/* * Demangle VC++ symbols into C function prototypes * * Copyright 2000 Jon Griffiths * 2004 Eric Pouech * * 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 "wine/port.h" #include #include #include #include "msvcrt.h" #include "wine/debug.h" WINE_DEFAULT_DEBUG_CHANNEL(msvcrt); /* TODO: * - document a bit (grammar + functions) * - back-port this new code into tools/winedump/msmangle.c */ #define UNDNAME_COMPLETE (0x0000) #define UNDNAME_NO_LEADING_UNDERSCORES (0x0001) /* Don't show __ in calling convention */ #define UNDNAME_NO_MS_KEYWORDS (0x0002) /* Don't show calling convention at all */ #define UNDNAME_NO_FUNCTION_RETURNS (0x0004) /* Don't show function/method return value */ #define UNDNAME_NO_ALLOCATION_MODEL (0x0008) #define UNDNAME_NO_ALLOCATION_LANGUAGE (0x0010) #define UNDNAME_NO_MS_THISTYPE (0x0020) #define UNDNAME_NO_CV_THISTYPE (0x0040) #define UNDNAME_NO_THISTYPE (0x0060) #define UNDNAME_NO_ACCESS_SPECIFIERS (0x0080) /* Don't show access specifier (public/protected/private) */ #define UNDNAME_NO_THROW_SIGNATURES (0x0100) #define UNDNAME_NO_MEMBER_TYPE (0x0200) /* Don't show static/virtual specifier */ #define UNDNAME_NO_RETURN_UDT_MODEL (0x0400) #define UNDNAME_32_BIT_DECODE (0x0800) #define UNDNAME_NAME_ONLY (0x1000) /* Only report the variable/method name */ #define UNDNAME_NO_ARGUMENTS (0x2000) /* Don't show method arguments */ #define UNDNAME_NO_SPECIAL_SYMS (0x4000) #define UNDNAME_NO_COMPLEX_TYPE (0x8000) /* How data types modifiers are stored: * M (in the following definitions) is defined for * 'A', 'B', 'C' and 'D' as follows * {}: "" * {}: "const " * {}: "volatile " * {}: "const volatile " * * in arguments: * Px {}x* * Qx {}x* const * Ax {}x& * in data fields: * same as for arguments and also the following * ?x {}x * */ struct array { unsigned start; /* first valid reference in array */ unsigned num; /* total number of used elts */ unsigned max; unsigned alloc; char** elts; }; /* Structure holding a parsed symbol */ struct parsed_symbol { unsigned flags; /* the UNDNAME_ flags used for demangling */ malloc_func_t mem_alloc_ptr; /* internal allocator */ free_func_t mem_free_ptr; /* internal deallocator */ const char* current; /* pointer in input (mangled) string */ char* result; /* demangled string */ struct array names; /* array of names for back reference */ struct array stack; /* stack of parsed strings */ void* alloc_list; /* linked list of allocated blocks */ unsigned avail_in_first; /* number of available bytes in head block */ }; /* Type for parsing mangled types */ struct datatype_t { const char* left; const char* right; }; /****************************************************************** * und_alloc * * Internal allocator. Uses a simple linked list of large blocks * where we use a poor-man allocator. It's fast, and since all * allocation is pool, memory management is easy (esp. freeing). */ static void* und_alloc(struct parsed_symbol* sym, unsigned int len) { void* ptr; #define BLOCK_SIZE 1024 #define AVAIL_SIZE (1024 - sizeof(void*)) if (len > AVAIL_SIZE) { /* allocate a specific block */ ptr = sym->mem_alloc_ptr(sizeof(void*) + len); if (!ptr) return NULL; *(void**)ptr = sym->alloc_list; sym->alloc_list = ptr; sym->avail_in_first = 0; ptr = (char*)sym->alloc_list + sizeof(void*); } else { if (len > sym->avail_in_first) { /* add a new block */ ptr = sym->mem_alloc_ptr(BLOCK_SIZE); if (!ptr) return NULL; *(void**)ptr = sym->alloc_list; sym->alloc_list = ptr; sym->avail_in_first = AVAIL_SIZE; } /* grab memory from head block */ ptr = (char*)sym->alloc_list + BLOCK_SIZE - sym->avail_in_first; sym->avail_in_first -= len; } return ptr; #undef BLOCK_SIZE #undef AVAIL_SIZE } /****************************************************************** * und_free * Frees all the blocks in the list of large blocks allocated by * und_alloc. */ static void und_free_all(struct parsed_symbol* sym) { void* next; while (sym->alloc_list) { next = *(void**)sym->alloc_list; if(sym->mem_free_ptr) sym->mem_free_ptr(sym->alloc_list); sym->alloc_list = next; } sym->avail_in_first = 0; } /****************************************************************** * str_array_init * Initialises an array of strings */ static void str_array_init(struct array* a) { a->start = a->num = a->max = a->alloc = 0; a->elts = NULL; } /****************************************************************** * str_array_push * Adding a new string to an array */ static BOOL str_array_push(struct parsed_symbol* sym, const char* ptr, int len, struct array* a) { char** new; assert(ptr); assert(a); if (!a->alloc) { new = und_alloc(sym, (a->alloc = 32) * sizeof(a->elts[0])); if (!new) return FALSE; a->elts = new; } else if (a->max >= a->alloc) { new = und_alloc(sym, (a->alloc * 2) * sizeof(a->elts[0])); if (!new) return FALSE; memcpy(new, a->elts, a->alloc * sizeof(a->elts[0])); a->alloc *= 2; a->elts = new; } if (len == -1) len = strlen(ptr); a->elts[a->num] = und_alloc(sym, len + 1); assert(a->elts[a->num]); memcpy(a->elts[a->num], ptr, len); a->elts[a->num][len] = '\0'; if (++a->num >= a->max) a->max = a->num; { int i; char c; for (i = a->max - 1; i >= 0; i--) { c = '>'; if (i < a->start) c = '-'; else if (i >= a->num) c = '}'; TRACE("%p\t%d%c %s\n", a, i, c, a->elts[i]); } } return TRUE; } /****************************************************************** * str_array_get_ref * Extracts a reference from an existing array (doing proper type * checking) */ static char* str_array_get_ref(struct array* cref, unsigned idx) { assert(cref); if (cref->start + idx >= cref->max) { WARN("Out of bounds: %p %d + %d >= %d\n", cref, cref->start, idx, cref->max); return NULL; } TRACE("Returning %p[%d] => %s\n", cref, idx, cref->elts[cref->start + idx]); return cref->elts[cref->start + idx]; } /****************************************************************** * str_printf * Helper for printf type of command (only %s and %c are implemented) * while dynamically allocating the buffer */ static char* str_printf(struct parsed_symbol* sym, const char* format, ...) { va_list args; unsigned int len = 1, i, sz; char* tmp; char* p; char* t; va_start(args, format); for (i = 0; format[i]; i++) { if (format[i] == '%') { switch (format[++i]) { case 's': t = va_arg(args, char*); if (t) len += strlen(t); break; case 'c': (void)va_arg(args, int); len++; break; default: i--; /* fall thru */ case '%': len++; break; } } else len++; } va_end(args); if (!(tmp = und_alloc(sym, len))) return NULL; va_start(args, format); for (p = tmp, i = 0; format[i]; i++) { if (format[i] == '%') { switch (format[++i]) { case 's': t = va_arg(args, char*); if (t) { sz = strlen(t); memcpy(p, t, sz); p += sz; } break; case 'c': *p++ = (char)va_arg(args, int); break; default: i--; /* fall thru */ case '%': *p++ = '%'; break; } } else *p++ = format[i]; } va_end(args); *p = '\0'; return tmp; } /* forward declaration */ static BOOL demangle_datatype(struct parsed_symbol* sym, struct datatype_t* ct, struct array* pmt, BOOL in_args); static const char* get_number(struct parsed_symbol* sym) { char* ptr; BOOL sgn = FALSE; if (*sym->current == '?') { sgn = TRUE; sym->current++; } if (*sym->current >= '0' && *sym->current <= '8') { ptr = und_alloc(sym, 3); if (sgn) ptr[0] = '-'; ptr[sgn ? 1 : 0] = *sym->current + 1; ptr[sgn ? 2 : 1] = '\0'; sym->current++; } else if (*sym->current == '9') { ptr = und_alloc(sym, 4); if (sgn) ptr[0] = '-'; ptr[sgn ? 1 : 0] = '1'; ptr[sgn ? 2 : 1] = '0'; ptr[sgn ? 3 : 2] = '\0'; sym->current++; } else if (*sym->current >= 'A' && *sym->current <= 'P') { int ret = 0; while (*sym->current >= 'A' && *sym->current <= 'P') { ret *= 16; ret += *sym->current++ - 'A'; } if (*sym->current != '@') return NULL; ptr = und_alloc(sym, 17); sprintf(ptr, "%s%d", sgn ? "-" : "", ret); sym->current++; } else return NULL; return ptr; } /****************************************************************** * get_args * Parses a list of function/method arguments, creates a string corresponding * to the arguments' list. */ static char* get_args(struct parsed_symbol* sym, struct array* pmt_ref, BOOL z_term, char open_char, char close_char) { struct datatype_t ct; struct array arg_collect; char* args_str = NULL; unsigned int i; str_array_init(&arg_collect); /* Now come the function arguments */ while (*sym->current) { /* Decode each data type and append it to the argument list */ if (*sym->current == '@') { sym->current++; break; } if (!demangle_datatype(sym, &ct, pmt_ref, TRUE)) return NULL; /* 'void' terminates an argument list in a function */ if (z_term && !strcmp(ct.left, "void")) break; if (!str_array_push(sym, str_printf(sym, "%s%s", ct.left, ct.right), -1, &arg_collect)) return NULL; if (!strcmp(ct.left, "...")) break; } /* Functions are always terminated by 'Z'. If we made it this far and * don't find it, we have incorrectly identified a data type. */ if (z_term && *sym->current++ != 'Z') return NULL; if (arg_collect.num == 0 || (arg_collect.num == 1 && !strcmp(arg_collect.elts[0], "void"))) return str_printf(sym, "%cvoid%c", open_char, close_char); for (i = 1; i < arg_collect.num; i++) { args_str = str_printf(sym, "%s,%s", args_str, arg_collect.elts[i]); } if (close_char == '>' && args_str && args_str[strlen(args_str) - 1] == '>') args_str = str_printf(sym, "%c%s%s %c", open_char, arg_collect.elts[0], args_str, close_char); else args_str = str_printf(sym, "%c%s%s%c", open_char, arg_collect.elts[0], args_str, close_char); return args_str; } /****************************************************************** * get_modifier * Parses