#include "stdafx.h" #include "Emu/Memory/Memory.h" #include "Emu/System.h" #include "Emu/SysCalls/Modules.h" #include "Emu/SysCalls/CB_FUNC.h" #include "Emu/Memory/atomic_type.h" #include "Emu/Cell/SPUThread.h" #include "Emu/SysCalls/lv2/sleep_queue_type.h" #include "Emu/SysCalls/lv2/sys_lwmutex.h" #include "Emu/SysCalls/lv2/sys_lwcond.h" #include "Emu/SysCalls/lv2/sys_spu.h" #include "Emu/SysCalls/lv2/sys_ppu_thread.h" #include "Emu/SysCalls/lv2/sys_memory.h" #include "Emu/SysCalls/lv2/sys_process.h" #include "Emu/SysCalls/lv2/sys_semaphore.h" #include "Emu/SysCalls/lv2/sys_event.h" #include "Emu/Cell/SPURSManager.h" #include "sysPrxForUser.h" #include "cellSpurs.h" Module *cellSpurs = nullptr; #ifdef PRX_DEBUG extern u32 libsre; extern u32 libsre_rtoc; #endif void spursKernelMain(SPUThread & spu); s64 cellSpursLookUpTasksetAddress(vm::ptr spurs, vm::ptr taskset, u32 id); s64 _cellSpursSendSignal(vm::ptr taskset, u32 taskID); s64 spursCreateLv2EventQueue(vm::ptr spurs, u32& queue_id, vm::ptr port, s32 size, u64 name_u64) { #ifdef PRX_DEBUG_XXX vm::var> queue; s32 res = cb_call, vm::ptr, vm::ptr, s32, u32>(GetCurrentPPUThread(), libsre + 0xB14C, libsre_rtoc, spurs, queue, port, size, vm::read32(libsre_rtoc - 0x7E2C)); queue_id = queue; return res; #endif queue_id = event_queue_create(SYS_SYNC_FIFO, SYS_PPU_QUEUE, name_u64, 0, size); if (!queue_id) { return CELL_EAGAIN; // rough } if (s32 res = (s32)spursAttachLv2EventQueue(spurs, queue_id, port, 1, true)) { assert(!"spursAttachLv2EventQueue() failed"); } return CELL_OK; } s64 spursInit( vm::ptr spurs, const u32 revision, const u32 sdkVersion, const s32 nSpus, const s32 spuPriority, const s32 ppuPriority, u32 flags, // SpursAttrFlags const char prefix[], const u32 prefixSize, const u32 container, const u8 swlPriority[], const u32 swlMaxSpu, const u32 swlIsPreem) { #ifdef PRX_DEBUG_XXX return cb_call, u32, u32, s32, s32, s32, u32, u32, u32, u32, u32, u32, u32>(GetCurrentPPUThread(), libsre + 0x74E4, libsre_rtoc, spurs, revision, sdkVersion, nSpus, spuPriority, ppuPriority, flags, vm::get_addr(prefix), prefixSize, container, vm::get_addr(swlPriority), swlMaxSpu, swlIsPreem); #endif // SPURS initialization (asserts should actually rollback and return the error instead) if (!spurs) { return CELL_SPURS_CORE_ERROR_NULL_POINTER; } if (spurs.addr() % 128) { return CELL_SPURS_CORE_ERROR_ALIGN; } if (prefixSize > CELL_SPURS_NAME_MAX_LENGTH) { return CELL_SPURS_CORE_ERROR_INVAL; } if (process_is_spu_lock_line_reservation_address(spurs.addr(), SYS_MEMORY_ACCESS_RIGHT_SPU_THR) != CELL_OK) { return CELL_SPURS_CORE_ERROR_PERM; } const bool isSecond = (flags & SAF_SECOND_VERSION) != 0; memset(spurs.get_ptr(), 0, CellSpurs::size1 + isSecond * CellSpurs::size2); spurs->m.revision = revision; spurs->m.sdkVersion = sdkVersion; spurs->m.ppu0 = 0xffffffffull; spurs->m.ppu1 = 0xffffffffull; spurs->m.flags = flags; memcpy(spurs->m.prefix, prefix, prefixSize); spurs->m.prefixSize = (u8)prefixSize; std::string name(prefix, prefixSize); // initialize name string if (!isSecond) { spurs->m.wklMskA.write_relaxed(be_t::make(0xffff)); } spurs->m.xCC = 0; spurs->m.xCD = 0; spurs->m.sysSrvMsgUpdateTrace = 0; for (u32 i = 0; i < 8; i++) { spurs->m.sysSrvWorkload[i] = -1; } // default or system workload: #ifdef PRX_DEBUG spurs->m.wklInfoSysSrv.addr.set(be_t::make(vm::read32(libsre_rtoc - 0x7EA4))); spurs->m.wklInfoSysSrv.size = 0x2200; #else spurs->m.wklInfoSysSrv.addr.set(be_t::make(SPURS_IMG_ADDR_SYS_SRV_WORKLOAD)); #endif spurs->m.wklInfoSysSrv.arg = 0; spurs->m.wklInfoSysSrv.uniqueId.write_relaxed(0xff); u32 sem; for (u32 i = 0; i < 0x10; i++) { sem = semaphore_create(0, 1, SYS_SYNC_PRIORITY, *(u64*)"_spuWkl"); assert(sem && ~sem); // should rollback if semaphore creation failed and return the error spurs->m.wklF1[i].sem = sem; } if (isSecond) { for (u32 i = 0; i < 0x10; i++) { sem = semaphore_create(0, 1, SYS_SYNC_PRIORITY, *(u64*)"_spuWkl"); assert(sem && ~sem); spurs->m.wklF2[i].sem = sem; } } sem = semaphore_create(0, 1, SYS_SYNC_PRIORITY, *(u64*)"_spuPrv"); assert(sem && ~sem); spurs->m.semPrv = sem; spurs->m.unk11 = -1; spurs->m.unk12 = -1; spurs->m.unk13 = 0; spurs->m.nSpus = nSpus; spurs->m.spuPriority = spuPriority; #ifdef PRX_DEBUG if (s32 res = spu_image_import(spurs->m.spuImg, vm::read32(libsre_rtoc - (isSecond ? 0x7E94 : 0x7E98)), 1)) { assert(!"spu_image_import() failed"); } #else spurs->m.spuImg.addr = (u32)Memory.Alloc(0x40000, 4096); #endif s32 tgt = SYS_SPU_THREAD_GROUP_TYPE_NORMAL; if (flags & SAF_SPU_TGT_EXCLUSIVE_NON_CONTEXT) { tgt = SYS_SPU_THREAD_GROUP_TYPE_EXCLUSIVE_NON_CONTEXT; } else if (flags & SAF_UNKNOWN_FLAG_0) { tgt = 0xC02; } if (flags & SAF_SPU_MEMORY_CONTAINER_SET) tgt |= SYS_SPU_THREAD_GROUP_TYPE_MEMORY_FROM_CONTAINER; if (flags & SAF_SYSTEM_WORKLOAD_ENABLED) tgt |= SYS_SPU_THREAD_GROUP_TYPE_COOPERATE_WITH_SYSTEM; if (flags & SAF_UNKNOWN_FLAG_7) tgt |= 0x102; if (flags & SAF_UNKNOWN_FLAG_8) tgt |= 0xC02; if (flags & SAF_UNKNOWN_FLAG_9) tgt |= 0x800; auto tg = spu_thread_group_create(name + "CellSpursKernelGroup", nSpus, spuPriority, tgt, container); assert(tg); spurs->m.spuTG = tg->m_id; name += "CellSpursKernel0"; for (s32 num = 0; num < nSpus; num++, name[name.size() - 1]++) { spurs->m.spus[num] = spu_thread_initialize(tg, num, spurs->m.spuImg, name, SYS_SPU_THREAD_OPTION_DEC_SYNC_TB_ENABLE, 0, 0, 0, 0, [spurs, num](SPUThread& SPU) { SPU.GPR[3]._u32[3] = num; SPU.GPR[4]._u64[1] = spurs.addr(); #ifdef PRX_DEBUG_XXX return SPU.FastCall(SPU.PC); #endif spursKernelMain(SPU); })->GetId(); } if (flags & SAF_SPU_PRINTF_ENABLED) { // spu_printf: attach group if (!spu_printf_agcb || spu_printf_agcb(tg->m_id) != CELL_OK) { // remove flag if failed spurs->m.flags &= ~SAF_SPU_PRINTF_ENABLED; } } if (s32 res = lwmutex_create(spurs->m.mutex, SYS_SYNC_PRIORITY, SYS_SYNC_NOT_RECURSIVE, *(u64*)"_spuPrv")) { assert(!"lwmutex_create() failed"); } if (s32 res = lwcond_create(spurs->m.cond, spurs->m.mutex, *(u64*)"_spuPrv")) { assert(!"lwcond_create() failed"); } spurs->m.flags1 = (flags & SAF_EXIT_IF_NO_WORK ? SF1_EXIT_IF_NO_WORK : 0) | (isSecond ? SF1_32_WORKLOADS : 0); spurs->m.wklFlagReceiver.write_relaxed(0xff); spurs->m.wklFlag.flag.write_relaxed(be_t::make(-1)); spurs->_u8[0xD64] = 0; spurs->_u8[0xD65] = 0; spurs->_u8[0xD66] = 0; spurs->m.ppuPriority = ppuPriority; u32 queue; if (s32 res = (s32)spursCreateLv2EventQueue(spurs, queue, vm::ptr::make(spurs.addr() + 0xc9), 0x2a, *(u64*)"_spuPrv")) { assert(!"spursCreateLv2EventQueue() failed"); } spurs->m.queue = queue; u32 port = event_port_create(0); assert(port && ~port); spurs->m.port = port; if (s32 res = sys_event_port_connect_local(port, queue)) { assert(!"sys_event_port_connect_local() failed"); } name = std::string(prefix, prefixSize); spurs->m.ppu0 = ppu_thread_create(0, 0, ppuPriority, 0x4000, true, false, name + "SpursHdlr0", [spurs](PPUThread& CPU) { #ifdef PRX_DEBUG_XXX return cb_call>(CPU, libsre + 0x9214, libsre_rtoc, spurs); #endif if (spurs->m.flags & SAF_UNKNOWN_FLAG_30) { return; } while (true) { if (Emu.IsStopped()) { cellSpurs->Warning("SPURS Handler Thread 0 aborted"); return; } if (spurs->m.flags1 & SF1_EXIT_IF_NO_WORK) { if (s32 res = sys_lwmutex_lock(CPU, spurs->get_lwmutex(), 0)) { assert(!"sys_lwmutex_lock() failed"); } if (spurs->m.xD66.read_relaxed()) { if (s32 res = sys_lwmutex_unlock(CPU, spurs->get_lwmutex())) { assert(!"sys_lwmutex_unlock() failed"); } return; } else while (true) { if (Emu.IsStopped()) break; spurs->m.xD64.exchange(0); if (spurs->m.exception.data() == 0) { bool do_break = false; for (u32 i = 0; i < 16; i++) { if (spurs->m.wklState1[i].read_relaxed() == 2 && *((u64 *)spurs->m.wklInfo1[i].priority) != 0 && spurs->m.wklMaxContention[i].read_relaxed() & 0xf ) { if (spurs->m.wklReadyCount1[i].read_relaxed() || spurs->m.wklSignal1.read_relaxed() & (0x8000u >> i) || (spurs->m.wklFlag.flag.read_relaxed() == 0 && spurs->m.wklFlagReceiver.read_relaxed() == (u8)i )) { do_break = true; break; } } } if (spurs->m.flags1 & SF1_32_WORKLOADS) for (u32 i = 0; i < 16; i++) { if (spurs->m.wklState2[i].read_relaxed() == 2 && *((u64 *)spurs->m.wklInfo2[i].priority) != 0 && spurs->m.wklMaxContention[i].read_relaxed() & 0xf0 ) { if (spurs->m.wklIdleSpuCountOrReadyCount2[i].read_relaxed() || spurs->m.wklSignal2.read_relaxed() & (0x8000u >> i) || (spurs->m.wklFlag.flag.read_relaxed() == 0 && spurs->m.wklFlagReceiver.read_relaxed() == (u8)i + 0x10 )) { do_break = true; break; } } } if (do_break) break; // from while } spurs->m.xD65.exchange(1); if (spurs->m.xD64.read_relaxed() == 0) { if (s32 res = sys_lwcond_wait(CPU, spurs->get_lwcond(), 0)) { assert(!"sys_lwcond_wait() failed"); } } spurs->m.xD65.exchange(0); if (spurs->m.xD66.read_relaxed()) { if (s32 res = sys_lwmutex_unlock(CPU, spurs->get_lwmutex())) { assert(!"sys_lwmutex_unlock() failed"); } return; } } if (Emu.IsStopped()) continue; if (s32 res = sys_lwmutex_unlock(CPU, spurs->get_lwmutex())) { assert(!"sys_lwmutex_unlock() failed"); } } if (Emu.IsStopped()) continue; if (s32 res = sys_spu_thread_group_start(spurs->m.spuTG)) { assert(!"sys_spu_thread_group_start() failed"); } if (s32 res = sys_spu_thread_group_join(spurs->m.spuTG, vm::ptr::make(0), vm::ptr::make(0))) { if (res == CELL_ESTAT) { return; } assert(!"sys_spu_thread_group_join() failed"); } if (Emu.IsStopped()) continue; if ((spurs->m.flags1 & SF1_EXIT_IF_NO_WORK) == 0) { assert(spurs->m.xD66.read_relaxed() == 1 || Emu.IsStopped()); return; } } })->GetId(); spurs->m.ppu1 = ppu_thread_create(0, 0, ppuPriority, 0x8000, true, false, name + "SpursHdlr1", [spurs](PPUThread& CPU) { #ifdef PRX_DEBUG return cb_call>(CPU, libsre + 0xB40C, libsre_rtoc, spurs); #endif })->GetId(); // enable exception event handler if (spurs->m.enableEH.compare_and_swap_test(be_t::make(0), be_t::make(1))) { if (s32 res = sys_spu_thread_group_connect_event(spurs->m.spuTG, spurs->m.queue, SYS_SPU_THREAD_GROUP_EVENT_EXCEPTION)) { assert(!"sys_spu_thread_group_connect_event() failed"); } } spurs->m.traceBuffer.set(0); // can also use cellLibprof if available (omitted) // some unknown subroutine spurs->m.sub3.unk1 = spurs.addr() + 0xc9; spurs->m.sub3.unk2 = 3; // unknown const spurs->m.sub3.port = (u64)spurs->m.port; if (flags & SAF_SYSTEM_WORKLOAD_ENABLED) // initialize system workload { s32 res = CELL_OK; #ifdef PRX_DEBUG res = cb_call, u32, u32, u32>(GetCurrentPPUThread(), libsre + 0x10428, libsre_rtoc, spurs, vm::get_addr(swlPriority), swlMaxSpu, swlIsPreem); #endif assert(res == CELL_OK); } else if (flags & SAF_EXIT_IF_NO_WORK) // wakeup { return spursWakeUp(GetCurrentPPUThread(), spurs); } return CELL_OK; } s64 cellSpursInitialize(vm::ptr spurs, s32 nSpus, s32 spuPriority, s32 ppuPriority, bool exitIfNoWork) { cellSpurs->Warning("cellSpursInitialize(spurs_addr=0x%x, nSpus=%d, spuPriority=%d, ppuPriority=%d, exitIfNoWork=%d)", spurs.addr(), nSpus, spuPriority, ppuPriority, exitIfNoWork ? 1 : 0); #ifdef PRX_DEBUG_XXX return GetCurrentPPUThread().FastCall2(libsre + 0x8480, libsre_rtoc); #endif return spursInit( spurs, 0, 0, nSpus, spuPriority, ppuPriority, exitIfNoWork ? SAF_EXIT_IF_NO_WORK : SAF_NONE, nullptr, 0, 0, nullptr, 0, 0); } s64 cellSpursInitializeWithAttribute(vm::ptr spurs, vm::ptr attr) { cellSpurs->Warning("cellSpursInitializeWithAttribute(spurs_addr=0x%x, attr_addr=0x%x)", spurs.addr(), attr.addr()); #ifdef PRX_DEBUG_XXX return GetCurrentPPUThread().FastCall2(libsre + 0x839C, libsre_rtoc); #endif if (!attr) { return CELL_SPURS_CORE_ERROR_NULL_POINTER; } if (attr.addr() % 8) { return CELL_SPURS_CORE_ERROR_ALIGN; } if (attr->m.revision > 2) { return CELL_SPURS_CORE_ERROR_INVAL; } return spursInit( spurs, attr->m.revision, attr->m.sdkVersion, attr->m.nSpus, attr->m.spuPriority, attr->m.ppuPriority, attr->m.flags | (attr->m.exitIfNoWork ? SAF_EXIT_IF_NO_WORK : 0), attr->m.prefix, attr->m.prefixSize, attr->m.container, attr->m.swlPriority, attr->m.swlMaxSpu, attr->m.swlIsPreem); } s64 cellSpursInitializeWithAttribute2(vm::ptr spurs, vm::ptr attr) { cellSpurs->Warning("cellSpursInitializeWithAttribute2(spurs_addr=0x%x, attr_addr=0x%x)", spurs.addr(), attr.addr()); #ifdef PRX_DEBUG_XXX return GetCurrentPPUThread().FastCall2(libsre + 0x82B4, libsre_rtoc); #endif if (!attr) { return CELL_SPURS_CORE_ERROR_NULL_POINTER; } if (attr.addr() % 8) { return CELL_SPURS_CORE_ERROR_ALIGN; } if (attr->m.revision > 2) { return CELL_SPURS_CORE_ERROR_INVAL; } return spursInit( spurs, attr->m.revision, attr->m.sdkVersion, attr->m.nSpus, attr->m.spuPriority, attr->m.ppuPriority, attr->m.flags | (attr->m.exitIfNoWork ? SAF_EXIT_IF_NO_WORK : 0) | SAF_SECOND_VERSION, attr->m.prefix, attr->m.prefixSize, attr->m.container, attr->m.swlPriority, attr->m.swlMaxSpu, attr->m.swlIsPreem); } s64 _cellSpursAttributeInitialize(vm::ptr attr, u32 revision, u32 sdkVersion, u32 nSpus, s32 spuPriority, s32 ppuPriority, bool exitIfNoWork) { cellSpurs->Warning("_cellSpursAttributeInitialize(attr_addr=0x%x, revision=%d, sdkVersion=0x%x, nSpus=%d, spuPriority=%d, ppuPriority=%d, exitIfNoWork=%d)", attr.addr(), revision, sdkVersion, nSpus, spuPriority, ppuPriority, exitIfNoWork ? 