| blob | 0ad8ac2075842a5cda9f0b87052a4c542acfc7f5 |
1 /* Backend support for Fortran 95 basic types and derived types.
2 Copyright (C) 2002-2015 Free Software Foundation, Inc.
3 Contributed by Paul Brook <paul@nowt.org>
4 and Steven Bosscher <s.bosscher@student.tudelft.nl>
6 This file is part of GCC.
8 GCC is free software; you can redistribute it and/or modify it under
9 the terms of the GNU General Public License as published by the Free
10 Software Foundation; either version 3, or (at your option) any later
11 version.
13 GCC is distributed in the hope that it will be useful, but WITHOUT ANY
14 WARRANTY; without even the implied warranty of MERCHANTABILITY or
15 FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
16 for more details.
18 You should have received a copy of the GNU General Public License
19 along with GCC; see the file COPYING3. If not see
20 <http://www.gnu.org/licenses/>. */
22 /* trans-types.c -- gfortran backend types */
28 INT64_TYPE, INT_LEAST8_TYPE, INT_LEAST16_TYPE,
29 INT_LEAST32_TYPE, INT_LEAST64_TYPE, INT_FAST8_TYPE,
30 INT_FAST16_TYPE, INT_FAST32_TYPE, INT_FAST64_TYPE,
31 BOOL_TYPE_SIZE, BITS_PER_UNIT, POINTER_SIZE,
32 INT_TYPE_SIZE, CHAR_TYPE_SIZE, SHORT_TYPE_SIZE,
33 LONG_TYPE_SIZE, LONG_LONG_TYPE_SIZE,
34 FLOAT_TYPE_SIZE, DOUBLE_TYPE_SIZE and
35 LONG_DOUBLE_TYPE_SIZE. */
61 \f
63 #if (GFC_MAX_DIMENSIONS < 10)
64 #define GFC_RANK_DIGITS 1
66 #elif (GFC_MAX_DIMENSIONS < 100)
67 #define GFC_RANK_DIGITS 2
69 #else
70 #error If you really need >99 dimensions, continue the sequence above...
71 #endif
73 /* array of structs so we don't have to worry about xmalloc or free */
76 tree gfc_array_index_type;
77 tree gfc_array_range_type;
78 tree gfc_character1_type_node;
79 tree pvoid_type_node;
80 tree prvoid_type_node;
81 tree ppvoid_type_node;
82 tree pchar_type_node;
83 tree pfunc_type_node;
85 tree gfc_charlen_type_node;
97 /* Arrays for all integral and real kinds. We'll fill this in at runtime
98 after the target has a chance to process command-line options. */
100 #define MAX_INT_KINDS 5
106 #define MAX_REAL_KINDS 5
111 #define MAX_CHARACTER_KINDS 2
118 /* The integer kind to use for array indices. This will be set to the
119 proper value based on target information from the backend. */
123 /* The default kinds of the various types. */
136 /* The kind size used for record offsets. If the target system supports
137 kind=8, this will be set to 8, otherwise it is set to 4. */
140 /* The integer kind used to store character lengths. */
143 /* The size of the numeric storage unit and character storage unit. */
148 bool
150 {
154 {
155 /* Check for any C interoperable kind for the given type/kind in ts.