the type modifier. Always returns a static string */ static BOOL get_modifier(char ch, const char** ret) { switch (ch) { case 'A': *ret = NULL; break; case 'B': *ret = "const"; break; case 'C': *ret = "volatile"; break; case 'D': *ret = "const volatile"; break; default: return FALSE; } return TRUE; } static BOOL get_modified_type(struct datatype_t *ct, struct parsed_symbol* sym, struct array *pmt_ref, char modif, BOOL in_args) { const char* modifier; const char* str_modif; switch (modif) { case 'A': str_modif = " &"; break; case 'B': str_modif = " & volatile"; break; case 'P': str_modif = " *"; break; case 'Q': str_modif = " * const"; break; case 'R': str_modif = " * volatile"; break; case 'S': str_modif = " * const volatile"; break; case '?': str_modif = ""; break; default: return FALSE; } if (get_modifier(*sym->current++, &modifier)) { unsigned mark = sym->stack.num; struct datatype_t sub_ct; /* multidimensional arrays */ if (*sym->current == 'Y') { const char* n1; int num; sym->current++; if (!(n1 = get_number(sym))) return FALSE; num = atoi(n1); if (str_modif[0] == ' ' && !modifier) str_modif++; if (modifier) { str_modif = str_printf(sym, " (%s%s)", modifier, str_modif); modifier = NULL; } else str_modif = str_printf(sym, " (%s)", str_modif); while (num--) str_modif = str_printf(sym, "%s[%s]", str_modif, get_number(sym)); } /* Recurse to get the referred-to type */ if (!demangle_datatype(sym, &sub_ct, pmt_ref, FALSE)) return FALSE; if (modifier) ct->left = str_printf(sym, "%s %s%s", sub_ct.left, modifier, str_modif ); else { /* don't insert a space between duplicate '*' */ if (!in_args && str_modif[0] && str_modif[1] == '*' && sub_ct.left[strlen(sub_ct.left)-1] == '*') str_modif++; ct->left = str_printf(sym, "%s%s", sub_ct.left, str_modif ); } ct->right = sub_ct.right; sym->stack.num = mark; } return TRUE; } /****************************************************************** * get_literal_string * Gets the literal name from the current position in the mangled * symbol to the first '@' character. It pushes the parsed name to * the symbol names stack and returns a pointer to it or NULL in * case of an error. */ static char* get_literal_string(struct parsed_symbol* sym) { const char *ptr = sym->current; do { if (!((*sym->current >= 'A' && *sym->current <= 'Z') || (*sym->current >= 'a' && *sym->current <= 'z') || (*sym->current >= '0' && *sym->current <= '9') || *sym->current == '_' || *sym->current == '$')) { TRACE("Failed at '%c' in %s\n", *sym->current, ptr); return NULL; } } while (*++sym->current != '@'); sym->current++; if (!str_array_push(sym, ptr, sym->current - 1 - ptr, &sym->names)) return NULL; return str_array_get_ref(&sym->names, sym->names.num - sym->names.start - 1); } /****************************************************************** * get_template_name * Parses a name with a template argument list and returns it as * a string. * In a template argument list the back reference to the names * table is separately created. '0' points to the class component * name with the template arguments. We use the same stack array * to hold the names but save/restore the stack state before/after * parsing the template argument list. */ static char* get_template_name(struct parsed_symbol* sym) { char *name, *args; unsigned num_mark = sym->names.num; unsigned start_mark = sym->names.start; unsigned stack_mark = sym->stack.num; struct array array_pmt; sym->names.start = sym->names.num; if (!(name = get_literal_string(sym))) return FALSE; str_array_init(&array_pmt); args = get_args(sym, &array_pmt, FALSE, '<', '>'); if (args != NULL) name = str_printf(sym, "%s%s", name, args); sym->names.num = num_mark; sym->names.start = start_mark; sym->stack.num = stack_mark; return name; } /****************************************************************** * get_class * Parses class as a list of parent-classes, terminated by '@' and stores the * result in 'a' array. Each parent-classes, as well as the inner element * (either field/method name or class name), are represented in the mangled * name by a literal name ([a-zA-Z0-9_]+ terminated by '@') or a back reference * ([0-9]) or a name with template arguments ('?