/* * Copyright (c) Atmosphère-NX * * This program is free software; you can redistribute it and/or modify it * under the terms and conditions of the GNU General Public License, * version 2, as published by the Free Software Foundation. * * This program is distributed in the hope it will be useful, but WITHOUT * ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or * FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for * more details. * * You should have received a copy of the GNU General Public License * along with this program. If not, see . */ #include namespace ams::kern::arch::arm64 { namespace { constexpr inline u64 ForbiddenBreakPointFlagsMask = (((1ul << 40) - 1) << 24) | /* Reserved upper bits. */ (((1ul << 1) - 1) << 23) | /* Match VMID BreakPoint Type. */ (((1ul << 2) - 1) << 14) | /* Security State Control. */ (((1ul << 1) - 1) << 13) | /* Hyp Mode Control. */ (((1ul << 4) - 1) << 9) | /* Reserved middle bits. */ (((1ul << 2) - 1) << 3) | /* Reserved lower bits. */ (((1ul << 2) - 1) << 1); /* Privileged Mode Control. */ static_assert(ForbiddenBreakPointFlagsMask == 0xFFFFFFFFFF80FE1Eul); constexpr inline u64 ForbiddenWatchPointFlagsMask = (((1ul << 32) - 1) << 32) | /* Reserved upper bits. */ (((1ul << 4) - 1) << 20) | /* WatchPoint Type. */ (((1ul << 2) - 1) << 14) | /* Security State Control. */ (((1ul << 1) - 1) << 13) | /* Hyp Mode Control. */ (((1ul << 2) - 1) << 1); /* Privileged Access Control. */ static_assert(ForbiddenWatchPointFlagsMask == 0xFFFFFFFF00F0E006ul); } uintptr_t KDebug::GetProgramCounter(const KThread &thread) { return GetExceptionContext(std::addressof(thread))->pc; } void KDebug::SetPreviousProgramCounter() { /* Get the current thread. */ KThread *thread = GetCurrentThreadPointer(); MESOSPHERE_ASSERT(thread->IsCallingSvc()); /* Get the exception context. */ KExceptionContext *e_ctx = GetExceptionContext(thread); /* Set the previous pc. */ if (e_ctx->write == 0) { /* Subtract from the program counter. */ if (thread->GetOwnerProcess()->Is64Bit()) { e_ctx->pc -= sizeof(u32); } else { e_ctx->pc -= (e_ctx->psr & 0x20) ? sizeof(u16) : sizeof(u32); } /* Mark that we've set. */ e_ctx->write = 1; } } Result KDebug::GetThreadContextImpl(ams::svc::ThreadContext *out, KThread *thread, u32 context_flags) { MESOSPHERE_ASSERT(KScheduler::IsSchedulerLockedByCurrentThread()); MESOSPHERE_ASSERT(thread != GetCurrentThreadPointer()); /* Get the exception context. */ const KExceptionContext *e_ctx = GetExceptionContext(thread); /* Get whether we're 64-bit. */ const bool is_64_bit = this->Is64Bit(); /* If general registers are requested, get them. */ if ((context_flags & ams::svc::ThreadContextFlag_General) != 0) { /* We can always get X0-X7/R0-R7. */ auto register_count = 8; if (!thread->IsCallingSvc() || thread->GetSvcId() == svc::SvcId_ReturnFromException) { if (is_64_bit) { /* We're not in an SVC, so we can get X0-X29. */ register_count = 29; } else { /* We're 32-bit, so we should get R0-R12. */ register_count = 13; } } /* Get the registers. */ for (auto i = 0; i < register_count; ++i) { out->r[i] = is_64_bit ? e_ctx->x[i] : static_cast(e_ctx->x[i]); } } /* If control flags are requested, get them. */ if ((context_flags & ams::svc::ThreadContextFlag_Control) != 0) { if (is_64_bit) { out->fp = e_ctx->x[29]; out->lr = e_ctx->x[30]; out->sp = e_ctx->sp; out->pc = e_ctx->pc; out->pstate = (e_ctx->psr & cpu::El0Aarch64PsrMask); /* Adjust PC if we should. */ if (e_ctx->write == 0 && thread->IsCallingSvc()) { out->pc -= sizeof(u32); } out->tpidr = e_ctx->tpidr; } else { out->r[11] = static_cast(e_ctx->x[11]); out->r[13] = static_cast(e_ctx->x[13]); out->r[14] = static_cast(e_ctx->x[14]); out->lr = 0; out->sp = 0; out->pc = e_ctx->pc; out->pstate = (e_ctx->psr & cpu::El0Aarch32PsrMask); /* Adjust PC if we should. */ if (e_ctx->write == 0 && thread->IsCallingSvc()) { out->pc -= (e_ctx->psr & 0x20) ? sizeof(u16) : sizeof(u32); } out->tpidr = static_cast(e_ctx->tpidr); } } /* Get the FPU context. */ R_RETURN(this->GetFpuContext(out, thread, context_flags)); } Result KDebug::SetThreadContextImpl(const ams::svc::ThreadContext &ctx, KThread *thread, u32 context_flags) { MESOSPHERE_ASSERT(KScheduler::IsSchedulerLockedByCurrentThread()); MESOSPHERE_ASSERT(thread != GetCurrentThreadPointer()); /* Get the exception context. */ KExceptionContext *e_ctx = GetExceptionContext(thread); /* If general registers are requested, set them. */ if ((context_flags & ams::svc::ThreadContextFlag_General) != 0) { if (this->Is64Bit()) { /* Set X0-X28. */ for (auto i = 0; i <= 28; ++i) { e_ctx->x[i] = ctx.r[i]; } } else { /* Set R0-R12. */ for (auto i = 0; i <= 12; ++i) { e_ctx->x[i] = static_cast(ctx.r[i]); } } } /* If control flags are requested, set them. */ if ((context_flags & ams::svc::ThreadContextFlag_Control) != 0) { /* Mark ourselve as having adjusted pc. */ e_ctx->write = 1; if (this->Is64Bit()) { e_ctx->x[29] = ctx.fp; e_ctx->x[30] = ctx.lr; e_ctx->sp = ctx.sp; e_ctx->pc = ctx.pc; e_ctx->psr = ((ctx.pstate & cpu::El0Aarch64PsrMask) | (e_ctx->psr & ~cpu::El0Aarch64PsrMask)); e_ctx->tpidr = ctx.tpidr; } else { e_ctx->x[13] = static_cast(ctx.r[13]); e_ctx->x[14] = static_cast(ctx.r[14]); e_ctx->x[30] = 0; e_ctx->sp = 0; e_ctx->pc = static_cast(ctx.pc); e_ctx->psr = ((ctx.pstate & cpu::El0Aarch32PsrMask) | (e_ctx->psr & ~cpu::El0Aarch32PsrMask)); e_ctx->tpidr = ctx.tpidr; } } /* Set the FPU context. */ R_RETURN(this->SetFpuContext(ctx, thread, context_flags)); } Result KDebug::GetFpuContext(ams::svc::ThreadContext *out, KThread *thread, u32 context_flags) { MESOSPHERE_ASSERT(KScheduler::IsSchedulerLockedByCurrentThread()); MESOSPHERE_ASSERT(thread != GetCurrentThreadPointer()); /* Succeed if there's nothing to do. */ R_SUCCEED_IF((context_flags & (ams::svc::ThreadContextFlag_Fpu | ams::svc::ThreadContextFlag_FpuControl)) == 0); /* Get the thread context. */ KThreadContext *t_ctx = std::addressof(thread->GetContext()); /* Get the FPU control registers, if required. */ if ((context_flags & ams::svc::ThreadContextFlag_FpuControl) != 0) { out->fpsr = t_ctx->GetFpsr(); out->fpcr = t_ctx->GetFpcr(); } /* Get the FPU registers, if required. */ if ((context_flags & ams::svc::ThreadContextFlag_Fpu) != 0) { static_assert(util::size(ams::svc::ThreadContext{}.v) == KThreadContext::NumFpuRegisters); const auto &caller_save = thread->GetCallerSaveFpuRegisters(); const auto &callee_save = t_ctx->GetCalleeSaveFpuRegisters(); if (this->Is64Bit()) { KThreadContext::GetFpuRegisters(out->v, caller_save.fpu64, callee_save.fpu64); } else { KThreadContext::GetFpuRegisters(out->v, caller_save.fpu32, callee_save.fpu32); for (size_t i = KThreadContext::NumFpuRegisters / 2; i < KThreadContext::NumFpuRegisters; ++i) { out->v[i] = 0; } } } R_SUCCEED(); } Result KDebug::SetFpuContext(const ams::svc::ThreadContext &ctx, KThread *thread, u32 context_flags) { MESOSPHERE_ASSERT(KScheduler::IsSchedulerLockedByCurrentThread()); MESOSPHERE_ASSERT(thread != GetCurrentThreadPointer()); /* Succeed if there's nothing to do. */ R_SUCCEED_IF((context_flags & (ams::svc::ThreadContextFlag_Fpu | ams::svc::ThreadContextFlag_FpuControl)) == 0); /* Get the thread context. */ KThreadContext *t_ctx = std::addressof(thread->GetContext()); /* Set the FPU control registers, if required. */ if ((context_flags & ams::svc::ThreadContextFlag_FpuControl) != 0) { t_ctx->SetFpsr(ctx.fpsr); t_ctx->SetFpcr(ctx.fpcr); } /* Set the FPU registers, if required. */ if ((context_flags & ams::svc::ThreadContextFlag_Fpu) != 0) { static_assert(util::size(ams::svc::ThreadContext{}.v) == KThreadContext::NumFpuRegisters); auto &caller_save = thread->GetCallerSaveFpuRegisters(); auto &callee_save = t_ctx->GetCalleeSaveFpuRegisters(); if (this->Is64Bit()) { KThreadContext::SetFpuRegisters(caller_save.fpu64, callee_save.fpu64, ctx.v); } else { KThreadContext::SetFpuRegisters(caller_save.fpu32, callee_save.fpu32, ctx.v); } } R_SUCCEED(); } Result KDebug::BreakIfAttached(ams::svc::BreakReason break_reason, uintptr_t address, size_t size) { const uintptr_t params[5] = { ams::svc::DebugException_UserBreak, GetProgramCounter(GetCurrentThread()), break_reason, address, size }; R_RETURN(KDebugBase::OnDebugEvent(ams::svc::DebugEvent_Exception, params, util::size(params))); } #define MESOSPHERE_SET_HW_BREAK_POINT(ID, FLAGS, VALUE) \ ({ \ cpu::SetDbgBcr##ID##El1(0); \ cpu::EnsureInstructionConsistencyFullSystem(); \ cpu::SetDbgBvr##ID##El1(VALUE); \ cpu::EnsureInstructionConsistencyFullSystem(); \ cpu::SetDbgBcr##ID##El1(FLAGS); \ cpu::EnsureInstructionConsistencyFullSystem(); \ }) #define MESOSPHERE_SET_HW_WATCH_POINT(ID, FLAGS, VALUE) \ ({ \ cpu::SetDbgWcr##ID##El1(0); \ cpu::EnsureInstructionConsistencyFullSystem(); \ cpu::SetDbgWvr##ID##El1(VALUE); \ cpu::EnsureInstructionConsistencyFullSystem(); \ cpu::SetDbgWcr##ID##El1(FLAGS); \ cpu::EnsureInstructionConsistencyFullSystem(); \ }) Result KDebug::SetHardwareBreakPoint(ams::svc::HardwareBreakPointRegisterName name, u64 flags, u64 value) { /* Get the debug feature register. */ cpu::DebugFeatureRegisterAccessor dfr0; /* Extract interesting info from the debug feature register. */ const auto num_bp = dfr0.GetNumBreakpoints(); const auto num_wp = dfr0.GetNumWatchpoints(); const auto num_ctx = dfr0.GetNumContextAwareBreakpoints(); if (ams::svc::HardwareBreakPointRegisterName_I0 <= name && name <= ams::svc::HardwareBreakPointRegisterName_I15) { /* Check that the name is a valid instruction breakpoint. */ R_UNLESS((name - ams::svc::HardwareBreakPointRegisterName_I0) <= num_bp, svc::ResultNotSupported()); /* Configure flags/value. */ if ((flags & 1) != 0) { /* We're enabling the breakpoint. Check that the flags are allowable. */ R_UNLESS((flags & ForbiddenBreakPointFlagsMask) == 0, svc::ResultInvalidCombination()); /* Require that the breakpoint be linked or match context id. */ R_UNLESS((flags & ((1ul << 21) | (1ul << 20))) != 0, svc::ResultInvalidCombination()); /* If the breakpoint matches context id, we need to get the context id. */ if ((flags & (1ul << 21)) != 0) { /* Ensure that the breakpoint is context-aware. */ R_UNLESS((name - ams::svc::HardwareBreakPointRegisterName_I0) >= (num_bp - num_ctx), svc::ResultNotSupported()); /* Check that the breakpoint does not have the mismatch bit. */ R_UNLESS((flags & (1ul << 22)) == 0, svc::ResultInvalidCombination()); /* Get the debug object from the current handle table. */ KScopedAutoObject debug = GetCurrentProcess().GetHandleTable().GetObject(static_cast(value)); R_UNLESS(debug.IsNotNull(), svc::ResultInvalidHandle()); /* Get the process from the debug object. */ R_UNLESS(debug->IsAttached(), svc::ResultProcessTerminated()); R_UNLESS(debug->OpenProcess(), svc::ResultProcessTerminated()); /* Close the process when we're done. */ ON_SCOPE_EXIT { debug->CloseProcess(); }; /* Get the proces. */ KProcess * const process = debug->GetProcessUnsafe(); /* Set the value to be the context id. */ value = process->GetId() & 0xFFFFFFFF; } /* Set the breakpoint as non-secure EL0-only. */ flags |= (1ul << 14) | (2ul << 1); } else { /* We're disabling the breakpoint. */ flags = 0; value = 0; } /* Set the breakpoint. */ switch (name) { case ams::svc::HardwareBreakPointRegisterName_I0: MESOSPHERE_SET_HW_BREAK_POINT( 0, flags, value); break; case ams::svc::HardwareBreakPointRegisterName_I1: MESOSPHERE_SET_HW_BREAK_POINT( 1, flags, value); break; case ams::svc::HardwareBreakPointRegisterName_I2: MESOSPHERE_SET_HW_BREAK_POINT( 2, flags, value); break; case ams::svc::HardwareBreakPointRegisterName_I3: MESOSPHERE_SET_HW_BREAK_POINT( 3, flags, value); break; case ams::svc::HardwareBreakPointRegisterName_I4: MESOSPHERE_SET_HW_BREAK_POINT( 4, flags, value); break; case ams::svc::HardwareBreakPointRegisterName_I5: MESOSPHERE_SET_HW_BREAK_POINT( 