#include #include #include #include #include #include #include "Emu/IdManager.h" #include "Emu/Cell/PPUThread.h" #include "Emu/Cell/SPUThread.h" #include "Emu/Cell/lv2/sys_lwmutex.h" #include "Emu/Cell/lv2/sys_lwcond.h" #include "Emu/Cell/lv2/sys_mutex.h" #include "Emu/Cell/lv2/sys_cond.h" #include "Emu/Cell/lv2/sys_semaphore.h" #include "Emu/Cell/lv2/sys_event_flag.h" #include "Emu/Cell/lv2/sys_rwlock.h" #include "Emu/Cell/lv2/sys_prx.h" #include "Emu/Cell/lv2/sys_overlay.h" #include "Emu/Cell/lv2/sys_memory.h" #include "Emu/Cell/lv2/sys_mmapper.h" #include "Emu/Cell/lv2/sys_spu.h" #include "Emu/Cell/lv2/sys_process.h" #include "Emu/Cell/lv2/sys_timer.h" #include "Emu/Cell/lv2/sys_rsx.h" #include "Emu/Cell/lv2/sys_vm.h" #include "Emu/Cell/lv2/sys_net.h" #include "Emu/Cell/lv2/sys_net/lv2_socket.h" #include "Emu/Cell/lv2/sys_fs.h" #include "Emu/Cell/lv2/sys_interrupt.h" #include "Emu/Cell/lv2/sys_rsxaudio.h" #include "Emu/Cell/Modules/cellSpurs.h" #include "Emu/RSX/RSXThread.h" #include "kernel_explorer.h" #include "qt_utils.h" constexpr auto qstr = QString::fromStdString; LOG_CHANNEL(sys_log, "SYS"); enum kernel_item_role { name_role = Qt::UserRole + 0, expanded_role = Qt::UserRole + 1, type_role = Qt::UserRole + 2, id_role = Qt::UserRole + 3, }; enum kernel_item_type : int { root, node, volatile_node, solid_node, leaf }; static QTreeWidgetItem* add_child(QTreeWidgetItem* parent, const QString& text, int column, kernel_item_type type) { if (parent) { for (int i = 0; i < parent->childCount(); i++) { if (parent->child(i)->data(0, kernel_item_role::name_role).toString() == text) { return parent->child(i); } } } QTreeWidgetItem* item = gui::utils::add_child(parent, text, column); if (item) { item->setData(0, kernel_item_role::name_role, text); item->setData(0, kernel_item_role::type_role, type); } return item; } static QTreeWidgetItem* add_leaf(QTreeWidgetItem* parent, const QString& text, int column = 0) { return add_child(parent, text, column, kernel_item_type::leaf); } static QTreeWidgetItem* add_node(u32 id, QTreeWidgetItem* parent, const QString& text, int column = 0) { QTreeWidgetItem* node = add_child(parent, text, column, kernel_item_type::node); if (node) { node->setData(0, kernel_item_role::id_role, id); } return node; } static QTreeWidgetItem* find_first_node(QTreeWidgetItem* parent, const QString& regexp) { if (parent) { const QRegularExpression re(regexp); for (int i = 0; i < parent->childCount(); i++) { if (QTreeWidgetItem* item = parent->child(i); item && item->data(0, kernel_item_role::type_role).toInt() != kernel_item_type::leaf && re.match(item->data(0, kernel_item_role::name_role).toString()).hasMatch()) { return item; } } } return nullptr; } // Find node with ID in selected node children static QTreeWidgetItem* find_node(QTreeWidgetItem* root, u32 id) { if (root) { for (int i = 0; i < root->childCount(); i++) { if (QTreeWidgetItem* item = root->child(i); item && item->data(0, kernel_item_role::type_role).toInt() == kernel_item_type::node && item->data(0, kernel_item_role::id_role).toUInt() == id) { return item; } } } sys_log.fatal("find_node(root=%s, id=%d) failed", root ? root->text(0) : "?", id); return nullptr; } static QTreeWidgetItem* add_volatile_node(QTreeWidgetItem* parent, const QString& base_text, const QString& text = "", int column = 0) { QTreeWidgetItem* node = find_first_node(parent, base_text + ".*"); if (!node) { node = add_child(parent, base_text, column, kernel_item_type::volatile_node); } if (node) { node->setText(0, text.isEmpty() ? base_text : text); } else { sys_log.fatal("add_volatile_node(parent=%s, regexp=%s) failed", parent ? parent->text(0) : "?", base_text + ".