#include "stdafx_gui.h" #include "Utilities/Log.h" #include "Emu/Memory/Memory.h" #include "Emu/System.h" #include "Emu/IdManager.h" #include "Emu/CPU/CPUThreadManager.h" #include "Emu/CPU/CPUThread.h" #include "Emu/SysCalls/SyncPrimitivesManager.h" #include "KernelExplorer.h" KernelExplorer::KernelExplorer(wxWindow* parent) : wxFrame(parent, wxID_ANY, "Kernel Explorer", wxDefaultPosition, wxSize(700, 450)) { this->SetBackgroundColour(wxColour(240,240,240)); //This fix the ugly background color under Windows wxBoxSizer* s_panel = new wxBoxSizer(wxVERTICAL); // Buttons wxBoxSizer* box_buttons = new wxBoxSizer(wxHORIZONTAL); wxButton* b_refresh = new wxButton(this, wxID_ANY, "Refresh"); box_buttons->AddSpacer(10); box_buttons->Add(b_refresh); box_buttons->AddSpacer(10); wxStaticBoxSizer* box_tree = new wxStaticBoxSizer(wxHORIZONTAL, this, "Kernel"); m_tree = new wxTreeCtrl(this, wxID_ANY, wxDefaultPosition, wxSize(600,300)); box_tree->Add(m_tree); // Merge and display everything s_panel->AddSpacer(10); s_panel->Add(box_buttons); s_panel->AddSpacer(10); s_panel->Add(box_tree, 0, 0, 100); s_panel->AddSpacer(10); SetSizerAndFit(s_panel); // Events b_refresh->Bind(wxEVT_BUTTON, &KernelExplorer::OnRefresh, this); // Fill the wxTreeCtrl Update(); }; void KernelExplorer::Update() { int count; char name[4096]; m_tree->DeleteAllItems(); const u32 total_memory_usage = Memory.GetUserMemTotalSize() - Memory.GetUserMemAvailSize(); const auto& root = m_tree->AddRoot(fmt::Format("Process, ID = 0x00000001, Total Memory Usage = 0x%x (%0.2f MB)", total_memory_usage, (float)total_memory_usage / (1024 * 1024))); // TODO: FileSystem // Semaphores count = Emu.GetIdManager().GetTypeCount(TYPE_SEMAPHORE); if (count) { sprintf(name, "Semaphores (%d)", count); const auto& node = m_tree->AppendItem(root, name); for (const auto& id : Emu.GetIdManager().GetTypeIDs(TYPE_SEMAPHORE)) { auto sem = Emu.GetSyncPrimManager().GetSemaphoreData(id); sprintf(name, "Semaphore: ID = 0x%08x '%s', Count = %d, Max Count = %d", id, sem.name.c_str(), sem.count, sem.max_count); m_tree->AppendItem(node, name); } } // Mutexes count = Emu.GetIdManager().GetTypeCount(TYPE_MUTEX); if (count) { sprintf(name, "Mutexes (%d)", count); const auto& node = m_tree->AppendItem(root, name); for (const auto& id : Emu.GetIdManager().GetTypeIDs(TYPE_MUTEX)) { sprintf(name, "Mutex: ID = 0x%08x '%s'", id, Emu.GetSyncPrimManager().GetSyncPrimName(id, TYPE_MUTEX).c_str()); m_tree->AppendItem(node, name); } } // Light Weight Mutexes count = Emu.GetIdManager().GetTypeCount(TYPE_LWMUTEX); if (count) { sprintf(name, "Light Weight Mutexes (%d)", count); const auto& node = m_tree->AppendItem(root, name); for (const auto& id : Emu.GetIdManager().GetTypeIDs(TYPE_LWMUTEX)) { auto lwm = Emu.GetSyncPrimManager().GetLwMutexData(id); sprintf(name, "LW Mutex: ID = 0x%08x '%s'", id, lwm.name.c_str()); m_tree->AppendItem(node, name); } } // Condition Variables count = Emu.GetIdManager().GetTypeCount(TYPE_COND); if (count) { sprintf(name, "Condition Variables (%d)", count); const auto& node = m_tree->AppendItem(root, name); for (const auto& id : Emu.GetIdManager().GetTypeIDs(TYPE_COND)) { sprintf(name, "Condition Variable: ID = 0x%08x '%s'", id, Emu.GetSyncPrimManager().GetSyncPrimName(id, TYPE_COND).c_str()); m_tree->AppendItem(node, name); } } // Light Weight Condition Variables count = Emu.GetIdManager().GetTypeCount(TYPE_LWCOND); if (count) { sprintf(name, "Light Weight Condition Variables (%d)", count); const auto& node = m_tree->AppendItem(root, name); for (const auto& id : Emu.GetIdManager().GetTypeIDs(TYPE_LWCOND)) { sprintf(name, "LW Condition Variable: ID = 0x%08x '%s'", id, Emu.GetSyncPrimManager().GetSyncPrimName(id, TYPE_LWCOND).c_str()); m_tree->AppendItem(node, name); } } // Event Queues count = Emu.GetIdManager().GetTypeCount(TYPE_EVENT_QUEUE); if (count) { sprintf(name, "Event Queues (%d)", count); const auto& node = m_tree->AppendItem(root, name); for (const auto& id : Emu.GetIdManager().GetTypeIDs(TYPE_EVENT_QUEUE)) { sprintf(name, "Event Queue: ID = 0x%08x", id); m_tree->AppendItem(node, name); } } // Modules count = Emu.GetIdManager().GetTypeCount(TYPE_PRX); if (count) { sprintf(name, "Modules (%d)", count); const auto& node = m_tree->AppendItem(root, name); //sprintf(name, "Segment List (%l)", 2 * objects.size()); // TODO: Assuming 2 segments per PRX file is not good //m_tree->AppendItem(node, name); for (const auto& id : Emu.GetIdManager().GetTypeIDs(TYPE_PRX)) { sprintf(name, "PRX: ID = 0x%08x", id); m_tree->AppendItem(node, name); } } // Memory Containers count = Emu.GetIdManager().GetTypeCount(TYPE_MEM); if (count) { sprintf(name, "Memory Containers (%d)", count); const auto& node = m_tree->AppendItem(root, name); for (const auto& id : Emu.GetIdManager().GetTypeIDs(TYPE_MEM)) { sprintf(name, "Memory Container: ID = 0x%08x", id); m_tree->AppendItem(node, name); } } // Event Flags count = Emu.GetIdManager().GetTypeCount(TYPE_EVENT_FLAG); if (count) { sprintf(name, "Event Flags (%d)", count); const auto& node = m_tree->AppendItem(root, name); for (const auto& id : Emu.GetIdManager().GetTypeIDs(TYPE_EVENT_FLAG)) { sprintf(name, "Event Flag: ID = 0x%08x", id); m_tree->AppendItem(node, name); } } // PPU / SPU / RawSPU threads { // TODO: add mutexes owners //const auto& objects = Emu.GetCPU().GetThreads(); u32 ppu_threads_count = 0; u32 spu_threads_count = 0; u32 raw_spu_threads_count = 0; //for (const auto& thread : objects) //{ // if (thread->GetType() == CPU_THREAD_PPU) // ppu_threads_count++; // if (thread->GetType() == CPU_THREAD_SPU) // spu_threads_count++; // if (thread->GetType() == CPU_THREAD_RAW_SPU) // raw_spu_threads_count++; //} //if (ppu_threads_count) //{ // sprintf(name, "PPU Threads (%d)", ppu_threads_count); // const auto& node = m_tree->AppendItem(root, name); // for (const auto& thread : objects) // { // if (thread->GetType() == CPU_THREAD_PPU) // { // sprintf(name, "Thread: ID = 0x%08x '%s', - %s", thread->GetId(), thread->GetName().c_str(), thread->ThreadStatusToString().c_str()); // m_tree->AppendItem(node, name); // } // } //} //if (spu_threads_count) //{ // sprintf(name, "SPU Threads (%d)", spu_threads_count); // const auto& node = m_tree->AppendItem(root, name); // for (const auto& thread : objects) // { // if (thread->GetType() == CPU_THREAD_SPU) // { // sprintf(name, "Thread: ID = 0x%08x '%s', - %s", thread->GetId(), thread->GetName().c_str(), thread->ThreadStatusToString().c_str()); // m_tree->AppendItem(node, name); // } // } //} //if (raw_spu_threads_count) //{ // sprintf(name, "RawSPU Threads (%d)", raw_spu_threads_count); // const auto& node = m_tree->AppendItem(root, name); // for (const auto& thread : objects) // { // if (thread->GetType() == CPU_THREAD_RAW_SPU) // { // sprintf(name, "Thread: ID = 0x%08x '%s', - %s", thread->GetId(), thread->GetName().c_str(), thread->ThreadStatusToString().c_str()); // m_tree->AppendItem(node, name); // } // } //} } m_tree->Expand(root); } void KernelExplorer::OnRefresh(wxCommandEvent& WXUNUSED(event)) { Update(); }