PR ld/11384
[binutils/dougsmingw.git] / gas / config / tc-xtensa.c
blobede3cb9bee101f2d09ab3d12615239e17781446b
1 /* tc-xtensa.c -- Assemble Xtensa instructions.
2 Copyright 2003, 2004, 2005, 2006, 2007, 2008, 2009
3 Free Software Foundation, Inc.
5 This file is part of GAS, the GNU Assembler.
7 GAS is free software; you can redistribute it and/or modify
8 it under the terms of the GNU General Public License as published by
9 the Free Software Foundation; either version 3, or (at your option)
10 any later version.
12 GAS is distributed in the hope that it will be useful,
13 but WITHOUT ANY WARRANTY; without even the implied warranty of
14 MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
15 GNU General Public License for more details.
17 You should have received a copy of the GNU General Public License
18 along with GAS; see the file COPYING. If not, write to
19 the Free Software Foundation, 51 Franklin Street - Fifth Floor, Boston,
20 MA 02110-1301, USA. */
22 #include <limits.h>
23 #include "as.h"
24 #include "sb.h"
25 #include "safe-ctype.h"
26 #include "tc-xtensa.h"
27 #include "subsegs.h"
28 #include "xtensa-relax.h"
29 #include "dwarf2dbg.h"
30 #include "xtensa-istack.h"
31 #include "struc-symbol.h"
32 #include "xtensa-config.h"
34 /* Provide default values for new configuration settings. */
35 #ifndef XSHAL_ABI
36 #define XSHAL_ABI 0
37 #endif
39 #ifndef uint32
40 #define uint32 unsigned int
41 #endif
42 #ifndef int32
43 #define int32 signed int
44 #endif
46 /* Notes:
48 Naming conventions (used somewhat inconsistently):
49 The xtensa_ functions are exported
50 The xg_ functions are internal
52 We also have a couple of different extensibility mechanisms.
53 1) The idiom replacement:
54 This is used when a line is first parsed to
55 replace an instruction pattern with another instruction
56 It is currently limited to replacements of instructions
57 with constant operands.
58 2) The xtensa-relax.c mechanism that has stronger instruction
59 replacement patterns. When an instruction's immediate field
60 does not fit the next instruction sequence is attempted.
61 In addition, "narrow" opcodes are supported this way. */
64 /* Define characters with special meanings to GAS. */
65 const char comment_chars[] = "#";
66 const char line_comment_chars[] = "#";
67 const char line_separator_chars[] = ";";
68 const char EXP_CHARS[] = "eE";
69 const char FLT_CHARS[] = "rRsSfFdDxXpP";
72 /* Flags to indicate whether the hardware supports the density and
73 absolute literals options. */
75 bfd_boolean density_supported = XCHAL_HAVE_DENSITY;
76 bfd_boolean absolute_literals_supported = XSHAL_USE_ABSOLUTE_LITERALS;
78 static vliw_insn cur_vinsn;
80 unsigned xtensa_num_pipe_stages;
81 unsigned xtensa_fetch_width = XCHAL_INST_FETCH_WIDTH;
83 static enum debug_info_type xt_saved_debug_type = DEBUG_NONE;
85 /* Some functions are only valid in the front end. This variable
86 allows us to assert that we haven't crossed over into the
87 back end. */
88 static bfd_boolean past_xtensa_end = FALSE;
90 /* Flags for properties of the last instruction in a segment. */
91 #define FLAG_IS_A0_WRITER 0x1
92 #define FLAG_IS_BAD_LOOPEND 0x2
95 /* We define a special segment names ".literal" to place literals
96 into. The .fini and .init sections are special because they
97 contain code that is moved together by the linker. We give them
98 their own special .fini.literal and .init.literal sections. */
100 #define LITERAL_SECTION_NAME xtensa_section_rename (".literal")
101 #define LIT4_SECTION_NAME xtensa_section_rename (".lit4")
102 #define INIT_SECTION_NAME xtensa_section_rename (".init")
103 #define FINI_SECTION_NAME xtensa_section_rename (".fini")
106 /* This type is used for the directive_stack to keep track of the
107 state of the literal collection pools. If lit_prefix is set, it is
108 used to determine the literal section names; otherwise, the literal
109 sections are determined based on the current text section. The
110 lit_seg and lit4_seg fields cache these literal sections, with the
111 current_text_seg field used a tag to indicate whether the cached
112 values are valid. */
114 typedef struct lit_state_struct
116 char *lit_prefix;
117 segT current_text_seg;
118 segT lit_seg;
119 segT lit4_seg;
120 } lit_state;
122 static lit_state default_lit_sections;
125 /* We keep a list of literal segments. The seg_list type is the node
126 for this list. The literal_head pointer is the head of the list,
127 with the literal_head_h dummy node at the start. */
129 typedef struct seg_list_struct
131 struct seg_list_struct *next;
132 segT seg;
133 } seg_list;
135 static seg_list literal_head_h;
136 static seg_list *literal_head = &literal_head_h;
139 /* Lists of symbols. We keep a list of symbols that label the current
140 instruction, so that we can adjust the symbols when inserting alignment
141 for various instructions. We also keep a list of all the symbols on
142 literals, so that we can fix up those symbols when the literals are
143 later moved into the text sections. */
145 typedef struct sym_list_struct
147 struct sym_list_struct *next;
148 symbolS *sym;
149 } sym_list;
151 static sym_list *insn_labels = NULL;
152 static sym_list *free_insn_labels = NULL;
153 static sym_list *saved_insn_labels = NULL;
155 static sym_list *literal_syms;
158 /* Flags to determine whether to prefer const16 or l32r
159 if both options are available. */
160 int prefer_const16 = 0;
161 int prefer_l32r = 0;
163 /* Global flag to indicate when we are emitting literals. */
164 int generating_literals = 0;
166 /* The following PROPERTY table definitions are copied from
167 <elf/xtensa.h> and must be kept in sync with the code there. */
169 /* Flags in the property tables to specify whether blocks of memory
170 are literals, instructions, data, or unreachable. For
171 instructions, blocks that begin loop targets and branch targets are
172 designated. Blocks that do not allow density, instruction
173 reordering or transformation are also specified. Finally, for
174 branch targets, branch target alignment priority is included.
175 Alignment of the next block is specified in the current block
176 and the size of the current block does not include any fill required
177 to align to the next block. */
179 #define XTENSA_PROP_LITERAL 0x00000001
180 #define XTENSA_PROP_INSN 0x00000002
181 #define XTENSA_PROP_DATA 0x00000004
182 #define XTENSA_PROP_UNREACHABLE 0x00000008
183 /* Instruction only properties at beginning of code. */
184 #define XTENSA_PROP_INSN_LOOP_TARGET 0x00000010
185 #define XTENSA_PROP_INSN_BRANCH_TARGET 0x00000020
186 /* Instruction only properties about code. */
187 #define XTENSA_PROP_INSN_NO_DENSITY 0x00000040
188 #define XTENSA_PROP_INSN_NO_REORDER 0x00000080
189 /* Historically, NO_TRANSFORM was a property of instructions,
190 but it should apply to literals under certain circumstances. */
191 #define XTENSA_PROP_NO_TRANSFORM 0x00000100
193 /* Branch target alignment information. This transmits information
194 to the linker optimization about the priority of aligning a
195 particular block for branch target alignment: None, low priority,
196 high priority, or required. These only need to be checked in
197 instruction blocks marked as XTENSA_PROP_INSN_BRANCH_TARGET.
198 Common usage is
200 switch (GET_XTENSA_PROP_BT_ALIGN (flags))
201 case XTENSA_PROP_BT_ALIGN_NONE:
202 case XTENSA_PROP_BT_ALIGN_LOW:
203 case XTENSA_PROP_BT_ALIGN_HIGH:
204 case XTENSA_PROP_BT_ALIGN_REQUIRE:
206 #define XTENSA_PROP_BT_ALIGN_MASK 0x00000600
208 /* No branch target alignment. */
209 #define XTENSA_PROP_BT_ALIGN_NONE 0x0
210 /* Low priority branch target alignment. */
211 #define XTENSA_PROP_BT_ALIGN_LOW 0x1
212 /* High priority branch target alignment. */
213 #define XTENSA_PROP_BT_ALIGN_HIGH 0x2
214 /* Required branch target alignment. */
215 #define XTENSA_PROP_BT_ALIGN_REQUIRE 0x3
217 #define GET_XTENSA_PROP_BT_ALIGN(flag) \
218 (((unsigned) ((flag) & (XTENSA_PROP_BT_ALIGN_MASK))) >> 9)
219 #define SET_XTENSA_PROP_BT_ALIGN(flag, align) \
220 (((flag) & (~XTENSA_PROP_BT_ALIGN_MASK)) | \
221 (((align) << 9) & XTENSA_PROP_BT_ALIGN_MASK))
224 /* Alignment is specified in the block BEFORE the one that needs
225 alignment. Up to 5 bits. Use GET_XTENSA_PROP_ALIGNMENT(flags) to
226 get the required alignment specified as a power of 2. Use
227 SET_XTENSA_PROP_ALIGNMENT(flags, pow2) to set the required
228 alignment. Be careful of side effects since the SET will evaluate
229 flags twice. Also, note that the SIZE of a block in the property
230 table does not include the alignment size, so the alignment fill
231 must be calculated to determine if two blocks are contiguous.
232 TEXT_ALIGN is not currently implemented but is a placeholder for a
233 possible future implementation. */
235 #define XTENSA_PROP_ALIGN 0x00000800
237 #define XTENSA_PROP_ALIGNMENT_MASK 0x0001f000
239 #define GET_XTENSA_PROP_ALIGNMENT(flag) \
240 (((unsigned) ((flag) & (XTENSA_PROP_ALIGNMENT_MASK))) >> 12)
241 #define SET_XTENSA_PROP_ALIGNMENT(flag, align) \
242 (((flag) & (~XTENSA_PROP_ALIGNMENT_MASK)) | \
243 (((align) << 12) & XTENSA_PROP_ALIGNMENT_MASK))
245 #define XTENSA_PROP_INSN_ABSLIT 0x00020000
248 /* Structure for saving instruction and alignment per-fragment data
249 that will be written to the object file. This structure is
250 equivalent to the actual data that will be written out to the file
251 but is easier to use. We provide a conversion to file flags
252 in frag_flags_to_number. */
254 typedef struct frag_flags_struct frag_flags;
256 struct frag_flags_struct
258 /* is_literal should only be used after xtensa_move_literals.
259 If you need to check if you are generating a literal fragment,
260 then use the generating_literals global. */
262 unsigned is_literal : 1;
263 unsigned is_insn : 1;
264 unsigned is_data : 1;
265 unsigned is_unreachable : 1;
267 /* is_specific_opcode implies no_transform. */
268 unsigned is_no_transform : 1;
270 struct
272 unsigned is_loop_target : 1;
273 unsigned is_branch_target : 1; /* Branch targets have a priority. */
274 unsigned bt_align_priority : 2;
276 unsigned is_no_density : 1;
277 /* no_longcalls flag does not need to be placed in the object file. */
279 unsigned is_no_reorder : 1;
281 /* Uses absolute literal addressing for l32r. */
282 unsigned is_abslit : 1;
283 } insn;
284 unsigned is_align : 1;
285 unsigned alignment : 5;
289 /* Structure for saving information about a block of property data
290 for frags that have the same flags. */
291 struct xtensa_block_info_struct
293 segT sec;
294 bfd_vma offset;
295 size_t size;
296 frag_flags flags;
297 struct xtensa_block_info_struct *next;
301 /* Structure for saving the current state before emitting literals. */
302 typedef struct emit_state_struct
304 const char *name;
305 segT now_seg;
306 subsegT now_subseg;
307 int generating_literals;
308 } emit_state;
311 /* Opcode placement information */
313 typedef unsigned long long bitfield;
314 #define bit_is_set(bit, bf) ((bf) & (0x01ll << (bit)))
315 #define set_bit(bit, bf) ((bf) |= (0x01ll << (bit)))
316 #define clear_bit(bit, bf) ((bf) &= ~(0x01ll << (bit)))
318 #define MAX_FORMATS 32
320 typedef struct op_placement_info_struct
322 int num_formats;
323 /* A number describing how restrictive the issue is for this
324 opcode. For example, an opcode that fits lots of different
325 formats has a high freedom, as does an opcode that fits
326 only one format but many slots in that format. The most
327 restrictive is the opcode that fits only one slot in one
328 format. */
329 int issuef;
330 xtensa_format narrowest;
331 char narrowest_size;
332 char narrowest_slot;
334 /* formats is a bitfield with the Nth bit set
335 if the opcode fits in the Nth xtensa_format. */
336 bitfield formats;
338 /* slots[N]'s Mth bit is set if the op fits in the
339 Mth slot of the Nth xtensa_format. */
340 bitfield slots[MAX_FORMATS];
342 /* A count of the number of slots in a given format
343 an op can fit (i.e., the bitcount of the slot field above). */
344 char slots_in_format[MAX_FORMATS];
346 } op_placement_info, *op_placement_info_table;
348 op_placement_info_table op_placement_table;
351 /* Extra expression types. */
353 #define O_pltrel O_md1 /* like O_symbol but use a PLT reloc */
354 #define O_hi16 O_md2 /* use high 16 bits of symbolic value */
355 #define O_lo16 O_md3 /* use low 16 bits of symbolic value */
356 #define O_pcrel O_md4 /* value is a PC-relative offset */
357 #define O_tlsfunc O_md5 /* TLS_FUNC/TLSDESC_FN relocation */
358 #define O_tlsarg O_md6 /* TLS_ARG/TLSDESC_ARG relocation */
359 #define O_tlscall O_md7 /* TLS_CALL relocation */
360 #define O_tpoff O_md8 /* TPOFF relocation */
361 #define O_dtpoff O_md9 /* DTPOFF relocation */
363 struct suffix_reloc_map
365 char *suffix;
366 int length;
367 bfd_reloc_code_real_type reloc;
368 unsigned char operator;
371 #define SUFFIX_MAP(str, reloc, op) { str, sizeof (str) - 1, reloc, op }
373 static struct suffix_reloc_map suffix_relocs[] =
375 SUFFIX_MAP ("l", BFD_RELOC_LO16, O_lo16),
376 SUFFIX_MAP ("h", BFD_RELOC_HI16, O_hi16),
377 SUFFIX_MAP ("plt", BFD_RELOC_XTENSA_PLT, O_pltrel),
378 SUFFIX_MAP ("pcrel", BFD_RELOC_32_PCREL, O_pcrel),
379 SUFFIX_MAP ("tlsfunc", BFD_RELOC_XTENSA_TLS_FUNC, O_tlsfunc),
380 SUFFIX_MAP ("tlsarg", BFD_RELOC_XTENSA_TLS_ARG, O_tlsarg),
381 SUFFIX_MAP ("tlscall", BFD_RELOC_XTENSA_TLS_CALL, O_tlscall),
382 SUFFIX_MAP ("tpoff", BFD_RELOC_XTENSA_TLS_TPOFF, O_tpoff),
383 SUFFIX_MAP ("dtpoff", BFD_RELOC_XTENSA_TLS_DTPOFF, O_dtpoff),
384 { (char *) 0, 0, BFD_RELOC_UNUSED, 0 }
388 /* Directives. */
390 typedef enum
392 directive_none = 0,
393 directive_literal,
394 directive_density,
395 directive_transform,
396 directive_freeregs,
397 directive_longcalls,
398 directive_literal_prefix,
399 directive_schedule,
400 directive_absolute_literals,
401 directive_last_directive
402 } directiveE;
404 typedef struct
406 const char *name;
407 bfd_boolean can_be_negated;
408 } directive_infoS;
410 const directive_infoS directive_info[] =
412 { "none", FALSE },
413 { "literal", FALSE },
414 { "density", TRUE },
415 { "transform", TRUE },
416 { "freeregs", FALSE },
417 { "longcalls", TRUE },
418 { "literal_prefix", FALSE },
419 { "schedule", TRUE },
420 { "absolute-literals", TRUE }
423 bfd_boolean directive_state[] =
425 FALSE, /* none */
426 FALSE, /* literal */
427 #if !XCHAL_HAVE_DENSITY
428 FALSE, /* density */
429 #else
430 TRUE, /* density */
431 #endif
432 TRUE, /* transform */
433 FALSE, /* freeregs */
434 FALSE, /* longcalls */
435 FALSE, /* literal_prefix */
436 FALSE, /* schedule */
437 #if XSHAL_USE_ABSOLUTE_LITERALS
438 TRUE /* absolute_literals */
439 #else
440 FALSE /* absolute_literals */
441 #endif
445 /* Directive functions. */
447 static void xtensa_begin_directive (int);
448 static void xtensa_end_directive (int);
449 static void xtensa_literal_prefix (void);
450 static void xtensa_literal_position (int);
451 static void xtensa_literal_pseudo (int);
452 static void xtensa_frequency_pseudo (int);
453 static void xtensa_elf_cons (int);
454 static void xtensa_leb128 (int);
456 /* Parsing and Idiom Translation. */
458 static bfd_reloc_code_real_type xtensa_elf_suffix (char **, expressionS *);
460 /* Various Other Internal Functions. */
462 extern bfd_boolean xg_is_single_relaxable_insn (TInsn *, TInsn *, bfd_boolean);
463 static bfd_boolean xg_build_to_insn (TInsn *, TInsn *, BuildInstr *);
464 static void xtensa_mark_literal_pool_location (void);
465 static addressT get_expanded_loop_offset (xtensa_opcode);
466 static fragS *get_literal_pool_location (segT);
467 static void set_literal_pool_location (segT, fragS *);
468 static void xtensa_set_frag_assembly_state (fragS *);
469 static void finish_vinsn (vliw_insn *);
470 static bfd_boolean emit_single_op (TInsn *);
471 static int total_frag_text_expansion (fragS *);
473 /* Alignment Functions. */
475 static int get_text_align_power (unsigned);
476 static int get_text_align_max_fill_size (int, bfd_boolean, bfd_boolean);
477 static int branch_align_power (segT);
479 /* Helpers for xtensa_relax_frag(). */
481 static long relax_frag_add_nop (fragS *);
483 /* Accessors for additional per-subsegment information. */
485 static unsigned get_last_insn_flags (segT, subsegT);
486 static void set_last_insn_flags (segT, subsegT, unsigned, bfd_boolean);
487 static float get_subseg_total_freq (segT, subsegT);
488 static float get_subseg_target_freq (segT, subsegT);
489 static void set_subseg_freq (segT, subsegT, float, float);
491 /* Segment list functions. */
493 static void xtensa_move_literals (void);
494 static void xtensa_reorder_segments (void);
495 static void xtensa_switch_to_literal_fragment (emit_state *);
496 static void xtensa_switch_to_non_abs_literal_fragment (emit_state *);
497 static void xtensa_switch_section_emit_state (emit_state *, segT, subsegT);
498 static void xtensa_restore_emit_state (emit_state *);
499 static segT cache_literal_section (bfd_boolean);
501 /* Import from elf32-xtensa.c in BFD library. */
503 extern asection *xtensa_make_property_section (asection *, const char *);
505 /* op_placement_info functions. */
507 static void init_op_placement_info_table (void);
508 extern bfd_boolean opcode_fits_format_slot (xtensa_opcode, xtensa_format, int);
509 static int xg_get_single_size (xtensa_opcode);
510 static xtensa_format xg_get_single_format (xtensa_opcode);
511 static int xg_get_single_slot (xtensa_opcode);
513 /* TInsn and IStack functions. */
515 static bfd_boolean tinsn_has_symbolic_operands (const TInsn *);
516 static bfd_boolean tinsn_has_invalid_symbolic_operands (const TInsn *);
517 static bfd_boolean tinsn_has_complex_operands (const TInsn *);
518 static bfd_boolean tinsn_to_insnbuf (TInsn *, xtensa_insnbuf);
519 static bfd_boolean tinsn_check_arguments (const TInsn *);
520 static void tinsn_from_chars (TInsn *, char *, int);
521 static void tinsn_immed_from_frag (TInsn *, fragS *, int);
522 static int get_num_stack_text_bytes (IStack *);
523 static int get_num_stack_literal_bytes (IStack *);
525 /* vliw_insn functions. */
527 static void xg_init_vinsn (vliw_insn *);
528 static void xg_copy_vinsn (vliw_insn *, vliw_insn *);
529 static void xg_clear_vinsn (vliw_insn *);
530 static bfd_boolean vinsn_has_specific_opcodes (vliw_insn *);
531 static void xg_free_vinsn (vliw_insn *);
532 static bfd_boolean vinsn_to_insnbuf
533 (vliw_insn *, char *, fragS *, bfd_boolean);
534 static void vinsn_from_chars (vliw_insn *, char *);
536 /* Expression Utilities. */
538 bfd_boolean expr_is_const (const expressionS *);
539 offsetT get_expr_const (const expressionS *);
540 void set_expr_const (expressionS *, offsetT);
541 bfd_boolean expr_is_register (const expressionS *);
542 offsetT get_expr_register (const expressionS *);
543 void set_expr_symbol_offset (expressionS *, symbolS *, offsetT);
544 bfd_boolean expr_is_equal (expressionS *, expressionS *);
545 static void copy_expr (expressionS *, const expressionS *);
547 /* Section renaming. */
549 static void build_section_rename (const char *);
552 /* ISA imported from bfd. */
553 extern xtensa_isa xtensa_default_isa;
555 extern int target_big_endian;
557 static xtensa_opcode xtensa_addi_opcode;
558 static xtensa_opcode xtensa_addmi_opcode;
559 static xtensa_opcode xtensa_call0_opcode;
560 static xtensa_opcode xtensa_call4_opcode;
561 static xtensa_opcode xtensa_call8_opcode;
562 static xtensa_opcode xtensa_call12_opcode;
563 static xtensa_opcode xtensa_callx0_opcode;
564 static xtensa_opcode xtensa_callx4_opcode;
565 static xtensa_opcode xtensa_callx8_opcode;
566 static xtensa_opcode xtensa_callx12_opcode;
567 static xtensa_opcode xtensa_const16_opcode;
568 static xtensa_opcode xtensa_entry_opcode;
569 static xtensa_opcode xtensa_extui_opcode;
570 static xtensa_opcode xtensa_movi_opcode;
571 static xtensa_opcode xtensa_movi_n_opcode;
572 static xtensa_opcode xtensa_isync_opcode;
573 static xtensa_opcode xtensa_j_opcode;
574 static xtensa_opcode xtensa_jx_opcode;
575 static xtensa_opcode xtensa_l32r_opcode;
576 static xtensa_opcode xtensa_loop_opcode;
577 static xtensa_opcode xtensa_loopnez_opcode;
578 static xtensa_opcode xtensa_loopgtz_opcode;
579 static xtensa_opcode xtensa_nop_opcode;
580 static xtensa_opcode xtensa_nop_n_opcode;
581 static xtensa_opcode xtensa_or_opcode;
582 static xtensa_opcode xtensa_ret_opcode;
583 static xtensa_opcode xtensa_ret_n_opcode;
584 static xtensa_opcode xtensa_retw_opcode;
585 static xtensa_opcode xtensa_retw_n_opcode;
586 static xtensa_opcode xtensa_rsr_lcount_opcode;
587 static xtensa_opcode xtensa_waiti_opcode;
588 static int config_max_slots = 0;
591 /* Command-line Options. */
593 bfd_boolean use_literal_section = TRUE;
594 enum flix_level produce_flix = FLIX_ALL;
595 static bfd_boolean align_targets = TRUE;
596 static bfd_boolean warn_unaligned_branch_targets = FALSE;
597 static bfd_boolean has_a0_b_retw = FALSE;
598 static bfd_boolean workaround_a0_b_retw = FALSE;
599 static bfd_boolean workaround_b_j_loop_end = FALSE;
600 static bfd_boolean workaround_short_loop = FALSE;
601 static bfd_boolean maybe_has_short_loop = FALSE;
602 static bfd_boolean workaround_close_loop_end = FALSE;
603 static bfd_boolean maybe_has_close_loop_end = FALSE;
604 static bfd_boolean enforce_three_byte_loop_align = FALSE;
606 /* When workaround_short_loops is TRUE, all loops with early exits must
607 have at least 3 instructions. workaround_all_short_loops is a modifier
608 to the workaround_short_loop flag. In addition to the
609 workaround_short_loop actions, all straightline loopgtz and loopnez
610 must have at least 3 instructions. */
612 static bfd_boolean workaround_all_short_loops = FALSE;
615 static void
616 xtensa_setup_hw_workarounds (int earliest, int latest)
618 if (earliest > latest)
619 as_fatal (_("illegal range of target hardware versions"));
621 /* Enable all workarounds for pre-T1050.0 hardware. */
622 if (earliest < 105000 || latest < 105000)
624 workaround_a0_b_retw |= TRUE;
625 workaround_b_j_loop_end |= TRUE;
626 workaround_short_loop |= TRUE;
627 workaround_close_loop_end |= TRUE;
628 workaround_all_short_loops |= TRUE;
629 enforce_three_byte_loop_align = TRUE;
634 enum
636 option_density = OPTION_MD_BASE,
637 option_no_density,
639 option_flix,
640 option_no_generate_flix,
641 option_no_flix,
643 option_relax,
644 option_no_relax,
646 option_link_relax,
647 option_no_link_relax,
649 option_generics,
650 option_no_generics,
652 option_transform,
653 option_no_transform,
655 option_text_section_literals,
656 option_no_text_section_literals,
658 option_absolute_literals,
659 option_no_absolute_literals,
661 option_align_targets,
662 option_no_align_targets,
664 option_warn_unaligned_targets,
666 option_longcalls,
667 option_no_longcalls,
669 option_workaround_a0_b_retw,
670 option_no_workaround_a0_b_retw,
672 option_workaround_b_j_loop_end,
673 option_no_workaround_b_j_loop_end,
675 option_workaround_short_loop,
676 option_no_workaround_short_loop,
678 option_workaround_all_short_loops,
679 option_no_workaround_all_short_loops,
681 option_workaround_close_loop_end,
682 option_no_workaround_close_loop_end,
684 option_no_workarounds,
686 option_rename_section_name,
688 option_prefer_l32r,
689 option_prefer_const16,
691 option_target_hardware
694 const char *md_shortopts = "";
696 struct option md_longopts[] =
698 { "density", no_argument, NULL, option_density },
699 { "no-density", no_argument, NULL, option_no_density },
701 { "flix", no_argument, NULL, option_flix },
702 { "no-generate-flix", no_argument, NULL, option_no_generate_flix },
703 { "no-allow-flix", no_argument, NULL, option_no_flix },
705 /* Both "relax" and "generics" are deprecated and treated as equivalent
706 to the "transform" option. */
707 { "relax", no_argument, NULL, option_relax },
708 { "no-relax", no_argument, NULL, option_no_relax },
709 { "generics", no_argument, NULL, option_generics },
710 { "no-generics", no_argument, NULL, option_no_generics },
712 { "transform", no_argument, NULL, option_transform },
713 { "no-transform", no_argument, NULL, option_no_transform },
714 { "text-section-literals", no_argument, NULL, option_text_section_literals },
715 { "no-text-section-literals", no_argument, NULL,
716 option_no_text_section_literals },
717 { "absolute-literals", no_argument, NULL, option_absolute_literals },
718 { "no-absolute-literals", no_argument, NULL, option_no_absolute_literals },
719 /* This option was changed from -align-target to -target-align
720 because it conflicted with the "-al" option. */
721 { "target-align", no_argument, NULL, option_align_targets },
722 { "no-target-align", no_argument, NULL, option_no_align_targets },
723 { "warn-unaligned-targets", no_argument, NULL,
724 option_warn_unaligned_targets },
725 { "longcalls", no_argument, NULL, option_longcalls },
726 { "no-longcalls", no_argument, NULL, option_no_longcalls },
728 { "no-workaround-a0-b-retw", no_argument, NULL,
729 option_no_workaround_a0_b_retw },
730 { "workaround-a0-b-retw", no_argument, NULL, option_workaround_a0_b_retw },
732 { "no-workaround-b-j-loop-end", no_argument, NULL,
733 option_no_workaround_b_j_loop_end },
734 { "workaround-b-j-loop-end", no_argument, NULL,
735 option_workaround_b_j_loop_end },
737 { "no-workaround-short-loops", no_argument, NULL,
738 option_no_workaround_short_loop },
739 { "workaround-short-loops", no_argument, NULL,
740 option_workaround_short_loop },
742 { "no-workaround-all-short-loops", no_argument, NULL,
743 option_no_workaround_all_short_loops },
744 { "workaround-all-short-loop", no_argument, NULL,
745 option_workaround_all_short_loops },
747 { "prefer-l32r", no_argument, NULL, option_prefer_l32r },
748 { "prefer-const16", no_argument, NULL, option_prefer_const16 },
750 { "no-workarounds", no_argument, NULL, option_no_workarounds },
752 { "no-workaround-close-loop-end", no_argument, NULL,
753 option_no_workaround_close_loop_end },
754 { "workaround-close-loop-end", no_argument, NULL,
755 option_workaround_close_loop_end },
757 { "rename-section", required_argument, NULL, option_rename_section_name },
759 { "link-relax", no_argument, NULL, option_link_relax },
760 { "no-link-relax", no_argument, NULL, option_no_link_relax },
762 { "target-hardware", required_argument, NULL, option_target_hardware },
764 { NULL, no_argument, NULL, 0 }
767 size_t md_longopts_size = sizeof md_longopts;
771 md_parse_option (int c, char *arg)
773 switch (c)
775 case option_density:
776 as_warn (_("--density option is ignored"));
777 return 1;
778 case option_no_density:
779 as_warn (_("--no-density option is ignored"));
780 return 1;
781 case option_link_relax:
782 linkrelax = 1;
783 return 1;
784 case option_no_link_relax:
785 linkrelax = 0;
786 return 1;
787 case option_flix:
788 produce_flix = FLIX_ALL;
789 return 1;
790 case option_no_generate_flix:
791 produce_flix = FLIX_NO_GENERATE;
792 return 1;
793 case option_no_flix:
794 produce_flix = FLIX_NONE;
795 return 1;
796 case option_generics:
797 as_warn (_("--generics is deprecated; use --transform instead"));
798 return md_parse_option (option_transform, arg);
799 case option_no_generics:
800 as_warn (_("--no-generics is deprecated; use --no-transform instead"));
801 return md_parse_option (option_no_transform, arg);
802 case option_relax:
803 as_warn (_("--relax is deprecated; use --transform instead"));
804 return md_parse_option (option_transform, arg);
805 case option_no_relax:
806 as_warn (_("--no-relax is deprecated; use --no-transform instead"));
807 return md_parse_option (option_no_transform, arg);
808 case option_longcalls:
809 directive_state[directive_longcalls] = TRUE;
810 return 1;
811 case option_no_longcalls:
812 directive_state[directive_longcalls] = FALSE;
813 return 1;
814 case option_text_section_literals:
815 use_literal_section = FALSE;
816 return 1;
817 case option_no_text_section_literals:
818 use_literal_section = TRUE;
819 return 1;
820 case option_absolute_literals:
821 if (!absolute_literals_supported)
823 as_fatal (_("--absolute-literals option not supported in this Xtensa configuration"));
824 return 0;
826 directive_state[directive_absolute_literals] = TRUE;
827 return 1;
828 case option_no_absolute_literals:
829 directive_state[directive_absolute_literals] = FALSE;
830 return 1;
832 case option_workaround_a0_b_retw:
833 workaround_a0_b_retw = TRUE;
834 return 1;
835 case option_no_workaround_a0_b_retw:
836 workaround_a0_b_retw = FALSE;
837 return 1;
838 case option_workaround_b_j_loop_end:
839 workaround_b_j_loop_end = TRUE;
840 return 1;
841 case option_no_workaround_b_j_loop_end:
842 workaround_b_j_loop_end = FALSE;
843 return 1;
845 case option_workaround_short_loop:
846 workaround_short_loop = TRUE;
847 return 1;
848 case option_no_workaround_short_loop:
849 workaround_short_loop = FALSE;
850 return 1;
852 case option_workaround_all_short_loops:
853 workaround_all_short_loops = TRUE;
854 return 1;
855 case option_no_workaround_all_short_loops:
856 workaround_all_short_loops = FALSE;
857 return 1;
859 case option_workaround_close_loop_end:
860 workaround_close_loop_end = TRUE;
861 return 1;
862 case option_no_workaround_close_loop_end:
863 workaround_close_loop_end = FALSE;
864 return 1;
866 case option_no_workarounds:
867 workaround_a0_b_retw = FALSE;
868 workaround_b_j_loop_end = FALSE;
869 workaround_short_loop = FALSE;
870 workaround_all_short_loops = FALSE;
871 workaround_close_loop_end = FALSE;
872 return 1;
874 case option_align_targets:
875 align_targets = TRUE;
876 return 1;
877 case option_no_align_targets:
878 align_targets = FALSE;
879 return 1;
881 case option_warn_unaligned_targets:
882 warn_unaligned_branch_targets = TRUE;
883 return 1;
885 case option_rename_section_name:
886 build_section_rename (arg);
887 return 1;
889 case 'Q':
890 /* -Qy, -Qn: SVR4 arguments controlling whether a .comment section
891 should be emitted or not. FIXME: Not implemented. */
892 return 1;
894 case option_prefer_l32r:
895 if (prefer_const16)
896 as_fatal (_("prefer-l32r conflicts with prefer-const16"));
897 prefer_l32r = 1;
898 return 1;
900 case option_prefer_const16:
901 if (prefer_l32r)
902 as_fatal (_("prefer-const16 conflicts with prefer-l32r"));
903 prefer_const16 = 1;
904 return 1;
906 case option_target_hardware:
908 int earliest, latest = 0;
909 if (*arg == 0 || *arg == '-')
910 as_fatal (_("invalid target hardware version"));
912 earliest = strtol (arg, &arg, 0);
914 if (*arg == 0)
915 latest = earliest;
916 else if (*arg == '-')
918 if (*++arg == 0)
919 as_fatal (_("invalid target hardware version"));
920 latest = strtol (arg, &arg, 0);
922 if (*arg != 0)
923 as_fatal (_("invalid target hardware version"));
925 xtensa_setup_hw_workarounds (earliest, latest);
926 return 1;
929 case option_transform:
930 /* This option has no affect other than to use the defaults,
931 which are already set. */
932 return 1;
934 case option_no_transform:
935 /* This option turns off all transformations of any kind.
936 However, because we want to preserve the state of other
937 directives, we only change its own field. Thus, before
938 you perform any transformation, always check if transform
939 is available. If you use the functions we provide for this
940 purpose, you will be ok. */
941 directive_state[directive_transform] = FALSE;
942 return 1;
944 default:
945 return 0;
950 void
951 md_show_usage (FILE *stream)
953 fputs ("\n\
954 Xtensa options:\n\
955 --[no-]text-section-literals\n\
956 [Do not] put literals in the text section\n\
957 --[no-]absolute-literals\n\
958 [Do not] default to use non-PC-relative literals\n\
959 --[no-]target-align [Do not] try to align branch targets\n\
960 --[no-]longcalls [Do not] emit 32-bit call sequences\n\
961 --[no-]transform [Do not] transform instructions\n\
962 --flix both allow hand-written and generate flix bundles\n\
963 --no-generate-flix allow hand-written but do not generate\n\
964 flix bundles\n\
965 --no-allow-flix neither allow hand-written nor generate\n\
966 flix bundles\n\
967 --rename-section old=new Rename section 'old' to 'new'\n", stream);
971 /* Functions related to the list of current label symbols. */
973 static void
974 xtensa_add_insn_label (symbolS *sym)
976 sym_list *l;
978 if (!free_insn_labels)
979 l = (sym_list *) xmalloc (sizeof (sym_list));
980 else
982 l = free_insn_labels;
983 free_insn_labels = l->next;
986 l->sym = sym;
987 l->next = insn_labels;
988 insn_labels = l;
992 static void
993 xtensa_clear_insn_labels (void)
995 sym_list **pl;
997 for (pl = &free_insn_labels; *pl != NULL; pl = &(*pl)->next)
999 *pl = insn_labels;
1000 insn_labels = NULL;
1004 static void
1005 xtensa_move_labels (fragS *new_frag, valueT new_offset)
1007 sym_list *lit;
1009 for (lit = insn_labels; lit; lit = lit->next)
1011 symbolS *lit_sym = lit->sym;
1012 S_SET_VALUE (lit_sym, new_offset);
1013 symbol_set_frag (lit_sym, new_frag);
1018 /* Directive data and functions. */
1020 typedef struct state_stackS_struct
1022 directiveE directive;
1023 bfd_boolean negated;
1024 bfd_boolean old_state;
1025 const char *file;
1026 unsigned int line;
1027 const void *datum;
1028 struct state_stackS_struct *prev;
1029 } state_stackS;
1031 state_stackS *directive_state_stack;
1033 const pseudo_typeS md_pseudo_table[] =
1035 { "align", s_align_bytes, 0 }, /* Defaulting is invalid (0). */
1036 { "literal_position", xtensa_literal_position, 0 },
1037 { "frame", s_ignore, 0 }, /* Formerly used for STABS debugging. */
1038 { "long", xtensa_elf_cons, 4 },
1039 { "word", xtensa_elf_cons, 4 },
1040 { "4byte", xtensa_elf_cons, 4 },
1041 { "short", xtensa_elf_cons, 2 },
1042 { "2byte", xtensa_elf_cons, 2 },
1043 { "sleb128", xtensa_leb128, 1},
1044 { "uleb128", xtensa_leb128, 0},
1045 { "begin", xtensa_begin_directive, 0 },
1046 { "end", xtensa_end_directive, 0 },
1047 { "literal", xtensa_literal_pseudo, 0 },
1048 { "frequency", xtensa_frequency_pseudo, 0 },
1049 { NULL, 0, 0 },
1053 static bfd_boolean
1054 use_transform (void)
1056 /* After md_end, you should be checking frag by frag, rather
1057 than state directives. */
1058 gas_assert (!past_xtensa_end);
1059 return directive_state[directive_transform];
1063 static bfd_boolean
1064 do_align_targets (void)
1066 /* Do not use this function after md_end; just look at align_targets
1067 instead. There is no target-align directive, so alignment is either
1068 enabled for all frags or not done at all. */
1069 gas_assert (!past_xtensa_end);
1070 return align_targets && use_transform ();
1074 static void
1075 directive_push (directiveE directive, bfd_boolean negated, const void *datum)
1077 char *file;
1078 unsigned int line;
1079 state_stackS *stack = (state_stackS *) xmalloc (sizeof (state_stackS));
1081 as_where (&file, &line);
1083 stack->directive = directive;
1084 stack->negated = negated;
1085 stack->old_state = directive_state[directive];
1086 stack->file = file;
1087 stack->line = line;
1088 stack->datum = datum;
1089 stack->prev = directive_state_stack;
1090 directive_state_stack = stack;
1092 directive_state[directive] = !negated;
1096 static void
1097 directive_pop (directiveE *directive,
1098 bfd_boolean *negated,
1099 const char **file,
1100 unsigned int *line,
1101 const void **datum)
1103 state_stackS *top = directive_state_stack;
1105 if (!directive_state_stack)
1107 as_bad (_("unmatched end directive"));
1108 *directive = directive_none;
1109 return;
1112 directive_state[directive_state_stack->directive] = top->old_state;
1113 *directive = top->directive;
1114 *negated = top->negated;
1115 *file = top->file;
1116 *line = top->line;
1117 *datum = top->datum;
1118 directive_state_stack = top->prev;
1119 free (top);
1123 static void
1124 directive_balance (void)
1126 while (directive_state_stack)
1128 directiveE directive;
1129 bfd_boolean negated;
1130 const char *file;
1131 unsigned int line;
1132 const void *datum;
1134 directive_pop (&directive, &negated, &file, &line, &datum);
1135 as_warn_where ((char *) file, line,
1136 _(".begin directive with no matching .end directive"));
1141 static bfd_boolean
1142 inside_directive (directiveE dir)
1144 state_stackS *top = directive_state_stack;
1146 while (top && top->directive != dir)
1147 top = top->prev;
1149 return (top != NULL);
1153 static void
1154 get_directive (directiveE *directive, bfd_boolean *negated)
1156 int len;
1157 unsigned i;
1158 char *directive_string;
1160 if (strncmp (input_line_pointer, "no-", 3) != 0)
1161 *negated = FALSE;
1162 else
1164 *negated = TRUE;
1165 input_line_pointer += 3;
1168 len = strspn (input_line_pointer,
1169 "abcdefghijklmnopqrstuvwxyz_-/0123456789.");
1171 /* This code is a hack to make .begin [no-][generics|relax] exactly
1172 equivalent to .begin [no-]transform. We should remove it when
1173 we stop accepting those options. */
1175 if (strncmp (input_line_pointer, "generics", strlen ("generics")) == 0)
1177 as_warn (_("[no-]generics is deprecated; use [no-]transform instead"));
1178 directive_string = "transform";
1180 else if (strncmp (input_line_pointer, "relax", strlen ("relax")) == 0)
1182 as_warn (_("[no-]relax is deprecated; use [no-]transform instead"));
1183 directive_string = "transform";
1185 else
1186 directive_string = input_line_pointer;
1188 for (i = 0; i < sizeof (directive_info) / sizeof (*directive_info); ++i)
1190 if (strncmp (directive_string, directive_info[i].name, len) == 0)
1192 input_line_pointer += len;
1193 *directive = (directiveE) i;
1194 if (*negated && !directive_info[i].can_be_negated)
1195 as_bad (_("directive %s cannot be negated"),
1196 directive_info[i].name);
1197 return;
1201 as_bad (_("unknown directive"));
1202 *directive = (directiveE) XTENSA_UNDEFINED;
1206 static void
1207 xtensa_begin_directive (int ignore ATTRIBUTE_UNUSED)
1209 directiveE directive;
1210 bfd_boolean negated;
1211 emit_state *state;
1212 lit_state *ls;
1214 get_directive (&directive, &negated);
1215 if (directive == (directiveE) XTENSA_UNDEFINED)
1217 discard_rest_of_line ();
1218 return;
1221 if (cur_vinsn.inside_bundle)
1222 as_bad (_("directives are not valid inside bundles"));
1224 switch (directive)
1226 case directive_literal:
1227 if (!inside_directive (directive_literal))
1229 /* Previous labels go with whatever follows this directive, not with
1230 the literal, so save them now. */
1231 saved_insn_labels = insn_labels;
1232 insn_labels = NULL;
1234 as_warn (_(".begin literal is deprecated; use .literal instead"));
1235 state = (emit_state *) xmalloc (sizeof (emit_state));
1236 xtensa_switch_to_literal_fragment (state);
1237 directive_push (directive_literal, negated, state);
1238 break;
1240 case directive_literal_prefix:
1241 /* Have to flush pending output because a movi relaxed to an l32r
1242 might produce a literal. */
1243 md_flush_pending_output ();
1244 /* Check to see if the current fragment is a literal
1245 fragment. If it is, then this operation is not allowed. */
1246 if (generating_literals)
1248 as_bad (_("cannot set literal_prefix inside literal fragment"));
1249 return;
1252 /* Allocate the literal state for this section and push
1253 onto the directive stack. */
1254 ls = xmalloc (sizeof (lit_state));
1255 gas_assert (ls);
1257 *ls = default_lit_sections;
1258 directive_push (directive_literal_prefix, negated, ls);
1260 /* Process the new prefix. */
1261 xtensa_literal_prefix ();
1262 break;
1264 case directive_freeregs:
1265 /* This information is currently unused, but we'll accept the statement
1266 and just discard the rest of the line. This won't check the syntax,
1267 but it will accept every correct freeregs directive. */
1268 input_line_pointer += strcspn (input_line_pointer, "\n");
1269 directive_push (directive_freeregs, negated, 0);
1270 break;
1272 case directive_schedule:
1273 md_flush_pending_output ();
1274 frag_var (rs_fill, 0, 0, frag_now->fr_subtype,
1275 frag_now->fr_symbol, frag_now->fr_offset, NULL);
1276 directive_push (directive_schedule, negated, 0);
1277 xtensa_set_frag_assembly_state (frag_now);
1278 break;
1280 case directive_density:
1281 as_warn (_(".begin [no-]density is ignored"));
1282 break;
1284 case directive_absolute_literals:
1285 md_flush_pending_output ();
1286 if (!absolute_literals_supported && !negated)
1288 as_warn (_("Xtensa absolute literals option not supported; ignored"));
1289 break;
1291 xtensa_set_frag_assembly_state (frag_now);
1292 directive_push (directive, negated, 0);
1293 break;
1295 default:
1296 md_flush_pending_output ();
1297 xtensa_set_frag_assembly_state (frag_now);
1298 directive_push (directive, negated, 0);
1299 break;
1302 demand_empty_rest_of_line ();
1306 static void
1307 xtensa_end_directive (int ignore ATTRIBUTE_UNUSED)
1309 directiveE begin_directive, end_directive;
1310 bfd_boolean begin_negated, end_negated;
1311 const char *file;
1312 unsigned int line;
1313 emit_state *state;
1314 emit_state **state_ptr;
1315 lit_state *s;
1317 if (cur_vinsn.inside_bundle)
1318 as_bad (_("directives are not valid inside bundles"));
1320 get_directive (&end_directive, &end_negated);
1322 md_flush_pending_output ();
1324 switch (end_directive)
1326 case (directiveE) XTENSA_UNDEFINED:
1327 discard_rest_of_line ();
1328 return;
1330 case directive_density:
1331 as_warn (_(".end [no-]density is ignored"));
1332 demand_empty_rest_of_line ();
1333 break;
1335 case directive_absolute_literals:
1336 if (!absolute_literals_supported && !end_negated)
1338 as_warn (_("Xtensa absolute literals option not supported; ignored"));
1339 demand_empty_rest_of_line ();
1340 return;
1342 break;
1344 default:
1345 break;
1348 state_ptr = &state; /* use state_ptr to avoid type-punning warning */
1349 directive_pop (&begin_directive, &begin_negated, &file, &line,
1350 (const void **) state_ptr);
1352 if (begin_directive != directive_none)
1354 if (begin_directive != end_directive || begin_negated != end_negated)
1356 as_bad (_("does not match begin %s%s at %s:%d"),
1357 begin_negated ? "no-" : "",
1358 directive_info[begin_directive].name, file, line);
1360 else
1362 switch (end_directive)
1364 case directive_literal:
1365 frag_var (rs_fill, 0, 0, 0, NULL, 0, NULL);
1366 xtensa_restore_emit_state (state);
1367 xtensa_set_frag_assembly_state (frag_now);
1368 free (state);
1369 if (!inside_directive (directive_literal))
1371 /* Restore the list of current labels. */
1372 xtensa_clear_insn_labels ();
1373 insn_labels = saved_insn_labels;
1375 break;
1377 case directive_literal_prefix:
1378 /* Restore the default collection sections from saved state. */
1379 s = (lit_state *) state;
1380 gas_assert (s);
1381 default_lit_sections = *s;
1383 /* Free the state storage. */
1384 free (s->lit_prefix);
1385 free (s);
1386 break;
1388 case directive_schedule:
1389 case directive_freeregs:
1390 break;
1392 default:
1393 xtensa_set_frag_assembly_state (frag_now);
1394 break;
1399 demand_empty_rest_of_line ();
1403 /* Place an aligned literal fragment at the current location. */
1405 static void
1406 xtensa_literal_position (int ignore ATTRIBUTE_UNUSED)
1408 md_flush_pending_output ();
1410 if (inside_directive (directive_literal))
1411 as_warn (_(".literal_position inside literal directive; ignoring"));
1412 xtensa_mark_literal_pool_location ();
1414 demand_empty_rest_of_line ();
1415 xtensa_clear_insn_labels ();
1419 /* Support .literal label, expr, ... */
1421 static void
1422 xtensa_literal_pseudo (int ignored ATTRIBUTE_UNUSED)
1424 emit_state state;
1425 char *p, *base_name;
1426 char c;
1427 segT dest_seg;
1429 if (inside_directive (directive_literal))
1431 as_bad (_(".literal not allowed inside .begin literal region"));
1432 ignore_rest_of_line ();
1433 return;
1436 md_flush_pending_output ();
1438 /* Previous labels go with whatever follows this directive, not with
1439 the literal, so save them now. */
1440 saved_insn_labels = insn_labels;
1441 insn_labels = NULL;
1443 /* If we are using text-section literals, then this is the right value... */
1444 dest_seg = now_seg;
1446 base_name = input_line_pointer;
1448 xtensa_switch_to_literal_fragment (&state);
1450 /* ...but if we aren't using text-section-literals, then we
1451 need to put them in the section we just switched to. */
1452 if (use_literal_section || directive_state[directive_absolute_literals])
1453 dest_seg = now_seg;
1455 /* All literals are aligned to four-byte boundaries. */
1456 frag_align (2, 0, 0);
1457 record_alignment (now_seg, 2);
1459 c = get_symbol_end ();
1460 /* Just after name is now '\0'. */
1461 p = input_line_pointer;
1462 *p = c;
1463 SKIP_WHITESPACE ();
1465 if (*input_line_pointer != ',' && *input_line_pointer != ':')
1467 as_bad (_("expected comma or colon after symbol name; "
1468 "rest of line ignored"));
1469 ignore_rest_of_line ();
1470 xtensa_restore_emit_state (&state);
1471 return;
1473 *p = 0;
1475 colon (base_name);
1477 *p = c;
1478 input_line_pointer++; /* skip ',' or ':' */
1480 xtensa_elf_cons (4);
1482 xtensa_restore_emit_state (&state);
1484 /* Restore the list of current labels. */
1485 xtensa_clear_insn_labels ();
1486 insn_labels = saved_insn_labels;
1490 static void
1491 xtensa_literal_prefix (void)
1493 char *name;
1494 int len;
1496 /* Parse the new prefix from the input_line_pointer. */
1497 SKIP_WHITESPACE ();
1498 len = strspn (input_line_pointer,
1499 "ABCDEFGHIJKLMNOPQRSTUVWXYZ"
1500 "abcdefghijklmnopqrstuvwxyz_/0123456789.$");
1502 /* Get a null-terminated copy of the name. */
1503 name = xmalloc (len + 1);
1504 gas_assert (name);
1505 strncpy (name, input_line_pointer, len);
1506 name[len] = 0;
1508 /* Skip the name in the input line. */
1509 input_line_pointer += len;
1511 default_lit_sections.lit_prefix = name;
1513 /* Clear cached literal sections, since the prefix has changed. */
1514 default_lit_sections.lit_seg = NULL;
1515 default_lit_sections.lit4_seg = NULL;
1519 /* Support ".frequency branch_target_frequency fall_through_frequency". */
1521 static void
1522 xtensa_frequency_pseudo (int ignored ATTRIBUTE_UNUSED)
1524 float fall_through_f, target_f;
1526 fall_through_f = (float) strtod (input_line_pointer, &input_line_pointer);
1527 if (fall_through_f < 0)
1529 as_bad (_("fall through frequency must be greater than 0"));
1530 ignore_rest_of_line ();
1531 return;
1534 target_f = (float) strtod (input_line_pointer, &input_line_pointer);
1535 if (target_f < 0)
1537 as_bad (_("branch target frequency must be greater than 0"));
1538 ignore_rest_of_line ();
1539 return;
1542 set_subseg_freq (now_seg, now_subseg, target_f + fall_through_f, target_f);
1544 demand_empty_rest_of_line ();
1548 /* Like normal .long/.short/.word, except support @plt, etc.
