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Cleanup ThreadState and XThread

This commit is contained in:
Dr. Chat 2015-11-27 23:07:06 -06:00 committed by Ben Vanik
parent 41d5b41523
commit 666f5543a8
6 changed files with 133 additions and 150 deletions
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5
src/xenia/cpu/ppc/testing/ppc_testing_main.cc
View File

@ -214,9 +214,8 @@ class TestRunner {
uint32_t stack_size = 64 * 1024; uint32_t stack_size = 64 * 1024;
uint32_t stack_address = START_ADDRESS - stack_size; uint32_t stack_address = START_ADDRESS - stack_size;
uint32_t pcr_address = stack_address - 0x1000; uint32_t pcr_address = stack_address - 0x1000;
thread_state.reset(new ThreadState(processor.get(), 0x100, thread_state.reset(
ThreadStackType::kUserStack, new ThreadState(processor.get(), 0x100, stack_address, pcr_address));
stack_address, stack_size, pcr_address));
return true; return true;
} }

5
src/xenia/cpu/testing/util.h
View File

@ -72,9 +72,8 @@ class TestFunction {
uint32_t stack_size = 64 * 1024; uint32_t stack_size = 64 * 1024;
uint32_t stack_address = memory_size - stack_size; uint32_t stack_address = memory_size - stack_size;
uint32_t thread_state_address = stack_address - 0x1000; uint32_t thread_state_address = stack_address - 0x1000;
auto thread_state = std::make_unique<ThreadState>( auto thread_state = std::make_unique<ThreadState>(processor.get(), 0x100);
processor.get(), 0x100, ThreadStackType::kUserStack, stack_address, assert_always(); // TODO: Allocate a thread stack!!!
stack_size, thread_state_address);
auto ctx = thread_state->context(); auto ctx = thread_state->context();
ctx->lr = 0xBCBCBCBC; ctx->lr = 0xBCBCBCBC;

55
src/xenia/cpu/thread_state.cc
View File

@ -26,16 +26,10 @@ namespace cpu {
thread_local ThreadState* thread_state_ = nullptr; thread_local ThreadState* thread_state_ = nullptr;
ThreadState::ThreadState(Processor* processor, uint32_t thread_id, ThreadState::ThreadState(Processor* processor, uint32_t thread_id,
ThreadStackType stack_type, uint32_t stack_address, uint32_t stack_base, uint32_t pcr_address)
uint32_t stack_size, uint32_t pcr_address)
: processor_(processor), : processor_(processor),
memory_(processor->memory()), memory_(processor->memory()),
thread_id_(thread_id), thread_id_(thread_id) {
stack_type_(stack_type),
name_(""),
backend_data_(0),
stack_size_(stack_size),
pcr_address_(pcr_address) {
if (thread_id_ == UINT_MAX) { if (thread_id_ == UINT_MAX) {
// System thread. Assign the system thread ID with a high bit // System thread. Assign the system thread ID with a high bit
// set so people know what's up. // set so people know what's up.
@ -44,44 +38,6 @@ ThreadState::ThreadState(Processor* processor, uint32_t thread_id,
} }
backend_data_ = processor->backend()->AllocThreadData(); backend_data_ = processor->backend()->AllocThreadData();
if (!stack_address) {
// We must always allocate 64K as a guard region before stacks, as we can
// only Protect() on system page granularity.
auto heap = memory()->LookupHeap(0x40000000);
stack_size = (stack_size + 0xFFF) & 0xFFFFF000;
uint32_t stack_alignment = (stack_size & 0xF000) ? 0x1000 : 0x10000;
uint32_t stack_padding = heap->page_size();
uint32_t actual_stack_size = stack_padding + stack_size;
bool top_down = false;
switch (stack_type) {
case ThreadStackType::kKernelStack:
top_down = true;
break;
case ThreadStackType::kUserStack:
top_down = false;
break;
default:
assert_unhandled_case(stack_type);
break;
}
heap->AllocRange(0x40000000, 0x7FFFFFFF, actual_stack_size, stack_alignment,
kMemoryAllocationReserve | kMemoryAllocationCommit,
kMemoryProtectRead | kMemoryProtectWrite, top_down,
&stack_address_);
assert_true(!(stack_address_ & 0xFFF)); // just to be safe
stack_allocated_ = true;
stack_base_ = stack_address_ + actual_stack_size;
stack_limit_ = stack_address_ + stack_padding;
memory()->Fill(stack_address_, actual_stack_size, 0xBE);
heap->Protect(stack_address_, stack_padding, kMemoryProtectNoAccess);
} else {
stack_address_ = stack_address;
stack_allocated_ = false;
stack_base_ = stack_address_ + stack_size;
stack_limit_ = stack_address_;
}
assert_not_zero(stack_address_);
// Allocate with 64b alignment. // Allocate with 64b alignment.
context_ = memory::AlignedAlloc<ppc::PPCContext>(64); context_ = memory::AlignedAlloc<ppc::PPCContext>(64);
assert_true(((uint64_t)context_ & 0x3F) == 0); assert_true(((uint64_t)context_ & 0x3F) == 0);
@ -96,8 +52,8 @@ ThreadState::ThreadState(Processor* processor, uint32_t thread_id,
context_->thread_id = thread_id_; context_->thread_id = thread_id_;
// Set initial registers. // Set initial registers.
context_->r[1] = stack_base_; context_->r[1] = stack_base;
context_->r[13] = pcr_address_; context_->r[13] = pcr_address;
} }
ThreadState::~ThreadState() { ThreadState::~ThreadState() {
@ -109,9 +65,6 @@ ThreadState::~ThreadState() {
} }
memory::AlignedFree(context_); memory::AlignedFree(context_);
if (stack_allocated_) {
memory()->LookupHeap(stack_address_)->Decommit(stack_address_, stack_size_);
}
} }
void ThreadState::Bind(ThreadState* thread_state) { void ThreadState::Bind(ThreadState* thread_state) {

