//===-- RegisterContextDarwin_arm.cpp ---------------------------*- C++ -*-===// // // The LLVM Compiler Infrastructure // // This file is distributed under the University of Illinois Open Source // License. See LICENSE.TXT for details. // //===----------------------------------------------------------------------===// #if defined(__APPLE__) #include "RegisterContextDarwin_arm.h" // C Includes #include #include // C++ Includes // Other libraries and framework includes #include "lldb/Core/DataBufferHeap.h" #include "lldb/Core/DataExtractor.h" #include "lldb/Core/Log.h" #include "lldb/Core/RegisterValue.h" #include "lldb/Core/Scalar.h" #include "lldb/Host/Endian.h" #include "llvm/Support/Compiler.h" #include "Plugins/Process/Utility/InstructionUtils.h" // Support building against older versions of LLVM, this macro was added // recently. #ifndef LLVM_EXTENSION #define LLVM_EXTENSION #endif // Project includes #include "ARM_GCC_Registers.h" #include "ARM_DWARF_Registers.h" using namespace lldb; using namespace lldb_private; enum { gpr_r0 = 0, gpr_r1, gpr_r2, gpr_r3, gpr_r4, gpr_r5, gpr_r6, gpr_r7, gpr_r8, gpr_r9, gpr_r10, gpr_r11, gpr_r12, gpr_r13, gpr_sp = gpr_r13, gpr_r14, gpr_lr = gpr_r14, gpr_r15, gpr_pc = gpr_r15, gpr_cpsr, fpu_s0, fpu_s1, fpu_s2, fpu_s3, fpu_s4, fpu_s5, fpu_s6, fpu_s7, fpu_s8, fpu_s9, fpu_s10, fpu_s11, fpu_s12, fpu_s13, fpu_s14, fpu_s15, fpu_s16, fpu_s17, fpu_s18, fpu_s19, fpu_s20, fpu_s21, fpu_s22, fpu_s23, fpu_s24, fpu_s25, fpu_s26, fpu_s27, fpu_s28, fpu_s29, fpu_s30, fpu_s31, fpu_fpscr, exc_exception, exc_fsr, exc_far, dbg_bvr0, dbg_bvr1, dbg_bvr2, dbg_bvr3, dbg_bvr4, dbg_bvr5, dbg_bvr6, dbg_bvr7, dbg_bvr8, dbg_bvr9, dbg_bvr10, dbg_bvr11, dbg_bvr12, dbg_bvr13, dbg_bvr14, dbg_bvr15, dbg_bcr0, dbg_bcr1, dbg_bcr2, dbg_bcr3, dbg_bcr4, dbg_bcr5, dbg_bcr6, dbg_bcr7, dbg_bcr8, dbg_bcr9, dbg_bcr10, dbg_bcr11, dbg_bcr12, dbg_bcr13, dbg_bcr14, dbg_bcr15, dbg_wvr0, dbg_wvr1, dbg_wvr2, dbg_wvr3, dbg_wvr4, dbg_wvr5, dbg_wvr6, dbg_wvr7, dbg_wvr8, dbg_wvr9, dbg_wvr10, dbg_wvr11, dbg_wvr12, dbg_wvr13, dbg_wvr14, dbg_wvr15, dbg_wcr0, dbg_wcr1, dbg_wcr2, dbg_wcr3, dbg_wcr4, dbg_wcr5, dbg_wcr6, dbg_wcr7, dbg_wcr8, dbg_wcr9, dbg_wcr10, dbg_wcr11, dbg_wcr12, dbg_wcr13, dbg_wcr14, dbg_wcr15, k_num_registers }; RegisterContextDarwin_arm::RegisterContextDarwin_arm(Thread &thread, uint32_t concrete_frame_idx) : RegisterContext(thread, concrete_frame_idx), gpr(), fpu(), exc() { uint32_t i; for (i=0; ireg[i]), DBG_OFFSET(reg[i]), eEncodingUint, eFormatHex, { LLDB_INVALID_REGNUM, LLDB_INVALID_REGNUM, LLDB_INVALID_REGNUM, LLDB_INVALID_REGNUM, dbg_##reg##i }, NULL, NULL #define REG_CONTEXT_SIZE (sizeof (RegisterContextDarwin_arm::GPR) + sizeof (RegisterContextDarwin_arm::FPU) + sizeof (RegisterContextDarwin_arm::EXC)) static RegisterInfo g_register_infos[] = { // General purpose registers // NAME ALT SZ OFFSET ENCODING FORMAT COMPILER DWARF GENERIC GDB LLDB NATIVE VALUE REGS INVALIDATE REGS // ====== ======= == ============= ============= ============ =============== =============== ========================= ===================== ============= ========== =============== { "r0", NULL, 4, GPR_OFFSET(0), eEncodingUint, eFormatHex, { gcc_r0, dwarf_r0, LLDB_INVALID_REGNUM, gdb_arm_r0, gpr_r0 }, NULL, NULL}, { "r1", NULL, 4, GPR_OFFSET(1), eEncodingUint, eFormatHex, { gcc_r1, dwarf_r1, LLDB_INVALID_REGNUM, gdb_arm_r1, gpr_r1 }, NULL, NULL}, { "r2", NULL, 4, GPR_OFFSET(2), eEncodingUint, eFormatHex, { gcc_r2, dwarf_r2, LLDB_INVALID_REGNUM, gdb_arm_r2, gpr_r2 }, NULL, NULL}, { "r3", NULL, 4, GPR_OFFSET(3), eEncodingUint, eFormatHex, { gcc_r3, dwarf_r3, LLDB_INVALID_REGNUM, gdb_arm_r3, gpr_r3 }, NULL, NULL}, { "r4", NULL, 4, GPR_OFFSET(4), eEncodingUint, eFormatHex, { gcc_r4, dwarf_r4, LLDB_INVALID_REGNUM, gdb_arm_r4, gpr_r4 }, NULL, NULL}, { "r5", NULL, 4, GPR_OFFSET(5), eEncodingUint, eFormatHex, { gcc_r5, dwarf_r5, LLDB_INVALID_REGNUM, gdb_arm_r5, gpr_r5 }, NULL, NULL}, { "r6", NULL, 4, GPR_OFFSET(6), eEncodingUint, eFormatHex, { gcc_r6, dwarf_r6, LLDB_INVALID_REGNUM, gdb_arm_r6, gpr_r6 }, NULL, NULL}, { "r7", NULL, 4, GPR_OFFSET(7), eEncodingUint, eFormatHex, { gcc_r7, dwarf_r7, LLDB_REGNUM_GENERIC_FP, gdb_arm_r7, gpr_r7 }, NULL, NULL}, { "r8", NULL, 4, GPR_OFFSET(8), eEncodingUint, eFormatHex, { gcc_r8, dwarf_r8, LLDB_INVALID_REGNUM, gdb_arm_r8, gpr_r8 }, NULL, NULL}, { "r9", NULL, 4, GPR_OFFSET(9), eEncodingUint, eFormatHex, { gcc_r9, dwarf_r9, LLDB_INVALID_REGNUM, gdb_arm_r9, gpr_r9 }, NULL, NULL}, { "r10", NULL, 4, GPR_OFFSET(10), eEncodingUint, eFormatHex, { gcc_r10, dwarf_r10, LLDB_INVALID_REGNUM, gdb_arm_r10, gpr_r10 }, NULL, NULL}, { "r11", NULL, 4, GPR_OFFSET(11), eEncodingUint, eFormatHex, { gcc_r11, dwarf_r11, LLDB_INVALID_REGNUM, gdb_arm_r11, gpr_r11 }, NULL, NULL}, { "r12", NULL, 4, GPR_OFFSET(12), eEncodingUint, eFormatHex, { gcc_r12, dwarf_r12, LLDB_INVALID_REGNUM, gdb_arm_r12, gpr_r12 }, NULL, NULL}, { "sp", "r13", 4, GPR_OFFSET(13), eEncodingUint, eFormatHex, { gcc_sp, dwarf_sp, LLDB_REGNUM_GENERIC_SP, gdb_arm_sp, gpr_sp }, NULL, NULL}, { "lr", "r14", 4, GPR_OFFSET(14), eEncodingUint, eFormatHex, { gcc_lr, dwarf_lr, LLDB_REGNUM_GENERIC_RA, gdb_arm_lr, gpr_lr }, NULL, NULL}, { "pc", "r15", 4, GPR_OFFSET(15), eEncodingUint, eFormatHex, { gcc_pc, dwarf_pc, LLDB_REGNUM_GENERIC_PC, gdb_arm_pc, gpr_pc }, NULL, NULL}, { "cpsr", "psr", 4, GPR_OFFSET(16), eEncodingUint, eFormatHex, { gcc_cpsr, dwarf_cpsr, LLDB_REGNUM_GENERIC_FLAGS, gdb_arm_cpsr, gpr_cpsr }, NULL, NULL}, { "s0", NULL, 4, FPU_OFFSET(0), eEncodingIEEE754,eFormatFloat, { LLDB_INVALID_REGNUM, dwarf_s0, LLDB_INVALID_REGNUM, gdb_arm_s0, fpu_s0 }, NULL, NULL}, { "s1", NULL, 4, FPU_OFFSET(1), eEncodingIEEE754,eFormatFloat, { LLDB_INVALID_REGNUM, dwarf_s1, LLDB_INVALID_REGNUM, gdb_arm_s1, fpu_s1 }, NULL, NULL}, { "s2", NULL, 4, FPU_OFFSET(2), eEncodingIEEE754,eFormatFloat, { LLDB_INVALID_REGNUM, dwarf_s2, LLDB_INVALID_REGNUM, gdb_arm_s2, fpu_s2 }, NULL, NULL}, { "s3", NULL, 4, FPU_OFFSET(3), eEncodingIEEE754,eFormatFloat, { LLDB_INVALID_REGNUM, dwarf_s3, LLDB_INVALID_REGNUM, gdb_arm_s3, fpu_s3 }, NULL, NULL}, { "s4", NULL, 4, FPU_OFFSET(4), eEncodingIEEE754,eFormatFloat, { LLDB_INVALID_REGNUM, dwarf_s4, LLDB_INVALID_REGNUM, gdb_arm_s4, fpu_s4 }, NULL, NULL}, { "s5", NULL, 4, FPU_OFFSET(5), eEncodingIEEE754,eFormatFloat, { LLDB_INVALID_REGNUM, dwarf_s5, LLDB_INVALID_REGNUM, gdb_arm_s5, fpu_s5 }, NULL, NULL}, { "s6", NULL, 4, FPU_OFFSET(6), eEncodingIEEE754,eFormatFloat, { LLDB_INVALID_REGNUM, dwarf_s6, LLDB_INVALID_REGNUM, gdb_arm_s6, fpu_s6 }, NULL, NULL}, { "s7", NULL, 4, FPU_OFFSET(7), eEncodingIEEE754,eFormatFloat, { LLDB_INVALID_REGNUM, dwarf_s7, LLDB_INVALID_REGNUM, gdb_arm_s7, fpu_s7 }, NULL, NULL}, { "s8", NULL, 4, FPU_OFFSET(8), eEncodingIEEE754,eFormatFloat, { LLDB_INVALID_REGNUM, dwarf_s8, LLDB_INVALID_REGNUM, gdb_arm_s8, fpu_s8 }, NULL, NULL}, { "s9", NULL, 4, FPU_OFFSET(9), eEncodingIEEE754,eFormatFloat, { LLDB_INVALID_REGNUM, dwarf_s9, LLDB_INVALID_REGNUM, gdb_arm_s9, fpu_s9 }, NULL, NULL}, { "s10", NULL, 4, FPU_OFFSET(10), eEncodingIEEE754,eFormatFloat, { LLDB_INVALID_REGNUM, dwarf_s10, LLDB_INVALID_REGNUM, gdb_arm_s10, fpu_s10 }, NULL, NULL}, { "s11", NULL, 4, FPU_OFFSET(11), eEncodingIEEE754,eFormatFloat, { LLDB_INVALID_REGNUM, dwarf_s11, LLDB_INVALID_REGNUM, gdb_arm_s11, fpu_s11 }, NULL, NULL}, { "s12", NULL, 4, FPU_OFFSET(12), eEncodingIEEE754,eFormatFloat, { LLDB_INVALID_REGNUM, dwarf_s12, LLDB_INVALID_REGNUM, gdb_arm_s12, fpu_s12 }, NULL, NULL}, { "s13", NULL, 4, FPU_OFFSET(13), eEncodingIEEE754,eFormatFloat, { LLDB_INVALID_REGNUM, dwarf_s13, LLDB_INVALID_REGNUM, gdb_arm_s13, fpu_s13 }, NULL, NULL}, { "s14", NULL, 4, FPU_OFFSET(14), eEncodingIEEE754,eFormatFloat, { LLDB_INVALID_REGNUM, dwarf_s14, LLDB_INVALID_REGNUM, gdb_arm_s14, fpu_s14 }, NULL, NULL}, { "s15", NULL, 4, FPU_OFFSET(15), eEncodingIEEE754,eFormatFloat, { LLDB_INVALID_REGNUM, dwarf_s15, LLDB_INVALID_REGNUM, gdb_arm_s15, fpu_s15 }, NULL, NULL}, { "s16", NULL, 4, FPU_OFFSET(16), eEncodingIEEE754,eFormatFloat, { LLDB_INVALID_REGNUM, dwarf_s16, LLDB_INVALID_REGNUM, gdb_arm_s16, fpu_s16 }, NULL, NULL}, { "s17", NULL, 4, FPU_OFFSET(17), eEncodingIEEE754,eFormatFloat, { LLDB_INVALID_REGNUM, dwarf_s17, LLDB_INVALID_REGNUM, gdb_arm_s17, fpu_s17 }, NULL, NULL}, { "s18", NULL, 4, FPU_OFFSET(18), eEncodingIEEE754,eFormatFloat, { LLDB_INVALID_REGNUM, dwarf_s18, LLDB_INVALID_REGNUM, gdb_arm_s18, fpu_s18 }, NULL, NULL}, { "s19", NULL, 4, FPU_OFFSET(19), eEncodingIEEE754,eFormatFloat, { LLDB_INVALID_REGNUM, dwarf_s19, LLDB_INVALID_REGNUM, gdb_arm_s19, fpu_s19 }, NULL, NULL}, { "s20", NULL, 4, FPU_OFFSET(20), eEncodingIEEE754,eFormatFloat, { LLDB_INVALID_REGNUM, dwarf_s20, LLDB_INVALID_REGNUM, gdb_arm_s20, fpu_s20 }, NULL, NULL}, { "s21", NULL, 4, FPU_OFFSET(21), eEncodingIEEE754,eFormatFloat, { LLDB_INVALID_REGNUM, dwarf_s21, LLDB_INVALID_REGNUM, gdb_arm_s21, fpu_s21 }, NULL, NULL}, { "s22", NULL, 4, FPU_OFFSET(22), eEncodingIEEE754,eFormatFloat, { LLDB_INVALID_REGNUM, dwarf_s22, LLDB_INVALID_REGNUM, gdb_arm_s22, fpu_s22 }, NULL, NULL}, { "s23", NULL, 4, FPU_OFFSET(23), eEncodingIEEE754,eFormatFloat, { LLDB_INVALID_REGNUM, dwarf_s23, LLDB_INVALID_REGNUM, gdb_arm_s23, fpu_s23 }, NULL, NULL}, { "s24", NULL, 4, FPU_OFFSET(24), eEncodingIEEE754,eFormatFloat, { LLDB_INVALID_REGNUM, dwarf_s24, LLDB_INVALID_REGNUM, gdb_arm_s24, fpu_s24 }, NULL, NULL}, { "s25", NULL, 4, FPU_OFFSET(25), eEncodingIEEE754,eFormatFloat, { LLDB_INVALID_REGNUM, dwarf_s25, LLDB_INVALID_REGNUM, gdb_arm_s25, fpu_s25 }, NULL, NULL}, { "s26", NULL, 4, FPU_OFFSET(26), eEncodingIEEE754,eFormatFloat, { LLDB_INVALID_REGNUM, dwarf_s26, LLDB_INVALID_REGNUM, gdb_arm_s26, fpu_s26 }, NULL, NULL}, { "s27", NULL, 4, FPU_OFFSET(27), eEncodingIEEE754,eFormatFloat, { LLDB_INVALID_REGNUM, dwarf_s27, LLDB_INVALID_REGNUM, gdb_arm_s27, fpu_s27 }, NULL, NULL}, { "s28", NULL, 4, FPU_OFFSET(28), eEncodingIEEE754,eFormatFloat, { LLDB_INVALID_REGNUM, dwarf_s28, LLDB_INVALID_REGNUM, gdb_arm_s28, fpu_s28 }, NULL, NULL}, { "s29", NULL, 4, FPU_OFFSET(29), eEncodingIEEE754,eFormatFloat, { LLDB_INVALID_REGNUM, dwarf_s29, LLDB_INVALID_REGNUM, gdb_arm_s29, fpu_s29 }, NULL, NULL}, { "s30", NULL, 4, FPU_OFFSET(30), eEncodingIEEE754,eFormatFloat, { LLDB_INVALID_REGNUM, dwarf_s30, LLDB_INVALID_REGNUM, gdb_arm_s30, fpu_s30 }, NULL, NULL}, { "s31", NULL, 4, FPU_OFFSET(31), eEncodingIEEE754,eFormatFloat, { LLDB_INVALID_REGNUM, dwarf_s31, LLDB_INVALID_REGNUM, gdb_arm_s31, fpu_s31 }, NULL, NULL}, { "fpscr", NULL, 4, FPU_OFFSET(32), eEncodingUint, eFormatHex, { LLDB_INVALID_REGNUM, LLDB_INVALID_REGNUM,LLDB_INVALID_REGNUM, gdb_arm_fpscr, fpu_fpscr }, NULL, NULL}, { "exception",NULL, 4, EXC_OFFSET(0), eEncodingUint, eFormatHex, { LLDB_INVALID_REGNUM, LLDB_INVALID_REGNUM,LLDB_INVALID_REGNUM, LLDB_INVALID_REGNUM, exc_exception }, NULL, NULL}, { "fsr", NULL, 4, EXC_OFFSET(1), eEncodingUint, eFormatHex, { LLDB_INVALID_REGNUM, LLDB_INVALID_REGNUM,LLDB_INVALID_REGNUM, LLDB_INVALID_REGNUM, exc_fsr }, NULL, NULL}, { "far", NULL, 4, EXC_OFFSET(2), eEncodingUint, eFormatHex, { LLDB_INVALID_REGNUM, LLDB_INVALID_REGNUM,LLDB_INVALID_REGNUM, LLDB_INVALID_REGNUM, exc_far }, NULL, NULL}, { DEFINE_DBG (bvr, 0) }, { DEFINE_DBG (bvr, 1) }, { DEFINE_DBG (bvr, 2) }, { DEFINE_DBG (bvr, 3) }, { DEFINE_DBG (bvr, 4) }, { DEFINE_DBG (bvr, 5) }, { DEFINE_DBG (bvr, 6) }, { DEFINE_DBG (bvr, 7) }, { DEFINE_DBG (bvr, 8) }, { DEFINE_DBG (bvr, 9) }, { DEFINE_DBG (bvr, 10) }, { DEFINE_DBG (bvr, 11) }, { DEFINE_DBG (bvr, 12) }, { DEFINE_DBG (bvr, 13) }, { DEFINE_DBG (bvr, 14) }, { DEFINE_DBG (bvr, 15) }, { DEFINE_DBG (bcr, 0) }, { DEFINE_DBG (bcr, 1) }, { DEFINE_DBG (bcr, 2) }, { DEFINE_DBG (bcr, 3) }, { DEFINE_DBG (bcr, 