/* * File expr.c - expression handling for Wine internal debugger. * * Copyright (C) 1997, Eric Youngdale. * * This library is free software; you can redistribute it and/or * modify it under the terms of the GNU Lesser General Public * License as published by the Free Software Foundation; either * version 2.1 of the License, or (at your option) any later version. * * This library is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU * Lesser General Public License for more details. * * You should have received a copy of the GNU Lesser General Public * License along with this library; if not, write to the Free Software * Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301, USA */ #include "config.h" #include <stdlib.h> #include <string.h> #include <stdarg.h> #include "debugger.h" #include "expr.h" #include "wine/debug.h" WINE_DEFAULT_DEBUG_CHANNEL(winedbg); struct expr { unsigned int type; union { struct { int value; } s_const; struct { unsigned int value; } u_const; struct { const char* str; } string; struct { const char* name; } symbol; struct { const char* name; } intvar; struct { int unop_type; struct expr* exp1; long int result; } unop; struct { int binop_type; struct expr* exp1; struct expr* exp2; long int result; } binop; struct { struct type_expr_t cast_to; struct expr* expr; } cast; struct { struct expr* exp1; const char* element_name; long int result; } structure; struct { const char* funcname; int nargs; struct expr* arg[5]; long int result; } call; } un; }; #define EXPR_TYPE_S_CONST 0 #define EXPR_TYPE_U_CONST 1 #define EXPR_TYPE_SYMBOL 2 #define EXPR_TYPE_INTVAR 3 #define EXPR_TYPE_BINOP 4 #define EXPR_TYPE_UNOP 5 #define EXPR_TYPE_STRUCT 6 #define EXPR_TYPE_PSTRUCT 7 #define EXPR_TYPE_CALL 8 #define EXPR_TYPE_STRING 9 #define EXPR_TYPE_CAST 10 static char expr_list[4096]; static unsigned int next_expr_free = 0; static struct expr* expr_alloc(void) { struct expr* rtn; rtn = (struct expr*)&expr_list[next_expr_free]; next_expr_free += sizeof(struct expr); assert(next_expr_free < sizeof(expr_list)); return rtn; } void expr_free_all(void) { next_expr_free = 0; } struct expr* expr_alloc_typecast(struct type_expr_t* tet, struct expr* exp) { struct expr* ex; ex = expr_alloc(); ex->type = EXPR_TYPE_CAST; ex->un.cast.cast_to = *tet; ex->un.cast.expr = exp; return ex; } struct expr* expr_alloc_internal_var(const char* name) { struct expr* ex; ex = expr_alloc(); ex->type = EXPR_TYPE_INTVAR; ex->un.intvar.name = name; return ex; } struct expr* expr_alloc_symbol(const char* name) { struct expr* ex; ex = expr_alloc(); ex->type = EXPR_TYPE_SYMBOL; ex->un.symbol.name = name; return ex; } struct expr* expr_alloc_sconstant(int value) { struct expr* ex; ex = expr_alloc(); ex->type = EXPR_TYPE_S_CONST; ex->un.s_const.value = value; return ex; } struct expr* expr_alloc_uconstant(unsigned int value) { struct expr* ex; ex = expr_alloc(); ex->type = EXPR_TYPE_U_CONST; ex->un.u_const.value = value; return ex; } struct expr* expr_alloc_string(const char* str) { struct expr* ex; ex = expr_alloc(); ex->type = EXPR_TYPE_STRING; ex->un.string.str = str; return ex; } struct expr* expr_alloc_binary_op(int op_type, struct expr* exp1, struct