32
src/xenia/cpu/thread_state.h
View File

@ -21,31 +21,17 @@ namespace cpu {
class Processor; class Processor;
enum class ThreadStackType {
kKernelStack,
kUserStack,
};
class ThreadState { class ThreadState {
public: public:
ThreadState(Processor* processor, uint32_t thread_id, ThreadState(Processor* processor, uint32_t thread_id, uint32_t stack_base = 0,
ThreadStackType stack_type, uint32_t stack_address, uint32_t pcr_address = 0);
uint32_t stack_size, uint32_t pcr_address);
~ThreadState(); ~ThreadState();
Processor* processor() const { return processor_; } Processor* processor() const { return processor_; }
Memory* memory() const { return memory_; } Memory* memory() const { return memory_; }
uint32_t thread_id() const { return thread_id_; }
ThreadStackType stack_type() const { return stack_type_; }
const std::string& name() const { return name_; }
void set_name(const std::string& value) { name_ = value; }
void* backend_data() const { return backend_data_; } void* backend_data() const { return backend_data_; }
uint32_t stack_address() const { return stack_address_; }
uint32_t stack_size() const { return stack_size_; }
uint32_t stack_base() const { return stack_base_; }
uint32_t stack_limit() const { return stack_limit_; }
uint32_t pcr_address() const { return pcr_address_; }
ppc::PPCContext* context() const { return context_; } ppc::PPCContext* context() const { return context_; }
uint32_t thread_id() const { return thread_id_; }
static void Bind(ThreadState* thread_state); static void Bind(ThreadState* thread_state);
static ThreadState* Get(); static ThreadState* Get();
@ -54,16 +40,10 @@ class ThreadState {
private: private:
Processor* processor_; Processor* processor_;
Memory* memory_; Memory* memory_;
uint32_t thread_id_;
ThreadStackType stack_type_;
std::string name_;
void* backend_data_; void* backend_data_;
uint32_t stack_address_;
bool stack_allocated_; uint32_t pcr_address_ = 0;
uint32_t stack_size_; uint32_t thread_id_ = 0;
uint32_t stack_base_;
uint32_t stack_limit_;
uint32_t pcr_address_;
// NOTE: must be 64b aligned for SSE ops. // NOTE: must be 64b aligned for SSE ops.
ppc::PPCContext* context_; ppc::PPCContext* context_;

