/* Part of CPP library. (Macro and #define handling.) Copyright (C) 1986-2014 Free Software Foundation, Inc. Written by Per Bothner, 1994. Based on CCCP program by Paul Rubin, June 1986 Adapted to ANSI C, Richard Stallman, Jan 1987 This program is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 3, or (at your option) any later version. This program 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 General Public License for more details. You should have received a copy of the GNU General Public License along with this program; see the file COPYING3. If not see . In other words, you are welcome to use, share and improve this program. You are forbidden to forbid anyone else to use, share and improve what you give them. Help stamp out software-hoarding! */ #include "config.h" #include "system.h" #include "cpplib.h" #include "internal.h" typedef struct macro_arg macro_arg; /* This structure represents the tokens of a macro argument. These tokens can be macro themselves, in which case they can be either expanded or unexpanded. When they are expanded, this data structure keeps both the expanded and unexpanded forms. */ struct macro_arg { const cpp_token **first; /* First token in unexpanded argument. */ const cpp_token **expanded; /* Macro-expanded argument. */ const cpp_token *stringified; /* Stringified argument. */ unsigned int count; /* # of tokens in argument. */ unsigned int expanded_count; /* # of tokens in expanded argument. */ source_location *virt_locs; /* Where virtual locations for unexpanded tokens are stored. */ source_location *expanded_virt_locs; /* Where virtual locations for expanded tokens are stored. */ }; /* The kind of macro tokens which the instance of macro_arg_token_iter is supposed to iterate over. */ enum macro_arg_token_kind { MACRO_ARG_TOKEN_NORMAL, /* This is a macro argument token that got transformed into a string litteral, e.g. #foo. */ MACRO_ARG_TOKEN_STRINGIFIED, /* This is a token resulting from the expansion of a macro argument that was itself a macro. */ MACRO_ARG_TOKEN_EXPANDED }; /* An iterator over tokens coming from a function-like macro argument. */ typedef struct macro_arg_token_iter macro_arg_token_iter; struct macro_arg_token_iter { /* Whether or not -ftrack-macro-expansion is used. */ bool track_macro_exp_p; /* The kind of token over which we are supposed to iterate. */ enum macro_arg_token_kind kind; /* A pointer to the current token pointed to by the iterator. */ const cpp_token **token_ptr; /* A pointer to the "full" location of the current token. If -ftrack-macro-expansion is used this location tracks loci across macro expansion. */ const source_location *location_ptr; #ifdef ENABLE_CHECKING /* The number of times the iterator went forward. This useful only when checking is enabled. */ size_t num_forwards; #endif }; /* Saved data about an identifier being used as a macro argument name. */ struct macro_arg_saved_data { /* The canonical (UTF-8) spelling of this identifier. */ cpp_hashnode *canonical_node; /* The previous value of this identifier. */ union _cpp_hashnode_value value; }; /* Macro expansion. */ static int enter_macro_context (cpp_reader *, cpp_hashnode *, const cpp_token *, source_location); static int builtin_macro (cpp_reader *, cpp_hashnode *, source_location); static void push_ptoken_context (cpp_reader *, cpp_hashnode *, _cpp_buff *, const cpp_token **, unsigned int); static void push_extended_tokens_context (cpp_reader *, cpp_hashnode *, _cpp_buff *, source_location *, const cpp_token **, unsigned int); static _cpp_buff *collect_args (cpp_reader *, const cpp_hashnode *, _cpp_buff **, unsigned *); static cpp_context *next_context (cpp_reader *); static const cpp_token *padding_token (cpp_reader *, const cpp_token *); static void expand_arg (cpp_reader *, macro_arg *); static const cpp_token *new_string_token (cpp_reader *, uchar *, unsigned int); static const cpp_token *stringify_arg (cpp_reader *, macro_arg *); static void paste_all_tokens (cpp_reader *, const cpp_token *); static bool paste_tokens (cpp_reader *, source_location, const cpp_token **, const cpp_token *); static void alloc_expanded_arg_mem (cpp_reader *, macro_arg *, size_t); static void ensure_expanded_arg_room (cpp_reader *, macro_arg *, size_t, size_t *); static void delete_macro_args (_cpp_buff*, unsigned num_args); static void set_arg_token (macro_arg *, const cpp_token *, source_location, size_t, enum macro_arg_token_kind, bool); static const source_location *get_arg_token_location (const macro_arg *, enum macro_arg_token_kind); static const cpp_token **arg_token_ptr_at (const macro_arg *, size_t, enum macro_arg_token_kind, source_location **virt_location); static void macro_arg_token_iter_init (macro_arg_token_iter *, bool, enum macro_arg_token_kind, const macro_arg *, const cpp_token **); static const cpp_token *macro_arg_token_iter_get_token (const macro_arg_token_iter *it); static source_location macro_arg_token_iter_get_location (const macro_arg_token_iter *); static void macro_arg_token_iter_forward (macro_arg_token_iter *); static _cpp_buff *tokens_buff_new (cpp_reader *, size_t, source_location **); static size_t tokens_buff_count (_cpp_buff *); static const cpp_token **tokens_buff_last_token_ptr (_cpp_buff *); static inline const cpp_token **tokens_buff_put_token_to (const cpp_token **, source_location *, const cpp_token *, source_location, source_location, const struct line_map *, unsigned int); static const cpp_token **tokens_buff_add_token (_cpp_buff *, source_location *, const cpp_token *, source_location, source_location, const struct line_map *, unsigned int); static inline void tokens_buff_remove_last_token (_cpp_buff *); static void replace_args (cpp_reader *, cpp_hashnode *, cpp_macro *, macro_arg *, source_location); static _cpp_buff *funlike_invocation_p (cpp_reader *, cpp_hashnode *, _cpp_buff **, unsigned *); static bool create_iso_definition (cpp_reader *, cpp_macro *); /* #define directive parsing and handling. */ static cpp_token *alloc_expansion_token (cpp_reader *, cpp_macro *); static cpp_token *lex_expansion_token (cpp_reader *, cpp_macro *); static bool warn_of_redefinition (cpp_reader *, cpp_hashnode *, const cpp_macro *); static bool parse_params (cpp_reader *, cpp_macro *); static void check_trad_stringification (cpp_reader *, const cpp_macro *, const cpp_string *); static bool reached_end_of_context (cpp_context *); static void consume_next_token_from_context (cpp_reader *pfile, const cpp_token **, source_location *); static const cpp_token* cpp_get_token_1 (cpp_reader *, source_location *); static cpp_hashnode* macro_of_context (cpp_context *context); static bool in_macro_expansion_p (cpp_reader *pfile); /* Statistical counter tracking the number of macros that got expanded. */ unsigned num_expanded_macros_counter = 0; /* Statistical counter tracking the total number tokens resulting from macro expansion. */ unsigned num_macro_tokens_counter = 0; /* Emits a warning if NODE is a macro defined in the main file that has not been used. */ int _cpp_warn_if_unused_macro (cpp_reader *pfile, cpp_hashnode *node, void *v ATTRIBUTE_UNUSED) { if (node->type == NT_MACRO && !(node->flags & NODE_BUILTIN)) { cpp_macro *macro = node->value.macro; if (!macro->used && MAIN_FILE_P (linemap_lookup (pfile->line_table, macro->line))) cpp_warning_with_line (pfile, CPP_W_UNUSED_MACROS, macro->line, 0, "macro \"%s\" is not used", NODE_NAME (node)); } return 1; } /* Allocates and returns a CPP_STRING token, containing TEXT of length LEN, after null-terminating it. TEXT must be in permanent storage. */ static const cpp_token * new_string_token (cpp_reader *pfile, unsigned char *text, unsigned int len) { cpp_token *token = _cpp_temp_token (pfile); text[len] = '\0'; token->type = CPP_STRING; token->val.str.len = len; token->val.str.text = text; token->flags = 0; return token; } static const char * const monthnames[] = { "Jan", "Feb", "Mar", "Apr", "May", "Jun", "Jul", "Aug", "Sep", "Oct", "Nov", "Dec" }; /* Helper function for builtin_macro. Returns the text generated by a builtin macro. */ const uchar * _cpp_builtin_macro_text (cpp_reader *pfile, cpp_hashnode *node) { const uchar *result = NULL; linenum_type number = 1; switch (node->value.builtin) { default: cpp_error (pfile, CPP_DL_ICE, "invalid built-in macro \"%s\"", NODE_NAME (node)); break; case BT_TIMESTAMP: { if (CPP_OPTION (pfile, warn_date_time)) cpp_warning (pfile, CPP_W_DATE_TIME, "macro \"%s\" might prevent " "reproducible builds", NODE_NAME (node)); cpp_buffer *pbuffer = cpp_get_buffer (pfile); if (pbuffer->timestamp == NULL) { /* Initialize timestamp value of the assotiated file. */ struct _cpp_file *file = cpp_get_file (pbuffer); if (file) { /* Generate __TIMESTAMP__ string, that represents the date and time of the last modification of the current source file. The string constant looks like "Sun Sep 16 01:03:52 1973". */ struct tm *tb = NULL; struct stat *st = _cpp_get_file_stat (file); if (st) tb = localtime (&st->st_mtime); if (tb) { char *str = asctime (tb); size_t len = strlen (str); unsigned char *buf = _cpp_unaligned_alloc (pfile, len + 2); buf[0] = '"'; strcpy ((char *) buf + 1, str); buf[len] = '"'; pbuffer->timestamp = buf; } else { cpp_errno (pfile, CPP_DL_WARNING, "could not determine file timestamp"); pbuffer->timestamp = UC"\"??? ??? ?? ??:??:?? ????\""; } } } result = pbuffer->timestamp; } break; case BT_FILE: case BT_BASE_FILE: { unsigned int len; const char *name; uchar *buf; if (node->value.builtin == BT_FILE) name = linemap_get_expansion_filename (pfile->line_table, pfile->line_table->highest_line); else { name = _cpp_get_file_name (pfile->main_file); if (!name) abort (); } len = strlen (name); buf = _cpp_unaligned_alloc (pfile, len * 2 + 3); result = buf; *buf = '"'; buf = cpp_quote_string (buf + 1, (const unsigned char *) name, len); *buf++ = '"'; *buf = '\0'; } break; case BT_INCLUDE_LEVEL: /* The line map depth counts the primary source as level 1, but historically __INCLUDE_DEPTH__ has called the primary source level 0. */ number = pfile->line_table->depth - 1; break; case BT_SPECLINE: /* If __LINE__ is embedded in a macro, it must expand to the line of the macro's invocation, not its definition. Otherwise things like assert() will not work properly. */ number = linemap_get_expansion_line (pfile->line_table, CPP_OPTION (pfile, traditional) ? pfile->line_table->highest_line : pfile->cur_token[-1].src_loc); break; /* __STDC__ has the value 1 under normal circumstances. However, if (a) we are in a system header, (b) the option stdc_0_in_system_headers is true (set by target config), and (c) we are not in strictly conforming mode, then it has the value 0. (b) and (c) are already checked in cpp_init_builtins. */ case BT_STDC: if (cpp_in_system_header (pfile)) number = 0; else number = 1; break; case BT_DATE: case BT_TIME: if (CPP_OPTION (pfile, warn_date_time)) cpp_warning (pfile, CPP_W_DATE_TIME, "macro \"%s\" might prevent " "reproducible builds", NODE_NAME (node)); if (pfile->date == NULL) { /* Allocate __DATE__ and __TIME__ strings from permanent storage. We only do this once, and don't generate them at init time, because time() and localtime() are very slow on some systems. */ time_t tt; struct tm *tb = NULL; /* (time_t) -1 is a legitimate value for "number of seconds since the Epoch", so we have to do a little dance to distinguish that from a genuine error. */ errno = 0; tt = time(NULL); if (tt != (time_t)-1 || errno == 0) tb = localtime (&tt); if (tb) { pfile->date = _cpp_unaligned_alloc (pfile, sizeof ("\"Oct 11 1347\"")); sprintf ((char *) pfile->date, "\"%s %2d %4d\"", monthnames[tb->tm_mon], tb->tm_mday, tb->tm_year + 1900); pfile->time = _cpp_unaligned_alloc (pfile, sizeof ("\"12:34:56\"")); sprintf ((char *) pfile->time, "\"%02d:%02d:%02d\"", tb->tm_hour, tb->tm_min, tb->tm_sec); } else { cpp_errno (pfile, CPP_DL_WARNING, "could not determine date and time"); pfile->date = UC"\"??? ?? ????\""; pfile->time = UC"\"??:??:??