*"); } return node; } static QTreeWidgetItem* add_solid_node(QTreeWidgetItem* parent, const QString& base_text, const QString& text = "", int column = 0) { QTreeWidgetItem* node = find_first_node(parent, base_text + ".*"); if (!node) { node = add_child(parent, base_text, column, kernel_item_type::solid_node); } if (node) { node->setText(0, text.isEmpty() ? base_text : text); } else { sys_log.fatal("add_solid_node(parent=%s, regexp=%s) failed", parent ? parent->text(0).toStdString() : "?", base_text.toStdString() + ".*"); } return node; } kernel_explorer::kernel_explorer(QWidget* parent) : QDialog(parent) { setWindowTitle(tr("Kernel Explorer | %1").arg(qstr(Emu.GetTitleAndTitleID()))); setObjectName("kernel_explorer"); setAttribute(Qt::WA_DeleteOnClose); setMinimumSize(QSize(800, 600)); QVBoxLayout* vbox_panel = new QVBoxLayout(); QHBoxLayout* hbox_buttons = new QHBoxLayout(); QPushButton* button_refresh = new QPushButton(tr("Refresh"), this); QPushButton* button_log = new QPushButton(tr("Log All"), this); hbox_buttons->addWidget(button_refresh); hbox_buttons->addSpacing(8); hbox_buttons->addWidget(button_log); hbox_buttons->addStretch(); m_tree = new QTreeWidget(this); m_tree->setBaseSize(QSize(700, 450)); m_tree->setWindowTitle(tr("Kernel")); m_tree->header()->close(); // Merge and display everything vbox_panel->addSpacing(8); vbox_panel->addLayout(hbox_buttons); vbox_panel->addSpacing(8); vbox_panel->addWidget(m_tree); setLayout(vbox_panel); // Events connect(button_refresh, &QAbstractButton::clicked, this, &kernel_explorer::update); connect(button_log, &QAbstractButton::clicked, this, [this]() { log(); m_log_buf.clear(); }); update(); } void kernel_explorer::update() { const auto dct = g_fxo->try_get(); if (!dct) { m_tree->clear(); return; } const std::initializer_list> tree_item_names = { { process_info , tr("Process Info")}, { SYS_MEM_OBJECT , tr("Shared Memory")}, { virtual_memory , tr("Virtual Memory")}, { SYS_MUTEX_OBJECT , tr("Mutexes")}, { SYS_COND_OBJECT , tr("Condition Variables")}, { SYS_RWLOCK_OBJECT , tr("Reader Writer Locks")}, { SYS_INTR_TAG_OBJECT , tr("Interrupt Tags")}, { SYS_INTR_SERVICE_HANDLE_OBJECT , tr("Interrupt Service Handles")}, { SYS_EVENT_QUEUE_OBJECT , tr("Event Queues")}, { SYS_EVENT_PORT_OBJECT , tr("Event Ports")}, { SYS_TRACE_OBJECT , tr("Traces")}, { SYS_SPUIMAGE_OBJECT , tr("SPU Images")}, { SYS_PRX_OBJECT , tr("PRX Modules")}, { SYS_SPUPORT_OBJECT , tr("SPU Ports")}, { SYS_OVERLAY_OBJECT , tr("Overlay Modules")}, { SYS_LWMUTEX_OBJECT , tr("Light Weight Mutexes")}, { SYS_TIMER_OBJECT , tr("Timers")}, { SYS_SEMAPHORE_OBJECT , tr("Semaphores")}, { SYS_FS_FD_OBJECT , tr("File Descriptors")}, { SYS_LWCOND_OBJECT , tr("Light Weight Condition Variables")}, { SYS_EVENT_FLAG_OBJECT , tr("Event Flags")}, { SYS_RSXAUDIO_OBJECT , tr("RSXAudio Objects")}, { memory_containers , tr("Memory Containers")}, { ppu_threads , tr("PPU Threads")}, { spu_threads , tr("SPU Threads")}, { spu_thread_groups , tr("SPU Thread Groups")}, { rsx_contexts , tr("RSX Contexts")}, { sockets , tr("Sockets")}, { file_descriptors , tr("File Descriptors")}, }; QTreeWidgetItem* root = m_tree->topLevelItem(0); if (!root) { root = new QTreeWidgetItem(); root->setData(0, kernel_item_role::type_role, kernel_item_type::root); m_tree->addTopLevelItem(root); for (const auto& [key, name] : tree_item_names) { add_node(key, root, name); } } else { std::function clean_up_tree; clean_up_tree = [&clean_up_tree](QTreeWidgetItem* item) { if (item && item->data(0, kernel_item_role::type_role).toInt() != kernel_item_type::leaf) { item->setText(0, item->data(0, kernel_item_role::name_role).toString()); item->setData(0, kernel_item_role::expanded_role, item->isExpanded()); for (int i = item->childCount() - 1; i >= 0; i--) { switch (item->child(i)->data(0, kernel_item_role::type_role).toInt()) { case kernel_item_type::leaf: { delete item->takeChild(i); break; } case kernel_item_type::volatile_node: { if (item->child(i)->childCount() <= 0) { // Cleanup volatile node if it has no children delete item->takeChild(i); break; } [[fallthrough]]; } case kernel_item_type::solid_node: case kernel_item_type::node: case kernel_item_type::root: default: { clean_up_tree(item->child(i)); break; } } } } }; clean_up_tree(root); } const u32 total_memory_usage = dct->used; root->setText(0, qstr(fmt::format("Process 0x%08x: Total Memory Usage: 0x%x/0x%x (%0.2f/%0.2f MB)", process_getpid(), total_memory_usage, dct->size, 1. * total_memory_usage / (1024 * 1024) , 1. * dct->size / (1024 * 1024)))); add_solid_node(find_node(root, additional_nodes::process_info), qstr(fmt::format("Process Info, Sdk Version: 0x%08x, PPC SEG: %#x, SFO Category: %s (Fake: %s)", g_ps3_process_info.sdk_ver, g_ps3_process_info.ppc_seg, Emu.GetCat(), Emu.GetFakeCat()))); auto display_program_segments = [this](QTreeWidgetItem* tree, const ppu_module& m) { for (usz i = 0; i < m.segs.size(); i++) { const u32 addr = m.segs[i].addr; const u32 size = m.segs[i].size; add_leaf(tree, qstr(fmt::format("Segment %u: (0x%08x...0x%08x), Flags: 0x%x" , i, addr, addr + std::max(size, 1) - 1, m.segs[i].flags))); } }; idm::select([&](u32 id, lv2_obj& obj) { const auto node = find_node(root, id >> 24); if (!node) { return; } auto show_waiters = [&](QTreeWidgetItem* tree, cpu_thread* cpu) { for (; cpu; cpu = cpu->get_next_cpu()) { add_leaf(tree, qstr(fmt::format("Waiter: ID: 0x%x", cpu->id_type() == 2 ? static_cast(cpu)->lv2_id : cpu->id))); } }; switch (id >> 24) { case SYS_MEM_OBJECT: { auto& mem = static_cast(obj); const f64 size_mb = mem.size * 1. / (1024 * 1024); if (mem.pshared) { add_leaf(node, qstr(fmt::format("Shared Mem 0x%08x: Size: 0x%x (%0.2f MB), Chunk: %s, Mappings: %u, Mem Container: %s, Key: %#llx", id, mem.size, size_mb, mem.align == 0x10000u ? "64K" : "1MB", +mem.counter, mem.ct->id, mem.key))); break; } add_leaf(node, qstr(fmt::format("Shared Mem 0x%08x: Size: 0x%x (%0.2f MB), Chunk: %s, Mem Container: %s, Mappings: %u", id, mem.size, size_mb, mem.align == 0x10000u ? "64K" : "1MB", mem.ct->id, +mem.counter))); break; } case SYS_MUTEX_OBJECT: { auto& mutex = static_cast(obj); const auto control = mutex.control.load(); show_waiters(add_solid_node(node, qstr(fmt::format(u8"Mutex 0x%08x: “%s”", id, lv2_obj::name64(mutex.name))), qstr(fmt::format(u8"Mutex 0x%08x: “%s”, %s,%s Owner: %#x, Locks: %u, Key: %#llx, Conds: %u", id, lv2_obj::name64(mutex.name), mutex.protocol, mutex.recursive == SYS_SYNC_RECURSIVE ? " Recursive," : "", control.owner, +mutex.lock_count, mutex.key, mutex.cond_count))), control.sq); break; } case SYS_COND_OBJECT: { auto& cond = static_cast(obj); show_waiters(add_solid_node(node, qstr(fmt::format(u8"Cond 0x%08x: “%s”", id, lv2_obj::name64(cond.name))), qstr(fmt::format(u8"Cond 0x%08x: “%s”, %s, Mutex: 0x%08x, Key: %#llx", id, lv2_obj::name64(cond.name), cond.mutex->protocol, cond.mtx_id, cond.key))), cond.sq); break; } case SYS_RWLOCK_OBJECT: { auto& rw = static_cast(obj); const s64 val = rw.owner; auto tree = add_solid_node(node, qstr(fmt::format(u8"RW Lock 0x%08x: “%s”", id, lv2_obj::name64(rw.name))), qstr(fmt::format(u8"RW Lock 0x%08x: “%s”, %s, Owner: %#x(%d), Key: %#llx", id, lv2_obj::name64(rw.name), rw.protocol, std::max(0, val >> 1), -std::min(0, val >> 1), rw.key))); if (auto rq = +rw.rq) { show_waiters(add_solid_node(tree, "Reader Waiters"), rq); } if (auto wq = +rw.wq) { show_waiters(add_solid_node(tree, "Writer Waiters"), wq); } break; } case SYS_INTR_TAG_OBJECT: { auto& tag = static_cast(obj); const auto handler = tag.handler.get(); if (lv2_obj::check(handler)) { add_leaf(node, qstr(fmt::format("Intr Tag 0x%08x, Handler: 0x%08x", id, handler->id))); break; } add_leaf(node, qstr(fmt::format("Intr Tag 0x%08x, Handler: Unbound", id))); break; } case SYS_INTR_SERVICE_HANDLE_OBJECT: { auto& serv = static_cast(obj); add_leaf(node, qstr(fmt::format("Intr Svc 0x%08x, PPU: 0x%07x, arg1: 0x%x, arg2: 0x%x", id, serv.thread->id, serv.arg1, serv.arg2))); break; } case SYS_EVENT_QUEUE_OBJECT: { auto& eq = static_cast(obj); show_waiters(add_solid_node(node, qstr(fmt::format(u8"Event Queue 0x%08x: “%s”", id, lv2_obj::name64(eq.name))), qstr(fmt::format(u8"Event Queue 0x%08x: “%s”, %s, %s, Key: %#llx, Events: %zu/%d", id, lv2_obj::name64(eq.name), eq.protocol, eq.type == SYS_SPU_QUEUE ? "SPU" : "PPU", eq.key, eq.events.size(), eq.size))), eq.type == SYS_SPU_QUEUE ? static_cast(+eq.sq) : +eq.pq); break; } case SYS_EVENT_PORT_OBJECT: { auto& ep = static_cast(obj); const auto type = ep.type == SYS_EVENT_PORT_LOCAL ? "LOCAL"sv : "IPC"sv; if (const auto queue = ep.queue.get(); lv2_obj::check(queue)) { if (queue == idm::check_unlocked(queue->id)) { add_leaf(node, qstr(fmt::format("Event Port 0x%08x: %s, Name: %#llx, Event Queue (ID): 0x%08x", id, type, ep.name, queue->id))); break; } // This code is unused until multi-process is implemented if (queue == lv2_event_queue::find(queue->key).get()) { add_leaf(node, qstr(fmt::format("Event Port 0x%08x: %s, Name: %#llx, Event Queue (IPC): %s", id, type, ep.name, queue->key))); break; } } add_leaf(node, qstr(fmt::format("Event Port 0x%08x: %s, Name: %#llx, Unbound", id, type, ep.name))); break; } case SYS_TRACE_OBJECT: { add_leaf(node, qstr(fmt::format("Trace 0x%08x", id))); break; } case SYS_SPUIMAGE_OBJECT: { auto& spi = static_cast(obj); add_leaf(node, qstr(fmt::format("SPU Image 0x%08x, Entry: 0x%x, Segs: *0x%x, Num Segs: %d", id, spi.e_entry, spi.segs, spi.nsegs))); break; } case SYS_PRX_OBJECT: { auto& prx = static_cast(obj); if (prx.segs.empty()) { add_leaf(node, qstr(fmt::format("PRX 0x%08x: '%s' (HLE)", id, prx.name))); break; } const QString text = qstr(fmt::format("PRX 0x%08x: '%s', attr=0x%x, lib=%s", id, prx.name, prx.module_info_attributes, prx.module_info_name)); QTreeWidgetItem* prx_tree = add_solid_node(node, text, text); display_program_segments(prx_tree, prx); break; } case SYS_SPUPORT_OBJECT: { add_leaf(node, qstr(fmt::format("SPU Port 0x%08x", id))); break; } case SYS_OVERLAY_OBJECT: { auto& ovl = static_cast(obj); const QString text = qstr(fmt::format("OVL 0x%08x: '%s'", id, ovl.name)); QTreeWidgetItem* ovl_tree = add_solid_node(node, text, text); display_program_segments(ovl_tree, ovl); break; } case SYS_LWMUTEX_OBJECT: { auto& lwm = static_cast(obj); std::string owner_str = "unknown"; // Either invalid state or the lwmutex control data was moved from sys_lwmutex_t lwm_data{}; auto lv2_control = lwm.lv2_control.load(); if (lwm.control.try_read(lwm_data) && lwm_data.sleep_queue == id) { switch (const u32 owner = lwm_data.vars.owner) { case lwmutex_free: owner_str = "free"; break; case lwmutex_dead: owner_str = "dead"; break; case lwmutex_reserved: owner_str = "reserved"; break; default: { if (idm::check_unlocked>(owner)) { owner_str = fmt::format("0x%x", owner); } else { fmt::append(owner_str, " (0x%x)", owner); } break; } } } else { show_waiters(add_solid_node(node, qstr(fmt::format(u8"LWMutex 0x%08x: “%s”", id, lv2_obj::name64(lwm.name))), qstr(fmt::format(u8"LWMutex 0x%08x: “%s”, %s, Signal: %#x (unmapped/invalid control data at *0x%x)", id, lv2_obj::name64(lwm.name), lwm.protocol, +lv2_control.signaled, lwm.control))), lv2_control.sq); break; } show_waiters(add_solid_node(node, qstr(fmt::format(u8"LWMutex 0x%08x: “%s”", id, lv2_obj::name64(lwm.name))), qstr(fmt::format(u8"LWMutex 0x%08x: “%s”, %s,%s Owner: %s, Locks: %u, Signal: %#x, Control: *0x%x", id, lv2_obj::name64(lwm.name), lwm.protocol, (lwm_data.attribute & SYS_SYNC_RECURSIVE) ? " Recursive," : "", owner_str, lwm_data.recursive_count, +lv2_control.signaled, lwm.control))), lv2_control.sq); break; } case SYS_TIMER_OBJECT: { auto& timer = static_cast(obj); u32 timer_state{SYS_TIMER_STATE_STOP}; std::shared_ptr port; u64 source = 0; u64 data1 = 0; u64 data2 = 0; u64 expire = 0; // Next expiration time u64 period = 0; // Period (oneshot if 0) if (reader_lock r_lock(timer.mutex); true) { timer_state = timer.state; port = timer.port; source = timer.source; data1 = timer.data1; data2 = timer.data2; expire = timer.expire; // Next expiration time period = timer.period; // Period (oneshot if 0) } add_leaf(node, qstr(fmt::format("Timer 0x%08x: State: %s, Period: 0x%llx, Next Expire: 0x%llx, Queue ID: 0x%08x, Source: 0x%08x, Data1: 0x%08x, Data2: 0x%08x", id, timer_state ? "Running" : "Stopped" , period, expire, port ? port->id : 0, source, data1, data2))); break; } case SYS_SEMAPHORE_OBJECT: { auto& sema = static_cast(obj); const auto val = +sema.val; show_waiters(add_solid_node(node, qstr(fmt::format(u8"Sema 0x%08x: “%s”", id, lv2_obj::name64(sema.name))), qstr(fmt::format(u8"Sema 0x%08x: “%s”, %s, Count: %d/%d, Key: %#llx", id, lv2_obj::name64(sema.name), sema.protocol, std::max(val, 0), sema.max, sema.key, -std::min(val, 0)))), sema.sq); break; } case SYS_LWCOND_OBJECT: { auto& lwc = static_cast(obj); show_waiters(add_solid_node(node, qstr(fmt::format(u8"LWCond 0x%08x: “%s”", id, lv2_obj::name64(lwc.name))), qstr(fmt::format(u8"LWCond 0x%08x: “%s”, %s, OG LWMutex: 0x%08x, Control: *0x%x", id, lv2_obj::name64(lwc.name), lwc.protocol, lwc.lwid, lwc.control))), lwc.sq); break; } case SYS_EVENT_FLAG_OBJECT: { auto& ef = static_cast(obj); show_waiters(add_solid_node(node, qstr(fmt::format(u8"Event Flag 0x%08x: “%s”", id, lv2_obj::name64(ef.name))), qstr(fmt::format(u8"Event Flag 0x%08x: “%s”, %s, Type: 0x%x, Key: %#llx, Pattern: 0x%llx", id, lv2_obj::name64(ef.name), ef.protocol, ef.type, ef.key, ef.pattern.load()))), ef.sq); break; } case SYS_RSXAUDIO_OBJECT: { auto& rao = static_cast(obj); std::lock_guard lock(rao.mutex); if (!rao.init) { break; } QTreeWidgetItem* rao_obj = add_solid_node(node, qstr(fmt::format(u8"RSXAudio 0x%08x: Shmem: 0x%08x", id, u32{rao.shmem}))); for (u64 q_idx = 0; q_idx < rao.event_queue.size(); q_idx++) { if (const auto eq = rao.event_queue[q_idx].lock()) { add_leaf(rao_obj, qstr(fmt::format(u8"Event Queue %u: ID: 0x%08x", q_idx, eq->id))); } } break; } default: { add_leaf(node, qstr(fmt::format("Unknown object 0x%08x", id))); } } }); idm::select([&](u32 /*id*/, sys_vm_t& vmo) { const u32 psize = vmo.psize; add_leaf(find_node(root, additional_nodes::virtual_memory), qstr(fmt::format("Virtual Mem 0x%08x: Virtual Size: 0x%x (%0.2f MB), Physical Size: 0x%x (%0.2f MB), Mem Container: %s", vmo.addr , vmo.size, vmo.size * 1. / (1024 * 1024), psize, psize * 1. / (1024 * 1024), vmo.ct->id))); }); idm::select([&](u32 id, lv2_socket& sock) { add_leaf(find_node(root, additional_nodes::sockets), qstr(fmt::format("Socket %u: Type: %s, Family: %s, Wq: %zu", id, sock.get_type(), sock.get_family(), sock.get_queue_size()))); }); idm::select([&](u32 id, lv2_memory_container& container) { const u32 used = container.used; add_leaf(find_node(root, additional_nodes::memory_containers), qstr(fmt::format("Memory Container 0x%08x: Used: 0x%x/0x%x (%0.2f/%0.2f MB)", id, used, container.size, used * 1. / (1024 * 1024), container.size * 1. / (1024 * 1024)))); }); std::optional> lock_idm_lv2(std::in_place, id_manager::g_mutex, lv2_obj::g_mutex); // Postponed as much as possible for time accuracy u64 current_time_storage = 0; auto get_current_time = [¤t_time_storage]() { if (!current_time_storage) { // Evaluate on the first use for better consistency (this function can be quite slow) // Yet once it is evaluated, keep it on the same value for consistency. current_time_storage = get_guest_system_time(); } return current_time_storage; }; auto get_wait_time_str = [&](u64 start_time) -> std::string { if (!start_time) { return {}; } if (start_time > get_current_time() && start_time - get_current_time() > 1'000'000) { return " (time underflow)"; } const f64 wait_time = (get_current_time() >= start_time ? get_current_time() - start_time : 0) / 1000000.; return fmt::format(" (%.1fs)", wait_time); }; idm::select>([&](u32 id, ppu_thread& ppu) { const auto func = ppu.last_function; const ppu_thread_status status = lv2_obj::ppu_state(&ppu, false, false); add_leaf(find_node(root, additional_nodes::ppu_threads), qstr(fmt::format(u8"PPU 0x%07x: “%s”, PRIO: %d, Joiner: %s, Status: %s, State: %s, %s func: “%s”%s", id, *ppu.ppu_tname.load(), ppu.prio.load().prio, ppu.joiner.load(), status, ppu.state.load() , ppu.ack_suspend ? "After" : (ppu.current_function ? "In" : "Last"), func ? func : "", get_wait_time_str(ppu.start_time)))); }, idm::unlocked); lock_idm_lv2.reset(); idm::select>([&](u32 /*id*/, spu_thread& spu) { const auto func = spu.current_func; const u64 start_time = spu.start_time; QTreeWidgetItem* spu_thread_tree = add_solid_node(find_node(root, additional_nodes::spu_threads), qstr(fmt::format(u8"SPU 0x%07x: “%s”", spu.lv2_id, *spu.spu_tname.load())), qstr(fmt::format(u8"SPU 0x%07x: “%s”, State: %s, Type: %s, Func: \"%s\"%s", spu.lv2_id, *spu.spu_tname.load(), spu.state.load(), spu.get_type(), start_time && func ? func : "", start_time ? get_wait_time_str(get_guest_system_time(start_time)) : ""))); if (spu.get_type() == spu_type::threaded) { reader_lock lock(spu.group->mutex); bool has_connected_ports = false; const auto first_spu = spu.group->threads[0].get(); // Always show information of the first thread in group // Or if information differs from that thread if (&spu == first_spu || std::any_of(std::begin(spu.spup), std::end(spu.spup), [&](const auto& port) { // Flag to avoid reporting information if no SPU ports are connected has_connected_ports |= lv2_obj::check(port); // Check if ports do not match with the first thread return port != first_spu->spup[&port - spu.spup]; })) { for (const auto& port : spu.spup) { if (lv2_obj::check(port)) { add_leaf(spu_thread_tree, qstr(fmt::format("SPU Port %u: Queue ID: 0x%08x", &port - spu.spup, port->id))); } } } else if (has_connected_ports) { // Avoid duplication of information between threads which is common add_leaf(spu_thread_tree, qstr(fmt::format("SPU Ports: As SPU 0x%07x", first_spu->lv2_id))); } for (const auto& [key, queue] : spu.spuq) { if (lv2_obj::check(queue)) { add_leaf(spu_thread_tree, qstr(fmt::format("SPU Queue: Queue ID: 0x%08x, Key: 0x%x", queue->id, key))); } } } else { for (const auto& ctrl : spu.int_ctrl) { if (lv2_obj::check(ctrl.tag)) { add_leaf(spu_thread_tree, qstr(fmt::format("Interrupt Tag %u: ID: 0x%x, Mask: 0x%x, Status: 0x%x", &ctrl - spu.int_ctrl.data(), ctrl.tag->id, +ctrl.mask, +ctrl.stat))); } } } }); idm::select([&](u32 id, lv2_spu_group& tg) { QTreeWidgetItem* spu_tree = add_solid_node(find_node(root, additional_nodes::spu_thread_groups), qstr(fmt::format(u8"SPU Group 0x%07x: “%s”, Type = 0x%x", id, tg.name, tg.type)), qstr(fmt::format(u8"SPU Group 0x%07x: “%s”, Status = %s, Priority = %d, Type = 0x%x", id, tg.name, tg.run_state.load(), tg.prio.load().prio, tg.type))); if (tg.name.ends_with("CellSpursKernelGroup"sv)) { vm::ptr pspurs{}; for (const auto& thread : tg.threads) { if (thread) { // Find SPURS structure address const u64 arg = tg.args[thread->index][1]; if (!pspurs) { if (arg < u32{umax} && arg % 0x80 == 0 && vm::check_addr(arg, vm::page_readable, pspurs.size())) { pspurs.set(static_cast(arg)); } else { break; } } else if (pspurs.addr() != arg) { pspurs = {}; break; } } } CellSpurs spurs{}; if (pspurs && pspurs.try_read(spurs)) { const QString branch_name = tr("SPURS %1").arg(pspurs.addr()); const u32 wklEnabled = spurs.wklEnabled; QTreeWidgetItem* spurs_tree = add_solid_node(spu_tree, branch_name, qstr(fmt::format("SPURS, Instance: *0x%x, LWMutex: 0x%x, LWCond: 0x%x, wklEnabled: 0x%x" , pspurs, spurs.mutex.sleep_queue, spurs.cond.lwcond_queue, wklEnabled))); const u32 signal_mask = u32{spurs.wklSignal1} << 16 | spurs.wklSignal2; for (u32 wid = 0; wid < CELL_SPURS_MAX_WORKLOAD2; wid++) { if (!(wklEnabled & (0x80000000u >> wid))) { continue; } const auto state = spurs.wklState(wid).raw(); if (state == SPURS_WKL_STATE_NON_EXISTENT) { continue; } const u32 ready_count = spurs.readyCount(wid); const auto& name = spurs.wklName(wid); const u8 evt = spurs.wklEvent(wid); const u8 status = spurs.wklStatus(wid); const auto has_signal = (signal_mask & (0x80000000u >> wid)) ? "Signalled"sv : "No Signal"sv; QTreeWidgetItem* wkl_tree = add_solid_node(spurs_tree, branch_name + qstr(fmt::format(" Work.%u", wid)), qstr(fmt::format("Work.%u, class: %s, %s, %s, Status: %#x, Event: %#x, %s, ReadyCnt: %u", wid, +name.nameClass, +name.nameInstance, state, status, evt, has_signal, ready_count))); auto contention = [&](u8 v) { if (wid >= CELL_SPURS_MAX_WORKLOAD) return (v >> 4); else return v & 0xf; }; const auto& winfo = spurs.wklInfo(wid); add_leaf(wkl_tree, qstr(fmt::format("Contention: %u/%u (pending: %u), Image: *0x%x (size: 0x%x, arg: 0x%x), Priority (BE64): %016x", contention(spurs.wklCurrentContention[wid % 16]) , contention(spurs.wklMaxContention[wid % 16]), contention(spurs.wklPendingContention[wid % 16]), +winfo.addr, winfo.size, winfo.arg, std::bit_cast>(winfo.priority)))); } add_leaf(spurs_tree, qstr(fmt::format("Handler Info: PPU0: 0x%x, PPU1: 0x%x, DirtyState: %u, Waiting: %u, Exiting: %u", spurs.ppu0, spurs.ppu1 , +spurs.handlerDirty, +spurs.handlerWaiting, +spurs.handlerExiting))); } else { // TODO: Might be old CellSpurs structure which is smaller } } }); QTreeWidgetItem* rsx_context_node = find_node(root, additional_nodes::rsx_contexts); do { // Currently a single context is supported at a time const auto rsx = rsx::get_current_renderer(); if (!rsx) { break; } const auto base = rsx->dma_address; if (!base) { break; } const QString branch_name = "RSX Context 0x55555555"; QTreeWidgetItem* rsx_tree = add_solid_node(rsx_context_node, branch_name, branch_name + qstr(fmt::format(u8", Local Size: %u MB, Base Addr: 0x%x, Device Addr: 0x%x, Handlers: 0x%x", rsx->local_mem_size >> 20, base, rsx->device_addr, +vm::_ref(rsx->driver_info).handlers))); QTreeWidgetItem* io_tree = add_volatile_node(rsx_tree, tr("IO-EA