177
src/xenia/kernel/xthread.cc
View File

@ -35,6 +35,12 @@ namespace kernel {
uint32_t next_xthread_id_ = 0; uint32_t next_xthread_id_ = 0;
thread_local XThread* current_thread_tls_ = nullptr; thread_local XThread* current_thread_tls_ = nullptr;
XThread::XThread(KernelState* kernel_state)
: XObject(kernel_state, kTypeThread), apc_list_(kernel_state->memory()) {
// The kernel does not take a reference. We must unregister in the dtor.
kernel_state_->RegisterThread(this);
}
XThread::XThread(KernelState* kernel_state, uint32_t stack_size, XThread::XThread(KernelState* kernel_state, uint32_t stack_size,
uint32_t xapi_thread_startup, uint32_t start_address, uint32_t xapi_thread_startup, uint32_t start_address,
uint32_t start_context, uint32_t creation_flags, uint32_t start_context, uint32_t creation_flags,
@ -124,11 +130,15 @@ void XThread::set_last_error(uint32_t error_code) {
} }
void XThread::set_name(const std::string& name) { void XThread::set_name(const std::string& name) {
name_ = name; StringBuffer buff;
buff.Append(name);
buff.AppendFormat(" (%.8X)", handle());
name_ = buff.ToString();
if (thread_) { if (thread_) {
// May be getting set before the thread is created. // May be getting set before the thread is created.
// One the thread is ready it will handle it. // One the thread is ready it will handle it.
thread_->set_name(name); thread_->set_name(buff.ToString());
} }
} }
@ -149,16 +159,96 @@ uint8_t GetFakeCpuNumber(uint8_t proc_mask) {
return cpu_number; return cpu_number;
} }
void XThread::InitializeGuestObject() {
auto guest_thread = guest_object<X_KTHREAD>();
// Setup the thread state block (last error/etc).
uint8_t* p = memory()->TranslateVirtual(guest_object());
guest_thread->header.type = 6;
guest_thread->suspend_count =
(creation_params_.creation_flags & X_CREATE_SUSPENDED) ? 1 : 0;
xe::store_and_swap<uint32_t>(p + 0x010, guest_object() + 0x010);
xe::store_and_swap<uint32_t>(p + 0x014, guest_object() + 0x010);
xe::store_and_swap<uint32_t>(p + 0x040, guest_object() + 0x018 + 8);
xe::store_and_swap<uint32_t>(p + 0x044, guest_object() + 0x018 + 8);
xe::store_and_swap<uint32_t>(p + 0x048, guest_object());
xe::store_and_swap<uint32_t>(p + 0x04C, guest_object() + 0x018);
xe::store_and_swap<uint16_t>(p + 0x054, 0x102);
xe::store_and_swap<uint16_t>(p + 0x056, 1);
xe::store_and_swap<uint32_t>(p + 0x05C, stack_base_);
xe::store_and_swap<uint32_t>(p + 0x060, stack_limit_);
xe::store_and_swap<uint32_t>(p + 0x068, tls_address_);
xe::store_and_swap<uint8_t>(p + 0x06C, 0);
xe::store_and_swap<uint32_t>(p + 0x074, guest_object() + 0x074);
xe::store_and_swap<uint32_t>(p + 0x078, guest_object() + 0x074);
xe::store_and_swap<uint32_t>(p + 0x07C, guest_object() + 0x07C);
xe::store_and_swap<uint32_t>(p + 0x080, guest_object() + 0x07C);
xe::store_and_swap<uint32_t>(p + 0x084,
kernel_state_->process_info_block_address());
xe::store_and_swap<uint8_t>(p + 0x08B, 1);
// 0xD4 = APC
// 0xFC = semaphore (ptr, 0, 2)
// 0xA88 = APC
// 0x18 = timer
xe::store_and_swap<uint32_t>(p + 0x09C, 0xFDFFD7FF);
xe::store_and_swap<uint32_t>(p + 0x0D0, stack_base_);
xe::store_and_swap<uint64_t>(p + 0x130, Clock::QueryGuestSystemTime());
xe::store_and_swap<uint32_t>(p + 0x144, guest_object() + 0x144);
xe::store_and_swap<uint32_t>(p + 0x148, guest_object() + 0x144);
xe::store_and_swap<uint32_t>(p + 0x14C, thread_id_);
xe::store_and_swap<uint32_t>(p + 0x150, creation_params_.start_address);
xe::store_and_swap<uint32_t>(p + 0x154, guest_object() + 0x154);
xe::store_and_swap<uint32_t>(p + 0x158, guest_object() + 0x154);
xe::store_and_swap<uint32_t>(p + 0x160, 0); // last error
xe::store_and_swap<uint32_t>(p + 0x16C, creation_params_.creation_flags);
xe::store_and_swap<uint32_t>(p + 0x17C, 1);
}
