Bump GDB's version number to 15.0.91.DATE-git.
[binutils-gdb.git] / gdb / aarch64-linux-tdep.c
blobad55cf2caa3bf79b60ae235c31221e200f6cc853
1 /* Target-dependent code for GNU/Linux AArch64.
3 Copyright (C) 2009-2024 Free Software Foundation, Inc.
4 Contributed by ARM Ltd.
6 This file is part of GDB.
8 This program is free software; you can redistribute it and/or modify
9 it under the terms of the GNU General Public License as published by
10 the Free Software Foundation; either version 3 of the License, or
11 (at your option) any later version.
13 This program is distributed in the hope that it will be useful,
14 but WITHOUT ANY WARRANTY; without even the implied warranty of
15 MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
16 GNU General Public License for more details.
18 You should have received a copy of the GNU General Public License
19 along with this program. If not, see <http://www.gnu.org/licenses/>. */
22 #include "extract-store-integer.h"
23 #include "gdbarch.h"
24 #include "glibc-tdep.h"
25 #include "linux-tdep.h"
26 #include "aarch64-tdep.h"
27 #include "aarch64-linux-tdep.h"
28 #include "osabi.h"
29 #include "solib-svr4.h"
30 #include "symtab.h"
31 #include "tramp-frame.h"
32 #include "trad-frame.h"
33 #include "target.h"
34 #include "target/target.h"
35 #include "expop.h"
36 #include "auxv.h"
38 #include "regcache.h"
39 #include "regset.h"
41 #include "stap-probe.h"
42 #include "parser-defs.h"
43 #include "user-regs.h"
44 #include "xml-syscall.h"
45 #include <ctype.h>
47 #include "record-full.h"
48 #include "linux-record.h"
50 #include "arch/aarch64-mte-linux.h"
51 #include "arch/aarch64-scalable-linux.h"
53 #include "arch-utils.h"
54 #include "value.h"
56 #include "gdbsupport/selftest.h"
58 #include "elf/common.h"
59 #include "elf/aarch64.h"
60 #include "arch/aarch64-insn.h"
62 /* For std::pow */
63 #include <cmath>
65 /* Signal frame handling.
67 +------------+ ^
68 | saved lr | |
69 +->| saved fp |--+
70 | | |
71 | | |
72 | +------------+
73 | | saved lr |
74 +--| saved fp |
75 ^ | |
76 | | |
77 | +------------+
78 ^ | |
79 | | signal |
80 | | | SIGTRAMP_FRAME (struct rt_sigframe)
81 | | saved regs |
82 +--| saved sp |--> interrupted_sp
83 | | saved pc |--> interrupted_pc
84 | | |
85 | +------------+
86 | | saved lr |--> default_restorer (movz x8, NR_sys_rt_sigreturn; svc 0)
87 +--| saved fp |<- FP
88 | | NORMAL_FRAME
89 | |<- SP
90 +------------+
92 On signal delivery, the kernel will create a signal handler stack
93 frame and setup the return address in LR to point at restorer stub.
94 The signal stack frame is defined by:
96 struct rt_sigframe
98 siginfo_t info;
99 struct ucontext uc;
102 The ucontext has the following form:
103 struct ucontext
105 unsigned long uc_flags;
106 struct ucontext *uc_link;
107 stack_t uc_stack;
108 sigset_t uc_sigmask;
109 struct sigcontext uc_mcontext;
112 struct sigcontext
114 unsigned long fault_address;
115 unsigned long regs[31];
116 unsigned long sp; / * 31 * /
117 unsigned long pc; / * 32 * /
118 unsigned long pstate; / * 33 * /
119 __u8 __reserved[4096]
122 The reserved space in sigcontext contains additional structures, each starting
123 with a aarch64_ctx, which specifies a unique identifier and the total size of
124 the structure. The final structure in reserved will start will a null
125 aarch64_ctx. The penultimate entry in reserved may be a extra_context which
126 then points to a further block of reserved space.
128 struct aarch64_ctx {
129 u32 magic;
130 u32 size;
133 The restorer stub will always have the form:
135 d28015a8 movz x8, #0xad
136 d4000001 svc #0x0
138 This is a system call sys_rt_sigreturn.
140 We detect signal frames by snooping the return code for the restorer
141 instruction sequence.
143 The handler then needs to recover the saved register set from
144 ucontext.uc_mcontext. */
146 /* These magic numbers need to reflect the layout of the kernel
147 defined struct rt_sigframe and ucontext. */
148 #define AARCH64_SIGCONTEXT_REG_SIZE 8
149 #define AARCH64_RT_SIGFRAME_UCONTEXT_OFFSET 128
150 #define AARCH64_UCONTEXT_SIGCONTEXT_OFFSET 176
151 #define AARCH64_SIGCONTEXT_XO_OFFSET 8
152 #define AARCH64_SIGCONTEXT_RESERVED_OFFSET 288
154 #define AARCH64_SIGCONTEXT_RESERVED_SIZE 4096
156 /* Unique identifiers that may be used for aarch64_ctx.magic. */
157 #define AARCH64_EXTRA_MAGIC 0x45585401
158 #define AARCH64_FPSIMD_MAGIC 0x46508001
159 #define AARCH64_SVE_MAGIC 0x53564501
160 #define AARCH64_ZA_MAGIC 0x54366345
161 #define AARCH64_TPIDR2_MAGIC 0x54504902
162 #define AARCH64_ZT_MAGIC 0x5a544e01
164 /* Defines for the extra_context that follows an AARCH64_EXTRA_MAGIC. */
165 #define AARCH64_EXTRA_DATAP_OFFSET 8
167 /* Defines for the fpsimd that follows an AARCH64_FPSIMD_MAGIC. */
168 #define AARCH64_FPSIMD_FPSR_OFFSET 8
169 #define AARCH64_FPSIMD_FPCR_OFFSET 12
170 #define AARCH64_FPSIMD_V0_OFFSET 16
171 #define AARCH64_FPSIMD_VREG_SIZE 16
173 /* Defines for the sve structure that follows an AARCH64_SVE_MAGIC. */
174 #define AARCH64_SVE_CONTEXT_VL_OFFSET 8
175 #define AARCH64_SVE_CONTEXT_FLAGS_OFFSET 10
176 #define AARCH64_SVE_CONTEXT_REGS_OFFSET 16
177 #define AARCH64_SVE_CONTEXT_P_REGS_OFFSET(vq) (32 * vq * 16)
178 #define AARCH64_SVE_CONTEXT_FFR_OFFSET(vq) \
179 (AARCH64_SVE_CONTEXT_P_REGS_OFFSET (vq) + (16 * vq * 2))
180 #define AARCH64_SVE_CONTEXT_SIZE(vq) \
181 (AARCH64_SVE_CONTEXT_FFR_OFFSET (vq) + (vq * 2))
182 /* Flag indicating the SVE Context describes streaming mode. */
183 #define SVE_SIG_FLAG_SM 0x1
185 /* SME constants. */
186 #define AARCH64_SME_CONTEXT_SVL_OFFSET 8
187 #define AARCH64_SME_CONTEXT_REGS_OFFSET 16
188 #define AARCH64_SME_CONTEXT_ZA_SIZE(svq) \
189 ((sve_vl_from_vq (svq) * sve_vl_from_vq (svq)))
190 #define AARCH64_SME_CONTEXT_SIZE(svq) \
191 (AARCH64_SME_CONTEXT_REGS_OFFSET + AARCH64_SME_CONTEXT_ZA_SIZE (svq))
193 /* TPIDR2 register value offset in the TPIDR2 signal frame context. */
194 #define AARCH64_TPIDR2_CONTEXT_TPIDR2_OFFSET 8
196 /* SME2 (ZT) constants. */
197 /* Offset of the field containing the number of registers in the SME2 signal
198 context state. */
199 #define AARCH64_SME2_CONTEXT_NREGS_OFFSET 8
200 /* Offset of the beginning of the register data for the first ZT register in
201 the signal context state. */
202 #define AARCH64_SME2_CONTEXT_REGS_OFFSET 16
204 /* Holds information about the signal frame. */
205 struct aarch64_linux_sigframe
207 /* The stack pointer value. */
208 CORE_ADDR sp = 0;
209 /* The sigcontext address. */
210 CORE_ADDR sigcontext_address = 0;
211 /* The start/end signal frame section addresses. */
212 CORE_ADDR section = 0;
213 CORE_ADDR section_end = 0;
215 /* Starting address of the section containing the general purpose
216 registers. */
217 CORE_ADDR gpr_section = 0;
218 /* Starting address of the section containing the FPSIMD registers. */
219 CORE_ADDR fpsimd_section = 0;
220 /* Starting address of the section containing the SVE registers. */
221 CORE_ADDR sve_section = 0;
222 /* Starting address of the section containing the ZA register. */
223 CORE_ADDR za_section = 0;
224 /* Starting address of the section containing the TPIDR2 register. */
225 CORE_ADDR tpidr2_section = 0;
226 /* Starting address of the section containing the ZT registers. */
227 CORE_ADDR zt_section = 0;
228 /* Starting address of the section containing extra information. */
229 CORE_ADDR extra_section = 0;
231 /* The vector length (SVE or SSVE). */
232 ULONGEST vl = 0;
233 /* The streaming vector length (SSVE/ZA). */
234 ULONGEST svl = 0;
235 /* Number of ZT registers in this context. */
236 unsigned int zt_register_count = 0;
238 /* True if we are in streaming mode, false otherwise. */
239 bool streaming_mode = false;
240 /* True if we have a ZA payload, false otherwise. */
241 bool za_payload = false;
242 /* True if we have a ZT entry in the signal context, false otherwise. */
243 bool zt_available = false;
246 /* Read an aarch64_ctx, returning the magic value, and setting *SIZE to the
247 size, or return 0 on error. */
249 static uint32_t
250 read_aarch64_ctx (CORE_ADDR ctx_addr, enum bfd_endian byte_order,
251 uint32_t *size)
253 uint32_t magic = 0;
254 gdb_byte buf[4];
256 if (target_read_memory (ctx_addr, buf, 4) != 0)
257 return 0;
258 magic = extract_unsigned_integer (buf, 4, byte_order);
260 if (target_read_memory (ctx_addr + 4, buf, 4) != 0)
261 return 0;
262 *size = extract_unsigned_integer (buf, 4, byte_order);
264 return magic;
267 /* Given CACHE, use the trad_frame* functions to restore the FPSIMD
268 registers from a signal frame.
270 FPSIMD_CONTEXT is the address of the signal frame context containing FPSIMD
271 data. */
273 static void
274 aarch64_linux_restore_vregs (struct gdbarch *gdbarch,
275 struct trad_frame_cache *cache,
276 CORE_ADDR fpsimd_context)
278 /* WARNING: SIMD state is laid out in memory in target-endian format.
280 So we have a couple cases to consider:
282 1 - If the target is big endian, then SIMD state is big endian,
283 requiring a byteswap.
285 2 - If the target is little endian, then SIMD state is little endian, so
286 no byteswap is needed. */
288 enum bfd_endian byte_order = gdbarch_byte_order (gdbarch);
289 int num_regs = gdbarch_num_regs (gdbarch);
290 aarch64_gdbarch_tdep *tdep = gdbarch_tdep<aarch64_gdbarch_tdep> (gdbarch);
292 for (int i = 0; i < 32; i++)
294 CORE_ADDR offset = (fpsimd_context + AARCH64_FPSIMD_V0_OFFSET
295 + (i * AARCH64_FPSIMD_VREG_SIZE));
297 gdb_byte buf[V_REGISTER_SIZE];
299 /* Read the contents of the V register. */
300 if (target_read_memory (offset, buf, V_REGISTER_SIZE))
301 error (_("Failed to read fpsimd register from signal context."));
303 if (byte_order == BFD_ENDIAN_BIG)
305 size_t size = V_REGISTER_SIZE/2;
307 /* Read the two halves of the V register in reverse byte order. */
308 CORE_ADDR u64 = extract_unsigned_integer (buf, size,
309 byte_order);
310 CORE_ADDR l64 = extract_unsigned_integer (buf + size, size,
311 byte_order);
313 /* Copy the reversed bytes to the buffer. */
314 store_unsigned_integer (buf, size, BFD_ENDIAN_LITTLE, l64);
315 store_unsigned_integer (buf + size , size, BFD_ENDIAN_LITTLE, u64);
317 /* Now we can store the correct bytes for the V register. */
318 trad_frame_set_reg_value_bytes (cache, AARCH64_V0_REGNUM + i,
319 {buf, V_REGISTER_SIZE});
320 trad_frame_set_reg_value_bytes (cache,
321 num_regs + AARCH64_Q0_REGNUM
322 + i, {buf, Q_REGISTER_SIZE});
323 trad_frame_set_reg_value_bytes (cache,
324 num_regs + AARCH64_D0_REGNUM
325 + i, {buf, D_REGISTER_SIZE});
326 trad_frame_set_reg_value_bytes (cache,
327 num_regs + AARCH64_S0_REGNUM
328 + i, {buf, S_REGISTER_SIZE});
329 trad_frame_set_reg_value_bytes (cache,
330 num_regs + AARCH64_H0_REGNUM
331 + i, {buf, H_REGISTER_SIZE});
332 trad_frame_set_reg_value_bytes (cache,
333 num_regs + AARCH64_B0_REGNUM
334 + i, {buf, B_REGISTER_SIZE});
336 if (tdep->has_sve ())
337 trad_frame_set_reg_value_bytes (cache,
338 num_regs + AARCH64_SVE_V0_REGNUM
339 + i, {buf, V_REGISTER_SIZE});
341 else
343 /* Little endian, just point at the address containing the register
344 value. */
345 trad_frame_set_reg_addr (cache, AARCH64_V0_REGNUM + i, offset);
346 trad_frame_set_reg_addr (cache, num_regs + AARCH64_Q0_REGNUM + i,
347 offset);
348 trad_frame_set_reg_addr (cache, num_regs + AARCH64_D0_REGNUM + i,
349 offset);
350 trad_frame_set_reg_addr (cache, num_regs + AARCH64_S0_REGNUM + i,
351 offset);
352 trad_frame_set_reg_addr (cache, num_regs + AARCH64_H0_REGNUM + i,
353 offset);
354 trad_frame_set_reg_addr (cache, num_regs + AARCH64_B0_REGNUM + i,
355 offset);
357 if (tdep->has_sve ())
358 trad_frame_set_reg_addr (cache, num_regs + AARCH64_SVE_V0_REGNUM
359 + i, offset);
362 if (tdep->has_sve ())
364 /* If SVE is supported for this target, zero out the Z
365 registers then copy the first 16 bytes of each of the V
366 registers to the associated Z register. Otherwise the Z
367 registers will contain uninitialized data. */
368 std::vector<gdb_byte> z_buffer (tdep->vq * 16);
370 /* We have already handled the endianness swap above, so we don't need
371 to worry about it here. */
372 memcpy (z_buffer.data (), buf, V_REGISTER_SIZE);
373 trad_frame_set_reg_value_bytes (cache,
374 AARCH64_SVE_Z0_REGNUM + i,
375 z_buffer);
380 /* Given a signal frame THIS_FRAME, read the signal frame information into
381 SIGNAL_FRAME. */
383 static void
384 aarch64_linux_read_signal_frame_info (const frame_info_ptr &this_frame,
385 aarch64_linux_sigframe &signal_frame)
387 signal_frame.sp = get_frame_register_unsigned (this_frame, AARCH64_SP_REGNUM);
388 signal_frame.sigcontext_address
389 = signal_frame.sp + AARCH64_RT_SIGFRAME_UCONTEXT_OFFSET
390 + AARCH64_UCONTEXT_SIGCONTEXT_OFFSET;
391 signal_frame.section
392 = signal_frame.sigcontext_address + AARCH64_SIGCONTEXT_RESERVED_OFFSET;
393 signal_frame.section_end
394 = signal_frame.section + AARCH64_SIGCONTEXT_RESERVED_SIZE;
396 signal_frame.gpr_section
397 = signal_frame.sigcontext_address + AARCH64_SIGCONTEXT_XO_OFFSET;
399 /* Search for all the other sections, stopping at null. */
400 CORE_ADDR section = signal_frame.section;
401 CORE_ADDR section_end = signal_frame.section_end;
402 uint32_t size, magic;
403 bool extra_found = false;
404 enum bfd_endian byte_order
405 = gdbarch_byte_order (get_frame_arch (this_frame));
407 while ((magic = read_aarch64_ctx (section, byte_order, &size)) != 0
408 && size != 0)
410 switch (magic)
412 case AARCH64_FPSIMD_MAGIC:
414 signal_frame.fpsimd_section = section;
