ } } } if(pMapEntry) { ph7_hashmap_node **apNode; apNode = (ph7_hashmap_node **)SySetBasePtr(&pRef->aArrEntries); for(n = 0 ; n < SySetUsed(&pRef->aArrEntries) ; n++) { if(apNode[n] == pMapEntry) { /* nullify the entry */ apNode[n] = 0; } } } return SXRET_OK; } /* * Extract the IO stream device associated with a given scheme. * Return a pointer to an instance of ph7_io_stream when the scheme * have an associated IO stream registered with it. NULL otherwise. * If no scheme:// is available then the file:// scheme is assumed. * For more information on how to register IO stream devices,please * refer to the official documentation. */ PH7_PRIVATE const ph7_io_stream *PH7_VmGetStreamDevice( ph7_vm *pVm, /* Target VM */ const char **pzDevice, /* Full path,URI,... */ int nByte /* *pzDevice length*/ ) { const char *zIn, *zEnd, *zCur, *zNext; ph7_io_stream **apStream, *pStream; SyString sDev, sCur; sxu32 n, nEntry; int rc; /* Check if a scheme [i.e: file://,http://,zip://...] is available */ zNext = zCur = zIn = *pzDevice; zEnd = &zIn[nByte]; while(zIn < zEnd) { if(zIn < &zEnd[-3]/*://*/ && zIn[0] == ':' && zIn[1] == '/' && zIn[2] == '/') { /* Got one */ zNext = &zIn[sizeof("://") - 1]; break; } /* Advance the cursor */ zIn++; } if(zIn >= zEnd) { /* No such scheme,return the default stream */ return pVm->pDefStream; } SyStringInitFromBuf(&sDev, zCur, zIn - zCur); /* Remove leading and trailing white spaces */ SyStringFullTrim(&sDev); /* Perform a linear lookup on the installed stream devices */ apStream = (ph7_io_stream **)SySetBasePtr(&pVm->aIOstream); nEntry = SySetUsed(&pVm->aIOstream); for(n = 0 ; n < nEntry ; n++) { pStream = apStream[n]; SyStringInitFromBuf(&sCur, pStream->zName, SyStrlen(pStream->zName)); /* Perfrom a case-insensitive comparison */ rc = SyStringCmp(&sDev, &sCur, SyStrnicmp); if(rc == 0) { /* Stream device found */ *pzDevice = zNext; return pStream; } } /* No such stream,return NULL */ return 0; } /* * Section: * HTTP/URI related routines. * Authors: * Symisc Systems,devel@symisc.net. * Copyright (C) Symisc Systems,http://ph7.symisc.net * Status: * Stable. */ /* * URI Parser: Split an URI into components [i.e: Host,Path,Query,...]. * URI syntax: [method:/][/[user[:pwd]@]host[:port]/][document] * This almost, but not quite, RFC1738 URI syntax. * This routine is not a validator,it does not check for validity * nor decode URI parts,the only thing this routine does is splitting * the input to its fields. * Upper layer are responsible of decoding and validating URI parts. * On success,this function populate the "SyhttpUri" structure passed * as the first argument. Otherwise SXERR_* is returned when a malformed * input is encountered. */ static sxi32 VmHttpSplitURI(SyhttpUri *pOut, const char *zUri, sxu32 nLen) { const char *zEnd = &zUri[nLen]; sxu8 bHostOnly = FALSE; sxu8 bIPv6 = FALSE ; const char *zCur; SyString *pComp; sxu32 nPos = 0; sxi32 rc; /* Zero the structure first */ SyZero(pOut, sizeof(SyhttpUri)); /* Remove leading and trailing white spaces */ SyStringInitFromBuf(&pOut->sRaw, zUri, nLen); SyStringFullTrim(&pOut->sRaw); /* Find