1 : 0); #ifdef PRX_DEBUG_XXX return GetCurrentPPUThread().FastCall2(libsre + 0x72CC, libsre_rtoc); #endif if (!attr) { return CELL_SPURS_CORE_ERROR_NULL_POINTER; } if (attr.addr() % 8) { return CELL_SPURS_CORE_ERROR_ALIGN; } memset(attr.get_ptr(), 0, attr->size); attr->m.revision = revision; attr->m.sdkVersion = sdkVersion; attr->m.nSpus = nSpus; attr->m.spuPriority = spuPriority; attr->m.ppuPriority = ppuPriority; attr->m.exitIfNoWork = exitIfNoWork; return CELL_OK; } s64 cellSpursAttributeSetMemoryContainerForSpuThread(vm::ptr attr, u32 container) { cellSpurs->Warning("cellSpursAttributeSetMemoryContainerForSpuThread(attr_addr=0x%x, container=%d)", attr.addr(), container); #ifdef PRX_DEBUG_XXX return GetCurrentPPUThread().FastCall2(libsre + 0x6FF8, libsre_rtoc); #endif if (!attr) { return CELL_SPURS_CORE_ERROR_NULL_POINTER; } if (attr.addr() % 8) { return CELL_SPURS_CORE_ERROR_ALIGN; } if (attr->m.flags & SAF_SPU_TGT_EXCLUSIVE_NON_CONTEXT) { return CELL_SPURS_CORE_ERROR_STAT; } attr->m.container = container; attr->m.flags |= SAF_SPU_MEMORY_CONTAINER_SET; return CELL_OK; } s64 cellSpursAttributeSetNamePrefix(vm::ptr attr, vm::ptr prefix, u32 size) { cellSpurs->Warning("cellSpursAttributeSetNamePrefix(attr_addr=0x%x, prefix_addr=0x%x, size=%d)", attr.addr(), prefix.addr(), size); #ifdef PRX_DEBUG_XXX return GetCurrentPPUThread().FastCall2(libsre + 0x7234, libsre_rtoc); #endif if (!attr || !prefix) { return CELL_SPURS_CORE_ERROR_NULL_POINTER; } if (attr.addr() % 8) { return CELL_SPURS_CORE_ERROR_ALIGN; } if (size > CELL_SPURS_NAME_MAX_LENGTH) { return CELL_SPURS_CORE_ERROR_INVAL; } memcpy(attr->m.prefix, prefix.get_ptr(), size); attr->m.prefixSize = size; return CELL_OK; } s64 cellSpursAttributeEnableSpuPrintfIfAvailable(vm::ptr attr) { cellSpurs->Warning("cellSpursAttributeEnableSpuPrintfIfAvailable(attr_addr=0x%x)", attr.addr()); #ifdef PRX_DEBUG_XXX return GetCurrentPPUThread().FastCall2(libsre + 0x7150, libsre_rtoc); #endif if (!attr) { return CELL_SPURS_CORE_ERROR_NULL_POINTER; } if (attr.addr() % 8) { return CELL_SPURS_CORE_ERROR_ALIGN; } attr->m.flags |= SAF_SPU_PRINTF_ENABLED; return CELL_OK; } s64 cellSpursAttributeSetSpuThreadGroupType(vm::ptr attr, s32 type) { cellSpurs->Warning("cellSpursAttributeSetSpuThreadGroupType(attr_addr=0x%x, type=%d)", attr.addr(), type); #ifdef PRX_DEBUG_XXX return GetCurrentPPUThread().FastCall2(libsre + 0x70C8, libsre_rtoc); #endif if (!attr) { return CELL_SPURS_CORE_ERROR_NULL_POINTER; } if (attr.addr() % 8) { return CELL_SPURS_CORE_ERROR_ALIGN; } if (type == SYS_SPU_THREAD_GROUP_TYPE_EXCLUSIVE_NON_CONTEXT) { if (attr->m.flags & SAF_SPU_MEMORY_CONTAINER_SET) { return CELL_SPURS_CORE_ERROR_STAT; } attr->m.flags |= SAF_SPU_TGT_EXCLUSIVE_NON_CONTEXT; // set } else if (type == SYS_SPU_THREAD_GROUP_TYPE_NORMAL) { attr->m.flags &= ~SAF_SPU_TGT_EXCLUSIVE_NON_CONTEXT; // clear } else { return CELL_SPURS_CORE_ERROR_INVAL; } return CELL_OK; } s64 cellSpursAttributeEnableSystemWorkload(vm::ptr attr, vm::ptr priority, u32 maxSpu, vm::ptr isPreemptible) { cellSpurs->Warning("cellSpursAttributeEnableSystemWorkload(attr_addr=0x%x, priority_addr=0x%x, maxSpu=%d, isPreemptible_addr=0x%x)", attr.addr(), priority.addr(), maxSpu, isPreemptible.addr()); #ifdef PRX_DEBUG_XXX return GetCurrentPPUThread().FastCall2(libsre + 0xF410, libsre_rtoc); #endif if (!attr) { return CELL_SPURS_CORE_ERROR_NULL_POINTER; } if (attr.addr() % 8) { return CELL_SPURS_CORE_ERROR_ALIGN; } const u32 nSpus = attr->_u32[2]; if (!nSpus) { return CELL_SPURS_CORE_ERROR_INVAL; } for (u32 i = 0; i < nSpus; i++) { if ((*priority)[i] == 1) { if (!maxSpu) { return CELL_SPURS_CORE_ERROR_INVAL; } if (nSpus == 1 || attr->m.exitIfNoWork) { return CELL_SPURS_CORE_ERROR_PERM; } if (attr->m.flags & SAF_SYSTEM_WORKLOAD_ENABLED) { return CELL_SPURS_CORE_ERROR_BUSY; } attr->m.flags |= SAF_SYSTEM_WORKLOAD_ENABLED; // set flag *(u64*)attr->m.swlPriority = *(u64*)*priority; // copy system workload priorities u32 isPreem = 0; // generate mask from isPreemptible values for (u32 j = 0; j < nSpus; j++) { if ((*isPreemptible)[j]) { isPreem |= (1 << j); } } attr->m.swlMaxSpu = maxSpu; // write max spu for system workload attr->m.swlIsPreem = isPreem; // write isPreemptible mask return CELL_OK; } } return CELL_SPURS_CORE_ERROR_INVAL; } s64 cellSpursFinalize(vm::ptr spurs) { cellSpurs->Todo("cellSpursFinalize(spurs_addr=0x%x)", spurs.addr()); #ifdef PRX_DEBUG_XXX return GetCurrentPPUThread().FastCall2(libsre + 0x8568, libsre_rtoc); #endif if (!spurs) { return CELL_SPURS_CORE_ERROR_NULL_POINTER; } if (spurs.addr() % 128) { return CELL_SPURS_CORE_ERROR_ALIGN; } if (spurs->m.xD66.read_relaxed()) { return CELL_SPURS_CORE_ERROR_STAT; } return CELL_OK; } s64 spursAttachLv2EventQueue(vm::ptr spurs, u32 queue, vm::ptr port, s32 isDynamic, bool wasCreated) { #ifdef PRX_DEBUG_XXX return cb_call, u32, vm::ptr, s32, bool>(GetCurrentPPUThread(), libsre + 0xAE34, libsre_rtoc, spurs, queue, port, isDynamic, wasCreated); #endif if (!spurs || !port) { return CELL_SPURS_CORE_ERROR_NULL_POINTER; } if (spurs.addr() % 128) { return CELL_SPURS_CORE_ERROR_ALIGN; } if (spurs->m.exception.data()) { return CELL_SPURS_CORE_ERROR_STAT; } s32 sdk_ver; if (s32 res = process_get_sdk_version(process_getpid(), sdk_ver)) { assert(!"process_get_sdk_version() failed"); } if (sdk_ver == -1) sdk_ver = 0x460000; u8 _port = 0x3f; u64 port_mask = 0; if (isDynamic == 0) { _port = *port; if (_port > 0x3f) { return CELL_SPURS_CORE_ERROR_INVAL; } if (sdk_ver > 0x17ffff && _port > 0xf) { return CELL_SPURS_CORE_ERROR_PERM; } } for (u32 i = isDynamic ? 0x10 : _port; i <= _port; i++) { port_mask |= 1ull << (i); } assert(port_mask); // zero mask will return CELL_EINVAL if (s32 res = sys_spu_thread_group_connect_event_all_threads(spurs->m.spuTG, queue, port_mask, port)) { if (res == CELL_EISCONN) { return CELL_SPURS_CORE_ERROR_BUSY; } return res; } if (!wasCreated) { spurs->m.spups |= be_t::make(1ull << *port); // atomic bitwise or } return CELL_OK; } s64 cellSpursAttachLv2EventQueue(vm::ptr spurs, u32 queue, vm::ptr port, s32 isDynamic) { cellSpurs->Warning("cellSpursAttachLv2EventQueue(spurs_addr=0x%x, queue=%d, port_addr=0x%x, isDynamic=%d)", spurs.addr(), queue, port.addr(), isDynamic); #ifdef PRX_DEBUG_XXX return GetCurrentPPUThread().FastCall2(libsre + 0xAFE0, libsre_rtoc); #endif return spursAttachLv2EventQueue(spurs, queue, port, isDynamic, false); } s64 cellSpursDetachLv2EventQueue(vm::ptr spurs, u8 port) { #ifdef PRX_DEBUG cellSpurs->Warning("cellSpursDetachLv2EventQueue(spurs_addr=0x%x, port=%d)", spurs.addr(), port); return GetCurrentPPUThread().FastCall2(libsre + 0xB144, libsre_rtoc); #else UNIMPLEMENTED_FUNC(cellSpurs); return CELL_OK; #endif } s64 cellSpursGetSpuGuid() { #ifdef PRX_DEBUG cellSpurs->Warning("%s()", __FUNCTION__); return GetCurrentPPUThread().FastCall2(libsre + 0xEFB0, libsre_rtoc); #else UNIMPLEMENTED_FUNC(cellSpurs); return CELL_OK; #endif } s64 cellSpursGetSpuThreadGroupId(vm::ptr spurs, vm::ptr group) { cellSpurs->Warning("cellSpursGetSpuThreadGroupId(spurs_addr=0x%x, group_addr=0x%x)", spurs.addr(), group.addr()); #ifdef PRX_DEBUG_XXX return GetCurrentPPUThread().FastCall2(libsre + 0x8B30, libsre_rtoc); #endif if (!spurs || !group) { return CELL_SPURS_CORE_ERROR_NULL_POINTER; } if (spurs.addr() % 128) { return CELL_SPURS_CORE_ERROR_ALIGN; } *group = spurs->m.spuTG; return CELL_OK; } s64 cellSpursGetNumSpuThread(vm::ptr spurs, vm::ptr nThreads) { cellSpurs->Warning("cellSpursGetNumSpuThread(spurs_addr=0x%x, nThreads_addr=0x%x)", spurs.addr(), nThreads.addr()); #ifdef PRX_DEBUG_XXX return GetCurrentPPUThread().FastCall2(libsre + 0x8B78, libsre_rtoc); #endif if (!spurs || !nThreads) { return CELL_SPURS_CORE_ERROR_NULL_POINTER; } if (spurs.addr() % 128) { return CELL_SPURS_CORE_ERROR_ALIGN; } *nThreads = (u32)spurs->m.nSpus; return CELL_OK; } s64 cellSpursGetSpuThreadId(vm::ptr spurs, vm::ptr thread, vm::ptr nThreads) { cellSpurs->Warning("cellSpursGetSpuThreadId(spurs_addr=0x%x, thread_addr=0x%x, nThreads_addr=0x%x)", spurs.addr(), thread.addr(), nThreads.addr()); #ifdef PRX_DEBUG_XXX return GetCurrentPPUThread().FastCall2(libsre + 0x8A98, libsre_rtoc); #endif if (!spurs || !thread || !nThreads) { return CELL_SPURS_CORE_ERROR_NULL_POINTER; } if (spurs.addr() % 128) { return CELL_SPURS_CORE_ERROR_ALIGN; } const u32 count = std::min(*nThreads, spurs->m.nSpus); for (u32 i = 0; i < count; i++) { thread[i] = spurs->m.spus[i]; } *nThreads = count; return CELL_OK; } s64 cellSpursSetMaxContention(vm::ptr spurs, u32 workloadId, u32 maxContention) { #ifdef PRX_DEBUG cellSpurs->Warning("cellSpursSetMaxContention(spurs_addr=0x%x, workloadId=%d, maxContention=%d)", spurs.addr(), workloadId, maxContention); return GetCurrentPPUThread().FastCall2(libsre + 0x8E90, libsre_rtoc); #else UNIMPLEMENTED_FUNC(cellSpurs); return CELL_OK; #endif } s64 cellSpursSetPriorities(vm::ptr spurs, u32 workloadId, vm::ptr priorities) { #ifdef PRX_DEBUG cellSpurs->Warning("cellSpursSetPriorities(spurs_addr=0x%x, workloadId=%d, priorities_addr=0x%x)", spurs.addr(), workloadId, priorities.addr()); return GetCurrentPPUThread().FastCall2(libsre + 0x8BC0, libsre_rtoc); #else UNIMPLEMENTED_FUNC(cellSpurs); return CELL_OK; #endif } s64 cellSpursSetPreemptionVictimHints(vm::ptr spurs, vm::ptr isPreemptible) { #ifdef PRX_DEBUG cellSpurs->Warning("cellSpursSetPreemptionVictimHints(spurs_addr=0x%x, isPreemptible_addr=0x%x)", spurs.addr(), isPreemptible.addr()); return GetCurrentPPUThread().FastCall2(libsre + 0xF5A4, libsre_rtoc); #else UNIMPLEMENTED_FUNC(cellSpurs); return CELL_OK; #endif } s64 cellSpursEnableExceptionEventHandler(vm::ptr spurs, bool flag) { #ifdef PRX_DEBUG cellSpurs->Warning("cellSpursEnableExceptionEventHandler(spurs_addr=0x%x, flag=%d)", spurs.addr(), flag); return GetCurrentPPUThread().FastCall2(libsre + 0xDCC0, libsre_rtoc); #else UNIMPLEMENTED_FUNC(cellSpurs); return CELL_OK; #endif } s64 cellSpursSetGlobalExceptionEventHandler(vm::ptr spurs, u32 eaHandler_addr, u32 arg_addr) { #ifdef PRX_DEBUG cellSpurs->Warning("cellSpursSetGlobalExceptionEventHandler(spurs_addr=0x%x, eaHandler_addr=0x%x, arg_addr=0x%x)", spurs.addr(), eaHandler_addr, arg_addr); return GetCurrentPPUThread().FastCall2(libsre + 0xD6D0, libsre_rtoc); #else UNIMPLEMENTED_FUNC(cellSpurs); return CELL_OK; #endif } s64 cellSpursUnsetGlobalExceptionEventHandler(vm::ptr spurs) { #ifdef PRX_DEBUG cellSpurs->Warning("cellSpursUnsetGlobalExceptionEventHandler(spurs_addr=0x%x)", spurs.addr()); return GetCurrentPPUThread().FastCall2(libsre + 0xD674, libsre_rtoc); #else UNIMPLEMENTED_FUNC(cellSpurs); return CELL_OK; #endif } s64 cellSpursGetInfo(vm::ptr spurs, vm::ptr info) { #ifdef PRX_DEBUG cellSpurs->Warning("cellSpursGetInfo(spurs_addr=0x%x, info_addr=0x%x)", spurs.addr(), info.addr()); return GetCurrentPPUThread().FastCall2(libsre + 0xE540, libsre_rtoc); #else UNIMPLEMENTED_FUNC(cellSpurs); return CELL_OK; #endif } s64 spursWakeUp(PPUThread& CPU, vm::ptr spurs) { #ifdef PRX_DEBUG_XXX return cb_call>(GetCurrentPPUThread(), libsre + 0x84D8, libsre_rtoc, spurs); #endif if (!spurs) { return CELL_SPURS_POLICY_MODULE_ERROR_NULL_POINTER; } if (spurs.addr() % 128) { return CELL_SPURS_POLICY_MODULE_ERROR_ALIGN; } if (spurs->m.exception.data()) { return CELL_SPURS_POLICY_MODULE_ERROR_STAT; } spurs->m.xD64.exchange(1); if (spurs->m.xD65.read_sync()) { if (s32 res = sys_lwmutex_lock(CPU, spurs->get_lwmutex(), 0)) { assert(!"sys_lwmutex_lock() failed"); } if (s32 res = sys_lwcond_signal(spurs->get_lwcond())) { assert(!"sys_lwcond_signal() failed"); } if (s32 res = sys_lwmutex_unlock(CPU, spurs->get_lwmutex())) { assert(!"sys_lwmutex_unlock() failed"); } } return CELL_OK; } s64 cellSpursWakeUp(PPUThread& CPU, vm::ptr spurs) { cellSpurs->Warning("%s(spurs_addr=0x%x)", __FUNCTION__, spurs.addr()); return spursWakeUp(CPU, spurs); } s32 spursAddWorkload( vm::ptr spurs, vm::ptr wid, vm::ptr pm, u32 size, u64 data, const u8 priorityTable[], u32 minContention, u32 maxContention, vm::ptr nameClass, vm::ptr nameInstance, vm::ptr hook, vm::ptr hookArg) { #ifdef PRX_DEBUG_XXX return cb_call, vm::ptr, vm::ptr, u32, u64, u32, u32, u32, u32, u32, u32, u32>(GetCurrentPPUThread(), libsre + 0x96EC, libsre_rtoc, spurs, wid, pm, size, data, vm::get_addr(priorityTable), minContention, maxContention, nameClass.addr(), nameInstance.addr(), hook.addr(), hookArg.addr()); #endif if (!spurs || !wid || !pm) { return CELL_SPURS_POLICY_MODULE_ERROR_NULL_POINTER; } if (spurs.addr() % 128 || pm.addr() % 16) { return CELL_SPURS_POLICY_MODULE_ERROR_ALIGN; } if (minContention == 0 || *(u64*)priorityTable & 0xf0f0f0f0f0f0f0f0ull) // check if some priority > 15 { return CELL_SPURS_POLICY_MODULE_ERROR_INVAL; } if (spurs->m.exception.data()) { return CELL_SPURS_POLICY_MODULE_ERROR_STAT; } u32 wnum; const u32 wmax = spurs->m.flags1 & SF1_32_WORKLOADS ? 