1061da546Spatrick //===-- DNBArchImpl.cpp -----------------------------------------*- C++ -*-===//
2061da546Spatrick //
3061da546Spatrick // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
4061da546Spatrick // See https://llvm.org/LICENSE.txt for license information.
5061da546Spatrick // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
6061da546Spatrick //
7061da546Spatrick //===----------------------------------------------------------------------===//
8061da546Spatrick //
9061da546Spatrick // Created by Greg Clayton on 6/25/07.
10061da546Spatrick //
11061da546Spatrick //===----------------------------------------------------------------------===//
12061da546Spatrick
13061da546Spatrick #if defined(__arm__) || defined(__arm64__) || defined(__aarch64__)
14061da546Spatrick
15061da546Spatrick #include "MacOSX/arm/DNBArchImpl.h"
16061da546Spatrick #include "ARM_DWARF_Registers.h"
17061da546Spatrick #include "ARM_ehframe_Registers.h"
18061da546Spatrick #include "DNB.h"
19061da546Spatrick #include "DNBBreakpoint.h"
20061da546Spatrick #include "DNBLog.h"
21061da546Spatrick #include "DNBRegisterInfo.h"
22061da546Spatrick #include "MacOSX/MachProcess.h"
23061da546Spatrick #include "MacOSX/MachThread.h"
24061da546Spatrick
25be691f3bSpatrick #include <cinttypes>
26061da546Spatrick #include <sys/sysctl.h>
27061da546Spatrick
28061da546Spatrick // BCR address match type
29061da546Spatrick #define BCR_M_IMVA_MATCH ((uint32_t)(0u << 21))
30061da546Spatrick #define BCR_M_CONTEXT_ID_MATCH ((uint32_t)(1u << 21))
31061da546Spatrick #define BCR_M_IMVA_MISMATCH ((uint32_t)(2u << 21))
32061da546Spatrick #define BCR_M_RESERVED ((uint32_t)(3u << 21))
33061da546Spatrick
34061da546Spatrick // Link a BVR/BCR or WVR/WCR pair to another
35061da546Spatrick #define E_ENABLE_LINKING ((uint32_t)(1u << 20))
36061da546Spatrick
37061da546Spatrick // Byte Address Select
38061da546Spatrick #define BAS_IMVA_PLUS_0 ((uint32_t)(1u << 5))
39061da546Spatrick #define BAS_IMVA_PLUS_1 ((uint32_t)(1u << 6))
40061da546Spatrick #define BAS_IMVA_PLUS_2 ((uint32_t)(1u << 7))
41061da546Spatrick #define BAS_IMVA_PLUS_3 ((uint32_t)(1u << 8))
42061da546Spatrick #define BAS_IMVA_0_1 ((uint32_t)(3u << 5))
43061da546Spatrick #define BAS_IMVA_2_3 ((uint32_t)(3u << 7))
44061da546Spatrick #define BAS_IMVA_ALL ((uint32_t)(0xfu << 5))
45061da546Spatrick
46061da546Spatrick // Break only in privileged or user mode
47061da546Spatrick #define S_RSVD ((uint32_t)(0u << 1))
48061da546Spatrick #define S_PRIV ((uint32_t)(1u << 1))
49061da546Spatrick #define S_USER ((uint32_t)(2u << 1))
50061da546Spatrick #define S_PRIV_USER ((S_PRIV) | (S_USER))
51061da546Spatrick
52061da546Spatrick #define BCR_ENABLE ((uint32_t)(1u))
53061da546Spatrick #define WCR_ENABLE ((uint32_t)(1u))
54061da546Spatrick
55061da546Spatrick // Watchpoint load/store
56061da546Spatrick #define WCR_LOAD ((uint32_t)(1u << 3))
57061da546Spatrick #define WCR_STORE ((uint32_t)(1u << 4))
58061da546Spatrick
59061da546Spatrick // Definitions for the Debug Status and Control Register fields:
60061da546Spatrick // [5:2] => Method of debug entry
61061da546Spatrick //#define WATCHPOINT_OCCURRED ((uint32_t)(2u))
62061da546Spatrick // I'm seeing this, instead.
63061da546Spatrick #define WATCHPOINT_OCCURRED ((uint32_t)(10u))
64061da546Spatrick
65061da546Spatrick // 0xE120BE70
66061da546Spatrick static const uint8_t g_arm_breakpoint_opcode[] = {0x70, 0xBE, 0x20, 0xE1};
67061da546Spatrick static const uint8_t g_thumb_breakpoint_opcode[] = {0x70, 0xBE};
68061da546Spatrick
69061da546Spatrick // A watchpoint may need to be implemented using two watchpoint registers.
70061da546Spatrick // e.g. watching an 8-byte region when the device can only watch 4-bytes.
71061da546Spatrick //
72061da546Spatrick // This stores the lo->hi mappings. It's safe to initialize to all 0's
73061da546Spatrick // since hi > lo and therefore LoHi[i] cannot be 0.
74061da546Spatrick static uint32_t LoHi[16] = {0};
75061da546Spatrick
76061da546Spatrick // ARM constants used during decoding
77061da546Spatrick #define REG_RD 0
78061da546Spatrick #define LDM_REGLIST 1
79061da546Spatrick #define PC_REG 15
80061da546Spatrick #define PC_REGLIST_BIT 0x8000
81061da546Spatrick
82061da546Spatrick // ARM conditions
83061da546Spatrick #define COND_EQ 0x0
84061da546Spatrick #define COND_NE 0x1
85061da546Spatrick #define COND_CS 0x2
86061da546Spatrick #define COND_HS 0x2
87061da546Spatrick #define COND_CC 0x3
88061da546Spatrick #define COND_LO 0x3
89061da546Spatrick #define COND_MI 0x4
90061da546Spatrick #define COND_PL 0x5
91061da546Spatrick #define COND_VS 0x6
92061da546Spatrick #define COND_VC 0x7
93061da546Spatrick #define COND_HI 0x8
94061da546Spatrick #define COND_LS 0x9
95061da546Spatrick #define COND_GE 0xA
96061da546Spatrick #define COND_LT 0xB
97061da546Spatrick #define COND_GT 0xC
98061da546Spatrick #define COND_LE 0xD
99061da546Spatrick #define COND_AL 0xE
100061da546Spatrick #define COND_UNCOND 0xF
101061da546Spatrick
102061da546Spatrick #define MASK_CPSR_T (1u << 5)
103061da546Spatrick #define MASK_CPSR_J (1u << 24)
104061da546Spatrick
105061da546Spatrick #define MNEMONIC_STRING_SIZE 32
106061da546Spatrick #define OPERAND_STRING_SIZE 128
107061da546Spatrick
108be691f3bSpatrick #if !defined(__arm64__) && !defined(__aarch64__)
109061da546Spatrick // Returns true if the first 16 bit opcode of a thumb instruction indicates
110061da546Spatrick // the instruction will be a 32 bit thumb opcode
IsThumb32Opcode(uint16_t opcode)111061da546Spatrick static bool IsThumb32Opcode(uint16_t opcode) {
112061da546Spatrick if (((opcode & 0xE000) == 0xE000) && (opcode & 0x1800))
113061da546Spatrick return true;
114061da546Spatrick return false;
115061da546Spatrick }
116be691f3bSpatrick #endif
117061da546Spatrick
Initialize()118061da546Spatrick void DNBArchMachARM::Initialize() {
119061da546Spatrick DNBArchPluginInfo arch_plugin_info = {
120061da546Spatrick CPU_TYPE_ARM, DNBArchMachARM::Create, DNBArchMachARM::GetRegisterSetInfo,
121061da546Spatrick DNBArchMachARM::SoftwareBreakpointOpcode};
122061da546Spatrick
123061da546Spatrick // Register this arch plug-in with the main protocol class
124061da546Spatrick DNBArchProtocol::RegisterArchPlugin(arch_plugin_info);
125061da546Spatrick }
126061da546Spatrick
Create(MachThread * thread)127061da546Spatrick DNBArchProtocol *DNBArchMachARM::Create(MachThread *thread) {
128061da546Spatrick DNBArchMachARM *obj = new DNBArchMachARM(thread);
129061da546Spatrick return obj;
130061da546Spatrick }
131061da546Spatrick
SoftwareBreakpointOpcode(nub_size_t byte_size)132061da546Spatrick const uint8_t *DNBArchMachARM::SoftwareBreakpointOpcode(nub_size_t byte_size) {
133061da546Spatrick switch (byte_size) {
134061da546Spatrick case 2:
135061da546Spatrick return g_thumb_breakpoint_opcode;
136061da546Spatrick case 4:
137061da546Spatrick return g_arm_breakpoint_opcode;
138061da546Spatrick }
139061da546Spatrick return NULL;
140061da546Spatrick }
141061da546Spatrick
GetCPUType()142061da546Spatrick uint32_t DNBArchMachARM::GetCPUType() { return CPU_TYPE_ARM; }
143061da546Spatrick
GetPC(uint64_t failValue)144061da546Spatrick uint64_t DNBArchMachARM::GetPC(uint64_t failValue) {
145061da546Spatrick // Get program counter
146061da546Spatrick if (GetGPRState(false) == KERN_SUCCESS)
147061da546Spatrick return m_state.context.gpr.__pc;
148061da546Spatrick return failValue;
149061da546Spatrick }
150061da546Spatrick
SetPC(uint64_t value)151061da546Spatrick kern_return_t DNBArchMachARM::SetPC(uint64_t value) {
152061da546Spatrick // Get program counter
153061da546Spatrick kern_return_t err = GetGPRState(false);
154061da546Spatrick if (err == KERN_SUCCESS) {
155061da546Spatrick m_state.context.gpr.__pc = (uint32_t)value;
156061da546Spatrick err = SetGPRState();
157061da546Spatrick }
158061da546Spatrick return err == KERN_SUCCESS;
159061da546Spatrick }
160061da546Spatrick
GetSP(uint64_t failValue)161061da546Spatrick uint64_t DNBArchMachARM::GetSP(uint64_t failValue) {
162061da546Spatrick // Get stack pointer
163061da546Spatrick if (GetGPRState(false) == KERN_SUCCESS)
164061da546Spatrick return m_state.context.gpr.__sp;
165061da546Spatrick return failValue;
166061da546Spatrick }
167061da546Spatrick
GetGPRState(bool force)168061da546Spatrick kern_return_t DNBArchMachARM::GetGPRState(bool force) {
169061da546Spatrick int set = e_regSetGPR;
170061da546Spatrick // Check if we have valid cached registers
171061da546Spatrick if (!force && m_state.GetError(set, Read) == KERN_SUCCESS)
172061da546Spatrick return KERN_SUCCESS;
173061da546Spatrick
174061da546Spatrick // Read the registers from our thread
175061da546Spatrick mach_msg_type_number_t count = ARM_THREAD_STATE_COUNT;
176061da546Spatrick kern_return_t kret =
177061da546Spatrick ::thread_get_state(m_thread->MachPortNumber(), ARM_THREAD_STATE,
178061da546Spatrick (thread_state_t)&m_state.context.gpr, &count);
179061da546Spatrick uint32_t *r = &m_state.context.gpr.__r[0];
180061da546Spatrick DNBLogThreadedIf(
181061da546Spatrick LOG_THREAD, "thread_get_state(0x%4.4x, %u, &gpr, %u) => 0x%8.8x (count = "
182061da546Spatrick "%u) regs r0=%8.8x r1=%8.8x r2=%8.8x r3=%8.8x r4=%8.8x "
183061da546Spatrick "r5=%8.8x r6=%8.8x r7=%8.8x r8=%8.8x r9=%8.8x r10=%8.8x "
184061da546Spatrick "r11=%8.8x s12=%8.8x sp=%8.8x lr=%8.8x pc=%8.8x cpsr=%8.8x",
185061da546Spatrick m_thread->MachPortNumber(), ARM_THREAD_STATE, ARM_THREAD_STATE_COUNT,
186061da546Spatrick kret, count, r[0], r[1], r[2], r[3], r[4], r[5], r[6], r[7], r[8], r[9],
187061da546Spatrick r[10], r[11], r[12], r[13], r[14], r[15], r[16]);
188061da546Spatrick m_state.SetError(set, Read, kret);
189061da546Spatrick return kret;
190061da546Spatrick }
191061da546Spatrick
GetVFPState(bool force)192061da546Spatrick kern_return_t DNBArchMachARM::GetVFPState(bool force) {
193061da546Spatrick int set = e_regSetVFP;
194061da546Spatrick // Check if we have valid cached registers
195061da546Spatrick if (!force && m_state.GetError(set, Read) == KERN_SUCCESS)
196061da546Spatrick return KERN_SUCCESS;
197061da546Spatrick
198061da546Spatrick kern_return_t kret;
199061da546Spatrick
200061da546Spatrick #if defined(__arm64__) || defined(__aarch64__)
201061da546Spatrick // Read the registers from our thread
202061da546Spatrick mach_msg_type_number_t count = ARM_NEON_STATE_COUNT;
203061da546Spatrick kret = ::thread_get_state(m_thread->MachPortNumber(), ARM_NEON_STATE,
204061da546Spatrick (thread_state_t)&m_state.context.vfp, &count);
205061da546Spatrick if (DNBLogEnabledForAny(LOG_THREAD)) {
206061da546Spatrick DNBLogThreaded(
207061da546Spatrick "thread_get_state(0x%4.4x, %u, &vfp, %u) => 0x%8.8x (count = %u) regs"
208061da546Spatrick "\n q0 = 0x%16.16llx%16.16llx"
209061da546Spatrick "\n q1 = 0x%16.16llx%16.16llx"
210061da546Spatrick "\n q2 = 0x%16.16llx%16.16llx"
211061da546Spatrick "\n q3 = 0x%16.16llx%16.16llx"
212061da546Spatrick "\n q4 = 0x%16.16llx%16.16llx"
213061da546Spatrick "\n q5 = 0x%16.16llx%16.16llx"
214061da546Spatrick "\n q6 = 0x%16.16llx%16.16llx"
215061da546Spatrick "\n q7 = 0x%16.16llx%16.16llx"
216061da546Spatrick "\n q8 = 0x%16.16llx%16.16llx"
217061da546Spatrick "\n q9 = 0x%16.16llx%16.16llx"
218061da546Spatrick "\n q10 = 0x%16.16llx%16.16llx"
219061da546Spatrick "\n q11 = 0x%16.16llx%16.16llx"
220061da546Spatrick "\n q12 = 0x%16.16llx%16.16llx"
221061da546Spatrick "\n q13 = 0x%16.16llx%16.16llx"
222061da546Spatrick "\n q14 = 0x%16.16llx%16.16llx"
223061da546Spatrick "\n q15 = 0x%16.16llx%16.16llx"
224061da546Spatrick "\n fpsr = 0x%8.8x"
225061da546Spatrick "\n fpcr = 0x%8.8x\n\n",
226061da546Spatrick m_thread->MachPortNumber(), ARM_NEON_STATE, ARM_NEON_STATE_COUNT, kret,
227061da546Spatrick count, ((uint64_t *)&m_state.context.vfp.__v[0])[0],
228061da546Spatrick ((uint64_t *)&m_state.context.vfp.__v[0])[1],
229061da546Spatrick ((uint64_t *)&m_state.context.vfp.__v[1])[0],
230061da546Spatrick ((uint64_t *)&m_state.context.vfp.__v[1])[1],
231061da546Spatrick ((uint64_t *)&m_state.context.vfp.__v[2])[0],
232061da546Spatrick ((uint64_t *)&m_state.context.vfp.__v[2])[1],
233061da546Spatrick ((uint64_t *)&m_state.context.vfp.__v[3])[0],
234061da546Spatrick ((uint64_t *)&m_state.context.vfp.__v[3])[1],
235061da546Spatrick ((uint64_t *)&m_state.context.vfp.__v[4])[0],
236061da546Spatrick ((uint64_t *)&m_state.context.vfp.__v[4])[1],
237061da546Spatrick ((uint64_t *)&m_state.context.vfp.__v[5])[0],
238061da546Spatrick ((uint64_t *)&m_state.context.vfp.__v[5])[1],
239061da546Spatrick ((uint64_t *)&m_state.context.vfp.__v[6])[0],
240061da546Spatrick ((uint64_t *)&m_state.context.vfp.__v[6])[1],
241061da546Spatrick ((uint64_t *)&m_state.context.vfp.__v[7])[0],
242061da546Spatrick ((uint64_t *)&m_state.context.vfp.__v[7])[1],
243061da546Spatrick ((uint64_t *)&m_state.context.vfp.__v[8])[0],
244061da546Spatrick ((uint64_t *)&m_state.context.vfp.__v[8])[1],
245061da546Spatrick ((uint64_t *)&m_state.context.vfp.__v[9])[0],
246061da546Spatrick ((uint64_t *)&m_state.context.vfp.__v[9])[1],
247061da546Spatrick ((uint64_t *)&m_state.context.vfp.__v[10])[0],
248061da546Spatrick ((uint64_t *)&m_state.context.vfp.__v[10])[1],
249061da546Spatrick ((uint64_t *)&m_state.context.vfp.__v[11])[0],
250061da546Spatrick ((uint64_t *)&m_state.context.vfp.__v[11])[1],
251061da546Spatrick ((uint64_t *)&m_state.context.vfp.__v[12])[0],
252061da546Spatrick ((uint64_t *)&m_state.context.vfp.__v[12])[1],
253061da546Spatrick ((uint64_t *)&m_state.context.vfp.__v[13])[0],
254061da546Spatrick ((uint64_t *)&m_state.context.vfp.__v[13])[1],
255061da546Spatrick ((uint64_t *)&m_state.context.vfp.__v[14])[0],
256061da546Spatrick ((uint64_t *)&m_state.context.vfp.__v[14])[1],
257061da546Spatrick ((uint64_t *)&m_state.context.vfp.__v[15])[0],
258061da546Spatrick ((uint64_t *)&m_state.context.vfp.__v[15])[1],
259061da546Spatrick m_state.context.vfp.__fpsr, m_state.context.vfp.__fpcr);
260061da546Spatrick }
261061da546Spatrick #else
262061da546Spatrick // Read the registers from our thread
263061da546Spatrick mach_msg_type_number_t count = ARM_VFP_STATE_COUNT;
264061da546Spatrick kret = ::thread_get_state(m_thread->MachPortNumber(), ARM_VFP_STATE,
265061da546Spatrick (thread_state_t)&m_state.context.vfp, &count);
266061da546Spatrick
267061da546Spatrick if (DNBLogEnabledForAny(LOG_THREAD)) {
268061da546Spatrick uint32_t *r = &m_state.context.vfp.__r[0];
269061da546Spatrick DNBLogThreaded(
270061da546Spatrick "thread_get_state(0x%4.4x, %u, &gpr, %u) => 0x%8.8x (count => %u)",
271061da546Spatrick m_thread->MachPortNumber(), ARM_THREAD_STATE, ARM_THREAD_STATE_COUNT,
272061da546Spatrick kret, count);
273061da546Spatrick DNBLogThreaded(" s0=%8.8x s1=%8.8x s2=%8.8x s3=%8.8x s4=%8.8x "
274061da546Spatrick "s5=%8.8x s6=%8.8x s7=%8.8x",
275061da546Spatrick r[0], r[1], r[2], r[3], r[4], r[5], r[6], r[7]);
276061da546Spatrick DNBLogThreaded(" s8=%8.8x s9=%8.8x s10=%8.8x s11=%8.8x s12=%8.8x "
277061da546Spatrick "s13=%8.8x s14=%8.8x s15=%8.8x",
278061da546Spatrick r[8], r[9], r[10], r[11], r[12], r[13], r[14], r[15]);