1549 Clobbers input_line_pointer, checks end-of-line. */
1551 static void
1552 xtensa_elf_cons (int nbytes)
1554 expressionS exp;
1555 bfd_reloc_code_real_type reloc;
1557 md_flush_pending_output ();
1559 if (cur_vinsn.inside_bundle)
1560 as_bad (_("directives are not valid inside bundles"));
1562 if (is_it_end_of_statement ())
1564 demand_empty_rest_of_line ();
1565 return;
1570 expression (&exp);
1571 if (exp.X_op == O_symbol
1572 && *input_line_pointer == '@'
1573 && ((reloc = xtensa_elf_suffix (&input_line_pointer, &exp))
1574 != BFD_RELOC_NONE))
1576 reloc_howto_type *reloc_howto =
1577 bfd_reloc_type_lookup (stdoutput, reloc);
1579 if (reloc == BFD_RELOC_UNUSED || !reloc_howto)
1580 as_bad (_("unsupported relocation"));
1581 else if ((reloc >= BFD_RELOC_XTENSA_SLOT0_OP
1582 && reloc <= BFD_RELOC_XTENSA_SLOT14_OP)
1583 || (reloc >= BFD_RELOC_XTENSA_SLOT0_ALT
1584 && reloc <= BFD_RELOC_XTENSA_SLOT14_ALT))
1585 as_bad (_("opcode-specific %s relocation used outside "
1586 "an instruction"), reloc_howto->name);
1587 else if (nbytes != (int) bfd_get_reloc_size (reloc_howto))
1588 as_bad (_("%s relocations do not fit in %d bytes"),
1589 reloc_howto->name, nbytes);
1590 else if (reloc == BFD_RELOC_XTENSA_TLS_FUNC
1591 || reloc == BFD_RELOC_XTENSA_TLS_ARG
1592 || reloc == BFD_RELOC_XTENSA_TLS_CALL)
1593 as_bad (_("invalid use of %s relocation"), reloc_howto->name);
1594 else
1596 char *p = frag_more ((int) nbytes);
1597 xtensa_set_frag_assembly_state (frag_now);
1598 fix_new_exp (frag_now, p - frag_now->fr_literal,
1599 nbytes, &exp, reloc_howto->pc_relative, reloc);
1602 else
1604 xtensa_set_frag_assembly_state (frag_now);
1605 emit_expr (&exp, (unsigned int) nbytes);
1608 while (*input_line_pointer++ == ',');
1610 input_line_pointer--; /* Put terminator back into stream. */
1611 demand_empty_rest_of_line ();
1614 static bfd_boolean is_leb128_expr;
1616 static void
1617 xtensa_leb128 (int sign)
1619 is_leb128_expr = TRUE;
1620 s_leb128 (sign);
1621 is_leb128_expr = FALSE;
1625 /* Parsing and Idiom Translation. */
1627 /* Parse @plt, etc. and return the desired relocation. */
1628 static bfd_reloc_code_real_type
1629 xtensa_elf_suffix (char **str_p, expressionS *exp_p)
1631 char ident[20];
1632 char *str = *str_p;
1633 char *str2;
1634 int ch;
1635 int len;
1636 struct suffix_reloc_map *ptr;
1638 if (*str++ != '@')
1639 return BFD_RELOC_NONE;
1641 for (ch = *str, str2 = ident;
1642 (str2 < ident + sizeof (ident) - 1
1643 && (ISALNUM (ch) || ch == '@'));
1644 ch = *++str)
1646 *str2++ = (ISLOWER (ch)) ? ch : TOLOWER (ch);
1649 *str2 = '\0';
1650 len = str2 - ident;
1652 ch = ident[0];
1653 for (ptr = &suffix_relocs[0]; ptr->length > 0; ptr++)
1654 if (ch == ptr->suffix[0]
1655 && len == ptr->length
1656 && memcmp (ident, ptr->suffix, ptr->length) == 0)
1658 /* Now check for "identifier@suffix+constant". */
1659 if (*str == '-' || *str == '+')
1661 char *orig_line = input_line_pointer;
1662 expressionS new_exp;
1664 input_line_pointer = str;
1665 expression (&new_exp);
1666 if (new_exp.X_op == O_constant)
1668 exp_p->X_add_number += new_exp.X_add_number;
1669 str = input_line_pointer;
1672 if (&input_line_pointer != str_p)
1673 input_line_pointer = orig_line;
1676 *str_p = str;
1677 return ptr->reloc;
1680 return BFD_RELOC_UNUSED;
1684 /* Find the matching operator type. */
1685 static unsigned char
1686 map_suffix_reloc_to_operator (bfd_reloc_code_real_type reloc)
1688 struct suffix_reloc_map *sfx;
1689 unsigned char operator = (unsigned char) -1;
1691 for (sfx = &suffix_relocs[0]; sfx->suffix; sfx++)
1693 if (sfx->reloc == reloc)
1695 operator = sfx->operator;
1696 break;
1699 gas_assert (operator != (unsigned char) -1);
1700 return operator;
1704 /* Find the matching reloc type. */
1705 static bfd_reloc_code_real_type
1706 map_operator_to_reloc (unsigned char operator, bfd_boolean is_literal)
1708 struct suffix_reloc_map *sfx;
1709 bfd_reloc_code_real_type reloc = BFD_RELOC_UNUSED;
1711 for (sfx = &suffix_relocs[0]; sfx->suffix; sfx++)
1713 if (sfx->operator == operator)
1715 reloc = sfx->reloc;
1716 break;
1720 if (is_literal)
1722 if (reloc == BFD_RELOC_XTENSA_TLS_FUNC)
1723 return BFD_RELOC_XTENSA_TLSDESC_FN;
1724 else if (reloc == BFD_RELOC_XTENSA_TLS_ARG)
1725 return BFD_RELOC_XTENSA_TLSDESC_ARG;
1728 if (reloc == BFD_RELOC_UNUSED)
1729 return BFD_RELOC_32;
1731 return reloc;
1735 static const char *
1736 expression_end (const char *name)
1738 while (1)
1740 switch (*name)
1742 case '}':
1743 case ';':
1744 case '\0':
1745 case ',':
1746 case ':':
1747 return name;
1748 case ' ':
1749 case '\t':
1750 ++name;
1751 continue;
1752 default:
1753 return 0;
1759 #define ERROR_REG_NUM ((unsigned) -1)
1761 static unsigned
1762 tc_get_register (const char *prefix)
1764 unsigned reg;
1765 const char *next_expr;
1766 const char *old_line_pointer;
1768 SKIP_WHITESPACE ();
1769 old_line_pointer = input_line_pointer;
1771 if (*input_line_pointer == '$')
1772 ++input_line_pointer;
1774 /* Accept "sp" as a synonym for "a1". */
1775 if (input_line_pointer[0] == 's' && input_line_pointer[1] == 'p'
1776 && expression_end (input_line_pointer + 2))
1778 input_line_pointer += 2;
1779 return 1; /* AR[1] */
1782 while (*input_line_pointer++ == *prefix++)
1784 --input_line_pointer;
1785 --prefix;
1787 if (*prefix)
1789 as_bad (_("bad register name: %s"), old_line_pointer);
1790 return ERROR_REG_NUM;
1793 if (!ISDIGIT ((unsigned char) *input_line_pointer))
1795 as_bad (_("bad register number: %s"), input_line_pointer);
1796 return ERROR_REG_NUM;
1799 reg = 0;
1801 while (ISDIGIT ((int) *input_line_pointer))
1802 reg = reg * 10 + *input_line_pointer++ - '0';
1804 if (!(next_expr = expression_end (input_line_pointer)))
1806 as_bad (_("bad register name: %s"), old_line_pointer);
1807 return ERROR_REG_NUM;
1810 input_line_pointer = (char *) next_expr;
1812 return reg;
1816 static void
1817 expression_maybe_register (xtensa_opcode opc, int opnd, expressionS *tok)
1819 xtensa_isa isa = xtensa_default_isa;
1821 /* Check if this is an immediate operand. */
1822 if (xtensa_operand_is_register (isa, opc, opnd) == 0)
1824 bfd_reloc_code_real_type reloc;
1825 segT t = expression (tok);
1827 if (t == absolute_section
1828 && xtensa_operand_is_PCrelative (isa, opc, opnd) == 1)
1830 gas_assert (tok->X_op == O_constant);
1831 tok->X_op = O_symbol;
1832 tok->X_add_symbol = &abs_symbol;
1835 if ((tok->X_op == O_constant || tok->X_op == O_symbol)
1836 && ((reloc = xtensa_elf_suffix (&input_line_pointer, tok))
1837 != BFD_RELOC_NONE))
1839 switch (reloc)
1841 case BFD_RELOC_LO16:
1842 if (tok->X_op == O_constant)
1844 tok->X_add_number &= 0xffff;
1845 return;
1847 break;
1848 case BFD_RELOC_HI16:
1849 if (tok->X_op == O_constant)
1851 tok->X_add_number = ((unsigned) tok->X_add_number) >> 16;
1852 return;
1854 break;
1855 case BFD_RELOC_UNUSED:
1856 as_bad (_("unsupported relocation"));
1857 return;
1858 case BFD_RELOC_32_PCREL:
1859 as_bad (_("pcrel relocation not allowed in an instruction"));
1860 return;
1861 default:
1862 break;
1864 tok->X_op = map_suffix_reloc_to_operator (reloc);
1867 else
1869 xtensa_regfile opnd_rf = xtensa_operand_regfile (isa, opc, opnd);
1870 unsigned reg = tc_get_register (xtensa_regfile_shortname (isa, opnd_rf));
1872 if (reg != ERROR_REG_NUM) /* Already errored */
1874 uint32 buf = reg;
1875 if (xtensa_operand_encode (isa, opc, opnd, &buf))
1876 as_bad (_("register number out of range"));
1879 tok->X_op = O_register;
1880 tok->X_add_symbol = 0;
1881 tok->X_add_number = reg;
1886 /* Split up the arguments for an opcode or pseudo-op. */
1888 static int
1889 tokenize_arguments (char **args, char *str)
1891 char *old_input_line_pointer;
1892 bfd_boolean saw_comma = FALSE;
1893 bfd_boolean saw_arg = FALSE;
1894 bfd_boolean saw_colon = FALSE;
1895 int num_args = 0;
1896 char *arg_end, *arg;
1897 int arg_len;
1899 /* Save and restore input_line_pointer around this function. */
1900 old_input_line_pointer = input_line_pointer;
1901 input_line_pointer = str;
1903 while (*input_line_pointer)
1905 SKIP_WHITESPACE ();
1906 switch (*input_line_pointer)
1908 case '\0':
1909 case '}':
1910 goto fini;
1912 case ':':
1913 input_line_pointer++;
1914 if (saw_comma || saw_colon || !saw_arg)
1915 goto err;
1916 saw_colon = TRUE;
1917 break;
1919 case ',':
1920 input_line_pointer++;
1921 if (saw_comma || saw_colon || !saw_arg)
1922 goto err;
1923 saw_comma = TRUE;
1924 break;
1926 default:
1927 if (!saw_comma && !saw_colon && saw_arg)
1928 goto err;
1930 arg_end = input_line_pointer + 1;
1931 while (!expression_end (arg_end))
1932 arg_end += 1;
1934 arg_len = arg_end - input_line_pointer;
1935 arg = (char *) xmalloc ((saw_colon ? 1 : 0) + arg_len + 1);
1936 args[num_args] = arg;
1938 if (saw_colon)
1939 *arg++ = ':';
1940 strncpy (arg, input_line_pointer, arg_len);
1941 arg[arg_len] = '\0';
1943 input_line_pointer = arg_end;
1944 num_args += 1;
1945 saw_comma = FALSE;
1946 saw_colon = FALSE;
1947 saw_arg = TRUE;
1948 break;
1952 fini:
1953 if (saw_comma || saw_colon)
1954 goto err;
1955 input_line_pointer = old_input_line_pointer;
1956 return num_args;
1958 err:
1959 if (saw_comma)
1960 as_bad (_("extra comma"));
1961 else if (saw_colon)
1962 as_bad (_("extra colon"));
1963 else if (!saw_arg)
1964 as_bad (_("missing argument"));
1965 else
1966 as_bad (_("missing comma or colon"));
1967 input_line_pointer = old_input_line_pointer;
1968 return -1;
1972 /* Parse the arguments to an opcode. Return TRUE on error. */
1974 static bfd_boolean
1975 parse_arguments (TInsn *insn, int num_args, char **arg_strings)
1977 expressionS *tok, *last_tok;
1978 xtensa_opcode opcode = insn->opcode;
1979 bfd_boolean had_error = TRUE;
1980 xtensa_isa isa = xtensa_default_isa;
1981 int n, num_regs = 0;
1982 int opcode_operand_count;
1983 int opnd_cnt, last_opnd_cnt;
1984 unsigned int next_reg = 0;
1985 char *old_input_line_pointer;
1987 if (insn->insn_type == ITYPE_LITERAL)
1988 opcode_operand_count = 1;
1989 else
1990 opcode_operand_count = xtensa_opcode_num_operands (isa, opcode);
1992 tok = insn->tok;
1993 memset (tok, 0, sizeof (*tok) * MAX_INSN_ARGS);
1995 /* Save and restore input_line_pointer around this function. */
1996 old_input_line_pointer = input_line_pointer;
1998 last_tok = 0;
1999 last_opnd_cnt = -1;
2000 opnd_cnt = 0;
2002 /* Skip invisible operands. */
2003 while (xtensa_operand_is_visible (isa, opcode, opnd_cnt) == 0)
2005 opnd_cnt += 1;
2006 tok++;
2009 for (n = 0; n < num_args; n++)
2011 input_line_pointer = arg_strings[n];
2012 if (*input_line_pointer == ':')
2014 xtensa_regfile opnd_rf;
2015 input_line_pointer++;
2016 if (num_regs == 0)
2017 goto err;
2018 gas_assert (opnd_cnt > 0);
2019 num_regs--;
2020 opnd_rf = xtensa_operand_regfile (isa, opcode, last_opnd_cnt);
2021 if (next_reg
2022 != tc_get_register (xtensa_regfile_shortname (isa, opnd_rf)))
2023 as_warn (_("incorrect register number, ignoring"));
2024 next_reg++;
2026 else
2028 if (opnd_cnt >= opcode_operand_count)
2030 as_warn (_("too many arguments"));
2031 goto err;
2033 gas_assert (opnd_cnt < MAX_INSN_ARGS);
2035 expression_maybe_register (opcode, opnd_cnt, tok);
2036 next_reg = tok->X_add_number + 1;
2038 if (tok->X_op == O_illegal || tok->X_op == O_absent)
2039 goto err;
2040 if (xtensa_operand_is_register (isa, opcode, opnd_cnt) == 1)
2042 num_regs = xtensa_operand_num_regs (isa, opcode, opnd_cnt) - 1;
2043 /* minus 1 because we are seeing one right now */
2045 else
2046 num_regs = 0;
2048 last_tok = tok;
2049 last_opnd_cnt = opnd_cnt;
2050 demand_empty_rest_of_line ();
2054 opnd_cnt += 1;
2055 tok++;
2057 while (xtensa_operand_is_visible (isa, opcode, opnd_cnt) == 0);
2061 if (num_regs > 0 && ((int) next_reg != last_tok->X_add_number + 1))
2062 goto err;
2064 insn->ntok = tok - insn->tok;
2065 had_error = FALSE;
2067 err:
2068 input_line_pointer = old_input_line_pointer;
2069 return had_error;
2073 static int
2074 get_invisible_operands (TInsn *insn)
2076 xtensa_isa isa = xtensa_default_isa;
2077 static xtensa_insnbuf slotbuf = NULL;
2078 xtensa_format fmt;
2079 xtensa_opcode opc = insn->opcode;
2080 int slot, opnd, fmt_found;
2081 unsigned val;
2083 if (!slotbuf)
2084 slotbuf = xtensa_insnbuf_alloc (isa);
2086 /* Find format/slot where this can be encoded. */
2087 fmt_found = 0;
2088 slot = 0;
2089 for (fmt = 0; fmt < xtensa_isa_num_formats (isa); fmt++)
2091 for (slot = 0; slot < xtensa_format_num_slots (isa, fmt); slot++)
2093 if (xtensa_opcode_encode (isa, fmt, slot, slotbuf, opc) == 0)
2095 fmt_found = 1;
2096 break;
2099 if (fmt_found) break;
2102 if (!fmt_found)
2104 as_bad (_("cannot encode opcode \"%s\""), xtensa_opcode_name (isa, opc));
2105 return -1;
2108 /* First encode all the visible operands
2109 (to deal with shared field operands). */
2110 for (opnd = 0; opnd < insn->ntok; opnd++)
2112 if (xtensa_operand_is_visible (isa, opc, opnd) == 1
2113 && (insn->tok[opnd].X_op == O_register
2114 || insn->tok[opnd].X_op == O_constant))
2116 val = insn->tok[opnd].X_add_number;
2117 xtensa_operand_encode (isa, opc, opnd, &val);
2118 xtensa_operand_set_field (isa, opc, opnd, fmt, slot, slotbuf, val);
2122 /* Then pull out the values for the invisible ones. */
2123 for (opnd = 0; opnd < insn->ntok; opnd++)
2125 if (xtensa_operand_is_visible (isa, opc, opnd) == 0)
2127 xtensa_operand_get_field (isa, opc, opnd, fmt, slot, slotbuf, &val);
2128 xtensa_operand_decode (isa, opc, opnd, &val);
2129 insn->tok[opnd].X_add_number = val;
2130 if (xtensa_operand_is_register (isa, opc, opnd) == 1)
2131 insn->tok[opnd].X_op = O_register;
2132 else
2133 insn->tok[opnd].X_op = O_constant;
2137 return 0;
2141 static void
2142 xg_reverse_shift_count (char **cnt_argp)
2144 char *cnt_arg, *new_arg;
2145 cnt_arg = *cnt_argp;
2147 /* replace the argument with "31-(argument)" */
2148 new_arg = (char *) xmalloc (strlen (cnt_arg) + 6);
2149 sprintf (new_arg, "31-(%s)", cnt_arg);
2151 free (cnt_arg);
2152 *cnt_argp = new_arg;
2156 /* If "arg" is a constant expression, return non-zero with the value
2157 in *valp. */
2159 static int
2160 xg_arg_is_constant (char *arg, offsetT *valp)
2162 expressionS exp;
2163 char *save_ptr = input_line_pointer;
2165 input_line_pointer = arg;
2166 expression (&exp);
2167 input_line_pointer = save_ptr;
2169 if (exp.X_op == O_constant)
2171 *valp = exp.X_add_number;
2172 return 1;
2175 return 0;
2179 static void
2180 xg_replace_opname (char **popname, char *newop)
2182 free (*popname);
2183 *popname = (char *) xmalloc (strlen (newop) + 1);
2184 strcpy (*popname, newop);
2188 static int
2189 xg_check_num_args (int *pnum_args,
2190 int expected_num,
2191 char *opname,
2192 char **arg_strings)
2194 int num_args = *pnum_args;
2196 if (num_args < expected_num)
2198 as_bad (_("not enough operands (%d) for '%s'; expected %d"),
2199 num_args, opname, expected_num);
2200 return -1;
2203 if (num_args > expected_num)
2205 as_warn (_("too many operands (%d) for '%s'; expected %d"),
2206 num_args, opname, expected_num);
2207 while (num_args-- > expected_num)
2209 free (arg_strings[num_args]);
2210 arg_strings[num_args] = 0;
2212 *pnum_args = expected_num;
2213 return -1;
2216 return 0;
2220 /* If the register is not specified as part of the opcode,
2221 then get it from the operand and move it to the opcode. */
2223 static int
2224 xg_translate_sysreg_op (char **popname, int *pnum_args, char **arg_strings)
2226 xtensa_isa isa = xtensa_default_isa;
2227 xtensa_sysreg sr;
2228 char *opname, *new_opname;
2229 const char *sr_name;
2230 int is_user, is_write;
2232 opname = *popname;
2233 if (*opname == '_')
2234 opname += 1;
2235 is_user = (opname[1] == 'u');
2236 is_write = (opname[0] == 'w');
2238 /* Opname == [rw]ur or [rwx]sr... */
2240 if (xg_check_num_args (pnum_args, 2, opname, arg_strings))
2241 return -1;
2243 /* Check if the argument is a symbolic register name. */
2244 sr = xtensa_sysreg_lookup_name (isa, arg_strings[1]);
2245 /* Handle WSR to "INTSET" as a special case. */
2246 if (sr == XTENSA_UNDEFINED && is_write && !is_user
2247 && !strcasecmp (arg_strings[1], "intset"))
2248 sr = xtensa_sysreg_lookup_name (isa, "interrupt");
2249 if (sr == XTENSA_UNDEFINED
2250 || (xtensa_sysreg_is_user (isa, sr) == 1) != is_user)
2252 /* Maybe it's a register number.... */
2253 offsetT val;
2254 if (!xg_arg_is_constant (arg_strings[1], &val))
2256 as_bad (_("invalid register '%s' for '%s' instruction"),
2257 arg_strings[1], opname);
2258 return -1;
2260 sr = xtensa_sysreg_lookup (isa, val, is_user);
2261 if (sr == XTENSA_UNDEFINED)
2263 as_bad (_("invalid register number (%ld) for '%s' instruction"),
2264 (long) val, opname);
2265 return -1;
2269 /* Remove the last argument, which is now part of the opcode. */
2270 free (arg_strings[1]);
2271 arg_strings[1] = 0;
2272 *pnum_args = 1;
2274 /* Translate the opcode. */
2275 sr_name = xtensa_sysreg_name (isa, sr);
2276 /* Another special case for "WSR.INTSET".... */
2277 if (is_write && !is_user && !strcasecmp ("interrupt", sr_name))
2278 sr_name = "intset";
2279 new_opname = (char *) xmalloc (strlen (sr_name) + 6);
2280 sprintf (new_opname, "%s.%s", *popname, sr_name);
2281 free (*popname);
2282 *popname = new_opname;
2284 return 0;
2288 static int
2289 xtensa_translate_old_userreg_ops (char **popname)
2291 xtensa_isa isa = xtensa_default_isa;
2292 xtensa_sysreg sr;
2293 char *opname, *new_opname;
2294 const char *sr_name;
2295 bfd_boolean has_underbar = FALSE;
2297 opname = *popname;
2298 if (opname[0] == '_')
2300 has_underbar = TRUE;
2301 opname += 1;
2304 sr = xtensa_sysreg_lookup_name (isa, opname + 1);
2305 if (sr != XTENSA_UNDEFINED)
2307 /* The new default name ("nnn") is different from the old default
2308 name ("URnnn"). The old default is handled below, and we don't
2309 want to recognize [RW]nnn, so do nothing if the name is the (new)
2310 default. */
2311 static char namebuf[10];
2312 sprintf (namebuf, "%d", xtensa_sysreg_number (isa, sr));
2313 if (strcmp (namebuf, opname + 1) == 0)
2314 return 0;
2316 else
2318 offsetT val;
2319 char *end;
2321 /* Only continue if the reg name is "URnnn". */
2322 if (opname[1] != 'u' || opname[2] != 'r')
2323 return 0;
2324 val = strtoul (opname + 3, &end, 10);
2325 if (*end != '\0')
2326 return 0;
2328 sr = xtensa_sysreg_lookup (isa, val, 1);
2329 if (sr == XTENSA_UNDEFINED)
2331 as_bad (_("invalid register number (%ld) for '%s'"),
2332 (long) val, opname);
2333 return -1;
2337 /* Translate the opcode. */
2338 sr_name = xtensa_sysreg_name (isa, sr);
2339 new_opname = (char *) xmalloc (strlen (sr_name) + 6);
2340 sprintf (new_opname, "%s%cur.%s", (has_underbar ? "_" : ""),
2341 opname[0], sr_name);
2342 free (*popname);
2343 *popname = new_opname;
2345 return 0;
2349 static int
2350 xtensa_translate_zero_immed (char *old_op,
2351 char *new_op,
2352 char **popname,
2353 int *pnum_args,
2354 char **arg_strings)
2356 char *opname;
2357 offsetT val;
2359 opname = *popname;
2360 gas_assert (opname[0] != '_');
2362 if (strcmp (opname, old_op) != 0)
2363 return 0;
2365 if (xg_check_num_args (pnum_args, 3, opname, arg_strings))
2366 return -1;
2367 if (xg_arg_is_constant (arg_strings[1], &val) && val == 0)
2369 xg_replace_opname (popname, new_op);
2370 free (arg_strings[1]);
2371 arg_strings[1] = arg_strings[2];
2372 arg_strings[2] = 0;
2373 *pnum_args = 2;
2376 return 0;
2380 /* If the instruction is an idiom (i.e., a built-in macro), translate it.
2381 Returns non-zero if an error was found. */
2383 static int
2384 xg_translate_idioms (char **popname, int *pnum_args, char **arg_strings)
2386 char *opname = *popname;
2387 bfd_boolean has_underbar = FALSE;
2389 if (*opname == '_')
2391 has_underbar = TRUE;
2392 opname += 1;
2395 if (strcmp (opname, "mov") == 0)
2397 if (use_transform () && !has_underbar && density_supported)
2398 xg_replace_opname (popname, "mov.n");
2399 else
2401 if (xg_check_num_args (pnum_args, 2, opname, arg_strings))
2402 return -1;
2403 xg_replace_opname (popname, (has_underbar ? "_or" : "or"));
2404 arg_strings[2] = (char *) xmalloc (strlen (arg_strings[1]) + 1);
2405 strcpy (arg_strings[2], arg_strings[1]);
2406 *pnum_args = 3;
2408 return 0;
2411 if (strcmp (opname, "bbsi.l") == 0)
2413 if (xg_check_num_args (pnum_args, 3, opname, arg_strings))
2414 return -1;
2415 xg_replace_opname (popname, (has_underbar ? "_bbsi" : "bbsi"));
2416 if (target_big_endian)
2417 xg_reverse_shift_count (&arg_strings[1]);
2418 return 0;
2421 if (strcmp (opname, "bbci.l") == 0)
2423 if (xg_check_num_args (pnum_args, 3, opname, arg_strings))
2424 return -1;
2425 xg_replace_opname (popname, (has_underbar ? "_bbci" : "bbci"));
2426 if (target_big_endian)
2427 xg_reverse_shift_count (&arg_strings[1]);
2428 return 0;
2431 /* Don't do anything special with NOPs inside FLIX instructions. They
2432 are handled elsewhere. Real NOP instructions are always available
2433 in configurations with FLIX, so this should never be an issue but
2434 check for it anyway. */
2435 if (!cur_vinsn.inside_bundle && xtensa_nop_opcode == XTENSA_UNDEFINED
2436 && strcmp (opname, "nop") == 0)
2438 if (use_transform () && !has_underbar && density_supported)
2439 xg_replace_opname (popname, "nop.n");
2440 else
2442 if (xg_check_num_args (pnum_args, 0, opname, arg_strings))
2443 return -1;
2444 xg_replace_opname (popname, (has_underbar ? "_or" : "or"));
2445 arg_strings[0] = (char *) xmalloc (3);
2446 arg_strings[1] = (char *) xmalloc (3);
2447 arg_strings[2] = (char *) xmalloc (3);
2448 strcpy (arg_strings[0], "a1");
2449 strcpy (arg_strings[1], "a1");
2450 strcpy (arg_strings[2], "a1");
2451 *pnum_args = 3;
2453 return 0;
2456 /* Recognize [RW]UR and [RWX]SR. */
2457 if ((((opname[0] == 'r' || opname[0] == 'w')
2458 && (opname[1] == 'u' || opname[1] == 's'))
2459 || (opname[0] == 'x' && opname[1] == 's'))
2460 && opname[2] == 'r'
2461 && opname[3] == '\0')
2462 return xg_translate_sysreg_op (popname, pnum_args, arg_strings);
2464 /* Backward compatibility for RUR and WUR: Recognize [RW]UR<nnn> and
2465 [RW]<name> if <name> is the non-default name of a user register. */
2466 if ((opname[0] == 'r' || opname[0] == 'w')
2467 && xtensa_opcode_lookup (xtensa_default_isa, opname) == XTENSA_UNDEFINED)
2468 return xtensa_translate_old_userreg_ops (popname);
2470 /* Relax branches that don't allow comparisons against an immediate value
2471 of zero to the corresponding branches with implicit zero immediates. */
2472 if (!has_underbar && use_transform ())
2474 if (xtensa_translate_zero_immed ("bnei", "bnez", popname,
2475 pnum_args, arg_strings))
2476 return -1;
2478 if (xtensa_translate_zero_immed ("beqi", "beqz", popname,
2479 pnum_args, arg_strings))
2480 return -1;
2482 if (xtensa_translate_zero_immed ("bgei", "bgez", popname,
2483 pnum_args, arg_strings))
2484 return -1;
2486 if (xtensa_translate_zero_immed ("blti", "bltz", popname,
2487 pnum_args, arg_strings))
2488 return -1;
2491 return 0;
2495 /* Functions for dealing with the Xtensa ISA. */
2497 /* Currently the assembler only allows us to use a single target per
2498 fragment. Because of this, only one operand for a given
2499 instruction may be symbolic. If there is a PC-relative operand,
2500 the last one is chosen. Otherwise, the result is the number of the
2501 last immediate operand, and if there are none of those, we fail and
2502 return -1. */
2504 static int
2505 get_relaxable_immed (xtensa_opcode opcode)
2507 int last_immed = -1;
2508 int noperands, opi;
2510 if (opcode == XTENSA_UNDEFINED)
2511 return -1;
2513 noperands = xtensa_opcode_num_operands (xtensa_default_isa, opcode);
2514 for (opi = noperands - 1; opi >= 0; opi--)
2516 if (xtensa_operand_is_visible (xtensa_default_isa, opcode, opi) == 0)
2517 continue;
2518 if (xtensa_operand_is_PCrelative (xtensa_default_isa, opcode, opi) == 1)
2519 return opi;
2520 if (last_immed == -1
2521 && xtensa_operand_is_register (xtensa_default_isa, opcode, opi) == 0)
2522 last_immed = opi;
2524 return last_immed;
2528 static xtensa_opcode
2529 get_opcode_from_buf (const char *buf, int slot)
2531 static xtensa_insnbuf insnbuf = NULL;
2532 static xtensa_insnbuf slotbuf = NULL;
2533 xtensa_isa isa = xtensa_default_isa;
2534 xtensa_format fmt;
2536 if (!insnbuf)
2538 insnbuf = xtensa_insnbuf_alloc (isa);
2539 slotbuf = xtensa_insnbuf_alloc (isa);
2542 xtensa_insnbuf_from_chars (isa, insnbuf, (const unsigned char *) buf, 0);
2543 fmt = xtensa_format_decode (isa, insnbuf);
2544 if (fmt == XTENSA_UNDEFINED)
2545 return XTENSA_UNDEFINED;
2547 if (slot >= xtensa_format_num_slots (isa, fmt))
2548 return XTENSA_UNDEFINED;
2550 xtensa_format_get_slot (isa, fmt, slot, insnbuf, slotbuf);
2551 return xtensa_opcode_decode (isa, fmt, slot, slotbuf);
2555 #ifdef TENSILICA_DEBUG
2557 /* For debugging, print out the mapping of opcode numbers to opcodes. */
2559 static void
2560 xtensa_print_insn_table (void)
2562 int num_opcodes, num_operands;
2563 xtensa_opcode opcode;
2564 xtensa_isa isa = xtensa_default_isa;
2566 num_opcodes = xtensa_isa_num_opcodes (xtensa_default_isa);
2567 for (opcode = 0; opcode < num_opcodes; opcode++)
2569 int opn;
2570 fprintf (stderr, "%d: %s: ", opcode, xtensa_opcode_name (isa, opcode));
2571 num_operands = xtensa_opcode_num_operands (isa, opcode);
2572 for (opn = 0; opn < num_operands; opn++)
2574 if (xtensa_operand_is_visible (isa, opcode, opn) == 0)
2575 continue;
2576 if (xtensa_operand_is_register (isa, opcode, opn) == 1)
2578 xtensa_regfile opnd_rf =
2579 xtensa_operand_regfile (isa, opcode, opn);
2580 fprintf (stderr, "%s ", xtensa_regfile_shortname (isa, opnd_rf));
2582 else if (xtensa_operand_is_PCrelative (isa, opcode, opn) == 1)
2583 fputs ("[lLr] ", stderr);
2584 else
2585 fputs ("i ", stderr);
2587 fprintf (stderr, "\n");
2592 static void
2593 print_vliw_insn (xtensa_insnbuf vbuf)
2595 xtensa_isa isa = xtensa_default_isa;
2596 xtensa_format f = xtensa_format_decode (isa, vbuf);
2597 xtensa_insnbuf sbuf = xtensa_insnbuf_alloc (isa);
2598 int op;
2600 fprintf (stderr, "format = %d\n", f);
2602 for (op = 0; op < xtensa_format_num_slots (isa, f); op++)
2604 xtensa_opcode opcode;
2605 const char *opname;
2606 int operands;
2608 xtensa_format_get_slot (isa, f, op, vbuf, sbuf);
2609 opcode = xtensa_opcode_decode (isa, f, op, sbuf);
2610 opname = xtensa_opcode_name (isa, opcode);
2612 fprintf (stderr, "op in slot %i is %s;\n", op, opname);
2613 fprintf (stderr, " operands = ");
2614 for (operands = 0;
2615 operands < xtensa_opcode_num_operands (isa, opcode);
2616 operands++)
2618 unsigned int val;
2619 if (xtensa_operand_is_visible (isa, opcode, operands) == 0)
2620 continue;
2621 xtensa_operand_get_field (isa, opcode, operands, f, op, sbuf, &val);
2622 xtensa_operand_decode (isa, opcode, operands, &val);
2623 fprintf (stderr, "%d ", val);
2625 fprintf (stderr, "\n");
2627 xtensa_insnbuf_free (isa, sbuf);
2630 #endif /* TENSILICA_DEBUG */
2633 static bfd_boolean
2634 is_direct_call_opcode (xtensa_opcode opcode)
2636 xtensa_isa isa = xtensa_default_isa;
2637 int n, num_operands;
2639 if (xtensa_opcode_is_call (isa, opcode) != 1)
2640 return FALSE;
2642 num_operands = xtensa_opcode_num_operands (isa, opcode);
2643 for (n = 0; n < num_operands; n++)
2645 if (xtensa_operand_is_register (isa, opcode, n) == 0
2646 && xtensa_operand_is_PCrelative (isa, opcode, n) == 1)
2647 return TRUE;
2649 return FALSE;
2653 /* Convert from BFD relocation type code to slot and operand number.
2654 Returns non-zero on failure. */
2656 static int
2657 decode_reloc (bfd_reloc_code_real_type reloc, int *slot, bfd_boolean *is_alt)
2659 if (reloc >= BFD_RELOC_XTENSA_SLOT0_OP
2660 && reloc <= BFD_RELOC_XTENSA_SLOT14_OP)
2662 *slot = reloc - BFD_RELOC_XTENSA_SLOT0_OP;
2663 *is_alt = FALSE;
2665 else if (reloc >= BFD_RELOC_XTENSA_SLOT0_ALT
2666 && reloc <= BFD_RELOC_XTENSA_SLOT14_ALT)
2668 *slot = reloc - BFD_RELOC_XTENSA_SLOT0_ALT;
2669 *is_alt = TRUE;
2671 else
2672 return -1;
2674 return 0;
2678 /* Convert from slot number to BFD relocation type code for the
2679 standard PC-relative relocations. Return BFD_RELOC_NONE on
2680 failure. */
2682 static bfd_reloc_code_real_type
2683 encode_reloc (int slot)
2685 if (slot < 0 || slot > 14)
2686 return BFD_RELOC_NONE;
2688 return BFD_RELOC_XTENSA_SLOT0_OP + slot;
2692 /* Convert from slot numbers to BFD relocation type code for the
2693 "alternate" relocations. Return BFD_RELOC_NONE on failure. */
2695 static bfd_reloc_code_real_type
2696 encode_alt_reloc (int slot)
2698 if (slot < 0 || slot > 14)
2699 return BFD_RELOC_NONE;
2701 return BFD_RELOC_XTENSA_SLOT0_ALT + slot;
2705 static void
2706 xtensa_insnbuf_set_operand (xtensa_insnbuf slotbuf,
2707 xtensa_format fmt,
2708 int slot,
2709 xtensa_opcode opcode,
2710 int operand,
2711 uint32 value,
2712 const char *file,
2713 unsigned int line)
2715 uint32 valbuf = value;
2717 if (xtensa_operand_encode (xtensa_default_isa, opcode, operand, &valbuf))
2719 if (xtensa_operand_is_PCrelative (xtensa_default_isa, opcode, operand)
2720 == 1)
2721 as_bad_where ((char *) file, line,
2722 _("operand %d of '%s' has out of range value '%u'"),
2723 operand + 1,
2724 xtensa_opcode_name (xtensa_default_isa, opcode),
2725 value);
2726 else
2727 as_bad_where ((char *) file, line,
2728 _("operand %d of '%s' has invalid value '%u'"),
2729 operand + 1,
2730 xtensa_opcode_name (xtensa_default_isa, opcode),
2731 value);
2732 return;
2735 xtensa_operand_set_field (xtensa_default_isa, opcode, operand, fmt, slot,
2736 slotbuf, valbuf);
2740 static uint32
2741 xtensa_insnbuf_get_operand (xtensa_insnbuf slotbuf,
2742 xtensa_format fmt,
2743 int slot,
2744 xtensa_opcode opcode,
2745 int opnum)
2747 uint32 val = 0;
2748 (void) xtensa_operand_get_field (xtensa_default_isa, opcode, opnum,
2749 fmt, slot, slotbuf, &val);
2750 (void) xtensa_operand_decode (xtensa_default_isa, opcode, opnum, &val);
2751 return val;
2755 /* Checks for rules from xtensa-relax tables. */
2757 /* The routine xg_instruction_matches_option_term must return TRUE
2758 when a given option term is true. The meaning of all of the option
2759 terms is given interpretation by this function. */
2761 static bfd_boolean
2762 xg_instruction_matches_option_term (TInsn *insn, const ReqOrOption *option)
2764 if (strcmp (option->option_name, "realnop") == 0
2765 || strncmp (option->option_name, "IsaUse", 6) == 0)
2767 /* These conditions were evaluated statically when building the
2768 relaxation table. There's no need to reevaluate them now. */
2769 return TRUE;
2771 else if (strcmp (option->option_name, "FREEREG") == 0)
2772 return insn->extra_arg.X_op == O_register;
2773 else
2775 as_fatal (_("internal error: unknown option name '%s'"),
2776 option->option_name);
2781 static bfd_boolean
2782 xg_instruction_matches_or_options (TInsn *insn,
2783 const ReqOrOptionList *or_option)
2785 const ReqOrOption *option;
2786 /* Must match each of the AND terms. */
2787 for (option = or_option; option != NULL; option = option->next)
2789 if (xg_instruction_matches_option_term (insn, option))
2790 return TRUE;
2792 return FALSE;
2796 static bfd_boolean
2797 xg_instruction_matches_options (TInsn *insn, const ReqOptionList *options)
2799 const ReqOption *req_options;
2800 /* Must match each of the AND terms. */
2801 for (req_options = options;
2802 req_options != NULL;
2803 req_options = req_options->next)
2805 /* Must match one of the OR clauses. */
2806 if (!xg_instruction_matches_or_options (insn,
2807 req_options->or_option_terms))
2808 return FALSE;
2810 return TRUE;
2814 /* Return the transition rule that matches or NULL if none matches. */
2816 static bfd_boolean
2817 xg_instruction_matches_rule (TInsn *insn, TransitionRule *rule)
2819 PreconditionList *condition_l;
2821 if (rule->opcode != insn->opcode)
2822 return FALSE;
2824 for (condition_l = rule->conditions;
2825 condition_l != NULL;
2826 condition_l = condition_l->next)
2828 expressionS *exp1;
2829 expressionS *exp2;
2830 Precondition *cond = condition_l->precond;
2832 switch (cond->typ)
2834 case OP_CONSTANT:
2835 /* The expression must be the constant. */
2836 gas_assert (cond->op_num < insn->ntok);
2837 exp1 = &insn->tok[cond->op_num];
2838 if (expr_is_const (exp1))
2840 switch (cond->cmp)
2842 case OP_EQUAL:
2843 if (get_expr_const (exp1) != cond->op_data)
2844 return FALSE;
2845 break;
2846 case OP_NOTEQUAL:
2847 if (get_expr_const (exp1) == cond->op_data)
2848 return FALSE;
2849 break;
2850 default:
2851 return FALSE;
2854 else if (expr_is_register (exp1))
2856 switch (cond->cmp)
2858 case OP_EQUAL:
2859 if (get_expr_register (exp1) != cond->op_data)
2860 return FALSE;
2861 break;
2862 case OP_NOTEQUAL:
2863 if (get_expr_register (exp1) == cond->op_data)
2864 return FALSE;
2865 break;
2866 default:
2867 return FALSE;
2870 else
2871 return FALSE;
2872 break;
2874 case OP_OPERAND:
2875 gas_assert (cond->op_num < insn->ntok);
2876 gas_assert (cond->op_data < insn->ntok);
2877 exp1 = &insn->tok[cond->op_num];
2878 exp2 = &insn->tok[cond->op_data];
2880 switch (cond->cmp)
2882 case OP_EQUAL:
2883 if (!expr_is_equal (exp1, exp2))
2884 return FALSE;
2885 break;
2886 case OP_NOTEQUAL:
2887 if (expr_is_equal (exp1, exp2))
2888 return FALSE;
2889 break;
2891 break;
2893 case OP_LITERAL:
2894 case OP_LABEL:
2895 default:
2896 return FALSE;
2899 if (!xg_instruction_matches_options (insn, rule->options))
2900 return FALSE;
2902 return TRUE;
2906 static int
2907 transition_rule_cmp (const TransitionRule *a, const TransitionRule *b)
2909 bfd_boolean a_greater = FALSE;
2910 bfd_boolean b_greater = FALSE;
2912 ReqOptionList *l_a = a->options;
2913 ReqOptionList *l_b = b->options;
2915 /* We only care if they both are the same except for
2916 a const16 vs. an l32r. */
2918 while (l_a && l_b && ((l_a->next == NULL) == (l_b->next == NULL)))
2920 ReqOrOptionList *l_or_a = l_a->or_option_terms;
2921 ReqOrOptionList *l_or_b = l_b->or_option_terms;
2922 while (l_or_a && l_or_b && ((l_a->next == NULL) == (l_b->next == NULL)))
2924 if (l_or_a->is_true != l_or_b->is_true)
2925 return 0;
2926 if (strcmp (l_or_a->option_name, l_or_b->option_name) != 0)
2928 /* This is the case we care about. */
2929 if (strcmp (l_or_a->option_name, "IsaUseConst16") == 0
2930 && strcmp (l_or_b->option_name, "IsaUseL32R") == 0)
2932 if (prefer_const16)
2933 a_greater = TRUE;
2934 else
2935 b_greater = TRUE;
2937 else if (strcmp (l_or_a->option_name, "IsaUseL32R") == 0
2938 && strcmp (l_or_b->option_name, "IsaUseConst16") == 0)
2940 if (prefer_const16)
2941 b_greater = TRUE;
2942 else
2943 a_greater = TRUE;
2945 else
2946 return 0;
2948 l_or_a = l_or_a->next;
2949 l_or_b = l_or_b->next;
2951 if (l_or_a || l_or_b)
2952 return 0;
2954 l_a = l_a->next;
2955 l_b = l_b->next;
2957 if (l_a || l_b)
2958 return 0;
2960 /* Incomparable if the substitution was used differently in two cases. */
2961 if (a_greater && b_greater)
2962 return 0;
2964 if (b_greater)
2965 return 1;
2966 if (a_greater)
2967 return -1;
2969 return 0;
2973 static TransitionRule *
2974 xg_instruction_match (TInsn *insn)
2976 TransitionTable *table = xg_build_simplify_table (&transition_rule_cmp);
2977 TransitionList *l;
2978 gas_assert (insn->opcode < table->num_opcodes);
2980 /* Walk through all of the possible transitions. */
2981 for (l = table->table[insn->opcode]; l != NULL; l = l->next)
2983 TransitionRule *rule = l->rule;
2984 if (xg_instruction_matches_rule (insn, rule))
2985 return rule;
2987 return NULL;
2991 /* Various Other Internal Functions. */
2993 static bfd_boolean
2994 is_unique_insn_expansion (TransitionRule *r)
2996 if (!r->to_instr || r->to_instr->next != NULL)
2997 return FALSE;
2998 if (r->to_instr->typ != INSTR_INSTR)
2999 return FALSE;
3000 return TRUE;
3004 /* Check if there is exactly one relaxation for INSN that converts it to
3005 another instruction of equal or larger size. If so, and if TARG is
3006 non-null, go ahead and generate the relaxed instruction into TARG. If
3007 NARROW_ONLY is true, then only consider relaxations that widen a narrow
3008 instruction, i.e., ignore relaxations that convert to an instruction of
3009 equal size. In some contexts where this function is used, only
3010 a single widening is allowed and the NARROW_ONLY argument is used to
3011 exclude cases like ADDI being "widened" to an ADDMI, which may
3012 later be relaxed to an ADDMI/ADDI pair. */
3014 bfd_boolean
3015 xg_is_single_relaxable_insn (TInsn *insn, TInsn *targ, bfd_boolean narrow_only)
3017 TransitionTable *table = xg_build_widen_table (&transition_rule_cmp);
3018 TransitionList *l;
3019 TransitionRule *match = 0;
3021 gas_assert (insn->insn_type == ITYPE_INSN);
3022 gas_assert (insn->opcode < table->num_opcodes);
3024 for (l = table->table[insn->opcode]; l != NULL; l = l->next)
3026 TransitionRule *rule = l->rule;
3028 if (xg_instruction_matches_rule (insn, rule)
3029 && is_unique_insn_expansion (rule)
3030 && (xg_get_single_size (insn->opcode) + (narrow_only ? 1 : 0)
3031 <= xg_get_single_size (rule->to_instr->opcode)))
3033 if (match)
3034 return FALSE;
3035 match = rule;
3038 if (!match)
3039 return FALSE;
3041 if (targ)
3042 xg_build_to_insn (targ, insn, match->to_instr);
3043 return TRUE;
3047 /* Return the maximum number of bytes this opcode can expand to. */
3049 static int
3050 xg_get_max_insn_widen_size (xtensa_opcode opcode)
3052 TransitionTable *table = xg_build_widen_table (&transition_rule_cmp);
3053 TransitionList *l;
3054 int max_size = xg_get_single_size (opcode);
3056 gas_assert (opcode < table->num_opcodes);
3058 for (l = table->table[opcode]; l != NULL; l = l->next)
3060 TransitionRule *rule = l->rule;
3061 BuildInstr *build_list;
3062 int this_size = 0;
3064 if (!rule)
3065 continue;
3066 build_list = rule->to_instr;
3067 if (is_unique_insn_expansion (rule))
3069 gas_assert (build_list->typ == INSTR_INSTR);
3070 this_size = xg_get_max_insn_widen_size (build_list->opcode);
3072 else
3073 for (; build_list != NULL; build_list = build_list->next)
3075 switch (build_list->typ)
3077 case INSTR_INSTR:
3078 this_size += xg_get_single_size (build_list->opcode);
3079 break;
3080 case INSTR_LITERAL_DEF:
3081 case INSTR_LABEL_DEF:
3082 default:
3083 break;
3086 if (this_size > max_size)
3087 max_size = this_size;
3089 return max_size;
3093 /* Return the maximum number of literal bytes this opcode can generate. */
3095 static int
3096 xg_get_max_insn_widen_literal_size (xtensa_opcode opcode)
3098 TransitionTable *table = xg_build_widen_table (&transition_rule_cmp);
3099 TransitionList *l;
3100 int max_size = 0;
3102 gas_assert (opcode < table->num_opcodes);
3104 for (l = table->table[opcode]; l != NULL; l = l->next)
3106 TransitionRule *rule = l->rule;
3107 BuildInstr *build_list;
3108 int this_size = 0;
3110 if (!rule)
3111 continue;
3112 build_list = rule->to_instr;
3113 if (is_unique_insn_expansion (rule))
3115 gas_assert (build_list->typ == INSTR_INSTR);
3116 this_size = xg_get_max_insn_widen_literal_size (build_list->opcode);
3118 else
3119 for (; build_list != NULL; build_list = build_list->next)
3121 switch (build_list->typ)
3123 case INSTR_LITERAL_DEF:
3124 /* Hard-coded 4-byte literal. */
3125 this_size += 4;
3126 break;
3127 case INSTR_INSTR:
3128 case INSTR_LABEL_DEF:
3129 default:
3130 break;
3133 if (this_size > max_size)
3134 max_size = this_size;
3136 return max_size;
3140 static bfd_boolean
3141 xg_is_relaxable_insn (TInsn *insn, int lateral_steps)
3143 int steps_taken = 0;
3144 TransitionTable *table = xg_build_widen_table (&transition_rule_cmp);
3145 TransitionList *l;
3147 gas_assert (insn->insn_type == ITYPE_INSN);
3148 gas_assert (insn->opcode < table->num_opcodes);
3150 for (l = table->table[insn->opcode]; l != NULL; l = l->next)
3152 TransitionRule *rule = l->rule;
3154 if (xg_instruction_matches_rule (insn, rule))
3156 if (steps_taken == lateral_steps)
3157 return TRUE;
3158 steps_taken++;
3161 return FALSE;
3165 static symbolS *
3166 get_special_literal_symbol (void)
3168 static symbolS *sym = NULL;
3170 if (sym == NULL)
3171 sym = symbol_find_or_make ("SPECIAL_LITERAL0\001");
3172 return sym;
3176 static symbolS *
3177 get_special_label_symbol (void)
3179 static symbolS *sym = NULL;
3181 if (sym == NULL)
3182 sym = symbol_find_or_make ("SPECIAL_LABEL0\001");
3183 return sym;
3187 static bfd_boolean
3188 xg_valid_literal_expression (const expressionS *exp)
3190 switch (exp->X_op)
3192 case O_constant:
3193 case O_symbol:
3194 case O_big:
3195 case O_uminus:
3196 case O_subtract:
3197 case O_pltrel:
3198 case O_pcrel:
3199 case O_tlsfunc:
3200 case O_tlsarg:
3201 case O_tpoff:
3202 case O_dtpoff:
3203 return TRUE;
3204 default:
3205 return FALSE;
3210 /* This will check to see if the value can be converted into the
3211 operand type. It will return TRUE if it does not fit. */
3213 static bfd_boolean
3214 xg_check_operand (int32 value, xtensa_opcode opcode, int operand)
3216 uint32 valbuf = value;
3217 if (xtensa_operand_encode (xtensa_default_isa, opcode, operand, &valbuf))
3218 return TRUE;
3219 return FALSE;
3223 /* Assumes: All immeds are constants. Check that all constants fit
3224 into their immeds; return FALSE if not. */
3226 static bfd_boolean
3227 xg_immeds_fit (const TInsn *insn)
3229 xtensa_isa isa = xtensa_default_isa;
3230 int i;
3232 int n = insn->ntok;
3233 gas_assert (insn->insn_type == ITYPE_INSN);
3234 for (i = 0; i < n; ++i)
3236 const expressionS *exp = &insn->tok[i];
3238 if (xtensa_operand_is_register (isa, insn->opcode, i) == 1)
3239 continue;
3241 switch (exp->X_op)
3243 case O_register:
3244 case O_constant:
3245 if (xg_check_operand (exp->X_add_number, insn->opcode, i))
3246 return FALSE;
3247 break;
3249 default:
3250 /* The symbol should have a fixup associated with it. */
3251 gas_assert (FALSE);
3252 break;
3255 return TRUE;
3259 /* This should only be called after we have an initial
3260 estimate of the addresses. */
3262 static bfd_boolean
3263 xg_symbolic_immeds_fit (const TInsn *insn,
3264 segT pc_seg,
3265 fragS *pc_frag,
3266 offsetT pc_offset,
3267 long stretch)
3269 xtensa_isa isa = xtensa_default_isa;
3270 symbolS *symbolP;
3271 fragS *sym_frag;
3272 offsetT target, pc;
3273 uint32 new_offset;
3274 int i;
3275 int n = insn->ntok;
3277 gas_assert (insn->insn_type == ITYPE_INSN);
3279 for (i = 0; i < n; ++i)
3281 const expressionS *exp = &insn->tok[i];
3283 if (xtensa_operand_is_register (isa, insn->opcode, i) == 1)
3284 continue;
3286 switch (exp->X_op)
3288 case O_register:
3289 case O_constant:
3290 if (xg_check_operand (exp->X_add_number, insn->opcode, i))
3291 return FALSE;
3292 break;
3294 case O_lo16:
3295 case O_hi16:
3296 /* Check for the worst case. */
3297 if (xg_check_operand (0xffff, insn->opcode, i))
3298 return FALSE;
3299 break;
3301 case O_symbol:
3302 /* We only allow symbols for PC-relative references.
