PR tree-optimization/79691 - -Wformat-truncation suppressed by (and only by) -Og
[official-gcc.git] / libcpp / include / line-map.h
blobec56de396151e1edd946f536cc4d2df7c50a7a31
1 /* Map (unsigned int) keys to (source file, line, column) triples.
2 Copyright (C) 2001-2017 Free Software Foundation, Inc.
4 This program is free software; you can redistribute it and/or modify it
5 under the terms of the GNU General Public License as published by the
6 Free Software Foundation; either version 3, or (at your option) any
7 later version.
9 This program is distributed in the hope that it will be useful,
10 but WITHOUT ANY WARRANTY; without even the implied warranty of
11 MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
12 GNU General Public License for more details.
14 You should have received a copy of the GNU General Public License
15 along with this program; see the file COPYING3. If not see
16 <http://www.gnu.org/licenses/>.
18 In other words, you are welcome to use, share and improve this program.
19 You are forbidden to forbid anyone else to use, share and improve
20 what you give them. Help stamp out software-hoarding! */
22 #ifndef LIBCPP_LINE_MAP_H
23 #define LIBCPP_LINE_MAP_H
25 #ifndef GTY
26 #define GTY(x) /* nothing */
27 #endif
29 /* Reason for creating a new line map with linemap_add. LC_ENTER is
30 when including a new file, e.g. a #include directive in C.
31 LC_LEAVE is when reaching a file's end. LC_RENAME is when a file
32 name or line number changes for neither of the above reasons
33 (e.g. a #line directive in C); LC_RENAME_VERBATIM is like LC_RENAME
34 but a filename of "" is not specially interpreted as standard
35 input. LC_ENTER_MACRO is when a macro expansion is about to start. */
36 enum lc_reason
38 LC_ENTER = 0,
39 LC_LEAVE,
40 LC_RENAME,
41 LC_RENAME_VERBATIM,
42 LC_ENTER_MACRO
43 /* FIXME: add support for stringize and paste. */
46 /* The type of line numbers. */
47 typedef unsigned int linenum_type;
49 /* The typedef "source_location" is a key within the location database,
50 identifying a source location or macro expansion, along with range
51 information, and (optionally) a pointer for use by gcc.
53 This key only has meaning in relation to a line_maps instance. Within
54 gcc there is a single line_maps instance: "line_table", declared in
55 gcc/input.h and defined in gcc/input.c.
57 The values of the keys are intended to be internal to libcpp,
58 but for ease-of-understanding the implementation, they are currently
59 assigned as follows:
61 Actual | Value | Meaning
62 -----------+-------------------------------+-------------------------------
63 0x00000000 | UNKNOWN_LOCATION (gcc/input.h)| Unknown/invalid location.
64 -----------+-------------------------------+-------------------------------
65 0x00000001 | BUILTINS_LOCATION | The location for declarations
66 | (gcc/input.h) | in "<built-in>"
67 -----------+-------------------------------+-------------------------------
68 0x00000002 | RESERVED_LOCATION_COUNT | The first location to be
69 | (also | handed out, and the
70 | ordmap[0]->start_location) | first line in ordmap 0
71 -----------+-------------------------------+-------------------------------
72 | ordmap[1]->start_location | First line in ordmap 1
73 | ordmap[1]->start_location+32 | First column in that line
74 | (assuming range_bits == 5) |
75 | ordmap[1]->start_location+64 | 2nd column in that line
76 | ordmap[1]->start_location+4096| Second line in ordmap 1
77 | (assuming column_bits == 12)
79 | Subsequent lines are offset by (1 << column_bits),
80 | e.g. 4096 for 12 bits, with a column value of 0 representing
81 | "the whole line".
83 | Within a line, the low "range_bits" (typically 5) are used for
84 | storing short ranges, so that there's an offset of
85 | (1 << range_bits) between individual columns within a line,
86 | typically 32.
87 | The low range_bits store the offset of the end point from the
88 | start point, and the start point is found by masking away
89 | the range bits.
91 | For example:
92 | ordmap[1]->start_location+64 "2nd column in that line"
93 | above means a caret at that location, with a range
94 | starting and finishing at the same place (the range bits
95 | are 0), a range of length 1.
97 | By contrast:
98 | ordmap[1]->start_location+68
99 | has range bits 0x4, meaning a caret with a range starting at
100 | that location, but with endpoint 4 columns further on: a range
101 | of length 5.
103 | Ranges that have caret != start, or have an endpoint too
104 | far away to fit in range_bits are instead stored as ad-hoc
105 | locations. Hence for range_bits == 5 we can compactly store
106 | tokens of length <= 32 without needing to use the ad-hoc
107 | table.
109 | This packing scheme means we effectively have
110 | (column_bits - range_bits)
111 | of bits for the columns, typically (12 - 5) = 7, for 128
112 | columns; longer line widths are accomodated by starting a
113 | new ordmap with a higher column_bits.
115 | ordmap[2]->start_location-1 | Final location in ordmap 1
116 -----------+-------------------------------+-------------------------------
117 | ordmap[2]->start_location | First line in ordmap 2
118 | ordmap[3]->start_location-1 | Final location in ordmap 2
119 -----------+-------------------------------+-------------------------------
120 | | (etc)
121 -----------+-------------------------------+-------------------------------
122 | ordmap[n-1]->start_location | First line in final ord map
123 | | (etc)
124 | set->highest_location - 1 | Final location in that ordmap
125 -----------+-------------------------------+-------------------------------
126 | set->highest_location | Location of the where the next
127 | | ordinary linemap would start
128 -----------+-------------------------------+-------------------------------
130 | VVVVVVVVVVVVVVVVVVVVVVVVVVV
131 | Ordinary maps grow this way
133 | (unallocated integers)
135 0x60000000 | LINE_MAP_MAX_LOCATION_WITH_COLS
136 | Beyond this point, ordinary linemaps have 0 bits per column:
137 | each increment of the value corresponds to a new source line.
139 0x70000000 | LINE_MAP_MAX_SOURCE_LOCATION
140 | Beyond the point, we give up on ordinary maps; attempts to
141 | create locations in them lead to UNKNOWN_LOCATION (0).
143 | (unallocated integers)
145 | Macro maps grow this way
146 | ^^^^^^^^^^^^^^^^^^^^^^^^
148 -----------+-------------------------------+-------------------------------
149 | LINEMAPS_MACRO_LOWEST_LOCATION| Locations within macro maps
150 | macromap[m-1]->start_location | Start of last macro map
152 -----------+-------------------------------+-------------------------------
153 | macromap[m-2]->start_location | Start of penultimate macro map
154 -----------+-------------------------------+-------------------------------
155 | macromap[1]->start_location | Start of macro map 1
156 -----------+-------------------------------+-------------------------------
157 | macromap[0]->start_location | Start of macro map 0
158 0x7fffffff | MAX_SOURCE_LOCATION | Also used as a mask for
159 | | accessing the ad-hoc data table
160 -----------+-------------------------------+-------------------------------
161 0x80000000 | Start of ad-hoc values; the lower 31 bits are used as an index
162 ... | into the line_table->location_adhoc_data_map.data array.
163 0xffffffff | UINT_MAX |
164 -----------+-------------------------------+-------------------------------
166 Examples of location encoding.
168 Packed ranges
169 =============
171 Consider encoding the location of a token "foo", seen underlined here
172 on line 523, within an ordinary line_map that starts at line 500:
174 11111111112
175 12345678901234567890
177 523 return foo + bar;
181 The location's caret and start are both at line 523, column 11; the
182 location's finish is on the same line, at column 13 (an offset of 2
183 columns, for length 3).
185 Line 523 is offset 23 from the starting line of the ordinary line_map.
187 caret == start, and the offset of the finish fits within 5 bits, so
188 this can be stored as a packed range.
190 This is encoded as:
191 ordmap->start
192 + (line_offset << ordmap->m_column_and_range_bits)
193 + (column << ordmap->m_range_bits)
194 + (range_offset);
195 i.e. (for line offset 23, column 11, range offset 2):
196 ordmap->start
197 + (23 << 12)
198 + (11 << 5)
199 + 2;
200 i.e.:
201 ordmap->start + 0x17162
202 assuming that the line_map uses the default of 7 bits for columns and
203 5 bits for packed range (giving 12 bits for m_column_and_range_bits).