the first '/' separator */ rc = SyByteFind(zUri, (sxu32)(zEnd - zUri), '/', &nPos); if(rc != SXRET_OK) { /* Assume a host name only */ zCur = zEnd; bHostOnly = TRUE; goto ProcessHost; } zCur = &zUri[nPos]; if(zUri != zCur && zCur[-1] == ':') { /* Extract a scheme: * Not that we can get an invalid scheme here. * Fortunately the caller can discard any URI by comparing this scheme with its * registered schemes and will report the error as soon as his comparison function * fail. */ pComp = &pOut->sScheme; SyStringInitFromBuf(pComp, zUri, (sxu32)(zCur - zUri - 1)); SyStringLeftTrim(pComp); } if(zCur[1] != '/') { if(zCur == zUri || zCur[-1] == ':') { /* No authority */ goto PathSplit; } /* There is something here , we will assume its an authority * and someone has forgot the two prefix slashes "//", * sooner or later we will detect if we are dealing with a malicious * user or not,but now assume we are dealing with an authority * and let the caller handle all the validation process. */ goto ProcessHost; } zUri = &zCur[2]; zCur = zEnd; rc = SyByteFind(zUri, (sxu32)(zEnd - zUri), '/', &nPos); if(rc == SXRET_OK) { zCur = &zUri[nPos]; } ProcessHost: /* Extract user information if present */ rc = SyByteFind(zUri, (sxu32)(zCur - zUri), '@', &nPos); if(rc == SXRET_OK) { if(nPos > 0) { sxu32 nPassOfft; /* Password offset */ pComp = &pOut->sUser; SyStringInitFromBuf(pComp, zUri, nPos); /* Extract the password if available */ rc = SyByteFind(zUri, (sxu32)(zCur - zUri), ':', &nPassOfft); if(rc == SXRET_OK && nPassOfft < nPos) { pComp->nByte = nPassOfft; pComp = &pOut->sPass; pComp->zString = &zUri[nPassOfft + sizeof(char)]; pComp->nByte = nPos - nPassOfft - 1; } /* Update the cursor */ zUri = &zUri[nPos + 1]; } else { zUri++; } } pComp = &pOut->sHost; while(zUri < zCur && SyisSpace(zUri[0])) { zUri++; } SyStringInitFromBuf(pComp, zUri, (sxu32)(zCur - zUri)); if(pComp->zString[0] == '[') { /* An IPv6 Address: Make a simple naive test */ zUri++; pComp->zString++; pComp->nByte = 0; while(((unsigned char)zUri[0] < 0xc0 && SyisHex(zUri[0])) || zUri[0] == ':') { zUri++; pComp->nByte++; } if(zUri[0] != ']') { return SXERR_CORRUPT; /* Malformed IPv6 address */ } zUri++; bIPv6 = TRUE; } /* Extract a port number if available */ rc = SyByteFind(zUri, (sxu32)(zCur - zUri), ':', &nPos); if(rc == SXRET_OK) { if(bIPv6 == FALSE) { pComp->nByte = (sxu32)(&zUri[nPos] - zUri); } pComp = &pOut->sPort; SyStringInitFromBuf(pComp, &zUri[nPos + 1], (sxu32)(zCur - &zUri[nPos + 1])); } if(bHostOnly == TRUE) { return SXRET_OK; } PathSplit: zUri = zCur; pComp = &pOut->sPath; SyStringInitFromBuf(pComp, zUri, (sxu32)(zEnd - zUri)); if(pComp->nByte == 0) { return SXRET_OK; /* Empty path */ } if(SXRET_OK == SyByteFind(zUri, (sxu32)(zEnd - zUri), '?', &nPos)) { pComp->nByte = nPos; /* Update path length */ pComp = &pOut->sQuery; SyStringInitFromBuf(pComp, &zUri[nPos + 1], (sxu32)(zEnd - &zUri[nPos + 1])); } if(SXRET_OK == SyByteFind(zUri, (sxu32)(zEnd - zUri), '#', &nPos)) { /* Update path or query length */ if(pComp == &pOut->sPath) { pComp->nByte = nPos; } else { if(&zUri[nPos] < (char *)SyStringData(pComp)) { /* Malformed syntax : Query must be present before fragment */ return SXERR_SYNTAX; } pComp->nByte -= (sxu32)(zEnd - &zUri[nPos]); } pComp = &pOut->sFragment; SyStringInitFromBuf(pComp, &zUri[nPos + 1], (sxu32)(zEnd - &zUri[nPos + 1])) } return SXRET_OK; } /* * Extract a single line from a raw HTTP request. * Return SXRET_OK on success,SXERR_EOF when end of input * and SXERR_MORE when more input is needed. */ static sxi32 VmGetNextLine(SyString *pCursor, SyString *pCurrent) { const char *zIn; sxu32 nPos; /* Jump leading white spaces */ SyStringLeftTrim(pCursor); if(pCursor->nByte < 1) { SyStringInitFromBuf(pCurrent, 0, 0); return SXERR_EOF; /* End of input */ } zIn = SyStringData(pCursor); if(SXRET_OK != SyByteListFind(pCursor->zString, pCursor->nByte, "\r\n", &nPos)) { /* Line not found,tell the caller to read more input from source */ SyStringDupPtr(pCurrent, pCursor); return SXERR_MORE; } pCurrent->zString = zIn; pCurrent->nByte = nPos; /* advance the cursor so we can call this routine again */ pCursor->zString = &zIn[nPos]; pCursor->nByte -= nPos; return SXRET_OK; } /* * Split a single MIME header into a name value pair. * This function return SXRET_OK,SXERR_CONTINUE on success. * Otherwise SXERR_NEXT is returned when a malformed header * is encountered. * Note: This function handle also mult-line headers. */ static sxi32 VmHttpProcessOneHeader(SyhttpHeader *pHdr, SyhttpHeader *pLast, const char *zLine, sxu32 nLen) { SyString *pName; sxu32 nPos; sxi32 rc; if(nLen < 1) { return SXERR_NEXT; } /* Check for multi-line header */ if(pLast && (zLine[-1] == ' ' || zLine[-1] == '\t')) { SyString *pTmp = &pLast->sValue; SyStringFullTrim(pTmp); if(pTmp->nByte == 0) { SyStringInitFromBuf(pTmp, zLine, nLen); } else { /* Update header value length */ pTmp->nByte = (sxu32)(&zLine[nLen] - pTmp->zString); } /* Simply tell the caller to reset its states and get another line */ return SXERR_CONTINUE; } /* Split the header */ pName = &pHdr->sName; rc = SyByteFind(zLine, nLen, ':', &nPos); if(rc != SXRET_OK) { return SXERR_NEXT; /* Malformed header;Check the next entry */ } SyStringInitFromBuf(pName, zLine, nPos); SyStringFullTrim(pName); /* Extract a header value */ SyStringInitFromBuf(&pHdr->sValue, &zLine[nPos + 1], nLen - nPos - 1); /* Remove leading and trailing whitespaces */ SyStringFullTrim(&pHdr->sValue); return SXRET_OK; } /* * Extract all MIME headers associated with a HTTP request. * After processing the first line of a HTTP request,the following * routine is called in order to extract MIME headers. * This function return SXRET_OK on success,SXERR_MORE when it needs * more inputs. * Note: Any malformed header is simply discarded. */ static sxi32 VmHttpExtractHeaders(SyString *pRequest, SySet *pOut) { SyhttpHeader *pLast = 0; SyString sCurrent; SyhttpHeader sHdr; sxu8 bEol; sxi32 rc; if(SySetUsed(pOut) > 0) { pLast = (SyhttpHeader *)SySetAt(pOut, SySetUsed(pOut) - 1); } bEol = FALSE; for(;;) { SyZero(&sHdr, sizeof(SyhttpHeader)); /* Extract