279061da546Spatrick DNBLogThreaded(" s16=%8.8x s17=%8.8x s18=%8.8x s19=%8.8x s20=%8.8x "
280061da546Spatrick "s21=%8.8x s22=%8.8x s23=%8.8x",
281061da546Spatrick r[16], r[17], r[18], r[19], r[20], r[21], r[22], r[23]);
282061da546Spatrick DNBLogThreaded(" s24=%8.8x s25=%8.8x s26=%8.8x s27=%8.8x s28=%8.8x "
283061da546Spatrick "s29=%8.8x s30=%8.8x s31=%8.8x",
284061da546Spatrick r[24], r[25], r[26], r[27], r[28], r[29], r[30], r[31]);
285061da546Spatrick DNBLogThreaded(" s32=%8.8x s33=%8.8x s34=%8.8x s35=%8.8x s36=%8.8x "
286061da546Spatrick "s37=%8.8x s38=%8.8x s39=%8.8x",
287061da546Spatrick r[32], r[33], r[34], r[35], r[36], r[37], r[38], r[39]);
288061da546Spatrick DNBLogThreaded(" s40=%8.8x s41=%8.8x s42=%8.8x s43=%8.8x s44=%8.8x "
289061da546Spatrick "s45=%8.8x s46=%8.8x s47=%8.8x",
290061da546Spatrick r[40], r[41], r[42], r[43], r[44], r[45], r[46], r[47]);
291061da546Spatrick DNBLogThreaded(" s48=%8.8x s49=%8.8x s50=%8.8x s51=%8.8x s52=%8.8x "
292061da546Spatrick "s53=%8.8x s54=%8.8x s55=%8.8x",
293061da546Spatrick r[48], r[49], r[50], r[51], r[52], r[53], r[54], r[55]);
294061da546Spatrick DNBLogThreaded(" s56=%8.8x s57=%8.8x s58=%8.8x s59=%8.8x s60=%8.8x "
295061da546Spatrick "s61=%8.8x s62=%8.8x s63=%8.8x fpscr=%8.8x",
296061da546Spatrick r[56], r[57], r[58], r[59], r[60], r[61], r[62], r[63],
297061da546Spatrick r[64]);
298061da546Spatrick }
299061da546Spatrick
300061da546Spatrick #endif
301061da546Spatrick m_state.SetError(set, Read, kret);
302061da546Spatrick return kret;
303061da546Spatrick }
304061da546Spatrick
GetEXCState(bool force)305061da546Spatrick kern_return_t DNBArchMachARM::GetEXCState(bool force) {
306061da546Spatrick int set = e_regSetEXC;
307061da546Spatrick // Check if we have valid cached registers
308061da546Spatrick if (!force && m_state.GetError(set, Read) == KERN_SUCCESS)
309061da546Spatrick return KERN_SUCCESS;
310061da546Spatrick
311061da546Spatrick // Read the registers from our thread
312061da546Spatrick mach_msg_type_number_t count = ARM_EXCEPTION_STATE_COUNT;
313061da546Spatrick kern_return_t kret =
314061da546Spatrick ::thread_get_state(m_thread->MachPortNumber(), ARM_EXCEPTION_STATE,
315061da546Spatrick (thread_state_t)&m_state.context.exc, &count);
316061da546Spatrick m_state.SetError(set, Read, kret);
317061da546Spatrick return kret;
318061da546Spatrick }
319061da546Spatrick
320be691f3bSpatrick #if 0
321061da546Spatrick static void DumpDBGState(const DNBArchMachARM::DBG &dbg) {
322061da546Spatrick uint32_t i = 0;
323061da546Spatrick for (i = 0; i < 16; i++) {
324061da546Spatrick DNBLogThreadedIf(LOG_STEP, "BVR%-2u/BCR%-2u = { 0x%8.8x, 0x%8.8x } "
325061da546Spatrick "WVR%-2u/WCR%-2u = { 0x%8.8x, 0x%8.8x }",
326061da546Spatrick i, i, dbg.__bvr[i], dbg.__bcr[i], i, i, dbg.__wvr[i],
327061da546Spatrick dbg.__wcr[i]);
328061da546Spatrick }
329061da546Spatrick }
330be691f3bSpatrick #endif
331061da546Spatrick
GetDBGState(bool force)332061da546Spatrick kern_return_t DNBArchMachARM::GetDBGState(bool force) {
333061da546Spatrick int set = e_regSetDBG;
334061da546Spatrick
335061da546Spatrick // Check if we have valid cached registers
336061da546Spatrick if (!force && m_state.GetError(set, Read) == KERN_SUCCESS)
337061da546Spatrick return KERN_SUCCESS;
338061da546Spatrick
339061da546Spatrick // Read the registers from our thread
340061da546Spatrick #if defined(ARM_DEBUG_STATE32) && (defined(__arm64__) || defined(__aarch64__))
341061da546Spatrick mach_msg_type_number_t count = ARM_DEBUG_STATE32_COUNT;
342061da546Spatrick kern_return_t kret =
343061da546Spatrick ::thread_get_state(m_thread->MachPortNumber(), ARM_DEBUG_STATE32,
344061da546Spatrick (thread_state_t)&m_state.dbg, &count);
345061da546Spatrick #else
346061da546Spatrick mach_msg_type_number_t count = ARM_DEBUG_STATE_COUNT;
347061da546Spatrick kern_return_t kret =
348061da546Spatrick ::thread_get_state(m_thread->MachPortNumber(), ARM_DEBUG_STATE,
349061da546Spatrick (thread_state_t)&m_state.dbg, &count);
350061da546Spatrick #endif
351061da546Spatrick m_state.SetError(set, Read, kret);
352061da546Spatrick
353061da546Spatrick return kret;
354061da546Spatrick }
355061da546Spatrick
SetGPRState()356061da546Spatrick kern_return_t DNBArchMachARM::SetGPRState() {
357061da546Spatrick int set = e_regSetGPR;
358061da546Spatrick kern_return_t kret = ::thread_set_state(
359061da546Spatrick m_thread->MachPortNumber(), ARM_THREAD_STATE,
360061da546Spatrick (thread_state_t)&m_state.context.gpr, ARM_THREAD_STATE_COUNT);
361061da546Spatrick m_state.SetError(set, Write,
362061da546Spatrick kret); // Set the current write error for this register set
363061da546Spatrick m_state.InvalidateRegisterSetState(set); // Invalidate the current register
364061da546Spatrick // state in case registers are read
365061da546Spatrick // back differently
366061da546Spatrick return kret; // Return the error code
367061da546Spatrick }
368061da546Spatrick
SetVFPState()369061da546Spatrick kern_return_t DNBArchMachARM::SetVFPState() {
370061da546Spatrick int set = e_regSetVFP;
371061da546Spatrick kern_return_t kret;
372061da546Spatrick mach_msg_type_number_t count;
373061da546Spatrick
374061da546Spatrick #if defined(__arm64__) || defined(__aarch64__)
375061da546Spatrick count = ARM_NEON_STATE_COUNT;
376061da546Spatrick kret = ::thread_set_state(m_thread->MachPortNumber(), ARM_NEON_STATE,
377061da546Spatrick (thread_state_t)&m_state.context.vfp, count);
378061da546Spatrick #else
379061da546Spatrick count = ARM_VFP_STATE_COUNT;
380061da546Spatrick kret = ::thread_set_state(m_thread->MachPortNumber(), ARM_VFP_STATE,
381061da546Spatrick (thread_state_t)&m_state.context.vfp, count);
382061da546Spatrick #endif
383061da546Spatrick
384061da546Spatrick #if defined(__arm64__) || defined(__aarch64__)
385061da546Spatrick if (DNBLogEnabledForAny(LOG_THREAD)) {
386061da546Spatrick DNBLogThreaded(
387061da546Spatrick "thread_set_state(0x%4.4x, %u, &vfp, %u) => 0x%8.8x (count = %u) regs"
388061da546Spatrick "\n q0 = 0x%16.16llx%16.16llx"
389061da546Spatrick "\n q1 = 0x%16.16llx%16.16llx"
390061da546Spatrick "\n q2 = 0x%16.16llx%16.16llx"
391061da546Spatrick "\n q3 = 0x%16.16llx%16.16llx"
392061da546Spatrick "\n q4 = 0x%16.16llx%16.16llx"
393061da546Spatrick "\n q5 = 0x%16.16llx%16.16llx"
394061da546Spatrick "\n q6 = 0x%16.16llx%16.16llx"
395061da546Spatrick "\n q7 = 0x%16.16llx%16.16llx"
396061da546Spatrick "\n q8 = 0x%16.16llx%16.16llx"
397061da546Spatrick "\n q9 = 0x%16.16llx%16.16llx"
398061da546Spatrick "\n q10 = 0x%16.16llx%16.16llx"
399061da546Spatrick "\n q11 = 0x%16.16llx%16.16llx"
400061da546Spatrick "\n q12 = 0x%16.16llx%16.16llx"
401061da546Spatrick "\n q13 = 0x%16.16llx%16.16llx"
402061da546Spatrick "\n q14 = 0x%16.16llx%16.16llx"
403061da546Spatrick "\n q15 = 0x%16.16llx%16.16llx"
404061da546Spatrick "\n fpsr = 0x%8.8x"
405061da546Spatrick "\n fpcr = 0x%8.8x\n\n",
406061da546Spatrick m_thread->MachPortNumber(), ARM_NEON_STATE, ARM_NEON_STATE_COUNT, kret,
407061da546Spatrick count, ((uint64_t *)&m_state.context.vfp.__v[0])[0],
408061da546Spatrick ((uint64_t *)&m_state.context.vfp.__v[0])[1],
409061da546Spatrick ((uint64_t *)&m_state.context.vfp.__v[1])[0],
410061da546Spatrick ((uint64_t *)&m_state.context.vfp.__v[1])[1],
411061da546Spatrick ((uint64_t *)&m_state.context.vfp.__v[2])[0],
412061da546Spatrick ((uint64_t *)&m_state.context.vfp.__v[2])[1],
413061da546Spatrick ((uint64_t *)&m_state.context.vfp.__v[3])[0],
414061da546Spatrick ((uint64_t *)&m_state.context.vfp.__v[3])[1],
415061da546Spatrick ((uint64_t *)&m_state.context.vfp.__v[4])[0],
416061da546Spatrick ((uint64_t *)&m_state.context.vfp.__v[4])[1],
417061da546Spatrick ((uint64_t *)&m_state.context.vfp.__v[5])[0],
418061da546Spatrick ((uint64_t *)&m_state.context.vfp.__v[5])[1],
419061da546Spatrick ((uint64_t *)&m_state.context.vfp.__v[6])[0],
420061da546Spatrick ((uint64_t *)&m_state.context.vfp.__v[6])[1],
421061da546Spatrick ((uint64_t *)&m_state.context.vfp.__v[7])[0],
422061da546Spatrick ((uint64_t *)&m_state.context.vfp.__v[7])[1],
423061da546Spatrick ((uint64_t *)&m_state.context.vfp.__v[8])[0],
424061da546Spatrick ((uint64_t *)&m_state.context.vfp.__v[8])[1],
425061da546Spatrick ((uint64_t *)&m_state.context.vfp.__v[9])[0],
426061da546Spatrick ((uint64_t *)&m_state.context.vfp.__v[9])[1],
427061da546Spatrick ((uint64_t *)&m_state.context.vfp.__v[10])[0],
428061da546Spatrick ((uint64_t *)&m_state.context.vfp.__v[10])[1],
429061da546Spatrick ((uint64_t *)&m_state.context.vfp.__v[11])[0],
430061da546Spatrick ((uint64_t *)&m_state.context.vfp.__v[11])[1],
431061da546Spatrick ((uint64_t *)&m_state.context.vfp.__v[12])[0],
432061da546Spatrick ((uint64_t *)&m_state.context.vfp.__v[12])[1],
433061da546Spatrick ((uint64_t *)&m_state.context.vfp.__v[13])[0],
434061da546Spatrick ((uint64_t *)&m_state.context.vfp.__v[13])[1],
435061da546Spatrick ((uint64_t *)&m_state.context.vfp.__v[14])[0],
436061da546Spatrick ((uint64_t *)&m_state.context.vfp.__v[14])[1],
437061da546Spatrick ((uint64_t *)&m_state.context.vfp.__v[15])[0],
438061da546Spatrick ((uint64_t *)&m_state.context.vfp.__v[15])[1],
439061da546Spatrick m_state.context.vfp.__fpsr, m_state.context.vfp.__fpcr);
440061da546Spatrick }
441061da546Spatrick #else
442061da546Spatrick if (DNBLogEnabledForAny(LOG_THREAD)) {
443061da546Spatrick uint32_t *r = &m_state.context.vfp.__r[0];
444061da546Spatrick DNBLogThreaded(
445061da546Spatrick "thread_get_state(0x%4.4x, %u, &gpr, %u) => 0x%8.8x (count => %u)",
446061da546Spatrick m_thread->MachPortNumber(), ARM_THREAD_STATE, ARM_THREAD_STATE_COUNT,
447061da546Spatrick kret, count);
448061da546Spatrick DNBLogThreaded(" s0=%8.8x s1=%8.8x s2=%8.8x s3=%8.8x s4=%8.8x "
449061da546Spatrick "s5=%8.8x s6=%8.8x s7=%8.8x",
450061da546Spatrick r[0], r[1], r[2], r[3], r[4], r[5], r[6], r[7]);
451061da546Spatrick DNBLogThreaded(" s8=%8.8x s9=%8.8x s10=%8.8x s11=%8.8x s12=%8.8x "
452061da546Spatrick "s13=%8.8x s14=%8.8x s15=%8.8x",
453061da546Spatrick r[8], r[9], r[10], r[11], r[12], r[13], r[14], r[15]);
454061da546Spatrick DNBLogThreaded(" s16=%8.8x s17=%8.8x s18=%8.8x s19=%8.8x s20=%8.8x "
455061da546Spatrick "s21=%8.8x s22=%8.8x s23=%8.8x",
456061da546Spatrick r[16], r[17], r[18], r[19], r[20], r[21], r[22], r[23]);
457061da546Spatrick DNBLogThreaded(" s24=%8.8x s25=%8.8x s26=%8.8x s27=%8.8x s28=%8.8x "
458061da546Spatrick "s29=%8.8x s30=%8.8x s31=%8.8x",
459061da546Spatrick r[24], r[25], r[26], r[27], r[28], r[29], r[30], r[31]);
460061da546Spatrick DNBLogThreaded(" s32=%8.8x s33=%8.8x s34=%8.8x s35=%8.8x s36=%8.8x "
461061da546Spatrick "s37=%8.8x s38=%8.8x s39=%8.8x",
462061da546Spatrick r[32], r[33], r[34], r[35], r[36], r[37], r[38], r[39]);
463061da546Spatrick DNBLogThreaded(" s40=%8.8x s41=%8.8x s42=%8.8x s43=%8.8x s44=%8.8x "
464061da546Spatrick "s45=%8.8x s46=%8.8x s47=%8.8x",
465061da546Spatrick r[40], r[41], r[42], r[43], r[44], r[45], r[46], r[47]);
466061da546Spatrick DNBLogThreaded(" s48=%8.8x s49=%8.8x s50=%8.8x s51=%8.8x s52=%8.8x "
467061da546Spatrick "s53=%8.8x s54=%8.8x s55=%8.8x",
468061da546Spatrick r[48], r[49], r[50], r[51], r[52], r[53], r[54], r[55]);
469061da546Spatrick DNBLogThreaded(" s56=%8.8x s57=%8.8x s58=%8.8x s59=%8.8x s60=%8.8x "
470061da546Spatrick "s61=%8.8x s62=%8.8x s63=%8.8x fpscr=%8.8x",
471061da546Spatrick r[56], r[57], r[58], r[59], r[60], r[61], r[62], r[63],
472061da546Spatrick r[64]);
473061da546Spatrick }
474061da546Spatrick #endif
475061da546Spatrick
476061da546Spatrick m_state.SetError(set, Write,
477061da546Spatrick kret); // Set the current write error for this register set
478061da546Spatrick m_state.InvalidateRegisterSetState(set); // Invalidate the current register
479061da546Spatrick // state in case registers are read
480061da546Spatrick // back differently
481061da546Spatrick return kret; // Return the error code
482061da546Spatrick }
483061da546Spatrick
SetEXCState()484061da546Spatrick kern_return_t DNBArchMachARM::SetEXCState() {
485061da546Spatrick int set = e_regSetEXC;
486061da546Spatrick kern_return_t kret = ::thread_set_state(
487061da546Spatrick m_thread->MachPortNumber(), ARM_EXCEPTION_STATE,
488061da546Spatrick (thread_state_t)&m_state.context.exc, ARM_EXCEPTION_STATE_COUNT);
489061da546Spatrick m_state.SetError(set, Write,
490061da546Spatrick kret); // Set the current write error for this register set
491061da546Spatrick m_state.InvalidateRegisterSetState(set); // Invalidate the current register
492061da546Spatrick // state in case registers are read
493061da546Spatrick // back differently
494061da546Spatrick return kret; // Return the error code
495061da546Spatrick }
496061da546Spatrick
SetDBGState(bool also_set_on_task)497061da546Spatrick kern_return_t DNBArchMachARM::SetDBGState(bool also_set_on_task) {
498061da546Spatrick int set = e_regSetDBG;
499061da546Spatrick #if defined(ARM_DEBUG_STATE32) && (defined(__arm64__) || defined(__aarch64__))
500061da546Spatrick kern_return_t kret =
501061da546Spatrick ::thread_set_state(m_thread->MachPortNumber(), ARM_DEBUG_STATE32,
502061da546Spatrick (thread_state_t)&m_state.dbg, ARM_DEBUG_STATE32_COUNT);
503061da546Spatrick if (also_set_on_task) {
504061da546Spatrick kern_return_t task_kret = ::task_set_state(
505061da546Spatrick m_thread->Process()->Task().TaskPort(), ARM_DEBUG_STATE32,
506061da546Spatrick (thread_state_t)&m_state.dbg, ARM_DEBUG_STATE32_COUNT);
507061da546Spatrick if (task_kret != KERN_SUCCESS)
508061da546Spatrick DNBLogThreadedIf(LOG_WATCHPOINTS, "DNBArchMachARM::SetDBGState failed to "
509061da546Spatrick "set debug control register state: "
510061da546Spatrick "0x%8.8x.",
511061da546Spatrick kret);
512061da546Spatrick }
513061da546Spatrick #else
514061da546Spatrick kern_return_t kret =
515061da546Spatrick ::thread_set_state(m_thread->MachPortNumber(), ARM_DEBUG_STATE,
516061da546Spatrick (thread_state_t)&m_state.dbg, ARM_DEBUG_STATE_COUNT);
517061da546Spatrick if (also_set_on_task) {
518061da546Spatrick kern_return_t task_kret = ::task_set_state(
519061da546Spatrick m_thread->Process()->Task().TaskPort(), ARM_DEBUG_STATE,
520061da546Spatrick (thread_state_t)&m_state.dbg, ARM_DEBUG_STATE_COUNT);
521061da546Spatrick if (task_kret != KERN_SUCCESS)
522061da546Spatrick DNBLogThreadedIf(LOG_WATCHPOINTS, "DNBArchMachARM::SetDBGState failed to "
523061da546Spatrick "set debug control register state: "
524061da546Spatrick "0x%8.8x.",
525061da546Spatrick kret);
526061da546Spatrick }
527061da546Spatrick #endif
528061da546Spatrick
529061da546Spatrick m_state.SetError(set, Write,
530061da546Spatrick kret); // Set the current write error for this register set
531061da546Spatrick m_state.InvalidateRegisterSetState(set); // Invalidate the current register
532061da546Spatrick // state in case registers are read
533061da546Spatrick // back differently
534061da546Spatrick return kret; // Return the error code
535061da546Spatrick }
536061da546Spatrick
ThreadWillResume()537061da546Spatrick void DNBArchMachARM::ThreadWillResume() {
538061da546Spatrick // Do we need to step this thread? If so, let the mach thread tell us so.