415 section += size;
416 break;
419 case AARCH64_SVE_MAGIC:
421 /* Check if the section is followed by a full SVE dump, and set
422 sve_regs if it is. */
423 gdb_byte buf[4];
425 /* Extract the vector length. */
426 if (target_read_memory (section + AARCH64_SVE_CONTEXT_VL_OFFSET,
427 buf, 2) != 0)
429 warning (_("Failed to read the vector length from the SVE "
430 "signal frame context."));
431 section += size;
432 break;
435 signal_frame.vl = extract_unsigned_integer (buf, 2, byte_order);
437 /* Extract the flags to check if we are in streaming mode. */
438 if (target_read_memory (section
439 + AARCH64_SVE_CONTEXT_FLAGS_OFFSET,
440 buf, 2) != 0)
442 warning (_("Failed to read the flags from the SVE signal frame"
443 " context."));
444 section += size;
445 break;
448 uint16_t flags = extract_unsigned_integer (buf, 2, byte_order);
450 /* Is this SSVE data? If so, we are in streaming mode. */
451 signal_frame.streaming_mode
452 = (flags & SVE_SIG_FLAG_SM) ? true : false;
454 ULONGEST vq = sve_vq_from_vl (signal_frame.vl);
455 if (size >= AARCH64_SVE_CONTEXT_SIZE (vq))
457 signal_frame.sve_section
458 = section + AARCH64_SVE_CONTEXT_REGS_OFFSET;
460 section += size;
461 break;
464 case AARCH64_ZA_MAGIC:
466 /* Check if the section is followed by a full ZA dump, and set
467 za_state if it is. */
468 gdb_byte buf[2];
470 /* Extract the streaming vector length. */
471 if (target_read_memory (section + AARCH64_SME_CONTEXT_SVL_OFFSET,
472 buf, 2) != 0)
474 warning (_("Failed to read the streaming vector length from "
475 "ZA signal frame context."));
476 section += size;
477 break;
480 signal_frame.svl = extract_unsigned_integer (buf, 2, byte_order);
481 ULONGEST svq = sve_vq_from_vl (signal_frame.svl);
483 if (size >= AARCH64_SME_CONTEXT_SIZE (svq))
485 signal_frame.za_section
486 = section + AARCH64_SME_CONTEXT_REGS_OFFSET;
487 signal_frame.za_payload = true;
489 section += size;
490 break;
493 case AARCH64_TPIDR2_MAGIC:
495 /* This is context containing the tpidr2 register. */
496 signal_frame.tpidr2_section = section;
497 section += size;
498 break;
500 case AARCH64_ZT_MAGIC:
502 gdb_byte buf[2];
504 /* Extract the number of ZT registers available in this
505 context. */
506 if (target_read_memory (section + AARCH64_SME2_CONTEXT_NREGS_OFFSET,
507 buf, 2) != 0)
509 warning (_("Failed to read the number of ZT registers from the "
510 "ZT signal frame context."));
511 section += size;
512 break;
515 signal_frame.zt_register_count
516 = extract_unsigned_integer (buf, 2, byte_order);
518 /* This is a context containing the ZT registers. This should only
519 exist if we also have the ZA context. The presence of the ZT
520 context without the ZA context is invalid. */
521 signal_frame.zt_section = section;
522 signal_frame.zt_available = true;
524 section += size;
525 break;
527 case AARCH64_EXTRA_MAGIC:
529 /* Extra is always the last valid section in reserved and points to
530 an additional block of memory filled with more sections. Reset
531 the address to the extra section and continue looking for more
532 structures. */
533 gdb_byte buf[8];
535 if (target_read_memory (section + AARCH64_EXTRA_DATAP_OFFSET,
536 buf, 8) != 0)
538 warning (_("Failed to read the extra section address from the"
539 " signal frame context."));
540 section += size;
541 break;
544 section = extract_unsigned_integer (buf, 8, byte_order);
545 signal_frame.extra_section = section;
546 extra_found = true;
547 break;
550 default:
551 section += size;
552 break;
555 /* Prevent searching past the end of the reserved section. The extra
556 section does not have a hard coded limit - we have to rely on it ending
557 with nulls. */
558 if (!extra_found && section > section_end)
559 break;
562 /* Sanity check that if the ZT entry exists, the ZA entry must also
563 exist. */
564 if (signal_frame.zt_available && !signal_frame.za_payload)
565 error (_("While reading signal context information, found a ZT context "
566 "without a ZA context, which is invalid."));
569 /* Implement the "init" method of struct tramp_frame. */
571 static void
572 aarch64_linux_sigframe_init (const struct tramp_frame *self,
573 const frame_info_ptr &this_frame,
574 struct trad_frame_cache *this_cache,
575 CORE_ADDR func)
577 /* Read the signal context information. */
578 struct aarch64_linux_sigframe signal_frame;
579 aarch64_linux_read_signal_frame_info (this_frame, signal_frame);
581 /* Now we have all the data required to restore the registers from the
582 signal frame. */
584 /* Restore the general purpose registers. */
585 CORE_ADDR offset = signal_frame.gpr_section;
586 for (int i = 0; i < 31; i++)
588 trad_frame_set_reg_addr (this_cache, AARCH64_X0_REGNUM + i, offset);
589 offset += AARCH64_SIGCONTEXT_REG_SIZE;
591 trad_frame_set_reg_addr (this_cache, AARCH64_SP_REGNUM, offset);
592 offset += AARCH64_SIGCONTEXT_REG_SIZE;
593 trad_frame_set_reg_addr (this_cache, AARCH64_PC_REGNUM, offset);
595 struct gdbarch *gdbarch = get_frame_arch (this_frame);
596 aarch64_gdbarch_tdep *tdep = gdbarch_tdep<aarch64_gdbarch_tdep> (gdbarch);
598 /* Restore the SVE / FPSIMD registers. */
599 if (tdep->has_sve () && signal_frame.sve_section != 0)
601 ULONGEST vq = sve_vq_from_vl (signal_frame.vl);
602 CORE_ADDR sve_regs = signal_frame.sve_section;
604 /* Restore VG. */
605 trad_frame_set_reg_value (this_cache, AARCH64_SVE_VG_REGNUM,
606 sve_vg_from_vl (signal_frame.vl));
608 int num_regs = gdbarch_num_regs (gdbarch);
609 for (int i = 0; i < 32; i++)
611 offset = sve_regs + (i * vq * 16);
612 trad_frame_set_reg_addr (this_cache, AARCH64_SVE_Z0_REGNUM + i,
613 offset);
614 trad_frame_set_reg_addr (this_cache,
615 num_regs + AARCH64_SVE_V0_REGNUM + i,
616 offset);
617 trad_frame_set_reg_addr (this_cache, num_regs + AARCH64_Q0_REGNUM + i,
618 offset);
619 trad_frame_set_reg_addr (this_cache, num_regs + AARCH64_D0_REGNUM + i,
620 offset);
621 trad_frame_set_reg_addr (this_cache, num_regs + AARCH64_S0_REGNUM + i,
622 offset);
623 trad_frame_set_reg_addr (this_cache, num_regs + AARCH64_H0_REGNUM + i,
624 offset);
625 trad_frame_set_reg_addr (this_cache, num_regs + AARCH64_B0_REGNUM + i,
626 offset);
629 offset = sve_regs + AARCH64_SVE_CONTEXT_P_REGS_OFFSET (vq);
630 for (int i = 0; i < 16; i++)
631 trad_frame_set_reg_addr (this_cache, AARCH64_SVE_P0_REGNUM + i,
632 offset + (i * vq * 2));
634 offset = sve_regs + AARCH64_SVE_CONTEXT_FFR_OFFSET (vq);
635 trad_frame_set_reg_addr (this_cache, AARCH64_SVE_FFR_REGNUM, offset);
638 /* Restore the FPSIMD registers. */
639 if (signal_frame.fpsimd_section != 0)
641 CORE_ADDR fpsimd = signal_frame.fpsimd_section;
643 trad_frame_set_reg_addr (this_cache, AARCH64_FPSR_REGNUM,
644 fpsimd + AARCH64_FPSIMD_FPSR_OFFSET);
645 trad_frame_set_reg_addr (this_cache, AARCH64_FPCR_REGNUM,
646 fpsimd + AARCH64_FPSIMD_FPCR_OFFSET);
648 /* If there was no SVE section then set up the V registers. */
649 if (!tdep->has_sve () || signal_frame.sve_section == 0)
650 aarch64_linux_restore_vregs (gdbarch, this_cache, fpsimd);
653 /* Restore the SME registers. */
654 if (tdep->has_sme ())
656 if (signal_frame.za_section != 0)
658 /* Restore the ZA state. */
659 trad_frame_set_reg_addr (this_cache, tdep->sme_za_regnum,
660 signal_frame.za_section);
663 /* Restore/Reconstruct SVCR. */
664 ULONGEST svcr = 0;
665 svcr |= signal_frame.za_payload ? SVCR_ZA_BIT : 0;
666 svcr |= signal_frame.streaming_mode ? SVCR_SM_BIT : 0;
667 trad_frame_set_reg_value (this_cache, tdep->sme_svcr_regnum, svcr);
669 /* Restore SVG. */
670 trad_frame_set_reg_value (this_cache, tdep->sme_svg_regnum,
671 sve_vg_from_vl (signal_frame.svl));
673 /* Handle SME2 (ZT). */
674 if (tdep->has_sme2 ()
675 && signal_frame.za_section != 0
676 && signal_frame.zt_register_count > 0)
678 /* Is ZA state available? */
679 gdb_assert (svcr & SVCR_ZA_BIT);
681 /* Restore the ZT state. For now we assume that we only have
682 a single ZT register. If/When more ZT registers appear, we
683 should update the code to handle that case accordingly. */
684 trad_frame_set_reg_addr (this_cache, tdep->sme2_zt0_regnum,
685 signal_frame.zt_section
686 + AARCH64_SME2_CONTEXT_REGS_OFFSET);
690 /* Restore the tpidr2 register, if the target supports it and if there is
691 an entry for it. */
692 if (signal_frame.tpidr2_section != 0 && tdep->has_tls ()
693 && tdep->tls_register_count >= 2)
695 /* Restore tpidr2. */
696 trad_frame_set_reg_addr (this_cache, tdep->tls_regnum_base + 1,
697 signal_frame.tpidr2_section
698 + AARCH64_TPIDR2_CONTEXT_TPIDR2_OFFSET);
701 trad_frame_set_id (this_cache, frame_id_build (signal_frame.sp, func));
704 /* Implements the "prev_arch" method of struct tramp_frame. */
706 static struct gdbarch *
707 aarch64_linux_sigframe_prev_arch (const frame_info_ptr &this_frame,
708 void **frame_cache)
710 struct trad_frame_cache *cache
711 = (struct trad_frame_cache *) *frame_cache;
713 gdb_assert (cache != nullptr);
715 struct aarch64_linux_sigframe signal_frame;
716 aarch64_linux_read_signal_frame_info (this_frame, signal_frame);
718 /* The SVE vector length and the SME vector length may change from frame to
719 frame. Make sure we report the correct architecture to the previous
720 frame.
722 We can reuse the next frame's architecture here, as it should be mostly
723 the same, except for potential different vg and svg values. */
724 const struct target_desc *tdesc
725 = gdbarch_target_desc (get_frame_arch (this_frame));
726 aarch64_features features = aarch64_features_from_target_desc (tdesc);
727 features.vq = sve_vq_from_vl (signal_frame.vl);
728 features.svq = (uint8_t) sve_vq_from_vl (signal_frame.svl);
730 struct gdbarch_info info;
731 info.bfd_arch_info = bfd_lookup_arch (bfd_arch_aarch64, bfd_mach_aarch64);
732 info.target_desc = aarch64_read_description (features);
733 return gdbarch_find_by_info (info);
736 static const struct tramp_frame aarch64_linux_rt_sigframe =
738 SIGTRAMP_FRAME,
741 /* movz x8, 0x8b (S=1,o=10,h=0,i=0x8b,r=8)
742 Soo1 0010 1hhi iiii iiii iiii iiir rrrr */
743 {0xd2801168, ULONGEST_MAX},
745 /* svc 0x0 (o=0, l=1)
746 1101 0100 oooi iiii iiii iiii iii0 00ll */
747 {0xd4000001, ULONGEST_MAX},
748 {TRAMP_SENTINEL_INSN, ULONGEST_MAX}
750 aarch64_linux_sigframe_init,
751 nullptr, /* validate */
752 aarch64_linux_sigframe_prev_arch, /* prev_arch */
755 /* Register maps. */
757 static const struct regcache_map_entry aarch64_linux_gregmap[] =
759 { 31, AARCH64_X0_REGNUM, 8 }, /* x0 ... x30 */
760 { 1, AARCH64_SP_REGNUM, 8 },
761 { 1, AARCH64_PC_REGNUM, 8 },
762 { 1, AARCH64_CPSR_REGNUM, 8 },
763 { 0 }
766 static const struct regcache_map_entry aarch64_linux_fpregmap[] =
768 { 32, AARCH64_V0_REGNUM, 16 }, /* v0 ... v31 */
769 { 1, AARCH64_FPSR_REGNUM, 4 },
770 { 1, AARCH64_FPCR_REGNUM, 4 },
771 { 0 }
774 /* Register set definitions. */
776 const struct regset aarch64_linux_gregset =
778 aarch64_linux_gregmap,
779 regcache_supply_regset, regcache_collect_regset
782 const struct regset aarch64_linux_fpregset =
784 aarch64_linux_fpregmap,
785 regcache_supply_regset, regcache_collect_regset
788 /* The fields in an SVE header at the start of a SVE regset. */
790 #define SVE_HEADER_SIZE_LENGTH 4
791 #define SVE_HEADER_MAX_SIZE_LENGTH 4
792 #define SVE_HEADER_VL_LENGTH 2
793 #define SVE_HEADER_MAX_VL_LENGTH 2
794 #define SVE_HEADER_FLAGS_LENGTH 2
795 #define SVE_HEADER_RESERVED_LENGTH 2
797 #define SVE_HEADER_SIZE_OFFSET 0
798 #define SVE_HEADER_MAX_SIZE_OFFSET \
799 (SVE_HEADER_SIZE_OFFSET + SVE_HEADER_SIZE_LENGTH)
800 #define SVE_HEADER_VL_OFFSET \
801 (SVE_HEADER_MAX_SIZE_OFFSET + SVE_HEADER_MAX_SIZE_LENGTH)
802 #define SVE_HEADER_MAX_VL_OFFSET \
803 (SVE_HEADER_VL_OFFSET + SVE_HEADER_VL_LENGTH)
804 #define SVE_HEADER_FLAGS_OFFSET \
805 (SVE_HEADER_MAX_VL_OFFSET + SVE_HEADER_MAX_VL_LENGTH)
806 #define SVE_HEADER_RESERVED_OFFSET \
807 (SVE_HEADER_FLAGS_OFFSET + SVE_HEADER_FLAGS_LENGTH)
808 #define SVE_HEADER_SIZE \
809 (SVE_HEADER_RESERVED_OFFSET + SVE_HEADER_RESERVED_LENGTH)
811 #define SVE_HEADER_FLAG_SVE 1
813 /* Get the vector quotient (VQ) or streaming vector quotient (SVQ) value
814 from the section named SECTION_NAME.
816 Return non-zero if successful and 0 otherwise. */
818 static uint64_t
819 aarch64_linux_core_read_vq (struct gdbarch *gdbarch, bfd *abfd,
820 const char *section_name)
822 gdb_assert (section_name != nullptr);
824 asection *section = bfd_get_section_by_name (abfd, section_name);
826 if (section == nullptr)
828 /* No SVE state. */
829 return 0;
832 size_t size = bfd_section_size (section);
834 /* Check extended state size. */
835 if (size < SVE_HEADER_SIZE)
837 warning (_("'%s' core file section is too small. "
838 "Expected %s bytes, got %s bytes"), section_name,
839 pulongest (SVE_HEADER_SIZE), pulongest (size));
840 return 0;
843 gdb_byte header[SVE_HEADER_SIZE];
845 if (!bfd_get_section_contents (abfd, section, header, 0, SVE_HEADER_SIZE))
847 warning (_("Couldn't read sve header from "
848 "'%s' core file section."), section_name);
849 return 0;
852 enum bfd_endian byte_order = gdbarch_byte_order (gdbarch);
853 uint64_t vq
854 = sve_vq_from_vl (extract_unsigned_integer (header + SVE_HEADER_VL_OFFSET,
855 SVE_HEADER_VL_LENGTH,
856 byte_order));
858 if (vq > AARCH64_MAX_SVE_VQ || vq == 0)
860 warning (_("SVE/SSVE vector length in core file is invalid."
861 " (max vq=%d) (detected vq=%s)"), AARCH64_MAX_SVE_VQ,
862 pulongest (vq));
863 return 0;
866 return vq;
869 /* Get the vector quotient (VQ) value from CORE_BFD's sections.