156 This can be used after verify_c_interop to make sure that the
157 Fortran kind being used exists in at least some form for C. */
161 }
164 }
167 static int
169 {
177 }
179 static int
181 {
192 }
194 /* Return a typenode for the "standard" C type with a given name. */
195 static tree
197 {
229 }
231 static int
233 {
235 }
238 /* Get the kind number corresponding to an integer of given size,
239 following the required return values for ISO_FORTRAN_ENV INT* constants:
240 -2 is returned if we support a kind of larger size, -1 otherwise. */
241 int
243 {
246 /* Look for a kind with matching storage size. */
251 /* Look for a kind with larger storage size. */
257 }
259 /* Get the kind number corresponding to a real of given storage size,
260 following the required return values for ISO_FORTRAN_ENV REAL* constants:
261 -2 is returned if we support a kind of larger size, -1 otherwise. */
262 int
264 {
269 /* Look for a kind with matching storage size. */
274 /* Look for a kind with larger storage size. */
280 }
284 static int
286 {
294 }
296 static int
298 {
306 }
309 /* Generate the CInteropKind_t objects for the C interoperable
310 kinds. */
312 void
314 {
317 /* init all pointers in the list to NULL */
319 {
320 /* Initialize the name and value fields. */
324 }
326 #define NAMED_INTCST(a,b,c,d) \
327 strncpy (c_interop_kinds_table[a].name, b, strlen(b) + 1); \
328 c_interop_kinds_table[a].f90_type = BT_INTEGER; \
329 c_interop_kinds_table[a].value = c;
330 #define NAMED_REALCST(a,b,c,d) \
331 strncpy (c_interop_kinds_table[a].name, b, strlen(b) + 1); \
332 c_interop_kinds_table[a].f90_type = BT_REAL; \
333 c_interop_kinds_table[a].value = c;
334 #define NAMED_CMPXCST(a,b,c,d) \
335 strncpy (c_interop_kinds_table[a].name, b, strlen(b) + 1); \
336 c_interop_kinds_table[a].f90_type = BT_COMPLEX; \
337 c_interop_kinds_table[a].value = c;
338 #define NAMED_LOGCST(a,b,c) \
339 strncpy (c_interop_kinds_table[a].name, b, strlen(b) + 1); \
340 c_interop_kinds_table[a].f90_type = BT_LOGICAL; \
341 c_interop_kinds_table[a].value = c;
342 #define NAMED_CHARKNDCST(a,b,c) \
343 strncpy (c_interop_kinds_table[a].name, b, strlen(b) + 1); \
344 c_interop_kinds_table[a].f90_type = BT_CHARACTER; \
345 c_interop_kinds_table[a].value = c;
346 #define NAMED_CHARCST(a,b,c) \
347 strncpy (c_interop_kinds_table[a].name, b, strlen(b) + 1); \
348 c_interop_kinds_table[a].f90_type = BT_CHARACTER; \
349 c_interop_kinds_table[a].value = c;
350 #define DERIVED_TYPE(a,b,c) \
351 strncpy (c_interop_kinds_table[a].name, b, strlen(b) + 1); \
352 c_interop_kinds_table[a].f90_type = BT_DERIVED; \
353 c_interop_kinds_table[a].value = c;
354 #define NAMED_FUNCTION(a,b,c,d) \
355 strncpy (c_interop_kinds_table[a].name, b, strlen(b) + 1); \
356 c_interop_kinds_table[a].f90_type = BT_PROCEDURE; \
357 c_interop_kinds_table[a].value = c;
358 #define NAMED_SUBROUTINE(a,b,c,d) \
359 strncpy (c_interop_kinds_table[a].name, b, strlen(b) + 1); \
360 c_interop_kinds_table[a].f90_type = BT_PROCEDURE; \
361 c_interop_kinds_table[a].value = c;
363 }
366 /* Query the target to determine which machine modes are available for
367 computation. Choose KIND numbers for them. */
369 void
371 {
378 {
384 /* The middle end doesn't support constants larger than 2*HWI.
385 Perhaps the target hook shouldn't have accepted these either,
386 but just to be safe... */
393 /* Let the kind equal the bit size divided by 8. This insulates the
394 programmer from the underlying byte size. */
411 }
413 /* Set the kind used to match GFC_INT_IO in libgfortran. This is
414 used for large file access. */
418 else
421 /* If we do not at least have kind = 4, everything is pointless. */
424 /* Set the maximum integer kind. Used with at least BOZ constants. */
428 {
438 /* Only let float, double, long double and __float128 go through.
439 Runtime support for others is not provided, so they would be
440 useless. */
442 mode))
447 #if defined(HAVE_TFmode) && defined(ENABLE_LIBQUADMATH_SUPPORT)
449 #endif
450 )
453 /* Let the kind equal the precision divided by 8, rounding up. Again,
454 this insulates the programmer from the underlying byte size.
456 Also, it effectively deals with IEEE extended formats. There, the
457 total size of the type may equal 16, but it's got 6 bytes of padding
458 and the increased size can get in the way of a real IEEE quad format
459 which may also be supported by the target.