206 "Pure" locations
207 ================
209 These are a special case of the above, where
210 caret == start == finish
211 They are stored as packed ranges with offset == 0.
212 For example, the location of the "f" of "foo" could be stored
213 as above, but with range offset 0, giving:
214 ordmap->start
215 + (23 << 12)
216 + (11 << 5)
217 + 0;
218 i.e.:
219 ordmap->start + 0x17160
222 Unoptimized ranges
223 ==================
225 Consider encoding the location of the binary expression
226 below:
228 11111111112
229 12345678901234567890
231 523 return foo + bar;
232 ~~~~^~~~~
235 The location's caret is at the "+", line 523 column 15, but starts
236 earlier, at the "f" of "foo" at column 11. The finish is at the "r"
237 of "bar" at column 19.
239 This can't be stored as a packed range since start != caret.
240 Hence it is stored as an ad-hoc location e.g. 0x80000003.
242 Stripping off the top bit gives us an index into the ad-hoc
243 lookaside table:
245 line_table->location_adhoc_data_map.data[0x3]
247 from which the caret, start and finish can be looked up,
248 encoded as "pure" locations:
250 start == ordmap->start + (23 << 12) + (11 << 5)
251 == ordmap->start + 0x17160 (as above; the "f" of "foo")
253 caret == ordmap->start + (23 << 12) + (15 << 5)
254 == ordmap->start + 0x171e0
256 finish == ordmap->start + (23 << 12) + (19 << 5)
257 == ordmap->start + 0x17260
259 To further see how source_location works in practice, see the
260 worked example in libcpp/location-example.txt. */
261 typedef unsigned int source_location;
263 /* Do not pack ranges if locations get higher than this.
264 If you change this, update:
265 gcc.dg/plugin/location-overflow-test-*.c. */
266 const source_location LINE_MAP_MAX_LOCATION_WITH_PACKED_RANGES = 0x50000000;
268 /* Do not track column numbers if locations get higher than this.
269 If you change this, update:
270 gcc.dg/plugin/location-overflow-test-*.c. */
271 const source_location LINE_MAP_MAX_LOCATION_WITH_COLS = 0x60000000;
273 /* A range of source locations.
275 Ranges are closed:
276 m_start is the first location within the range,
277 m_finish is the last location within the range.
279 We may need a more compact way to store these, but for now,
280 let's do it the simple way, as a pair. */
281 struct GTY(()) source_range
283 source_location m_start;
284 source_location m_finish;
286 /* We avoid using constructors, since various structs that
287 don't yet have constructors will embed instances of
288 source_range. */
290 /* Make a source_range from a source_location. */
291 static source_range from_location (source_location loc)
293 source_range result;
294 result.m_start = loc;
295 result.m_finish = loc;
296 return result;
299 /* Make a source_range from a pair of source_location. */
300 static source_range from_locations (source_location start,
301 source_location finish)
303 source_range result;
304 result.m_start = start;
305 result.m_finish = finish;
306 return result;
309 /* Is there any part of this range on the given line? */
310 bool intersects_line_p (const char *file, int line) const;
313 /* Memory allocation function typedef. Works like xrealloc. */
314 typedef void *(*line_map_realloc) (void *, size_t);
316 /* Memory allocator function that returns the actual allocated size,
317 for a given requested allocation. */
318 typedef size_t (*line_map_round_alloc_size_func) (size_t);
320 /* A line_map encodes a sequence of locations.
321 There are two kinds of maps. Ordinary maps and macro expansion
322 maps, a.k.a macro maps.
324 A macro map encodes source locations of tokens that are part of a
325 macro replacement-list, at a macro expansion point. E.g, in:
327 #define PLUS(A,B) A + B
329 No macro map is going to be created there, because we are not at a
330 macro expansion point. We are at a macro /definition/ point. So the
331 locations of the tokens of the macro replacement-list (i.e, A + B)
332 will be locations in an ordinary map, not a macro map.
334 On the other hand, if we later do:
336 int a = PLUS (1,2);
338 The invocation of PLUS here is a macro expansion. So we are at a
339 macro expansion point. The preprocessor expands PLUS (1,2) and
340 replaces it with the tokens of its replacement-list: 1 + 2. A macro
341 map is going to be created to hold (or rather to map, haha ...) the
342 locations of the tokens 1, + and 2. The macro map also records the
343 location of the expansion point of PLUS. That location is mapped in
344 the map that is active right before the location of the invocation
345 of PLUS. */
346 struct GTY((tag ("0"), desc ("%h.reason == LC_ENTER_MACRO ? 2 : 1"))) line_map {
347 source_location start_location;
349 /* The reason for creation of this line map. */
350 ENUM_BITFIELD (lc_reason) reason : CHAR_BIT;
353 /* An ordinary line map encodes physical source locations. Those
354 physical source locations are called "spelling locations".
356 Physical source file TO_FILE at line TO_LINE at column 0 is represented
357 by the logical START_LOCATION. TO_LINE+L at column C is represented by
358 START_LOCATION+(L*(1<<m_column_and_range_bits))+(C*1<<m_range_bits), as
359 long as C<(1<<effective range bits), and the result_location is less than
360 the next line_map's start_location.
361 (The top line is line 1 and the leftmost column is column 1; line/column 0
362 means "entire file/line" or "unknown line/column" or "not applicable".)
364 The highest possible source location is MAX_SOURCE_LOCATION. */
365 struct GTY((tag ("1"))) line_map_ordinary : public line_map {
366 const char *to_file;
367 linenum_type to_line;
369 /* An index into the set that gives the line mapping at whose end
370 the current one was included. File(s) at the bottom of the
371 include stack have this set to -1. */
372 int included_from;
374 /* SYSP is one for a system header, two for a C system header file
375 that therefore needs to be extern "C" protected in C++, and zero
376 otherwise. This field isn't really needed now that it's in
377 cpp_buffer. */
378 unsigned char sysp;
380 /* Number of the low-order source_location bits used for column numbers
381 and ranges. */
382 unsigned int m_column_and_range_bits : 8;
384 /* Number of the low-order "column" bits used for storing short ranges
385 inline, rather than in the ad-hoc table.
386 MSB LSB
387 31 0
388 +-------------------------+-------------------------------------------+
389 | |<---map->column_and_range_bits (e.g. 12)-->|
390 +-------------------------+-----------------------+-------------------+
391 | | column_and_range_bits | map->range_bits |
392 | | - range_bits | |
393 +-------------------------+-----------------------+-------------------+
394 | row bits | effective column bits | short range bits |
395 | | (e.g. 7) | (e.g. 5) |
396 +-------------------------+-----------------------+-------------------+ */
397 unsigned int m_range_bits : 8;
400 /* This is the highest possible source location encoded within an
401 ordinary or macro map. */
402 const source_location MAX_SOURCE_LOCATION = 0x7FFFFFFF;
404 struct cpp_hashnode;
406 /* A macro line map encodes location of tokens coming from a macro
407 expansion.
409 The offset from START_LOCATION is used to index into
410 MACRO_LOCATIONS; this holds the original location of the token. */
411 struct GTY((tag ("2"))) line_map_macro : public line_map {
412 /* The cpp macro which expansion gave birth to this macro map. */
413 struct cpp_hashnode * GTY ((nested_ptr (union tree_node,
414 "%h ? CPP_HASHNODE (GCC_IDENT_TO_HT_IDENT (%h)) : NULL",
415 "%h ? HT_IDENT_TO_GCC_IDENT (HT_NODE (%h)) : NULL")))
416 macro;
418 /* The number of tokens inside the replacement-list of MACRO. */
419 unsigned int n_tokens;
421 /* This array of location is actually an array of pairs of
422 locations. The elements inside it thus look like:
424 x0,y0, x1,y1, x2,y2, ...., xn,yn.
426 where n == n_tokens;
428 Remember that these xI,yI are collected when libcpp is about to
429 expand a given macro.
431 yI is the location in the macro definition, either of the token
432 itself or of a macro parameter that it replaces.
434 Imagine this:
436 #define PLUS(A, B) A + B <--- #1
438 int a = PLUS (1,2); <--- #2
440 There is a macro map for the expansion of PLUS in #2. PLUS is
441 expanded into its expansion-list. The expansion-list is the
442 replacement-list of PLUS where the macro parameters are replaced
443 with their arguments. So the replacement-list of PLUS is made of
444 the tokens:
446 A, +, B
448 and the expansion-list is made of the tokens:
450 1, +, 2
452 Let's consider the case of token "+". Its y1 [yI for I == 1] is
453 its spelling location in #1.