539061da546Spatrick if (m_thread->IsStepping()) {
540061da546Spatrick // This is the primary thread, let the arch do anything it needs
541061da546Spatrick if (NumSupportedHardwareBreakpoints() > 0) {
542061da546Spatrick if (EnableHardwareSingleStep(true) != KERN_SUCCESS) {
543061da546Spatrick DNBLogThreaded("DNBArchMachARM::ThreadWillResume() failed to enable "
544061da546Spatrick "hardware single step");
545061da546Spatrick }
546061da546Spatrick }
547061da546Spatrick }
548061da546Spatrick
549061da546Spatrick // Disable the triggered watchpoint temporarily before we resume.
550061da546Spatrick // Plus, we try to enable hardware single step to execute past the instruction
551061da546Spatrick // which triggered our watchpoint.
552061da546Spatrick if (m_watchpoint_did_occur) {
553061da546Spatrick if (m_watchpoint_hw_index >= 0) {
554061da546Spatrick kern_return_t kret = GetDBGState(false);
555061da546Spatrick if (kret == KERN_SUCCESS &&
556061da546Spatrick !IsWatchpointEnabled(m_state.dbg, m_watchpoint_hw_index)) {
557061da546Spatrick // The watchpoint might have been disabled by the user. We don't need
558061da546Spatrick // to do anything at all
559061da546Spatrick // to enable hardware single stepping.
560061da546Spatrick m_watchpoint_did_occur = false;
561061da546Spatrick m_watchpoint_hw_index = -1;
562061da546Spatrick return;
563061da546Spatrick }
564061da546Spatrick
565061da546Spatrick DisableHardwareWatchpoint(m_watchpoint_hw_index, false);
566061da546Spatrick DNBLogThreadedIf(LOG_WATCHPOINTS, "DNBArchMachARM::ThreadWillResume() "
567061da546Spatrick "DisableHardwareWatchpoint(%d) called",
568061da546Spatrick m_watchpoint_hw_index);
569061da546Spatrick
570061da546Spatrick // Enable hardware single step to move past the watchpoint-triggering
571061da546Spatrick // instruction.
572061da546Spatrick m_watchpoint_resume_single_step_enabled =
573061da546Spatrick (EnableHardwareSingleStep(true) == KERN_SUCCESS);
574061da546Spatrick
575061da546Spatrick // If we are not able to enable single step to move past the
576061da546Spatrick // watchpoint-triggering instruction,
577061da546Spatrick // at least we should reset the two watchpoint member variables so that
578061da546Spatrick // the next time around
579061da546Spatrick // this callback function is invoked, the enclosing logical branch is
580061da546Spatrick // skipped.
581061da546Spatrick if (!m_watchpoint_resume_single_step_enabled) {
582061da546Spatrick // Reset the two watchpoint member variables.
583061da546Spatrick m_watchpoint_did_occur = false;
584061da546Spatrick m_watchpoint_hw_index = -1;
585061da546Spatrick DNBLogThreadedIf(
586061da546Spatrick LOG_WATCHPOINTS,
587061da546Spatrick "DNBArchMachARM::ThreadWillResume() failed to enable single step");
588061da546Spatrick } else
589061da546Spatrick DNBLogThreadedIf(LOG_WATCHPOINTS, "DNBArchMachARM::ThreadWillResume() "
590061da546Spatrick "succeeded to enable single step");
591061da546Spatrick }
592061da546Spatrick }
593061da546Spatrick }
594061da546Spatrick
ThreadDidStop()595061da546Spatrick bool DNBArchMachARM::ThreadDidStop() {
596061da546Spatrick bool success = true;
597061da546Spatrick
598061da546Spatrick m_state.InvalidateRegisterSetState(e_regSetALL);
599061da546Spatrick
600061da546Spatrick if (m_watchpoint_resume_single_step_enabled) {
601061da546Spatrick // Great! We now disable the hardware single step as well as re-enable the
602061da546Spatrick // hardware watchpoint.
603061da546Spatrick // See also ThreadWillResume().
604061da546Spatrick if (EnableHardwareSingleStep(false) == KERN_SUCCESS) {
605061da546Spatrick if (m_watchpoint_did_occur && m_watchpoint_hw_index >= 0) {
606061da546Spatrick ReenableHardwareWatchpoint(m_watchpoint_hw_index);
607061da546Spatrick m_watchpoint_resume_single_step_enabled = false;
608061da546Spatrick m_watchpoint_did_occur = false;
609061da546Spatrick m_watchpoint_hw_index = -1;
610061da546Spatrick } else {
611061da546Spatrick DNBLogError("internal error detected: m_watchpoint_resume_step_enabled "
612061da546Spatrick "is true but (m_watchpoint_did_occur && "
613061da546Spatrick "m_watchpoint_hw_index >= 0) does not hold!");
614061da546Spatrick }
615061da546Spatrick } else {
616061da546Spatrick DNBLogError("internal error detected: m_watchpoint_resume_step_enabled "
617061da546Spatrick "is true but unable to disable single step!");
618061da546Spatrick }
619061da546Spatrick }
620061da546Spatrick
621061da546Spatrick // Are we stepping a single instruction?
622061da546Spatrick if (GetGPRState(true) == KERN_SUCCESS) {
623061da546Spatrick // We are single stepping, was this the primary thread?
624061da546Spatrick if (m_thread->IsStepping()) {
625061da546Spatrick success = EnableHardwareSingleStep(false) == KERN_SUCCESS;
626061da546Spatrick } else {
627061da546Spatrick // The MachThread will automatically restore the suspend count
628061da546Spatrick // in ThreadDidStop(), so we don't need to do anything here if
629061da546Spatrick // we weren't the primary thread the last time
630061da546Spatrick }
631061da546Spatrick }
632061da546Spatrick return success;
633061da546Spatrick }
634061da546Spatrick
NotifyException(MachException::Data & exc)635061da546Spatrick bool DNBArchMachARM::NotifyException(MachException::Data &exc) {
636061da546Spatrick switch (exc.exc_type) {
637061da546Spatrick default:
638061da546Spatrick break;
639061da546Spatrick case EXC_BREAKPOINT:
640061da546Spatrick if (exc.exc_data.size() == 2 && exc.exc_data[0] == EXC_ARM_DA_DEBUG) {
641061da546Spatrick // The data break address is passed as exc_data[1].
642061da546Spatrick nub_addr_t addr = exc.exc_data[1];
643061da546Spatrick // Find the hardware index with the side effect of possibly massaging the
644061da546Spatrick // addr to return the starting address as seen from the debugger side.
645061da546Spatrick uint32_t hw_index = GetHardwareWatchpointHit(addr);
646061da546Spatrick DNBLogThreadedIf(LOG_WATCHPOINTS, "DNBArchMachARM::NotifyException "
647061da546Spatrick "watchpoint %d was hit on address "
648061da546Spatrick "0x%llx",
649061da546Spatrick hw_index, (uint64_t)addr);
650be691f3bSpatrick const uint32_t num_watchpoints = NumSupportedHardwareWatchpoints();
651be691f3bSpatrick for (uint32_t i = 0; i < num_watchpoints; i++) {
652061da546Spatrick if (LoHi[i] != 0 && LoHi[i] == hw_index && LoHi[i] != i &&
653061da546Spatrick GetWatchpointAddressByIndex(i) != INVALID_NUB_ADDRESS) {
654061da546Spatrick addr = GetWatchpointAddressByIndex(i);
655061da546Spatrick DNBLogThreadedIf(LOG_WATCHPOINTS, "DNBArchMachARM::NotifyException "
656061da546Spatrick "It is a linked watchpoint; "
657061da546Spatrick "rewritten to index %d addr 0x%llx",
658061da546Spatrick LoHi[i], (uint64_t)addr);
659061da546Spatrick }
660061da546Spatrick }
661061da546Spatrick if (hw_index != INVALID_NUB_HW_INDEX) {
662061da546Spatrick m_watchpoint_did_occur = true;
663061da546Spatrick m_watchpoint_hw_index = hw_index;
664061da546Spatrick exc.exc_data[1] = addr;
665061da546Spatrick // Piggyback the hw_index in the exc.data.
666061da546Spatrick exc.exc_data.push_back(hw_index);
667061da546Spatrick }
668061da546Spatrick
669061da546Spatrick return true;
670061da546Spatrick }
671061da546Spatrick break;
672061da546Spatrick }
673061da546Spatrick return false;
674061da546Spatrick }
675061da546Spatrick
StepNotComplete()676061da546Spatrick bool DNBArchMachARM::StepNotComplete() {
677061da546Spatrick if (m_hw_single_chained_step_addr != INVALID_NUB_ADDRESS) {
678061da546Spatrick kern_return_t kret = KERN_INVALID_ARGUMENT;
679061da546Spatrick kret = GetGPRState(false);
680061da546Spatrick if (kret == KERN_SUCCESS) {
681061da546Spatrick if (m_state.context.gpr.__pc == m_hw_single_chained_step_addr) {
682061da546Spatrick DNBLogThreadedIf(LOG_STEP, "Need to step some more at 0x%8.8llx",
683061da546Spatrick (uint64_t)m_hw_single_chained_step_addr);
684061da546Spatrick return true;
685061da546Spatrick }
686061da546Spatrick }
687061da546Spatrick }
688061da546Spatrick
689061da546Spatrick m_hw_single_chained_step_addr = INVALID_NUB_ADDRESS;
690061da546Spatrick return false;
691061da546Spatrick }
692061da546Spatrick
693061da546Spatrick // Set the single step bit in the processor status register.
EnableHardwareSingleStep(bool enable)694061da546Spatrick kern_return_t DNBArchMachARM::EnableHardwareSingleStep(bool enable) {
695061da546Spatrick DNBError err;
696061da546Spatrick DNBLogThreadedIf(LOG_STEP, "%s( enable = %d )", __FUNCTION__, enable);
697061da546Spatrick
698061da546Spatrick err = GetGPRState(false);
699061da546Spatrick
700061da546Spatrick if (err.Fail()) {
701061da546Spatrick err.LogThreaded("%s: failed to read the GPR registers", __FUNCTION__);
702061da546Spatrick return err.Status();
703061da546Spatrick }
704061da546Spatrick
705061da546Spatrick err = GetDBGState(false);
706061da546Spatrick
707061da546Spatrick if (err.Fail()) {
708061da546Spatrick err.LogThreaded("%s: failed to read the DBG registers", __FUNCTION__);
709061da546Spatrick return err.Status();
710061da546Spatrick }
711061da546Spatrick
712061da546Spatrick // The use of __arm64__ here is not ideal. If debugserver is running on
713061da546Spatrick // an armv8 device, regardless of whether it was built for arch arm or arch
714061da546Spatrick // arm64,
715061da546Spatrick // it needs to use the MDSCR_EL1 SS bit to single instruction step.
716061da546Spatrick
717061da546Spatrick #if defined(__arm64__) || defined(__aarch64__)
718061da546Spatrick if (enable) {
719061da546Spatrick DNBLogThreadedIf(LOG_STEP,
720061da546Spatrick "%s: Setting MDSCR_EL1 Single Step bit at pc 0x%llx",
721061da546Spatrick __FUNCTION__, (uint64_t)m_state.context.gpr.__pc);
722061da546Spatrick m_state.dbg.__mdscr_el1 |=
723061da546Spatrick 1; // Set bit 0 (single step, SS) in the MDSCR_EL1.
724061da546Spatrick } else {
725061da546Spatrick DNBLogThreadedIf(LOG_STEP,
726061da546Spatrick "%s: Clearing MDSCR_EL1 Single Step bit at pc 0x%llx",
727061da546Spatrick __FUNCTION__, (uint64_t)m_state.context.gpr.__pc);
728061da546Spatrick m_state.dbg.__mdscr_el1 &=
729061da546Spatrick ~(1ULL); // Clear bit 0 (single step, SS) in the MDSCR_EL1.
730061da546Spatrick }
731061da546Spatrick #else
732061da546Spatrick const uint32_t i = 0;
733061da546Spatrick if (enable) {
734061da546Spatrick m_hw_single_chained_step_addr = INVALID_NUB_ADDRESS;
735061da546Spatrick
736061da546Spatrick // Save our previous state
737061da546Spatrick m_dbg_save = m_state.dbg;
738061da546Spatrick // Set a breakpoint that will stop when the PC doesn't match the current
739061da546Spatrick // one!
740061da546Spatrick m_state.dbg.__bvr[i] =
741061da546Spatrick m_state.context.gpr.__pc &
742061da546Spatrick 0xFFFFFFFCu; // Set the current PC as the breakpoint address
743061da546Spatrick m_state.dbg.__bcr[i] = BCR_M_IMVA_MISMATCH | // Stop on address mismatch
744061da546Spatrick S_USER | // Stop only in user mode
745061da546Spatrick BCR_ENABLE; // Enable this breakpoint
746061da546Spatrick if (m_state.context.gpr.__cpsr & 0x20) {
747061da546Spatrick // Thumb breakpoint
748061da546Spatrick if (m_state.context.gpr.__pc & 2)
749061da546Spatrick m_state.dbg.__bcr[i] |= BAS_IMVA_2_3;
750061da546Spatrick else
751061da546Spatrick m_state.dbg.__bcr[i] |= BAS_IMVA_0_1;
752061da546Spatrick
753061da546Spatrick uint16_t opcode;
754061da546Spatrick if (sizeof(opcode) ==
755061da546Spatrick m_thread->Process()->Task().ReadMemory(m_state.context.gpr.__pc,
756061da546Spatrick sizeof(opcode), &opcode)) {
757061da546Spatrick if (IsThumb32Opcode(opcode)) {
758061da546Spatrick // 32 bit thumb opcode...
759061da546Spatrick if (m_state.context.gpr.__pc & 2) {
760061da546Spatrick // We can't take care of a 32 bit thumb instruction single step
761061da546Spatrick // with just IVA mismatching. We will need to chain an extra
762061da546Spatrick // hardware single step in order to complete this single step...
763061da546Spatrick m_hw_single_chained_step_addr = m_state.context.gpr.__pc + 2;
764061da546Spatrick } else {
765061da546Spatrick // Extend the number of bits to ignore for the mismatch
766061da546Spatrick m_state.dbg.__bcr[i] |= BAS_IMVA_ALL;
767061da546Spatrick }
768061da546Spatrick }
769061da546Spatrick }
770061da546Spatrick } else {
771061da546Spatrick // ARM breakpoint
772061da546Spatrick m_state.dbg.__bcr[i] |= BAS_IMVA_ALL; // Stop when any address bits change
773061da546Spatrick }
774061da546Spatrick
775061da546Spatrick DNBLogThreadedIf(LOG_STEP, "%s: BVR%u=0x%8.8x BCR%u=0x%8.8x", __FUNCTION__,
776061da546Spatrick i, m_state.dbg.__bvr[i], i, m_state.dbg.__bcr[i]);
777061da546Spatrick
778061da546Spatrick for (uint32_t j = i + 1; j < 16; ++j) {
779061da546Spatrick // Disable all others
780061da546Spatrick m_state.dbg.__bvr[j] = 0;
781061da546Spatrick m_state.dbg.__bcr[j] = 0;
782061da546Spatrick }
783061da546Spatrick } else {
784061da546Spatrick // Just restore the state we had before we did single stepping
785061da546Spatrick m_state.dbg = m_dbg_save;
786061da546Spatrick }
787061da546Spatrick #endif
788061da546Spatrick
789061da546Spatrick return SetDBGState(false);
790061da546Spatrick }
791061da546Spatrick
792061da546Spatrick // return 1 if bit "BIT" is set in "value"
bit(uint32_t value,uint32_t bit)793061da546Spatrick static inline uint32_t bit(uint32_t value, uint32_t bit) {
794061da546Spatrick return (value >> bit) & 1u;
795061da546Spatrick }
796061da546Spatrick
797061da546Spatrick // return the bitfield "value[msbit:lsbit]".