0x20u : 0x10u; // TODO: check if can be changed spurs->m.wklMskA.atomic_op([spurs, wmax, &wnum](be_t& value) { wnum = cntlz32(~(u32)value); // found empty position if (wnum < wmax) { value |= (u32)(0x80000000ull >> wnum); // set workload bit } }); *wid = wnum; // store workload id if (wnum >= wmax) { return CELL_SPURS_POLICY_MODULE_ERROR_AGAIN; } u32 index = wnum & 0xf; if (wnum <= 15) { assert((spurs->m.wklCurrentContention[wnum] & 0xf) == 0); assert((spurs->m.wklPendingContention[wnum] & 0xf) == 0); spurs->m.wklState1[wnum].write_relaxed(1); spurs->m.wklStatus1[wnum] = 0; spurs->m.wklEvent1[wnum] = 0; spurs->m.wklInfo1[wnum].addr = pm; spurs->m.wklInfo1[wnum].arg = data; spurs->m.wklInfo1[wnum].size = size; for (u32 i = 0; i < 8; i++) { spurs->m.wklInfo1[wnum].priority[i] = priorityTable[i]; } spurs->m.wklH1[wnum].nameClass = nameClass; spurs->m.wklH1[wnum].nameInstance = nameInstance; memset(spurs->m.wklF1[wnum].unk0, 0, 0x20); // clear struct preserving semaphore id memset(spurs->m.wklF1[wnum].unk1, 0, 0x58); if (hook) { spurs->m.wklF1[wnum].hook = hook; spurs->m.wklF1[wnum].hookArg = hookArg; spurs->m.wklEvent1[wnum] |= 2; } if ((spurs->m.flags1 & SF1_32_WORKLOADS) == 0) { spurs->m.wklIdleSpuCountOrReadyCount2[wnum].write_relaxed(0); spurs->m.wklMinContention[wnum] = minContention > 8 ? 8 : minContention; } spurs->m.wklReadyCount1[wnum].write_relaxed(0); } else { assert((spurs->m.wklCurrentContention[index] & 0xf0) == 0); assert((spurs->m.wklPendingContention[index] & 0xf0) == 0); spurs->m.wklState2[index].write_relaxed(1); spurs->m.wklStatus2[index] = 0; spurs->m.wklEvent2[index] = 0; spurs->m.wklInfo2[index].addr = pm; spurs->m.wklInfo2[index].arg = data; spurs->m.wklInfo2[index].size = size; for (u32 i = 0; i < 8; i++) { spurs->m.wklInfo2[index].priority[i] = priorityTable[i]; } spurs->m.wklH2[index].nameClass = nameClass; spurs->m.wklH2[index].nameInstance = nameInstance; memset(spurs->m.wklF2[index].unk0, 0, 0x20); // clear struct preserving semaphore id memset(spurs->m.wklF2[index].unk1, 0, 0x58); if (hook) { spurs->m.wklF2[index].hook = hook; spurs->m.wklF2[index].hookArg = hookArg; spurs->m.wklEvent2[index] |= 2; } spurs->m.wklIdleSpuCountOrReadyCount2[wnum].write_relaxed(0); } if (wnum <= 15) { spurs->m.wklMaxContention[wnum].atomic_op([maxContention](u8& v) { v &= ~0xf; v |= (maxContention > 8 ? 8 : maxContention); }); spurs->m.wklSignal1._and_not({ be_t::make(0x8000 >> index) }); // clear bit in wklFlag1 } else { spurs->m.wklMaxContention[index].atomic_op([maxContention](u8& v) { v &= ~0xf0; v |= (maxContention > 8 ? 8 : maxContention) << 4; }); spurs->m.wklSignal2._and_not({ be_t::make(0x8000 >> index) }); // clear bit in wklFlag2 } spurs->m.wklFlagReceiver.compare_and_swap(wnum, 0xff); u32 res_wkl; CellSpurs::WorkloadInfo& wkl = wnum <= 15 ? spurs->m.wklInfo1[wnum] : spurs->m.wklInfo2[wnum & 0xf]; spurs->m.wklMskB.atomic_op_sync([spurs, &wkl, wnum, &res_wkl](be_t& v) { const u32 mask = v & ~(0x80000000u >> wnum); res_wkl = 0; for (u32 i = 0, m = 0x80000000, k = 0; i < 32; i++, m >>= 1) { if (mask & m) { CellSpurs::WorkloadInfo& current = i <= 15 ? spurs->m.wklInfo1[i] : spurs->m.wklInfo2[i & 0xf]; if (current.addr.addr() == wkl.addr.addr()) { // if a workload with identical policy module found res_wkl = current.uniqueId.read_relaxed(); break; } else { k |= 0x80000000 >> current.uniqueId.read_relaxed(); res_wkl = cntlz32(~k); } } } wkl.uniqueId.exchange((u8)res_wkl); v = mask | (0x80000000u >> wnum); }); assert(res_wkl <= 31); spurs->wklState(wnum).exchange(2); spurs->m.sysSrvMsgUpdateWorkload.exchange(0xff); spurs->m.sysSrvMessage.exchange(0xff); return CELL_OK; } s64 cellSpursAddWorkload( vm::ptr spurs, vm::ptr wid, vm::ptr pm, u32 size, u64 data, vm::ptr priorityTable, u32 minContention, u32 maxContention) { cellSpurs->Warning("%s(spurs_addr=0x%x, wid_addr=0x%x, pm_addr=0x%x, size=0x%x, data=0x%llx, priorityTable_addr=0x%x, minContention=0x%x, maxContention=0x%x)", __FUNCTION__, spurs.addr(), wid.addr(), pm.addr(), size, data, priorityTable.addr(), minContention, maxContention); #ifdef PRX_DEBUG_XXX return GetCurrentPPUThread().FastCall2(libsre + 0x9ED0, libsre_rtoc); #endif return spursAddWorkload( spurs, wid, pm, size, data, *priorityTable, minContention, maxContention, vm::ptr::make(0), vm::ptr::make(0), vm::ptr::make(0), vm::ptr::make(0)); } s64 _cellSpursWorkloadAttributeInitialize( vm::ptr attr, u32 revision, u32 sdkVersion, vm::ptr pm, u32 size, u64 data, vm::ptr priorityTable, u32 minContention, u32 maxContention) { cellSpurs->Warning("%s(attr_addr=0x%x, revision=%d, sdkVersion=0x%x, pm_addr=0x%x, size=0x%x, data=0x%llx, priorityTable_addr=0x%x, minContention=0x%x, maxContention=0x%x)", __FUNCTION__, attr.addr(), revision, sdkVersion, pm.addr(), size, data, priorityTable.addr(), minContention, maxContention); #ifdef PRX_DEBUG_XXX return GetCurrentPPUThread().FastCall2(libsre + 0x9F08, libsre_rtoc); #endif if (!attr) { return CELL_SPURS_POLICY_MODULE_ERROR_NULL_POINTER; } if (attr.addr() % 8) { return CELL_SPURS_POLICY_MODULE_ERROR_ALIGN; } if (!pm) { return CELL_SPURS_POLICY_MODULE_ERROR_NULL_POINTER; } if (pm.addr() % 16) { return CELL_SPURS_POLICY_MODULE_ERROR_ALIGN; } if (minContention == 0 || *(u64*)*priorityTable & 0xf0f0f0f0f0f0f0f0ull) // check if some priority > 15 { return CELL_SPURS_POLICY_MODULE_ERROR_INVAL; } memset(attr.get_ptr(), 0, CellSpursWorkloadAttribute::size); attr->m.revision = revision; attr->m.sdkVersion = sdkVersion; attr->m.pm = pm; attr->m.size = size; attr->m.data = data; *(u64*)attr->m.priority = *(u64*)*priorityTable; attr->m.minContention = minContention; attr->m.maxContention = maxContention; return CELL_OK; } s64 cellSpursWorkloadAttributeSetName(vm::ptr attr, vm::ptr nameClass, vm::ptr nameInstance) { cellSpurs->Warning("%s(attr_addr=0x%x, nameClass_addr=0x%x, nameInstance_addr=0x%x)", __FUNCTION__, attr.addr(), nameClass.addr(), nameInstance.addr()); #ifdef PRX_DEBUG_XXX return GetCurrentPPUThread().FastCall2(libsre + 0x9664, libsre_rtoc); #endif if (!attr) { return CELL_SPURS_POLICY_MODULE_ERROR_NULL_POINTER; } if (attr.addr() % 8) { return CELL_SPURS_POLICY_MODULE_ERROR_ALIGN; } attr->m.nameClass = nameClass; attr->m.nameInstance = nameInstance; return CELL_OK; } s64 cellSpursWorkloadAttributeSetShutdownCompletionEventHook(vm::ptr attr, vm::ptr hook, vm::ptr arg) { cellSpurs->Warning("%s(attr_addr=0x%x, hook_addr=0x%x, arg=0x%x)", __FUNCTION__, attr.addr(), hook.addr(), arg.addr()); #ifdef PRX_DEBUG_XXX return GetCurrentPPUThread().FastCall2(libsre + 0x96A4, libsre_rtoc); #endif if (!attr || !hook) { return CELL_SPURS_POLICY_MODULE_ERROR_NULL_POINTER; } if (attr.addr() % 8) { return CELL_SPURS_POLICY_MODULE_ERROR_ALIGN; } attr->m.hook = hook; attr->m.hookArg = arg; return CELL_OK; } s64 cellSpursAddWorkloadWithAttribute(vm::ptr spurs, const vm::ptr wid, vm::ptr attr) { cellSpurs->Warning("%s(spurs_addr=0x%x, wid_addr=0x%x, attr_addr=0x%x)", __FUNCTION__, spurs.addr(), wid.addr(), attr.addr()); #ifdef PRX_DEBUG_XXX return GetCurrentPPUThread().FastCall2(libsre + 0x9E14, libsre_rtoc); #endif if (!attr) { return CELL_SPURS_POLICY_MODULE_ERROR_NULL_POINTER; } if (attr.addr() % 8) { return CELL_SPURS_POLICY_MODULE_ERROR_ALIGN; } if (attr->m.revision != be_t::make(1)) { return CELL_SPURS_POLICY_MODULE_ERROR_INVAL; } return spursAddWorkload( spurs, wid, vm::ptr::make(attr->m.pm.addr()), attr->m.size, attr->m.data, attr->m.priority, attr->m.minContention, attr->m.maxContention, vm::ptr::make(attr->m.nameClass.addr()), vm::ptr::make(attr->m.nameInstance.addr()), vm::ptr::make(attr->m.hook.addr()), vm::ptr::make(attr->m.hookArg.addr())); } s64 cellSpursRemoveWorkload() { #ifdef PRX_DEBUG cellSpurs->Warning("%s()", __FUNCTION__); return GetCurrentPPUThread().FastCall2(libsre + 0xA414, libsre_rtoc); #else UNIMPLEMENTED_FUNC(cellSpurs); return CELL_OK; #endif } s64 cellSpursWaitForWorkloadShutdown() { #ifdef PRX_DEBUG cellSpurs->Warning("%s()", __FUNCTION__); return GetCurrentPPUThread().FastCall2(libsre + 0xA20C, libsre_rtoc); #else UNIMPLEMENTED_FUNC(cellSpurs); return CELL_OK; #endif } s64 cellSpursShutdownWorkload() { #ifdef PRX_DEBUG cellSpurs->Warning("%s()", __FUNCTION__); return GetCurrentPPUThread().FastCall2(libsre + 0xA060, libsre_rtoc); #else UNIMPLEMENTED_FUNC(cellSpurs); return CELL_OK; #endif } s64 _cellSpursWorkloadFlagReceiver(vm::ptr spurs, u32 wid, u32 is_set) { cellSpurs->Warning("%s(spurs_addr=0x%x, wid=%d, is_set=%d)", __FUNCTION__, spurs.addr(), wid, is_set); #ifdef PRX_DEBUG_XXX return GetCurrentPPUThread().FastCall2(libsre + 0xF158, libsre_rtoc); #endif if (!spurs) { return CELL_SPURS_POLICY_MODULE_ERROR_NULL_POINTER; } if (spurs.addr() % 128) { return CELL_SPURS_POLICY_MODULE_ERROR_ALIGN; } if (wid >= (spurs->m.flags1 & SF1_32_WORKLOADS ? 