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/* Primary expression subroutines Copyright (C) 2000, 2001, 2002, 2004, 2005, 2006, 2007, 2008 Free Software Foundation, Inc. Contributed by Andy Vaught This file is part of GCC. GCC 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. GCC 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 GCC; see the file COPYING3. If not see <http://www.gnu.org/licenses/>. */ #include "config.h" #include "system.h" #include "flags.h" #include "gfortran.h" #include "arith.h" #include "match.h" #include "parse.h" #include "toplev.h" /* Matches a kind-parameter expression, which is either a named symbolic constant or a nonnegative integer constant. If successful, sets the kind value to the correct integer. */ static match match_kind_param (int *kind) { char name[GFC_MAX_SYMBOL_LEN + 1]; gfc_symbol *sym; const char *p; match m; m = gfc_match_small_literal_int (kind, NULL); if (m != MATCH_NO) return m; m = gfc_match_name (name); if (m != MATCH_YES) return m; if (gfc_find_symbol (name, NULL, 1, &sym)) return MATCH_ERROR; if (sym == NULL) return MATCH_NO; if (sym->attr.flavor != FL_PARAMETER) return MATCH_NO; if (sym->value == NULL) return MATCH_NO; p = gfc_extract_int (sym->value, kind); if (p != NULL) return MATCH_NO; gfc_set_sym_referenced (sym); if (*kind < 0) return MATCH_NO; return MATCH_YES; } /* Get a trailing kind-specification for non-character variables. Returns: the integer kind value or: -1 if an error was generated -2 if no kind was found */ static int get_kind (void) { int kind; match m; if (gfc_match_char ('_') != MATCH_YES) return -2; m = match_kind_param (&kind); if (m == MATCH_NO) gfc_error ("Missing kind-parameter at %C"); return (m == MATCH_YES) ? kind : -1; } /* Given a character and a radix, see if the character is a valid digit in that radix. */ int gfc_check_digit (char c, int radix) { int r; switch (radix) { case 2: r = ('0' <= c && c <= '1'); break; case 8: r = ('0' <= c && c <= '7'); break; case 10: r = ('0' <= c && c <= '9'); break; case 16: r = ISXDIGIT (c); break; default: gfc_internal_error ("gfc_check_digit(): bad radix"); } return r; } /* Match the digit string part of an integer if signflag is not set, the signed digit string part if signflag is set. If the buffer is NULL, we just count characters for the resolution pass. Returns the number of characters matched, -1 for no match. */ static int match_digits (int signflag, int radix, char *buffer) { locus old_loc; int length; char c; length = 0; c = gfc_next_ascii_char (); if (signflag && (c == '+' || c == '-')) { if (buffer != NULL) *buffer++ = c; gfc_gobble_whitespace (); c = gfc_next_ascii_char (); length++; } if (!gfc_check_digit (c, radix)) return -1; length++; if (buffer != NULL) *buffer++ = c; for (;;) { old_loc = gfc_current_locus; c = gfc_next_ascii_char (); if (!gfc_check_digit (c, radix)) break; if (buffer != NULL) *buffer++ = c; length++; } gfc_current_locus = old_loc; return length; } /* Match an integer (digit string and optional kind). A sign will be accepted if signflag is set. */ static match match_integer_constant (gfc_expr **result, int signflag) { int length, kind; locus old_loc; char *buffer; gfc_expr *e; old_loc = gfc_current_locus; gfc_gobble_whitespace (); length = match_digits (signflag, 10, NULL); gfc_current_locus = old_loc; if (length == -1) return MATCH_NO; buffer = (char *) alloca (length + 1); memset (buffer, '\0', length + 1); gfc_gobble_whitespace (); match_digits (signflag, 10, buffer); kind = get_kind (); if (kind == -2) kind = gfc_default_integer_kind; if (kind == -1) return MATCH_ERROR; if (gfc_validate_kind (BT_INTEGER, kind, true) < 0) { gfc_error ("Integer kind %d at %C not available", kind); return MATCH_ERROR; } e = gfc_convert_integer (buffer, kind, 10, &gfc_current_locus); if (gfc_range_check (e) != ARITH_OK) { gfc_error ("Integer too big for its kind at %C. This check can be " "disabled with the option -fno-range-check"); gfc_free_expr (e); return MATCH_ERROR; } *result = e; return MATCH_YES; } /* Match a Hollerith constant. */ static match match_hollerith_constant (gfc_expr **result) { locus old_loc; gfc_expr *e = NULL; const char *msg; int num; int i; old_loc = gfc_current_locus; gfc_gobble_whitespace (); if (match_integer_constant (&e, 0) == MATCH_YES && gfc_match_char ('h') == MATCH_YES) { if (gfc_notify_std (GFC_STD_LEGACY, "Extension: Hollerith constant " "at %C") == FAILURE) goto cleanup; msg = gfc_extract_int (e, &num); if (msg != NULL) { gfc_error (msg); goto cleanup; } if (num == 0) { gfc_error ("Invalid Hollerith constant: %L must contain at least " "one character", &old_loc); goto cleanup; } if (e->ts.kind != gfc_default_integer_kind) { gfc_error ("Invalid Hollerith constant: Integer kind at %L " "should be default", &old_loc); goto cleanup; } else { gfc_free_expr (e); e = gfc_constant_result (BT_HOLLERITH, gfc_default_character_kind, &gfc_current_locus); e->representation.string = XCNEWVEC (char, num + 1); for (i = 0; i < num; i++) { gfc_char_t c = gfc_next_char_literal (1); if (! gfc_wide_fits_in_byte (c)) { gfc_error ("Invalid Hollerith constant at %L contains a " "wide character", &old_loc); goto cleanup; } e->representation.string[i] = (unsigned char) c; } e->representation.string[num] = '\0'; e->representation.length = num; *result = e; return MATCH_YES; } } gfc_free_expr (e); gfc_current_locus = old_loc; return MATCH_NO; cleanup: gfc_free_expr (e); return MATCH_ERROR; } /* Match a binary, octal or hexadecimal constant that can be found in a DATA statement. The standard permits b'010...', o'73...', and z'a1...' where b, o, and z can be capital letters. This function also accepts postfixed forms of the constants: '01...'b, '73...'o, and 'a1...'z. An additional extension is the use of x for z. */ static match match_boz_constant (gfc_expr **result) { int radix, length, x_hex, kind; locus old_loc, start_loc; char *buffer, post, delim; gfc_expr *e; start_loc = old_loc = gfc_current_locus; gfc_gobble_whitespace (); x_hex = 0; switch (post = gfc_next_ascii_char ()) { case 'b': radix = 2; post = 0; break; case 'o': radix = 8; post = 0; break; case 'x': x_hex = 1; /* Fall through. */ case 'z': radix = 16; post = 0; break; case '\'': /* Fall through. */ case '\"': delim = post; post = 1; radix = 16; /* Set to accept any valid digit string. */ break; default: goto backup; } /* No whitespace allowed here. */ if (post == 0) delim = gfc_next_ascii_char (); if (delim != '\'' && delim != '\"') goto backup; if (x_hex && (gfc_notify_std (GFC_STD_GNU, "Extension: Hexadecimal " "constant at %C uses non-standard syntax") == FAILURE)) return MATCH_ERROR; old_loc = gfc_current_locus; length = match_digits (0, radix, NULL); if (length == -1) { gfc_error ("Empty set of digits in BOZ constant at %C"); return MATCH_ERROR; } if (gfc_next_ascii_char () != delim) { gfc_error ("Illegal character in BOZ constant at %C"); return MATCH_ERROR; } if (post == 1) { switch (gfc_next_ascii_char ()) { case 'b': radix = 2; break; case 'o': radix = 8; break; case 'x': /* Fall through. */ case 'z': radix = 16; break; default: goto backup; } if (gfc_notify_std (GFC_STD_GNU, "Extension: BOZ constant " "at %C uses non-standard postfix syntax") == FAILURE) return MATCH_ERROR; } gfc_current_locus = old_loc; buffer = (char *) alloca (length + 1); memset (buffer, '\0', length + 1); match_digits (0, radix, buffer); gfc_next_ascii_char (); /* Eat delimiter. */ if (post == 1) gfc_next_ascii_char (); /* Eat postfixed b, o, z, or x. */ /* In section 5.2.5 and following C567 in the Fortran 2003 standard, we find "If a data-stmt-constant is a boz-literal-constant, the corresponding variable shall be of type integer. The boz-literal-constant is treated as if it were an int-literal-constant with a kind-param that specifies