bits(uint32_t value,uint32_t msbit,uint32_t lsbit)798061da546Spatrick static inline uint32_t bits(uint32_t value, uint32_t msbit, uint32_t lsbit) {
799061da546Spatrick assert(msbit >= lsbit);
800061da546Spatrick uint32_t shift_left = sizeof(value) * 8 - 1 - msbit;
801061da546Spatrick value <<=
802061da546Spatrick shift_left; // shift anything above the msbit off of the unsigned edge
803061da546Spatrick value >>= (shift_left + lsbit); // shift it back again down to the lsbit
804061da546Spatrick // (including undoing any shift from above)
805061da546Spatrick return value; // return our result
806061da546Spatrick }
807061da546Spatrick
ConditionPassed(uint8_t condition,uint32_t cpsr)808061da546Spatrick bool DNBArchMachARM::ConditionPassed(uint8_t condition, uint32_t cpsr) {
809061da546Spatrick uint32_t cpsr_n = bit(cpsr, 31); // Negative condition code flag
810061da546Spatrick uint32_t cpsr_z = bit(cpsr, 30); // Zero condition code flag
811061da546Spatrick uint32_t cpsr_c = bit(cpsr, 29); // Carry condition code flag
812061da546Spatrick uint32_t cpsr_v = bit(cpsr, 28); // Overflow condition code flag
813061da546Spatrick
814061da546Spatrick switch (condition) {
815061da546Spatrick case COND_EQ: // (0x0)
816061da546Spatrick if (cpsr_z == 1)
817061da546Spatrick return true;
818061da546Spatrick break;
819061da546Spatrick case COND_NE: // (0x1)
820061da546Spatrick if (cpsr_z == 0)
821061da546Spatrick return true;
822061da546Spatrick break;
823061da546Spatrick case COND_CS: // (0x2)
824061da546Spatrick if (cpsr_c == 1)
825061da546Spatrick return true;
826061da546Spatrick break;
827061da546Spatrick case COND_CC: // (0x3)
828061da546Spatrick if (cpsr_c == 0)
829061da546Spatrick return true;
830061da546Spatrick break;
831061da546Spatrick case COND_MI: // (0x4)
832061da546Spatrick if (cpsr_n == 1)
833061da546Spatrick return true;
834061da546Spatrick break;
835061da546Spatrick case COND_PL: // (0x5)
836061da546Spatrick if (cpsr_n == 0)
837061da546Spatrick return true;
838061da546Spatrick break;
839061da546Spatrick case COND_VS: // (0x6)
840061da546Spatrick if (cpsr_v == 1)
841061da546Spatrick return true;
842061da546Spatrick break;
843061da546Spatrick case COND_VC: // (0x7)
844061da546Spatrick if (cpsr_v == 0)
845061da546Spatrick return true;
846061da546Spatrick break;
847061da546Spatrick case COND_HI: // (0x8)
848061da546Spatrick if ((cpsr_c == 1) && (cpsr_z == 0))
849061da546Spatrick return true;
850061da546Spatrick break;
851061da546Spatrick case COND_LS: // (0x9)
852061da546Spatrick if ((cpsr_c == 0) || (cpsr_z == 1))
853061da546Spatrick return true;
854061da546Spatrick break;
855061da546Spatrick case COND_GE: // (0xA)
856061da546Spatrick if (cpsr_n == cpsr_v)
857061da546Spatrick return true;
858061da546Spatrick break;
859061da546Spatrick case COND_LT: // (0xB)
860061da546Spatrick if (cpsr_n != cpsr_v)
861061da546Spatrick return true;
862061da546Spatrick break;
863061da546Spatrick case COND_GT: // (0xC)
864061da546Spatrick if ((cpsr_z == 0) && (cpsr_n == cpsr_v))
865061da546Spatrick return true;
866061da546Spatrick break;
867061da546Spatrick case COND_LE: // (0xD)
868061da546Spatrick if ((cpsr_z == 1) || (cpsr_n != cpsr_v))
869061da546Spatrick return true;
870061da546Spatrick break;
871061da546Spatrick default:
872061da546Spatrick return true;
873061da546Spatrick break;
874061da546Spatrick }
875061da546Spatrick
876061da546Spatrick return false;
877061da546Spatrick }
878061da546Spatrick
NumSupportedHardwareBreakpoints()879061da546Spatrick uint32_t DNBArchMachARM::NumSupportedHardwareBreakpoints() {
880061da546Spatrick // Set the init value to something that will let us know that we need to
881061da546Spatrick // autodetect how many breakpoints are supported dynamically...
882061da546Spatrick static uint32_t g_num_supported_hw_breakpoints = UINT_MAX;
883061da546Spatrick if (g_num_supported_hw_breakpoints == UINT_MAX) {
884061da546Spatrick // Set this to zero in case we can't tell if there are any HW breakpoints
885061da546Spatrick g_num_supported_hw_breakpoints = 0;
886061da546Spatrick
887061da546Spatrick size_t len;
888061da546Spatrick uint32_t n = 0;
889061da546Spatrick len = sizeof(n);
890061da546Spatrick if (::sysctlbyname("hw.optional.breakpoint", &n, &len, NULL, 0) == 0) {
891061da546Spatrick g_num_supported_hw_breakpoints = n;
892061da546Spatrick DNBLogThreadedIf(LOG_THREAD, "hw.optional.breakpoint=%u", n);
893061da546Spatrick } else {
894061da546Spatrick #if !defined(__arm64__) && !defined(__aarch64__)
895061da546Spatrick // Read the DBGDIDR to get the number of available hardware breakpoints
896061da546Spatrick // However, in some of our current armv7 processors, hardware
897061da546Spatrick // breakpoints/watchpoints were not properly connected. So detect those
898061da546Spatrick // cases using a field in a sysctl. For now we are using "hw.cpusubtype"
899061da546Spatrick // field to distinguish CPU architectures. This is a hack until we can
900061da546Spatrick // get <rdar://problem/6372672> fixed, at which point we will switch to
901061da546Spatrick // using a different sysctl string that will tell us how many BRPs
902061da546Spatrick // are available to us directly without having to read DBGDIDR.
903061da546Spatrick uint32_t register_DBGDIDR;
904061da546Spatrick
905061da546Spatrick asm("mrc p14, 0, %0, c0, c0, 0" : "=r"(register_DBGDIDR));
906061da546Spatrick uint32_t numBRPs = bits(register_DBGDIDR, 27, 24);
907061da546Spatrick // Zero is reserved for the BRP count, so don't increment it if it is zero
908061da546Spatrick if (numBRPs > 0)
909061da546Spatrick numBRPs++;
910061da546Spatrick DNBLogThreadedIf(LOG_THREAD, "DBGDIDR=0x%8.8x (number BRP pairs = %u)",
911061da546Spatrick register_DBGDIDR, numBRPs);
912061da546Spatrick
913061da546Spatrick if (numBRPs > 0) {
914061da546Spatrick uint32_t cpusubtype;
915061da546Spatrick len = sizeof(cpusubtype);
916061da546Spatrick // TODO: remove this hack and change to using hw.optional.xx when
917061da546Spatrick // implmented
918061da546Spatrick if (::sysctlbyname("hw.cpusubtype", &cpusubtype, &len, NULL, 0) == 0) {
919061da546Spatrick DNBLogThreadedIf(LOG_THREAD, "hw.cpusubtype=%d", cpusubtype);
920061da546Spatrick if (cpusubtype == CPU_SUBTYPE_ARM_V7)
921061da546Spatrick DNBLogThreadedIf(LOG_THREAD, "Hardware breakpoints disabled for "
922061da546Spatrick "armv7 (rdar://problem/6372672)");
923061da546Spatrick else
924061da546Spatrick g_num_supported_hw_breakpoints = numBRPs;
925061da546Spatrick }
926061da546Spatrick }
927061da546Spatrick #endif
928061da546Spatrick }
929061da546Spatrick }
930061da546Spatrick return g_num_supported_hw_breakpoints;
931061da546Spatrick }
932061da546Spatrick
NumSupportedHardwareWatchpoints()933061da546Spatrick uint32_t DNBArchMachARM::NumSupportedHardwareWatchpoints() {
934061da546Spatrick // Set the init value to something that will let us know that we need to
935061da546Spatrick // autodetect how many watchpoints are supported dynamically...
936061da546Spatrick static uint32_t g_num_supported_hw_watchpoints = UINT_MAX;
937061da546Spatrick if (g_num_supported_hw_watchpoints == UINT_MAX) {
938061da546Spatrick // Set this to zero in case we can't tell if there are any HW breakpoints
939061da546Spatrick g_num_supported_hw_watchpoints = 0;
940061da546Spatrick
941061da546Spatrick size_t len;
942061da546Spatrick uint32_t n = 0;
943061da546Spatrick len = sizeof(n);
944061da546Spatrick if (::sysctlbyname("hw.optional.watchpoint", &n, &len, NULL, 0) == 0) {
945061da546Spatrick g_num_supported_hw_watchpoints = n;
946061da546Spatrick DNBLogThreadedIf(LOG_THREAD, "hw.optional.watchpoint=%u", n);
947061da546Spatrick } else {
948061da546Spatrick #if !defined(__arm64__) && !defined(__aarch64__)
949061da546Spatrick // Read the DBGDIDR to get the number of available hardware breakpoints
950061da546Spatrick // However, in some of our current armv7 processors, hardware
951061da546Spatrick // breakpoints/watchpoints were not properly connected. So detect those
952061da546Spatrick // cases using a field in a sysctl. For now we are using "hw.cpusubtype"
953061da546Spatrick // field to distinguish CPU architectures. This is a hack until we can
954061da546Spatrick // get <rdar://problem/6372672> fixed, at which point we will switch to
955061da546Spatrick // using a different sysctl string that will tell us how many WRPs
956061da546Spatrick // are available to us directly without having to read DBGDIDR.
957061da546Spatrick
958061da546Spatrick uint32_t register_DBGDIDR;
959061da546Spatrick asm("mrc p14, 0, %0, c0, c0, 0" : "=r"(register_DBGDIDR));
960061da546Spatrick uint32_t numWRPs = bits(register_DBGDIDR, 31, 28) + 1;
961061da546Spatrick DNBLogThreadedIf(LOG_THREAD, "DBGDIDR=0x%8.8x (number WRP pairs = %u)",
962061da546Spatrick register_DBGDIDR, numWRPs);
963061da546Spatrick
964061da546Spatrick if (numWRPs > 0) {
965061da546Spatrick uint32_t cpusubtype;
966061da546Spatrick size_t len;
967061da546Spatrick len = sizeof(cpusubtype);
968061da546Spatrick // TODO: remove this hack and change to using hw.optional.xx when
969061da546Spatrick // implmented
970061da546Spatrick if (::sysctlbyname("hw.cpusubtype", &cpusubtype, &len, NULL, 0) == 0) {
971061da546Spatrick DNBLogThreadedIf(LOG_THREAD, "hw.cpusubtype=0x%d", cpusubtype);
972061da546Spatrick
973061da546Spatrick if (cpusubtype == CPU_SUBTYPE_ARM_V7)
974061da546Spatrick DNBLogThreadedIf(LOG_THREAD, "Hardware watchpoints disabled for "
975061da546Spatrick "armv7 (rdar://problem/6372672)");
976061da546Spatrick else
977061da546Spatrick g_num_supported_hw_watchpoints = numWRPs;
978061da546Spatrick }
979061da546Spatrick }
980061da546Spatrick #endif
981061da546Spatrick }
982061da546Spatrick }
983061da546Spatrick return g_num_supported_hw_watchpoints;
984061da546Spatrick }
985061da546Spatrick
EnableHardwareBreakpoint(nub_addr_t addr,nub_size_t size,bool also_set_on_task)986061da546Spatrick uint32_t DNBArchMachARM::EnableHardwareBreakpoint(nub_addr_t addr,
987dda28197Spatrick nub_size_t size,
988dda28197Spatrick bool also_set_on_task) {
989061da546Spatrick // Make sure our address isn't bogus
990061da546Spatrick if (addr & 1)
991061da546Spatrick return INVALID_NUB_HW_INDEX;
992061da546Spatrick
993061da546Spatrick kern_return_t kret = GetDBGState(false);
994061da546Spatrick
995061da546Spatrick if (kret == KERN_SUCCESS) {
996061da546Spatrick const uint32_t num_hw_breakpoints = NumSupportedHardwareBreakpoints();
997061da546Spatrick uint32_t i;
998061da546Spatrick for (i = 0; i < num_hw_breakpoints; ++i) {
999061da546Spatrick if ((m_state.dbg.__bcr[i] & BCR_ENABLE) == 0)
1000061da546Spatrick break; // We found an available hw breakpoint slot (in i)
1001061da546Spatrick }
1002061da546Spatrick
1003061da546Spatrick // See if we found an available hw breakpoint slot above
1004061da546Spatrick if (i < num_hw_breakpoints) {
1005061da546Spatrick // Make sure bits 1:0 are clear in our address
1006061da546Spatrick m_state.dbg.__bvr[i] = addr & ~((nub_addr_t)3);
1007061da546Spatrick
1008061da546Spatrick if (size == 2 || addr & 2) {
1009061da546Spatrick uint32_t byte_addr_select = (addr & 2) ? BAS_IMVA_2_3 : BAS_IMVA_0_1;
1010061da546Spatrick
1011061da546Spatrick // We have a thumb breakpoint
1012061da546Spatrick // We have an ARM breakpoint
1013061da546Spatrick m_state.dbg.__bcr[i] =
1014*f6aab3d8Srobert BCR_M_IMVA_MATCH | // Stop on address match
1015061da546Spatrick byte_addr_select | // Set the correct byte address select so we only
1016061da546Spatrick // trigger on the correct opcode
1017061da546Spatrick S_USER | // Which modes should this breakpoint stop in?
1018061da546Spatrick BCR_ENABLE; // Enable this hardware breakpoint
1019061da546Spatrick DNBLogThreadedIf(LOG_BREAKPOINTS,
1020061da546Spatrick "DNBArchMachARM::EnableHardwareBreakpoint( addr = "
1021061da546Spatrick "0x%8.8llx, size = %llu ) - BVR%u/BCR%u = 0x%8.8x / "
1022061da546Spatrick "0x%8.8x (Thumb)",
1023061da546Spatrick (uint64_t)addr, (uint64_t)size, i, i,
1024061da546Spatrick m_state.dbg.__bvr[i], m_state.dbg.__bcr[i]);
1025061da546Spatrick } else if (size == 4) {
1026061da546Spatrick // We have an ARM breakpoint
1027061da546Spatrick m_state.dbg.__bcr[i] =
1028*f6aab3d8Srobert BCR_M_IMVA_MATCH | // Stop on address match
1029061da546Spatrick BAS_IMVA_ALL | // Stop on any of the four bytes following the IMVA
1030061da546Spatrick S_USER | // Which modes should this breakpoint stop in?
1031061da546Spatrick BCR_ENABLE; // Enable this hardware breakpoint
1032061da546Spatrick DNBLogThreadedIf(LOG_BREAKPOINTS,
1033061da546Spatrick "DNBArchMachARM::EnableHardwareBreakpoint( addr = "
1034061da546Spatrick "0x%8.8llx, size = %llu ) - BVR%u/BCR%u = 0x%8.8x / "
1035061da546Spatrick "0x%8.8x (ARM)",
1036061da546Spatrick (uint64_t)addr, (uint64_t)size, i, i,
1037061da546Spatrick m_state.dbg.__bvr[i], m_state.dbg.__bcr[i]);
1038061da546Spatrick }
1039061da546Spatrick
1040061da546Spatrick kret = SetDBGState(false);
1041061da546Spatrick DNBLogThreadedIf(LOG_BREAKPOINTS, "DNBArchMachARM::"
1042061da546Spatrick "EnableHardwareBreakpoint() "
1043061da546Spatrick "SetDBGState() => 0x%8.8x.",
1044061da546Spatrick kret);
1045061da546Spatrick
1046061da546Spatrick if (kret == KERN_SUCCESS)
1047061da546Spatrick return i;
1048061da546Spatrick } else {
1049061da546Spatrick DNBLogThreadedIf(LOG_BREAKPOINTS,
1050061da546Spatrick "DNBArchMachARM::EnableHardwareBreakpoint(addr = "
1051061da546Spatrick "0x%8.8llx, size = %llu) => all hardware breakpoint "
1052061da546Spatrick "resources are being used.",
1053061da546Spatrick (uint64_t)addr, (uint64_t)size);
1054061da546Spatrick }
1055061da546Spatrick }
1056061da546Spatrick
1057061da546Spatrick return INVALID_NUB_HW_INDEX;
1058061da546Spatrick }
1059061da546Spatrick
DisableHardwareBreakpoint(uint32_t hw_index,bool also_set_on_task)1060dda28197Spatrick bool DNBArchMachARM::DisableHardwareBreakpoint(uint32_t hw_index,
1061dda28197Spatrick bool also_set_on_task) {
1062061da546Spatrick kern_return_t kret = GetDBGState(false);
1063061da546Spatrick
1064061da546Spatrick const uint32_t num_hw_points = NumSupportedHardwareBreakpoints();
1065061da546Spatrick if (kret == KERN_SUCCESS) {
1066061da546Spatrick if (hw_index < num_hw_points) {
1067061da546Spatrick m_state.dbg.__bcr[hw_index] = 0;
1068061da546Spatrick DNBLogThreadedIf(LOG_BREAKPOINTS, "DNBArchMachARM::SetHardwareBreakpoint("
1069061da546Spatrick " %u ) - BVR%u = 0x%8.8x BCR%u = "
1070061da546Spatrick "0x%8.8x",
1071061da546Spatrick hw_index, hw_index, m_state.dbg.__bvr[hw_index],
1072061da546Spatrick hw_index, m_state.dbg.__bcr[hw_index]);
1073061da546Spatrick
1074061da546Spatrick kret = SetDBGState(false);
1075061da546Spatrick
1076061da546Spatrick if (kret == KERN_SUCCESS)
1077061da546Spatrick return true;
1078061da546Spatrick }
1079061da546Spatrick }
1080061da546Spatrick return false;
1081061da546Spatrick }
1082061da546Spatrick
1083061da546Spatrick // ARM v7 watchpoints may be either word-size or double-word-size.
1084061da546Spatrick // It's implementation defined which they can handle. It looks like on an
1085061da546Spatrick // armv8 device, armv7 processes can watch dwords. But on a genuine armv7
1086061da546Spatrick // device I tried, only word watchpoints are supported.
1087061da546Spatrick
1088061da546Spatrick #if defined(__arm64__) || defined(__aarch64__)
1089061da546Spatrick #define WATCHPOINTS_ARE_DWORD 1
1090061da546Spatrick #else
1091061da546Spatrick #undef WATCHPOINTS_ARE_DWORD
1092061da546Spatrick #endif
1093061da546Spatrick
EnableHardwareWatchpoint(nub_addr_t addr,nub_size_t size,bool read,bool write,bool also_set_on_task)1094061da546Spatrick uint32_t DNBArchMachARM::EnableHardwareWatchpoint(nub_addr_t addr,
1095061da546Spatrick nub_size_t size, bool read,
1096061da546Spatrick bool write,
1097061da546Spatrick bool also_set_on_task) {
1098061da546Spatrick
1099061da546Spatrick DNBLogThreadedIf(LOG_WATCHPOINTS, "DNBArchMachARM::EnableHardwareWatchpoint("
1100061da546Spatrick "addr = 0x%8.8llx, size = %zu, read = %u, "
1101061da546Spatrick "write = %u)",
1102061da546Spatrick (uint64_t)addr, size, read, write);
1103061da546Spatrick
1104061da546Spatrick const uint32_t num_hw_watchpoints = NumSupportedHardwareWatchpoints();
1105061da546Spatrick
1106061da546Spatrick // Can't watch zero bytes
1107061da546Spatrick if (size == 0)
1108061da546Spatrick return INVALID_NUB_HW_INDEX;
1109061da546Spatrick
1110061da546Spatrick // We must watch for either read or write
1111061da546Spatrick if (read == false && write == false)
1112061da546Spatrick return INVALID_NUB_HW_INDEX;
1113061da546Spatrick
1114061da546Spatrick // Otherwise, can't watch more than 8 bytes per WVR/WCR pair
1115061da546Spatrick if (size > 8)
1116061da546Spatrick return INVALID_NUB_HW_INDEX;
1117061da546Spatrick
1118061da546Spatrick // Treat arm watchpoints as having an 8-byte alignment requirement. You can put
1119061da546Spatrick // a watchpoint on a 4-byte
1120061da546Spatrick // offset address but you can only watch 4 bytes with that watchpoint.