$' literal name followed by the * template argument list). The class name components appear in the reverse * order in the mangled name, e.g aaa@bbb@ccc@@ will be demangled to * ccc::bbb::aaa * For each of these class name components a string will be allocated in the * array. */ static BOOL get_class(struct parsed_symbol* sym) { const char* name = NULL; while (*sym->current != '@') { switch (*sym->current) { case '\0': return FALSE; case '0': case '1': case '2': case '3': case '4': case '5': case '6': case '7': case '8': case '9': name = str_array_get_ref(&sym->names, *sym->current++ - '0'); break; case '?': if (*++sym->current == '$') { sym->current++; if ((name = get_template_name(sym)) && !str_array_push(sym, name, -1, &sym->names)) return FALSE; } break; default: name = get_literal_string(sym); break; } if (!name || !str_array_push(sym, name, -1, &sym->stack)) return FALSE; } sym->current++; return TRUE; } /****************************************************************** * get_class_string * From an array collected by get_class in sym->stack, constructs the * corresponding (allocated) string */ static char* get_class_string(struct parsed_symbol* sym, int start) { int i; unsigned int len, sz; char* ret; struct array *a = &sym->stack; for (len = 0, i = start; i < a->num; i++) { assert(a->elts[i]); len += 2 + strlen(a->elts[i]); } if (!(ret = und_alloc(sym, len - 1))) return NULL; for (len = 0, i = a->num - 1; i >= start; i--) { sz = strlen(a->elts[i]); memcpy(ret + len, a->elts[i], sz); len += sz; if (i > start) { ret[len++] = ':'; ret[len++] = ':'; } } ret[len] = '\0'; return ret; } /****************************************************************** * get_class_name * Wrapper around get_class and get_class_string. */ static char* get_class_name(struct parsed_symbol* sym) { unsigned mark = sym->stack.num; char* s = NULL; if (get_class(sym)) s = get_class_string(sym, mark); sym->stack.num = mark; return s; } /****************************************************************** * get_calling_convention * Returns a static string corresponding to the calling convention described * by char 'ch'. Sets export to TRUE iff the calling convention is exported. */ static BOOL get_calling_convention(char ch, const char** call_conv, const char** exported, unsigned flags) { *call_conv = *exported = NULL; if (!(flags & (UNDNAME_NO_MS_KEYWORDS | UNDNAME_NO_ALLOCATION_LANGUAGE))) { if (flags & UNDNAME_NO_LEADING_UNDERSCORES) { if (((ch - 'A') % 2) == 1) *exported = "dll_export "; switch (ch) { case 'A': case 'B': *call_conv = "cdecl"; break; case 'C': case 'D': *call_conv = "pascal"; break; case 'E': case 'F': *call_conv = "thiscall"; break; case 'G': case 'H': *call_conv = "stdcall"; break; case 'I': case 'J': *call_conv = "fastcall"; break; case 'K': case 'L': break; case 'M': *call_conv = "clrcall"; break; default: ERR("Unknown calling convention %c\n", ch); return FALSE; } } else { if (((ch - 'A') % 2) == 1) *exported = "__dll_export "; switch (ch) { case 'A': case 'B': *call_conv = "__cdecl"; break; case 'C': case 'D': *call_conv = "__pascal"; break; case 'E': case 'F': *call_conv = "__thiscall"; break; case 'G': case 'H': *call_conv = "__stdcall"; break; case 'I': case 'J': *call_conv = "__fastcall"; break; case 'K': case 'L': break; case 'M': *call_conv = "__clrcall"; break; default: ERR("Unknown calling convention %c\n", ch); return FALSE; } } } return TRUE; } /******************************************************************* * get_simple_type * Return a string containing an allocated string for a simple data type */ static const char* get_simple_type(char c) { const char* type_string; switch (c) { case 'C': type_string = "signed char"; break; case 'D': type_string = "char"; break; case 'E': type_string = "unsigned char"; break; case 'F': type_string = "short"; break; case 'G': type_string = "unsigned short"; break; case 'H': type_string = "int"; break; case 'I': type_string = "unsigned int"; break; case 'J': type_string = "long"; break; case 'K': type_string = "unsigned long"; break; case 'M': type_string = "float"; break; case 'N': type_string = "double"; break; case 'O': type_string = "long double"; break; case 'X': type_string = "void"; break; case 'Z': type_string = "..."; break; default: type_string = NULL; break; } return type_string; } /******************************************************************* * get_extended_type * Return a string containing an allocated string for a simple data type */ static const char* get_extended_type(char c) { const char* type_string; switch (c) { case 'D': type_string = "__int8"; break; case 'E': type_string = "unsigned __int8"; break; case 'F': type_string = "__int16"; break; case 'G': type_string = "unsigned __int16"; break; case 'H': type_string = "__int32"; break; case 'I': type_string = "unsigned __int32"; break; case 'J': type_string = "__int64"; break; case 'K': type_string = "unsigned __int64"; break; case 'L': type_string = "__int128"; break; case 'M': type_string = "unsigned __int128"; break; case 'N': type_string = "bool"; break; case 'W': type_string = "wchar_t"; break; default: type_string = NULL; break; } return type_string; } /******************************************************************* * demangle_datatype * * Attempt to demangle a C++ data type, which may be datatype. * a datatype type is made up of