455 y0 (thus for token "1") is the spelling location of A in #1.
457 And y2 (of token "2") is the spelling location of B in #1.
459 When the token is /not/ an argument for a macro, xI is the same
460 location as yI. Otherwise, xI is the location of the token
461 outside this macro expansion. If this macro was expanded from
462 another macro expansion, xI is a virtual location representing
463 the token in that macro expansion; otherwise, it is the spelling
464 location of the token.
466 Note that a virtual location is a location returned by
467 linemap_add_macro_token. It encodes the relevant locations (x,y
468 pairs) of that token across the macro expansions from which it
469 (the token) might come from.
471 In the example above x1 (for token "+") is going to be the same
472 as y1. x0 is the spelling location for the argument token "1",
473 and x2 is the spelling location for the argument token "2". */
474 source_location * GTY((atomic)) macro_locations;
476 /* This is the location of the expansion point of the current macro
477 map. It's the location of the macro name. That location is held
478 by the map that was current right before the current one. It
479 could have been either a macro or an ordinary map, depending on
480 if we are in a nested expansion context not. */
481 source_location expansion;
484 #if CHECKING_P && (GCC_VERSION >= 2007)
486 /* Assertion macro to be used in line-map code. */
487 #define linemap_assert(EXPR) \
488 do { \
489 if (! (EXPR)) \
490 abort (); \
491 } while (0)
493 /* Assert that becomes a conditional expression when checking is disabled at
494 compilation time. Use this for conditions that should not happen but if
495 they happen, it is better to handle them gracefully rather than crash
496 randomly later.
497 Usage:
499 if (linemap_assert_fails(EXPR)) handle_error(); */
500 #define linemap_assert_fails(EXPR) __extension__ \
501 ({linemap_assert (EXPR); false;})
503 #else
504 /* Include EXPR, so that unused variable warnings do not occur. */
505 #define linemap_assert(EXPR) ((void)(0 && (EXPR)))
506 #define linemap_assert_fails(EXPR) (! (EXPR))
507 #endif
509 /* Return TRUE if MAP encodes locations coming from a macro
510 replacement-list at macro expansion point. */
511 bool
512 linemap_macro_expansion_map_p (const struct line_map *);
514 /* Assert that MAP encodes locations of tokens that are not part of
515 the replacement-list of a macro expansion, downcasting from
516 line_map * to line_map_ordinary *. */
518 inline line_map_ordinary *
519 linemap_check_ordinary (struct line_map *map)
521 linemap_assert (!linemap_macro_expansion_map_p (map));
522 return (line_map_ordinary *)map;
525 /* Assert that MAP encodes locations of tokens that are not part of
526 the replacement-list of a macro expansion, downcasting from
527 const line_map * to const line_map_ordinary *. */
529 inline const line_map_ordinary *
530 linemap_check_ordinary (const struct line_map *map)
532 linemap_assert (!linemap_macro_expansion_map_p (map));
533 return (const line_map_ordinary *)map;
536 /* Assert that MAP is a macro expansion and downcast to the appropriate
537 subclass. */
539 inline line_map_macro *linemap_check_macro (line_map *map)
541 linemap_assert (linemap_macro_expansion_map_p (map));
542 return (line_map_macro *)map;
545 /* Assert that MAP is a macro expansion and downcast to the appropriate
546 subclass. */
548 inline const line_map_macro *
549 linemap_check_macro (const line_map *map)
551 linemap_assert (linemap_macro_expansion_map_p (map));
552 return (const line_map_macro *)map;
555 /* Read the start location of MAP. */
557 inline source_location
558 MAP_START_LOCATION (const line_map *map)
560 return map->start_location;
563 /* Get the starting line number of ordinary map MAP. */
565 inline linenum_type
566 ORDINARY_MAP_STARTING_LINE_NUMBER (const line_map_ordinary *ord_map)
568 return ord_map->to_line;
571 /* Get the index of the ordinary map at whose end
572 ordinary map MAP was included.
574 File(s) at the bottom of the include stack have this set. */
576 inline int
577 ORDINARY_MAP_INCLUDER_FILE_INDEX (const line_map_ordinary *ord_map)
579 return ord_map->included_from;
582 /* Return a positive value if map encodes locations from a system
583 header, 0 otherwise. Returns 1 if ordinary map MAP encodes locations
584 in a system header and 2 if it encodes locations in a C system header
585 that therefore needs to be extern "C" protected in C++. */
587 inline unsigned char
588 ORDINARY_MAP_IN_SYSTEM_HEADER_P (const line_map_ordinary *ord_map)
590 return ord_map->sysp;
593 /* Get the filename of ordinary map MAP. */
595 inline const char *
596 ORDINARY_MAP_FILE_NAME (const line_map_ordinary *ord_map)
598 return ord_map->to_file;
601 /* Get the cpp macro whose expansion gave birth to macro map MAP. */
603 inline cpp_hashnode *
604 MACRO_MAP_MACRO (const line_map_macro *macro_map)
606 return macro_map->macro;
609 /* Get the number of tokens inside the replacement-list of the macro
610 that led to macro map MAP. */
612 inline unsigned int
613 MACRO_MAP_NUM_MACRO_TOKENS (const line_map_macro *macro_map)
615 return macro_map->n_tokens;
618 /* Get the array of pairs of locations within macro map MAP.
619 See the declaration of line_map_macro for more information. */
621 inline source_location *
622 MACRO_MAP_LOCATIONS (const line_map_macro *macro_map)
624 return macro_map->macro_locations;
627 /* Get the location of the expansion point of the macro map MAP. */
629 inline source_location
630 MACRO_MAP_EXPANSION_POINT_LOCATION (const line_map_macro *macro_map)
632 return macro_map->expansion;
635 /* The abstraction of a set of location maps. There can be several
636 types of location maps. This abstraction contains the attributes
637 that are independent from the type of the map.
639 Essentially this is just a vector of T_linemap_subclass,
640 which can only ever grow in size. */
642 struct GTY(()) maps_info_ordinary {
643 /* This array contains the "ordinary" line maps, for all
644 events other than macro expansion
645 (e.g. when a new preprocessing unit starts or ends). */
646 line_map_ordinary * GTY ((length ("%h.used"))) maps;
648 /* The total number of allocated maps. */
649 unsigned int allocated;
651 /* The number of elements used in maps. This number is smaller
652 or equal to ALLOCATED. */
653 unsigned int used;
655 unsigned int cache;
658 struct GTY(()) maps_info_macro {
659 /* This array contains the macro line maps.
660 A macro line map is created whenever a macro expansion occurs. */
661 line_map_macro * GTY ((length ("%h.used"))) maps;
663 /* The total number of allocated maps. */
664 unsigned int allocated;
666 /* The number of elements used in maps. This number is smaller
667 or equal to ALLOCATED. */
668 unsigned int used;
670 unsigned int cache;
673 /* Data structure to associate a source_range together with an arbitrary
674 data pointer with a source location. */
675 struct GTY(()) location_adhoc_data {
676 source_location locus;
677 source_range src_range;
678 void * GTY((skip)) data;
681 struct htab;
683 /* The following data structure encodes a location with some adhoc data
684 and maps it to a new unsigned integer (called an adhoc location)
685 that replaces the original location to represent the mapping.