expr* exp2) { struct expr* ex; ex = expr_alloc(); ex->type = EXPR_TYPE_BINOP; ex->un.binop.binop_type = op_type; ex->un.binop.exp1 = exp1; ex->un.binop.exp2 = exp2; return ex; } struct expr* expr_alloc_unary_op(int op_type, struct expr* exp1) { struct expr* ex; ex = expr_alloc(); ex->type = EXPR_TYPE_UNOP; ex->un.unop.unop_type = op_type; ex->un.unop.exp1 = exp1; return ex; } struct expr* expr_alloc_struct(struct expr* exp, const char* element) { struct expr* ex; ex = expr_alloc(); ex->type = EXPR_TYPE_STRUCT; ex->un.structure.exp1 = exp; ex->un.structure.element_name = element; return ex; } struct expr* expr_alloc_pstruct(struct expr* exp, const char* element) { struct expr* ex; ex = expr_alloc(); ex->type = EXPR_TYPE_PSTRUCT; ex->un.structure.exp1 = exp; ex->un.structure.element_name = element; return ex; } struct expr* expr_alloc_func_call(const char* funcname, int nargs, ...) { struct expr* ex; va_list ap; int i; ex = expr_alloc(); ex->type = EXPR_TYPE_CALL; ex->un.call.funcname = funcname; ex->un.call.nargs = nargs; va_start(ap, nargs); for (i = 0; i < nargs; i++) { ex->un.call.arg[i] = va_arg(ap, struct expr*); } va_end(ap); return ex; } /****************************************************************** * expr_eval * */ struct dbg_lvalue expr_eval(struct expr* exp) { struct dbg_lvalue rtn; int i; struct dbg_lvalue exp1; struct dbg_lvalue exp2; unsigned int cexp[5]; DWORD64 scale1, scale2, scale3; struct dbg_type type1, type2; DWORD tag; const struct dbg_internal_var* div; rtn.cookie = 0; rtn.type.id = dbg_itype_none; rtn.type.module = 0; rtn.addr.Mode = AddrModeFlat; rtn.addr.Offset = 0; rtn.addr.Segment = 0; switch (exp->type) { case EXPR_TYPE_CAST: /* this is really brute force, we simply change the type... without * checking if this is right or not */ rtn = expr_eval(exp->un.cast.expr); switch (exp->un.cast.cast_to.type) { case type_expr_type_id: if (exp->un.cast.cast_to.u.type.id == dbg_itype_none) { dbg_printf("Can't cast to unknown type\n"); RaiseException(DEBUG_STATUS_BAD_TYPE, 0, 0, NULL); } rtn.type = exp->un.cast.cast_to.u.type; break; case type_expr_udt_class: case type_expr_udt_struct: case type_expr_udt_union: rtn.type = types_find_type(rtn.type.module, exp->un.cast.cast_to.u.name, SymTagUDT); if (rtn.type.id == dbg_itype_none) { dbg_printf("Can't cast to UDT %s\n", exp->un.cast.cast_to.u.name); RaiseException(DEBUG_STATUS_BAD_TYPE, 0, 0, NULL); } break; case type_expr_enumeration: rtn.type = types_find_type(rtn.type.module, exp->un.cast.cast_to.u.name, SymTagEnum); if (rtn.type.id == dbg_itype_none) { dbg_printf("Can't cast to enumeration %s\n", exp->un.cast.cast_to.u.name); RaiseException(DEBUG_STATUS_BAD_TYPE, 0, 0, NULL); } break; default: dbg_printf("Unsupported cast type %u\n", exp->un.cast.cast_to.type); RaiseException(DEBUG_STATUS_BAD_TYPE, 0, 0, NULL); } for (i = 0; i < exp->un.cast.cast_to.deref_count; i++) { rtn.type = types_find_pointer(&rtn.type); if (rtn.type.id == dbg_itype_none) { dbg_printf("Cannot find pointer type\n"); RaiseException(DEBUG_STATUS_BAD_TYPE, 0, 0, NULL); } } break; case EXPR_TYPE_STRING: rtn.cookie = DLV_HOST; rtn.type.id = dbg_itype_astring; rtn.type.module = 0; rtn.addr.Offset = (unsigned int)&exp->un.string.str; break; case EXPR_TYPE_U_CONST: rtn.cookie = DLV_HOST; rtn.type.id = dbg_itype_unsigned_int; rtn.type.module = 0; rtn.addr.Offset = (unsigned int)&exp->un.u_const.value; break; case EXPR_TYPE_S_CONST: rtn.cookie = DLV_HOST; rtn.type.id = dbg_itype_signed_int; rtn.type.module = 0; rtn.addr.Offset = (unsigned int)&exp->un.s_const.value; break; case EXPR_TYPE_SYMBOL: switch (symbol_get_lvalue(exp->un.symbol.name, -1, &rtn, FALSE)) { case sglv_found: break; case sglv_unknown: RaiseException(DEBUG_STATUS_NO_SYMBOL, 0, 0, NULL); /* should never be here */ case sglv_aborted: RaiseException(DEBUG_STATUS_ABORT, 0, 0, NULL); /* should never be here */ } break; case EXPR_TYPE_PSTRUCT: exp1 = expr_eval(exp->un.structure.exp1); if (exp1.type.id == dbg_itype_none || !types_deref(&exp1, &rtn) || rtn.type.id == dbg_itype_none) RaiseException(DEBUG_STATUS_BAD_TYPE, 0, 0, NULL); if (!types_udt_find_element(&rtn, exp->un.structure.element_name, &exp->un.structure.result)) { dbg_printf("%s\n", exp->un.structure.element_name); RaiseException(DEBUG_STATUS_NO_FIELD, 0, 0, NULL); } break; case EXPR_TYPE_STRUCT: exp1 = expr_eval(exp->un.structure.exp1); if (exp1.type.id == dbg_itype_none) RaiseException(DEBUG_STATUS_BAD_TYPE, 0, 0, NULL); rtn = exp1; if (!types_udt_find_element(&rtn, exp->un.structure.element_name, &exp->un.structure.result)) { dbg_printf("%s\n", exp->un.structure.element_name); RaiseException(DEBUG_STATUS_NO_FIELD, 0, 0, NULL); } break; case EXPR_TYPE_CALL: /* * First, evaluate all of the arguments. If any of them are not * evaluable, then bail. */ for (i = 0; i < exp->un.call.nargs; i++) { exp1 = expr_eval(exp->un.call.arg[i]); if (exp1.type.id == dbg_itype_none) RaiseException(DEBUG_STATUS_BAD_TYPE, 0, 0, NULL); cexp[i] = types_extract_as_integer(&exp1); } /* * Now look up the address of the function itself. */ switch (symbol_get_lvalue(exp->un.call.funcname, -1, &rtn, FALSE)) { case sglv_found: break; case sglv_unknown: RaiseException(DEBUG_STATUS_NO_SYMBOL, 0, 0, NULL); /* should never be here */ case sglv_aborted: RaiseException(DEBUG_STATUS_ABORT, 0, 0, NULL); /* should never be here */ } #if 0 /* FIXME: NEWDBG NIY */ /* Anyway, I wonder how this could work depending on the calling order of * the function (cdecl vs pascal for example) */ int (*fptr)(); fptr = (int (*)()) rtn.addr.off; switch (exp->un.call.nargs) { case 0: exp->un.call.result = (*fptr)(); break; case 1: exp->un.call.result = (*fptr)(cexp[0]); break; case 2: exp->un.call.result = (*fptr)(cexp[0], cexp[1]); break; case 3: exp->un.call.result = (*fptr)(cexp[0], cexp[1], cexp[2]); break; case 4: exp->un.call.result = (*fptr)(cexp[0], cexp[1], cexp[2], cexp[3]); break; case 5: exp->un.call.result = (*fptr)(cexp[0], cexp[1], cexp[2], cexp[3], cexp[4]); break; } #else dbg_printf("Function call no longer implemented\n"); /* would need to set up a call to this function, and then restore the current * context afterwards... */ exp->un.call.result = 0; #endif rtn.cookie = DLV_HOST; /* get return type from function signature tupe */ types_get_info(&rtn.type, TI_GET_TYPE, &rtn.type.id); rtn.addr.Offset = (unsigned int)&exp->un.call.result; break; case EXPR_TYPE_INTVAR: rtn.cookie = DLV_HOST; if (!