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|
// Copyright 2014 Citra Emulator Project
// Licensed under GPLv2 or any later version
// Refer to the license.txt file included.
#include <algorithm>
#include <cinttypes>
#include <map>
#include "common/logging/log.h"
#include "common/microprofile.h"
#include "common/scope_exit.h"
#include "common/string_util.h"
#include "core/arm/arm_interface.h"
#include "core/core_timing.h"
#include "core/hle/function_wrappers.h"
#include "core/hle/kernel/address_arbiter.h"
#include "core/hle/kernel/client_port.h"
#include "core/hle/kernel/client_session.h"
#include "core/hle/kernel/errors.h"
#include "core/hle/kernel/event.h"
#include "core/hle/kernel/handle_table.h"
#include "core/hle/kernel/memory.h"
#include "core/hle/kernel/mutex.h"
#include "core/hle/kernel/process.h"
#include "core/hle/kernel/resource_limit.h"
#include "core/hle/kernel/semaphore.h"
#include "core/hle/kernel/server_port.h"
#include "core/hle/kernel/server_session.h"
#include "core/hle/kernel/session.h"
#include "core/hle/kernel/shared_memory.h"
#include "core/hle/kernel/thread.h"
#include "core/hle/kernel/timer.h"
#include "core/hle/kernel/vm_manager.h"
#include "core/hle/kernel/wait_object.h"
#include "core/hle/lock.h"
#include "core/hle/result.h"
#include "core/hle/service/service.h"
////////////////////////////////////////////////////////////////////////////////////////////////////
// Namespace SVC
using Kernel::ERR_INVALID_HANDLE;
using Kernel::Handle;
using Kernel::SharedPtr;
namespace SVC {
enum ControlMemoryOperation {
MEMOP_FREE = 1,
MEMOP_RESERVE = 2, // This operation seems to be unsupported in the kernel
MEMOP_COMMIT = 3,
MEMOP_MAP = 4,
MEMOP_UNMAP = 5,
MEMOP_PROTECT = 6,
MEMOP_OPERATION_MASK = 0xFF,
MEMOP_REGION_APP = 0x100,
MEMOP_REGION_SYSTEM = 0x200,
MEMOP_REGION_BASE = 0x300,
MEMOP_REGION_MASK = 0xF00,
MEMOP_LINEAR = 0x10000,
};
/// Map application or GSP heap memory
static ResultCode ControlMemory(u32* out_addr, u32 operation, u32 addr0, u32 addr1, u32 size,
u32 permissions) {
using namespace Kernel;
LOG_DEBUG(Kernel_SVC,
"called operation=0x%08X, addr0=0x%08X, addr1=0x%08X, size=0x%X, permissions=0x%08X",
operation, addr0, addr1, size, permissions);
if ((addr0 & Memory::PAGE_MASK) != 0 || (addr1 & Memory::PAGE_MASK) != 0) {
return ERR_MISALIGNED_ADDRESS;
}
if ((size & Memory::PAGE_MASK) != 0) {
return ERR_MISALIGNED_SIZE;
}
u32 region = operation & MEMOP_REGION_MASK;
operation &= ~MEMOP_REGION_MASK;
if (region != 0) {
LOG_WARNING(Kernel_SVC, "ControlMemory with specified region not supported, region=%X",
region);
}
if ((permissions & (u32)MemoryPermission::ReadWrite) != permissions) {
return ERR_INVALID_COMBINATION;
}
VMAPermission vma_permissions = (VMAPermission)permissions;
auto& process = *g_current_process;
switch (operation & MEMOP_OPERATION_MASK) {
case MEMOP_FREE: {
// TODO(Subv): What happens if an application tries to FREE a block of memory that has a
// SharedMemory pointing to it?
if (addr0 >= Memory::HEAP_VADDR && addr0 < Memory::HEAP_VADDR_END) {
ResultCode result = process.HeapFree(addr0, size);
if (result.IsError())
return result;
} else if (addr0 >= process.GetLinearHeapBase() && addr0 < process.GetLinearHeapLimit()) {
ResultCode result = process.LinearFree(addr0, size);
if (result.IsError())
return result;
} else {
return ERR_INVALID_ADDRESS;
}
*out_addr = addr0;
break;
}
case MEMOP_COMMIT: {
if (operation & MEMOP_LINEAR) {
CASCADE_RESULT(*out_addr, process.LinearAllocate(addr0, size, vma_permissions));
} else {
CASCADE_RESULT(*out_addr, process.HeapAllocate(addr0, size, vma_permissions));
}
break;
}
case MEMOP_MAP: // TODO: This is just a hack to avoid regressions until memory aliasing is
// implemented
{
CASCADE_RESULT(*out_addr, process.HeapAllocate(addr0, size, vma_permissions));
break;
}
case MEMOP_UNMAP: // TODO: This is just a hack to avoid regressions until memory aliasing is
// implemented
{
ResultCode result = process.HeapFree(addr0, size);
if (result.IsError())
return result;
break;
}
case MEMOP_PROTECT: {
ResultCode result = process.vm_manager.ReprotectRange(addr0, size, vma_permissions);
if (result.IsError())
return result;
break;
}
default:
LOG_ERROR(Kernel_SVC, "unknown operation=0x%08X", operation);
return ERR_INVALID_COMBINATION;
}
process.vm_manager.LogLayout(Log::Level::Trace);
return RESULT_SUCCESS;
}
/// Maps a memory block to specified address
static ResultCode MapMemoryBlock(Kernel::Handle handle, u32 addr, u32 permissions,
u32 other_permissions) {
using Kernel::SharedMemory;
using Kernel::MemoryPermission;
LOG_TRACE(Kernel_SVC,
"called memblock=0x%08X, addr=0x%08X, mypermissions=0x%08X, otherpermission=%d",
handle, addr, permissions, other_permissions);
SharedPtr<SharedMemory> shared_memory = Kernel::g_handle_table.Get<SharedMemory>(handle);
if (shared_memory == nullptr)
return ERR_INVALID_HANDLE;
MemoryPermission permissions_type = static_cast<MemoryPermission>(permissions);
switch (permissions_type) {
case MemoryPermission::Read:
case MemoryPermission::Write:
case MemoryPermission::ReadWrite:
case MemoryPermission::Execute:
case MemoryPermission::ReadExecute:
case MemoryPermission::WriteExecute:
case MemoryPermission::ReadWriteExecute:
case MemoryPermission::DontCare:
return shared_memory->Map(Kernel::g_current_process.get(), addr, permissions_type,
static_cast<MemoryPermission>(other_permissions));
default:
LOG_ERROR(Kernel_SVC, "unknown permissions=0x%08X", permissions);
}
return Kernel::ERR_INVALID_COMBINATION;
}
static ResultCode UnmapMemoryBlock(Kernel::Handle handle, u32 addr) {
using Kernel::SharedMemory;
LOG_TRACE(Kernel_SVC, "called memblock=0x%08X, addr=0x%08X", handle, addr);
// TODO(Subv): Return E0A01BF5 if the address is not in the application's heap
SharedPtr<SharedMemory> shared_memory = Kernel::g_handle_table.Get<SharedMemory>(handle);
if (shared_memory == nullptr)
return ERR_INVALID_HANDLE;
return shared_memory->Unmap(Kernel::g_current_process.get(), addr);
}
/// Connect to an OS service given the port name, returns the handle to the port to out
static ResultCode ConnectToPort(Kernel::Handle* out_handle, const char* port_name) {
if (port_name == nullptr)
return Kernel::ERR_NOT_FOUND;
if (std::strlen(port_name) > 11)
return Kernel::ERR_PORT_NAME_TOO_LONG;
LOG_TRACE(Kernel_SVC, "called port_name=%s", port_name);
auto it = Service::g_kernel_named_ports.find(port_name);
if (it == Service::g_kernel_named_ports.end()) {
LOG_WARNING(Kernel_SVC, "tried to connect to unknown port: %s", port_name);
return Kernel::ERR_NOT_FOUND;
}
auto client_port = it->second;
SharedPtr<Kernel::ClientSession> client_session;
CASCADE_RESULT(client_session, client_port->Connect());
// Return the client session
CASCADE_RESULT(*out_handle, Kernel::g_handle_table.Create(client_session));
return RESULT_SUCCESS;
}
/// Makes a blocking IPC call to an OS service.