bool XThread::AllocateStack(uint32_t size) {
auto heap = memory()->LookupHeap(0x40000000);
auto alignment = heap->page_size();
auto padding = heap->page_size() * 2; // Guard pages
size = xe::round_up(size, alignment);
auto actual_size = size + padding;
uint32_t address = 0;
if (!heap->AllocRange(0x40000000, 0x7F000000, actual_size, alignment,
kMemoryAllocationReserve | kMemoryAllocationCommit,
kMemoryProtectRead | kMemoryProtectWrite, false,
&address)) {
return false;
}
stack_alloc_base_ = address;
stack_alloc_size_ = actual_size;
stack_limit_ = address + (padding / 2);
stack_base_ = stack_limit_ + size;
// Initialize the stack with junk
memory()->Fill(stack_alloc_base_, actual_size, 0xBE);
// Setup the guard pages
heap->Protect(stack_alloc_base_, padding / 2, kMemoryProtectNoAccess);
heap->Protect(stack_base_, padding / 2, kMemoryProtectNoAccess);
return true;
}
X_STATUS XThread::Create() { X_STATUS XThread::Create() {
// Thread kernel object. // Thread kernel object.
// This call will also setup the native pointer for us. if (!CreateNative<X_KTHREAD>()) {
auto guest_thread = CreateNative<X_KTHREAD>();
if (!guest_thread) {
XELOGW("Unable to allocate thread object"); XELOGW("Unable to allocate thread object");
return X_STATUS_NO_MEMORY; return X_STATUS_NO_MEMORY;
} }
auto module = kernel_state()->GetExecutableModule(); // Allocate a stack.
if (!AllocateStack(creation_params_.stack_size)) {
return X_STATUS_NO_MEMORY;
}
// Allocate thread scratch. // Allocate thread scratch.
// This is used by interrupts/APCs/etc so we can round-trip pointers through. // This is used by interrupts/APCs/etc so we can round-trip pointers through.
@ -168,6 +258,7 @@ X_STATUS XThread::Create() {
// Allocate TLS block. // Allocate TLS block.
// Games will specify a certain number of 4b slots that each thread will get. // Games will specify a certain number of 4b slots that each thread will get.
xex2_opt_tls_info* tls_header = nullptr; xex2_opt_tls_info* tls_header = nullptr;
auto module = kernel_state()->GetExecutableModule();
if (module) { if (module) {
module->GetOptHeader(XEX_HEADER_TLS_INFO, &tls_header); module->GetOptHeader(XEX_HEADER_TLS_INFO, &tls_header);
} }
@ -224,84 +315,38 @@ X_STATUS XThread::Create() {
// Allocate processor thread state. // Allocate processor thread state.
// This is thread safe. // This is thread safe.
thread_state_ = new cpu::ThreadState( thread_state_ = new cpu::ThreadState(kernel_state()->processor(), thread_id_,
kernel_state()->processor(), thread_id_, cpu::ThreadStackType::kUserStack, stack_base_, pcr_address_);
0, creation_params_.stack_size, pcr_address_); XELOGI("XThread%08X (%X) Stack: %.8X-%.8X", handle(), thread_id_,
XELOGI("XThread%08X (%X) Stack: %.8X-%.8X", handle(), stack_limit_, stack_base_);
thread_state_->thread_id(), thread_state_->stack_limit(),
thread_state_->stack_base());
// Exports use this to get the kernel. // Exports use this to get the kernel.
thread_state_->context()->kernel_state = kernel_state_; thread_state_->context()->kernel_state = kernel_state_;
uint8_t proc_mask =
static_cast<uint8_t>(creation_params_.creation_flags >> 24);
X_KPCR* pcr = memory()->TranslateVirtual<X_KPCR*>(pcr_address_); X_KPCR* pcr = memory()->TranslateVirtual<X_KPCR*>(pcr_address_);
pcr->tls_ptr = tls_address_; pcr->tls_ptr = tls_address_;
pcr->pcr_ptr = pcr_address_; pcr->pcr_ptr = pcr_address_;
pcr->current_thread = guest_object(); pcr->current_thread = guest_object();
pcr->stack_base_ptr = pcr->stack_base_ptr = stack_base_;
thread_state_->stack_address() + thread_state_->stack_size(); pcr->stack_end_ptr = stack_limit_;
pcr->stack_end_ptr = thread_state_->stack_address();
uint8_t proc_mask =
static_cast<uint8_t>(creation_params_.creation_flags >> 24);
