#include "stdafx.h" #include "Emu/System.h" #include "Emu/IdManager.h" #include "Emu/Cell/PPUModule.h" #include "Emu/Cell/lv2/sys_fs.h" #include "Emu/Cell/lv2/sys_sync.h" #include "cellFs.h" #include "Utilities/StrUtil.h" #include namespace vm { using namespace ps3; } logs::channel cellFs("cellFs", logs::level::notice); s32 cellFsAccess() { UNIMPLEMENTED_FUNC(cellFs); return CELL_OK; } s32 cellFsOpen(vm::cptr path, s32 flags, vm::ptr fd, vm::cptr arg, u64 size) { cellFs.warning("cellFsOpen(path=%s, flags=%#o, fd=*0x%x, arg=*0x%x, size=0x%llx) -> sys_fs_open()", path, flags, fd, arg, size); // TODO // call the syscall return sys_fs_open(path, flags, fd, flags & CELL_FS_O_CREAT ? CELL_FS_S_IRUSR | CELL_FS_S_IWUSR : 0, arg, size); } s32 cellFsOpen2() { UNIMPLEMENTED_FUNC(cellFs); return CELL_OK; } s32 cellFsRead(u32 fd, vm::ptr buf, u64 nbytes, vm::ptr nread) { cellFs.trace("cellFsRead(fd=0x%x, buf=0x%x, nbytes=0x%llx, nread=0x%x)", fd, buf, nbytes, nread); // call the syscall return sys_fs_read(fd, buf, nbytes, nread ? nread : vm::var{}); } s32 cellFsWrite(u32 fd, vm::cptr buf, u64 nbytes, vm::ptr nwrite) { cellFs.trace("cellFsWrite(fd=0x%x, buf=*0x%x, nbytes=0x%llx, nwrite=*0x%x)", fd, buf, nbytes, nwrite); // call the syscall return sys_fs_write(fd, buf, nbytes, nwrite ? nwrite : vm::var{}); } s32 cellFsClose(u32 fd) { cellFs.trace("cellFsClose(fd=0x%x)", fd); // call the syscall return sys_fs_close(fd); } s32 cellFsOpendir(vm::cptr path, vm::ptr fd) { cellFs.warning("cellFsOpendir(path=%s, fd=*0x%x) -> sys_fs_opendir()", path, fd); // TODO // call the syscall return sys_fs_opendir(path, fd); } s32 cellFsReaddir(u32 fd, vm::ptr dir, vm::ptr nread) { cellFs.trace("cellFsReaddir(fd=0x%x, dir=*0x%x, nread=*0x%x)", fd, dir, nread); if (!dir || !nread) { return CELL_EFAULT; } // call the syscall return sys_fs_readdir(fd, dir, nread); } s32 cellFsClosedir(u32 fd) { cellFs.trace("cellFsClosedir(fd=0x%x)", fd); // call the syscall return sys_fs_closedir(fd); } s32 cellFsStat(vm::cptr path, vm::ptr sb) { cellFs.warning("cellFsStat(path=%s, sb=*0x%x) -> sys_fs_stat()", path, sb); // TODO // call the syscall return sys_fs_stat(path, sb); } s32 cellFsFstat(u32 fd, vm::ptr sb) { cellFs.trace("cellFsFstat(fd=0x%x, sb=*0x%x)", fd, sb); // call the syscall return sys_fs_fstat(fd, sb); } s32 cellFsMkdir(vm::cptr path, s32 mode) { cellFs.warning("cellFsMkdir(path=%s, mode=%#o) -> sys_fs_mkdir()", path, mode); // TODO // call the syscall return sys_fs_mkdir(path, mode); } s32 cellFsRename(vm::cptr from, vm::cptr to) { cellFs.warning("cellFsRename(from=%s, to=%s) -> sys_fs_rename()", from, to); // TODO // call the syscall return sys_fs_rename(from, to); } s32 cellFsRmdir(vm::cptr path) { cellFs.warning("cellFsRmdir(path=%s) -> sys_fs_rmdir()", path); // TODO // call the syscall return sys_fs_rmdir(path); } s32 cellFsUnlink(vm::cptr path) { cellFs.warning("cellFsUnlink(path=%s) -> sys_fs_unlink()", path); // TODO // call the syscall return sys_fs_unlink(path); } s32 cellFsLseek(u32 fd, s64 offset, u32 whence, vm::ptr pos) { cellFs.trace("cellFsLseek(fd=0x%x, offset=0x%llx, whence=0x%x, pos=*0x%x)", fd, offset, whence, pos); if (!pos) { return CELL_EFAULT; } // call the syscall return sys_fs_lseek(fd, offset, whence, pos); } s32 cellFsFdatasync(u32 fd) { cellFs.trace("cellFsFdatasync(fd=%d)", fd); // Call the syscall return sys_fs_fdatasync(fd); } s32 cellFsFsync(u32 fd) { cellFs.trace("cellFsFsync(fd=%d)", fd); // Call