1121061da546Spatrick
1122061da546Spatrick // arm watchpoints on an 8-byte (double word) aligned addr can watch any bytes
1123061da546Spatrick // in that
1124061da546Spatrick // 8-byte long region of memory. They can watch the 1st byte, the 2nd byte, 3rd
1125061da546Spatrick // byte, etc, or any
1126061da546Spatrick // combination therein by setting the bits in the BAS [12:5] (Byte Address
1127061da546Spatrick // Select) field of
1128061da546Spatrick // the DBGWCRn_EL1 reg for the watchpoint.
1129061da546Spatrick
1130061da546Spatrick // If the MASK [28:24] bits in the DBGWCRn_EL1 allow a single watchpoint to
1131061da546Spatrick // monitor a larger region
1132061da546Spatrick // of memory (16 bytes, 32 bytes, or 2GB) but the Byte Address Select bitfield
1133061da546Spatrick // then selects a larger
1134061da546Spatrick // range of bytes, instead of individual bytes. See the ARMv8 Debug
1135061da546Spatrick // Architecture manual for details.
1136061da546Spatrick // This implementation does not currently use the MASK bits; the largest single
1137061da546Spatrick // region watched by a single
1138061da546Spatrick // watchpoint right now is 8-bytes.
1139061da546Spatrick
1140061da546Spatrick #if defined(WATCHPOINTS_ARE_DWORD)
1141061da546Spatrick nub_addr_t aligned_wp_address = addr & ~0x7;
1142061da546Spatrick uint32_t addr_dword_offset = addr & 0x7;
1143061da546Spatrick const int max_watchpoint_size = 8;
1144061da546Spatrick #else
1145061da546Spatrick nub_addr_t aligned_wp_address = addr & ~0x3;
1146061da546Spatrick uint32_t addr_dword_offset = addr & 0x3;
1147061da546Spatrick const int max_watchpoint_size = 4;
1148061da546Spatrick #endif
1149061da546Spatrick
1150061da546Spatrick DNBLogThreadedIf(LOG_WATCHPOINTS, "DNBArchMachARM::EnableHardwareWatchpoint "
1151061da546Spatrick "aligned_wp_address is 0x%llx and "
1152061da546Spatrick "addr_dword_offset is 0x%x",
1153061da546Spatrick (uint64_t)aligned_wp_address, addr_dword_offset);
1154061da546Spatrick
1155061da546Spatrick // Do we need to split up this logical watchpoint into two hardware watchpoint
1156061da546Spatrick // registers?
1157061da546Spatrick // e.g. a watchpoint of length 4 on address 6. We need do this with
1158061da546Spatrick // one watchpoint on address 0 with bytes 6 & 7 being monitored
1159061da546Spatrick // one watchpoint on address 8 with bytes 0, 1, 2, 3 being monitored
1160061da546Spatrick
1161061da546Spatrick if (addr_dword_offset + size > max_watchpoint_size) {
1162061da546Spatrick DNBLogThreadedIf(LOG_WATCHPOINTS, "DNBArchMachARM::"
1163061da546Spatrick "EnableHardwareWatchpoint(addr = "
1164061da546Spatrick "0x%8.8llx, size = %zu) needs two "
1165061da546Spatrick "hardware watchpoints slots to monitor",
1166061da546Spatrick (uint64_t)addr, size);
1167061da546Spatrick int low_watchpoint_size = max_watchpoint_size - addr_dword_offset;
1168061da546Spatrick int high_watchpoint_size = addr_dword_offset + size - max_watchpoint_size;
1169061da546Spatrick
1170061da546Spatrick uint32_t lo = EnableHardwareWatchpoint(addr, low_watchpoint_size, read,
1171061da546Spatrick write, also_set_on_task);
1172061da546Spatrick if (lo == INVALID_NUB_HW_INDEX)
1173061da546Spatrick return INVALID_NUB_HW_INDEX;
1174061da546Spatrick uint32_t hi = EnableHardwareWatchpoint(
1175061da546Spatrick aligned_wp_address + max_watchpoint_size, high_watchpoint_size, read,
1176061da546Spatrick write, also_set_on_task);
1177061da546Spatrick if (hi == INVALID_NUB_HW_INDEX) {
1178061da546Spatrick DisableHardwareWatchpoint(lo, also_set_on_task);
1179061da546Spatrick return INVALID_NUB_HW_INDEX;
1180061da546Spatrick }
1181061da546Spatrick // Tag this lo->hi mapping in our database.
1182061da546Spatrick LoHi[lo] = hi;
1183061da546Spatrick return lo;
1184061da546Spatrick }
1185061da546Spatrick
1186061da546Spatrick // At this point
1187061da546Spatrick // 1 aligned_wp_address is the requested address rounded down to 8-byte
1188061da546Spatrick // alignment
1189061da546Spatrick // 2 addr_dword_offset is the offset into that double word (8-byte) region
1190061da546Spatrick // that we are watching
1191061da546Spatrick // 3 size is the number of bytes within that 8-byte region that we are
1192061da546Spatrick // watching
1193061da546Spatrick
1194061da546Spatrick // Set the Byte Address Selects bits DBGWCRn_EL1 bits [12:5] based on the
1195061da546Spatrick // above.
1196061da546Spatrick // The bit shift and negation operation will give us 0b11 for 2, 0b1111 for 4,
1197061da546Spatrick // etc, up to 0b11111111 for 8.
1198061da546Spatrick // then we shift those bits left by the offset into this dword that we are
1199061da546Spatrick // interested in.
1200061da546Spatrick // e.g. if we are watching bytes 4,5,6,7 in a dword we want a BAS of
1201061da546Spatrick // 0b11110000.
1202061da546Spatrick uint32_t byte_address_select = ((1 << size) - 1) << addr_dword_offset;
1203061da546Spatrick
1204061da546Spatrick // Read the debug state
1205061da546Spatrick kern_return_t kret = GetDBGState(true);
1206061da546Spatrick
1207061da546Spatrick if (kret == KERN_SUCCESS) {
1208061da546Spatrick // Check to make sure we have the needed hardware support
1209061da546Spatrick uint32_t i = 0;
1210061da546Spatrick
1211061da546Spatrick for (i = 0; i < num_hw_watchpoints; ++i) {
1212061da546Spatrick if ((m_state.dbg.__wcr[i] & WCR_ENABLE) == 0)
1213061da546Spatrick break; // We found an available hw watchpoint slot (in i)
1214061da546Spatrick }
1215061da546Spatrick
1216061da546Spatrick // See if we found an available hw watchpoint slot above
1217061da546Spatrick if (i < num_hw_watchpoints) {
1218061da546Spatrick // DumpDBGState(m_state.dbg);
1219061da546Spatrick
1220061da546Spatrick // Clear any previous LoHi joined-watchpoint that may have been in use
1221061da546Spatrick LoHi[i] = 0;
1222061da546Spatrick
1223061da546Spatrick // shift our Byte Address Select bits up to the correct bit range for the
1224061da546Spatrick // DBGWCRn_EL1
1225061da546Spatrick byte_address_select = byte_address_select << 5;
1226061da546Spatrick
1227061da546Spatrick // Make sure bits 1:0 are clear in our address
1228061da546Spatrick m_state.dbg.__wvr[i] = aligned_wp_address; // DVA (Data Virtual Address)
1229061da546Spatrick m_state.dbg.__wcr[i] = byte_address_select | // Which bytes that follow
1230061da546Spatrick // the DVA that we will watch
1231061da546Spatrick S_USER | // Stop only in user mode
1232061da546Spatrick (read ? WCR_LOAD : 0) | // Stop on read access?
1233061da546Spatrick (write ? WCR_STORE : 0) | // Stop on write access?
1234061da546Spatrick WCR_ENABLE; // Enable this watchpoint;
1235061da546Spatrick
1236061da546Spatrick DNBLogThreadedIf(
1237061da546Spatrick LOG_WATCHPOINTS, "DNBArchMachARM::EnableHardwareWatchpoint() adding "
1238061da546Spatrick "watchpoint on address 0x%llx with control register "
1239061da546Spatrick "value 0x%x",
1240061da546Spatrick (uint64_t)m_state.dbg.__wvr[i], (uint32_t)m_state.dbg.__wcr[i]);
1241061da546Spatrick
1242061da546Spatrick // The kernel will set the MDE_ENABLE bit in the MDSCR_EL1 for us
1243061da546Spatrick // automatically, don't need to do it here.
1244061da546Spatrick
1245061da546Spatrick kret = SetDBGState(also_set_on_task);
1246061da546Spatrick // DumpDBGState(m_state.dbg);
1247061da546Spatrick
1248061da546Spatrick DNBLogThreadedIf(LOG_WATCHPOINTS, "DNBArchMachARM::"
1249061da546Spatrick "EnableHardwareWatchpoint() "
1250061da546Spatrick "SetDBGState() => 0x%8.8x.",
1251061da546Spatrick kret);
1252061da546Spatrick
1253061da546Spatrick if (kret == KERN_SUCCESS)
1254061da546Spatrick return i;
1255061da546Spatrick } else {
1256061da546Spatrick DNBLogThreadedIf(LOG_WATCHPOINTS, "DNBArchMachARM::"
1257061da546Spatrick "EnableHardwareWatchpoint(): All "
1258061da546Spatrick "hardware resources (%u) are in use.",
1259061da546Spatrick num_hw_watchpoints);
1260061da546Spatrick }
1261061da546Spatrick }
1262061da546Spatrick return INVALID_NUB_HW_INDEX;
1263061da546Spatrick }
1264061da546Spatrick
ReenableHardwareWatchpoint(uint32_t hw_index)1265061da546Spatrick bool DNBArchMachARM::ReenableHardwareWatchpoint(uint32_t hw_index) {
1266061da546Spatrick // If this logical watchpoint # is actually implemented using
1267061da546Spatrick // two hardware watchpoint registers, re-enable both of them.
1268061da546Spatrick
1269061da546Spatrick if (hw_index < NumSupportedHardwareWatchpoints() && LoHi[hw_index]) {
1270061da546Spatrick return ReenableHardwareWatchpoint_helper(hw_index) &&
1271061da546Spatrick ReenableHardwareWatchpoint_helper(LoHi[hw_index]);
1272061da546Spatrick } else {
1273061da546Spatrick return ReenableHardwareWatchpoint_helper(hw_index);
1274061da546Spatrick }
1275061da546Spatrick }
1276061da546Spatrick
ReenableHardwareWatchpoint_helper(uint32_t hw_index)1277061da546Spatrick bool DNBArchMachARM::ReenableHardwareWatchpoint_helper(uint32_t hw_index) {
1278061da546Spatrick kern_return_t kret = GetDBGState(false);
1279061da546Spatrick if (kret != KERN_SUCCESS)
1280061da546Spatrick return false;
1281061da546Spatrick const uint32_t num_hw_points = NumSupportedHardwareWatchpoints();
1282061da546Spatrick if (hw_index >= num_hw_points)
1283061da546Spatrick return false;
1284061da546Spatrick
1285061da546Spatrick m_state.dbg.__wvr[hw_index] = m_disabled_watchpoints[hw_index].addr;
1286061da546Spatrick m_state.dbg.__wcr[hw_index] = m_disabled_watchpoints[hw_index].control;
1287061da546Spatrick
1288061da546Spatrick DNBLogThreadedIf(LOG_WATCHPOINTS, "DNBArchMachARM::EnableHardwareWatchpoint( "
1289061da546Spatrick "%u ) - WVR%u = 0x%8.8llx WCR%u = "
1290061da546Spatrick "0x%8.8llx",
1291061da546Spatrick hw_index, hw_index, (uint64_t)m_state.dbg.__wvr[hw_index],
1292061da546Spatrick hw_index, (uint64_t)m_state.dbg.__wcr[hw_index]);
1293061da546Spatrick
1294061da546Spatrick // The kernel will set the MDE_ENABLE bit in the MDSCR_EL1 for us
1295061da546Spatrick // automatically, don't need to do it here.
1296061da546Spatrick
1297061da546Spatrick kret = SetDBGState(false);
1298061da546Spatrick
1299061da546Spatrick return (kret == KERN_SUCCESS);
1300061da546Spatrick }
1301061da546Spatrick
DisableHardwareWatchpoint(uint32_t hw_index,bool also_set_on_task)1302061da546Spatrick bool DNBArchMachARM::DisableHardwareWatchpoint(uint32_t hw_index,
1303061da546Spatrick bool also_set_on_task) {
1304061da546Spatrick if (hw_index < NumSupportedHardwareWatchpoints() && LoHi[hw_index]) {
1305061da546Spatrick return DisableHardwareWatchpoint_helper(hw_index, also_set_on_task) &&
1306061da546Spatrick DisableHardwareWatchpoint_helper(LoHi[hw_index], also_set_on_task);
1307061da546Spatrick } else {
1308061da546Spatrick return DisableHardwareWatchpoint_helper(hw_index, also_set_on_task);
1309061da546Spatrick }
1310061da546Spatrick }
1311061da546Spatrick
DisableHardwareWatchpoint_helper(uint32_t hw_index,bool also_set_on_task)1312061da546Spatrick bool DNBArchMachARM::DisableHardwareWatchpoint_helper(uint32_t hw_index,
1313061da546Spatrick bool also_set_on_task) {
1314061da546Spatrick kern_return_t kret = GetDBGState(false);
1315061da546Spatrick if (kret != KERN_SUCCESS)
1316061da546Spatrick return false;
1317061da546Spatrick
1318061da546Spatrick const uint32_t num_hw_points = NumSupportedHardwareWatchpoints();
1319061da546Spatrick if (hw_index >= num_hw_points)
1320061da546Spatrick return false;
1321061da546Spatrick
1322061da546Spatrick m_disabled_watchpoints[hw_index].addr = m_state.dbg.__wvr[hw_index];
1323061da546Spatrick m_disabled_watchpoints[hw_index].control = m_state.dbg.__wcr[hw_index];
1324061da546Spatrick
1325061da546Spatrick m_state.dbg.__wvr[hw_index] = 0;
1326061da546Spatrick m_state.dbg.__wcr[hw_index] = 0;
1327061da546Spatrick DNBLogThreadedIf(LOG_WATCHPOINTS, "DNBArchMachARM::DisableHardwareWatchpoint("
1328061da546Spatrick " %u ) - WVR%u = 0x%8.8llx WCR%u = "
1329061da546Spatrick "0x%8.8llx",
1330061da546Spatrick hw_index, hw_index, (uint64_t)m_state.dbg.__wvr[hw_index],
1331061da546Spatrick hw_index, (uint64_t)m_state.dbg.__wcr[hw_index]);
1332061da546Spatrick
1333061da546Spatrick kret = SetDBGState(also_set_on_task);
1334061da546Spatrick
1335061da546Spatrick return (kret == KERN_SUCCESS);
1336061da546Spatrick }
1337061da546Spatrick
1338061da546Spatrick // Returns -1 if the trailing bit patterns are not one of:
1339061da546Spatrick // { 0b???1, 0b??10, 0b?100, 0b1000 }.
LowestBitSet(uint32_t val)1340061da546Spatrick static inline int32_t LowestBitSet(uint32_t val) {
1341061da546Spatrick for (unsigned i = 0; i < 4; ++i) {
1342061da546Spatrick if (bit(val, i))
1343061da546Spatrick return i;
1344061da546Spatrick }
1345061da546Spatrick return -1;
1346061da546Spatrick }
1347061da546Spatrick
1348061da546Spatrick // Iterate through the debug registers; return the index of the first watchpoint
1349061da546Spatrick // whose address matches.
1350061da546Spatrick // As a side effect, the starting address as understood by the debugger is
1351061da546Spatrick // returned which could be
1352061da546Spatrick // different from 'addr' passed as an in/out argument.
GetHardwareWatchpointHit(nub_addr_t & addr)1353061da546Spatrick uint32_t DNBArchMachARM::GetHardwareWatchpointHit(nub_addr_t &addr) {
1354061da546Spatrick // Read the debug state
1355061da546Spatrick kern_return_t kret = GetDBGState(true);
1356061da546Spatrick // DumpDBGState(m_state.dbg);
1357061da546Spatrick DNBLogThreadedIf(
1358061da546Spatrick LOG_WATCHPOINTS,
1359061da546Spatrick "DNBArchMachARM::GetHardwareWatchpointHit() GetDBGState() => 0x%8.8x.",
1360061da546Spatrick kret);
1361061da546Spatrick DNBLogThreadedIf(LOG_WATCHPOINTS,
1362061da546Spatrick "DNBArchMachARM::GetHardwareWatchpointHit() addr = 0x%llx",
1363061da546Spatrick (uint64_t)addr);
1364061da546Spatrick
1365061da546Spatrick // This is the watchpoint value to match against, i.e., word address.
1366061da546Spatrick #if defined(WATCHPOINTS_ARE_DWORD)
1367061da546Spatrick nub_addr_t wp_val = addr & ~((nub_addr_t)7);
1368061da546Spatrick #else
1369061da546Spatrick nub_addr_t wp_val = addr & ~((nub_addr_t)3);
1370061da546Spatrick #endif
1371061da546Spatrick if (kret == KERN_SUCCESS) {
1372061da546Spatrick DBG &debug_state = m_state.dbg;
1373061da546Spatrick uint32_t i, num = NumSupportedHardwareWatchpoints();
1374061da546Spatrick for (i = 0; i < num; ++i) {
1375061da546Spatrick nub_addr_t wp_addr = GetWatchAddress(debug_state, i);
1376061da546Spatrick DNBLogThreadedIf(LOG_WATCHPOINTS, "DNBArchMachARM::"
1377061da546Spatrick "GetHardwareWatchpointHit() slot: %u "
1378061da546Spatrick "(addr = 0x%llx).",
1379061da546Spatrick i, (uint64_t)wp_addr);
1380061da546Spatrick if (wp_val == wp_addr) {
1381061da546Spatrick #if defined(WATCHPOINTS_ARE_DWORD)
1382061da546Spatrick uint32_t byte_mask = bits(debug_state.__wcr[i], 12, 5);
1383061da546Spatrick #else
1384061da546Spatrick uint32_t byte_mask = bits(debug_state.__wcr[i], 8, 5);
1385061da546Spatrick #endif
1386061da546Spatrick
1387061da546Spatrick // Sanity check the byte_mask, first.