(div = dbg_get_internal_var(exp->un.intvar.name))) RaiseException(DEBUG_STATUS_NO_SYMBOL, 0, 0, NULL); rtn.type.id = div->typeid; rtn.type.module = 0; rtn.addr.Offset = (unsigned int)div->pval; break; case EXPR_TYPE_BINOP: rtn.cookie = DLV_HOST; exp1 = expr_eval(exp->un.binop.exp1); exp2 = expr_eval(exp->un.binop.exp2); if (exp1.type.id == dbg_itype_none || exp2.type.id == dbg_itype_none) RaiseException(DEBUG_STATUS_BAD_TYPE, 0, 0, NULL); rtn.type.id = dbg_itype_signed_int; rtn.type.module = 0; rtn.addr.Offset = (unsigned int)&exp->un.binop.result; type1 = exp1.type; type2 = exp2.type; switch (exp->un.binop.binop_type) { case EXP_OP_ADD: if (!types_get_info(&exp1.type, TI_GET_SYMTAG, &tag) || tag != SymTagPointerType || !types_get_info(&exp1.type, TI_GET_TYPE, &type1.id)) type1.id = dbg_itype_none; if (!types_get_info(&exp2.type, TI_GET_SYMTAG, &tag) || tag != SymTagPointerType || !types_get_info(&exp2.type, TI_GET_TYPE, &type2.id)) type2.id = dbg_itype_none; scale1 = 1; scale2 = 1; if (type1.id != dbg_itype_none && type2.id != dbg_itype_none) RaiseException(DEBUG_STATUS_BAD_TYPE, 0, 0, NULL); if (type1.id != dbg_itype_none) { types_get_info(&type1, TI_GET_LENGTH, &scale2); rtn.type = exp1.type; } else if (type2.id != dbg_itype_none) { types_get_info(&type2, TI_GET_LENGTH, &scale1); rtn.type = exp2.type; } exp->un.binop.result = types_extract_as_integer(&exp1) * (DWORD)scale1 + (DWORD)scale2 * types_extract_as_integer(&exp2); break; case EXP_OP_SUB: if (!types_get_info(&exp1.type, TI_GET_SYMTAG, &tag) || tag != SymTagPointerType || !types_get_info(&exp1.type, TI_GET_TYPE, &type1.id)) type1.id = dbg_itype_none; if (!types_get_info(&exp2.type, TI_GET_SYMTAG, &tag) || tag != SymTagPointerType || !types_get_info(&exp2.type, TI_GET_TYPE, &type2.id)) type2.id = dbg_itype_none; scale1 = 1; scale2 = 1; scale3 = 1; if (type1.id != dbg_itype_none && type2.id != dbg_itype_none) { WINE_FIXME("This may fail (if module base address are wrongly calculated)\n"); if (memcmp(&type1, &type2, sizeof(struct dbg_type))) RaiseException(DEBUG_STATUS_BAD_TYPE, 0, 0, NULL); types_get_info(&type1, TI_GET_LENGTH, &scale3); } else if (type1.id != dbg_itype_none) { types_get_info(&type1, TI_GET_LENGTH, &scale2); rtn.type = exp1.type; } else if (type2.id != dbg_itype_none) { types_get_info(&type2, TI_GET_LENGTH, &scale1); rtn.type = exp2.type; } exp->un.binop.result = (types_extract_as_integer(&exp1) * (DWORD)scale1 - types_extract_as_integer(&exp2) * (DWORD)scale2) / (DWORD)scale3; break; case EXP_OP_SEG: rtn.type.id = dbg_itype_segptr; rtn.type.module = 0; be_cpu->build_addr(dbg_curr_thread->handle, &dbg_context, &rtn.addr, types_extract_as_integer(&exp1), types_extract_as_integer(&exp2)); break; case EXP_OP_LOR: exp->un.binop.result = (types_extract_as_integer(&exp1) || types_extract_as_integer(&exp2)); break; case EXP_OP_LAND: exp->un.binop.result = (types_extract_as_integer(&exp1) && types_extract_as_integer(&exp2)); break; case EXP_OP_OR: exp->un.binop.result = (types_extract_as_integer(&exp1) | types_extract_as_integer(&exp2)); break; case EXP_OP_AND: exp->un.binop.result = (types_extract_as_integer(&exp1) & types_extract_as_integer(&exp2)); break; case EXP_OP_XOR: exp->un.binop.result = (types_extract_as_integer(&exp1) ^ types_extract_as_integer(&exp2)); break; case EXP_OP_EQ: exp->un.binop.result = (types_extract_as_integer(&exp1) == types_extract_as_integer(&exp2)); break; case EXP_OP_GT: exp->un.binop.result = (types_extract_as_integer(&exp1) > types_extract_as_integer(&exp2)); break; case EXP_OP_LT: exp->un.binop.result = (types_extract_as_integer(&exp1) < types_extract_as_integer(&exp2)); break; case EXP_OP_GE: exp->un.binop.result = (types_extract_as_integer(&exp1) >= types_extract_as_integer(&exp2)); break; case EXP_OP_LE: exp->un.binop.result = (types_extract_as_integer(&exp1) <= types_extract_as_integer(&exp2)); break; case EXP_OP_NE: exp->un.binop.result = (types_extract_as_integer(&exp1) != types_extract_as_integer(&exp2)); break; case EXP_OP_SHL: exp->un.binop.result = ((unsigned long)types_extract_as_integer(&exp1) << types_extract_as_integer(&exp2)); break; case EXP_OP_SHR: exp->un.binop.result = ((unsigned long)types_extract_as_integer(&exp1) >> types_extract_as_integer(&exp2)); break; case EXP_OP_MUL: exp->un.binop.result = (types_extract_as_integer(&exp1) * types_extract_as_integer(&exp2)); break; case EXP_OP_DIV: if (types_extract_as_integer(&exp2) == 0) RaiseException(DEBUG_STATUS_DIV_BY_ZERO, 0, 0, NULL); exp->un.binop.result = (types_extract_as_integer(&exp1) / types_extract_as_integer(&exp2)); break; case EXP_OP_REM: if (types_extract_as_integer(&exp2) == 0) RaiseException(DEBUG_STATUS_DIV_BY_ZERO, 0, 0, NULL); exp->un.binop.result = (types_extract_as_integer(&exp1) % types_extract_as_integer(&exp2)); break; case EXP_OP_ARR: if (!types_array_index(&exp1, types_extract_as_integer(&exp2), &rtn)) RaiseException(DEBUG_STATUS_CANT_DEREF, 0, 0, NULL); break; default: RaiseException(DEBUG_STATUS_INTERNAL_ERROR, 0, 0, NULL); } break; case EXPR_TYPE_UNOP: rtn.cookie = DLV_HOST; exp1 = expr_eval(exp->un.unop.exp1); if (exp1.type.id == dbg_itype_none) RaiseException(DEBUG_STATUS_BAD_TYPE, 0, 0, NULL); rtn.addr.Offset = (unsigned int)&exp->un.unop.result; rtn.type.id = dbg_itype_signed_int; rtn.type.module = 0; switch (exp->un.unop.unop_type) { case EXP_OP_NEG: exp->un.unop.result = -types_extract_as_integer(&exp1); break; case EXP_OP_NOT: exp->un.unop.result = !types_extract_as_integer(&exp1); break; case EXP_OP_LNOT: exp->un.unop.result = ~types_extract_as_integer(&exp1); break; case EXP_OP_DEREF: if (!types_deref(&exp1, &rtn)) RaiseException(DEBUG_STATUS_BAD_TYPE, 0, 0, NULL); break; case EXP_OP_FORCE_DEREF: rtn = exp1; if (exp1.cookie == DLV_TARGET) dbg_read_memory(memory_to_linear_addr(&exp1.addr), &rtn.addr.Offset, sizeof(rtn.addr.Offset)); break; case EXP_OP_ADDR: /* only do it on linear addresses */ if (exp1.addr.Mode != AddrModeFlat) RaiseException(DEBUG_STATUS_CANT_DEREF, 0, 0, NULL); exp->un.unop.result = (unsigned int)memory_to_linear_addr(&exp1.addr); rtn.type = types_find_pointer(&exp1.type); if (rtn.type.id == dbg_itype_none) RaiseException(DEBUG_STATUS_CANT_DEREF, 0, 0, NULL); break; default: RaiseException(DEBUG_STATUS_INTERNAL_ERROR, 0, 0, NULL); } break; default: WINE_FIXME("Unexpected expression (%d).