a number of simple types. e.g: * char** = (pointer to (pointer to (char))) */ static BOOL demangle_datatype(struct parsed_symbol* sym, struct datatype_t* ct, struct array* pmt_ref, BOOL in_args) { char dt; BOOL add_pmt = TRUE; assert(ct); ct->left = ct->right = NULL; switch (dt = *sym->current++) { case '_': /* MS type: __int8,__int16 etc */ ct->left = get_extended_type(*sym->current++); break; case 'C': case 'D': case 'E': case 'F': case 'G': case 'H': case 'I': case 'J': case 'K': case 'M': case 'N': case 'O': case 'X': case 'Z': /* Simple data types */ ct->left = get_simple_type(dt); add_pmt = FALSE; break; case 'T': /* union */ case 'U': /* struct */ case 'V': /* class */ case 'Y': /* cointerface */ /* Class/struct/union/cointerface */ { const char* struct_name = NULL; const char* type_name = NULL; if (!(struct_name = get_class_name(sym))) goto done; if (!(sym->flags & UNDNAME_NO_COMPLEX_TYPE)) { switch (dt) { case 'T': type_name = "union "; break; case 'U': type_name = "struct "; break; case 'V': type_name = "class "; break; case 'Y': type_name = "cointerface "; break; } } ct->left = str_printf(sym, "%s%s", type_name, struct_name); } break; case '?': /* not all the time is seems */ if (in_args) { const char* ptr; if (!(ptr = get_number(sym))) goto done; ct->left = str_printf(sym, "`template-parameter-%s'", ptr); } else { if (!get_modified_type(ct, sym, pmt_ref, '?', in_args)) goto done; } break; case 'A': /* reference */ case 'B': /* volatile reference */ if (!get_modified_type(ct, sym, pmt_ref, dt, in_args)) goto done; break; case 'Q': /* const pointer */ case 'R': /* volatile pointer */ case 'S': /* const volatile pointer */ if (!get_modified_type(ct, sym, pmt_ref, in_args ? dt : 'P', in_args)) goto done; break; case 'P': /* Pointer */ if (isdigit(*sym->current)) { /* FIXME: P6 = Function pointer, others who knows.. */ if (*sym->current++ == '6') { char* args = NULL; const char* call_conv; const char* exported; struct datatype_t sub_ct; unsigned mark = sym->stack.num; if (!get_calling_convention(*sym->current++, &call_conv, &exported, sym->flags & ~UNDNAME_NO_ALLOCATION_LANGUAGE) || !demangle_datatype(sym, &sub_ct, pmt_ref, FALSE)) goto done; args = get_args(sym, pmt_ref, TRUE, '(', ')'); if (!args) goto done; sym->stack.num = mark; ct->left = str_printf(sym, "%s%s (%s*", sub_ct.left, sub_ct.right, call_conv); ct->right = str_printf(sym, ")%s", args); } else goto done; } else if (!get_modified_type(ct, sym, pmt_ref, 'P', in_args)) goto done; break; case 'W': if (*sym->current == '4') { char* enum_name; sym->current++; if (!(enum_name = get_class_name(sym))) goto done; if (sym->flags & UNDNAME_NO_COMPLEX_TYPE) ct->left = enum_name; else ct->left = str_printf(sym, "enum %s", enum_name); } else goto done; break; case '0': case '1': case '2': case '3': case '4': case '5': case '6': case '7': case '8': case '9': /* Referring back to previously parsed type */ /* left and right are pushed as two separate strings */ ct->left = str_array_get_ref(pmt_ref, (dt - '0') * 2); ct->right = str_array_get_ref(pmt_ref, (dt - '0') * 2 + 1); if (!ct->left) goto done; add_pmt = FALSE; break; case '$': switch (*sym->current++) { case '0': if (!(ct->left = get_number(sym))) goto done; break; case 'D': { const char* ptr; if (!(ptr = get_number(sym))) goto done; ct->left = str_printf(sym, "`template-parameter%s'", ptr); } break; case 'F': { const char* p1; const char* p2; if (!(p1 = get_number(sym))) goto done; if (!(p2 = get_number(sym))) goto done; ct->left = str_printf(sym, "{%s,%s}", p1, p2); } break; case 'G': { const char* p1; const char* p2; const char* p3; if (!(p1 = get_number(sym))) goto done; if (!(p2 = get_number(sym))) goto done; if (!(p3 = get_number(sym))) goto done; ct->left = str_printf(sym, "{%s,%s,%s}", p1, p2, p3); } break; case 'Q': { const char* ptr; if (!(ptr = get_number(sym))) goto done; ct->left = str_printf(sym, "`non-type-template-parameter%s'", ptr); } break; case '$': if (*sym->current == 'C') { const char* ptr; sym->current++; if (!get_modifier(*sym->current++, &ptr)) goto done; if (!demangle_datatype(sym, ct, pmt_ref, in_args)) goto done; ct->left = str_printf(sym, "%s %s", ct->left, ptr); } break; } break; default : ERR("Unknown type %c\n", dt); break; } if (add_pmt && pmt_ref && in_args) { /* left and right are pushed as two separate strings */ if (!str_array_push(sym, ct->left ? ct->left : "", -1, pmt_ref) || !str_array_push(sym, ct->right ? ct->right : "", -1, pmt_ref)) return FALSE; } done: return ct->left != NULL; } /****************************************************************** * handle_data * Does the final parsing and handling for a variable or a field in * a class. */ static BOOL handle_data(struct parsed_symbol* sym) { const char* access = NULL; const char* member_type = NULL; const char* modifier = NULL; struct datatype_t ct; char* name = NULL; BOOL ret = FALSE; /* 0 private static * 1 protected static * 2 public static * 3 private non-static * 4 protected non-static * 5 public non-static * 6 ?? static * 7 ?? static */ if (!