461 We round up so as to handle IA-64 __floatreg (RFmode), which is an
462 82 bit type. Not to be confused with __float80 (XFmode), which is
463 an 80 bit type also supported by IA-64. So XFmode should come out
464 to be kind=10, and RFmode should come out to be kind=11. Egads. */
477 /* Careful we don't stumble a weird internal mode. */
479 /* Or have too many modes for the allocated space. */
488 /* This is an IBM extended double format (or the MIPS variant)
489 made up of two IEEE doubles. The value of the long double is
490 the sum of the values of the two parts. The most significant
491 part is required to be the value of the long double rounded
492 to the nearest double. If we use emax of 1024 then we can't
493 represent huge(x) = (1 - b**(-p)) * b**(emax-1) * b, because
494 rounding will make the most significant part overflow. */
498 }
500 /* Choose the default integer kind. We choose 4 unless the user directs us
501 otherwise. Even if the user specified that the default integer kind is 8,
502 the numeric storage size is not 64 bits. In this case, a warning will be
503 issued when NUMERIC_STORAGE_SIZE is used. Set NUMERIC_STORAGE_SIZE to 32. */
508 {
515 }
517 {
523 }
525 {
527 }
528 else
529 {
532 }
534 /* Choose the default real kind. Again, we choose 4 when possible. */
536 {
542 }
544 {
550 }
552 {
558 }
560 {
566 }
569 else
572 /* Choose the default double kind. If -fdefault-real and -fdefault-double
573 are specified, we use kind=8, if it's available. If -fdefault-real is
574 specified without -fdefault-double, we use kind=16, if it's available.
575 Otherwise we do not change anything. */
585 {
591 }
593 {
599 }
601 {
607 }
610 else
611 {
612 /* F95 14.6.3.1: A nonpointer scalar object of type double precision
613 real ... occupies two contiguous numeric storage units.
615 Therefore we must be supplied a kind twice as large as we chose
616 for single precision. There are loopholes, in that double
617 precision must *occupy* two storage units, though it doesn't have
618 to *use* two storage units. Which means that you can make this
619 kind artificially wide by padding it. But at present there are
620 no GCC targets for which a two-word type does not exist, so we
621 just let gfc_validate_kind abort and tell us if something breaks. */
623 gfc_default_double_kind
625 }
627 /* The default logical kind is constrained to be the same as the
628 default integer kind. Similarly with complex and real. */
632 /* We only have two character kinds: ASCII and UCS-4.
633 ASCII corresponds to a 8-bit integer type, if one is available.
634 UCS-4 corresponds to a 32-bit integer type, if one is available. */
637 {
641 i_index++;
642 }
644 {
648 i_index++;
649 }
651 /* Choose the smallest integer kind for our default character. */
657 /* Pick a kind the same size as the C "int" type. */
660 /* Choose atomic kinds to match C's int. */
663 }
666 /* Make sure that a valid kind is present. Returns an index into the
667 associated kinds array, -1 if the kind is not present. */
669 static int
671 {
679 }
681 static int
683 {
691 }
693 static int
695 {
703 }
705 static int
707 {
715 }
717 /* Validate a kind given a basic type. The return value is the same
718 for the child functions, with -1 indicating nonexistence of the
719 type. If MAY_FAIL is false, then -1 is never returned, and we ICE. */
721 int
723 {
727 {
744 }
750 }
753 /* Four subroutines of gfc_init_types. Create type nodes for the given kind.
754 Reuse common type nodes where possible. Recognize if the kind matches up
755 with a C type. This will be used later in determining which routines may
756 be scarfed from libm. */
758 static tree
760 {
786 }
788 tree
790 {
803 }
806 static tree
808 {
810 tree new_type;
819 {
822 }
835 }
837 static tree
839 {
840 tree new_type;
855 }
857 static tree
859 {
861 tree new_type;
864 {
867 }
875 }
878 /* Create the backend type nodes. We map them to their
879 equivalent C type, at least for now. We also give
880 names to the types here, and we push them in the
881 global binding level context.*/
883 void
885 {
888 tree type;
891 /* Create and name the types. */
892 #define PUSH_TYPE(name, node) \
893 pushdecl (build_decl (input_location, \
894 TYPE_DECL, get_identifier (name), node))
897 {
899 /* Ensure integer(kind=1) doesn't have TYPE_STRING_FLAG set. */
906 }
909 {
915 }
918 {
936 }
939 {
947 }
953 /* DBX debugging output gets upset if these aren't set. */
959 #undef PUSH_TYPE
965 pfunc_type_node
969 /* We cannot use gfc_index_zero_node in definition of gfc_array_range_type,
970 since this function is called before gfc_init_constants. */
971 gfc_array_range_type