static ResultCode SendSyncRequest(Kernel::Handle handle) {
SharedPtr<Kernel::ClientSession> session =
Kernel::g_handle_table.Get<Kernel::ClientSession>(handle);
if (session == nullptr) {
return ERR_INVALID_HANDLE;
}
LOG_TRACE(Kernel_SVC, "called handle=0x%08X(%s)", handle, session->GetName().c_str());
Core::System::GetInstance().PrepareReschedule();
// TODO(Subv): svcSendSyncRequest should put the caller thread to sleep while the server
// responds and cause a reschedule.
return session->SendSyncRequest(Kernel::GetCurrentThread());
}
/// Close a handle
static ResultCode CloseHandle(Kernel::Handle handle) {
LOG_TRACE(Kernel_SVC, "Closing handle 0x%08X", handle);
return Kernel::g_handle_table.Close(handle);
}
/// Wait for a handle to synchronize, timeout after the specified nanoseconds
static ResultCode WaitSynchronization1(Kernel::Handle handle, s64 nano_seconds) {
auto object = Kernel::g_handle_table.Get<Kernel::WaitObject>(handle);
Kernel::Thread* thread = Kernel::GetCurrentThread();
if (object == nullptr)
return ERR_INVALID_HANDLE;
LOG_TRACE(Kernel_SVC, "called handle=0x%08X(%s:%s), nanoseconds=%lld", handle,
object->GetTypeName().c_str(), object->GetName().c_str(), nano_seconds);
if (object->ShouldWait(thread)) {
if (nano_seconds == 0)
return Kernel::RESULT_TIMEOUT;
thread->wait_objects = {object};
object->AddWaitingThread(thread);
thread->status = THREADSTATUS_WAIT_SYNCH_ANY;
// Create an event to wake the thread up after the specified nanosecond delay has passed
thread->WakeAfterDelay(nano_seconds);
thread->wakeup_callback = [](ThreadWakeupReason reason,
Kernel::SharedPtr<Kernel::Thread> thread,
Kernel::SharedPtr<Kernel::WaitObject> object) {
ASSERT(thread->status == THREADSTATUS_WAIT_SYNCH_ANY);
if (reason == ThreadWakeupReason::Timeout) {
thread->SetWaitSynchronizationResult(Kernel::RESULT_TIMEOUT);
return;
}
ASSERT(reason == ThreadWakeupReason::Signal);
thread->SetWaitSynchronizationResult(RESULT_SUCCESS);
// WaitSynchronization1 doesn't have an output index like WaitSynchronizationN, so we
// don't have to do anything else here.
};
Core::System::GetInstance().PrepareReschedule();
// Note: The output of this SVC will be set to RESULT_SUCCESS if the thread
// resumes due to a signal in its wait objects.
// Otherwise we retain the default value of timeout.
return Kernel::RESULT_TIMEOUT;
}
object->Acquire(thread);
return RESULT_SUCCESS;
}
/// Wait for the given handles to synchronize, timeout after the specified nanoseconds
static ResultCode WaitSynchronizationN(s32* out, VAddr handles_address, s32 handle_count,
bool wait_all, s64 nano_seconds) {
Kernel::Thread* thread = Kernel::GetCurrentThread();
if (!Memory::IsValidVirtualAddress(handles_address))
return Kernel::ERR_INVALID_POINTER;
// NOTE: on real hardware, there is no nullptr check for 'out' (tested with firmware 4.4). If
// this happens, the running application will crash.
ASSERT_MSG(out != nullptr, "invalid output pointer specified!");
// Check if 'handle_count' is invalid
if (handle_count < 0)
return Kernel::ERR_OUT_OF_RANGE;
using ObjectPtr = Kernel::SharedPtr<Kernel::WaitObject>;
std::vector<ObjectPtr> objects(handle_count);
for (int i = 0; i < handle_count; ++i) {
Kernel::Handle handle = Memory::Read32(handles_address + i * sizeof(Kernel::Handle));
auto object = Kernel::g_handle_table.Get<Kernel::WaitObject>(handle);
if (object == nullptr)
return ERR_INVALID_HANDLE;
objects[i] = object;
}
if (wait_all) {
bool all_available =
std::all_of(objects.begin(), objects.end(),
[thread](const ObjectPtr& object) { return !object->ShouldWait(thread); });
if (all_available) {
// We can acquire all objects right now, do so.
for (auto& object : objects)
object->Acquire(thread);
// Note: In this case, the `out` parameter is not set,
// and retains whatever value it had before.
return RESULT_SUCCESS;
}
// Not all objects were available right now, prepare to suspend the thread.
// If a timeout value of 0 was provided, just return the Timeout error code instead of
// suspending the thread.
if (nano_seconds == 0)
return Kernel::RESULT_TIMEOUT;
// Put the thread to sleep
thread->status = THREADSTATUS_WAIT_SYNCH_ALL;
// Add the thread to each of the objects' waiting threads.
for (auto& object : objects) {
object->AddWaitingThread(thread);
}
thread->wait_objects = std::move(objects);
// Create an event to wake the thread up after the specified nanosecond delay has passed
thread->WakeAfterDelay(nano_seconds);
thread->wakeup_callback = [](ThreadWakeupReason reason,
Kernel::SharedPtr<Kernel::Thread> thread,
Kernel::SharedPtr<Kernel::WaitObject> object) {
ASSERT(thread->status == THREADSTATUS_WAIT_SYNCH_ALL);
if (reason == ThreadWakeupReason::Timeout) {
thread->SetWaitSynchronizationResult(Kernel::RESULT_TIMEOUT);
return;
}
ASSERT(reason == ThreadWakeupReason::Signal);
thread->SetWaitSynchronizationResult(RESULT_SUCCESS);
// The wait_all case does not update the output index.
};
Core::System::GetInstance().PrepareReschedule();
// This value gets set to -1 by default in this case, it is not modified after this.