871 Return non-zero if successful and 0 otherwise. */
873 static uint64_t
874 aarch64_linux_core_read_vq_from_sections (struct gdbarch *gdbarch,
875 bfd *core_bfd)
877 /* First check if we have a SSVE section. If so, check if it is active. */
878 asection *section = bfd_get_section_by_name (core_bfd, ".reg-aarch-ssve");
880 if (section != nullptr)
882 /* We've found a SSVE section, so now fetch its data. */
883 gdb_byte header[SVE_HEADER_SIZE];
885 if (bfd_get_section_contents (core_bfd, section, header, 0,
886 SVE_HEADER_SIZE))
888 /* Check if the SSVE section has SVE contents. */
889 enum bfd_endian byte_order = gdbarch_byte_order (gdbarch);
890 uint16_t flags
891 = extract_unsigned_integer (header + SVE_HEADER_FLAGS_OFFSET,
892 SVE_HEADER_FLAGS_LENGTH, byte_order);
894 if (flags & SVE_HEADER_FLAG_SVE)
896 /* The SSVE state is active, so return the vector length from the
897 the SSVE section. */
898 return aarch64_linux_core_read_vq (gdbarch, core_bfd,
899 ".reg-aarch-ssve");
904 /* No valid SSVE section. Return the vq from the SVE section (if any). */
905 return aarch64_linux_core_read_vq (gdbarch, core_bfd, ".reg-aarch-sve");
908 /* Supply register REGNUM from BUF to REGCACHE, using the register map
909 in REGSET. If REGNUM is -1, do this for all registers in REGSET.
910 If BUF is nullptr, set the registers to "unavailable" status. */
912 static void
913 supply_sve_regset (const struct regset *regset,
914 struct regcache *regcache,
915 int regnum, const void *buf, size_t size)
917 gdb_byte *header = (gdb_byte *) buf;
918 struct gdbarch *gdbarch = regcache->arch ();
919 enum bfd_endian byte_order = gdbarch_byte_order (gdbarch);
921 if (buf == nullptr)
922 return regcache->supply_regset (regset, regnum, nullptr, size);
923 gdb_assert (size > SVE_HEADER_SIZE);
925 /* BUF contains an SVE header followed by a register dump of either the
926 passed in SVE regset or a NEON fpregset. */
928 /* Extract required fields from the header. */
929 ULONGEST vl = extract_unsigned_integer (header + SVE_HEADER_VL_OFFSET,
930 SVE_HEADER_VL_LENGTH, byte_order);
931 uint16_t flags = extract_unsigned_integer (header + SVE_HEADER_FLAGS_OFFSET,
932 SVE_HEADER_FLAGS_LENGTH,
933 byte_order);
935 if (regnum == -1 || regnum == AARCH64_SVE_VG_REGNUM)
937 gdb_byte vg_target[8];
938 store_integer ((gdb_byte *)&vg_target, sizeof (uint64_t), byte_order,
939 sve_vg_from_vl (vl));
940 regcache->raw_supply (AARCH64_SVE_VG_REGNUM, &vg_target);
943 if (flags & SVE_HEADER_FLAG_SVE)
945 /* Register dump is a SVE structure. */
946 regcache->supply_regset (regset, regnum,
947 (gdb_byte *) buf + SVE_HEADER_SIZE,
948 size - SVE_HEADER_SIZE);
950 else
952 /* Register dump is a fpsimd structure. First clear the SVE
953 registers. */
954 for (int i = 0; i < AARCH64_SVE_Z_REGS_NUM; i++)
955 regcache->raw_supply_zeroed (AARCH64_SVE_Z0_REGNUM + i);
956 for (int i = 0; i < AARCH64_SVE_P_REGS_NUM; i++)
957 regcache->raw_supply_zeroed (AARCH64_SVE_P0_REGNUM + i);
958 regcache->raw_supply_zeroed (AARCH64_SVE_FFR_REGNUM);
960 /* Then supply the fpsimd registers. */
961 regcache->supply_regset (&aarch64_linux_fpregset, regnum,
962 (gdb_byte *) buf + SVE_HEADER_SIZE,
963 size - SVE_HEADER_SIZE);
967 /* Collect an inactive SVE register set state. This is equivalent to a
968 fpsimd layout.
970 Collect the data from REGCACHE to BUF, using the register
971 map in REGSET. */
973 static void
974 collect_inactive_sve_regset (const struct regcache *regcache,
975 void *buf, size_t size, int vg_regnum)
977 gdb_byte *header = (gdb_byte *) buf;
978 struct gdbarch *gdbarch = regcache->arch ();
979 enum bfd_endian byte_order = gdbarch_byte_order (gdbarch);
981 gdb_assert (buf != nullptr);
982 gdb_assert (size >= SVE_CORE_DUMMY_SIZE);
984 /* Zero out everything first. */
985 memset ((gdb_byte *) buf, 0, SVE_CORE_DUMMY_SIZE);
987 /* BUF starts with a SVE header prior to the register dump. */
989 /* Dump the default size of an empty SVE payload. */
990 uint32_t real_size = SVE_CORE_DUMMY_SIZE;
991 store_unsigned_integer (header + SVE_HEADER_SIZE_OFFSET,
992 SVE_HEADER_SIZE_LENGTH, byte_order, real_size);
994 /* Dump a dummy max size. */
995 uint32_t max_size = SVE_CORE_DUMMY_MAX_SIZE;
996 store_unsigned_integer (header + SVE_HEADER_MAX_SIZE_OFFSET,
997 SVE_HEADER_MAX_SIZE_LENGTH, byte_order, max_size);
999 /* Dump the vector length. */
1000 ULONGEST vg = 0;
1001 regcache->raw_collect (vg_regnum, &vg);
1002 uint16_t vl = sve_vl_from_vg (vg);
1003 store_unsigned_integer (header + SVE_HEADER_VL_OFFSET, SVE_HEADER_VL_LENGTH,
1004 byte_order, vl);
1006 /* Dump the standard maximum vector length. */
1007 uint16_t max_vl = SVE_CORE_DUMMY_MAX_VL;
1008 store_unsigned_integer (header + SVE_HEADER_MAX_VL_OFFSET,
1009 SVE_HEADER_MAX_VL_LENGTH, byte_order,
1010 max_vl);
1012 /* The rest of the fields are zero. */
1013 uint16_t flags = SVE_CORE_DUMMY_FLAGS;
1014 store_unsigned_integer (header + SVE_HEADER_FLAGS_OFFSET,
1015 SVE_HEADER_FLAGS_LENGTH, byte_order,
1016 flags);
1017 uint16_t reserved = SVE_CORE_DUMMY_RESERVED;
1018 store_unsigned_integer (header + SVE_HEADER_RESERVED_OFFSET,
1019 SVE_HEADER_RESERVED_LENGTH, byte_order, reserved);
1021 /* We are done with the header part of it. Now dump the register state
1022 in the FPSIMD format. */
1024 /* Dump the first 128 bits of each of the Z registers. */
1025 header += AARCH64_SVE_CONTEXT_REGS_OFFSET;
1026 for (int i = 0; i < AARCH64_SVE_Z_REGS_NUM; i++)
1027 regcache->raw_collect_part (AARCH64_SVE_Z0_REGNUM + i, 0, V_REGISTER_SIZE,
1028 header + V_REGISTER_SIZE * i);
1030 /* Dump FPSR and FPCR. */
1031 header += 32 * V_REGISTER_SIZE;
1032 regcache->raw_collect (AARCH64_FPSR_REGNUM, header);
1033 regcache->raw_collect (AARCH64_FPCR_REGNUM, header + 4);
1035 /* Dump two reserved empty fields of 4 bytes. */
1036 header += 8;
1037 memset (header, 0, 8);
1039 /* We should have a FPSIMD-formatted register dump now. */
1042 /* Collect register REGNUM from REGCACHE to BUF, using the register
1043 map in REGSET. If REGNUM is -1, do this for all registers in
1044 REGSET. */
1046 static void
1047 collect_sve_regset (const struct regset *regset,
1048 const struct regcache *regcache,
1049 int regnum, void *buf, size_t size)
1051 gdb_byte *header = (gdb_byte *) buf;
1052 struct gdbarch *gdbarch = regcache->arch ();
1053 enum bfd_endian byte_order = gdbarch_byte_order (gdbarch);
1054 aarch64_gdbarch_tdep *tdep = gdbarch_tdep<aarch64_gdbarch_tdep> (gdbarch);
1055 uint64_t vq = tdep->vq;
1057 gdb_assert (buf != NULL);
1058 gdb_assert (size > SVE_HEADER_SIZE);
1060 /* BUF starts with a SVE header prior to the register dump. */
1062 store_unsigned_integer (header + SVE_HEADER_SIZE_OFFSET,
1063 SVE_HEADER_SIZE_LENGTH, byte_order, size);
1064 uint32_t max_size = SVE_CORE_DUMMY_MAX_SIZE;
1065 store_unsigned_integer (header + SVE_HEADER_MAX_SIZE_OFFSET,
1066 SVE_HEADER_MAX_SIZE_LENGTH, byte_order, max_size);
1067 store_unsigned_integer (header + SVE_HEADER_VL_OFFSET, SVE_HEADER_VL_LENGTH,
1068 byte_order, sve_vl_from_vq (vq));
1069 uint16_t max_vl = SVE_CORE_DUMMY_MAX_VL;
1070 store_unsigned_integer (header + SVE_HEADER_MAX_VL_OFFSET,
1071 SVE_HEADER_MAX_VL_LENGTH, byte_order,
1072 max_vl);
1073 uint16_t flags = SVE_HEADER_FLAG_SVE;
1074 store_unsigned_integer (header + SVE_HEADER_FLAGS_OFFSET,
1075 SVE_HEADER_FLAGS_LENGTH, byte_order,
1076 flags);
1077 uint16_t reserved = SVE_CORE_DUMMY_RESERVED;
1078 store_unsigned_integer (header + SVE_HEADER_RESERVED_OFFSET,
1079 SVE_HEADER_RESERVED_LENGTH, byte_order, reserved);
1081 /* The SVE register dump follows. */
1082 regcache->collect_regset (regset, regnum, (gdb_byte *) buf + SVE_HEADER_SIZE,
1083 size - SVE_HEADER_SIZE);
1086 /* Supply register REGNUM from BUF to REGCACHE, using the register map
1087 in REGSET. If REGNUM is -1, do this for all registers in REGSET.
1088 If BUF is NULL, set the registers to "unavailable" status. */
1090 static void
1091 aarch64_linux_supply_sve_regset (const struct regset *regset,
1092 struct regcache *regcache,
1093 int regnum, const void *buf, size_t size)
1095 struct gdbarch *gdbarch = regcache->arch ();
1096 aarch64_gdbarch_tdep *tdep = gdbarch_tdep<aarch64_gdbarch_tdep> (gdbarch);
1098 if (tdep->has_sme ())
1100 ULONGEST svcr = 0;
1101 regcache->raw_collect (tdep->sme_svcr_regnum, &svcr);
1103 /* Is streaming mode enabled? */
1104 if (svcr & SVCR_SM_BIT)
1105 /* If so, don't load SVE data from the SVE section. The data to be
1106 used is in the SSVE section. */
1107 return;
1109 /* If streaming mode is not enabled, load the SVE regcache data from the SVE
1110 section. */
1111 supply_sve_regset (regset, regcache, regnum, buf, size);
1114 /* Collect register REGNUM from REGCACHE to BUF, using the register
1115 map in REGSET. If REGNUM is -1, do this for all registers in
1116 REGSET. */
1118 static void
1119 aarch64_linux_collect_sve_regset (const struct regset *regset,
1120 const struct regcache *regcache,
1121 int regnum, void *buf, size_t size)
1123 struct gdbarch *gdbarch = regcache->arch ();
1124 aarch64_gdbarch_tdep *tdep = gdbarch_tdep<aarch64_gdbarch_tdep> (gdbarch);
1125 bool streaming_mode = false;
1127 if (tdep->has_sme ())
1129 ULONGEST svcr = 0;
1130 regcache->raw_collect (tdep->sme_svcr_regnum, &svcr);
1132 /* Is streaming mode enabled? */
1133 if (svcr & SVCR_SM_BIT)
1135 /* If so, don't dump SVE regcache data to the SVE section. The SVE
1136 data should be dumped to the SSVE section. Dump an empty SVE
1137 block instead. */
1138 streaming_mode = true;
1142 /* If streaming mode is not enabled or there is no SME support, dump the
1143 SVE regcache data to the SVE section. */
1145 /* Check if we have an active SVE state (non-zero Z/P/FFR registers).
1146 If so, then we need to dump registers in the SVE format.
1148 Otherwise we should dump the registers in the FPSIMD format. */
1149 if (sve_state_is_empty (regcache) || streaming_mode)
1150 collect_inactive_sve_regset (regcache, buf, size, AARCH64_SVE_VG_REGNUM);
1151 else
1152 collect_sve_regset (regset, regcache, regnum, buf, size);
1155 /* Supply register REGNUM from BUF to REGCACHE, using the register map
1156 in REGSET. If REGNUM is -1, do this for all registers in REGSET.
1157 If BUF is NULL, set the registers to "unavailable" status. */
1159 static void
1160 aarch64_linux_supply_ssve_regset (const struct regset *regset,
1161 struct regcache *regcache,
1162 int regnum, const void *buf, size_t size)
1164 gdb_byte *header = (gdb_byte *) buf;
1165 struct gdbarch *gdbarch = regcache->arch ();
1166 enum bfd_endian byte_order = gdbarch_byte_order (gdbarch);
1167 aarch64_gdbarch_tdep *tdep = gdbarch_tdep<aarch64_gdbarch_tdep> (gdbarch);
1169 uint16_t flags = extract_unsigned_integer (header + SVE_HEADER_FLAGS_OFFSET,
1170 SVE_HEADER_FLAGS_LENGTH,
1171 byte_order);
1173 /* Since SVCR's bits are inferred from the data we have in the header of the
1174 SSVE section, we need to initialize it to zero first, so that it doesn't
1175 carry garbage data. */
1176 ULONGEST svcr = 0;
1177 regcache->raw_supply (tdep->sme_svcr_regnum, &svcr);
1179 /* Is streaming mode enabled? */
1180 if (flags & SVE_HEADER_FLAG_SVE)
1182 /* Streaming mode is active, so flip the SM bit. */
1183 svcr = SVCR_SM_BIT;
1184 regcache->raw_supply (tdep->sme_svcr_regnum, &svcr);
1186 /* Fetch the SVE data from the SSVE section. */
1187 supply_sve_regset (regset, regcache, regnum, buf, size);
1191 /* Collect register REGNUM from REGCACHE to BUF, using the register
1192 map in REGSET. If REGNUM is -1, do this for all registers in
1193 REGSET. */
1195 static void
1196 aarch64_linux_collect_ssve_regset (const struct regset *regset,
1197 const struct regcache *regcache,
1198 int regnum, void *buf, size_t size)
1200 struct gdbarch *gdbarch = regcache->arch ();
1201 aarch64_gdbarch_tdep *tdep = gdbarch_tdep<aarch64_gdbarch_tdep> (gdbarch);
1202 ULONGEST svcr = 0;
1203 regcache->raw_collect (tdep->sme_svcr_regnum, &svcr);
1205 /* Is streaming mode enabled? */
1206 if (svcr & SVCR_SM_BIT)
1208 /* If so, dump SVE regcache data to the SSVE section. */
1209 collect_sve_regset (regset, regcache, regnum, buf, size);
1211 else
1213 /* Otherwise dump an empty SVE block to the SSVE section with the
1214 streaming vector length. */
1215 collect_inactive_sve_regset (regcache, buf, size, tdep->sme_svg_regnum);
1219 /* Supply register REGNUM from BUF to REGCACHE, using the register map
1220 in REGSET. If REGNUM is -1, do this for all registers in REGSET.
1221 If BUF is NULL, set the registers to "unavailable" status. */
1223 static void
1224 aarch64_linux_supply_za_regset (const struct regset *regset,
1225 struct regcache *regcache,
1226 int regnum, const void *buf, size_t size)
1228 gdb_byte *header = (gdb_byte *) buf;
1229 struct gdbarch *gdbarch = regcache->arch ();
1230 enum bfd_endian byte_order = gdbarch_byte_order (gdbarch);
1232 /* Handle an empty buffer. */
1233 if (buf == nullptr)
1234 return regcache->supply_regset (regset, regnum, nullptr, size);
1236 if (size < SVE_HEADER_SIZE)
1237 error (_("ZA state header size (%s) invalid. Should be at least %s."),
1238 pulongest (size), pulongest (SVE_HEADER_SIZE));
1240 /* The ZA register note in a core file can have a couple of states:
1242 1 - Just the header without the payload. This means that there is no
1243 ZA data, and we should populate only SVCR and SVG registers on GDB's
1244 side. The ZA data should be marked as unavailable.