3303 If pc_frag == 0, then we don't have frag locations yet. */
3304 if (pc_frag == 0
3305 || xtensa_operand_is_PCrelative (isa, insn->opcode, i) == 0)
3306 return FALSE;
3308 /* If it is a weak symbol or a symbol in a different section,
3309 it cannot be known to fit at assembly time. */
3310 if (S_IS_WEAK (exp->X_add_symbol)
3311 || S_GET_SEGMENT (exp->X_add_symbol) != pc_seg)
3313 /* For a direct call with --no-longcalls, be optimistic and
3314 assume it will be in range. If the symbol is weak and
3315 undefined, it may remain undefined at link-time, in which
3316 case it will have a zero value and almost certainly be out
3317 of range for a direct call; thus, relax for undefined weak
3318 symbols even if longcalls is not enabled. */
3319 if (is_direct_call_opcode (insn->opcode)
3320 && ! pc_frag->tc_frag_data.use_longcalls
3321 && (! S_IS_WEAK (exp->X_add_symbol)
3322 || S_IS_DEFINED (exp->X_add_symbol)))
3323 return TRUE;
3325 return FALSE;
3328 symbolP = exp->X_add_symbol;
3329 sym_frag = symbol_get_frag (symbolP);
3330 target = S_GET_VALUE (symbolP) + exp->X_add_number;
3331 pc = pc_frag->fr_address + pc_offset;
3333 /* If frag has yet to be reached on this pass, assume it
3334 will move by STRETCH just as we did. If this is not so,
3335 it will be because some frag between grows, and that will
3336 force another pass. Beware zero-length frags. There
3337 should be a faster way to do this. */
3339 if (stretch != 0
3340 && sym_frag->relax_marker != pc_frag->relax_marker
3341 && S_GET_SEGMENT (symbolP) == pc_seg)
3343 target += stretch;
3346 new_offset = target;
3347 xtensa_operand_do_reloc (isa, insn->opcode, i, &new_offset, pc);
3348 if (xg_check_operand (new_offset, insn->opcode, i))
3349 return FALSE;
3350 break;
3352 default:
3353 /* The symbol should have a fixup associated with it. */
3354 return FALSE;
3358 return TRUE;
3362 /* Return TRUE on success. */
3364 static bfd_boolean
3365 xg_build_to_insn (TInsn *targ, TInsn *insn, BuildInstr *bi)
3367 BuildOp *op;
3368 symbolS *sym;
3370 tinsn_init (targ);
3371 targ->debug_line = insn->debug_line;
3372 targ->loc_directive_seen = insn->loc_directive_seen;
3373 switch (bi->typ)
3375 case INSTR_INSTR:
3376 op = bi->ops;
3377 targ->opcode = bi->opcode;
3378 targ->insn_type = ITYPE_INSN;
3379 targ->is_specific_opcode = FALSE;
3381 for (; op != NULL; op = op->next)
3383 int op_num = op->op_num;
3384 int op_data = op->op_data;
3386 gas_assert (op->op_num < MAX_INSN_ARGS);
3388 if (targ->ntok <= op_num)
3389 targ->ntok = op_num + 1;
3391 switch (op->typ)
3393 case OP_CONSTANT:
3394 set_expr_const (&targ->tok[op_num], op_data);
3395 break;
3396 case OP_OPERAND:
3397 gas_assert (op_data < insn->ntok);
3398 copy_expr (&targ->tok[op_num], &insn->tok[op_data]);
3399 break;
3400 case OP_FREEREG:
3401 if (insn->extra_arg.X_op != O_register)
3402 return FALSE;
3403 copy_expr (&targ->tok[op_num], &insn->extra_arg);
3404 break;
3405 case OP_LITERAL:
3406 sym = get_special_literal_symbol ();
3407 set_expr_symbol_offset (&targ->tok[op_num], sym, 0);
3408 if (insn->tok[op_data].X_op == O_tlsfunc
3409 || insn->tok[op_data].X_op == O_tlsarg)
3410 copy_expr (&targ->extra_arg, &insn->tok[op_data]);
3411 break;
3412 case OP_LABEL:
3413 sym = get_special_label_symbol ();
3414 set_expr_symbol_offset (&targ->tok[op_num], sym, 0);
3415 break;
3416 case OP_OPERAND_HI16U:
3417 case OP_OPERAND_LOW16U:
3418 gas_assert (op_data < insn->ntok);
3419 if (expr_is_const (&insn->tok[op_data]))
3421 long val;
3422 copy_expr (&targ->tok[op_num], &insn->tok[op_data]);
3423 val = xg_apply_userdef_op_fn (op->typ,
3424 targ->tok[op_num].
3425 X_add_number);
3426 targ->tok[op_num].X_add_number = val;
3428 else
3430 /* For const16 we can create relocations for these. */
3431 if (targ->opcode == XTENSA_UNDEFINED
3432 || (targ->opcode != xtensa_const16_opcode))
3433 return FALSE;
3434 gas_assert (op_data < insn->ntok);
3435 /* Need to build a O_lo16 or O_hi16. */
3436 copy_expr (&targ->tok[op_num], &insn->tok[op_data]);
3437 if (targ->tok[op_num].X_op == O_symbol)
3439 if (op->typ == OP_OPERAND_HI16U)
3440 targ->tok[op_num].X_op = O_hi16;
3441 else if (op->typ == OP_OPERAND_LOW16U)
3442 targ->tok[op_num].X_op = O_lo16;
3443 else
3444 return FALSE;
3447 break;
3448 default:
3449 /* currently handles:
3450 OP_OPERAND_LOW8
3451 OP_OPERAND_HI24S
3452 OP_OPERAND_F32MINUS */
3453 if (xg_has_userdef_op_fn (op->typ))
3455 gas_assert (op_data < insn->ntok);
3456 if (expr_is_const (&insn->tok[op_data]))
3458 long val;
3459 copy_expr (&targ->tok[op_num], &insn->tok[op_data]);
3460 val = xg_apply_userdef_op_fn (op->typ,
3461 targ->tok[op_num].
3462 X_add_number);
3463 targ->tok[op_num].X_add_number = val;
3465 else
3466 return FALSE; /* We cannot use a relocation for this. */
3467 break;
3469 gas_assert (0);
3470 break;
3473 break;
3475 case INSTR_LITERAL_DEF:
3476 op = bi->ops;
3477 targ->opcode = XTENSA_UNDEFINED;
3478 targ->insn_type = ITYPE_LITERAL;
3479 targ->is_specific_opcode = FALSE;
3480 for (; op != NULL; op = op->next)
3482 int op_num = op->op_num;
3483 int op_data = op->op_data;
3484 gas_assert (op->op_num < MAX_INSN_ARGS);
3486 if (targ->ntok <= op_num)
3487 targ->ntok = op_num + 1;
3489 switch (op->typ)
3491 case OP_OPERAND:
3492 gas_assert (op_data < insn->ntok);
3493 /* We can only pass resolvable literals through. */
3494 if (!xg_valid_literal_expression (&insn->tok[op_data]))
3495 return FALSE;
3496 copy_expr (&targ->tok[op_num], &insn->tok[op_data]);
3497 break;
3498 case OP_LITERAL:
3499 case OP_CONSTANT:
3500 case OP_LABEL:
3501 default:
3502 gas_assert (0);
3503 break;
3506 break;
3508 case INSTR_LABEL_DEF:
3509 op = bi->ops;
3510 targ->opcode = XTENSA_UNDEFINED;
3511 targ->insn_type = ITYPE_LABEL;
3512 targ->is_specific_opcode = FALSE;
3513 /* Literal with no ops is a label? */
3514 gas_assert (op == NULL);
3515 break;
3517 default:
3518 gas_assert (0);
3521 return TRUE;
3525 /* Return TRUE on success. */
3527 static bfd_boolean
3528 xg_build_to_stack (IStack *istack, TInsn *insn, BuildInstr *bi)
3530 for (; bi != NULL; bi = bi->next)
3532 TInsn *next_insn = istack_push_space (istack);
3534 if (!xg_build_to_insn (next_insn, insn, bi))
3535 return FALSE;
3537 return TRUE;
3541 /* Return TRUE on valid expansion. */
3543 static bfd_boolean
3544 xg_expand_to_stack (IStack *istack, TInsn *insn, int lateral_steps)
3546 int stack_size = istack->ninsn;
3547 int steps_taken = 0;
3548 TransitionTable *table = xg_build_widen_table (&transition_rule_cmp);
3549 TransitionList *l;
3551 gas_assert (insn->insn_type == ITYPE_INSN);
3552 gas_assert (insn->opcode < table->num_opcodes);
3554 for (l = table->table[insn->opcode]; l != NULL; l = l->next)
3556 TransitionRule *rule = l->rule;
3558 if (xg_instruction_matches_rule (insn, rule))
3560 if (lateral_steps == steps_taken)
3562 int i;
3564 /* This is it. Expand the rule to the stack. */
3565 if (!xg_build_to_stack (istack, insn, rule->to_instr))
3566 return FALSE;
3568 /* Check to see if it fits. */
3569 for (i = stack_size; i < istack->ninsn; i++)
3571 TInsn *tinsn = &istack->insn[i];
3573 if (tinsn->insn_type == ITYPE_INSN
3574 && !tinsn_has_symbolic_operands (tinsn)
3575 && !xg_immeds_fit (tinsn))
3577 istack->ninsn = stack_size;
3578 return FALSE;
3581 return TRUE;
3583 steps_taken++;
3586 return FALSE;
3590 /* Relax the assembly instruction at least "min_steps".
3591 Return the number of steps taken.
3593 For relaxation to correctly terminate, every relaxation chain must
3594 terminate in one of two ways:
3596 1. If the chain from one instruction to the next consists entirely of
3597 single instructions, then the chain *must* handle all possible
3598 immediates without failing. It must not ever fail because an
3599 immediate is out of range. The MOVI.N -> MOVI -> L32R relaxation
3600 chain is one example. L32R loads 32 bits, and there cannot be an
3601 immediate larger than 32 bits, so it satisfies this condition.
3602 Single instruction relaxation chains are as defined by
3603 xg_is_single_relaxable_instruction.
3605 2. Otherwise, the chain must end in a multi-instruction expansion: e.g.,
3606 BNEZ.N -> BNEZ -> BNEZ.W15 -> BENZ.N/J
3608 Strictly speaking, in most cases you can violate condition 1 and be OK
3609 -- in particular when the last two instructions have the same single
3610 size. But nevertheless, you should guarantee the above two conditions.
3612 We could fix this so that single-instruction expansions correctly
3613 terminate when they can't handle the range, but the error messages are
3614 worse, and it actually turns out that in every case but one (18-bit wide
3615 branches), you need a multi-instruction expansion to get the full range
3616 anyway. And because 18-bit branches are handled identically to 15-bit
3617 branches, there isn't any point in changing it. */
3619 static int
3620 xg_assembly_relax (IStack *istack,
3621 TInsn *insn,
3622 segT pc_seg,
3623 fragS *pc_frag, /* if pc_frag == 0, not pc-relative */
3624 offsetT pc_offset, /* offset in fragment */
3625 int min_steps, /* minimum conversion steps */
3626 long stretch) /* number of bytes stretched so far */
3628 int steps_taken = 0;
3630 /* Some of its immeds don't fit. Try to build a relaxed version.
3631 This may go through a couple of stages of single instruction
3632 transformations before we get there. */
3634 TInsn single_target;
3635 TInsn current_insn;
3636 int lateral_steps = 0;
3637 int istack_size = istack->ninsn;
3639 if (xg_symbolic_immeds_fit (insn, pc_seg, pc_frag, pc_offset, stretch)
3640 && steps_taken >= min_steps)
3642 istack_push (istack, insn);
3643 return steps_taken;
3645 current_insn = *insn;
3647 /* Walk through all of the single instruction expansions. */
3648 while (xg_is_single_relaxable_insn (&current_insn, &single_target, FALSE))
3650 steps_taken++;
3651 if (xg_symbolic_immeds_fit (&single_target, pc_seg, pc_frag, pc_offset,
3652 stretch))
3654 if (steps_taken >= min_steps)
3656 istack_push (istack, &single_target);
3657 return steps_taken;
3660 current_insn = single_target;
3663 /* Now check for a multi-instruction expansion. */
3664 while (xg_is_relaxable_insn (&current_insn, lateral_steps))
3666 if (xg_symbolic_immeds_fit (&current_insn, pc_seg, pc_frag, pc_offset,
3667 stretch))
3669 if (steps_taken >= min_steps)
3671 istack_push (istack, &current_insn);
3672 return steps_taken;
3675 steps_taken++;
3676 if (xg_expand_to_stack (istack, &current_insn, lateral_steps))
3678 if (steps_taken >= min_steps)
3679 return steps_taken;
3681 lateral_steps++;
3682 istack->ninsn = istack_size;
3685 /* It's not going to work -- use the original. */
3686 istack_push (istack, insn);
3687 return steps_taken;
3691 static void
3692 xg_finish_frag (char *last_insn,
3693 enum xtensa_relax_statesE frag_state,
3694 enum xtensa_relax_statesE slot0_state,
3695 int max_growth,
3696 bfd_boolean is_insn)
3698 /* Finish off this fragment so that it has at LEAST the desired
3699 max_growth. If it doesn't fit in this fragment, close this one
3700 and start a new one. In either case, return a pointer to the
3701 beginning of the growth area. */
3703 fragS *old_frag;
3705 frag_grow (max_growth);
3706 old_frag = frag_now;
3708 frag_now->fr_opcode = last_insn;
3709 if (is_insn)
3710 frag_now->tc_frag_data.is_insn = TRUE;
3712 frag_var (rs_machine_dependent, max_growth, max_growth,
3713 frag_state, frag_now->fr_symbol, frag_now->fr_offset, last_insn);
3715 old_frag->tc_frag_data.slot_subtypes[0] = slot0_state;
3716 xtensa_set_frag_assembly_state (frag_now);
3718 /* Just to make sure that we did not split it up. */
3719 gas_assert (old_frag->fr_next == frag_now);
3723 /* Return TRUE if the target frag is one of the next non-empty frags. */
3725 static bfd_boolean
3726 is_next_frag_target (const fragS *fragP, const fragS *target)
3728 if (fragP == NULL)
3729 return FALSE;
3731 for (; fragP; fragP = fragP->fr_next)
3733 if (fragP == target)
3734 return TRUE;
3735 if (fragP->fr_fix != 0)
3736 return FALSE;
3737 if (fragP->fr_type == rs_fill && fragP->fr_offset != 0)
3738 return FALSE;
3739 if ((fragP->fr_type == rs_align || fragP->fr_type == rs_align_code)
3740 && ((fragP->fr_address % (1 << fragP->fr_offset)) != 0))
3741 return FALSE;
3742 if (fragP->fr_type == rs_space)
3743 return FALSE;
3745 return FALSE;
3749 static bfd_boolean
3750 is_branch_jmp_to_next (TInsn *insn, fragS *fragP)
3752 xtensa_isa isa = xtensa_default_isa;
3753 int i;
3754 int num_ops = xtensa_opcode_num_operands (isa, insn->opcode);
3755 int target_op = -1;
3756 symbolS *sym;
3757 fragS *target_frag;
3759 if (xtensa_opcode_is_branch (isa, insn->opcode) != 1
3760 && xtensa_opcode_is_jump (isa, insn->opcode) != 1)
3761 return FALSE;
3763 for (i = 0; i < num_ops; i++)
3765 if (xtensa_operand_is_PCrelative (isa, insn->opcode, i) == 1)
3767 target_op = i;
3768 break;
3771 if (target_op == -1)
3772 return FALSE;
3774 if (insn->ntok <= target_op)
3775 return FALSE;
3777 if (insn->tok[target_op].X_op != O_symbol)
3778 return FALSE;
3780 sym = insn->tok[target_op].X_add_symbol;
3781 if (sym == NULL)
3782 return FALSE;
3784 if (insn->tok[target_op].X_add_number != 0)
3785 return FALSE;
3787 target_frag = symbol_get_frag (sym);
3788 if (target_frag == NULL)
3789 return FALSE;
3791 if (is_next_frag_target (fragP->fr_next, target_frag)
3792 && S_GET_VALUE (sym) == target_frag->fr_address)
3793 return TRUE;
3795 return FALSE;
3799 static void
3800 xg_add_branch_and_loop_targets (TInsn *insn)
3802 xtensa_isa isa = xtensa_default_isa;
3803 int num_ops = xtensa_opcode_num_operands (isa, insn->opcode);
3805 if (xtensa_opcode_is_loop (isa, insn->opcode) == 1)
3807 int i = 1;
3808 if (xtensa_operand_is_PCrelative (isa, insn->opcode, i) == 1
3809 && insn->tok[i].X_op == O_symbol)
3810 symbol_get_tc (insn->tok[i].X_add_symbol)->is_loop_target = TRUE;
3811 return;
3814 if (xtensa_opcode_is_branch (isa, insn->opcode) == 1
3815 || xtensa_opcode_is_loop (isa, insn->opcode) == 1)
3817 int i;
3819 for (i = 0; i < insn->ntok && i < num_ops; i++)
3821 if (xtensa_operand_is_PCrelative (isa, insn->opcode, i) == 1
3822 && insn->tok[i].X_op == O_symbol)
3824 symbolS *sym = insn->tok[i].X_add_symbol;
3825 symbol_get_tc (sym)->is_branch_target = TRUE;
3826 if (S_IS_DEFINED (sym))
3827 symbol_get_frag (sym)->tc_frag_data.is_branch_target = TRUE;
3834 /* Return FALSE if no error. */
3836 static bfd_boolean
3837 xg_build_token_insn (BuildInstr *instr_spec, TInsn *old_insn, TInsn *new_insn)
3839 int num_ops = 0;
3840 BuildOp *b_op;
3842 switch (instr_spec->typ)
3844 case INSTR_INSTR:
3845 new_insn->insn_type = ITYPE_INSN;
3846 new_insn->opcode = instr_spec->opcode;
3847 break;
3848 case INSTR_LITERAL_DEF:
3849 new_insn->insn_type = ITYPE_LITERAL;
3850 new_insn->opcode = XTENSA_UNDEFINED;
3851 break;
3852 case INSTR_LABEL_DEF:
3853 abort ();
3855 new_insn->is_specific_opcode = FALSE;
3856 new_insn->debug_line = old_insn->debug_line;
3857 new_insn->loc_directive_seen = old_insn->loc_directive_seen;
3859 for (b_op = instr_spec->ops; b_op != NULL; b_op = b_op->next)
3861 expressionS *exp;
3862 const expressionS *src_exp;
3864 num_ops++;
3865 switch (b_op->typ)
3867 case OP_CONSTANT:
3868 /* The expression must be the constant. */
3869 gas_assert (b_op->op_num < MAX_INSN_ARGS);
3870 exp = &new_insn->tok[b_op->op_num];
3871 set_expr_const (exp, b_op->op_data);
3872 break;
3874 case OP_OPERAND:
3875 gas_assert (b_op->op_num < MAX_INSN_ARGS);
3876 gas_assert (b_op->op_data < (unsigned) old_insn->ntok);
3877 src_exp = &old_insn->tok[b_op->op_data];
3878 exp = &new_insn->tok[b_op->op_num];
3879 copy_expr (exp, src_exp);
3880 break;
3882 case OP_LITERAL:
3883 case OP_LABEL:
3884 as_bad (_("can't handle generation of literal/labels yet"));
3885 gas_assert (0);
3887 default:
3888 as_bad (_("can't handle undefined OP TYPE"));
3889 gas_assert (0);
3893 new_insn->ntok = num_ops;
3894 return FALSE;
3898 /* Return TRUE if it was simplified. */
3900 static bfd_boolean
3901 xg_simplify_insn (TInsn *old_insn, TInsn *new_insn)
3903 TransitionRule *rule;
3904 BuildInstr *insn_spec;
3906 if (old_insn->is_specific_opcode || !density_supported)
3907 return FALSE;
3909 rule = xg_instruction_match (old_insn);
3910 if (rule == NULL)
3911 return FALSE;
3913 insn_spec = rule->to_instr;
3914 /* There should only be one. */
3915 gas_assert (insn_spec != NULL);
3916 gas_assert (insn_spec->next == NULL);
3917 if (insn_spec->next != NULL)
3918 return FALSE;
3920 xg_build_token_insn (insn_spec, old_insn, new_insn);
3922 return TRUE;
3926 /* xg_expand_assembly_insn: (1) Simplify the instruction, i.e., l32i ->
3927 l32i.n. (2) Check the number of operands. (3) Place the instruction
3928 tokens into the stack or relax it and place multiple
3929 instructions/literals onto the stack. Return FALSE if no error. */
3931 static bfd_boolean
3932 xg_expand_assembly_insn (IStack *istack, TInsn *orig_insn)
3934 int noperands;
3935 TInsn new_insn;
3936 bfd_boolean do_expand;
3938 tinsn_init (&new_insn);
3940 /* Narrow it if we can. xg_simplify_insn now does all the
3941 appropriate checking (e.g., for the density option). */
3942 if (xg_simplify_insn (orig_insn, &new_insn))
3943 orig_insn = &new_insn;
3945 noperands = xtensa_opcode_num_operands (xtensa_default_isa,
3946 orig_insn->opcode);
3947 if (orig_insn->ntok < noperands)
3949 as_bad (_("found %d operands for '%s': Expected %d"),
3950 orig_insn->ntok,
3951 xtensa_opcode_name (xtensa_default_isa, orig_insn->opcode),
3952 noperands);
3953 return TRUE;
3955 if (orig_insn->ntok > noperands)
3956 as_warn (_("found too many (%d) operands for '%s': Expected %d"),
3957 orig_insn->ntok,
3958 xtensa_opcode_name (xtensa_default_isa, orig_insn->opcode),
3959 noperands);
3961 /* If there are not enough operands, we will assert above. If there
3962 are too many, just cut out the extras here. */
3963 orig_insn->ntok = noperands;
3965 if (tinsn_has_invalid_symbolic_operands (orig_insn))
3966 return TRUE;
3968 /* Special case for extui opcode which has constraints not handled
3969 by the ordinary operand encoding checks. The number of operands
3970 and related syntax issues have already been checked. */
3971 if (orig_insn->opcode == xtensa_extui_opcode)
3973 int shiftimm = orig_insn->tok[2].X_add_number;
3974 int maskimm = orig_insn->tok[3].X_add_number;
3975 if (shiftimm + maskimm > 32)
3977 as_bad (_("immediate operands sum to greater than 32"));
3978 return TRUE;
3982 /* If the instruction will definitely need to be relaxed, it is better
3983 to expand it now for better scheduling. Decide whether to expand
3984 now.... */
3985 do_expand = (!orig_insn->is_specific_opcode && use_transform ());
3987 /* Calls should be expanded to longcalls only in the backend relaxation
3988 so that the assembly scheduler will keep the L32R/CALLX instructions
3989 adjacent. */
3990 if (is_direct_call_opcode (orig_insn->opcode))
3991 do_expand = FALSE;
3993 if (tinsn_has_symbolic_operands (orig_insn))
3995 /* The values of symbolic operands are not known yet, so only expand
3996 now if an operand is "complex" (e.g., difference of symbols) and
3997 will have to be stored as a literal regardless of the value. */
3998 if (!tinsn_has_complex_operands (orig_insn))
3999 do_expand = FALSE;
4001 else if (xg_immeds_fit (orig_insn))
4002 do_expand = FALSE;
4004 if (do_expand)
4005 xg_assembly_relax (istack, orig_insn, 0, 0, 0, 0, 0);
4006 else
4007 istack_push (istack, orig_insn);
4009 return FALSE;
4013 /* Return TRUE if the section flags are marked linkonce
4014 or the name is .gnu.linkonce.*. */
4016 static int linkonce_len = sizeof (".gnu.linkonce.") - 1;
4018 static bfd_boolean
4019 get_is_linkonce_section (bfd *abfd ATTRIBUTE_UNUSED, segT sec)
4021 flagword flags, link_once_flags;
4023 flags = bfd_get_section_flags (abfd, sec);
4024 link_once_flags = (flags & SEC_LINK_ONCE);
4026 /* Flags might not be set yet. */
4027 if (!link_once_flags
4028 && strncmp (segment_name (sec), ".gnu.linkonce.", linkonce_len) == 0)
4029 link_once_flags = SEC_LINK_ONCE;
4031 return (link_once_flags != 0);
4035 static void
4036 xtensa_add_literal_sym (symbolS *sym)
4038 sym_list *l;
4040 l = (sym_list *) xmalloc (sizeof (sym_list));
4041 l->sym = sym;
4042 l->next = literal_syms;
4043 literal_syms = l;
4047 static symbolS *
4048 xtensa_create_literal_symbol (segT sec, fragS *frag)
4050 static int lit_num = 0;
4051 static char name[256];
4052 symbolS *symbolP;
4054 sprintf (name, ".L_lit_sym%d", lit_num);
4056 /* Create a local symbol. If it is in a linkonce section, we have to
4057 be careful to make sure that if it is used in a relocation that the
4058 symbol will be in the output file. */
4059 if (get_is_linkonce_section (stdoutput, sec))
4061 symbolP = symbol_new (name, sec, 0, frag);
4062 S_CLEAR_EXTERNAL (symbolP);
4063 /* symbolP->local = 1; */
4065 else
4066 symbolP = symbol_new (name, sec, 0, frag);
4068 xtensa_add_literal_sym (symbolP);
4070 lit_num++;
4071 return symbolP;
4075 /* Currently all literals that are generated here are 32-bit L32R targets. */
4077 static symbolS *
4078 xg_assemble_literal (/* const */ TInsn *insn)
4080 emit_state state;
4081 symbolS *lit_sym = NULL;
4082 bfd_reloc_code_real_type reloc;
4083 bfd_boolean pcrel = FALSE;
4084 char *p;
4086 /* size = 4 for L32R. It could easily be larger when we move to
4087 larger constants. Add a parameter later. */
4088 offsetT litsize = 4;
4089 offsetT litalign = 2; /* 2^2 = 4 */
4090 expressionS saved_loc;
4091 expressionS * emit_val;
4093 set_expr_symbol_offset (&saved_loc, frag_now->fr_symbol, frag_now_fix ());
4095 gas_assert (insn->insn_type == ITYPE_LITERAL);
4096 gas_assert (insn->ntok == 1); /* must be only one token here */
4098 xtensa_switch_to_literal_fragment (&state);
4100 emit_val = &insn->tok[0];
4101 if (emit_val->X_op == O_big)
4103 int size = emit_val->X_add_number * CHARS_PER_LITTLENUM;
4104 if (size > litsize)
4106 /* This happens when someone writes a "movi a2, big_number". */
4107 as_bad_where (frag_now->fr_file, frag_now->fr_line,
4108 _("invalid immediate"));
4109 xtensa_restore_emit_state (&state);
4110 return NULL;
4114 /* Force a 4-byte align here. Note that this opens a new frag, so all
4115 literals done with this function have a frag to themselves. That's
4116 important for the way text section literals work. */
4117 frag_align (litalign, 0, 0);
4118 record_alignment (now_seg, litalign);
4120 switch (emit_val->X_op)
4122 case O_pcrel:
4123 pcrel = TRUE;
4124 /* fall through */
4125 case O_pltrel:
4126 case O_tlsfunc:
4127 case O_tlsarg:
4128 case O_tpoff:
4129 case O_dtpoff:
4130 p = frag_more (litsize);
4131 xtensa_set_frag_assembly_state (frag_now);
4132 reloc = map_operator_to_reloc (emit_val->X_op, TRUE);
4133 if (emit_val->X_add_symbol)
4134 emit_val->X_op = O_symbol;
4135 else
4136 emit_val->X_op = O_constant;
4137 fix_new_exp (frag_now, p - frag_now->fr_literal,
4138 litsize, emit_val, pcrel, reloc);
4139 break;
4141 default:
4142 emit_expr (emit_val, litsize);
4143 break;
4146 gas_assert (frag_now->tc_frag_data.literal_frag == NULL);
4147 frag_now->tc_frag_data.literal_frag = get_literal_pool_location (now_seg);
4148 frag_now->fr_symbol = xtensa_create_literal_symbol (now_seg, frag_now);
4149 lit_sym = frag_now->fr_symbol;
4151 /* Go back. */
4152 xtensa_restore_emit_state (&state);
4153 return lit_sym;
4157 static void
4158 xg_assemble_literal_space (/* const */ int size, int slot)
4160 emit_state state;
4161 /* We might have to do something about this alignment. It only
4162 takes effect if something is placed here. */
4163 offsetT litalign = 2; /* 2^2 = 4 */
4164 fragS *lit_saved_frag;
4166 gas_assert (size % 4 == 0);
4168 xtensa_switch_to_literal_fragment (&state);
4170 /* Force a 4-byte align here. */
4171 frag_align (litalign, 0, 0);
4172 record_alignment (now_seg, litalign);
4174 frag_grow (size);
4176 lit_saved_frag = frag_now;
4177 frag_now->tc_frag_data.literal_frag = get_literal_pool_location (now_seg);
4178 frag_now->fr_symbol = xtensa_create_literal_symbol (now_seg, frag_now);
4179 xg_finish_frag (0, RELAX_LITERAL, 0, size, FALSE);
4181 /* Go back. */
4182 xtensa_restore_emit_state (&state);
4183 frag_now->tc_frag_data.literal_frags[slot] = lit_saved_frag;
4187 /* Put in a fixup record based on the opcode.
4188 Return TRUE on success. */
4190 static bfd_boolean
4191 xg_add_opcode_fix (TInsn *tinsn,
4192 int opnum,
4193 xtensa_format fmt,
4194 int slot,
4195 expressionS *exp,
4196 fragS *fragP,
4197 offsetT offset)
4199 xtensa_opcode opcode = tinsn->opcode;
4200 bfd_reloc_code_real_type reloc;
4201 reloc_howto_type *howto;
4202 int fmt_length;
4203 fixS *the_fix;
4205 reloc = BFD_RELOC_NONE;
4207 /* First try the special cases for "alternate" relocs. */
4208 if (opcode == xtensa_l32r_opcode)
4210 if (fragP->tc_frag_data.use_absolute_literals)
4211 reloc = encode_alt_reloc (slot);
4213 else if (opcode == xtensa_const16_opcode)
4215 if (exp->X_op == O_lo16)
4217 reloc = encode_reloc (slot);
4218 exp->X_op = O_symbol;
4220 else if (exp->X_op == O_hi16)
4222 reloc = encode_alt_reloc (slot);
4223 exp->X_op = O_symbol;
4227 if (opnum != get_relaxable_immed (opcode))
4229 as_bad (_("invalid relocation for operand %i of '%s'"),
4230 opnum + 1, xtensa_opcode_name (xtensa_default_isa, opcode));
4231 return FALSE;
4234 /* Handle erroneous "@h" and "@l" expressions here before they propagate
4235 into the symbol table where the generic portions of the assembler
4236 won't know what to do with them. */
4237 if (exp->X_op == O_lo16 || exp->X_op == O_hi16)
4239 as_bad (_("invalid expression for operand %i of '%s'"),
4240 opnum + 1, xtensa_opcode_name (xtensa_default_isa, opcode));
4241 return FALSE;
4244 /* Next try the generic relocs. */
4245 if (reloc == BFD_RELOC_NONE)
4246 reloc = encode_reloc (slot);
4247 if (reloc == BFD_RELOC_NONE)
4249 as_bad (_("invalid relocation in instruction slot %i"), slot);
4250 return FALSE;
4253 howto = bfd_reloc_type_lookup (stdoutput, reloc);
4254 if (!howto)
4256 as_bad (_("undefined symbol for opcode \"%s\""),
4257 xtensa_opcode_name (xtensa_default_isa, opcode));
4258 return FALSE;
4261 fmt_length = xtensa_format_length (xtensa_default_isa, fmt);
4262 the_fix = fix_new_exp (fragP, offset, fmt_length, exp,
4263 howto->pc_relative, reloc);
4264 the_fix->fx_no_overflow = 1;
4265 the_fix->tc_fix_data.X_add_symbol = exp->X_add_symbol;
4266 the_fix->tc_fix_data.X_add_number = exp->X_add_number;
4267 the_fix->tc_fix_data.slot = slot;
4269 return TRUE;
4273 static bfd_boolean
4274 xg_emit_insn_to_buf (TInsn *tinsn,
4275 char *buf,
4276 fragS *fragP,
4277 offsetT offset,
4278 bfd_boolean build_fix)
4280 static xtensa_insnbuf insnbuf = NULL;
4281 bfd_boolean has_symbolic_immed = FALSE;
4282 bfd_boolean ok = TRUE;
4284 if (!insnbuf)
4285 insnbuf = xtensa_insnbuf_alloc (xtensa_default_isa);
4287 has_symbolic_immed = tinsn_to_insnbuf (tinsn, insnbuf);
4288 if (has_symbolic_immed && build_fix)
4290 /* Add a fixup. */
4291 xtensa_format fmt = xg_get_single_format (tinsn->opcode);
4292 int slot = xg_get_single_slot (tinsn->opcode);
4293 int opnum = get_relaxable_immed (tinsn->opcode);
4294 expressionS *exp = &tinsn->tok[opnum];
4296 if (!xg_add_opcode_fix (tinsn, opnum, fmt, slot, exp, fragP, offset))
4297 ok = FALSE;
4299 fragP->tc_frag_data.is_insn = TRUE;
4300 xtensa_insnbuf_to_chars (xtensa_default_isa, insnbuf,
4301 (unsigned char *) buf, 0);
4302 return ok;
4306 static void
4307 xg_resolve_literals (TInsn *insn, symbolS *lit_sym)
4309 symbolS *sym = get_special_literal_symbol ();
4310 int i;
4311 if (lit_sym == 0)
4312 return;
4313 gas_assert (insn->insn_type == ITYPE_INSN);
4314 for (i = 0; i < insn->ntok; i++)
4315 if (insn->tok[i].X_add_symbol == sym)
4316 insn->tok[i].X_add_symbol = lit_sym;
4321 static void
4322 xg_resolve_labels (TInsn *insn, symbolS *label_sym)
4324 symbolS *sym = get_special_label_symbol ();
4325 int i;
4326 for (i = 0; i < insn->ntok; i++)
4327 if (insn->tok[i].X_add_symbol == sym)
4328 insn->tok[i].X_add_symbol = label_sym;
4333 /* Return TRUE if the instruction can write to the specified
4334 integer register. */
4336 static bfd_boolean
4337 is_register_writer (const TInsn *insn, const char *regset, int regnum)
4339 int i;
4340 int num_ops;
4341 xtensa_isa isa = xtensa_default_isa;
4343 num_ops = xtensa_opcode_num_operands (isa, insn->opcode);
4345 for (i = 0; i < num_ops; i++)
4347 char inout;
4348 inout = xtensa_operand_inout (isa, insn->opcode, i);
4349 if ((inout == 'o' || inout == 'm')
4350 && xtensa_operand_is_register (isa, insn->opcode, i) == 1)
4352 xtensa_regfile opnd_rf =
4353 xtensa_operand_regfile (isa, insn->opcode, i);
4354 if (!strcmp (xtensa_regfile_shortname (isa, opnd_rf), regset))
4356 if ((insn->tok[i].X_op == O_register)
4357 && (insn->tok[i].X_add_number == regnum))
4358 return TRUE;
4362 return FALSE;
4366 static bfd_boolean
4367 is_bad_loopend_opcode (const TInsn *tinsn)
4369 xtensa_opcode opcode = tinsn->opcode;
4371 if (opcode == XTENSA_UNDEFINED)
4372 return FALSE;
4374 if (opcode == xtensa_call0_opcode
4375 || opcode == xtensa_callx0_opcode
4376 || opcode == xtensa_call4_opcode
4377 || opcode == xtensa_callx4_opcode
4378 || opcode == xtensa_call8_opcode
4379 || opcode == xtensa_callx8_opcode
4380 || opcode == xtensa_call12_opcode
4381 || opcode == xtensa_callx12_opcode
4382 || opcode == xtensa_isync_opcode
4383 || opcode == xtensa_ret_opcode
4384 || opcode == xtensa_ret_n_opcode
4385 || opcode == xtensa_retw_opcode
4386 || opcode == xtensa_retw_n_opcode
4387 || opcode == xtensa_waiti_opcode
4388 || opcode == xtensa_rsr_lcount_opcode)
4389 return TRUE;
4391 return FALSE;
4395 /* Labels that begin with ".Ln" or ".LM" are unaligned.
4396 This allows the debugger to add unaligned labels.
4397 Also, the assembler generates stabs labels that need
4398 not be aligned: FAKE_LABEL_NAME . {"F", "L", "endfunc"}. */
4400 static bfd_boolean
4401 is_unaligned_label (symbolS *sym)
4403 const char *name = S_GET_NAME (sym);
4404 static size_t fake_size = 0;
4406 if (name
4407 && name[0] == '.'
4408 && name[1] == 'L' && (name[2] == 'n' || name[2] == 'M'))
4409 return TRUE;
4411 /* FAKE_LABEL_NAME followed by "F", "L" or "endfunc" */
4412 if (fake_size == 0)
4413 fake_size = strlen (FAKE_LABEL_NAME);
4415 if (name
4416 && strncmp (FAKE_LABEL_NAME, name, fake_size) == 0
4417 && (name[fake_size] == 'F'
4418 || name[fake_size] == 'L'
4419 || (name[fake_size] == 'e'
4420 && strncmp ("endfunc", name+fake_size, 7) == 0)))
4421 return TRUE;
4423 return FALSE;
4427 static fragS *
4428 next_non_empty_frag (const fragS *fragP)
4430 fragS *next_fragP = fragP->fr_next;
4432 /* Sometimes an empty will end up here due storage allocation issues.
4433 So we have to skip until we find something legit. */
4434 while (next_fragP && next_fragP->fr_fix == 0)
4435 next_fragP = next_fragP->fr_next;
4437 if (next_fragP == NULL || next_fragP->fr_fix == 0)
4438 return NULL;
4440 return next_fragP;
4444 static bfd_boolean
4445 next_frag_opcode_is_loop (const fragS *fragP, xtensa_opcode *opcode)
4447 xtensa_opcode out_opcode;
4448 const fragS *next_fragP = next_non_empty_frag (fragP);
4450 if (next_fragP == NULL)
4451 return FALSE;
4453 out_opcode = get_opcode_from_buf (next_fragP->fr_literal, 0);
4454 if (xtensa_opcode_is_loop (xtensa_default_isa, out_opcode) == 1)
4456 *opcode = out_opcode;
4457 return TRUE;
4459 return FALSE;
4463 static int
4464 frag_format_size (const fragS *fragP)
4466 static xtensa_insnbuf insnbuf = NULL;
4467 xtensa_isa isa = xtensa_default_isa;
4468 xtensa_format fmt;
4469 int fmt_size;
4471 if (!insnbuf)
4472 insnbuf = xtensa_insnbuf_alloc (isa);
4474 if (fragP == NULL)
4475 return XTENSA_UNDEFINED;
4477 xtensa_insnbuf_from_chars (isa, insnbuf,
4478 (unsigned char *) fragP->fr_literal, 0);
4480 fmt = xtensa_format_decode (isa, insnbuf);
4481 if (fmt == XTENSA_UNDEFINED)
4482 return XTENSA_UNDEFINED;
4483 fmt_size = xtensa_format_length (isa, fmt);
4485 /* If the next format won't be changing due to relaxation, just
4486 return the length of the first format. */
4487 if (fragP->fr_opcode != fragP->fr_literal)
4488 return fmt_size;
4490 /* If during relaxation we have to pull an instruction out of a
4491 multi-slot instruction, we will return the more conservative
4492 number. This works because alignment on bigger instructions
4493 is more restrictive than alignment on smaller instructions.
4494 This is more conservative than we would like, but it happens
4495 infrequently. */
4497 if (xtensa_format_num_slots (xtensa_default_isa, fmt) > 1)
4498 return fmt_size;
4500 /* If we aren't doing one of our own relaxations or it isn't
4501 slot-based, then the insn size won't change. */
4502 if (fragP->fr_type != rs_machine_dependent)
4503 return fmt_size;
4504 if (fragP->fr_subtype != RELAX_SLOTS)
4505 return fmt_size;
4507 /* If an instruction is about to grow, return the longer size. */
4508 if (fragP->tc_frag_data.slot_subtypes[0] == RELAX_IMMED_STEP1
4509 || fragP->tc_frag_data.slot_subtypes[0] == RELAX_IMMED_STEP2
4510 || fragP->tc_frag_data.slot_subtypes[0] == RELAX_IMMED_STEP3)
4512 /* For most frags at RELAX_IMMED_STEPX, with X > 0, the first
4513 instruction in the relaxed version is of length 3. (The case
4514 where we have to pull the instruction out of a FLIX bundle
4515 is handled conservatively above.) However, frags with opcodes
4516 that are expanding to wide branches end up having formats that
4517 are not determinable by the RELAX_IMMED_STEPX enumeration, and
4518 we can't tell directly what format the relaxer picked. This
4519 is a wart in the design of the relaxer that should someday be
4520 fixed, but would require major changes, or at least should
4521 be accompanied by major changes to make use of that data.
4523 In any event, we can tell that we are expanding from a single-slot
4524 format to a wider one with the logic below. */
4526 int i;
4527 int relaxed_size = fmt_size + fragP->tc_frag_data.text_expansion[0];
4529 for (i = 0; i < xtensa_isa_num_formats (isa); i++)
4531 if (relaxed_size == xtensa_format_length (isa, i))
4532 return relaxed_size;
4535 return 3;
4538 if (fragP->tc_frag_data.slot_subtypes[0] == RELAX_NARROW)
4539 return 2 + fragP->tc_frag_data.text_expansion[0];
4541 return fmt_size;
4545 static int
4546 next_frag_format_size (const fragS *fragP)
4548 const fragS *next_fragP = next_non_empty_frag (fragP);
4549 return frag_format_size (next_fragP);
4553 /* In early Xtensa Processors, for reasons that are unclear, the ISA
4554 required two-byte instructions to be treated as three-byte instructions
4555 for loop instruction alignment. This restriction was removed beginning
4556 with Xtensa LX. Now the only requirement on loop instruction alignment
4557 is that the first instruction of the loop must appear at an address that
4558 does not cross a fetch boundary. */
4560 static int
4561 get_loop_align_size (int insn_size)
4563 if (insn_size == XTENSA_UNDEFINED)
4564 return xtensa_fetch_width;
4566 if (enforce_three_byte_loop_align && insn_size == 2)
4567 return 3;
4569 return insn_size;
4573 /* If the next legit fragment is an end-of-loop marker,
4574 switch its state so it will instantiate a NOP. */
4576 static void
4577 update_next_frag_state (fragS *fragP)
4579 fragS *next_fragP = fragP->fr_next;
4580 fragS *new_target = NULL;
4582 if (align_targets)
4584 /* We are guaranteed there will be one of these... */
4585 while (!(next_fragP->fr_type == rs_machine_dependent
4586 && (next_fragP->fr_subtype == RELAX_MAYBE_UNREACHABLE
4587 || next_fragP->fr_subtype == RELAX_UNREACHABLE)))
4588 next_fragP = next_fragP->fr_next;
4590 gas_assert (next_fragP->fr_type == rs_machine_dependent
4591 && (next_fragP->fr_subtype == RELAX_MAYBE_UNREACHABLE
4592 || next_fragP->fr_subtype == RELAX_UNREACHABLE));
4594 /* ...and one of these. */
4595 new_target = next_fragP->fr_next;
4596 while (!(new_target->fr_type == rs_machine_dependent
4597 && (new_target->fr_subtype == RELAX_MAYBE_DESIRE_ALIGN
4598 || new_target->fr_subtype == RELAX_DESIRE_ALIGN)))
4599 new_target = new_target->fr_next;
4601 gas_assert (new_target->fr_type == rs_machine_dependent
4602 && (new_target->fr_subtype == RELAX_MAYBE_DESIRE_ALIGN
4603 || new_target->fr_subtype == RELAX_DESIRE_ALIGN));
4606 while (next_fragP && next_fragP->fr_fix == 0)
4608 if (next_fragP->fr_type == rs_machine_dependent
4609 && next_fragP->fr_subtype == RELAX_LOOP_END)
4611 next_fragP->fr_subtype = RELAX_LOOP_END_ADD_NOP;
4612 return;
4615 next_fragP = next_fragP->fr_next;
4620 static bfd_boolean
4621 next_frag_is_branch_target (const fragS *fragP)
4623 /* Sometimes an empty will end up here due to storage allocation issues,
4624 so we have to skip until we find something legit. */
4625 for (fragP = fragP->fr_next; fragP; fragP = fragP->fr_next)
4627 if (fragP->tc_frag_data.is_branch_target)
4628 return TRUE;
4629 if (fragP->fr_fix != 0)
4630 break;
4632 return FALSE;
4636 static bfd_boolean
4637 next_frag_is_loop_target (const fragS *fragP)
4639 /* Sometimes an empty will end up here due storage allocation issues.