the syscall return sys_fs_fsync(fd); } s32 cellFsFGetBlockSize(u32 fd, vm::ptr sector_size, vm::ptr block_size) { cellFs.trace("cellFsFGetBlockSize(fd=0x%x, sector_size=*0x%x, block_size=*0x%x)", fd, sector_size, block_size); if (!sector_size || !block_size) { return CELL_EFAULT; } // call the syscall return sys_fs_fget_block_size(fd, sector_size, block_size, vm::var{}, vm::var{}); } s32 cellFsFGetBlockSize2() { UNIMPLEMENTED_FUNC(cellFs); return CELL_OK; } s32 cellFsGetBlockSize(vm::cptr path, vm::ptr sector_size, vm::ptr block_size) { cellFs.warning("cellFsGetBlockSize(path=%s, sector_size=*0x%x, block_size=*0x%x) -> sys_fs_get_block_size()", path, sector_size, block_size); // TODO // call the syscall return sys_fs_get_block_size(path, sector_size, block_size, vm::var{}); } s32 cellFsGetBlockSize2() { UNIMPLEMENTED_FUNC(cellFs); return CELL_OK; } s32 cellFsTruncate(vm::cptr path, u64 size) { cellFs.warning("cellFsTruncate(path=%s, size=0x%llx) -> sys_fs_truncate()", path, size); // TODO // call the syscall return sys_fs_truncate(path, size); } s32 cellFsFtruncate(u32 fd, u64 size) { cellFs.trace("cellFsFtruncate(fd=0x%x, size=0x%llx)", fd, size); // call the syscall return sys_fs_ftruncate(fd, size); } s32 cellFsChmod(vm::cptr path, s32 mode) { cellFs.warning("cellFsChmod(path=%s, mode=%#o) -> sys_fs_chmod()", path, mode); // TODO // call the syscall return sys_fs_chmod(path, mode); } s32 cellFsChown() { UNIMPLEMENTED_FUNC(cellFs); return CELL_OK; } s32 cellFsUtime(vm::cptr path, vm::cptr timep) { cellFs.warning("cellFsUtime(path=%s, timep=*0x%x) -> sys_fs_utime()", path, timep); // TODO // Call the syscall return sys_fs_utime(path, timep); } s32 cellFsGetFreeSize(vm::cptr path, vm::ptr block_size, vm::ptr block_count) { cellFs.warning("cellFsGetFreeSize(path=%s, block_size=*0x%x, block_count=*0x%x)", path, block_size, block_count); // TODO: Get real values. Currently, it always returns 40 GB of free space divided in 4 KB blocks *block_size = 4096; // ? *block_count = 10 * 1024 * 1024; // ? return CELL_OK; } error_code cellFsGetDirectoryEntries(u32 fd, vm::ptr entries, u32 entries_size, vm::ptr data_count) { cellFs.trace("cellFsGetDirectoryEntries(fd=%d, entries=*0x%x, entries_size=0x%x, data_count=*0x%x)", fd, entries, entries_size, data_count); if (!data_count || !entries) { return CELL_EFAULT; } if (fd - 3 > 252) { return CELL_EBADF; } vm::var op; op->_vtable = vm::cast(0xfae12000); // Intentionally wrong (provide correct vtable if necessary) op->op = 0xe0000012; op->arg._code = 0; op->arg._size = 0; op->arg.ptr = entries; op->arg.max = entries_size / sizeof(CellFsDirectoryEntry); // Call the syscall const s32 rc = sys_fs_fcntl(fd, 0xe0000012, op.ptr(&lv2_file_op_dir::arg), 0x10); *data_count = op->arg._size; // Select the result return not_an_error(rc ? rc : +op->arg._code); } error_code cellFsReadWithOffset(u32 fd, u64 offset, vm::ptr buf, u64 buffer_size, vm::ptr nread) { cellFs.trace("cellFsReadWithOffset(fd=%d, offset=0x%llx, buf=*0x%x, buffer_size=0x%llx, nread=*0x%x)", fd, offset, buf, buffer_size, nread); if (fd - 3 > 252) { if (nread) *nread = 0; return CELL_EBADF; } vm::var arg; arg->_vtable = vm::cast(0xfa8a0000); // Intentionally wrong (provide correct vtable if necessary) arg->op = 0x8000000a; arg->fd = fd; arg->buf = buf; arg->offset = offset; arg->size = buffer_size; // Call the syscall const s32 rc = sys_fs_fcntl(fd, 0x8000000a, arg, arg.size()); // Write size read if (nread) *nread = rc && rc != CELL_EFSSPECIFIC ? 