*out = -1;
// Note: The output of this SVC will be set to RESULT_SUCCESS if the thread resumes due to
// a signal in one of its wait objects.
return Kernel::RESULT_TIMEOUT;
} else {
// Find the first object that is acquirable in the provided list of objects
auto itr = std::find_if(objects.begin(), objects.end(), [thread](const ObjectPtr& object) {
return !object->ShouldWait(thread);
});
if (itr != objects.end()) {
// We found a ready object, acquire it and set the result value
Kernel::WaitObject* object = itr->get();
object->Acquire(thread);
*out = static_cast<s32>(std::distance(objects.begin(), itr));
return RESULT_SUCCESS;
}
// No objects were ready to be acquired, prepare to suspend the thread.
// If a timeout value of 0 was provided, just return the Timeout error code instead of
// suspending the thread.
if (nano_seconds == 0)
return Kernel::RESULT_TIMEOUT;
// Put the thread to sleep
thread->status = THREADSTATUS_WAIT_SYNCH_ANY;
// Add the thread to each of the objects' waiting threads.
for (size_t i = 0; i < objects.size(); ++i) {
Kernel::WaitObject* object = objects[i].get();
object->AddWaitingThread(thread);
}
thread->wait_objects = std::move(objects);
// Note: If no handles and no timeout were given, then the thread will deadlock, this is
// consistent with hardware behavior.
// Create an event to wake the thread up after the specified nanosecond delay has passed
thread->WakeAfterDelay(nano_seconds);
thread->wakeup_callback = [](ThreadWakeupReason reason,
Kernel::SharedPtr<Kernel::Thread> thread,
Kernel::SharedPtr<Kernel::WaitObject> object) {
ASSERT(thread->status == THREADSTATUS_WAIT_SYNCH_ANY);
if (reason == ThreadWakeupReason::Timeout) {
thread->SetWaitSynchronizationResult(Kernel::RESULT_TIMEOUT);
return;
}
ASSERT(reason == ThreadWakeupReason::Signal);
thread->SetWaitSynchronizationResult(RESULT_SUCCESS);
thread->SetWaitSynchronizationOutput(thread->GetWaitObjectIndex(object.get()));
};
Core::System::GetInstance().PrepareReschedule();
// Note: The output of this SVC will be set to RESULT_SUCCESS if the thread resumes due to a
// signal in one of its wait objects.
// Otherwise we retain the default value of timeout, and -1 in the out parameter
*out = -1;
return Kernel::RESULT_TIMEOUT;
}
}
/// In a single operation, sends a IPC reply and waits for a new request.
static ResultCode ReplyAndReceive(s32* index, Kernel::Handle* handles, s32 handle_count,
Kernel::Handle reply_target) {
// 'handles' has to be a valid pointer even if 'handle_count' is 0.
if (handles == nullptr)
return Kernel::ERR_INVALID_POINTER;
// Check if 'handle_count' is invalid
if (handle_count < 0)
return Kernel::ERR_OUT_OF_RANGE;
using ObjectPtr = SharedPtr<Kernel::WaitObject>;
std::vector<ObjectPtr> objects(handle_count);
for (int i = 0; i < handle_count; ++i) {
auto object = Kernel::g_handle_table.Get<Kernel::WaitObject>(handles[i]);
if (object == nullptr)
return ERR_INVALID_HANDLE;
objects[i] = object;
}
// We are also sending a command reply.
// Do not send a reply if the command id in the command buffer is 0xFFFF.
u32* cmd_buff = Kernel::GetCommandBuffer();
IPC::Header header{cmd_buff[0]};
if (reply_target != 0 && header.command_id != 0xFFFF) {
auto session = Kernel::g_handle_table.Get<Kernel::ServerSession>(reply_target);
if (session == nullptr)
return ERR_INVALID_HANDLE;
auto request_thread = std::move(session->currently_handling);
// Mark the request as "handled".
session->currently_handling = nullptr;
// Error out if there's no request thread or the session was closed.
// TODO(Subv): Is the same error code (ClosedByRemote) returned for both of these cases?
if (request_thread == nullptr || session->parent->client == nullptr) {
*index = -1;
return Kernel::ERR_SESSION_CLOSED_BY_REMOTE;
}
// TODO(Subv): Perform IPC translation from the current thread to request_thread.
// Note: The scheduler is not invoked here.
request_thread->ResumeFromWait();
}
if (handle_count == 0) {
*index = 0;
// The kernel uses this value as a placeholder for the real error, and returns it when we
// pass no handles and do not perform any reply.
if (reply_target == 0 || header.command_id == 0xFFFF)
return ResultCode(0xE7E3FFFF);
return RESULT_SUCCESS;
}
auto thread = Kernel::GetCurrentThread();
// Find the first object that is acquirable in the provided list of objects
auto itr = std::find_if(objects.begin(), objects.end(), [thread](const ObjectPtr& object) {
return !object->ShouldWait(thread);
});
if (itr != objects.end()) {
// We found a ready object, acquire it and set the result value
Kernel::WaitObject* object = itr->get();
object->Acquire(thread);
*index = static_cast<s32>(std::distance(objects.begin(), itr));
if (object->GetHandleType() == Kernel::HandleType::ServerSession) {
auto server_session = static_cast<Kernel::ServerSession*>(object);
if (server_session->parent->client == nullptr)
return Kernel::ERR_SESSION_CLOSED_BY_REMOTE;
// TODO(Subv): Perform IPC translation from the ServerSession to the current thread.
}
return RESULT_SUCCESS;
}
// No objects were ready to be acquired, prepare to suspend the thread.
// Put the thread to sleep
thread->status = THREADSTATUS_WAIT_SYNCH_ANY;
// Add the thread to each of the objects' waiting threads.
for (size_t i = 0; i < objects.size(); ++i) {
Kernel::WaitObject* object = objects[i].get();
object->AddWaitingThread(thread);
}
thread->wait_objects = std::move(objects);
thread->wakeup_callback = [](ThreadWakeupReason reason,
Kernel::SharedPtr<Kernel::Thread> thread,
Kernel::SharedPtr<Kernel::WaitObject> object) {
ASSERT(thread->status == THREADSTATUS_WAIT_SYNCH_ANY);
ASSERT(reason == ThreadWakeupReason::Signal);
thread->SetWaitSynchronizationResult(RESULT_SUCCESS);
thread->SetWaitSynchronizationOutput(thread->GetWaitObjectIndex(object.get()));
// TODO(Subv): Perform IPC translation upon wakeup.
};
Core::System::GetInstance().PrepareReschedule();
// Note: The output of this SVC will be set to RESULT_SUCCESS if the thread resumes due to a
// signal in one of its wait objects, or to 0xC8A01836 if there was a translation error.
// By default the index is set to -1.