974 NULL_TREE);
976 /* The maximum array element size that can be handled is determined
977 by the number of bits available to store this field in the array
978 descriptor. */
981 gfc_max_array_element_size
990 /* ??? Shouldn't this be based on gfc_index_integer_kind or so? */
993 }
995 /* Get the type node for the given type and kind. */
997 tree
999 {
1002 }
1004 tree
1006 {
1009 }
1011 tree
1013 {
1016 }
1018 tree
1020 {
1023 }
1025 tree
1027 {
1030 }
1032 tree
1034 {
1037 }
1039 \f
1040 /* Create a character type with the given kind and length. */
1042 tree
1044 {
1052 }
1054 tree
1056 {
1059 }
1062 /* Get a type node for a character kind. */
1064 tree
1066 {
1067 tree len;
1072 }
1073 \f
1074 /* Covert a basic type. This will be an array for character types. */
1076 tree
1078 {
1079 tree basetype;
1082 {
1087 /* We use INTEGER(c_intptr_t) for C_PTR and C_FUNPTR once the symbol
1088 has been resolved. This is done so we can convert C_PTR and
1089 C_FUNPTR to simple variables that get translated to (void *). */
1091 {
1095 else
1097 }
1098 else
1119 /* Since this cannot be used, return a length one character. */
1121 gfc_index_one_node);
1131 /* If we're dealing with either C_PTR or C_FUNPTR, we modified the
1132 type and kind to fit a (void *) and the basetype returned was a
1133 ptr_type_node. We need to pass up this new information to the
1134 symbol that was declared of type C_PTR or C_FUNPTR. */
1136 {
1140 }
1144 /* This is for the second arg to c_f_pointer and c_f_procpointer
1145 of the iso_c_binding module, to accept any ptr type. */
1148 {
1152 else
1154 }
1158 }
1160 }
1161 \f
1162 /* Build an INT_CST for constant expressions, otherwise return NULL_TREE. */
1164 static tree
1166 {
1167 /* If expr is an integer constant, return that. */
1171 /* Otherwise return NULL. */
1173 }
1174 \f
1175 /* Return the type of an element of the array. Note that scalar coarrays
1176 are special. In particular, for GFC_ARRAY_TYPE_P, the original argument
1177 (with POINTER_TYPE stripped) is returned. */
1179 tree
1181 {
1182 tree element;
1185 {
1189 {
1192 }
1193 else
1194 {
1197 }
1198 }
1199 else
1200 {
1207 /* For arrays, which are not scalar coarrays. */
1210 }
1213 }
1214 \f
1215 /* Build an array. This function is called from gfc_sym_type().
1216 Actually returns array descriptor type.
1218 Format of array descriptors is as follows:
1220 struct gfc_array_descriptor
1221 {
1222 array *data
1223 index offset;
1224 index dtype;
1225 struct descriptor_dimension dimension[N_DIM];
1226 }
1228 struct descriptor_dimension
1229 {
1230 index stride;
1231 index lbound;
1232 index ubound;
1233 }
1235 Translation code should use gfc_conv_descriptor_* rather than
1236 accessing the descriptor directly. Any changes to the array
1237 descriptor type will require changes in gfc_conv_descriptor_* and
1238 gfc_build_array_initializer.
1240 This is represented internally as a RECORD_TYPE. The index nodes
1241 are gfc_array_index_type and the data node is a pointer to the
1242 data. See below for the handling of character types.
1244 The dtype member is formatted as follows:
1245 rank = dtype & GFC_DTYPE_RANK_MASK // 3 bits
1246 type = (dtype & GFC_DTYPE_TYPE_MASK) >> GFC_DTYPE_TYPE_SHIFT // 3 bits
1247 size = dtype >> GFC_DTYPE_SIZE_SHIFT
1249 I originally used nested ARRAY_TYPE nodes to represent arrays, but
1250 this generated poor code for assumed/deferred size arrays. These
1251 require use of PLACEHOLDER_EXPR/WITH_RECORD_EXPR, which isn't part
1252 of the GENERIC grammar. Also, there is no way to explicitly set
1253 the array stride, so all data must be packed(1). I've tried to
1254 mark all the functions which would require modification with a GCC
1255 ARRAYS comment.
1257 The data component points to the first element in the array. The
1258 offset field is the position of the origin of the array (i.e. element
1259 (0, 0 ...)). This may be outside the bounds of the array.
1261 An element is accessed by
1262 data[offset + index0*stride0 + index1*stride1 + index2*stride2]
1263 This gives good performance as the computation does not involve the
1264 bounds of the array. For packed arrays, this is optimized further
1265 by substituting the known strides.
1267 This system has one problem: all array bounds must be within 2^31
1268 elements of the origin (2^63 on 64-bit machines). For example
1269 integer, dimension (80000:90000, 80000:90000, 2) :: array
1270 may not work properly on 32-bit machines because 80000*80000 >
1271 2^31, so the calculation for stride2 would overflow. This may
1272 still work, but I haven't checked, and it relies on the overflow
1273 doing the right thing.