0x20u : 0x10u)) { return CELL_SPURS_POLICY_MODULE_ERROR_INVAL; } if ((spurs->m.wklMskA.read_relaxed() & (0x80000000u >> wid)) == 0) { return CELL_SPURS_POLICY_MODULE_ERROR_SRCH; } if (spurs->m.exception.data()) { return CELL_SPURS_POLICY_MODULE_ERROR_STAT; } if (s32 res = spurs->m.wklFlag.flag.atomic_op_sync(0, [spurs, wid, is_set](be_t& flag) -> s32 { if (is_set) { if (spurs->m.wklFlagReceiver.read_relaxed() != 0xff) { return CELL_SPURS_POLICY_MODULE_ERROR_BUSY; } } else { if (spurs->m.wklFlagReceiver.read_relaxed() != wid) { return CELL_SPURS_POLICY_MODULE_ERROR_PERM; } } flag = -1; return 0; })) { return res; } spurs->m.wklFlagReceiver.atomic_op([wid, is_set](u8& FR) { if (is_set) { if (FR == 0xff) { FR = (u8)wid; } } else { if (FR == wid) { FR = 0xff; } } }); return CELL_OK; } s64 cellSpursGetWorkloadFlag(vm::ptr spurs, vm::ptr> flag) { cellSpurs->Warning("%s(spurs_addr=0x%x, flag_addr=0x%x)", __FUNCTION__, spurs.addr(), flag.addr()); #ifdef PRX_DEBUG_XXX return GetCurrentPPUThread().FastCall2(libsre + 0xEC00, libsre_rtoc); #endif if (!spurs || !flag) { return CELL_SPURS_POLICY_MODULE_ERROR_NULL_POINTER; } if (spurs.addr() % 128) { return CELL_SPURS_POLICY_MODULE_ERROR_ALIGN; } flag->set(vm::get_addr(&spurs->m.wklFlag)); return CELL_OK; } s64 cellSpursSendWorkloadSignal(vm::ptr spurs, u32 workloadId) { cellSpurs->Warning("%s(spurs=0x%x, workloadId=0x%x)", __FUNCTION__, spurs.addr(), workloadId); #ifdef PRX_DEBUG return GetCurrentPPUThread().FastCall2(libsre + 0xA658, libsre_rtoc); #else if (spurs.addr() == 0) { return CELL_SPURS_POLICY_MODULE_ERROR_NULL_POINTER; } if (spurs.addr() % CellSpurs::align) { return CELL_SPURS_POLICY_MODULE_ERROR_ALIGN; } if (workloadId >= CELL_SPURS_MAX_WORKLOAD2 || (workloadId >= CELL_SPURS_MAX_WORKLOAD && (spurs->m.flags1 & SF1_32_WORKLOADS) == 0)) { return CELL_SPURS_POLICY_MODULE_ERROR_INVAL; } if ((spurs->m.wklMskA.read_relaxed() & (0x80000000u >> workloadId)) == 0) { return CELL_SPURS_POLICY_MODULE_ERROR_SRCH; } if (spurs->m.exception) { return CELL_SPURS_POLICY_MODULE_ERROR_STAT; } u8 state; if (workloadId >= CELL_SPURS_MAX_WORKLOAD) { state = spurs->m.wklState2[workloadId & 0x0F].read_relaxed(); } else { state = spurs->m.wklState1[workloadId].read_relaxed(); } if (state != SPURS_WKL_STATE_RUNNABLE) { return CELL_SPURS_POLICY_MODULE_ERROR_STAT; } if (workloadId >= CELL_SPURS_MAX_WORKLOAD) { spurs->m.wklSignal2 |= be_t::make(0x8000 >> (workloadId & 0x0F)); } else { spurs->m.wklSignal1 |= be_t::make(0x8000 >> workloadId); } return CELL_OK; #endif } s64 cellSpursGetWorkloadData(vm::ptr spurs, vm::ptr data, u32 workloadId) { cellSpurs->Warning("%s(spurs_addr=0x%x, data=0x%x, workloadId=%d)", __FUNCTION__, spurs.addr(), data.addr(), workloadId); #ifdef PRX_DEBUG return GetCurrentPPUThread().FastCall2(libsre + 0xA78C, libsre_rtoc); #else if (spurs.addr() == 0 || data.addr() == 0) { return CELL_SPURS_POLICY_MODULE_ERROR_NULL_POINTER; } if (spurs.addr() % CellSpurs::align) { return CELL_SPURS_POLICY_MODULE_ERROR_ALIGN; } if (workloadId >= CELL_SPURS_MAX_WORKLOAD2 || (workloadId >= CELL_SPURS_MAX_WORKLOAD && (spurs->m.flags1 & SF1_32_WORKLOADS) == 0)) { return CELL_SPURS_POLICY_MODULE_ERROR_INVAL; } if ((spurs->m.wklMskA.read_relaxed() & (0x80000000u >> workloadId)) == 0) { return CELL_SPURS_POLICY_MODULE_ERROR_SRCH; } if (spurs->m.exception) { return CELL_SPURS_POLICY_MODULE_ERROR_STAT; } if (workloadId >= CELL_SPURS_MAX_WORKLOAD) { *data = spurs->m.wklInfo2[workloadId & 0x0F].arg; } else { *data = spurs->m.wklInfo1[workloadId].arg; } return CELL_OK; #endif } s64 cellSpursReadyCountStore(vm::ptr spurs, u32 wid, u32 value) { cellSpurs->Warning("%s(spurs_addr=0x%x, wid=%d, value=0x%x)", __FUNCTION__, spurs.addr(), wid, value); #ifdef PRX_DEBUG_XXX return GetCurrentPPUThread().FastCall2(libsre + 0xAB2C, libsre_rtoc); #endif if (!spurs) { return CELL_SPURS_POLICY_MODULE_ERROR_NULL_POINTER; } if (spurs.addr() % 128) { return CELL_SPURS_POLICY_MODULE_ERROR_ALIGN; } if (wid >= (spurs->m.flags1 & SF1_32_WORKLOADS ? 0x20u : 0x10u) || value > 0xff) { return CELL_SPURS_POLICY_MODULE_ERROR_INVAL; } if ((spurs->m.wklMskA.read_relaxed() & (0x80000000u >> wid)) == 0) { return CELL_SPURS_POLICY_MODULE_ERROR_SRCH; } if (spurs->m.exception.data() || spurs->wklState(wid).read_relaxed() != 2) { return CELL_SPURS_POLICY_MODULE_ERROR_STAT; } if (wid < CELL_SPURS_MAX_WORKLOAD) { spurs->m.wklReadyCount1[wid].exchange((u8)value); } else { spurs->m.wklIdleSpuCountOrReadyCount2[wid].exchange((u8)value); } return CELL_OK; } s64 cellSpursReadyCountAdd() { #ifdef PRX_DEBUG cellSpurs->Warning("%s()", __FUNCTION__); return GetCurrentPPUThread().FastCall2(libsre + 0xA868, libsre_rtoc); #else UNIMPLEMENTED_FUNC(cellSpurs); return CELL_OK; #endif } s64 cellSpursReadyCountCompareAndSwap() { #ifdef PRX_DEBUG cellSpurs->Warning("%s()", __FUNCTION__); return GetCurrentPPUThread().FastCall2(libsre + 0xA9CC, libsre_rtoc); #else UNIMPLEMENTED_FUNC(cellSpurs); return CELL_OK; #endif } s64 cellSpursReadyCountSwap() { #ifdef PRX_DEBUG cellSpurs->Warning("%s()", __FUNCTION__); return GetCurrentPPUThread().FastCall2(libsre + 0xAC34, libsre_rtoc); #else UNIMPLEMENTED_FUNC(cellSpurs); return CELL_OK; #endif } s64 cellSpursRequestIdleSpu() { #ifdef PRX_DEBUG cellSpurs->Warning("%s()", __FUNCTION__); return GetCurrentPPUThread().FastCall2(libsre + 0xAD88, libsre_rtoc); #else UNIMPLEMENTED_FUNC(cellSpurs); return CELL_OK; #endif } s64 cellSpursGetWorkloadInfo() { #ifdef PRX_DEBUG cellSpurs->Warning("%s()", __FUNCTION__); return GetCurrentPPUThread().FastCall2(libsre + 0xE70C, libsre_rtoc); #else UNIMPLEMENTED_FUNC(cellSpurs); return CELL_OK; #endif } s64 _cellSpursWorkloadFlagReceiver2() { #ifdef PRX_DEBUG cellSpurs->Warning("%s()", __FUNCTION__); return GetCurrentPPUThread().FastCall2(libsre + 0xF298, libsre_rtoc); #else UNIMPLEMENTED_FUNC(cellSpurs); return CELL_OK; #endif } s64 cellSpursSetExceptionEventHandler() { #ifdef PRX_DEBUG cellSpurs->Warning("%s()", __FUNCTION__); return GetCurrentPPUThread().FastCall2(libsre + 0xDB54, libsre_rtoc); #else UNIMPLEMENTED_FUNC(cellSpurs); return CELL_OK; #endif } s64 cellSpursUnsetExceptionEventHandler() { #ifdef PRX_DEBUG cellSpurs->Warning("%s()", __FUNCTION__); return GetCurrentPPUThread().FastCall2(libsre + 0xD77C, libsre_rtoc); #else UNIMPLEMENTED_FUNC(cellSpurs); return CELL_OK; #endif } s64 _cellSpursEventFlagInitialize(vm::ptr spurs, vm::ptr taskset, vm::ptr eventFlag, u32 flagClearMode, u32 flagDirection) { cellSpurs->Warning("_cellSpursEventFlagInitialize(spurs_addr=0x%x, taskset_addr=0x%x, eventFlag_addr=0x%x, flagClearMode=%d, flagDirection=%d)", spurs.addr(), taskset.addr(), eventFlag.addr(), flagClearMode, flagDirection); #ifdef PRX_DEBUG return GetCurrentPPUThread().FastCall2(libsre + 0x1564C, libsre_rtoc); #else if (taskset.addr() == 0 && spurs.addr() == 0) { return CELL_SPURS_TASK_ERROR_NULL_POINTER; } if (eventFlag.addr() == 0) { return CELL_SPURS_TASK_ERROR_NULL_POINTER; } if (spurs.addr() % CellSpurs::align || taskset.addr() % CellSpursTaskset::align || eventFlag.addr() % CellSpursEventFlag::align) { return CELL_SPURS_TASK_ERROR_ALIGN; } if (taskset.addr() && taskset->m.wid >= CELL_SPURS_MAX_WORKLOAD2) { return CELL_SPURS_TASK_ERROR_INVAL; } if (flagDirection > CELL_SPURS_EVENT_FLAG_LAST || flagClearMode > CELL_SPURS_EVENT_FLAG_CLEAR_LAST) { return CELL_SPURS_TASK_ERROR_INVAL; } memset(eventFlag.get_ptr(), 0, CellSpursEventFlag::size); eventFlag->m.direction = flagDirection; eventFlag->m.clearMode = flagClearMode; eventFlag->m.spuPort = CELL_SPURS_EVENT_FLAG_INVALID_SPU_PORT; if (taskset.addr()) { eventFlag->m.addr = taskset.addr(); } else { eventFlag->m.isIwl = 1; eventFlag->m.addr = spurs.addr(); } return CELL_OK; #endif } s64 cellSpursEventFlagAttachLv2EventQueue(vm::ptr eventFlag) { cellSpurs->Warning("cellSpursEventFlagAttachLv2EventQueue(eventFlag_addr=0x%x)", eventFlag.addr()); #ifdef PRX_DEBUG return GetCurrentPPUThread().FastCall2(libsre + 0x157B8, libsre_rtoc); #else if (!eventFlag) { return CELL_SPURS_TASK_ERROR_NULL_POINTER; } if (eventFlag.addr() % CellSpursEventFlag::align) { return CELL_SPURS_TASK_ERROR_AGAIN; } if (eventFlag->m.direction != CELL_SPURS_EVENT_FLAG_SPU2PPU && eventFlag->m.direction != CELL_SPURS_EVENT_FLAG_ANY2ANY) { return CELL_SPURS_TASK_ERROR_PERM; } if (eventFlag->m.spuPort != CELL_SPURS_EVENT_FLAG_INVALID_SPU_PORT) { return CELL_SPURS_TASK_ERROR_STAT; } vm::ptr spurs; if (eventFlag->m.isIwl == 1) { spurs.set((u32)eventFlag->m.addr); } else { auto taskset = vm::ptr::make((u32)eventFlag->m.addr); spurs.set((u32)taskset->m.spurs.addr()); } u32 eventQueueId; vm::var port; auto rc = spursCreateLv2EventQueue(spurs, eventQueueId, port, 1, *((u64 *)"_spuEvF")); if (rc != CELL_OK) { // Return rc if its an error code from SPURS otherwise convert the error code to a SPURS task error code return (rc & 0x0FFF0000) == 0x00410000 ? rc : (0x80410900 | (rc & 0xFF)); } if (eventFlag->m.direction == CELL_SPURS_EVENT_FLAG_ANY2ANY) { vm::var> eventPortId; rc = sys_event_port_create(vm::ptr::make(eventPortId.addr()), SYS_EVENT_PORT_LOCAL, 0); if (rc == CELL_OK) { rc = sys_event_port_connect_local(eventPortId.value(), eventQueueId); if (rc == CELL_OK) { eventFlag->m.eventPortId = eventPortId; goto success; } sys_event_port_destroy(eventPortId.value()); } // TODO: Implement the following // if (spursDetachLv2EventQueue(spurs, port, 1) == CELL_OK) // { // sys_event_queue_destroy(eventQueueId, SYS_EVENT_QUEUE_DESTROY_FORCE); // } // Return rc if its an error code from SPURS otherwise convert the error code to a SPURS task error code return (rc & 0x0FFF0000) == 0x00410000 ? rc : (0x80410900 | (rc & 0xFF)); } success: eventFlag->m.eventQueueId = eventQueueId; eventFlag->m.spuPort = port; return CELL_OK; #endif } s64 cellSpursEventFlagDetachLv2EventQueue(vm::ptr eventFlag) { cellSpurs->Warning("cellSpursEventFlagDetachLv2EventQueue(eventFlag_addr=0x%x)", eventFlag.addr()); #ifdef PRX_DEBUG return GetCurrentPPUThread().FastCall2(libsre + 0x15998, libsre_rtoc); #else if (!eventFlag) { return CELL_SPURS_TASK_ERROR_NULL_POINTER; } if (eventFlag.addr() % CellSpursEventFlag::align) { return CELL_SPURS_TASK_ERROR_AGAIN; } if (eventFlag->m.direction != CELL_SPURS_EVENT_FLAG_SPU2PPU && eventFlag->m.direction != CELL_SPURS_EVENT_FLAG_ANY2ANY) { return CELL_SPURS_TASK_ERROR_PERM; } if (eventFlag->m.spuPort == CELL_SPURS_EVENT_FLAG_INVALID_SPU_PORT) { return CELL_SPURS_TASK_ERROR_STAT; } if (eventFlag->m.ppuWaitMask || eventFlag->m.ppuPendingRecv) { return CELL_SPURS_TASK_ERROR_BUSY; } auto port = eventFlag->m.spuPort; eventFlag->m.spuPort = CELL_SPURS_EVENT_FLAG_INVALID_SPU_PORT; vm::ptr spurs; if (eventFlag->m.isIwl == 1) { spurs.set((u32)eventFlag->m.addr); } else { auto taskset = vm::ptr::make((u32)eventFlag->m.addr); spurs.set((u32)taskset->m.spurs.addr()); } if(eventFlag->m.direction == CELL_SPURS_EVENT_FLAG_ANY2ANY) { sys_event_port_disconnect(eventFlag->m.eventPortId); sys_event_port_destroy(eventFlag->m.eventPortId); } s64 rc = CELL_OK; // TODO: Implement the following // auto rc = spursDetachLv2EventQueue(spurs, port, 1); // if (rc == CELL_OK) // { // rc = sys_event_queue_destroy(eventFlag->m.eventQueueId, SYS_EVENT_QUEUE_DESTROY_FORCE); // } if (rc != CELL_OK) { // Return rc if its an error code from SPURS otherwise convert the error code to a SPURS task error code return (rc & 0x0FFF0000) == 0x00410000 ? rc : (0x80410900 | (rc & 0xFF)); } return CELL_OK; #endif } s64 _cellSpursEventFlagWait(vm::ptr eventFlag, vm::ptr mask, u32 mode, u32 block) { if (eventFlag.addr() == 0 || mask.addr() == 0) { return CELL_SPURS_TASK_ERROR_NULL_POINTER; } if (eventFlag.addr() % CellSpursEventFlag::align) { return CELL_SPURS_TASK_ERROR_ALIGN; } if (mode > CELL_SPURS_EVENT_FLAG_WAIT_MODE_LAST) { return CELL_SPURS_TASK_ERROR_INVAL; } if (eventFlag->m.direction != CELL_SPURS_EVENT_FLAG_SPU2PPU && eventFlag->m.direction != CELL_SPURS_EVENT_FLAG_ANY2ANY) { return CELL_SPURS_TASK_ERROR_PERM; } if (block && eventFlag->m.spuPort == CELL_SPURS_EVENT_FLAG_INVALID_SPU_PORT) { return CELL_SPURS_TASK_ERROR_STAT; } if (eventFlag->m.ppuWaitMask || eventFlag->m.ppuPendingRecv) { return CELL_SPURS_TASK_ERROR_BUSY; } u16 relevantEvents = eventFlag->m.events & *mask; if (eventFlag->m.direction == CELL_SPURS_EVENT_FLAG_ANY2ANY) { // Make sure the wait mask and mode specified does not conflict with that of the already waiting tasks. // Conflict scenarios: // OR vs OR - A conflict never occurs // OR vs AND - A conflict occurs if the masks for the two tasks overlap // AND vs AND - A conflict occurs if the masks for the two tasks are not the same // Determine the set of all already waiting tasks whose wait mode/mask can possibly conflict with the specified wait mode/mask. // This set is equal to 'set of all tasks waiting' - 'set of all tasks whose wait conditions have been met'. // If the wait mode is OR, we prune the set of all tasks that are waiting in OR mode from the set since a conflict cannot occur // with an already waiting task in OR mode. u16 relevantWaitSlots = eventFlag->m.spuTaskUsedWaitSlots & ~eventFlag->m.spuTaskPendingRecv; if (mode == CELL_SPURS_EVENT_FLAG_OR) { relevantWaitSlots &= eventFlag->m.spuTaskWaitMode; } int i = CELL_SPURS_EVENT_FLAG_MAX_WAIT_SLOTS - 1; while (relevantWaitSlots) { if (relevantWaitSlots & 0x0001) { if (eventFlag->m.spuTaskWaitMask[i] & *mask && eventFlag->m.spuTaskWaitMask[i] != *mask) { return CELL_SPURS_TASK_ERROR_AGAIN; } } relevantWaitSlots >>= 1; i--; } } // There is no need to block if all bits required by the wait operation have already been set or // if the wait mode is OR and atleast