5, flags, value); break; case ams::svc::HardwareBreakPointRegisterName_I6: MESOSPHERE_SET_HW_BREAK_POINT( 6, flags, value); break; case ams::svc::HardwareBreakPointRegisterName_I7: MESOSPHERE_SET_HW_BREAK_POINT( 7, flags, value); break; case ams::svc::HardwareBreakPointRegisterName_I8: MESOSPHERE_SET_HW_BREAK_POINT( 8, flags, value); break; case ams::svc::HardwareBreakPointRegisterName_I9: MESOSPHERE_SET_HW_BREAK_POINT( 9, flags, value); break; case ams::svc::HardwareBreakPointRegisterName_I10: MESOSPHERE_SET_HW_BREAK_POINT(10, flags, value); break; case ams::svc::HardwareBreakPointRegisterName_I11: MESOSPHERE_SET_HW_BREAK_POINT(11, flags, value); break; case ams::svc::HardwareBreakPointRegisterName_I12: MESOSPHERE_SET_HW_BREAK_POINT(12, flags, value); break; case ams::svc::HardwareBreakPointRegisterName_I13: MESOSPHERE_SET_HW_BREAK_POINT(13, flags, value); break; case ams::svc::HardwareBreakPointRegisterName_I14: MESOSPHERE_SET_HW_BREAK_POINT(14, flags, value); break; case ams::svc::HardwareBreakPointRegisterName_I15: MESOSPHERE_SET_HW_BREAK_POINT(15, flags, value); break; default: break; } } else if (ams::svc::HardwareBreakPointRegisterName_D0 <= name && name <= ams::svc::HardwareBreakPointRegisterName_D15) { /* Check that the name is a valid data breakpoint. */ R_UNLESS((name - ams::svc::HardwareBreakPointRegisterName_D0) <= num_wp, svc::ResultNotSupported()); /* Configure flags/value. */ if ((flags & 1) != 0) { /* We're enabling the watchpoint. Check that the flags are allowable. */ R_UNLESS((flags & ForbiddenWatchPointFlagsMask) == 0, svc::ResultInvalidCombination()); /* Set the breakpoint as linked non-secure EL0-only. */ flags |= (1ul << 20) | (1ul << 14) | (2ul << 1); } else { /* We're disabling the watchpoint. */ flags = 0; value = 0; } /* Set the watchpoint. */ switch (name) { case ams::svc::HardwareBreakPointRegisterName_D0: MESOSPHERE_SET_HW_WATCH_POINT( 0, flags, value); break; case ams::svc::HardwareBreakPointRegisterName_D1: MESOSPHERE_SET_HW_WATCH_POINT( 1, flags, value); break; case ams::svc::HardwareBreakPointRegisterName_D2: MESOSPHERE_SET_HW_WATCH_POINT( 2, flags, value); break; case ams::svc::HardwareBreakPointRegisterName_D3: MESOSPHERE_SET_HW_WATCH_POINT( 3, flags, value); break; case ams::svc::HardwareBreakPointRegisterName_D4: MESOSPHERE_SET_HW_WATCH_POINT( 4, flags, value); break; case ams::svc::HardwareBreakPointRegisterName_D5: MESOSPHERE_SET_HW_WATCH_POINT( 5, flags, value); break; case ams::svc::HardwareBreakPointRegisterName_D6: MESOSPHERE_SET_HW_WATCH_POINT( 6, flags, value); break; case ams::svc::HardwareBreakPointRegisterName_D7: MESOSPHERE_SET_HW_WATCH_POINT( 7, flags, value); break; case ams::svc::HardwareBreakPointRegisterName_D8: MESOSPHERE_SET_HW_WATCH_POINT( 8, flags, value); break; case ams::svc::HardwareBreakPointRegisterName_D9: MESOSPHERE_SET_HW_WATCH_POINT( 9, flags, value); break; case ams::svc::HardwareBreakPointRegisterName_D10: MESOSPHERE_SET_HW_WATCH_POINT(10, flags, value); break; case ams::svc::HardwareBreakPointRegisterName_D11: MESOSPHERE_SET_HW_WATCH_POINT(11, flags, value); break; case ams::svc::HardwareBreakPointRegisterName_D12: MESOSPHERE_SET_HW_WATCH_POINT(12, flags, value); break; case ams::svc::HardwareBreakPointRegisterName_D13: MESOSPHERE_SET_HW_WATCH_POINT(13, flags, value); break; case ams::svc::HardwareBreakPointRegisterName_D14: MESOSPHERE_SET_HW_WATCH_POINT(14, flags, value); break; case ams::svc::HardwareBreakPointRegisterName_D15: MESOSPHERE_SET_HW_WATCH_POINT(15, flags, value); break; default: break; } } else { /* Invalid name. */ R_THROW(svc::ResultInvalidEnumValue()); } R_SUCCEED(); } #undef MESOSPHERE_SET_HW_WATCH_POINT #undef MESOSPHERE_SET_HW_BREAK_POINT void KDebug::PrintRegister(KThread *thread) { #if defined(MESOSPHERE_BUILD_FOR_DEBUGGING) { /* Treat no thread as current thread. */ if (thread == nullptr) { thread = GetCurrentThreadPointer(); } /* Get the exception