4640 So we have to skip until we find something legit. */
4641 for (fragP = fragP->fr_next; fragP; fragP = fragP->fr_next)
4643 if (fragP->tc_frag_data.is_loop_target)
4644 return TRUE;
4645 if (fragP->fr_fix != 0)
4646 break;
4648 return FALSE;
4652 /* As specified in the relaxation table, when a loop instruction is
4653 relaxed, there are 24 bytes between the loop instruction itself and
4654 the first instruction in the loop. */
4656 #define RELAXED_LOOP_INSN_BYTES 24
4658 static addressT
4659 next_frag_pre_opcode_bytes (const fragS *fragp)
4661 const fragS *next_fragp = fragp->fr_next;
4662 xtensa_opcode next_opcode;
4664 if (!next_frag_opcode_is_loop (fragp, &next_opcode))
4665 return 0;
4667 /* Sometimes an empty will end up here due to storage allocation issues,
4668 so we have to skip until we find something legit. */
4669 while (next_fragp->fr_fix == 0)
4670 next_fragp = next_fragp->fr_next;
4672 if (next_fragp->fr_type != rs_machine_dependent)
4673 return 0;
4675 /* There is some implicit knowledge encoded in here.
4676 The LOOP instructions that are NOT RELAX_IMMED have
4677 been relaxed. Note that we can assume that the LOOP
4678 instruction is in slot 0 because loops aren't bundleable. */
4679 if (next_fragp->tc_frag_data.slot_subtypes[0] > RELAX_IMMED)
4680 return get_expanded_loop_offset (next_opcode) + RELAXED_LOOP_INSN_BYTES;
4682 return 0;
4686 /* Mark a location where we can later insert literal frags. Update
4687 the section's literal_pool_loc, so subsequent literals can be
4688 placed nearest to their use. */
4690 static void
4691 xtensa_mark_literal_pool_location (void)
4693 /* Any labels pointing to the current location need
4694 to be adjusted to after the literal pool. */
4695 emit_state s;
4696 fragS *pool_location;
4698 if (use_literal_section)
4699 return;
4701 /* We stash info in these frags so we can later move the literal's
4702 fixes into this frchain's fix list. */
4703 pool_location = frag_now;
4704 frag_now->tc_frag_data.lit_frchain = frchain_now;
4705 frag_now->tc_frag_data.literal_frag = frag_now;
4706 frag_variant (rs_machine_dependent, 0, 0,
4707 RELAX_LITERAL_POOL_BEGIN, NULL, 0, NULL);
4708 xtensa_set_frag_assembly_state (frag_now);
4709 frag_now->tc_frag_data.lit_seg = now_seg;
4710 frag_variant (rs_machine_dependent, 0, 0,
4711 RELAX_LITERAL_POOL_END, NULL, 0, NULL);
4712 xtensa_set_frag_assembly_state (frag_now);
4714 /* Now put a frag into the literal pool that points to this location. */
4715 set_literal_pool_location (now_seg, pool_location);
4716 xtensa_switch_to_non_abs_literal_fragment (&s);
4717 frag_align (2, 0, 0);
4718 record_alignment (now_seg, 2);
4720 /* Close whatever frag is there. */
4721 frag_variant (rs_fill, 0, 0, 0, NULL, 0, NULL);
4722 xtensa_set_frag_assembly_state (frag_now);
4723 frag_now->tc_frag_data.literal_frag = pool_location;
4724 frag_variant (rs_fill, 0, 0, 0, NULL, 0, NULL);
4725 xtensa_restore_emit_state (&s);
4726 xtensa_set_frag_assembly_state (frag_now);
4730 /* Build a nop of the correct size into tinsn. */
4732 static void
4733 build_nop (TInsn *tinsn, int size)
4735 tinsn_init (tinsn);
4736 switch (size)
4738 case 2:
4739 tinsn->opcode = xtensa_nop_n_opcode;
4740 tinsn->ntok = 0;
4741 if (tinsn->opcode == XTENSA_UNDEFINED)
4742 as_fatal (_("opcode 'NOP.N' unavailable in this configuration"));
4743 break;
4745 case 3:
4746 if (xtensa_nop_opcode == XTENSA_UNDEFINED)
4748 tinsn->opcode = xtensa_or_opcode;
4749 set_expr_const (&tinsn->tok[0], 1);
4750 set_expr_const (&tinsn->tok[1], 1);
4751 set_expr_const (&tinsn->tok[2], 1);
4752 tinsn->ntok = 3;
4754 else
4755 tinsn->opcode = xtensa_nop_opcode;
4757 gas_assert (tinsn->opcode != XTENSA_UNDEFINED);
4762 /* Assemble a NOP of the requested size in the buffer. User must have
4763 allocated "buf" with at least "size" bytes. */
4765 static void
4766 assemble_nop (int size, char *buf)
4768 static xtensa_insnbuf insnbuf = NULL;
4769 TInsn tinsn;
4771 build_nop (&tinsn, size);
4773 if (!insnbuf)
4774 insnbuf = xtensa_insnbuf_alloc (xtensa_default_isa);
4776 tinsn_to_insnbuf (&tinsn, insnbuf);
4777 xtensa_insnbuf_to_chars (xtensa_default_isa, insnbuf,
4778 (unsigned char *) buf, 0);
4782 /* Return the number of bytes for the offset of the expanded loop
4783 instruction. This should be incorporated into the relaxation
4784 specification but is hard-coded here. This is used to auto-align
4785 the loop instruction. It is invalid to call this function if the
4786 configuration does not have loops or if the opcode is not a loop
4787 opcode. */
4789 static addressT
4790 get_expanded_loop_offset (xtensa_opcode opcode)
4792 /* This is the OFFSET of the loop instruction in the expanded loop.
4793 This MUST correspond directly to the specification of the loop
4794 expansion. It will be validated on fragment conversion. */
4795 gas_assert (opcode != XTENSA_UNDEFINED);
4796 if (opcode == xtensa_loop_opcode)
4797 return 0;
4798 if (opcode == xtensa_loopnez_opcode)
4799 return 3;
4800 if (opcode == xtensa_loopgtz_opcode)
4801 return 6;
4802 as_fatal (_("get_expanded_loop_offset: invalid opcode"));
4803 return 0;
4807 static fragS *
4808 get_literal_pool_location (segT seg)
4810 return seg_info (seg)->tc_segment_info_data.literal_pool_loc;
4814 static void
4815 set_literal_pool_location (segT seg, fragS *literal_pool_loc)
4817 seg_info (seg)->tc_segment_info_data.literal_pool_loc = literal_pool_loc;
4821 /* Set frag assembly state should be called when a new frag is
4822 opened and after a frag has been closed. */
4824 static void
4825 xtensa_set_frag_assembly_state (fragS *fragP)
4827 if (!density_supported)
4828 fragP->tc_frag_data.is_no_density = TRUE;
4830 /* This function is called from subsegs_finish, which is called
4831 after xtensa_end, so we can't use "use_transform" or
4832 "use_schedule" here. */
4833 if (!directive_state[directive_transform])
4834 fragP->tc_frag_data.is_no_transform = TRUE;
4835 if (directive_state[directive_longcalls])
4836 fragP->tc_frag_data.use_longcalls = TRUE;
4837 fragP->tc_frag_data.use_absolute_literals =
4838 directive_state[directive_absolute_literals];
4839 fragP->tc_frag_data.is_assembly_state_set = TRUE;
4843 static bfd_boolean
4844 relaxable_section (asection *sec)
4846 return ((sec->flags & SEC_DEBUGGING) == 0
4847 && strcmp (sec->name, ".eh_frame") != 0);
4851 static void
4852 xtensa_mark_frags_for_org (void)
4854 segT *seclist;
4856 /* Walk over each fragment of all of the current segments. If we find
4857 a .org frag in any of the segments, mark all frags prior to it as
4858 "no transform", which will prevent linker optimizations from messing
4859 up the .org distance. This should be done after
4860 xtensa_find_unmarked_state_frags, because we don't want to worry here
4861 about that function trashing the data we save here. */
4863 for (seclist = &stdoutput->sections;
4864 seclist && *seclist;
4865 seclist = &(*seclist)->next)
4867 segT sec = *seclist;
4868 segment_info_type *seginfo;
4869 fragS *fragP;
4870 flagword flags;
4871 flags = bfd_get_section_flags (stdoutput, sec);
4872 if (flags & SEC_DEBUGGING)
4873 continue;
4874 if (!(flags & SEC_ALLOC))
4875 continue;
4877 seginfo = seg_info (sec);
4878 if (seginfo && seginfo->frchainP)
4880 fragS *last_fragP = seginfo->frchainP->frch_root;
4881 for (fragP = seginfo->frchainP->frch_root; fragP;
4882 fragP = fragP->fr_next)
4884 /* cvt_frag_to_fill has changed the fr_type of org frags to
4885 rs_fill, so use the value as cached in rs_subtype here. */
4886 if (fragP->fr_subtype == RELAX_ORG)
4888 while (last_fragP != fragP->fr_next)
4890 last_fragP->tc_frag_data.is_no_transform = TRUE;
4891 last_fragP = last_fragP->fr_next;
4900 static void
4901 xtensa_find_unmarked_state_frags (void)
4903 segT *seclist;
4905 /* Walk over each fragment of all of the current segments. For each
4906 unmarked fragment, mark it with the same info as the previous
4907 fragment. */
4908 for (seclist = &stdoutput->sections;
4909 seclist && *seclist;
4910 seclist = &(*seclist)->next)
4912 segT sec = *seclist;
4913 segment_info_type *seginfo;
4914 fragS *fragP;
4915 flagword flags;
4916 flags = bfd_get_section_flags (stdoutput, sec);
4917 if (flags & SEC_DEBUGGING)
4918 continue;
4919 if (!(flags & SEC_ALLOC))
4920 continue;
4922 seginfo = seg_info (sec);
4923 if (seginfo && seginfo->frchainP)
4925 fragS *last_fragP = 0;
4926 for (fragP = seginfo->frchainP->frch_root; fragP;
4927 fragP = fragP->fr_next)
4929 if (fragP->fr_fix != 0
4930 && !fragP->tc_frag_data.is_assembly_state_set)
4932 if (last_fragP == 0)
4934 as_warn_where (fragP->fr_file, fragP->fr_line,
4935 _("assembly state not set for first frag in section %s"),
4936 sec->name);
4938 else
4940 fragP->tc_frag_data.is_assembly_state_set = TRUE;
4941 fragP->tc_frag_data.is_no_density =
4942 last_fragP->tc_frag_data.is_no_density;
4943 fragP->tc_frag_data.is_no_transform =
4944 last_fragP->tc_frag_data.is_no_transform;
4945 fragP->tc_frag_data.use_longcalls =
4946 last_fragP->tc_frag_data.use_longcalls;
4947 fragP->tc_frag_data.use_absolute_literals =
4948 last_fragP->tc_frag_data.use_absolute_literals;
4951 if (fragP->tc_frag_data.is_assembly_state_set)
4952 last_fragP = fragP;
4959 static void
4960 xtensa_find_unaligned_branch_targets (bfd *abfd ATTRIBUTE_UNUSED,
4961 asection *sec,
4962 void *unused ATTRIBUTE_UNUSED)
4964 flagword flags = bfd_get_section_flags (abfd, sec);
4965 segment_info_type *seginfo = seg_info (sec);
4966 fragS *frag = seginfo->frchainP->frch_root;
4968 if (flags & SEC_CODE)
4970 xtensa_isa isa = xtensa_default_isa;
4971 xtensa_insnbuf insnbuf = xtensa_insnbuf_alloc (isa);
4972 while (frag != NULL)
4974 if (frag->tc_frag_data.is_branch_target)
4976 int op_size;
4977 addressT branch_align, frag_addr;
4978 xtensa_format fmt;
4980 xtensa_insnbuf_from_chars
4981 (isa, insnbuf, (unsigned char *) frag->fr_literal, 0);
4982 fmt = xtensa_format_decode (isa, insnbuf);
4983 op_size = xtensa_format_length (isa, fmt);
4984 branch_align = 1 << branch_align_power (sec);
4985 frag_addr = frag->fr_address % branch_align;
4986 if (frag_addr + op_size > branch_align)
4987 as_warn_where (frag->fr_file, frag->fr_line,
4988 _("unaligned branch target: %d bytes at 0x%lx"),
4989 op_size, (long) frag->fr_address);
4991 frag = frag->fr_next;
4993 xtensa_insnbuf_free (isa, insnbuf);
4998 static void
4999 xtensa_find_unaligned_loops (bfd *abfd ATTRIBUTE_UNUSED,
5000 asection *sec,
5001 void *unused ATTRIBUTE_UNUSED)
5003 flagword flags = bfd_get_section_flags (abfd, sec);
5004 segment_info_type *seginfo = seg_info (sec);
5005 fragS *frag = seginfo->frchainP->frch_root;
5006 xtensa_isa isa = xtensa_default_isa;
5008 if (flags & SEC_CODE)
5010 xtensa_insnbuf insnbuf = xtensa_insnbuf_alloc (isa);
5011 while (frag != NULL)
5013 if (frag->tc_frag_data.is_first_loop_insn)
5015 int op_size;
5016 addressT frag_addr;
5017 xtensa_format fmt;
5019 if (frag->fr_fix == 0)
5020 frag = next_non_empty_frag (frag);
5022 if (frag)
5024 xtensa_insnbuf_from_chars
5025 (isa, insnbuf, (unsigned char *) frag->fr_literal, 0);
5026 fmt = xtensa_format_decode (isa, insnbuf);
5027 op_size = xtensa_format_length (isa, fmt);
5028 frag_addr = frag->fr_address % xtensa_fetch_width;
5030 if (frag_addr + op_size > xtensa_fetch_width)
5031 as_warn_where (frag->fr_file, frag->fr_line,
5032 _("unaligned loop: %d bytes at 0x%lx"),
5033 op_size, (long) frag->fr_address);
5036 frag = frag->fr_next;
5038 xtensa_insnbuf_free (isa, insnbuf);
5043 static int
5044 xg_apply_fix_value (fixS *fixP, valueT val)
5046 xtensa_isa isa = xtensa_default_isa;
5047 static xtensa_insnbuf insnbuf = NULL;
5048 static xtensa_insnbuf slotbuf = NULL;
5049 xtensa_format fmt;
5050 int slot;
5051 bfd_boolean alt_reloc;
5052 xtensa_opcode opcode;
5053 char *const fixpos = fixP->fx_frag->fr_literal + fixP->fx_where;
5055 if (decode_reloc (fixP->fx_r_type, &slot, &alt_reloc)
5056 || alt_reloc)
5057 as_fatal (_("unexpected fix"));
5059 if (!insnbuf)
5061 insnbuf = xtensa_insnbuf_alloc (isa);
5062 slotbuf = xtensa_insnbuf_alloc (isa);
5065 xtensa_insnbuf_from_chars (isa, insnbuf, (unsigned char *) fixpos, 0);
5066 fmt = xtensa_format_decode (isa, insnbuf);
5067 if (fmt == XTENSA_UNDEFINED)
5068 as_fatal (_("undecodable fix"));
5069 xtensa_format_get_slot (isa, fmt, slot, insnbuf, slotbuf);
5070 opcode = xtensa_opcode_decode (isa, fmt, slot, slotbuf);
5071 if (opcode == XTENSA_UNDEFINED)
5072 as_fatal (_("undecodable fix"));
5074 /* CONST16 immediates are not PC-relative, despite the fact that we
5075 reuse the normal PC-relative operand relocations for the low part
5076 of a CONST16 operand. */
5077 if (opcode == xtensa_const16_opcode)
5078 return 0;
5080 xtensa_insnbuf_set_operand (slotbuf, fmt, slot, opcode,
5081 get_relaxable_immed (opcode), val,
5082 fixP->fx_file, fixP->fx_line);
5084 xtensa_format_set_slot (isa, fmt, slot, insnbuf, slotbuf);
5085 xtensa_insnbuf_to_chars (isa, insnbuf, (unsigned char *) fixpos, 0);
5087 return 1;
5091 /* External Functions and Other GAS Hooks. */
5093 const char *
5094 xtensa_target_format (void)
5096 return (target_big_endian ? "elf32-xtensa-be" : "elf32-xtensa-le");
5100 void
5101 xtensa_file_arch_init (bfd *abfd)
5103 bfd_set_private_flags (abfd, 0x100 | 0x200);
5107 void
5108 md_number_to_chars (char *buf, valueT val, int n)
5110 if (target_big_endian)
5111 number_to_chars_bigendian (buf, val, n);
5112 else
5113 number_to_chars_littleendian (buf, val, n);
5117 /* This function is called once, at assembler startup time. It should
5118 set up all the tables, etc. that the MD part of the assembler will
5119 need. */
5121 void
5122 md_begin (void)
5124 segT current_section = now_seg;
5125 int current_subsec = now_subseg;
5126 xtensa_isa isa;
5127 int i;
5129 xtensa_default_isa = xtensa_isa_init (0, 0);
5130 isa = xtensa_default_isa;
5132 linkrelax = 1;
5134 /* Set up the literal sections. */
5135 memset (&default_lit_sections, 0, sizeof (default_lit_sections));
5137 subseg_set (current_section, current_subsec);
5139 xtensa_addi_opcode = xtensa_opcode_lookup (isa, "addi");
5140 xtensa_addmi_opcode = xtensa_opcode_lookup (isa, "addmi");
5141 xtensa_call0_opcode = xtensa_opcode_lookup (isa, "call0");
5142 xtensa_call4_opcode = xtensa_opcode_lookup (isa, "call4");
5143 xtensa_call8_opcode = xtensa_opcode_lookup (isa, "call8");
5144 xtensa_call12_opcode = xtensa_opcode_lookup (isa, "call12");
5145 xtensa_callx0_opcode = xtensa_opcode_lookup (isa, "callx0");
5146 xtensa_callx4_opcode = xtensa_opcode_lookup (isa, "callx4");
5147 xtensa_callx8_opcode = xtensa_opcode_lookup (isa, "callx8");
5148 xtensa_callx12_opcode = xtensa_opcode_lookup (isa, "callx12");
5149 xtensa_const16_opcode = xtensa_opcode_lookup (isa, "const16");
5150 xtensa_entry_opcode = xtensa_opcode_lookup (isa, "entry");
5151 xtensa_extui_opcode = xtensa_opcode_lookup (isa, "extui");
5152 xtensa_movi_opcode = xtensa_opcode_lookup (isa, "movi");
5153 xtensa_movi_n_opcode = xtensa_opcode_lookup (isa, "movi.n");
5154 xtensa_isync_opcode = xtensa_opcode_lookup (isa, "isync");
5155 xtensa_j_opcode = xtensa_opcode_lookup (isa, "j");
5156 xtensa_jx_opcode = xtensa_opcode_lookup (isa, "jx");
5157 xtensa_l32r_opcode = xtensa_opcode_lookup (isa, "l32r");
5158 xtensa_loop_opcode = xtensa_opcode_lookup (isa, "loop");
5159 xtensa_loopnez_opcode = xtensa_opcode_lookup (isa, "loopnez");
5160 xtensa_loopgtz_opcode = xtensa_opcode_lookup (isa, "loopgtz");
5161 xtensa_nop_opcode = xtensa_opcode_lookup (isa, "nop");
5162 xtensa_nop_n_opcode = xtensa_opcode_lookup (isa, "nop.n");
5163 xtensa_or_opcode = xtensa_opcode_lookup (isa, "or");
5164 xtensa_ret_opcode = xtensa_opcode_lookup (isa, "ret");
5165 xtensa_ret_n_opcode = xtensa_opcode_lookup (isa, "ret.n");
5166 xtensa_retw_opcode = xtensa_opcode_lookup (isa, "retw");
5167 xtensa_retw_n_opcode = xtensa_opcode_lookup (isa, "retw.n");
5168 xtensa_rsr_lcount_opcode = xtensa_opcode_lookup (isa, "rsr.lcount");
5169 xtensa_waiti_opcode = xtensa_opcode_lookup (isa, "waiti");
5171 for (i = 0; i < xtensa_isa_num_formats (isa); i++)
5173 int format_slots = xtensa_format_num_slots (isa, i);
5174 if (format_slots > config_max_slots)
5175 config_max_slots = format_slots;
5178 xg_init_vinsn (&cur_vinsn);
5180 xtensa_num_pipe_stages = xtensa_isa_num_pipe_stages (isa);
5182 init_op_placement_info_table ();
5184 /* Set up the assembly state. */
5185 if (!frag_now->tc_frag_data.is_assembly_state_set)
5186 xtensa_set_frag_assembly_state (frag_now);
5190 /* TC_INIT_FIX_DATA hook */
5192 void
5193 xtensa_init_fix_data (fixS *x)
5195 x->tc_fix_data.slot = 0;
5196 x->tc_fix_data.X_add_symbol = NULL;
5197 x->tc_fix_data.X_add_number = 0;
5201 /* tc_frob_label hook */
5203 void
5204 xtensa_frob_label (symbolS *sym)
5206 float freq;
5208 if (cur_vinsn.inside_bundle)
5210 as_bad (_("labels are not valid inside bundles"));
5211 return;
5214 freq = get_subseg_target_freq (now_seg, now_subseg);
5216 /* Since the label was already attached to a frag associated with the
5217 previous basic block, it now needs to be reset to the current frag. */
5218 symbol_set_frag (sym, frag_now);
5219 S_SET_VALUE (sym, (valueT) frag_now_fix ());
5221 if (generating_literals)
5222 xtensa_add_literal_sym (sym);
5223 else
5224 xtensa_add_insn_label (sym);
5226 if (symbol_get_tc (sym)->is_loop_target)
5228 if ((get_last_insn_flags (now_seg, now_subseg)
5229 & FLAG_IS_BAD_LOOPEND) != 0)
5230 as_bad (_("invalid last instruction for a zero-overhead loop"));
5232 xtensa_set_frag_assembly_state (frag_now);
5233 frag_var (rs_machine_dependent, 4, 4, RELAX_LOOP_END,
5234 frag_now->fr_symbol, frag_now->fr_offset, NULL);
5236 xtensa_set_frag_assembly_state (frag_now);
5237 xtensa_move_labels (frag_now, 0);
5240 /* No target aligning in the absolute section. */
5241 if (now_seg != absolute_section
5242 && !is_unaligned_label (sym)
5243 && !generating_literals)
5245 xtensa_set_frag_assembly_state (frag_now);
5247 if (do_align_targets ())
5248 frag_var (rs_machine_dependent, 0, (int) freq,
5249 RELAX_DESIRE_ALIGN_IF_TARGET, frag_now->fr_symbol,
5250 frag_now->fr_offset, NULL);
5251 else
5252 frag_var (rs_fill, 0, 0, frag_now->fr_subtype,
5253 frag_now->fr_symbol, frag_now->fr_offset, NULL);
5254 xtensa_set_frag_assembly_state (frag_now);
5255 xtensa_move_labels (frag_now, 0);
5258 /* We need to mark the following properties even if we aren't aligning. */
5260 /* If the label is already known to be a branch target, i.e., a
5261 forward branch, mark the frag accordingly. Backward branches
5262 are handled by xg_add_branch_and_loop_targets. */
5263 if (symbol_get_tc (sym)->is_branch_target)
5264 symbol_get_frag (sym)->tc_frag_data.is_branch_target = TRUE;
5266 /* Loops only go forward, so they can be identified here. */
5267 if (symbol_get_tc (sym)->is_loop_target)
5268 symbol_get_frag (sym)->tc_frag_data.is_loop_target = TRUE;
5270 dwarf2_emit_label (sym);
5274 /* tc_unrecognized_line hook */
5277 xtensa_unrecognized_line (int ch)
5279 switch (ch)
5281 case '{' :
5282 if (cur_vinsn.inside_bundle == 0)
5284 /* PR8110: Cannot emit line number info inside a FLIX bundle
5285 when using --gstabs. Temporarily disable debug info. */
5286 generate_lineno_debug ();
5287 if (debug_type == DEBUG_STABS)
5289 xt_saved_debug_type = debug_type;
5290 debug_type = DEBUG_NONE;
5293 cur_vinsn.inside_bundle = 1;
5295 else
5297 as_bad (_("extra opening brace"));
5298 return 0;
5300 break;
5302 case '}' :
5303 if (cur_vinsn.inside_bundle)
5304 finish_vinsn (&cur_vinsn);
5305 else
5307 as_bad (_("extra closing brace"));
5308 return 0;
5310 break;
5311 default:
5312 as_bad (_("syntax error"));
5313 return 0;
5315 return 1;
5319 /* md_flush_pending_output hook */
5321 void
5322 xtensa_flush_pending_output (void)
5324 /* This line fixes a bug where automatically generated gstabs info
5325 separates a function label from its entry instruction, ending up
5326 with the literal position between the function label and the entry
5327 instruction and crashing code. It only happens with --gstabs and
5328 --text-section-literals, and when several other obscure relaxation
5329 conditions are met. */
5330 if (outputting_stabs_line_debug)
5331 return;
5333 if (cur_vinsn.inside_bundle)
5334 as_bad (_("missing closing brace"));
5336 /* If there is a non-zero instruction fragment, close it. */
5337 if (frag_now_fix () != 0 && frag_now->tc_frag_data.is_insn)
5339 frag_wane (frag_now);
5340 frag_new (0);
5341 xtensa_set_frag_assembly_state (frag_now);
5343 frag_now->tc_frag_data.is_insn = FALSE;
5345 xtensa_clear_insn_labels ();
5349 /* We had an error while parsing an instruction. The string might look
5350 like this: "insn arg1, arg2 }". If so, we need to see the closing
5351 brace and reset some fields. Otherwise, the vinsn never gets closed
5352 and the num_slots field will grow past the end of the array of slots,
5353 and bad things happen. */
5355 static void
5356 error_reset_cur_vinsn (void)
5358 if (cur_vinsn.inside_bundle)
5360 if (*input_line_pointer == '}'
5361 || *(input_line_pointer - 1) == '}'
5362 || *(input_line_pointer - 2) == '}')
5363 xg_clear_vinsn (&cur_vinsn);
5368 void
5369 md_assemble (char *str)
5371 xtensa_isa isa = xtensa_default_isa;
5372 char *opname;
5373 unsigned opnamelen;
5374 bfd_boolean has_underbar = FALSE;
5375 char *arg_strings[MAX_INSN_ARGS];
5376 int num_args;
5377 TInsn orig_insn; /* Original instruction from the input. */
5379 tinsn_init (&orig_insn);
5381 /* Split off the opcode. */
5382 opnamelen = strspn (str, "abcdefghijklmnopqrstuvwxyz_/0123456789.");
5383 opname = xmalloc (opnamelen + 1);
5384 memcpy (opname, str, opnamelen);
5385 opname[opnamelen] = '\0';
5387 num_args = tokenize_arguments (arg_strings, str + opnamelen);
5388 if (num_args == -1)
5390 as_bad (_("syntax error"));
5391 return;
5394 if (xg_translate_idioms (&opname, &num_args, arg_strings))
5395 return;
5397 /* Check for an underbar prefix. */
5398 if (*opname == '_')
5400 has_underbar = TRUE;
5401 opname += 1;
5404 orig_insn.insn_type = ITYPE_INSN;
5405 orig_insn.ntok = 0;
5406 orig_insn.is_specific_opcode = (has_underbar || !use_transform ());
5407 orig_insn.opcode = xtensa_opcode_lookup (isa, opname);
5409 /* Special case: Check for "CALLXn.TLS" psuedo op. If found, grab its
5410 extra argument and set the opcode to "CALLXn". */
5411 if (orig_insn.opcode == XTENSA_UNDEFINED
5412 && strncasecmp (opname, "callx", 5) == 0)
5414 unsigned long window_size;
5415 char *suffix;
5417 window_size = strtoul (opname + 5, &suffix, 10);
5418 if (suffix != opname + 5
5419 && (window_size == 0
5420 || window_size == 4
5421 || window_size == 8
5422 || window_size == 12)
5423 && strcasecmp (suffix, ".tls") == 0)
5425 switch (window_size)
5427 case 0: orig_insn.opcode = xtensa_callx0_opcode; break;
5428 case 4: orig_insn.opcode = xtensa_callx4_opcode; break;
5429 case 8: orig_insn.opcode = xtensa_callx8_opcode; break;
5430 case 12: orig_insn.opcode = xtensa_callx12_opcode; break;
5433 if (num_args != 2)
5434 as_bad (_("wrong number of operands for '%s'"), opname);
5435 else
5437 bfd_reloc_code_real_type reloc;
5438 char *old_input_line_pointer;
5439 expressionS *tok = &orig_insn.extra_arg;
5440 segT t;
5442 old_input_line_pointer = input_line_pointer;
5443 input_line_pointer = arg_strings[num_args - 1];
5445 t = expression (tok);
5446 if (tok->X_op == O_symbol
5447 && ((reloc = xtensa_elf_suffix (&input_line_pointer, tok))
5448 == BFD_RELOC_XTENSA_TLS_CALL))
5449 tok->X_op = map_suffix_reloc_to_operator (reloc);
5450 else
5451 as_bad (_("bad relocation expression for '%s'"), opname);
5453 input_line_pointer = old_input_line_pointer;
5454 num_args -= 1;
5459 /* Special case: Check for "j.l" psuedo op. */
5460 if (orig_insn.opcode == XTENSA_UNDEFINED
5461 && strncasecmp (opname, "j.l", 3) == 0)
5463 if (num_args != 2)
5464 as_bad (_("wrong number of operands for '%s'"), opname);
5465 else
5467 char *old_input_line_pointer;
5468 expressionS *tok = &orig_insn.extra_arg;
5470 old_input_line_pointer = input_line_pointer;
5471 input_line_pointer = arg_strings[num_args - 1];
5473 expression_maybe_register (xtensa_jx_opcode, 0, tok);
5474 input_line_pointer = old_input_line_pointer;
5476 num_args -= 1;
5477 orig_insn.opcode = xtensa_j_opcode;
5481 if (orig_insn.opcode == XTENSA_UNDEFINED)
5483 xtensa_format fmt = xtensa_format_lookup (isa, opname);
5484 if (fmt == XTENSA_UNDEFINED)
5486 as_bad (_("unknown opcode or format name '%s'"), opname);
5487 error_reset_cur_vinsn ();
5488 return;
5490 if (!cur_vinsn.inside_bundle)
5492 as_bad (_("format names only valid inside bundles"));
5493 error_reset_cur_vinsn ();
5494 return;
5496 if (cur_vinsn.format != XTENSA_UNDEFINED)
5497 as_warn (_("multiple formats specified for one bundle; using '%s'"),
5498 opname);
5499 cur_vinsn.format = fmt;
5500 free (has_underbar ? opname - 1 : opname);
5501 error_reset_cur_vinsn ();
5502 return;
5505 /* Parse the arguments. */
5506 if (parse_arguments (&orig_insn, num_args, arg_strings))
5508 as_bad (_("syntax error"));
5509 error_reset_cur_vinsn ();
5510 return;
5513 /* Free the opcode and argument strings, now that they've been parsed. */
5514 free (has_underbar ? opname - 1 : opname);
5515 opname = 0;
5516 while (num_args-- > 0)
5517 free (arg_strings[num_args]);
5519 /* Get expressions for invisible operands. */
5520 if (get_invisible_operands (&orig_insn))
5522 error_reset_cur_vinsn ();
5523 return;
5526 /* Check for the right number and type of arguments. */
5527 if (tinsn_check_arguments (&orig_insn))
5529 error_reset_cur_vinsn ();
5530 return;
5533 /* Record the line number for each TInsn, because a FLIX bundle may be
5534 spread across multiple input lines and individual instructions may be
5535 moved around in some cases. */
5536 orig_insn.loc_directive_seen = dwarf2_loc_directive_seen;
5537 dwarf2_where (&orig_insn.debug_line);
5538 dwarf2_consume_line_info ();
5540 xg_add_branch_and_loop_targets (&orig_insn);
5542 /* Check that immediate value for ENTRY is >= 16. */
5543 if (orig_insn.opcode == xtensa_entry_opcode && orig_insn.ntok >= 3)
5545 expressionS *exp = &orig_insn.tok[2];
5546 if (exp->X_op == O_constant && exp->X_add_number < 16)
5547 as_warn (_("entry instruction with stack decrement < 16"));
5550 /* Finish it off:
5551 assemble_tokens (opcode, tok, ntok);
5552 expand the tokens from the orig_insn into the
5553 stack of instructions that will not expand
5554 unless required at relaxation time. */
5556 if (!cur_vinsn.inside_bundle)
5557 emit_single_op (&orig_insn);
5558 else /* We are inside a bundle. */
5560 cur_vinsn.slots[cur_vinsn.num_slots] = orig_insn;
5561 cur_vinsn.num_slots++;
5562 if (*input_line_pointer == '}'
5563 || *(input_line_pointer - 1) == '}'
5564 || *(input_line_pointer - 2) == '}')
5565 finish_vinsn (&cur_vinsn);
5568 /* We've just emitted a new instruction so clear the list of labels. */
5569 xtensa_clear_insn_labels ();
5573 /* HANDLE_ALIGN hook */
5575 /* For a .align directive, we mark the previous block with the alignment
5576 information. This will be placed in the object file in the
5577 property section corresponding to this section. */
5579 void
5580 xtensa_handle_align (fragS *fragP)
5582 if (linkrelax
5583 && ! fragP->tc_frag_data.is_literal
5584 && (fragP->fr_type == rs_align
5585 || fragP->fr_type == rs_align_code)
5586 && fragP->fr_address + fragP->fr_fix > 0
5587 && fragP->fr_offset > 0
5588 && now_seg != bss_section)
5590 fragP->tc_frag_data.is_align = TRUE;
5591 fragP->tc_frag_data.alignment = fragP->fr_offset;
5594 if (fragP->fr_type == rs_align_test)
5596 int count;
5597 count = fragP->fr_next->fr_address - fragP->fr_address - fragP->fr_fix;
5598 if (count != 0)
5599 as_bad_where (fragP->fr_file, fragP->fr_line,
5600 _("unaligned entry instruction"));
5603 if (linkrelax && fragP->fr_type == rs_org)
5604 fragP->fr_subtype = RELAX_ORG;
5608 /* TC_FRAG_INIT hook */
5610 void
5611 xtensa_frag_init (fragS *frag)
5613 xtensa_set_frag_assembly_state (frag);
5617 symbolS *
5618 md_undefined_symbol (char *name ATTRIBUTE_UNUSED)
5620 return NULL;
5624 /* Round up a section size to the appropriate boundary. */
5626 valueT
5627 md_section_align (segT segment ATTRIBUTE_UNUSED, valueT size)
5629 return size; /* Byte alignment is fine. */
5633 long
5634 md_pcrel_from (fixS *fixP)
5636 char *insn_p;
5637 static xtensa_insnbuf insnbuf = NULL;
5638 static xtensa_insnbuf slotbuf = NULL;
5639 int opnum;
5640 uint32 opnd_value;
5641 xtensa_opcode opcode;
5642 xtensa_format fmt;
5643 int slot;
5644 xtensa_isa isa = xtensa_default_isa;
5645 valueT addr = fixP->fx_where + fixP->fx_frag->fr_address;
5646 bfd_boolean alt_reloc;
5648 if (fixP->fx_r_type == BFD_RELOC_XTENSA_ASM_EXPAND)
5649 return 0;
5651 if (fixP->fx_r_type == BFD_RELOC_32_PCREL)
5652 return addr;
5654 if (!insnbuf)
5656 insnbuf = xtensa_insnbuf_alloc (isa);
5657 slotbuf = xtensa_insnbuf_alloc (isa);
5660 insn_p = &fixP->fx_frag->fr_literal[fixP->fx_where];
5661 xtensa_insnbuf_from_chars (isa, insnbuf, (unsigned char *) insn_p, 0);
5662 fmt = xtensa_format_decode (isa, insnbuf);
5664 if (fmt == XTENSA_UNDEFINED)
5665 as_fatal (_("bad instruction format"));
5667 if (decode_reloc (fixP->fx_r_type, &slot, &alt_reloc) != 0)
5668 as_fatal (_("invalid relocation"));
5670 xtensa_format_get_slot (isa, fmt, slot, insnbuf, slotbuf);
5671 opcode = xtensa_opcode_decode (isa, fmt, slot, slotbuf);
5673 /* Check for "alternate" relocations (operand not specified). None
5674 of the current uses for these are really PC-relative. */
5675 if (alt_reloc || opcode == xtensa_const16_opcode)
5677 if (opcode != xtensa_l32r_opcode
5678 && opcode != xtensa_const16_opcode)
5679 as_fatal (_("invalid relocation for '%s' instruction"),
5680 xtensa_opcode_name (isa, opcode));
5681 return 0;
5684 opnum = get_relaxable_immed (opcode);
5685 opnd_value = 0;
5686 if (xtensa_operand_is_PCrelative (isa, opcode, opnum) != 1
5687 || xtensa_operand_do_reloc (isa, opcode, opnum, &opnd_value, addr))
5689 as_bad_where (fixP->fx_file,
5690 fixP->fx_line,
5691 _("invalid relocation for operand %d of '%s'"),
5692 opnum, xtensa_opcode_name (isa, opcode));
5693 return 0;
5695 return 0 - opnd_value;
5699 /* TC_FORCE_RELOCATION hook */
5702 xtensa_force_relocation (fixS *fix)
5704 switch (fix->fx_r_type)
5706 case BFD_RELOC_XTENSA_ASM_EXPAND:
5707 case BFD_RELOC_XTENSA_SLOT0_ALT:
5708 case BFD_RELOC_XTENSA_SLOT1_ALT:
5709 case BFD_RELOC_XTENSA_SLOT2_ALT:
5710 case BFD_RELOC_XTENSA_SLOT3_ALT:
5711 case BFD_RELOC_XTENSA_SLOT4_ALT:
5712 case BFD_RELOC_XTENSA_SLOT5_ALT:
5713 case BFD_RELOC_XTENSA_SLOT6_ALT:
5714 case BFD_RELOC_XTENSA_SLOT7_ALT:
5715 case BFD_RELOC_XTENSA_SLOT8_ALT:
5716 case BFD_RELOC_XTENSA_SLOT9_ALT:
5717 case BFD_RELOC_XTENSA_SLOT10_ALT:
5718 case BFD_RELOC_XTENSA_SLOT11_ALT:
5719 case BFD_RELOC_XTENSA_SLOT12_ALT:
5720 case BFD_RELOC_XTENSA_SLOT13_ALT:
5721 case BFD_RELOC_XTENSA_SLOT14_ALT:
5722 return 1;
5723 default:
5724 break;
5727 if (linkrelax && fix->fx_addsy
5728 && relaxable_section (S_GET_SEGMENT (fix->fx_addsy)))
5729 return 1;
5731 return generic_force_reloc (fix);
5735 /* TC_VALIDATE_FIX_SUB hook */
5738 xtensa_validate_fix_sub (fixS *fix)
5740 segT add_symbol_segment, sub_symbol_segment;
5742 /* The difference of two symbols should be resolved by the assembler when
5743 linkrelax is not set. If the linker may relax the section containing
5744 the symbols, then an Xtensa DIFF relocation must be generated so that
5745 the linker knows to adjust the difference value. */
5746 if (!linkrelax || fix->fx_addsy == NULL)
5747 return 0;
5749 /* Make sure both symbols are in the same segment, and that segment is
5750 "normal" and relaxable. If the segment is not "normal", then the
5751 fix is not valid. If the segment is not "relaxable", then the fix
5752 should have been handled earlier. */
5753 add_symbol_segment = S_GET_SEGMENT (fix->fx_addsy);
5754 if (! SEG_NORMAL (add_symbol_segment) ||
5755 ! relaxable_section (add_symbol_segment))
5756 return 0;
5757 sub_symbol_segment = S_GET_SEGMENT (fix->fx_subsy);
5758 return (sub_symbol_segment == add_symbol_segment);
5762 /* NO_PSEUDO_DOT hook */
5764 /* This function has nothing to do with pseudo dots, but this is the
5765 nearest macro to where the check needs to take place. FIXME: This
5766 seems wrong. */
5768 bfd_boolean
5769 xtensa_check_inside_bundle (void)
5771 if (cur_vinsn.inside_bundle && input_line_pointer[-1] == '.')
5772 as_bad (_("directives are not valid inside bundles"));
5774 /* This function must always return FALSE because it is called via a
5775 macro that has nothing to do with bundling. */
5776 return FALSE;
5780 /* md_elf_section_change_hook */
5782 void
5783 xtensa_elf_section_change_hook (void)
5785 /* Set up the assembly state. */
5786 if (!frag_now->tc_frag_data.is_assembly_state_set)
5787 xtensa_set_frag_assembly_state (frag_now);
5791 /* tc_fix_adjustable hook */
5793 bfd_boolean
5794 xtensa_fix_adjustable (fixS *fixP)
5796 /* We need the symbol name for the VTABLE entries. */
5797 if (fixP->fx_r_type == BFD_RELOC_VTABLE_INHERIT
5798 || fixP->fx_r_type == BFD_RELOC_VTABLE_ENTRY)
5799 return 0;
5801 return 1;
5805 /* tc_symbol_new_hook */
5807 symbolS *expr_symbols = NULL;
5809 void
5810 xtensa_symbol_new_hook (symbolS *sym)
5812 if (is_leb128_expr && S_GET_SEGMENT (sym) == expr_section)
5814 symbol_get_tc (sym)->next_expr_symbol = expr_symbols;
5815 expr_symbols = sym;
5820 void
5821 md_apply_fix (fixS *fixP, valueT *valP, segT seg)
5823 char *const fixpos = fixP->fx_frag->fr_literal + fixP->fx_where;
5824 valueT val = 0;
5826 /* Subtracted symbols are only allowed for a few relocation types, and
5827 unless linkrelax is enabled, they should not make it to this point. */
5828 if (fixP->fx_subsy && !(linkrelax && (fixP->fx_r_type == BFD_RELOC_32
5829 || fixP->fx_r_type == BFD_RELOC_16
5830 || fixP->fx_r_type == BFD_RELOC_8)))
5831 as_bad_where (fixP->fx_file, fixP->fx_line, _("expression too complex"));
5833 switch (fixP->fx_r_type)
5835 case BFD_RELOC_32_PCREL:
5836 case BFD_RELOC_32:
5837 case BFD_RELOC_16:
5838 case BFD_RELOC_8:
5839 if (fixP->fx_subsy)
5841 switch (fixP->fx_r_type)
5843 case BFD_RELOC_8:
5844 fixP->fx_r_type = BFD_RELOC_XTENSA_DIFF8;
5845 break;
5846 case BFD_RELOC_16:
5847 fixP->fx_r_type = BFD_RELOC_XTENSA_DIFF16;
5848 break;
5849 case BFD_RELOC_32:
5850 fixP->fx_r_type = BFD_RELOC_XTENSA_DIFF32;
5851 break;
5852 default:
5853 break;
5856 val = (S_GET_VALUE (fixP->fx_addsy) + fixP->fx_offset
5857 - S_GET_VALUE (fixP->fx_subsy));
5859 /* The difference value gets written out, and the DIFF reloc
5860 identifies the address of the subtracted symbol (i.e., the one
5861 with the lowest address). */
5862 *valP = val;
5863 fixP->fx_offset -= val;
5864 fixP->fx_subsy = NULL;
5866 else if (! fixP->fx_addsy)
5868 val = *valP;
5869 fixP->fx_done = 1;
5871 /* fall through */
5873 case BFD_RELOC_XTENSA_PLT:
5874 md_number_to_chars (fixpos, val, fixP->fx_size);
5875 fixP->fx_no_overflow = 0; /* Use the standard overflow check. */
5876 break;
5878 case BFD_RELOC_XTENSA_TLSDESC_FN:
5879 case BFD_RELOC_XTENSA_TLSDESC_ARG:
5880 case BFD_RELOC_XTENSA_TLS_TPOFF:
5881 case BFD_RELOC_XTENSA_TLS_DTPOFF:
5882 S_SET_THREAD_LOCAL (fixP->fx_addsy);
5883 md_number_to_chars (fixpos, 0, fixP->fx_size);
5884 fixP->fx_no_overflow = 0; /* Use the standard overflow check. */
5885 break;
5887 case BFD_RELOC_XTENSA_SLOT0_OP:
5888 case BFD_RELOC_XTENSA_SLOT1_OP:
5889 case BFD_RELOC_XTENSA_SLOT2_OP:
5890 case BFD_RELOC_XTENSA_SLOT3_OP:
5891 case BFD_RELOC_XTENSA_SLOT4_OP:
5892 case BFD_RELOC_XTENSA_SLOT5_OP:
5893 case BFD_RELOC_XTENSA_SLOT6_OP:
5894 case BFD_RELOC_XTENSA_SLOT7_OP:
5895 case BFD_RELOC_XTENSA_SLOT8_OP:
5896 case BFD_RELOC_XTENSA_SLOT9_OP:
5897 case BFD_RELOC_XTENSA_SLOT10_OP:
5898 case BFD_RELOC_XTENSA_SLOT11_OP:
5899 case BFD_RELOC_XTENSA_SLOT12_OP:
5900 case BFD_RELOC_XTENSA_SLOT13_OP:
5901 case BFD_RELOC_XTENSA_SLOT14_OP:
5902 if (linkrelax)
5904 /* Write the tentative value of a PC-relative relocation to a
5905 local symbol into the instruction. The value will be ignored
5906 by the linker, and it makes the object file disassembly
5907 readable when all branch targets are encoded in relocations. */
5909 gas_assert (fixP->fx_addsy);
5910 if (S_GET_SEGMENT (fixP->fx_addsy) == seg
5911 && !S_FORCE_RELOC (fixP->fx_addsy, 1))
5913 val = (S_GET_VALUE (fixP->fx_addsy) + fixP->fx_offset
5914 - md_pcrel_from (fixP));
5915 (void) xg_apply_fix_value (fixP, val);
5918 else if (! fixP->fx_addsy)
5920 val = *valP;
5921 if (xg_apply_fix_value (fixP, val))
5922 fixP->fx_done = 1;
5924 break;
5926 case BFD_RELOC_XTENSA_ASM_EXPAND:
5927 case BFD_RELOC_XTENSA_TLS_FUNC:
5928 case BFD_RELOC_XTENSA_TLS_ARG:
5929 case BFD_RELOC_XTENSA_TLS_CALL:
5930 case BFD_RELOC_XTENSA_SLOT0_ALT:
5931 case BFD_RELOC_XTENSA_SLOT1_ALT:
5932 case BFD_RELOC_XTENSA_SLOT2_ALT:
5933 case BFD_RELOC_XTENSA_SLOT3_ALT:
5934 case BFD_RELOC_XTENSA_SLOT4_ALT:
5935 case BFD_RELOC_XTENSA_SLOT5_ALT:
5936 case BFD_RELOC_XTENSA_SLOT6_ALT:
5937 case BFD_RELOC_XTENSA_SLOT7_ALT:
5938 case BFD_RELOC_XTENSA_SLOT8_ALT:
5939 case BFD_RELOC_XTENSA_SLOT9_ALT:
5940 case BFD_RELOC_XTENSA_SLOT10_ALT:
5941 case BFD_RELOC_XTENSA_SLOT11_ALT:
5942 case BFD_RELOC_XTENSA_SLOT12_ALT:
5943 case BFD_RELOC_XTENSA_SLOT13_ALT:
5944 case BFD_RELOC_XTENSA_SLOT14_ALT:
5945 /* These all need to be resolved at link-time. Do nothing now. */
5946 break;
5948 case BFD_RELOC_VTABLE_INHERIT:
5949 case BFD_RELOC_VTABLE_ENTRY:
5950 fixP->fx_done = 0;
5951 break;
5953 default:
5954 as_bad (_("unhandled local relocation fix %s"),
5955 bfd_get_reloc_code_name (fixP->fx_r_type));
5960 char *
5961 md_atof (int type, char *litP, int *sizeP)
5963 return ieee_md_atof (type, litP, sizeP, target_big_endian);
5968 md_estimate_size_before_relax (fragS *fragP, segT seg ATTRIBUTE_UNUSED)
5970 return total_frag_text_expansion (fragP);
5974 /* Translate internal representation of relocation info to BFD target
5975 format. */
5977 arelent *
5978 tc_gen_reloc (asection *section ATTRIBUTE_UNUSED, fixS *fixp)
5980 arelent *reloc;
5982 reloc = (arelent *) xmalloc (sizeof (arelent));
5983 reloc->sym_ptr_ptr = (asymbol **) xmalloc (sizeof (asymbol *));
5984 *reloc->sym_ptr_ptr = symbol_get_bfdsym (fixp->fx_addsy);
5985 reloc->address = fixp->fx_frag->fr_address + fixp->fx_where;
5987 /* Make sure none of our internal relocations make it this far.