4) }, { DEFINE_DBG (bcr, 5) }, { DEFINE_DBG (bcr, 6) }, { DEFINE_DBG (bcr, 7) }, { DEFINE_DBG (bcr, 8) }, { DEFINE_DBG (bcr, 9) }, { DEFINE_DBG (bcr, 10) }, { DEFINE_DBG (bcr, 11) }, { DEFINE_DBG (bcr, 12) }, { DEFINE_DBG (bcr, 13) }, { DEFINE_DBG (bcr, 14) }, { DEFINE_DBG (bcr, 15) }, { DEFINE_DBG (wvr, 0) }, { DEFINE_DBG (wvr, 1) }, { DEFINE_DBG (wvr, 2) }, { DEFINE_DBG (wvr, 3) }, { DEFINE_DBG (wvr, 4) }, { DEFINE_DBG (wvr, 5) }, { DEFINE_DBG (wvr, 6) }, { DEFINE_DBG (wvr, 7) }, { DEFINE_DBG (wvr, 8) }, { DEFINE_DBG (wvr, 9) }, { DEFINE_DBG (wvr, 10) }, { DEFINE_DBG (wvr, 11) }, { DEFINE_DBG (wvr, 12) }, { DEFINE_DBG (wvr, 13) }, { DEFINE_DBG (wvr, 14) }, { DEFINE_DBG (wvr, 15) }, { DEFINE_DBG (wcr, 0) }, { DEFINE_DBG (wcr, 1) }, { DEFINE_DBG (wcr, 2) }, { DEFINE_DBG (wcr, 3) }, { DEFINE_DBG (wcr, 4) }, { DEFINE_DBG (wcr, 5) }, { DEFINE_DBG (wcr, 6) }, { DEFINE_DBG (wcr, 7) }, { DEFINE_DBG (wcr, 8) }, { DEFINE_DBG (wcr, 9) }, { DEFINE_DBG (wcr, 10) }, { DEFINE_DBG (wcr, 11) }, { DEFINE_DBG (wcr, 12) }, { DEFINE_DBG (wcr, 13) }, { DEFINE_DBG (wcr, 14) }, { DEFINE_DBG (wcr, 15) } }; // General purpose registers static uint32_t g_gpr_regnums[] = { gpr_r0, gpr_r1, gpr_r2, gpr_r3, gpr_r4, gpr_r5, gpr_r6, gpr_r7, gpr_r8, gpr_r9, gpr_r10, gpr_r11, gpr_r12, gpr_sp, gpr_lr, gpr_pc, gpr_cpsr }; // Floating point registers static uint32_t g_fpu_regnums[] = { fpu_s0, fpu_s1, fpu_s2, fpu_s3, fpu_s4, fpu_s5, fpu_s6, fpu_s7, fpu_s8, fpu_s9, fpu_s10, fpu_s11, fpu_s12, fpu_s13, fpu_s14, fpu_s15, fpu_s16, fpu_s17, fpu_s18, fpu_s19, fpu_s20, fpu_s21, fpu_s22, fpu_s23, fpu_s24, fpu_s25, fpu_s26, fpu_s27, fpu_s28, fpu_s29, fpu_s30, fpu_s31, fpu_fpscr, }; // Exception registers static uint32_t g_exc_regnums[] = { exc_exception, exc_fsr, exc_far, }; static size_t k_num_register_infos = (sizeof(g_register_infos)/sizeof(RegisterInfo)); void RegisterContextDarwin_arm::InvalidateAllRegisters () { InvalidateAllRegisterStates(); } size_t RegisterContextDarwin_arm::GetRegisterCount () { assert(k_num_register_infos == k_num_registers); return k_num_registers; } const RegisterInfo * RegisterContextDarwin_arm::GetRegisterInfoAtIndex (size_t reg) { assert(k_num_register_infos == k_num_registers); if (reg < k_num_registers) return &g_register_infos[reg]; return NULL; } size_t RegisterContextDarwin_arm::GetRegisterInfosCount () { return k_num_register_infos; } const RegisterInfo * RegisterContextDarwin_arm::GetRegisterInfos () { return g_register_infos; } // Number of registers in each register set const size_t k_num_gpr_registers = sizeof(g_gpr_regnums) / sizeof(uint32_t); const size_t k_num_fpu_registers = sizeof(g_fpu_regnums) / sizeof(uint32_t); const size_t k_num_exc_registers = sizeof(g_exc_regnums) / sizeof(uint32_t); //---------------------------------------------------------------------- // Register set definitions. The first definitions at register set index // of zero is for all registers, followed by other registers sets. The // register information for the all register set need not be filled in. //---------------------------------------------------------------------- static const RegisterSet g_reg_sets[] = { { "General Purpose Registers", "gpr", k_num_gpr_registers, g_gpr_regnums, }, { "Floating Point Registers", "fpu", k_num_fpu_registers, g_fpu_regnums }, { "Exception State Registers", "exc", k_num_exc_registers, g_exc_regnums } }; const size_t k_num_regsets = sizeof(g_reg_sets) / sizeof(RegisterSet); size_t RegisterContextDarwin_arm::GetRegisterSetCount () { return k_num_regsets; } const RegisterSet * RegisterContextDarwin_arm::GetRegisterSet (size_t reg_set) { if (reg_set < k_num_regsets) return &g_reg_sets[reg_set]; return NULL; } //---------------------------------------------------------------------- // Register information defintions for 32 bit i386. //---------------------------------------------------------------------- int