the representation method with the largest decimal exponent range supported by the processor." */ kind = gfc_max_integer_kind; e = gfc_convert_integer (buffer, kind, radix, &gfc_current_locus); /* Mark as boz variable. */ e->is_boz = 1; if (gfc_range_check (e) != ARITH_OK) { gfc_error ("Integer too big for integer kind %i at %C", kind); gfc_free_expr (e); return MATCH_ERROR; } if (!gfc_in_match_data () && (gfc_notify_std (GFC_STD_F2003, "Fortran 2003: BOZ used outside a DATA " "statement at %C") == FAILURE)) return MATCH_ERROR; *result = e; return MATCH_YES; backup: gfc_current_locus = start_loc; return MATCH_NO; } /* Match a real constant of some sort. Allow a signed constant if signflag is nonzero. */ static match match_real_constant (gfc_expr **result, int signflag) { int kind, count, seen_dp, seen_digits; locus old_loc, temp_loc; char *p, *buffer, c, exp_char; gfc_expr *e; bool negate; old_loc = gfc_current_locus; gfc_gobble_whitespace (); e = NULL; count = 0; seen_dp = 0; seen_digits = 0; exp_char = ' '; negate = FALSE; c = gfc_next_ascii_char (); if (signflag && (c == '+' || c == '-')) { if (c == '-') negate = TRUE; gfc_gobble_whitespace (); c = gfc_next_ascii_char (); } /* Scan significand. */ for (;; c = gfc_next_ascii_char (), count++) { if (c == '.') { if (seen_dp) goto done; /* Check to see if "." goes with a following operator like ".eq.". */ temp_loc = gfc_current_locus; c = gfc_next_ascii_char (); if (c == 'e' || c == 'd' || c == 'q') { c = gfc_next_ascii_char (); if (c == '.') goto done; /* Operator named .e. or .d. */ } if (ISALPHA (c)) goto done; /* Distinguish 1.e9 from 1.eq.2 */ gfc_current_locus = temp_loc; seen_dp = 1; continue; } if (ISDIGIT (c)) { seen_digits = 1; continue; } break; } if (!seen_digits || (c != 'e' && c != 'd' && c != 'q')) goto done; exp_char = c; /* Scan exponent. */ c = gfc_next_ascii_char (); count++; if (c == '+' || c == '-') { /* optional sign */ c = gfc_next_ascii_char (); count++; } if (!ISDIGIT (c)) { gfc_error ("Missing exponent in real number at %C"); return MATCH_ERROR; } while (ISDIGIT (c)) { c = gfc_next_ascii_char (); count++; } done: /* Check that we have a numeric constant. */ if (!seen_digits || (!seen_dp && exp_char == ' ')) { gfc_current_locus = old_loc; return MATCH_NO; } /* Convert the number. */ gfc_current_locus = old_loc; gfc_gobble_whitespace (); buffer = (char *) alloca (count + 1); memset (buffer, '\0', count + 1); p = buffer; c = gfc_next_ascii_char (); if (c == '+' || c == '-') { gfc_gobble_whitespace (); c = gfc_next_ascii_char (); } /* Hack for mpfr_set_str(). */ for (;;) { if (c == 'd' || c == 'q') *p = 'e'; else *p = c; p++; if (--count == 0) break; c = gfc_next_ascii_char (); } kind = get_kind (); if (kind == -1) goto cleanup; switch (exp_char) { case 'd': if (kind != -2) { gfc_error ("Real number at %C has a 'd' exponent and an explicit " "kind"); goto cleanup; } kind = gfc_default_double_kind; break; default: if (kind == -2) kind = gfc_default_real_kind; if (gfc_validate_kind (BT_REAL, kind, true) < 0) { gfc_error ("Invalid real kind %d at %C", kind); goto cleanup; } } e = gfc_convert_real (buffer, kind, &gfc_current_locus); if (negate) mpfr_neg (e->value.real, e->value.real, GFC_RND_MODE); switch (gfc_range_check (e)) { case ARITH_OK: break; case ARITH_OVERFLOW: gfc_error ("Real constant overflows its kind at %C"); goto cleanup; case ARITH_UNDERFLOW: if (gfc_option.warn_underflow) gfc_warning ("Real constant underflows its kind at %C"); mpfr_set_ui (e->value.real, 0, GFC_RND_MODE); break; default: gfc_internal_error ("gfc_range_check() returned bad value"); } *result = e; return MATCH_YES; cleanup: gfc_free_expr (e); return MATCH_ERROR; } /* Match a substring reference. */ static match match_substring (gfc_charlen *cl, int init, gfc_ref **result) { gfc_expr *start, *end; locus old_loc; gfc_ref *ref; match m; start = NULL; end = NULL; old_loc = gfc_current_locus; m = gfc_match_char ('('); if (m != MATCH_YES) return MATCH_NO; if (gfc_match_char (':') != MATCH_YES) { if (init) m = gfc_match_init_expr (&start); else m = gfc_match_expr (&start); if (m != MATCH_YES) { m = MATCH_NO; goto cleanup; } m = gfc_match_char (':'); if (m != MATCH_YES) goto cleanup; } if (gfc_match_char (')') != MATCH_YES) { if (init) m = gfc_match_init_expr (&end); else m = gfc_match_expr (&end); if (m == MATCH_NO) goto syntax; if (m == MATCH_ERROR) goto cleanup; m = gfc_match_char (')'); if (m == MATCH_NO) goto syntax; } /* Optimize away the (:) reference. */ if (start == NULL && end == NULL) ref = NULL; else { ref = gfc_get_ref (); ref->type = REF_SUBSTRING; if (start == NULL) start = gfc_int_expr (1); ref->u.ss.start = start; if (end == NULL && cl) end = gfc_copy_expr (cl->length); ref->u.ss.end = end; ref->u.ss.length = cl; } *result = ref; return MATCH_YES; syntax: gfc_error ("Syntax error in SUBSTRING specification at %C"); m = MATCH_ERROR; cleanup: gfc_free_expr (start); gfc_free_expr (end); gfc_current_locus = old_loc; return m; } /* Reads the next character of a string constant, taking care to return doubled delimiters on the input as a single instance of the delimiter. Special return values for "ret" argument are: -1 End of the string, as determined by the delimiter -2 Unterminated string detected Backslash codes are also expanded at this time. */ static gfc_char_t next_string_char (gfc_char_t delimiter, int *ret) { locus old_locus; gfc_char_t c; c = gfc_next_char_literal (1); *ret = 0; if (c == '\n') { *ret = -2; return 0; } if (gfc_option.flag_backslash && c == '\\') { old_locus = gfc_current_locus; if (gfc_match_special_char (&c) == MATCH_NO) gfc_current_locus = old_locus; if (!(gfc_option.allow_std & GFC_STD_GNU) && !inhibit_warnings) gfc_warning ("Extension: backslash character at %C"); } if (c != delimiter) return c; old_locus = gfc_current_locus; c = gfc_next_char_literal (0); if (c == delimiter) return c; gfc_current_locus = old_locus; *ret = -1; return 0; } /* Special case of gfc_match_name() that matches a parameter kind name before a string constant. This takes case of the weird but legal case of: kind_____'string' where kind____ is a parameter. gfc_match_name() will happily slurp up all the underscores, which leads to problems. If we return MATCH_YES, the parse pointer points to the final underscore, which is not part of the name. We never return MATCH_ERROR-- errors in the name will be detected later. */ static match match_charkind_name (char *name) { locus old_loc; char c, peek; int len; gfc_gobble_whitespace (); c = gfc_next_ascii_char (); if (!ISALPHA (c)) return MATCH_NO; *name++ = c; len = 1; for (;;) { old_loc = gfc_current_locus; c = gfc_next_ascii_char (); if (c == '_') { peek = gfc_peek_ascii_char (); if (peek == '\'' || peek == '\"') { gfc_current_locus = old_loc; *name = '\0'; return MATCH_YES; } } if (!ISALNUM (c) && c != '_' && (c != '$' || !gfc_option.flag_dollar_ok)) break; *name++ = c; if (++len > GFC_MAX_SYMBOL_LEN) break; } return MATCH_NO; } /* See if the current input matches a character constant. Lots of contortions have to be done to match the kind parameter which comes before the actual string. The main consideration is that we don't want to error out too quickly. For example, we don't actually do any validation of the kinds until we have actually seen a legal delimiter. Using match_kind_param() generates errors too quickly. */ static match match_string_constant (gfc_expr **result) { char name[GFC_MAX_SYMBOL_LEN + 1], peek; int i, kind, length, warn_ampersand, ret; locus old_locus, start_locus; gfc_symbol *sym; gfc_expr *e; const char *q; match m; gfc_char_t c, delimiter, *p; old_locus = gfc_current_locus; gfc_gobble_whitespace (); start_locus = gfc_current_locus; c = gfc_next_char (); if (c == '\'' || c == '"') { kind = gfc_default_character_kind; goto