5988 They'd better have been fully resolved by this point. */
5989 gas_assert ((int) fixp->fx_r_type > 0);
5991 reloc->addend = fixp->fx_offset;
5993 reloc->howto = bfd_reloc_type_lookup (stdoutput, fixp->fx_r_type);
5994 if (reloc->howto == NULL)
5996 as_bad_where (fixp->fx_file, fixp->fx_line,
5997 _("cannot represent `%s' relocation in object file"),
5998 bfd_get_reloc_code_name (fixp->fx_r_type));
5999 free (reloc->sym_ptr_ptr);
6000 free (reloc);
6001 return NULL;
6004 if (!fixp->fx_pcrel != !reloc->howto->pc_relative)
6005 as_fatal (_("internal error; cannot generate `%s' relocation"),
6006 bfd_get_reloc_code_name (fixp->fx_r_type));
6008 return reloc;
6012 /* Checks for resource conflicts between instructions. */
6014 /* The func unit stuff could be implemented as bit-vectors rather
6015 than the iterative approach here. If it ends up being too
6016 slow, we will switch it. */
6018 resource_table *
6019 new_resource_table (void *data,
6020 int cycles,
6021 int nu,
6022 unit_num_copies_func uncf,
6023 opcode_num_units_func onuf,
6024 opcode_funcUnit_use_unit_func ouuf,
6025 opcode_funcUnit_use_stage_func ousf)
6027 int i;
6028 resource_table *rt = (resource_table *) xmalloc (sizeof (resource_table));
6029 rt->data = data;
6030 rt->cycles = cycles;
6031 rt->allocated_cycles = cycles;
6032 rt->num_units = nu;
6033 rt->unit_num_copies = uncf;
6034 rt->opcode_num_units = onuf;
6035 rt->opcode_unit_use = ouuf;
6036 rt->opcode_unit_stage = ousf;
6038 rt->units = (unsigned char **) xcalloc (cycles, sizeof (unsigned char *));
6039 for (i = 0; i < cycles; i++)
6040 rt->units[i] = (unsigned char *) xcalloc (nu, sizeof (unsigned char));
6042 return rt;
6046 void
6047 clear_resource_table (resource_table *rt)
6049 int i, j;
6050 for (i = 0; i < rt->allocated_cycles; i++)
6051 for (j = 0; j < rt->num_units; j++)
6052 rt->units[i][j] = 0;
6056 /* We never shrink it, just fake it into thinking so. */
6058 void
6059 resize_resource_table (resource_table *rt, int cycles)
6061 int i, old_cycles;
6063 rt->cycles = cycles;
6064 if (cycles <= rt->allocated_cycles)
6065 return;
6067 old_cycles = rt->allocated_cycles;
6068 rt->allocated_cycles = cycles;
6070 rt->units = xrealloc (rt->units,
6071 rt->allocated_cycles * sizeof (unsigned char *));
6072 for (i = 0; i < old_cycles; i++)
6073 rt->units[i] = xrealloc (rt->units[i],
6074 rt->num_units * sizeof (unsigned char));
6075 for (i = old_cycles; i < cycles; i++)
6076 rt->units[i] = xcalloc (rt->num_units, sizeof (unsigned char));
6080 bfd_boolean
6081 resources_available (resource_table *rt, xtensa_opcode opcode, int cycle)
6083 int i;
6084 int uses = (rt->opcode_num_units) (rt->data, opcode);
6086 for (i = 0; i < uses; i++)
6088 xtensa_funcUnit unit = (rt->opcode_unit_use) (rt->data, opcode, i);
6089 int stage = (rt->opcode_unit_stage) (rt->data, opcode, i);
6090 int copies_in_use = rt->units[stage + cycle][unit];
6091 int copies = (rt->unit_num_copies) (rt->data, unit);
6092 if (copies_in_use >= copies)
6093 return FALSE;
6095 return TRUE;
6099 void
6100 reserve_resources (resource_table *rt, xtensa_opcode opcode, int cycle)
6102 int i;
6103 int uses = (rt->opcode_num_units) (rt->data, opcode);
6105 for (i = 0; i < uses; i++)
6107 xtensa_funcUnit unit = (rt->opcode_unit_use) (rt->data, opcode, i);
6108 int stage = (rt->opcode_unit_stage) (rt->data, opcode, i);
6109 /* Note that this allows resources to be oversubscribed. That's
6110 essential to the way the optional scheduler works.
6111 resources_available reports when a resource is over-subscribed,
6112 so it's easy to tell. */
6113 rt->units[stage + cycle][unit]++;
6118 void
6119 release_resources (resource_table *rt, xtensa_opcode opcode, int cycle)
6121 int i;
6122 int uses = (rt->opcode_num_units) (rt->data, opcode);
6124 for (i = 0; i < uses; i++)
6126 xtensa_funcUnit unit = (rt->opcode_unit_use) (rt->data, opcode, i);
6127 int stage = (rt->opcode_unit_stage) (rt->data, opcode, i);
6128 gas_assert (rt->units[stage + cycle][unit] > 0);
6129 rt->units[stage + cycle][unit]--;
6134 /* Wrapper functions make parameterized resource reservation
6135 more convenient. */
6138 opcode_funcUnit_use_unit (void *data, xtensa_opcode opcode, int idx)
6140 xtensa_funcUnit_use *use = xtensa_opcode_funcUnit_use (data, opcode, idx);
6141 return use->unit;
6146 opcode_funcUnit_use_stage (void *data, xtensa_opcode opcode, int idx)
6148 xtensa_funcUnit_use *use = xtensa_opcode_funcUnit_use (data, opcode, idx);
6149 return use->stage;
6153 /* Note that this function does not check issue constraints, but
6154 solely whether the hardware is available to execute the given
6155 instructions together. It also doesn't check if the tinsns
6156 write the same state, or access the same tieports. That is
6157 checked by check_t1_t2_reads_and_writes. */
6159 static bfd_boolean
6160 resources_conflict (vliw_insn *vinsn)
6162 int i;
6163 static resource_table *rt = NULL;
6165 /* This is the most common case by far. Optimize it. */
6166 if (vinsn->num_slots == 1)
6167 return FALSE;
6169 if (rt == NULL)
6171 xtensa_isa isa = xtensa_default_isa;
6172 rt = new_resource_table
6173 (isa, xtensa_num_pipe_stages,
6174 xtensa_isa_num_funcUnits (isa),
6175 (unit_num_copies_func) xtensa_funcUnit_num_copies,
6176 (opcode_num_units_func) xtensa_opcode_num_funcUnit_uses,
6177 opcode_funcUnit_use_unit,
6178 opcode_funcUnit_use_stage);
6181 clear_resource_table (rt);
6183 for (i = 0; i < vinsn->num_slots; i++)
6185 if (!resources_available (rt, vinsn->slots[i].opcode, 0))
6186 return TRUE;
6187 reserve_resources (rt, vinsn->slots[i].opcode, 0);
6190 return FALSE;
6194 /* finish_vinsn, emit_single_op and helper functions. */
6196 static bfd_boolean find_vinsn_conflicts (vliw_insn *);
6197 static xtensa_format xg_find_narrowest_format (vliw_insn *);
6198 static void xg_assemble_vliw_tokens (vliw_insn *);
6201 /* We have reached the end of a bundle; emit into the frag. */
6203 static void
6204 finish_vinsn (vliw_insn *vinsn)
6206 IStack slotstack;
6207 int i;
6208 char *file_name;
6209 unsigned line;
6211 if (find_vinsn_conflicts (vinsn))
6213 xg_clear_vinsn (vinsn);
6214 return;
6217 /* First, find a format that works. */
6218 if (vinsn->format == XTENSA_UNDEFINED)
6219 vinsn->format = xg_find_narrowest_format (vinsn);
6221 if (xtensa_format_num_slots (xtensa_default_isa, vinsn->format) > 1
6222 && produce_flix == FLIX_NONE)
6224 as_bad (_("The option \"--no-allow-flix\" prohibits multi-slot flix."));
6225 xg_clear_vinsn (vinsn);
6226 return;
6229 if (vinsn->format == XTENSA_UNDEFINED)
6231 as_where (&file_name, &line);
6232 as_bad_where (file_name, line,
6233 _("couldn't find a valid instruction format"));
6234 fprintf (stderr, _(" ops were: "));
6235 for (i = 0; i < vinsn->num_slots; i++)
6236 fprintf (stderr, _(" %s;"),
6237 xtensa_opcode_name (xtensa_default_isa,
6238 vinsn->slots[i].opcode));
6239 fprintf (stderr, _("\n"));
6240 xg_clear_vinsn (vinsn);
6241 return;
6244 if (vinsn->num_slots
6245 != xtensa_format_num_slots (xtensa_default_isa, vinsn->format))
6247 as_bad (_("format '%s' allows %d slots, but there are %d opcodes"),
6248 xtensa_format_name (xtensa_default_isa, vinsn->format),
6249 xtensa_format_num_slots (xtensa_default_isa, vinsn->format),
6250 vinsn->num_slots);
6251 xg_clear_vinsn (vinsn);
6252 return;
6255 if (resources_conflict (vinsn))
6257 as_where (&file_name, &line);
6258 as_bad_where (file_name, line, _("illegal resource usage in bundle"));
6259 fprintf (stderr, " ops were: ");
6260 for (i = 0; i < vinsn->num_slots; i++)
6261 fprintf (stderr, " %s;",
6262 xtensa_opcode_name (xtensa_default_isa,
6263 vinsn->slots[i].opcode));
6264 fprintf (stderr, "\n");
6265 xg_clear_vinsn (vinsn);
6266 return;
6269 for (i = 0; i < vinsn->num_slots; i++)
6271 if (vinsn->slots[i].opcode != XTENSA_UNDEFINED)
6273 symbolS *lit_sym = NULL;
6274 int j;
6275 bfd_boolean e = FALSE;
6276 bfd_boolean saved_density = density_supported;
6278 /* We don't want to narrow ops inside multi-slot bundles. */
6279 if (vinsn->num_slots > 1)
6280 density_supported = FALSE;
6282 istack_init (&slotstack);
6283 if (vinsn->slots[i].opcode == xtensa_nop_opcode)
6285 vinsn->slots[i].opcode =
6286 xtensa_format_slot_nop_opcode (xtensa_default_isa,
6287 vinsn->format, i);
6288 vinsn->slots[i].ntok = 0;
6291 if (xg_expand_assembly_insn (&slotstack, &vinsn->slots[i]))
6293 e = TRUE;
6294 continue;
6297 density_supported = saved_density;
6299 if (e)
6301 xg_clear_vinsn (vinsn);
6302 return;
6305 for (j = 0; j < slotstack.ninsn; j++)
6307 TInsn *insn = &slotstack.insn[j];
6308 if (insn->insn_type == ITYPE_LITERAL)
6310 gas_assert (lit_sym == NULL);
6311 lit_sym = xg_assemble_literal (insn);
6313 else
6315 gas_assert (insn->insn_type == ITYPE_INSN);
6316 if (lit_sym)
6317 xg_resolve_literals (insn, lit_sym);
6318 if (j != slotstack.ninsn - 1)
6319 emit_single_op (insn);
6323 if (vinsn->num_slots > 1)
6325 if (opcode_fits_format_slot
6326 (slotstack.insn[slotstack.ninsn - 1].opcode,
6327 vinsn->format, i))
6329 vinsn->slots[i] = slotstack.insn[slotstack.ninsn - 1];
6331 else
6333 emit_single_op (&slotstack.insn[slotstack.ninsn - 1]);
6334 if (vinsn->format == XTENSA_UNDEFINED)
6335 vinsn->slots[i].opcode = xtensa_nop_opcode;
6336 else
6337 vinsn->slots[i].opcode
6338 = xtensa_format_slot_nop_opcode (xtensa_default_isa,
6339 vinsn->format, i);
6341 vinsn->slots[i].ntok = 0;
6344 else
6346 vinsn->slots[0] = slotstack.insn[slotstack.ninsn - 1];
6347 vinsn->format = XTENSA_UNDEFINED;
6352 /* Now check resource conflicts on the modified bundle. */
6353 if (resources_conflict (vinsn))
6355 as_where (&file_name, &line);
6356 as_bad_where (file_name, line, _("illegal resource usage in bundle"));
6357 fprintf (stderr, " ops were: ");
6358 for (i = 0; i < vinsn->num_slots; i++)
6359 fprintf (stderr, " %s;",
6360 xtensa_opcode_name (xtensa_default_isa,
6361 vinsn->slots[i].opcode));
6362 fprintf (stderr, "\n");
6363 xg_clear_vinsn (vinsn);
6364 return;
6367 /* First, find a format that works. */
6368 if (vinsn->format == XTENSA_UNDEFINED)
6369 vinsn->format = xg_find_narrowest_format (vinsn);
6371 xg_assemble_vliw_tokens (vinsn);
6373 xg_clear_vinsn (vinsn);
6377 /* Given an vliw instruction, what conflicts are there in register
6378 usage and in writes to states and queues?
6380 This function does two things:
6381 1. Reports an error when a vinsn contains illegal combinations
6382 of writes to registers states or queues.
6383 2. Marks individual tinsns as not relaxable if the combination
6384 contains antidependencies.
6386 Job 2 handles things like swap semantics in instructions that need
6387 to be relaxed. For example,
6389 addi a0, a1, 100000
6391 normally would be relaxed to
6393 l32r a0, some_label
6394 add a0, a1, a0
6396 _but_, if the above instruction is bundled with an a0 reader, e.g.,
6398 { addi a0, a1, 10000 ; add a2, a0, a4 ; }
6400 then we can't relax it into
6402 l32r a0, some_label
6403 { add a0, a1, a0 ; add a2, a0, a4 ; }
6405 because the value of a0 is trashed before the second add can read it. */
6407 static char check_t1_t2_reads_and_writes (TInsn *, TInsn *);
6409 static bfd_boolean
6410 find_vinsn_conflicts (vliw_insn *vinsn)
6412 int i, j;
6413 int branches = 0;
6414 xtensa_isa isa = xtensa_default_isa;
6416 gas_assert (!past_xtensa_end);
6418 for (i = 0 ; i < vinsn->num_slots; i++)
6420 TInsn *op1 = &vinsn->slots[i];
6421 if (op1->is_specific_opcode)
6422 op1->keep_wide = TRUE;
6423 else
6424 op1->keep_wide = FALSE;
6427 for (i = 0 ; i < vinsn->num_slots; i++)
6429 TInsn *op1 = &vinsn->slots[i];
6431 if (xtensa_opcode_is_branch (isa, op1->opcode) == 1)
6432 branches++;
6434 for (j = 0; j < vinsn->num_slots; j++)
6436 if (i != j)
6438 TInsn *op2 = &vinsn->slots[j];
6439 char conflict_type = check_t1_t2_reads_and_writes (op1, op2);
6440 switch (conflict_type)
6442 case 'c':
6443 as_bad (_("opcodes '%s' (slot %d) and '%s' (slot %d) write the same register"),
6444 xtensa_opcode_name (isa, op1->opcode), i,
6445 xtensa_opcode_name (isa, op2->opcode), j);
6446 return TRUE;
6447 case 'd':
6448 as_bad (_("opcodes '%s' (slot %d) and '%s' (slot %d) write the same state"),
6449 xtensa_opcode_name (isa, op1->opcode), i,
6450 xtensa_opcode_name (isa, op2->opcode), j);
6451 return TRUE;
6452 case 'e':
6453 as_bad (_("opcodes '%s' (slot %d) and '%s' (slot %d) write the same port"),
6454 xtensa_opcode_name (isa, op1->opcode), i,
6455 xtensa_opcode_name (isa, op2->opcode), j);
6456 return TRUE;
6457 case 'f':
6458 as_bad (_("opcodes '%s' (slot %d) and '%s' (slot %d) both have volatile port accesses"),
6459 xtensa_opcode_name (isa, op1->opcode), i,
6460 xtensa_opcode_name (isa, op2->opcode), j);
6461 return TRUE;
6462 default:
6463 /* Everything is OK. */
6464 break;
6466 op2->is_specific_opcode = (op2->is_specific_opcode
6467 || conflict_type == 'a');
6472 if (branches > 1)
6474 as_bad (_("multiple branches or jumps in the same bundle"));
6475 return TRUE;
6478 return FALSE;
6482 /* Check how the state used by t1 and t2 relate.
6483 Cases found are:
6485 case A: t1 reads a register t2 writes (an antidependency within a bundle)
6486 case B: no relationship between what is read and written (both could
6487 read the same reg though)
6488 case C: t1 writes a register t2 writes (a register conflict within a
6489 bundle)
6490 case D: t1 writes a state that t2 also writes
6491 case E: t1 writes a tie queue that t2 also writes
6492 case F: two volatile queue accesses
6495 static char
6496 check_t1_t2_reads_and_writes (TInsn *t1, TInsn *t2)
6498 xtensa_isa isa = xtensa_default_isa;
6499 xtensa_regfile t1_regfile, t2_regfile;
6500 int t1_reg, t2_reg;
6501 int t1_base_reg, t1_last_reg;
6502 int t2_base_reg, t2_last_reg;
6503 char t1_inout, t2_inout;
6504 int i, j;
6505 char conflict = 'b';
6506 int t1_states;
6507 int t2_states;
6508 int t1_interfaces;
6509 int t2_interfaces;
6510 bfd_boolean t1_volatile = FALSE;
6511 bfd_boolean t2_volatile = FALSE;
6513 /* Check registers. */
6514 for (j = 0; j < t2->ntok; j++)
6516 if (xtensa_operand_is_register (isa, t2->opcode, j) != 1)
6517 continue;
6519 t2_regfile = xtensa_operand_regfile (isa, t2->opcode, j);
6520 t2_base_reg = t2->tok[j].X_add_number;
6521 t2_last_reg = t2_base_reg + xtensa_operand_num_regs (isa, t2->opcode, j);
6523 for (i = 0; i < t1->ntok; i++)
6525 if (xtensa_operand_is_register (isa, t1->opcode, i) != 1)
6526 continue;
6528 t1_regfile = xtensa_operand_regfile (isa, t1->opcode, i);
6530 if (t1_regfile != t2_regfile)
6531 continue;
6533 t1_inout = xtensa_operand_inout (isa, t1->opcode, i);
6534 t2_inout = xtensa_operand_inout (isa, t2->opcode, j);
6536 if (xtensa_operand_is_known_reg (isa, t1->opcode, i) == 0
6537 || xtensa_operand_is_known_reg (isa, t2->opcode, j) == 0)
6539 if (t1_inout == 'm' || t1_inout == 'o'
6540 || t2_inout == 'm' || t2_inout == 'o')
6542 conflict = 'a';
6543 continue;
6547 t1_base_reg = t1->tok[i].X_add_number;
6548 t1_last_reg = (t1_base_reg
6549 + xtensa_operand_num_regs (isa, t1->opcode, i));
6551 for (t1_reg = t1_base_reg; t1_reg < t1_last_reg; t1_reg++)
6553 for (t2_reg = t2_base_reg; t2_reg < t2_last_reg; t2_reg++)
6555 if (t1_reg != t2_reg)
6556 continue;
6558 if (t2_inout == 'i' && (t1_inout == 'm' || t1_inout == 'o'))
6560 conflict = 'a';
6561 continue;
6564 if (t1_inout == 'i' && (t2_inout == 'm' || t2_inout == 'o'))
6566 conflict = 'a';
6567 continue;
6570 if (t1_inout != 'i' && t2_inout != 'i')
6571 return 'c';
6577 /* Check states. */
6578 t1_states = xtensa_opcode_num_stateOperands (isa, t1->opcode);
6579 t2_states = xtensa_opcode_num_stateOperands (isa, t2->opcode);
6580 for (j = 0; j < t2_states; j++)
6582 xtensa_state t2_so = xtensa_stateOperand_state (isa, t2->opcode, j);
6583 t2_inout = xtensa_stateOperand_inout (isa, t2->opcode, j);
6584 for (i = 0; i < t1_states; i++)
6586 xtensa_state t1_so = xtensa_stateOperand_state (isa, t1->opcode, i);
6587 t1_inout = xtensa_stateOperand_inout (isa, t1->opcode, i);
6588 if (t1_so != t2_so || xtensa_state_is_shared_or (isa, t1_so) == 1)
6589 continue;
6591 if (t2_inout == 'i' && (t1_inout == 'm' || t1_inout == 'o'))
6593 conflict = 'a';
6594 continue;
6597 if (t1_inout == 'i' && (t2_inout == 'm' || t2_inout == 'o'))
6599 conflict = 'a';
6600 continue;
6603 if (t1_inout != 'i' && t2_inout != 'i')
6604 return 'd';
6608 /* Check tieports. */
6609 t1_interfaces = xtensa_opcode_num_interfaceOperands (isa, t1->opcode);
6610 t2_interfaces = xtensa_opcode_num_interfaceOperands (isa, t2->opcode);
6611 for (j = 0; j < t2_interfaces; j++)
6613 xtensa_interface t2_int
6614 = xtensa_interfaceOperand_interface (isa, t2->opcode, j);
6615 int t2_class = xtensa_interface_class_id (isa, t2_int);
6617 t2_inout = xtensa_interface_inout (isa, t2_int);
6618 if (xtensa_interface_has_side_effect (isa, t2_int) == 1)
6619 t2_volatile = TRUE;
6621 for (i = 0; i < t1_interfaces; i++)
6623 xtensa_interface t1_int
6624 = xtensa_interfaceOperand_interface (isa, t1->opcode, j);
6625 int t1_class = xtensa_interface_class_id (isa, t1_int);
6627 t1_inout = xtensa_interface_inout (isa, t1_int);
6628 if (xtensa_interface_has_side_effect (isa, t1_int) == 1)
6629 t1_volatile = TRUE;
6631 if (t1_volatile && t2_volatile && (t1_class == t2_class))
6632 return 'f';
6634 if (t1_int != t2_int)
6635 continue;
6637 if (t2_inout == 'i' && t1_inout == 'o')
6639 conflict = 'a';
6640 continue;
6643 if (t1_inout == 'i' && t2_inout == 'o')
6645 conflict = 'a';
6646 continue;
6649 if (t1_inout != 'i' && t2_inout != 'i')
6650 return 'e';
6654 return conflict;
6658 static xtensa_format
6659 xg_find_narrowest_format (vliw_insn *vinsn)
6661 /* Right now we assume that the ops within the vinsn are properly
6662 ordered for the slots that the programmer wanted them in. In
6663 other words, we don't rearrange the ops in hopes of finding a
6664 better format. The scheduler handles that. */
6666 xtensa_isa isa = xtensa_default_isa;
6667 xtensa_format format;
6668 xtensa_opcode nop_opcode = xtensa_nop_opcode;
6670 if (vinsn->num_slots == 1)
6671 return xg_get_single_format (vinsn->slots[0].opcode);
6673 for (format = 0; format < xtensa_isa_num_formats (isa); format++)
6675 vliw_insn v_copy;
6676 xg_copy_vinsn (&v_copy, vinsn);
6677 if (xtensa_format_num_slots (isa, format) == v_copy.num_slots)
6679 int slot;
6680 int fit = 0;
6681 for (slot = 0; slot < v_copy.num_slots; slot++)
6683 if (v_copy.slots[slot].opcode == nop_opcode)
6685 v_copy.slots[slot].opcode =
6686 xtensa_format_slot_nop_opcode (isa, format, slot);
6687 v_copy.slots[slot].ntok = 0;
6690 if (opcode_fits_format_slot (v_copy.slots[slot].opcode,
6691 format, slot))
6692 fit++;
6693 else if (v_copy.num_slots > 1)
6695 TInsn widened;
6696 /* Try the widened version. */
6697 if (!v_copy.slots[slot].keep_wide
6698 && !v_copy.slots[slot].is_specific_opcode
6699 && xg_is_single_relaxable_insn (&v_copy.slots[slot],
6700 &widened, TRUE)
6701 && opcode_fits_format_slot (widened.opcode,
6702 format, slot))
6704 v_copy.slots[slot] = widened;
6705 fit++;
6709 if (fit == v_copy.num_slots)
6711 xg_copy_vinsn (vinsn, &v_copy);
6712 xtensa_format_encode (isa, format, vinsn->insnbuf);
6713 vinsn->format = format;
6714 break;
6719 if (format == xtensa_isa_num_formats (isa))
6720 return XTENSA_UNDEFINED;
6722 return format;
6726 /* Return the additional space needed in a frag
6727 for possible relaxations of any ops in a VLIW insn.
6728 Also fill out the relaxations that might be required of
6729 each tinsn in the vinsn. */
6731 static int
6732 relaxation_requirements (vliw_insn *vinsn, bfd_boolean *pfinish_frag)
6734 bfd_boolean finish_frag = FALSE;
6735 int extra_space = 0;
6736 int slot;
6738 for (slot = 0; slot < vinsn->num_slots; slot++)
6740 TInsn *tinsn = &vinsn->slots[slot];
6741 if (!tinsn_has_symbolic_operands (tinsn))
6743 /* A narrow instruction could be widened later to help
6744 alignment issues. */
6745 if (xg_is_single_relaxable_insn (tinsn, 0, TRUE)
6746 && !tinsn->is_specific_opcode
6747 && vinsn->num_slots == 1)
6749 /* Difference in bytes between narrow and wide insns... */
6750 extra_space += 1;
6751 tinsn->subtype = RELAX_NARROW;
6754 else
6756 if (workaround_b_j_loop_end
6757 && tinsn->opcode == xtensa_jx_opcode
6758 && use_transform ())
6760 /* Add 2 of these. */
6761 extra_space += 3; /* for the nop size */
6762 tinsn->subtype = RELAX_ADD_NOP_IF_PRE_LOOP_END;
6765 /* Need to assemble it with space for the relocation. */
6766 if (xg_is_relaxable_insn (tinsn, 0)
6767 && !tinsn->is_specific_opcode)
6769 int max_size = xg_get_max_insn_widen_size (tinsn->opcode);
6770 int max_literal_size =
6771 xg_get_max_insn_widen_literal_size (tinsn->opcode);
6773 tinsn->literal_space = max_literal_size;
6775 tinsn->subtype = RELAX_IMMED;
6776 extra_space += max_size;
6778 else
6780 /* A fix record will be added for this instruction prior
6781 to relaxation, so make it end the frag. */
6782 finish_frag = TRUE;
6786 *pfinish_frag = finish_frag;
6787 return extra_space;
6791 static void
6792 bundle_tinsn (TInsn *tinsn, vliw_insn *vinsn)
6794 xtensa_isa isa = xtensa_default_isa;
6795 int slot, chosen_slot;
6797 vinsn->format = xg_get_single_format (tinsn->opcode);
6798 gas_assert (vinsn->format != XTENSA_UNDEFINED);
6799 vinsn->num_slots = xtensa_format_num_slots (isa, vinsn->format);
6801 chosen_slot = xg_get_single_slot (tinsn->opcode);
6802 for (slot = 0; slot < vinsn->num_slots; slot++)
6804 if (slot == chosen_slot)
6805 vinsn->slots[slot] = *tinsn;
6806 else
6808 vinsn->slots[slot].opcode =
6809 xtensa_format_slot_nop_opcode (isa, vinsn->format, slot);
6810 vinsn->slots[slot].ntok = 0;
6811 vinsn->slots[slot].insn_type = ITYPE_INSN;
6817 static bfd_boolean
6818 emit_single_op (TInsn *orig_insn)
6820 int i;
6821 IStack istack; /* put instructions into here */
6822 symbolS *lit_sym = NULL;
6823 symbolS *label_sym = NULL;
6825 istack_init (&istack);
6827 /* Special-case for "movi aX, foo" which is guaranteed to need relaxing.
6828 Because the scheduling and bundling characteristics of movi and
6829 l32r or const16 are so different, we can do much better if we relax
6830 it prior to scheduling and bundling, rather than after. */
6831 if ((orig_insn->opcode == xtensa_movi_opcode
6832 || orig_insn->opcode == xtensa_movi_n_opcode)
6833 && !cur_vinsn.inside_bundle
6834 && (orig_insn->tok[1].X_op == O_symbol
6835 || orig_insn->tok[1].X_op == O_pltrel
6836 || orig_insn->tok[1].X_op == O_tlsfunc
6837 || orig_insn->tok[1].X_op == O_tlsarg
6838 || orig_insn->tok[1].X_op == O_tpoff
6839 || orig_insn->tok[1].X_op == O_dtpoff)
6840 && !orig_insn->is_specific_opcode && use_transform ())
6841 xg_assembly_relax (&istack, orig_insn, now_seg, frag_now, 0, 1, 0);
6842 else
6843 if (xg_expand_assembly_insn (&istack, orig_insn))
6844 return TRUE;
6846 for (i = 0; i < istack.ninsn; i++)
6848 TInsn *insn = &istack.insn[i];
6849 switch (insn->insn_type)
6851 case ITYPE_LITERAL:
6852 gas_assert (lit_sym == NULL);
6853 lit_sym = xg_assemble_literal (insn);
6854 break;
6855 case ITYPE_LABEL:
6857 static int relaxed_sym_idx = 0;
6858 char *label = xmalloc (strlen (FAKE_LABEL_NAME) + 12);
6859 sprintf (label, "%s_rl_%x", FAKE_LABEL_NAME, relaxed_sym_idx++);
6860 colon (label);
6861 gas_assert (label_sym == NULL);
6862 label_sym = symbol_find_or_make (label);
6863 gas_assert (label_sym);
6864 free (label);
6866 break;
6867 case ITYPE_INSN:
6869 vliw_insn v;
6870 if (lit_sym)
6871 xg_resolve_literals (insn, lit_sym);
6872 if (label_sym)
6873 xg_resolve_labels (insn, label_sym);
6874 xg_init_vinsn (&v);
6875 bundle_tinsn (insn, &v);
6876 finish_vinsn (&v);
6877 xg_free_vinsn (&v);
6879 break;
6880 default:
6881 gas_assert (0);
6882 break;
6885 return FALSE;
6889 static int
6890 total_frag_text_expansion (fragS *fragP)
6892 int slot;
6893 int total_expansion = 0;
6895 for (slot = 0; slot < config_max_slots; slot++)
6896 total_expansion += fragP->tc_frag_data.text_expansion[slot];
6898 return total_expansion;
6902 /* Emit a vliw instruction to the current fragment. */
6904 static void
6905 xg_assemble_vliw_tokens (vliw_insn *vinsn)
6907 bfd_boolean finish_frag;
6908 bfd_boolean is_jump = FALSE;
6909 bfd_boolean is_branch = FALSE;
6910 xtensa_isa isa = xtensa_default_isa;
6911 int insn_size;
6912 int extra_space;
6913 char *f = NULL;
6914 int slot;
6915 struct dwarf2_line_info debug_line;
6916 bfd_boolean loc_directive_seen = FALSE;
6917 TInsn *tinsn;
6919 memset (&debug_line, 0, sizeof (struct dwarf2_line_info));
6921 if (generating_literals)
6923 static int reported = 0;
6924 if (reported < 4)
6925 as_bad_where (frag_now->fr_file, frag_now->fr_line,
6926 _("cannot assemble into a literal fragment"));
6927 if (reported == 3)
6928 as_bad (_("..."));
6929 reported++;
6930 return;
6933 if (frag_now_fix () != 0
6934 && (! frag_now->tc_frag_data.is_insn
6935 || (vinsn_has_specific_opcodes (vinsn) && use_transform ())
6936 || !use_transform () != frag_now->tc_frag_data.is_no_transform
6937 || (directive_state[directive_longcalls]
6938 != frag_now->tc_frag_data.use_longcalls)
6939 || (directive_state[directive_absolute_literals]
6940 != frag_now->tc_frag_data.use_absolute_literals)))
6942 frag_wane (frag_now);
6943 frag_new (0);
6944 xtensa_set_frag_assembly_state (frag_now);
6947 if (workaround_a0_b_retw
6948 && vinsn->num_slots == 1
6949 && (get_last_insn_flags (now_seg, now_subseg) & FLAG_IS_A0_WRITER) != 0
6950 && xtensa_opcode_is_branch (isa, vinsn->slots[0].opcode) == 1
6951 && use_transform ())
6953 has_a0_b_retw = TRUE;
6955 /* Mark this fragment with the special RELAX_ADD_NOP_IF_A0_B_RETW.
6956 After the first assembly pass we will check all of them and
6957 add a nop if needed. */
6958 frag_now->tc_frag_data.is_insn = TRUE;
6959 frag_var (rs_machine_dependent, 4, 4,
6960 RELAX_ADD_NOP_IF_A0_B_RETW,
6961 frag_now->fr_symbol,
6962 frag_now->fr_offset,
6963 NULL);
6964 xtensa_set_frag_assembly_state (frag_now);
6965 frag_now->tc_frag_data.is_insn = TRUE;
6966 frag_var (rs_machine_dependent, 4, 4,
6967 RELAX_ADD_NOP_IF_A0_B_RETW,
6968 frag_now->fr_symbol,
6969 frag_now->fr_offset,
6970 NULL);
6971 xtensa_set_frag_assembly_state (frag_now);
6974 for (slot = 0; slot < vinsn->num_slots; slot++)
6976 tinsn = &vinsn->slots[slot];
6978 /* See if the instruction implies an aligned section. */
6979 if (xtensa_opcode_is_loop (isa, tinsn->opcode) == 1)
6980 record_alignment (now_seg, 2);
6982 /* Determine the best line number for debug info. */
6983 if ((tinsn->loc_directive_seen || !loc_directive_seen)
6984 && (tinsn->debug_line.filenum != debug_line.filenum
6985 || tinsn->debug_line.line < debug_line.line
6986 || tinsn->debug_line.column < debug_line.column))
6987 debug_line = tinsn->debug_line;
6988 if (tinsn->loc_directive_seen)
6989 loc_directive_seen = TRUE;
6992 /* Special cases for instructions that force an alignment... */
6993 /* None of these opcodes are bundle-able. */
6994 if (xtensa_opcode_is_loop (isa, vinsn->slots[0].opcode) == 1)
6996 int max_fill;
6998 /* Remember the symbol that marks the end of the loop in the frag
6999 that marks the start of the loop. This way we can easily find
7000 the end of the loop at the beginning, without adding special code
7001 to mark the loop instructions themselves. */
7002 symbolS *target_sym = NULL;
7003 if (vinsn->slots[0].tok[1].X_op == O_symbol)
7004 target_sym = vinsn->slots[0].tok[1].X_add_symbol;
7006 xtensa_set_frag_assembly_state (frag_now);
7007 frag_now->tc_frag_data.is_insn = TRUE;
7009 max_fill = get_text_align_max_fill_size
7010 (get_text_align_power (xtensa_fetch_width),
7011 TRUE, frag_now->tc_frag_data.is_no_density);
7013 if (use_transform ())
7014 frag_var (rs_machine_dependent, max_fill, max_fill,
7015 RELAX_ALIGN_NEXT_OPCODE, target_sym, 0, NULL);
7016 else
7017 frag_var (rs_machine_dependent, 0, 0,
7018 RELAX_CHECK_ALIGN_NEXT_OPCODE, target_sym, 0, NULL);
7019 xtensa_set_frag_assembly_state (frag_now);
7022 if (vinsn->slots[0].opcode == xtensa_entry_opcode
7023 && !vinsn->slots[0].is_specific_opcode)
7025 xtensa_mark_literal_pool_location ();
7026 xtensa_move_labels (frag_now, 0);
7027 frag_var (rs_align_test, 1, 1, 0, NULL, 2, NULL);
7030 if (vinsn->num_slots == 1)
7032 if (workaround_a0_b_retw && use_transform ())
7033 set_last_insn_flags (now_seg, now_subseg, FLAG_IS_A0_WRITER,
7034 is_register_writer (&vinsn->slots[0], "a", 0));
7036 set_last_insn_flags (now_seg, now_subseg, FLAG_IS_BAD_LOOPEND,
7037 is_bad_loopend_opcode (&vinsn->slots[0]));
7039 else
7040 set_last_insn_flags (now_seg, now_subseg, FLAG_IS_BAD_LOOPEND, FALSE);
7042 insn_size = xtensa_format_length (isa, vinsn->format);
7044 extra_space = relaxation_requirements (vinsn, &finish_frag);
7046 /* vinsn_to_insnbuf will produce the error. */
7047 if (vinsn->format != XTENSA_UNDEFINED)
7049 f = frag_more (insn_size + extra_space);
7050 xtensa_set_frag_assembly_state (frag_now);
7051 frag_now->tc_frag_data.is_insn = TRUE;
7054 vinsn_to_insnbuf (vinsn, f, frag_now, FALSE);
7055 if (vinsn->format == XTENSA_UNDEFINED)
7056 return;
7058 xtensa_insnbuf_to_chars (isa, vinsn->insnbuf, (unsigned char *) f, 0);
7060 if (debug_type == DEBUG_DWARF2 || loc_directive_seen)
7061 dwarf2_gen_line_info (frag_now_fix () - (insn_size + extra_space),
7062 &debug_line);
7064 for (slot = 0; slot < vinsn->num_slots; slot++)
7066 tinsn = &vinsn->slots[slot];
7067 frag_now->tc_frag_data.slot_subtypes[slot] = tinsn->subtype;
7068 frag_now->tc_frag_data.slot_symbols[slot] = tinsn->symbol;
7069 frag_now->tc_frag_data.slot_offsets[slot] = tinsn->offset;
7070 frag_now->tc_frag_data.literal_frags[slot] = tinsn->literal_frag;
7071 if (tinsn->literal_space != 0)
7072 xg_assemble_literal_space (tinsn->literal_space, slot);
7073 frag_now->tc_frag_data.free_reg[slot] = tinsn->extra_arg;
7075 if (tinsn->subtype == RELAX_NARROW)
7076 gas_assert (vinsn->num_slots == 1);
7077 if (xtensa_opcode_is_jump (isa, tinsn->opcode) == 1)
7078 is_jump = TRUE;
7079 if (xtensa_opcode_is_branch (isa, tinsn->opcode) == 1)
7080 is_branch = TRUE;
7082 if (tinsn->subtype || tinsn->symbol || tinsn->offset
7083 || tinsn->literal_frag || is_jump || is_branch)
7084 finish_frag = TRUE;
7087 if (vinsn_has_specific_opcodes (vinsn) && use_transform ())
7088 frag_now->tc_frag_data.is_specific_opcode = TRUE;
7090 if (finish_frag)
7092 frag_variant (rs_machine_dependent,
7093 extra_space, extra_space, RELAX_SLOTS,
7094 frag_now->fr_symbol, frag_now->fr_offset, f);
7095 xtensa_set_frag_assembly_state (frag_now);
7098 /* Special cases for loops:
7099 close_loop_end should be inserted AFTER short_loop.
7100 Make sure that CLOSE loops are processed BEFORE short_loops
7101 when converting them. */
7103 /* "short_loop": Add a NOP if the loop is < 4 bytes. */
7104 if (xtensa_opcode_is_loop (isa, vinsn->slots[0].opcode) == 1
7105 && !vinsn->slots[0].is_specific_opcode)
7107 if (workaround_short_loop && use_transform ())
7109 maybe_has_short_loop = TRUE;
7110 frag_now->tc_frag_data.is_insn = TRUE;
7111 frag_var (rs_machine_dependent, 4, 4,
7112 RELAX_ADD_NOP_IF_SHORT_LOOP,
7113 frag_now->fr_symbol, frag_now->fr_offset, NULL);
7114 frag_now->tc_frag_data.is_insn = TRUE;
7115 frag_var (rs_machine_dependent, 4, 4,
7116 RELAX_ADD_NOP_IF_SHORT_LOOP,
7117 frag_now->fr_symbol, frag_now->fr_offset, NULL);
7120 /* "close_loop_end": Add up to 12 bytes of NOPs to keep a
7121 loop at least 12 bytes away from another loop's end. */
7122 if (workaround_close_loop_end && use_transform ())
7124 maybe_has_close_loop_end = TRUE;
7125 frag_now->tc_frag_data.is_insn = TRUE;
7126 frag_var (rs_machine_dependent, 12, 12,
7127 RELAX_ADD_NOP_IF_CLOSE_LOOP_END,
7128 frag_now->fr_symbol, frag_now->fr_offset, NULL);
7132 if (use_transform ())
7134 if (is_jump)
7136 gas_assert (finish_frag);
7137 frag_var (rs_machine_dependent,
7138 xtensa_fetch_width, xtensa_fetch_width,
7139 RELAX_UNREACHABLE,
7140 frag_now->fr_symbol, frag_now->fr_offset, NULL);
7141 xtensa_set_frag_assembly_state (frag_now);
7143 else if (is_branch && do_align_targets ())
7145 gas_assert (finish_frag);
7146 frag_var (rs_machine_dependent,
7147 xtensa_fetch_width, xtensa_fetch_width,
7148 RELAX_MAYBE_UNREACHABLE,
7149 frag_now->fr_symbol, frag_now->fr_offset, NULL);
7150 xtensa_set_frag_assembly_state (frag_now);
7151 frag_var (rs_machine_dependent,
7152 0, 0,
7153 RELAX_MAYBE_DESIRE_ALIGN,
7154 frag_now->fr_symbol, frag_now->fr_offset, NULL);
7155 xtensa_set_frag_assembly_state (frag_now);
7159 /* Now, if the original opcode was a call... */
7160 if (do_align_targets ()
7161 && xtensa_opcode_is_call (isa, vinsn->slots[0].opcode) == 1)
7163 float freq = get_subseg_total_freq (now_seg, now_subseg);
7164 frag_now->tc_frag_data.is_insn = TRUE;
7165 frag_var (rs_machine_dependent, 4, (int) freq, RELAX_DESIRE_ALIGN,
7166 frag_now->fr_symbol, frag_now->fr_offset, NULL);
7167 xtensa_set_frag_assembly_state (frag_now);
7170 if (vinsn_has_specific_opcodes (vinsn) && use_transform ())
7172 frag_wane (frag_now);
7173 frag_new (0);
7174 xtensa_set_frag_assembly_state (frag_now);
7179 /* xtensa_end and helper functions. */
7181 static void xtensa_cleanup_align_frags (void);
7182 static void xtensa_fix_target_frags (void);
7183 static void xtensa_mark_narrow_branches (void);
7184 static void xtensa_mark_zcl_first_insns (void);
7185 static void xtensa_mark_difference_of_two_symbols (void);
7186 static void xtensa_fix_a0_b_retw_frags (void);
7187 static void xtensa_fix_b_j_loop_end_frags (void);
7188 static void xtensa_fix_close_loop_end_frags (void);
7189 static void xtensa_fix_short_loop_frags (void);
7190 static void xtensa_sanity_check (void);
7191 static void xtensa_add_config_info (void);
7193 void
7194 xtensa_end (void)
7196 directive_balance ();
7197 xtensa_flush_pending_output ();
7199 past_xtensa_end = TRUE;
7201 xtensa_move_literals ();
7203 xtensa_reorder_segments ();
7204 xtensa_cleanup_align_frags ();
7205 xtensa_fix_target_frags ();
7206 if (workaround_a0_b_retw && has_a0_b_retw)
7207 xtensa_fix_a0_b_retw_frags ();
7208 if (workaround_b_j_loop_end)
7209 xtensa_fix_b_j_loop_end_frags ();
7211 /* "close_loop_end" should be processed BEFORE "short_loop". */
7212 if (workaround_close_loop_end && maybe_has_close_loop_end)
7213 xtensa_fix_close_loop_end_frags ();
7215 if (workaround_short_loop && maybe_has_short_loop)
7216 xtensa_fix_short_loop_frags ();
7217 if (align_targets)
7218 xtensa_mark_narrow_branches ();
7219 xtensa_mark_zcl_first_insns ();
7221 xtensa_sanity_check ();
7223 xtensa_add_config_info ();
7227 static void
7228 xtensa_cleanup_align_frags (void)
7230 frchainS *frchP;
7231 asection *s;
7233 for (s = stdoutput->sections; s; s = s->next)
7234 for (frchP = seg_info (s)->frchainP; frchP; frchP = frchP->frch_next)
7236 fragS *fragP;
7237 /* Walk over all of the fragments in a subsection. */
7238 for (fragP = frchP->frch_root; fragP; fragP = fragP->fr_next)
7240 if ((fragP->fr_type == rs_align
7241 || fragP->fr_type == rs_align_code
7242 || (fragP->fr_type == rs_machine_dependent
7243 && (fragP->fr_subtype == RELAX_DESIRE_ALIGN
7244 || fragP->fr_subtype == RELAX_DESIRE_ALIGN_IF_TARGET)))
7245 && fragP->fr_fix == 0)
7247 fragS *next = fragP->fr_next;
7249 while (next
7250 && next->fr_fix == 0
7251 && next->fr_type == rs_machine_dependent
7252 && next->fr_subtype == RELAX_DESIRE_ALIGN_IF_TARGET)
7254 frag_wane (next);
7255 next = next->fr_next;
7258 /* If we don't widen branch targets, then they
7259 will be easier to align. */
7260 if (fragP->tc_frag_data.is_branch_target
7261 && fragP->fr_opcode == fragP->fr_literal
7262 && fragP->fr_type == rs_machine_dependent
7263 && fragP->fr_subtype == RELAX_SLOTS
7264 && fragP->tc_frag_data.slot_subtypes[0] == RELAX_NARROW)
7265 frag_wane (fragP);
7266 if (fragP->fr_type == rs_machine_dependent
7267 && fragP->fr_subtype == RELAX_UNREACHABLE)
7268 fragP->tc_frag_data.is_unreachable = TRUE;
7274 /* Re-process all of the fragments looking to convert all of the
7275 RELAX_DESIRE_ALIGN_IF_TARGET fragments. If there is a branch
7276 target in the next fragment, convert this to RELAX_DESIRE_ALIGN.
7277 Otherwise, convert to a .fill 0. */
7279 static void
7280 xtensa_fix_target_frags (void)
7282 frchainS *frchP;
7283 asection *s;
7285 /* When this routine is called, all of the subsections are still intact
7286 so we walk over subsections instead of sections. */
7287 for (s = stdoutput->sections; s; s = s->next)
7288 for (frchP = seg_info (s)->frchainP; frchP; frchP = frchP->frch_next)
7290 fragS *fragP;
7292 /* Walk over all of the fragments in a subsection. */
7293 for (fragP = frchP->frch_root; fragP; fragP = fragP->fr_next)
7295 if (fragP->fr_type == rs_machine_dependent
7296 && fragP->fr_subtype == RELAX_DESIRE_ALIGN_IF_TARGET)
7298 if (next_frag_is_branch_target (fragP))
7299 fragP->fr_subtype = RELAX_DESIRE_ALIGN;
7300 else
7301 frag_wane (fragP);
7308 static bfd_boolean is_narrow_branch_guaranteed_in_range (fragS *, TInsn *);
7310 static void
7311 xtensa_mark_narrow_branches (void)
7313 frchainS *frchP;
7314 asection *s;
7316 for (s = stdoutput->sections; s; s = s->next)
7317 for (frchP = seg_info (s)->frchainP; frchP; frchP = frchP->frch_next)
7319 fragS *fragP;
7320 /* Walk over all of the fragments in a subsection. */
7321 for (fragP = frchP->frch_root; fragP; fragP = fragP->fr_next)
7323 if (fragP->fr_type == rs_machine_dependent
7324 && fragP->fr_subtype == RELAX_SLOTS
7325 && fragP->tc_frag_data.slot_subtypes[0] == RELAX_IMMED)
7327 vliw_insn vinsn;
7329 vinsn_from_chars (&vinsn, fragP->fr_opcode);
7330 tinsn_immed_from_frag (&vinsn.slots[0], fragP, 0);
7332 if (vinsn.num_slots == 1
7333 && xtensa_opcode_is_branch (xtensa_default_isa,
7334 vinsn.slots[0].opcode) == 1
7335 && xg_get_single_size (vinsn.slots[0].opcode) == 2
7336 && is_narrow_branch_guaranteed_in_range (fragP,
7337 &vinsn.slots[0]))
7339 fragP->fr_subtype = RELAX_SLOTS;
7340 fragP->tc_frag_data.slot_subtypes[0] = RELAX_NARROW;
7341 fragP->tc_frag_data.is_aligning_branch = 1;
7349 /* A branch is typically widened only when its target is out of
7350 range. However, we would like to widen them to align a subsequent
7351 branch target when possible.
7353 Because the branch relaxation code is so convoluted, the optimal solution
7354 (combining the two cases) is difficult to get right in all circumstances.
7355 We therefore go with an "almost as good" solution, where we only
7356 use for alignment narrow branches that definitely will not expand to a
7357 jump and a branch. These functions find and mark these cases. */
7359 /* The range in bytes of BNEZ.N and BEQZ.N. The target operand is encoded
7360 as PC + 4 + imm6, where imm6 is a 6-bit immediate ranging from 0 to 63.
