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Atmosphere/libraries/libmesosphere/source/kern_k_debug_base.cpp

1187 lines
50 KiB
C++

/*
* 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 <http://www.gnu.org/licenses/>.
*/
#include <mesosphere.hpp>
namespace ams::kern {
namespace {
ALWAYS_INLINE KDebugBase *GetDebugObject(KProcess *process) {
return static_cast<KDebugBase *>(process->GetDebugObject());
}
}
void KDebugBase::Initialize() {
/* Clear the continue flags. */
m_continue_flags = 0;
m_is_force_debug_prod = GetCurrentProcess().CanForceDebugProd();
}
bool KDebugBase::Is64Bit() const {
MESOSPHERE_ASSERT(m_lock.IsLockedByCurrentThread());
MESOSPHERE_ASSERT(m_is_attached);
KProcess * const process = this->GetProcessUnsafe();
MESOSPHERE_ASSERT(process != nullptr);
return process->Is64Bit();
}
Result KDebugBase::QueryMemoryInfo(ams::svc::MemoryInfo *out_memory_info, ams::svc::PageInfo *out_page_info, KProcessAddress address) {
/* Check that we're attached. */
R_UNLESS(this->IsAttached(), svc::ResultProcessTerminated());
/* Open a reference to our process. */
R_UNLESS(this->OpenProcess(), svc::ResultProcessTerminated());
/* Close our reference to our process when we're done. */
ON_SCOPE_EXIT { this->CloseProcess(); };
/* Lock ourselves. */
KScopedLightLock lk(m_lock);
/* Check that we're still attached now that we're locked. */
R_UNLESS(this->IsAttached(), svc::ResultProcessTerminated());
/* Get the process pointer. */
KProcess * const process = this->GetProcessUnsafe();
/* Check that the process isn't terminated. */
R_UNLESS(!process->IsTerminated(), svc::ResultProcessTerminated());
/* Query the mapping's info. */
KMemoryInfo info;
R_TRY(process->GetPageTable().QueryInfo(std::addressof(info), out_page_info, address));
/* Write output. */
*out_memory_info = info.GetSvcMemoryInfo();
R_SUCCEED();
}
Result KDebugBase::ReadMemory(KProcessAddress buffer, KProcessAddress address, size_t size) {
/* Check that we're attached. */
R_UNLESS(this->IsAttached(), svc::ResultProcessTerminated());
/* Open a reference to our process. */
R_UNLESS(this->OpenProcess(), svc::ResultProcessTerminated());
/* Close our reference to our process when we're done. */
ON_SCOPE_EXIT { this->CloseProcess(); };
/* Lock ourselves. */
KScopedLightLock lk(m_lock);
/* Check that we're still attached now that we're locked. */
R_UNLESS(this->IsAttached(), svc::ResultProcessTerminated());
/* Get the process pointer. */
KProcess * const process = this->GetProcessUnsafe();
/* Check that the process isn't terminated. */
R_UNLESS(!process->IsTerminated(), svc::ResultProcessTerminated());
/* Get the page tables. */
KProcessPageTable &debugger_pt = GetCurrentProcess().GetPageTable();
KProcessPageTable &target_pt = process->GetPageTable();
/* Verify that the regions are in range. */
R_UNLESS(target_pt.Contains(address, size), svc::ResultInvalidCurrentMemory());
R_UNLESS(debugger_pt.Contains(buffer, size), svc::ResultInvalidCurrentMemory());
/* Iterate over the target process's memory blocks. */
KProcessAddress cur_address = address;
size_t remaining = size;
while (remaining > 0) {
/* Get the current memory info. */
KMemoryInfo info;
ams::svc::PageInfo pi;
R_TRY(target_pt.QueryInfo(std::addressof(info), std::addressof(pi), cur_address));
/* Check that the memory is accessible. */
R_UNLESS(info.GetState() != static_cast<KMemoryState>(ams::svc::MemoryState_Inaccessible), svc::ResultInvalidAddress());
/* Get the current size. */
const size_t cur_size = std::min(remaining, info.GetEndAddress() - GetInteger(cur_address));
/* Read the memory. */
if (info.GetSvcState() != ams::svc::MemoryState_Io) {
/* The memory is normal memory. */
R_TRY(target_pt.ReadDebugMemory(GetVoidPointer(buffer), cur_address, cur_size, this->IsForceDebugProd()));
} else {
/* Only allow IO memory to be read if not force debug prod. */
R_UNLESS(!this->IsForceDebugProd(), svc::ResultInvalidCurrentMemory());
/* The memory is IO memory. */
R_TRY(target_pt.ReadDebugIoMemory(GetVoidPointer(buffer), cur_address, cur_size, info.GetState()));
}
/* Advance. */
buffer += cur_size;
cur_address += cur_size;
remaining -= cur_size;
}
R_SUCCEED();
}
Result KDebugBase::WriteMemory(KProcessAddress buffer, KProcessAddress address, size_t size) {
/* Check that we're attached. */
R_UNLESS(this->IsAttached(), svc::ResultProcessTerminated());
/* Open a reference to our process. */
R_UNLESS(this->OpenProcess(), svc::ResultProcessTerminated());
/* Close our reference to our process when we're done. */
ON_SCOPE_EXIT { this->CloseProcess(); };
/* Lock ourselves. */
KScopedLightLock lk(m_lock);