RegisterContextDarwin_arm::GetSetForNativeRegNum (int reg) { if (reg < fpu_s0) return GPRRegSet; else if (reg < exc_exception) return FPURegSet; else if (reg < k_num_registers) return EXCRegSet; return -1; } int RegisterContextDarwin_arm::ReadGPR (bool force) { int set = GPRRegSet; if (force || !RegisterSetIsCached(set)) { SetError(set, Read, DoReadGPR(GetThreadID(), set, gpr)); } return GetError(GPRRegSet, Read); } int RegisterContextDarwin_arm::ReadFPU (bool force) { int set = FPURegSet; if (force || !RegisterSetIsCached(set)) { SetError(set, Read, DoReadFPU(GetThreadID(), set, fpu)); } return GetError(FPURegSet, Read); } int RegisterContextDarwin_arm::ReadEXC (bool force) { int set = EXCRegSet; if (force || !RegisterSetIsCached(set)) { SetError(set, Read, DoReadEXC(GetThreadID(), set, exc)); } return GetError(EXCRegSet, Read); } int RegisterContextDarwin_arm::ReadDBG (bool force) { int set = DBGRegSet; if (force || !RegisterSetIsCached(set)) { SetError(set, Read, DoReadDBG(GetThreadID(), set, dbg)); } return GetError(DBGRegSet, Read); } int RegisterContextDarwin_arm::WriteGPR () { int set = GPRRegSet; if (!RegisterSetIsCached(set)) { SetError (set, Write, -1); return KERN_INVALID_ARGUMENT; } SetError (set, Write, DoWriteGPR(GetThreadID(), set, gpr)); SetError (set, Read, -1); return GetError(GPRRegSet, Write); } int RegisterContextDarwin_arm::WriteFPU () { int set = FPURegSet; if (!RegisterSetIsCached(set)) { SetError (set, Write, -1); return KERN_INVALID_ARGUMENT; } SetError (set, Write, DoWriteFPU(GetThreadID(), set, fpu)); SetError (set, Read, -1); return GetError(FPURegSet, Write); } int RegisterContextDarwin_arm::WriteEXC () { int set = EXCRegSet; if (!RegisterSetIsCached(set)) { SetError (set, Write, -1); return KERN_INVALID_ARGUMENT; } SetError (set, Write, DoWriteEXC(GetThreadID(), set, exc)); SetError (set, Read, -1); return GetError(EXCRegSet, Write); } int RegisterContextDarwin_arm::WriteDBG () { int set = DBGRegSet; if (!RegisterSetIsCached(set)) { SetError (set, Write, -1); return KERN_INVALID_ARGUMENT; } SetError (set, Write, DoWriteDBG(GetThreadID(), set, dbg)); SetError (set, Read, -1); return GetError(DBGRegSet, Write); } int RegisterContextDarwin_arm::ReadRegisterSet (uint32_t set, bool force) { switch (set) { case GPRRegSet: return ReadGPR(force); case FPURegSet: return ReadFPU(force); case EXCRegSet: return ReadEXC(force); case DBGRegSet: return ReadDBG(force); default: break; } return KERN_INVALID_ARGUMENT; } int RegisterContextDarwin_arm::WriteRegisterSet (uint32_t set) { // Make sure we have a valid context to set. if (RegisterSetIsCached(set)) { switch (set) { case GPRRegSet: return WriteGPR(); case FPURegSet: return WriteFPU(); case EXCRegSet: return WriteEXC(); case DBGRegSet: return WriteDBG(); default: break; } } return KERN_INVALID_ARGUMENT; } void RegisterContextDarwin_arm::LogDBGRegisters (Log *log, const DBG& dbg) { if (log) { for (uint32_t i=0; i<16; i++) log->Printf("BVR%-2u/BCR%-2u = { 0x%8.8x, 0x%8.8x } WVR%-2u/WCR%-2u = { 0x%8.8x, 0x%8.8x }", i, i, dbg.bvr[i], dbg.bcr[i], i, i, dbg.wvr[i], dbg.wcr[i]); } } bool RegisterContextDarwin_arm::ReadRegister (const RegisterInfo *reg_info, RegisterValue &value) { const uint32_t reg = reg_info->kinds[eRegisterKindLLDB]; int set = RegisterContextDarwin_arm::GetSetForNativeRegNum (reg); if (set == -1) return false; if (ReadRegisterSet(set, false) != KERN_SUCCESS) return false; switch (reg) { case gpr_r0: case gpr_r1: case gpr_r2: case gpr_r3: case gpr_r4: case gpr_r5: case gpr_r6: case gpr_r7: case gpr_r8: case gpr_r9: case gpr_r10: case gpr_r11: case gpr_r12: case gpr_sp: case gpr_lr: case gpr_pc: case gpr_cpsr: value.SetUInt32 (gpr.r[reg - gpr_r0]); break; case fpu_s0: case fpu_s1: case fpu_s2: case fpu_s3: case fpu_s4: case fpu_s5: case fpu_s6: case fpu_s7: case fpu_s8: case fpu_s9: case fpu_s10: case fpu_s11: case fpu_s12: case fpu_s13: case fpu_s14: case fpu_s15: case fpu_s16: case fpu_s17: case fpu_s18: case fpu_s19: case fpu_s20: case fpu_s21: case fpu_s22: case fpu_s23: case fpu_s24: case fpu_s25: case fpu_s26: case fpu_s27: case fpu_s28: case fpu_s29: case fpu_s30: case fpu_s31: value.SetUInt32 (fpu.floats.s[reg], RegisterValue::eTypeFloat); break; case fpu_fpscr: value.SetUInt32 (fpu.fpscr); break; case exc_exception: value.SetUInt32 (exc.exception); break; case exc_fsr: value.SetUInt32 (exc.fsr); break; case exc_far: value.SetUInt32 (exc.far); break; default: value.SetValueToInvalid(); return false; } return true; } bool RegisterContextDarwin_arm::WriteRegister (const RegisterInfo *reg_info, const RegisterValue &value) { const uint32_t reg = reg_info->kinds[eRegisterKindLLDB]; int set = GetSetForNativeRegNum (reg); if (set == -1) return false; if (ReadRegisterSet(set, false) != KERN_SUCCESS) return false; switch (reg) { case gpr_r0: case gpr_r1: case gpr_r2: case gpr_r3: case gpr_r4: case gpr_r5: case gpr_r6: case gpr_r7: case gpr_r8: case gpr_r9: case gpr_r10: case gpr_r11: case gpr_r12: case gpr_sp: case gpr_lr: case gpr_pc: case gpr_cpsr: gpr.r[reg - gpr_r0] = value.GetAsUInt32(); break; case fpu_s0: case fpu_s1: case fpu_s2: case fpu_s3: case fpu_s4: case fpu_s5: case fpu_s6: case fpu_s7: case fpu_s8: case fpu_s9: case fpu_s10: case fpu_s11: case fpu_s12: case fpu_s13: case fpu_s14: case fpu_s15: case fpu_s16: case fpu_s17: case fpu_s18: case fpu_s19: case fpu_s20: case fpu_s21: case fpu_s22: case fpu_s23: case fpu_s24: case fpu_s25: case fpu_s26: case fpu_s27: case fpu_s28: case fpu_s29: case fpu_s30: case fpu_s31: fpu.floats.s[reg] = value.GetAsUInt32(); break; case fpu_fpscr: fpu.fpscr = value.GetAsUInt32(); break; case exc_exception: exc.exception = value.GetAsUInt32(); break; case exc_fsr: exc.fsr = value.GetAsUInt32(); break; case exc_far: exc.far = value.GetAsUInt32(); break; default: return false; } return WriteRegisterSet(set) == KERN_SUCCESS; } bool RegisterContextDarwin_arm::ReadAllRegisterValues (lldb::DataBufferSP &data_sp) { data_sp.reset (new DataBufferHeap (REG_CONTEXT_SIZE, 0)); if (data_sp && ReadGPR (false) == KERN_SUCCESS && ReadFPU (false) == KERN_SUCCESS && ReadEXC (false) == KERN_SUCCESS) { uint8_t *dst = data_sp->GetBytes(); ::memcpy (dst, &gpr, sizeof(gpr)); dst += sizeof(gpr); ::memcpy (dst, &fpu, sizeof(fpu)); dst += sizeof(gpr); ::memcpy (dst, &exc, sizeof(exc)); return true; } return false; } bool RegisterContextDarwin_arm::WriteAllRegisterValues (const lldb::DataBufferSP &data_sp) { if (data_sp && data_sp->GetByteSize() == REG_CONTEXT_SIZE) { const uint8_t *src = data_sp->GetBytes(); ::memcpy (&gpr, src, sizeof(gpr)); src += sizeof(gpr); ::memcpy (&fpu, src, sizeof(fpu)); src += sizeof(gpr); ::memcpy (&exc, src, sizeof(exc)); uint32_t success_count = 0; if (WriteGPR() == KERN_SUCCESS) ++success_count; if (WriteFPU() == KERN_SUCCESS) ++success_count; if (WriteEXC() == KERN_SUCCESS) ++success_count; return success_count == 3; } return false; } uint32_t RegisterContextDarwin_arm::ConvertRegisterKindToRegisterNumber (uint32_t kind, uint32_t reg) { if (kind == eRegisterKindGeneric) { switch (reg) { case LLDB_REGNUM_GENERIC_PC: return gpr_pc; case LLDB_REGNUM_GENERIC_SP: return gpr_sp; case LLDB_REGNUM_GENERIC_FP: return gpr_r7; case LLDB_REGNUM_GENERIC_RA: return gpr_lr; case LLDB_REGNUM_GENERIC_FLAGS: return gpr_cpsr; default: break; } } else if (kind == eRegisterKindDWARF) { switch (reg) { case dwarf_r0: return gpr_r0; case dwarf_r1: return gpr_r1; case dwarf_r2: return gpr_r2; case dwarf_r3: return gpr_r3; case dwarf_r4: return gpr_r4; case dwarf_r5: return gpr_r5; case dwarf_r6: return gpr_r6; case dwarf_r7: return gpr_r7; case dwarf_r8: return gpr_r8; case dwarf_r9: return gpr_r9; case dwarf_r10: return gpr_r10; case dwarf_r11: return gpr_r11; case dwarf_r12: return gpr_r12; case dwarf_sp: return gpr_sp; case