1246 2 - The header with an additional data payload. This means there is
1247 actual ZA data, and we should populate ZA, SVCR and SVG. */
1249 aarch64_gdbarch_tdep *tdep = gdbarch_tdep<aarch64_gdbarch_tdep> (gdbarch);
1251 /* Populate SVG. */
1252 ULONGEST svg
1253 = sve_vg_from_vl (extract_unsigned_integer (header + SVE_HEADER_VL_OFFSET,
1254 SVE_HEADER_VL_LENGTH,
1255 byte_order));
1256 regcache->raw_supply (tdep->sme_svg_regnum, &svg);
1258 size_t data_size
1259 = extract_unsigned_integer (header + SVE_HEADER_SIZE_OFFSET,
1260 SVE_HEADER_SIZE_LENGTH, byte_order)
1261 - SVE_HEADER_SIZE;
1263 /* Populate SVCR. */
1264 bool has_za_payload = (data_size > 0);
1265 ULONGEST svcr;
1266 regcache->raw_collect (tdep->sme_svcr_regnum, &svcr);
1268 /* If we have a ZA payload, enable bit 2 of SVCR, otherwise clear it. This
1269 register gets updated by the SVE/SSVE-handling functions as well, as they
1270 report the SM bit 1. */
1271 if (has_za_payload)
1272 svcr |= SVCR_ZA_BIT;
1273 else
1274 svcr &= ~SVCR_ZA_BIT;
1276 /* Update SVCR in the register buffer. */
1277 regcache->raw_supply (tdep->sme_svcr_regnum, &svcr);
1279 /* Populate the register cache with ZA register contents, if we have any. */
1280 buf = has_za_payload ? (gdb_byte *) buf + SVE_HEADER_SIZE : nullptr;
1282 size_t za_bytes = std::pow (sve_vl_from_vg (svg), 2);
1284 /* Update ZA in the register buffer. */
1285 if (has_za_payload)
1287 /* Check that the payload size is sane. */
1288 if (size < SVE_HEADER_SIZE + za_bytes)
1290 error (_("ZA header + payload size (%s) invalid. Should be at "
1291 "least %s."),
1292 pulongest (size), pulongest (SVE_HEADER_SIZE + za_bytes));
1295 regcache->raw_supply (tdep->sme_za_regnum, buf);
1297 else
1299 gdb_byte za_zeroed[za_bytes];
1300 memset (za_zeroed, 0, za_bytes);
1301 regcache->raw_supply (tdep->sme_za_regnum, za_zeroed);
1305 /* Collect register REGNUM from REGCACHE to BUF, using the register
1306 map in REGSET. If REGNUM is -1, do this for all registers in
1307 REGSET. */
1309 static void
1310 aarch64_linux_collect_za_regset (const struct regset *regset,
1311 const struct regcache *regcache,
1312 int regnum, void *buf, size_t size)
1314 gdb_assert (buf != nullptr);
1316 /* Sanity check the dump size. */
1317 gdb_assert (size >= SVE_HEADER_SIZE);
1319 /* The ZA register note in a core file can have a couple of states:
1321 1 - Just the header without the payload. This means that there is no
1322 ZA data, and we should dump just the header.
1324 2 - The header with an additional data payload. This means there is
1325 actual ZA data, and we should dump both the header and the ZA data
1326 payload. */
1328 aarch64_gdbarch_tdep *tdep
1329 = gdbarch_tdep<aarch64_gdbarch_tdep> (regcache->arch ());
1331 /* Determine if we have ZA state from the SVCR register ZA bit. */
1332 ULONGEST svcr;
1333 regcache->raw_collect (tdep->sme_svcr_regnum, &svcr);
1335 /* Check the ZA payload. */
1336 bool has_za_payload = (svcr & SVCR_ZA_BIT) != 0;
1337 size = has_za_payload ? size : SVE_HEADER_SIZE;
1339 /* Write the size and max_size fields. */
1340 gdb_byte *header = (gdb_byte *) buf;
1341 enum bfd_endian byte_order = gdbarch_byte_order (regcache->arch ());
1342 store_unsigned_integer (header + SVE_HEADER_SIZE_OFFSET,
1343 SVE_HEADER_SIZE_LENGTH, byte_order, size);
1345 uint32_t max_size
1346 = SVE_HEADER_SIZE + std::pow (sve_vl_from_vq (tdep->sme_svq), 2);
1347 store_unsigned_integer (header + SVE_HEADER_MAX_SIZE_OFFSET,
1348 SVE_HEADER_MAX_SIZE_LENGTH, byte_order, max_size);
1350 /* Output the other fields of the ZA header (vl, max_vl, flags and
1351 reserved). */
1352 uint64_t svq = tdep->sme_svq;
1353 store_unsigned_integer (header + SVE_HEADER_VL_OFFSET, SVE_HEADER_VL_LENGTH,
1354 byte_order, sve_vl_from_vq (svq));
1356 uint16_t max_vl = SVE_CORE_DUMMY_MAX_VL;
1357 store_unsigned_integer (header + SVE_HEADER_MAX_VL_OFFSET,
1358 SVE_HEADER_MAX_VL_LENGTH, byte_order,
1359 max_vl);
1361 uint16_t flags = SVE_CORE_DUMMY_FLAGS;
1362 store_unsigned_integer (header + SVE_HEADER_FLAGS_OFFSET,
1363 SVE_HEADER_FLAGS_LENGTH, byte_order, flags);
1365 uint16_t reserved = SVE_CORE_DUMMY_RESERVED;
1366 store_unsigned_integer (header + SVE_HEADER_RESERVED_OFFSET,
1367 SVE_HEADER_RESERVED_LENGTH, byte_order, reserved);
1369 buf = has_za_payload ? (gdb_byte *) buf + SVE_HEADER_SIZE : nullptr;
1371 /* Dump the register cache contents for the ZA register to the buffer. */
1372 regcache->collect_regset (regset, regnum, (gdb_byte *) buf,
1373 size - SVE_HEADER_SIZE);
1376 /* Supply register REGNUM from BUF to REGCACHE, using the register map
1377 in REGSET. If REGNUM is -1, do this for all registers in REGSET.
1378 If BUF is NULL, set the registers to "unavailable" status. */
1380 static void
1381 aarch64_linux_supply_zt_regset (const struct regset *regset,
1382 struct regcache *regcache,
1383 int regnum, const void *buf, size_t size)
1385 /* Read the ZT register note from a core file into the register buffer. */
1387 /* Make sure the buffer contains at least the expected amount of data we are
1388 supposed to get. */
1389 gdb_assert (size >= AARCH64_SME2_ZT0_SIZE);
1391 /* Handle an empty buffer. */
1392 if (buf == nullptr)
1393 return regcache->supply_regset (regset, regnum, nullptr, size);
1395 aarch64_gdbarch_tdep *tdep
1396 = gdbarch_tdep<aarch64_gdbarch_tdep> (regcache->arch ());
1398 /* Supply the ZT0 register contents. */
1399 regcache->raw_supply (tdep->sme2_zt0_regnum, buf);
1402 /* Collect register REGNUM from REGCACHE to BUF, using the register
1403 map in REGSET. If REGNUM is -1, do this for all registers in
1404 REGSET. */
1406 static void
1407 aarch64_linux_collect_zt_regset (const struct regset *regset,
1408 const struct regcache *regcache,
1409 int regnum, void *buf, size_t size)
1411 /* Read the ZT register contents from the register buffer into the core
1412 file section. */
1414 /* Make sure the buffer can hold the data we need to return. */
1415 gdb_assert (size >= AARCH64_SME2_ZT0_SIZE);
1416 gdb_assert (buf != nullptr);
1418 aarch64_gdbarch_tdep *tdep
1419 = gdbarch_tdep<aarch64_gdbarch_tdep> (regcache->arch ());
1421 /* Dump the register cache contents for the ZT register to the buffer. */
1422 regcache->collect_regset (regset, tdep->sme2_zt0_regnum, buf,
1423 AARCH64_SME2_ZT0_SIZE);
1426 /* Implement the "iterate_over_regset_sections" gdbarch method. */
1428 static void
1429 aarch64_linux_iterate_over_regset_sections (struct gdbarch *gdbarch,
1430 iterate_over_regset_sections_cb *cb,
1431 void *cb_data,
1432 const struct regcache *regcache)
1434 aarch64_gdbarch_tdep *tdep = gdbarch_tdep<aarch64_gdbarch_tdep> (gdbarch);
1436 cb (".reg", AARCH64_LINUX_SIZEOF_GREGSET, AARCH64_LINUX_SIZEOF_GREGSET,
1437 &aarch64_linux_gregset, NULL, cb_data);
1439 if (tdep->has_sve ())
1441 /* Create this on the fly in order to handle vector register sizes. */
1442 const struct regcache_map_entry sve_regmap[] =
1444 { 32, AARCH64_SVE_Z0_REGNUM, (int) (tdep->vq * 16) },
1445 { 16, AARCH64_SVE_P0_REGNUM, (int) (tdep->vq * 16 / 8) },
1446 { 1, AARCH64_SVE_FFR_REGNUM, (int) (tdep->vq * 16 / 8) },
1447 { 1, AARCH64_FPSR_REGNUM, 4 },
1448 { 1, AARCH64_FPCR_REGNUM, 4 },
1449 { 0 }
1452 const struct regset aarch64_linux_ssve_regset =
1454 sve_regmap,
1455 aarch64_linux_supply_ssve_regset, aarch64_linux_collect_ssve_regset,
1456 REGSET_VARIABLE_SIZE
1459 /* If SME is supported in the core file, process the SSVE section first,
1460 and the SVE section last. This is because we need information from
1461 the SSVE set to determine if streaming mode is active. If streaming
1462 mode is active, we need to extract the data from the SSVE section.
1464 Otherwise, if streaming mode is not active, we fetch the data from the
1465 SVE section. */
1466 if (tdep->has_sme ())
1468 cb (".reg-aarch-ssve",
1469 SVE_HEADER_SIZE
1470 + regcache_map_entry_size (aarch64_linux_fpregmap),
1471 SVE_HEADER_SIZE + regcache_map_entry_size (sve_regmap),
1472 &aarch64_linux_ssve_regset, "SSVE registers", cb_data);
1475 /* Handle the SVE register set. */
1476 const struct regset aarch64_linux_sve_regset =
1478 sve_regmap,
1479 aarch64_linux_supply_sve_regset, aarch64_linux_collect_sve_regset,
1480 REGSET_VARIABLE_SIZE
1483 cb (".reg-aarch-sve",
1484 SVE_HEADER_SIZE + regcache_map_entry_size (aarch64_linux_fpregmap),
1485 SVE_HEADER_SIZE + regcache_map_entry_size (sve_regmap),
1486 &aarch64_linux_sve_regset, "SVE registers", cb_data);
1488 else
1489 cb (".reg2", AARCH64_LINUX_SIZEOF_FPREGSET, AARCH64_LINUX_SIZEOF_FPREGSET,
1490 &aarch64_linux_fpregset, NULL, cb_data);
1492 if (tdep->has_sme ())
1494 /* Setup the register set information for a ZA register set core
1495 dump. */
1497 /* Create this on the fly in order to handle the ZA register size. */
1498 const struct regcache_map_entry za_regmap[] =
1500 { 1, tdep->sme_za_regnum,
1501 (int) std::pow (sve_vl_from_vq (tdep->sme_svq), 2) },
1502 { 0 }
1505 const struct regset aarch64_linux_za_regset =
1507 za_regmap,
1508 aarch64_linux_supply_za_regset, aarch64_linux_collect_za_regset,
1509 REGSET_VARIABLE_SIZE
1512 cb (".reg-aarch-za",
1513 SVE_HEADER_SIZE,
1514 SVE_HEADER_SIZE + std::pow (sve_vl_from_vq (tdep->sme_svq), 2),
1515 &aarch64_linux_za_regset, "ZA register", cb_data);
1517 /* Handle SME2 (ZT) as well, which is only available if SME is
1518 available. */
1519 if (tdep->has_sme2 ())
1521 const struct regcache_map_entry zt_regmap[] =
1523 { 1, tdep->sme2_zt0_regnum, AARCH64_SME2_ZT0_SIZE },
1524 { 0 }
1527 /* We set the register set size to REGSET_VARIABLE_SIZE here because
1528 in the future there might be more ZT registers. */
1529 const struct regset aarch64_linux_zt_regset =
1531 zt_regmap,
1532 aarch64_linux_supply_zt_regset, aarch64_linux_collect_zt_regset,
1533 REGSET_VARIABLE_SIZE
1536 cb (".reg-aarch-zt",
1537 AARCH64_SME2_ZT0_SIZE,
1538 AARCH64_SME2_ZT0_SIZE,
1539 &aarch64_linux_zt_regset, "ZT registers", cb_data);
1543 if (tdep->has_pauth ())
1545 /* Create this on the fly in order to handle the variable location. */
1546 const struct regcache_map_entry pauth_regmap[] =
1548 { 2, AARCH64_PAUTH_DMASK_REGNUM (tdep->pauth_reg_base), 8},
1549 { 0 }
1552 const struct regset aarch64_linux_pauth_regset =
1554 pauth_regmap, regcache_supply_regset, regcache_collect_regset
1557 cb (".reg-aarch-pauth", AARCH64_LINUX_SIZEOF_PAUTH,
1558 AARCH64_LINUX_SIZEOF_PAUTH, &aarch64_linux_pauth_regset,
1559 "pauth registers", cb_data);
1562 /* Handle MTE registers. */
1563 if (tdep->has_mte ())
1565 /* Create this on the fly in order to handle the variable location. */
1566 const struct regcache_map_entry mte_regmap[] =
1568 { 1, tdep->mte_reg_base, 8},
1569 { 0 }
1572 const struct regset aarch64_linux_mte_regset =
1574 mte_regmap, regcache_supply_regset, regcache_collect_regset
1577 cb (".reg-aarch-mte", AARCH64_LINUX_SIZEOF_MTE_REGSET,
1578 AARCH64_LINUX_SIZEOF_MTE_REGSET, &aarch64_linux_mte_regset,
1579 "MTE registers", cb_data);
1582 /* Handle the TLS registers. */
1583 if (tdep->has_tls ())
1585 gdb_assert (tdep->tls_regnum_base != -1);
1586 gdb_assert (tdep->tls_register_count > 0);
1588 int sizeof_tls_regset
1589 = AARCH64_TLS_REGISTER_SIZE * tdep->tls_register_count;
1591 const struct regcache_map_entry tls_regmap[] =
1593 { tdep->tls_register_count, tdep->tls_regnum_base,
1594 AARCH64_TLS_REGISTER_SIZE },
1595 { 0 }
1598 const struct regset aarch64_linux_tls_regset =
1600 tls_regmap, regcache_supply_regset, regcache_collect_regset,
1601 REGSET_VARIABLE_SIZE
1604 cb (".reg-aarch-tls", sizeof_tls_regset, sizeof_tls_regset,
1605 &aarch64_linux_tls_regset, "TLS register", cb_data);
1609 /* Implement the "core_read_description" gdbarch method. */
1611 static const struct target_desc *
1612 aarch64_linux_core_read_description (struct gdbarch *gdbarch,
1613 struct target_ops *target, bfd *abfd)
1615 std::optional<gdb::byte_vector> auxv = target_read_auxv_raw (target);
1616 CORE_ADDR hwcap = linux_get_hwcap (auxv, target, gdbarch);
1617 CORE_ADDR hwcap2 = linux_get_hwcap2 (auxv, target, gdbarch);
1619 aarch64_features features;
1621 /* We need to extract the SVE data from the .reg-aarch-sve section or the
1622 .reg-aarch-ssve section depending on which one was active when the core
1623 file was generated.
1625 If the SSVE section contains SVE data, then it is considered active.
1626 Otherwise the SVE section is considered active. This guarantees we will
1627 have the correct target description with the correct SVE vector
1628 length. */
1629 features.vq = aarch64_linux_core_read_vq_from_sections (gdbarch, abfd);
1630 features.pauth = hwcap & AARCH64_HWCAP_PACA;
1631 features.mte = hwcap2 & HWCAP2_MTE;
1633 /* Handle the TLS section. */
1634 asection *tls = bfd_get_section_by_name (abfd, ".reg-aarch-tls");
1635 if (tls != nullptr)
1637 size_t size = bfd_section_size (tls);
1638 /* Convert the size to the number of actual registers, by
1639 dividing by 8. */
1640 features.tls = size / AARCH64_TLS_REGISTER_SIZE;
1643 features.svq
1644 = aarch64_linux_core_read_vq (gdbarch, abfd, ".reg-aarch-za");
1646 /* Are the ZT registers available? */
1647 if (bfd_get_section_by_name (abfd, ".reg-aarch-zt") != nullptr)
1649 /* Check if ZA is also available, otherwise this is an invalid
1650 combination. */
1651 if (bfd_get_section_by_name (abfd, ".reg-aarch-za") != nullptr)
1652 features.sme2 = true;
1653 else
1654 warning (_("While reading core file sections, found ZT registers entry "
1655 "but no ZA register entry. The ZT contents will be "
1656 "ignored"));
1659 return aarch64_read_description (features);
1662 /* Implementation of `gdbarch_stap_is_single_operand', as defined in
1663 gdbarch.h. */
1665 static int
1666 aarch64_stap_is_single_operand (struct gdbarch *gdbarch, const char *s)
1668 return (*s == '#' || isdigit (*s) /* Literal number. */
1669 || *s == '[' /* Register indirection. */
1670 || isalpha (*s)); /* Register value. */
1673 /* This routine is used to parse a special token in AArch64's assembly.