/* Check that we're still attached now that we're locked. */
R_UNLESS(this->IsAttached(), svc::ResultProcessTerminated());
/* Get the process pointer. */
KProcess * const process = this->GetProcessUnsafe();
/* Check that the process isn't terminated. */
R_UNLESS(!process->IsTerminated(), svc::ResultProcessTerminated());
/* Get the page tables. */
KProcessPageTable &debugger_pt = GetCurrentProcess().GetPageTable();
KProcessPageTable &target_pt = process->GetPageTable();
/* Verify that the regions are in range. */
R_UNLESS(target_pt.Contains(address, size), svc::ResultInvalidCurrentMemory());
R_UNLESS(debugger_pt.Contains(buffer, size), svc::ResultInvalidCurrentMemory());
/* Iterate over the target process's memory blocks. */
KProcessAddress cur_address = address;
size_t remaining = size;
while (remaining > 0) {
/* Get the current memory info. */
KMemoryInfo info;
ams::svc::PageInfo pi;
R_TRY(target_pt.QueryInfo(std::addressof(info), std::addressof(pi), cur_address));
/* Check that the memory is accessible. */
R_UNLESS(info.GetState() != static_cast<KMemoryState>(ams::svc::MemoryState_Inaccessible), svc::ResultInvalidAddress());
/* Get the current size. */
const size_t cur_size = std::min(remaining, info.GetEndAddress() - GetInteger(cur_address));
/* Read the memory. */
if (info.GetSvcState() != ams::svc::MemoryState_Io) {
/* The memory is normal memory. */
R_TRY(target_pt.WriteDebugMemory(cur_address, GetVoidPointer(buffer), cur_size));
} else {
/* The memory is IO memory. */
R_TRY(target_pt.WriteDebugIoMemory(cur_address, GetVoidPointer(buffer), cur_size, info.GetState()));
}
/* Advance. */
buffer += cur_size;
cur_address += cur_size;
remaining -= cur_size;
}
R_SUCCEED();
}
Result KDebugBase::GetRunningThreadInfo(ams::svc::LastThreadContext *out_context, u64 *out_thread_id) {
/* Check that we're attached. */
R_UNLESS(this->IsAttached(), svc::ResultProcessTerminated());
/* Open a reference to our process. */
R_UNLESS(this->OpenProcess(), svc::ResultProcessTerminated());
/* Close our reference to our process when we're done. */
ON_SCOPE_EXIT { this->CloseProcess(); };
/* Get the process pointer. */
KProcess * const process = this->GetProcessUnsafe();
/* Get the thread info. */
{
KScopedSchedulerLock sl;
/* Get the running thread. */
const s32 core_id = GetCurrentCoreId();
KThread *thread = process->GetRunningThread(core_id);
/* We want to check that the thread is actually running. */
/* If it is, then the scheduler will have just switched from the thread to the current thread. */
/* This implies exactly one switch will have taken place, and the current thread will be on the current core. */
const auto &scheduler = Kernel::GetScheduler(core_id);
if (!(thread != nullptr && thread->GetActiveCore() == core_id && process->GetRunningThreadSwitchCount(core_id) + 1 == scheduler.GetSwitchCount())) {
/* The most recent thread switch was from a thread other than the expected one to the current one. */
/* We want to use the appropriate result to inform userland about what thread we switched from. */
if (scheduler.GetIdleCount() + 1 == scheduler.GetSwitchCount()) {
/* We switched from the idle thread. */
R_THROW(svc::ResultNoThread());
} else {
/* We switched from some other unknown thread. */
R_THROW(svc::ResultUnknownThread());
}
}
/* Get the thread's exception context. */
GetExceptionContext(thread)->GetSvcThreadContext(out_context);
/* Get the thread's id. */
*out_thread_id = thread->GetId();
}
R_SUCCEED();
}
Result KDebugBase::Attach(KProcess *target) {
/* Check that the process isn't null. */
MESOSPHERE_ASSERT(target != nullptr);
/* Clear ourselves as unattached. */
m_is_attached = false;
/* Attach to the process. */
{
/* Lock both ourselves, the target process, and the scheduler. */
KScopedLightLock state_lk(target->GetStateLock());
KScopedLightLock list_lk(target->GetListLock());
KScopedLightLock this_lk(m_lock);
KScopedSchedulerLock sl;
/* Check that the process isn't already being debugged. */
R_UNLESS(!target->IsAttachedToDebugger(), svc::ResultBusy());
{
/* Ensure the process is in a state that allows for debugging. */
const KProcess::State state = target->GetState();
switch (state) {
case KProcess::State_Created:
case KProcess::State_Running:
/* Created and running processes can only be debugged if the debugger is not ForceDebugProd. */
R_UNLESS(!this->IsForceDebugProd(), svc::ResultInvalidState());
break;
case KProcess::State_Crashed:
break;
case KProcess::State_CreatedAttached:
case KProcess::State_RunningAttached:
case KProcess::State_DebugBreak:
R_THROW(svc::ResultBusy());
case KProcess::State_Terminating:
case KProcess::State_Terminated:
R_THROW(svc::ResultProcessTerminated());
MESOSPHERE_UNREACHABLE_DEFAULT_CASE();
}
/* Attach to the target. */
m_process_holder.Attach(target);
m_is_attached = true;
/* Set ourselves as the process's attached object. */
m_old_process_state = target->SetDebugObject(this);
/* Send an event for our attaching to the process. */
this->PushDebugEvent(ams::svc::DebugEvent_CreateProcess, nullptr, 0);
/* Send events for attaching to each thread in the process. */
{
auto end = target->GetThreadList().end();
for (auto it = target->GetThreadList().begin(); it != end; ++it) {
/* Request that we suspend the thread. */
it->RequestSuspend(KThread::SuspendType_Debug);
/* If the thread is in a state for us to do so, generate the event. */
if (const auto thread_state = it->GetState(); thread_state == KThread::ThreadState_Runnable || thread_state == KThread::ThreadState_Waiting) {
/* Mark the thread as attached to. */
it->SetDebugAttached();
/* Send the event. */
const uintptr_t params[2] = { it->GetId(), GetInteger(it->GetThreadLocalRegionAddress()) };
this->PushDebugEvent(ams::svc::DebugEvent_CreateThread, params, util::size(params));
}
}
}
/* Send the process's jit debug info, if relevant. */
if (KEventInfo *jit_info = target->GetJitDebugInfo(); jit_info != nullptr) {
this->EnqueueDebugEventInfo(jit_info);
}
/* Send an exception event to represent our attaching. */
const uintptr_t params[1] = { static_cast<uintptr_t>(ams::svc::DebugException_DebuggerAttached) };
this->PushDebugEvent(ams::svc::DebugEvent_Exception, params, util::size(params));
/* Signal. */
this->NotifyAvailable();
}
}
R_SUCCEED();
}
Result KDebugBase::BreakProcess() {
/* Check that we're attached. */
R_UNLESS(this->IsAttached(), svc::ResultProcessTerminated());
/* Open a reference to our process. */
R_UNLESS(this->OpenProcess(), svc::ResultProcessTerminated());
/* Close our reference to our process when we're done. */
ON_SCOPE_EXIT { this->CloseProcess(); };
/* Get the process pointer. */
KProcess * const target = this->GetProcessUnsafe();
/* Lock both ourselves, the target process, and the scheduler. */
KScopedLightLock state_lk(target->GetStateLock());
KScopedLightLock list_lk(target->GetListLock());
KScopedLightLock this_lk(m_lock);
KScopedSchedulerLock sl;
/* Check that we're still attached now that we're locked. */
R_UNLESS(this->IsAttached(), svc::ResultProcessTerminated());
/* Check that the process isn't terminated. */
R_UNLESS(!target->IsTerminated(), svc::ResultProcessTerminated());
/* Get the currently active threads. */
constexpr u64 ThreadIdNoThread = -1ll;
constexpr u64 ThreadIdUnknownThread = -2ll;
uintptr_t debug_info_params[1 + cpu::NumCores] = { static_cast<uintptr_t>(ams::svc::DebugException_DebuggerBreak), };
for (size_t i = 0; i < cpu::NumCores; ++i) {
/* Get the currently running thread. */
KThread *thread = target->GetRunningThread(i);
/* Check that the thread's idle count is correct. */
if (target->GetRunningThreadIdleCount(i) == Kernel::GetScheduler(i).GetIdleCount()) {
if (thread != nullptr && static_cast<size_t>(thread->GetActiveCore()) == i) {
debug_info_params[1 + i] = thread->GetId();
} else {
/* We found an unknown thread. */
debug_info_params[1 + i] = ThreadIdUnknownThread;
}
} else {
/* We didn't find a thread. */
debug_info_params[1 + i] = ThreadIdNoThread;
}
}
/* Suspend all the threads in the process. */
{
auto end = target->GetThreadList().end();
for (auto it = target->GetThreadList().begin(); it != end; ++it) {
/* Request that we suspend the thread. */
it->RequestSuspend(KThread::SuspendType_Debug);
}
}
/* Send an exception event to represent our breaking the process. */
this->PushDebugEvent(ams::svc::DebugEvent_Exception, debug_info_params, util::size(debug_info_params));
/* Signal. */
this->NotifyAvailable();
/* Set the process as breaked. */
target->SetDebugBreak();
R_SUCCEED();
}
Result KDebugBase::TerminateProcess() {
/* Check that we're attached. */
R_UNLESS(this->IsAttached(), ResultSuccess());
/* Open a reference to our process. */
R_UNLESS(this->OpenProcess(), ResultSuccess());
/* Close our reference to our process when we're done. */
ON_SCOPE_EXIT { this->CloseProcess(); };
/* Get the process pointer. */
KProcess * const target = this->GetProcessUnsafe();
/* Terminate the process. */
target->Terminate();
R_SUCCEED();
}
Result KDebugBase::GetThreadContext(ams::svc::ThreadContext *out, u64 thread_id, u32 context_flags) {
/* Check that we're attached. */
R_UNLESS(this->IsAttached(), svc::ResultProcessTerminated());
/* Open a reference to our process. */