*index = -1;
return RESULT_SUCCESS;
}
/// Create an address arbiter (to allocate access to shared resources)
static ResultCode CreateAddressArbiter(Kernel::Handle* out_handle) {
using Kernel::AddressArbiter;
SharedPtr<AddressArbiter> arbiter = AddressArbiter::Create();
CASCADE_RESULT(*out_handle, Kernel::g_handle_table.Create(std::move(arbiter)));
LOG_TRACE(Kernel_SVC, "returned handle=0x%08X", *out_handle);
return RESULT_SUCCESS;
}
/// Arbitrate address
static ResultCode ArbitrateAddress(Kernel::Handle handle, u32 address, u32 type, u32 value,
s64 nanoseconds) {
using Kernel::AddressArbiter;
LOG_TRACE(Kernel_SVC, "called handle=0x%08X, address=0x%08X, type=0x%08X, value=0x%08X", handle,
address, type, value);
SharedPtr<AddressArbiter> arbiter = Kernel::g_handle_table.Get<AddressArbiter>(handle);
if (arbiter == nullptr)
return ERR_INVALID_HANDLE;
auto res = arbiter->ArbitrateAddress(static_cast<Kernel::ArbitrationType>(type), address, value,
nanoseconds);
// TODO(Subv): Identify in which specific cases this call should cause a reschedule.
Core::System::GetInstance().PrepareReschedule();
return res;
}
static void Break(u8 break_reason) {
LOG_CRITICAL(Debug_Emulated, "Emulated program broke execution!");
std::string reason_str;
switch (break_reason) {
case 0:
reason_str = "PANIC";
break;
case 1:
reason_str = "ASSERT";
break;
case 2:
reason_str = "USER";
break;
default:
reason_str = "UNKNOWN";
break;
}
LOG_CRITICAL(Debug_Emulated, "Break reason: %s", reason_str.c_str());
}
/// Used to output a message on a debug hardware unit - does nothing on a retail unit
static void OutputDebugString(const char* string, int len) {
LOG_DEBUG(Debug_Emulated, "%.*s", len, string);
}
/// Get resource limit
static ResultCode GetResourceLimit(Kernel::Handle* resource_limit, Kernel::Handle process_handle) {
LOG_TRACE(Kernel_SVC, "called process=0x%08X", process_handle);
SharedPtr<Kernel::Process> process =
Kernel::g_handle_table.Get<Kernel::Process>(process_handle);
if (process == nullptr)
return ERR_INVALID_HANDLE;
CASCADE_RESULT(*resource_limit, Kernel::g_handle_table.Create(process->resource_limit));
return RESULT_SUCCESS;
}
/// Get resource limit current values
static ResultCode GetResourceLimitCurrentValues(s64* values, Kernel::Handle resource_limit_handle,
u32* names, u32 name_count) {
LOG_TRACE(Kernel_SVC, "called resource_limit=%08X, names=%p, name_count=%d",
resource_limit_handle, names, name_count);
SharedPtr<Kernel::ResourceLimit> resource_limit =
Kernel::g_handle_table.Get<Kernel::ResourceLimit>(resource_limit_handle);
if (resource_limit == nullptr)
return ERR_INVALID_HANDLE;
for (unsigned int i = 0; i < name_count; ++i)
values[i] = resource_limit->GetCurrentResourceValue(names[i]);
return RESULT_SUCCESS;
}
/// Get resource limit max values
static ResultCode GetResourceLimitLimitValues(s64* values, Kernel::Handle resource_limit_handle,
u32* names, u32 name_count) {
LOG_TRACE(Kernel_SVC, "called resource_limit=%08X, names=%p, name_count=%d",
resource_limit_handle, names, name_count);
SharedPtr<Kernel::ResourceLimit> resource_limit =
Kernel::g_handle_table.Get<Kernel::ResourceLimit>(resource_limit_handle);
if (resource_limit == nullptr)
return ERR_INVALID_HANDLE;
for (unsigned int i = 0; i < name_count; ++i)
values[i] = resource_limit->GetMaxResourceValue(names[i]);
return RESULT_SUCCESS;
}
/// Creates a new thread
static ResultCode CreateThread(Kernel::Handle* out_handle, u32 priority, u32 entry_point, u32 arg,
u32 stack_top, s32 processor_id) {
using Kernel::Thread;
std::string name = Common::StringFromFormat("unknown-%08" PRIX32, entry_point);
if (priority > THREADPRIO_LOWEST) {
return Kernel::ERR_OUT_OF_RANGE;
}
using Kernel::ResourceLimit;
Kernel::SharedPtr<ResourceLimit>& resource_limit = Kernel::g_current_process->resource_limit;
if (resource_limit->GetMaxResourceValue(Kernel::ResourceTypes::PRIORITY) > priority) {
return Kernel::ERR_NOT_AUTHORIZED;
}
switch (processor_id) {
case THREADPROCESSORID_ALL:
case THREADPROCESSORID_DEFAULT:
case THREADPROCESSORID_0:
case THREADPROCESSORID_1:
break;
default:
// TODO(bunnei): Implement support for other processor IDs
ASSERT_MSG(false, "Unsupported thread processor ID: %d", processor_id);
break;
}
if (processor_id == THREADPROCESSORID_ALL) {
LOG_INFO(Kernel_SVC,
"Newly created thread is allowed to be run in any Core, unimplemented.");
}
if (processor_id == THREADPROCESSORID_DEFAULT &&
Kernel::g_current_process->ideal_processor == THREADPROCESSORID_1) {
LOG_WARNING(
Kernel_SVC,
"Newly created thread is allowed to be run in the SysCore (Core1), unimplemented.");
}
if (processor_id == THREADPROCESSORID_1) {
LOG_ERROR(Kernel_SVC,
"Newly created thread must run in the SysCore (Core1), unimplemented.");
}
CASCADE_RESULT(SharedPtr<Thread> thread,
Kernel::Thread::Create(name, entry_point, priority, arg, processor_id, stack_top,
Kernel::g_current_process));
thread->context.fpscr =
FPSCR_DEFAULT_NAN | FPSCR_FLUSH_TO_ZERO | FPSCR_ROUND_TOZERO; // 0x03C00000
CASCADE_RESULT(*out_handle, Kernel::g_handle_table.Create(std::move(thread)));
Core::System::GetInstance().PrepareReschedule();
LOG_TRACE(Kernel_SVC, "called entrypoint=0x%08X (%s), arg=0x%08X, stacktop=0x%08X, "
"threadpriority=0x%08X, processorid=0x%08X : created handle=0x%08X",
entry_point, name.c_str(), arg, stack_top, priority, processor_id, *out_handle);
return RESULT_SUCCESS;
}
/// Called when a thread exits
static void ExitThread() {
LOG_TRACE(Kernel_SVC, "called, pc=0x%08X", Core::CPU().GetPC());
Kernel::ExitCurrentThread();
Core::System::GetInstance().PrepareReschedule();
}
/// Gets the priority for the specified thread
static ResultCode GetThreadPriority(u32* priority, Kernel::Handle handle) {
const SharedPtr<Kernel::Thread> thread = Kernel::g_handle_table.Get<Kernel::Thread>(handle);
if (thread == nullptr)
return ERR_INVALID_HANDLE;
*priority = thread->GetPriority();
return RESULT_SUCCESS;
}
/// Sets the priority for the specified thread
static ResultCode SetThreadPriority(Kernel::Handle handle, u32 priority) {
if (priority > THREADPRIO_LOWEST) {
return Kernel::ERR_OUT_OF_RANGE;
}
SharedPtr<Kernel::Thread> thread = Kernel::g_handle_table.Get<Kernel::Thread>(handle);
if (thread == nullptr)
return ERR_INVALID_HANDLE;
using Kernel::ResourceLimit;
// Note: The kernel uses the current process's resource limit instead of
// the one from the thread owner's resource limit.