(sym->flags & UNDNAME_NO_ACCESS_SPECIFIERS)) { /* we only print the access for static members */ switch (*sym->current) { case '0': access = "private: "; break; case '1': access = "protected: "; break; case '2': access = "public: "; break; } } if (!(sym->flags & UNDNAME_NO_MEMBER_TYPE)) { if (*sym->current >= '0' && *sym->current <= '2') member_type = "static "; } name = get_class_string(sym, 0); switch (*sym->current++) { case '0': case '1': case '2': case '3': case '4': case '5': { unsigned mark = sym->stack.num; struct array pmt; str_array_init(&pmt); if (!demangle_datatype(sym, &ct, &pmt, FALSE)) goto done; if (!get_modifier(*sym->current++, &modifier)) goto done; sym->stack.num = mark; } break; case '6' : /* compiler generated static */ case '7' : /* compiler generated static */ ct.left = ct.right = NULL; if (!get_modifier(*sym->current++, &modifier)) goto done; if (*sym->current != '@') { char* cls = NULL; if (!(cls = get_class_name(sym))) goto done; ct.right = str_printf(sym, "{for `%s'}", cls); } break; case '8': case '9': modifier = ct.left = ct.right = NULL; break; default: goto done; } if (sym->flags & UNDNAME_NAME_ONLY) ct.left = ct.right = modifier = NULL; sym->result = str_printf(sym, "%s%s%s%s%s%s%s%s", access, member_type, ct.left, modifier && ct.left ? " " : NULL, modifier, modifier || ct.left ? " " : NULL, name, ct.right); ret = TRUE; done: return ret; } /****************************************************************** * handle_method * Does the final parsing and handling for a function or a method in * a class. */ static BOOL handle_method(struct parsed_symbol* sym, BOOL cast_op) { char accmem; const char* access = NULL; const char* member_type = NULL; struct datatype_t ct_ret; const char* call_conv; const char* modifier = NULL; const char* exported; const char* args_str = NULL; const char* name = NULL; BOOL ret = FALSE; unsigned mark; struct array array_pmt; /* FIXME: why 2 possible letters for each option? * 'A' private: * 'B' private: * 'C' private: static * 'D' private: static * 'E' private: virtual * 'F' private: virtual * 'G' private: thunk * 'H' private: thunk * 'I' protected: * 'J' protected: * 'K' protected: static * 'L' protected: static * 'M' protected: virtual * 'N' protected: virtual * 'O' protected: thunk * 'P' protected: thunk * 'Q' public: * 'R' public: * 'S' public: static * 'T' public: static * 'U' public: virtual * 'V' public: virtual * 'W' public: thunk * 'X' public: thunk * 'Y' * 'Z' */ accmem = *sym->current++; if (accmem < 'A' || accmem > 'Z') goto done; if (!(sym->flags & UNDNAME_NO_ACCESS_SPECIFIERS)) { switch ((accmem - 'A') / 8) { case 0: access = "private: "; break; case 1: access = "protected: "; break; case 2: access = "public: "; break; } } if (!(sym->flags & UNDNAME_NO_MEMBER_TYPE)) { if (accmem <= 'X') { switch ((accmem - 'A') % 8) { case 2: case 3: member_type = "static "; break; case 4: case 5: member_type = "virtual "; break; case 6: case 7: access = str_printf(sym, "[thunk]:%s", access); member_type = "virtual "; break; } } } name = get_class_string(sym, 0); if ((accmem - 'A') % 8 == 6 || (accmem - '8') % 8 == 7) /* a thunk */ name = str_printf(sym, "%s`adjustor{%s}' ", name, get_number(sym)); if (accmem <= 'X') { if (((accmem - 'A') % 8) != 2 && ((accmem - 'A') % 8) != 3) { /* Implicit 'this' pointer */ /* If there is an implicit this pointer, const modifier follows */ if (!get_modifier(*sym->current, &modifier)) goto done; sym->current++; } } if (!get_calling_convention(*sym->current++, &call_conv, &exported, sym->flags)) goto done; str_array_init(&array_pmt); /* Return type, or @ if 'void' */ if (*sym->current == '@') { ct_ret.left = "void"; ct_ret.right = NULL; sym->current++; } else { if (!demangle_datatype(sym, &ct_ret, &array_pmt, FALSE)) goto done; } if (sym->flags & UNDNAME_NO_FUNCTION_RETURNS) ct_ret.left = ct_ret.right = NULL; if (cast_op) { name = str_printf(sym, "%s%s%s", name, ct_ret.left, ct_ret.right); ct_ret.left = ct_ret.right = NULL; } mark = sym->stack.num; if (!(args_str = get_args(sym, &array_pmt, TRUE, '(', ')'))) goto done; if (sym->flags & UNDNAME_NAME_ONLY) args_str = modifier = NULL; sym->stack.num = mark; /* Note: '()' after 'Z' means 'throws', but we don't care here * Yet!!! FIXME */ sym->result = str_printf(sym, "%s%s%s%s%s%s%s%s%s%s%s%s", access, member_type, ct_ret.left, (ct_ret.left && !ct_ret.right) ? " " : NULL, call_conv, call_conv ? " " : NULL, exported, name, args_str, modifier, modifier ? " " : NULL, ct_ret.right); ret = TRUE; done: return ret; } /****************************************************************** * handle_template * Does the final parsing and handling for a name with templates */ static BOOL handle_template(struct parsed_symbol* sym) { const char* name; const char* args; assert(*sym->current++ == '$'); if (!