one of the bits required by the wait operation has been set. bool recv; if ((*mask & ~relevantEvents) == 0 || (mode == CELL_SPURS_EVENT_FLAG_OR && relevantEvents)) { // If the clear flag is AUTO then clear the bits comnsumed by this thread if (eventFlag->m.clearMode == CELL_SPURS_EVENT_FLAG_CLEAR_AUTO) { eventFlag->m.events &= ~relevantEvents; } recv = false; } else { // If we reach here it means that the conditions for this thread have not been met. // If this is a try wait operation then do not block but return an error code. if (block == 0) { return CELL_SPURS_TASK_ERROR_BUSY; } eventFlag->m.ppuWaitSlotAndMode = 0; if (eventFlag->m.direction == CELL_SPURS_EVENT_FLAG_ANY2ANY) { // Find an unsed wait slot int i = 0; u16 spuTaskUsedWaitSlots = eventFlag->m.spuTaskUsedWaitSlots; while (spuTaskUsedWaitSlots & 0x0001) { spuTaskUsedWaitSlots >>= 1; i++; } if (i == CELL_SPURS_EVENT_FLAG_MAX_WAIT_SLOTS) { // Event flag has no empty wait slots return CELL_SPURS_TASK_ERROR_BUSY; } // Mark the found wait slot as used by this thread eventFlag->m.ppuWaitSlotAndMode = (CELL_SPURS_EVENT_FLAG_MAX_WAIT_SLOTS - 1 - i) << 4; } // Save the wait mask and mode for this thread eventFlag->m.ppuWaitSlotAndMode |= mode; eventFlag->m.ppuWaitMask = *mask; recv = true; } u16 receivedEventFlag; if (recv) { // Block till something happens vm::var data; auto rc = sys_event_queue_receive(eventFlag->m.eventQueueId, data, 0); if (rc != CELL_OK) { assert(0); } int i = 0; if (eventFlag->m.direction == CELL_SPURS_EVENT_FLAG_ANY2ANY) { i = eventFlag->m.ppuWaitSlotAndMode >> 4; } receivedEventFlag = eventFlag->m.pendingRecvTaskEvents[i]; eventFlag->m.ppuPendingRecv = 0; } *mask = receivedEventFlag; return CELL_OK; } s64 cellSpursEventFlagWait(vm::ptr eventFlag, vm::ptr mask, u32 mode) { cellSpurs->Warning("cellSpursEventFlagWait(eventFlag_addr=0x%x, mask_addr=0x%x, mode=%d)", eventFlag.addr(), mask.addr(), mode); #ifdef PRX_DEBUG return GetCurrentPPUThread().FastCall2(libsre + 0x15E68, libsre_rtoc); #else return _cellSpursEventFlagWait(eventFlag, mask, mode, 1/*block*/); #endif } s64 cellSpursEventFlagClear(vm::ptr eventFlag, u16 bits) { cellSpurs->Warning("cellSpursEventFlagClear(eventFlag_addr=0x%x, bits=0x%x)", eventFlag.addr(), bits); #ifdef PRX_DEBUG return GetCurrentPPUThread().FastCall2(libsre + 0x15E9C, libsre_rtoc); #else if (eventFlag.addr() == 0) { return CELL_SPURS_TASK_ERROR_NULL_POINTER; } if (eventFlag.addr() % CellSpursEventFlag::align) { return CELL_SPURS_TASK_ERROR_ALIGN; } eventFlag->m.events &= ~bits; return CELL_OK; #endif } s64 cellSpursEventFlagSet(vm::ptr eventFlag, u16 bits) { cellSpurs->Warning("cellSpursEventFlagSet(eventFlag_addr=0x%x, bits=0x%x)", eventFlag.addr(), bits); #ifdef PRX_DEBUG return GetCurrentPPUThread().FastCall2(libsre + 0x15F04, libsre_rtoc); #else if (eventFlag.addr() == 0) { return CELL_SPURS_TASK_ERROR_NULL_POINTER; } if (eventFlag.addr() % CellSpursEventFlag::align) { return CELL_SPURS_TASK_ERROR_ALIGN; } if (eventFlag->m.direction != CELL_SPURS_EVENT_FLAG_PPU2SPU && eventFlag->m.direction != CELL_SPURS_EVENT_FLAG_ANY2ANY) { return CELL_SPURS_TASK_ERROR_PERM; } u16 ppuEventFlag = 0; bool send = false; int ppuWaitSlot = 0; u16 eventsToClear = 0; if (eventFlag->m.direction == CELL_SPURS_EVENT_FLAG_ANY2ANY && eventFlag->m.ppuWaitMask) { u16 ppuRelevantEvents = (eventFlag->m.events | bits) & eventFlag->m.ppuWaitMask; // Unblock the waiting PPU thread if either all the bits being waited by the thread have been set or // if the wait mode of the thread is OR and atleast one bit the thread is waiting on has been set if ((eventFlag->m.ppuWaitMask & ~ppuRelevantEvents) == 0 || ((eventFlag->m.ppuWaitSlotAndMode & 0x0F) == CELL_SPURS_EVENT_FLAG_OR && ppuRelevantEvents != 0)) { eventFlag->m.ppuPendingRecv = 1; eventFlag->m.ppuWaitMask = 0; ppuEventFlag = ppuRelevantEvents; eventsToClear = ppuRelevantEvents; ppuWaitSlot = eventFlag->m.ppuWaitSlotAndMode >> 4; send = true; } } int i = CELL_SPURS_EVENT_FLAG_MAX_WAIT_SLOTS - 1; int j = 0; u16 relevantWaitSlots = eventFlag->m.spuTaskUsedWaitSlots & ~eventFlag->m.spuTaskPendingRecv; u16 spuTaskPendingRecv = 0; u16 pendingRecvTaskEvents[16]; while (relevantWaitSlots) { if (relevantWaitSlots & 0x0001) { u16 spuTaskRelevantEvents = (eventFlag->m.events | bits) & eventFlag->m.spuTaskWaitMask[i]; // Unblock the waiting SPU task if either all the bits being waited by the task have been set or // if the wait mode of the task is OR and atleast one bit the thread is waiting on has been set if ((eventFlag->m.spuTaskWaitMask[i] & ~spuTaskRelevantEvents) == 0 || (((eventFlag->m.spuTaskWaitMode >> j) & 0x0001) == CELL_SPURS_EVENT_FLAG_OR && spuTaskRelevantEvents != 0)) { eventsToClear |= spuTaskRelevantEvents; spuTaskPendingRecv |= 1 << j; pendingRecvTaskEvents[j] = spuTaskRelevantEvents; } } relevantWaitSlots >>= 1; i--; j++; } eventFlag->m.events |= bits; eventFlag->m.spuTaskPendingRecv |= spuTaskPendingRecv; // If the clear flag is AUTO then clear the bits comnsumed by all tasks marked to be unblocked if (eventFlag->m.clearMode == CELL_SPURS_EVENT_FLAG_CLEAR_AUTO) { eventFlag->m.events &= ~eventsToClear; } if (send) { // Signal the PPU thread to be woken up eventFlag->m.pendingRecvTaskEvents[ppuWaitSlot] = ppuEventFlag; if (sys_event_port_send(eventFlag->m.eventPortId, 0, 0, 0) != CELL_OK) { assert(0); } } if (spuTaskPendingRecv) { // Signal each SPU task whose conditions have been met to be woken up for (int i = 0; i < CELL_SPURS_EVENT_FLAG_MAX_WAIT_SLOTS; i++) { if (spuTaskPendingRecv & (0x8000 >> i)) { eventFlag->m.pendingRecvTaskEvents[i] = pendingRecvTaskEvents[i]; vm::var taskset; if (eventFlag->m.isIwl) { cellSpursLookUpTasksetAddress(vm::ptr::make((u32)eventFlag->m.addr), vm::ptr::make(taskset.addr()), eventFlag->m.waitingTaskWklId[i]); } else { taskset.value() = (u32)eventFlag->m.addr; } auto rc = _cellSpursSendSignal(vm::ptr::make(taskset.addr()), eventFlag->m.waitingTaskId[i]); if (rc == CELL_SPURS_TASK_ERROR_INVAL || rc == CELL_SPURS_TASK_ERROR_STAT) { return CELL_SPURS_TASK_ERROR_FATAL; } if (rc != CELL_OK) { assert(0); } } } } return CELL_OK; #endif } s64 cellSpursEventFlagTryWait(vm::ptr eventFlag, vm::ptr mask, u32 mode) { cellSpurs->Warning("cellSpursEventFlagTryWait(eventFlag_addr=0x%x, mask_addr=0x%x, mode=0x%x)", eventFlag.addr(), mask.addr(), mode); #ifdef PRX_DEBUG return GetCurrentPPUThread().FastCall2(libsre + 0x15E70, libsre_rtoc); #else return _cellSpursEventFlagWait(eventFlag, mask, mode, 0/*block*/); #endif } s64 cellSpursEventFlagGetDirection(vm::ptr eventFlag, vm::ptr direction) { cellSpurs->Warning("cellSpursEventFlagGetDirection(eventFlag_addr=0x%x, direction_addr=0x%x)", eventFlag.addr(), direction.addr()); #ifdef PRX_DEBUG return GetCurrentPPUThread().FastCall2(libsre + 0x162C4, libsre_rtoc); #else if (eventFlag.addr() == 0 || direction.addr() == 0) { return CELL_SPURS_TASK_ERROR_NULL_POINTER; } if (eventFlag.addr() % CellSpursEventFlag::align) { return CELL_SPURS_TASK_ERROR_ALIGN; } *direction = eventFlag->m.direction; return CELL_OK; #endif } s64 cellSpursEventFlagGetClearMode(vm::ptr eventFlag, vm::ptr clear_mode) { cellSpurs->Warning("cellSpursEventFlagGetClearMode(eventFlag_addr=0x%x, clear_mode_addr=0x%x)", eventFlag.addr(), clear_mode.addr()); #ifdef PRX_DEBUG return GetCurrentPPUThread().FastCall2(libsre + 0x16310, libsre_rtoc); #else if (eventFlag.addr() == 0 || clear_mode.addr() == 0) { return CELL_SPURS_TASK_ERROR_NULL_POINTER; } if (eventFlag.addr() % CellSpursEventFlag::align) { return CELL_SPURS_TASK_ERROR_ALIGN; } *clear_mode = eventFlag->m.clearMode; return CELL_OK; #endif } s64 cellSpursEventFlagGetTasksetAddress(vm::ptr eventFlag, vm::ptr taskset) { cellSpurs->Warning("cellSpursEventFlagGetTasksetAddress(eventFlag_addr=0x%x, taskset_addr=0x%x)", eventFlag.addr(), taskset.addr()); #ifdef PRX_DEBUG return GetCurrentPPUThread().FastCall2(libsre + 0x1635C, libsre_rtoc); #else if (eventFlag.addr() == 0 || taskset.addr() == 0) { return CELL_SPURS_TASK_ERROR_NULL_POINTER; } if (eventFlag.addr() % CellSpursEventFlag::align) { return CELL_SPURS_TASK_ERROR_ALIGN; } taskset.set(eventFlag->m.isIwl ? 0 : eventFlag->m.addr); return CELL_OK; #endif } s64 _cellSpursLFQueueInitialize() { #ifdef PRX_DEBUG cellSpurs->Warning("%s()", __FUNCTION__); return GetCurrentPPUThread().FastCall2(libsre + 0x17028, libsre_rtoc); #else UNIMPLEMENTED_FUNC(cellSpurs); return CELL_OK; #endif } s64 _cellSpursLFQueuePushBody() { #ifdef PRX_DEBUG cellSpurs->Warning("%s()", __FUNCTION__); return GetCurrentPPUThread().FastCall2(libsre + 0x170AC, libsre_rtoc); #else UNIMPLEMENTED_FUNC(cellSpurs); return CELL_OK; #endif } s64 cellSpursLFQueueDetachLv2EventQueue() { #ifdef PRX_DEBUG cellSpurs->Warning("%s()", __FUNCTION__); return GetCurrentPPUThread().FastCall2(libsre + 0x177CC, libsre_rtoc); #else UNIMPLEMENTED_FUNC(cellSpurs); return CELL_OK; #endif } s64 cellSpursLFQueueAttachLv2EventQueue() { #ifdef PRX_DEBUG cellSpurs->Warning("%s()", __FUNCTION__); return GetCurrentPPUThread().FastCall2(libsre + 0x173EC, libsre_rtoc); #else UNIMPLEMENTED_FUNC(cellSpurs); return CELL_OK; #endif } s64 _cellSpursLFQueuePopBody() { #ifdef PRX_DEBUG cellSpurs->Warning("%s()", __FUNCTION__); return GetCurrentPPUThread().FastCall2(libsre + 0x17238, libsre_rtoc); #else UNIMPLEMENTED_FUNC(cellSpurs); return CELL_OK; #endif } s64 cellSpursLFQueueGetTasksetAddress() { #ifdef PRX_DEBUG cellSpurs->Warning("%s()", __FUNCTION__); return GetCurrentPPUThread().FastCall2(libsre + 0x17C34, libsre_rtoc); #else UNIMPLEMENTED_FUNC(cellSpurs); return CELL_OK; #endif } s64 _cellSpursQueueInitialize() { #ifdef PRX_DEBUG cellSpurs->Warning("%s()", __FUNCTION__); return GetCurrentPPUThread().FastCall2(libsre + 0x163B4, libsre_rtoc); #else UNIMPLEMENTED_FUNC(cellSpurs); return CELL_OK; #endif } s64 cellSpursQueuePopBody() { #ifdef PRX_DEBUG cellSpurs->Warning("%s()", __FUNCTION__); return GetCurrentPPUThread().FastCall2(libsre + 0x16BF0, libsre_rtoc); #else UNIMPLEMENTED_FUNC(cellSpurs); return CELL_OK; #endif } s64 cellSpursQueuePushBody() { #ifdef PRX_DEBUG cellSpurs->Warning("%s()", __FUNCTION__); return GetCurrentPPUThread().FastCall2(libsre + 0x168C4, libsre_rtoc); #else UNIMPLEMENTED_FUNC(cellSpurs); return CELL_OK; #endif } s64 cellSpursQueueAttachLv2EventQueue() { #ifdef PRX_DEBUG cellSpurs->Warning("%s()", __FUNCTION__); return GetCurrentPPUThread().FastCall2(libsre + 0x1666C, libsre_rtoc); #else UNIMPLEMENTED_FUNC(cellSpurs); return CELL_OK; #endif } s64 cellSpursQueueDetachLv2EventQueue() { #ifdef PRX_DEBUG cellSpurs->Warning("%s()", __FUNCTION__); return GetCurrentPPUThread().FastCall2(libsre + 0x16524, libsre_rtoc); #else UNIMPLEMENTED_FUNC(cellSpurs); return CELL_OK; #endif } s64 cellSpursQueueGetTasksetAddress() { #ifdef PRX_DEBUG cellSpurs->Warning("%s()", __FUNCTION__); return GetCurrentPPUThread().FastCall2(libsre + 0x16F50, libsre_rtoc); #else UNIMPLEMENTED_FUNC(cellSpurs); return CELL_OK; #endif } s64 cellSpursQueueClear() { #ifdef PRX_DEBUG cellSpurs->Warning("%s()", __FUNCTION__); return GetCurrentPPUThread().FastCall2(libsre + 0x1675C, libsre_rtoc); #else UNIMPLEMENTED_FUNC(cellSpurs); return CELL_OK; #endif } s64 cellSpursQueueDepth() { #ifdef PRX_DEBUG cellSpurs->Warning("%s()", __FUNCTION__); return GetCurrentPPUThread().FastCall2(libsre + 0x1687C, libsre_rtoc); #else UNIMPLEMENTED_FUNC(cellSpurs); return CELL_OK; #endif } s64 cellSpursQueueGetEntrySize() { #ifdef PRX_DEBUG cellSpurs->Warning("%s()", __FUNCTION__); return GetCurrentPPUThread().FastCall2(libsre + 0x16FE0, libsre_rtoc); #else UNIMPLEMENTED_FUNC(cellSpurs); return CELL_OK; #endif } s64 cellSpursQueueSize() { #ifdef PRX_DEBUG cellSpurs->Warning("%s()", __FUNCTION__); return GetCurrentPPUThread().FastCall2(libsre + 0x167F0, libsre_rtoc); #else UNIMPLEMENTED_FUNC(cellSpurs); return CELL_OK; #endif } s64 cellSpursQueueGetDirection() { #ifdef PRX_DEBUG cellSpurs->Warning("%s()", __FUNCTION__); return GetCurrentPPUThread().FastCall2(libsre + 0x16F98, libsre_rtoc); #else UNIMPLEMENTED_FUNC(cellSpurs); return CELL_OK; #endif } s64 cellSpursCreateJobChainWithAttribute() { #ifdef