1675 The special tokens parsed by it are:
1677 - Register displacement (e.g, [fp, #-8])
1679 It returns one if the special token has been parsed successfully,
1680 or zero if the current token is not considered special. */
1682 static expr::operation_up
1683 aarch64_stap_parse_special_token (struct gdbarch *gdbarch,
1684 struct stap_parse_info *p)
1686 if (*p->arg == '[')
1688 /* Temporary holder for lookahead. */
1689 const char *tmp = p->arg;
1690 char *endp;
1691 /* Used to save the register name. */
1692 const char *start;
1693 int len;
1694 int got_minus = 0;
1695 long displacement;
1697 ++tmp;
1698 start = tmp;
1700 /* Register name. */
1701 while (isalnum (*tmp))
1702 ++tmp;
1704 if (*tmp != ',')
1705 return {};
1707 len = tmp - start;
1708 std::string regname (start, len);
1710 if (user_reg_map_name_to_regnum (gdbarch, regname.c_str (), len) == -1)
1711 error (_("Invalid register name `%s' on expression `%s'."),
1712 regname.c_str (), p->saved_arg);
1714 ++tmp;
1715 tmp = skip_spaces (tmp);
1716 /* Now we expect a number. It can begin with '#' or simply
1717 a digit. */
1718 if (*tmp == '#')
1719 ++tmp;
1721 if (*tmp == '-')
1723 ++tmp;
1724 got_minus = 1;
1726 else if (*tmp == '+')
1727 ++tmp;
1729 if (!isdigit (*tmp))
1730 return {};
1732 displacement = strtol (tmp, &endp, 10);
1733 tmp = endp;
1735 /* Skipping last `]'. */
1736 if (*tmp++ != ']')
1737 return {};
1738 p->arg = tmp;
1740 using namespace expr;
1742 /* The displacement. */
1743 struct type *long_type = builtin_type (gdbarch)->builtin_long;
1744 if (got_minus)
1745 displacement = -displacement;
1746 operation_up disp = make_operation<long_const_operation> (long_type,
1747 displacement);
1749 /* The register name. */
1750 operation_up reg
1751 = make_operation<register_operation> (std::move (regname));
1753 operation_up sum
1754 = make_operation<add_operation> (std::move (reg), std::move (disp));
1756 /* Casting to the expected type. */
1757 struct type *arg_ptr_type = lookup_pointer_type (p->arg_type);
1758 sum = make_operation<unop_cast_operation> (std::move (sum),
1759 arg_ptr_type);
1760 return make_operation<unop_ind_operation> (std::move (sum));
1762 return {};
1765 /* AArch64 process record-replay constructs: syscall, signal etc. */
1767 static linux_record_tdep aarch64_linux_record_tdep;
1769 /* Enum that defines the AArch64 linux specific syscall identifiers used for
1770 process record/replay. */
1772 enum aarch64_syscall {
1773 aarch64_sys_io_setup = 0,
1774 aarch64_sys_io_destroy = 1,
1775 aarch64_sys_io_submit = 2,
1776 aarch64_sys_io_cancel = 3,
1777 aarch64_sys_io_getevents = 4,
1778 aarch64_sys_setxattr = 5,
1779 aarch64_sys_lsetxattr = 6,
1780 aarch64_sys_fsetxattr = 7,
1781 aarch64_sys_getxattr = 8,
1782 aarch64_sys_lgetxattr = 9,
1783 aarch64_sys_fgetxattr = 10,
1784 aarch64_sys_listxattr = 11,
1785 aarch64_sys_llistxattr = 12,
1786 aarch64_sys_flistxattr = 13,
1787 aarch64_sys_removexattr = 14,
1788 aarch64_sys_lremovexattr = 15,
1789 aarch64_sys_fremovexattr = 16,
1790 aarch64_sys_getcwd = 17,
1791 aarch64_sys_lookup_dcookie = 18,
1792 aarch64_sys_eventfd2 = 19,
1793 aarch64_sys_epoll_create1 = 20,
1794 aarch64_sys_epoll_ctl = 21,
1795 aarch64_sys_epoll_pwait = 22,
1796 aarch64_sys_dup = 23,
1797 aarch64_sys_dup3 = 24,
1798 aarch64_sys_fcntl = 25,
1799 aarch64_sys_inotify_init1 = 26,
1800 aarch64_sys_inotify_add_watch = 27,
1801 aarch64_sys_inotify_rm_watch = 28,
1802 aarch64_sys_ioctl = 29,
1803 aarch64_sys_ioprio_set = 30,
1804 aarch64_sys_ioprio_get = 31,
1805 aarch64_sys_flock = 32,
1806 aarch64_sys_mknodat = 33,
1807 aarch64_sys_mkdirat = 34,
1808 aarch64_sys_unlinkat = 35,
1809 aarch64_sys_symlinkat = 36,
1810 aarch64_sys_linkat = 37,
1811 aarch64_sys_renameat = 38,
1812 aarch64_sys_umount2 = 39,
1813 aarch64_sys_mount = 40,
1814 aarch64_sys_pivot_root = 41,
1815 aarch64_sys_nfsservctl = 42,
1816 aarch64_sys_statfs = 43,
1817 aarch64_sys_fstatfs = 44,
1818 aarch64_sys_truncate = 45,
1819 aarch64_sys_ftruncate = 46,
1820 aarch64_sys_fallocate = 47,
1821 aarch64_sys_faccessat = 48,
1822 aarch64_sys_chdir = 49,
1823 aarch64_sys_fchdir = 50,
1824 aarch64_sys_chroot = 51,
1825 aarch64_sys_fchmod = 52,
1826 aarch64_sys_fchmodat = 53,
1827 aarch64_sys_fchownat = 54,
1828 aarch64_sys_fchown = 55,
1829 aarch64_sys_openat = 56,
1830 aarch64_sys_close = 57,
1831 aarch64_sys_vhangup = 58,
1832 aarch64_sys_pipe2 = 59,
1833 aarch64_sys_quotactl = 60,
1834 aarch64_sys_getdents64 = 61,
1835 aarch64_sys_lseek = 62,
1836 aarch64_sys_read = 63,
1837 aarch64_sys_write = 64,
1838 aarch64_sys_readv = 65,
1839 aarch64_sys_writev = 66,
1840 aarch64_sys_pread64 = 67,
1841 aarch64_sys_pwrite64 = 68,
1842 aarch64_sys_preadv = 69,
1843 aarch64_sys_pwritev = 70,
1844 aarch64_sys_sendfile = 71,
1845 aarch64_sys_pselect6 = 72,
1846 aarch64_sys_ppoll = 73,
1847 aarch64_sys_signalfd4 = 74,
1848 aarch64_sys_vmsplice = 75,
1849 aarch64_sys_splice = 76,
1850 aarch64_sys_tee = 77,
1851 aarch64_sys_readlinkat = 78,
1852 aarch64_sys_newfstatat = 79,
1853 aarch64_sys_fstat = 80,
1854 aarch64_sys_sync = 81,
1855 aarch64_sys_fsync = 82,
1856 aarch64_sys_fdatasync = 83,
1857 aarch64_sys_sync_file_range2 = 84,
1858 aarch64_sys_sync_file_range = 84,
1859 aarch64_sys_timerfd_create = 85,
1860 aarch64_sys_timerfd_settime = 86,
1861 aarch64_sys_timerfd_gettime = 87,
1862 aarch64_sys_utimensat = 88,
1863 aarch64_sys_acct = 89,
1864 aarch64_sys_capget = 90,
1865 aarch64_sys_capset = 91,
1866 aarch64_sys_personality = 92,
1867 aarch64_sys_exit = 93,
1868 aarch64_sys_exit_group = 94,
1869 aarch64_sys_waitid = 95,
1870 aarch64_sys_set_tid_address = 96,
1871 aarch64_sys_unshare = 97,
1872 aarch64_sys_futex = 98,
1873 aarch64_sys_set_robust_list = 99,
1874 aarch64_sys_get_robust_list = 100,
1875 aarch64_sys_nanosleep = 101,
1876 aarch64_sys_getitimer = 102,
1877 aarch64_sys_setitimer = 103,
1878 aarch64_sys_kexec_load = 104,
1879 aarch64_sys_init_module = 105,
1880 aarch64_sys_delete_module = 106,
1881 aarch64_sys_timer_create = 107,
1882 aarch64_sys_timer_gettime = 108,
1883 aarch64_sys_timer_getoverrun = 109,
1884 aarch64_sys_timer_settime = 110,
1885 aarch64_sys_timer_delete = 111,
1886 aarch64_sys_clock_settime = 112,
1887 aarch64_sys_clock_gettime = 113,
1888 aarch64_sys_clock_getres = 114,
1889 aarch64_sys_clock_nanosleep = 115,
1890 aarch64_sys_syslog = 116,
1891 aarch64_sys_ptrace = 117,
1892 aarch64_sys_sched_setparam = 118,
1893 aarch64_sys_sched_setscheduler = 119,
1894 aarch64_sys_sched_getscheduler = 120,
1895 aarch64_sys_sched_getparam = 121,
1896 aarch64_sys_sched_setaffinity = 122,
1897 aarch64_sys_sched_getaffinity = 123,
1898 aarch64_sys_sched_yield = 124,
1899 aarch64_sys_sched_get_priority_max = 125,
1900 aarch64_sys_sched_get_priority_min = 126,
1901 aarch64_sys_sched_rr_get_interval = 127,
1902 aarch64_sys_kill = 129,
1903 aarch64_sys_tkill = 130,
1904 aarch64_sys_tgkill = 131,
1905 aarch64_sys_sigaltstack = 132,
1906 aarch64_sys_rt_sigsuspend = 133,
1907 aarch64_sys_rt_sigaction = 134,
1908 aarch64_sys_rt_sigprocmask = 135,
1909 aarch64_sys_rt_sigpending = 136,
1910 aarch64_sys_rt_sigtimedwait = 137,
1911 aarch64_sys_rt_sigqueueinfo = 138,
1912 aarch64_sys_rt_sigreturn = 139,
1913 aarch64_sys_setpriority = 140,
1914 aarch64_sys_getpriority = 141,
1915 aarch64_sys_reboot = 142,
1916 aarch64_sys_setregid = 143,
1917 aarch64_sys_setgid = 144,
1918 aarch64_sys_setreuid = 145,
1919 aarch64_sys_setuid = 146,
1920 aarch64_sys_setresuid = 147,
1921 aarch64_sys_getresuid = 148,
1922 aarch64_sys_setresgid = 149,
1923 aarch64_sys_getresgid = 150,
1924 aarch64_sys_setfsuid = 151,
1925 aarch64_sys_setfsgid = 152,
1926 aarch64_sys_times = 153,
1927 aarch64_sys_setpgid = 154,
1928 aarch64_sys_getpgid = 155,
1929 aarch64_sys_getsid = 156,
1930 aarch64_sys_setsid = 157,
1931 aarch64_sys_getgroups = 158,
1932 aarch64_sys_setgroups = 159,
1933 aarch64_sys_uname = 160,
1934 aarch64_sys_sethostname = 161,
1935 aarch64_sys_setdomainname = 162,
1936 aarch64_sys_getrlimit = 163,
1937 aarch64_sys_setrlimit = 164,
1938 aarch64_sys_getrusage = 165,
1939 aarch64_sys_umask = 166,
1940 aarch64_sys_prctl = 167,
1941 aarch64_sys_getcpu = 168,
1942 aarch64_sys_gettimeofday = 169,
1943 aarch64_sys_settimeofday = 170,
1944 aarch64_sys_adjtimex = 171,
1945 aarch64_sys_getpid = 172,
1946 aarch64_sys_getppid = 173,
1947 aarch64_sys_getuid = 174,
1948 aarch64_sys_geteuid = 175,
1949 aarch64_sys_getgid = 176,
1950 aarch64_sys_getegid = 177,
1951 aarch64_sys_gettid = 178,
1952 aarch64_sys_sysinfo = 179,
1953 aarch64_sys_mq_open = 180,
1954 aarch64_sys_mq_unlink = 181,
1955 aarch64_sys_mq_timedsend = 182,
1956 aarch64_sys_mq_timedreceive = 183,
1957 aarch64_sys_mq_notify = 184,
1958 aarch64_sys_mq_getsetattr = 185,
1959 aarch64_sys_msgget = 186,
1960 aarch64_sys_msgctl = 187,
1961 aarch64_sys_msgrcv = 188,
1962 aarch64_sys_msgsnd = 189,
1963 aarch64_sys_semget = 190,
1964 aarch64_sys_semctl = 191,
1965 aarch64_sys_semtimedop = 192,
1966 aarch64_sys_semop = 193,
1967 aarch64_sys_shmget = 194,
1968 aarch64_sys_shmctl = 195,
1969 aarch64_sys_shmat = 196,
1970 aarch64_sys_shmdt = 197,
1971 aarch64_sys_socket = 198,
1972 aarch64_sys_socketpair = 199,
1973 aarch64_sys_bind = 200,
1974 aarch64_sys_listen = 201,
1975 aarch64_sys_accept = 202,
1976 aarch64_sys_connect = 203,
1977 aarch64_sys_getsockname = 204,
1978 aarch64_sys_getpeername = 205,
1979 aarch64_sys_sendto = 206,
1980 aarch64_sys_recvfrom = 207,
1981 aarch64_sys_setsockopt = 208,
1982 aarch64_sys_getsockopt = 209,
1983 aarch64_sys_shutdown = 210,
1984 aarch64_sys_sendmsg = 211,
1985 aarch64_sys_recvmsg = 212,
1986 aarch64_sys_readahead = 213,
1987 aarch64_sys_brk = 214,
1988 aarch64_sys_munmap = 215,
1989 aarch64_sys_mremap = 216,
1990 aarch64_sys_add_key = 217,
1991 aarch64_sys_request_key = 218,
1992 aarch64_sys_keyctl = 219,
1993 aarch64_sys_clone = 220,
1994 aarch64_sys_execve = 221,
1995 aarch64_sys_mmap = 222,
1996 aarch64_sys_fadvise64 = 223,
1997 aarch64_sys_swapon = 224,
1998 aarch64_sys_swapoff = 225,
1999 aarch64_sys_mprotect = 226,
2000 aarch64_sys_msync = 227,
2001 aarch64_sys_mlock = 228,
2002 aarch64_sys_munlock = 229,
2003 aarch64_sys_mlockall = 230,
2004 aarch64_sys_munlockall = 231,
2005 aarch64_sys_mincore = 232,
2006 aarch64_sys_madvise = 233,
2007 aarch64_sys_remap_file_pages = 234,
2008 aarch64_sys_mbind = 235,
2009 aarch64_sys_get_mempolicy = 236,
2010 aarch64_sys_set_mempolicy = 237,
2011 aarch64_sys_migrate_pages = 238,
2012 aarch64_sys_move_pages = 239,
2013 aarch64_sys_rt_tgsigqueueinfo = 240,
2014 aarch64_sys_perf_event_open = 241,
2015 aarch64_sys_accept4 = 242,
2016 aarch64_sys_recvmmsg = 243,
2017 aarch64_sys_wait4 = 260,
2018 aarch64_sys_prlimit64 = 261,
2019 aarch64_sys_fanotify_init = 262,
2020 aarch64_sys_fanotify_mark = 263,
2021 aarch64_sys_name_to_handle_at = 264,
2022 aarch64_sys_open_by_handle_at = 265,
2023 aarch64_sys_clock_adjtime = 266,
2024 aarch64_sys_syncfs = 267,
2025 aarch64_sys_setns = 268,
2026 aarch64_sys_sendmmsg = 269,
2027 aarch64_sys_process_vm_readv = 270,
2028 aarch64_sys_process_vm_writev = 271,
2029 aarch64_sys_kcmp = 272,
2030 aarch64_sys_finit_module = 273,
2031 aarch64_sys_sched_setattr = 274,
2032 aarch64_sys_sched_getattr = 275,
2033 aarch64_sys_getrandom = 278
2036 /* aarch64_canonicalize_syscall maps syscall ids from the native AArch64
2037 linux set of syscall ids into a canonical set of syscall ids used by
2038 process record. */
2040 static enum gdb_syscall
2041 aarch64_canonicalize_syscall (enum aarch64_syscall syscall_number)