1388061da546Spatrick if (LowestBitSet(byte_mask) < 0)
1389061da546Spatrick continue;
1390061da546Spatrick
1391061da546Spatrick // Compute the starting address (from the point of view of the
1392061da546Spatrick // debugger).
1393061da546Spatrick addr = wp_addr + LowestBitSet(byte_mask);
1394061da546Spatrick return i;
1395061da546Spatrick }
1396061da546Spatrick }
1397061da546Spatrick }
1398061da546Spatrick return INVALID_NUB_HW_INDEX;
1399061da546Spatrick }
1400061da546Spatrick
GetWatchpointAddressByIndex(uint32_t hw_index)1401061da546Spatrick nub_addr_t DNBArchMachARM::GetWatchpointAddressByIndex(uint32_t hw_index) {
1402061da546Spatrick kern_return_t kret = GetDBGState(true);
1403061da546Spatrick if (kret != KERN_SUCCESS)
1404061da546Spatrick return INVALID_NUB_ADDRESS;
1405061da546Spatrick const uint32_t num = NumSupportedHardwareWatchpoints();
1406061da546Spatrick if (hw_index >= num)
1407061da546Spatrick return INVALID_NUB_ADDRESS;
1408061da546Spatrick if (IsWatchpointEnabled(m_state.dbg, hw_index))
1409061da546Spatrick return GetWatchAddress(m_state.dbg, hw_index);
1410061da546Spatrick return INVALID_NUB_ADDRESS;
1411061da546Spatrick }
1412061da546Spatrick
IsWatchpointEnabled(const DBG & debug_state,uint32_t hw_index)1413061da546Spatrick bool DNBArchMachARM::IsWatchpointEnabled(const DBG &debug_state,
1414061da546Spatrick uint32_t hw_index) {
1415061da546Spatrick // Watchpoint Control Registers, bitfield definitions
1416061da546Spatrick // ...
1417061da546Spatrick // Bits Value Description
1418061da546Spatrick // [0] 0 Watchpoint disabled
1419061da546Spatrick // 1 Watchpoint enabled.
1420061da546Spatrick return (debug_state.__wcr[hw_index] & 1u);
1421061da546Spatrick }
1422061da546Spatrick
GetWatchAddress(const DBG & debug_state,uint32_t hw_index)1423061da546Spatrick nub_addr_t DNBArchMachARM::GetWatchAddress(const DBG &debug_state,
1424061da546Spatrick uint32_t hw_index) {
1425061da546Spatrick // Watchpoint Value Registers, bitfield definitions
1426061da546Spatrick // Bits Description
1427061da546Spatrick // [31:2] Watchpoint value (word address, i.e., 4-byte aligned)
1428061da546Spatrick // [1:0] RAZ/SBZP
1429061da546Spatrick return bits(debug_state.__wvr[hw_index], 31, 0);
1430061da546Spatrick }
1431061da546Spatrick
1432061da546Spatrick // Register information definitions for 32 bit ARMV7.
1433061da546Spatrick enum gpr_regnums {
1434061da546Spatrick gpr_r0 = 0,
1435061da546Spatrick gpr_r1,
1436061da546Spatrick gpr_r2,
1437061da546Spatrick gpr_r3,
1438061da546Spatrick gpr_r4,
1439061da546Spatrick gpr_r5,
1440061da546Spatrick gpr_r6,
1441061da546Spatrick gpr_r7,
1442061da546Spatrick gpr_r8,
1443061da546Spatrick gpr_r9,
1444061da546Spatrick gpr_r10,
1445061da546Spatrick gpr_r11,
1446061da546Spatrick gpr_r12,
1447061da546Spatrick gpr_sp,
1448061da546Spatrick gpr_lr,
1449061da546Spatrick gpr_pc,
1450061da546Spatrick gpr_cpsr
1451061da546Spatrick };
1452061da546Spatrick
1453061da546Spatrick enum {
1454061da546Spatrick vfp_s0 = 0,
1455061da546Spatrick vfp_s1,
1456061da546Spatrick vfp_s2,
1457061da546Spatrick vfp_s3,
1458061da546Spatrick vfp_s4,
1459061da546Spatrick vfp_s5,
1460061da546Spatrick vfp_s6,
1461061da546Spatrick vfp_s7,
1462061da546Spatrick vfp_s8,
1463061da546Spatrick vfp_s9,
1464061da546Spatrick vfp_s10,
1465061da546Spatrick vfp_s11,
1466061da546Spatrick vfp_s12,
1467061da546Spatrick vfp_s13,
1468061da546Spatrick vfp_s14,
1469061da546Spatrick vfp_s15,
1470061da546Spatrick vfp_s16,
1471061da546Spatrick vfp_s17,
1472061da546Spatrick vfp_s18,
1473061da546Spatrick vfp_s19,
1474061da546Spatrick vfp_s20,
1475061da546Spatrick vfp_s21,
1476061da546Spatrick vfp_s22,
1477061da546Spatrick vfp_s23,
1478061da546Spatrick vfp_s24,
1479061da546Spatrick vfp_s25,
1480061da546Spatrick vfp_s26,
1481061da546Spatrick vfp_s27,
1482061da546Spatrick vfp_s28,
1483061da546Spatrick vfp_s29,
1484061da546Spatrick vfp_s30,
1485061da546Spatrick vfp_s31,
1486061da546Spatrick vfp_d0,
1487061da546Spatrick vfp_d1,
1488061da546Spatrick vfp_d2,
1489061da546Spatrick vfp_d3,
1490061da546Spatrick vfp_d4,
1491061da546Spatrick vfp_d5,
1492061da546Spatrick vfp_d6,
1493061da546Spatrick vfp_d7,
1494061da546Spatrick vfp_d8,
1495061da546Spatrick vfp_d9,
1496061da546Spatrick vfp_d10,
1497061da546Spatrick vfp_d11,
1498061da546Spatrick vfp_d12,
1499061da546Spatrick vfp_d13,
1500061da546Spatrick vfp_d14,
1501061da546Spatrick vfp_d15,
1502061da546Spatrick vfp_d16,
1503061da546Spatrick vfp_d17,
1504061da546Spatrick vfp_d18,
1505061da546Spatrick vfp_d19,
1506061da546Spatrick vfp_d20,
1507061da546Spatrick vfp_d21,
1508061da546Spatrick vfp_d22,
1509061da546Spatrick vfp_d23,
1510061da546Spatrick vfp_d24,
1511061da546Spatrick vfp_d25,
1512061da546Spatrick vfp_d26,
1513061da546Spatrick vfp_d27,
1514061da546Spatrick vfp_d28,
1515061da546Spatrick vfp_d29,
1516061da546Spatrick vfp_d30,
1517061da546Spatrick vfp_d31,
1518061da546Spatrick vfp_q0,
1519061da546Spatrick vfp_q1,
1520061da546Spatrick vfp_q2,
1521061da546Spatrick vfp_q3,
1522061da546Spatrick vfp_q4,
1523061da546Spatrick vfp_q5,
1524061da546Spatrick vfp_q6,
1525061da546Spatrick vfp_q7,
1526061da546Spatrick vfp_q8,
1527061da546Spatrick vfp_q9,
1528061da546Spatrick vfp_q10,
1529061da546Spatrick vfp_q11,
1530061da546Spatrick vfp_q12,
1531061da546Spatrick vfp_q13,
1532061da546Spatrick vfp_q14,
1533061da546Spatrick vfp_q15,
1534061da546Spatrick #if defined(__arm64__) || defined(__aarch64__)
1535061da546Spatrick vfp_fpsr,
1536061da546Spatrick vfp_fpcr,
1537061da546Spatrick #else
1538061da546Spatrick vfp_fpscr
1539061da546Spatrick #endif
1540061da546Spatrick };
1541061da546Spatrick
1542061da546Spatrick enum {
1543061da546Spatrick exc_exception,
1544061da546Spatrick exc_fsr,
1545061da546Spatrick exc_far,
1546061da546Spatrick };
1547061da546Spatrick
1548061da546Spatrick #define GPR_OFFSET_IDX(idx) (offsetof(DNBArchMachARM::GPR, __r[idx]))
1549061da546Spatrick #define GPR_OFFSET_NAME(reg) (offsetof(DNBArchMachARM::GPR, __##reg))
1550061da546Spatrick
1551061da546Spatrick #define EXC_OFFSET(reg) \
1552061da546Spatrick (offsetof(DNBArchMachARM::EXC, __##reg) + \
1553061da546Spatrick offsetof(DNBArchMachARM::Context, exc))
1554061da546Spatrick
1555061da546Spatrick // These macros will auto define the register name, alt name, register size,
1556061da546Spatrick // register offset, encoding, format and native register. This ensures that
1557061da546Spatrick // the register state structures are defined correctly and have the correct
1558061da546Spatrick // sizes and offsets.
1559061da546Spatrick #define DEFINE_GPR_IDX(idx, reg, alt, gen) \
1560061da546Spatrick { \
1561061da546Spatrick e_regSetGPR, gpr_##reg, #reg, alt, Uint, Hex, 4, GPR_OFFSET_IDX(idx), \
1562061da546Spatrick ehframe_##reg, dwarf_##reg, gen, INVALID_NUB_REGNUM, NULL, NULL \
1563061da546Spatrick }
1564061da546Spatrick #define DEFINE_GPR_NAME(reg, alt, gen, inval) \
1565061da546Spatrick { \
1566061da546Spatrick e_regSetGPR, gpr_##reg, #reg, alt, Uint, Hex, 4, GPR_OFFSET_NAME(reg), \
1567061da546Spatrick ehframe_##reg, dwarf_##reg, gen, INVALID_NUB_REGNUM, NULL, inval \
1568061da546Spatrick }
1569061da546Spatrick
1570061da546Spatrick // In case we are debugging to a debug target that the ability to
1571061da546Spatrick // change into the protected modes with folded registers (ABT, IRQ,
1572061da546Spatrick // FIQ, SYS, USR, etc..), we should invalidate r8-r14 if the CPSR
1573061da546Spatrick // gets modified.
1574061da546Spatrick
1575061da546Spatrick const char *g_invalidate_cpsr[] = {"r8", "r9", "r10", "r11",
1576061da546Spatrick "r12", "sp", "lr", NULL};
1577061da546Spatrick
1578061da546Spatrick // General purpose registers
1579061da546Spatrick const DNBRegisterInfo DNBArchMachARM::g_gpr_registers[] = {
1580061da546Spatrick DEFINE_GPR_IDX(0, r0, "arg1", GENERIC_REGNUM_ARG1),
1581061da546Spatrick DEFINE_GPR_IDX(1, r1, "arg2", GENERIC_REGNUM_ARG2),
1582061da546Spatrick DEFINE_GPR_IDX(2, r2, "arg3", GENERIC_REGNUM_ARG3),
1583061da546Spatrick DEFINE_GPR_IDX(3, r3, "arg4", GENERIC_REGNUM_ARG4),
1584061da546Spatrick DEFINE_GPR_IDX(4, r4, NULL, INVALID_NUB_REGNUM),
1585061da546Spatrick DEFINE_GPR_IDX(5, r5, NULL, INVALID_NUB_REGNUM),
1586061da546Spatrick DEFINE_GPR_IDX(6, r6, NULL, INVALID_NUB_REGNUM),
1587061da546Spatrick DEFINE_GPR_IDX(7, r7, "fp", GENERIC_REGNUM_FP),
1588061da546Spatrick DEFINE_GPR_IDX(8, r8, NULL, INVALID_NUB_REGNUM),
1589061da546Spatrick DEFINE_GPR_IDX(9, r9, NULL, INVALID_NUB_REGNUM),
1590061da546Spatrick DEFINE_GPR_IDX(10, r10, NULL, INVALID_NUB_REGNUM),
1591061da546Spatrick DEFINE_GPR_IDX(11, r11, NULL, INVALID_NUB_REGNUM),
1592061da546Spatrick DEFINE_GPR_IDX(12, r12, NULL, INVALID_NUB_REGNUM),
1593061da546Spatrick DEFINE_GPR_NAME(sp, "r13", GENERIC_REGNUM_SP, NULL),
1594061da546Spatrick DEFINE_GPR_NAME(lr, "r14", GENERIC_REGNUM_RA, NULL),
1595061da546Spatrick DEFINE_GPR_NAME(pc, "r15", GENERIC_REGNUM_PC, NULL),
1596061da546Spatrick DEFINE_GPR_NAME(cpsr, "flags", GENERIC_REGNUM_FLAGS, g_invalidate_cpsr)};
1597061da546Spatrick
1598061da546Spatrick const char *g_contained_q0[]{"q0", NULL};
1599061da546Spatrick const char *g_contained_q1[]{"q1", NULL};
1600061da546Spatrick const char *g_contained_q2[]{"q2", NULL};
1601061da546Spatrick const char *g_contained_q3[]{"q3", NULL};
1602061da546Spatrick const char *g_contained_q4[]{"q4", NULL};
1603061da546Spatrick const char *g_contained_q5[]{"q5", NULL};
1604061da546Spatrick const char *g_contained_q6[]{"q6", NULL};
1605061da546Spatrick const char *g_contained_q7[]{"q7", NULL};
1606061da546Spatrick const char *g_contained_q8[]{"q8", NULL};
1607061da546Spatrick const char *g_contained_q9[]{"q9", NULL};
1608061da546Spatrick const char *g_contained_q10[]{"q10", NULL};
1609061da546Spatrick const char *g_contained_q11[]{"q11", NULL};
1610061da546Spatrick const char *g_contained_q12[]{"q12", NULL};
1611061da546Spatrick const char *g_contained_q13[]{"q13", NULL};
1612061da546Spatrick const char *g_contained_q14[]{"q14", NULL};
1613061da546Spatrick const char *g_contained_q15[]{"q15", NULL};
1614061da546Spatrick
1615061da546Spatrick const char *g_invalidate_q0[]{"q0", "d0", "d1", "s0", "s1", "s2", "s3", NULL};
1616061da546Spatrick const char *g_invalidate_q1[]{"q1", "d2", "d3", "s4", "s5", "s6", "s7", NULL};
1617061da546Spatrick const char *g_invalidate_q2[]{"q2", "d4", "d5", "s8", "s9", "s10", "s11", NULL};
1618061da546Spatrick const char *g_invalidate_q3[]{"q3", "d6", "d7", "s12",
1619061da546Spatrick "s13", "s14", "s15", NULL};
1620061da546Spatrick const char *g_invalidate_q4[]{"q4", "d8", "d9", "s16",
1621061da546Spatrick "s17", "s18", "s19", NULL};
1622061da546Spatrick const char *g_invalidate_q5[]{"q5", "d10", "d11", "s20",
1623061da546Spatrick "s21", "s22", "s23", NULL};
1624061da546Spatrick const char *g_invalidate_q6[]{"q6", "d12", "d13", "s24",
1625061da546Spatrick "s25", "s26", "s27", NULL};
1626061da546Spatrick const char *g_invalidate_q7[]{"q7", "d14", "d15", "s28",
1627061da546Spatrick "s29", "s30", "s31", NULL};
1628061da546Spatrick const char *g_invalidate_q8[]{"q8", "d16", "d17", NULL};
1629061da546Spatrick const char *g_invalidate_q9[]{"q9", "d18", "d19", NULL};
1630061da546Spatrick const char *g_invalidate_q10[]{"q10", "d20", "d21", NULL};
1631061da546Spatrick const char *g_invalidate_q11[]{"q11", "d22", "d23", NULL};
1632061da546Spatrick const char *g_invalidate_q12[]{"q12", "d24", "d25", NULL};
1633061da546Spatrick const char *g_invalidate_q13[]{"q13", "d26", "d27", NULL};
1634061da546Spatrick const char *g_invalidate_q14[]{"q14", "d28", "d29", NULL};
1635061da546Spatrick const char *g_invalidate_q15[]{"q15", "d30", "d31", NULL};
1636061da546Spatrick
1637061da546Spatrick #define VFP_S_OFFSET_IDX(idx) \
1638061da546Spatrick (((idx) % 4) * 4) // offset into q reg: 0, 4, 8, 12
1639061da546Spatrick #define VFP_D_OFFSET_IDX(idx) (((idx) % 2) * 8) // offset into q reg: 0, 8
1640061da546Spatrick #define VFP_Q_OFFSET_IDX(idx) (VFP_S_OFFSET_IDX((idx)*4))
1641061da546Spatrick
1642061da546Spatrick #define VFP_OFFSET_NAME(reg) \
1643061da546Spatrick (offsetof(DNBArchMachARM::FPU, __##reg) + \
1644061da546Spatrick offsetof(DNBArchMachARM::Context, vfp))
1645061da546Spatrick
1646061da546Spatrick #define FLOAT_FORMAT Float
1647061da546Spatrick
1648061da546Spatrick #define DEFINE_VFP_S_IDX(idx) \
1649061da546Spatrick e_regSetVFP, vfp_s##idx, "s" #idx, NULL, IEEE754, FLOAT_FORMAT, 4, \
1650061da546Spatrick VFP_S_OFFSET_IDX(idx), INVALID_NUB_REGNUM, dwarf_s##idx, \
1651061da546Spatrick INVALID_NUB_REGNUM, INVALID_NUB_REGNUM
1652061da546Spatrick #define DEFINE_VFP_D_IDX(idx) \
1653061da546Spatrick e_regSetVFP, vfp_d##idx, "d" #idx, NULL, IEEE754, FLOAT_FORMAT, 8, \
1654061da546Spatrick VFP_D_OFFSET_IDX(idx), INVALID_NUB_REGNUM, dwarf_d##idx, \