pcr->current_cpu = GetFakeCpuNumber(proc_mask); // Current CPU(?) pcr->current_cpu = GetFakeCpuNumber(proc_mask); // Current CPU(?)
pcr->dpc_active = 0; // DPC active bool? pcr->dpc_active = 0; // DPC active bool?
// Setup the thread state block (last error/etc). // Initialize the KTHREAD object.
uint8_t* p = memory()->TranslateVirtual(guest_object()); InitializeGuestObject();
guest_thread->header.type = 6;
guest_thread->suspend_count =
(creation_params_.creation_flags & X_CREATE_SUSPENDED) ? 1 : 0;
xe::store_and_swap<uint32_t>(p + 0x010, guest_object() + 0x010);
xe::store_and_swap<uint32_t>(p + 0x014, guest_object() + 0x010);
xe::store_and_swap<uint32_t>(p + 0x040, guest_object() + 0x018 + 8);
xe::store_and_swap<uint32_t>(p + 0x044, guest_object() + 0x018 + 8);
xe::store_and_swap<uint32_t>(p + 0x048, guest_object());
xe::store_and_swap<uint32_t>(p + 0x04C, guest_object() + 0x018);
xe::store_and_swap<uint16_t>(p + 0x054, 0x102);
xe::store_and_swap<uint16_t>(p + 0x056, 1);
xe::store_and_swap<uint32_t>(
p + 0x05C, thread_state_->stack_address() + thread_state_->stack_size());
xe::store_and_swap<uint32_t>(p + 0x060, thread_state_->stack_address());
xe::store_and_swap<uint32_t>(p + 0x068, tls_address_);
xe::store_and_swap<uint8_t>(p + 0x06C, 0);
xe::store_and_swap<uint32_t>(p + 0x074, guest_object() + 0x074);
xe::store_and_swap<uint32_t>(p + 0x078, guest_object() + 0x074);
xe::store_and_swap<uint32_t>(p + 0x07C, guest_object() + 0x07C);
xe::store_and_swap<uint32_t>(p + 0x080, guest_object() + 0x07C);
xe::store_and_swap<uint32_t>(p + 0x084,
kernel_state_->process_info_block_address());
xe::store_and_swap<uint8_t>(p + 0x08B, 1);
// 0xD4 = APC
// 0xFC = semaphore (ptr, 0, 2)
// 0xA88 = APC
// 0x18 = timer
xe::store_and_swap<uint32_t>(p + 0x09C, 0xFDFFD7FF);
xe::store_and_swap<uint32_t>(
p + 0x0D0, thread_state_->stack_address() + thread_state_->stack_size());
xe::store_and_swap<uint64_t>(p + 0x130, Clock::QueryGuestSystemTime());
xe::store_and_swap<uint32_t>(p + 0x144, guest_object() + 0x144);
xe::store_and_swap<uint32_t>(p + 0x148, guest_object() + 0x144);
xe::store_and_swap<uint32_t>(p + 0x14C, thread_id_);
xe::store_and_swap<uint32_t>(p + 0x150, creation_params_.start_address);
xe::store_and_swap<uint32_t>(p + 0x154, guest_object() + 0x154);
xe::store_and_swap<uint32_t>(p + 0x158, guest_object() + 0x154);
xe::store_and_swap<uint32_t>(p + 0x160, 0); // last error
xe::store_and_swap<uint32_t>(p + 0x16C, creation_params_.creation_flags);
xe::store_and_swap<uint32_t>(p + 0x17C, 1);
// Always retain when starting - the thread owns itself until exited. // Always retain when starting - the thread owns itself until exited.
Retain(); Retain();
RetainHandle(); RetainHandle();
xe::threading::Thread::CreationParameters params; xe::threading::Thread::CreationParameters params;
params.stack_size = 16 * 1024 * 1024; // Ignore game, always big! params.stack_size = 16 * 1024 * 1024; // Allocate a big host stack.
params.create_suspended = true; params.create_suspended = true;
thread_ = xe::threading::Thread::Create(params, [this]() { thread_ = xe::threading::Thread::Create(params, [this]() {
// Set thread ID override. This is used by logging. // Set thread ID override. This is used by logging.
@ -334,8 +379,8 @@ X_STATUS XThread::Create() {
// Set the thread name based on host ID (for easier debugging). // Set the thread name based on host ID (for easier debugging).
if (name_.empty()) { if (name_.empty()) {
char thread_name[32]; char thread_name[32];
snprintf(thread_name, xe::countof(thread_name), "XThread%04X (%04X)", snprintf(thread_name, xe::countof(thread_name), "XThread%.04X",
handle(), thread_->system_id()); thread_->system_id());
set_name(thread_name); set_name(thread_name);
} }