687 The new adhoc_loc uses the highest bit as the enabling bit, i.e. if the
688 highest bit is 1, then the number is adhoc_loc. Otherwise, it serves as
689 the original location. Once identified as the adhoc_loc, the lower 31
690 bits of the integer is used to index the location_adhoc_data array,
691 in which the locus and associated data is stored. */
693 struct GTY(()) location_adhoc_data_map {
694 struct htab * GTY((skip)) htab;
695 source_location curr_loc;
696 unsigned int allocated;
697 struct location_adhoc_data GTY((length ("%h.allocated"))) *data;
700 /* A set of chronological line_map structures. */
701 struct GTY(()) line_maps {
703 ~line_maps ();
705 maps_info_ordinary info_ordinary;
707 maps_info_macro info_macro;
709 /* Depth of the include stack, including the current file. */
710 unsigned int depth;
712 /* If true, prints an include trace a la -H. */
713 bool trace_includes;
715 /* Highest source_location "given out". */
716 source_location highest_location;
718 /* Start of line of highest source_location "given out". */
719 source_location highest_line;
721 /* The maximum column number we can quickly allocate. Higher numbers
722 may require allocating a new line_map. */
723 unsigned int max_column_hint;
725 /* If non-null, the allocator to use when resizing 'maps'. If null,
726 xrealloc is used. */
727 line_map_realloc reallocator;
729 /* The allocators' function used to know the actual size it
730 allocated, for a certain allocation size requested. */
731 line_map_round_alloc_size_func round_alloc_size;
733 struct location_adhoc_data_map location_adhoc_data_map;
735 /* The special location value that is used as spelling location for
736 built-in tokens. */
737 source_location builtin_location;
739 /* True if we've seen a #line or # 44 "file" directive. */
740 bool seen_line_directive;
742 /* The default value of range_bits in ordinary line maps. */
743 unsigned int default_range_bits;
745 unsigned int num_optimized_ranges;
746 unsigned int num_unoptimized_ranges;
749 /* Returns the number of allocated maps so far. MAP_KIND shall be TRUE
750 if we are interested in macro maps, FALSE otherwise. */
751 inline unsigned int
752 LINEMAPS_ALLOCATED (const line_maps *set, bool map_kind)
754 if (map_kind)
755 return set->info_macro.allocated;
756 else
757 return set->info_ordinary.allocated;
760 /* As above, but by reference (e.g. as an lvalue). */
762 inline unsigned int &
763 LINEMAPS_ALLOCATED (line_maps *set, bool map_kind)
765 if (map_kind)
766 return set->info_macro.allocated;
767 else
768 return set->info_ordinary.allocated;
771 /* Returns the number of used maps so far. MAP_KIND shall be TRUE if
772 we are interested in macro maps, FALSE otherwise.*/
773 inline unsigned int
774 LINEMAPS_USED (const line_maps *set, bool map_kind)
776 if (map_kind)
777 return set->info_macro.used;
778 else
779 return set->info_ordinary.used;
782 /* As above, but by reference (e.g. as an lvalue). */
784 inline unsigned int &
785 LINEMAPS_USED (line_maps *set, bool map_kind)
787 if (map_kind)
788 return set->info_macro.used;
789 else
790 return set->info_ordinary.used;
793 /* Returns the index of the last map that was looked up with
794 linemap_lookup. MAP_KIND shall be TRUE if we are interested in
795 macro maps, FALSE otherwise. */
796 inline unsigned int
797 LINEMAPS_CACHE (const line_maps *set, bool map_kind)
799 if (map_kind)
800 return set->info_macro.cache;
801 else
802 return set->info_ordinary.cache;
805 /* As above, but by reference (e.g. as an lvalue). */
807 inline unsigned int &
808 LINEMAPS_CACHE (line_maps *set, bool map_kind)
810 if (map_kind)
811 return set->info_macro.cache;
812 else
813 return set->info_ordinary.cache;
816 /* Return the map at a given index. */
817 inline line_map *
818 LINEMAPS_MAP_AT (const line_maps *set, bool map_kind, int index)
820 if (map_kind)
821 return &set->info_macro.maps[index];
822 else
823 return &set->info_ordinary.maps[index];
826 /* Returns the last map used in the line table SET. MAP_KIND
827 shall be TRUE if we are interested in macro maps, FALSE
828 otherwise.*/
829 inline line_map *
830 LINEMAPS_LAST_MAP (const line_maps *set, bool map_kind)
832 return LINEMAPS_MAP_AT (set, map_kind,
833 LINEMAPS_USED (set, map_kind) - 1);
836 /* Returns the last map that was allocated in the line table SET.
837 MAP_KIND shall be TRUE if we are interested in macro maps, FALSE
838 otherwise.*/
839 inline line_map *
840 LINEMAPS_LAST_ALLOCATED_MAP (const line_maps *set, bool map_kind)
842 return LINEMAPS_MAP_AT (set, map_kind,
843 LINEMAPS_ALLOCATED (set, map_kind) - 1);
846 /* Returns a pointer to the memory region where ordinary maps are
847 allocated in the line table SET. */
848 inline line_map_ordinary *
849 LINEMAPS_ORDINARY_MAPS (const line_maps *set)
851 return set->info_ordinary.maps;
854 /* Returns the INDEXth ordinary map. */
855 inline line_map_ordinary *
856 LINEMAPS_ORDINARY_MAP_AT (const line_maps *set, int index)
858 linemap_assert (index >= 0);
859 linemap_assert ((unsigned int)index < set->info_ordinary.used);
860 return &set->info_ordinary.maps[index];
863 /* Return the number of ordinary maps allocated in the line table
864 SET. */
865 inline unsigned int
866 LINEMAPS_ORDINARY_ALLOCATED (const line_maps *set)
868 return LINEMAPS_ALLOCATED (set, false);
871 /* Return the number of ordinary maps used in the line table SET. */
872 inline unsigned int
873 LINEMAPS_ORDINARY_USED (const line_maps *set)
875 return LINEMAPS_USED (set, false);
878 /* Return the index of the last ordinary map that was looked up with
879 linemap_lookup. */
880 inline unsigned int
881 LINEMAPS_ORDINARY_CACHE (const line_maps *set)
883 return LINEMAPS_CACHE (set, false);
886 /* As above, but by reference (e.g. as an lvalue). */
888 inline unsigned int &
889 LINEMAPS_ORDINARY_CACHE (line_maps *set)
891 return LINEMAPS_CACHE (set, false);
894 /* Returns a pointer to the last ordinary map used in the line table
895 SET. */
896 inline line_map_ordinary *
897 LINEMAPS_LAST_ORDINARY_MAP (const line_maps *set)
899 return (line_map_ordinary *)LINEMAPS_LAST_MAP (set, false);
902 /* Returns a pointer to the last ordinary map allocated the line table
903 SET. */
904 inline line_map_ordinary *
905 LINEMAPS_LAST_ALLOCATED_ORDINARY_MAP (const line_maps *set)
907 return (line_map_ordinary *)LINEMAPS_LAST_ALLOCATED_MAP (set, false);
910 /* Returns a pointer to the beginning of the region where macro maps
911 are allcoated. */
912 inline line_map_macro *
913 LINEMAPS_MACRO_MAPS (const line_maps *set)
915 return set->info_macro.maps;
918 /* Returns the INDEXth macro map. */
919 inline line_map_macro *
920 LINEMAPS_MACRO_MAP_AT (const line_maps *set, int index)
922 linemap_assert (index >= 0);
923 linemap_assert ((unsigned int)index < set->info_macro.used);
924 return &set->info_macro.maps[index];
927 /* Returns the number of macro maps that were allocated in the line
928 table SET. */
929 inline unsigned int
930 LINEMAPS_MACRO_ALLOCATED (const line_maps *set)
932 return LINEMAPS_ALLOCATED (set, true);
935 /* Returns the number of macro maps used in the line table SET. */
936 inline unsigned int
937 LINEMAPS_MACRO_USED (const line_maps *set)
939 return LINEMAPS_USED (set, true);
942 /* Returns the index of the last macro map looked up with
943 linemap_lookup. */
944 inline unsigned int
945 LINEMAPS_MACRO_CACHE (const line_maps *set)
947 return LINEMAPS_CACHE (set, true);
950 /* As above, but by reference (e.g. as an lvalue). */
952 inline unsigned int &
953 LINEMAPS_MACRO_CACHE (line_maps *set)
955 return LINEMAPS_CACHE (set, true);
958 /* Returns the last macro map used in the line table SET. */
959 inline line_map_macro *
960 LINEMAPS_LAST_MACRO_MAP (const line_maps *set)
962 return (line_map_macro *)LINEMAPS_LAST_MAP (set, true);
965 /* Returns the lowest location [of a token resulting from macro
966 expansion] encoded in this line table. */
967 inline source_location
968 LINEMAPS_MACRO_LOWEST_LOCATION (const line_maps *set)
970 return LINEMAPS_MACRO_USED (set)
971 ? MAP_START_LOCATION (LINEMAPS_LAST_MACRO_MAP (set))
972 : MAX_SOURCE_LOCATION;
975 /* Returns the last macro map allocated in the line table SET. */
976 inline line_map_macro *
977 LINEMAPS_LAST_ALLOCATED_MACRO_MAP (const line_maps *set)
979 return (line_map_macro *)LINEMAPS_LAST_ALLOCATED_MAP (set, true);
982 extern source_location get_combined_adhoc_loc (struct line_maps *,
983 source_location,
984 source_range,
985 void *);
986 extern void *get_data_from_adhoc_loc (struct line_maps *, source_location);
987 extern source_location get_location_from_adhoc_loc (struct line_maps *,
988 source_location);
990 extern source_range get_range_from_loc (line_maps *set, source_location loc);
992 /* Get whether location LOC is an ad-hoc location. */
994 inline bool
995 IS_ADHOC_LOC (source_location loc)
997 return (loc & MAX_SOURCE_LOCATION) != loc;
1000 /* Get whether location LOC is a "pure" location, or
1001 whether it is an ad-hoc location, or embeds range information. */
1003 bool
1004 pure_location_p (line_maps *set, source_location loc);
1006 /* Given location LOC within SET, strip away any packed range information
1007 or ad-hoc information. */
1009 extern source_location get_pure_location (line_maps *set,
1010 source_location loc);