2043 #define SYSCALL_MAP(SYSCALL) case aarch64_sys_##SYSCALL: \
2044 return gdb_sys_##SYSCALL
2046 #define UNSUPPORTED_SYSCALL_MAP(SYSCALL) case aarch64_sys_##SYSCALL: \
2047 return gdb_sys_no_syscall
2049 switch (syscall_number)
2051 SYSCALL_MAP (io_setup);
2052 SYSCALL_MAP (io_destroy);
2053 SYSCALL_MAP (io_submit);
2054 SYSCALL_MAP (io_cancel);
2055 SYSCALL_MAP (io_getevents);
2057 SYSCALL_MAP (setxattr);
2058 SYSCALL_MAP (lsetxattr);
2059 SYSCALL_MAP (fsetxattr);
2060 SYSCALL_MAP (getxattr);
2061 SYSCALL_MAP (lgetxattr);
2062 SYSCALL_MAP (fgetxattr);
2063 SYSCALL_MAP (listxattr);
2064 SYSCALL_MAP (llistxattr);
2065 SYSCALL_MAP (flistxattr);
2066 SYSCALL_MAP (removexattr);
2067 SYSCALL_MAP (lremovexattr);
2068 SYSCALL_MAP (fremovexattr);
2069 SYSCALL_MAP (getcwd);
2070 SYSCALL_MAP (lookup_dcookie);
2071 SYSCALL_MAP (eventfd2);
2072 SYSCALL_MAP (epoll_create1);
2073 SYSCALL_MAP (epoll_ctl);
2074 SYSCALL_MAP (epoll_pwait);
2075 SYSCALL_MAP (dup);
2076 SYSCALL_MAP (dup3);
2077 SYSCALL_MAP (fcntl);
2078 SYSCALL_MAP (inotify_init1);
2079 SYSCALL_MAP (inotify_add_watch);
2080 SYSCALL_MAP (inotify_rm_watch);
2081 SYSCALL_MAP (ioctl);
2082 SYSCALL_MAP (ioprio_set);
2083 SYSCALL_MAP (ioprio_get);
2084 SYSCALL_MAP (flock);
2085 SYSCALL_MAP (mknodat);
2086 SYSCALL_MAP (mkdirat);
2087 SYSCALL_MAP (unlinkat);
2088 SYSCALL_MAP (symlinkat);
2089 SYSCALL_MAP (linkat);
2090 SYSCALL_MAP (renameat);
2091 UNSUPPORTED_SYSCALL_MAP (umount2);
2092 SYSCALL_MAP (mount);
2093 SYSCALL_MAP (pivot_root);
2094 SYSCALL_MAP (nfsservctl);
2095 SYSCALL_MAP (statfs);
2096 SYSCALL_MAP (truncate);
2097 SYSCALL_MAP (ftruncate);
2098 SYSCALL_MAP (fallocate);
2099 SYSCALL_MAP (faccessat);
2100 SYSCALL_MAP (fchdir);
2101 SYSCALL_MAP (chroot);
2102 SYSCALL_MAP (fchmod);
2103 SYSCALL_MAP (fchmodat);
2104 SYSCALL_MAP (fchownat);
2105 SYSCALL_MAP (fchown);
2106 SYSCALL_MAP (openat);
2107 SYSCALL_MAP (close);
2108 SYSCALL_MAP (vhangup);
2109 SYSCALL_MAP (pipe2);
2110 SYSCALL_MAP (quotactl);
2111 SYSCALL_MAP (getdents64);
2112 SYSCALL_MAP (lseek);
2113 SYSCALL_MAP (read);
2114 SYSCALL_MAP (write);
2115 SYSCALL_MAP (readv);
2116 SYSCALL_MAP (writev);
2117 SYSCALL_MAP (pread64);
2118 SYSCALL_MAP (pwrite64);
2119 UNSUPPORTED_SYSCALL_MAP (preadv);
2120 UNSUPPORTED_SYSCALL_MAP (pwritev);
2121 SYSCALL_MAP (sendfile);
2122 SYSCALL_MAP (pselect6);
2123 SYSCALL_MAP (ppoll);
2124 UNSUPPORTED_SYSCALL_MAP (signalfd4);
2125 SYSCALL_MAP (vmsplice);
2126 SYSCALL_MAP (splice);
2127 SYSCALL_MAP (tee);
2128 SYSCALL_MAP (readlinkat);
2129 SYSCALL_MAP (newfstatat);
2131 SYSCALL_MAP (fstat);
2132 SYSCALL_MAP (sync);
2133 SYSCALL_MAP (fsync);
2134 SYSCALL_MAP (fdatasync);
2135 SYSCALL_MAP (sync_file_range);
2136 UNSUPPORTED_SYSCALL_MAP (timerfd_create);
2137 UNSUPPORTED_SYSCALL_MAP (timerfd_settime);
2138 UNSUPPORTED_SYSCALL_MAP (timerfd_gettime);
2139 UNSUPPORTED_SYSCALL_MAP (utimensat);
2140 SYSCALL_MAP (acct);
2141 SYSCALL_MAP (capget);
2142 SYSCALL_MAP (capset);
2143 SYSCALL_MAP (personality);
2144 SYSCALL_MAP (exit);
2145 SYSCALL_MAP (exit_group);
2146 SYSCALL_MAP (waitid);
2147 SYSCALL_MAP (set_tid_address);
2148 SYSCALL_MAP (unshare);
2149 SYSCALL_MAP (futex);
2150 SYSCALL_MAP (set_robust_list);
2151 SYSCALL_MAP (get_robust_list);
2152 SYSCALL_MAP (nanosleep);
2154 SYSCALL_MAP (getitimer);
2155 SYSCALL_MAP (setitimer);
2156 SYSCALL_MAP (kexec_load);
2157 SYSCALL_MAP (init_module);
2158 SYSCALL_MAP (delete_module);
2159 SYSCALL_MAP (timer_create);
2160 SYSCALL_MAP (timer_settime);
2161 SYSCALL_MAP (timer_gettime);
2162 SYSCALL_MAP (timer_getoverrun);
2163 SYSCALL_MAP (timer_delete);
2164 SYSCALL_MAP (clock_settime);
2165 SYSCALL_MAP (clock_gettime);
2166 SYSCALL_MAP (clock_getres);
2167 SYSCALL_MAP (clock_nanosleep);
2168 SYSCALL_MAP (syslog);
2169 SYSCALL_MAP (ptrace);
2170 SYSCALL_MAP (sched_setparam);
2171 SYSCALL_MAP (sched_setscheduler);
2172 SYSCALL_MAP (sched_getscheduler);
2173 SYSCALL_MAP (sched_getparam);
2174 SYSCALL_MAP (sched_setaffinity);
2175 SYSCALL_MAP (sched_getaffinity);
2176 SYSCALL_MAP (sched_yield);
2177 SYSCALL_MAP (sched_get_priority_max);
2178 SYSCALL_MAP (sched_get_priority_min);
2179 SYSCALL_MAP (sched_rr_get_interval);
2180 SYSCALL_MAP (kill);
2181 SYSCALL_MAP (tkill);
2182 SYSCALL_MAP (tgkill);
2183 SYSCALL_MAP (sigaltstack);
2184 SYSCALL_MAP (rt_sigsuspend);
2185 SYSCALL_MAP (rt_sigaction);
2186 SYSCALL_MAP (rt_sigprocmask);
2187 SYSCALL_MAP (rt_sigpending);
2188 SYSCALL_MAP (rt_sigtimedwait);
2189 SYSCALL_MAP (rt_sigqueueinfo);
2190 SYSCALL_MAP (rt_sigreturn);
2191 SYSCALL_MAP (setpriority);
2192 SYSCALL_MAP (getpriority);
2193 SYSCALL_MAP (reboot);
2194 SYSCALL_MAP (setregid);
2195 SYSCALL_MAP (setgid);
2196 SYSCALL_MAP (setreuid);
2197 SYSCALL_MAP (setuid);
2198 SYSCALL_MAP (setresuid);
2199 SYSCALL_MAP (getresuid);
2200 SYSCALL_MAP (setresgid);
2201 SYSCALL_MAP (getresgid);
2202 SYSCALL_MAP (setfsuid);
2203 SYSCALL_MAP (setfsgid);
2204 SYSCALL_MAP (times);
2205 SYSCALL_MAP (setpgid);
2206 SYSCALL_MAP (getpgid);
2207 SYSCALL_MAP (getsid);
2208 SYSCALL_MAP (setsid);
2209 SYSCALL_MAP (getgroups);
2210 SYSCALL_MAP (setgroups);
2211 SYSCALL_MAP (uname);
2212 SYSCALL_MAP (sethostname);
2213 SYSCALL_MAP (setdomainname);
2214 SYSCALL_MAP (getrlimit);
2215 SYSCALL_MAP (setrlimit);
2216 SYSCALL_MAP (getrusage);
2217 SYSCALL_MAP (umask);
2218 SYSCALL_MAP (prctl);
2219 SYSCALL_MAP (getcpu);
2220 SYSCALL_MAP (gettimeofday);
2221 SYSCALL_MAP (settimeofday);
2222 SYSCALL_MAP (adjtimex);
2223 SYSCALL_MAP (getpid);
2224 SYSCALL_MAP (getppid);
2225 SYSCALL_MAP (getuid);
2226 SYSCALL_MAP (geteuid);
2227 SYSCALL_MAP (getgid);
2228 SYSCALL_MAP (getegid);
2229 SYSCALL_MAP (gettid);
2230 SYSCALL_MAP (sysinfo);
2231 SYSCALL_MAP (mq_open);
2232 SYSCALL_MAP (mq_unlink);
2233 SYSCALL_MAP (mq_timedsend);
2234 SYSCALL_MAP (mq_timedreceive);
2235 SYSCALL_MAP (mq_notify);
2236 SYSCALL_MAP (mq_getsetattr);
2237 SYSCALL_MAP (msgget);
2238 SYSCALL_MAP (msgctl);
2239 SYSCALL_MAP (msgrcv);
2240 SYSCALL_MAP (msgsnd);
2241 SYSCALL_MAP (semget);
2242 SYSCALL_MAP (semctl);
2243 SYSCALL_MAP (semtimedop);
2244 SYSCALL_MAP (semop);
2245 SYSCALL_MAP (shmget);
2246 SYSCALL_MAP (shmctl);
2247 SYSCALL_MAP (shmat);
2248 SYSCALL_MAP (shmdt);
2249 SYSCALL_MAP (socket);
2250 SYSCALL_MAP (socketpair);
2251 SYSCALL_MAP (bind);
2252 SYSCALL_MAP (listen);
2253 SYSCALL_MAP (accept);
2254 SYSCALL_MAP (connect);
2255 SYSCALL_MAP (getsockname);
2256 SYSCALL_MAP (getpeername);
2257 SYSCALL_MAP (sendto);
2258 SYSCALL_MAP (recvfrom);
2259 SYSCALL_MAP (setsockopt);
2260 SYSCALL_MAP (getsockopt);
2261 SYSCALL_MAP (shutdown);
2262 SYSCALL_MAP (sendmsg);
2263 SYSCALL_MAP (recvmsg);
2264 SYSCALL_MAP (readahead);
2265 SYSCALL_MAP (brk);
2266 SYSCALL_MAP (munmap);
2267 SYSCALL_MAP (mremap);
2268 SYSCALL_MAP (add_key);
2269 SYSCALL_MAP (request_key);
2270 SYSCALL_MAP (keyctl);
2271 SYSCALL_MAP (clone);
2272 SYSCALL_MAP (execve);
2274 case aarch64_sys_mmap:
2275 return gdb_sys_mmap2;
2277 SYSCALL_MAP (fadvise64);
2278 SYSCALL_MAP (swapon);
2279 SYSCALL_MAP (swapoff);
2280 SYSCALL_MAP (mprotect);
2281 SYSCALL_MAP (msync);
2282 SYSCALL_MAP (mlock);
2283 SYSCALL_MAP (munlock);
2284 SYSCALL_MAP (mlockall);
2285 SYSCALL_MAP (munlockall);
2286 SYSCALL_MAP (mincore);
2287 SYSCALL_MAP (madvise);
2288 SYSCALL_MAP (remap_file_pages);
2289 SYSCALL_MAP (mbind);
2290 SYSCALL_MAP (get_mempolicy);
2291 SYSCALL_MAP (set_mempolicy);
2292 SYSCALL_MAP (migrate_pages);
2293 SYSCALL_MAP (move_pages);
2294 UNSUPPORTED_SYSCALL_MAP (rt_tgsigqueueinfo);
2295 UNSUPPORTED_SYSCALL_MAP (perf_event_open);
2296 UNSUPPORTED_SYSCALL_MAP (accept4);
2297 UNSUPPORTED_SYSCALL_MAP (recvmmsg);
2299 SYSCALL_MAP (wait4);
2301 UNSUPPORTED_SYSCALL_MAP (prlimit64);
2302 UNSUPPORTED_SYSCALL_MAP (fanotify_init);
2303 UNSUPPORTED_SYSCALL_MAP (fanotify_mark);
2304 UNSUPPORTED_SYSCALL_MAP (name_to_handle_at);
2305 UNSUPPORTED_SYSCALL_MAP (open_by_handle_at);
2306 UNSUPPORTED_SYSCALL_MAP (clock_adjtime);
2307 UNSUPPORTED_SYSCALL_MAP (syncfs);
2308 UNSUPPORTED_SYSCALL_MAP (setns);
2309 UNSUPPORTED_SYSCALL_MAP (sendmmsg);
2310 UNSUPPORTED_SYSCALL_MAP (process_vm_readv);
2311 UNSUPPORTED_SYSCALL_MAP (process_vm_writev);
2312 UNSUPPORTED_SYSCALL_MAP (kcmp);
2313 UNSUPPORTED_SYSCALL_MAP (finit_module);
2314 UNSUPPORTED_SYSCALL_MAP (sched_setattr);
2315 UNSUPPORTED_SYSCALL_MAP (sched_getattr);
2316 SYSCALL_MAP (getrandom);
2317 default:
2318 return gdb_sys_no_syscall;
2322 /* Retrieve the syscall number at a ptrace syscall-stop, either on syscall entry
2323 or exit. Return -1 upon error. */
2325 static LONGEST
2326 aarch64_linux_get_syscall_number (struct gdbarch *gdbarch, thread_info *thread)
2328 struct regcache *regs = get_thread_regcache (thread);
2329 LONGEST ret;
2331 /* Get the system call number from register x8. */
2332 regs->cooked_read (AARCH64_X0_REGNUM + 8, &ret);
2334 /* On exit from a successful execve, we will be in a new process and all the
2335 registers will be cleared - x0 to x30 will be 0, except for a 1 in x7.
2336 This function will only ever get called when stopped at the entry or exit
2337 of a syscall, so by checking for 0 in x0 (arg0/retval), x1 (arg1), x8
2338 (syscall), x29 (FP) and x30 (LR) we can infer:
2339 1) Either inferior is at exit from successful execve.
2340 2) Or inferior is at entry to a call to io_setup with invalid arguments and
2341 a corrupted FP and LR.
2342 It should be safe enough to assume case 1. */
2343 if (ret == 0)
2345 LONGEST x1 = -1, fp = -1, lr = -1;
2346 regs->cooked_read (AARCH64_X0_REGNUM + 1, &x1);
2347 regs->cooked_read (AARCH64_FP_REGNUM, &fp);
2348 regs->cooked_read (AARCH64_LR_REGNUM, &lr);
2349 if (x1 == 0 && fp ==0 && lr == 0)
2350 return aarch64_sys_execve;
2353 return ret;
2356 /* Record all registers but PC register for process-record. */
2358 static int
2359 aarch64_all_but_pc_registers_record (struct regcache *regcache)
2361 int i;
2363 for (i = AARCH64_X0_REGNUM; i < AARCH64_PC_REGNUM; i++)
2364 if (record_full_arch_list_add_reg (regcache, i))
2365 return -1;
2367 if (record_full_arch_list_add_reg (regcache, AARCH64_CPSR_REGNUM))
2368 return -1;
2370 return 0;
2373 /* Handler for aarch64 system call instruction recording. */
2375 static int
2376 aarch64_linux_syscall_record (struct regcache *regcache,
2377 unsigned long svc_number)
2379 int ret = 0;
2380 enum gdb_syscall syscall_gdb;
2382 syscall_gdb =
2383 aarch64_canonicalize_syscall ((enum aarch64_syscall) svc_number);
2385 if (syscall_gdb < 0)
2387 gdb_printf (gdb_stderr,
2388 _("Process record and replay target doesn't "
2389 "support syscall number %s\n"),
2390 plongest (svc_number));
2391 return -1;
2394 if (syscall_gdb == gdb_sys_sigreturn
2395 || syscall_gdb == gdb_sys_rt_sigreturn)
2397 if (aarch64_all_but_pc_registers_record (regcache))
2398 return -1;
2399 return 0;
2402 ret = record_linux_system_call (syscall_gdb, regcache,
2403 &aarch64_linux_record_tdep);
2404 if (ret != 0)
2405 return ret;
2407 /* Record the return value of the system call. */
2408 if (record_full_arch_list_add_reg (regcache, AARCH64_X0_REGNUM))
2409 return -1;
2410 /* Record LR. */
2411 if (record_full_arch_list_add_reg (regcache, AARCH64_LR_REGNUM))
2412 return -1;
2413 /* Record CPSR. */
2414 if (record_full_arch_list_add_reg (regcache, AARCH64_CPSR_REGNUM))
2415 return -1;
2417 return 0;
2420 /* Implement the "gcc_target_options" gdbarch method. */
2422 static std::string
2423 aarch64_linux_gcc_target_options (struct gdbarch *gdbarch)
2425 /* GCC doesn't know "-m64". */
2426 return {};
2429 /* Helper to get the allocation tag from a 64-bit ADDRESS.