R_UNLESS(this->OpenProcess(), svc::ResultProcessTerminated());
/* Close our reference to our process when we're done. */
ON_SCOPE_EXIT { this->CloseProcess(); };
/* Lock ourselves. */
KScopedLightLock lk(m_lock);
/* Check that we're still attached now that we're locked. */
R_UNLESS(this->IsAttached(), svc::ResultProcessTerminated());
/* Get the process pointer. */
KProcess * const process = this->GetProcessUnsafe();
/* Get the thread from its id. */
KThread *thread = KThread::GetThreadFromId(thread_id);
R_UNLESS(thread != nullptr, svc::ResultInvalidId());
ON_SCOPE_EXIT { thread->Close(); };
/* Verify that the thread is owned by our process. */
R_UNLESS(process == thread->GetOwnerProcess(), svc::ResultInvalidId());
/* Verify that the thread isn't terminated. */
R_UNLESS(thread->GetState() != KThread::ThreadState_Terminated, svc::ResultTerminationRequested());
/* Check that the thread is not the current one. */
/* NOTE: Nintendo does not check this, and thus the following loop will deadlock. */
R_UNLESS(thread != GetCurrentThreadPointer(), svc::ResultInvalidId());
/* Try to get the thread context until the thread isn't current on any core. */
while (true) {
KScopedSchedulerLock sl;
/* The thread needs to be requested for debug suspension. */
R_UNLESS(thread->IsSuspendRequested(KThread::SuspendType_Debug), svc::ResultInvalidState());
/* If the thread's raw state isn't runnable, check if it's current on some core. */
if (thread->GetRawState() != KThread::ThreadState_Runnable) {
bool current = false;
for (auto i = 0; i < static_cast<s32>(cpu::NumCores); ++i) {
if (thread == Kernel::GetScheduler(i).GetSchedulerCurrentThread()) {
current = true;
break;
}
}
/* If the thread is current, retry until it isn't. */
if (current) {
continue;
}
}
/* Get the thread context. */
static_assert(std::derived_from<KDebug, KDebugBase>);
R_RETURN(static_cast<KDebug *>(this)->GetThreadContextImpl(out, thread, context_flags));
}
}
Result KDebugBase::SetThreadContext(const ams::svc::ThreadContext &ctx, u64 thread_id, u32 context_flags) {
/* Check that we're attached. */
R_UNLESS(this->IsAttached(), svc::ResultProcessTerminated());
/* Open a reference to our process. */
R_UNLESS(this->OpenProcess(), svc::ResultProcessTerminated());
/* Close our reference to our process when we're done. */
ON_SCOPE_EXIT { this->CloseProcess(); };
/* Lock ourselves. */
KScopedLightLock lk(m_lock);
/* Check that we're still attached now that we're locked. */
R_UNLESS(this->IsAttached(), svc::ResultProcessTerminated());
/* Get the process pointer. */
KProcess * const process = this->GetProcessUnsafe();
/* Get the thread from its id. */
KThread *thread = KThread::GetThreadFromId(thread_id);
R_UNLESS(thread != nullptr, svc::ResultInvalidId());
ON_SCOPE_EXIT { thread->Close(); };
/* Verify that the thread is owned by our process. */
R_UNLESS(process == thread->GetOwnerProcess(), svc::ResultInvalidId());
/* Verify that the thread isn't terminated. */
R_UNLESS(thread->GetState() != KThread::ThreadState_Terminated, svc::ResultTerminationRequested());
/* Check that the thread is not the current one. */
/* NOTE: Nintendo does not check this, and thus the following loop will deadlock. */
R_UNLESS(thread != GetCurrentThreadPointer(), svc::ResultInvalidId());
/* Try to get the thread context until the thread isn't current on any core. */
while (true) {
KScopedSchedulerLock sl;
/* The thread needs to be requested for debug suspension. */
R_UNLESS(thread->IsSuspendRequested(KThread::SuspendType_Debug), svc::ResultInvalidState());
/* If the thread's raw state isn't runnable, check if it's current on some core. */
if (thread->GetRawState() != KThread::ThreadState_Runnable) {
bool current = false;
for (auto i = 0; i < static_cast<s32>(cpu::NumCores); ++i) {
if (thread == Kernel::GetScheduler(i).GetSchedulerCurrentThread()) {
current = true;
break;
}
}
/* If the thread is current, retry until it isn't. */
if (current) {
continue;
}
}
/* Update thread single-step state. */
#if defined(MESOSPHERE_ENABLE_HARDWARE_SINGLE_STEP)
{
if ((context_flags & ams::svc::ThreadContextFlag_SetSingleStep) != 0) {
/* Set single step. */
thread->SetHardwareSingleStep();
/* If no other thread flags are present, we're done. */
R_SUCCEED_IF((context_flags & ~ams::svc::ThreadContextFlag_SetSingleStep) == 0);
} else if ((context_flags & ams::svc::ThreadContextFlag_ClearSingleStep) != 0) {
/* Clear single step. */
thread->ClearHardwareSingleStep();
/* If no other thread flags are present, we're done. */
R_SUCCEED_IF((context_flags & ~ams::svc::ThreadContextFlag_ClearSingleStep) == 0);
}
}
#endif