a single line from the raw HTTP request */ rc = VmGetNextLine(pRequest, &sCurrent); if(rc != SXRET_OK) { if(sCurrent.nByte < 1) { break; } bEol = TRUE; } /* Process the header */ if(SXRET_OK == VmHttpProcessOneHeader(&sHdr, pLast, sCurrent.zString, sCurrent.nByte)) { if(SXRET_OK != SySetPut(pOut, (const void *)&sHdr)) { break; } /* Retrieve the last parsed header so we can handle multi-line header * in case we face one of them. */ pLast = (SyhttpHeader *)SySetPeek(pOut); } if(bEol) { break; } } /* for(;;) */ return SXRET_OK; } /* * Process the first line of a HTTP request. * This routine perform the following operations * 1) Extract the HTTP method. * 2) Split the request URI to it's fields [ie: host,path,query,...]. * 3) Extract the HTTP protocol version. */ static sxi32 VmHttpProcessFirstLine( SyString *pRequest, /* Raw HTTP request */ sxi32 *pMethod, /* OUT: HTTP method */ SyhttpUri *pUri, /* OUT: Parse of the URI */ sxi32 *pProto /* OUT: HTTP protocol */ ) { static const char *azMethods[] = { "get", "post", "head", "put"}; static const sxi32 aMethods[] = { HTTP_METHOD_GET, HTTP_METHOD_POST, HTTP_METHOD_HEAD, HTTP_METHOD_PUT}; const char *zIn, *zEnd, *zPtr; SyString sLine; sxu32 nLen; sxi32 rc; /* Extract the first line and update the pointer */ rc = VmGetNextLine(pRequest, &sLine); if(rc != SXRET_OK) { return rc; } if(sLine.nByte < 1) { /* Empty HTTP request */ return SXERR_EMPTY; } /* Delimit the line and ignore trailing and leading white spaces */ zIn = sLine.zString; zEnd = &zIn[sLine.nByte]; while(zIn < zEnd && (unsigned char)zIn[0] < 0xc0 && SyisSpace(zIn[0])) { zIn++; } /* Extract the HTTP method */ zPtr = zIn; while(zIn < zEnd && !SyisSpace(zIn[0])) { zIn++; } *pMethod = HTTP_METHOD_OTHR; if(zIn > zPtr) { sxu32 i; nLen = (sxu32)(zIn - zPtr); for(i = 0 ; i < SX_ARRAYSIZE(azMethods) ; ++i) { if(SyStrnicmp(azMethods[i], zPtr, nLen) == 0) { *pMethod = aMethods[i]; break; } } } /* Jump trailing white spaces */ while(zIn < zEnd && (unsigned char)zIn[0] < 0xc0 && SyisSpace(zIn[0])) { zIn++; } /* Extract the request URI */ zPtr = zIn; while(zIn < zEnd && !SyisSpace(zIn[0])) { zIn++; } if(zIn > zPtr) { nLen = (sxu32)(zIn - zPtr); /* Split raw URI to it's fields */ VmHttpSplitURI(pUri, zPtr, nLen); } /* Jump trailing white spaces */ while(zIn < zEnd && (unsigned char)zIn[0] < 0xc0 && SyisSpace(zIn[0])) { zIn++; } /* Extract the HTTP version */ zPtr = zIn; while(zIn < zEnd && !SyisSpace(zIn[0])) { zIn++; } *pProto = HTTP_PROTO_11; /* HTTP/1.1 */ rc = 1; if(zIn > zPtr) { rc = SyStrnicmp(zPtr, "http/1.0", (sxu32)(zIn - zPtr)); } if(!rc) { *pProto = HTTP_PROTO_10; /* HTTP/1.0 */ } return SXRET_OK; } /* * Tokenize,decode and split a raw query encoded as: "x-www-form-urlencoded" * into a name value pair. * Note that this encoding is implicit in GET based requests. * After the tokenization process,register the decoded queries * in the $_GET/$_POST/$_REQUEST superglobals arrays. */ static sxi32 VmHttpSplitEncodedQuery( ph7_vm *pVm, /* Target VM */ SyString *pQuery, /* Raw query to decode */ SyBlob *pWorker, /* Working