7361 We start counting beginning with the frag after the 2-byte branch, so the
7362 maximum offset is (4 - 2) + 63 = 65. */
7363 #define MAX_IMMED6 65
7365 static offsetT unrelaxed_frag_max_size (fragS *);
7367 static bfd_boolean
7368 is_narrow_branch_guaranteed_in_range (fragS *fragP, TInsn *tinsn)
7370 const expressionS *exp = &tinsn->tok[1];
7371 symbolS *symbolP = exp->X_add_symbol;
7372 offsetT max_distance = exp->X_add_number;
7373 fragS *target_frag;
7375 if (exp->X_op != O_symbol)
7376 return FALSE;
7378 target_frag = symbol_get_frag (symbolP);
7380 max_distance += (S_GET_VALUE (symbolP) - target_frag->fr_address);
7381 if (is_branch_jmp_to_next (tinsn, fragP))
7382 return FALSE;
7384 /* The branch doesn't branch over it's own frag,
7385 but over the subsequent ones. */
7386 fragP = fragP->fr_next;
7387 while (fragP != NULL && fragP != target_frag && max_distance <= MAX_IMMED6)
7389 max_distance += unrelaxed_frag_max_size (fragP);
7390 fragP = fragP->fr_next;
7392 if (max_distance <= MAX_IMMED6 && fragP == target_frag)
7393 return TRUE;
7394 return FALSE;
7398 static void
7399 xtensa_mark_zcl_first_insns (void)
7401 frchainS *frchP;
7402 asection *s;
7404 for (s = stdoutput->sections; s; s = s->next)
7405 for (frchP = seg_info (s)->frchainP; frchP; frchP = frchP->frch_next)
7407 fragS *fragP;
7408 /* Walk over all of the fragments in a subsection. */
7409 for (fragP = frchP->frch_root; fragP; fragP = fragP->fr_next)
7411 if (fragP->fr_type == rs_machine_dependent
7412 && (fragP->fr_subtype == RELAX_ALIGN_NEXT_OPCODE
7413 || fragP->fr_subtype == RELAX_CHECK_ALIGN_NEXT_OPCODE))
7415 /* Find the loop frag. */
7416 fragS *loop_frag = next_non_empty_frag (fragP);
7417 /* Find the first insn frag. */
7418 fragS *targ_frag = next_non_empty_frag (loop_frag);
7420 /* Handle a corner case that comes up in hardware
7421 diagnostics. The original assembly looks like this:
7423 loop aX, LabelA
7424 <empty_frag>--not found by next_non_empty_frag
7425 loop aY, LabelB
7427 Depending on the start address, the assembler may or
7428 may not change it to look something like this:
7430 loop aX, LabelA
7431 nop--frag isn't empty anymore
7432 loop aY, LabelB
7434 So set up to check the alignment of the nop if it
7435 exists */
7436 while (loop_frag != targ_frag)
7438 if (loop_frag->fr_type == rs_machine_dependent
7439 && (loop_frag->fr_subtype == RELAX_ALIGN_NEXT_OPCODE
7440 || loop_frag->fr_subtype
7441 == RELAX_CHECK_ALIGN_NEXT_OPCODE))
7442 targ_frag = loop_frag;
7443 else
7444 loop_frag = loop_frag->fr_next;
7447 /* Of course, sometimes (mostly for toy test cases) a
7448 zero-cost loop instruction is the last in a section. */
7449 if (targ_frag)
7451 targ_frag->tc_frag_data.is_first_loop_insn = TRUE;
7452 /* Do not widen a frag that is the first instruction of a
7453 zero-cost loop. It makes that loop harder to align. */
7454 if (targ_frag->fr_type == rs_machine_dependent
7455 && targ_frag->fr_subtype == RELAX_SLOTS
7456 && (targ_frag->tc_frag_data.slot_subtypes[0]
7457 == RELAX_NARROW))
7459 if (targ_frag->tc_frag_data.is_aligning_branch)
7460 targ_frag->tc_frag_data.slot_subtypes[0] = RELAX_IMMED;
7461 else
7463 frag_wane (targ_frag);
7464 targ_frag->tc_frag_data.slot_subtypes[0] = 0;
7468 if (fragP->fr_subtype == RELAX_CHECK_ALIGN_NEXT_OPCODE)
7469 frag_wane (fragP);
7476 /* When a difference-of-symbols expression is encoded as a uleb128 or
7477 sleb128 value, the linker is unable to adjust that value to account for
7478 link-time relaxation. Mark all the code between such symbols so that
7479 its size cannot be changed by linker relaxation. */
7481 static void
7482 xtensa_mark_difference_of_two_symbols (void)
7484 symbolS *expr_sym;
7486 for (expr_sym = expr_symbols; expr_sym;
7487 expr_sym = symbol_get_tc (expr_sym)->next_expr_symbol)
7489 expressionS *exp = symbol_get_value_expression (expr_sym);
7491 if (exp->X_op == O_subtract)
7493 symbolS *left = exp->X_add_symbol;
7494 symbolS *right = exp->X_op_symbol;
7496 /* Difference of two symbols not in the same section
7497 are handled with relocations in the linker. */
7498 if (S_GET_SEGMENT (left) == S_GET_SEGMENT (right))
7500 fragS *start;
7501 fragS *end;
7502 fragS *walk;
7504 if (symbol_get_frag (left)->fr_address
7505 <= symbol_get_frag (right)->fr_address)
7507 start = symbol_get_frag (left);
7508 end = symbol_get_frag (right);
7510 else
7512 start = symbol_get_frag (right);
7513 end = symbol_get_frag (left);
7516 if (start->tc_frag_data.no_transform_end != NULL)
7517 walk = start->tc_frag_data.no_transform_end;
7518 else
7519 walk = start;
7522 walk->tc_frag_data.is_no_transform = 1;
7523 walk = walk->fr_next;
7525 while (walk && walk->fr_address < end->fr_address);
7527 start->tc_frag_data.no_transform_end = walk;
7534 /* Re-process all of the fragments looking to convert all of the
7535 RELAX_ADD_NOP_IF_A0_B_RETW. If the next instruction is a
7536 conditional branch or a retw/retw.n, convert this frag to one that
7537 will generate a NOP. In any case close it off with a .fill 0. */
7539 static bfd_boolean next_instrs_are_b_retw (fragS *);
7541 static void
7542 xtensa_fix_a0_b_retw_frags (void)
7544 frchainS *frchP;
7545 asection *s;
7547 /* When this routine is called, all of the subsections are still intact
7548 so we walk over subsections instead of sections. */
7549 for (s = stdoutput->sections; s; s = s->next)
7550 for (frchP = seg_info (s)->frchainP; frchP; frchP = frchP->frch_next)
7552 fragS *fragP;
7554 /* Walk over all of the fragments in a subsection. */
7555 for (fragP = frchP->frch_root; fragP; fragP = fragP->fr_next)
7557 if (fragP->fr_type == rs_machine_dependent
7558 && fragP->fr_subtype == RELAX_ADD_NOP_IF_A0_B_RETW)
7560 if (next_instrs_are_b_retw (fragP))
7562 if (fragP->tc_frag_data.is_no_transform)
7563 as_bad (_("instruction sequence (write a0, branch, retw) may trigger hardware errata"));
7564 else
7565 relax_frag_add_nop (fragP);
7567 frag_wane (fragP);
7574 static bfd_boolean
7575 next_instrs_are_b_retw (fragS *fragP)
7577 xtensa_opcode opcode;
7578 xtensa_format fmt;
7579 const fragS *next_fragP = next_non_empty_frag (fragP);
7580 static xtensa_insnbuf insnbuf = NULL;
7581 static xtensa_insnbuf slotbuf = NULL;
7582 xtensa_isa isa = xtensa_default_isa;
7583 int offset = 0;
7584 int slot;
7585 bfd_boolean branch_seen = FALSE;
7587 if (!insnbuf)
7589 insnbuf = xtensa_insnbuf_alloc (isa);
7590 slotbuf = xtensa_insnbuf_alloc (isa);
7593 if (next_fragP == NULL)
7594 return FALSE;
7596 /* Check for the conditional branch. */
7597 xtensa_insnbuf_from_chars
7598 (isa, insnbuf, (unsigned char *) &next_fragP->fr_literal[offset], 0);
7599 fmt = xtensa_format_decode (isa, insnbuf);
7600 if (fmt == XTENSA_UNDEFINED)
7601 return FALSE;
7603 for (slot = 0; slot < xtensa_format_num_slots (isa, fmt); slot++)
7605 xtensa_format_get_slot (isa, fmt, slot, insnbuf, slotbuf);
7606 opcode = xtensa_opcode_decode (isa, fmt, slot, slotbuf);
7608 branch_seen = (branch_seen
7609 || xtensa_opcode_is_branch (isa, opcode) == 1);
7612 if (!branch_seen)
7613 return FALSE;
7615 offset += xtensa_format_length (isa, fmt);
7616 if (offset == next_fragP->fr_fix)
7618 next_fragP = next_non_empty_frag (next_fragP);
7619 offset = 0;
7622 if (next_fragP == NULL)
7623 return FALSE;
7625 /* Check for the retw/retw.n. */
7626 xtensa_insnbuf_from_chars
7627 (isa, insnbuf, (unsigned char *) &next_fragP->fr_literal[offset], 0);
7628 fmt = xtensa_format_decode (isa, insnbuf);
7630 /* Because RETW[.N] is not bundleable, a VLIW bundle here means that we
7631 have no problems. */
7632 if (fmt == XTENSA_UNDEFINED
7633 || xtensa_format_num_slots (isa, fmt) != 1)
7634 return FALSE;
7636 xtensa_format_get_slot (isa, fmt, 0, insnbuf, slotbuf);
7637 opcode = xtensa_opcode_decode (isa, fmt, 0, slotbuf);
7639 if (opcode == xtensa_retw_opcode || opcode == xtensa_retw_n_opcode)
7640 return TRUE;
7642 return FALSE;
7646 /* Re-process all of the fragments looking to convert all of the
7647 RELAX_ADD_NOP_IF_PRE_LOOP_END. If there is one instruction and a
7648 loop end label, convert this frag to one that will generate a NOP.
7649 In any case close it off with a .fill 0. */
7651 static bfd_boolean next_instr_is_loop_end (fragS *);
7653 static void
7654 xtensa_fix_b_j_loop_end_frags (void)
7656 frchainS *frchP;
7657 asection *s;
7659 /* When this routine is called, all of the subsections are still intact
7660 so we walk over subsections instead of sections. */
7661 for (s = stdoutput->sections; s; s = s->next)
7662 for (frchP = seg_info (s)->frchainP; frchP; frchP = frchP->frch_next)
7664 fragS *fragP;
7666 /* Walk over all of the fragments in a subsection. */
7667 for (fragP = frchP->frch_root; fragP; fragP = fragP->fr_next)
7669 if (fragP->fr_type == rs_machine_dependent
7670 && fragP->fr_subtype == RELAX_ADD_NOP_IF_PRE_LOOP_END)
7672 if (next_instr_is_loop_end (fragP))
7674 if (fragP->tc_frag_data.is_no_transform)
7675 as_bad (_("branching or jumping to a loop end may trigger hardware errata"));
7676 else
7677 relax_frag_add_nop (fragP);
7679 frag_wane (fragP);
7686 static bfd_boolean
7687 next_instr_is_loop_end (fragS *fragP)
7689 const fragS *next_fragP;
7691 if (next_frag_is_loop_target (fragP))
7692 return FALSE;
7694 next_fragP = next_non_empty_frag (fragP);
7695 if (next_fragP == NULL)
7696 return FALSE;
7698 if (!next_frag_is_loop_target (next_fragP))
7699 return FALSE;
7701 /* If the size is >= 3 then there is more than one instruction here.
7702 The hardware bug will not fire. */
7703 if (next_fragP->fr_fix > 3)
7704 return FALSE;
7706 return TRUE;
7710 /* Re-process all of the fragments looking to convert all of the
7711 RELAX_ADD_NOP_IF_CLOSE_LOOP_END. If there is an loop end that is
7712 not MY loop's loop end within 12 bytes, add enough nops here to
7713 make it at least 12 bytes away. In any case close it off with a
7714 .fill 0. */
7716 static offsetT min_bytes_to_other_loop_end
7717 (fragS *, fragS *, offsetT);
7719 static void
7720 xtensa_fix_close_loop_end_frags (void)
7722 frchainS *frchP;
7723 asection *s;
7725 /* When this routine is called, all of the subsections are still intact
7726 so we walk over subsections instead of sections. */
7727 for (s = stdoutput->sections; s; s = s->next)
7728 for (frchP = seg_info (s)->frchainP; frchP; frchP = frchP->frch_next)
7730 fragS *fragP;
7732 fragS *current_target = NULL;
7734 /* Walk over all of the fragments in a subsection. */
7735 for (fragP = frchP->frch_root; fragP; fragP = fragP->fr_next)
7737 if (fragP->fr_type == rs_machine_dependent
7738 && ((fragP->fr_subtype == RELAX_ALIGN_NEXT_OPCODE)
7739 || (fragP->fr_subtype == RELAX_CHECK_ALIGN_NEXT_OPCODE)))
7740 current_target = symbol_get_frag (fragP->fr_symbol);
7742 if (current_target
7743 && fragP->fr_type == rs_machine_dependent
7744 && fragP->fr_subtype == RELAX_ADD_NOP_IF_CLOSE_LOOP_END)
7746 offsetT min_bytes;
7747 int bytes_added = 0;
7749 #define REQUIRED_LOOP_DIVIDING_BYTES 12
7750 /* Max out at 12. */
7751 min_bytes = min_bytes_to_other_loop_end
7752 (fragP->fr_next, current_target, REQUIRED_LOOP_DIVIDING_BYTES);
7754 if (min_bytes < REQUIRED_LOOP_DIVIDING_BYTES)
7756 if (fragP->tc_frag_data.is_no_transform)
7757 as_bad (_("loop end too close to another loop end may trigger hardware errata"));
7758 else
7760 while (min_bytes + bytes_added
7761 < REQUIRED_LOOP_DIVIDING_BYTES)
7763 int length = 3;
7765 if (fragP->fr_var < length)
7766 as_fatal (_("fr_var %lu < length %d"),
7767 (long) fragP->fr_var, length);
7768 else
7770 assemble_nop (length,
7771 fragP->fr_literal + fragP->fr_fix);
7772 fragP->fr_fix += length;
7773 fragP->fr_var -= length;
7775 bytes_added += length;
7779 frag_wane (fragP);
7781 gas_assert (fragP->fr_type != rs_machine_dependent
7782 || fragP->fr_subtype != RELAX_ADD_NOP_IF_CLOSE_LOOP_END);
7788 static offsetT unrelaxed_frag_min_size (fragS *);
7790 static offsetT
7791 min_bytes_to_other_loop_end (fragS *fragP,
7792 fragS *current_target,
7793 offsetT max_size)
7795 offsetT offset = 0;
7796 fragS *current_fragP;
7798 for (current_fragP = fragP;
7799 current_fragP;
7800 current_fragP = current_fragP->fr_next)
7802 if (current_fragP->tc_frag_data.is_loop_target
7803 && current_fragP != current_target)
7804 return offset;
7806 offset += unrelaxed_frag_min_size (current_fragP);
7808 if (offset >= max_size)
7809 return max_size;
7811 return max_size;
7815 static offsetT
7816 unrelaxed_frag_min_size (fragS *fragP)
7818 offsetT size = fragP->fr_fix;
7820 /* Add fill size. */
7821 if (fragP->fr_type == rs_fill)
7822 size += fragP->fr_offset;
7824 return size;
7828 static offsetT
7829 unrelaxed_frag_max_size (fragS *fragP)
7831 offsetT size = fragP->fr_fix;
7832 switch (fragP->fr_type)
7834 case 0:
7835 /* Empty frags created by the obstack allocation scheme
7836 end up with type 0. */
7837 break;
7838 case rs_fill:
7839 case rs_org:
7840 case rs_space:
7841 size += fragP->fr_offset;
7842 break;
7843 case rs_align:
7844 case rs_align_code:
7845 case rs_align_test:
7846 case rs_leb128:
7847 case rs_cfa:
7848 case rs_dwarf2dbg:
7849 /* No further adjustments needed. */
7850 break;
7851 case rs_machine_dependent:
7852 if (fragP->fr_subtype != RELAX_DESIRE_ALIGN)
7853 size += fragP->fr_var;
7854 break;
7855 default:
7856 /* We had darn well better know how big it is. */
7857 gas_assert (0);
7858 break;
7861 return size;
7865 /* Re-process all of the fragments looking to convert all
7866 of the RELAX_ADD_NOP_IF_SHORT_LOOP. If:
7869 1) the instruction size count to the loop end label
7870 is too short (<= 2 instructions),
7871 2) loop has a jump or branch in it
7873 or B)
7874 1) workaround_all_short_loops is TRUE
7875 2) The generating loop was a 'loopgtz' or 'loopnez'
7876 3) the instruction size count to the loop end label is too short
7877 (<= 2 instructions)
7878 then convert this frag (and maybe the next one) to generate a NOP.
7879 In any case close it off with a .fill 0. */
7881 static int count_insns_to_loop_end (fragS *, bfd_boolean, int);
7882 static bfd_boolean branch_before_loop_end (fragS *);
7884 static void
7885 xtensa_fix_short_loop_frags (void)
7887 frchainS *frchP;
7888 asection *s;
7890 /* When this routine is called, all of the subsections are still intact
7891 so we walk over subsections instead of sections. */
7892 for (s = stdoutput->sections; s; s = s->next)
7893 for (frchP = seg_info (s)->frchainP; frchP; frchP = frchP->frch_next)
7895 fragS *fragP;
7896 fragS *current_target = NULL;
7897 xtensa_opcode current_opcode = XTENSA_UNDEFINED;
7899 /* Walk over all of the fragments in a subsection. */
7900 for (fragP = frchP->frch_root; fragP; fragP = fragP->fr_next)
7902 if (fragP->fr_type == rs_machine_dependent
7903 && ((fragP->fr_subtype == RELAX_ALIGN_NEXT_OPCODE)
7904 || (fragP->fr_subtype == RELAX_CHECK_ALIGN_NEXT_OPCODE)))
7906 TInsn t_insn;
7907 fragS *loop_frag = next_non_empty_frag (fragP);
7908 tinsn_from_chars (&t_insn, loop_frag->fr_opcode, 0);
7909 current_target = symbol_get_frag (fragP->fr_symbol);
7910 current_opcode = t_insn.opcode;
7911 gas_assert (xtensa_opcode_is_loop (xtensa_default_isa,
7912 current_opcode) == 1);
7915 if (fragP->fr_type == rs_machine_dependent
7916 && fragP->fr_subtype == RELAX_ADD_NOP_IF_SHORT_LOOP)
7918 if (count_insns_to_loop_end (fragP->fr_next, TRUE, 3) < 3
7919 && (branch_before_loop_end (fragP->fr_next)
7920 || (workaround_all_short_loops
7921 && current_opcode != XTENSA_UNDEFINED
7922 && current_opcode != xtensa_loop_opcode)))
7924 if (fragP->tc_frag_data.is_no_transform)
7925 as_bad (_("loop containing less than three instructions may trigger hardware errata"));
7926 else
7927 relax_frag_add_nop (fragP);
7929 frag_wane (fragP);
7936 static int unrelaxed_frag_min_insn_count (fragS *);
7938 static int
7939 count_insns_to_loop_end (fragS *base_fragP,
7940 bfd_boolean count_relax_add,
7941 int max_count)
7943 fragS *fragP = NULL;
7944 int insn_count = 0;
7946 fragP = base_fragP;
7948 for (; fragP && !fragP->tc_frag_data.is_loop_target; fragP = fragP->fr_next)
7950 insn_count += unrelaxed_frag_min_insn_count (fragP);
7951 if (insn_count >= max_count)
7952 return max_count;
7954 if (count_relax_add)
7956 if (fragP->fr_type == rs_machine_dependent
7957 && fragP->fr_subtype == RELAX_ADD_NOP_IF_SHORT_LOOP)
7959 /* In order to add the appropriate number of
7960 NOPs, we count an instruction for downstream
7961 occurrences. */
7962 insn_count++;
7963 if (insn_count >= max_count)
7964 return max_count;
7968 return insn_count;
7972 static int
7973 unrelaxed_frag_min_insn_count (fragS *fragP)
7975 xtensa_isa isa = xtensa_default_isa;
7976 static xtensa_insnbuf insnbuf = NULL;
7977 int insn_count = 0;
7978 int offset = 0;
7980 if (!fragP->tc_frag_data.is_insn)
7981 return insn_count;
7983 if (!insnbuf)
7984 insnbuf = xtensa_insnbuf_alloc (isa);
7986 /* Decode the fixed instructions. */
7987 while (offset < fragP->fr_fix)
7989 xtensa_format fmt;
7991 xtensa_insnbuf_from_chars
7992 (isa, insnbuf, (unsigned char *) fragP->fr_literal + offset, 0);
7993 fmt = xtensa_format_decode (isa, insnbuf);
7995 if (fmt == XTENSA_UNDEFINED)
7997 as_fatal (_("undecodable instruction in instruction frag"));
7998 return insn_count;
8000 offset += xtensa_format_length (isa, fmt);
8001 insn_count++;
8004 return insn_count;
8008 static bfd_boolean unrelaxed_frag_has_b_j (fragS *);
8010 static bfd_boolean
8011 branch_before_loop_end (fragS *base_fragP)
8013 fragS *fragP;
8015 for (fragP = base_fragP;
8016 fragP && !fragP->tc_frag_data.is_loop_target;
8017 fragP = fragP->fr_next)
8019 if (unrelaxed_frag_has_b_j (fragP))
8020 return TRUE;
8022 return FALSE;
8026 static bfd_boolean
8027 unrelaxed_frag_has_b_j (fragS *fragP)
8029 static xtensa_insnbuf insnbuf = NULL;
8030 xtensa_isa isa = xtensa_default_isa;
8031 int offset = 0;
8033 if (!fragP->tc_frag_data.is_insn)
8034 return FALSE;
8036 if (!insnbuf)
8037 insnbuf = xtensa_insnbuf_alloc (isa);
8039 /* Decode the fixed instructions. */
8040 while (offset < fragP->fr_fix)
8042 xtensa_format fmt;
8043 int slot;
8045 xtensa_insnbuf_from_chars
8046 (isa, insnbuf, (unsigned char *) fragP->fr_literal + offset, 0);
8047 fmt = xtensa_format_decode (isa, insnbuf);
8048 if (fmt == XTENSA_UNDEFINED)
8049 return FALSE;
8051 for (slot = 0; slot < xtensa_format_num_slots (isa, fmt); slot++)
8053 xtensa_opcode opcode =
8054 get_opcode_from_buf (fragP->fr_literal + offset, slot);
8055 if (xtensa_opcode_is_branch (isa, opcode) == 1
8056 || xtensa_opcode_is_jump (isa, opcode) == 1)
8057 return TRUE;
8059 offset += xtensa_format_length (isa, fmt);
8061 return FALSE;
8065 /* Checks to be made after initial assembly but before relaxation. */
8067 static bfd_boolean is_empty_loop (const TInsn *, fragS *);
8068 static bfd_boolean is_local_forward_loop (const TInsn *, fragS *);
8070 static void
8071 xtensa_sanity_check (void)
8073 char *file_name;
8074 unsigned line;
8075 frchainS *frchP;
8076 asection *s;
8078 as_where (&file_name, &line);
8079 for (s = stdoutput->sections; s; s = s->next)
8080 for (frchP = seg_info (s)->frchainP; frchP; frchP = frchP->frch_next)
8082 fragS *fragP;
8084 /* Walk over all of the fragments in a subsection. */
8085 for (fragP = frchP->frch_root; fragP; fragP = fragP->fr_next)
8087 if (fragP->fr_type == rs_machine_dependent
8088 && fragP->fr_subtype == RELAX_SLOTS
8089 && fragP->tc_frag_data.slot_subtypes[0] == RELAX_IMMED)
8091 static xtensa_insnbuf insnbuf = NULL;
8092 TInsn t_insn;
8094 if (fragP->fr_opcode != NULL)
8096 if (!insnbuf)
8097 insnbuf = xtensa_insnbuf_alloc (xtensa_default_isa);
8098 tinsn_from_chars (&t_insn, fragP->fr_opcode, 0);
8099 tinsn_immed_from_frag (&t_insn, fragP, 0);
8101 if (xtensa_opcode_is_loop (xtensa_default_isa,
8102 t_insn.opcode) == 1)
8104 if (is_empty_loop (&t_insn, fragP))
8106 new_logical_line (fragP->fr_file, fragP->fr_line);
8107 as_bad (_("invalid empty loop"));
8109 if (!is_local_forward_loop (&t_insn, fragP))
8111 new_logical_line (fragP->fr_file, fragP->fr_line);
8112 as_bad (_("loop target does not follow "
8113 "loop instruction in section"));
8120 new_logical_line (file_name, line);
8124 #define LOOP_IMMED_OPN 1
8126 /* Return TRUE if the loop target is the next non-zero fragment. */
8128 static bfd_boolean
8129 is_empty_loop (const TInsn *insn, fragS *fragP)
8131 const expressionS *exp;
8132 symbolS *symbolP;
8133 fragS *next_fragP;
8135 if (insn->insn_type != ITYPE_INSN)
8136 return FALSE;
8138 if (xtensa_opcode_is_loop (xtensa_default_isa, insn->opcode) != 1)
8139 return FALSE;
8141 if (insn->ntok <= LOOP_IMMED_OPN)
8142 return FALSE;
8144 exp = &insn->tok[LOOP_IMMED_OPN];
8146 if (exp->X_op != O_symbol)
8147 return FALSE;
8149 symbolP = exp->X_add_symbol;
8150 if (!symbolP)
8151 return FALSE;
8153 if (symbol_get_frag (symbolP) == NULL)
8154 return FALSE;
8156 if (S_GET_VALUE (symbolP) != 0)
8157 return FALSE;
8159 /* Walk through the zero-size fragments from this one. If we find
8160 the target fragment, then this is a zero-size loop. */
8162 for (next_fragP = fragP->fr_next;
8163 next_fragP != NULL;
8164 next_fragP = next_fragP->fr_next)
8166 if (next_fragP == symbol_get_frag (symbolP))
8167 return TRUE;
8168 if (next_fragP->fr_fix != 0)
8169 return FALSE;
8171 return FALSE;
8175 static bfd_boolean
8176 is_local_forward_loop (const TInsn *insn, fragS *fragP)
8178 const expressionS *exp;
8179 symbolS *symbolP;
8180 fragS *next_fragP;
8182 if (insn->insn_type != ITYPE_INSN)
8183 return FALSE;
8185 if (xtensa_opcode_is_loop (xtensa_default_isa, insn->opcode) != 1)
8186 return FALSE;
8188 if (insn->ntok <= LOOP_IMMED_OPN)
8189 return FALSE;
8191 exp = &insn->tok[LOOP_IMMED_OPN];
8193 if (exp->X_op != O_symbol)
8194 return FALSE;
8196 symbolP = exp->X_add_symbol;
8197 if (!symbolP)
8198 return FALSE;
8200 if (symbol_get_frag (symbolP) == NULL)
8201 return FALSE;
8203 /* Walk through fragments until we find the target.
8204 If we do not find the target, then this is an invalid loop. */
8206 for (next_fragP = fragP->fr_next;
8207 next_fragP != NULL;
8208 next_fragP = next_fragP->fr_next)
8210 if (next_fragP == symbol_get_frag (symbolP))
8211 return TRUE;
8214 return FALSE;
8218 #define XTINFO_NAME "Xtensa_Info"
8219 #define XTINFO_NAMESZ 12
8220 #define XTINFO_TYPE 1
8222 static void
8223 xtensa_add_config_info (void)
8225 asection *info_sec;
8226 char *data, *p;
8227 int sz;
8229 info_sec = subseg_new (".xtensa.info", 0);
8230 bfd_set_section_flags (stdoutput, info_sec, SEC_HAS_CONTENTS | SEC_READONLY);
8232 data = xmalloc (100);
8233 sprintf (data, "USE_ABSOLUTE_LITERALS=%d\nABI=%d\n",
8234 XSHAL_USE_ABSOLUTE_LITERALS, XSHAL_ABI);
8235 sz = strlen (data) + 1;
8237 /* Add enough null terminators to pad to a word boundary. */
8239 data[sz++] = 0;
8240 while ((sz & 3) != 0);
8242 /* Follow the standard note section layout:
8243 First write the length of the name string. */
8244 p = frag_more (4);
8245 md_number_to_chars (p, (valueT) XTINFO_NAMESZ, 4);
8247 /* Next comes the length of the "descriptor", i.e., the actual data. */
8248 p = frag_more (4);
8249 md_number_to_chars (p, (valueT) sz, 4);
8251 /* Write the note type. */
8252 p = frag_more (4);
8253 md_number_to_chars (p, (valueT) XTINFO_TYPE, 4);
8255 /* Write the name field. */
8256 p = frag_more (XTINFO_NAMESZ);
8257 memcpy (p, XTINFO_NAME, XTINFO_NAMESZ);
8259 /* Finally, write the descriptor. */
8260 p = frag_more (sz);
8261 memcpy (p, data, sz);
8263 free (data);
8267 /* Alignment Functions. */
8269 static int
8270 get_text_align_power (unsigned target_size)
8272 if (target_size <= 4)
8273 return 2;
8275 if (target_size <= 8)
8276 return 3;
8278 if (target_size <= 16)
8279 return 4;
8281 if (target_size <= 32)
8282 return 5;
8284 if (target_size <= 64)
8285 return 6;
8287 if (target_size <= 128)
8288 return 7;
8290 if (target_size <= 256)
8291 return 8;
8293 if (target_size <= 512)
8294 return 9;
8296 if (target_size <= 1024)
8297 return 10;
8299 gas_assert (0);
8300 return 0;
8304 static int
8305 get_text_align_max_fill_size (int align_pow,
8306 bfd_boolean use_nops,
8307 bfd_boolean use_no_density)
8309 if (!use_nops)
8310 return (1 << align_pow);
8311 if (use_no_density)
8312 return 3 * (1 << align_pow);
8314 return 1 + (1 << align_pow);
8318 /* Calculate the minimum bytes of fill needed at "address" to align a
8319 target instruction of size "target_size" so that it does not cross a
8320 power-of-two boundary specified by "align_pow". If "use_nops" is FALSE,
8321 the fill can be an arbitrary number of bytes. Otherwise, the space must
8322 be filled by NOP instructions. */
8324 static int
8325 get_text_align_fill_size (addressT address,
8326 int align_pow,
8327 int target_size,
8328 bfd_boolean use_nops,
8329 bfd_boolean use_no_density)
8331 addressT alignment, fill, fill_limit, fill_step;
8332 bfd_boolean skip_one = FALSE;
8334 alignment = (1 << align_pow);
8335 gas_assert (target_size > 0 && alignment >= (addressT) target_size);
8337 if (!use_nops)
8339 fill_limit = alignment;
8340 fill_step = 1;
8342 else if (!use_no_density)
8344 /* Combine 2- and 3-byte NOPs to fill anything larger than one. */
8345 fill_limit = alignment * 2;
8346 fill_step = 1;
8347 skip_one = TRUE;
8349 else
8351 /* Fill with 3-byte NOPs -- can only fill multiples of 3. */
8352 fill_limit = alignment * 3;
8353 fill_step = 3;
8356 /* Try all fill sizes until finding one that works. */
8357 for (fill = 0; fill < fill_limit; fill += fill_step)
8359 if (skip_one && fill == 1)
8360 continue;
8361 if ((address + fill) >> align_pow
8362 == (address + fill + target_size - 1) >> align_pow)
8363 return fill;
8365 gas_assert (0);
8366 return 0;
8370 static int
8371 branch_align_power (segT sec)
8373 /* If the Xtensa processor has a fetch width of X, and
8374 the section is aligned to at least that boundary, then a branch
8375 target need only fit within that aligned block of memory to avoid
8376 a stall. Otherwise, try to fit branch targets within 4-byte
8377 aligned blocks (which may be insufficient, e.g., if the section
8378 has no alignment, but it's good enough). */
8379 int fetch_align = get_text_align_power(xtensa_fetch_width);
8380 int sec_align = get_recorded_alignment (sec);
8382 if (sec_align >= fetch_align)
8383 return fetch_align;
8385 return 2;
8389 /* This will assert if it is not possible. */
8391 static int
8392 get_text_align_nop_count (offsetT fill_size, bfd_boolean use_no_density)
8394 int count = 0;
8396 if (use_no_density)
8398 gas_assert (fill_size % 3 == 0);
8399 return (fill_size / 3);
8402 gas_assert (fill_size != 1); /* Bad argument. */
8404 while (fill_size > 1)
8406 int insn_size = 3;
8407 if (fill_size == 2 || fill_size == 4)
8408 insn_size = 2;
8409 fill_size -= insn_size;
8410 count++;
8412 gas_assert (fill_size != 1); /* Bad algorithm. */
8413 return count;
8417 static int
8418 get_text_align_nth_nop_size (offsetT fill_size,
8419 int n,
8420 bfd_boolean use_no_density)
8422 int count = 0;
8424 if (use_no_density)
8425 return 3;
8427 gas_assert (fill_size != 1); /* Bad argument. */
8429 while (fill_size > 1)
8431 int insn_size = 3;
8432 if (fill_size == 2 || fill_size == 4)
8433 insn_size = 2;
8434 fill_size -= insn_size;
8435 count++;
8436 if (n + 1 == count)
8437 return insn_size;
8439 gas_assert (0);
8440 return 0;
8444 /* For the given fragment, find the appropriate address
8445 for it to begin at if we are using NOPs to align it. */
8447 static addressT
8448 get_noop_aligned_address (fragS *fragP, addressT address)
8450 /* The rule is: get next fragment's FIRST instruction. Find
8451 the smallest number of bytes that need to be added to
8452 ensure that the next fragment's FIRST instruction will fit
8453 in a single word.
8455 E.G., 2 bytes : 0, 1, 2 mod 4
8456 3 bytes: 0, 1 mod 4
8458 If the FIRST instruction MIGHT be relaxed,
8459 assume that it will become a 3-byte instruction.
8461 Note again here that LOOP instructions are not bundleable,
8462 and this relaxation only applies to LOOP opcodes. */
8464 int fill_size = 0;
8465 int first_insn_size;
8466 int loop_insn_size;
8467 addressT pre_opcode_bytes;
8468 int align_power;
8469 fragS *first_insn;
8470 xtensa_opcode opcode;
8471 bfd_boolean is_loop;
8473 gas_assert (fragP->fr_type == rs_machine_dependent);
8474 gas_assert (fragP->fr_subtype == RELAX_ALIGN_NEXT_OPCODE);
8476 /* Find the loop frag. */
8477 first_insn = next_non_empty_frag (fragP);
8478 /* Now find the first insn frag. */
8479 first_insn = next_non_empty_frag (first_insn);
8481 is_loop = next_frag_opcode_is_loop (fragP, &opcode);
8482 gas_assert (is_loop);
8483 loop_insn_size = xg_get_single_size (opcode);
8485 pre_opcode_bytes = next_frag_pre_opcode_bytes (fragP);
8486 pre_opcode_bytes += loop_insn_size;
8488 /* For loops, the alignment depends on the size of the
8489 instruction following the loop, not the LOOP instruction. */
8491 if (first_insn == NULL)
8492 first_insn_size = xtensa_fetch_width;
8493 else
8494 first_insn_size = get_loop_align_size (frag_format_size (first_insn));
8496 /* If it was 8, then we'll need a larger alignment for the section. */
8497 align_power = get_text_align_power (first_insn_size);
8498 record_alignment (now_seg, align_power);
8500 fill_size = get_text_align_fill_size
8501 (address + pre_opcode_bytes, align_power, first_insn_size, TRUE,
8502 fragP->tc_frag_data.is_no_density);
8504 return address + fill_size;
8508 /* 3 mechanisms for relaxing an alignment:
8510 Align to a power of 2.
8511 Align so the next fragment's instruction does not cross a word boundary.
8512 Align the current instruction so that if the next instruction
8513 were 3 bytes, it would not cross a word boundary.
8515 We can align with:
8517 zeros - This is easy; always insert zeros.
8518 nops - 3-byte and 2-byte instructions
8519 2 - 2-byte nop
8520 3 - 3-byte nop
8521 4 - 2 2-byte nops
8522 >=5 : 3-byte instruction + fn (n-3)
8523 widening - widen previous instructions. */
8525 static offsetT
8526 get_aligned_diff (fragS *fragP, addressT address, offsetT *max_diff)
8528 addressT target_address, loop_insn_offset;
8529 int target_size;
8530 xtensa_opcode loop_opcode;
8531 bfd_boolean is_loop;
8532 int align_power;
8533 offsetT opt_diff;
8534 offsetT branch_align;
8535 fragS *loop_frag;
8537 gas_assert (fragP->fr_type == rs_machine_dependent);
8538 switch (fragP->fr_subtype)
8540 case RELAX_DESIRE_ALIGN:
8541 target_size = next_frag_format_size (fragP);
8542 if (target_size == XTENSA_UNDEFINED)
8543 target_size = 3;
8544 align_power = branch_align_power (now_seg);
8545 branch_align = 1 << align_power;
8546 /* Don't count on the section alignment being as large as the target. */
8547 if (target_size > branch_align)
8548 target_size = branch_align;
8549 opt_diff = get_text_align_fill_size (address, align_power,
8550 target_size, FALSE, FALSE);
8552 *max_diff = (opt_diff + branch_align
8553 - (target_size + ((address + opt_diff) % branch_align)));
8554 gas_assert (*max_diff >= opt_diff);
8555 return opt_diff;
8557 case RELAX_ALIGN_NEXT_OPCODE:
8558 /* The next non-empty frag after this one holds the LOOP instruction
8559 that needs to be aligned. The required alignment depends on the
8560 size of the next non-empty frag after the loop frag, i.e., the
8561 first instruction in the loop. */
8562 loop_frag = next_non_empty_frag (fragP);
8563 target_size = get_loop_align_size (next_frag_format_size (loop_frag));
8564 loop_insn_offset = 0;
8565 is_loop = next_frag_opcode_is_loop (fragP, &loop_opcode);
8566 gas_assert (is_loop);
8568 /* If the loop has been expanded then the LOOP instruction
8569 could be at an offset from this fragment. */
8570 if (loop_frag->tc_frag_data.slot_subtypes[0] != RELAX_IMMED)
8571 loop_insn_offset = get_expanded_loop_offset (loop_opcode);
8573 /* In an ideal world, which is what we are shooting for here,
8574 we wouldn't need to use any NOPs immediately prior to the
8575 LOOP instruction. If this approach fails, relax_frag_loop_align
8576 will call get_noop_aligned_address. */
8577 target_address =
8578 address + loop_insn_offset + xg_get_single_size (loop_opcode);
8579 align_power = get_text_align_power (target_size);
8580 opt_diff = get_text_align_fill_size (target_address, align_power,
8581 target_size, FALSE, FALSE);
8583 *max_diff = xtensa_fetch_width
8584 - ((target_address + opt_diff) % xtensa_fetch_width)
8585 - target_size + opt_diff;
8586 gas_assert (*max_diff >= opt_diff);
8587 return opt_diff;
8589 default:
8590 break;
8592 gas_assert (0);
8593 return 0;
8597 /* md_relax_frag Hook and Helper Functions. */
8599 static long relax_frag_loop_align (fragS *, long);
8600 static long relax_frag_for_align (fragS *, long);
8601 static long relax_frag_immed
8602 (segT, fragS *, long, int, xtensa_format, int, int *, bfd_boolean);
8605 /* Return the number of bytes added to this fragment, given that the
8606 input has been stretched already by "stretch". */
8608 long
8609 xtensa_relax_frag (fragS *fragP, long stretch, int *stretched_p)
8611 xtensa_isa isa = xtensa_default_isa;
8612 int unreported = fragP->tc_frag_data.unreported_expansion;
8613 long new_stretch = 0;
8614 char *file_name;
8615 unsigned line;
8616 int lit_size;
8617 static xtensa_insnbuf vbuf = NULL;
8618 int slot, num_slots;
8619 xtensa_format fmt;
8621 as_where (&file_name, &line);
8622 new_logical_line (fragP->fr_file, fragP->fr_line);
8624 fragP->tc_frag_data.unreported_expansion = 0;
8626 switch (fragP->fr_subtype)
8628 case RELAX_ALIGN_NEXT_OPCODE:
8629 /* Always convert. */
8630 if (fragP->tc_frag_data.relax_seen)
8631 new_stretch = relax_frag_loop_align (fragP, stretch);
8632 break;
8634 case RELAX_LOOP_END:
8635 /* Do nothing. */
8636 break;
8638 case RELAX_LOOP_END_ADD_NOP:
8639 /* Add a NOP and switch to .fill 0. */
8640 new_stretch = relax_frag_add_nop (fragP);
8641 frag_wane (fragP);
8642 break;
8644 case RELAX_DESIRE_ALIGN:
8645 /* Do nothing. The narrowing before this frag will either align
8646 it or not. */
8647 break;
8649 case RELAX_LITERAL:
8650 case RELAX_LITERAL_FINAL:
8651 return 0;
8653 case RELAX_LITERAL_NR:
8654 lit_size = 4;
8655 fragP->fr_subtype = RELAX_LITERAL_FINAL;
8656 gas_assert (unreported == lit_size);
8657 memset (&fragP->fr_literal[fragP->fr_fix], 0, 4);
8658 fragP->fr_var -= lit_size;
8659 fragP->fr_fix += lit_size;
8660 new_stretch = 4;
8661 break;
8663 case RELAX_SLOTS:
8664 if (vbuf == NULL)
8665 vbuf = xtensa_insnbuf_alloc (isa);
8667 xtensa_insnbuf_from_chars
8668 (isa, vbuf, (unsigned char *) fragP->fr_opcode, 0);
8669 fmt = xtensa_format_decode (isa, vbuf);
8670 num_slots = xtensa_format_num_slots (isa, fmt);
8672 for (slot = 0; slot < num_slots; slot++)
8674 switch (fragP->tc_frag_data.slot_subtypes[slot])
8676 case RELAX_NARROW:
8677 if (fragP->tc_frag_data.relax_seen)
8678 new_stretch += relax_frag_for_align (fragP, stretch);
8679 break;
8681 case RELAX_IMMED:
8682 case RELAX_IMMED_STEP1:
8683 case RELAX_IMMED_STEP2:
8684 case RELAX_IMMED_STEP3:
8685 /* Place the immediate. */
8686 new_stretch += relax_frag_immed
8687 (now_seg, fragP, stretch,
8688 fragP->tc_frag_data.slot_subtypes[slot] - RELAX_IMMED,
8689 fmt, slot, stretched_p, FALSE);
8690 break;
8692 default:
8693 /* This is OK; see the note in xg_assemble_vliw_tokens. */
8694 break;
8697 break;
8699 case RELAX_LITERAL_POOL_BEGIN:
8700 case RELAX_LITERAL_POOL_END:
8701 case RELAX_MAYBE_UNREACHABLE:
8702 case RELAX_MAYBE_DESIRE_ALIGN:
8703 /* No relaxation required. */
8704 break;
8706 case RELAX_FILL_NOP:
8707 case RELAX_UNREACHABLE:
8708 if (fragP->tc_frag_data.relax_seen)
8709 new_stretch += relax_frag_for_align (fragP, stretch);
8710 break;
8712 default:
8713 as_bad (_("bad relaxation state"));
8716 /* Tell gas we need another relaxation pass. */
8717 if (! fragP->tc_frag_data.relax_seen)
8719 fragP->tc_frag_data.relax_seen = TRUE;
8720 *stretched_p = 1;
8723 new_logical_line (file_name, line);
8724 return new_stretch;
8728 static long
8729 relax_frag_loop_align (fragS *fragP, long stretch)
8731 addressT old_address, old_next_address, old_size;
8732 addressT new_address, new_next_address, new_size;
8733 addressT growth;
8735 /* All the frags with relax_frag_for_alignment prior to this one in the
8736 section have been done, hopefully eliminating the need for a NOP here.
8737 But, this will put it in if necessary. */
8739 /* Calculate the old address of this fragment and the next fragment. */
8740 old_address = fragP->fr_address - stretch;
8741 old_next_address = (fragP->fr_address - stretch + fragP->fr_fix +
8742 fragP->tc_frag_data.text_expansion[0]);
8743 old_size = old_next_address - old_address;
8745 /* Calculate the new address of this fragment and the next fragment. */
8746 new_address = fragP->fr_address;
8747 new_next_address =
8748 get_noop_aligned_address (fragP, fragP->fr_address + fragP->fr_fix);
8749 new_size = new_next_address - new_address;
8751 growth = new_size - old_size;
8753 /* Fix up the text_expansion field and return the new growth. */
8754 fragP->tc_frag_data.text_expansion[0] += growth;
8755 return growth;
8759 /* Add a NOP instruction. */
8761 static long
8762 relax_frag_add_nop (fragS *fragP)
8764 char *nop_buf = fragP->fr_literal + fragP->fr_fix;
8765 int length = fragP->tc_frag_data.is_no_density ? 3 : 2;
8766 assemble_nop (length, nop_buf);
8767 fragP->tc_frag_data.is_insn = TRUE;
8769 if (fragP->fr_var < length)
8771 as_fatal (_("fr_var (%ld) < length (%d)"), (long) fragP->fr_var, length);
8772 return 0;
8775 fragP->fr_fix += length;
8776 fragP->fr_var -= length;
8777 return length;
8781 static long future_alignment_required (fragS *, long);
8783 static long
8784 relax_frag_for_align (fragS *fragP, long stretch)
8786 /* Overview of the relaxation procedure for alignment:
8787 We can widen with NOPs or by widening instructions or by filling
8788 bytes after jump instructions. Find the opportune places and widen
8789 them if necessary. */
8791 long stretch_me;
8792 long diff;
8794 gas_assert (fragP->fr_subtype == RELAX_FILL_NOP
8795 || fragP->fr_subtype == RELAX_UNREACHABLE
8796 || (fragP->fr_subtype == RELAX_SLOTS
8797 && fragP->tc_frag_data.slot_subtypes[0] == RELAX_NARROW));
8799 stretch_me = future_alignment_required (fragP, stretch);
8800 diff = stretch_me - fragP->tc_frag_data.text_expansion[0];
8801 if (diff == 0)
8802 return 0;
8804 if (diff < 0)
8806 /* We expanded on a previous pass. Can we shrink now? */
8807 long shrink = fragP->tc_frag_data.text_expansion[0] - stretch_me;
8808 if (shrink <= stretch && stretch > 0)
8810 fragP->tc_frag_data.text_expansion[0] = stretch_me;
8811 return -shrink;
8813 return 0;
8816 /* Below here, diff > 0. */
8817 fragP->tc_frag_data.text_expansion[0] = stretch_me;
8819 return diff;
8823 /* Return the address of the next frag that should be aligned.
8825 By "address" we mean the address it _would_ be at if there
8826 is no action taken to align it between here and the target frag.
8827 In other words, if no narrows and no fill nops are used between
8828 here and the frag to align, _even_if_ some of the frags we use
8829 to align targets have already expanded on a previous relaxation
8830 pass.
8832 Also, count each frag that may be used to help align the target.
8834 Return 0 if there are no frags left in the chain that need to be
8835 aligned. */
8837 static addressT
8838 find_address_of_next_align_frag (fragS **fragPP,
8839 int *wide_nops,
8840 int *narrow_nops,
8841 int *widens,
8842 bfd_boolean *paddable)
8844 fragS *fragP = *fragPP;
8845 addressT address = fragP->fr_address;
8847 /* Do not reset the counts to 0. */
8849 while (fragP)
8851 /* Limit this to a small search. */
8852 if (*widens >= (int) xtensa_fetch_width)
8854 *fragPP = fragP;
8855 return 0;
8857 address += fragP->fr_fix;
8859 if (fragP->fr_type == rs_fill)
8860 address += fragP->fr_offset * fragP->fr_var;
8861 else if (fragP->fr_type == rs_machine_dependent)
8863 switch (fragP->fr_subtype)
8865 case RELAX_UNREACHABLE:
8866 *paddable = TRUE;
8867 break;
8869 case RELAX_FILL_NOP:
8870 (*wide_nops)++;
8871 if (!fragP->tc_frag_data.is_no_density)
8872 (*narrow_nops)++;
8873 break;
8875 case RELAX_SLOTS:
8876 if (fragP->tc_frag_data.slot_subtypes[0] == RELAX_NARROW)
8878 (*widens)++;
8879 break;
8881 address += total_frag_text_expansion (fragP);;
8882 break;
8884 case RELAX_IMMED:
8885 address += fragP->tc_frag_data.text_expansion[0];
8886 break;
8888 case RELAX_ALIGN_NEXT_OPCODE:
8889 case RELAX_DESIRE_ALIGN:
8890 *fragPP = fragP;
8891 return address;
8893 case RELAX_MAYBE_UNREACHABLE:
8894 case RELAX_MAYBE_DESIRE_ALIGN:
8895 /* Do nothing. */
8896 break;
8898 default:
8899 /* Just punt if we don't know the type. */
8900 *fragPP = fragP;
8901 return 0;
8904 else
8906 /* Just punt if we don't know the type. */
8907 *fragPP = fragP;
8908 return 0;
8910 fragP = fragP->fr_next;
8913 *fragPP = fragP;
8914 return 0;
8918 static long bytes_to_stretch (fragS *, int, int, int, int);
8920 static long
8921 future_alignment_required (fragS *fragP, long stretch ATTRIBUTE_UNUSED)
8923 fragS *this_frag = fragP;
8924 long address;
8925 int num_widens = 0;
8926 int wide_nops = 0;
8927 int narrow_nops = 0;
8928 bfd_boolean paddable = FALSE;
8929 offsetT local_opt_diff;
8930 offsetT opt_diff;
8931 offsetT max_diff;
8932 int stretch_amount = 0;
8933 int local_stretch_amount;
8934 int global_stretch_amount;
8936 address = find_address_of_next_align_frag
8937 (&fragP, &wide_nops, &narrow_nops, &num_widens, &paddable);
8939 if (!address)
8941 if (this_frag->tc_frag_data.is_aligning_branch)
8942 this_frag->tc_frag_data.slot_subtypes[0] = RELAX_IMMED;
8943 else
8944 frag_wane (this_frag);
8946 else
8948 local_opt_diff = get_aligned_diff (fragP, address, &max_diff);
8949 opt_diff = local_opt_diff;
8950 gas_assert (opt_diff >= 0);
8951 gas_assert (max_diff >= opt_diff);
8952 if (max_diff == 0)
8953 return 0;
8955 if (fragP)
8956 fragP = fragP->fr_next;
8958 while (fragP && opt_diff < max_diff && address)
8960 /* We only use these to determine if we can exit early
8961 because there will be plenty of ways to align future
8962 align frags. */
8963 int glob_widens = 0;
8964 int dnn = 0;
8965 int dw = 0;
8966 bfd_boolean glob_pad = 0;
8967 address = find_address_of_next_align_frag
8968 (&fragP, &glob_widens, &dnn, &dw, &glob_pad);
8969 /* If there is a padable portion, then skip. */
8970 if (glob_pad || glob_widens >= (1 << branch_align_power (now_seg)))
8971 address = 0;
8973 if (address)
8975 offsetT next_m_diff;
8976 offsetT next_o_diff;
8978 /* Downrange frags haven't had stretch added to them yet. */
8979 address += stretch;
8981 /* The address also includes any text expansion from this
8982 frag in a previous pass, but we don't want that. */
8983 address -= this_frag->tc_frag_data.text_expansion[0];
8985 /* Assume we are going to move at least opt_diff. In
8986 reality, we might not be able to, but assuming that
8987 we will helps catch cases where moving opt_diff pushes
8988 the next target from aligned to unaligned. */
8989 address += opt_diff;
8991 next_o_diff = get_aligned_diff (fragP, address, &next_m_diff);
8993 /* Now cleanup for the adjustments to address. */
8994 next_o_diff += opt_diff;
8995 next_m_diff += opt_diff;
8996 if (next_o_diff <= max_diff && next_o_diff > opt_diff)
8997 opt_diff = next_o_diff;
8998 if (next_m_diff < max_diff)
8999 max_diff = next_m_diff;
9000 fragP = fragP->fr_next;
9004 /* If there are enough wideners in between, do it. */
9005 if (paddable)
9007 if (this_frag->fr_subtype == RELAX_UNREACHABLE)
9009 gas_assert (opt_diff <= (signed) xtensa_fetch_width);
9010 return opt_diff;
9012 return 0;
9014 local_stretch_amount
9015 = bytes_to_stretch (this_frag, wide_nops, narrow_nops,
9016 num_widens, local_opt_diff);
9017 global_stretch_amount
9018 = bytes_to_stretch (this_frag, wide_nops, narrow_nops,
9019 num_widens, opt_diff);
9020 /* If the condition below is true, then the frag couldn't
9021 stretch the correct amount for the global case, so we just
9022 optimize locally. We'll rely on the subsequent frags to get
9023 the correct alignment in the global case. */
9024 if (global_stretch_amount < local_stretch_amount)
9025 stretch_amount = local_stretch_amount;
9026 else
9027 stretch_amount = global_stretch_amount;
9029 if (this_frag->fr_subtype == RELAX_SLOTS
9030 && this_frag->tc_frag_data.slot_subtypes[0] == RELAX_NARROW)
9031 gas_assert (stretch_amount <= 1);
9032 else if (this_frag->fr_subtype == RELAX_FILL_NOP)
9034 if (this_frag->tc_frag_data.is_no_density)
9035 gas_assert (stretch_amount == 3 || stretch_amount == 0);
9036 else
9037 gas_assert (stretch_amount <= 3);
9040 return stretch_amount;
9044 /* The idea: widen everything you can to get a target or loop aligned,
9045 then start using NOPs.