got_delim; } if (gfc_wide_is_digit (c)) { kind = 0; while (gfc_wide_is_digit (c)) { kind = kind * 10 + c - '0'; if (kind > 9999999) goto no_match; c = gfc_next_char (); } } else { gfc_current_locus = old_locus; m = match_charkind_name (name); if (m != MATCH_YES) goto no_match; if (gfc_find_symbol (name, NULL, 1, &sym) || sym == NULL || sym->attr.flavor != FL_PARAMETER) goto no_match; kind = -1; c = gfc_next_char (); } if (c == ' ') { gfc_gobble_whitespace (); c = gfc_next_char (); } if (c != '_') goto no_match; gfc_gobble_whitespace (); start_locus = gfc_current_locus; c = gfc_next_char (); if (c != '\'' && c != '"') goto no_match; if (kind == -1) { q = gfc_extract_int (sym->value, &kind); if (q != NULL) { gfc_error (q); return MATCH_ERROR; } gfc_set_sym_referenced (sym); } if (gfc_validate_kind (BT_CHARACTER, kind, true) < 0) { gfc_error ("Invalid kind %d for CHARACTER constant at %C", kind); return MATCH_ERROR; } got_delim: /* Scan the string into a block of memory by first figuring out how long it is, allocating the structure, then re-reading it. This isn't particularly efficient, but string constants aren't that common in most code. TODO: Use obstacks? */ delimiter = c; length = 0; for (;;) { c = next_string_char (delimiter, &ret); if (ret == -1) break; if (ret == -2) { gfc_current_locus = start_locus; gfc_error ("Unterminated character constant beginning at %C"); return MATCH_ERROR; } length++; } /* Peek at the next character to see if it is a b, o, z, or x for the postfixed BOZ literal constants. */ peek = gfc_peek_ascii_char (); if (peek == 'b' || peek == 'o' || peek =='z' || peek == 'x') goto no_match; e = gfc_get_expr (); e->expr_type = EXPR_CONSTANT; e->ref = NULL; e->ts.type = BT_CHARACTER; e->ts.kind = kind; e->ts.is_c_interop = 0; e->ts.is_iso_c = 0; e->where = start_locus; e->value.character.string = p = gfc_get_wide_string (length + 1); e->value.character.length = length; gfc_current_locus = start_locus; gfc_next_char (); /* Skip delimiter */ /* We disable the warning for the following loop as the warning has already been printed in the loop above. */ warn_ampersand = gfc_option.warn_ampersand; gfc_option.warn_ampersand = 0; for (i = 0; i < length; i++) { c = next_string_char (delimiter, &ret); if (!gfc_check_character_range (c, kind)) { gfc_error ("Character '%s' in string at %C is not representable " "in character kind %d", gfc_print_wide_char (c), kind); return MATCH_ERROR; } *p++ = c; } *p = '\0'; /* TODO: C-style string is for development/debug purposes. */ gfc_option.warn_ampersand = warn_ampersand; next_string_char (delimiter, &ret); if (ret != -1) gfc_internal_error ("match_string_constant(): Delimiter not found"); if (match_substring (NULL, 0, &e->ref) != MATCH_NO) e->expr_type = EXPR_SUBSTRING; *result = e; return MATCH_YES; no_match: gfc_current_locus = old_locus; return MATCH_NO; } /* Match a .true. or .false. Returns 1 if a .true. was found, 0 if a .false. was found, and -1 otherwise. */ static int match_logical_constant_string (void) { locus orig_loc = gfc_current_locus; gfc_gobble_whitespace (); if (gfc_next_ascii_char () == '.') { char ch = gfc_next_ascii_char (); if (ch == 'f') { if (gfc_next_ascii_char () == 'a' && gfc_next_ascii_char () == 'l' && gfc_next_ascii_char () == 's' && gfc_next_ascii_char () == 'e' && gfc_next_ascii_char () == '.') /* Matched ".false.". */ return 0; } else if (ch == 't') { if (gfc_next_ascii_char () == 'r' && gfc_next_ascii_char () == 'u' && gfc_next_ascii_char () == 'e' && gfc_next_ascii_char () == '.') /* Matched ".true.". */ return 1; } } gfc_current_locus = orig_loc; return -1; } /* Match a .true. or .false. */ static match match_logical_constant (gfc_expr **result) { gfc_expr *e; int i, kind; i = match_logical_constant_string (); if (i == -1) return MATCH_NO; kind = get_kind (); if (kind == -1) return MATCH_ERROR; if (kind == -2) kind = gfc_default_logical_kind; if (gfc_validate_kind (BT_LOGICAL, kind, true) < 0) { gfc_error ("Bad kind for logical constant at %C"); return MATCH_ERROR; } e = gfc_get_expr (); e->expr_type = EXPR_CONSTANT; e->value.logical = i; e->ts.type = BT_LOGICAL; e->ts.kind = kind; e->ts.is_c_interop = 0; e->ts.is_iso_c = 0; e->where = gfc_current_locus; *result = e; return MATCH_YES; } /* Match a real or imaginary part of a complex constant that is a symbolic constant. */ static match match_sym_complex_part (gfc_expr **result) { char name[GFC_MAX_SYMBOL_LEN + 1]; gfc_symbol *sym; gfc_expr *e; match m; m = gfc_match_name (name); if (m != MATCH_YES) return m; if (gfc_find_symbol (name, NULL, 1, &sym) || sym == NULL) return MATCH_NO; if (sym->attr.flavor != FL_PARAMETER) { gfc_error ("Expected PARAMETER symbol in complex constant at %C"); return MATCH_ERROR; } if (!gfc_numeric_ts (&sym->value->ts)) { gfc_error ("Numeric PARAMETER required in complex constant at %C"); return MATCH_ERROR; } if (sym->value->rank != 0) { gfc_error ("Scalar PARAMETER required in complex constant at %C"); return MATCH_ERROR; } if (gfc_notify_std (GFC_STD_F2003, "Fortran 2003: PARAMETER symbol in " "complex constant at %C") == FAILURE) return MATCH_ERROR; switch (sym->value->ts.type) { case BT_REAL: e = gfc_copy_expr (sym->value); break; case BT_COMPLEX: e = gfc_complex2real (sym->value, sym->value->ts.kind); if (e == NULL) goto error; break; case BT_INTEGER: e = gfc_int2real (sym->value, gfc_default_real_kind); if (e == NULL) goto error; break; default: gfc_internal_error ("gfc_match_sym_complex_part(): Bad type"); } *result = e; /* e is a scalar, real, constant expression. */ return MATCH_YES; error: gfc_error ("Error converting PARAMETER constant in complex constant at %C"); return MATCH_ERROR; } /* Match a real or imaginary part of a complex number. */ static match match_complex_part (gfc_expr **result) { match m; m = match_sym_complex_part (result); if (m != MATCH_NO) return m; m = match_real_constant (result, 1); if (m != MATCH_NO) return m; return match_integer_constant (result, 1); } /* Try to match a complex constant. */ static match match_complex_constant (gfc_expr **result) { gfc_expr *e, *real, *imag; gfc_error_buf old_error; gfc_typespec target; locus old_loc; int kind; match m; old_loc = gfc_current_locus; real = imag = e = NULL; m = gfc_match_char ('('); if (m != MATCH_YES) return m; gfc_push_error (&old_error); m = match_complex_part (&real); if (m == MATCH_NO) { gfc_free_error (&old_error); goto cleanup; } if (gfc_match_char (',') == MATCH_NO) { gfc_pop_error (&old_error); m = MATCH_NO; goto cleanup; } /* If m is error, then something was wrong with the real part and we assume we have a complex constant because we've seen the ','. An ambiguous case here is the start of an iterator list of some sort. These sort of lists are matched prior to coming here. */ if (m == MATCH_ERROR) { gfc_free_error (&old_error); goto cleanup; } gfc_pop_error (&old_error); m = match_complex_part (&imag); if (m == MATCH_NO) goto syntax; if (m == MATCH_ERROR) goto cleanup; m = gfc_match_char (')'); if (m == MATCH_NO) { /* Give the matcher for implied do-loops a chance to run. This yields a much saner error message for (/ (i, 4=i, 6) /). */ if (gfc_peek_ascii_char () == '=') { m = MATCH_ERROR; goto cleanup; } else goto syntax; } if (m == MATCH_ERROR) goto cleanup; /* Decide on the kind of this complex number. */ if (real->ts.type == BT_REAL) { if (imag->ts.type == BT_REAL) kind = gfc_kind_max (real, imag); else kind = real->ts.kind; } else { if (imag->ts.type == BT_REAL) kind = imag->ts.kind; else kind = gfc_default_real_kind; } target.type = BT_REAL; target.kind = kind; target.is_c_interop = 0; target.is_iso_c = 0; if (real->ts.type != BT_REAL || kind != real->ts.kind) gfc_convert_type (real, &target, 2); if (imag->ts.type != BT_REAL || kind != imag->ts.kind) gfc_convert_type (imag, &target, 2); e = gfc_convert_complex (real, imag, kind); e->where = gfc_current_locus; gfc_free_expr (real); gfc_free_expr (imag); *result = e; return MATCH_YES; syntax: gfc_error ("Syntax error in COMPLEX constant at %C"); m = MATCH_ERROR; cleanup: gfc_free_expr (e); gfc_free_expr (real); gfc_free_expr (imag); gfc_current_locus = old_loc; return m; } /* Match constants in any of several forms. Returns nonzero for a match, zero for no match. */ match gfc_match_literal_constant (gfc_expr **result, int signflag) { match m; m = match_complex_constant (result); if (m != MATCH_NO) return m; m = match_string_constant (result); if (m != MATCH_NO) return m; m = match_boz_constant (result); if (m != MATCH_NO) return m; m = match_real_constant (result, signflag); if (m != MATCH_NO) return m; m = match_hollerith_constant (result); if (m != MATCH_NO) return m; m = match_integer_constant (result, signflag); if (m != MATCH_NO) return m; m = match_logical_constant (result); if (m != MATCH_NO) return m; return MATCH_NO; } /* This checks if a symbol is the return value of an encompassing function. Function nesting can be maximally two levels deep, but we may have additional local namespaces like BLOCK etc. */ bool gfc_is_function_return_value (gfc_symbol *sym, gfc_namespace *ns) { if (!sym->attr.function || (sym->result != sym)) return false; while (ns) { if (ns->proc_name == sym) return true; ns = ns->parent; } return false; } /* Match a single actual argument value. An actual argument is usually an expression, but can also be a procedure name. If the argument is a single name, it is not always possible to tell whether the name is a dummy procedure or not. We treat these cases by creating an argument that looks like a dummy procedure and fixing things later during resolution. */ static match match_actual_arg (gfc_expr **result) { char name[GFC_MAX_SYMBOL_LEN + 1]; gfc_symtree *symtree; locus where, w; gfc_expr *e; char c; gfc_gobble_whitespace (); where = gfc_current_locus; switch (gfc_match_name (name)) { case MATCH_ERROR: return MATCH_ERROR; case MATCH_NO: break; case MATCH_YES: w = gfc_current_locus; gfc_gobble_whitespace (); c = gfc_next_ascii_char (); gfc_current_locus = w; if (c != ',' && c != ')') break; if (gfc_find_sym_tree (name, NULL, 1, &symtree)) break; /* Handle error elsewhere. */ /* Eliminate a couple of common cases where we know we don't have a function argument. */ if (symtree == NULL) { gfc_get_sym_tree (name, NULL, &symtree, false); gfc_set_sym_referenced (symtree->n.sym); } else { gfc_symbol *sym; sym = symtree->n.sym; gfc_set_sym_referenced (sym); if (sym->attr.flavor != FL_PROCEDURE && sym->attr.flavor != FL_UNKNOWN) break; if (sym->attr.in_common && !sym->attr.proc_pointer) { gfc_add_flavor (&sym->attr, FL_VARIABLE, sym->name, &sym->declared_at); break; } /* If the symbol is a function with itself as the result and is being defined, then we have a variable. */ if (sym->attr.function && sym->result == sym) { if (gfc_is_function_return_value (sym, gfc_current_ns)) break; if (sym->attr.entry && (sym->ns == gfc_current_ns || sym->ns == gfc_current_ns->parent)) { gfc_entry_list *el = NULL; for (el = sym->ns->entries; el; el = el->next) if (sym == el->sym) break; if (el) break; } } } e = gfc_get_expr (); /* Leave it unknown for now */ e->symtree = symtree; e->expr_type = EXPR_VARIABLE; e->ts.type = BT_PROCEDURE; e->where = where; *result = e; return MATCH_YES; } gfc_current_locus = where; return gfc_match_expr (result); } /* Match a keyword argument. */ static match match_keyword_arg (gfc_actual_arglist *actual, gfc_actual_arglist *base) { char name[GFC_MAX_SYMBOL_LEN + 1]; gfc_actual_arglist *a; locus name_locus; match m; name_locus = gfc_current_locus; m = gfc_match_name (name); if (m != MATCH_YES) goto cleanup; if (gfc_match_char ('=') != MATCH_YES) { m = MATCH_NO; goto cleanup; } m = match_actual_arg (&actual->expr); if (m != MATCH_YES) goto cleanup; /* Make sure this name has not appeared yet. */ if (name[0] != '\0') { for (a = base; a; a = a->next) if (a->name != NULL && strcmp (a->name, name) == 0) { gfc_error ("Keyword '%s' at %C has already appeared in the " "current argument list", name); return MATCH_ERROR; } } actual->name = gfc_get_string (name); return MATCH_YES; cleanup: gfc_current_locus = name_locus; return m; } /* Match an argument list function, such as %VAL. */ static match match_arg_list_function (gfc_actual_arglist *result) { char name[GFC_MAX_SYMBOL_LEN + 1]; locus old_locus; match m; old_locus = gfc_current_locus; if (gfc_match_char ('%') != MATCH_YES) { m = MATCH_NO; goto cleanup; } m = gfc_match ("%n (", name); if (m != MATCH_YES) goto cleanup; if (name[0] != '\0') { switch (name[0]) { case 'l': if (strncmp (name, "loc", 3) == 0) { result->name = "%LOC"; break; } case 'r': if (strncmp (name, "ref", 3) == 0) { result->name = "%REF"; break; } case 'v': if (strncmp (name, "val", 3) == 0) { result->name = "%VAL"; break; } default: m = MATCH_ERROR; goto cleanup; } } if (gfc_notify_std (GFC_STD_GNU, "Extension: argument list " "function at %C") == FAILURE) { m = MATCH_ERROR; goto cleanup; } m = match_actual_arg (&result->expr); if (m != MATCH_YES) goto cleanup; if (gfc_match_char (')') != MATCH_YES) { m = MATCH_NO; goto cleanup; } return MATCH_YES; cleanup: gfc_current_locus = old_locus; return m; } /* Matches an actual argument list of a function or subroutine, from the opening parenthesis to the closing parenthesis. The argument list is assumed to allow keyword arguments because we don't know if the symbol associated with the procedure has an implicit interface or not. We make sure keywords are unique. If sub_flag is set, we're matching the argument list of a subroutine. */ match gfc_match_actual_arglist (int sub_flag, gfc_actual_arglist **argp) { gfc_actual_arglist *head, *tail; int seen_keyword; gfc_st_label *label; locus old_loc; match m; *argp = tail = NULL; old_loc = gfc_current_locus; seen_keyword = 0; if (gfc_match_char ('(') == MATCH_NO) return (sub_flag) ? MATCH_YES : MATCH_NO; if (gfc_match_char (')') == MATCH_YES) return MATCH_YES; head = NULL; for (;;) { if (head == NULL) head = tail = gfc_get_actual_arglist (); else { tail->next = gfc_get_actual_arglist (); tail = tail->next; } if (sub_flag && gfc_match_char ('*') == MATCH_YES) { m = gfc_match_st_label (&label); if (m == MATCH_NO) gfc_error ("Expected alternate return label at %C"); if (m != MATCH_YES) goto cleanup; tail->label = label; goto next; } /* After the first keyword argument is seen, the following arguments must also have keywords. */ if (seen_keyword) { m = match_keyword_arg (tail, head); if (m == MATCH_ERROR) goto cleanup; if (m == MATCH_NO) { gfc_error ("Missing keyword name in actual argument list at %C"); goto cleanup; } } else { /* Try an argument list function, like %VAL. */ m = match_arg_list_function (tail); if (m == MATCH_ERROR) goto cleanup; /* See if we have the first keyword argument. */ if (m == MATCH_NO) { m = match_keyword_arg (tail, head); if (m == MATCH_YES) seen_keyword = 1; if (m == MATCH_ERROR) goto cleanup; } if (m == MATCH_NO) { /* Try for a non-keyword argument. */ m = match_actual_arg (&tail->expr); if (m == MATCH_ERROR) goto cleanup; if (m == MATCH_NO) goto syntax; } } next: if (gfc_match_char (')') == MATCH_YES) break; if (gfc_match_char (',') != MATCH_YES) goto syntax; } *argp = head; return MATCH_YES; syntax: gfc_error ("Syntax error in argument list at %C"); cleanup: gfc_free_actual_arglist (head); gfc_current_locus = old_loc; return MATCH_ERROR; } /* Used by gfc_match_varspec() to extend the reference list by one element. */ static gfc_ref * extend_ref (gfc_expr *primary, gfc_ref *tail) { if (primary->ref == NULL) primary->ref = tail = gfc_get_ref (); else { if (tail == NULL) gfc_internal_error ("extend_ref(): Bad tail"); tail->next = gfc_get_ref (); tail = tail->next; } return tail; } /* Match any additional specifications associated with the current variable like member references or substrings. If equiv_flag is set we only match stuff that is allowed inside an EQUIVALENCE statement. sub_flag tells whether we expect a type-bound procedure found to be a subroutine as part of CALL or a FUNCTION. For procedure pointer components, 'ppc_arg' determines whether the PPC may be called (with an argument list), or whether it may just be referred to as a pointer. */ match gfc_match_varspec (gfc_expr *primary, int equiv_flag, bool sub_flag, bool ppc_arg) { char name[GFC_MAX_SYMBOL_LEN + 1]; gfc_ref *substring, *tail; gfc_component *component; gfc_symbol *sym = primary->symtree->n.sym; match m; bool unknown; tail = NULL; gfc_gobble_whitespace (); if ((equiv_flag && gfc_peek_ascii_char () == '(') || (sym->attr.dimension && !sym->attr.proc_pointer && !gfc_is_proc_ptr_comp (primary, NULL) && !