\""; } } if (node->value.builtin == BT_DATE) result = pfile->date; else result = pfile->time; break; case BT_COUNTER: if (CPP_OPTION (pfile, directives_only) && pfile->state.in_directive) cpp_error (pfile, CPP_DL_ERROR, "__COUNTER__ expanded inside directive with -fdirectives-only"); number = pfile->counter++; break; } if (result == NULL) { /* 21 bytes holds all NUL-terminated unsigned 64-bit numbers. */ result = _cpp_unaligned_alloc (pfile, 21); sprintf ((char *) result, "%u", number); } return result; } /* Convert builtin macros like __FILE__ to a token and push it on the context stack. Also handles _Pragma, for which a new token may not be created. Returns 1 if it generates a new token context, 0 to return the token to the caller. LOC is the location of the expansion point of the macro. */ static int builtin_macro (cpp_reader *pfile, cpp_hashnode *node, source_location loc) { const uchar *buf; size_t len; char *nbuf; if (node->value.builtin == BT_PRAGMA) { /* Don't interpret _Pragma within directives. The standard is not clear on this, but to me this makes most sense. */ if (pfile->state.in_directive) return 0; return _cpp_do__Pragma (pfile); } buf = _cpp_builtin_macro_text (pfile, node); len = ustrlen (buf); nbuf = (char *) alloca (len + 1); memcpy (nbuf, buf, len); nbuf[len]='\n'; cpp_push_buffer (pfile, (uchar *) nbuf, len, /* from_stage3 */ true); _cpp_clean_line (pfile); /* Set pfile->cur_token as required by _cpp_lex_direct. */ pfile->cur_token = _cpp_temp_token (pfile); cpp_token *token = _cpp_lex_direct (pfile); /* We should point to the expansion point of the builtin macro. */ token->src_loc = loc; if (pfile->context->tokens_kind == TOKENS_KIND_EXTENDED) { /* We are tracking tokens resulting from macro expansion. Create a macro line map and generate a virtual location for the token resulting from the expansion of the built-in macro. */ source_location *virt_locs = NULL; _cpp_buff *token_buf = tokens_buff_new (pfile, 1, &virt_locs); const line_map * map = linemap_enter_macro (pfile->line_table, node, token->src_loc, 1); tokens_buff_add_token (token_buf, virt_locs, token, pfile->line_table->builtin_location, pfile->line_table->builtin_location, map, /*macro_token_index=*/0); push_extended_tokens_context (pfile, node, token_buf, virt_locs, (const cpp_token **)token_buf->base, 1); } else _cpp_push_token_context (pfile, NULL, token, 1); if (pfile->buffer->cur != pfile->buffer->rlimit) cpp_error (pfile, CPP_DL_ICE, "invalid built-in macro \"%s\"", NODE_NAME (node)); _cpp_pop_buffer (pfile); return 1; } /* Copies SRC, of length LEN, to DEST, adding backslashes before all backslashes and double quotes. DEST must be of sufficient size. Returns a pointer to the end of the string. */ uchar * cpp_quote_string (uchar *dest, const uchar *src, unsigned int len) { while (len--) { uchar c = *src++; if (c == '\\' || c == '"') { *dest++ = '\\'; *dest++ = c; } else *dest++ = c; } return dest; } /* Convert a token sequence ARG to a single string token according to the rules of the ISO C #-operator. */ static const cpp_token * stringify_arg (cpp_reader *pfile, macro_arg *arg) { unsigned char *dest; unsigned int i, escape_it, backslash_count = 0; const cpp_token *source = NULL; size_t len; if (BUFF_ROOM (pfile->u_buff) < 3) _cpp_extend_buff (pfile, &pfile->u_buff, 3); dest = BUFF_FRONT (pfile->u_buff); *dest++ = '"'; /* Loop, reading in the argument's tokens. */ for (i = 0; i < arg->count; i++) { const cpp_token *token = arg->first[i]; if (token->type == CPP_PADDING) { if (source == NULL || (!(source->flags & PREV_WHITE) && token->val.source == NULL)) source = token->val.source; continue; } escape_it = (token->type == CPP_STRING || token->type == CPP_CHAR || token->type == CPP_WSTRING || token->type == CPP_WCHAR || token->type == CPP_STRING32 || token->type == CPP_CHAR32 || token->type == CPP_STRING16 || token->type == CPP_CHAR16 || token->type == CPP_UTF8STRING || cpp_userdef_string_p (token->type) || cpp_userdef_char_p (token->type)); /* Room for each char being written in octal, initial space and final quote and NUL. */ len = cpp_token_len (token); if (escape_it) len *= 4; len += 3; if ((size_t) (BUFF_LIMIT (pfile->u_buff) - dest) < len) { size_t len_so_far = dest - BUFF_FRONT (pfile->u_buff); _cpp_extend_buff (pfile, &pfile->u_buff, len); dest = BUFF_FRONT (pfile->u_buff) + len_so_far; } /* Leading white space? */ if (dest - 1 != BUFF_FRONT (pfile->u_buff)) { if (source == NULL) source = token; if (source->flags & PREV_WHITE) *dest++ = ' '; } source = NULL; if (escape_it) { _cpp_buff *buff = _cpp_get_buff (pfile, len); unsigned char *buf = BUFF_FRONT (buff); len = cpp_spell_token (pfile, token, buf, true) - buf; dest = cpp_quote_string (dest, buf, len); _cpp_release_buff (pfile, buff); } else dest = cpp_spell_token (pfile, token, dest, true); if (token->type == CPP_OTHER && token->val.str.text[0] == '\\') backslash_count++; else backslash_count = 0; } /* Ignore the final \ of invalid string literals. */ if (backslash_count & 1) { cpp_error (pfile, CPP_DL_WARNING, "invalid string literal, ignoring final '\\'"); dest--; } /* Commit the memory, including NUL, and return the token. */ *dest++ = '"'; len = dest - BUFF_FRONT (pfile->u_buff); BUFF_FRONT (pfile->u_buff) = dest + 1; return new_string_token (pfile, dest - len, len); } /* Try to paste two tokens. On success, return nonzero. In any case, PLHS is updated to point to the pasted token, which is guaranteed to not have the PASTE_LEFT flag set. LOCATION is the virtual location used for error reporting. */ static bool paste_tokens (cpp_reader *pfile, source_location location, const cpp_token **plhs, const cpp_token *rhs) { unsigned char *buf, *end, *lhsend; cpp_token *lhs; unsigned int len; len = cpp_token_len (*plhs) + cpp_token_len (rhs) + 1; buf = (unsigned char *) alloca (len); end = lhsend = cpp_spell_token (pfile, *plhs, buf, true); /* Avoid comment headers, since they are still processed in stage 3. It is simpler to insert a space here, rather than modifying the lexer to ignore comments in some circumstances. Simply returning false doesn't work, since we want to clear the PASTE_LEFT flag. */ if ((*plhs)->type == CPP_DIV && rhs->type != CPP_EQ) *end++ = ' '; /* In one obscure case we might see padding here. */ if (rhs->type != CPP_PADDING) end = cpp_spell_token (pfile, rhs, end, true); *end = '\n'; cpp_push_buffer (pfile, buf, end - buf, /* from_stage3 */ true); _cpp_clean_line (pfile); /* Set pfile->cur_token as required by _cpp_lex_direct. */ pfile->cur_token = _cpp_temp_token (pfile); lhs = _cpp_lex_direct (pfile); if (pfile->buffer->cur != pfile->buffer->rlimit) { source_location saved_loc = lhs->src_loc; _cpp_pop_buffer (pfile); _cpp_backup_tokens (pfile, 1); *lhsend = '\0'; /* We have to remove the PASTE_LEFT flag from the old lhs, but we want to keep the new location. */ *lhs = **plhs; *plhs = lhs; lhs->src_loc = saved_loc; lhs->flags &= ~PASTE_LEFT; /* Mandatory error for all apart from assembler. */ if (CPP_OPTION (pfile, lang) != CLK_ASM) cpp_error_with_line (pfile, CPP_DL_ERROR, location, 0, "pasting \"%s\" and \"%s\" does not give a valid preprocessing token", buf, cpp_token_as_text (pfile, rhs)); return false; } *plhs = lhs; _cpp_pop_buffer (pfile); return true; } /* Handles an arbitrarily long sequence of ## operators, with initial operand LHS. This implementation is left-associative, non-recursive, and finishes a paste before handling succeeding ones. If a paste fails, we back up to the RHS of the failing ## operator before pushing the context containing the result of prior successful pastes, with the effect that the RHS appears in the output stream after the pasted LHS normally. */ static void paste_all_tokens (cpp_reader *pfile, const cpp_token *lhs) { const cpp_token *rhs = NULL; cpp_context *context = pfile->context; source_location virt_loc = 0; /* We are expanding a macro and we must have been called on a token that appears at the left hand side of a ## operator. */ if (macro_of_context (pfile->context) == NULL || (!(lhs->flags & PASTE_LEFT))) abort (); if (context->tokens_kind == TOKENS_KIND_EXTENDED) /* The caller must have called consume_next_token_from_context right before calling us. That has incremented the pointer to the current virtual location. So it now points to the location of the token that comes right after *LHS. We want the resulting pasted token to have the location of the current *LHS, though. */ virt_loc = context->c.mc->cur_virt_loc[-1]; else /* We are not tracking macro expansion. So the best virtual location we can get here is the expansion point of the macro we are currently expanding. */ virt_loc = pfile->invocation_location; do { /* Take the token directly from the current context. We can do this, because we are in the replacement list of either an object-like macro, or a function-like macro with arguments inserted. In either case, the constraints to #define guarantee we have at least one more token. */ if (context->tokens_kind == TOKENS_KIND_DIRECT) rhs = FIRST (context).token++; else if (context->tokens_kind == TOKENS_KIND_INDIRECT) rhs = *FIRST (context).ptoken++; else if (context->tokens_kind == TOKENS_KIND_EXTENDED) { /* So we are in presence of an extended token context, which means that each token in this context has a virtual location attached to it. So let's not forget to update the pointer to the current virtual location of the current token when we update the pointer to the current token */ rhs = *FIRST (context).ptoken++; /* context->c.mc must be non-null, as if we were not in a macro context, context->tokens_kind could not be equal to TOKENS_KIND_EXTENDED. */ context->c.mc->cur_virt_loc++; } if (rhs->type == CPP_PADDING) { if (rhs->flags & PASTE_LEFT) abort (); } if (!paste_tokens (pfile, virt_loc, &lhs, rhs)) break; } while (rhs->flags & PASTE_LEFT); /* Put the resulting token in its own context. */ if (context->tokens_kind == TOKENS_KIND_EXTENDED) { source_location *virt_locs = NULL; _cpp_buff *token_buf = tokens_buff_new (pfile, 1, &virt_locs); tokens_buff_add_token (token_buf, virt_locs, lhs, virt_loc, 0, NULL, 0); push_extended_tokens_context (pfile, context->c.mc->macro_node, token_buf, virt_locs, (const cpp_token **)token_buf->base, 1); } else _cpp_push_token_context (pfile, NULL, lhs, 1); } /* Returns TRUE if the number of arguments ARGC supplied in an invocation of the MACRO referenced by NODE is valid. An empty invocation to a macro with no parameters should pass ARGC as zero. Note that MACRO cannot necessarily be deduced from NODE, in case NODE was redefined whilst collecting arguments. */ bool _cpp_arguments_ok (cpp_reader *pfile, cpp_macro *macro, const cpp_hashnode *node, unsigned int argc) { if (argc == macro->paramc) return true; if (argc < macro->paramc) { /* As an extension, variadic arguments are allowed to not appear in the invocation at all. e.g. #define debug(format, args...) something debug("string"); This is exactly the same as if an empty variadic list had been supplied - debug("string", ). */ if (argc + 1 == macro->paramc && macro->variadic) { if (CPP_PEDANTIC (pfile) && ! macro->syshdr) { if (CPP_OPTION (pfile, cplusplus)) cpp_error (pfile, CPP_DL_PEDWARN, "ISO C++11 requires at least one argument " "for the \"...\" in a variadic macro"); else cpp_error (pfile, CPP_DL_PEDWARN, "ISO C99 requires at least one argument " "for the \"...