9
src/xenia/kernel/xthread.h
View File

@ -113,6 +113,7 @@ class XThread : public XObject {
uint32_t creation_flags; uint32_t creation_flags;
}; };
XThread(KernelState* kernel_state);
XThread(KernelState* kernel_state, uint32_t stack_size, XThread(KernelState* kernel_state, uint32_t stack_size,
uint32_t xapi_thread_startup, uint32_t start_address, uint32_t xapi_thread_startup, uint32_t start_address,
uint32_t start_context, uint32_t creation_flags, bool guest_thread); uint32_t start_context, uint32_t creation_flags, bool guest_thread);
@ -174,13 +175,15 @@ class XThread : public XObject {
uint32_t suspend_count(); uint32_t suspend_count();
X_STATUS Resume(uint32_t* out_suspend_count = nullptr); X_STATUS Resume(uint32_t* out_suspend_count = nullptr);
X_STATUS Suspend(uint32_t* out_suspend_count); X_STATUS Suspend(uint32_t* out_suspend_count = nullptr);
X_STATUS Delay(uint32_t processor_mode, uint32_t alertable, X_STATUS Delay(uint32_t processor_mode, uint32_t alertable,
uint64_t interval); uint64_t interval);
xe::threading::WaitHandle* GetWaitHandle() override { return thread_.get(); } xe::threading::WaitHandle* GetWaitHandle() override { return thread_.get(); }
protected: protected:
bool AllocateStack(uint32_t size);
void InitializeGuestObject();
void DeliverAPCs(); void DeliverAPCs();
void RundownAPCs(); void RundownAPCs();
@ -192,6 +195,10 @@ class XThread : public XObject {
uint32_t scratch_size_ = 0; uint32_t scratch_size_ = 0;
uint32_t tls_address_ = 0; uint32_t tls_address_ = 0;
uint32_t pcr_address_ = 0; uint32_t pcr_address_ = 0;
uint32_t stack_alloc_base_ = 0; // Stack alloc base
uint32_t stack_alloc_size_ = 0; // Stack alloc size
uint32_t stack_base_ = 0; // High address
uint32_t stack_limit_ = 0; // Low address
cpu::ThreadState* thread_state_ = nullptr; cpu::ThreadState* thread_state_ = nullptr;
bool guest_thread_ = false; bool guest_thread_ = false;
bool can_debugger_suspend_ = true; bool can_debugger_suspend_ = true;