(gfc_matching_procptr_assignment && sym->attr.flavor == FL_PROCEDURE)) || (sym->ts.type == BT_CLASS && sym->ts.u.derived->components->attr.dimension)) { /* In EQUIVALENCE, we don't know yet whether we are seeing an array, character variable or array of character variables. We'll leave the decision till resolve time. */ tail = extend_ref (primary, tail); tail->type = REF_ARRAY; m = gfc_match_array_ref (&tail->u.ar, equiv_flag ? NULL : sym->as, equiv_flag); if (m != MATCH_YES) return m; gfc_gobble_whitespace (); if (equiv_flag && gfc_peek_ascii_char () == '(') { tail = extend_ref (primary, tail); tail->type = REF_ARRAY; m = gfc_match_array_ref (&tail->u.ar, NULL, equiv_flag); if (m != MATCH_YES) return m; } } primary->ts = sym->ts; if (equiv_flag) return MATCH_YES; if (sym->ts.type == BT_UNKNOWN && gfc_peek_ascii_char () == '%' && gfc_get_default_type (sym->name, sym->ns)->type == BT_DERIVED) gfc_set_default_type (sym, 0, sym->ns); if ((sym->ts.type != BT_DERIVED && sym->ts.type != BT_CLASS) || gfc_match_char ('%') != MATCH_YES) goto check_substring; sym = sym->ts.u.derived; for (;;) { gfc_try t; gfc_symtree *tbp; m = gfc_match_name (name); if (m == MATCH_NO) gfc_error ("Expected structure component name at %C"); if (m != MATCH_YES) return MATCH_ERROR; if (sym->f2k_derived) tbp = gfc_find_typebound_proc (sym, &t, name, false, &gfc_current_locus); else tbp = NULL; if (tbp) { gfc_symbol* tbp_sym; if (t == FAILURE) return MATCH_ERROR; gcc_assert (!tail || !tail->next); gcc_assert (primary->expr_type == EXPR_VARIABLE); if (tbp->n.tb->is_generic) tbp_sym = NULL; else tbp_sym = tbp->n.tb->u.specific->n.sym; primary->expr_type = EXPR_COMPCALL; primary->value.compcall.tbp = tbp->n.tb; primary->value.compcall.name = tbp->name; primary->value.compcall.ignore_pass = 0; primary->value.compcall.assign = 0; primary->value.compcall.base_object = NULL; gcc_assert (primary->symtree->n.sym->attr.referenced); if (tbp_sym) primary->ts = tbp_sym->ts; m = gfc_match_actual_arglist (tbp->n.tb->subroutine, &primary->value.compcall.actual); if (m == MATCH_ERROR) return MATCH_ERROR; if (m == MATCH_NO) { if (sub_flag) primary->value.compcall.actual = NULL; else { gfc_error ("Expected argument list at %C"); return MATCH_ERROR; } } break; } component = gfc_find_component (sym, name, false, false); if (component == NULL) return MATCH_ERROR; tail = extend_ref (primary, tail); tail->type = REF_COMPONENT; tail->u.c.component = component; tail->u.c.sym = sym; primary->ts = component->ts; if (component->attr.proc_pointer && ppc_arg && !gfc_matching_procptr_assignment) { m = gfc_match_actual_arglist (sub_flag, &primary->value.compcall.actual); if (m == MATCH_ERROR) return MATCH_ERROR; if (m == MATCH_YES) primary->expr_type = EXPR_PPC; break; } if (component->as != NULL && !component->attr.proc_pointer) { tail = extend_ref (primary, tail); tail->type = REF_ARRAY; m = gfc_match_array_ref (&tail->u.ar, component->as, equiv_flag); if (m != MATCH_YES) return m; } else if (component->ts.type == BT_CLASS && component->ts.u.derived->components->as != NULL && !component->attr.proc_pointer) { tail = extend_ref (primary, tail); tail->type = REF_ARRAY; m = gfc_match_array_ref (&tail->u.ar, component->ts.u.derived->components->as, equiv_flag); if (m != MATCH_YES) return m; } if ((component->ts.type != BT_DERIVED && component->ts.type != BT_CLASS) || gfc_match_char ('%') != MATCH_YES) break; sym = component->ts.u.derived; } check_substring: unknown = false; if (primary->ts.type == BT_UNKNOWN && sym->attr.flavor != FL_DERIVED) { if (gfc_get_default_type (sym->name, sym->ns)->type == BT_CHARACTER) { gfc_set_default_type (sym, 0, sym->ns); primary->ts = sym->ts; unknown = true; } } if (primary->ts.type == BT_CHARACTER) { switch (match_substring (primary->ts.u.cl, equiv_flag, &substring)) { case MATCH_YES: if (tail == NULL) primary->ref = substring; else tail->next = substring; if (primary->expr_type == EXPR_CONSTANT) primary->expr_type = EXPR_SUBSTRING; if (substring) primary->ts.u.cl = NULL; break; case MATCH_NO: if (unknown) { gfc_clear_ts (&primary->ts); gfc_clear_ts (&sym->ts); } break; case MATCH_ERROR: return MATCH_ERROR; } } return MATCH_YES; } /* Given an expression that is a variable, figure out what the ultimate variable's type and attribute is, traversing the reference structures if necessary. This subroutine is trickier than it looks. We start at the base symbol and store the attribute. Component references load a completely new attribute. A couple of rules come into play. Subobjects of targets are always targets themselves. If we see a component that goes through a pointer, then the expression must also be a target, since the pointer is associated with something (if it isn't core will soon be dumped). If we see a full part or section of an array, the expression is also an array. We can have at most one full array reference. */ symbol_attribute gfc_variable_attr (gfc_expr *expr, gfc_typespec *ts) { int dimension, pointer, allocatable, target; symbol_attribute attr; gfc_ref *ref; gfc_symbol *sym; gfc_component *comp; if (expr->expr_type != EXPR_VARIABLE && expr->expr_type != EXPR_FUNCTION) gfc_internal_error ("gfc_variable_attr(): Expression isn't a variable"); ref = expr->ref; sym = expr->symtree->n.sym; attr = sym->attr; if (sym->ts.type == BT_CLASS) { dimension = sym->ts.u.derived->components->attr.dimension; pointer = sym->ts.u.derived->components->attr.pointer; allocatable = sym->ts.u.derived->components->attr.allocatable; } else { dimension = attr.dimension; pointer = attr.pointer; allocatable = attr.allocatable; } target = attr.target; if (pointer || attr.proc_pointer) target = 1; if (ts != NULL && expr->ts.type == BT_UNKNOWN) *ts = sym->ts; for (; ref; ref = ref->next) switch (ref->type) { case REF_ARRAY: switch (ref->u.ar.type) { case AR_FULL: dimension = 1; break; case AR_SECTION: allocatable = pointer = 0; dimension = 1; break; case AR_ELEMENT: allocatable = pointer = 0; break; case AR_UNKNOWN: gfc_internal_error ("gfc_variable_attr(): Bad array reference"); } break; case REF_COMPONENT: comp = ref->u.c.component; attr = comp->attr; if (ts != NULL) { *ts = comp->ts; /* Don't set the string length if a substring reference follows. */ if (ts->type == BT_CHARACTER && ref->next && ref->next->type == REF_SUBSTRING) ts->u.cl = NULL; } if (comp->ts.type == BT_CLASS) { pointer = comp->ts.u.derived->components->attr.pointer; allocatable = comp->ts.u.derived->components->attr.allocatable; } else { pointer = comp->attr.pointer; allocatable = comp->attr.allocatable; } if (pointer || attr.proc_pointer) target = 1; break; case REF_SUBSTRING: allocatable = pointer = 0; break; } attr.dimension = dimension; attr.pointer = pointer; attr.allocatable = allocatable; attr.target = target; return attr; } /* Return the attribute from