1275 The way to fix this problem is to access elements as follows:
1276 data[(index0-lbound0)*stride0 + (index1-lbound1)*stride1]
1277 Obviously this is much slower. I will make this a compile time
1278 option, something like -fsmall-array-offsets. Mixing code compiled
1279 with and without this switch will work.
1281 (1) This can be worked around by modifying the upper bound of the
1282 previous dimension. This requires extra fields in the descriptor
1283 (both real_ubound and fake_ubound). */
1286 /* Returns true if the array sym does not require a descriptor. */
1288 int
1290 {
1293 /* We only want local arrays. */
1297 /* We want a descriptor for associate-name arrays that do not have an
1298 explicitly known shape already. */
1312 }
1315 /* Create an array descriptor type. */
1317 static tree
1321 {
1326 /* Assumed-shape arrays do not have codimension information stored in the
1327 descriptor. */
1335 {
1338 }
1341 {
1342 /* Create expressions for the known bounds of the array. */
1345 else
1348 }
1351 {
1354 else
1359 }
1371 }
1372 \f
1373 /* Returns the struct descriptor_dimension type. */
1375 static tree
1377 {
1378 tree type;
1384 /* Build the type node. */
1390 /* Consists of the stride, lbound and ubound members. */
1406 /* Finish off the type. */
1412 }
1415 /* Return the DTYPE for an array. This describes the type and type parameters
1416 of the array. */
1417 /* TODO: Only call this when the value is actually used, and make all the
1418 unknown cases abort. */
1420 tree
1422 {
1423 tree size;
1425 HOST_WIDE_INT i;
1426 tree tmp;
1427 tree dtype;
1430 {
1447 /* We will never have arrays of arrays. */
1461 /* TODO: Don't do dtype for temporary descriptorless arrays. */
1462 /* We can strange array types for temporary arrays. */
1464 }
1471 {
1476 }
1480 {
1483 gfc_array_index_type,
1487 }
1488 /* If we don't know the size we leave it as zero. This should never happen
1489 for anything that is actually used. */
1490 /* TODO: Check this is actually true, particularly when repacking
1491 assumed size parameters. */
1494 }
1497 tree
1499 {
1500 tree dtype;
1501 tree etype;
1515 }
1518 /* Build an array type for use without a descriptor, packed according
1519 to the value of PACKED. */
1521 tree
1524 {
1525 tree range;
1526 tree type;
1527 tree tmp;
1531 mpz_t offset;
1532 mpz_t stride;
1533 mpz_t delta;
1540 /* We don't use build_array_type because this does not include include
1541 lang-specific information (i.e. the bounds of the array) when checking
1542 for duplicates. */
1545 else
1554 {
1555 /* Fill in the stride and bound components of the type. */
1558 else
1564 {
1566 gfc_index_integer_kind);
1567 }
1568 else
1569 {
1572 }
1576 {
1577 /* Calculate the offset. */
1580 }
1581 else
1586 {
1588 gfc_index_integer_kind);
1589 }
1590 else
1591 {
1594 }
1598 {
1599 /* Calculate the stride. */
1604 }
1606 /* Only the first stride is known for partial packed arrays. */
1609 }
1611 {
1615 gfc_index_integer_kind);
1616 else
1623 gfc_index_integer_kind);
1624 else
1628 }
1631 {
1634 }
1635 else
1639 {
1642 }
1643 else
1650 NULL_TREE);
1651 /* TODO: use main type if it is unbounded. */
1657 TYPE_QUAL_RESTRICT);
1660 {
1662 {
1670 }
1673 }
1676 {
1679 }
1680 else
1695 /* Represent packed arrays as multi-dimensional if they have rank >
1696 1 and with proper bounds, instead of flat arrays. This makes for
1697 better debug info. */
1699 {
1703 {
1708 }
1712 }
1716 {
1717 /* For dummy arrays and automatic (heap allocated) arrays we
1718 want a pointer to the array. */
1724 }
1726 }
1729 /* Return or create the base type for an array descriptor. */
1731 static tree
1734 {
1739 /* Assumed-rank array. */
1748 {
1751 }
1755 /* Build the type node. */
1762 /* Add the data member as the first element of the descriptor. */
1765 (restricted
1766 ? prvoid_type_node
1769 /* Add the base component. */
1775 /* Add the dtype component. */
1781 /* Build the array type for the stride and bound components. */
1783 {
1784 arraytype =
1787 gfc_index_zero_node,
1793 }
1797 {
1802 }
1804 /* Finish off the type. */
1811 else
1815 }
1818 /* Build an array (descriptor) type with given bounds. */
1820 tree
1824 {
1832 /* Make sure that nontarget and target array type have the same canonical
1833 type (and same stub decl for debug info). */
1843 else
1858 /* Build an array descriptor record type. */
1861 else
1864 {
1870 else
1874 {
1877 else
1879 }
1886 {
1889 else
1891 }
1897 {
1902 gfc_index_one_node);
1905 /* Check the folding worked. */
1907 }
1908 else
1910 }
1913 /* TODO: known offsets for descriptors. */
1917 {
1924 }
1926 /* We define data as an array with the correct size if possible.