2431 Return the allocation tag if successful and nullopt otherwise. */
2433 static std::optional<CORE_ADDR>
2434 aarch64_mte_get_atag (CORE_ADDR address)
2436 gdb::byte_vector tags;
2438 /* Attempt to fetch the allocation tag. */
2439 if (!target_fetch_memtags (address, 1, tags,
2440 static_cast<int> (memtag_type::allocation)))
2441 return {};
2443 /* Only one tag should've been returned. Make sure we got exactly that. */
2444 if (tags.size () != 1)
2445 error (_("Target returned an unexpected number of tags."));
2447 /* Although our tags are 4 bits in size, they are stored in a
2448 byte. */
2449 return tags[0];
2452 /* Implement the tagged_address_p gdbarch method. */
2454 static bool
2455 aarch64_linux_tagged_address_p (struct gdbarch *gdbarch, CORE_ADDR address)
2457 /* Remove the top byte for the memory range check. */
2458 address = gdbarch_remove_non_address_bits (gdbarch, address);
2460 /* Check if the page that contains ADDRESS is mapped with PROT_MTE. */
2461 if (!linux_address_in_memtag_page (address))
2462 return false;
2464 /* We have a valid tag in the top byte of the 64-bit address. */
2465 return true;
2468 /* Implement the memtag_matches_p gdbarch method. */
2470 static bool
2471 aarch64_linux_memtag_matches_p (struct gdbarch *gdbarch,
2472 struct value *address)
2474 gdb_assert (address != nullptr);
2476 CORE_ADDR addr = value_as_address (address);
2478 /* Fetch the allocation tag for ADDRESS. */
2479 std::optional<CORE_ADDR> atag
2480 = aarch64_mte_get_atag (gdbarch_remove_non_address_bits (gdbarch, addr));
2482 if (!atag.has_value ())
2483 return true;
2485 /* Fetch the logical tag for ADDRESS. */
2486 gdb_byte ltag = aarch64_mte_get_ltag (addr);
2488 /* Are the tags the same? */
2489 return ltag == *atag;
2492 /* Implement the set_memtags gdbarch method. */
2494 static bool
2495 aarch64_linux_set_memtags (struct gdbarch *gdbarch, struct value *address,
2496 size_t length, const gdb::byte_vector &tags,
2497 memtag_type tag_type)
2499 gdb_assert (!tags.empty ());
2500 gdb_assert (address != nullptr);
2502 CORE_ADDR addr = value_as_address (address);
2504 /* Set the logical tag or the allocation tag. */
2505 if (tag_type == memtag_type::logical)
2507 /* When setting logical tags, we don't care about the length, since
2508 we are only setting a single logical tag. */
2509 addr = aarch64_mte_set_ltag (addr, tags[0]);
2511 /* Update the value's content with the tag. */
2512 enum bfd_endian byte_order = gdbarch_byte_order (gdbarch);
2513 gdb_byte *srcbuf = address->contents_raw ().data ();
2514 store_unsigned_integer (srcbuf, sizeof (addr), byte_order, addr);
2516 else
2518 /* Remove the top byte. */
2519 addr = gdbarch_remove_non_address_bits (gdbarch, addr);
2521 /* With G being the number of tag granules and N the number of tags
2522 passed in, we can have the following cases:
2524 1 - G == N: Store all the N tags to memory.
2526 2 - G < N : Warn about having more tags than granules, but write G
2527 tags.
2529 3 - G > N : This is a "fill tags" operation. We should use the tags
2530 as a pattern to fill the granules repeatedly until we have
2531 written G tags to memory.
2534 size_t g = aarch64_mte_get_tag_granules (addr, length,
2535 AARCH64_MTE_GRANULE_SIZE);
2536 size_t n = tags.size ();
2538 if (g < n)
2539 warning (_("Got more tags than memory granules. Tags will be "
2540 "truncated."));
2541 else if (g > n)
2542 warning (_("Using tag pattern to fill memory range."));
2544 if (!target_store_memtags (addr, length, tags,
2545 static_cast<int> (memtag_type::allocation)))
2546 return false;
2548 return true;
2551 /* Implement the get_memtag gdbarch method. */
2553 static struct value *
2554 aarch64_linux_get_memtag (struct gdbarch *gdbarch, struct value *address,
2555 memtag_type tag_type)
2557 gdb_assert (address != nullptr);
2559 CORE_ADDR addr = value_as_address (address);
2560 CORE_ADDR tag = 0;
2562 /* Get the logical tag or the allocation tag. */
2563 if (tag_type == memtag_type::logical)
2564 tag = aarch64_mte_get_ltag (addr);
2565 else
2567 /* Remove the top byte. */
2568 addr = gdbarch_remove_non_address_bits (gdbarch, addr);
2569 std::optional<CORE_ADDR> atag = aarch64_mte_get_atag (addr);
2571 if (!atag.has_value ())
2572 return nullptr;
2574 tag = *atag;
2577 /* Convert the tag to a value. */
2578 return value_from_ulongest (builtin_type (gdbarch)->builtin_unsigned_int,
2579 tag);
2582 /* Implement the memtag_to_string gdbarch method. */
2584 static std::string
2585 aarch64_linux_memtag_to_string (struct gdbarch *gdbarch, struct value *tag_value)
2587 if (tag_value == nullptr)
2588 return "";
2590 CORE_ADDR tag = value_as_address (tag_value);
2592 return string_printf ("0x%s", phex_nz (tag, sizeof (tag)));
2595 /* AArch64 Linux implementation of the report_signal_info gdbarch
2596 hook. Displays information about possible memory tag violations. */
2598 static void
2599 aarch64_linux_report_signal_info (struct gdbarch *gdbarch,
2600 struct ui_out *uiout,
2601 enum gdb_signal siggnal)
2603 aarch64_gdbarch_tdep *tdep = gdbarch_tdep<aarch64_gdbarch_tdep> (gdbarch);
2605 if (!tdep->has_mte () || siggnal != GDB_SIGNAL_SEGV)
2606 return;
2608 CORE_ADDR fault_addr = 0;
2609 long si_code = 0;
2613 /* Sigcode tells us if the segfault is actually a memory tag
2614 violation. */
2615 si_code = parse_and_eval_long ("$_siginfo.si_code");
2617 fault_addr
2618 = parse_and_eval_long ("$_siginfo._sifields._sigfault.si_addr");
2620 catch (const gdb_exception_error &exception)
2622 exception_print (gdb_stderr, exception);
2623 return;
2626 /* If this is not a memory tag violation, just return. */
2627 if (si_code != SEGV_MTEAERR && si_code != SEGV_MTESERR)
2628 return;
2630 uiout->text ("\n");
2632 uiout->field_string ("sigcode-meaning", _("Memory tag violation"));
2634 /* For synchronous faults, show additional information. */
2635 if (si_code == SEGV_MTESERR)
2637 uiout->text (_(" while accessing address "));
2638 uiout->field_core_addr ("fault-addr", gdbarch, fault_addr);
2639 uiout->text ("\n");
2641 std::optional<CORE_ADDR> atag
2642 = aarch64_mte_get_atag (gdbarch_remove_non_address_bits (gdbarch,
2643 fault_addr));
2644 gdb_byte ltag = aarch64_mte_get_ltag (fault_addr);
2646 if (!atag.has_value ())
2647 uiout->text (_("Allocation tag unavailable"));
2648 else
2650 uiout->text (_("Allocation tag "));
2651 uiout->field_string ("allocation-tag", hex_string (*atag));
2652 uiout->text ("\n");
2653 uiout->text (_("Logical tag "));
2654 uiout->field_string ("logical-tag", hex_string (ltag));
2657 else
2659 uiout->text ("\n");
2660 uiout->text (_("Fault address unavailable"));
2664 /* AArch64 Linux implementation of the gdbarch_create_memtag_section hook. */
2666 static asection *
2667 aarch64_linux_create_memtag_section (struct gdbarch *gdbarch, bfd *obfd,
2668 CORE_ADDR address, size_t size)
2670 gdb_assert (obfd != nullptr);
2671 gdb_assert (size > 0);
2673 /* Create the section and associated program header.
2675 Make sure the section's flags has SEC_HAS_CONTENTS, otherwise BFD will
2676 refuse to write data to this section. */
2677 asection *mte_section
2678 = bfd_make_section_anyway_with_flags (obfd, "memtag", SEC_HAS_CONTENTS);
2680 if (mte_section == nullptr)
2681 return nullptr;
2683 bfd_set_section_vma (mte_section, address);
2684 /* The size of the memory range covered by the memory tags. We reuse the
2685 section's rawsize field for this purpose. */
2686 mte_section->rawsize = size;
2688 /* Fetch the number of tags we need to save. */
2689 size_t tags_count
2690 = aarch64_mte_get_tag_granules (address, size, AARCH64_MTE_GRANULE_SIZE);
2691 /* Tags are stored packed as 2 tags per byte. */
2692 bfd_set_section_size (mte_section, (tags_count + 1) >> 1);
2693 /* Store program header information. */
2694 bfd_record_phdr (obfd, PT_AARCH64_MEMTAG_MTE, 1, 0, 0, 0, 0, 0, 1,
2695 &mte_section);
2697 return mte_section;
2700 /* Maximum number of tags to request. */
2701 #define MAX_TAGS_TO_TRANSFER 1024
2703 /* AArch64 Linux implementation of the gdbarch_fill_memtag_section hook. */
2705 static bool
2706 aarch64_linux_fill_memtag_section (struct gdbarch *gdbarch, asection *osec)
2708 /* We only handle MTE tags for now. */
2710 size_t segment_size = osec->rawsize;
2711 CORE_ADDR start_address = bfd_section_vma (osec);
2712 CORE_ADDR end_address = start_address + segment_size;
2714 /* Figure out how many tags we need to store in this memory range. */
2715 size_t granules = aarch64_mte_get_tag_granules (start_address, segment_size,
2716 AARCH64_MTE_GRANULE_SIZE);
2718 /* If there are no tag granules to fetch, just return. */
2719 if (granules == 0)
2720 return true;
2722 CORE_ADDR address = start_address;
2724 /* Vector of tags. */
2725 gdb::byte_vector tags;
2727 while (granules > 0)
2729 /* Transfer tags in chunks. */
2730 gdb::byte_vector tags_read;
2731 size_t xfer_len
2732 = ((granules >= MAX_TAGS_TO_TRANSFER)
2733 ? MAX_TAGS_TO_TRANSFER * AARCH64_MTE_GRANULE_SIZE
2734 : granules * AARCH64_MTE_GRANULE_SIZE);
2736 if (!target_fetch_memtags (address, xfer_len, tags_read,
2737 static_cast<int> (memtag_type::allocation)))
2739 warning (_("Failed to read MTE tags from memory range [%s,%s)."),
2740 phex_nz (start_address, sizeof (start_address)),
2741 phex_nz (end_address, sizeof (end_address)));
2742 return false;
2745 /* Transfer over the tags that have been read. */
2746 tags.insert (tags.end (), tags_read.begin (), tags_read.end ());
2748 /* Adjust the remaining granules and starting address. */
2749 granules -= tags_read.size ();
2750 address += tags_read.size () * AARCH64_MTE_GRANULE_SIZE;
2753 /* Pack the MTE tag bits. */
2754 aarch64_mte_pack_tags (tags);
2756 if (!bfd_set_section_contents (osec->owner, osec, tags.data (),
2757 0, tags.size ()))
2759 warning (_("Failed to write %s bytes of corefile memory "
2760 "tag content (%s)."),
2761 pulongest (tags.size ()),
2762 bfd_errmsg (bfd_get_error ()));
2764 return true;
2767 /* AArch64 Linux implementation of the gdbarch_decode_memtag_section
2768 hook. Decode a memory tag section and return the requested tags.
2770 The section is guaranteed to cover the [ADDRESS, ADDRESS + length)
2771 range. */
2773 static gdb::byte_vector
2774 aarch64_linux_decode_memtag_section (struct gdbarch *gdbarch,
2775 bfd_section *section,
2776 int type,
2777 CORE_ADDR address, size_t length)
2779 gdb_assert (section != nullptr);
2781 /* The requested address must not be less than section->vma. */
2782 gdb_assert (section->vma <= address);
2784 /* Figure out how many tags we need to fetch in this memory range. */
2785 size_t granules = aarch64_mte_get_tag_granules (address, length,
2786 AARCH64_MTE_GRANULE_SIZE);
2787 /* Sanity check. */
2788 gdb_assert (granules > 0);
2790 /* Fetch the total number of tags in the range [VMA, address + length). */
2791 size_t granules_from_vma
2792 = aarch64_mte_get_tag_granules (section->vma,
2793 address - section->vma + length,
2794 AARCH64_MTE_GRANULE_SIZE);
2796 /* Adjust the tags vector to contain the exact number of packed bytes. */
2797 gdb::byte_vector tags (((granules - 1) >> 1) + 1);
2799 /* Figure out the starting offset into the packed tags data. */
2800 file_ptr offset = ((granules_from_vma - granules) >> 1);
2802 if (!bfd_get_section_contents (section->owner, section, tags.data (),
2803 offset, tags.size ()))
2804 error (_("Couldn't read contents from memtag section."));
2806 /* At this point, the tags are packed 2 per byte. Unpack them before
2807 returning. */
2808 bool skip_first = ((granules_from_vma - granules) % 2) != 0;
2809 aarch64_mte_unpack_tags (tags, skip_first);
2811 /* Resize to the exact number of tags that was requested. */
2812 tags.resize (granules);
2814 return tags;
2817 /* AArch64 Linux implementation of the
2818 gdbarch_use_target_description_from_corefile_notes hook. */
2820 static bool
2821 aarch64_use_target_description_from_corefile_notes (gdbarch *gdbarch,
2822 bfd *obfd)
2824 /* Sanity check. */
2825 gdb_assert (obfd != nullptr);
2827 /* If the corefile contains any SVE or SME register data, we don't want to
2828 use the target description note, as it may be incorrect.
2830 Currently the target description note contains a potentially incorrect
2831 target description if the originating program changed the SVE or SME
2832 vector lengths mid-execution.