/* Verify that the thread's svc state is valid. */
if (thread->IsCallingSvc()) {
const u8 svc_id = thread->GetSvcId();
const bool is_valid_svc = svc_id == svc::SvcId_Break ||
svc_id == svc::SvcId_ReturnFromException;
R_UNLESS(is_valid_svc, svc::ResultInvalidState());
}
/* Set the thread context. */
static_assert(std::derived_from<KDebug, KDebugBase>);
R_RETURN(static_cast<KDebug *>(this)->SetThreadContextImpl(ctx, thread, context_flags));
}
}
Result KDebugBase::ContinueDebug(const u32 flags, const u64 *thread_ids, size_t num_thread_ids) {
/* Check that we're attached. */
R_UNLESS(this->IsAttached(), svc::ResultProcessTerminated());
/* Open a reference to our process. */
R_UNLESS(this->OpenProcess(), svc::ResultProcessTerminated());
/* Close our reference to our process when we're done. */
ON_SCOPE_EXIT { this->CloseProcess(); };
/* Get the process pointer. */
KProcess * const target = this->GetProcessUnsafe();
/* Lock both ourselves, the target process, and the scheduler. */
KScopedLightLock state_lk(target->GetStateLock());
KScopedLightLock list_lk(target->GetListLock());
KScopedLightLock this_lk(m_lock);
KScopedSchedulerLock sl;
/* Check that we're still attached now that we're locked. */
R_UNLESS(this->IsAttached(), svc::ResultProcessTerminated());
/* Check that the process isn't terminated. */
R_UNLESS(!target->IsTerminated(), svc::ResultProcessTerminated());
/* Check that we have no pending events. */
R_UNLESS(m_event_info_list.empty(), svc::ResultBusy());
/* Clear the target's JIT debug info. */
target->ClearJitDebugInfo();
/* Set our continue flags. */
m_continue_flags = flags;
/* Iterate over threads, continuing them as we should. */
bool has_debug_break_thread = false;
{
/* Parse our flags. */
const bool exception_handled = (m_continue_flags & ams::svc::ContinueFlag_ExceptionHandled) != 0;
const bool continue_all = (m_continue_flags & ams::svc::ContinueFlag_ContinueAll) != 0;
const bool continue_others = (m_continue_flags & ams::svc::ContinueFlag_ContinueOthers) != 0;
/* Update each thread. */
auto end = target->GetThreadList().end();
for (auto it = target->GetThreadList().begin(); it != end; ++it) {
/* Determine if we should continue the thread. */
bool should_continue;
{
if (continue_all) {
/* Continue all threads. */
should_continue = true;
} else if (continue_others) {
/* Continue the thread if it doesn't match one of our target ids. */
const u64 thread_id = it->GetId();
should_continue = true;
for (size_t i = 0; i < num_thread_ids; ++i) {
if (thread_ids[i] == thread_id) {
should_continue = false;
break;
}
}
} else {
/* Continue the thread if it matches one of our target ids. */
const u64 thread_id = it->GetId();
should_continue = false;
for (size_t i = 0; i < num_thread_ids; ++i) {
if (thread_ids[i] == thread_id) {
should_continue = true;
break;
}
}
}
}
/* Continue the thread if we should. */
if (should_continue) {
if (exception_handled) {
it->SetDebugExceptionResult(svc::ResultStopProcessingException());
}
it->Resume(KThread::SuspendType_Debug);
}
/* If the thread has debug suspend requested, note so. */
if (it->IsSuspendRequested(KThread::SuspendType_Debug)) {
has_debug_break_thread = true;
}
}
}
/* Set the process's state. */
if (has_debug_break_thread) {
target->SetDebugBreak();
} else {
target->SetAttached();
}
R_SUCCEED();
}
KEventInfo *KDebugBase::CreateDebugEvent(ams::svc::DebugEvent event, u64 cur_thread_id, const uintptr_t *params, size_t num_params) {
/* Allocate a new event. */
KEventInfo *info = KEventInfo::Allocate();
/* Populate the event info. */
if (info != nullptr) {
/* Set common fields. */
info->event = event;
info->thread_id = 0;
info->flags = ams::svc::DebugEventFlag_Stopped;
/* Set event specific fields. */
switch (event) {
case ams::svc::DebugEvent_CreateProcess:
{
/* Check parameters. */
MESOSPHERE_ASSERT(params == nullptr);
MESOSPHERE_ASSERT(num_params == 0);
}
break;
case ams::svc::DebugEvent_CreateThread:
{
/* Check parameters. */
MESOSPHERE_ASSERT(params != nullptr);
MESOSPHERE_ASSERT(num_params == 2);
/* Set the thread id. */
info->thread_id = params[0];
/* Set the thread creation info. */
info->info.create_thread.thread_id = params[0];
info->info.create_thread.tls_address = params[1];
}
break;
case ams::svc::DebugEvent_ExitProcess:
{
/* Check parameters. */
MESOSPHERE_ASSERT(params != nullptr);
MESOSPHERE_ASSERT(num_params == 1);
/* Set the exit reason. */
info->info.exit_process.reason = static_cast<ams::svc::ProcessExitReason>(params[0]);
/* Clear the thread id and flags. */
info->thread_id = 0;
info->flags = 0;
}
break;
case ams::svc::DebugEvent_ExitThread:
{