1927 Much better than doing pointer arithmetic. */
1932 else
1940 /* This will generate the base declarations we need to emit debug
1941 information for this type. FIXME: there must be a better way to
1942 avoid divergence between compilations with and without debug
1943 information. */
1944 {
1948 }
1951 }
1952 \f
1953 /* Build a pointer type. This function is called from gfc_sym_type(). */
1955 static tree
1957 {
1958 /* Array pointer types aren't actually pointers. */
1961 else
1963 }
1966 /* Given two record or union type nodes TO and FROM, ensure
1967 that all fields in FROM have a corresponding field in TO,
1968 their type being nonrestrict variants. This accepts a TO
1969 node that already has a prefix of the fields in FROM. */
1970 static void
1972 {
1976 /* Forward to the end of TOs fields. */
1981 {
1986 }
1988 /* Now add all fields remaining in FROM (starting with ffrom). */
1990 {
1993 /* The store to DECL_CHAIN might seem redundant with the
1994 stores to *chain, but not clearing it here would mean
1995 leaving a chain into the old fields. If ever
1996 our called functions would look at them confusion
1997 will arise. */
2003 {
2006 }
2007 }
2009 }
2011 /* Given a type T, returns a different type of the same structure,
2012 except that all types it refers to (recursively) are always
2013 non-restrict qualified types. */
2014 static tree
2016 {
2019 /* If the type isn't laid out yet, don't copy it. If something
2020 needs it for real it should wait until the type got finished. */
2026 /* If we're dealing with this very node already further up
2027 the call chain (recursion via pointers and struct members)
2028 we haven't yet determined if we really need a new type node.
2029 Assume we don't, return T itself. */
2033 /* If we have calculated this all already, just return it. */
2037 /* Mark this type. */
2041 {
2047 {
2053 else
2057 }
2061 {
2065 else
2066 {
2071 {
2075 {
2080 }
2081 }
2082 }
2083 }
2089 {
2090 tree field;
2091 /* First determine if we need a new type at all.
2092 Careful, the two calls to gfc_nonrestricted_type per field
2093 might return different values. That happens exactly when
2094 one of the fields reaches back to this very record type
2095 (via pointers). The first calls will assume that we don't
2096 need to copy T (see the error_mark_node marking). If there
2097 are any reasons for copying T apart from having to copy T,
2098 we'll indeed copy it, and the second calls to
2099 gfc_nonrestricted_type will use that new node if they
2100 reach back to T. */
2103 {
2107 }
2113 /* Here we make sure that as soon as we know we have to copy
2114 T, that also fields reaching back to us will use the new
2115 copy. It's okay if that copy still contains the old fields,
2116 we won't look at them. */
2119 }
2121 }
2125 }
2127 \f
2128 /* Return the type for a symbol. Special handling is required for character
2129 types to get the correct level of indirection.
2130 For functions return the return type.
2131 For subroutines return void_type_node.
2132 Calling this multiple times for the same symbol should be avoided,
2133 especially for character and array types. */
2135 tree
2137 {
2138 tree type;
2142 /* Procedure Pointers inside COMMON blocks. */
2144 {
2145 /* Unset proc_pointer as gfc_get_function_type calls gfc_sym_type. */
2150 }
2155 /* In the case of a function the fake result variable may have a
2156 type different from the function type, so don't return early in
2157 that case. */
2169 else
2174 else
2183 {
2185 {
2186 /* If this is a character argument of unknown length, just use the
2187 base type. */
2191 {
2193 byref ? PACKED_FULL
2195 restricted);
2197 }
2198 }
2199 else
2200 {
2209 }
2210 }
2211 else
2212 {
2216 }
2218 /* We currently pass all parameters by reference.
2219 See f95_get_function_decl. For dummy function parameters return the
2220 function type. */
2222 {
2223 /* We must use pointer types for potentially absent variables. The
2224 optimizers assume a reference type argument is never NULL. */
2228 else
2229 {
2233 }
2234 }
2237 }
2238 \f
2239 /* Layout and output debug info for a record type. */
2241 void
2243 {
2244 tree decl;
2252 }
2253 \f
2254 /* Add a field of given NAME and TYPE to the context of a UNION_TYPE
2255 or RECORD_TYPE pointed to by CONTEXT. The new field is chained
2256 to the end of the field list pointed to by *CHAIN.