\n", exp->type); RaiseException(DEBUG_STATUS_INTERNAL_ERROR, 0, 0, NULL); break; } return rtn; } int expr_print(const struct expr* exp) { int i; struct dbg_type type; switch (exp->type) { case EXPR_TYPE_CAST: WINE_FIXME("No longer supported (missing module base)\n"); dbg_printf("(("); switch (exp->un.cast.cast_to.type) { case type_expr_type_id: type.module = 0; type.id = exp->un.cast.cast_to.type; types_print_type(&type, FALSE); break; case type_expr_udt_class: dbg_printf("class %s", exp->un.cast.cast_to.u.name); break; case type_expr_udt_struct: dbg_printf("struct %s", exp->un.cast.cast_to.u.name); break; case type_expr_udt_union: dbg_printf("union %s", exp->un.cast.cast_to.u.name); break; case type_expr_enumeration: dbg_printf("enum %s", exp->un.cast.cast_to.u.name); break; } for (i = 0; i < exp->un.cast.cast_to.deref_count; i++) dbg_printf("*"); dbg_printf(")"); expr_print(exp->un.cast.expr); dbg_printf(")"); break; case EXPR_TYPE_INTVAR: dbg_printf("$%s", exp->un.intvar.name); break; case EXPR_TYPE_U_CONST: dbg_printf("%u", exp->un.u_const.value); break; case EXPR_TYPE_S_CONST: dbg_printf("%d", exp->un.s_const.value); break; case EXPR_TYPE_STRING: dbg_printf("\"%s\"", exp->un.string.str); break; case EXPR_TYPE_SYMBOL: dbg_printf("%s" , exp->un.symbol.name); break; case EXPR_TYPE_PSTRUCT: expr_print(exp->un.structure.exp1); dbg_printf("->%s", exp->un.structure.element_name); break; case EXPR_TYPE_STRUCT: expr_print(exp->un.structure.exp1); dbg_printf(".%s", exp->un.structure.element_name); break; case EXPR_TYPE_CALL: dbg_printf("%s(",exp->un.call.funcname); for (i = 0; i < exp->un.call.nargs; i++) { expr_print(exp->un.call.arg[i]); if (i != exp->un.call.nargs - 1) dbg_printf(", "); } dbg_printf(")"); break; case EXPR_TYPE_BINOP: dbg_printf("("); expr_print(exp->un.binop.exp1); switch (exp->un.binop.binop_type) { case EXP_OP_ADD: dbg_printf(" + "); break; case EXP_OP_SUB: dbg_printf(" - "); break; case EXP_OP_SEG: dbg_printf(":"); break; case EXP_OP_LOR: dbg_printf(" || "); break; case EXP_OP_LAND: dbg_printf(" && "); break; case EXP_OP_OR: dbg_printf(" | "); break; case EXP_OP_AND: dbg_printf(" & "); break; case EXP_OP_XOR: dbg_printf(" ^ "); break; case EXP_OP_EQ: dbg_printf(" == "); break; case EXP_OP_GT: dbg_printf(" > "); break; case EXP_OP_LT: dbg_printf(" < "); break; case EXP_OP_GE: dbg_printf(" >= "); break; case EXP_OP_LE: dbg_printf(" <= "); break; case EXP_OP_NE: dbg_printf(" != "); break; case EXP_OP_SHL: dbg_printf(" << "); break; case EXP_OP_SHR: dbg_printf(" >> "); break; case EXP_OP_MUL: dbg_printf(" * "); break; case EXP_OP_DIV: dbg_printf(" / "); break; case EXP_OP_REM: dbg_printf(" %% "); break; case EXP_OP_ARR: dbg_printf("["); break; default: break; } expr_print(exp->un.binop.exp2); if (exp->un.binop.binop_type == EXP_OP_ARR) dbg_printf("]"); dbg_printf(")"); break; case EXPR_TYPE_UNOP: switch (exp->un.unop.unop_type) { case EXP_OP_NEG: dbg_printf("-"); break; case EXP_OP_NOT: dbg_printf("!"); break; case EXP_OP_LNOT: dbg_printf("~"); break; case EXP_OP_DEREF: dbg_printf("*"); break; case EXP_OP_ADDR: dbg_printf("&"); break; } expr_print(exp->un.unop.exp1); break; default: WINE_FIXME("Unexpected expression (%u).