(name = get_literal_string(sym))) return FALSE; if (!(args = get_args(sym, NULL, FALSE, '<', '>'))) return FALSE; sym->result = str_printf(sym, "%s%s", name, args); return TRUE; } /******************************************************************* * symbol_demangle * Demangle a C++ linker symbol */ static BOOL symbol_demangle(struct parsed_symbol* sym) { BOOL ret = FALSE; unsigned do_after = 0; static CHAR dashed_null[] = "--null--"; /* FIXME seems wrong as name, as it demangles a simple data type */ if (sym->flags & UNDNAME_NO_ARGUMENTS) { struct datatype_t ct; if (demangle_datatype(sym, &ct, NULL, FALSE)) { sym->result = str_printf(sym, "%s%s", ct.left, ct.right); ret = TRUE; } goto done; } /* MS mangled names always begin with '?' */ if (*sym->current != '?') return FALSE; str_array_init(&sym->names); str_array_init(&sym->stack); sym->current++; /* Then function name or operator code */ if (*sym->current == '?' && sym->current[1] != '$') { const char* function_name = NULL; /* C++ operator code (one character, or two if the first is '_') */ switch (*++sym->current) { case '0': do_after = 1; break; case '1': do_after = 2; break; case '2': function_name = "operator new"; break; case '3': function_name = "operator delete"; break; case '4': function_name = "operator="; break; case '5': function_name = "operator>>"; break; case '6': function_name = "operator<<"; break; case '7': function_name = "operator!"; break; case '8': function_name = "operator=="; break; case '9': function_name = "operator!="; break; case 'A': function_name = "operator[]"; break; case 'B': function_name = "operator "; do_after = 3; break; case 'C': function_name = "operator->"; break; case 'D': function_name = "operator*"; break; case 'E': function_name = "operator++"; break; case 'F': function_name = "operator--"; break; case 'G': function_name = "operator-"; break; case 'H': function_name = "operator+"; break; case 'I': function_name = "operator&"; break; case 'J': function_name = "operator->*"; break; case 'K': function_name = "operator/"; break; case 'L': function_name = "operator%"; break; case 'M': function_name = "operator<"; break; case 'N': function_name = "operator<="; break; case 'O': function_name = "operator>"; break; case 'P': function_name = "operator>="; break; case 'Q': function_name = "operator,"; break; case 'R': function_name = "operator()"; break; case 'S': function_name = "operator~"; break; case 'T': function_name = "operator^"; break; case 'U': function_name = "operator|"; break; case 'V': function_name = "operator&&"; break; case 'W': function_name = "operator||"; break; case 'X': function_name = "operator*="; break; case 'Y': function_name = "operator+="; break; case 'Z': function_name = "operator-="; break; case '_': switch (*++sym->current) { case '0': function_name = "operator/="; break; case '1': function_name = "operator%="; break; case '2': function_name = "operator>>="; break; case '3': function_name = "operator<<="; break; case '4': function_name = "operator&="; break; case '5': function_name = "operator|="; break; case '6': function_name = "operator^="; break; case '7': function_name = "`vftable'"; break; case '8': function_name = "`vbtable'"; break; case '9': function_name = "`vcall'"; break; case 'A': function_name = "`typeof'"; break; case 'B': function_name = "`local static guard'"; break; case 'C': function_name = "`string'"; do_after = 4; break; case 'D': function_name = "`vbase destructor'"; break; case 'E': function_name = "`vector deleting destructor'"; break; case 'F': function_name = "`default constructor closure'"; break; case 'G': function_name = "`scalar deleting destructor'"; break; case 'H': function_name = "`vector constructor iterator'"; break; case 'I': function_name = "`vector destructor iterator'"; break; case 'J': function_name = "`vector vbase constructor iterator'"; break; case 'K': function_name = "`virtual displacement map'"; break; case 'L': function_name = "`eh vector constructor iterator'"; break; case 'M': function_name = "`eh vector destructor iterator'"; break; case 'N': function_name = "`eh vector vbase constructor iterator'"; break; case 'O': function_name = "`copy constructor closure'"; break; case 'R': sym->flags |= UNDNAME_NO_FUNCTION_RETURNS; switch (*++sym->current) { case '0': { struct datatype_t ct; struct array pmt; sym->current++; str_array_init(&pmt); demangle_datatype(sym, &ct, &pmt, FALSE); function_name = str_printf(sym, "%s%s `RTTI Type Descriptor'", ct.left, ct.right); sym->current--; } break; case '1': { const char* n1, *n2, *n3, *n4; sym->current++; n1 = get_number(sym); n2 = get_number(sym); n3 = get_number(sym); n4 = get_number(sym); sym->current--; function_name = str_printf(sym, "`RTTI Base Class Descriptor at (%s,%s,%s,%s)'", n1, n2, n3, n4); } break; case '2': function_name = "`RTTI Base Class Array'"; break; case '3': function_name = "`RTTI Class Hierarchy Descriptor'"; break; case '4': function_name = "`RTTI Complete Object Locator'"; break; default: ERR("Unknown RTTI operator: _R%c\n", *sym->current); break; } break; case 'S': function_name = "`local vftable'"; break; case 'T': function_name = "`local vftable constructor closure'"; break; case 'U': function_name = "operator new[]"; break; case 'V': function_name = "operator delete[]"; break; case 'X': function_name = "`placement delete closure'"; break; case 'Y': function_name = "`placement delete[] closure'"; break; default: ERR("Unknown operator: _%c\n", *sym->current); return FALSE; } break; default: /* FIXME: Other operators */ ERR("Unknown operator: %c\n", *sym->current); return FALSE; } sym->current++; switch (do_after) { case 1: case 2: if (!str_array_push(sym, dashed_null, -1, &sym->stack)) return FALSE; break; case 4: sym->result = (char*)function_name; ret = TRUE; goto done; default: if (!str_array_push(sym, function_name, -1, &sym->stack)) return FALSE; break; } } else if (*sym->current == '$') { /* Strange construct, it's a name with a template argument list and that's all. */ sym->current++; ret = (sym->result = get_template_name(sym)) != NULL; goto done; } else if (*sym->current == '?' && sym->current[1] == '$') do_after = 5; /* Either a class name, or '@' if the symbol is not a class member */ switch (*sym->current) { case '@': sym->current++; break; case '$': break; default: /* Class the function is associated with, terminated by '@@' */ if (!get_class(sym)) goto done; break; } switch (do_after) { case 0: default: break; case 1: case 2: /* it's time to set the member name for ctor & dtor */ if (sym->stack.num <= 1) goto done; if (do_after == 1) sym->stack.elts[0] = sym->stack.elts[1]; else sym->stack.elts[0] = str_printf(sym, "~%s", sym->stack.elts[1]); /* ctors and dtors don't have return type */ sym->flags |= UNDNAME_NO_FUNCTION_RETURNS; break; case 3: sym->flags &= ~UNDNAME_NO_FUNCTION_RETURNS; break; case 5: sym->names.start = 1; break; } /* Function/Data type and access level */ if (*sym->current >= '0' && *sym->current <= '9') ret = handle_data(sym); else if (*sym->current >= 'A' && *sym->current <= 'Z') ret = handle_method(sym, do_after == 3); else if (*sym->current == '$') ret = handle_template(sym); else ret = FALSE; done: if (ret) assert(sym->result); else WARN("Failed at %s\n", sym->current); return ret; } /********************************************************************* * __unDNameEx (MSVCRT.@) * * Demangle a C++ identifier. * * PARAMS * buffer [O] If not NULL, the place to put the demangled string * mangled [I] Mangled name of the function * buflen [I] Length of buffer * memget [I] Function to allocate memory with * memfree [I] Function to free memory with * unknown [?] Unknown, possibly a call back * flags [I] Flags determining demangled format * * RETURNS * Success: A string pointing to the unmangled name, allocated with memget. * Failure: NULL. */ char* CDECL __unDNameEx(char* buffer, const char* mangled, int buflen, malloc_func_t memget, free_func_t memfree, void* unknown, unsigned short int flags) { struct parsed_symbol sym; const char* result; TRACE("(%p,%s,%d,%p,%p,%p,%x)\n", buffer, mangled, buflen, memget, memfree, unknown, flags); /* The flags details is not documented by MS. However, it looks exactly * like the UNDNAME_ manifest constants from imagehlp.h and dbghelp.h * So, we copied those (on top of the file) */ memset(&sym, 0, sizeof(struct parsed_symbol)); if (flags & UNDNAME_NAME_ONLY) flags |= UNDNAME_NO_FUNCTION_RETURNS | UNDNAME_NO_ACCESS_SPECIFIERS | UNDNAME_NO_MEMBER_TYPE | UNDNAME_NO_ALLOCATION_LANGUAGE | UNDNAME_NO_COMPLEX_TYPE; sym.flags = flags; sym.mem_alloc_ptr = memget; sym.mem_free_ptr = memfree; sym.current = mangled; result = symbol_demangle(&sym) ? sym.result : mangled; if (buffer && buflen) { lstrcpynA( buffer, result, buflen); } else { buffer = memget(strlen(result) + 1); if (buffer) strcpy(buffer, result); } und_free_all(&sym); return buffer; } /********************************************************************* * __unDName (MSVCRT.@) */ char* CDECL __unDName(char* buffer, const char* mangled, int buflen, malloc_func_t memget, free_func_t memfree, unsigned short int flags) { return __unDNameEx(buffer, mangled, buflen, memget, memfree, NULL, flags); }