\" in a variadic macro"); } return true; } cpp_error (pfile, CPP_DL_ERROR, "macro \"%s\" requires %u arguments, but only %u given", NODE_NAME (node), macro->paramc, argc); } else cpp_error (pfile, CPP_DL_ERROR, "macro \"%s\" passed %u arguments, but takes just %u", NODE_NAME (node), argc, macro->paramc); return false; } /* Reads and returns the arguments to a function-like macro invocation. Assumes the opening parenthesis has been processed. If there is an error, emits an appropriate diagnostic and returns NULL. Each argument is terminated by a CPP_EOF token, for the future benefit of expand_arg(). If there are any deferred #pragma directives among macro arguments, store pointers to the CPP_PRAGMA ... CPP_PRAGMA_EOL tokens into *PRAGMA_BUFF buffer. What is returned is the buffer that contains the memory allocated to hold the macro arguments. NODE is the name of the macro this function is dealing with. If NUM_ARGS is non-NULL, *NUM_ARGS is set to the actual number of macro arguments allocated in the returned buffer. */ static _cpp_buff * collect_args (cpp_reader *pfile, const cpp_hashnode *node, _cpp_buff **pragma_buff, unsigned *num_args) { _cpp_buff *buff, *base_buff; cpp_macro *macro; macro_arg *args, *arg; const cpp_token *token; unsigned int argc; source_location virt_loc; bool track_macro_expansion_p = CPP_OPTION (pfile, track_macro_expansion); unsigned num_args_alloced = 0; macro = node->value.macro; if (macro->paramc) argc = macro->paramc; else argc = 1; #define DEFAULT_NUM_TOKENS_PER_MACRO_ARG 50 #define ARG_TOKENS_EXTENT 1000 buff = _cpp_get_buff (pfile, argc * (DEFAULT_NUM_TOKENS_PER_MACRO_ARG * sizeof (cpp_token *) + sizeof (macro_arg))); base_buff = buff; args = (macro_arg *) buff->base; memset (args, 0, argc * sizeof (macro_arg)); buff->cur = (unsigned char *) &args[argc]; arg = args, argc = 0; /* Collect the tokens making up each argument. We don't yet know how many arguments have been supplied, whether too many or too few. Hence the slightly bizarre usage of "argc" and "arg". */ do { unsigned int paren_depth = 0; unsigned int ntokens = 0; unsigned virt_locs_capacity = DEFAULT_NUM_TOKENS_PER_MACRO_ARG; num_args_alloced++; argc++; arg->first = (const cpp_token **) buff->cur; if (track_macro_expansion_p) { virt_locs_capacity = DEFAULT_NUM_TOKENS_PER_MACRO_ARG; arg->virt_locs = XNEWVEC (source_location, virt_locs_capacity); } for (;;) { /* Require space for 2 new tokens (including a CPP_EOF). */ if ((unsigned char *) &arg->first[ntokens + 2] > buff->limit) { buff = _cpp_append_extend_buff (pfile, buff, ARG_TOKENS_EXTENT * sizeof (cpp_token *)); arg->first = (const cpp_token **) buff->cur; } if (track_macro_expansion_p && (ntokens + 2 > virt_locs_capacity)) { virt_locs_capacity += ARG_TOKENS_EXTENT; arg->virt_locs = XRESIZEVEC (source_location, arg->virt_locs, virt_locs_capacity); } token = cpp_get_token_1 (pfile, &virt_loc); if (token->type == CPP_PADDING) { /* Drop leading padding. */ if (ntokens == 0) continue; } else if (token->type == CPP_OPEN_PAREN) paren_depth++; else if (token->type == CPP_CLOSE_PAREN) { if (paren_depth-- == 0) break; } else if (token->type == CPP_COMMA) { /* A comma does not terminate an argument within parentheses or as part of a variable argument. */ if (paren_depth == 0 && ! (macro->variadic && argc == macro->paramc)) break; } else if (token->type == CPP_EOF || (token->type == CPP_HASH && token->flags & BOL)) break; else if (token->type == CPP_PRAGMA) { cpp_token *newtok = _cpp_temp_token (pfile); /* CPP_PRAGMA token lives in directive_result, which will be overwritten on the next directive. */ *newtok = *token; token = newtok; do { if (*pragma_buff == NULL || BUFF_ROOM (*pragma_buff) < sizeof (cpp_token *)) { _cpp_buff *next; if (*pragma_buff == NULL) *pragma_buff = _cpp_get_buff (pfile, 32 * sizeof (cpp_token *)); else { next = *pragma_buff; *pragma_buff = _cpp_get_buff (pfile, (BUFF_FRONT (*pragma_buff) - (*pragma_buff)->base) * 2); (*pragma_buff)->next = next; } } *(const cpp_token **) BUFF_FRONT (*pragma_buff) = token; BUFF_FRONT (*pragma_buff) += sizeof (cpp_token *); if (token->type == CPP_PRAGMA_EOL) break; token = cpp_get_token_1 (pfile, &virt_loc); } while (token->type != CPP_EOF); /* In deferred pragmas parsing_args and prevent_expansion had been changed, reset it. */ pfile->state.parsing_args = 2; pfile->state.prevent_expansion = 1; if (token->type == CPP_EOF) break; else continue; } set_arg_token (arg, token, virt_loc, ntokens, MACRO_ARG_TOKEN_NORMAL, CPP_OPTION (pfile, track_macro_expansion)); ntokens++; } /* Drop trailing padding. */ while (ntokens > 0 && arg->first[ntokens - 1]->type == CPP_PADDING) ntokens--; arg->count = ntokens; set_arg_token (arg, &pfile->eof, pfile->eof.src_loc, ntokens, MACRO_ARG_TOKEN_NORMAL, CPP_OPTION (pfile, track_macro_expansion)); /* Terminate the argument. Excess arguments loop back and overwrite the final legitimate argument, before failing. */ if (argc <= macro->paramc) { buff->cur = (unsigned char *) &arg->first[ntokens + 1]; if (argc != macro->paramc) arg++; } } while (token->type != CPP_CLOSE_PAREN && token->type != CPP_EOF); if (token->type == CPP_EOF) { /* We still need the CPP_EOF to end directives, and to end pre-expansion of a macro argument. Step back is not unconditional, since we don't want to return a CPP_EOF to our callers at the end of an -include-d file. */ if (pfile->context->prev || pfile->state.in_directive) _cpp_backup_tokens (pfile, 1); cpp_error (pfile, CPP_DL_ERROR, "unterminated argument list invoking macro \"%s\"", NODE_NAME (node)); } else { /* A single empty argument is counted as no argument. */ if (argc == 1 && macro->paramc == 0 && args[0].count == 0) argc = 0; if (_cpp_arguments_ok (pfile, macro, node, argc)) { /* GCC has special semantics for , ## b where b is a varargs parameter: we remove the comma if b was omitted entirely. If b was merely an empty argument, the comma is retained. If the macro takes just one (varargs) parameter, then we retain the comma only if we are standards conforming. If FIRST is NULL replace_args () swallows the comma. */ if (macro->variadic && (argc < macro->paramc || (argc == 1 && args[0].count == 0 && !CPP_OPTION (pfile, std)))) args[macro->paramc - 1].first = NULL; if (num_args) *num_args = num_args_alloced; return base_buff; } } /* An error occurred. */ _cpp_release_buff (pfile, base_buff); return NULL; } /* Search for an opening parenthesis to the macro of NODE, in such a way that, if none is found, we don't lose the information in any intervening padding tokens. If we find the parenthesis, collect the arguments and return the buffer containing them. PRAGMA_BUFF argument is the same as in collect_args. If NUM_ARGS is non-NULL, *NUM_ARGS is set to the number of arguments contained in the returned buffer. */ static _cpp_buff * funlike_invocation_p (cpp_reader *pfile, cpp_hashnode *node, _cpp_buff **pragma_buff, unsigned *num_args) { const cpp_token *token, *padding = NULL; for (;;) { token = cpp_get_token (pfile); if (token->type != CPP_PADDING) break; if (padding == NULL || (!(padding->flags & PREV_WHITE) && token->val.source == NULL)) padding = token; } if (token->type == CPP_OPEN_PAREN) { pfile->state.parsing_args = 2; return collect_args (pfile, node, pragma_buff, num_args); } /* CPP_EOF can be the end of macro arguments, or the end of the file. We mustn't back up over the latter. Ugh. */ if (token->type != CPP_EOF || token == &pfile->eof) { /* Back up. We may have skipped padding, in which case backing up more than one token when expanding macros is in general too difficult. We re-insert it in its own context. */ _cpp_backup_tokens (pfile, 1); if (padding) _cpp_push_token_context (pfile, NULL, padding, 1); } return NULL; } /* Return the real number of tokens in the expansion of MACRO. */ static inline unsigned int macro_real_token_count (const cpp_macro *macro) { unsigned int i; if (__builtin_expect (!macro->extra_tokens, true)) return macro->count; for (i = 0; i < macro->count; i++) if (macro->exp.tokens[i].type == CPP_PASTE) return i; abort (); } /* Push the context of a macro with hash entry NODE onto the context stack. If we can successfully expand the macro, we push a context containing its yet-to-be-rescanned replacement list and return one. If there were additionally any unexpanded deferred #pragma directives among macro arguments, push another context containing the pragma tokens before the yet-to-be-rescanned replacement list and return two. Otherwise, we don't push a context and return zero. LOCATION is the location of the expansion point of the macro. */ static int enter_macro_context (cpp_reader *pfile, cpp_hashnode *node, const cpp_token *result, source_location location) { /* The presence of a macro invalidates a file's controlling macro. */ pfile->mi_valid = false; pfile->state.angled_headers = false; /* From here to when we push the context for the macro later down this function, we need to flag the fact that we are about to expand a macro. This is useful when -ftrack-macro-expansion is turned off. In that case, we need to record the location of the expansion point of the top-most macro we are about to to expand, into pfile->invocation_location. But we must not record any such location once the process of expanding the macro starts; that is, we must not do that recording between now and later down this function where set this flag to FALSE. */ pfile->about_to_expand_macro_p = true; if ((node->flags & NODE_BUILTIN) && !(node->flags & NODE_USED)) { node->flags |= NODE_USED; if ((!pfile->cb.user_builtin_macro || !pfile->cb.user_builtin_macro (pfile, node)) && pfile->cb.used_define) pfile->cb.used_define (pfile, pfile->directive_line, node); } /* Handle standard macros. */ if (! (node->flags & NODE_BUILTIN)) { cpp_macro *macro = node->value.macro; _cpp_buff *pragma_buff = NULL; if (macro->fun_like) { _cpp_buff *buff; unsigned num_args = 0; pfile->state.prevent_expansion++; pfile->keep_tokens++; pfile->state.parsing_args = 1; buff = funlike_invocation_p (pfile, node, &pragma_buff, &num_args); pfile->state.parsing_args = 0; pfile->keep_tokens--; pfile->state.prevent_expansion--; if (buff == NULL) { if (CPP_WTRADITIONAL (pfile) && ! node->value.macro->syshdr) cpp_warning (pfile, CPP_W_TRADITIONAL, "function-like macro \"%s\" must be used with arguments in traditional C", NODE_NAME (node)); if (pragma_buff) _cpp_release_buff (pfile, pragma_buff); pfile->about_to_expand_macro_p = false; return 0; } if (macro->paramc > 0) replace_args (pfile, node, macro, (macro_arg *) buff->base, location); /* Free the memory used by the arguments of this function-like macro. This memory has been allocated by funlike_invocation_p and by replace_args. */ delete_macro_args (buff, num_args); } /* Disable the macro within its expansion. */ node->flags |= NODE_DISABLED; if (!(node->flags & NODE_USED)) { node->flags |= NODE_USED; if (pfile->cb.used_define) pfile->cb.used_define (pfile, pfile->directive_line, node); } if (pfile->cb.used) pfile->cb.used (pfile, location, node); macro->used = 1; if (macro->paramc == 0) { unsigned tokens_count = macro_real_token_count (macro); if (CPP_OPTION (pfile, track_macro_expansion)) { unsigned int i; const cpp_token *src = macro->exp.tokens; const struct line_map *map; source_location *virt_locs = NULL; _cpp_buff *macro_tokens = tokens_buff_new (pfile, tokens_count, &virt_locs); /* Create a macro map to record the locations of the tokens that are involved in the expansion. LOCATION is the location of the macro expansion point. */ map = linemap_enter_macro (pfile->line_table, node, location, tokens_count); for (i = 0; i < tokens_count; ++i) { tokens_buff_add_token (macro_tokens, virt_locs, src, src->src_loc, src->src_loc, map, i); ++src; } push_extended_tokens_context (pfile, node, macro_tokens, virt_locs, (const cpp_token **) macro_tokens->base, tokens_count); } else _cpp_push_token_context (pfile, node, macro->exp.tokens, tokens_count); num_macro_tokens_counter += tokens_count; } if (pragma_buff) { if (!pfile->state.in_directive) _cpp_push_token_context (pfile, NULL, padding_token (pfile, result), 1); do { unsigned tokens_count; _cpp_buff *tail = pragma_buff->next; pragma_buff->next = NULL; tokens_count = ((const cpp_token **) BUFF_FRONT (pragma_buff) - (const cpp_token **) pragma_buff->base); push_ptoken_context (pfile, NULL, pragma_buff, (const cpp_token **) pragma_buff->base, tokens_count); pragma_buff = tail; if (!CPP_OPTION (pfile, track_macro_expansion)) num_macro_tokens_counter += tokens_count; } while (pragma_buff != NULL); pfile->about_to_expand_macro_p = false; return 2; } pfile->about_to_expand_macro_p = false; return 1; } pfile->about_to_expand_macro_p = false; /* Handle built-in macros and the _Pragma operator. */ return builtin_macro (pfile, node, location); } /* De-allocate the memory used by BUFF which is an array of instances of macro_arg. NUM_ARGS is the number of instances of macro_arg present in BUFF. */ static void delete_macro_args (_cpp_buff *buff, unsigned num_args) { macro_arg *macro_args; unsigned i; if (buff == NULL) return; macro_args = (macro_arg *) buff->base; /* Walk instances of macro_arg to free their expanded tokens as well as their macro_arg::virt_locs members. */ for (i = 0; i < num_args; ++i) { if (macro_args[i].expanded) { free (macro_args[i].expanded); macro_args[i].expanded = NULL; } if (macro_args[i].virt_locs) { free (macro_args[i].virt_locs); macro_args[i].virt_locs = NULL; } if (macro_args[i].expanded_virt_locs) { free (macro_args[i].expanded_virt_locs); macro_args[i].expanded_virt_locs = NULL; } } _cpp_free_buff (buff); } /* Set the INDEXth token of the macro argument ARG. TOKEN is the token to set, LOCATION is its virtual location. "Virtual" location means the location that encodes loci across macro expansion. Otherwise it has to be TOKEN->SRC_LOC. KIND is the kind of tokens the argument ARG is supposed to contain. Note that ARG must be tailored so that it has enough room to contain INDEX + 1 numbers of tokens, at least. */ static void set_arg_token (macro_arg *arg, const cpp_token *token, source_location location, size_t index, enum macro_arg_token_kind kind, bool track_macro_exp_p) { const cpp_token **token_ptr; source_location *loc = NULL; token_ptr = arg_token_ptr_at (arg, index, kind, track_macro_exp_p ? &loc : NULL); *token_ptr = token; if (loc != NULL) { #ifdef ENABLE_CHECKING if (kind == MACRO_ARG_TOKEN_STRINGIFIED || !track_macro_exp_p) /* We can't set the location of a stringified argument token and we can't set any location if we aren't tracking macro expansion locations. */ abort (); #endif *loc = location; } } /* Get the pointer to the location of the argument token of the function-like macro argument ARG. This function must be called only when we -ftrack-macro-expansion is on. */ static const source_location * get_arg_token_location (const macro_arg *arg, enum macro_arg_token_kind kind) { const source_location *loc = NULL; const cpp_token **token_ptr = arg_token_ptr_at (arg, 0, kind, (source_location **) &loc); if (token_ptr == NULL) return NULL; return loc; } /* Return the pointer to the INDEXth token of the macro argument ARG. KIND specifies the kind of token the macro argument ARG contains. If VIRT_LOCATION is non NULL, *VIRT_LOCATION is set to the address of the virtual location of the returned token if the -ftrack-macro-expansion flag is on; otherwise, it's set to the spelling location of the returned token. */ static const cpp_token ** arg_token_ptr_at (const macro_arg *arg, size_t index, enum macro_arg_token_kind kind, source_location **virt_location) { const cpp_token **tokens_ptr = NULL; switch (kind) { case MACRO_ARG_TOKEN_NORMAL: tokens_ptr = arg->first; break; case MACRO_ARG_TOKEN_STRINGIFIED: tokens_ptr = (const cpp_token **) &arg->stringified; break; case MACRO_ARG_TOKEN_EXPANDED: tokens_ptr = arg->expanded; break; } if (tokens_ptr == NULL) /* This can happen for e.g, an empty token argument to a funtion-like macro. */ return tokens_ptr; if (virt_location) { if (kind == MACRO_ARG_TOKEN_NORMAL) *virt_location = &arg->virt_locs[index]; else if (kind == MACRO_ARG_TOKEN_EXPANDED) *virt_location = &arg->expanded_virt_locs[index]; else if (kind == MACRO_ARG_TOKEN_STRINGIFIED) *virt_location = (source_location *) &tokens_ptr[index]->src_loc; } return &tokens_ptr[index]; } /* Initialize an iterator so that it iterates over the tokens of a function-like macro argument. KIND is the kind of tokens we want ITER to iterate over. TOKEN_PTR points the first token ITER will iterate over. */ static void macro_arg_token_iter_init (macro_arg_token_iter *iter, bool track_macro_exp_p, enum macro_arg_token_kind kind, const macro_arg *arg, const cpp_token **token_ptr) { iter->track_macro_exp_p = track_macro_exp_p; iter->kind = kind; iter->token_ptr = token_ptr; /* Unconditionally initialize this so that the compiler doesn't warn about iter->location_ptr being possibly uninitialized later after this code has been inlined somewhere. */ iter->location_ptr = NULL; if (track_macro_exp_p) iter->location_ptr = get_arg_token_location (arg, kind); #ifdef ENABLE_CHECKING iter->num_forwards = 0; if (track_macro_exp_p && token_ptr != NULL && iter->location_ptr == NULL) abort (); #endif } /* Move the iterator one token forward. Note that if IT was initialized on an argument that has a stringified token, moving it forward doesn't make sense as a stringified token is essentially one string. */ static void macro_arg_token_iter_forward (macro_arg_token_iter *it) { switch (it->kind) { case MACRO_ARG_TOKEN_NORMAL: case MACRO_ARG_TOKEN_EXPANDED: it->token_ptr++; if (it->track_macro_exp_p) it->location_ptr++; break; case MACRO_ARG_TOKEN_STRINGIFIED: #ifdef ENABLE_CHECKING if (it->num_forwards > 0) abort (); #endif break; } #ifdef ENABLE_CHECKING it->num_forwards++; #endif } /* Return the token pointed to by the iterator. */ static const cpp_token * macro_arg_token_iter_get_token (const macro_arg_token_iter *it) { #ifdef ENABLE_CHECKING if (it->kind == MACRO_ARG_TOKEN_STRINGIFIED && it->num_forwards > 0) abort (); #endif if (it->token_ptr == NULL) return NULL; return *it->token_ptr; } /* Return the location of the token pointed to by the iterator.*/ static source_location macro_arg_token_iter_get_location (const macro_arg_token_iter *it) { #ifdef ENABLE_CHECKING if (it->kind == MACRO_ARG_TOKEN_STRINGIFIED && it->num_forwards > 0) abort (); #endif if (it->track_macro_exp_p) return *it->location_ptr; else return (*it->token_ptr)->src_loc; } /* Return the index of a token [resulting from macro expansion] inside the total list of tokens resulting from a given macro expansion. The index can be different depending on whether if we want each tokens resulting from function-like macro arguments expansion to have a different location or not. E.g, consider this function-like macro: #define M(x) x - 3 Then consider us "calling" it (and thus expanding it) like: M(1+4) It will be expanded into: 1+4-3 Let's consider the case of the token '4'. Its index can be 2 (it's the third token of the set of tokens resulting from the expansion) or it can be 0 if we consider that all tokens resulting from the expansion of the argument "1+2" have the same index, which is 0. In this later case, the index of token '-' would then be 1 and the index of token '3' would be 2. The later case is useful to use less memory e.g, for the case of the user using the option -ftrack-macro-expansion=1. ABSOLUTE_TOKEN_INDEX is the index of the macro argument token we are interested in. CUR_REPLACEMENT_TOKEN is the token of the macro parameter (inside the macro replacement list) that corresponds to the macro argument for which ABSOLUTE_TOKEN_INDEX is a token index of. If we refer to the example above, for the '4' argument token, ABSOLUTE_TOKEN_INDEX would be set to 2, and CUR_REPLACEMENT_TOKEN would be set to the token 'x', in the replacement list "x - 3" of macro M. This is a subroutine of replace_args. */ inline static unsigned expanded_token_index (cpp_reader *pfile, cpp_macro *macro, const cpp_token *cur_replacement_token, unsigned absolute_token_index) { if (CPP_OPTION (pfile, track_macro_expansion) > 1) return absolute_token_index; return cur_replacement_token - macro->exp.tokens; } /* Replace the parameters in a function-like macro of NODE with the actual ARGS, and place the result in a newly pushed token context. Expand each argument before replacing, unless it is operated upon by the # or ## operators. EXPANSION_POINT_LOC is the location of the expansion point of the macro. E.g, the location of the function-like macro invocation. */ static void replace_args (cpp_reader *pfile, cpp_hashnode *node, cpp_macro *macro, macro_arg *args, source_location expansion_point_loc) { unsigned int i, total; const cpp_token *src, *limit; const cpp_token **first = NULL; macro_arg *arg; _cpp_buff *buff = NULL; source_location *virt_locs = NULL; unsigned int exp_count; const struct line_map *map = NULL; int track_macro_exp; /* First, fully macro-expand arguments, calculating the number of tokens in the final expansion as we go. The ordering of the if statements below is subtle; we must handle stringification before pasting. */ /* EXP_COUNT is the number of tokens in the macro replacement list. TOTAL is the number of tokens /after/ macro parameters have been replaced by their arguments. */ exp_count = macro_real_token_count (macro); total = exp_count; limit = macro->exp.tokens + exp_count; for (src = macro->exp.tokens; src < limit; src++) if (src->type == CPP_MACRO_ARG) { /* Leading and trailing padding tokens. */ total += 2; /* Account for leading and padding tokens in exp_count too. This is going to be important later down this function, when we want to handle the case of (track_macro_exp < 2). */ exp_count += 2; /* We have an argument. If it is not being stringified or pasted it is macro-replaced before insertion. */ arg = &args[src->val.macro_arg.arg_no - 1]; if (src->flags & STRINGIFY_ARG) { if (!arg->stringified) arg->stringified = stringify_arg (pfile, arg); } else if ((src->flags & PASTE_LEFT) || (src > macro->exp.tokens && (src[-1].flags & PASTE_LEFT))) total += arg->count - 1; else { if (!arg->expanded) expand_arg (pfile, arg); total += arg->expanded_count - 1; } } /* When the compiler is called with the -ftrack-macro-expansion flag, we need to keep track of the location of each token that results from macro expansion. A token resulting from macro expansion is not a new token. It is simply the same token as the token coming from the macro definition. The new things that are allocated are the buffer that holds the tokens resulting from macro expansion and a new location that records many things like the locus of the expansion point as well as the original locus inside the definition of the macro. This location is called a virtual location. So the buffer BUFF holds a set of cpp_token*, and the buffer VIRT_LOCS holds the virtual locations of the tokens held by BUFF. Both of these two buffers are going to be hung off of the macro context, when the latter is pushed. The memory allocated to store the tokens and their locations is going to be freed once the context of macro expansion is popped. As far as tokens are concerned, the memory overhead of -ftrack-macro-expansion is proportional to the number of macros that get expanded multiplied by sizeof (source_location). The good news is that extra memory gets freed when the macro context is freed, i.e shortly after the macro got expanded. */ /* Is the -ftrack-macro-expansion flag in effect? */ track_macro_exp = CPP_OPTION (pfile, track_macro_expansion); /* Now allocate memory space for tokens and locations resulting from the macro expansion, copy the tokens and replace the arguments. This memory must be freed when the context of the macro MACRO is popped. */ buff = tokens_buff_new (pfile, total, track_macro_exp ? &virt_locs : NULL); first = (const cpp_token **) buff->base; /* Create a macro map to record the locations of the tokens that are involved in the expansion. Note that the expansion point is set to the location of the closing parenthesis. Otherwise, the subsequent map created for the first token that comes after the macro map might have a wrong line number. That would lead to tokens with wrong line numbers after the macro expansion. This adds up to the memory overhead of the -ftrack-macro-expansion flag; for every macro that is expanded, a "macro map" is created. */ if (track_macro_exp) { int num_macro_tokens = total; if (track_macro_exp < 2) /* Then the number of macro tokens won't take in account the fact that function-like macro arguments can expand to multiple tokens. This is to save memory at the expense of accuracy. Suppose we have #define SQARE(A) A * A And then we do SQARE(2+3) Then the tokens 2, +, 3, will have the same location, saying they come from the expansion of the argument A. */ num_macro_tokens = exp_count; map = linemap_enter_macro (pfile->line_table, node, expansion_point_loc, num_macro_tokens); } i = 0; for (src = macro->exp.tokens; src < limit; src++) { unsigned int arg_tokens_count; macro_arg_token_iter from; const cpp_token **paste_flag = NULL; const cpp_token **tmp_token_ptr; if (src->type != CPP_MACRO_ARG) { /* Allocate a virtual location for token SRC, and add that token and its virtual location into the buffers BUFF and VIRT_LOCS. */ unsigned index = expanded_token_index (pfile, macro, src, i); tokens_buff_add_token (buff, virt_locs, src, src->src_loc, src->src_loc, map, index); i += 1; continue; } paste_flag = 0; arg = &args[src->val.macro_arg.arg_no - 1]; /* SRC is a macro parameter that we need to replace with its corresponding argument. So at some point we'll need to iterate over the tokens of the macro argument and copy them into the "place" now holding the correspondig macro parameter. We are going to use the iterator type macro_argo_token_iter to handle that iterating. The 'if' below is to initialize the iterator depending on the type of tokens the macro argument has. It also does some adjustment related to padding tokens and some pasting corner cases. */ if (src->flags & STRINGIFY_ARG) { arg_tokens_count = 1; macro_arg_token_iter_init (&from, CPP_OPTION (pfile, track_macro_expansion), MACRO_ARG_TOKEN_STRINGIFIED, arg, &arg->stringified); } else if (src->flags & PASTE_LEFT) { arg_tokens_count = arg->count; macro_arg_token_iter_init (&from, CPP_OPTION (pfile, track_macro_expansion), MACRO_ARG_TOKEN_NORMAL, arg, arg->first); } else if (src != macro->exp.tokens && (src[-1].flags & PASTE_LEFT)) { int num_toks; arg_tokens_count = arg->count; macro_arg_token_iter_init (&from, CPP_OPTION (pfile, track_macro_expansion), MACRO_ARG_TOKEN_NORMAL, arg, arg->first); num_toks = tokens_buff_count (buff); if (num_toks != 0) { /* So the current parameter token is pasted to the previous token in the replacement list. Let's look at what we have as previous and current arguments. */ /* This is the previous argument's token ... */ tmp_token_ptr = tokens_buff_last_token_ptr (buff); if ((*tmp_token_ptr)->type == CPP_COMMA && macro->variadic && src->val.macro_arg.arg_no == macro->paramc) { /* ... which is a comma; and the current parameter is the last parameter of a variadic function-like macro. If the argument to the current last parameter is NULL, then swallow the comma, otherwise drop the paste flag. */ if (macro_arg_token_iter_get_token (&from) == NULL) tokens_buff_remove_last_token (buff); else paste_flag = tmp_token_ptr; } /* Remove the paste flag if the RHS is a placemarker. */ else if (arg_tokens_count == 0) paste_flag = tmp_token_ptr; } } else { arg_tokens_count = arg->expanded_count; macro_arg_token_iter_init (&from, CPP_OPTION (pfile, track_macro_expansion), MACRO_ARG_TOKEN_EXPANDED, arg, arg->expanded); } /* Padding on the left of an argument (unless RHS of ##). */ if ((!pfile->state.in_directive || pfile->state.directive_wants_padding) && src != macro->exp.tokens && !(src[-1].flags & PASTE_LEFT)) { const cpp_token *t = padding_token (pfile, src); unsigned index = expanded_token_index (pfile, macro, src, i); /* Allocate a virtual location for the padding token and append the token and its location to BUFF and VIRT_LOCS. */ tokens_buff_add_token (buff, virt_locs, t, t->src_loc, t->src_loc, map, index); } if (arg_tokens_count) { /* So now we've got the number of tokens that make up the argument that is going to replace the current parameter in the macro's replacement list. */ unsigned int j; for (j = 0; j < arg_tokens_count; ++j) { /* So if track_macro_exp is < 2, the user wants to save extra memory while tracking macro expansion locations. So in that case here is what we do: Suppose we have #define SQARE(A) A * A And then we do SQARE(2+3) Then the tokens 2, +, 3, will have the same location, saying they come from the expansion of the argument A. So that means we are going to ignore the COUNT tokens resulting from the expansion of the current macro arugment. In other words all the ARG_TOKENS_COUNT tokens resulting from the expansion of the macro argument will have the index I. Normally, each of those token should have index I+J. */ unsigned token_index = i; unsigned index; if (track_macro_exp > 1) token_index += j; index = expanded_token_index (pfile, macro, src, token_index); tokens_buff_add_token (buff, virt_locs, macro_arg_token_iter_get_token (&from), macro_arg_token_iter_get_location (&from), src->src_loc, map, index); macro_arg_token_iter_forward (&from); } /* With a non-empty argument on the LHS of ##, the last token should be flagged PASTE_LEFT. */ if (src->flags & PASTE_LEFT) paste_flag = (const cpp_token **) tokens_buff_last_token_ptr (buff); } else if (CPP_PEDANTIC (pfile) && ! CPP_OPTION (pfile, c99) && ! macro->syshdr && ! cpp_in_system_header (pfile)) { if (CPP_OPTION (pfile, cplusplus)) cpp_pedwarning (pfile, CPP_W_PEDANTIC, "invoking macro %s argument %d: " "empty macro arguments are undefined" " in ISO C++98", NODE_NAME (node), src->val.macro_arg.arg_no); else if (CPP_OPTION (pfile, cpp_warn_c90_c99_compat)) cpp_pedwarning (pfile, CPP_OPTION (pfile, cpp_warn_c90_c99_compat) > 0 ? CPP_W_C90_C99_COMPAT : CPP_W_PEDANTIC, "invoking macro %s argument %d: " "empty macro arguments are undefined" " in ISO C90", NODE_NAME (node), src->val.macro_arg.arg_no); } else if (CPP_OPTION (pfile, cpp_warn_c90_c99_compat) > 0 && ! CPP_OPTION (pfile, cplusplus) && ! macro->syshdr && ! cpp_in_system_header (pfile)) cpp_warning (pfile, CPP_W_C90_C99_COMPAT, "invoking macro %s argument %d: " "empty macro arguments are undefined" " in ISO C90", NODE_NAME (node), src->val.macro_arg.arg_no); /* Avoid paste on RHS (even case count == 0). */ if (!pfile->state.in_directive && !(src->flags & PASTE_LEFT)) { const cpp_token *t = &pfile->avoid_paste; tokens_buff_add_token (buff, virt_locs, t, t->src_loc, t->src_loc, NULL, 0); } /* Add a new paste flag, or remove an unwanted one. */ if (paste_flag) { cpp_token *token = _cpp_temp_token (pfile); token->type = (*paste_flag)->type; token->val = (*paste_flag)->val; if (src->flags & PASTE_LEFT) token->flags = (*paste_flag)->flags | PASTE_LEFT; else token->flags = (*paste_flag)->flags & ~PASTE_LEFT; *paste_flag = token; } i += arg_tokens_count; } if (track_macro_exp) push_extended_tokens_context (pfile, node, buff, virt_locs, first, tokens_buff_count (buff)); else push_ptoken_context (pfile, node, buff, first, tokens_buff_count (buff)); num_macro_tokens_counter += tokens_buff_count (buff); } /* Return a special padding token, with padding inherited from SOURCE. */ static const cpp_token * padding_token (cpp_reader *pfile, const cpp_token *source) { cpp_token *result = _cpp_temp_token (pfile); result->type = CPP_PADDING; /* Data in GCed data structures cannot be made const so far, so we need a cast here. */ result->val.source = (cpp_token *) source; result->flags = 0; return result; } /* Get a new uninitialized context. Create a new one if we cannot re-use an old one. */ static cpp_context * next_context (cpp_reader *pfile) { cpp_context *result = pfile->context->next; if (result == 0) { result = XNEW (cpp_context); memset (result, 0, sizeof (cpp_context)); result->prev = pfile->context; result->next = 0; pfile->context->next = result; } pfile->context = result; return result; } /* Push a list of pointers to tokens. */ static void push_ptoken_context (cpp_reader *pfile, cpp_hashnode *macro, _cpp_buff *buff, const cpp_token **first, unsigned int count) { cpp_context *context = next_context (pfile); context->tokens_kind = TOKENS_KIND_INDIRECT; context->c.macro = macro; context->buff = buff; FIRST (context).ptoken = first; LAST (context).ptoken = first + count; } /* Push a list of tokens. A NULL macro means that we should continue the current macro expansion, in essence. That means that if we are currently in a macro expansion context, we'll make the new pfile->context refer to the current macro. */ void _cpp_push_token_context (cpp_reader *pfile, cpp_hashnode *macro, const cpp_token *first, unsigned int count) { cpp_context *context; if (macro == NULL) macro = macro_of_context (pfile->context); context = next_context (pfile); context->tokens_kind = TOKENS_KIND_DIRECT; context->c.macro = macro; context->buff = NULL; FIRST (context).token = first; LAST (context).token = first + count; } /* Build a context containing a list of tokens as well as their virtual locations and push it. TOKENS_BUFF is the buffer that contains the tokens pointed to by FIRST. If TOKENS_BUFF is non-NULL, it means that the context owns it, meaning that _cpp_pop_context will free it as well as VIRT_LOCS_BUFF that contains the virtual locations. A NULL macro means that we should continue the current macro expansion, in essence. That means that if we are currently in a macro expansion context, we'll make the new pfile->context refer to the current macro. */ static void push_extended_tokens_context (cpp_reader *pfile, cpp_hashnode *macro, _cpp_buff *token_buff, source_location *virt_locs, const cpp_token **first, unsigned int count) { cpp_context *context; macro_context *m; if (macro == NULL) macro = macro_of_context (pfile->context); context = next_context (pfile); context->tokens_kind = TOKENS_KIND_EXTENDED; context->buff = token_buff; m = XNEW (macro_context); m->macro_node = macro; m->virt_locs = virt_locs; m->cur_virt_loc = virt_locs; context->c.mc = m; FIRST (context).ptoken = first; LAST (context).ptoken = first + count; } /* Push a traditional macro's replacement text. */ void _cpp_push_text_context (cpp_reader *pfile, cpp_hashnode *macro, const uchar *start, size_t len) { cpp_context *context = next_context (pfile); context->tokens_kind = TOKENS_KIND_DIRECT; context->c.macro = macro; context->buff = NULL; CUR (context) = start; RLIMIT (context) = start + len; macro->flags |= NODE_DISABLED; } /* Creates a buffer that holds tokens a.k.a "token buffer", usually for the purpose of storing them on a cpp_context. If VIRT_LOCS is non-null (which means that -ftrack-macro-expansion is on), *VIRT_LOCS is set to a newly allocated buffer that is supposed to hold the virtual locations of the tokens resulting from macro expansion. */ static _cpp_buff* tokens_buff_new (cpp_reader *pfile, size_t len, source_location **virt_locs) { size_t tokens_size = len * sizeof (cpp_token *); size_t locs_size = len * sizeof (source_location); if (virt_locs != NULL) *virt_locs = XNEWVEC (source_location, locs_size); return _cpp_get_buff (pfile, tokens_size); } /* Returns the number of tokens contained in a token buffer. The buffer holds a set of cpp_token*. */ static size_t tokens_buff_count (_cpp_buff *buff) { return (BUFF_FRONT (buff) - buff->base) / sizeof (cpp_token *); } /* Return a pointer to the last token contained in the token buffer BUFF. */ static const cpp_token ** tokens_buff_last_token_ptr (_cpp_buff *buff) { return &((const cpp_token **) BUFF_FRONT (buff))[-1]; } /* Remove the last token contained in the token buffer TOKENS_BUFF. If VIRT_LOCS_BUFF is non-NULL, it should point at the buffer containing the virtual locations of the tokens in TOKENS_BUFF; in which case the function updates that buffer as well. */ static inline void tokens_buff_remove_last_token (_cpp_buff *tokens_buff) { if (BUFF_FRONT (tokens_buff) > tokens_buff->base) BUFF_FRONT (tokens_buff) = (unsigned char *) &((cpp_token **) BUFF_FRONT (tokens_buff))[-1]; } /* Insert a token into the token buffer at the position pointed to by DEST. Note that the buffer is not enlarged so the previous token that was at *DEST is overwritten. VIRT_LOC_DEST, if non-null, means -ftrack-macro-expansion is effect; it then points to where to insert the virtual location of TOKEN. TOKEN is the token to insert. VIRT_LOC is the virtual location of the token, i.e, the location possibly encoding its locus across macro expansion. If TOKEN is an argument of a function-like macro (inside a macro replacement list), PARM_DEF_LOC is the spelling location of the macro parameter that TOKEN is replacing, in the replacement list of the macro. If TOKEN is not an argument of a function-like macro or if it doesn't come from a macro expansion, then VIRT_LOC can just be set to the same value as PARM_DEF_LOC. If MAP is non null, it means TOKEN comes from a macro expansion and MAP is the macro map associated to the macro. MACRO_TOKEN_INDEX points to the index of the token in the macro map; it is not considered if MAP is NULL. Upon successful completion this function returns the a pointer to the position of the token coming right after the insertion point. */ static inline const cpp_token ** tokens_buff_put_token_to (const cpp_token **dest, source_location *virt_loc_dest, const cpp_token *token, source_location virt_loc, source_location parm_def_loc, const struct line_map *map, unsigned int