2258 Returns a pointer to the new field. */
2260 static tree
2262 {
2270 {
2274 }
2277 }
2279 /* Like `gfc_add_field_to_struct_1', but adds alignment
2280 information. */
2282 tree
2284 {
2292 }
2295 /* Copy the backend_decl and component backend_decls if
2296 the two derived type symbols are "equal", as described
2297 in 4.4.2 and resolved by gfc_compare_derived_types. */
2299 int
2302 {
2318 /* Copy the component declarations. If a component is itself
2319 a derived type, we need a copy of its component declarations.
2320 This is done by recursing into gfc_get_derived_type and
2321 ensures that the component's component declarations have
2322 been built. If it is a character, we need the character
2323 length, as well. */
2325 {
2335 }
2338 }
2341 /* Build a tree node for a procedure pointer component. */
2343 tree
2345 {
2346 tree t;
2348 /* Explicit interface. */
2352 /* Implicit interface (only return value may be known). */
2355 else
2359 }
2362 /* Build a tree node for a derived type. If there are equal
2363 derived types, with different local names, these are built
2364 at the same time. If an equal derived type has been built
2365 in a parent namespace, this is used. */
2367 tree
2369 {
2389 /* See if it's one of the iso_c_binding derived types. */
2391 {
2397 else
2402 /* Set the f90_type to BT_VOID as a way to recognize something of type
2403 BT_INTEGER that needs to fit a void * for the purpose of the
2404 iso_c_binding derived types. */
2408 }
2410 /* If use associated, use the module type for this one. */
2417 /* The derived types from an earlier namespace can be used as the
2418 canonical type. */
2421 {
2425 {
2428 {
2432 }
2433 }
2434 }
2436 /* Store up the canonical type to be added to this one. */
2438 {
2441 else
2445 }
2447 /* derived->backend_decl != 0 means we saw it before, but its
2448 components' backend_decl may have not been built. */
2450 {
2451 /* Its components' backend_decl have been built or we are
2452 seeing recursion through the formal arglist of a procedure
2453 pointer component. */
2458 {
2459 /* If an abstract derived type with procedure pointer
2460 components has no other type of component, return the
2461 backend_decl. Otherwise build the components if any of the
2462 non-procedure pointer components have no backend_decl. */
2464 {
2469 }
2471 }
2472 else
2474 }
2475 else
2476 {
2477 /* We see this derived type first time, so build the type node. */
2482 }
2490 /* Go through the derived type components, building them as
2491 necessary. The reason for doing this now is that it is
2492 possible to recurse back to this derived type through a
2493 pointer component (PR24092). If this happens, the fields
2494 will be built and so we can return the type. */
2496 {
2505 {
2506 /* Need to copy the modified ts from the derived type. The
2507 typespec was modified because C_PTR/C_FUNPTR are translated
2508 into (void *) from derived types. */
2513 {
2518 }
2519 }
2520 }
2525 /* Build the type member list. Install the newly created RECORD_TYPE
2526 node as DECL_CONTEXT of each FIELD_DECL. */
2528 {
2533 else
2534 {
2536 {
2537 /* Evaluate the string length. */
2540 }
2546 }
2548 /* This returns an array descriptor type. Initialization may be
2549 required. */
2551 {
2553 {
2558 else
2560 /* Pointers to arrays aren't actually pointer types. The
2561 descriptors are separate, but the data is common. */
2566 }
2567 else
2569 PACKED_STATIC,
2571 }
2580 /* vtype fields can point to different types to the base type. */
2586 /* Ensure that the CLASS language specific flag is set. */
2588 {
2591 else
2593 }
2610 }
2612 /* Now lay out the derived type, including the fields. */
2620 {
2624 {
2628 }
2629 }
2633 copy_derived_types:
2639 }
2642 int
2644 {
2658 /* Possibly return complex numbers by reference for g77 compatibility.