dwarf_lr: return gpr_lr; case dwarf_pc: return gpr_pc; case dwarf_spsr: return gpr_cpsr; case dwarf_s0: return fpu_s0; case dwarf_s1: return fpu_s1; case dwarf_s2: return fpu_s2; case dwarf_s3: return fpu_s3; case dwarf_s4: return fpu_s4; case dwarf_s5: return fpu_s5; case dwarf_s6: return fpu_s6; case dwarf_s7: return fpu_s7; case dwarf_s8: return fpu_s8; case dwarf_s9: return fpu_s9; case dwarf_s10: return fpu_s10; case dwarf_s11: return fpu_s11; case dwarf_s12: return fpu_s12; case dwarf_s13: return fpu_s13; case dwarf_s14: return fpu_s14; case dwarf_s15: return fpu_s15; case dwarf_s16: return fpu_s16; case dwarf_s17: return fpu_s17; case dwarf_s18: return fpu_s18; case dwarf_s19: return fpu_s19; case dwarf_s20: return fpu_s20; case dwarf_s21: return fpu_s21; case dwarf_s22: return fpu_s22; case dwarf_s23: return fpu_s23; case dwarf_s24: return fpu_s24; case dwarf_s25: return fpu_s25; case dwarf_s26: return fpu_s26; case dwarf_s27: return fpu_s27; case dwarf_s28: return fpu_s28; case dwarf_s29: return fpu_s29; case dwarf_s30: return fpu_s30; case dwarf_s31: return fpu_s31; default: break; } } else if (kind == eRegisterKindGCC) { switch (reg) { case gcc_r0: return gpr_r0; case gcc_r1: return gpr_r1; case gcc_r2: return gpr_r2; case gcc_r3: return gpr_r3; case gcc_r4: return gpr_r4; case gcc_r5: return gpr_r5; case gcc_r6: return gpr_r6; case gcc_r7: return gpr_r7; case gcc_r8: return gpr_r8; case gcc_r9: return gpr_r9; case gcc_r10: return gpr_r10; case gcc_r11: return gpr_r11; case gcc_r12: return gpr_r12; case gcc_sp: return gpr_sp; case gcc_lr: return gpr_lr; case gcc_pc: return gpr_pc; case gcc_cpsr: return gpr_cpsr; } } else if (kind == eRegisterKindLLDB) { return reg; } return LLDB_INVALID_REGNUM; } uint32_t RegisterContextDarwin_arm::NumSupportedHardwareBreakpoints () { #if defined (__arm__) // Set the init value to something that will let us know that we need to // autodetect how many breakpoints are supported dynamically... static uint32_t g_num_supported_hw_breakpoints = UINT32_MAX; if (g_num_supported_hw_breakpoints == UINT32_MAX) { // Set this to zero in case we can't tell if there are any HW breakpoints g_num_supported_hw_breakpoints = 0; uint32_t register_DBGDIDR; asm("mrc p14, 0, %0, c0, c0, 0" : "=r" (register_DBGDIDR)); g_num_supported_hw_breakpoints = Bits32 (register_DBGDIDR, 27, 24); // Zero is reserved for the BRP count, so don't increment it if it is zero if (g_num_supported_hw_breakpoints > 0) g_num_supported_hw_breakpoints++; // if (log) log->Printf ("DBGDIDR=0x%8.8x (number BRP pairs = %u)", register_DBGDIDR, g_num_supported_hw_breakpoints); } return g_num_supported_hw_breakpoints; #else // TODO: figure out remote case here! return 6; #endif } uint32_t RegisterContextDarwin_arm::SetHardwareBreakpoint (lldb::addr_t addr, size_t size) { // Make sure our address isn't bogus if (addr & 1) return LLDB_INVALID_INDEX32; int kret = ReadDBG (false); if (kret == KERN_SUCCESS) { const uint32_t num_hw_breakpoints = NumSupportedHardwareBreakpoints(); uint32_t i; for (i=0; iPrintf ("RegisterContextDarwin_arm::EnableHardwareBreakpoint( addr = %8.8p, size = %u ) - BVR%u/BCR%u = 0x%8.8x / 0x%8.8x (Thumb)", // addr, // size, // i, // i, // dbg.bvr[i], // dbg.bcr[i]); } else if (size == 4) { // We have an ARM breakpoint dbg.bcr[i] = BCR_M_IMVA_MATCH | // Stop on address mismatch BAS_IMVA_ALL | // Stop on any of the four bytes following the IMVA S_USER | // Which modes should this breakpoint stop in? BCR_ENABLE; // Enable this hardware breakpoint // if (log) log->Printf ("RegisterContextDarwin_arm::EnableHardwareBreakpoint( addr = %8.8p, size = %u ) - BVR%u/BCR%u = 0x%8.8x / 0x%8.8x (ARM)", // addr, // size, // i, // i, // dbg.bvr[i], // dbg.bcr[i]); } kret = WriteDBG(); // if (log) log->Printf ("RegisterContextDarwin_arm::EnableHardwareBreakpoint() WriteDBG() => 0x%8.8x.", kret); if (kret == KERN_SUCCESS) return