Kernel::SharedPtr<ResourceLimit>& resource_limit = Kernel::g_current_process->resource_limit;
if (resource_limit->GetMaxResourceValue(Kernel::ResourceTypes::PRIORITY) > priority) {
return Kernel::ERR_NOT_AUTHORIZED;
}
thread->SetPriority(priority);
thread->UpdatePriority();
// Update the mutexes that this thread is waiting for
for (auto& mutex : thread->pending_mutexes)
mutex->UpdatePriority();
Core::System::GetInstance().PrepareReschedule();
return RESULT_SUCCESS;
}
/// Create a mutex
static ResultCode CreateMutex(Kernel::Handle* out_handle, u32 initial_locked) {
using Kernel::Mutex;
SharedPtr<Mutex> mutex = Mutex::Create(initial_locked != 0);
mutex->name = Common::StringFromFormat("mutex-%08x", Core::CPU().GetReg(14));
CASCADE_RESULT(*out_handle, Kernel::g_handle_table.Create(std::move(mutex)));
LOG_TRACE(Kernel_SVC, "called initial_locked=%s : created handle=0x%08X",
initial_locked ? "true" : "false", *out_handle);
return RESULT_SUCCESS;
}
/// Release a mutex
static ResultCode ReleaseMutex(Kernel::Handle handle) {
using Kernel::Mutex;
LOG_TRACE(Kernel_SVC, "called handle=0x%08X", handle);
SharedPtr<Mutex> mutex = Kernel::g_handle_table.Get<Mutex>(handle);
if (mutex == nullptr)
return ERR_INVALID_HANDLE;
mutex->Release();
return RESULT_SUCCESS;
}
/// Get the ID of the specified process
static ResultCode GetProcessId(u32* process_id, Kernel::Handle process_handle) {
LOG_TRACE(Kernel_SVC, "called process=0x%08X", process_handle);
const SharedPtr<Kernel::Process> process =
Kernel::g_handle_table.Get<Kernel::Process>(process_handle);
if (process == nullptr)
return ERR_INVALID_HANDLE;
*process_id = process->process_id;
return RESULT_SUCCESS;
}
/// Get the ID of the process that owns the specified thread
static ResultCode GetProcessIdOfThread(u32* process_id, Kernel::Handle thread_handle) {
LOG_TRACE(Kernel_SVC, "called thread=0x%08X", thread_handle);
const SharedPtr<Kernel::Thread> thread =
Kernel::g_handle_table.Get<Kernel::Thread>(thread_handle);
if (thread == nullptr)
return ERR_INVALID_HANDLE;
const SharedPtr<Kernel::Process> process = thread->owner_process;
ASSERT_MSG(process != nullptr, "Invalid parent process for thread=0x%08X", thread_handle);
*process_id = process->process_id;
return RESULT_SUCCESS;
}
/// Get the ID for the specified thread.
static ResultCode GetThreadId(u32* thread_id, Kernel::Handle handle) {
LOG_TRACE(Kernel_SVC, "called thread=0x%08X", handle);
const SharedPtr<Kernel::Thread> thread = Kernel::g_handle_table.Get<Kernel::Thread>(handle);
if (thread == nullptr)
return ERR_INVALID_HANDLE;
*thread_id = thread->GetThreadId();
return RESULT_SUCCESS;
}
/// Creates a semaphore
static ResultCode CreateSemaphore(Kernel::Handle* out_handle, s32 initial_count, s32 max_count) {
using Kernel::Semaphore;
CASCADE_RESULT(SharedPtr<Semaphore> semaphore, Semaphore::Create(initial_count, max_count));
semaphore->name = Common::StringFromFormat("semaphore-%08x", Core::CPU().GetReg(14));
CASCADE_RESULT(*out_handle, Kernel::g_handle_table.Create(std::move(semaphore)));
LOG_TRACE(Kernel_SVC, "called initial_count=%d, max_count=%d, created handle=0x%08X",
initial_count, max_count, *out_handle);
return RESULT_SUCCESS;
}
/// Releases a certain number of slots in a semaphore
static ResultCode ReleaseSemaphore(s32* count, Kernel::Handle handle, s32 release_count) {
using Kernel::Semaphore;
LOG_TRACE(Kernel_SVC, "called release_count=%d, handle=0x%08X", release_count, handle);
SharedPtr<Semaphore> semaphore = Kernel::g_handle_table.Get<Semaphore>(handle);
if (semaphore == nullptr)
return ERR_INVALID_HANDLE;
CASCADE_RESULT(*count, semaphore->Release(release_count));
return RESULT_SUCCESS;
}
/// Query process memory
static ResultCode QueryProcessMemory(MemoryInfo* memory_info, PageInfo* page_info,
Kernel::Handle process_handle, u32 addr) {
using Kernel::Process;
Kernel::SharedPtr<Process> process = Kernel::g_handle_table.Get<Process>(process_handle);
if (process == nullptr)
return ERR_INVALID_HANDLE;
auto vma = process->vm_manager.FindVMA(addr);
if (vma == Kernel::g_current_process->vm_manager.vma_map.end())
return Kernel::ERR_INVALID_ADDRESS;
memory_info->base_address = vma->second.base;
memory_info->permission = static_cast<u32>(vma->second.permissions);
memory_info->size = vma->second.size;
memory_info->state = static_cast<u32>(vma->second.meminfo_state);
page_info->flags = 0;
LOG_TRACE(Kernel_SVC, "called process=0x%08X addr=0x%08X", process_handle, addr);
return RESULT_SUCCESS;
}
/// Query memory
static ResultCode QueryMemory(MemoryInfo* memory_info, PageInfo* page_info, u32 addr) {
return QueryProcessMemory(memory_info, page_info, Kernel::CurrentProcess, addr);
}
/// Create an event
static ResultCode CreateEvent(Kernel::Handle* out_handle, u32 reset_type) {
using Kernel::Event;
SharedPtr<Event> evt = Event::Create(static_cast<Kernel::ResetType>(reset_type));
evt->name = Common::StringFromFormat("event-%08x", Core::CPU().GetReg(14));
CASCADE_RESULT(*out_handle, Kernel::g_handle_table.Create(std::move(evt)));
LOG_TRACE(Kernel_SVC, "called reset_type=0x%08X : created handle=0x%08X", reset_type,
*out_handle);
return RESULT_SUCCESS;
}
/// Duplicates a kernel handle
static ResultCode DuplicateHandle(Kernel::Handle* out, Kernel::Handle handle) {
CASCADE_RESULT(*out, Kernel::g_handle_table.Duplicate(handle));
LOG_TRACE(Kernel_SVC, "duplicated 0x%08X to 0x%08X", handle, *out);
return RESULT_SUCCESS;
}
/// Signals an event
static ResultCode SignalEvent(Kernel::Handle handle) {
using Kernel::Event;
LOG_TRACE(Kernel_SVC, "called event=0x%08X", handle);