a general expression. */ symbol_attribute gfc_expr_attr (gfc_expr *e) { symbol_attribute attr; switch (e->expr_type) { case EXPR_VARIABLE: attr = gfc_variable_attr (e, NULL); break; case EXPR_FUNCTION: gfc_clear_attr (&attr); if (e->value.function.esym != NULL) { gfc_symbol *sym = e->value.function.esym->result; attr = sym->attr; if (sym->ts.type == BT_CLASS) { attr.dimension = sym->ts.u.derived->components->attr.dimension; attr.pointer = sym->ts.u.derived->components->attr.pointer; attr.allocatable = sym->ts.u.derived->components->attr.allocatable; } } else attr = gfc_variable_attr (e, NULL); /* TODO: NULL() returns pointers. May have to take care of this here. */ break; default: gfc_clear_attr (&attr); break; } return attr; } /* Match a structure constructor. The initial symbol has already been seen. */ typedef struct gfc_structure_ctor_component { char* name; gfc_expr* val; locus where; struct gfc_structure_ctor_component* next; } gfc_structure_ctor_component; #define gfc_get_structure_ctor_component() XCNEW (gfc_structure_ctor_component) static void gfc_free_structure_ctor_component (gfc_structure_ctor_component *comp) { gfc_free (comp->name); gfc_free_expr (comp->val); } /* Translate the component list into the actual constructor by sorting it in the order required; this also checks along the way that each and every component actually has an initializer and handles default initializers for components without explicit value given. */ static gfc_try build_actual_constructor (gfc_structure_ctor_component **comp_head, gfc_constructor **ctor_head, gfc_symbol *sym) { gfc_structure_ctor_component *comp_iter; gfc_constructor *ctor_tail = NULL; gfc_component *comp; for (comp = sym->components; comp; comp = comp->next) { gfc_structure_ctor_component **next_ptr; gfc_expr *value = NULL; /* Try to find the initializer for the current component by name. */ next_ptr = comp_head; for (comp_iter = *comp_head; comp_iter; comp_iter = comp_iter->next) { if (!strcmp (comp_iter->name, comp->name)) break; next_ptr = &comp_iter->next; } /* If an extension, try building the parent derived type by building a value expression for the parent derived type and calling self. */ if (!comp_iter && comp == sym->components && sym->attr.extension) { value = gfc_get_expr (); value->expr_type = EXPR_STRUCTURE; value->value.constructor = NULL; value->ts = comp->ts; value->where = gfc_current_locus; if (build_actual_constructor (comp_head, &value->value.constructor, comp->ts.u.derived) == FAILURE) { gfc_free_expr (value); return FAILURE; } *ctor_head = ctor_tail = gfc_get_constructor (); ctor_tail->expr = value; continue; } /* If it was not found, try the default initializer if there's any; otherwise, it's an error. */ if (!comp_iter) { if (comp->initializer) { if (gfc_notify_std (GFC_STD_F2003, "Fortran 2003: Structure" " constructor with missing optional arguments" " at %C") == FAILURE) return FAILURE; value = gfc_copy_expr (comp->initializer); } else { gfc_error ("No initializer for component '%s' given in the" " structure constructor at %C!", comp->name); return FAILURE; } } else value = comp_iter->val; /* Add the value to the constructor chain built. */ if (ctor_tail) { ctor_tail->next = gfc_get_constructor (); ctor_tail = ctor_tail->next; } else *ctor_head = ctor_tail = gfc_get_constructor (); gcc_assert (value); ctor_tail->expr = value; /* Remove the entry from the component list. We don't want the expression value to be free'd, so set it to NULL. */ if (comp_iter) { *next_ptr = comp_iter->next; comp_iter->val = NULL; gfc_free_structure_ctor_component (comp_iter); } } return SUCCESS; } match gfc_match_structure_constructor (gfc_symbol *sym, gfc_expr **result, bool parent) { gfc_structure_ctor_component *comp_tail, *comp_head, *comp_iter; gfc_constructor *ctor_head, *ctor_tail; gfc_component *comp; /* Is set NULL when named component is first seen */ gfc_expr *e; locus where; match m; const char* last_name = NULL; comp_tail = comp_head = NULL; ctor_head = ctor_tail = NULL; if (!parent && gfc_match_char ('(') != MATCH_YES) goto syntax; where = gfc_current_locus; gfc_find_component (sym, NULL, false, true); /* Check that we're not about to construct an ABSTRACT type. */ if (!parent && sym->attr.abstract) { gfc_error ("Can't construct ABSTRACT type '%s' at %C", sym->name); return MATCH_ERROR; } /* Match the component list and store it in a list together with the corresponding component names. Check for empty argument list first. */ if (gfc_match_char (')') != MATCH_YES) { comp = sym->components; do { gfc_component *this_comp = NULL; if (!comp_head) comp_tail = comp_head = gfc_get_structure_ctor_component (); else { comp_tail->next = gfc_get_structure_ctor_component (); comp_tail = comp_tail->next; } comp_tail->name = XCNEWVEC (char, GFC_MAX_SYMBOL_LEN + 1); comp_tail->val = NULL; comp_tail->where = gfc_current_locus; /* Try matching a component name. */ if (gfc_match_name (comp_tail->name) == MATCH_YES && gfc_match_char ('=') == MATCH_YES) { if (gfc_notify_std (GFC_STD_F2003, "Fortran 2003: Structure" " constructor with named arguments at %C") == FAILURE) goto cleanup; last_name = comp_tail->name; comp = NULL; } else { /* Components without name are not allowed after the first named component initializer! */ if (!comp) { if (last_name) gfc_error ("Component initializer without name after" " component named %s at %C!", last_name); else if (!parent) gfc_error ("Too many components in structure constructor at" " %C!"); goto cleanup; } gfc_current_locus = comp_tail->where; strncpy (comp_tail->name, comp->name, GFC_MAX_SYMBOL_LEN + 1); } /* Find the current component in the structure definition and check its access is not private. */ if (comp) this_comp = gfc_find_component (sym, comp->name, false, false); else { this_comp = gfc_find_component (sym, (const char *)comp_tail->name, false, false); comp = NULL; /* Reset needed! */ } /* Here we can check if a component name is given which does not correspond to any component of the defined structure. */ if (!this_comp) goto cleanup; /* Check if this component is already given a value. */ for (comp_iter = comp_head; comp_iter != comp_tail; comp_iter = comp_iter->next) { gcc_assert (comp_iter); if (!strcmp (comp_iter->name, comp_tail->name)) { gfc_error ("Component '%s' is initialized twice in the" " structure constructor at %C!", comp_tail->name); goto cleanup; } } /* Match the current initializer expression. */ m = gfc_match_expr (&comp_tail->val); if (m == MATCH_NO) goto syntax; if (m == MATCH_ERROR) goto cleanup; /* If not explicitly a parent constructor, gather up the components and build one. */ if (comp && comp == sym->components && sym->attr.extension && (comp_tail->val->ts.type != BT_DERIVED || comp_tail->val->ts.u.derived != this_comp->ts.u.derived)) { gfc_current_locus = where; gfc_free_expr (comp_tail->val); comp_tail->val = NULL; m = gfc_match_structure_constructor (comp->ts.u.derived, &comp_tail->val, true); if (m == MATCH_NO) goto syntax; if (m == MATCH_ERROR) goto cleanup; } if (comp) comp = comp->next; if (parent && !comp) break; } while (gfc_match_char (',') == MATCH_YES); if (!parent && gfc_match_char (')') != MATCH_YES) goto syntax; } if (build_actual_constructor (&comp_head, &ctor_head, sym) == FAILURE) goto cleanup; /* No component should be left, as this should have caused an error in the loop constructing the component-list (name that does not correspond to any component in the structure definition). */ if (comp_head && sym->attr.extension) { for (comp_iter = comp_head; comp_iter; comp_iter = comp_iter->next) { gfc_error ("component '%s' at %L has already been set by a " "parent derived type constructor", comp_iter->name, &comp_iter->where); } goto cleanup; } else gcc_assert (!comp_head); e = gfc_get_expr (); e->expr_type = EXPR_STRUCTURE; e->ts.type = BT_DERIVED; e->ts.u.derived = sym; e->where = where; e->value.constructor = ctor_head; *result = e; return MATCH_YES; syntax: gfc_error ("Syntax error in structure constructor at %C"); cleanup: for (comp_iter = comp_head; comp_iter; ) { gfc_structure_ctor_component *next = comp_iter->next; gfc_free_structure_ctor_component (comp_iter); comp_iter = next; } gfc_free_constructor (ctor_head); return MATCH_ERROR; } /* If the symbol is an implicit do loop index and implicitly typed, it should not be host associated. Provide a symtree from the current namespace. */ static match check_for_implicit_index (gfc_symtree **st, gfc_symbol **sym) { if ((*sym)->attr.flavor == FL_VARIABLE && (*sym)->ns != gfc_current_ns && (*sym)->attr.implied_index && (*sym)->attr.implicit_type && !