9047 wide_nops = the number of wide NOPs available for aligning
9048 narrow_nops = the number of narrow NOPs available for aligning
9049 (a subset of wide_nops)
9050 widens = the number of narrow instructions that should be widened
9054 static long
9055 bytes_to_stretch (fragS *this_frag,
9056 int wide_nops,
9057 int narrow_nops,
9058 int num_widens,
9059 int desired_diff)
9061 int nops_needed;
9062 int nop_bytes;
9063 int extra_bytes;
9064 int bytes_short = desired_diff - num_widens;
9066 gas_assert (desired_diff >= 0
9067 && desired_diff < (signed) xtensa_fetch_width);
9068 if (desired_diff == 0)
9069 return 0;
9071 gas_assert (wide_nops > 0 || num_widens > 0);
9073 /* Always prefer widening to NOP-filling. */
9074 if (bytes_short < 0)
9076 /* There are enough RELAX_NARROW frags after this one
9077 to align the target without widening this frag in any way. */
9078 return 0;
9081 if (bytes_short == 0)
9083 /* Widen every narrow between here and the align target
9084 and the align target will be properly aligned. */
9085 if (this_frag->fr_subtype == RELAX_FILL_NOP)
9086 return 0;
9087 else
9088 return 1;
9091 /* From here we will need at least one NOP to get an alignment.
9092 However, we may not be able to align at all, in which case,
9093 don't widen. */
9094 nops_needed = desired_diff / 3;
9096 /* If there aren't enough nops, don't widen. */
9097 if (nops_needed > wide_nops)
9098 return 0;
9100 /* First try it with all wide nops. */
9101 nop_bytes = nops_needed * 3;
9102 extra_bytes = desired_diff - nop_bytes;
9104 if (nop_bytes + num_widens >= desired_diff)
9106 if (this_frag->fr_subtype == RELAX_FILL_NOP)
9107 return 3;
9108 else if (num_widens == extra_bytes)
9109 return 1;
9110 return 0;
9113 /* Add a narrow nop. */
9114 nops_needed++;
9115 nop_bytes += 2;
9116 extra_bytes -= 2;
9117 if (narrow_nops == 0 || nops_needed > wide_nops)
9118 return 0;
9120 if (nop_bytes + num_widens >= desired_diff && extra_bytes >= 0)
9122 if (this_frag->fr_subtype == RELAX_FILL_NOP)
9123 return !this_frag->tc_frag_data.is_no_density ? 2 : 3;
9124 else if (num_widens == extra_bytes)
9125 return 1;
9126 return 0;
9129 /* Replace a wide nop with a narrow nop--we can get here if
9130 extra_bytes was negative in the previous conditional. */
9131 if (narrow_nops == 1)
9132 return 0;
9133 nop_bytes--;
9134 extra_bytes++;
9135 if (nop_bytes + num_widens >= desired_diff)
9137 if (this_frag->fr_subtype == RELAX_FILL_NOP)
9138 return !this_frag->tc_frag_data.is_no_density ? 2 : 3;
9139 else if (num_widens == extra_bytes)
9140 return 1;
9141 return 0;
9144 /* If we can't satisfy any of the above cases, then we can't align
9145 using padding or fill nops. */
9146 return 0;
9150 static long
9151 relax_frag_immed (segT segP,
9152 fragS *fragP,
9153 long stretch,
9154 int min_steps,
9155 xtensa_format fmt,
9156 int slot,
9157 int *stretched_p,
9158 bfd_boolean estimate_only)
9160 TInsn tinsn;
9161 int old_size;
9162 bfd_boolean negatable_branch = FALSE;
9163 bfd_boolean branch_jmp_to_next = FALSE;
9164 bfd_boolean from_wide_insn = FALSE;
9165 xtensa_isa isa = xtensa_default_isa;
9166 IStack istack;
9167 offsetT frag_offset;
9168 int num_steps;
9169 int num_text_bytes, num_literal_bytes;
9170 int literal_diff, total_text_diff, this_text_diff;
9172 gas_assert (fragP->fr_opcode != NULL);
9174 xg_clear_vinsn (&cur_vinsn);
9175 vinsn_from_chars (&cur_vinsn, fragP->fr_opcode);
9176 if (cur_vinsn.num_slots > 1)
9177 from_wide_insn = TRUE;
9179 tinsn = cur_vinsn.slots[slot];
9180 tinsn_immed_from_frag (&tinsn, fragP, slot);
9182 if (estimate_only && xtensa_opcode_is_loop (isa, tinsn.opcode) == 1)
9183 return 0;
9185 if (workaround_b_j_loop_end && ! fragP->tc_frag_data.is_no_transform)
9186 branch_jmp_to_next = is_branch_jmp_to_next (&tinsn, fragP);
9188 negatable_branch = (xtensa_opcode_is_branch (isa, tinsn.opcode) == 1);
9190 old_size = xtensa_format_length (isa, fmt);
9192 /* Special case: replace a branch to the next instruction with a NOP.
9193 This is required to work around a hardware bug in T1040.0 and also
9194 serves as an optimization. */
9196 if (branch_jmp_to_next
9197 && ((old_size == 2) || (old_size == 3))
9198 && !next_frag_is_loop_target (fragP))
9199 return 0;
9201 /* Here is the fun stuff: Get the immediate field from this
9202 instruction. If it fits, we are done. If not, find the next
9203 instruction sequence that fits. */
9205 frag_offset = fragP->fr_opcode - fragP->fr_literal;
9206 istack_init (&istack);
9207 num_steps = xg_assembly_relax (&istack, &tinsn, segP, fragP, frag_offset,
9208 min_steps, stretch);
9209 gas_assert (num_steps >= min_steps && num_steps <= RELAX_IMMED_MAXSTEPS);
9211 fragP->tc_frag_data.slot_subtypes[slot] = (int) RELAX_IMMED + num_steps;
9213 /* Figure out the number of bytes needed. */
9214 num_literal_bytes = get_num_stack_literal_bytes (&istack);
9215 literal_diff
9216 = num_literal_bytes - fragP->tc_frag_data.literal_expansion[slot];
9217 num_text_bytes = get_num_stack_text_bytes (&istack);
9219 if (from_wide_insn)
9221 int first = 0;
9222 while (istack.insn[first].opcode == XTENSA_UNDEFINED)
9223 first++;
9225 num_text_bytes += old_size;
9226 if (opcode_fits_format_slot (istack.insn[first].opcode, fmt, slot))
9227 num_text_bytes -= xg_get_single_size (istack.insn[first].opcode);
9228 else
9230 /* The first instruction in the relaxed sequence will go after
9231 the current wide instruction, and thus its symbolic immediates
9232 might not fit. */
9234 istack_init (&istack);
9235 num_steps = xg_assembly_relax (&istack, &tinsn, segP, fragP,
9236 frag_offset + old_size,
9237 min_steps, stretch + old_size);
9238 gas_assert (num_steps >= min_steps && num_steps <= RELAX_IMMED_MAXSTEPS);
9240 fragP->tc_frag_data.slot_subtypes[slot]
9241 = (int) RELAX_IMMED + num_steps;
9243 num_literal_bytes = get_num_stack_literal_bytes (&istack);
9244 literal_diff
9245 = num_literal_bytes - fragP->tc_frag_data.literal_expansion[slot];
9247 num_text_bytes = get_num_stack_text_bytes (&istack) + old_size;
9251 total_text_diff = num_text_bytes - old_size;
9252 this_text_diff = total_text_diff - fragP->tc_frag_data.text_expansion[slot];
9254 /* It MUST get larger. If not, we could get an infinite loop. */
9255 gas_assert (num_text_bytes >= 0);
9256 gas_assert (literal_diff >= 0);
9257 gas_assert (total_text_diff >= 0);
9259 fragP->tc_frag_data.text_expansion[slot] = total_text_diff;
9260 fragP->tc_frag_data.literal_expansion[slot] = num_literal_bytes;
9261 gas_assert (fragP->tc_frag_data.text_expansion[slot] >= 0);
9262 gas_assert (fragP->tc_frag_data.literal_expansion[slot] >= 0);
9264 /* Find the associated expandable literal for this. */
9265 if (literal_diff != 0)
9267 fragS *lit_fragP = fragP->tc_frag_data.literal_frags[slot];
9268 if (lit_fragP)
9270 gas_assert (literal_diff == 4);
9271 lit_fragP->tc_frag_data.unreported_expansion += literal_diff;
9273 /* We expect that the literal section state has NOT been
9274 modified yet. */
9275 gas_assert (lit_fragP->fr_type == rs_machine_dependent
9276 && lit_fragP->fr_subtype == RELAX_LITERAL);
9277 lit_fragP->fr_subtype = RELAX_LITERAL_NR;
9279 /* We need to mark this section for another iteration
9280 of relaxation. */
9281 (*stretched_p)++;
9285 if (negatable_branch && istack.ninsn > 1)
9286 update_next_frag_state (fragP);
9288 return this_text_diff;
9292 /* md_convert_frag Hook and Helper Functions. */
9294 static void convert_frag_align_next_opcode (fragS *);
9295 static void convert_frag_narrow (segT, fragS *, xtensa_format, int);
9296 static void convert_frag_fill_nop (fragS *);
9297 static void convert_frag_immed (segT, fragS *, int, xtensa_format, int);
9299 void
9300 md_convert_frag (bfd *abfd ATTRIBUTE_UNUSED, segT sec, fragS *fragp)
9302 static xtensa_insnbuf vbuf = NULL;
9303 xtensa_isa isa = xtensa_default_isa;
9304 int slot;
9305 int num_slots;
9306 xtensa_format fmt;
9307 char *file_name;
9308 unsigned line;
9310 as_where (&file_name, &line);
9311 new_logical_line (fragp->fr_file, fragp->fr_line);
9313 switch (fragp->fr_subtype)
9315 case RELAX_ALIGN_NEXT_OPCODE:
9316 /* Always convert. */
9317 convert_frag_align_next_opcode (fragp);
9318 break;
9320 case RELAX_DESIRE_ALIGN:
9321 /* Do nothing. If not aligned already, too bad. */
9322 break;
9324 case RELAX_LITERAL:
9325 case RELAX_LITERAL_FINAL:
9326 break;
9328 case RELAX_SLOTS:
9329 if (vbuf == NULL)
9330 vbuf = xtensa_insnbuf_alloc (isa);
9332 xtensa_insnbuf_from_chars
9333 (isa, vbuf, (unsigned char *) fragp->fr_opcode, 0);
9334 fmt = xtensa_format_decode (isa, vbuf);
9335 num_slots = xtensa_format_num_slots (isa, fmt);
9337 for (slot = 0; slot < num_slots; slot++)
9339 switch (fragp->tc_frag_data.slot_subtypes[slot])
9341 case RELAX_NARROW:
9342 convert_frag_narrow (sec, fragp, fmt, slot);
9343 break;
9345 case RELAX_IMMED:
9346 case RELAX_IMMED_STEP1:
9347 case RELAX_IMMED_STEP2:
9348 case RELAX_IMMED_STEP3:
9349 /* Place the immediate. */
9350 convert_frag_immed
9351 (sec, fragp,
9352 fragp->tc_frag_data.slot_subtypes[slot] - RELAX_IMMED,
9353 fmt, slot);
9354 break;
9356 default:
9357 /* This is OK because some slots could have
9358 relaxations and others have none. */
9359 break;
9362 break;
9364 case RELAX_UNREACHABLE:
9365 memset (&fragp->fr_literal[fragp->fr_fix], 0, fragp->fr_var);
9366 fragp->fr_fix += fragp->tc_frag_data.text_expansion[0];
9367 fragp->fr_var -= fragp->tc_frag_data.text_expansion[0];
9368 frag_wane (fragp);
9369 break;
9371 case RELAX_MAYBE_UNREACHABLE:
9372 case RELAX_MAYBE_DESIRE_ALIGN:
9373 frag_wane (fragp);
9374 break;
9376 case RELAX_FILL_NOP:
9377 convert_frag_fill_nop (fragp);
9378 break;
9380 case RELAX_LITERAL_NR:
9381 if (use_literal_section)
9383 /* This should have been handled during relaxation. When
9384 relaxing a code segment, literals sometimes need to be
9385 added to the corresponding literal segment. If that
9386 literal segment has already been relaxed, then we end up
9387 in this situation. Marking the literal segments as data
9388 would make this happen less often (since GAS always relaxes
9389 code before data), but we could still get into trouble if
9390 there are instructions in a segment that is not marked as
9391 containing code. Until we can implement a better solution,
9392 cheat and adjust the addresses of all the following frags.
9393 This could break subsequent alignments, but the linker's
9394 literal coalescing will do that anyway. */
9396 fragS *f;
9397 fragp->fr_subtype = RELAX_LITERAL_FINAL;
9398 gas_assert (fragp->tc_frag_data.unreported_expansion == 4);
9399 memset (&fragp->fr_literal[fragp->fr_fix], 0, 4);
9400 fragp->fr_var -= 4;
9401 fragp->fr_fix += 4;
9402 for (f = fragp->fr_next; f; f = f->fr_next)
9403 f->fr_address += 4;
9405 else
9406 as_bad (_("invalid relaxation fragment result"));
9407 break;
9410 fragp->fr_var = 0;
9411 new_logical_line (file_name, line);
9415 static void
9416 convert_frag_align_next_opcode (fragS *fragp)
9418 char *nop_buf; /* Location for Writing. */
9419 bfd_boolean use_no_density = fragp->tc_frag_data.is_no_density;
9420 addressT aligned_address;
9421 offsetT fill_size;
9422 int nop, nop_count;
9424 aligned_address = get_noop_aligned_address (fragp, fragp->fr_address +
9425 fragp->fr_fix);
9426 fill_size = aligned_address - (fragp->fr_address + fragp->fr_fix);
9427 nop_count = get_text_align_nop_count (fill_size, use_no_density);
9428 nop_buf = fragp->fr_literal + fragp->fr_fix;
9430 for (nop = 0; nop < nop_count; nop++)
9432 int nop_size;
9433 nop_size = get_text_align_nth_nop_size (fill_size, nop, use_no_density);
9435 assemble_nop (nop_size, nop_buf);
9436 nop_buf += nop_size;
9439 fragp->fr_fix += fill_size;
9440 fragp->fr_var -= fill_size;
9444 static void
9445 convert_frag_narrow (segT segP, fragS *fragP, xtensa_format fmt, int slot)
9447 TInsn tinsn, single_target;
9448 int size, old_size, diff;
9449 offsetT frag_offset;
9451 gas_assert (slot == 0);
9452 tinsn_from_chars (&tinsn, fragP->fr_opcode, 0);
9454 if (fragP->tc_frag_data.is_aligning_branch == 1)
9456 gas_assert (fragP->tc_frag_data.text_expansion[0] == 1
9457 || fragP->tc_frag_data.text_expansion[0] == 0);
9458 convert_frag_immed (segP, fragP, fragP->tc_frag_data.text_expansion[0],
9459 fmt, slot);
9460 return;
9463 if (fragP->tc_frag_data.text_expansion[0] == 0)
9465 /* No conversion. */
9466 fragP->fr_var = 0;
9467 return;
9470 gas_assert (fragP->fr_opcode != NULL);
9472 /* Frags in this relaxation state should only contain
9473 single instruction bundles. */
9474 tinsn_immed_from_frag (&tinsn, fragP, 0);
9476 /* Just convert it to a wide form.... */
9477 size = 0;
9478 old_size = xg_get_single_size (tinsn.opcode);
9480 tinsn_init (&single_target);
9481 frag_offset = fragP->fr_opcode - fragP->fr_literal;
9483 if (! xg_is_single_relaxable_insn (&tinsn, &single_target, FALSE))
9485 as_bad (_("unable to widen instruction"));
9486 return;
9489 size = xg_get_single_size (single_target.opcode);
9490 xg_emit_insn_to_buf (&single_target, fragP->fr_opcode, fragP,
9491 frag_offset, TRUE);
9493 diff = size - old_size;
9494 gas_assert (diff >= 0);
9495 gas_assert (diff <= fragP->fr_var);
9496 fragP->fr_var -= diff;
9497 fragP->fr_fix += diff;
9499 /* clean it up */
9500 fragP->fr_var = 0;
9504 static void
9505 convert_frag_fill_nop (fragS *fragP)
9507 char *loc = &fragP->fr_literal[fragP->fr_fix];
9508 int size = fragP->tc_frag_data.text_expansion[0];
9509 gas_assert ((unsigned) size == (fragP->fr_next->fr_address
9510 - fragP->fr_address - fragP->fr_fix));
9511 if (size == 0)
9513 /* No conversion. */
9514 fragP->fr_var = 0;
9515 return;
9517 assemble_nop (size, loc);
9518 fragP->tc_frag_data.is_insn = TRUE;
9519 fragP->fr_var -= size;
9520 fragP->fr_fix += size;
9521 frag_wane (fragP);
9525 static fixS *fix_new_exp_in_seg
9526 (segT, subsegT, fragS *, int, int, expressionS *, int,
9527 bfd_reloc_code_real_type);
9528 static void convert_frag_immed_finish_loop (segT, fragS *, TInsn *);
9530 static void
9531 convert_frag_immed (segT segP,
9532 fragS *fragP,
9533 int min_steps,
9534 xtensa_format fmt,
9535 int slot)
9537 char *immed_instr = fragP->fr_opcode;
9538 TInsn orig_tinsn;
9539 bfd_boolean expanded = FALSE;
9540 bfd_boolean branch_jmp_to_next = FALSE;
9541 char *fr_opcode = fragP->fr_opcode;
9542 xtensa_isa isa = xtensa_default_isa;
9543 bfd_boolean from_wide_insn = FALSE;
9544 int bytes;
9545 bfd_boolean is_loop;
9547 gas_assert (fr_opcode != NULL);
9549 xg_clear_vinsn (&cur_vinsn);
9551 vinsn_from_chars (&cur_vinsn, fr_opcode);
9552 if (cur_vinsn.num_slots > 1)
9553 from_wide_insn = TRUE;
9555 orig_tinsn = cur_vinsn.slots[slot];
9556 tinsn_immed_from_frag (&orig_tinsn, fragP, slot);
9558 is_loop = xtensa_opcode_is_loop (xtensa_default_isa, orig_tinsn.opcode) == 1;
9560 if (workaround_b_j_loop_end && ! fragP->tc_frag_data.is_no_transform)
9561 branch_jmp_to_next = is_branch_jmp_to_next (&orig_tinsn, fragP);
9563 if (branch_jmp_to_next && !next_frag_is_loop_target (fragP))
9565 /* Conversion just inserts a NOP and marks the fix as completed. */
9566 bytes = xtensa_format_length (isa, fmt);
9567 if (bytes >= 4)
9569 cur_vinsn.slots[slot].opcode =
9570 xtensa_format_slot_nop_opcode (isa, cur_vinsn.format, slot);
9571 cur_vinsn.slots[slot].ntok = 0;
9573 else
9575 bytes += fragP->tc_frag_data.text_expansion[0];
9576 gas_assert (bytes == 2 || bytes == 3);
9577 build_nop (&cur_vinsn.slots[0], bytes);
9578 fragP->fr_fix += fragP->tc_frag_data.text_expansion[0];
9580 vinsn_to_insnbuf (&cur_vinsn, fr_opcode, frag_now, TRUE);
9581 xtensa_insnbuf_to_chars
9582 (isa, cur_vinsn.insnbuf, (unsigned char *) fr_opcode, 0);
9583 fragP->fr_var = 0;
9585 else
9587 /* Here is the fun stuff: Get the immediate field from this
9588 instruction. If it fits, we're done. If not, find the next
9589 instruction sequence that fits. */
9591 IStack istack;
9592 int i;
9593 symbolS *lit_sym = NULL;
9594 int total_size = 0;
9595 int target_offset = 0;
9596 int old_size;
9597 int diff;
9598 symbolS *gen_label = NULL;
9599 offsetT frag_offset;
9600 bfd_boolean first = TRUE;
9601 bfd_boolean last_is_jump;
9603 /* It does not fit. Find something that does and
9604 convert immediately. */
9605 frag_offset = fr_opcode - fragP->fr_literal;
9606 istack_init (&istack);
9607 xg_assembly_relax (&istack, &orig_tinsn,
9608 segP, fragP, frag_offset, min_steps, 0);
9610 old_size = xtensa_format_length (isa, fmt);
9612 /* Assemble this right inline. */
9614 /* First, create the mapping from a label name to the REAL label. */
9615 target_offset = 0;
9616 for (i = 0; i < istack.ninsn; i++)
9618 TInsn *tinsn = &istack.insn[i];
9619 fragS *lit_frag;
9621 switch (tinsn->insn_type)
9623 case ITYPE_LITERAL:
9624 if (lit_sym != NULL)
9625 as_bad (_("multiple literals in expansion"));
9626 /* First find the appropriate space in the literal pool. */
9627 lit_frag = fragP->tc_frag_data.literal_frags[slot];
9628 if (lit_frag == NULL)
9629 as_bad (_("no registered fragment for literal"));
9630 if (tinsn->ntok != 1)
9631 as_bad (_("number of literal tokens != 1"));
9633 /* Set the literal symbol and add a fixup. */
9634 lit_sym = lit_frag->fr_symbol;
9635 break;
9637 case ITYPE_LABEL:
9638 if (align_targets && !is_loop)
9640 fragS *unreach = fragP->fr_next;
9641 while (!(unreach->fr_type == rs_machine_dependent
9642 && (unreach->fr_subtype == RELAX_MAYBE_UNREACHABLE
9643 || unreach->fr_subtype == RELAX_UNREACHABLE)))
9645 unreach = unreach->fr_next;
9648 gas_assert (unreach->fr_type == rs_machine_dependent
9649 && (unreach->fr_subtype == RELAX_MAYBE_UNREACHABLE
9650 || unreach->fr_subtype == RELAX_UNREACHABLE));
9652 target_offset += unreach->tc_frag_data.text_expansion[0];
9654 gas_assert (gen_label == NULL);
9655 gen_label = symbol_new (FAKE_LABEL_NAME, now_seg,
9656 fr_opcode - fragP->fr_literal
9657 + target_offset, fragP);
9658 break;
9660 case ITYPE_INSN:
9661 if (first && from_wide_insn)
9663 target_offset += xtensa_format_length (isa, fmt);
9664 first = FALSE;
9665 if (!opcode_fits_format_slot (tinsn->opcode, fmt, slot))
9666 target_offset += xg_get_single_size (tinsn->opcode);
9668 else
9669 target_offset += xg_get_single_size (tinsn->opcode);
9670 break;
9674 total_size = 0;
9675 first = TRUE;
9676 last_is_jump = FALSE;
9677 for (i = 0; i < istack.ninsn; i++)
9679 TInsn *tinsn = &istack.insn[i];
9680 fragS *lit_frag;
9681 int size;
9682 segT target_seg;
9683 bfd_reloc_code_real_type reloc_type;
9685 switch (tinsn->insn_type)
9687 case ITYPE_LITERAL:
9688 lit_frag = fragP->tc_frag_data.literal_frags[slot];
9689 /* Already checked. */
9690 gas_assert (lit_frag != NULL);
9691 gas_assert (lit_sym != NULL);
9692 gas_assert (tinsn->ntok == 1);
9693 /* Add a fixup. */
9694 target_seg = S_GET_SEGMENT (lit_sym);
9695 gas_assert (target_seg);
9696 reloc_type = map_operator_to_reloc (tinsn->tok[0].X_op, TRUE);
9697 fix_new_exp_in_seg (target_seg, 0, lit_frag, 0, 4,
9698 &tinsn->tok[0], FALSE, reloc_type);
9699 break;
9701 case ITYPE_LABEL:
9702 break;
9704 case ITYPE_INSN:
9705 xg_resolve_labels (tinsn, gen_label);
9706 xg_resolve_literals (tinsn, lit_sym);
9707 if (from_wide_insn && first)
9709 first = FALSE;
9710 if (opcode_fits_format_slot (tinsn->opcode, fmt, slot))
9712 cur_vinsn.slots[slot] = *tinsn;
9714 else
9716 cur_vinsn.slots[slot].opcode =
9717 xtensa_format_slot_nop_opcode (isa, fmt, slot);
9718 cur_vinsn.slots[slot].ntok = 0;
9720 vinsn_to_insnbuf (&cur_vinsn, immed_instr, fragP, TRUE);
9721 xtensa_insnbuf_to_chars (isa, cur_vinsn.insnbuf,
9722 (unsigned char *) immed_instr, 0);
9723 fragP->tc_frag_data.is_insn = TRUE;
9724 size = xtensa_format_length (isa, fmt);
9725 if (!opcode_fits_format_slot (tinsn->opcode, fmt, slot))
9727 xg_emit_insn_to_buf
9728 (tinsn, immed_instr + size, fragP,
9729 immed_instr - fragP->fr_literal + size, TRUE);
9730 size += xg_get_single_size (tinsn->opcode);
9733 else
9735 size = xg_get_single_size (tinsn->opcode);
9736 xg_emit_insn_to_buf (tinsn, immed_instr, fragP,
9737 immed_instr - fragP->fr_literal, TRUE);
9739 immed_instr += size;
9740 total_size += size;
9741 break;
9745 diff = total_size - old_size;
9746 gas_assert (diff >= 0);
9747 if (diff != 0)
9748 expanded = TRUE;
9749 gas_assert (diff <= fragP->fr_var);
9750 fragP->fr_var -= diff;
9751 fragP->fr_fix += diff;
9754 /* Check for undefined immediates in LOOP instructions. */
9755 if (is_loop)
9757 symbolS *sym;
9758 sym = orig_tinsn.tok[1].X_add_symbol;
9759 if (sym != NULL && !S_IS_DEFINED (sym))
9761 as_bad (_("unresolved loop target symbol: %s"), S_GET_NAME (sym));
9762 return;
9764 sym = orig_tinsn.tok[1].X_op_symbol;
9765 if (sym != NULL && !S_IS_DEFINED (sym))
9767 as_bad (_("unresolved loop target symbol: %s"), S_GET_NAME (sym));
9768 return;
9772 if (expanded && xtensa_opcode_is_loop (isa, orig_tinsn.opcode) == 1)
9773 convert_frag_immed_finish_loop (segP, fragP, &orig_tinsn);
9775 if (expanded && is_direct_call_opcode (orig_tinsn.opcode))
9777 /* Add an expansion note on the expanded instruction. */
9778 fix_new_exp_in_seg (now_seg, 0, fragP, fr_opcode - fragP->fr_literal, 4,
9779 &orig_tinsn.tok[0], TRUE,
9780 BFD_RELOC_XTENSA_ASM_EXPAND);
9785 /* Add a new fix expression into the desired segment. We have to
9786 switch to that segment to do this. */
9788 static fixS *
9789 fix_new_exp_in_seg (segT new_seg,
9790 subsegT new_subseg,
9791 fragS *frag,
9792 int where,
9793 int size,
9794 expressionS *exp,
9795 int pcrel,
9796 bfd_reloc_code_real_type r_type)
9798 fixS *new_fix;
9799 segT seg = now_seg;
9800 subsegT subseg = now_subseg;
9802 gas_assert (new_seg != 0);
9803 subseg_set (new_seg, new_subseg);
9805 new_fix = fix_new_exp (frag, where, size, exp, pcrel, r_type);
9806 subseg_set (seg, subseg);
9807 return new_fix;
9811 /* Relax a loop instruction so that it can span loop >256 bytes.
9813 loop as, .L1
9814 .L0:
9815 rsr as, LEND
9816 wsr as, LBEG
9817 addi as, as, lo8 (label-.L1)
9818 addmi as, as, mid8 (label-.L1)
9819 wsr as, LEND
9820 isync
9821 rsr as, LCOUNT
9822 addi as, as, 1
9823 .L1:
9824 <<body>>
9825 label:
9828 static void
9829 convert_frag_immed_finish_loop (segT segP, fragS *fragP, TInsn *tinsn)
9831 TInsn loop_insn;
9832 TInsn addi_insn;
9833 TInsn addmi_insn;
9834 unsigned long target;
9835 static xtensa_insnbuf insnbuf = NULL;
9836 unsigned int loop_length, loop_length_hi, loop_length_lo;
9837 xtensa_isa isa = xtensa_default_isa;
9838 addressT loop_offset;
9839 addressT addi_offset = 9;
9840 addressT addmi_offset = 12;
9841 fragS *next_fragP;
9842 int target_count;
9844 if (!insnbuf)
9845 insnbuf = xtensa_insnbuf_alloc (isa);
9847 /* Get the loop offset. */
9848 loop_offset = get_expanded_loop_offset (tinsn->opcode);
9850 /* Validate that there really is a LOOP at the loop_offset. Because
9851 loops are not bundleable, we can assume that the instruction will be
9852 in slot 0. */
9853 tinsn_from_chars (&loop_insn, fragP->fr_opcode + loop_offset, 0);
9854 tinsn_immed_from_frag (&loop_insn, fragP, 0);
9856 gas_assert (xtensa_opcode_is_loop (isa, loop_insn.opcode) == 1);
9857 addi_offset += loop_offset;
9858 addmi_offset += loop_offset;
9860 gas_assert (tinsn->ntok == 2);
9861 if (tinsn->tok[1].X_op == O_constant)
9862 target = tinsn->tok[1].X_add_number;
9863 else if (tinsn->tok[1].X_op == O_symbol)
9865 /* Find the fragment. */
9866 symbolS *sym = tinsn->tok[1].X_add_symbol;
9867 gas_assert (S_GET_SEGMENT (sym) == segP
9868 || S_GET_SEGMENT (sym) == absolute_section);
9869 target = (S_GET_VALUE (sym) + tinsn->tok[1].X_add_number);
9871 else
9873 as_bad (_("invalid expression evaluation type %d"), tinsn->tok[1].X_op);
9874 target = 0;
9877 loop_length = target - (fragP->fr_address + fragP->fr_fix);
9878 loop_length_hi = loop_length & ~0x0ff;
9879 loop_length_lo = loop_length & 0x0ff;
9880 if (loop_length_lo >= 128)
9882 loop_length_lo -= 256;
9883 loop_length_hi += 256;
9886 /* Because addmi sign-extends the immediate, 'loop_length_hi' can be at most
9887 32512. If the loop is larger than that, then we just fail. */
9888 if (loop_length_hi > 32512)
9889 as_bad_where (fragP->fr_file, fragP->fr_line,
9890 _("loop too long for LOOP instruction"));
9892 tinsn_from_chars (&addi_insn, fragP->fr_opcode + addi_offset, 0);
9893 gas_assert (addi_insn.opcode == xtensa_addi_opcode);
9895 tinsn_from_chars (&addmi_insn, fragP->fr_opcode + addmi_offset, 0);
9896 gas_assert (addmi_insn.opcode == xtensa_addmi_opcode);
9898 set_expr_const (&addi_insn.tok[2], loop_length_lo);
9899 tinsn_to_insnbuf (&addi_insn, insnbuf);
9901 fragP->tc_frag_data.is_insn = TRUE;
9902 xtensa_insnbuf_to_chars
9903 (isa, insnbuf, (unsigned char *) fragP->fr_opcode + addi_offset, 0);
9905 set_expr_const (&addmi_insn.tok[2], loop_length_hi);
9906 tinsn_to_insnbuf (&addmi_insn, insnbuf);
9907 xtensa_insnbuf_to_chars
9908 (isa, insnbuf, (unsigned char *) fragP->fr_opcode + addmi_offset, 0);
9910 /* Walk through all of the frags from here to the loop end
9911 and mark them as no_transform to keep them from being modified
9912 by the linker. If we ever have a relocation for the
9913 addi/addmi of the difference of two symbols we can remove this. */
9915 target_count = 0;
9916 for (next_fragP = fragP; next_fragP != NULL;
9917 next_fragP = next_fragP->fr_next)
9919 next_fragP->tc_frag_data.is_no_transform = TRUE;
9920 if (next_fragP->tc_frag_data.is_loop_target)
9921 target_count++;
9922 if (target_count == 2)
9923 break;
9928 /* A map that keeps information on a per-subsegment basis. This is
9929 maintained during initial assembly, but is invalid once the
9930 subsegments are smashed together. I.E., it cannot be used during
9931 the relaxation. */
9933 typedef struct subseg_map_struct
9935 /* the key */
9936 segT seg;
9937 subsegT subseg;
9939 /* the data */
9940 unsigned flags;
9941 float total_freq; /* fall-through + branch target frequency */
9942 float target_freq; /* branch target frequency alone */
9944 struct subseg_map_struct *next;
9945 } subseg_map;
9948 static subseg_map *sseg_map = NULL;
9950 static subseg_map *
9951 get_subseg_info (segT seg, subsegT subseg)
9953 subseg_map *subseg_e;
9955 for (subseg_e = sseg_map; subseg_e; subseg_e = subseg_e->next)
9957 if (seg == subseg_e->seg && subseg == subseg_e->subseg)
9958 break;
9960 return subseg_e;
9964 static subseg_map *
9965 add_subseg_info (segT seg, subsegT subseg)
9967 subseg_map *subseg_e = (subseg_map *) xmalloc (sizeof (subseg_map));
9968 memset (subseg_e, 0, sizeof (subseg_map));
9969 subseg_e->seg = seg;
9970 subseg_e->subseg = subseg;
9971 subseg_e->flags = 0;
9972 /* Start off considering every branch target very important. */
9973 subseg_e->target_freq = 1.0;
9974 subseg_e->total_freq = 1.0;
9975 subseg_e->next = sseg_map;
9976 sseg_map = subseg_e;
9977 return subseg_e;
9981 static unsigned
9982 get_last_insn_flags (segT seg, subsegT subseg)
9984 subseg_map *subseg_e = get_subseg_info (seg, subseg);
9985 if (subseg_e)
9986 return subseg_e->flags;
9987 return 0;
9991 static void
9992 set_last_insn_flags (segT seg,
9993 subsegT subseg,
9994 unsigned fl,
9995 bfd_boolean val)
9997 subseg_map *subseg_e = get_subseg_info (seg, subseg);
9998 if (! subseg_e)
9999 subseg_e = add_subseg_info (seg, subseg);
10000 if (val)
10001 subseg_e->flags |= fl;
10002 else
10003 subseg_e->flags &= ~fl;
10007 static float
10008 get_subseg_total_freq (segT seg, subsegT subseg)
10010 subseg_map *subseg_e = get_subseg_info (seg, subseg);
10011 if (subseg_e)
10012 return subseg_e->total_freq;
10013 return 1.0;
10017 static float
10018 get_subseg_target_freq (segT seg, subsegT subseg)
10020 subseg_map *subseg_e = get_subseg_info (seg, subseg);
10021 if (subseg_e)
10022 return subseg_e->target_freq;
10023 return 1.0;
10027 static void
10028 set_subseg_freq (segT seg, subsegT subseg, float total_f, float target_f)
10030 subseg_map *subseg_e = get_subseg_info (seg, subseg);
10031 if (! subseg_e)
10032 subseg_e = add_subseg_info (seg, subseg);
10033 subseg_e->total_freq = total_f;
10034 subseg_e->target_freq = target_f;
10038 /* Segment Lists and emit_state Stuff. */
10040 static void
10041 xtensa_move_seg_list_to_beginning (seg_list *head)
10043 head = head->next;
10044 while (head)
10046 segT literal_section = head->seg;
10048 /* Move the literal section to the front of the section list. */
10049 gas_assert (literal_section);
10050 if (literal_section != stdoutput->sections)
10052 bfd_section_list_remove (stdoutput, literal_section);
10053 bfd_section_list_prepend (stdoutput, literal_section);
10055 head = head->next;
10060 static void mark_literal_frags (seg_list *);
10062 static void
10063 xtensa_move_literals (void)
10065 seg_list *segment;
10066 frchainS *frchain_from, *frchain_to;
10067 fragS *search_frag, *next_frag, *last_frag, *literal_pool, *insert_after;
10068 fragS **frag_splice;
10069 emit_state state;
10070 segT dest_seg;
10071 fixS *fix, *next_fix, **fix_splice;
10072 sym_list *lit;
10074 mark_literal_frags (literal_head->next);
10076 if (use_literal_section)
10077 return;
10079 for (segment = literal_head->next; segment; segment = segment->next)
10081 /* Keep the literals for .init and .fini in separate sections. */
10082 if (!strcmp (segment_name (segment->seg), INIT_SECTION_NAME)
10083 || !strcmp (segment_name (segment->seg), FINI_SECTION_NAME))
10084 continue;
10086 frchain_from = seg_info (segment->seg)->frchainP;
10087 search_frag = frchain_from->frch_root;
10088 literal_pool = NULL;
10089 frchain_to = NULL;
10090 frag_splice = &(frchain_from->frch_root);
10092 while (!search_frag->tc_frag_data.literal_frag)
10094 gas_assert (search_frag->fr_fix == 0
10095 || search_frag->fr_type == rs_align);
10096 search_frag = search_frag->fr_next;
10099 gas_assert (search_frag->tc_frag_data.literal_frag->fr_subtype
10100 == RELAX_LITERAL_POOL_BEGIN);
10101 xtensa_switch_section_emit_state (&state, segment->seg, 0);
10103 /* Make sure that all the frags in this series are closed, and
10104 that there is at least one left over of zero-size. This
10105 prevents us from making a segment with an frchain without any
10106 frags in it. */
10107 frag_variant (rs_fill, 0, 0, 0, NULL, 0, NULL);
10108 xtensa_set_frag_assembly_state (frag_now);
10109 last_frag = frag_now;
10110 frag_variant (rs_fill, 0, 0, 0, NULL, 0, NULL);
10111 xtensa_set_frag_assembly_state (frag_now);
10113 while (search_frag != frag_now)
10115 next_frag = search_frag->fr_next;
10117 /* First, move the frag out of the literal section and
10118 to the appropriate place. */
10119 if (search_frag->tc_frag_data.literal_frag)
10121 literal_pool = search_frag->tc_frag_data.literal_frag;
10122 gas_assert (literal_pool->fr_subtype == RELAX_LITERAL_POOL_BEGIN);
10123 frchain_to = literal_pool->tc_frag_data.lit_frchain;
10124 gas_assert (frchain_to);
10126 insert_after = literal_pool->tc_frag_data.literal_frag;
10127 dest_seg = insert_after->fr_next->tc_frag_data.lit_seg;
10129 *frag_splice = next_frag;
10130 search_frag->fr_next = insert_after->fr_next;
10131 insert_after->fr_next = search_frag;
10132 search_frag->tc_frag_data.lit_seg = dest_seg;
10133 literal_pool->tc_frag_data.literal_frag = search_frag;
10135 /* Now move any fixups associated with this frag to the
10136 right section. */
10137 fix = frchain_from->fix_root;
10138 fix_splice = &(frchain_from->fix_root);
10139 while (fix)
10141 next_fix = fix->fx_next;
10142 if (fix->fx_frag == search_frag)
10144 *fix_splice = next_fix;
10145 fix->fx_next = frchain_to->fix_root;
10146 frchain_to->fix_root = fix;
10147 if (frchain_to->fix_tail == NULL)
10148 frchain_to->fix_tail = fix;
10150 else
10151 fix_splice = &(fix->fx_next);
10152 fix = next_fix;
10154 search_frag = next_frag;
10157 if (frchain_from->fix_root != NULL)
10159 frchain_from = seg_info (segment->seg)->frchainP;
10160 as_warn (_("fixes not all moved from %s"), segment->seg->name);
10162 gas_assert (frchain_from->fix_root == NULL);
10164 frchain_from->fix_tail = NULL;
10165 xtensa_restore_emit_state (&state);
10168 /* Now fix up the SEGMENT value for all the literal symbols. */
10169 for (lit = literal_syms; lit; lit = lit->next)
10171 symbolS *lit_sym = lit->sym;
10172 segT dseg = symbol_get_frag (lit_sym)->tc_frag_data.lit_seg;
10173 if (dseg)
10174 S_SET_SEGMENT (lit_sym, dseg);
10179 /* Walk over all the frags for segments in a list and mark them as
10180 containing literals. As clunky as this is, we can't rely on frag_var
10181 and frag_variant to get called in all situations. */
10183 static void
10184 mark_literal_frags (seg_list *segment)
10186 frchainS *frchain_from;
10187 fragS *search_frag;
10189 while (segment)
10191 frchain_from = seg_info (segment->seg)->frchainP;
10192 search_frag = frchain_from->frch_root;
10193 while (search_frag)
10195 search_frag->tc_frag_data.is_literal = TRUE;
10196 search_frag = search_frag->fr_next;
10198 segment = segment->next;
10203 static void
10204 xtensa_reorder_seg_list (seg_list *head, segT after)
10206 /* Move all of the sections in the section list to come
10207 after "after" in the gnu segment list. */
10209 head = head->next;
10210 while (head)
10212 segT literal_section = head->seg;
10214 /* Move the literal section after "after". */
10215 gas_assert (literal_section);
10216 if (literal_section != after)
10218 bfd_section_list_remove (stdoutput, literal_section);
10219 bfd_section_list_insert_after (stdoutput, after, literal_section);
10222 head = head->next;
10227 /* Push all the literal segments to the end of the gnu list. */
10229 static void
10230 xtensa_reorder_segments (void)
10232 segT sec;
10233 segT last_sec = 0;
10234 int old_count = 0;
10235 int new_count = 0;
10237 for (sec = stdoutput->sections; sec != NULL; sec = sec->next)
10239 last_sec = sec;
10240 old_count++;
10243 /* Now that we have the last section, push all the literal
10244 sections to the end. */
10245 xtensa_reorder_seg_list (literal_head, last_sec);
10247 /* Now perform the final error check. */
10248 for (sec = stdoutput->sections; sec != NULL; sec = sec->next)
10249 new_count++;
10250 gas_assert (new_count == old_count);
10254 /* Change the emit state (seg, subseg, and frag related stuff) to the
10255 correct location. Return a emit_state which can be passed to
10256 xtensa_restore_emit_state to return to current fragment. */
10258 static void
10259 xtensa_switch_to_literal_fragment (emit_state *result)
10261 if (directive_state[directive_absolute_literals])
10263 segT lit4_seg = cache_literal_section (TRUE);
10264 xtensa_switch_section_emit_state (result, lit4_seg, 0);
10266 else
10267 xtensa_switch_to_non_abs_literal_fragment (result);
10269 /* Do a 4-byte align here. */
10270 frag_align (2, 0, 0);
10271 record_alignment (now_seg, 2);
10275 static void
10276 xtensa_switch_to_non_abs_literal_fragment (emit_state *result)
10278 static bfd_boolean recursive = FALSE;
10279 fragS *pool_location = get_literal_pool_location (now_seg);
10280 segT lit_seg;
10281 bfd_boolean is_init =
10282 (now_seg && !strcmp (segment_name (now_seg), INIT_SECTION_NAME));
10283 bfd_boolean is_fini =
10284 (now_seg && !strcmp (segment_name (now_seg), FINI_SECTION_NAME));
10286 if (pool_location == NULL
10287 && !use_literal_section
10288 && !recursive
10289 && !is_init && ! is_fini)
10291 as_bad (_("literal pool location required for text-section-literals; specify with .literal_position"));
10293 /* When we mark a literal pool location, we want to put a frag in
10294 the literal pool that points to it. But to do that, we want to
10295 switch_to_literal_fragment. But literal sections don't have
10296 literal pools, so their location is always null, so we would
10297 recurse forever. This is kind of hacky, but it works. */
10299 recursive = TRUE;
10300 xtensa_mark_literal_pool_location ();
10301 recursive = FALSE;
10304 lit_seg = cache_literal_section (FALSE);
10305 xtensa_switch_section_emit_state (result, lit_seg, 0);
10307 if (!use_literal_section
10308 && !is_init && !is_fini
10309 && get_literal_pool_location (now_seg) != pool_location)
10311 /* Close whatever frag is there. */
10312 frag_variant (rs_fill, 0, 0, 0, NULL, 0, NULL);
10313 xtensa_set_frag_assembly_state (frag_now);
10314 frag_now->tc_frag_data.literal_frag = pool_location;
10315 frag_variant (rs_fill, 0, 0, 0, NULL, 0, NULL);
10316 xtensa_set_frag_assembly_state (frag_now);
10321 /* Call this function before emitting data into the literal section.
10322 This is a helper function for xtensa_switch_to_literal_fragment.
10323 This is similar to a .section new_now_seg subseg. */
10325 static void
10326 xtensa_switch_section_emit_state (emit_state *state,
10327 segT new_now_seg,
10328 subsegT new_now_subseg)
10330 state->name = now_seg->name;
10331 state->now_seg = now_seg;
10332 state->now_subseg = now_subseg;
10333 state->generating_literals = generating_literals;
10334 generating_literals++;
10335 subseg_set (new_now_seg, new_now_subseg);
10339 /* Use to restore the emitting into the normal place. */
10341 static void
10342 xtensa_restore_emit_state (emit_state *state)
10344 generating_literals = state->generating_literals;
10345 subseg_set (state->now_seg, state->now_subseg);
10349 /* Predicate function used to look up a section in a particular group. */
10351 static bfd_boolean
10352 match_section_group (bfd *abfd ATTRIBUTE_UNUSED, asection *sec, void *inf)
10354 const char *gname = inf;
10355 const char *group_name = elf_group_name (sec);
10357 return (group_name == gname
10358 || (group_name != NULL
10359 && gname != NULL
10360 && strcmp (group_name, gname) == 0));
10364 /* Get the literal section to be used for the current text section.
10365 The result may be cached in the default_lit_sections structure. */
10367 static segT
10368 cache_literal_section (bfd_boolean use_abs_literals)
10370 const char *text_name, *group_name = 0;
10371 char *base_name, *name, *suffix;
10372 segT *pcached;
10373 segT seg, current_section;
10374 int current_subsec;
10375 bfd_boolean linkonce = FALSE;
10377 /* Save the current section/subsection. */
10378 current_section = now_seg;
10379 current_subsec = now_subseg;
10381 /* Clear the cached values if they are no longer valid. */
10382 if (now_seg != default_lit_sections.current_text_seg)
10384 default_lit_sections.current_text_seg = now_seg;
10385 default_lit_sections.lit_seg = NULL;
10386 default_lit_sections.lit4_seg = NULL;
10389 /* Check if the literal section is already cached. */
10390 if (use_abs_literals)
10391 pcached = &default_lit_sections.lit4_seg;
10392 else
10393 pcached = &default_lit_sections.lit_seg;
10395 if (*pcached)
10396 return *pcached;
10398 text_name = default_lit_sections.lit_prefix;
10399 if (! text_name || ! *text_name)
10401 text_name = segment_name (current_section);
10402 group_name = elf_group_name (current_section);
10403 linkonce = (current_section->flags & SEC_LINK_ONCE) != 0;
10406 base_name = use_abs_literals ? ".lit4" : ".literal";
10407 if (group_name)
10409 name = xmalloc (strlen (base_name) + strlen (group_name) + 2);
10410 sprintf (name, "%s.%s", base_name, group_name);
10412 else if (strncmp (text_name, ".gnu.linkonce.", linkonce_len) == 0)
10414 suffix = strchr (text_name + linkonce_len, '.');
10416 name = xmalloc (linkonce_len + strlen (base_name) + 1
10417 + (suffix ? strlen (suffix) : 0));
10418 strcpy (name, ".gnu.linkonce");
10419 strcat (name, base_name);
10420 if (suffix)
10421 strcat (name, suffix);
10422 linkonce = TRUE;
10424 else
10426 /* If the section name begins or ends with ".text", then replace
10427 that portion instead of appending an additional suffix. */
10428 size_t len = strlen (text_name);
10429 if (len >= 5
10430 && (strcmp (text_name + len - 5, ".text") == 0
10431 || strncmp (text_name, ".text", 5) == 0))
10432 len -= 5;
10434 name = xmalloc (len + strlen (base_name) + 1);
10435 if (strncmp (text_name, ".text", 5) == 0)
10437 strcpy (name, base_name);
10438 strcat (name, text_name + 5);
10440 else
10442 strcpy (name, text_name);
10443 strcpy (name + len, base_name);
10447 /* Canonicalize section names to allow renaming literal sections.