macro_token_index) { source_location macro_loc = virt_loc; const cpp_token **result; if (virt_loc_dest) { /* -ftrack-macro-expansion is on. */ if (map) macro_loc = linemap_add_macro_token (map, macro_token_index, virt_loc, parm_def_loc); *virt_loc_dest = macro_loc; } *dest = token; result = &dest[1]; return result; } /* Adds a token at the end of the tokens contained in BUFFER. Note that this function doesn't enlarge BUFFER when the number of tokens reaches BUFFER's size; it aborts in that situation. TOKEN is the token to append. VIRT_LOC is the virtual location of the token, i.e, the location possibly encoding its locus across macro expansion. If TOKEN is an argument of a function-like macro (inside a macro replacement list), PARM_DEF_LOC is the location of the macro parameter that TOKEN is replacing. If TOKEN doesn't come from a macro expansion, then VIRT_LOC can just be set to the same value as PARM_DEF_LOC. If MAP is non null, it means TOKEN comes from a macro expansion and MAP is the macro map associated to the macro. MACRO_TOKEN_INDEX points to the index of the token in the macro map; It is not considered if MAP is NULL. If VIRT_LOCS is non-null, it means -ftrack-macro-expansion is on; in which case this function adds the virtual location DEF_LOC to the VIRT_LOCS array, at the same index as the one of TOKEN in BUFFER. Upon successful completion this function returns the a pointer to the position of the token coming right after the insertion point. */ static const cpp_token ** tokens_buff_add_token (_cpp_buff *buffer, source_location *virt_locs, const cpp_token *token, source_location virt_loc, source_location parm_def_loc, const struct line_map *map, unsigned int macro_token_index) { const cpp_token **result; source_location *virt_loc_dest = NULL; unsigned token_index = (BUFF_FRONT (buffer) - buffer->base) / sizeof (cpp_token *); /* Abort if we pass the end the buffer. */ if (BUFF_FRONT (buffer) > BUFF_LIMIT (buffer)) abort (); if (virt_locs != NULL) virt_loc_dest = &virt_locs[token_index]; result = tokens_buff_put_token_to ((const cpp_token **) BUFF_FRONT (buffer), virt_loc_dest, token, virt_loc, parm_def_loc, map, macro_token_index); BUFF_FRONT (buffer) = (unsigned char *) result; return result; } /* Allocate space for the function-like macro argument ARG to store the tokens resulting from the macro-expansion of the tokens that make up ARG itself. That space is allocated in ARG->expanded and needs to be freed using free. */ static void alloc_expanded_arg_mem (cpp_reader *pfile, macro_arg *arg, size_t capacity) { #ifdef ENABLE_CHECKING if (arg->expanded != NULL || arg->expanded_virt_locs != NULL) abort (); #endif arg->expanded = XNEWVEC (const cpp_token *, capacity); if (CPP_OPTION (pfile, track_macro_expansion)) arg->expanded_virt_locs = XNEWVEC (source_location, capacity); } /* If necessary, enlarge ARG->expanded to so that it can contain SIZE tokens. */ static void ensure_expanded_arg_room (cpp_reader *pfile, macro_arg *arg, size_t size, size_t *expanded_capacity) { if (size <= *expanded_capacity) return; size *= 2; arg->expanded = XRESIZEVEC (const cpp_token *, arg->expanded, size); *expanded_capacity = size; if (CPP_OPTION (pfile, track_macro_expansion)) { if (arg->expanded_virt_locs == NULL) arg->expanded_virt_locs = XNEWVEC (source_location, size); else arg->expanded_virt_locs = XRESIZEVEC (source_location, arg->expanded_virt_locs, size); } } /* Expand an argument ARG before replacing parameters in a function-like macro. This works by pushing a context with the argument's tokens, and then expanding that into a temporary buffer as if it were a normal part of the token stream. collect_args() has terminated the argument's tokens with a CPP_EOF so that we know when we have fully expanded the argument. */ static void expand_arg (cpp_reader *pfile, macro_arg *arg) { size_t capacity; bool saved_warn_trad; bool track_macro_exp_p = CPP_OPTION (pfile, track_macro_expansion); if (arg->count == 0 || arg->expanded != NULL) return; /* Don't warn about funlike macros when pre-expanding. */ saved_warn_trad = CPP_WTRADITIONAL (pfile); CPP_WTRADITIONAL (pfile) = 0; /* Loop, reading in the tokens of the argument. */ capacity = 256; alloc_expanded_arg_mem (pfile, arg, capacity); if (track_macro_exp_p) push_extended_tokens_context (pfile, NULL, NULL, arg->virt_locs, arg->first, arg->count + 1); else push_ptoken_context (pfile, NULL, NULL, arg->first, arg->count + 1); for (;;) { const cpp_token *token; source_location location; ensure_expanded_arg_room (pfile, arg, arg->expanded_count + 1, &capacity); token = cpp_get_token_1 (pfile, &location); if (token->type == CPP_EOF) break; set_arg_token (arg, token, location, arg->expanded_count, MACRO_ARG_TOKEN_EXPANDED, CPP_OPTION (pfile, track_macro_expansion)); arg->expanded_count++; } _cpp_pop_context (pfile); CPP_WTRADITIONAL (pfile) = saved_warn_trad; } /* Returns the macro associated to the current context if we are in the context a macro expansion, NULL otherwise. */ static cpp_hashnode* macro_of_context (cpp_context *context) { if (context == NULL) return NULL; return (context->tokens_kind == TOKENS_KIND_EXTENDED) ? context->c.mc->macro_node : context->c.macro; } /* Return TRUE iff we are expanding a macro or are about to start expanding one. If we are effectively expanding a macro, the function macro_of_context returns a pointer to the macro being expanded. */ static bool in_macro_expansion_p (cpp_reader *pfile) { if (pfile == NULL) return false; return (pfile->about_to_expand_macro_p || macro_of_context (pfile->context)); } /* Pop the current context off the stack, re-enabling the macro if the context represented a macro's replacement list. Initially the context structure was not freed so that we can re-use it later, but now we do free it to reduce peak memory consumption. */ void _cpp_pop_context (cpp_reader *pfile) { cpp_context *context = pfile->context; /* We should not be popping the base context. */ if (context == &pfile->base_context) abort (); if (context->c.macro) { cpp_hashnode *macro; if (context->tokens_kind == TOKENS_KIND_EXTENDED) { macro_context *mc = context->c.mc; macro = mc->macro_node; /* If context->buff is set, it means the life time of tokens is bound to the life time of this context; so we must free the tokens; that means we must free the virtual locations of these tokens too. */ if (context->buff && mc->virt_locs) { free (mc->virt_locs); mc->virt_locs = NULL; } free (mc); context->c.mc = NULL; } else macro = context->c.macro; /* Beware that MACRO can be NULL in cases like when we are called from expand_arg. In those cases, a dummy context with tokens is pushed just for the purpose of walking them using cpp_get_token_1. In that case, no 'macro' field is set into the dummy context. */ if (macro != NULL /* Several contiguous macro expansion contexts can be associated to the same macro; that means it's the same macro expansion that spans across all these (sub) contexts. So we should re-enable an expansion-disabled macro only when we are sure we are really out of that macro expansion. */ && macro_of_context (context->prev) != macro) macro->flags &= ~NODE_DISABLED; } if (context->buff) { /* Decrease memory peak consumption by freeing the memory used by the context. */ _cpp_free_buff (context->buff); } pfile->context = context->prev; /* decrease peak memory consumption by feeing the context. */ pfile->context->next = NULL; free (context); } /* Return TRUE if we reached the end of the set of tokens stored in CONTEXT, FALSE otherwise. */ static inline bool reached_end_of_context (cpp_context *context) { if (context->tokens_kind == TOKENS_KIND_DIRECT) return FIRST (context).token == LAST (context).token; else if (context->tokens_kind == TOKENS_KIND_INDIRECT || context->tokens_kind == TOKENS_KIND_EXTENDED) return FIRST (context).ptoken == LAST (context).ptoken; else abort (); } /* Consume the next token contained in the current context of PFILE, and return it in *TOKEN. It's "full location" is returned in *LOCATION. If -ftrack-macro-location is in effeect, fFull location" means the location encoding the locus of the token across macro expansion; otherwise it's just is the "normal" location of the token which (*TOKEN)->src_loc. */ static inline void consume_next_token_from_context (cpp_reader *pfile, const cpp_token ** token, source_location *location) { cpp_context *c = pfile->context; if ((c)->tokens_kind == TOKENS_KIND_DIRECT) { *token = FIRST (c).token; *location = (*token)->src_loc; FIRST (c).token++; } else if ((c)->tokens_kind == TOKENS_KIND_INDIRECT) { *token = *FIRST (c).ptoken; *location = (*token)->src_loc; FIRST (c).ptoken++; } else if ((c)->tokens_kind == TOKENS_KIND_EXTENDED) { macro_context *m = c->c.mc; *token = *FIRST (c).ptoken; if (m->virt_locs) { *location = *m->cur_virt_loc; m->cur_virt_loc++; } else *location = (*token)->src_loc; FIRST (c).ptoken++; } else abort (); } /* In the traditional mode of the preprocessor, if we are currently in a directive, the location of a token must be the location of the start of the directive line. This function returns the proper location if we are in the traditional mode, and just returns LOCATION otherwise. */ static inline source_location maybe_adjust_loc_for_trad_cpp (cpp_reader *pfile, source_location location) { if (CPP_OPTION (pfile, traditional)) { if (pfile->state.in_directive) return pfile->directive_line; } return location; } /* Routine to get a token as well as its location. Macro expansions and directives are transparently handled, including entering included files. Thus tokens are post-macro expansion, and after any intervening directives. External callers see CPP_EOF only at EOF. Internal callers also see it when meeting a directive inside a macro call, when at the end of a directive and state.in_directive is still 1, and at the end of argument pre-expansion. LOC is an out parameter; *LOC is set to the location "as expected by the user". Please read the comment of cpp_get_token_with_location to learn more about the meaning of this location. */ static const cpp_token* cpp_get_token_1 (cpp_reader *pfile, source_location *location) { const cpp_token *result; /* This token is a virtual token that either encodes a location related to macro expansion or a spelling location. */ source_location virt_loc = 0; /* pfile->about_to_expand_macro_p can be overriden by indirect calls to functions that push macro contexts. So let's save it so that we can restore it when we are about to leave this routine. */ bool saved_about_to_expand_macro = pfile->about_to_expand_macro_p; for (;;) { cpp_hashnode *node; cpp_context *context = pfile->context; /* Context->prev == 0 <=> base context. */ if (!context->prev) { result = _cpp_lex_token (pfile); virt_loc = result->src_loc; } else if (!reached_end_of_context (context)) { consume_next_token_from_context (pfile, &result, &virt_loc); if (result->flags & PASTE_LEFT) { paste_all_tokens (pfile, result); if (pfile->state.in_directive) continue; result = padding_token (pfile, result); goto out; } } else { if (pfile->context->c.macro) ++num_expanded_macros_counter; _cpp_pop_context (pfile); if (pfile->state.in_directive) continue; result = &pfile->avoid_paste; goto out; } if (pfile->state.in_directive && result->type == CPP_COMMENT) continue; if (result->type != CPP_NAME) break; node = result->val.node.node; if (node->type != NT_MACRO || (result->flags & NO_EXPAND)) break; if (!