1012 /* Combine LOC and BLOCK, giving a combined adhoc location. */
1014 inline source_location
1015 COMBINE_LOCATION_DATA (struct line_maps *set,
1016 source_location loc,
1017 source_range src_range,
1018 void *block)
1020 return get_combined_adhoc_loc (set, loc, src_range, block);
1023 extern void rebuild_location_adhoc_htab (struct line_maps *);
1025 /* Initialize a line map set. SET is the line map set to initialize
1026 and BUILTIN_LOCATION is the special location value to be used as
1027 spelling location for built-in tokens. This BUILTIN_LOCATION has
1028 to be strictly less than RESERVED_LOCATION_COUNT. */
1029 extern void linemap_init (struct line_maps *set,
1030 source_location builtin_location);
1032 /* Check for and warn about line_maps entered but not exited. */
1034 extern void linemap_check_files_exited (struct line_maps *);
1036 /* Return a source_location for the start (i.e. column==0) of
1037 (physical) line TO_LINE in the current source file (as in the
1038 most recent linemap_add). MAX_COLUMN_HINT is the highest column
1039 number we expect to use in this line (but it does not change
1040 the highest_location). */
1042 extern source_location linemap_line_start
1043 (struct line_maps *set, linenum_type to_line, unsigned int max_column_hint);
1045 /* Add a mapping of logical source line to physical source file and
1046 line number. This function creates an "ordinary map", which is a
1047 map that records locations of tokens that are not part of macro
1048 replacement-lists present at a macro expansion point.
1050 The text pointed to by TO_FILE must have a lifetime
1051 at least as long as the lifetime of SET. An empty
1052 TO_FILE means standard input. If reason is LC_LEAVE, and
1053 TO_FILE is NULL, then TO_FILE, TO_LINE and SYSP are given their
1054 natural values considering the file we are returning to.
1056 A call to this function can relocate the previous set of
1057 maps, so any stored line_map pointers should not be used. */
1058 extern const struct line_map *linemap_add
1059 (struct line_maps *, enum lc_reason, unsigned int sysp,
1060 const char *to_file, linenum_type to_line);
1062 /* Given a logical source location, returns the map which the
1063 corresponding (source file, line, column) triplet can be deduced
1064 from. Since the set is built chronologically, the logical lines are
1065 monotonic increasing, and so the list is sorted and we can use a
1066 binary search. If no line map have been allocated yet, this
1067 function returns NULL. */
1068 extern const struct line_map *linemap_lookup
1069 (struct line_maps *, source_location);
1071 /* Returns TRUE if the line table set tracks token locations across
1072 macro expansion, FALSE otherwise. */
1073 bool linemap_tracks_macro_expansion_locs_p (struct line_maps *);
1075 /* Return the name of the macro associated to MACRO_MAP. */
1076 const char* linemap_map_get_macro_name (const line_map_macro *);
1078 /* Return a positive value if LOCATION is the locus of a token that is
1079 located in a system header, O otherwise. It returns 1 if LOCATION
1080 is the locus of a token that is located in a system header, and 2
1081 if LOCATION is the locus of a token located in a C system header
1082 that therefore needs to be extern "C" protected in C++.
1084 Note that this function returns 1 if LOCATION belongs to a token
1085 that is part of a macro replacement-list defined in a system
1086 header, but expanded in a non-system file. */
1087 int linemap_location_in_system_header_p (struct line_maps *,
1088 source_location);
1090 /* Return TRUE if LOCATION is a source code location of a token that is part of
1091 a macro expansion, FALSE otherwise. */
1092 bool linemap_location_from_macro_expansion_p (const struct line_maps *,
1093 source_location);
1095 /* TRUE if LOCATION is a source code location of a token that is part of the
1096 definition of a macro, FALSE otherwise. */
1097 bool linemap_location_from_macro_definition_p (struct line_maps *,
1098 source_location);
1100 /* With the precondition that LOCATION is the locus of a token that is
1101 an argument of a function-like macro MACRO_MAP and appears in the
1102 expansion of MACRO_MAP, return the locus of that argument in the
1103 context of the caller of MACRO_MAP. */
1105 extern source_location linemap_macro_map_loc_unwind_toward_spelling
1106 (line_maps *set, const line_map_macro *macro_map, source_location location);
1108 /* source_location values from 0 to RESERVED_LOCATION_COUNT-1 will
1109 be reserved for libcpp user as special values, no token from libcpp
1110 will contain any of those locations. */
1111 const source_location RESERVED_LOCATION_COUNT = 2;
1113 /* Converts a map and a source_location to source line. */
1114 inline linenum_type
1115 SOURCE_LINE (const line_map_ordinary *ord_map, source_location loc)
1117 return ((loc - ord_map->start_location)
1118 >> ord_map->m_column_and_range_bits) + ord_map->to_line;
1121 /* Convert a map and source_location to source column number. */
1122 inline linenum_type
1123 SOURCE_COLUMN (const line_map_ordinary *ord_map, source_location loc)
1125 return ((loc - ord_map->start_location)
1126 & ((1 << ord_map->m_column_and_range_bits) - 1)) >> ord_map->m_range_bits;
1129 /* Return the location of the last source line within an ordinary
1130 map. */
1131 inline source_location
1132 LAST_SOURCE_LINE_LOCATION (const line_map_ordinary *map)
1134 return (((map[1].start_location - 1
1135 - map->start_location)
1136 & ~((1 << map->m_column_and_range_bits) - 1))
1137 + map->start_location);
1140 /* Returns the last source line number within an ordinary map. This
1141 is the (last) line of the #include, or other directive, that caused
1142 a map change. */
1143 inline linenum_type
1144 LAST_SOURCE_LINE (const line_map_ordinary *map)
1146 return SOURCE_LINE (map, LAST_SOURCE_LINE_LOCATION (map));
1149 /* Return the last column number within an ordinary map. */
1151 inline linenum_type
1152 LAST_SOURCE_COLUMN (const line_map_ordinary *map)
1154 return SOURCE_COLUMN (map, LAST_SOURCE_LINE_LOCATION (map));
1157 /* Returns the map a given map was included from, or NULL if the map
1158 belongs to the main file, i.e, a file that wasn't included by
1159 another one. */
1160 inline line_map_ordinary *
1161 INCLUDED_FROM (struct line_maps *set, const line_map_ordinary *ord_map)
1163 return ((ord_map->included_from == -1)
1164 ? NULL
1165 : LINEMAPS_ORDINARY_MAP_AT (set, ord_map->included_from));
1168 /* True if the map is at the bottom of the include stack. */
1170 inline bool
1171 MAIN_FILE_P (const line_map_ordinary *ord_map)
1173 return ord_map->included_from < 0;
1176 /* Encode and return a source_location from a column number. The
1177 source line considered is the last source line used to call
1178 linemap_line_start, i.e, the last source line which a location was
1179 encoded from. */
1180 extern source_location
1181 linemap_position_for_column (struct line_maps *, unsigned int);
1183 /* Encode and return a source location from a given line and
1184 column. */
1185 source_location
1186 linemap_position_for_line_and_column (line_maps *set,
1187 const line_map_ordinary *,
1188 linenum_type, unsigned int);
1190 /* Encode and return a source_location starting from location LOC and
1191 shifting it by OFFSET columns. This function does not support
1192 virtual locations. */
1193 source_location
1194 linemap_position_for_loc_and_offset (struct line_maps *set,
1195 source_location loc,
1196 unsigned int offset);
1198 /* Return the file this map is for. */
1199 inline const char *
1200 LINEMAP_FILE (const line_map_ordinary *ord_map)
1202 return ord_map->to_file;
1205 /* Return the line number this map started encoding location from. */
1206 inline linenum_type
1207 LINEMAP_LINE (const line_map_ordinary *ord_map)
1209 return ord_map->to_line;
1212 /* Return a positive value if map encodes locations from a system
1213 header, 0 otherwise. Returns 1 if MAP encodes locations in a
1214 system header and 2 if it encodes locations in a C system header
1215 that therefore needs to be extern "C" protected in C++. */
1216 inline unsigned char
1217 LINEMAP_SYSP (const line_map_ordinary *ord_map)
1219 return ord_map->sysp;
1222 /* Return a positive value if PRE denotes the location of a token that
1223 comes before the token of POST, 0 if PRE denotes the location of
1224 the same token as the token for POST, and a negative value
1225 otherwise. */
1226 int linemap_compare_locations (struct line_maps *set,
1227 source_location pre,
1228 source_location post);
1230 /* Return TRUE if LOC_A denotes the location a token that comes
1231 topogically before the token denoted by location LOC_B, or if they
1232 are equal. */
1233 inline bool
1234 linemap_location_before_p (struct line_maps *set,
1235 source_location loc_a,
1236 source_location loc_b)
1238 return linemap_compare_locations (set, loc_a, loc_b) >= 0;
1241 typedef struct
1243 /* The name of the source file involved. */
1244 const char *file;
1246 /* The line-location in the source file. */
1247 int line;
1249 int column;
1251 void *data;
1253 /* In a system header?. */
1254 bool sysp;
1255 } expanded_location;
1257 /* Both gcc and emacs number source *lines* starting at 1, but
1258 they have differing conventions for *columns*.