context. */ KExceptionContext *e_ctx = GetExceptionContext(thread); /* Get the owner process. */ if (auto *process = thread->GetOwnerProcess(); process != nullptr) { /* Lock the owner process. */ KScopedLightLock state_lk(process->GetStateLock()); KScopedLightLock list_lk(process->GetListLock()); /* Suspend all the process's threads. */ { KScopedSchedulerLock sl; auto end = process->GetThreadList().end(); for (auto it = process->GetThreadList().begin(); it != end; ++it) { if (std::addressof(*it) != GetCurrentThreadPointer()) { it->RequestSuspend(KThread::SuspendType_Backtrace); } } } /* Print the registers. */ MESOSPHERE_RELEASE_LOG("Registers\n"); if ((e_ctx->psr & 0x10) == 0) { /* 64-bit thread. */ for (auto i = 0; i < 31; ++i) { MESOSPHERE_RELEASE_LOG(" X[%2d]: 0x%016lx\n", i, e_ctx->x[i]); } MESOSPHERE_RELEASE_LOG(" SP: 0x%016lx\n", e_ctx->sp); MESOSPHERE_RELEASE_LOG(" PC: 0x%016lx\n", e_ctx->pc - sizeof(u32)); MESOSPHERE_RELEASE_LOG(" PSR: 0x%08x\n", e_ctx->psr); MESOSPHERE_RELEASE_LOG(" TPIDR_EL0: 0x%016lx\n", e_ctx->tpidr); } else { /* 32-bit thread. */ for (auto i = 0; i < 13; ++i) { MESOSPHERE_RELEASE_LOG(" R[%2d]: 0x%08x\n", i, static_cast(e_ctx->x[i])); } MESOSPHERE_RELEASE_LOG(" SP: 0x%08x\n", static_cast(e_ctx->x[13])); MESOSPHERE_RELEASE_LOG(" LR: 0x%08x\n", static_cast(e_ctx->x[14])); MESOSPHERE_RELEASE_LOG(" PC: 0x%08x\n", static_cast(e_ctx->pc) - static_cast((e_ctx->psr & 0x20) ? sizeof(u16) : sizeof(u32))); MESOSPHERE_RELEASE_LOG(" PSR: 0x%08x\n", e_ctx->psr); MESOSPHERE_RELEASE_LOG(" TPIDR: 0x%08x\n", static_cast(e_ctx->tpidr)); } /* Resume the threads that we suspended. */ { KScopedSchedulerLock sl; auto end = process->GetThreadList().end(); for (auto it = process->GetThreadList().begin(); it != end; ++it) { if (std::addressof(*it) != GetCurrentThreadPointer()) { it->Resume(KThread::SuspendType_Backtrace); } } } } } #else MESOSPHERE_UNUSED(thread); #endif } #if defined(MESOSPHERE_BUILD_FOR_DEBUGGING) namespace { bool IsHeapPhysicalAddress(KPhysicalAddress phys_addr) { const KMemoryRegion *cached = nullptr; return KMemoryLayout::IsHeapPhysicalAddress(cached, phys_addr); } template bool ReadValue(T *out, KProcess *process, uintptr_t address) { KPhysicalAddress phys_addr; KMemoryInfo mem_info; ams::svc::PageInfo page_info; if (!util::IsAligned(address, sizeof(T))) { return false; } if (R_FAILED(process->GetPageTable().QueryInfo(std::addressof(mem_info), std::addressof(page_info), address))) { return false; } if ((mem_info.GetPermission() & KMemoryPermission_UserRead) != KMemoryPermission_UserRead) { return false; } if (!process->GetPageTable().GetPhysicalAddress(std::addressof(phys_addr), address)) { return false; } if (!IsHeapPhysicalAddress(phys_addr)) { return false; } *out = *GetPointer(process->GetPageTable().GetHeapVirtualAddress(phys_addr)); return true; } bool GetModuleName(char *dst, size_t dst_size, KProcess *process, uintptr_t base_address) { /* Locate .rodata. */ KMemoryInfo mem_info; ams::svc::PageInfo page_info; KMemoryState mem_state = KMemoryState_None; while (true) { if (R_FAILED(process->GetPageTable().QueryInfo(std::addressof(mem_info), std::addressof(page_info), base_address))) { return false; } if (mem_state == KMemoryState_None) { mem_state = mem_info.GetState(); if (mem_state != KMemoryState_Code && mem_state != KMemoryState_AliasCode) { return false; } } if (mem_info.GetState() != mem_state) { return false; } if (mem_info.GetPermission() == KMemoryPermission_UserRead) { break; } base_address = mem_info.GetEndAddress(); } /* Check that first value is 0. */ u32 val; if (!ReadValue(std::addressof(val), process, base_address)) { return false; } if (val != 0) { return false; } /* Read the name length. */ if (!ReadValue(std::addressof(val), process, base_address + sizeof(u32))) { return false; } if (!