(*sym)->attr.use_assoc) { int i; i = gfc_get_sym_tree ((*sym)->name, NULL, st, false); if (i) return MATCH_ERROR; *sym = (*st)->n.sym; } return MATCH_YES; } /* Procedure pointer as function result: Replace the function symbol by the auto-generated hidden result variable named "ppr@". */ static gfc_try replace_hidden_procptr_result (gfc_symbol **sym, gfc_symtree **st) { /* Check for procedure pointer result variable. */ if ((*sym)->attr.function && !(*sym)->attr.external && (*sym)->result && (*sym)->result != *sym && (*sym)->result->attr.proc_pointer && (*sym) == gfc_current_ns->proc_name && (*sym) == (*sym)->result->ns->proc_name && strcmp ("ppr@", (*sym)->result->name) == 0) { /* Automatic replacement with "hidden" result variable. */ (*sym)->result->attr.referenced = (*sym)->attr.referenced; *sym = (*sym)->result; *st = gfc_find_symtree ((*sym)->ns->sym_root, (*sym)->name); return SUCCESS; } return FAILURE; } /* Matches a variable name followed by anything that might follow it-- array reference, argument list of a function, etc. */ match gfc_match_rvalue (gfc_expr **result) { gfc_actual_arglist *actual_arglist; char name[GFC_MAX_SYMBOL_LEN + 1], argname[GFC_MAX_SYMBOL_LEN + 1]; gfc_state_data *st; gfc_symbol *sym; gfc_symtree *symtree; locus where, old_loc; gfc_expr *e; match m, m2; int i; gfc_typespec *ts; bool implicit_char; gfc_ref *ref; m = gfc_match_name (name); if (m != MATCH_YES) return m; if (gfc_find_state (COMP_INTERFACE) == SUCCESS && !gfc_current_ns->has_import_set) i = gfc_get_sym_tree (name, NULL, &symtree, false); else i = gfc_get_ha_sym_tree (name, &symtree); if (i) return MATCH_ERROR; sym = symtree->n.sym; e = NULL; where = gfc_current_locus; replace_hidden_procptr_result (&sym, &symtree); /* If this is an implicit do loop index and implicitly typed, it should not be host associated. */ m = check_for_implicit_index (&symtree, &sym); if (m != MATCH_YES) return m; gfc_set_sym_referenced (sym); sym->attr.implied_index = 0; if (sym->attr.function && sym->result == sym) { /* See if this is a directly recursive function call. */ gfc_gobble_whitespace (); if (sym->attr.recursive && gfc_peek_ascii_char () == '(' && gfc_current_ns->proc_name == sym && !sym->attr.dimension) { gfc_error ("'%s' at %C is the name of a recursive function " "and so refers to the result variable. Use an " "explicit RESULT variable for direct recursion " "(12.5.2.1)", sym->name); return MATCH_ERROR; } if (gfc_is_function_return_value (sym, gfc_current_ns)) goto variable; if (sym->attr.entry && (sym->ns == gfc_current_ns || sym->ns == gfc_current_ns->parent)) { gfc_entry_list *el = NULL; for (el = sym->ns->entries; el; el = el->next) if (sym == el->sym) goto variable; } } if (gfc_matching_procptr_assignment) goto procptr0; if (sym->attr.function || sym->attr.external || sym->attr.intrinsic) goto function0; if (sym->attr.generic) goto generic_function; switch (sym->attr.flavor) { case FL_VARIABLE: variable: e = gfc_get_expr (); e->expr_type = EXPR_VARIABLE; e->symtree = symtree; m = gfc_match_varspec (e, 0, false, true); break; case FL_PARAMETER: /* A statement of the form "REAL, parameter :: a(0:10) = 1" will end up here. Unfortunately, sym->value->expr_type is set to EXPR_CONSTANT, and so the if () branch would be followed without the !sym->as check. */ if (sym->value && sym->value->expr_type != EXPR_ARRAY && !sym->as) e = gfc_copy_expr (sym->value); else { e = gfc_get_expr (); e->expr_type = EXPR_VARIABLE; } e->symtree = symtree; m = gfc_match_varspec (e, 0, false, true); if (sym->ts.is_c_interop || sym->ts.is_iso_c) break; /* Variable array references to derived type parameters cause all sorts of headaches in simplification. Treating such expressions as variable works just fine for all array references. */ if (sym->value && sym->ts.type == BT_DERIVED && e->ref) { for (ref = e->ref; ref; ref = ref->next) if (ref->type == REF_ARRAY) break; if (ref == NULL || ref->u.ar.type == AR_FULL) break; ref = e->ref; e->ref = NULL; gfc_free_expr (e); e = gfc_get_expr (); e->expr_type = EXPR_VARIABLE; e->symtree = symtree; e->ref = ref; } break; case FL_DERIVED: sym = gfc_use_derived (sym); if (sym == NULL) m = MATCH_ERROR; else m = gfc_match_structure_constructor (sym, &e, false); break; /* If we're here, then the name is known to be the name of a procedure, yet it is not sure to be the name of a function. */ case FL_PROCEDURE: /* Procedure Pointer Assignments. */ procptr0: if (gfc_matching_procptr_assignment) { gfc_gobble_whitespace (); if (!sym->attr.dimension && gfc_peek_ascii_char () == '(') /* Parse functions returning a procptr. */ goto function0; if (gfc_is_intrinsic (sym, 0, gfc_current_locus) || gfc_is_intrinsic (sym, 1, gfc_current_locus)) sym->attr.intrinsic = 1; e = gfc_get_expr (); e->expr_type = EXPR_VARIABLE; e->symtree = symtree; m = gfc_match_varspec (e, 0, false, true); break; } if (sym->attr.subroutine) { gfc_error ("Unexpected use of subroutine name '%s' at %C", sym->name); m = MATCH_ERROR; break; } /* At this point, the name has to be a non-statement function. If the name is the same as the current function being compiled, then we have a variable reference (to the function result) if the name is non-recursive. */ st = gfc_enclosing_unit (NULL); if (st != NULL && st->state == COMP_FUNCTION && st->sym == sym && !sym->attr.recursive) { e = gfc_get_expr (); e->symtree = symtree; e->expr_type = EXPR_VARIABLE; m = gfc_match_varspec (e, 0, false, true); break; } /* Match a function reference. */ function0: m = gfc_match_actual_arglist (0, &actual_arglist); if (m == MATCH_NO) { if (sym->attr.proc == PROC_ST_FUNCTION) gfc_error ("Statement function '%s' requires argument list at %C", sym->name); else gfc_error ("Function '%s' requires an argument list at %C", sym->name); m = MATCH_ERROR; break; } if (m != MATCH_YES) { m = MATCH_ERROR; break; } gfc_get_ha_sym_tree (name, &symtree); /* Can't fail */ sym = symtree->n.sym; replace_hidden_procptr_result (&sym, &symtree); e = gfc_get_expr (); e->symtree = symtree; e->expr_type = EXPR_FUNCTION; e->value.function.actual = actual_arglist; e->where = gfc_current_locus; if (sym->as != NULL) e->rank = sym->as->rank; if (!sym->attr.function && gfc_add_function (&sym->attr, sym->name, NULL) == FAILURE) { m = MATCH_ERROR; break; } /* Check here for the existence of at least one argument for the iso_c_binding functions C_LOC, C_FUNLOC, and C_ASSOCIATED. The argument(s) given will be checked in gfc_iso_c_func_interface, during resolution of the function call. */ if (sym->attr.is_iso_c == 1 && (sym->from_intmod == INTMOD_ISO_C_BINDING && (sym->intmod_sym_id == ISOCBINDING_LOC || sym->intmod_sym_id == ISOCBINDING_FUNLOC || sym->intmod_sym_id == ISOCBINDING_ASSOCIATED))) { /* make sure we were given a param */ if (actual_arglist == NULL) { gfc_error ("Missing argument to '%s' at %C", sym->name); m = MATCH_ERROR; break; } } if (sym->result == NULL) sym->result = sym; m = MATCH_YES; break; case FL_UNKNOWN: /* Special case