1260 GCC uses a 1-based convention for source columns,
1261 whereas Emacs's M-x column-number-mode uses a 0-based convention.
1263 For example, an error in the initial, left-hand
1264 column of source line 3 is reported by GCC as:
1266 some-file.c:3:1: error: ...etc...
1268 On navigating to the location of that error in Emacs
1269 (e.g. via "next-error"),
1270 the locus is reported in the Mode Line
1271 (assuming M-x column-number-mode) as:
1273 some-file.c 10% (3, 0)
1275 i.e. "3:1:" in GCC corresponds to "(3, 0)" in Emacs. */
1277 /* A location within a rich_location: a caret&range, with
1278 the caret potentially flagged for display. */
1280 struct location_range
1282 source_location m_loc;
1284 /* Should a caret be drawn for this range? Typically this is
1285 true for the 0th range, and false for subsequent ranges,
1286 but the Fortran frontend overrides this for rendering things like:
1288 x = x + y
1290 Error: Shapes for operands at (1) and (2) are not conformable
1292 where "1" and "2" are notionally carets. */
1293 bool m_show_caret_p;
1296 /* A partially-embedded vec for use within rich_location for storing
1297 ranges and fix-it hints.
1299 Elements [0..NUM_EMBEDDED) are allocated within m_embed, after
1300 that they are within the dynamically-allocated m_extra.
1302 This allows for static allocation in the common case, whilst
1303 supporting the rarer case of an arbitrary number of elements.
1305 Dynamic allocation is not performed unless it's needed. */
1307 template <typename T, int NUM_EMBEDDED>
1308 class semi_embedded_vec
1310 public:
1311 semi_embedded_vec ();
1312 ~semi_embedded_vec ();
1314 unsigned int count () const { return m_num; }
1315 T& operator[] (int idx);
1316 const T& operator[] (int idx) const;
1318 void push (const T&);
1319 void truncate (int len);
1321 private:
1322 int m_num;
1323 T m_embedded[NUM_EMBEDDED];
1324 int m_alloc;
1325 T *m_extra;
1328 /* Constructor for semi_embedded_vec. In particular, no dynamic allocation
1329 is done. */
1331 template <typename T, int NUM_EMBEDDED>
1332 semi_embedded_vec<T, NUM_EMBEDDED>::semi_embedded_vec ()
1333 : m_num (0), m_alloc (0), m_extra (NULL)
1337 /* semi_embedded_vec's dtor. Release any dynamically-allocated memory. */
1339 template <typename T, int NUM_EMBEDDED>
1340 semi_embedded_vec<T, NUM_EMBEDDED>::~semi_embedded_vec ()
1342 XDELETEVEC (m_extra);
1345 /* Look up element IDX, mutably. */
1347 template <typename T, int NUM_EMBEDDED>
1349 semi_embedded_vec<T, NUM_EMBEDDED>::operator[] (int idx)
1351 linemap_assert (idx < m_num);
1352 if (idx < NUM_EMBEDDED)
1353 return m_embedded[idx];
1354 else
1356 linemap_assert (m_extra != NULL);
1357 return m_extra[idx - NUM_EMBEDDED];
1361 /* Look up element IDX (const). */
1363 template <typename T, int NUM_EMBEDDED>
1364 const T&
1365 semi_embedded_vec<T, NUM_EMBEDDED>::operator[] (int idx) const
1367 linemap_assert (idx < m_num);
1368 if (idx < NUM_EMBEDDED)
1369 return m_embedded[idx];
1370 else
1372 linemap_assert (m_extra != NULL);
1373 return m_extra[idx - NUM_EMBEDDED];
1377 /* Append VALUE to the end of the semi_embedded_vec. */
1379 template <typename T, int NUM_EMBEDDED>
1380 void
1381 semi_embedded_vec<T, NUM_EMBEDDED>::push (const T& value)
1383 int idx = m_num++;
1384 if (idx < NUM_EMBEDDED)
1385 m_embedded[idx] = value;
1386 else
1388 /* Offset "idx" to be an index within m_extra. */
1389 idx -= NUM_EMBEDDED;
1390 if (NULL == m_extra)
1392 linemap_assert (m_alloc == 0);
1393 m_alloc = 16;
1394 m_extra = XNEWVEC (T, m_alloc);
1396 else if (idx >= m_alloc)
1398 linemap_assert (m_alloc > 0);
1399 m_alloc *= 2;
1400 m_extra = XRESIZEVEC (T, m_extra, m_alloc);
1402 linemap_assert (m_extra);
1403 linemap_assert (idx < m_alloc);
1404 m_extra[idx] = value;
1408 /* Truncate to length LEN. No deallocation is performed. */
1410 template <typename T, int NUM_EMBEDDED>
1411 void
1412 semi_embedded_vec<T, NUM_EMBEDDED>::truncate (int len)
1414 linemap_assert (len <= m_num);
1415 m_num = len;
1418 class fixit_hint;
1419 class fixit_insert;
1420 class fixit_replace;
1422 /* A "rich" source code location, for use when printing diagnostics.
1423 A rich_location has one or more carets&ranges, where the carets
1424 are optional. These are referred to as "ranges" from here.
1425 Typically the zeroth range has a caret; other ranges sometimes
1426 have carets.
1428 The "primary" location of a rich_location is the caret of range 0,
1429 used for determining the line/column when printing diagnostic
1430 text, such as:
1432 some-file.c:3:1: error: ...etc...
1434 Additional ranges may be added to help the user identify other
1435 pertinent clauses in a diagnostic.
1437 rich_location instances are intended to be allocated on the stack
1438 when generating diagnostics, and to be short-lived.
1440 Examples of rich locations
1441 --------------------------
1443 Example A
1444 *********
1445 int i = "foo";
1447 This "rich" location is simply a single range (range 0), with
1448 caret = start = finish at the given point.
1450 Example B
1451 *********
1452 a = (foo && bar)
1453 ~~~~~^~~~~~~
1454 This rich location has a single range (range 0), with the caret
1455 at the first "&", and the start/finish at the parentheses.