/* Check parameters. */
MESOSPHERE_ASSERT(params != nullptr);
MESOSPHERE_ASSERT(num_params == 2);
/* Set the thread id. */
info->thread_id = params[0];
/* Set the exit reason. */
info->info.exit_thread.reason = static_cast<ams::svc::ThreadExitReason>(params[1]);
}
break;
case ams::svc::DebugEvent_Exception:
{
/* Check parameters. */
MESOSPHERE_ASSERT(params != nullptr);
MESOSPHERE_ASSERT(num_params >= 1);
/* Set the thread id. */
info->thread_id = cur_thread_id;
/* Set the exception type, and clear the count. */
info->info.exception.exception_type = static_cast<ams::svc::DebugException>(params[0]);
info->info.exception.exception_data_count = 0;
switch (static_cast<ams::svc::DebugException>(params[0])) {
case ams::svc::DebugException_UndefinedInstruction:
case ams::svc::DebugException_BreakPoint:
case ams::svc::DebugException_UndefinedSystemCall:
{
MESOSPHERE_ASSERT(num_params >= 3);
info->info.exception.exception_address = params[1];
info->info.exception.exception_data_count = 1;
info->info.exception.exception_data[0] = params[2];
}
break;
case ams::svc::DebugException_DebuggerAttached:
{
info->thread_id = 0;
info->info.exception.exception_address = 0;
}
break;
case ams::svc::DebugException_UserBreak:
{
MESOSPHERE_ASSERT(num_params >= 2);
info->info.exception.exception_address = params[1];
info->info.exception.exception_data_count = 0;
for (size_t i = 2; i < num_params; ++i) {
info->info.exception.exception_data[info->info.exception.exception_data_count++] = params[i];
}
}
break;
case ams::svc::DebugException_DebuggerBreak:
{
info->thread_id = 0;
info->info.exception.exception_address = 0;
info->info.exception.exception_data_count = 0;
for (size_t i = 1; i < num_params; ++i) {
info->info.exception.exception_data[info->info.exception.exception_data_count++] = params[i];
}
}
break;
case ams::svc::DebugException_MemorySystemError:
{
info->info.exception.exception_address = 0;
}
break;
case ams::svc::DebugException_InstructionAbort:
case ams::svc::DebugException_DataAbort:
case ams::svc::DebugException_AlignmentFault:
default:
{
MESOSPHERE_ASSERT(num_params >= 2);
info->info.exception.exception_address = params[1];
}
break;
}
}
break;
}
}
return info;
}
void KDebugBase::PushDebugEvent(ams::svc::DebugEvent event, const uintptr_t *params, size_t num_params) {
/* Create and enqueue and event. */
if (KEventInfo *new_info = CreateDebugEvent(event, GetCurrentThread().GetId(), params, num_params); new_info != nullptr) {
this->EnqueueDebugEventInfo(new_info);
}
}
void KDebugBase::EnqueueDebugEventInfo(KEventInfo *info) {
/* Lock the scheduler. */
KScopedSchedulerLock sl;
/* Push the event to the back of the list. */
m_event_info_list.push_back(*info);
}
template<typename T> requires (std::same_as<T, ams::svc::lp64::DebugEventInfo> || std::same_as<T, ams::svc::ilp32::DebugEventInfo>)
Result KDebugBase::GetDebugEventInfoImpl(T *out) {
/* Check that we're attached. */
R_UNLESS(this->IsAttached(), svc::ResultProcessTerminated());
/* Open a reference to our process. */
R_UNLESS(this->OpenProcess(), svc::ResultProcessTerminated());
/* Close our reference to our process when we're done. */
ON_SCOPE_EXIT { this->CloseProcess(); };
/* Get the process pointer. */
KProcess * const process = this->GetProcessUnsafe();
/* Pop an event info from our queue. */
KEventInfo *info = nullptr;
{
KScopedSchedulerLock sl;
/* Check that we have an event to dequeue. */
R_UNLESS(!m_event_info_list.empty(), svc::ResultNoEvent());
/* Pop the event from the front of the queue. */
info = std::addressof(m_event_info_list.front());
m_event_info_list.pop_front();
}
MESOSPHERE_ASSERT(info != nullptr);
/* Free the event info once we're done with it. */
ON_SCOPE_EXIT { KEventInfo::Free(info); };
/* Set common fields. */
out->type = info->event;
out->thread_id = info->thread_id;
out->flags = info->flags;
/* Set event specific fields. */
switch (info->event) {
case ams::svc::DebugEvent_CreateProcess:
{
out->info.create_process.program_id = process->GetProgramId();
out->info.create_process.process_id = process->GetId();
out->info.create_process.flags = process->GetCreateProcessFlags();
out->info.create_process.user_exception_context_address = GetInteger(process->GetProcessLocalRegionAddress());
std::memcpy(out->info.create_process.name, process->GetName(), sizeof(out->info.create_process.name));
}
break;
case ams::svc::DebugEvent_CreateThread:
{
out->info.create_thread.thread_id = info->info.create_thread.thread_id;
out->info.create_thread.tls_address = info->info.create_thread.tls_address;
}
break;
case ams::svc::DebugEvent_ExitProcess:
{