SharedPtr<Event> evt = Kernel::g_handle_table.Get<Kernel::Event>(handle);
if (evt == nullptr)
return ERR_INVALID_HANDLE;
evt->Signal();
return RESULT_SUCCESS;
}
/// Clears an event
static ResultCode ClearEvent(Kernel::Handle handle) {
using Kernel::Event;
LOG_TRACE(Kernel_SVC, "called event=0x%08X", handle);
SharedPtr<Event> evt = Kernel::g_handle_table.Get<Kernel::Event>(handle);
if (evt == nullptr)
return ERR_INVALID_HANDLE;
evt->Clear();
return RESULT_SUCCESS;
}
/// Creates a timer
static ResultCode CreateTimer(Kernel::Handle* out_handle, u32 reset_type) {
using Kernel::Timer;
SharedPtr<Timer> timer = Timer::Create(static_cast<Kernel::ResetType>(reset_type));
timer->name = Common::StringFromFormat("timer-%08x", Core::CPU().GetReg(14));
CASCADE_RESULT(*out_handle, Kernel::g_handle_table.Create(std::move(timer)));
LOG_TRACE(Kernel_SVC, "called reset_type=0x%08X : created handle=0x%08X", reset_type,
*out_handle);
return RESULT_SUCCESS;
}
/// Clears a timer
static ResultCode ClearTimer(Kernel::Handle handle) {
using Kernel::Timer;
LOG_TRACE(Kernel_SVC, "called timer=0x%08X", handle);
SharedPtr<Timer> timer = Kernel::g_handle_table.Get<Timer>(handle);
if (timer == nullptr)
return ERR_INVALID_HANDLE;
timer->Clear();
return RESULT_SUCCESS;
}
/// Starts a timer
static ResultCode SetTimer(Kernel::Handle handle, s64 initial, s64 interval) {
using Kernel::Timer;
LOG_TRACE(Kernel_SVC, "called timer=0x%08X", handle);
if (initial < 0 || interval < 0) {
return Kernel::ERR_OUT_OF_RANGE_KERNEL;
}
SharedPtr<Timer> timer = Kernel::g_handle_table.Get<Timer>(handle);
if (timer == nullptr)
return ERR_INVALID_HANDLE;
timer->Set(initial, interval);
return RESULT_SUCCESS;
}
/// Cancels a timer
static ResultCode CancelTimer(Kernel::Handle handle) {
using Kernel::Timer;
LOG_TRACE(Kernel_SVC, "called timer=0x%08X", handle);
SharedPtr<Timer> timer = Kernel::g_handle_table.Get<Timer>(handle);
if (timer == nullptr)
return ERR_INVALID_HANDLE;
timer->Cancel();
return RESULT_SUCCESS;
}
/// Sleep the current thread
static void SleepThread(s64 nanoseconds) {
LOG_TRACE(Kernel_SVC, "called nanoseconds=%lld", nanoseconds);
// Don't attempt to yield execution if there are no available threads to run,
// this way we avoid a useless reschedule to the idle thread.
if (nanoseconds == 0 && !Kernel::HaveReadyThreads())
return;
// Sleep current thread and check for next thread to schedule
Kernel::WaitCurrentThread_Sleep();
// Create an event to wake the thread up after the specified nanosecond delay has passed
Kernel::GetCurrentThread()->WakeAfterDelay(nanoseconds);
Core::System::GetInstance().PrepareReschedule();
}
/// This returns the total CPU ticks elapsed since the CPU was powered-on
static s64 GetSystemTick() {
s64 result = CoreTiming::GetTicks();
// Advance time to defeat dumb games (like Cubic Ninja) that busy-wait for the frame to end.
CoreTiming::AddTicks(150); // Measured time between two calls on a 9.2 o3DS with Ninjhax 1.1b
return result;
}
/// Creates a memory block at the specified address with the specified permissions and size
static ResultCode CreateMemoryBlock(Kernel::Handle* out_handle, u32 addr, u32 size,
u32 my_permission, u32 other_permission) {
using Kernel::SharedMemory;
if (size % Memory::PAGE_SIZE != 0)
return Kernel::ERR_MISALIGNED_SIZE;
SharedPtr<SharedMemory> shared_memory = nullptr;
using Kernel::MemoryPermission;
auto VerifyPermissions = [](MemoryPermission permission) {
// SharedMemory blocks can not be created with Execute permissions
switch (permission) {
case MemoryPermission::None:
case MemoryPermission::Read:
case MemoryPermission::Write:
case MemoryPermission::ReadWrite:
case MemoryPermission::DontCare:
return true;
default:
return false;
}
};
if (!VerifyPermissions(static_cast<MemoryPermission>(my_permission)) ||
!VerifyPermissions(static_cast<MemoryPermission>(other_permission)))
return Kernel::ERR_INVALID_COMBINATION;
// TODO(Subv): Processes with memory type APPLICATION are not allowed
// to create memory blocks with addr = 0, any attempts to do so
// should return error 0xD92007EA.
if ((addr < Memory::PROCESS_IMAGE_VADDR || addr + size > Memory::SHARED_MEMORY_VADDR_END) &&
addr != 0) {
return Kernel::ERR_INVALID_ADDRESS;
}
// When trying to create a memory block with address = 0,
// if the process has the Shared Device Memory flag in the exheader,
// then we have to allocate from the same region as the caller process instead of the BASE
// region.
Kernel::MemoryRegion region = Kernel::MemoryRegion::BASE;
if (addr == 0 && Kernel::g_current_process->flags.shared_device_mem)
region = Kernel::g_current_process->flags.memory_region;
shared_memory = SharedMemory::Create(
Kernel::g_current_process, size, static_cast<MemoryPermission>(my_permission),
static_cast<MemoryPermission>(other_permission), addr, region);
CASCADE_RESULT(*out_handle, Kernel::g_handle_table.Create(std::move(shared_memory)));
LOG_WARNING(Kernel_SVC, "called addr=0x%08X", addr);
return RESULT_SUCCESS;
}
static ResultCode CreatePort(Kernel::Handle* server_port, Kernel::Handle* client_port,
const char* name, u32 max_sessions) {
// TODO(Subv): Implement named ports.
ASSERT_MSG(name == nullptr, "Named ports are currently unimplemented");
using Kernel::ServerPort;
using Kernel::ClientPort;
auto ports = ServerPort::CreatePortPair(max_sessions);
CASCADE_RESULT(*client_port, Kernel::g_handle_table.Create(
std::move(std::get<SharedPtr<ClientPort>>(ports))));
// Note: The 3DS kernel also leaks the client port handle if the server port handle fails to be
// created.