1655061da546Spatrick INVALID_NUB_REGNUM, INVALID_NUB_REGNUM
1656061da546Spatrick #define DEFINE_VFP_Q_IDX(idx) \
1657061da546Spatrick e_regSetVFP, vfp_q##idx, "q" #idx, NULL, Vector, VectorOfUInt8, 16, \
1658061da546Spatrick VFP_Q_OFFSET_IDX(idx), INVALID_NUB_REGNUM, dwarf_q##idx, \
1659061da546Spatrick INVALID_NUB_REGNUM, INVALID_NUB_REGNUM
1660061da546Spatrick
1661061da546Spatrick // Floating point registers
1662061da546Spatrick const DNBRegisterInfo DNBArchMachARM::g_vfp_registers[] = {
1663061da546Spatrick {DEFINE_VFP_S_IDX(0), g_contained_q0, g_invalidate_q0},
1664061da546Spatrick {DEFINE_VFP_S_IDX(1), g_contained_q0, g_invalidate_q0},
1665061da546Spatrick {DEFINE_VFP_S_IDX(2), g_contained_q0, g_invalidate_q0},
1666061da546Spatrick {DEFINE_VFP_S_IDX(3), g_contained_q0, g_invalidate_q0},
1667061da546Spatrick {DEFINE_VFP_S_IDX(4), g_contained_q1, g_invalidate_q1},
1668061da546Spatrick {DEFINE_VFP_S_IDX(5), g_contained_q1, g_invalidate_q1},
1669061da546Spatrick {DEFINE_VFP_S_IDX(6), g_contained_q1, g_invalidate_q1},
1670061da546Spatrick {DEFINE_VFP_S_IDX(7), g_contained_q1, g_invalidate_q1},
1671061da546Spatrick {DEFINE_VFP_S_IDX(8), g_contained_q2, g_invalidate_q2},
1672061da546Spatrick {DEFINE_VFP_S_IDX(9), g_contained_q2, g_invalidate_q2},
1673061da546Spatrick {DEFINE_VFP_S_IDX(10), g_contained_q2, g_invalidate_q2},
1674061da546Spatrick {DEFINE_VFP_S_IDX(11), g_contained_q2, g_invalidate_q2},
1675061da546Spatrick {DEFINE_VFP_S_IDX(12), g_contained_q3, g_invalidate_q3},
1676061da546Spatrick {DEFINE_VFP_S_IDX(13), g_contained_q3, g_invalidate_q3},
1677061da546Spatrick {DEFINE_VFP_S_IDX(14), g_contained_q3, g_invalidate_q3},
1678061da546Spatrick {DEFINE_VFP_S_IDX(15), g_contained_q3, g_invalidate_q3},
1679061da546Spatrick {DEFINE_VFP_S_IDX(16), g_contained_q4, g_invalidate_q4},
1680061da546Spatrick {DEFINE_VFP_S_IDX(17), g_contained_q4, g_invalidate_q4},
1681061da546Spatrick {DEFINE_VFP_S_IDX(18), g_contained_q4, g_invalidate_q4},
1682061da546Spatrick {DEFINE_VFP_S_IDX(19), g_contained_q4, g_invalidate_q4},
1683061da546Spatrick {DEFINE_VFP_S_IDX(20), g_contained_q5, g_invalidate_q5},
1684061da546Spatrick {DEFINE_VFP_S_IDX(21), g_contained_q5, g_invalidate_q5},
1685061da546Spatrick {DEFINE_VFP_S_IDX(22), g_contained_q5, g_invalidate_q5},
1686061da546Spatrick {DEFINE_VFP_S_IDX(23), g_contained_q5, g_invalidate_q5},
1687061da546Spatrick {DEFINE_VFP_S_IDX(24), g_contained_q6, g_invalidate_q6},
1688061da546Spatrick {DEFINE_VFP_S_IDX(25), g_contained_q6, g_invalidate_q6},
1689061da546Spatrick {DEFINE_VFP_S_IDX(26), g_contained_q6, g_invalidate_q6},
1690061da546Spatrick {DEFINE_VFP_S_IDX(27), g_contained_q6, g_invalidate_q6},
1691061da546Spatrick {DEFINE_VFP_S_IDX(28), g_contained_q7, g_invalidate_q7},
1692061da546Spatrick {DEFINE_VFP_S_IDX(29), g_contained_q7, g_invalidate_q7},
1693061da546Spatrick {DEFINE_VFP_S_IDX(30), g_contained_q7, g_invalidate_q7},
1694061da546Spatrick {DEFINE_VFP_S_IDX(31), g_contained_q7, g_invalidate_q7},
1695061da546Spatrick
1696061da546Spatrick {DEFINE_VFP_D_IDX(0), g_contained_q0, g_invalidate_q0},
1697061da546Spatrick {DEFINE_VFP_D_IDX(1), g_contained_q0, g_invalidate_q0},
1698061da546Spatrick {DEFINE_VFP_D_IDX(2), g_contained_q1, g_invalidate_q1},
1699061da546Spatrick {DEFINE_VFP_D_IDX(3), g_contained_q1, g_invalidate_q1},
1700061da546Spatrick {DEFINE_VFP_D_IDX(4), g_contained_q2, g_invalidate_q2},
1701061da546Spatrick {DEFINE_VFP_D_IDX(5), g_contained_q2, g_invalidate_q2},
1702061da546Spatrick {DEFINE_VFP_D_IDX(6), g_contained_q3, g_invalidate_q3},
1703061da546Spatrick {DEFINE_VFP_D_IDX(7), g_contained_q3, g_invalidate_q3},
1704061da546Spatrick {DEFINE_VFP_D_IDX(8), g_contained_q4, g_invalidate_q4},
1705061da546Spatrick {DEFINE_VFP_D_IDX(9), g_contained_q4, g_invalidate_q4},
1706061da546Spatrick {DEFINE_VFP_D_IDX(10), g_contained_q5, g_invalidate_q5},
1707061da546Spatrick {DEFINE_VFP_D_IDX(11), g_contained_q5, g_invalidate_q5},
1708061da546Spatrick {DEFINE_VFP_D_IDX(12), g_contained_q6, g_invalidate_q6},
1709061da546Spatrick {DEFINE_VFP_D_IDX(13), g_contained_q6, g_invalidate_q6},
1710061da546Spatrick {DEFINE_VFP_D_IDX(14), g_contained_q7, g_invalidate_q7},
1711061da546Spatrick {DEFINE_VFP_D_IDX(15), g_contained_q7, g_invalidate_q7},
1712061da546Spatrick {DEFINE_VFP_D_IDX(16), g_contained_q8, g_invalidate_q8},
1713061da546Spatrick {DEFINE_VFP_D_IDX(17), g_contained_q8, g_invalidate_q8},
1714061da546Spatrick {DEFINE_VFP_D_IDX(18), g_contained_q9, g_invalidate_q9},
1715061da546Spatrick {DEFINE_VFP_D_IDX(19), g_contained_q9, g_invalidate_q9},
1716061da546Spatrick {DEFINE_VFP_D_IDX(20), g_contained_q10, g_invalidate_q10},
1717061da546Spatrick {DEFINE_VFP_D_IDX(21), g_contained_q10, g_invalidate_q10},
1718061da546Spatrick {DEFINE_VFP_D_IDX(22), g_contained_q11, g_invalidate_q11},
1719061da546Spatrick {DEFINE_VFP_D_IDX(23), g_contained_q11, g_invalidate_q11},
1720061da546Spatrick {DEFINE_VFP_D_IDX(24), g_contained_q12, g_invalidate_q12},
1721061da546Spatrick {DEFINE_VFP_D_IDX(25), g_contained_q12, g_invalidate_q12},
1722061da546Spatrick {DEFINE_VFP_D_IDX(26), g_contained_q13, g_invalidate_q13},
1723061da546Spatrick {DEFINE_VFP_D_IDX(27), g_contained_q13, g_invalidate_q13},
1724061da546Spatrick {DEFINE_VFP_D_IDX(28), g_contained_q14, g_invalidate_q14},
1725061da546Spatrick {DEFINE_VFP_D_IDX(29), g_contained_q14, g_invalidate_q14},
1726061da546Spatrick {DEFINE_VFP_D_IDX(30), g_contained_q15, g_invalidate_q15},
1727061da546Spatrick {DEFINE_VFP_D_IDX(31), g_contained_q15, g_invalidate_q15},
1728061da546Spatrick
1729061da546Spatrick {DEFINE_VFP_Q_IDX(0), NULL, g_invalidate_q0},
1730061da546Spatrick {DEFINE_VFP_Q_IDX(1), NULL, g_invalidate_q1},
1731061da546Spatrick {DEFINE_VFP_Q_IDX(2), NULL, g_invalidate_q2},
1732061da546Spatrick {DEFINE_VFP_Q_IDX(3), NULL, g_invalidate_q3},
1733061da546Spatrick {DEFINE_VFP_Q_IDX(4), NULL, g_invalidate_q4},
1734061da546Spatrick {DEFINE_VFP_Q_IDX(5), NULL, g_invalidate_q5},
1735061da546Spatrick {DEFINE_VFP_Q_IDX(6), NULL, g_invalidate_q6},
1736061da546Spatrick {DEFINE_VFP_Q_IDX(7), NULL, g_invalidate_q7},
1737061da546Spatrick {DEFINE_VFP_Q_IDX(8), NULL, g_invalidate_q8},
1738061da546Spatrick {DEFINE_VFP_Q_IDX(9), NULL, g_invalidate_q9},
1739061da546Spatrick {DEFINE_VFP_Q_IDX(10), NULL, g_invalidate_q10},
1740061da546Spatrick {DEFINE_VFP_Q_IDX(11), NULL, g_invalidate_q11},
1741061da546Spatrick {DEFINE_VFP_Q_IDX(12), NULL, g_invalidate_q12},
1742061da546Spatrick {DEFINE_VFP_Q_IDX(13), NULL, g_invalidate_q13},
1743061da546Spatrick {DEFINE_VFP_Q_IDX(14), NULL, g_invalidate_q14},
1744061da546Spatrick {DEFINE_VFP_Q_IDX(15), NULL, g_invalidate_q15},
1745061da546Spatrick
1746061da546Spatrick #if defined(__arm64__) || defined(__aarch64__)
1747061da546Spatrick {e_regSetVFP, vfp_fpsr, "fpsr", NULL, Uint, Hex, 4, VFP_OFFSET_NAME(fpsr),
1748061da546Spatrick INVALID_NUB_REGNUM, INVALID_NUB_REGNUM, INVALID_NUB_REGNUM,
1749061da546Spatrick INVALID_NUB_REGNUM, NULL, NULL},
1750061da546Spatrick {e_regSetVFP, vfp_fpcr, "fpcr", NULL, Uint, Hex, 4, VFP_OFFSET_NAME(fpcr),
1751061da546Spatrick INVALID_NUB_REGNUM, INVALID_NUB_REGNUM, INVALID_NUB_REGNUM,
1752061da546Spatrick INVALID_NUB_REGNUM, NULL, NULL}
1753061da546Spatrick #else
1754061da546Spatrick {e_regSetVFP, vfp_fpscr, "fpscr", NULL, Uint, Hex, 4,
1755061da546Spatrick VFP_OFFSET_NAME(fpscr), INVALID_NUB_REGNUM, INVALID_NUB_REGNUM,
1756061da546Spatrick INVALID_NUB_REGNUM, INVALID_NUB_REGNUM, NULL, NULL}
1757061da546Spatrick #endif
1758061da546Spatrick };
1759061da546Spatrick
1760061da546Spatrick // Exception registers
1761061da546Spatrick
1762061da546Spatrick const DNBRegisterInfo DNBArchMachARM::g_exc_registers[] = {
1763061da546Spatrick {e_regSetVFP, exc_exception, "exception", NULL, Uint, Hex, 4,
1764061da546Spatrick EXC_OFFSET(exception), INVALID_NUB_REGNUM, INVALID_NUB_REGNUM,
1765be691f3bSpatrick INVALID_NUB_REGNUM, INVALID_NUB_REGNUM, NULL, NULL},
1766061da546Spatrick {e_regSetVFP, exc_fsr, "fsr", NULL, Uint, Hex, 4, EXC_OFFSET(fsr),
1767061da546Spatrick INVALID_NUB_REGNUM, INVALID_NUB_REGNUM, INVALID_NUB_REGNUM,
1768be691f3bSpatrick INVALID_NUB_REGNUM, NULL, NULL},
1769061da546Spatrick {e_regSetVFP, exc_far, "far", NULL, Uint, Hex, 4, EXC_OFFSET(far),
1770061da546Spatrick INVALID_NUB_REGNUM, INVALID_NUB_REGNUM, INVALID_NUB_REGNUM,
1771be691f3bSpatrick INVALID_NUB_REGNUM, NULL, NULL}};
1772061da546Spatrick
1773061da546Spatrick // Number of registers in each register set
1774061da546Spatrick const size_t DNBArchMachARM::k_num_gpr_registers =
1775061da546Spatrick sizeof(g_gpr_registers) / sizeof(DNBRegisterInfo);
1776061da546Spatrick const size_t DNBArchMachARM::k_num_vfp_registers =
1777061da546Spatrick sizeof(g_vfp_registers) / sizeof(DNBRegisterInfo);
1778061da546Spatrick const size_t DNBArchMachARM::k_num_exc_registers =
1779061da546Spatrick sizeof(g_exc_registers) / sizeof(DNBRegisterInfo);
1780061da546Spatrick const size_t DNBArchMachARM::k_num_all_registers =
1781061da546Spatrick k_num_gpr_registers + k_num_vfp_registers + k_num_exc_registers;
1782061da546Spatrick
1783061da546Spatrick // Register set definitions. The first definitions at register set index
1784061da546Spatrick // of zero is for all registers, followed by other registers sets. The
1785061da546Spatrick // register information for the all register set need not be filled in.
1786061da546Spatrick const DNBRegisterSetInfo DNBArchMachARM::g_reg_sets[] = {
1787061da546Spatrick {"ARM Registers", NULL, k_num_all_registers},
1788061da546Spatrick {"General Purpose Registers", g_gpr_registers, k_num_gpr_registers},
1789061da546Spatrick {"Floating Point Registers", g_vfp_registers, k_num_vfp_registers},
1790061da546Spatrick {"Exception State Registers", g_exc_registers, k_num_exc_registers}};
1791061da546Spatrick // Total number of register sets for this architecture
1792061da546Spatrick const size_t DNBArchMachARM::k_num_register_sets =
1793061da546Spatrick sizeof(g_reg_sets) / sizeof(DNBRegisterSetInfo);
1794061da546Spatrick
1795061da546Spatrick const DNBRegisterSetInfo *
GetRegisterSetInfo(nub_size_t * num_reg_sets)1796061da546Spatrick DNBArchMachARM::GetRegisterSetInfo(nub_size_t *num_reg_sets) {
1797061da546Spatrick *num_reg_sets = k_num_register_sets;
1798061da546Spatrick return g_reg_sets;
1799061da546Spatrick }
1800061da546Spatrick
GetRegisterValue(uint32_t set,uint32_t reg,DNBRegisterValue * value)1801061da546Spatrick bool DNBArchMachARM::GetRegisterValue(uint32_t set, uint32_t reg,
1802061da546Spatrick DNBRegisterValue *value) {
1803061da546Spatrick if (set == REGISTER_SET_GENERIC) {
1804061da546Spatrick switch (reg) {
1805061da546Spatrick case GENERIC_REGNUM_PC: // Program Counter
1806061da546Spatrick set = e_regSetGPR;
1807061da546Spatrick reg = gpr_pc;
1808061da546Spatrick break;
1809061da546Spatrick
1810061da546Spatrick case GENERIC_REGNUM_SP: // Stack Pointer
1811061da546Spatrick set = e_regSetGPR;
1812061da546Spatrick reg = gpr_sp;
1813061da546Spatrick break;
1814061da546Spatrick
1815061da546Spatrick case GENERIC_REGNUM_FP: // Frame Pointer
1816061da546Spatrick set = e_regSetGPR;
1817061da546Spatrick reg = gpr_r7; // is this the right reg?
1818061da546Spatrick break;
1819061da546Spatrick
1820061da546Spatrick case GENERIC_REGNUM_RA: // Return Address
1821061da546Spatrick set = e_regSetGPR;
1822061da546Spatrick reg = gpr_lr;
1823061da546Spatrick break;
1824061da546Spatrick
1825061da546Spatrick case GENERIC_REGNUM_FLAGS: // Processor flags register
1826061da546Spatrick set = e_regSetGPR;
1827061da546Spatrick reg = gpr_cpsr;
1828061da546Spatrick break;
1829061da546Spatrick
1830061da546Spatrick default:
1831061da546Spatrick return false;
1832061da546Spatrick }
1833061da546Spatrick }
1834061da546Spatrick
1835061da546Spatrick if (GetRegisterState(set, false) != KERN_SUCCESS)
1836061da546Spatrick return false;
1837061da546Spatrick
1838061da546Spatrick const DNBRegisterInfo *regInfo = m_thread->GetRegisterInfo(set, reg);
1839061da546Spatrick if (regInfo) {
1840061da546Spatrick value->info = *regInfo;
1841061da546Spatrick switch (set) {
1842061da546Spatrick case e_regSetGPR:
1843061da546Spatrick if (reg < k_num_gpr_registers) {
1844061da546Spatrick value->value.uint32 = m_state.context.gpr.__r[reg];
1845061da546Spatrick return true;
1846061da546Spatrick }
1847061da546Spatrick break;
1848061da546Spatrick
1849061da546Spatrick case e_regSetVFP:
1850061da546Spatrick // "reg" is an index into the floating point register set at this point.
1851061da546Spatrick // We need to translate it up so entry 0 in the fp reg set is the same as
1852061da546Spatrick // vfp_s0
1853061da546Spatrick // in the enumerated values for case statement below.