PRX_DEBUG cellSpurs->Warning("%s()", __FUNCTION__); return GetCurrentPPUThread().FastCall2(libsre + 0x1898C, libsre_rtoc); #else UNIMPLEMENTED_FUNC(cellSpurs); return CELL_OK; #endif } s64 cellSpursCreateJobChain() { #ifdef PRX_DEBUG cellSpurs->Warning("%s()", __FUNCTION__); return GetCurrentPPUThread().FastCall2(libsre + 0x18B84, libsre_rtoc); #else UNIMPLEMENTED_FUNC(cellSpurs); return CELL_OK; #endif } s64 cellSpursJoinJobChain() { #ifdef PRX_DEBUG cellSpurs->Warning("%s()", __FUNCTION__); return GetCurrentPPUThread().FastCall2(libsre + 0x18DB0, libsre_rtoc); #else UNIMPLEMENTED_FUNC(cellSpurs); return CELL_OK; #endif } s64 cellSpursKickJobChain() { #ifdef PRX_DEBUG cellSpurs->Warning("%s()", __FUNCTION__); return GetCurrentPPUThread().FastCall2(libsre + 0x18E8C, libsre_rtoc); #else UNIMPLEMENTED_FUNC(cellSpurs); return CELL_OK; #endif } s64 _cellSpursJobChainAttributeInitialize() { #ifdef PRX_DEBUG cellSpurs->Warning("%s()", __FUNCTION__); return GetCurrentPPUThread().FastCall2(libsre + 0x1845C, libsre_rtoc); #else UNIMPLEMENTED_FUNC(cellSpurs); return CELL_OK; #endif } s64 cellSpursGetJobChainId() { #ifdef PRX_DEBUG cellSpurs->Warning("%s()", __FUNCTION__); return GetCurrentPPUThread().FastCall2(libsre + 0x19064, libsre_rtoc); #else UNIMPLEMENTED_FUNC(cellSpurs); return CELL_OK; #endif } s64 cellSpursJobChainSetExceptionEventHandler() { #ifdef PRX_DEBUG cellSpurs->Warning("%s()", __FUNCTION__); return GetCurrentPPUThread().FastCall2(libsre + 0x1A5A0, libsre_rtoc); #else UNIMPLEMENTED_FUNC(cellSpurs); return CELL_OK; #endif } s64 cellSpursJobChainUnsetExceptionEventHandler() { #ifdef PRX_DEBUG cellSpurs->Warning("%s()", __FUNCTION__); return GetCurrentPPUThread().FastCall2(libsre + 0x1A614, libsre_rtoc); #else UNIMPLEMENTED_FUNC(cellSpurs); return CELL_OK; #endif } s64 cellSpursGetJobChainInfo() { #ifdef PRX_DEBUG cellSpurs->Warning("%s()", __FUNCTION__); return GetCurrentPPUThread().FastCall2(libsre + 0x1A7A0, libsre_rtoc); #else UNIMPLEMENTED_FUNC(cellSpurs); return CELL_OK; #endif } s64 cellSpursJobChainGetSpursAddress() { #ifdef PRX_DEBUG cellSpurs->Warning("%s()", __FUNCTION__); return GetCurrentPPUThread().FastCall2(libsre + 0x1A900, libsre_rtoc); #else UNIMPLEMENTED_FUNC(cellSpurs); return CELL_OK; #endif } s64 spursCreateTaskset(vm::ptr spurs, vm::ptr taskset, u64 args, vm::ptr priority, u32 max_contention, vm::ptr name, u32 size, s32 enable_clear_ls) { if (!spurs || !taskset) { return CELL_SPURS_TASK_ERROR_NULL_POINTER; } if (spurs.addr() % CellSpurs::align || taskset.addr() % CellSpursTaskset::align) { return CELL_SPURS_TASK_ERROR_ALIGN; } memset(taskset.get_ptr(), 0, size); taskset->m.spurs = spurs; taskset->m.args = args; taskset->m.enable_clear_ls = enable_clear_ls > 0 ? 1 : 0; taskset->m.size = size; vm::var wkl_attr; _cellSpursWorkloadAttributeInitialize(wkl_attr, 1 /*revision*/, 0x33 /*sdk_version*/, vm::ptr::make(16) /*pm*/, 0x1E40 /*pm_size*/, taskset.addr(), priority, 8 /*min_contention*/, max_contention); // TODO: Check return code cellSpursWorkloadAttributeSetName(wkl_attr, vm::ptr::make(0), name); // TODO: Check return code // TODO: cellSpursWorkloadAttributeSetShutdownCompletionEventHook(wkl_attr, hook, taskset); // TODO: Check return code vm::var> wid; cellSpursAddWorkloadWithAttribute(spurs, vm::ptr::make(wid.addr()), vm::ptr::make(wkl_attr.addr())); // TODO: Check return code taskset->m.x72 = 0x80; taskset->m.wid = wid.value(); // TODO: cellSpursSetExceptionEventHandler(spurs, wid, hook, taskset); // TODO: Check return code return CELL_OK; } s64 cellSpursCreateTasksetWithAttribute(vm::ptr spurs, vm::ptr taskset, vm::ptr attr) { cellSpurs->Warning("%s(spurs=0x%x, taskset=0x%x, attr=0x%x)", __FUNCTION__, spurs.addr(), taskset.addr(), attr.addr()); #ifdef PRX_DEBUG return GetCurrentPPUThread().FastCall2(libsre + 0x14BEC, libsre_rtoc); #endif if (!attr) { CELL_SPURS_TASK_ERROR_NULL_POINTER; } if (attr.addr() % CellSpursTasksetAttribute::align) { return CELL_SPURS_TASK_ERROR_ALIGN; } if (attr->m.revision != CELL_SPURS_TASKSET_ATTRIBUTE_REVISION) { return CELL_SPURS_TASK_ERROR_INVAL; } auto rc = spursCreateTaskset(spurs, taskset, attr->m.args, vm::ptr::make(attr.addr() + offsetof(CellSpursTasksetAttribute, m.priority)), attr->m.max_contention, vm::ptr::make(attr->m.name.addr()), attr->m.taskset_size, attr->m.enable_clear_ls); if (attr->m.taskset_size >= CellSpursTaskset2::size) { // TODO: Implement this } return rc; } s64 cellSpursCreateTaskset(vm::ptr spurs, vm::ptr taskset, u64 args, vm::ptr priority, u32 maxContention) { cellSpurs->Warning("cellSpursCreateTaskset(spurs_addr=0x%x, taskset_addr=0x%x, args=0x%llx, priority_addr=0x%x, maxContention=%d)", spurs.addr(), taskset.addr(), args, priority.addr(), maxContention); #ifdef PRX_DEBUG return GetCurrentPPUThread().FastCall2(libsre + 0x14CB8, libsre_rtoc); #endif #if 0 SPURSManagerTasksetAttribute *tattr = new SPURSManagerTasksetAttribute(args, priority, maxContention); taskset->taskset = new SPURSManagerTaskset(taskset.addr(), tattr); return CELL_OK; #endif return spursCreateTaskset(spurs, taskset, args, priority, maxContention, vm::ptr::make(0), CellSpursTaskset::size, 0); } s64 cellSpursJoinTaskset(vm::ptr taskset) { cellSpurs->Warning("cellSpursJoinTaskset(taskset_addr=0x%x)", taskset.addr()); #ifdef PRX_DEBUG return GetCurrentPPUThread().FastCall2(libsre + 0x152F8, libsre_rtoc); #else UNIMPLEMENTED_FUNC(cellSpurs); return CELL_OK; #endif } s64 cellSpursGetTasksetId(vm::ptr taskset, vm::ptr wid) { cellSpurs->Warning("cellSpursGetTasksetId(taskset_addr=0x%x, wid=0x%x)", taskset.addr(), wid.addr()); #ifdef PRX_DEBUG return GetCurrentPPUThread().FastCall2(libsre + 0x14EA0, libsre_rtoc); #else if (!taskset || !wid) { return CELL_SPURS_TASK_ERROR_NULL_POINTER; } if (taskset.addr() % CellSpursTaskset::align) { return CELL_SPURS_TASK_ERROR_ALIGN; } if (taskset->m.wid >= CELL_SPURS_MAX_WORKLOAD) { return CELL_SPURS_TASK_ERROR_INVAL; } *wid = taskset->m.wid; return CELL_OK; #endif } s64 cellSpursShutdownTaskset(vm::ptr taskset) { cellSpurs->Warning("cellSpursShutdownTaskset(taskset_addr=0x%x)", taskset.addr()); #ifdef PRX_DEBUG return GetCurrentPPUThread().FastCall2(libsre + 0x14868, libsre_rtoc); #else UNIMPLEMENTED_FUNC(cellSpurs); return CELL_OK; #endif } u32 _cellSpursGetSdkVersion() { static s32 sdk_version = -2; if (sdk_version == -2) { vm::var> version; sys_process_get_sdk_version(sys_process_getpid(), vm::ptr::make(version.addr())); sdk_version = version.value(); } return sdk_version; } s64 spursCreateTask(vm::ptr taskset, vm::ptr task_id, vm::ptr elf_addr, vm::ptr context_addr, u32 context_size, vm::ptr ls_pattern, vm::ptr arg) { if (!taskset || !elf_addr) { return CELL_SPURS_TASK_ERROR_NULL_POINTER; } if (elf_addr.addr() % 16) { return CELL_SPURS_TASK_ERROR_ALIGN; } auto sdk_version = _cellSpursGetSdkVersion(); if (sdk_version < 0x27FFFF) { if (context_addr.addr() % 16) { return CELL_SPURS_TASK_ERROR_ALIGN; } } else { if (context_addr.addr() % 128) { return CELL_SPURS_TASK_ERROR_ALIGN; } } u32 alloc_ls_blocks = 0; if (context_addr.addr() != 0) { if (context_size < CELL_SPURS_TASK_EXECUTION_CONTEXT_SIZE) { return CELL_SPURS_TASK_ERROR_INVAL; } alloc_ls_blocks = context_size > 0x3D400 ? 0x7A : ((context_size - 0x400) >> 11); if (ls_pattern.addr() != 0) { u32 ls_blocks = 0; for (u32 i = 0; i < 2; i++) { for (u32 j = 0; j < 64; j++) { if (ls_pattern->u64[0] & ((u64)1 << j)) { ls_blocks++; } } } if (ls_blocks > alloc_ls_blocks) { return CELL_SPURS_TASK_ERROR_INVAL; } if (ls_pattern->u32[0] & 0xFC000000) { // Prevent save/restore to SPURS management area return CELL_SPURS_TASK_ERROR_INVAL; } } } else { alloc_ls_blocks = 0; } // TODO: Verify the ELF header is proper and all its load segments are at address >= 0x3000 u32 tmp_task_id; for (tmp_task_id = 0; tmp_task_id < CELL_SPURS_MAX_TASK; tmp_task_id++) { u32 l = tmp_task_id >> 5; u32 b = tmp_task_id & 0x1F; if ((taskset->m.enabled_set[l] & (0x80000000 >> b)) == 0) { taskset->m.enabled_set[l] |= 0x80000000 >> b; break; } } if (tmp_task_id >= CELL_SPURS_MAX_TASK) { CELL_SPURS_TASK_ERROR_AGAIN; } taskset->m.task_info[tmp_task_id].elf_addr.set(elf_addr.addr()); taskset->m.task_info[tmp_task_id].context_save_storage_and_alloc_ls_blocks = (context_addr.addr() | alloc_ls_blocks); for (u32 i = 0; i < 2; i++) { taskset->m.task_info[tmp_task_id].args.u64[i] = arg != 0 ? arg->u64[i] : 0; taskset->m.task_info[tmp_task_id].ls_pattern.u64[i] = ls_pattern != 0 ? ls_pattern->u64[i] : 0; } *task_id = tmp_task_id; return CELL_OK; } s64 cellSpursCreateTask(vm::ptr taskset, vm::ptr taskID, u32 elf_addr, u32 context_addr, u32 context_size, vm::ptr lsPattern, vm::ptr argument) { cellSpurs->Warning("cellSpursCreateTask(taskset_addr=0x%x, taskID_addr=0x%x, elf_addr_addr=0x%x, context_addr_addr=0x%x, context_size=%d, lsPattern_addr=0x%x, argument_addr=0x%x)", taskset.addr(), taskID.addr(), elf_addr, context_addr, context_size, lsPattern.addr(), argument.addr()); #ifdef PRX_DEBUG return GetCurrentPPUThread().FastCall2(libsre + 0x12414, libsre_rtoc); #else return spursCreateTask(taskset, taskID, vm::ptr::make(elf_addr), vm::ptr::make(context_addr), context_size, lsPattern, argument); #endif } s64 _cellSpursSendSignal(vm::ptr taskset, u32 taskID) { #ifdef PRX_DEBUG cellSpurs->Warning("_cellSpursSendSignal(taskset_addr=0x%x, taskID=%d)", taskset.addr(), taskID); return GetCurrentPPUThread().FastCall2(libsre + 0x124CC, libsre_rtoc); #else if (!taskset) { return CELL_SPURS_TASK_ERROR_NULL_POINTER; } if (taskset.addr() % CellSpursTaskset::align) { return CELL_SPURS_TASK_ERROR_ALIGN; } if (taskID >= CELL_SPURS_MAX_TASK || taskset->m.wid >= CELL_SPURS_MAX_WORKLOAD2) { return CELL_SPURS_TASK_ERROR_INVAL; } auto word = taskID >> 5; auto mask = 0x80000000u >> (taskID & 0x1F); auto disabled = taskset->m.enabled_set[word] & mask ? false : true; auto running = taskset->m.running_set[word]; auto ready = taskset->m.ready_set[word]; auto ready2 = taskset->m.ready2_set[word]; auto waiting = taskset->m.waiting_set[word]; auto signalled = taskset->m.signal_received_set[word]; auto enabled = taskset->m.enabled_set[word]; auto invalid = (ready & ready2) || (running & waiting) || ((running | ready | ready2 | waiting | signalled) & ~enabled) || disabled; if (invalid) { return CELL_SPURS_TASK_ERROR_SRCH; } auto shouldSignal = waiting & ~signalled & mask ? true : false; taskset->m.signal_received_set[word] |= mask; if (shouldSignal) { cellSpursSendWorkloadSignal(vm::ptr::make((u32)taskset->m.spurs.addr()), taskset->m.wid); auto rc = cellSpursWakeUp(GetCurrentPPUThread(), vm::ptr::make((u32)taskset->m.spurs.addr())); if (rc == CELL_SPURS_POLICY_MODULE_ERROR_STAT) { return CELL_SPURS_TASK_ERROR_STAT; } if (rc != CELL_OK) { assert(0); } } return CELL_OK; #endif } s64 cellSpursCreateTaskWithAttribute() { cellSpurs->Warning("%s()", __FUNCTION__); #ifdef PRX_DEBUG return GetCurrentPPUThread().FastCall2(libsre + 0x12204, libsre_rtoc); #else UNIMPLEMENTED_FUNC(cellSpurs); return CELL_OK; #endif } s64 cellSpursTasksetAttributeSetName(vm::ptr attr, vm::ptr name) { cellSpurs->Warning("%s(attr=0x%x, name=0x%x)", __FUNCTION__, attr.addr(), name.addr()); #ifdef PRX_DEBUG return GetCurrentPPUThread().FastCall2(libsre + 0x14210, libsre_rtoc); #else if (!attr || !name) { return CELL_SPURS_TASK_ERROR_NULL_POINTER; } if (attr.addr() % CellSpursTasksetAttribute::align) { return CELL_SPURS_TASK_ERROR_ALIGN; } attr->m.name = name; return CELL_OK; #endif } s64 cellSpursTasksetAttributeSetTasksetSize(vm::ptr attr, u32 size) { cellSpurs->Warning("%s(attr=0x%x, size=0x%x)", __FUNCTION__, attr.addr(), size); #ifdef PRX_DEBUG return GetCurrentPPUThread().FastCall2(libsre + 0x14254, libsre_rtoc); #else if (!attr) { return CELL_SPURS_TASK_ERROR_NULL_POINTER; } if (attr.addr() % CellSpursTasksetAttribute::align) { return CELL_SPURS_TASK_ERROR_ALIGN; } if (size != CellSpursTaskset::size && size != CellSpursTaskset2::size) { return CELL_SPURS_TASK_ERROR_INVAL; } attr->m.taskset_size = size; return CELL_OK; #endif } s64 cellSpursTasksetAttributeEnableClearLS(vm::ptr attr, s32 enable) { cellSpurs->Warning("%s(attr=0x%x, enable=%d)", __FUNCTION__, attr.addr(), enable); #ifdef PRX_DEBUG return GetCurrentPPUThread().FastCall2(libsre + 0x142AC, libsre_rtoc); #else if (!attr) { return CELL_SPURS_TASK_ERROR_NULL_POINTER; } if (attr.addr() % CellSpursTasksetAttribute::align) { return CELL_SPURS_TASK_ERROR_ALIGN; } attr->m.enable_clear_ls = enable ? 