(node->flags & NODE_DISABLED)) { int ret = 0; /* If not in a macro context, and we're going to start an expansion, record the location. */ if (!in_macro_expansion_p (pfile)) pfile->invocation_location = result->src_loc; if (pfile->state.prevent_expansion) break; /* Conditional macros require that a predicate be evaluated first. */ if ((node->flags & NODE_CONDITIONAL) != 0) { if (pfile->cb.macro_to_expand) { bool whitespace_after; const cpp_token *peek_tok = cpp_peek_token (pfile, 0); whitespace_after = (peek_tok->type == CPP_PADDING || (peek_tok->flags & PREV_WHITE)); node = pfile->cb.macro_to_expand (pfile, result); if (node) ret = enter_macro_context (pfile, node, result, virt_loc); else if (whitespace_after) { /* If macro_to_expand hook returned NULL and it ate some tokens, see if we don't need to add a padding token in between this and the next token. */ peek_tok = cpp_peek_token (pfile, 0); if (peek_tok->type != CPP_PADDING && (peek_tok->flags & PREV_WHITE) == 0) _cpp_push_token_context (pfile, NULL, padding_token (pfile, peek_tok), 1); } } } else ret = enter_macro_context (pfile, node, result, virt_loc); if (ret) { if (pfile->state.in_directive || ret == 2) continue; result = padding_token (pfile, result); goto out; } } else { /* Flag this token as always unexpandable. FIXME: move this to collect_args()?. */ cpp_token *t = _cpp_temp_token (pfile); t->type = result->type; t->flags = result->flags | NO_EXPAND; t->val = result->val; result = t; } break; } out: if (location != NULL) { if (virt_loc == 0) virt_loc = result->src_loc; *location = virt_loc; if (!CPP_OPTION (pfile, track_macro_expansion) && macro_of_context (pfile->context) != NULL) /* We are in a macro expansion context, are not tracking virtual location, but were asked to report the location of the expansion point of the macro being expanded. */ *location = pfile->invocation_location; *location = maybe_adjust_loc_for_trad_cpp (pfile, *location); } pfile->about_to_expand_macro_p = saved_about_to_expand_macro; return result; } /* External routine to get a token. Also used nearly everywhere internally, except for places where we know we can safely call _cpp_lex_token directly, such as lexing a directive name. Macro expansions and directives are transparently handled, including entering included files. Thus tokens are post-macro expansion, and after any intervening directives. External callers see CPP_EOF only at EOF. Internal callers also see it when meeting a directive inside a macro call, when at the end of a directive and state.in_directive is still 1, and at the end of argument pre-expansion. */ const cpp_token * cpp_get_token (cpp_reader *pfile) { return cpp_get_token_1 (pfile, NULL); } /* Like cpp_get_token, but also returns a virtual token location separate from the spelling location carried by the returned token. LOC is an out parameter; *LOC is set to the location "as expected by the user". This matters when a token results from macro expansion; in that case the token's spelling location indicates the locus of the token in the definition of the macro but *LOC virtually encodes all the other meaningful locuses associated to the token. What? virtual location? Yes, virtual location. If the token results from macro expansion and if macro expansion location tracking is enabled its virtual location encodes (at the same time): - the spelling location of the token - the locus of the macro expansion point - the locus of the point where the token got instantiated as part of the macro expansion process. You have to use the linemap API to get the locus you are interested in from a given virtual location. Note however that virtual locations are not necessarily ordered for relations '<' and '>'. One must use the function linemap_location_before_p instead of using the relational operator '<'. If macro expansion tracking is off and if the token results from macro expansion the virtual location is the expansion point of the macro that got expanded. When the token doesn't result from macro expansion, the virtual location is just the same thing as its spelling location. */ const cpp_token * cpp_get_token_with_location (cpp_reader *pfile, source_location *loc) { return cpp_get_token_1 (pfile, loc); } /* Returns true if we're expanding an object-like macro that was defined in a system header. Just checks the macro at the top of the stack. Used for diagnostic suppression. */ int cpp_sys_macro_p (cpp_reader *pfile) { cpp_hashnode *node = NULL; if (pfile->context->tokens_kind == TOKENS_KIND_EXTENDED) node = pfile->context->c.mc->macro_node; else node = pfile->context->c.macro; return node && node->value.macro && node->value.macro->syshdr; } /* Read each token in, until end of the current file. Directives are transparently processed. */ void cpp_scan_nooutput (cpp_reader *pfile) { /* Request a CPP_EOF token at the end of this file, rather than transparently continuing with the including file. */ pfile->buffer->return_at_eof = true; pfile->state.discarding_output++; pfile->state.prevent_expansion++; if (CPP_OPTION (pfile, traditional)) while (_cpp_read_logical_line_trad (pfile)) ; else while (cpp_get_token (pfile)->type != CPP_EOF) ; pfile->state.discarding_output--; pfile->state.prevent_expansion--; } /* Step back one or more tokens obtained from the lexer. */ void _cpp_backup_tokens_direct (cpp_reader *pfile, unsigned int count) { pfile->lookaheads += count; while (count--) { pfile->cur_token--; if (pfile->cur_token == pfile->cur_run->base /* Possible with -fpreprocessed and no leading #line. */ && pfile->cur_run->prev != NULL) { pfile->cur_run = pfile->cur_run->prev; pfile->cur_token = pfile->cur_run->limit; } } } /* Step back one (or more) tokens. Can only step back more than 1 if they are from the lexer, and not from macro expansion. */ void _cpp_backup_tokens (cpp_reader *pfile, unsigned int count) { if (pfile->context->prev == NULL) _cpp_backup_tokens_direct (pfile, count); else { if (count != 1) abort (); if (pfile->context->tokens_kind == TOKENS_KIND_DIRECT) FIRST (pfile->context).token--; else if (pfile->context->tokens_kind == TOKENS_KIND_INDIRECT) FIRST (pfile->context).ptoken--; else if (pfile->context->tokens_kind == TOKENS_KIND_EXTENDED) { FIRST (pfile->context).ptoken--; if (pfile->context->c.macro) { macro_context *m = pfile->context->c.mc; m->cur_virt_loc--; #ifdef ENABLE_CHECKING if (m->cur_virt_loc < m->virt_locs) abort (); #endif } else abort (); } else abort (); } } /* #define directive parsing and handling. */ /* Returns nonzero if a macro redefinition warning is required. */ static bool warn_of_redefinition (cpp_reader *pfile, cpp_hashnode *node, const cpp_macro *macro2) { const cpp_macro *macro1; unsigned int i; /* Some redefinitions need to be warned about regardless. */ if (node->flags & NODE_WARN) return true; /* Suppress warnings for builtins that lack the NODE_WARN flag, unless Wbuiltin-macro-redefined. */ if (node->flags & NODE_BUILTIN && (!pfile->cb.user_builtin_macro || !pfile->cb.user_builtin_macro (pfile, node))) return CPP_OPTION (pfile, warn_builtin_macro_redefined); /* Redefinitions of conditional (context-sensitive) macros, on the other hand, must be allowed silently. */ if (node->flags & NODE_CONDITIONAL) return false; /* Redefinition of a macro is allowed if and only if the old and new definitions are the same. (6.10.3 paragraph 2). */ macro1 = node->value.macro; /* Don't check count here as it can be different in valid traditional redefinitions with just whitespace differences. */ if (macro1->paramc != macro2->paramc || macro1->fun_like != macro2->fun_like || macro1->variadic != macro2->variadic) return true; /* Check parameter spellings. */ for (i = 0; i < macro1->paramc; i++) if (macro1->params[i] != macro2->params[i]) return true; /* Check the replacement text or tokens. */ if (CPP_OPTION (pfile, traditional)) return _cpp_expansions_different_trad (macro1, macro2); if (macro1->count != macro2->count) return true; for (i = 0; i < macro1->count; i++) if (!_cpp_equiv_tokens (¯o1->exp.tokens[i], ¯o2->exp.tokens[i])) return true; return false; } /* Free the definition of hashnode H. */ void _cpp_free_definition (cpp_hashnode *h) { /* Macros and assertions no longer have anything to free. */ h->type = NT_VOID; /* Clear builtin flag in case of redefinition. */ h->flags &= ~(NODE_BUILTIN | NODE_DISABLED | NODE_USED); } /* Save parameter NODE (spelling SPELLING) to the parameter list of macro MACRO. Returns zero on success, nonzero if the parameter is a duplicate. */ bool _cpp_save_parameter (cpp_reader *pfile, cpp_macro *macro, cpp_hashnode *node, cpp_hashnode *spelling) { unsigned int len; /* Constraint 6.10.3.6 - duplicate parameter names. */ if (node->flags & NODE_MACRO_ARG) { cpp_error (pfile, CPP_DL_ERROR, "duplicate macro parameter \"%s\"", NODE_NAME (node)); return true; } if (BUFF_ROOM (pfile->a_buff) < (macro->paramc + 1) * sizeof (cpp_hashnode *)) _cpp_extend_buff (pfile, &pfile->a_buff, sizeof (cpp_hashnode *)); ((cpp_hashnode **) BUFF_FRONT (pfile->a_buff))[macro->paramc++] = spelling; node->flags |= NODE_MACRO_ARG; len = macro->paramc * sizeof (struct macro_arg_saved_data); if (len > pfile->macro_buffer_len) { pfile->macro_buffer = XRESIZEVEC (unsigned char, pfile->macro_buffer, len); pfile->macro_buffer_len = len; } struct macro_arg_saved_data save; save.value = node->value; save.canonical_node = node; ((struct macro_arg_saved_data *) pfile->macro_buffer)[macro->paramc - 1] = save; node->value.arg_index = macro->paramc; return false; } /* Check the syntax of the parameters in a MACRO definition. Returns false if an error occurs. */ static bool parse_params (cpp_reader *pfile, cpp_macro *macro) { unsigned int prev_ident = 0; for (;;) { const cpp_token *token = _cpp_lex_token (pfile); switch (token->type) { default: /* Allow/ignore comments in parameter lists if we are preserving comments in macro expansions. */ if (token->type == CPP_COMMENT && ! CPP_OPTION (pfile, discard_comments_in_macro_exp)) continue; cpp_error (pfile, CPP_DL_ERROR, "\"%s\" may not appear in macro parameter list", cpp_token_as_text (pfile, token)); return false; case CPP_NAME: if (prev_ident) { cpp_error (pfile, CPP_DL_ERROR, "macro parameters must be comma-separated"); return false; } prev_ident = 1; if (_cpp_save_parameter (pfile, macro, token->val.node.node, token->val.node.spelling)) return false; continue; case CPP_CLOSE_PAREN: if (prev_ident || macro->paramc == 0) return true; /* Fall through to pick up the error. */ case CPP_COMMA: if (!prev_ident) { cpp_error (pfile, CPP_DL_ERROR, "parameter name missing"); return false; } prev_ident = 0; continue; case CPP_ELLIPSIS: macro->variadic = 1; if (!prev_ident) { _cpp_save_parameter (pfile, macro, pfile->spec_nodes.n__VA_ARGS__, pfile->spec_nodes.n__VA_ARGS__); pfile->state.va_args_ok = 1; if (! CPP_OPTION (pfile, c99) && CPP_OPTION (pfile, cpp_pedantic) && CPP_OPTION (pfile, warn_variadic_macros)) { if (CPP_OPTION (pfile, cplusplus)) cpp_pedwarning (pfile, CPP_W_VARIADIC_MACROS, "anonymous variadic macros were introduced in C++11"); else cpp_pedwarning (pfile, CPP_W_VARIADIC_MACROS, "anonymous variadic macros were introduced in C99"); } else if (CPP_OPTION (pfile, cpp_warn_c90_c99_compat) > 0 && ! CPP_OPTION (pfile, cplusplus)) cpp_error (pfile, CPP_DL_WARNING, "anonymous variadic macros were introduced in C99"); } else if (CPP_OPTION (pfile, cpp_pedantic) && CPP_OPTION (pfile, warn_variadic_macros)) { if (CPP_OPTION (pfile, cplusplus)) cpp_pedwarning (pfile, CPP_W_VARIADIC_MACROS, "ISO C++ does not permit named variadic macros"); else cpp_pedwarning (pfile, CPP_W_VARIADIC_MACROS, "ISO C does not permit named variadic macros"); } /* We're at the end, and just expect a closing parenthesis. */ token = _cpp_lex_token (pfile); if (token->type == CPP_CLOSE_PAREN) return true; /* Fall through. */ case CPP_EOF: cpp_error (pfile, CPP_DL_ERROR, "missing ')' in macro parameter list"); return false; } } } /* Allocate room for a token from a macro's replacement list. */ static cpp_token * alloc_expansion_token (cpp_reader *pfile, cpp_macro *macro) { if (BUFF_ROOM (pfile->a_buff) < (macro->count + 1) * sizeof (cpp_token)) _cpp_extend_buff (pfile, &pfile->a_buff, sizeof (cpp_token)); return &((cpp_token *) BUFF_FRONT (pfile->a_buff))[macro->count++]; } /* Lex a token from the expansion of MACRO, but mark parameters as we find them and warn of traditional stringification. */ static cpp_token * lex_expansion_token (cpp_reader *pfile, cpp_macro *macro) { cpp_token *token, *saved_cur_token; saved_cur_token = pfile->cur_token; pfile->cur_token = alloc_expansion_token (pfile, macro); token = _cpp_lex_direct (pfile); pfile->cur_token = saved_cur_token; /* Is this a parameter? */ if (token->type == CPP_NAME && (token->val.node.node->flags & NODE_MACRO_ARG) != 0) { cpp_hashnode *spelling = token->val.node.spelling; token->type = CPP_MACRO_ARG; token->val.macro_arg.arg_no = token->val.node.node->value.arg_index; token->val.macro_arg.spelling = spelling; } else if (CPP_WTRADITIONAL (pfile) && macro->paramc > 0 && (token->type == CPP_STRING || token->type == CPP_CHAR)) check_trad_stringification (pfile, macro, &token->val.str); return token; } static bool create_iso_definition (cpp_reader *pfile, cpp_macro *macro) { cpp_token *token; const cpp_token *ctoken; bool following_paste_op = false; const char *paste_op_error_msg = N_("'##' cannot appear at either end of a macro expansion"); unsigned int num_extra_tokens = 0; /* Get the first token of the expansion (or the '(' of a function-like macro). */ ctoken = _cpp_lex_token (pfile); if (ctoken->type == CPP_OPEN_PAREN && !