1456 Compare with example C below.
1458 Example C
1459 *********
1460 a = (foo && bar)
1461 ~~~ ^~ ~~~
1462 This rich location has three ranges:
1463 - Range 0 has its caret and start location at the first "&" and
1464 end at the second "&.
1465 - Range 1 has its start and finish at the "f" and "o" of "foo";
1466 the caret is not flagged for display, but is perhaps at the "f"
1467 of "foo".
1468 - Similarly, range 2 has its start and finish at the "b" and "r" of
1469 "bar"; the caret is not flagged for display, but is perhaps at the
1470 "b" of "bar".
1471 Compare with example B above.
1473 Example D (Fortran frontend)
1474 ****************************
1475 x = x + y
1477 This rich location has range 0 at "1", and range 1 at "2".
1478 Both are flagged for caret display. Both ranges have start/finish
1479 equal to their caret point. The frontend overrides the diagnostic
1480 context's default caret character for these ranges.
1482 Example E
1483 *********
1484 printf ("arg0: %i arg1: %s arg2: %i",
1486 100, 101, 102);
1488 This rich location has two ranges:
1489 - range 0 is at the "%s" with start = caret = "%" and finish at
1490 the "s".
1491 - range 1 has start/finish covering the "101" and is not flagged for
1492 caret printing; it is perhaps at the start of "101".
1495 Fix-it hints
1496 ------------
1498 Rich locations can also contain "fix-it hints", giving suggestions
1499 for the user on how to edit their code to fix a problem. These
1500 can be expressed as insertions, replacements, and removals of text.
1501 The edits by default are relative to the zeroth range within the
1502 rich_location, but optionally they can be expressed relative to
1503 other locations (using various overloaded methods of the form
1504 rich_location::add_fixit_*).
1506 For example:
1508 Example F: fix-it hint: insert_before
1509 *************************************
1510 ptr = arr[0];
1511 ^~~~~~
1513 This rich location has a single range (range 0) covering "arr[0]",
1514 with the caret at the start. The rich location has a single
1515 insertion fix-it hint, inserted before range 0, added via
1516 richloc.add_fixit_insert_before ("&");
1518 Example G: multiple fix-it hints: insert_before and insert_after
1519 ****************************************************************
1520 #define FN(ARG0, ARG1, ARG2) fn(ARG0, ARG1, ARG2)
1521 ^~~~ ^~~~ ^~~~
1522 ( ) ( ) ( )
1523 This rich location has three ranges, covering "arg0", "arg1",
1524 and "arg2", all with caret-printing enabled.
1525 The rich location has 6 insertion fix-it hints: each arg
1526 has a pair of insertion fix-it hints, suggesting wrapping
1527 them with parentheses: one a '(' inserted before,
1528 the other a ')' inserted after, added via
1529 richloc.add_fixit_insert_before (LOC, "(");
1531 richloc.add_fixit_insert_after (LOC, ")");
1533 Example H: fix-it hint: removal
1534 *******************************
1535 struct s {int i};;
1538 This rich location has a single range at the stray trailing
1539 semicolon, along with a single removal fix-it hint, covering
1540 the same range, added via:
1541 richloc.add_fixit_remove ();
1543 Example I: fix-it hint: replace
1544 *******************************
1545 c = s.colour;
1546 ^~~~~~
1547 color
1548 This rich location has a single range (range 0) covering "colour",
1549 and a single "replace" fix-it hint, covering the same range,
1550 added via
1551 richloc.add_fixit_replace ("color");
1553 Adding a fix-it hint can fail: for example, attempts to insert content
1554 at the transition between two line maps may fail due to there being no
1555 source_location (aka location_t) value to express the new location.
1557 Attempts to add a fix-it hint within a macro expansion will fail.
1559 We do not yet support newlines in fix-it text; attempts to do so will fail.
1561 The rich_location API handles these failures gracefully, so that
1562 diagnostics can attempt to add fix-it hints without each needing
1563 extensive checking.
1565 Fix-it hints within a rich_location are "atomic": if any hints can't
1566 be applied, none of them will be (tracked by the m_seen_impossible_fixit
1567 flag), and no fix-its hints will be displayed for that rich_location.
1568 This implies that diagnostic messages need to be worded in such a way
1569 that they make sense whether or not the fix-it hints are displayed,
1570 or that richloc.seen_impossible_fixit_p () should be checked before
1571 issuing the diagnostics. */
1573 class rich_location
1575 public:
1576 /* Constructors. */
1578 /* Constructing from a location. */
1579 rich_location (line_maps *set, source_location loc);
1581 /* Destructor. */
1582 ~rich_location ();
1584 /* Accessors. */
1585 source_location get_loc () const { return get_loc (0); }
1586 source_location get_loc (unsigned int idx) const;
1588 void
1589 add_range (source_location loc, bool show_caret_p);
1591 void
1592 set_range (line_maps *set, unsigned int idx, source_location loc,
1593 bool show_caret_p);
1595 unsigned int get_num_locations () const { return m_ranges.count (); }
1597 const location_range *get_range (unsigned int idx) const;
1598 location_range *get_range (unsigned int idx);
1600 expanded_location get_expanded_location (unsigned int idx);
1602 void
1603 override_column (int column);
1605 /* Fix-it hints. */
1607 /* Methods for adding insertion fix-it hints. */
1609 /* Suggest inserting NEW_CONTENT immediately before the primary
1610 range's start. */
1611 void
1612 add_fixit_insert_before (const char *new_content);
1614 /* Suggest inserting NEW_CONTENT immediately before the start of WHERE. */
1615 void
1616 add_fixit_insert_before (source_location where,
1617 const char *new_content);
1619 /* Suggest inserting NEW_CONTENT immediately after the end of the primary
1620 range. */
1621 void
1622 add_fixit_insert_after (const char *new_content);
1624 /* Suggest inserting NEW_CONTENT immediately after the end of WHERE. */
1625 void
1626 add_fixit_insert_after (source_location where,
1627 const char *new_content);
1629 /* Methods for adding removal fix-it hints. */
1631 /* Suggest removing the content covered by range 0. */
1632 void
1633 add_fixit_remove ();
1635 /* Suggest removing the content covered between the start and finish
1636 of WHERE. */
1637 void
1638 add_fixit_remove (source_location where);
1640 /* Suggest removing the content covered by SRC_RANGE. */
1641 void
1642 add_fixit_remove (source_range src_range);
1644 /* Methods for adding "replace" fix-it hints. */
1646 /* Suggest replacing the content covered by range 0 with NEW_CONTENT. */
1647 void
1648 add_fixit_replace (const char *new_content);
1650 /* Suggest replacing the content between the start and finish of
1651 WHERE with NEW_CONTENT. */
1652 void
1653 add_fixit_replace (source_location where,
1654 const char *new_content);
1656 /* Suggest replacing the content covered by SRC_RANGE with
1657 NEW_CONTENT. */
1658 void
1659 add_fixit_replace (source_range src_range,
1660 const char *new_content);
1662 unsigned int get_num_fixit_hints () const { return m_fixit_hints.count (); }
1663 fixit_hint *get_fixit_hint (int idx) const { return m_fixit_hints[idx]; }
1664 fixit_hint *get_last_fixit_hint () const;
1665 bool seen_impossible_fixit_p () const { return m_seen_impossible_fixit; }
1667 private:
1668 bool reject_impossible_fixit (source_location where);
1669 void stop_supporting_fixits ();
1670 void add_fixit (fixit_hint *hint);
1672 public:
1673 static const int STATICALLY_ALLOCATED_RANGES = 3;
1675 protected:
1676 line_maps *m_line_table;
1677 semi_embedded_vec <location_range, STATICALLY_ALLOCATED_RANGES> m_ranges;
1679 int m_column_override;
1681 bool m_have_expanded_location;
1682 expanded_location m_expanded_location;
1684 static const int MAX_STATIC_FIXIT_HINTS = 2;
1685 semi_embedded_vec <fixit_hint *, MAX_STATIC_FIXIT_HINTS> m_fixit_hints;
1687 bool m_seen_impossible_fixit;
1690 class fixit_hint
1692 public:
1693 enum kind {INSERT, REPLACE};
1695 virtual ~fixit_hint () {}
1697 virtual enum kind get_kind () const = 0;
1698 virtual bool affects_line_p (const char *file, int line) const = 0;
1699 virtual source_location get_start_loc () const = 0;
1700 virtual bool maybe_get_end_loc (source_location *out) const = 0;
1701 /* Vfunc for consolidating successor fixits. */
1702 virtual bool maybe_append_replace (line_maps *set,
1703 source_range src_range,
1704 const char *new_content) = 0;
1707 class fixit_insert : public fixit_hint
1709 public:
1710 fixit_insert (source_location where,
1711 const char *new_content);
1712 ~fixit_insert ();
1713 enum kind get_kind () const { return INSERT; }
1714 bool affects_line_p (const char *file, int line) const;
1715 source_location get_start_loc () const { return m_where; }
1716 bool maybe_get_end_loc (source_location *) const { return false; }
1717 bool maybe_append_replace (line_maps *set,
1718 source_range src_range,
1719 const char *new_content);
1721 source_location get_location () const { return m_where; }
1722 const char *get_string () const { return m_bytes; }
1723 size_t get_length () const { return m_len; }
1725 private:
1726 source_location m_where;
1727 char *m_bytes;
1728 size_t m_len;
1731 class fixit_replace : public fixit_hint
1733 public:
1734 fixit_replace (source_range src_range,
1735 const char *new_content);
1736 ~fixit_replace ();
1738 enum kind get_kind () const { return REPLACE; }
1739 bool affects_line_p (const char *file, int line) const;
1740 source_location get_start_loc () const { return m_src_range.m_start; }
1741 bool maybe_get_end_loc (source_location *out) const
1743 *out = m_src_range.m_finish;
1744 return true;
1746 bool maybe_append_replace (line_maps *set,
1747 source_range src_range,
1748 const char *new_content);
1750 source_range get_range () const { return m_src_range; }
1751 const char *get_string () const { return m_bytes; }
1752 size_t get_length () const { return m_len; }
1754 private:
1755 source_range m_src_range;
1756 char *m_bytes;
1757 size_t m_len;
1761 /* This is enum is used by the function linemap_resolve_location
1762 below. The meaning of the values is explained in the comment of
1763 that function. */
1764 enum location_resolution_kind
1766 LRK_MACRO_EXPANSION_POINT,
1767 LRK_SPELLING_LOCATION,
1768 LRK_MACRO_DEFINITION_LOCATION
1771 /* Resolve a virtual location into either a spelling location, an
1772 expansion point location or a token argument replacement point
1773 location. Return the map that encodes the virtual location as well
1774 as the resolved location.