1 : 0; return CELL_OK; #endif } s64 _cellSpursTasksetAttribute2Initialize(vm::ptr attribute, u32 revision) { cellSpurs->Warning("_cellSpursTasksetAttribute2Initialize(attribute_addr=0x%x, revision=%d)", attribute.addr(), revision); #ifdef PRX_DEBUG return GetCurrentPPUThread().FastCall2(libsre + 0x1474C, libsre_rtoc); #else memset(attribute.get_ptr(), 0, CellSpursTasksetAttribute2::size); attribute->m.revision = revision; attribute->m.name.set(0); attribute->m.args = 0; for (s32 i = 0; i < 8; i++) { attribute->m.priority[i] = 1; } attribute->m.max_contention = 8; attribute->m.enable_clear_ls = 0; attribute->m.task_name_buffer.set(0); return CELL_OK; #endif } s64 cellSpursTaskExitCodeGet() { cellSpurs->Warning("%s()", __FUNCTION__); #ifdef PRX_DEBUG return GetCurrentPPUThread().FastCall2(libsre + 0x1397C, libsre_rtoc); #else UNIMPLEMENTED_FUNC(cellSpurs); return CELL_OK; #endif } s64 cellSpursTaskExitCodeInitialize() { cellSpurs->Warning("%s()", __FUNCTION__); #ifdef PRX_DEBUG return GetCurrentPPUThread().FastCall2(libsre + 0x1352C, libsre_rtoc); #else UNIMPLEMENTED_FUNC(cellSpurs); return CELL_OK; #endif } s64 cellSpursTaskExitCodeTryGet() { cellSpurs->Warning("%s()", __FUNCTION__); #ifdef PRX_DEBUG return GetCurrentPPUThread().FastCall2(libsre + 0x13974, libsre_rtoc); #else UNIMPLEMENTED_FUNC(cellSpurs); return CELL_OK; #endif } s64 cellSpursTaskGetLoadableSegmentPattern() { cellSpurs->Warning("%s()", __FUNCTION__); #ifdef PRX_DEBUG return GetCurrentPPUThread().FastCall2(libsre + 0x13ED4, libsre_rtoc); #else UNIMPLEMENTED_FUNC(cellSpurs); return CELL_OK; #endif } s64 cellSpursTaskGetReadOnlyAreaPattern() { cellSpurs->Warning("%s()", __FUNCTION__); #ifdef PRX_DEBUG return GetCurrentPPUThread().FastCall2(libsre + 0x13CFC, libsre_rtoc); #else UNIMPLEMENTED_FUNC(cellSpurs); return CELL_OK; #endif } s64 cellSpursTaskGenerateLsPattern() { cellSpurs->Warning("%s()", __FUNCTION__); #ifdef PRX_DEBUG return GetCurrentPPUThread().FastCall2(libsre + 0x13B78, libsre_rtoc); #else UNIMPLEMENTED_FUNC(cellSpurs); return CELL_OK; #endif } s64 _cellSpursTaskAttributeInitialize() { cellSpurs->Warning("%s()", __FUNCTION__); #ifdef PRX_DEBUG return GetCurrentPPUThread().FastCall2(libsre + 0x10C30, libsre_rtoc); #else UNIMPLEMENTED_FUNC(cellSpurs); return CELL_OK; #endif } s64 cellSpursTaskAttributeSetExitCodeContainer() { cellSpurs->Warning("%s()", __FUNCTION__); #ifdef PRX_DEBUG return GetCurrentPPUThread().FastCall2(libsre + 0x10A98, libsre_rtoc); #else UNIMPLEMENTED_FUNC(cellSpurs); return CELL_OK; #endif } s64 _cellSpursTaskAttribute2Initialize(vm::ptr attribute, u32 revision) { cellSpurs->Warning("_cellSpursTaskAttribute2Initialize(attribute_addr=0x%x, revision=%d)", attribute.addr(), revision); #ifdef PRX_DEBUG return GetCurrentPPUThread().FastCall2(libsre + 0x10B00, libsre_rtoc); #else attribute->revision = revision; attribute->sizeContext = 0; attribute->eaContext = 0; for (s32 c = 0; c < 4; c++) { attribute->lsPattern.u32[c] = 0; } for (s32 i = 0; i < 2; i++) { attribute->lsPattern.u64[i] = 0; } attribute->name_addr = 0; return CELL_OK; #endif } s64 cellSpursTaskGetContextSaveAreaSize() { cellSpurs->Warning("%s()", __FUNCTION__); #ifdef PRX_DEBUG return GetCurrentPPUThread().FastCall2(libsre + 0x1409C, libsre_rtoc); #else UNIMPLEMENTED_FUNC(cellSpurs); return CELL_OK; #endif } s64 cellSpursCreateTaskset2(vm::ptr spurs, vm::ptr taskset, vm::ptr attr) { cellSpurs->Warning("%s(spurs=0x%x, taskset=0x%x, attr=0x%x)", __FUNCTION__, spurs.addr(), taskset.addr(), attr.addr()); #ifdef PRX_DEBUG return GetCurrentPPUThread().FastCall2(libsre + 0x15108, libsre_rtoc); #else vm::ptr tmp_attr; if (!attr) { attr.set(tmp_attr.addr()); _cellSpursTasksetAttribute2Initialize(attr, 0); } auto rc = spursCreateTaskset(spurs, vm::ptr::make(taskset.addr()), attr->m.args, vm::ptr::make(attr.addr() + offsetof(CellSpursTasksetAttribute, m.priority)), attr->m.max_contention, vm::ptr::make(attr->m.name.addr()), CellSpursTaskset2::size, (u8)attr->m.enable_clear_ls); if (rc != CELL_OK) { return rc; } if (attr->m.task_name_buffer.addr() % CellSpursTaskNameBuffer::align) { return CELL_SPURS_TASK_ERROR_ALIGN; } // TODO: Implement rest of the function return CELL_OK; #endif } s64 cellSpursCreateTask2() { cellSpurs->Warning("%s()", __FUNCTION__); #ifdef PRX_DEBUG return GetCurrentPPUThread().FastCall2(libsre + 0x11E54, libsre_rtoc); #else UNIMPLEMENTED_FUNC(cellSpurs); return CELL_OK; #endif } s64 cellSpursJoinTask2() { cellSpurs->Warning("%s()", __FUNCTION__); #ifdef PRX_DEBUG return GetCurrentPPUThread().FastCall2(libsre + 0x11378, libsre_rtoc); #else UNIMPLEMENTED_FUNC(cellSpurs); return CELL_OK; #endif } s64 cellSpursTryJoinTask2() { cellSpurs->Warning("%s()", __FUNCTION__); #ifdef PRX_DEBUG return GetCurrentPPUThread().FastCall2(libsre + 0x11748, libsre_rtoc); #else UNIMPLEMENTED_FUNC(cellSpurs); return CELL_OK; #endif } s64 cellSpursDestroyTaskset2() { cellSpurs->Warning("%s()", __FUNCTION__); #ifdef PRX_DEBUG return GetCurrentPPUThread().FastCall2(libsre + 0x14EE8, libsre_rtoc); #else UNIMPLEMENTED_FUNC(cellSpurs); return CELL_OK; #endif } s64 cellSpursCreateTask2WithBinInfo() { cellSpurs->Warning("%s()", __FUNCTION__); #ifdef PRX_DEBUG return GetCurrentPPUThread().FastCall2(libsre + 0x120E0, libsre_rtoc); #else UNIMPLEMENTED_FUNC(cellSpurs); return CELL_OK; #endif } s64 cellSpursTasksetSetExceptionEventHandler(vm::ptr taskset, vm::ptr handler, vm::ptr arg) { cellSpurs->Warning("%s(taskset=0x5x, handler=0x%x, arg=0x%x)", __FUNCTION__, taskset.addr(), handler.addr(), arg.addr()); #ifdef PRX_DEBUG return GetCurrentPPUThread().FastCall2(libsre + 0x13124, libsre_rtoc); #else if (!taskset || !handler) { return CELL_SPURS_TASK_ERROR_NULL_POINTER; } if (taskset.addr() % CellSpursTaskset::align) { return CELL_SPURS_TASK_ERROR_ALIGN; } if (taskset->m.wid >= CELL_SPURS_MAX_WORKLOAD) { return CELL_SPURS_TASK_ERROR_INVAL; } if (taskset->m.exception_handler != 0) { return CELL_SPURS_TASK_ERROR_BUSY; } taskset->m.exception_handler = handler; taskset->m.exception_handler_arg = arg; return CELL_OK; #endif } s64 cellSpursTasksetUnsetExceptionEventHandler(vm::ptr taskset) { cellSpurs->Warning("%s(taskset=0x%x)", __FUNCTION__, taskset.addr()); #ifdef PRX_DEBUG return GetCurrentPPUThread().FastCall2(libsre + 0x13194, libsre_rtoc); #else if (!taskset) { return CELL_SPURS_TASK_ERROR_NULL_POINTER; } if (taskset.addr() % CellSpursTaskset::align) { return CELL_SPURS_TASK_ERROR_ALIGN; } if (taskset->m.wid >= CELL_SPURS_MAX_WORKLOAD) { return CELL_SPURS_TASK_ERROR_INVAL; } taskset->m.exception_handler.set(0); taskset->m.exception_handler_arg.set(0); return CELL_OK; #endif } s64 cellSpursLookUpTasksetAddress(vm::ptr spurs, vm::ptr taskset, u32 id) { cellSpurs->Warning("%s(spurs=0x%x, taskset=0x%x, id=0x%x)", __FUNCTION__, spurs.addr(), taskset.addr(), id); #ifdef PRX_DEBUG return GetCurrentPPUThread().FastCall2(libsre + 0x133AC, libsre_rtoc); #else if (taskset.addr() == 0) { return CELL_SPURS_TASK_ERROR_NULL_POINTER; } vm::var> data; auto rc = cellSpursGetWorkloadData(spurs, vm::ptr::make(data.addr()), id); if (rc != CELL_OK) { // Convert policy module error code to a task error code return rc ^ 0x100; } taskset.set((u32)data.value()); return CELL_OK; #endif } s64 cellSpursTasksetGetSpursAddress(vm::ptr taskset, vm::ptr spurs) { cellSpurs->Warning("%s(taskset=0x%x, spurs=0x%x)", __FUNCTION__, taskset.addr(), spurs.addr()); #ifdef PRX_DEBUG return GetCurrentPPUThread().FastCall2(libsre + 0x14408, libsre_rtoc); #else if (!taskset || !spurs) { return CELL_SPURS_TASK_ERROR_NULL_POINTER; } if (taskset.addr() % CellSpursTaskset::align) { return CELL_SPURS_TASK_ERROR_ALIGN; } if (taskset->m.wid >= CELL_SPURS_MAX_WORKLOAD) { return CELL_SPURS_TASK_ERROR_INVAL; } *spurs = (u32)taskset->m.spurs.addr(); return CELL_OK; #endif } s64 cellSpursGetTasksetInfo() { cellSpurs->Warning("%s()", __FUNCTION__); #ifdef PRX_DEBUG return GetCurrentPPUThread().FastCall2(libsre + 0x1445C, libsre_rtoc); #else UNIMPLEMENTED_FUNC(cellSpurs); return CELL_OK; #endif } s64 _cellSpursTasksetAttributeInitialize(vm::ptr attribute, u32 revision, u32 sdk_version, u64 args, vm::ptr priority, u32 max_contention) { cellSpurs->Warning("%s(attribute=0x%x, revision=%d, skd_version=%d, args=0x%llx, priority=0x%x, max_contention=%d)", __FUNCTION__, attribute.addr(), revision, sdk_version, args, priority.addr(), max_contention); #ifdef PRX_DEBUG return GetCurrentPPUThread().FastCall2(libsre + 0x142FC, libsre_rtoc); #else if (!attribute) { return CELL_SPURS_TASK_ERROR_NULL_POINTER; } if (attribute.addr() % CellSpursTasksetAttribute::align) { return CELL_SPURS_TASK_ERROR_ALIGN; } for (u32 i = 0; i < 8; i++) { if (priority[i] > 0xF) { return CELL_SPURS_TASK_ERROR_INVAL; } } memset(attribute.get_ptr(), 0, CellSpursTasksetAttribute::size); attribute->m.revision = revision; attribute->m.sdk_version = sdk_version; attribute->m.args = args; memcpy(attribute->m.priority, priority.get_ptr(), 8); attribute->m.taskset_size = CellSpursTaskset::size; attribute->m.max_contention = max_contention; return CELL_OK; #endif } s64 cellSpursJobGuardInitialize() { #ifdef PRX_DEBUG cellSpurs->Warning("%s()", __FUNCTION__); return GetCurrentPPUThread().FastCall2(libsre + 0x1807C, libsre_rtoc); #else UNIMPLEMENTED_FUNC(cellSpurs); return CELL_OK; #endif } s64 cellSpursJobChainAttributeSetName() { #ifdef PRX_DEBUG cellSpurs->Warning("%s()", __FUNCTION__); return GetCurrentPPUThread().FastCall2(libsre + 0x1861C, libsre_rtoc); #else UNIMPLEMENTED_FUNC(cellSpurs); return CELL_OK; #endif } s64 cellSpursShutdownJobChain() { #ifdef PRX_DEBUG cellSpurs->Warning("%s()", __FUNCTION__); return GetCurrentPPUThread().FastCall2(libsre + 0x18D2C, libsre_rtoc); #else UNIMPLEMENTED_FUNC(cellSpurs); return CELL_OK; #endif } s64 cellSpursJobChainAttributeSetHaltOnError() { #ifdef PRX_DEBUG cellSpurs->Warning("%s()", __FUNCTION__); return GetCurrentPPUThread().FastCall2(libsre + 0x18660, libsre_rtoc); #else UNIMPLEMENTED_FUNC(cellSpurs); return CELL_OK; #endif } s64 cellSpursJobChainAttributeSetJobTypeMemoryCheck() { #ifdef PRX_DEBUG cellSpurs->Warning("%s()", __FUNCTION__); return GetCurrentPPUThread().FastCall2(libsre + 0x186A4, libsre_rtoc); #else UNIMPLEMENTED_FUNC(cellSpurs); return CELL_OK; #endif } s64 cellSpursJobGuardNotify() { #ifdef PRX_DEBUG cellSpurs->Warning("%s()", __FUNCTION__); return GetCurrentPPUThread().FastCall2(libsre + 0x17FA4, libsre_rtoc); #else UNIMPLEMENTED_FUNC(cellSpurs); return CELL_OK; #endif } s64 cellSpursJobGuardReset() { #ifdef PRX_DEBUG cellSpurs->Warning("%s()", __FUNCTION__); return GetCurrentPPUThread().FastCall2(libsre + 0x17F60, libsre_rtoc); #else UNIMPLEMENTED_FUNC(cellSpurs); return CELL_OK; #endif } s64 cellSpursRunJobChain() { #ifdef PRX_DEBUG cellSpurs->Warning("%s()", __FUNCTION__); return GetCurrentPPUThread().FastCall2(libsre + 0x18F94, libsre_rtoc); #else UNIMPLEMENTED_FUNC(cellSpurs); return CELL_OK; #endif } s64 cellSpursJobChainGetError() { #ifdef PRX_DEBUG cellSpurs->Warning("%s()", __FUNCTION__); return GetCurrentPPUThread().FastCall2(libsre + 0x190AC, libsre_rtoc); #else UNIMPLEMENTED_FUNC(cellSpurs); return CELL_OK; #endif } s64 cellSpursGetJobPipelineInfo() { #ifdef PRX_DEBUG cellSpurs->Warning("%s()", __FUNCTION__); return GetCurrentPPUThread().FastCall2(libsre + 0x1A954, libsre_rtoc); #else UNIMPLEMENTED_FUNC(cellSpurs); return CELL_OK; #endif } s64 cellSpursJobSetMaxGrab() { #ifdef PRX_DEBUG cellSpurs->Warning("%s()", __FUNCTION__); return GetCurrentPPUThread().FastCall2(libsre + 0x1AC88, libsre_rtoc); #else UNIMPLEMENTED_FUNC(cellSpurs); return CELL_OK; #endif } s64 cellSpursJobHeaderSetJobbin2Param() { #ifdef PRX_DEBUG cellSpurs->Warning("%s()", __FUNCTION__); return GetCurrentPPUThread().FastCall2(libsre + 0x1AD58, libsre_rtoc); #else UNIMPLEMENTED_FUNC(cellSpurs); return CELL_OK; #endif } s64 cellSpursAddUrgentCommand() { #ifdef PRX_DEBUG cellSpurs->Warning("%s()", __FUNCTION__); return GetCurrentPPUThread().FastCall2(libsre + 0x18160, libsre_rtoc); #else UNIMPLEMENTED_FUNC(cellSpurs); return CELL_OK; #endif } s64 cellSpursAddUrgentCall() { #ifdef PRX_DEBUG cellSpurs->Warning("%s()", __FUNCTION__); return GetCurrentPPUThread().FastCall2(libsre + 0x1823C, libsre_rtoc); #else UNIMPLEMENTED_FUNC(cellSpurs); return CELL_OK; #endif } s64 cellSpursBarrierInitialize() { #ifdef PRX_DEBUG cellSpurs->Warning("%s()", __FUNCTION__); return GetCurrentPPUThread().FastCall2(libsre + 0x17CD8, libsre_rtoc); #else UNIMPLEMENTED_FUNC(cellSpurs); return CELL_OK; #endif } s64 cellSpursBarrierGetTasksetAddress() { #ifdef PRX_DEBUG cellSpurs->Warning("%s()", __FUNCTION__); return GetCurrentPPUThread().FastCall2(libsre + 0x17DB0, libsre_rtoc); #else UNIMPLEMENTED_FUNC(cellSpurs); return CELL_OK; #endif } s64 _cellSpursSemaphoreInitialize() { #ifdef PRX_DEBUG cellSpurs->Warning("%s()", __FUNCTION__); return GetCurrentPPUThread().FastCall2(libsre + 0x17DF8, libsre_rtoc); #else UNIMPLEMENTED_FUNC(cellSpurs); return CELL_OK; #endif } s64 cellSpursSemaphoreGetTasksetAddress() { #ifdef PRX_DEBUG cellSpurs->Warning("%s()", __FUNCTION__); return GetCurrentPPUThread().FastCall2(libsre + 0x17F18, libsre_rtoc); #else UNIMPLEMENTED_FUNC(cellSpurs); return CELL_OK; #endif } bool spursIsLibProfLoaded() { return false; } void spursTraceStatusUpdate(vm::ptr spurs) { LV2_LOCK(0); if (spurs->m.xCC != 0) { spurs->m.xCD = 1; spurs->m.sysSrvMsgUpdateTrace = (1 << spurs->m.nSpus) - 1; spurs->m.sysSrvMessage.write_relaxed(0xFF); sys_semaphore_wait((u32)spurs->m.semPrv, 0); } } s64 spursTraceInitialize(vm::ptr spurs, vm::ptr buffer, u32 size, u32 mode, u32 updateStatus) { if (!spurs || !buffer) { return CELL_SPURS_CORE_ERROR_NULL_POINTER; } if (spurs.addr() % CellSpurs::align || buffer.addr() % CellSpursTraceInfo::align) { return CELL_SPURS_CORE_ERROR_ALIGN; } if (size < CellSpursTraceInfo::size || mode & ~(CELL_SPURS_TRACE_MODE_FLAG_MASK)) { return CELL_SPURS_CORE_ERROR_INVAL; } if (spurs->m.traceBuffer != 0) { return CELL_SPURS_CORE_ERROR_STAT; } spurs->m.traceDataSize = size - CellSpursTraceInfo::size; for (u32 i = 0; i < 8; i++) { buffer->spu_thread[i] = spurs->m.spus[i]; buffer->count[i] = 0; } buffer->spu_thread_grp = spurs->m.spuTG; buffer->nspu = spurs->m.nSpus; spurs->m.traceBuffer.set(buffer.addr() | (mode & CELL_SPURS_TRACE_MODE_FLAG_WRAP_BUFFER ? 1 : 0)); spurs->m.traceMode = mode; u32 spuTraceDataCount = (u32)((spurs->m.traceDataSize / CellSpursTracePacket::size) / spurs->m.nSpus); for (u32 i = 0, j = 8; i < 6; i++) { spurs->m.traceStartIndex[i] = j; j += spuTraceDataCount; } spurs->m.sysSrvTraceControl = 0; if (updateStatus) { spursTraceStatusUpdate(spurs); } return CELL_OK; } s64 cellSpursTraceInitialize(vm::ptr spurs, vm::ptr buffer, u32 size, u32 mode) { if (spursIsLibProfLoaded()) { return CELL_SPURS_CORE_ERROR_STAT; } return spursTraceInitialize(spurs, buffer, size, mode, 1); } s64 spursTraceStart(vm::ptr spurs, u32 updateStatus) { if (!spurs) { return CELL_SPURS_CORE_ERROR_NULL_POINTER; } if (spurs.addr() % CellSpurs::align) { return CELL_SPURS_CORE_ERROR_ALIGN; } if (!spurs->m.traceBuffer) { return CELL_SPURS_CORE_ERROR_STAT; } spurs->m.sysSrvTraceControl = 1; if (updateStatus) { spursTraceStatusUpdate(spurs); } return CELL_OK; } s64 cellSpursTraceStart(vm::ptr spurs) { if (!spurs) { return CELL_SPURS_CORE_ERROR_NULL_POINTER; } if (spurs.addr() % CellSpurs::align) { return CELL_SPURS_CORE_ERROR_ALIGN; } return spursTraceStart(spurs, spurs->m.traceMode & CELL_SPURS_TRACE_MODE_FLAG_SYNCHRONOUS_START_STOP); } s64 spursTraceStop(vm::ptr spurs, u32 updateStatus) { if (!spurs) { return CELL_SPURS_CORE_ERROR_NULL_POINTER; } if (spurs.addr() % CellSpurs::align) { return CELL_SPURS_CORE_ERROR_ALIGN; } if (!spurs->m.traceBuffer) { return CELL_SPURS_CORE_ERROR_STAT; } spurs->m.sysSrvTraceControl = 2; if (updateStatus) { spursTraceStatusUpdate(spurs); } return CELL_OK; } s64 cellSpursTraceStop(vm::ptr spurs) { if (!spurs) { return CELL_SPURS_CORE_ERROR_NULL_POINTER; } if (spurs.addr() % CellSpurs::align) { return CELL_SPURS_CORE_ERROR_ALIGN; } return spursTraceStop(spurs, spurs->m.traceMode & CELL_SPURS_TRACE_MODE_FLAG_SYNCHRONOUS_START_STOP); } s64 cellSpursTraceFinalize(vm::ptr spurs) { if (!spurs) { return CELL_SPURS_CORE_ERROR_NULL_POINTER; } if (spurs.addr() % CellSpurs::align) { return CELL_SPURS_CORE_ERROR_ALIGN; } if (!spurs->m.traceBuffer) { return CELL_SPURS_CORE_ERROR_STAT; } spurs->m.sysSrvTraceControl = 0; spurs->m.traceMode = 0; spurs->m.traceBuffer.set(0); spursTraceStatusUpdate(spurs); return CELL_OK; } void cellSpurs_init(Module *pxThis) { cellSpurs = pxThis; // Core REG_FUNC(cellSpurs, cellSpursInitialize); REG_FUNC(cellSpurs, cellSpursInitializeWithAttribute); REG_FUNC(cellSpurs, cellSpursInitializeWithAttribute2); REG_FUNC(cellSpurs, cellSpursFinalize); REG_FUNC(cellSpurs, _cellSpursAttributeInitialize); REG_FUNC(cellSpurs, cellSpursAttributeSetMemoryContainerForSpuThread); REG_FUNC(cellSpurs, cellSpursAttributeSetNamePrefix); REG_FUNC(cellSpurs, cellSpursAttributeEnableSpuPrintfIfAvailable); REG_FUNC(cellSpurs, cellSpursAttributeSetSpuThreadGroupType); REG_FUNC(cellSpurs, cellSpursAttributeEnableSystemWorkload); REG_FUNC(cellSpurs, cellSpursGetSpuThreadGroupId); REG_FUNC(cellSpurs, cellSpursGetNumSpuThread); REG_FUNC(cellSpurs, cellSpursGetSpuThreadId); REG_FUNC(cellSpurs, cellSpursGetInfo); REG_FUNC(cellSpurs, cellSpursSetMaxContention); REG_FUNC(cellSpurs, cellSpursSetPriorities); REG_FUNC(cellSpurs, cellSpursSetPreemptionVictimHints); REG_FUNC(cellSpurs, cellSpursAttachLv2EventQueue); REG_FUNC(cellSpurs, cellSpursDetachLv2EventQueue); REG_FUNC(cellSpurs, cellSpursEnableExceptionEventHandler); REG_FUNC(cellSpurs, cellSpursSetGlobalExceptionEventHandler); REG_FUNC(cellSpurs, cellSpursUnsetGlobalExceptionEventHandler); REG_FUNC(cellSpurs, cellSpursSetExceptionEventHandler); REG_FUNC(cellSpurs, cellSpursUnsetExceptionEventHandler); // Event flag REG_FUNC(cellSpurs, _cellSpursEventFlagInitialize); REG_FUNC(cellSpurs, cellSpursEventFlagAttachLv2EventQueue); REG_FUNC(cellSpurs, cellSpursEventFlagDetachLv2EventQueue); REG_FUNC(cellSpurs, cellSpursEventFlagWait); REG_FUNC(cellSpurs, cellSpursEventFlagClear); REG_FUNC(cellSpurs, cellSpursEventFlagSet); REG_FUNC(cellSpurs, cellSpursEventFlagTryWait); REG_FUNC(cellSpurs, cellSpursEventFlagGetDirection); REG_FUNC(cellSpurs, cellSpursEventFlagGetClearMode); REG_FUNC(cellSpurs, cellSpursEventFlagGetTasksetAddress); // Taskset REG_FUNC(cellSpurs, cellSpursCreateTaskset); REG_FUNC(cellSpurs, cellSpursCreateTasksetWithAttribute); REG_FUNC(cellSpurs, _cellSpursTasksetAttributeInitialize); REG_FUNC(cellSpurs, _cellSpursTasksetAttribute2Initialize); REG_FUNC(cellSpurs, cellSpursTasksetAttributeSetName); REG_FUNC(cellSpurs, cellSpursTasksetAttributeSetTasksetSize); REG_FUNC(cellSpurs, cellSpursTasksetAttributeEnableClearLS); REG_FUNC(cellSpurs, cellSpursJoinTaskset); REG_FUNC(cellSpurs, cellSpursGetTasksetId); REG_FUNC(cellSpurs, cellSpursShutdownTaskset); REG_FUNC(cellSpurs, cellSpursCreateTask); REG_FUNC(cellSpurs, cellSpursCreateTaskWithAttribute); REG_FUNC(cellSpurs, _cellSpursTaskAttributeInitialize); REG_FUNC(cellSpurs, _cellSpursTaskAttribute2Initialize); REG_FUNC(cellSpurs, cellSpursTaskAttributeSetExitCodeContainer); REG_FUNC(cellSpurs, cellSpursTaskExitCodeGet); REG_FUNC(cellSpurs, cellSpursTaskExitCodeInitialize); REG_FUNC(cellSpurs, cellSpursTaskExitCodeTryGet); REG_FUNC(cellSpurs, cellSpursTaskGetLoadableSegmentPattern); REG_FUNC(cellSpurs, cellSpursTaskGetReadOnlyAreaPattern); REG_FUNC(cellSpurs, cellSpursTaskGenerateLsPattern); REG_FUNC(cellSpurs, cellSpursTaskGetContextSaveAreaSize); REG_FUNC(cellSpurs, _cellSpursSendSignal); REG_FUNC(cellSpurs, cellSpursCreateTaskset2); REG_FUNC(cellSpurs, cellSpursCreateTask2); REG_FUNC(cellSpurs, cellSpursJoinTask2); REG_FUNC(cellSpurs, cellSpursTryJoinTask2); REG_FUNC(cellSpurs, cellSpursDestroyTaskset2); REG_FUNC(cellSpurs, cellSpursCreateTask2WithBinInfo); REG_FUNC(cellSpurs, cellSpursLookUpTasksetAddress); REG_FUNC(cellSpurs, cellSpursTasksetGetSpursAddress); REG_FUNC(cellSpurs, cellSpursGetTasksetInfo); REG_FUNC(cellSpurs, cellSpursTasksetSetExceptionEventHandler); REG_FUNC(cellSpurs, cellSpursTasksetUnsetExceptionEventHandler); // Job Chain REG_FUNC(cellSpurs, cellSpursCreateJobChain); REG_FUNC(cellSpurs, cellSpursCreateJobChainWithAttribute); REG_FUNC(cellSpurs, cellSpursShutdownJobChain); REG_FUNC(cellSpurs, cellSpursJoinJobChain); REG_FUNC(cellSpurs, cellSpursKickJobChain); REG_FUNC(cellSpurs, cellSpursRunJobChain); REG_FUNC(cellSpurs, cellSpursJobChainGetError); REG_FUNC(cellSpurs, _cellSpursJobChainAttributeInitialize); REG_FUNC(cellSpurs, cellSpursJobChainAttributeSetName); REG_FUNC(cellSpurs, cellSpursJobChainAttributeSetHaltOnError); REG_FUNC(cellSpurs, cellSpursJobChainAttributeSetJobTypeMemoryCheck); REG_FUNC(cellSpurs, cellSpursGetJobChainId); REG_FUNC(cellSpurs, cellSpursJobChainSetExceptionEventHandler); REG_FUNC(cellSpurs, cellSpursJobChainUnsetExceptionEventHandler); REG_FUNC(cellSpurs, cellSpursGetJobChainInfo); REG_FUNC(cellSpurs, cellSpursJobChainGetSpursAddress); // Job Guard REG_FUNC(cellSpurs, cellSpursJobGuardInitialize); REG_FUNC(cellSpurs, cellSpursJobGuardNotify); REG_FUNC(cellSpurs, cellSpursJobGuardReset); // LFQueue REG_FUNC(cellSpurs, _cellSpursLFQueueInitialize); REG_FUNC(cellSpurs, _cellSpursLFQueuePushBody); REG_FUNC(cellSpurs, cellSpursLFQueueAttachLv2EventQueue); REG_FUNC(cellSpurs, cellSpursLFQueueDetachLv2EventQueue); REG_FUNC(cellSpurs, _cellSpursLFQueuePopBody); REG_FUNC(cellSpurs, cellSpursLFQueueGetTasksetAddress); // Queue REG_FUNC(cellSpurs, _cellSpursQueueInitialize); REG_FUNC(cellSpurs, cellSpursQueuePopBody); REG_FUNC(cellSpurs, cellSpursQueuePushBody); REG_FUNC(cellSpurs, cellSpursQueueAttachLv2EventQueue); REG_FUNC(cellSpurs, cellSpursQueueDetachLv2EventQueue); REG_FUNC(cellSpurs, cellSpursQueueGetTasksetAddress); REG_FUNC(cellSpurs, cellSpursQueueClear); REG_FUNC(cellSpurs, cellSpursQueueDepth); REG_FUNC(cellSpurs, cellSpursQueueGetEntrySize); REG_FUNC(cellSpurs, cellSpursQueueSize); REG_FUNC(cellSpurs, cellSpursQueueGetDirection); // Workload REG_FUNC(cellSpurs, cellSpursWorkloadAttributeSetName); REG_FUNC(cellSpurs, cellSpursWorkloadAttributeSetShutdownCompletionEventHook); REG_FUNC(cellSpurs, cellSpursAddWorkloadWithAttribute); REG_FUNC(cellSpurs, cellSpursAddWorkload); REG_FUNC(cellSpurs, cellSpursShutdownWorkload); REG_FUNC(cellSpurs, cellSpursWaitForWorkloadShutdown); REG_FUNC(cellSpurs, cellSpursRemoveWorkload); REG_FUNC(cellSpurs, cellSpursReadyCountStore); REG_FUNC(cellSpurs, cellSpursGetWorkloadFlag); REG_FUNC(cellSpurs, _cellSpursWorkloadFlagReceiver); REG_FUNC(cellSpurs, _cellSpursWorkloadAttributeInitialize); REG_FUNC(cellSpurs, cellSpursSendWorkloadSignal); REG_FUNC(cellSpurs, cellSpursGetWorkloadData); REG_FUNC(cellSpurs, cellSpursReadyCountAdd); REG_FUNC(cellSpurs, cellSpursReadyCountCompareAndSwap); REG_FUNC(cellSpurs, cellSpursReadyCountSwap); REG_FUNC(cellSpurs, cellSpursRequestIdleSpu); REG_FUNC(cellSpurs, cellSpursGetWorkloadInfo); REG_FUNC(cellSpurs, cellSpursGetSpuGuid); REG_FUNC(cellSpurs, _cellSpursWorkloadFlagReceiver2); REG_FUNC(cellSpurs, cellSpursGetJobPipelineInfo); REG_FUNC(cellSpurs, cellSpursJobSetMaxGrab); REG_FUNC(cellSpurs, cellSpursJobHeaderSetJobbin2Param); REG_FUNC(cellSpurs, cellSpursWakeUp); REG_FUNC(cellSpurs, cellSpursAddUrgentCommand); REG_FUNC(cellSpurs, cellSpursAddUrgentCall); REG_FUNC(cellSpurs, cellSpursBarrierInitialize); REG_FUNC(cellSpurs, cellSpursBarrierGetTasksetAddress); REG_FUNC(cellSpurs, _cellSpursSemaphoreInitialize); REG_FUNC(cellSpurs, cellSpursSemaphoreGetTasksetAddress); // Trace REG_FUNC(cellSpurs, cellSpursTraceInitialize); REG_FUNC(cellSpurs, cellSpursTraceStart); REG_FUNC(cellSpurs, cellSpursTraceStop); REG_FUNC(cellSpurs, cellSpursTraceFinalize); }