out->info.exit_process.reason = info->info.exit_process.reason;
}
break;
case ams::svc::DebugEvent_ExitThread:
{
out->info.exit_thread.reason = info->info.exit_thread.reason;
}
break;
case ams::svc::DebugEvent_Exception:
{
out->info.exception.type = info->info.exception.exception_type;
out->info.exception.address = info->info.exception.exception_address;
switch (info->info.exception.exception_type) {
case ams::svc::DebugException_UndefinedInstruction:
{
MESOSPHERE_ASSERT(info->info.exception.exception_data_count == 1);
/* Only save the instruction if the caller is not force debug prod. */
if (this->IsForceDebugProd()) {
out->info.exception.specific.undefined_instruction.insn = 0;
} else {
out->info.exception.specific.undefined_instruction.insn = info->info.exception.exception_data[0];
}
}
break;
case ams::svc::DebugException_BreakPoint:
{
MESOSPHERE_ASSERT(info->info.exception.exception_data_count == 1);
out->info.exception.specific.break_point.type = static_cast<ams::svc::BreakPointType>(info->info.exception.exception_data[0]);
out->info.exception.specific.break_point.address = 0;
}
break;
case ams::svc::DebugException_UserBreak:
{
MESOSPHERE_ASSERT(info->info.exception.exception_data_count == 3);
out->info.exception.specific.user_break.break_reason = static_cast<ams::svc::BreakReason>(info->info.exception.exception_data[0]);
out->info.exception.specific.user_break.address = info->info.exception.exception_data[1];
out->info.exception.specific.user_break.size = info->info.exception.exception_data[2];
}
break;
case ams::svc::DebugException_DebuggerBreak:
{
/* TODO: How does this work with non-4 cpu count? */
static_assert(cpu::NumCores <= 4);
MESOSPHERE_ASSERT(info->info.exception.exception_data_count == cpu::NumCores);
out->info.exception.specific.debugger_break.active_thread_ids[0] = info->info.exception.exception_data[0];
out->info.exception.specific.debugger_break.active_thread_ids[1] = info->info.exception.exception_data[1];
out->info.exception.specific.debugger_break.active_thread_ids[2] = info->info.exception.exception_data[2];
out->info.exception.specific.debugger_break.active_thread_ids[3] = info->info.exception.exception_data[3];
}
break;
case ams::svc::DebugException_UndefinedSystemCall:
{
MESOSPHERE_ASSERT(info->info.exception.exception_data_count == 1);
out->info.exception.specific.undefined_system_call.id = info->info.exception.exception_data[0];
}
break;
default:
{
/* ... */
}
break;
}
}
break;
}
R_SUCCEED();
}
Result KDebugBase::GetDebugEventInfo(ams::svc::lp64::DebugEventInfo *out) {
R_RETURN(this->GetDebugEventInfoImpl(out));
}
Result KDebugBase::GetDebugEventInfo(ams::svc::ilp32::DebugEventInfo *out) {
R_RETURN(this->GetDebugEventInfoImpl(out));
}
void KDebugBase::Finalize() {
/* Perform base finalization. */
KSynchronizationObject::Finalize();
/* Perform post-synchronization finalization. */
this->OnFinalizeSynchronizationObject();
}
void KDebugBase::OnFinalizeSynchronizationObject() {
/* Detach from our process, if we have one. */
if (this->IsAttached() && this->OpenProcess()) {
/* Close the process when we're done with it. */
ON_SCOPE_EXIT { this->CloseProcess(); };
/* Get the process pointer. */
KProcess * const process = this->GetProcessUnsafe();
/* Lock both ourselves and the target process. */
KScopedLightLock state_lk(process->GetStateLock());
KScopedLightLock list_lk(process->GetListLock());
KScopedLightLock this_lk(m_lock);
/* Check that we're still attached. */
if (m_is_attached) {
KScopedSchedulerLock sl;
/* Detach ourselves from the process. */
process->ClearDebugObject(m_old_process_state);
/* Release all threads. */
const bool resume = (process->GetState() != KProcess::State_Crashed);
{
auto end = process->GetThreadList().end();
for (auto it = process->GetThreadList().begin(); it != end; ++it) {
#if defined(MESOSPHERE_ENABLE_HARDWARE_SINGLE_STEP)
/* Clear the thread's single-step state. */
it->ClearHardwareSingleStep();
#endif
if (resume) {
/* If the process isn't crashed, resume threads. */
it->Resume(KThread::SuspendType_Debug);
} else {
/* Otherwise, suspend them. */
it->RequestSuspend(KThread::SuspendType_Debug);
}
}
}
/* Note we're now unattached. */
m_is_attached = false;
/* Close the initial reference opened to our process. */
this->CloseProcess();
}
}
/* Free any pending events. */
{
KScopedSchedulerLock sl;
while (!m_event_info_list.empty()) {
KEventInfo *info = std::addressof(m_event_info_list.front());
m_event_info_list.pop_front();
KEventInfo::Free(info);
}
}
}
bool KDebugBase::IsSignaled() const {
bool empty;
{
KScopedSchedulerLock sl;
empty = m_event_info_list.empty();
}