2659 We don't do this for calls to intrinsics (as the library uses the
2660 -fno-f2c calling convention), nor for calls to functions which always
2661 require an explicit interface, as no compatibility problems can
2662 arise there. */
2668 }
2669 \f
2670 static tree
2672 {
2673 tree type;
2683 /* Build the type node. */
2689 {
2690 /* Search for duplicates. */
2699 }
2701 /* Finish off the type. */
2705 }
2706 \f
2707 /* Create a "fn spec" based on the formal arguments;
2708 cf. create_function_arglist. */
2710 static tree
2712 {
2716 tree tmp;
2725 {
2730 else
2734 }
2738 {
2752 }
2757 }
2760 tree
2762 {
2763 tree type;
2770 /* Make sure this symbol is a function, a subroutine or the main
2771 program. */
2775 /* To avoid recursing infinitely on recursive types, we use error_mark_node
2776 so that they can be detected here and handled further down. */
2783 else
2787 /* Additional parameter for selecting an entry point. */
2792 else
2798 /* Some functions we use an extra parameter for the return value. */
2800 {
2809 {
2811 /* Transfer by value. */
2813 else
2814 /* Deferred character lengths are transferred by reference
2815 so that the value can be returned. */
2817 }
2818 }
2820 /* Build the argument types for the function. */
2822 {
2825 {
2826 /* Evaluate constant character lengths here so that they can be
2827 included in the type. */
2832 {
2835 }
2836 else
2839 /* Parameter Passing Convention
2841 We currently pass all parameters by reference.
2842 Parameters with INTENT(IN) could be passed by value.
2843 The problem arises if a function is called via an implicit
2844 prototype. In this situation the INTENT is not known.
2845 For this reason all parameters to global functions must be
2846 passed by reference. Passing by value would potentially
2847 generate bad code. Worse there would be no way of telling that
2848 this code was bad, except that it would give incorrect results.
2850 Contained procedures could pass by value as these are never
2851 used without an explicit interface, and cannot be passed as
2852 actual parameters for a dummy procedure. */
2855 }
2856 else
2857 {
2860 }
2861 }
2863 /* Add hidden string length parameters. */
2865 {
2868 {
2870 /* Transfer by value. */
2872 else
2873 /* Deferred character lengths are transferred by reference
2874 so that the value can be returned. */
2878 }
2879 }
2889 arg_type_list_done:
2900 {
2901 /* Special case: f2c calling conventions require that (scalar)
2902 default REAL functions return the C type double instead. f2c
2903 compatibility is only an issue with functions that don't
2904 require an explicit interface, as only these could be
2905 implemented in Fortran 77. */
2909 }
2911 /* Procedure pointer return values. */
2912 {
2914 {
2915 /* Unset proc_pointer as gfc_get_function_type
2916 is called recursively. */
2920 }
2921 else
2923 }
2924 else
2929 else
2934 }
2935 \f
2936 /* Language hooks for middle-end access to type nodes. */
2938 /* Return an integer type with BITS bits of precision,
2939 that is unsigned if UNSIGNEDP is nonzero, otherwise signed. */
2941 tree
2943 {
2945 {
2948 {
2952 }
2954 /* Handle TImode as a special case because it is used by some backends
2955 (e.g. ARM) even though it is not available for normal use. */
2956 #if HOST_BITS_PER_WIDE_INT >= 64
2959 #endif
2971 }
2972 else
2973 {
2984 }
2987 }
2989 /* Return a data type that has machine mode MODE. If the mode is an
2990 integer, then UNSIGNEDP selects between signed and unsigned types. */
2992 tree
2994 {
3003 {
3006 }
3008 {
3014 }
3015 else
3019 {
3023 }
3026 }
3028 /* Return TRUE if TYPE is a type with a hidden descriptor, fill in INFO
3029 in that case. */
3031 bool
3033 {
3041 {
3048 }
3058 /* If the type is not a scalar coarray. */
3062 /* Can't handle variable sized elements yet. */
3065 /* Nor non-constant lower bounds in assumed shape arrays. */
3068 {
3073 }
3082 {
3088 }
3095 else
3125 {
3138 {
3139 /* Assumed shape arrays have known lower bounds. */
3151 }
3159 }
3162 }
3165 /* Create a type to handle vector subscripts for coarray library calls. It
3166 has the form:
3167 struct caf_vector_t {
3168 size_t nvec; // size of the vector
3169 union {
3170 struct {
3171 void *vector;
3172 int kind;
3173 } v;
3174 struct {
3175 ptrdiff_t lower_bound;
3176 ptrdiff_t upper_bound;
3177 ptrdiff_t stride;
3178 } triplet;
3179 } u;
3180 }
3181 where nvec == 0 for DIMEN_ELEMENT or DIMEN_RANGE and nvec being the vector
3182 size in case of DIMEN_VECTOR, where kind is the integer type of the vector. */
3184 tree
3186 {
3195 {
3243 }
3249 }