for derived type variables that get their types via an IMPLICIT statement. This can't wait for the resolution phase. */ if (gfc_peek_ascii_char () == '%' && sym->ts.type == BT_UNKNOWN && gfc_get_default_type (sym->name, sym->ns)->type == BT_DERIVED) gfc_set_default_type (sym, 0, sym->ns); /* If the symbol has a dimension attribute, the expression is a variable. */ if (sym->attr.dimension) { if (gfc_add_flavor (&sym->attr, FL_VARIABLE, sym->name, NULL) == FAILURE) { m = MATCH_ERROR; break; } e = gfc_get_expr (); e->symtree = symtree; e->expr_type = EXPR_VARIABLE; m = gfc_match_varspec (e, 0, false, true); break; } /* Name is not an array, so we peek to see if a '(' implies a function call or a substring reference. Otherwise the variable is just a scalar. */ gfc_gobble_whitespace (); if (gfc_peek_ascii_char () != '(') { /* Assume a scalar variable */ e = gfc_get_expr (); e->symtree = symtree; e->expr_type = EXPR_VARIABLE; if (gfc_add_flavor (&sym->attr, FL_VARIABLE, sym->name, NULL) == FAILURE) { m = MATCH_ERROR; break; } /*FIXME:??? gfc_match_varspec does set this for us: */ e->ts = sym->ts; m = gfc_match_varspec (e, 0, false, true); break; } /* See if this is a function reference with a keyword argument as first argument. We do this because otherwise a spurious symbol would end up in the symbol table. */ old_loc = gfc_current_locus; m2 = gfc_match (" ( %n =", argname); gfc_current_locus = old_loc; e = gfc_get_expr (); e->symtree = symtree; if (m2 != MATCH_YES) { /* Try to figure out whether we're dealing with a character type. We're peeking ahead here, because we don't want to call match_substring if we're dealing with an implicitly typed non-character variable. */ implicit_char = false; if (sym->ts.type == BT_UNKNOWN) { ts = gfc_get_default_type (sym->name, NULL); if (ts->type == BT_CHARACTER) implicit_char = true; } /* See if this could possibly be a substring reference of a name that we're not sure is a variable yet. */ if ((implicit_char || sym->ts.type == BT_CHARACTER) && match_substring (sym->ts.u.cl, 0, &e->ref) == MATCH_YES) { e->expr_type = EXPR_VARIABLE; if (sym->attr.flavor != FL_VARIABLE && gfc_add_flavor (&sym->attr, FL_VARIABLE, sym->name, NULL) == FAILURE) { m = MATCH_ERROR; break; } if (sym->ts.type == BT_UNKNOWN && gfc_set_default_type (sym, 1, NULL) == FAILURE) { m = MATCH_ERROR; break; } e->ts = sym->ts; if (e->ref) e->ts.u.cl = NULL; m = MATCH_YES; break; } } /* Give up, assume we have a function. */ gfc_get_sym_tree (name, NULL, &symtree, false); /* Can't fail */ sym = symtree->n.sym; e->expr_type = EXPR_FUNCTION; if (!sym->attr.function && gfc_add_function (&sym->attr, sym->name, NULL) == FAILURE) { m = MATCH_ERROR; break; } sym->result = sym; m = gfc_match_actual_arglist (0, &e->value.function.actual); if (m == MATCH_NO) gfc_error ("Missing argument list in function '%s' at %C", sym->name); if (m != MATCH_YES) { m = MATCH_ERROR; break; } /* If our new function returns a character, array or structure type, it might have subsequent references. */ m = gfc_match_varspec (e, 0, false, true); if (m == MATCH_NO) m = MATCH_YES; break; generic_function: gfc_get_sym_tree (name, NULL, &symtree, false); /* Can't fail */ e = gfc_get_expr (); e->symtree = symtree; e->expr_type = EXPR_FUNCTION; m = gfc_match_actual_arglist (0, &e->value.function.actual); break; default: gfc_error ("Symbol at %C is not appropriate for an expression"); return MATCH_ERROR; } if (m == MATCH_YES) { e->where = where; *result = e; } else gfc_free_expr (e); return m; } /* Match a variable, i.e. something that can be assigned to. This starts as a symbol, can be a structure component or an array reference. It can be a function if the function doesn't have a separate RESULT variable. If the symbol has not been previously seen, we assume it is a variable. This function is called by two interface functions: gfc_match_variable, which has host_flag = 1, and gfc_match_equiv_variable, with host_flag = 0, to restrict the match of the symbol to the local scope. */ static match match_variable (gfc_expr **result, int equiv_flag, int host_flag) { gfc_symbol *sym; gfc_symtree *st; gfc_expr *expr; locus where; match m; /* Since nothing has any business being an lvalue in a module specification block, an interface block or a contains section, we force the changed_symbols mechanism to work by setting host_flag to 0. This prevents valid symbols that have the name of keywords, such as 'end', being turned into variables by failed matching to assignments for, e.g., END INTERFACE. */ if (gfc_current_state () == COMP_MODULE || gfc_current_state () == COMP_INTERFACE || gfc_current_state () == COMP_CONTAINS) host_flag = 0; where = gfc_current_locus; m = gfc_match_sym_tree (&st, host_flag); if (m != MATCH_YES) return m; sym = st->n.sym; /* If this is an implicit do loop index and implicitly typed, it should not be host associated. */ m = check_for_implicit_index (&st, &sym); if (m != MATCH_YES) return m; sym->attr.implied_index = 0; gfc_set_sym_referenced (sym); switch (sym->attr.flavor) { case FL_VARIABLE: if (sym->attr.is_protected && sym->attr.use_assoc) { gfc_error ("Assigning to PROTECTED variable at %C"); return MATCH_ERROR; } break; case FL_UNKNOWN: { sym_flavor flavor = FL_UNKNOWN; gfc_gobble_whitespace (); if (sym->attr.external || sym->attr.procedure || sym->attr.function || sym->attr.subroutine) flavor = FL_PROCEDURE; /* If it is not a procedure, is not typed and is host associated, we cannot give it a flavor yet. */ else if (sym->ns == gfc_current_ns->parent && sym->ts.type == BT_UNKNOWN) break; /* These are definitive indicators that this is a variable. */ else if (gfc_peek_ascii_char () != '(' || sym->ts.type != BT_UNKNOWN || sym->attr.pointer || sym->as != NULL) flavor = FL_VARIABLE; if (flavor != FL_UNKNOWN && gfc_add_flavor (&sym->attr, flavor, sym->name, NULL) == FAILURE) return MATCH_ERROR; } break; case FL_PARAMETER: if (equiv_flag) gfc_error ("Named constant at %C in an EQUIVALENCE"); else gfc_error ("Cannot assign to a named constant at %C"); return MATCH_ERROR; break; case FL_PROCEDURE: /* Check for a nonrecursive function result variable. */ if (sym->attr.function && !sym->attr.external && sym->result == sym && (gfc_is_function_return_value (sym, gfc_current_ns) || (sym->attr.entry && sym->ns == gfc_current_ns) || (sym->attr.entry && sym->ns == gfc_current_ns->parent))) { /* If a function result is a derived type, then the derived type may still have to be resolved. */ if (sym->ts.type == BT_DERIVED && gfc_use_derived (sym->ts.u.derived) == NULL) return MATCH_ERROR; break; } if (sym->attr.proc_pointer || replace_hidden_procptr_result (&sym, &st) == SUCCESS) break; /* Fall through to error */ default: gfc_error ("'%s' at %C is not a variable", sym->name); return MATCH_ERROR; } /* Special case for derived type variables that get their types via an IMPLICIT statement. This can't wait for the resolution phase. */ { gfc_namespace * implicit_ns; if (gfc_current_ns->proc_name == sym) implicit_ns = gfc_current_ns; else implicit_ns = sym->ns; if (gfc_peek_ascii_char () == '%' && sym->ts.type == BT_UNKNOWN && gfc_get_default_type (sym->name, implicit_ns)->type == BT_DERIVED) gfc_set_default_type (sym, 0, implicit_ns); } expr = gfc_get_expr (); expr->expr_type = EXPR_VARIABLE; expr->symtree = st; expr->ts = sym->ts; expr->where = where; /* Now see if we have to do more. */ m = gfc_match_varspec (expr, equiv_flag, false, false); if (m != MATCH_YES) { gfc_free_expr (expr); return m; } *result = expr; return MATCH_YES; } match gfc_match_variable (gfc_expr **result, int equiv_flag) { return match_variable (result, equiv_flag, 1); } match gfc_match_equiv_variable (gfc_expr **result) { return match_variable (result, 1, 0); }
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