1776 If LOC is *NOT* the location of a token resulting from the
1777 expansion of a macro, then the parameter LRK (which stands for
1778 Location Resolution Kind) is ignored and the resulting location
1779 just equals the one given in argument.
1781 Now if LOC *IS* the location of a token resulting from the
1782 expansion of a macro, this is what happens.
1784 * If LRK is set to LRK_MACRO_EXPANSION_POINT
1785 -------------------------------
1787 The virtual location is resolved to the first macro expansion point
1788 that led to this macro expansion.
1790 * If LRK is set to LRK_SPELLING_LOCATION
1791 -------------------------------------
1793 The virtual location is resolved to the locus where the token has
1794 been spelled in the source. This can follow through all the macro
1795 expansions that led to the token.
1797 * If LRK is set to LRK_MACRO_DEFINITION_LOCATION
1798 --------------------------------------
1800 The virtual location is resolved to the locus of the token in the
1801 context of the macro definition.
1803 If LOC is the locus of a token that is an argument of a
1804 function-like macro [replacing a parameter in the replacement list
1805 of the macro] the virtual location is resolved to the locus of the
1806 parameter that is replaced, in the context of the definition of the
1807 macro.
1809 If LOC is the locus of a token that is not an argument of a
1810 function-like macro, then the function behaves as if LRK was set to
1811 LRK_SPELLING_LOCATION.
1813 If LOC_MAP is not NULL, *LOC_MAP is set to the map encoding the
1814 returned location. Note that if the returned location wasn't originally
1815 encoded by a map, the *MAP is set to NULL. This can happen if LOC
1816 resolves to a location reserved for the client code, like
1817 UNKNOWN_LOCATION or BUILTINS_LOCATION in GCC. */
1819 source_location linemap_resolve_location (struct line_maps *,
1820 source_location loc,
1821 enum location_resolution_kind lrk,
1822 const line_map_ordinary **loc_map);
1824 /* Suppose that LOC is the virtual location of a token coming from the
1825 expansion of a macro M. This function then steps up to get the
1826 location L of the point where M got expanded. If L is a spelling
1827 location inside a macro expansion M', then this function returns
1828 the point where M' was expanded. LOC_MAP is an output parameter.
1829 When non-NULL, *LOC_MAP is set to the map of the returned
1830 location. */
1831 source_location linemap_unwind_toward_expansion (struct line_maps *,
1832 source_location loc,
1833 const struct line_map **loc_map);
1835 /* If LOC is the virtual location of a token coming from the expansion
1836 of a macro M and if its spelling location is reserved (e.g, a
1837 location for a built-in token), then this function unwinds (using
1838 linemap_unwind_toward_expansion) the location until a location that
1839 is not reserved and is not in a system header is reached. In other
1840 words, this unwinds the reserved location until a location that is
1841 in real source code is reached.
1843 Otherwise, if the spelling location for LOC is not reserved or if
1844 LOC doesn't come from the expansion of a macro, the function
1845 returns LOC as is and *MAP is not touched.
1847 *MAP is set to the map of the returned location if the later is
1848 different from LOC. */
1849 source_location linemap_unwind_to_first_non_reserved_loc (struct line_maps *,
1850 source_location loc,
1851 const struct line_map **map);
1853 /* Expand source code location LOC and return a user readable source
1854 code location. LOC must be a spelling (non-virtual) location. If
1855 it's a location < RESERVED_LOCATION_COUNT a zeroed expanded source
1856 location is returned. */
1857 expanded_location linemap_expand_location (struct line_maps *,
1858 const struct line_map *,
1859 source_location loc);
1861 /* Statistics about maps allocation and usage as returned by
1862 linemap_get_statistics. */
1863 struct linemap_stats
1865 long num_ordinary_maps_allocated;
1866 long num_ordinary_maps_used;
1867 long ordinary_maps_allocated_size;
1868 long ordinary_maps_used_size;
1869 long num_expanded_macros;
1870 long num_macro_tokens;
1871 long num_macro_maps_used;
1872 long macro_maps_allocated_size;
1873 long macro_maps_used_size;
1874 long macro_maps_locations_size;
1875 long duplicated_macro_maps_locations_size;
1876 long adhoc_table_size;
1877 long adhoc_table_entries_used;
1880 /* Return the highest location emitted for a given file for which
1881 there is a line map in SET. FILE_NAME is the file name to
1882 consider. If the function returns TRUE, *LOC is set to the highest
1883 location emitted for that file. */
1884 bool linemap_get_file_highest_location (struct line_maps * set,
1885 const char *file_name,
1886 source_location *loc);
1888 /* Compute and return statistics about the memory consumption of some
1889 parts of the line table SET. */
1890 void linemap_get_statistics (struct line_maps *, struct linemap_stats *);
1892 /* Dump debugging information about source location LOC into the file
1893 stream STREAM. SET is the line map set LOC comes from. */
1894 void linemap_dump_location (struct line_maps *, source_location, FILE *);
1896 /* Dump line map at index IX in line table SET to STREAM. If STREAM
1897 is NULL, use stderr. IS_MACRO is true if the caller wants to
1898 dump a macro map, false otherwise. */
1899 void linemap_dump (FILE *, struct line_maps *, unsigned, bool);
1901 /* Dump line table SET to STREAM. If STREAM is NULL, stderr is used.
1902 NUM_ORDINARY specifies how many ordinary maps to dump. NUM_MACRO
1903 specifies how many macro maps to dump. */
1904 void line_table_dump (FILE *, struct line_maps *, unsigned int, unsigned int);
1906 /* The rich_location class requires a way to expand source_location instances.
1907 We would directly use expand_location_to_spelling_point, which is
1908 implemented in gcc/input.c, but we also need to use it for rich_location
1909 within genmatch.c.
1910 Hence we require client code of libcpp to implement the following
1911 symbol. */
1912 extern expanded_location
1913 linemap_client_expand_location_to_spelling_point (source_location );
1915 #endif /* !LIBCPP_LINE_MAP_H */