(0 < val && val < dst_size)) { return false; } const size_t name_len = val; /* Read the name, one character at a time. */ for (size_t i = 0; i < name_len; ++i) { if (!ReadValue(dst + i, process, base_address + 2 * sizeof(u32) + i)) { return false; } if (!(0 < dst[i] && dst[i] <= 0x7F)) { return false; } } /* NULL-terminate. */ dst[name_len] = 0; return true; } void PrintAddress(uintptr_t address) { MESOSPHERE_RELEASE_LOG(" %p\n", reinterpret_cast(address)); } void PrintAddressWithModuleName(uintptr_t address, bool has_module_name, const char *module_name, uintptr_t base_address) { if (has_module_name) { MESOSPHERE_RELEASE_LOG(" %p [%10s + %8lx]\n", reinterpret_cast(address), module_name, address - base_address); } else { MESOSPHERE_RELEASE_LOG(" %p [%10lx + %8lx]\n", reinterpret_cast(address), base_address, address - base_address); } } void PrintAddressWithSymbol(uintptr_t address, bool has_module_name, const char *module_name, uintptr_t base_address, const char *symbol_name, uintptr_t func_address) { if (has_module_name) { MESOSPHERE_RELEASE_LOG(" %p [%10s + %8lx] (%s + %lx)\n", reinterpret_cast(address), module_name, address - base_address, symbol_name, address - func_address); } else { MESOSPHERE_RELEASE_LOG(" %p [%10lx + %8lx] (%s + %lx)\n", reinterpret_cast(address), base_address, address - base_address, symbol_name, address - func_address); } } void PrintCodeAddress(KProcess *process, uintptr_t address, bool is_lr = true) { /* Prepare to parse + print the address. */ uintptr_t test_address = is_lr ? address - sizeof(u32) : address; uintptr_t base_address = address; uintptr_t dyn_address = 0; uintptr_t sym_tab = 0; uintptr_t str_tab = 0; size_t num_sym = 0; u64 temp_64; u32 temp_32; /* Locate the start of .text. */ KMemoryInfo mem_info; ams::svc::PageInfo page_info; KMemoryState mem_state = KMemoryState_None; while (true) { if (R_FAILED(process->GetPageTable().QueryInfo(std::addressof(mem_info), std::addressof(page_info), base_address))) { return PrintAddress(address); } if (mem_state == KMemoryState_None) { mem_state = mem_info.GetState(); if (mem_state != KMemoryState_Code && mem_state != KMemoryState_AliasCode) { return PrintAddress(address); } } else if (mem_info.GetState() != mem_state) { return PrintAddress(address); } if (mem_info.GetPermission() != KMemoryPermission_UserReadExecute) { return PrintAddress(address); } base_address = mem_info.GetAddress(); if (R_FAILED(process->GetPageTable().QueryInfo(std::addressof(mem_info), std::addressof(page_info), base_address - 1))) { return PrintAddress(address); } if (mem_info.GetState() != mem_state) { break; } if (mem_info.GetPermission() != KMemoryPermission_UserReadExecute) { break; } } /* Read the first instruction. */ if (!ReadValue(std::addressof(temp_32), process, base_address)) { return PrintAddress(address); } /* Get the module name. */ char module_name[0x20]; const bool has_module_name = GetModuleName(module_name, sizeof(module_name), process, base_address); /* If the process is 32-bit, just print the module. */ if (!process->Is64Bit()) { return PrintAddressWithModuleName(address, has_module_name, module_name, base_address); } if (temp_32 == 0) { /* Module is dynamically loaded by rtld. */ u32 mod_offset; if (!ReadValue(std::addressof(mod_offset), process, base_address + sizeof(u32))) { return PrintAddressWithModuleName(address, has_module_name, module_name, base_address); } if (!ReadValue(std::addressof(temp_32), process, base_address + mod_offset)) { return PrintAddressWithModuleName(address, has_module_name, module_name, base_address); } if (temp_32 != 0x30444F4D) { /* MOD0 */ return PrintAddressWithModuleName(address, has_module_name, module_name, base_address); } if (!ReadValue(std::addressof(temp_32), process, base_address + mod_offset + sizeof(u32))) { return PrintAddressWithModuleName(address, has_module_name, module_name, base_address); } dyn_address = base_address + mod_offset + temp_32; } else if (temp_32 == 0x14000002) { /* Module embeds rtld. */ if (!ReadValue(std::addressof(temp_32), process, base_address + 0x5C)) { return PrintAddressWithModuleName(address, has_module_name, module_name, base_address); } if (temp_32 != 0x94000002) { return PrintAddressWithModuleName(address, has_module_name, module_name, base_address); } if (!ReadValue(std::addressof(temp_32), process, base_address + 0x60)) { return PrintAddressWithModuleName(address, has_module_name, module_name, base_address); } dyn_address = base_address + 0x60 + temp_32; } else { return PrintAddressWithModuleName(address, has_module_name, module_name, base_address); } /* Locate tables inside .dyn. */ for (size_t ofs = 0; /* ... */; ofs += 0x10) { /* Read the DynamicTag. */ if (!ReadValue(std::addressof(temp_64), process, dyn_address + ofs)) { return PrintAddressWithModuleName(address, has_module_name, module_name, base_address); } if (temp_64 == 0) { /* We're done parsing .dyn. */ break; } else if (temp_64 == 4) { /* We found DT_HASH */ if (!ReadValue(std::addressof(temp_64), process, dyn_address + ofs + sizeof(u64))) { return PrintAddressWithModuleName(address, has_module_name, module_name, base_address); } /* Read nchain, to get the number of symbols. */ if (!ReadValue(std::addressof(temp_32), process, base_address + temp_64 + sizeof(u32))) { return PrintAddressWithModuleName(address, has_module_name, module_name, base_address); } num_sym = temp_32; } else if (temp_64 == 5) { /* We found DT_STRTAB */ if (!ReadValue(std::addressof(temp_64), process, dyn_address + ofs + sizeof(u64))) { return PrintAddressWithModuleName(address, has_module_name, module_name, base_address); } str_tab = base_address + temp_64; } else if (temp_64 == 6) { /* We found DT_SYMTAB */ if (!ReadValue(std::addressof(temp_64), process, dyn_address + ofs + sizeof(u64))) { return PrintAddressWithModuleName(address, has_module_name, module_name, base_address); } sym_tab = base_address + temp_64; } } /* Check that we found all the tables. */ if (!(sym_tab != 0 && str_tab != 0 && num_sym != 0)) { return PrintAddressWithModuleName(address, has_module_name, module_name, base_address); } /* Try to locate an appropriate symbol. */ for (size_t i = 0; i < num_sym; ++i) { /* Read the symbol from userspace. */ struct { u32 st_name; u8 st_info; u8 st_other; u16 st_shndx; u64 st_value; u64 st_size; } sym; { u64 x[sizeof(sym) / sizeof(u64)]; for (size_t j = 0; j < util::size(x); ++j) { if (!ReadValue(x + j, process, sym_tab + sizeof(sym) * i + sizeof(u64) * j)) { return PrintAddressWithModuleName(address, has_module_name, module_name, base_address); } } std::memcpy(std::addressof(sym), x, sizeof(sym)); } /* Check the symbol is valid/STT_FUNC. */ if (sym.st_shndx == 0 || ((sym.st_shndx & 0xFF00) == 0xFF00)) { continue; } if ((sym.st_info & 0xF) != 2) { continue; } /* Check the address. */ const uintptr_t func_start = base_address + sym.st_value; if (func_start <= test_address && test_address < func_start + sym.st_size) { /* Read the symbol name. */ const uintptr_t sym_address = str_tab + sym.st_name; char sym_name[0x80]; sym_name[util::size(sym_name) - 1] = 0; for (size_t j = 0; j < util::size(sym_name) - 1; ++j) { if (!ReadValue(sym_name + j, process, sym_address + j)) { return PrintAddressWithModuleName(address, has_module_name, module_name, base_address); } if (sym_name[j] == 0) { break; } } /* Print the symbol. */ return PrintAddressWithSymbol(address, has_module_name, module_name, base_address, sym_name, func_start); } } /* Fall back to printing the module. */ return PrintAddressWithModuleName(address, has_module_name, module_name, base_address); } } #endif void KDebug::PrintBacktrace(KThread *thread) { #if defined(MESOSPHERE_BUILD_FOR_DEBUGGING) { /* Treat no thread as current thread. */ if (thread == nullptr) { thread = GetCurrentThreadPointer(); } /* Get the exception context. */ KExceptionContext *e_ctx = GetExceptionContext(thread); /* Get the owner process. */ if (auto *process = thread->GetOwnerProcess(); process != nullptr) { /* Lock the owner process. */ KScopedLightLock state_lk(process->GetStateLock()); KScopedLightLock list_lk(process->GetListLock()); /* Suspend all the process's threads. */ { KScopedSchedulerLock sl; auto end = process->GetThreadList().end(); for (auto it = process->GetThreadList().begin(); it != end; ++it) { if (std::addressof(*it) != GetCurrentThreadPointer()) { it->RequestSuspend(KThread::SuspendType_Backtrace); } } } /* Print the backtrace. */ MESOSPHERE_RELEASE_LOG("User Backtrace\n"); if ((e_ctx->psr & 0x10) == 0) { /* 64-bit thread. */ PrintCodeAddress(process, e_ctx->pc, false); PrintCodeAddress(process, e_ctx->x[30]); /* Walk the stack frames. */ uintptr_t fp = static_cast(e_ctx->x[29]); for (auto i = 0; i < 0x20 && fp != 0 && util::IsAligned(fp, 0x10); ++i) { /* Read the next frame. */ struct { u64 fp; u64 lr; } stack_frame; { KMemoryInfo mem_info; ams::svc::PageInfo page_info; KPhysicalAddress phys_addr; if (R_FAILED(process->GetPageTable().QueryInfo(std::addressof(mem_info), std::addressof(page_info), fp))) { break; } if ((mem_info.GetState() & KMemoryState_FlagReferenceCounted) == 0) { break; } if ((mem_info.GetAttribute() & KMemoryAttribute_Uncached) != 0) { break; } if ((mem_info.GetPermission() & KMemoryPermission_UserRead) != KMemoryPermission_UserRead) { break; } if (!process->GetPageTable().GetPhysicalAddress(std::addressof(phys_addr), fp)) { break; } if (!IsHeapPhysicalAddress(phys_addr)) { break; } u64 *frame_ptr = GetPointer(process->GetPageTable().GetHeapVirtualAddress(phys_addr)); stack_frame.fp = frame_ptr[0]; stack_frame.lr = frame_ptr[1]; } /* Print and advance. */ PrintCodeAddress(process, stack_frame.lr); fp = stack_frame.fp; } } else { /* 32-bit thread. */ PrintCodeAddress(process, e_ctx->pc, false); PrintCodeAddress(process, e_ctx->x[14]); /* Walk the stack frames. */ uintptr_t fp = static_cast(e_ctx->x[11]); for (auto i = 0; i < 0x20 && fp != 0 && util::IsAligned(fp, 4); ++i) { /* Read the next frame. */ struct { u32 fp; u32 lr; } stack_frame; { KMemoryInfo mem_info; ams::svc::PageInfo page_info; KPhysicalAddress phys_addr; /* Read FP */ if (R_FAILED(process->GetPageTable().QueryInfo(std::addressof(mem_info), std::addressof(page_info), fp))) { break; } if ((mem_info.GetState() & KMemoryState_FlagReferenceCounted) == 0) { break; } if ((mem_info.GetAttribute() & KMemoryAttribute_Uncached) != 0) { break; } if ((mem_info.GetPermission() & KMemoryPermission_UserRead) != KMemoryPermission_UserRead) { break; } if (!process->GetPageTable().GetPhysicalAddress(std::addressof(phys_addr), fp)) { break; } if (!IsHeapPhysicalAddress(phys_addr)) { break; } stack_frame.fp = *GetPointer(process->GetPageTable().GetHeapVirtualAddress(phys_addr)); /* Read LR. */ uintptr_t lr_ptr = (e_ctx->x[13] <= stack_frame.fp && stack_frame.fp < e_ctx->x[13] + PageSize) ? fp + 4 : fp - 4; if (R_FAILED(process->GetPageTable().QueryInfo(std::addressof(mem_info), std::addressof(page_info), lr_ptr))) { break; } if ((mem_info.GetState() & KMemoryState_FlagReferenceCounted) == 0) { break; } if ((mem_info.GetAttribute() & KMemoryAttribute_Uncached) != 0) { break; } if ((mem_info.GetPermission() & KMemoryPermission_UserRead) != KMemoryPermission_UserRead) { break; } if (!process->GetPageTable().GetPhysicalAddress(std::addressof(phys_addr), lr_ptr)) { break; } if (!IsHeapPhysicalAddress(phys_addr)) { break; } stack_frame.lr = *GetPointer(process->GetPageTable().GetHeapVirtualAddress(phys_addr)); } /* Print and advance. */ PrintCodeAddress(process, stack_frame.lr); fp = stack_frame.fp; } } /* Resume the threads that we suspended. */ { KScopedSchedulerLock sl; auto end = process->GetThreadList().end(); for (auto it = process->GetThreadList().begin(); it != end; ++it) { if (std::addressof(*it) != GetCurrentThreadPointer()) { it->Resume(KThread::SuspendType_Backtrace); } } } } } #else MESOSPHERE_UNUSED(thread); #endif } }