return !empty || !m_is_attached || this->GetProcessUnsafe()->IsTerminated();
}
Result KDebugBase::ProcessDebugEvent(ams::svc::DebugEvent event, const uintptr_t *params, size_t num_params) {
/* Get the current process. */
KProcess *process = GetCurrentProcessPointer();
/* If the event is CreateThread and we've already attached, there's nothing to do. */
if (event == ams::svc::DebugEvent_CreateThread) {
R_SUCCEED_IF(GetCurrentThread().IsAttachedToDebugger());
}
while (true) {
/* Lock the process and the scheduler. */
KScopedLightLock state_lk(process->GetStateLock());
KScopedLightLock list_lk(process->GetListLock());
KScopedSchedulerLock sl;
/* If the current thread is terminating, we can't process an event. */
R_SUCCEED_IF(GetCurrentThread().IsTerminationRequested());
/* Get the debug object. If we have none, there's nothing to process. */
KDebugBase *debug = GetDebugObject(process);
R_SUCCEED_IF(debug == nullptr);
/* If the event is an exception and we don't have exception events enabled, we can't handle the event. */
if (event == ams::svc::DebugEvent_Exception && (debug->m_continue_flags & ams::svc::ContinueFlag_EnableExceptionEvent) == 0) {
GetCurrentThread().SetDebugExceptionResult(ResultSuccess());
R_THROW(svc::ResultNotHandled());
}
/* If the current thread is suspended, retry. */
if (GetCurrentThread().IsSuspended()) {
continue;
}
/* Suspend all the process's threads. */
{
auto end = process->GetThreadList().end();
for (auto it = process->GetThreadList().begin(); it != end; ++it) {
it->RequestSuspend(KThread::SuspendType_Debug);
}
}
/* Push the event. */
debug->PushDebugEvent(event, params, num_params);
debug->NotifyAvailable();
/* Set the process as breaked. */
process->SetDebugBreak();
/* If the event is an exception, set the result and clear single step. */
if (event == ams::svc::DebugEvent_Exception) {
GetCurrentThread().SetDebugExceptionResult(ResultSuccess());
}
/* Exit our retry loop. */
break;
}
/* If the event is an exception, get the exception result. */
if (event == ams::svc::DebugEvent_Exception) {
/* Lock the scheduler. */
KScopedSchedulerLock sl;
/* If the thread is terminating, we can't process the exception. */
R_UNLESS(!GetCurrentThread().IsTerminationRequested(), svc::ResultStopProcessingException());
/* Get the debug object. */
if (KDebugBase *debug = GetDebugObject(process); debug != nullptr) {
/* If we have one, check the debug exception. */
R_RETURN(GetCurrentThread().GetDebugExceptionResult());
} else {
/* We don't have a debug object, so stop processing the exception. */
R_THROW(svc::ResultStopProcessingException());
}
}
R_SUCCEED();
}
Result KDebugBase::OnDebugEvent(ams::svc::DebugEvent event, const uintptr_t *params, size_t num_params) {
if (KProcess *process = GetCurrentProcessPointer(); process != nullptr && process->IsAttachedToDebugger()) {
R_RETURN(ProcessDebugEvent(event, params, num_params));
}
R_SUCCEED();
}
Result KDebugBase::OnExitProcess(KProcess *process) {
MESOSPHERE_ASSERT(process != nullptr);
/* Check if we're attached to a debugger. */
if (process->IsAttachedToDebugger()) {
/* If we are, lock the scheduler. */
KScopedSchedulerLock sl;
/* Push the event. */
if (KDebugBase *debug = GetDebugObject(process); debug != nullptr) {
const uintptr_t params[1] = { static_cast<uintptr_t>(ams::svc::ProcessExitReason_ExitProcess) };
debug->PushDebugEvent(ams::svc::DebugEvent_ExitProcess, params, util::size(params));
debug->NotifyAvailable();
}
}
R_SUCCEED();
}
Result KDebugBase::OnTerminateProcess(KProcess *process) {
MESOSPHERE_ASSERT(process != nullptr);
/* Check if we're attached to a debugger. */
if (process->IsAttachedToDebugger()) {
/* If we are, lock the scheduler. */
KScopedSchedulerLock sl;
/* Push the event. */
if (KDebugBase *debug = GetDebugObject(process); debug != nullptr) {
const uintptr_t params[1] = { static_cast<uintptr_t>(ams::svc::ProcessExitReason_TerminateProcess) };
debug->PushDebugEvent(ams::svc::DebugEvent_ExitProcess, params, util::size(params));
debug->NotifyAvailable();
}
}
R_SUCCEED();
}
Result KDebugBase::OnExitThread(KThread *thread) {
MESOSPHERE_ASSERT(thread != nullptr);
/* Check if we're attached to a debugger. */
if (KProcess *process = thread->GetOwnerProcess(); process != nullptr && process->IsAttachedToDebugger()) {
/* If we are, submit the event. */
const uintptr_t params[2] = { thread->GetId(), static_cast<uintptr_t>(thread->IsTerminationRequested() ? ams::svc::ThreadExitReason_TerminateThread : ams::svc::ThreadExitReason_ExitThread) };
R_TRY(OnDebugEvent(ams::svc::DebugEvent_ExitThread, params, util::size(params)));
}
R_SUCCEED();
}
}