1854061da546Spatrick if (reg >= vfp_s0 && reg <= vfp_s31) {
1855061da546Spatrick #if defined(__arm64__) || defined(__aarch64__)
1856061da546Spatrick uint32_t *s_reg =
1857061da546Spatrick ((uint32_t *)&m_state.context.vfp.__v[0]) + (reg - vfp_s0);
1858061da546Spatrick memcpy(&value->value.v_uint8, s_reg, 4);
1859061da546Spatrick #else
1860061da546Spatrick value->value.uint32 = m_state.context.vfp.__r[reg];
1861061da546Spatrick #endif
1862061da546Spatrick return true;
1863061da546Spatrick } else if (reg >= vfp_d0 && reg <= vfp_d31) {
1864061da546Spatrick #if defined(__arm64__) || defined(__aarch64__)
1865061da546Spatrick uint64_t *d_reg =
1866061da546Spatrick ((uint64_t *)&m_state.context.vfp.__v[0]) + (reg - vfp_d0);
1867061da546Spatrick memcpy(&value->value.v_uint8, d_reg, 8);
1868061da546Spatrick #else
1869061da546Spatrick uint32_t d_reg_idx = reg - vfp_d0;
1870061da546Spatrick uint32_t s_reg_idx = d_reg_idx * 2;
1871061da546Spatrick value->value.v_sint32[0] = m_state.context.vfp.__r[s_reg_idx + 0];
1872061da546Spatrick value->value.v_sint32[1] = m_state.context.vfp.__r[s_reg_idx + 1];
1873061da546Spatrick #endif
1874061da546Spatrick return true;
1875061da546Spatrick } else if (reg >= vfp_q0 && reg <= vfp_q15) {
1876061da546Spatrick #if defined(__arm64__) || defined(__aarch64__)
1877061da546Spatrick memcpy(&value->value.v_uint8,
1878061da546Spatrick (uint8_t *)&m_state.context.vfp.__v[reg - vfp_q0], 16);
1879061da546Spatrick #else
1880061da546Spatrick uint32_t s_reg_idx = (reg - vfp_q0) * 4;
1881061da546Spatrick memcpy(&value->value.v_uint8,
1882061da546Spatrick (uint8_t *)&m_state.context.vfp.__r[s_reg_idx], 16);
1883061da546Spatrick #endif
1884061da546Spatrick return true;
1885061da546Spatrick }
1886061da546Spatrick #if defined(__arm64__) || defined(__aarch64__)
1887061da546Spatrick else if (reg == vfp_fpsr) {
1888061da546Spatrick value->value.uint32 = m_state.context.vfp.__fpsr;
1889061da546Spatrick return true;
1890061da546Spatrick } else if (reg == vfp_fpcr) {
1891061da546Spatrick value->value.uint32 = m_state.context.vfp.__fpcr;
1892061da546Spatrick return true;
1893061da546Spatrick }
1894061da546Spatrick #else
1895061da546Spatrick else if (reg == vfp_fpscr) {
1896061da546Spatrick value->value.uint32 = m_state.context.vfp.__fpscr;
1897061da546Spatrick return true;
1898061da546Spatrick }
1899061da546Spatrick #endif
1900061da546Spatrick break;
1901061da546Spatrick
1902061da546Spatrick case e_regSetEXC:
1903061da546Spatrick if (reg < k_num_exc_registers) {
1904061da546Spatrick value->value.uint32 = (&m_state.context.exc.__exception)[reg];
1905061da546Spatrick return true;
1906061da546Spatrick }
1907061da546Spatrick break;
1908061da546Spatrick }
1909061da546Spatrick }
1910061da546Spatrick return false;
1911061da546Spatrick }
1912061da546Spatrick
SetRegisterValue(uint32_t set,uint32_t reg,const DNBRegisterValue * value)1913061da546Spatrick bool DNBArchMachARM::SetRegisterValue(uint32_t set, uint32_t reg,
1914061da546Spatrick const DNBRegisterValue *value) {
1915061da546Spatrick if (set == REGISTER_SET_GENERIC) {
1916061da546Spatrick switch (reg) {
1917061da546Spatrick case GENERIC_REGNUM_PC: // Program Counter
1918061da546Spatrick set = e_regSetGPR;
1919061da546Spatrick reg = gpr_pc;
1920061da546Spatrick break;
1921061da546Spatrick
1922061da546Spatrick case GENERIC_REGNUM_SP: // Stack Pointer
1923061da546Spatrick set = e_regSetGPR;
1924061da546Spatrick reg = gpr_sp;
1925061da546Spatrick break;
1926061da546Spatrick
1927061da546Spatrick case GENERIC_REGNUM_FP: // Frame Pointer
1928061da546Spatrick set = e_regSetGPR;
1929061da546Spatrick reg = gpr_r7;
1930061da546Spatrick break;
1931061da546Spatrick
1932061da546Spatrick case GENERIC_REGNUM_RA: // Return Address
1933061da546Spatrick set = e_regSetGPR;
1934061da546Spatrick reg = gpr_lr;
1935061da546Spatrick break;
1936061da546Spatrick
1937061da546Spatrick case GENERIC_REGNUM_FLAGS: // Processor flags register
1938061da546Spatrick set = e_regSetGPR;
1939061da546Spatrick reg = gpr_cpsr;
1940061da546Spatrick break;
1941061da546Spatrick
1942061da546Spatrick default:
1943061da546Spatrick return false;
1944061da546Spatrick }
1945061da546Spatrick }
1946061da546Spatrick
1947061da546Spatrick if (GetRegisterState(set, false) != KERN_SUCCESS)
1948061da546Spatrick return false;
1949061da546Spatrick
1950061da546Spatrick bool success = false;
1951061da546Spatrick const DNBRegisterInfo *regInfo = m_thread->GetRegisterInfo(set, reg);
1952061da546Spatrick if (regInfo) {
1953061da546Spatrick switch (set) {
1954061da546Spatrick case e_regSetGPR:
1955061da546Spatrick if (reg < k_num_gpr_registers) {
1956061da546Spatrick m_state.context.gpr.__r[reg] = value->value.uint32;
1957061da546Spatrick success = true;
1958061da546Spatrick }
1959061da546Spatrick break;
1960061da546Spatrick
1961061da546Spatrick case e_regSetVFP:
1962061da546Spatrick // "reg" is an index into the floating point register set at this point.
1963061da546Spatrick // We need to translate it up so entry 0 in the fp reg set is the same as
1964061da546Spatrick // vfp_s0
1965061da546Spatrick // in the enumerated values for case statement below.
1966061da546Spatrick if (reg >= vfp_s0 && reg <= vfp_s31) {
1967061da546Spatrick #if defined(__arm64__) || defined(__aarch64__)
1968061da546Spatrick uint32_t *s_reg =
1969061da546Spatrick ((uint32_t *)&m_state.context.vfp.__v[0]) + (reg - vfp_s0);
1970061da546Spatrick memcpy(s_reg, &value->value.v_uint8, 4);
1971061da546Spatrick #else
1972061da546Spatrick m_state.context.vfp.__r[reg] = value->value.uint32;
1973061da546Spatrick #endif
1974061da546Spatrick success = true;
1975061da546Spatrick } else if (reg >= vfp_d0 && reg <= vfp_d31) {
1976061da546Spatrick #if defined(__arm64__) || defined(__aarch64__)
1977061da546Spatrick uint64_t *d_reg =
1978061da546Spatrick ((uint64_t *)&m_state.context.vfp.__v[0]) + (reg - vfp_d0);
1979061da546Spatrick memcpy(d_reg, &value->value.v_uint8, 8);
1980061da546Spatrick #else
1981061da546Spatrick uint32_t d_reg_idx = reg - vfp_d0;
1982061da546Spatrick uint32_t s_reg_idx = d_reg_idx * 2;
1983061da546Spatrick m_state.context.vfp.__r[s_reg_idx + 0] = value->value.v_sint32[0];
1984061da546Spatrick m_state.context.vfp.__r[s_reg_idx + 1] = value->value.v_sint32[1];
1985061da546Spatrick #endif
1986061da546Spatrick success = true;
1987061da546Spatrick } else if (reg >= vfp_q0 && reg <= vfp_q15) {
1988061da546Spatrick #if defined(__arm64__) || defined(__aarch64__)
1989061da546Spatrick memcpy((uint8_t *)&m_state.context.vfp.__v[reg - vfp_q0],
1990061da546Spatrick &value->value.v_uint8, 16);
1991061da546Spatrick #else
1992061da546Spatrick uint32_t s_reg_idx = (reg - vfp_q0) * 4;
1993061da546Spatrick memcpy((uint8_t *)&m_state.context.vfp.__r[s_reg_idx],
1994061da546Spatrick &value->value.v_uint8, 16);
1995061da546Spatrick #endif
1996061da546Spatrick success = true;
1997061da546Spatrick }
1998061da546Spatrick #if defined(__arm64__) || defined(__aarch64__)
1999061da546Spatrick else if (reg == vfp_fpsr) {
2000061da546Spatrick m_state.context.vfp.__fpsr = value->value.uint32;
2001061da546Spatrick success = true;
2002061da546Spatrick } else if (reg == vfp_fpcr) {
2003061da546Spatrick m_state.context.vfp.__fpcr = value->value.uint32;
2004061da546Spatrick success = true;
2005061da546Spatrick }
2006061da546Spatrick #else
2007061da546Spatrick else if (reg == vfp_fpscr) {
2008061da546Spatrick m_state.context.vfp.__fpscr = value->value.uint32;
2009061da546Spatrick success = true;
2010061da546Spatrick }
2011061da546Spatrick #endif
2012061da546Spatrick break;
2013061da546Spatrick
2014061da546Spatrick case e_regSetEXC:
2015061da546Spatrick if (reg < k_num_exc_registers) {
2016061da546Spatrick (&m_state.context.exc.__exception)[reg] = value->value.uint32;
2017061da546Spatrick success = true;
2018061da546Spatrick }
2019061da546Spatrick break;
2020061da546Spatrick }
2021061da546Spatrick }
2022061da546Spatrick if (success)
2023061da546Spatrick return SetRegisterState(set) == KERN_SUCCESS;
2024061da546Spatrick return false;
2025061da546Spatrick }
2026061da546Spatrick
GetRegisterState(int set,bool force)2027061da546Spatrick kern_return_t DNBArchMachARM::GetRegisterState(int set, bool force) {
2028061da546Spatrick switch (set) {
2029061da546Spatrick case e_regSetALL:
2030061da546Spatrick return GetGPRState(force) | GetVFPState(force) | GetEXCState(force) |
2031061da546Spatrick GetDBGState(force);
2032061da546Spatrick case e_regSetGPR:
2033061da546Spatrick return GetGPRState(force);
2034061da546Spatrick case e_regSetVFP:
2035061da546Spatrick return GetVFPState(force);
2036061da546Spatrick case e_regSetEXC:
2037061da546Spatrick return GetEXCState(force);
2038061da546Spatrick case e_regSetDBG:
2039061da546Spatrick return GetDBGState(force);
2040061da546Spatrick default:
2041061da546Spatrick break;
2042061da546Spatrick }
2043061da546Spatrick return KERN_INVALID_ARGUMENT;
2044061da546Spatrick }
2045061da546Spatrick
SetRegisterState(int set)2046061da546Spatrick kern_return_t DNBArchMachARM::SetRegisterState(int set) {
2047061da546Spatrick // Make sure we have a valid context to set.
2048061da546Spatrick kern_return_t err = GetRegisterState(set, false);
2049061da546Spatrick if (err != KERN_SUCCESS)
2050061da546Spatrick return err;
2051061da546Spatrick
2052061da546Spatrick switch (set) {
2053061da546Spatrick case e_regSetALL:
2054061da546Spatrick return SetGPRState() | SetVFPState() | SetEXCState() | SetDBGState(false);
2055061da546Spatrick case e_regSetGPR:
2056061da546Spatrick return SetGPRState();
2057061da546Spatrick case e_regSetVFP:
2058061da546Spatrick return SetVFPState();
2059061da546Spatrick case e_regSetEXC:
2060061da546Spatrick return SetEXCState();
2061061da546Spatrick case e_regSetDBG:
2062061da546Spatrick return SetDBGState(false);
2063061da546Spatrick default:
2064061da546Spatrick break;
2065061da546Spatrick }
2066061da546Spatrick return KERN_INVALID_ARGUMENT;
2067061da546Spatrick }
2068061da546Spatrick
RegisterSetStateIsValid(int set) const2069061da546Spatrick bool DNBArchMachARM::RegisterSetStateIsValid(int set) const {
2070061da546Spatrick return m_state.RegsAreValid(set);
2071061da546Spatrick }
2072061da546Spatrick
GetRegisterContext(void * buf,nub_size_t buf_len)2073061da546Spatrick nub_size_t DNBArchMachARM::GetRegisterContext(void *buf, nub_size_t buf_len) {
2074061da546Spatrick nub_size_t size = sizeof(m_state.context.gpr) + sizeof(m_state.context.vfp) +
2075061da546Spatrick sizeof(m_state.context.exc);
2076061da546Spatrick
2077061da546Spatrick if (buf && buf_len) {
2078061da546Spatrick if (size > buf_len)
2079061da546Spatrick size = buf_len;
2080061da546Spatrick
2081061da546Spatrick bool force = false;
2082061da546Spatrick if (GetGPRState(force) | GetVFPState(force) | GetEXCState(force))
2083061da546Spatrick return 0;
2084061da546Spatrick
2085061da546Spatrick // Copy each struct individually to avoid any padding that might be between
2086061da546Spatrick // the structs in m_state.context
2087061da546Spatrick uint8_t *p = (uint8_t *)buf;
2088061da546Spatrick ::memcpy(p, &m_state.context.gpr, sizeof(m_state.context.gpr));
2089061da546Spatrick p += sizeof(m_state.context.gpr);
2090061da546Spatrick ::memcpy(p, &m_state.context.vfp, sizeof(m_state.context.vfp));
2091061da546Spatrick p += sizeof(m_state.context.vfp);
2092061da546Spatrick ::memcpy(p, &m_state.context.exc, sizeof(m_state.context.exc));
2093061da546Spatrick p += sizeof(m_state.context.exc);
2094061da546Spatrick
2095061da546Spatrick size_t bytes_written = p - (uint8_t *)buf;
2096061da546Spatrick UNUSED_IF_ASSERT_DISABLED(bytes_written);
2097061da546Spatrick assert(bytes_written == size);
2098061da546Spatrick }
2099061da546Spatrick DNBLogThreadedIf(
2100061da546Spatrick LOG_THREAD,
2101061da546Spatrick "DNBArchMachARM::GetRegisterContext (buf = %p, len = %llu) => %llu", buf,
2102061da546Spatrick (uint64_t)buf_len, (uint64_t)size);
2103061da546Spatrick // Return the size of the register context even if NULL was passed in
2104061da546Spatrick return size;
2105061da546Spatrick }
2106061da546Spatrick
SetRegisterContext(const void * buf,nub_size_t buf_len)2107061da546Spatrick nub_size_t DNBArchMachARM::SetRegisterContext(const void *buf,
2108061da546Spatrick nub_size_t buf_len) {
2109061da546Spatrick nub_size_t size = sizeof(m_state.context.gpr) + sizeof(m_state.context.vfp) +
2110061da546Spatrick sizeof(m_state.context.exc);
2111061da546Spatrick
2112061da546Spatrick if (buf == NULL || buf_len == 0)
2113061da546Spatrick size = 0;
2114061da546Spatrick
2115061da546Spatrick if (size) {
2116061da546Spatrick if (size > buf_len)
2117061da546Spatrick size = buf_len;
2118061da546Spatrick
2119061da546Spatrick // Copy each struct individually to avoid any padding that might be between
2120061da546Spatrick // the structs in m_state.context
2121be691f3bSpatrick uint8_t *p = const_cast<uint8_t*>(reinterpret_cast<const uint8_t *>(buf));
2122061da546Spatrick ::memcpy(&m_state.context.gpr, p, sizeof(m_state.context.gpr));
2123061da546Spatrick p += sizeof(m_state.context.gpr);
2124061da546Spatrick ::memcpy(&m_state.context.vfp, p, sizeof(m_state.context.vfp));
2125061da546Spatrick p += sizeof(m_state.context.vfp);
2126061da546Spatrick ::memcpy(&m_state.context.exc, p, sizeof(m_state.context.exc));
2127061da546Spatrick p += sizeof(m_state.context.exc);
2128061da546Spatrick
2129be691f3bSpatrick size_t bytes_written = p - reinterpret_cast<const uint8_t *>(buf);
2130061da546Spatrick UNUSED_IF_ASSERT_DISABLED(bytes_written);
2131061da546Spatrick assert(bytes_written == size);
2132061da546Spatrick
2133061da546Spatrick if (SetGPRState() | SetVFPState() | SetEXCState())
2134061da546Spatrick return 0;
2135061da546Spatrick }
2136061da546Spatrick DNBLogThreadedIf(
2137061da546Spatrick LOG_THREAD,
2138061da546Spatrick "DNBArchMachARM::SetRegisterContext (buf = %p, len = %llu) => %llu", buf,
2139061da546Spatrick (uint64_t)buf_len, (uint64_t)size);
2140061da546Spatrick return size;
2141061da546Spatrick }
2142061da546Spatrick
SaveRegisterState()2143061da546Spatrick uint32_t DNBArchMachARM::SaveRegisterState() {
2144061da546Spatrick kern_return_t kret = ::thread_abort_safely(m_thread->MachPortNumber());
2145061da546Spatrick DNBLogThreadedIf(
2146061da546Spatrick LOG_THREAD, "thread = 0x%4.4x calling thread_abort_safely (tid) => %u "
2147061da546Spatrick "(SetGPRState() for stop_count = %u)",
2148061da546Spatrick m_thread->MachPortNumber(), kret, m_thread->Process()->StopCount());
2149061da546Spatrick
2150061da546Spatrick // Always re-read the registers because above we call thread_abort_safely();
2151061da546Spatrick bool force = true;
2152061da546Spatrick
2153061da546Spatrick if ((kret = GetGPRState(force)) != KERN_SUCCESS) {
2154061da546Spatrick DNBLogThreadedIf(LOG_THREAD, "DNBArchMachARM::SaveRegisterState () error: "
2155061da546Spatrick "GPR regs failed to read: %u ",
2156061da546Spatrick kret);
2157061da546Spatrick } else if ((kret = GetVFPState(force)) != KERN_SUCCESS) {
2158061da546Spatrick DNBLogThreadedIf(LOG_THREAD, "DNBArchMachARM::SaveRegisterState () error: "
2159061da546Spatrick "%s regs failed to read: %u",
2160061da546Spatrick "VFP", kret);
2161061da546Spatrick } else {
2162061da546Spatrick const uint32_t save_id = GetNextRegisterStateSaveID();
2163061da546Spatrick m_saved_register_states[save_id] = m_state.context;
2164061da546Spatrick return save_id;
2165061da546Spatrick }
2166061da546Spatrick return UINT32_MAX;
2167061da546Spatrick }
2168061da546Spatrick
RestoreRegisterState(uint32_t save_id)2169061da546Spatrick bool DNBArchMachARM::RestoreRegisterState(uint32_t save_id) {
2170061da546Spatrick SaveRegisterStates::iterator pos = m_saved_register_states.find(save_id);
2171061da546Spatrick if (pos != m_saved_register_states.end()) {
2172061da546Spatrick m_state.context.gpr = pos->second.gpr;
2173061da546Spatrick m_state.context.vfp = pos->second.vfp;
2174061da546Spatrick kern_return_t kret;
2175061da546Spatrick bool success = true;
2176061da546Spatrick if ((kret = SetGPRState()) != KERN_SUCCESS) {
2177061da546Spatrick DNBLogThreadedIf(LOG_THREAD, "DNBArchMachARM::RestoreRegisterState "
2178061da546Spatrick "(save_id = %u) error: GPR regs failed to "
2179061da546Spatrick "write: %u",
2180061da546Spatrick save_id, kret);
2181061da546Spatrick success = false;
2182061da546Spatrick } else if ((kret = SetVFPState()) != KERN_SUCCESS) {
2183061da546Spatrick DNBLogThreadedIf(LOG_THREAD, "DNBArchMachARM::RestoreRegisterState "
2184061da546Spatrick "(save_id = %u) error: %s regs failed to "
2185061da546Spatrick "write: %u",
2186061da546Spatrick save_id, "VFP", kret);
2187061da546Spatrick success = false;
2188061da546Spatrick }
2189061da546Spatrick m_saved_register_states.erase(pos);
2190061da546Spatrick return success;
2191061da546Spatrick }
2192061da546Spatrick return false;
2193061da546Spatrick }
2194061da546Spatrick
2195061da546Spatrick #endif // #if defined (__arm__)
2196