(ctoken->flags & PREV_WHITE)) { bool ok = parse_params (pfile, macro); macro->params = (cpp_hashnode **) BUFF_FRONT (pfile->a_buff); if (!ok) return false; /* Success. Commit or allocate the parameter array. */ if (pfile->hash_table->alloc_subobject) { cpp_hashnode **params = (cpp_hashnode **) pfile->hash_table->alloc_subobject (sizeof (cpp_hashnode *) * macro->paramc); memcpy (params, macro->params, sizeof (cpp_hashnode *) * macro->paramc); macro->params = params; } else BUFF_FRONT (pfile->a_buff) = (uchar *) ¯o->params[macro->paramc]; macro->fun_like = 1; } else if (ctoken->type != CPP_EOF && !(ctoken->flags & PREV_WHITE)) { /* While ISO C99 requires whitespace before replacement text in a macro definition, ISO C90 with TC1 allows characters from the basic source character set there. */ if (CPP_OPTION (pfile, c99)) { if (CPP_OPTION (pfile, cplusplus)) cpp_error (pfile, CPP_DL_PEDWARN, "ISO C++11 requires whitespace after the macro name"); else cpp_error (pfile, CPP_DL_PEDWARN, "ISO C99 requires whitespace after the macro name"); } else { int warntype = CPP_DL_WARNING; switch (ctoken->type) { case CPP_ATSIGN: case CPP_AT_NAME: case CPP_OBJC_STRING: /* '@' is not in basic character set. */ warntype = CPP_DL_PEDWARN; break; case CPP_OTHER: /* Basic character set sans letters, digits and _. */ if (strchr ("!\"#%&'()*+,-./:;<=>?[\\]^{|}~", ctoken->val.str.text[0]) == NULL) warntype = CPP_DL_PEDWARN; break; default: /* All other tokens start with a character from basic character set. */ break; } cpp_error (pfile, warntype, "missing whitespace after the macro name"); } } if (macro->fun_like) token = lex_expansion_token (pfile, macro); else { token = alloc_expansion_token (pfile, macro); *token = *ctoken; } for (;;) { /* Check the stringifying # constraint 6.10.3.2.1 of function-like macros when lexing the subsequent token. */ if (macro->count > 1 && token[-1].type == CPP_HASH && macro->fun_like) { if (token->type == CPP_MACRO_ARG) { if (token->flags & PREV_WHITE) token->flags |= SP_PREV_WHITE; if (token[-1].flags & DIGRAPH) token->flags |= SP_DIGRAPH; token->flags &= ~PREV_WHITE; token->flags |= STRINGIFY_ARG; token->flags |= token[-1].flags & PREV_WHITE; token[-1] = token[0]; macro->count--; } /* Let assembler get away with murder. */ else if (CPP_OPTION (pfile, lang) != CLK_ASM) { cpp_error (pfile, CPP_DL_ERROR, "'#' is not followed by a macro parameter"); return false; } } if (token->type == CPP_EOF) { /* Paste operator constraint 6.10.3.3.1: Token-paste ##, can appear in both object-like and function-like macros, but not at the end. */ if (following_paste_op) { cpp_error (pfile, CPP_DL_ERROR, paste_op_error_msg); return false; } break; } /* Paste operator constraint 6.10.3.3.1. */ if (token->type == CPP_PASTE) { /* Token-paste ##, can appear in both object-like and function-like macros, but not at the beginning. */ if (macro->count == 1) { cpp_error (pfile, CPP_DL_ERROR, paste_op_error_msg); return false; } if (token[-1].flags & PASTE_LEFT) { macro->extra_tokens = 1; num_extra_tokens++; token->val.token_no = macro->count - 1; } else { --macro->count; token[-1].flags |= PASTE_LEFT; if (token->flags & DIGRAPH) token[-1].flags |= SP_DIGRAPH; if (token->flags & PREV_WHITE) token[-1].flags |= SP_PREV_WHITE; } } following_paste_op = (token->type == CPP_PASTE); token = lex_expansion_token (pfile, macro); } macro->exp.tokens = (cpp_token *) BUFF_FRONT (pfile->a_buff); macro->traditional = 0; /* Don't count the CPP_EOF. */ macro->count--; /* Clear whitespace on first token for warn_of_redefinition(). */ if (macro->count) macro->exp.tokens[0].flags &= ~PREV_WHITE; /* Commit or allocate the memory. */ if (pfile->hash_table->alloc_subobject) { cpp_token *tokns = (cpp_token *) pfile->hash_table->alloc_subobject (sizeof (cpp_token) * macro->count); if (num_extra_tokens) { /* Place second and subsequent ## or %:%: tokens in sequences of consecutive such tokens at the end of the list to preserve information about where they appear, how they are spelt and whether they are preceded by whitespace without otherwise interfering with macro expansion. */ cpp_token *normal_dest = tokns; cpp_token *extra_dest = tokns + macro->count - num_extra_tokens; unsigned int i; for (i = 0; i < macro->count; i++) { if (macro->exp.tokens[i].type == CPP_PASTE) *extra_dest++ = macro->exp.tokens[i]; else *normal_dest++ = macro->exp.tokens[i]; } } else memcpy (tokns, macro->exp.tokens, sizeof (cpp_token) * macro->count); macro->exp.tokens = tokns; } else BUFF_FRONT (pfile->a_buff) = (uchar *) ¯o->exp.tokens[macro->count]; return true; } /* Parse a macro and save its expansion. Returns nonzero on success. */ bool _cpp_create_definition (cpp_reader *pfile, cpp_hashnode *node) { cpp_macro *macro; unsigned int i; bool ok; if (pfile->hash_table->alloc_subobject) macro = (cpp_macro *) pfile->hash_table->alloc_subobject (sizeof (cpp_macro)); else macro = (cpp_macro *) _cpp_aligned_alloc (pfile, sizeof (cpp_macro)); macro->line = pfile->directive_line; macro->params = 0; macro->paramc = 0; macro->variadic = 0; macro->used = !CPP_OPTION (pfile, warn_unused_macros); macro->count = 0; macro->fun_like = 0; macro->extra_tokens = 0; /* To suppress some diagnostics. */ macro->syshdr = pfile->buffer && pfile->buffer->sysp != 0; if (CPP_OPTION (pfile, traditional)) ok = _cpp_create_trad_definition (pfile, macro); else { ok = create_iso_definition (pfile, macro); /* We set the type for SEEN_EOL() in directives.c. Longer term we should lex the whole line before coming here, and just copy the expansion. */ /* Stop the lexer accepting __VA_ARGS__. */ pfile->state.va_args_ok = 0; } /* Clear the fast argument lookup indices. */ for (i = macro->paramc; i-- > 0; ) { struct macro_arg_saved_data *save = &((struct macro_arg_saved_data *) pfile->macro_buffer)[i]; struct cpp_hashnode *node = save->canonical_node; node->flags &= ~ NODE_MACRO_ARG; node->value = save->value; } if (!ok) return ok; if (node->type == NT_MACRO) { if (CPP_OPTION (pfile, warn_unused_macros)) _cpp_warn_if_unused_macro (pfile, node, NULL); if (warn_of_redefinition (pfile, node, macro)) { const int reason = ((node->flags & NODE_BUILTIN) && !(node->flags & NODE_WARN)) ? CPP_W_BUILTIN_MACRO_REDEFINED : CPP_W_NONE; bool warned = cpp_pedwarning_with_line (pfile, reason, pfile->directive_line, 0, "\"%s\" redefined", NODE_NAME (node)); if (warned && node->type == NT_MACRO && !(node->flags & NODE_BUILTIN)) cpp_error_with_line (pfile, CPP_DL_NOTE, node->value.macro->line, 0, "this is the location of the previous definition"); } } if (node->type != NT_VOID) _cpp_free_definition (node); /* Enter definition in hash table. */ node->type = NT_MACRO; node->value.macro = macro; if (! ustrncmp (NODE_NAME (node), DSC ("__STDC_")) && ustrcmp (NODE_NAME (node), (const uchar *) "__STDC_FORMAT_MACROS") /* __STDC_LIMIT_MACROS and __STDC_CONSTANT_MACROS are mentioned in the C standard, as something that one must use in C++. However DR#593 and C++11 indicate that they play no role in C++. We special-case them anyway. */ && ustrcmp (NODE_NAME (node), (const uchar *) "__STDC_LIMIT_MACROS") && ustrcmp (NODE_NAME (node), (const uchar *) "__STDC_CONSTANT_MACROS")) node->flags |= NODE_WARN; /* If user defines one of the conditional macros, remove the conditional flag */ node->flags &= ~NODE_CONDITIONAL; return ok; } /* Warn if a token in STRING matches one of a function-like MACRO's parameters. */ static void check_trad_stringification (cpp_reader *pfile, const cpp_macro *macro, const cpp_string *string) { unsigned int i, len; const uchar *p, *q, *limit; /* Loop over the string. */ limit = string->text + string->len - 1; for (p = string->text + 1; p < limit; p = q) { /* Find the start of an identifier. */ while (p < limit && !is_idstart (*p)) p++; /* Find the end of the identifier. */ q = p; while (q < limit && is_idchar (*q)) q++; len = q - p; /* Loop over the function macro arguments to see if the identifier inside the string matches one of them. */ for (i = 0; i < macro->paramc; i++) { const cpp_hashnode *node = macro->params[i]; if (NODE_LEN (node) == len && !memcmp (p, NODE_NAME (node), len)) { cpp_error (pfile, CPP_DL_WARNING, "macro argument \"%s\" would be stringified in traditional C", NODE_NAME (node)); break; } } } } /* Returns the name, arguments and expansion of a macro, in a format suitable to be read back in again, and therefore also for DWARF 2 debugging info. e.g. "PASTE(X, Y) X ## Y", or "MACNAME EXPANSION". Caller is expected to generate the "#define" bit if needed. The returned text is temporary, and automatically freed later. */ const unsigned char * cpp_macro_definition (cpp_reader *pfile, cpp_hashnode *node) { unsigned int i, len; const cpp_macro *macro; unsigned char *buffer; if (node->type != NT_MACRO || (node->flags & NODE_BUILTIN)) { if (node->type != NT_MACRO || !pfile->cb.user_builtin_macro || !pfile->cb.user_builtin_macro (pfile, node)) { cpp_error (pfile, CPP_DL_ICE, "invalid hash type %d in cpp_macro_definition", node->type); return 0; } } macro = node->value.macro; /* Calculate length. */ len = NODE_LEN (node) * 10 + 2; /* ' ' and NUL. */ if (macro->fun_like) { len += 4; /* "()" plus possible final ".." of named varargs (we have + 1 below). */ for (i = 0; i < macro->paramc; i++) len += NODE_LEN (macro->params[i]) + 1; /* "," */ } /* This should match below where we fill in the buffer. */ if (CPP_OPTION (pfile, traditional)) len += _cpp_replacement_text_len (macro); else { unsigned int count = macro_real_token_count (macro); for (i = 0; i < count; i++) { cpp_token *token = ¯o->exp.tokens[i]; if (token->type == CPP_MACRO_ARG) len += NODE_LEN (token->val.macro_arg.spelling); else len += cpp_token_len (token); if (token->flags & STRINGIFY_ARG) len++; /* "#" */ if (token->flags & PASTE_LEFT) len += 3; /* " ##" */ if (token->flags & PREV_WHITE) len++; /* " " */ } } if (len > pfile->macro_buffer_len) { pfile->macro_buffer = XRESIZEVEC (unsigned char, pfile->macro_buffer, len); pfile->macro_buffer_len = len; } /* Fill in the buffer. Start with the macro name. */ buffer = pfile->macro_buffer; buffer = _cpp_spell_ident_ucns (buffer, node); /* Parameter names. */ if (macro->fun_like) { *buffer++ = '('; for (i = 0; i < macro->paramc; i++) { cpp_hashnode *param = macro->params[i]; if (param != pfile->spec_nodes.n__VA_ARGS__) { memcpy (buffer, NODE_NAME (param), NODE_LEN (param)); buffer += NODE_LEN (param); } if (i + 1 < macro->paramc) /* Don't emit a space after the comma here; we're trying to emit a Dwarf-friendly definition, and the Dwarf spec forbids spaces in the argument list. */ *buffer++ = ','; else if (macro->variadic) *buffer++ = '.', *buffer++ = '.', *buffer++ = '.'; } *buffer++ = ')'; } /* The Dwarf spec requires a space after the macro name, even if the definition is the empty string. */ *buffer++ = ' '; if (CPP_OPTION (pfile, traditional)) buffer = _cpp_copy_replacement_text (macro, buffer); else if (macro->count) /* Expansion tokens. */ { unsigned int count = macro_real_token_count (macro); for (i = 0; i < count; i++) { cpp_token *token = ¯o->exp.tokens[i]; if (token->flags & PREV_WHITE) *buffer++ = ' '; if (token->flags & STRINGIFY_ARG) *buffer++ = '#'; if (token->type == CPP_MACRO_ARG) { memcpy (buffer, NODE_NAME (token->val.macro_arg.spelling), NODE_LEN (token->val.macro_arg.spelling)); buffer += NODE_LEN (token->val.macro_arg.spelling); } else buffer = cpp_spell_token (pfile, token, buffer, true); if (token->flags & PASTE_LEFT) { *buffer++ = ' '; *buffer++ = '#'; *buffer++ = '#'; /* Next has PREV_WHITE; see _cpp_create_definition. */ } } } *buffer = '\0'; return pfile->macro_buffer; }