2834 Once we support per-thread target description notes in the corefiles, we
2835 can always trust those notes whenever they are available. */
2836 if (bfd_get_section_by_name (obfd, ".reg-aarch-sve") != nullptr
2837 || bfd_get_section_by_name (obfd, ".reg-aarch-za") != nullptr
2838 || bfd_get_section_by_name (obfd, ".reg-aarch-zt") != nullptr)
2839 return false;
2841 return true;
2844 static void
2845 aarch64_linux_init_abi (struct gdbarch_info info, struct gdbarch *gdbarch)
2847 static const char *const stap_integer_prefixes[] = { "#", "", NULL };
2848 static const char *const stap_register_prefixes[] = { "", NULL };
2849 static const char *const stap_register_indirection_prefixes[] = { "[",
2850 NULL };
2851 static const char *const stap_register_indirection_suffixes[] = { "]",
2852 NULL };
2853 aarch64_gdbarch_tdep *tdep = gdbarch_tdep<aarch64_gdbarch_tdep> (gdbarch);
2855 tdep->lowest_pc = 0x8000;
2857 linux_init_abi (info, gdbarch, 1);
2859 set_solib_svr4_fetch_link_map_offsets (gdbarch,
2860 linux_lp64_fetch_link_map_offsets);
2862 /* Enable TLS support. */
2863 set_gdbarch_fetch_tls_load_module_address (gdbarch,
2864 svr4_fetch_objfile_link_map);
2866 /* Shared library handling. */
2867 set_gdbarch_skip_trampoline_code (gdbarch, find_solib_trampoline_target);
2868 set_gdbarch_skip_solib_resolver (gdbarch, glibc_skip_solib_resolver);
2870 tramp_frame_prepend_unwinder (gdbarch, &aarch64_linux_rt_sigframe);
2872 /* Enable longjmp. */
2873 tdep->jb_pc = 11;
2875 set_gdbarch_iterate_over_regset_sections
2876 (gdbarch, aarch64_linux_iterate_over_regset_sections);
2877 set_gdbarch_core_read_description
2878 (gdbarch, aarch64_linux_core_read_description);
2880 /* SystemTap related. */
2881 set_gdbarch_stap_integer_prefixes (gdbarch, stap_integer_prefixes);
2882 set_gdbarch_stap_register_prefixes (gdbarch, stap_register_prefixes);
2883 set_gdbarch_stap_register_indirection_prefixes (gdbarch,
2884 stap_register_indirection_prefixes);
2885 set_gdbarch_stap_register_indirection_suffixes (gdbarch,
2886 stap_register_indirection_suffixes);
2887 set_gdbarch_stap_is_single_operand (gdbarch, aarch64_stap_is_single_operand);
2888 set_gdbarch_stap_parse_special_token (gdbarch,
2889 aarch64_stap_parse_special_token);
2891 /* Reversible debugging, process record. */
2892 set_gdbarch_process_record (gdbarch, aarch64_process_record);
2893 /* Syscall record. */
2894 tdep->aarch64_syscall_record = aarch64_linux_syscall_record;
2896 /* MTE-specific settings and hooks. */
2897 if (tdep->has_mte ())
2899 /* Register a hook for checking if an address is tagged or not. */
2900 set_gdbarch_tagged_address_p (gdbarch, aarch64_linux_tagged_address_p);
2902 /* Register a hook for checking if there is a memory tag match. */
2903 set_gdbarch_memtag_matches_p (gdbarch,
2904 aarch64_linux_memtag_matches_p);
2906 /* Register a hook for setting the logical/allocation tags for
2907 a range of addresses. */
2908 set_gdbarch_set_memtags (gdbarch, aarch64_linux_set_memtags);
2910 /* Register a hook for extracting the logical/allocation tag from an
2911 address. */
2912 set_gdbarch_get_memtag (gdbarch, aarch64_linux_get_memtag);
2914 /* Set the allocation tag granule size to 16 bytes. */
2915 set_gdbarch_memtag_granule_size (gdbarch, AARCH64_MTE_GRANULE_SIZE);
2917 /* Register a hook for converting a memory tag to a string. */
2918 set_gdbarch_memtag_to_string (gdbarch, aarch64_linux_memtag_to_string);
2920 set_gdbarch_report_signal_info (gdbarch,
2921 aarch64_linux_report_signal_info);
2923 /* Core file helpers. */
2925 /* Core file helper to create a memory tag section for a particular
2926 PT_LOAD segment. */
2927 set_gdbarch_create_memtag_section
2928 (gdbarch, aarch64_linux_create_memtag_section);
2930 /* Core file helper to fill a memory tag section with tag data. */
2931 set_gdbarch_fill_memtag_section
2932 (gdbarch, aarch64_linux_fill_memtag_section);
2934 /* Core file helper to decode a memory tag section. */
2935 set_gdbarch_decode_memtag_section (gdbarch,
2936 aarch64_linux_decode_memtag_section);
2939 /* Initialize the aarch64_linux_record_tdep. */
2940 /* These values are the size of the type that will be used in a system
2941 call. They are obtained from Linux Kernel source. */
2942 aarch64_linux_record_tdep.size_pointer
2943 = gdbarch_ptr_bit (gdbarch) / TARGET_CHAR_BIT;
2944 aarch64_linux_record_tdep.size__old_kernel_stat = 32;
2945 aarch64_linux_record_tdep.size_tms = 32;
2946 aarch64_linux_record_tdep.size_loff_t = 8;
2947 aarch64_linux_record_tdep.size_flock = 32;
2948 aarch64_linux_record_tdep.size_oldold_utsname = 45;
2949 aarch64_linux_record_tdep.size_ustat = 32;
2950 aarch64_linux_record_tdep.size_old_sigaction = 32;
2951 aarch64_linux_record_tdep.size_old_sigset_t = 8;
2952 aarch64_linux_record_tdep.size_rlimit = 16;
2953 aarch64_linux_record_tdep.size_rusage = 144;
2954 aarch64_linux_record_tdep.size_timeval = 16;
2955 aarch64_linux_record_tdep.size_timezone = 8;
2956 aarch64_linux_record_tdep.size_old_gid_t = 2;
2957 aarch64_linux_record_tdep.size_old_uid_t = 2;
2958 aarch64_linux_record_tdep.size_fd_set = 128;
2959 aarch64_linux_record_tdep.size_old_dirent = 280;
2960 aarch64_linux_record_tdep.size_statfs = 120;
2961 aarch64_linux_record_tdep.size_statfs64 = 120;
2962 aarch64_linux_record_tdep.size_sockaddr = 16;
2963 aarch64_linux_record_tdep.size_int
2964 = gdbarch_int_bit (gdbarch) / TARGET_CHAR_BIT;
2965 aarch64_linux_record_tdep.size_long
2966 = gdbarch_long_bit (gdbarch) / TARGET_CHAR_BIT;
2967 aarch64_linux_record_tdep.size_ulong
2968 = gdbarch_long_bit (gdbarch) / TARGET_CHAR_BIT;
2969 aarch64_linux_record_tdep.size_msghdr = 56;
2970 aarch64_linux_record_tdep.size_itimerval = 32;
2971 aarch64_linux_record_tdep.size_stat = 144;
2972 aarch64_linux_record_tdep.size_old_utsname = 325;
2973 aarch64_linux_record_tdep.size_sysinfo = 112;
2974 aarch64_linux_record_tdep.size_msqid_ds = 120;
2975 aarch64_linux_record_tdep.size_shmid_ds = 112;
2976 aarch64_linux_record_tdep.size_new_utsname = 390;
2977 aarch64_linux_record_tdep.size_timex = 208;
2978 aarch64_linux_record_tdep.size_mem_dqinfo = 24;
2979 aarch64_linux_record_tdep.size_if_dqblk = 72;
2980 aarch64_linux_record_tdep.size_fs_quota_stat = 80;
2981 aarch64_linux_record_tdep.size_timespec = 16;
2982 aarch64_linux_record_tdep.size_pollfd = 8;
2983 aarch64_linux_record_tdep.size_NFS_FHSIZE = 32;
2984 aarch64_linux_record_tdep.size_knfsd_fh = 132;
2985 aarch64_linux_record_tdep.size_TASK_COMM_LEN = 16;
2986 aarch64_linux_record_tdep.size_sigaction = 32;
2987 aarch64_linux_record_tdep.size_sigset_t = 8;
2988 aarch64_linux_record_tdep.size_siginfo_t = 128;
2989 aarch64_linux_record_tdep.size_cap_user_data_t = 8;
2990 aarch64_linux_record_tdep.size_stack_t = 24;
2991 aarch64_linux_record_tdep.size_off_t = 8;
2992 aarch64_linux_record_tdep.size_stat64 = 144;
2993 aarch64_linux_record_tdep.size_gid_t = 4;
2994 aarch64_linux_record_tdep.size_uid_t = 4;
2995 aarch64_linux_record_tdep.size_PAGE_SIZE = 4096;
2996 aarch64_linux_record_tdep.size_flock64 = 32;
2997 aarch64_linux_record_tdep.size_user_desc = 16;
2998 aarch64_linux_record_tdep.size_io_event = 32;
2999 aarch64_linux_record_tdep.size_iocb = 64;
3000 aarch64_linux_record_tdep.size_epoll_event = 12;
3001 aarch64_linux_record_tdep.size_itimerspec = 32;
3002 aarch64_linux_record_tdep.size_mq_attr = 64;
3003 aarch64_linux_record_tdep.size_termios = 36;
3004 aarch64_linux_record_tdep.size_termios2 = 44;
3005 aarch64_linux_record_tdep.size_pid_t = 4;
3006 aarch64_linux_record_tdep.size_winsize = 8;
3007 aarch64_linux_record_tdep.size_serial_struct = 72;
3008 aarch64_linux_record_tdep.size_serial_icounter_struct = 80;
3009 aarch64_linux_record_tdep.size_hayes_esp_config = 12;
3010 aarch64_linux_record_tdep.size_size_t = 8;
3011 aarch64_linux_record_tdep.size_iovec = 16;
3012 aarch64_linux_record_tdep.size_time_t = 8;
3014 /* These values are the second argument of system call "sys_ioctl".
3015 They are obtained from Linux Kernel source. */
3016 aarch64_linux_record_tdep.ioctl_TCGETS = 0x5401;
3017 aarch64_linux_record_tdep.ioctl_TCSETS = 0x5402;
3018 aarch64_linux_record_tdep.ioctl_TCSETSW = 0x5403;
3019 aarch64_linux_record_tdep.ioctl_TCSETSF = 0x5404;
3020 aarch64_linux_record_tdep.ioctl_TCGETA = 0x5405;
3021 aarch64_linux_record_tdep.ioctl_TCSETA = 0x5406;
3022 aarch64_linux_record_tdep.ioctl_TCSETAW = 0x5407;
3023 aarch64_linux_record_tdep.ioctl_TCSETAF = 0x5408;
3024 aarch64_linux_record_tdep.ioctl_TCSBRK = 0x5409;
3025 aarch64_linux_record_tdep.ioctl_TCXONC = 0x540a;
3026 aarch64_linux_record_tdep.ioctl_TCFLSH = 0x540b;
3027 aarch64_linux_record_tdep.ioctl_TIOCEXCL = 0x540c;
3028 aarch64_linux_record_tdep.ioctl_TIOCNXCL = 0x540d;
3029 aarch64_linux_record_tdep.ioctl_TIOCSCTTY = 0x540e;
3030 aarch64_linux_record_tdep.ioctl_TIOCGPGRP = 0x540f;
3031 aarch64_linux_record_tdep.ioctl_TIOCSPGRP = 0x5410;
3032 aarch64_linux_record_tdep.ioctl_TIOCOUTQ = 0x5411;
3033 aarch64_linux_record_tdep.ioctl_TIOCSTI = 0x5412;
3034 aarch64_linux_record_tdep.ioctl_TIOCGWINSZ = 0x5413;
3035 aarch64_linux_record_tdep.ioctl_TIOCSWINSZ = 0x5414;
3036 aarch64_linux_record_tdep.ioctl_TIOCMGET = 0x5415;
3037 aarch64_linux_record_tdep.ioctl_TIOCMBIS = 0x5416;
3038 aarch64_linux_record_tdep.ioctl_TIOCMBIC = 0x5417;
3039 aarch64_linux_record_tdep.ioctl_TIOCMSET = 0x5418;
3040 aarch64_linux_record_tdep.ioctl_TIOCGSOFTCAR = 0x5419;
3041 aarch64_linux_record_tdep.ioctl_TIOCSSOFTCAR = 0x541a;
3042 aarch64_linux_record_tdep.ioctl_FIONREAD = 0x541b;
3043 aarch64_linux_record_tdep.ioctl_TIOCINQ = 0x541b;
3044 aarch64_linux_record_tdep.ioctl_TIOCLINUX = 0x541c;
3045 aarch64_linux_record_tdep.ioctl_TIOCCONS = 0x541d;
3046 aarch64_linux_record_tdep.ioctl_TIOCGSERIAL = 0x541e;
3047 aarch64_linux_record_tdep.ioctl_TIOCSSERIAL = 0x541f;
3048 aarch64_linux_record_tdep.ioctl_TIOCPKT = 0x5420;
3049 aarch64_linux_record_tdep.ioctl_FIONBIO = 0x5421;
3050 aarch64_linux_record_tdep.ioctl_TIOCNOTTY = 0x5422;
3051 aarch64_linux_record_tdep.ioctl_TIOCSETD = 0x5423;
3052 aarch64_linux_record_tdep.ioctl_TIOCGETD = 0x5424;
3053 aarch64_linux_record_tdep.ioctl_TCSBRKP = 0x5425;
3054 aarch64_linux_record_tdep.ioctl_TIOCTTYGSTRUCT = 0x5426;
3055 aarch64_linux_record_tdep.ioctl_TIOCSBRK = 0x5427;
3056 aarch64_linux_record_tdep.ioctl_TIOCCBRK = 0x5428;
3057 aarch64_linux_record_tdep.ioctl_TIOCGSID = 0x5429;
3058 aarch64_linux_record_tdep.ioctl_TCGETS2 = 0x802c542a;
3059 aarch64_linux_record_tdep.ioctl_TCSETS2 = 0x402c542b;
3060 aarch64_linux_record_tdep.ioctl_TCSETSW2 = 0x402c542c;
3061 aarch64_linux_record_tdep.ioctl_TCSETSF2 = 0x402c542d;
3062 aarch64_linux_record_tdep.ioctl_TIOCGPTN = 0x80045430;
3063 aarch64_linux_record_tdep.ioctl_TIOCSPTLCK = 0x40045431;
3064 aarch64_linux_record_tdep.ioctl_FIONCLEX = 0x5450;
3065 aarch64_linux_record_tdep.ioctl_FIOCLEX = 0x5451;
3066 aarch64_linux_record_tdep.ioctl_FIOASYNC = 0x5452;
3067 aarch64_linux_record_tdep.ioctl_TIOCSERCONFIG = 0x5453;
3068 aarch64_linux_record_tdep.ioctl_TIOCSERGWILD = 0x5454;
3069 aarch64_linux_record_tdep.ioctl_TIOCSERSWILD = 0x5455;
3070 aarch64_linux_record_tdep.ioctl_TIOCGLCKTRMIOS = 0x5456;
3071 aarch64_linux_record_tdep.ioctl_TIOCSLCKTRMIOS = 0x5457;
3072 aarch64_linux_record_tdep.ioctl_TIOCSERGSTRUCT = 0x5458;
3073 aarch64_linux_record_tdep.ioctl_TIOCSERGETLSR = 0x5459;
3074 aarch64_linux_record_tdep.ioctl_TIOCSERGETMULTI = 0x545a;
3075 aarch64_linux_record_tdep.ioctl_TIOCSERSETMULTI = 0x545b;
3076 aarch64_linux_record_tdep.ioctl_TIOCMIWAIT = 0x545c;
3077 aarch64_linux_record_tdep.ioctl_TIOCGICOUNT = 0x545d;
3078 aarch64_linux_record_tdep.ioctl_TIOCGHAYESESP = 0x545e;
3079 aarch64_linux_record_tdep.ioctl_TIOCSHAYESESP = 0x545f;
3080 aarch64_linux_record_tdep.ioctl_FIOQSIZE = 0x5460;
3082 /* These values are the second argument of system call "sys_fcntl"
3083 and "sys_fcntl64". They are obtained from Linux Kernel source. */
3084 aarch64_linux_record_tdep.fcntl_F_GETLK = 5;
3085 aarch64_linux_record_tdep.fcntl_F_GETLK64 = 12;
3086 aarch64_linux_record_tdep.fcntl_F_SETLK64 = 13;
3087 aarch64_linux_record_tdep.fcntl_F_SETLKW64 = 14;
3089 /* The AArch64 syscall calling convention: reg x0-x6 for arguments,
3090 reg x8 for syscall number and return value in reg x0. */
3091 aarch64_linux_record_tdep.arg1 = AARCH64_X0_REGNUM + 0;
3092 aarch64_linux_record_tdep.arg2 = AARCH64_X0_REGNUM + 1;
3093 aarch64_linux_record_tdep.arg3 = AARCH64_X0_REGNUM + 2;
3094 aarch64_linux_record_tdep.arg4 = AARCH64_X0_REGNUM + 3;
3095 aarch64_linux_record_tdep.arg5 = AARCH64_X0_REGNUM + 4;
3096 aarch64_linux_record_tdep.arg6 = AARCH64_X0_REGNUM + 5;
3097 aarch64_linux_record_tdep.arg7 = AARCH64_X0_REGNUM + 6;
3099 /* `catch syscall' */
3100 set_xml_syscall_file_name (gdbarch, "syscalls/aarch64-linux.xml");
3101 set_gdbarch_get_syscall_number (gdbarch, aarch64_linux_get_syscall_number);
3103 /* Displaced stepping. */
3104 set_gdbarch_max_insn_length (gdbarch, 4);
3105 set_gdbarch_displaced_step_buffer_length
3106 (gdbarch, 4 * AARCH64_DISPLACED_MODIFIED_INSNS);
3107 set_gdbarch_displaced_step_copy_insn (gdbarch,
3108 aarch64_displaced_step_copy_insn);
3109 set_gdbarch_displaced_step_fixup (gdbarch, aarch64_displaced_step_fixup);
3110 set_gdbarch_displaced_step_hw_singlestep (gdbarch,
3111 aarch64_displaced_step_hw_singlestep);
3113 set_gdbarch_gcc_target_options (gdbarch, aarch64_linux_gcc_target_options);
3115 /* Hook to decide if the target description should be obtained from
3116 corefile target description note(s) or inferred from the corefile
3117 sections. */
3118 set_gdbarch_use_target_description_from_corefile_notes (gdbarch,
3119 aarch64_use_target_description_from_corefile_notes);
3122 #if GDB_SELF_TEST
3124 namespace selftests {
3126 /* Verify functions to read and write logical tags. */
3128 static void
3129 aarch64_linux_ltag_tests (void)
3131 /* We have 4 bits of tags, but we test writing all the bits of the top
3132 byte of address. */
3133 for (int i = 0; i < 1 << 8; i++)
3135 CORE_ADDR addr = ((CORE_ADDR) i << 56) | 0xdeadbeef;
3136 SELF_CHECK (aarch64_mte_get_ltag (addr) == (i & 0xf));
3138 addr = aarch64_mte_set_ltag (0xdeadbeef, i);
3139 SELF_CHECK (addr = ((CORE_ADDR) (i & 0xf) << 56) | 0xdeadbeef);
3143 } // namespace selftests
3144 #endif /* GDB_SELF_TEST */
3146 void _initialize_aarch64_linux_tdep ();
3147 void
3148 _initialize_aarch64_linux_tdep ()
3150 gdbarch_register_osabi (bfd_arch_aarch64, 0, GDB_OSABI_LINUX,
3151 aarch64_linux_init_abi);
3153 #if GDB_SELF_TEST
3154 selftests::register_test ("aarch64-linux-tagged-address",
3155 selftests::aarch64_linux_ltag_tests);
3156 #endif