10448 The group name, if any, came from the current text section and
10449 has already been canonicalized. */
10450 name = tc_canonicalize_symbol_name (name);
10452 seg = bfd_get_section_by_name_if (stdoutput, name, match_section_group,
10453 (void *) group_name);
10454 if (! seg)
10456 flagword flags;
10458 seg = subseg_force_new (name, 0);
10460 if (! use_abs_literals)
10462 /* Add the newly created literal segment to the list. */
10463 seg_list *n = (seg_list *) xmalloc (sizeof (seg_list));
10464 n->seg = seg;
10465 n->next = literal_head->next;
10466 literal_head->next = n;
10469 flags = (SEC_HAS_CONTENTS | SEC_READONLY | SEC_ALLOC | SEC_LOAD
10470 | (linkonce ? (SEC_LINK_ONCE | SEC_LINK_DUPLICATES_DISCARD) : 0)
10471 | (use_abs_literals ? SEC_DATA : SEC_CODE));
10473 elf_group_name (seg) = group_name;
10475 bfd_set_section_flags (stdoutput, seg, flags);
10476 bfd_set_section_alignment (stdoutput, seg, 2);
10479 *pcached = seg;
10480 subseg_set (current_section, current_subsec);
10481 return seg;
10485 /* Property Tables Stuff. */
10487 #define XTENSA_INSN_SEC_NAME ".xt.insn"
10488 #define XTENSA_LIT_SEC_NAME ".xt.lit"
10489 #define XTENSA_PROP_SEC_NAME ".xt.prop"
10491 typedef bfd_boolean (*frag_predicate) (const fragS *);
10492 typedef void (*frag_flags_fn) (const fragS *, frag_flags *);
10494 static bfd_boolean get_frag_is_literal (const fragS *);
10495 static void xtensa_create_property_segments
10496 (frag_predicate, frag_predicate, const char *, xt_section_type);
10497 static void xtensa_create_xproperty_segments
10498 (frag_flags_fn, const char *, xt_section_type);
10499 static bfd_boolean exclude_section_from_property_tables (segT);
10500 static bfd_boolean section_has_property (segT, frag_predicate);
10501 static bfd_boolean section_has_xproperty (segT, frag_flags_fn);
10502 static void add_xt_block_frags
10503 (segT, xtensa_block_info **, frag_predicate, frag_predicate);
10504 static bfd_boolean xtensa_frag_flags_is_empty (const frag_flags *);
10505 static void xtensa_frag_flags_init (frag_flags *);
10506 static void get_frag_property_flags (const fragS *, frag_flags *);
10507 static flagword frag_flags_to_number (const frag_flags *);
10508 static void add_xt_prop_frags (segT, xtensa_block_info **, frag_flags_fn);
10510 /* Set up property tables after relaxation. */
10512 void
10513 xtensa_post_relax_hook (void)
10515 xtensa_move_seg_list_to_beginning (literal_head);
10517 xtensa_find_unmarked_state_frags ();
10518 xtensa_mark_frags_for_org ();
10519 xtensa_mark_difference_of_two_symbols ();
10521 xtensa_create_property_segments (get_frag_is_literal,
10522 NULL,
10523 XTENSA_LIT_SEC_NAME,
10524 xt_literal_sec);
10525 xtensa_create_xproperty_segments (get_frag_property_flags,
10526 XTENSA_PROP_SEC_NAME,
10527 xt_prop_sec);
10529 if (warn_unaligned_branch_targets)
10530 bfd_map_over_sections (stdoutput, xtensa_find_unaligned_branch_targets, 0);
10531 bfd_map_over_sections (stdoutput, xtensa_find_unaligned_loops, 0);
10535 /* This function is only meaningful after xtensa_move_literals. */
10537 static bfd_boolean
10538 get_frag_is_literal (const fragS *fragP)
10540 gas_assert (fragP != NULL);
10541 return fragP->tc_frag_data.is_literal;
10545 static void
10546 xtensa_create_property_segments (frag_predicate property_function,
10547 frag_predicate end_property_function,
10548 const char *section_name_base,
10549 xt_section_type sec_type)
10551 segT *seclist;
10553 /* Walk over all of the current segments.
10554 Walk over each fragment
10555 For each non-empty fragment,
10556 Build a property record (append where possible). */
10558 for (seclist = &stdoutput->sections;
10559 seclist && *seclist;
10560 seclist = &(*seclist)->next)
10562 segT sec = *seclist;
10564 if (exclude_section_from_property_tables (sec))
10565 continue;
10567 if (section_has_property (sec, property_function))
10569 segment_info_type *xt_seg_info;
10570 xtensa_block_info **xt_blocks;
10571 segT prop_sec = xtensa_make_property_section (sec, section_name_base);
10573 prop_sec->output_section = prop_sec;
10574 subseg_set (prop_sec, 0);
10575 xt_seg_info = seg_info (prop_sec);
10576 xt_blocks = &xt_seg_info->tc_segment_info_data.blocks[sec_type];
10578 /* Walk over all of the frchains here and add new sections. */
10579 add_xt_block_frags (sec, xt_blocks, property_function,
10580 end_property_function);
10584 /* Now we fill them out.... */
10586 for (seclist = &stdoutput->sections;
10587 seclist && *seclist;
10588 seclist = &(*seclist)->next)
10590 segment_info_type *seginfo;
10591 xtensa_block_info *block;
10592 segT sec = *seclist;
10594 seginfo = seg_info (sec);
10595 block = seginfo->tc_segment_info_data.blocks[sec_type];
10597 if (block)
10599 xtensa_block_info *cur_block;
10600 int num_recs = 0;
10601 bfd_size_type rec_size;
10603 for (cur_block = block; cur_block; cur_block = cur_block->next)
10604 num_recs++;
10606 rec_size = num_recs * 8;
10607 bfd_set_section_size (stdoutput, sec, rec_size);
10609 if (num_recs)
10611 char *frag_data;
10612 int i;
10614 subseg_set (sec, 0);
10615 frag_data = frag_more (rec_size);
10616 cur_block = block;
10617 for (i = 0; i < num_recs; i++)
10619 fixS *fix;
10621 /* Write the fixup. */
10622 gas_assert (cur_block);
10623 fix = fix_new (frag_now, i * 8, 4,
10624 section_symbol (cur_block->sec),
10625 cur_block->offset,
10626 FALSE, BFD_RELOC_32);
10627 fix->fx_file = "<internal>";
10628 fix->fx_line = 0;
10630 /* Write the length. */
10631 md_number_to_chars (&frag_data[4 + i * 8],
10632 cur_block->size, 4);
10633 cur_block = cur_block->next;
10635 frag_wane (frag_now);
10636 frag_new (0);
10637 frag_wane (frag_now);
10644 static void
10645 xtensa_create_xproperty_segments (frag_flags_fn flag_fn,
10646 const char *section_name_base,
10647 xt_section_type sec_type)
10649 segT *seclist;
10651 /* Walk over all of the current segments.
10652 Walk over each fragment.
10653 For each fragment that has instructions,
10654 build an instruction record (append where possible). */
10656 for (seclist = &stdoutput->sections;
10657 seclist && *seclist;
10658 seclist = &(*seclist)->next)
10660 segT sec = *seclist;
10662 if (exclude_section_from_property_tables (sec))
10663 continue;
10665 if (section_has_xproperty (sec, flag_fn))
10667 segment_info_type *xt_seg_info;
10668 xtensa_block_info **xt_blocks;
10669 segT prop_sec = xtensa_make_property_section (sec, section_name_base);
10671 prop_sec->output_section = prop_sec;
10672 subseg_set (prop_sec, 0);
10673 xt_seg_info = seg_info (prop_sec);
10674 xt_blocks = &xt_seg_info->tc_segment_info_data.blocks[sec_type];
10676 /* Walk over all of the frchains here and add new sections. */
10677 add_xt_prop_frags (sec, xt_blocks, flag_fn);
10681 /* Now we fill them out.... */
10683 for (seclist = &stdoutput->sections;
10684 seclist && *seclist;
10685 seclist = &(*seclist)->next)
10687 segment_info_type *seginfo;
10688 xtensa_block_info *block;
10689 segT sec = *seclist;
10691 seginfo = seg_info (sec);
10692 block = seginfo->tc_segment_info_data.blocks[sec_type];
10694 if (block)
10696 xtensa_block_info *cur_block;
10697 int num_recs = 0;
10698 bfd_size_type rec_size;
10700 for (cur_block = block; cur_block; cur_block = cur_block->next)
10701 num_recs++;
10703 rec_size = num_recs * (8 + 4);
10704 bfd_set_section_size (stdoutput, sec, rec_size);
10705 /* elf_section_data (sec)->this_hdr.sh_entsize = 12; */
10707 if (num_recs)
10709 char *frag_data;
10710 int i;
10712 subseg_set (sec, 0);
10713 frag_data = frag_more (rec_size);
10714 cur_block = block;
10715 for (i = 0; i < num_recs; i++)
10717 fixS *fix;
10719 /* Write the fixup. */
10720 gas_assert (cur_block);
10721 fix = fix_new (frag_now, i * 12, 4,
10722 section_symbol (cur_block->sec),
10723 cur_block->offset,
10724 FALSE, BFD_RELOC_32);
10725 fix->fx_file = "<internal>";
10726 fix->fx_line = 0;
10728 /* Write the length. */
10729 md_number_to_chars (&frag_data[4 + i * 12],
10730 cur_block->size, 4);
10731 md_number_to_chars (&frag_data[8 + i * 12],
10732 frag_flags_to_number (&cur_block->flags),
10733 sizeof (flagword));
10734 cur_block = cur_block->next;
10736 frag_wane (frag_now);
10737 frag_new (0);
10738 frag_wane (frag_now);
10745 static bfd_boolean
10746 exclude_section_from_property_tables (segT sec)
10748 flagword flags = bfd_get_section_flags (stdoutput, sec);
10750 /* Sections that don't contribute to the memory footprint are excluded. */
10751 if ((flags & SEC_DEBUGGING)
10752 || !(flags & SEC_ALLOC)
10753 || (flags & SEC_MERGE))
10754 return TRUE;
10756 /* Linker cie and fde optimizations mess up property entries for
10757 eh_frame sections, but there is nothing inside them relevant to
10758 property tables anyway. */
10759 if (strcmp (sec->name, ".eh_frame") == 0)
10760 return TRUE;
10762 return FALSE;
10766 static bfd_boolean
10767 section_has_property (segT sec, frag_predicate property_function)
10769 segment_info_type *seginfo = seg_info (sec);
10770 fragS *fragP;
10772 if (seginfo && seginfo->frchainP)
10774 for (fragP = seginfo->frchainP->frch_root; fragP; fragP = fragP->fr_next)
10776 if (property_function (fragP)
10777 && (fragP->fr_type != rs_fill || fragP->fr_fix != 0))
10778 return TRUE;
10781 return FALSE;
10785 static bfd_boolean
10786 section_has_xproperty (segT sec, frag_flags_fn property_function)
10788 segment_info_type *seginfo = seg_info (sec);
10789 fragS *fragP;
10791 if (seginfo && seginfo->frchainP)
10793 for (fragP = seginfo->frchainP->frch_root; fragP; fragP = fragP->fr_next)
10795 frag_flags prop_flags;
10796 property_function (fragP, &prop_flags);
10797 if (!xtensa_frag_flags_is_empty (&prop_flags))
10798 return TRUE;
10801 return FALSE;
10805 /* Two types of block sections exist right now: literal and insns. */
10807 static void
10808 add_xt_block_frags (segT sec,
10809 xtensa_block_info **xt_block,
10810 frag_predicate property_function,
10811 frag_predicate end_property_function)
10813 fragS *fragP;
10815 /* Build it if needed. */
10816 while (*xt_block != NULL)
10817 xt_block = &(*xt_block)->next;
10818 /* We are either at NULL at the beginning or at the end. */
10820 /* Walk through the frags. */
10821 if (seg_info (sec)->frchainP)
10823 for (fragP = seg_info (sec)->frchainP->frch_root;
10824 fragP;
10825 fragP = fragP->fr_next)
10827 if (property_function (fragP)
10828 && (fragP->fr_type != rs_fill || fragP->fr_fix != 0))
10830 if (*xt_block != NULL)
10832 if ((*xt_block)->offset + (*xt_block)->size
10833 == fragP->fr_address)
10834 (*xt_block)->size += fragP->fr_fix;
10835 else
10836 xt_block = &((*xt_block)->next);
10838 if (*xt_block == NULL)
10840 xtensa_block_info *new_block = (xtensa_block_info *)
10841 xmalloc (sizeof (xtensa_block_info));
10842 new_block->sec = sec;
10843 new_block->offset = fragP->fr_address;
10844 new_block->size = fragP->fr_fix;
10845 new_block->next = NULL;
10846 xtensa_frag_flags_init (&new_block->flags);
10847 *xt_block = new_block;
10849 if (end_property_function
10850 && end_property_function (fragP))
10852 xt_block = &((*xt_block)->next);
10860 /* Break the encapsulation of add_xt_prop_frags here. */
10862 static bfd_boolean
10863 xtensa_frag_flags_is_empty (const frag_flags *prop_flags)
10865 if (prop_flags->is_literal
10866 || prop_flags->is_insn
10867 || prop_flags->is_data
10868 || prop_flags->is_unreachable)
10869 return FALSE;
10870 return TRUE;
10874 static void
10875 xtensa_frag_flags_init (frag_flags *prop_flags)
10877 memset (prop_flags, 0, sizeof (frag_flags));
10881 static void
10882 get_frag_property_flags (const fragS *fragP, frag_flags *prop_flags)
10884 xtensa_frag_flags_init (prop_flags);
10885 if (fragP->tc_frag_data.is_literal)
10886 prop_flags->is_literal = TRUE;
10887 if (fragP->tc_frag_data.is_specific_opcode
10888 || fragP->tc_frag_data.is_no_transform)
10890 prop_flags->is_no_transform = TRUE;
10891 if (xtensa_frag_flags_is_empty (prop_flags))
10892 prop_flags->is_data = TRUE;
10894 if (fragP->tc_frag_data.is_unreachable)
10895 prop_flags->is_unreachable = TRUE;
10896 else if (fragP->tc_frag_data.is_insn)
10898 prop_flags->is_insn = TRUE;
10899 if (fragP->tc_frag_data.is_loop_target)
10900 prop_flags->insn.is_loop_target = TRUE;
10901 if (fragP->tc_frag_data.is_branch_target)
10902 prop_flags->insn.is_branch_target = TRUE;
10903 if (fragP->tc_frag_data.is_no_density)
10904 prop_flags->insn.is_no_density = TRUE;
10905 if (fragP->tc_frag_data.use_absolute_literals)
10906 prop_flags->insn.is_abslit = TRUE;
10908 if (fragP->tc_frag_data.is_align)
10910 prop_flags->is_align = TRUE;
10911 prop_flags->alignment = fragP->tc_frag_data.alignment;
10912 if (xtensa_frag_flags_is_empty (prop_flags))
10913 prop_flags->is_data = TRUE;
10918 static flagword
10919 frag_flags_to_number (const frag_flags *prop_flags)
10921 flagword num = 0;
10922 if (prop_flags->is_literal)
10923 num |= XTENSA_PROP_LITERAL;
10924 if (prop_flags->is_insn)
10925 num |= XTENSA_PROP_INSN;
10926 if (prop_flags->is_data)
10927 num |= XTENSA_PROP_DATA;
10928 if (prop_flags->is_unreachable)
10929 num |= XTENSA_PROP_UNREACHABLE;
10930 if (prop_flags->insn.is_loop_target)
10931 num |= XTENSA_PROP_INSN_LOOP_TARGET;
10932 if (prop_flags->insn.is_branch_target)
10934 num |= XTENSA_PROP_INSN_BRANCH_TARGET;
10935 num = SET_XTENSA_PROP_BT_ALIGN (num, prop_flags->insn.bt_align_priority);
10938 if (prop_flags->insn.is_no_density)
10939 num |= XTENSA_PROP_INSN_NO_DENSITY;
10940 if (prop_flags->is_no_transform)
10941 num |= XTENSA_PROP_NO_TRANSFORM;
10942 if (prop_flags->insn.is_no_reorder)
10943 num |= XTENSA_PROP_INSN_NO_REORDER;
10944 if (prop_flags->insn.is_abslit)
10945 num |= XTENSA_PROP_INSN_ABSLIT;
10947 if (prop_flags->is_align)
10949 num |= XTENSA_PROP_ALIGN;
10950 num = SET_XTENSA_PROP_ALIGNMENT (num, prop_flags->alignment);
10953 return num;
10957 static bfd_boolean
10958 xtensa_frag_flags_combinable (const frag_flags *prop_flags_1,
10959 const frag_flags *prop_flags_2)
10961 /* Cannot combine with an end marker. */
10963 if (prop_flags_1->is_literal != prop_flags_2->is_literal)
10964 return FALSE;
10965 if (prop_flags_1->is_insn != prop_flags_2->is_insn)
10966 return FALSE;
10967 if (prop_flags_1->is_data != prop_flags_2->is_data)
10968 return FALSE;
10970 if (prop_flags_1->is_insn)
10972 /* Properties of the beginning of the frag. */
10973 if (prop_flags_2->insn.is_loop_target)
10974 return FALSE;
10975 if (prop_flags_2->insn.is_branch_target)
10976 return FALSE;
10977 if (prop_flags_1->insn.is_no_density !=
10978 prop_flags_2->insn.is_no_density)
10979 return FALSE;
10980 if (prop_flags_1->is_no_transform !=
10981 prop_flags_2->is_no_transform)
10982 return FALSE;
10983 if (prop_flags_1->insn.is_no_reorder !=
10984 prop_flags_2->insn.is_no_reorder)
10985 return FALSE;
10986 if (prop_flags_1->insn.is_abslit !=
10987 prop_flags_2->insn.is_abslit)
10988 return FALSE;
10991 if (prop_flags_1->is_align)
10992 return FALSE;
10994 return TRUE;
10998 static bfd_vma
10999 xt_block_aligned_size (const xtensa_block_info *xt_block)
11001 bfd_vma end_addr;
11002 unsigned align_bits;
11004 if (!xt_block->flags.is_align)
11005 return xt_block->size;
11007 end_addr = xt_block->offset + xt_block->size;
11008 align_bits = xt_block->flags.alignment;
11009 end_addr = ((end_addr + ((1 << align_bits) -1)) >> align_bits) << align_bits;
11010 return end_addr - xt_block->offset;
11014 static bfd_boolean
11015 xtensa_xt_block_combine (xtensa_block_info *xt_block,
11016 const xtensa_block_info *xt_block_2)
11018 if (xt_block->sec != xt_block_2->sec)
11019 return FALSE;
11020 if (xt_block->offset + xt_block_aligned_size (xt_block)
11021 != xt_block_2->offset)
11022 return FALSE;
11024 if (xt_block_2->size == 0
11025 && (!xt_block_2->flags.is_unreachable
11026 || xt_block->flags.is_unreachable))
11028 if (xt_block_2->flags.is_align
11029 && xt_block->flags.is_align)
11031 /* Nothing needed. */
11032 if (xt_block->flags.alignment >= xt_block_2->flags.alignment)
11033 return TRUE;
11035 else
11037 if (xt_block_2->flags.is_align)
11039 /* Push alignment to previous entry. */
11040 xt_block->flags.is_align = xt_block_2->flags.is_align;
11041 xt_block->flags.alignment = xt_block_2->flags.alignment;
11043 return TRUE;
11046 if (!xtensa_frag_flags_combinable (&xt_block->flags,
11047 &xt_block_2->flags))
11048 return FALSE;
11050 xt_block->size += xt_block_2->size;
11052 if (xt_block_2->flags.is_align)
11054 xt_block->flags.is_align = TRUE;
11055 xt_block->flags.alignment = xt_block_2->flags.alignment;
11058 return TRUE;
11062 static void
11063 add_xt_prop_frags (segT sec,
11064 xtensa_block_info **xt_block,
11065 frag_flags_fn property_function)
11067 fragS *fragP;
11069 /* Build it if needed. */
11070 while (*xt_block != NULL)
11072 xt_block = &(*xt_block)->next;
11074 /* We are either at NULL at the beginning or at the end. */
11076 /* Walk through the frags. */
11077 if (seg_info (sec)->frchainP)
11079 for (fragP = seg_info (sec)->frchainP->frch_root; fragP;
11080 fragP = fragP->fr_next)
11082 xtensa_block_info tmp_block;
11083 tmp_block.sec = sec;
11084 tmp_block.offset = fragP->fr_address;
11085 tmp_block.size = fragP->fr_fix;
11086 tmp_block.next = NULL;
11087 property_function (fragP, &tmp_block.flags);
11089 if (!xtensa_frag_flags_is_empty (&tmp_block.flags))
11090 /* && fragP->fr_fix != 0) */
11092 if ((*xt_block) == NULL
11093 || !xtensa_xt_block_combine (*xt_block, &tmp_block))
11095 xtensa_block_info *new_block;
11096 if ((*xt_block) != NULL)
11097 xt_block = &(*xt_block)->next;
11098 new_block = (xtensa_block_info *)
11099 xmalloc (sizeof (xtensa_block_info));
11100 *new_block = tmp_block;
11101 *xt_block = new_block;
11109 /* op_placement_info_table */
11111 /* op_placement_info makes it easier to determine which
11112 ops can go in which slots. */
11114 static void
11115 init_op_placement_info_table (void)
11117 xtensa_isa isa = xtensa_default_isa;
11118 xtensa_insnbuf ibuf = xtensa_insnbuf_alloc (isa);
11119 xtensa_opcode opcode;
11120 xtensa_format fmt;
11121 int slot;
11122 int num_opcodes = xtensa_isa_num_opcodes (isa);
11124 op_placement_table = (op_placement_info_table)
11125 xmalloc (sizeof (op_placement_info) * num_opcodes);
11126 gas_assert (xtensa_isa_num_formats (isa) < MAX_FORMATS);
11128 for (opcode = 0; opcode < num_opcodes; opcode++)
11130 op_placement_info *opi = &op_placement_table[opcode];
11131 /* FIXME: Make tinsn allocation dynamic. */
11132 if (xtensa_opcode_num_operands (isa, opcode) > MAX_INSN_ARGS)
11133 as_fatal (_("too many operands in instruction"));
11134 opi->narrowest = XTENSA_UNDEFINED;
11135 opi->narrowest_size = 0x7F;
11136 opi->narrowest_slot = 0;
11137 opi->formats = 0;
11138 opi->num_formats = 0;
11139 opi->issuef = 0;
11140 for (fmt = 0; fmt < xtensa_isa_num_formats (isa); fmt++)
11142 opi->slots[fmt] = 0;
11143 for (slot = 0; slot < xtensa_format_num_slots (isa, fmt); slot++)
11145 if (xtensa_opcode_encode (isa, fmt, slot, ibuf, opcode) == 0)
11147 int fmt_length = xtensa_format_length (isa, fmt);
11148 opi->issuef++;
11149 set_bit (fmt, opi->formats);
11150 set_bit (slot, opi->slots[fmt]);
11151 if (fmt_length < opi->narrowest_size
11152 || (fmt_length == opi->narrowest_size
11153 && (xtensa_format_num_slots (isa, fmt)
11154 < xtensa_format_num_slots (isa,
11155 opi->narrowest))))
11157 opi->narrowest = fmt;
11158 opi->narrowest_size = fmt_length;
11159 opi->narrowest_slot = slot;
11163 if (opi->formats)
11164 opi->num_formats++;
11167 xtensa_insnbuf_free (isa, ibuf);
11171 bfd_boolean
11172 opcode_fits_format_slot (xtensa_opcode opcode, xtensa_format fmt, int slot)
11174 return bit_is_set (slot, op_placement_table[opcode].slots[fmt]);
11178 /* If the opcode is available in a single slot format, return its size. */
11180 static int
11181 xg_get_single_size (xtensa_opcode opcode)
11183 return op_placement_table[opcode].narrowest_size;
11187 static xtensa_format
11188 xg_get_single_format (xtensa_opcode opcode)
11190 return op_placement_table[opcode].narrowest;
11194 static int
11195 xg_get_single_slot (xtensa_opcode opcode)
11197 return op_placement_table[opcode].narrowest_slot;
11201 /* Instruction Stack Functions (from "xtensa-istack.h"). */
11203 void
11204 istack_init (IStack *stack)
11206 stack->ninsn = 0;
11210 bfd_boolean
11211 istack_empty (IStack *stack)
11213 return (stack->ninsn == 0);
11217 bfd_boolean
11218 istack_full (IStack *stack)
11220 return (stack->ninsn == MAX_ISTACK);
11224 /* Return a pointer to the top IStack entry.
11225 It is an error to call this if istack_empty () is TRUE. */
11227 TInsn *
11228 istack_top (IStack *stack)
11230 int rec = stack->ninsn - 1;
11231 gas_assert (!istack_empty (stack));
11232 return &stack->insn[rec];
11236 /* Add a new TInsn to an IStack.
11237 It is an error to call this if istack_full () is TRUE. */
11239 void
11240 istack_push (IStack *stack, TInsn *insn)
11242 int rec = stack->ninsn;
11243 gas_assert (!istack_full (stack));
11244 stack->insn[rec] = *insn;
11245 stack->ninsn++;
11249 /* Clear space for the next TInsn on the IStack and return a pointer
11250 to it. It is an error to call this if istack_full () is TRUE. */
11252 TInsn *
11253 istack_push_space (IStack *stack)
11255 int rec = stack->ninsn;
11256 TInsn *insn;
11257 gas_assert (!istack_full (stack));
11258 insn = &stack->insn[rec];
11259 tinsn_init (insn);
11260 stack->ninsn++;
11261 return insn;
11265 /* Remove the last pushed instruction. It is an error to call this if
11266 istack_empty () returns TRUE. */
11268 void
11269 istack_pop (IStack *stack)
11271 int rec = stack->ninsn - 1;
11272 gas_assert (!istack_empty (stack));
11273 stack->ninsn--;
11274 tinsn_init (&stack->insn[rec]);
11278 /* TInsn functions. */
11280 void
11281 tinsn_init (TInsn *dst)
11283 memset (dst, 0, sizeof (TInsn));
11287 /* Return TRUE if ANY of the operands in the insn are symbolic. */
11289 static bfd_boolean
11290 tinsn_has_symbolic_operands (const TInsn *insn)
11292 int i;
11293 int n = insn->ntok;
11295 gas_assert (insn->insn_type == ITYPE_INSN);
11297 for (i = 0; i < n; ++i)
11299 switch (insn->tok[i].X_op)
11301 case O_register:
11302 case O_constant:
11303 break;
11304 default:
11305 return TRUE;
11308 return FALSE;
11312 bfd_boolean
11313 tinsn_has_invalid_symbolic_operands (const TInsn *insn)
11315 xtensa_isa isa = xtensa_default_isa;
11316 int i;
11317 int n = insn->ntok;
11319 gas_assert (insn->insn_type == ITYPE_INSN);
11321 for (i = 0; i < n; ++i)
11323 switch (insn->tok[i].X_op)
11325 case O_register:
11326 case O_constant:
11327 break;
11328 case O_big:
11329 case O_illegal:
11330 case O_absent:
11331 /* Errors for these types are caught later. */
11332 break;
11333 case O_hi16:
11334 case O_lo16:
11335 default:
11336 /* Symbolic immediates are only allowed on the last immediate
11337 operand. At this time, CONST16 is the only opcode where we
11338 support non-PC-relative relocations. */
11339 if (i != get_relaxable_immed (insn->opcode)
11340 || (xtensa_operand_is_PCrelative (isa, insn->opcode, i) != 1
11341 && insn->opcode != xtensa_const16_opcode))
11343 as_bad (_("invalid symbolic operand"));
11344 return TRUE;
11348 return FALSE;
11352 /* For assembly code with complex expressions (e.g. subtraction),
11353 we have to build them in the literal pool so that
11354 their results are calculated correctly after relaxation.
11355 The relaxation only handles expressions that
11356 boil down to SYMBOL + OFFSET. */
11358 static bfd_boolean
11359 tinsn_has_complex_operands (const TInsn *insn)
11361 int i;
11362 int n = insn->ntok;
11363 gas_assert (insn->insn_type == ITYPE_INSN);
11364 for (i = 0; i < n; ++i)
11366 switch (insn->tok[i].X_op)
11368 case O_register:
11369 case O_constant:
11370 case O_symbol:
11371 case O_lo16:
11372 case O_hi16:
11373 break;
11374 default:
11375 return TRUE;
11378 return FALSE;
11382 /* Encode a TInsn opcode and its constant operands into slotbuf.
11383 Return TRUE if there is a symbol in the immediate field. This
11384 function assumes that:
11385 1) The number of operands are correct.
11386 2) The insn_type is ITYPE_INSN.
11387 3) The opcode can be encoded in the specified format and slot.
11388 4) Operands are either O_constant or O_symbol, and all constants fit. */
11390 static bfd_boolean
11391 tinsn_to_slotbuf (xtensa_format fmt,
11392 int slot,
11393 TInsn *tinsn,
11394 xtensa_insnbuf slotbuf)
11396 xtensa_isa isa = xtensa_default_isa;
11397 xtensa_opcode opcode = tinsn->opcode;
11398 bfd_boolean has_fixup = FALSE;
11399 int noperands = xtensa_opcode_num_operands (isa, opcode);
11400 int i;
11402 gas_assert (tinsn->insn_type == ITYPE_INSN);
11403 if (noperands != tinsn->ntok)
11404 as_fatal (_("operand number mismatch"));
11406 if (xtensa_opcode_encode (isa, fmt, slot, slotbuf, opcode))
11408 as_bad (_("cannot encode opcode \"%s\" in the given format \"%s\""),
11409 xtensa_opcode_name (isa, opcode), xtensa_format_name (isa, fmt));
11410 return FALSE;
11413 for (i = 0; i < noperands; i++)
11415 expressionS *exp = &tinsn->tok[i];
11416 int rc;
11417 unsigned line;
11418 char *file_name;
11419 uint32 opnd_value;
11421 switch (exp->X_op)
11423 case O_register:
11424 if (xtensa_operand_is_visible (isa, opcode, i) == 0)
11425 break;
11426 /* The register number has already been checked in
11427 expression_maybe_register, so we don't need to check here. */
11428 opnd_value = exp->X_add_number;
11429 (void) xtensa_operand_encode (isa, opcode, i, &opnd_value);
11430 rc = xtensa_operand_set_field (isa, opcode, i, fmt, slot, slotbuf,
11431 opnd_value);
11432 if (rc != 0)
11433 as_warn (_("xtensa-isa failure: %s"), xtensa_isa_error_msg (isa));
11434 break;
11436 case O_constant:
11437 if (xtensa_operand_is_visible (isa, opcode, i) == 0)
11438 break;
11439 as_where (&file_name, &line);
11440 /* It is a constant and we called this function
11441 then we have to try to fit it. */
11442 xtensa_insnbuf_set_operand (slotbuf, fmt, slot, opcode, i,
11443 exp->X_add_number, file_name, line);
11444 break;
11446 default:
11447 has_fixup = TRUE;
11448 break;
11452 return has_fixup;
11456 /* Encode a single TInsn into an insnbuf. If the opcode can only be encoded
11457 into a multi-slot instruction, fill the other slots with NOPs.
11458 Return TRUE if there is a symbol in the immediate field. See also the
11459 assumptions listed for tinsn_to_slotbuf. */
11461 static bfd_boolean
11462 tinsn_to_insnbuf (TInsn *tinsn, xtensa_insnbuf insnbuf)
11464 static xtensa_insnbuf slotbuf = 0;
11465 static vliw_insn vinsn;
11466 xtensa_isa isa = xtensa_default_isa;
11467 bfd_boolean has_fixup = FALSE;
11468 int i;
11470 if (!slotbuf)
11472 slotbuf = xtensa_insnbuf_alloc (isa);
11473 xg_init_vinsn (&vinsn);
11476 xg_clear_vinsn (&vinsn);
11478 bundle_tinsn (tinsn, &vinsn);
11480 xtensa_format_encode (isa, vinsn.format, insnbuf);
11482 for (i = 0; i < vinsn.num_slots; i++)
11484 /* Only one slot may have a fix-up because the rest contains NOPs. */
11485 has_fixup |=
11486 tinsn_to_slotbuf (vinsn.format, i, &vinsn.slots[i], vinsn.slotbuf[i]);
11487 xtensa_format_set_slot (isa, vinsn.format, i, insnbuf, vinsn.slotbuf[i]);
11490 return has_fixup;
11494 /* Check the instruction arguments. Return TRUE on failure. */
11496 static bfd_boolean
11497 tinsn_check_arguments (const TInsn *insn)
11499 xtensa_isa isa = xtensa_default_isa;
11500 xtensa_opcode opcode = insn->opcode;
11501 xtensa_regfile t1_regfile, t2_regfile;
11502 int t1_reg, t2_reg;
11503 int t1_base_reg, t1_last_reg;
11504 int t2_base_reg, t2_last_reg;
11505 char t1_inout, t2_inout;
11506 int i, j;
11508 if (opcode == XTENSA_UNDEFINED)
11510 as_bad (_("invalid opcode"));
11511 return TRUE;
11514 if (xtensa_opcode_num_operands (isa, opcode) > insn->ntok)
11516 as_bad (_("too few operands"));
11517 return TRUE;
11520 if (xtensa_opcode_num_operands (isa, opcode) < insn->ntok)
11522 as_bad (_("too many operands"));
11523 return TRUE;
11526 /* Check registers. */
11527 for (j = 0; j < insn->ntok; j++)
11529 if (xtensa_operand_is_register (isa, insn->opcode, j) != 1)
11530 continue;
11532 t2_regfile = xtensa_operand_regfile (isa, insn->opcode, j);
11533 t2_base_reg = insn->tok[j].X_add_number;
11534 t2_last_reg
11535 = t2_base_reg + xtensa_operand_num_regs (isa, insn->opcode, j);
11537 for (i = 0; i < insn->ntok; i++)
11539 if (i == j)
11540 continue;
11542 if (xtensa_operand_is_register (isa, insn->opcode, i) != 1)
11543 continue;
11545 t1_regfile = xtensa_operand_regfile (isa, insn->opcode, i);
11547 if (t1_regfile != t2_regfile)
11548 continue;
11550 t1_inout = xtensa_operand_inout (isa, insn->opcode, i);
11551 t2_inout = xtensa_operand_inout (isa, insn->opcode, j);
11553 t1_base_reg = insn->tok[i].X_add_number;
11554 t1_last_reg = (t1_base_reg
11555 + xtensa_operand_num_regs (isa, insn->opcode, i));
11557 for (t1_reg = t1_base_reg; t1_reg < t1_last_reg; t1_reg++)
11559 for (t2_reg = t2_base_reg; t2_reg < t2_last_reg; t2_reg++)
11561 if (t1_reg != t2_reg)
11562 continue;
11564 if (t1_inout != 'i' && t2_inout != 'i')
11566 as_bad (_("multiple writes to the same register"));
11567 return TRUE;
11573 return FALSE;
11577 /* Load an instruction from its encoded form. */
11579 static void
11580 tinsn_from_chars (TInsn *tinsn, char *f, int slot)
11582 vliw_insn vinsn;
11584 xg_init_vinsn (&vinsn);
11585 vinsn_from_chars (&vinsn, f);
11587 *tinsn = vinsn.slots[slot];
11588 xg_free_vinsn (&vinsn);
11592 static void
11593 tinsn_from_insnbuf (TInsn *tinsn,
11594 xtensa_insnbuf slotbuf,
11595 xtensa_format fmt,
11596 int slot)
11598 int i;
11599 xtensa_isa isa = xtensa_default_isa;
11601 /* Find the immed. */
11602 tinsn_init (tinsn);
11603 tinsn->insn_type = ITYPE_INSN;
11604 tinsn->is_specific_opcode = FALSE; /* must not be specific */
11605 tinsn->opcode = xtensa_opcode_decode (isa, fmt, slot, slotbuf);
11606 tinsn->ntok = xtensa_opcode_num_operands (isa, tinsn->opcode);
11607 for (i = 0; i < tinsn->ntok; i++)
11609 set_expr_const (&tinsn->tok[i],
11610 xtensa_insnbuf_get_operand (slotbuf, fmt, slot,
11611 tinsn->opcode, i));
11616 /* Read the value of the relaxable immed from the fr_symbol and fr_offset. */
11618 static void
11619 tinsn_immed_from_frag (TInsn *tinsn, fragS *fragP, int slot)
11621 xtensa_opcode opcode = tinsn->opcode;
11622 int opnum;
11624 if (fragP->tc_frag_data.slot_symbols[slot])
11626 opnum = get_relaxable_immed (opcode);
11627 gas_assert (opnum >= 0);
11628 set_expr_symbol_offset (&tinsn->tok[opnum],
11629 fragP->tc_frag_data.slot_symbols[slot],
11630 fragP->tc_frag_data.slot_offsets[slot]);
11632 tinsn->extra_arg = fragP->tc_frag_data.free_reg[slot];
11636 static int
11637 get_num_stack_text_bytes (IStack *istack)
11639 int i;
11640 int text_bytes = 0;
11642 for (i = 0; i < istack->ninsn; i++)
11644 TInsn *tinsn = &istack->insn[i];
11645 if (tinsn->insn_type == ITYPE_INSN)
11646 text_bytes += xg_get_single_size (tinsn->opcode);
11648 return text_bytes;
11652 static int
11653 get_num_stack_literal_bytes (IStack *istack)
11655 int i;
11656 int lit_bytes = 0;
11658 for (i = 0; i < istack->ninsn; i++)
11660 TInsn *tinsn = &istack->insn[i];
11661 if (tinsn->insn_type == ITYPE_LITERAL && tinsn->ntok == 1)
11662 lit_bytes += 4;
11664 return lit_bytes;
11668 /* vliw_insn functions. */
11670 static void
11671 xg_init_vinsn (vliw_insn *v)
11673 int i;
11674 xtensa_isa isa = xtensa_default_isa;
11676 xg_clear_vinsn (v);
11678 v->insnbuf = xtensa_insnbuf_alloc (isa);
11679 if (v->insnbuf == NULL)
11680 as_fatal (_("out of memory"));
11682 for (i = 0; i < config_max_slots; i++)
11684 v->slotbuf[i] = xtensa_insnbuf_alloc (isa);
11685 if (v->slotbuf[i] == NULL)
11686 as_fatal (_("out of memory"));
11691 static void
11692 xg_clear_vinsn (vliw_insn *v)
11694 int i;
11696 memset (v, 0, offsetof (vliw_insn, slots)
11697 + sizeof(TInsn) * config_max_slots);
11699 v->format = XTENSA_UNDEFINED;
11700 v->num_slots = 0;
11701 v->inside_bundle = FALSE;
11703 if (xt_saved_debug_type != DEBUG_NONE)
11704 debug_type = xt_saved_debug_type;
11706 for (i = 0; i < config_max_slots; i++)
11707 v->slots[i].opcode = XTENSA_UNDEFINED;
11711 static void
11712 xg_copy_vinsn (vliw_insn *dst, vliw_insn *src)
11714 memcpy (dst, src,
11715 offsetof(vliw_insn, slots) + src->num_slots * sizeof(TInsn));
11716 dst->insnbuf = src->insnbuf;
11717 memcpy (dst->slotbuf, src->slotbuf, src->num_slots * sizeof(xtensa_insnbuf));
11721 static bfd_boolean
11722 vinsn_has_specific_opcodes (vliw_insn *v)
11724 int i;
11726 for (i = 0; i < v->num_slots; i++)
11728 if (v->slots[i].is_specific_opcode)
11729 return TRUE;
11731 return FALSE;
11735 static void
11736 xg_free_vinsn (vliw_insn *v)
11738 int i;
11739 xtensa_insnbuf_free (xtensa_default_isa, v->insnbuf);
11740 for (i = 0; i < config_max_slots; i++)
11741 xtensa_insnbuf_free (xtensa_default_isa, v->slotbuf[i]);
11745 /* Encode a vliw_insn into an insnbuf. Return TRUE if there are any symbolic
11746 operands. See also the assumptions listed for tinsn_to_slotbuf. */
11748 static bfd_boolean
11749 vinsn_to_insnbuf (vliw_insn *vinsn,
11750 char *frag_offset,
11751 fragS *fragP,
11752 bfd_boolean record_fixup)
11754 xtensa_isa isa = xtensa_default_isa;
11755 xtensa_format fmt = vinsn->format;
11756 xtensa_insnbuf insnbuf = vinsn->insnbuf;
11757 int slot;
11758 bfd_boolean has_fixup = FALSE;
11760 xtensa_format_encode (isa, fmt, insnbuf);
11762 for (slot = 0; slot < vinsn->num_slots; slot++)
11764 TInsn *tinsn = &vinsn->slots[slot];
11765 expressionS *extra_arg = &tinsn->extra_arg;
11766 bfd_boolean tinsn_has_fixup =
11767 tinsn_to_slotbuf (vinsn->format, slot, tinsn,
11768 vinsn->slotbuf[slot]);
11770 xtensa_format_set_slot (isa, fmt, slot,
11771 insnbuf, vinsn->slotbuf[slot]);
11772 if (extra_arg->X_op != O_illegal && extra_arg->X_op != O_register)
11774 if (vinsn->num_slots != 1)
11775 as_bad (_("TLS relocation not allowed in FLIX bundle"));
11776 else if (record_fixup)
11777 /* Instructions that generate TLS relocations should always be
11778 relaxed in the front-end. If "record_fixup" is set, then this
11779 function is being called during back-end relaxation, so flag
11780 the unexpected behavior as an error. */
11781 as_bad (_("unexpected TLS relocation"));
11782 else
11783 fix_new (fragP, frag_offset - fragP->fr_literal,
11784 xtensa_format_length (isa, fmt),
11785 extra_arg->X_add_symbol, extra_arg->X_add_number,
11786 FALSE, map_operator_to_reloc (extra_arg->X_op, FALSE));
11788 if (tinsn_has_fixup)
11790 int i;
11791 xtensa_opcode opcode = tinsn->opcode;
11792 int noperands = xtensa_opcode_num_operands (isa, opcode);
11793 has_fixup = TRUE;
11795 for (i = 0; i < noperands; i++)
11797 expressionS* exp = &tinsn->tok[i];
11798 switch (exp->X_op)
11800 case O_symbol:
11801 case O_lo16:
11802 case O_hi16:
11803 if (get_relaxable_immed (opcode) == i)
11805 /* Add a fix record for the instruction, except if this
11806 function is being called prior to relaxation, i.e.,
11807 if record_fixup is false, and the instruction might
11808 be relaxed later. */
11809 if (record_fixup
11810 || tinsn->is_specific_opcode
11811 || !xg_is_relaxable_insn (tinsn, 0))
11813 xg_add_opcode_fix (tinsn, i, fmt, slot, exp, fragP,
11814 frag_offset - fragP->fr_literal);
11816 else
11818 if (exp->X_op != O_symbol)
11819 as_bad (_("invalid operand"));
11820 tinsn->symbol = exp->X_add_symbol;
11821 tinsn->offset = exp->X_add_number;
11824 else
11825 as_bad (_("symbolic operand not allowed"));
11826 break;
11828 case O_constant:
11829 case O_register:
11830 break;
11832 default:
11833 as_bad (_("expression too complex"));
11834 break;
11840 return has_fixup;
11844 static void
11845 vinsn_from_chars (vliw_insn *vinsn, char *f)
11847 static xtensa_insnbuf insnbuf = NULL;
11848 static xtensa_insnbuf slotbuf = NULL;
11849 int i;
11850 xtensa_format fmt;
11851 xtensa_isa isa = xtensa_default_isa;
11853 if (!insnbuf)
11855 insnbuf = xtensa_insnbuf_alloc (isa);
11856 slotbuf = xtensa_insnbuf_alloc (isa);
11859 xtensa_insnbuf_from_chars (isa, insnbuf, (unsigned char *) f, 0);
11860 fmt = xtensa_format_decode (isa, insnbuf);
11861 if (fmt == XTENSA_UNDEFINED)
11862 as_fatal (_("cannot decode instruction format"));
11863 vinsn->format = fmt;
11864 vinsn->num_slots = xtensa_format_num_slots (isa, fmt);
11866 for (i = 0; i < vinsn->num_slots; i++)
11868 TInsn *tinsn = &vinsn->slots[i];
11869 xtensa_format_get_slot (isa, fmt, i, insnbuf, slotbuf);
11870 tinsn_from_insnbuf (tinsn, slotbuf, fmt, i);
11875 /* Expression utilities. */
11877 /* Return TRUE if the expression is an integer constant. */
11879 bfd_boolean
11880 expr_is_const (const expressionS *s)
11882 return (s->X_op == O_constant);
11886 /* Get the expression constant.
11887 Calling this is illegal if expr_is_const () returns TRUE. */
11889 offsetT
11890 get_expr_const (const expressionS *s)
11892 gas_assert (expr_is_const (s));
11893 return s->X_add_number;
11897 /* Set the expression to a constant value. */
11899 void
11900 set_expr_const (expressionS *s, offsetT val)
11902 s->X_op = O_constant;
11903 s->X_add_number = val;
11904 s->X_add_symbol = NULL;
11905 s->X_op_symbol = NULL;
11909 bfd_boolean
11910 expr_is_register (const expressionS *s)
11912 return (s->X_op == O_register);
11916 /* Get the expression constant.
11917 Calling this is illegal if expr_is_const () returns TRUE. */
11919 offsetT
11920 get_expr_register (const expressionS *s)
11922 gas_assert (expr_is_register (s));
11923 return s->X_add_number;
11927 /* Set the expression to a symbol + constant offset. */
11929 void
11930 set_expr_symbol_offset (expressionS *s, symbolS *sym, offsetT offset)
11932 s->X_op = O_symbol;
11933 s->X_add_symbol = sym;
11934 s->X_op_symbol = NULL; /* unused */
11935 s->X_add_number = offset;
11939 /* Return TRUE if the two expressions are equal. */
11941 bfd_boolean
11942 expr_is_equal (expressionS *s1, expressionS *s2)
11944 if (s1->X_op != s2->X_op)
11945 return FALSE;
11946 if (s1->X_add_symbol != s2->X_add_symbol)
11947 return FALSE;
11948 if (s1->X_op_symbol != s2->X_op_symbol)
11949 return FALSE;
11950 if (s1->X_add_number != s2->X_add_number)
11951 return FALSE;
11952 return TRUE;
11956 static void
11957 copy_expr (expressionS *dst, const expressionS *src)
11959 memcpy (dst, src, sizeof (expressionS));
11963 /* Support for the "--rename-section" option. */
11965 struct rename_section_struct
11967 char *old_name;
11968 char *new_name;
11969 struct rename_section_struct *next;
11972 static struct rename_section_struct *section_rename;
11975 /* Parse the string "oldname=new_name(:oldname2=new_name2)*" and add
11976 entries to the section_rename list. Note: Specifying multiple
11977 renamings separated by colons is not documented and is retained only
11978 for backward compatibility. */
11980 static void
11981 build_section_rename (const char *arg)
11983 struct rename_section_struct *r;
11984 char *this_arg = NULL;
11985 char *next_arg = NULL;
11987 for (this_arg = xstrdup (arg); this_arg != NULL; this_arg = next_arg)
11989 char *old_name, *new_name;
11991 if (this_arg)
11993 next_arg = strchr (this_arg, ':');
11994 if (next_arg)
11996 *next_arg = '\0';
11997 next_arg++;
12001 old_name = this_arg;
12002 new_name = strchr (this_arg, '=');
12004 if (*old_name == '\0')
12006 as_warn (_("ignoring extra '-rename-section' delimiter ':'"));
12007 continue;
12009 if (!new_name || new_name[1] == '\0')
12011 as_warn (_("ignoring invalid '-rename-section' specification: '%s'"),
12012 old_name);
12013 continue;
12015 *new_name = '\0';
12016 new_name++;
12018 /* Check for invalid section renaming. */
12019 for (r = section_rename; r != NULL; r = r->next)
12021 if (strcmp (r->old_name, old_name) == 0)
12022 as_bad (_("section %s renamed multiple times"), old_name);
12023 if (strcmp (r->new_name, new_name) == 0)
12024 as_bad (_("multiple sections remapped to output section %s"),
12025 new_name);
12028 /* Now add it. */
12029 r = (struct rename_section_struct *)
12030 xmalloc (sizeof (struct rename_section_struct));
12031 r->old_name = xstrdup (old_name);
12032 r->new_name = xstrdup (new_name);
12033 r->next = section_rename;
12034 section_rename = r;
12039 char *
12040 xtensa_section_rename (char *name)
12042 struct rename_section_struct *r = section_rename;
12044 for (r = section_rename; r != NULL; r = r->next)
12046 if (strcmp (r->old_name, name) == 0)
12047 return r->new_name;
12050 return name;