CASCADE_RESULT(*server_port, Kernel::g_handle_table.Create(
std::move(std::get<SharedPtr<ServerPort>>(ports))));
LOG_TRACE(Kernel_SVC, "called max_sessions=%u", max_sessions);
return RESULT_SUCCESS;
}
static ResultCode CreateSessionToPort(Handle* out_client_session, Handle client_port_handle) {
using Kernel::ClientPort;
SharedPtr<ClientPort> client_port = Kernel::g_handle_table.Get<ClientPort>(client_port_handle);
if (client_port == nullptr)
return ERR_INVALID_HANDLE;
CASCADE_RESULT(auto session, client_port->Connect());
CASCADE_RESULT(*out_client_session, Kernel::g_handle_table.Create(std::move(session)));
return RESULT_SUCCESS;
}
static ResultCode CreateSession(Handle* server_session, Handle* client_session) {
auto sessions = Kernel::ServerSession::CreateSessionPair();
auto& server = std::get<SharedPtr<Kernel::ServerSession>>(sessions);
CASCADE_RESULT(*server_session, Kernel::g_handle_table.Create(std::move(server)));
auto& client = std::get<SharedPtr<Kernel::ClientSession>>(sessions);
CASCADE_RESULT(*client_session, Kernel::g_handle_table.Create(std::move(client)));
LOG_TRACE(Kernel_SVC, "called");
return RESULT_SUCCESS;
}
static ResultCode AcceptSession(Handle* out_server_session, Handle server_port_handle) {
using Kernel::ServerPort;
SharedPtr<ServerPort> server_port = Kernel::g_handle_table.Get<ServerPort>(server_port_handle);
if (server_port == nullptr)
return ERR_INVALID_HANDLE;
CASCADE_RESULT(auto session, server_port->Accept());
CASCADE_RESULT(*out_server_session, Kernel::g_handle_table.Create(std::move(session)));
return RESULT_SUCCESS;
}
static ResultCode GetSystemInfo(s64* out, u32 type, s32 param) {
using Kernel::MemoryRegion;
LOG_TRACE(Kernel_SVC, "called type=%u param=%d", type, param);
switch ((SystemInfoType)type) {
case SystemInfoType::REGION_MEMORY_USAGE:
switch ((SystemInfoMemUsageRegion)param) {
case SystemInfoMemUsageRegion::ALL:
*out = Kernel::GetMemoryRegion(Kernel::MemoryRegion::APPLICATION)->used +
Kernel::GetMemoryRegion(Kernel::MemoryRegion::SYSTEM)->used +
Kernel::GetMemoryRegion(Kernel::MemoryRegion::BASE)->used;
break;
case SystemInfoMemUsageRegion::APPLICATION:
*out = Kernel::GetMemoryRegion(Kernel::MemoryRegion::APPLICATION)->used;
break;
case SystemInfoMemUsageRegion::SYSTEM:
*out = Kernel::GetMemoryRegion(Kernel::MemoryRegion::SYSTEM)->used;
break;
case SystemInfoMemUsageRegion::BASE:
*out = Kernel::GetMemoryRegion(Kernel::MemoryRegion::BASE)->used;
break;
default:
LOG_ERROR(Kernel_SVC, "unknown GetSystemInfo type=0 region: param=%d", param);
*out = 0;
break;
}
break;
case SystemInfoType::KERNEL_ALLOCATED_PAGES:
LOG_ERROR(Kernel_SVC, "unimplemented GetSystemInfo type=2 param=%d", param);
*out = 0;
break;
case SystemInfoType::KERNEL_SPAWNED_PIDS:
*out = 5;
break;
default:
LOG_ERROR(Kernel_SVC, "unknown GetSystemInfo type=%u param=%d", type, param);
*out = 0;
break;
}
// This function never returns an error, even if invalid parameters were passed.
return RESULT_SUCCESS;
}
static ResultCode GetProcessInfo(s64* out, Kernel::Handle process_handle, u32 type) {
LOG_TRACE(Kernel_SVC, "called process=0x%08X type=%u", process_handle, type);
using Kernel::Process;
Kernel::SharedPtr<Process> process = Kernel::g_handle_table.Get<Process>(process_handle);
if (process == nullptr)
return ERR_INVALID_HANDLE;
switch (type) {
case 0:
case 2:
// TODO(yuriks): Type 0 returns a slightly higher number than type 2, but I'm not sure
// what's the difference between them.
*out = process->heap_used + process->linear_heap_used + process->misc_memory_used;
if (*out % Memory::PAGE_SIZE != 0) {
LOG_ERROR(Kernel_SVC, "called, memory size not page-aligned");
return Kernel::ERR_MISALIGNED_SIZE;
}
break;
case 1:
case 3:
case 4:
case 5:
case 6:
case 7:
case 8:
// These are valid, but not implemented yet
LOG_ERROR(Kernel_SVC, "unimplemented GetProcessInfo type=%u", type);
break;
case 20:
*out = Memory::FCRAM_PADDR - process->GetLinearHeapBase();
break;
case 21:
case 22:
case 23:
// These return a different error value than higher invalid values
LOG_ERROR(Kernel_SVC, "unknown GetProcessInfo type=%u", type);
return Kernel::ERR_NOT_IMPLEMENTED;
default:
LOG_ERROR(Kernel_SVC, "unknown GetProcessInfo type=%u", type);
return Kernel::ERR_INVALID_ENUM_VALUE;
}
return RESULT_SUCCESS;
}
namespace {
struct FunctionDef {
using Func = void();
u32 id;
Func* func;
const char* name;
};
} // namespace
static const FunctionDef SVC_Table[] = {
{0x00, nullptr, "Unknown"},
{0x01, HLE::Wrap<ControlMemory>, "ControlMemory"},
{0x02, HLE::Wrap<QueryMemory>, "QueryMemory"},
{0x03, nullptr, "ExitProcess"},
{0x04, nullptr, "GetProcessAffinityMask"},
{0x05, nullptr, "SetProcessAffinityMask"},
{0x06, nullptr, "GetProcessIdealProcessor"},
{0x07, nullptr, "SetProcessIdealProcessor"},
{0x08, HLE::Wrap<CreateThread>, "CreateThread"},
{0x09, ExitThread, "ExitThread"},
{0x0A, HLE::Wrap<SleepThread>, "SleepThread"},
{0x0B, HLE::Wrap<GetThreadPriority>, "GetThreadPriority"},
{0x0C, HLE::Wrap<SetThreadPriority>, "SetThreadPriority"},
{0x0D, nullptr, "GetThreadAffinityMask"},
{0x0E, nullptr, "SetThreadAffinityMask"},
{0x0F, nullptr, "GetThreadIdealProcessor"},
{0x10, nullptr, "SetThreadIdealProcessor"},
{0x11, nullptr, "GetCurrentProcessorNumber"},
{0x12, nullptr, "Run"},