\n", exp->type); RaiseException(DEBUG_STATUS_INTERNAL_ERROR, 0, 0, NULL); break; } return TRUE; } struct expr* expr_clone(const struct expr* exp, BOOL *local_binding) { int i; struct expr* rtn; rtn = HeapAlloc(GetProcessHeap(), 0, sizeof(struct expr)); /* * First copy the contents of the expression itself. */ *rtn = *exp; switch (exp->type) { case EXPR_TYPE_CAST: rtn->un.cast.expr = expr_clone(exp->un.cast.expr, local_binding); break; case EXPR_TYPE_INTVAR: rtn->un.intvar.name = strcpy(HeapAlloc(GetProcessHeap(), 0, strlen(exp->un.intvar.name) + 1), exp->un.intvar.name); break; case EXPR_TYPE_U_CONST: case EXPR_TYPE_S_CONST: break; case EXPR_TYPE_STRING: rtn->un.string.str = strcpy(HeapAlloc(GetProcessHeap(), 0, strlen(exp->un.string.str) + 1), exp->un.string.str); break; case EXPR_TYPE_SYMBOL: rtn->un.symbol.name = strcpy(HeapAlloc(GetProcessHeap(), 0, strlen(exp->un.symbol.name) + 1), exp->un.symbol.name); if (local_binding && symbol_is_local(exp->un.symbol.name)) *local_binding = TRUE; break; case EXPR_TYPE_PSTRUCT: case EXPR_TYPE_STRUCT: rtn->un.structure.exp1 = expr_clone(exp->un.structure.exp1, local_binding); rtn->un.structure.element_name = strcpy(HeapAlloc(GetProcessHeap(), 0, strlen(exp->un.structure.element_name) + 1), exp->un.structure.element_name); break; case EXPR_TYPE_CALL: for (i = 0; i < exp->un.call.nargs; i++) { rtn->un.call.arg[i] = expr_clone(exp->un.call.arg[i], local_binding); } rtn->un.call.funcname = strcpy(HeapAlloc(GetProcessHeap(), 0, strlen(exp->un.call.funcname) + 1), exp->un.call.funcname); break; case EXPR_TYPE_BINOP: rtn->un.binop.exp1 = expr_clone(exp->un.binop.exp1, local_binding); rtn->un.binop.exp2 = expr_clone(exp->un.binop.exp2, local_binding); break; case EXPR_TYPE_UNOP: rtn->un.unop.exp1 = expr_clone(exp->un.unop.exp1, local_binding); break; default: WINE_FIXME("Unexpected expression (%u).\n", exp->type); RaiseException(DEBUG_STATUS_INTERNAL_ERROR, 0, 0, NULL); break; } return rtn; } /* * Recursively go through an expression tree and free all memory associated * with it. */ int expr_free(struct expr* exp) { int i; switch (exp->type) { case EXPR_TYPE_CAST: expr_free(exp->un.cast.expr); break; case EXPR_TYPE_INTVAR: HeapFree(GetProcessHeap(), 0, (char*)exp->un.intvar.name); break; case EXPR_TYPE_U_CONST: case EXPR_TYPE_S_CONST: break; case EXPR_TYPE_STRING: HeapFree(GetProcessHeap(), 0, (char*)exp->un.string.str); break; case EXPR_TYPE_SYMBOL: HeapFree(GetProcessHeap(), 0, (char*)exp->un.symbol.name); break; case EXPR_TYPE_PSTRUCT: case EXPR_TYPE_STRUCT: expr_free(exp->un.structure.exp1); HeapFree(GetProcessHeap(), 0, (char*)exp->un.structure.element_name); break; case EXPR_TYPE_CALL: for (i = 0; i < exp->un.call.nargs; i++) { expr_free(exp->un.call.arg[i]); } HeapFree(GetProcessHeap(), 0, (char*)exp->un.call.funcname); break; case EXPR_TYPE_BINOP: expr_free(exp->un.binop.exp1); expr_free(exp->un.binop.exp2); break; case EXPR_TYPE_UNOP: expr_free(exp->un.unop.exp1); break; default: WINE_FIXME("Unexpected expression (%u).\n", exp->type); RaiseException(DEBUG_STATUS_INTERNAL_ERROR, 0, 0, NULL); break; } HeapFree(GetProcessHeap(), 0, exp); return TRUE; }