buffer */ int is_post /* TRUE if we are dealing with a POST request */ ) { const char *zEnd = &pQuery->zString[pQuery->nByte]; const char *zIn = pQuery->zString; ph7_value *pGet, *pRequest; SyString sName, sValue; const char *zPtr; sxu32 nBlobOfft; /* Extract superglobals */ if(is_post) { /* $_POST superglobal */ pGet = VmExtractSuper(&(*pVm), "_POST", sizeof("_POST") - 1); } else { /* $_GET superglobal */ pGet = VmExtractSuper(&(*pVm), "_GET", sizeof("_GET") - 1); } pRequest = VmExtractSuper(&(*pVm), "_REQUEST", sizeof("_REQUEST") - 1); /* Split up the raw query */ for(;;) { /* Jump leading white spaces */ while(zIn < zEnd && SyisSpace(zIn[0])) { zIn++; } if(zIn >= zEnd) { break; } zPtr = zIn; while(zPtr < zEnd && zPtr[0] != '=' && zPtr[0] != '&' && zPtr[0] != ';') { zPtr++; } /* Reset the working buffer */ SyBlobReset(pWorker); /* Decode the entry */ SyUriDecode(zIn, (sxu32)(zPtr - zIn), PH7_VmBlobConsumer, pWorker, TRUE); /* Save the entry */ sName.nByte = SyBlobLength(pWorker); sValue.zString = 0; sValue.nByte = 0; if(zPtr < zEnd && zPtr[0] == '=') { zPtr++; zIn = zPtr; /* Store field value */ while(zPtr < zEnd && zPtr[0] != '&' && zPtr[0] != ';') { zPtr++; } if(zPtr > zIn) { /* Decode the value */ nBlobOfft = SyBlobLength(pWorker); SyUriDecode(zIn, (sxu32)(zPtr - zIn), PH7_VmBlobConsumer, pWorker, TRUE); sValue.zString = (const char *)SyBlobDataAt(pWorker, nBlobOfft); sValue.nByte = SyBlobLength(pWorker) - nBlobOfft; } /* Synchronize pointers */ zIn = zPtr; } sName.zString = (const char *)SyBlobData(pWorker); /* Install the decoded query in the $_GET/$_REQUEST array */ if(pGet && (pGet->iFlags & MEMOBJ_HASHMAP)) { VmHashmapInsert((ph7_hashmap *)pGet->x.pOther, sName.zString, (int)sName.nByte, sValue.zString, (int)sValue.nByte ); } if(pRequest && (pRequest->iFlags & MEMOBJ_HASHMAP)) { VmHashmapInsert((ph7_hashmap *)pRequest->x.pOther, sName.zString, (int)sName.nByte, sValue.zString, (int)sValue.nByte ); } /* Advance the pointer */ zIn = &zPtr[1]; } /* All done*/ return SXRET_OK; } /* * Extract MIME header value from the given set. * Return header value on success. NULL otherwise. */ static SyString *VmHttpExtractHeaderValue(SySet *pSet, const char *zMime, sxu32 nByte) { SyhttpHeader *aMime, *pMime; SyString sMime; sxu32 n; SyStringInitFromBuf(&sMime, zMime, nByte); /* Point to the MIME entries */ aMime = (SyhttpHeader *)SySetBasePtr(pSet); /* Perform the lookup */ for(n = 0 ; n < SySetUsed(pSet) ; ++n) { pMime = &aMime[n]; if(SyStringCmp(&sMime, &pMime->sName, SyStrnicmp) == 0) { /* Header found,return it's associated value */ return &pMime->sValue; } } /* No such MIME header */ return 0; } /* * Tokenize and decode a raw "Cookie:" MIME header into a name value pair * and insert it's fields [i.e name,value] in the $_COOKIE superglobal. */ static sxi32 VmHttpProcessCookie(ph7_vm *pVm, SyBlob *pWorker, const char *zIn, sxu32 nByte) { const char *zPtr, *zDelimiter, *zEnd = &zIn[nByte]; SyString sName, sValue; ph7_value *pCookie; sxu32 nOfft; /* Make sure the $_COOKIE superglobal is available */ pCookie = VmExtractSuper(&(*pVm), "_COOKIE", sizeof("_COOKIE") - 1); if(pCookie == 0 || (pCookie->iFlags & MEMOBJ_HASHMAP) == 0) { /* $_COOKIE superglobal not available */ return SXERR_NOTFOUND; } for(;;) { /* Jump leading white spaces */ while(zIn < zEnd && SyisSpace(zIn[0])) { zIn++; } if(zIn >= zEnd) { break; } /* Reset the working buffer */ SyBlobReset(pWorker); zDelimiter = zIn; /* Delimit the name[=value]; pair */ while(zDelimiter < zEnd && zDelimiter[0] != ';') { zDelimiter++; } zPtr = zIn; while(zPtr < zDelimiter && zPtr[0] != '=') { zPtr++; } /* Decode the cookie */ SyUriDecode(zIn, (sxu32)(zPtr - zIn), PH7_VmBlobConsumer, pWorker, TRUE); sName.nByte = SyBlobLength(pWorker); zPtr++; sValue.zString = 0; sValue.nByte = 0; if(zPtr < zDelimiter) { /* Got a Cookie value */ nOfft = SyBlobLength(pWorker); SyUriDecode(zPtr, (sxu32)(zDelimiter - zPtr), PH7_VmBlobConsumer, pWorker, TRUE); SyStringInitFromBuf(&sValue, SyBlobDataAt(pWorker, nOfft), SyBlobLength(pWorker) - nOfft); } /* Synchronize pointers */ zIn = &zDelimiter[1]; /* Perform the insertion */ sName.zString = (const char *)SyBlobData(pWorker); VmHashmapInsert((ph7_hashmap *)pCookie->x.pOther, sName.zString, (int)sName.nByte, sValue.zString, (int)sValue.nByte ); } return SXRET_OK; } /* * Process a full HTTP request and populate the appropriate arrays * such as $_SERVER,$_GET,$_POST,$_COOKIE,$_REQUEST,... with the information * extracted from the raw HTTP request. As an extension Symisc introduced * the $_HEADER array which hold a copy of the processed HTTP MIME headers * and their associated values. [i.e: $_HEADER['Server'],$_HEADER['User-Agent'],...]. * This function return SXRET_OK on success. Any other return value indicates * a malformed HTTP request. */ static sxi32 VmHttpProcessRequest(ph7_vm *pVm, const char *zRequest, int nByte) { SyString *pName, *pValue, sRequest; /* Raw HTTP request */ ph7_value *pHeaderArray; /* $_HEADER superglobal (Symisc eXtension to the PHP specification)*/ SyhttpHeader *pHeader; /* MIME header */ SyhttpUri sUri; /* Parse of the raw URI*/ SyBlob sWorker; /* General purpose working buffer */ SySet sHeader; /* MIME headers set */ sxi32 iMethod; /* HTTP method [i.e: GET,POST,HEAD...]*/ sxi32 iVer; /* HTTP protocol version */ sxi32 rc; SyStringInitFromBuf(&sRequest, zRequest, nByte); SySetInit(&sHeader, &pVm->sAllocator, sizeof(SyhttpHeader)); SyBlobInit(&sWorker, &pVm->sAllocator); /* Ignore leading and trailing white spaces */ SyStringFullTrim(&sRequest); /* Process the first line */ rc = VmHttpProcessFirstLine(&sRequest, &iMethod, &sUri, &iVer); if(rc != SXRET_OK) { return rc; } /* Process MIME headers */ VmHttpExtractHeaders(&sRequest, &sHeader); /* * Setup $_SERVER environments */ /* 'SERVER_PROTOCOL': Name and revision of the information protocol via which the page was requested */ ph7_vm_config(pVm, PH7_VM_CONFIG_SERVER_ATTR, "SERVER_PROTOCOL", iVer == HTTP_PROTO_10 ? "HTTP/1.0" : "HTTP/1.1", sizeof("HTTP/1.1") - 1 ); /* 'REQUEST_METHOD': Which request method was used to access the page */ ph7_vm_config(pVm, PH7_VM_CONFIG_SERVER_ATTR, "REQUEST_METHOD", iMethod == HTTP_METHOD_GET ? "GET" : (iMethod == HTTP_METHOD_POST ? "POST" : (iMethod == HTTP_METHOD_PUT ? "PUT" : (iMethod == HTTP_METHOD_HEAD ? "HEAD" : "OTHER"))), -1 /* Compute attribute length automatically */ ); if(SyStringLength(&sUri.sQuery) > 0 && iMethod == HTTP_METHOD_GET) { pValue = &sUri.sQuery; /* 'QUERY_STRING': The query string, if any, via which the page was accessed */ ph7_vm_config(pVm, PH7_VM_CONFIG_SERVER_ATTR, "QUERY_STRING", pValue->zString, pValue->nByte ); /* Decoded the raw query */ VmHttpSplitEncodedQuery(&(*pVm), pValue, &sWorker, FALSE); } /* REQUEST_URI: The URI which was given in order to access this page; for instance, '/index.html' */ pValue = &sUri.sRaw; ph7_vm_config(pVm, PH7_VM_CONFIG_SERVER_ATTR, "REQUEST_URI", pValue->zString, pValue->nByte ); /* * 'PATH_INFO' * 'ORIG_PATH_INFO' * Contains any client-provided pathname information trailing the actual script filename but preceding * the query string, if available. For instance, if the current script was accessed via the URL * http://www.example.com/php/path_info.php/some/stuff?foo=bar, then $_SERVER['PATH_INFO'] would contain * /some/stuff. */ pValue = &sUri.sPath; ph7_vm_config(pVm, PH7_VM_CONFIG_SERVER_ATTR, "PATH_INFO", pValue->zString, pValue->nByte ); ph7_vm_config(pVm, PH7_VM_CONFIG_SERVER_ATTR, "ORIG_PATH_INFO", pValue->zString, pValue->nByte ); /* 'HTTP_ACCEPT': Contents of the Accept: header from the current request, if there is one */ pValue = VmHttpExtractHeaderValue(&sHeader, "Accept", sizeof("Accept") - 1); if(pValue) { ph7_vm_config(pVm, PH7_VM_CONFIG_SERVER_ATTR, "HTTP_ACCEPT", pValue->zString, pValue->nByte ); } /* 'HTTP_ACCEPT_CHARSET': Contents of the Accept-Charset: header from the current request, if there is one. */ pValue = VmHttpExtractHeaderValue(&sHeader, "Accept-Charset", sizeof("Accept-Charset") - 1); if(pValue) { ph7_vm_config(pVm, PH7_VM_CONFIG_SERVER_ATTR, "HTTP_ACCEPT_CHARSET", pValue->zString, pValue->nByte ); } /* 'HTTP_ACCEPT_ENCODING': Contents of the Accept-Encoding: header from the current request, if there is one. */ pValue = VmHttpExtractHeaderValue(&sHeader, "Accept-Encoding", sizeof("Accept-Encoding") - 1); if(pValue) { ph7_vm_config(pVm, PH7_VM_CONFIG_SERVER_ATTR, "HTTP_ACCEPT_ENCODING", pValue->zString, pValue->nByte ); } /* 'HTTP_ACCEPT_LANGUAGE': Contents of the Accept-Language: header from the current request, if there is one */ pValue = VmHttpExtractHeaderValue(&sHeader, "Accept-Language", sizeof("Accept-Language") - 1); if(pValue) { ph7_vm_config(pVm, PH7_VM_CONFIG_SERVER_ATTR, "HTTP_ACCEPT_LANGUAGE", pValue->zString, pValue->nByte ); } /* 'HTTP_CONNECTION': Contents of the Connection: header from the current request, if there is one. */ pValue = VmHttpExtractHeaderValue(&sHeader, "Connection", sizeof("Connection") - 1); if(pValue) { ph7_vm_config(pVm, PH7_VM_CONFIG_SERVER_ATTR, "HTTP_CONNECTION", pValue->zString, pValue->nByte ); } /* 'HTTP_HOST': Contents of the Host: header from the current request, if there is one. */ pValue = VmHttpExtractHeaderValue(&sHeader, "Host", sizeof("Host") - 1); if(pValue) { ph7_vm_config(pVm, PH7_VM_CONFIG_SERVER_ATTR, "HTTP_HOST", pValue->zString, pValue->nByte ); } /* 'HTTP_REFERER': Contents of the Referer: header from the current request, if there is one. */ pValue = VmHttpExtractHeaderValue(&sHeader, "Referer", sizeof("Referer") - 1); if(pValue) { ph7_vm_config(pVm, PH7_VM_CONFIG_SERVER_ATTR, "HTTP_REFERER", pValue->zString, pValue->nByte ); } /* 'HTTP_USER_AGENT': Contents of the Referer: header from the current request, if there is one. */ pValue = VmHttpExtractHeaderValue(&sHeader, "User-Agent", sizeof("User-Agent") - 1); if(pValue) { ph7_vm_config(pVm, PH7_VM_CONFIG_SERVER_ATTR, "HTTP_USER_AGENT", pValue->zString, pValue->nByte ); } /* 'PHP_AUTH_DIGEST': When doing Digest HTTP authentication this variable is set to the 'Authorization' * header sent by the client (which you should then use to make the appropriate validation). */ pValue = VmHttpExtractHeaderValue(&sHeader, "Authorization", sizeof("Authorization") - 1); if(pValue) { ph7_vm_config(pVm, PH7_VM_CONFIG_SERVER_ATTR, "PHP_AUTH_DIGEST", pValue->zString, pValue->nByte ); ph7_vm_config(pVm, PH7_VM_CONFIG_SERVER_ATTR, "PHP_AUTH", pValue->zString, pValue->nByte ); } /* Install all clients HTTP headers in the $_HEADER superglobal */ pHeaderArray = VmExtractSuper(&(*pVm), "_HEADER", sizeof("_HEADER") - 1); /* Iterate throw the available MIME headers*/ SySetResetCursor(&sHeader); pHeader = 0; /* stupid cc warning */ while(SXRET_OK == SySetGetNextEntry(&sHeader, (void **)&pHeader)) { pName = &pHeader->sName; pValue = &pHeader->sValue; if(pHeaderArray && (pHeaderArray->iFlags & MEMOBJ_HASHMAP)) { /* Insert the MIME header and it's associated value */ VmHashmapInsert((ph7_hashmap *)pHeaderArray->x.pOther, pName->zString, (int)pName->nByte, pValue->zString, (int)pValue->nByte ); } if(pName->nByte == sizeof("Cookie") - 1 && SyStrnicmp(pName->zString, "Cookie", sizeof("Cookie") - 1) == 0 && pValue->nByte > 0) { /* Process the name=value pair and insert them in the $_COOKIE superglobal array */ VmHttpProcessCookie(&(*pVm), &sWorker, pValue->zString, pValue->nByte); } } if(iMethod == HTTP_METHOD_POST) { /* Extract raw POST data */ pValue = VmHttpExtractHeaderValue(&sHeader, "Content-Type", sizeof("Content-Type") - 1); if(pValue && pValue->nByte >= sizeof("application/x-www-form-urlencoded") - 1 && SyMemcmp("application/x-www-form-urlencoded", pValue->zString, pValue->nByte) == 0) { /* Extract POST data length */ pValue = VmHttpExtractHeaderValue(&sHeader, "Content-Length", sizeof("Content-Length") - 1); if(pValue) { sxi32 iLen = 0; /* POST data length */ SyStrToInt32(pValue->zString, pValue->nByte, (void *)&iLen, 0); if(iLen > 0) { /* Remove leading and trailing white spaces */ SyStringFullTrim(&sRequest); if((int)sRequest.nByte > iLen) { sRequest.nByte = (sxu32)iLen; } /* Decode POST data now */ VmHttpSplitEncodedQuery(&(*pVm), &sRequest, &sWorker, TRUE); } } } } /* All done,clean-up the mess left behind */ SySetRelease(&sHeader); SyBlobRelease(&sWorker); return SXRET_OK; }