{0x13, HLE::Wrap<CreateMutex>, "CreateMutex"},
{0x14, HLE::Wrap<ReleaseMutex>, "ReleaseMutex"},
{0x15, HLE::Wrap<CreateSemaphore>, "CreateSemaphore"},
{0x16, HLE::Wrap<ReleaseSemaphore>, "ReleaseSemaphore"},
{0x17, HLE::Wrap<CreateEvent>, "CreateEvent"},
{0x18, HLE::Wrap<SignalEvent>, "SignalEvent"},
{0x19, HLE::Wrap<ClearEvent>, "ClearEvent"},
{0x1A, HLE::Wrap<CreateTimer>, "CreateTimer"},
{0x1B, HLE::Wrap<SetTimer>, "SetTimer"},
{0x1C, HLE::Wrap<CancelTimer>, "CancelTimer"},
{0x1D, HLE::Wrap<ClearTimer>, "ClearTimer"},
{0x1E, HLE::Wrap<CreateMemoryBlock>, "CreateMemoryBlock"},
{0x1F, HLE::Wrap<MapMemoryBlock>, "MapMemoryBlock"},
{0x20, HLE::Wrap<UnmapMemoryBlock>, "UnmapMemoryBlock"},
{0x21, HLE::Wrap<CreateAddressArbiter>, "CreateAddressArbiter"},
{0x22, HLE::Wrap<ArbitrateAddress>, "ArbitrateAddress"},
{0x23, HLE::Wrap<CloseHandle>, "CloseHandle"},
{0x24, HLE::Wrap<WaitSynchronization1>, "WaitSynchronization1"},
{0x25, HLE::Wrap<WaitSynchronizationN>, "WaitSynchronizationN"},
{0x26, nullptr, "SignalAndWait"},
{0x27, HLE::Wrap<DuplicateHandle>, "DuplicateHandle"},
{0x28, HLE::Wrap<GetSystemTick>, "GetSystemTick"},
{0x29, nullptr, "GetHandleInfo"},
{0x2A, HLE::Wrap<GetSystemInfo>, "GetSystemInfo"},
{0x2B, HLE::Wrap<GetProcessInfo>, "GetProcessInfo"},
{0x2C, nullptr, "GetThreadInfo"},
{0x2D, HLE::Wrap<ConnectToPort>, "ConnectToPort"},
{0x2E, nullptr, "SendSyncRequest1"},
{0x2F, nullptr, "SendSyncRequest2"},
{0x30, nullptr, "SendSyncRequest3"},
{0x31, nullptr, "SendSyncRequest4"},
{0x32, HLE::Wrap<SendSyncRequest>, "SendSyncRequest"},
{0x33, nullptr, "OpenProcess"},
{0x34, nullptr, "OpenThread"},
{0x35, HLE::Wrap<GetProcessId>, "GetProcessId"},
{0x36, HLE::Wrap<GetProcessIdOfThread>, "GetProcessIdOfThread"},
{0x37, HLE::Wrap<GetThreadId>, "GetThreadId"},
{0x38, HLE::Wrap<GetResourceLimit>, "GetResourceLimit"},
{0x39, HLE::Wrap<GetResourceLimitLimitValues>, "GetResourceLimitLimitValues"},
{0x3A, HLE::Wrap<GetResourceLimitCurrentValues>, "GetResourceLimitCurrentValues"},
{0x3B, nullptr, "GetThreadContext"},
{0x3C, HLE::Wrap<Break>, "Break"},
{0x3D, HLE::Wrap<OutputDebugString>, "OutputDebugString"},
{0x3E, nullptr, "ControlPerformanceCounter"},
{0x3F, nullptr, "Unknown"},
{0x40, nullptr, "Unknown"},
{0x41, nullptr, "Unknown"},
{0x42, nullptr, "Unknown"},
{0x43, nullptr, "Unknown"},
{0x44, nullptr, "Unknown"},
{0x45, nullptr, "Unknown"},
{0x46, nullptr, "Unknown"},
{0x47, HLE::Wrap<CreatePort>, "CreatePort"},
{0x48, HLE::Wrap<CreateSessionToPort>, "CreateSessionToPort"},
{0x49, HLE::Wrap<CreateSession>, "CreateSession"},
{0x4A, HLE::Wrap<AcceptSession>, "AcceptSession"},
{0x4B, nullptr, "ReplyAndReceive1"},
{0x4C, nullptr, "ReplyAndReceive2"},
{0x4D, nullptr, "ReplyAndReceive3"},
{0x4E, nullptr, "ReplyAndReceive4"},
{0x4F, HLE::Wrap<ReplyAndReceive>, "ReplyAndReceive"},
{0x50, nullptr, "BindInterrupt"},
{0x51, nullptr, "UnbindInterrupt"},
{0x52, nullptr, "InvalidateProcessDataCache"},
{0x53, nullptr, "StoreProcessDataCache"},
{0x54, nullptr, "FlushProcessDataCache"},
{0x55, nullptr, "StartInterProcessDma"},
{0x56, nullptr, "StopDma"},
{0x57, nullptr, "GetDmaState"},
{0x58, nullptr, "RestartDma"},
{0x59, nullptr, "Unknown"},
{0x5A, nullptr, "Unknown"},
{0x5B, nullptr, "Unknown"},
{0x5C, nullptr, "Unknown"},
{0x5D, nullptr, "Unknown"},
{0x5E, nullptr, "Unknown"},
{0x5F, nullptr, "Unknown"},
{0x60, nullptr, "DebugActiveProcess"},
{0x61, nullptr, "BreakDebugProcess"},
{0x62, nullptr, "TerminateDebugProcess"},
{0x63, nullptr, "GetProcessDebugEvent"},
{0x64, nullptr, "ContinueDebugEvent"},
{0x65, nullptr, "GetProcessList"},
{0x66, nullptr, "GetThreadList"},
{0x67, nullptr, "GetDebugThreadContext"},
{0x68, nullptr, "SetDebugThreadContext"},
{0x69, nullptr, "QueryDebugProcessMemory"},
{0x6A, nullptr, "ReadProcessMemory"},
{0x6B, nullptr, "WriteProcessMemory"},
{0x6C, nullptr, "SetHardwareBreakPoint"},
{0x6D, nullptr, "GetDebugThreadParam"},
{0x6E, nullptr, "Unknown"},
{0x6F, nullptr, "Unknown"},
{0x70, nullptr, "ControlProcessMemory"},
{0x71, nullptr, "MapProcessMemory"},
{0x72, nullptr, "UnmapProcessMemory"},
{0x73, nullptr, "CreateCodeSet"},
{0x74, nullptr, "RandomStub"},
{0x75, nullptr, "CreateProcess"},
{0x76, nullptr, "TerminateProcess"},
{0x77, nullptr, "SetProcessResourceLimits"},
{0x78, nullptr, "CreateResourceLimit"},
{0x79, nullptr, "SetResourceLimitValues"},
{0x7A, nullptr, "AddCodeSegment"},
{0x7B, nullptr, "Backdoor"},
{0x7C, nullptr, "KernelSetState"},
{0x7D, HLE::Wrap<QueryProcessMemory>, "QueryProcessMemory"},
};
static const FunctionDef* GetSVCInfo(u32 func_num) {
if (func_num >= ARRAY_SIZE(SVC_Table)) {
LOG_ERROR(Kernel_SVC, "unknown svc=0x%02X", func_num);
return nullptr;
}
return &SVC_Table[func_num];
}
MICROPROFILE_DEFINE(Kernel_SVC, "Kernel", "SVC", MP_RGB(70, 200, 70));
void CallSVC(u32 immediate) {
MICROPROFILE_SCOPE(Kernel_SVC);
// Lock the global kernel mutex when we enter the kernel HLE.
std::lock_guard<std::recursive_mutex> lock(HLE::g_hle_lock);
const FunctionDef* info = GetSVCInfo(immediate);
if (info) {
if (info->func) {
info->func();
} else {
LOG_ERROR(Kernel_SVC, "unimplemented SVC function %s(..)", info->name);
}
}
}
} // namespace SVC
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