i; } // else // { // if (log) log->Printf ("RegisterContextDarwin_arm::EnableHardwareBreakpoint(addr = %8.8p, size = %u) => all hardware breakpoint resources are being used.", addr, size); // } } return LLDB_INVALID_INDEX32; } bool RegisterContextDarwin_arm::ClearHardwareBreakpoint (uint32_t hw_index) { int kret = ReadDBG (false); const uint32_t num_hw_points = NumSupportedHardwareBreakpoints(); if (kret == KERN_SUCCESS) { if (hw_index < num_hw_points) { dbg.bcr[hw_index] = 0; // if (log) log->Printf ("RegisterContextDarwin_arm::SetHardwareBreakpoint( %u ) - BVR%u = 0x%8.8x BCR%u = 0x%8.8x", // hw_index, // hw_index, // dbg.bvr[hw_index], // hw_index, // dbg.bcr[hw_index]); kret = WriteDBG(); if (kret == KERN_SUCCESS) return true; } } return false; } uint32_t RegisterContextDarwin_arm::NumSupportedHardwareWatchpoints () { #if defined (__arm__) // Set the init value to something that will let us know that we need to // autodetect how many watchpoints are supported dynamically... static uint32_t g_num_supported_hw_watchpoints = UINT32_MAX; if (g_num_supported_hw_watchpoints == UINT32_MAX) { // Set this to zero in case we can't tell if there are any HW breakpoints g_num_supported_hw_watchpoints = 0; uint32_t register_DBGDIDR; asm("mrc p14, 0, %0, c0, c0, 0" : "=r" (register_DBGDIDR)); g_num_supported_hw_watchpoints = Bits32 (register_DBGDIDR, 31, 28) + 1; // if (log) log->Printf ("DBGDIDR=0x%8.8x (number WRP pairs = %u)", register_DBGDIDR, g_num_supported_hw_watchpoints); } return g_num_supported_hw_watchpoints; #else // TODO: figure out remote case here! return 2; #endif } uint32_t RegisterContextDarwin_arm::SetHardwareWatchpoint (lldb::addr_t addr, size_t size, bool read, bool write) { // if (log) log->Printf ("RegisterContextDarwin_arm::EnableHardwareWatchpoint(addr = %8.8p, size = %u, read = %u, write = %u)", addr, size, read, write); const uint32_t num_hw_watchpoints = NumSupportedHardwareWatchpoints(); // Can't watch zero bytes if (size == 0) return LLDB_INVALID_INDEX32; // We must watch for either read or write if (read == false && write == false) return LLDB_INVALID_INDEX32; // Can't watch more than 4 bytes per WVR/WCR pair if (size > 4) return LLDB_INVALID_INDEX32; // We can only watch up to four bytes that follow a 4 byte aligned address // per watchpoint register pair. Since we have at most so we can only watch // until the next 4 byte boundary and we need to make sure we can properly // encode this. uint32_t addr_word_offset = addr % 4; // if (log) log->Printf ("RegisterContextDarwin_arm::EnableHardwareWatchpoint() - addr_word_offset = 0x%8.8x", addr_word_offset); uint32_t byte_mask = ((1u << size) - 1u) << addr_word_offset; // if (log) log->Printf ("RegisterContextDarwin_arm::EnableHardwareWatchpoint() - byte_mask = 0x%8.8x", byte_mask); if (byte_mask > 0xfu) return LLDB_INVALID_INDEX32; // Read the debug state int kret = ReadDBG (false); if (kret == KERN_SUCCESS) { // Check to make sure we have the needed hardware support uint32_t i = 0; for (i=0; iPrintf ("RegisterContextDarwin_arm::EnableHardwareWatchpoint() WriteDBG() => 0x%8.8x.", kret); if (kret == KERN_SUCCESS) return i; } else { // if (log) log->Printf ("RegisterContextDarwin_arm::EnableHardwareWatchpoint(): All hardware resources (%u) are in use.", num_hw_watchpoints); } } return LLDB_INVALID_INDEX32; } bool RegisterContextDarwin_arm::ClearHardwareWatchpoint (uint32_t hw_index) { int kret = ReadDBG (false); const uint32_t num_hw_points = NumSupportedHardwareWatchpoints(); if (kret == KERN_SUCCESS) { if (hw_index < num_hw_points) { dbg.wcr[hw_index] = 0; // if (log) log->Printf ("RegisterContextDarwin_arm::ClearHardwareWatchpoint( %u ) - WVR%u = 0x%8.8x WCR%u = 0x%8.8x", // hw_index, // hw_index, // dbg.wvr[hw_index], // hw_index, // dbg.wcr[hw_index]); kret = WriteDBG(); if (kret == KERN_SUCCESS) return true; } } return false; } #endif