Table")); QTreeWidgetItem* zc_tree = add_volatile_node(rsx_tree, tr("Zcull Bindings")); QTreeWidgetItem* db_tree = add_volatile_node(rsx_tree, tr("Display Buffers")); decltype(rsx->iomap_table) table; decltype(rsx->display_buffers) dbs; decltype(rsx->zculls) zcs; { reader_lock lock(rsx->sys_rsx_mtx); std::memcpy(&table, &rsx->iomap_table, sizeof(table)); std::memcpy(&dbs, rsx->display_buffers, sizeof(dbs)); std::memcpy(&zcs, &rsx->zculls, sizeof(zcs)); } for (u32 i = 0, size_block = 0, first_ea = 0, first_io = 0;;) { const auto addr = table.get_addr(i << 20); if (addr == umax) { if (size_block) { // Print block add_leaf(io_tree, qstr(fmt::format("IO: %08x, EA: %08x, Size: %uMB", first_io, first_ea, size_block))); } if (i >= 512u) { break; } size_block = 0; i++; continue; } const auto old_block_size = size_block++; i++; if (old_block_size) { if (first_ea + (old_block_size << 20) == addr) { continue; } else { // Print last block before we continue to a new one add_leaf(io_tree, qstr(fmt::format("IO: %08x, EA: %08x, Size: %uMB", first_io, first_ea, old_block_size))); size_block = 1; first_ea = addr; first_io = (i - 1) << 20; continue; } } else { first_ea = addr; first_io = (i - 1) << 20; } } for (const auto& zc : zcs) { if (zc.bound) { add_leaf(zc_tree, qstr(fmt::format("O: %07x, W: %u, H: %u, Zformat: 0x%x, AAformat: 0x%x, Dir: 0x%x, sFunc: 0x%x, sRef: %02x, sMask: %02x" , zc.offset, zc.height, zc.width, zc.zFormat, zc.aaFormat, zc.zcullDir, zc.sFunc, zc.sRef, zc.sMask))); } } for (const auto& db : dbs) { if (db.valid()) { add_leaf(db_tree, qstr(fmt::format("Offset: %07x, Width: %u, Height: %u, Pitch: %u" , db.offset, db.height, db.width, db.pitch))); } } } while (false); idm::select([&](u32 id, lv2_fs_object& fo) { const std::string str = fmt::format("FD %u: %s", id, [&]() -> std::string { if (idm::check_unlocked(id)) { return fmt::format("%s", static_cast(fo)); } if (idm::check_unlocked(id)) { return fmt::format("%s", static_cast(fo)); } return "Unknown object!"; }()); add_leaf(find_node(root, additional_nodes::file_descriptors), qstr(str)); }); std::function final_touches; final_touches = [&final_touches](QTreeWidgetItem* item) -> int { int visible_children = 0; for (int i = 0; i < item->childCount(); i++) { auto node = item->child(i); if (!node) { continue; } switch (const int type = node->data(0, kernel_item_role::type_role).toInt()) { case kernel_item_type::leaf: { node->setHidden(false); break; } case kernel_item_type::node: case kernel_item_type::solid_node: case kernel_item_type::volatile_node: { const int count = final_touches(node); if (count > 0) { // Append count node->setText(0, node->text(0) + qstr(fmt::format(" (%zu)", count))); // Expand if necessary node->setExpanded(node->data(0, kernel_item_role::expanded_role).toBool()); } // Hide node if it has no children node->setHidden(type != kernel_item_type::solid_node && count <= 0); break; } case kernel_item_type::root: default: { break; } } if (!node->isHidden()) { visible_children++; } } return visible_children; }; final_touches(root); root->setExpanded(true); } void kernel_explorer::log(u32 level, QTreeWidgetItem* item) { if (!item) { item = m_tree->topLevelItem(0); if (!item) { return; } m_log_buf = qstr(fmt::format("Kernel Explorer: %s\n", Emu.GetTitleAndTitleID())); log(level + 1, item); sys_log.success("%s", m_log_buf); return; } for (u32 j = 0; j < level; j++) { m_log_buf += QChar::Space; } m_log_buf.append(item->text(0)); m_log_buf += '\n'; for (int i = 0; i < item->childCount(); i++) { if (auto node = item->child(i); node && !node->isHidden()) { log(level + 1, node); } } }