0 : arg->out_size.value(); return not_an_error(rc ? rc : arg->out_code.value()); } error_code cellFsWriteWithOffset(u32 fd, u64 offset, vm::cptr buf, u64 data_size, vm::ptr nwrite) { cellFs.trace("cellFsWriteWithOffset(fd=%d, offset=0x%llx, buf=*0x%x, data_size=0x%llx, nwrite=*0x%x)", fd, offset, buf, data_size, nwrite); if (!buf) { if (nwrite) *nwrite = 0; return CELL_EFAULT; } if (fd - 3 > 252) { if (nwrite) *nwrite = 0; return CELL_EBADF; } vm::var arg; arg->_vtable = vm::cast(0xfa8b0000); // Intentionally wrong (provide correct vtable if necessary) arg->op = 0x8000000b; arg->fd = fd; arg->buf = vm::const_ptr_cast(buf); arg->offset = offset; arg->size = data_size; // Call the syscall const s32 rc = sys_fs_fcntl(fd, 0x8000000b, arg, arg.size()); // Write size written if (nwrite) *nwrite = rc && rc != CELL_EFSSPECIFIC ? 0 : arg->out_size.value(); return not_an_error(rc ? rc : arg->out_code.value()); } s32 cellFsStReadInit(u32 fd, vm::cptr ringbuf) { cellFs.todo("cellFsStReadInit(fd=%d, ringbuf=*0x%x)", fd, ringbuf); if (ringbuf->copy & ~CELL_FS_ST_COPYLESS) { return CELL_EINVAL; } if (ringbuf->block_size & 0xfff) // check if a multiple of sector size { return CELL_EINVAL; } if (ringbuf->ringbuf_size % ringbuf->block_size) // check if a multiple of block_size { return CELL_EINVAL; } const auto file = idm::get(fd); if (!file) { return CELL_EBADF; } if (file->flags & CELL_FS_O_WRONLY) { return CELL_EPERM; } // TODO return CELL_OK; } s32 cellFsStReadFinish(u32 fd) { cellFs.todo("cellFsStReadFinish(fd=%d)", fd); const auto file = idm::get(fd); if (!file) { return CELL_EBADF; // ??? } // TODO return CELL_OK; } s32 cellFsStReadGetRingBuf(u32 fd, vm::ptr ringbuf) { cellFs.todo("cellFsStReadGetRingBuf(fd=%d, ringbuf=*0x%x)", fd, ringbuf); const auto file = idm::get(fd); if (!file) { return CELL_EBADF; } // TODO return CELL_OK; } s32 cellFsStReadGetStatus(u32 fd, vm::ptr status) { cellFs.todo("cellFsStReadGetRingBuf(fd=%d, status=*0x%x)", fd, status); const auto file = idm::get(fd); if (!file) { return CELL_EBADF; } // TODO return CELL_OK; } s32 cellFsStReadGetRegid(u32 fd, vm::ptr regid) { cellFs.todo("cellFsStReadGetRingBuf(fd=%d, regid=*0x%x)", fd, regid); const auto file = idm::get(fd); if (!file) { return CELL_EBADF; } // TODO return CELL_OK; } s32 cellFsStReadStart(u32 fd, u64 offset, u64 size) { cellFs.todo("cellFsStReadStart(fd=%d, offset=0x%llx, size=0x%llx)", fd, offset, size); const auto file = idm::get(fd); if (!file) { return CELL_EBADF; } // TODO return CELL_OK; } s32 cellFsStReadStop(u32 fd) { cellFs.todo("cellFsStReadStop(fd=%d)", fd); const auto file = idm::get(fd); if (!file) { return CELL_EBADF; } // TODO return CELL_OK; } s32 cellFsStRead(u32 fd, vm::ptr buf, u64 size, vm::ptr rsize) { cellFs.todo("cellFsStRead(fd=%d, buf=*0x%x, size=0x%llx, rsize=*0x%x)", fd, buf, size, rsize); const auto file = idm::get(fd); if (!file) { return CELL_EBADF; } // TODO return CELL_OK; } s32 cellFsStReadGetCurrentAddr(u32 fd, vm::ptr addr, vm::ptr size) { cellFs.todo("cellFsStReadGetCurrentAddr(fd=%d, addr=*0x%x, size=*0x%x)", fd, addr, size); const auto file = idm::get(fd); if (!file) { return CELL_EBADF; } // TODO return CELL_OK; } s32 cellFsStReadPutCurrentAddr(u32 fd, vm::ptr addr, u64 size) { cellFs.todo("cellFsStReadPutCurrentAddr(fd=%d, addr=*0x%x, size=0x%llx)", fd, addr, size); const auto file = idm::get(fd); if (!file) { return CELL_EBADF; } // TODO return CELL_OK; } s32 cellFsStReadWait(u32 fd, u64 size) { cellFs.todo("cellFsStReadWait(fd=%d, size=0x%llx)", fd, size); const auto file = idm::get(fd); if (!file) { return CELL_EBADF; } // TODO return CELL_OK; } s32 cellFsStReadWaitCallback(u32 fd, u64 size, vm::ptr func) { cellFs.todo("cellFsStReadWaitCallback(fd=%d, size=0x%llx, func=*0x%x)", fd, size, func); const auto file = idm::get(fd); if (!file) { return CELL_EBADF; } // TODO return CELL_OK; } s32 cellFsSdataOpen(vm::cptr path, s32 flags, vm::ptr fd, vm::cptr arg, u64 size) { cellFs.notice("cellFsSdataOpen(path=%s, flags=%#o, fd=*0x%x, arg=*0x%x, size=0x%llx)", path, flags, fd, arg, size); if (flags != CELL_FS_O_RDONLY) { return CELL_EINVAL; } return cellFsOpen(path, CELL_FS_O_RDONLY, fd, vm::make_var[2]>({0x180, 0x10}), 8); } s32 cellFsSdataOpenByFd(u32 mself_fd, s32 flags, vm::ptr sdata_fd, u64 offset, vm::cptr arg, u64 size) { cellFs.notice("cellFsSdataOpenByFd(mself_fd=0x%x, flags=%#o, sdata_fd=*0x%x, offset=0x%llx, arg=*0x%x, size=0x%llx)", mself_fd, flags, sdata_fd, offset, arg, size); if (!sdata_fd) { return CELL_EFAULT; } *sdata_fd = -1; if (mself_fd < 3 || mself_fd > 255) { return CELL_EBADF; } if (flags) { return CELL_EINVAL; } vm::var ctrl; ctrl->_vtable = vm::cast(0xfa880000); // Intentionally wrong (provide correct vtable if necessary) ctrl->op = 0x80000009; ctrl->fd = mself_fd; ctrl->offset = offset; ctrl->_vtabl2 = vm::cast(0xfa880020); ctrl->arg1 = 0x180; ctrl->arg2 = 0x10; ctrl->arg_ptr = arg.addr(); ctrl->arg_size = u32(size); if (const s32 rc = sys_fs_fcntl(mself_fd, 0x80000009, ctrl, 0x40)) { return rc; } if (const s32 rc = ctrl->out_code) { return rc; } *sdata_fd = ctrl->out_fd; return CELL_OK; } s32 cellFsSdataOpenWithVersion() { UNIMPLEMENTED_FUNC(cellFs); return CELL_OK; } using fs_aio_cb_t = vm::ptr xaio, s32 error, s32 xid, u64 size)>; // temporarily struct lv2_fs_mount_point { std::mutex mutex; }; struct fs_aio_thread : ppu_thread { using ppu_thread::ppu_thread; virtual void cpu_task() override { while (cmd64 cmd = cmd_wait()) { const u32 type = cmd.arg1(); const s32 xid = cmd.arg2(); const cmd64 cmd2 = cmd_get(1); const auto aio = cmd2.arg1>(); const auto func = cmd2.arg2(); cmd_pop(1); s32 error = CELL_OK; u64 result = 0; const auto file = idm::get(aio->fd); if (!file || (type == 1 && file->flags & CELL_FS_O_WRONLY) || (type == 2 && !(file->flags & CELL_FS_O_ACCMODE))) { error = CELL_EBADF; } else { std::lock_guard lock(file->mp->mutex); const auto old_pos = file->file.pos(); file->file.seek(aio->offset); result = type == 2 ? file->op_write(aio->buf, aio->size) : file->op_read(aio->buf, aio->size); file->file.seek(old_pos); } func(*this, aio, error, xid, result); lv2_obj::sleep(*this); } } }; struct fs_aio_manager { std::shared_ptr thread; }; s32 cellFsAioInit(vm::cptr mount_point) { cellFs.warning("cellFsAioInit(mount_point=%s)", mount_point); // TODO: create AIO thread (if not exists) for specified mount point const auto m = fxm::make(); if (m) { m->thread = idm::make_ptr("FS AIO Thread", 500); m->thread->run(); } return CELL_OK; } s32 cellFsAioFinish(vm::cptr mount_point) { cellFs.warning("cellFsAioFinish(mount_point=%s)", mount_point); // TODO: delete existing AIO thread for specified mount point return CELL_OK; } atomic_t g_fs_aio_id; s32 cellFsAioRead(vm::ptr aio, vm::ptr id, fs_aio_cb_t func) { cellFs.warning("cellFsAioRead(aio=*0x%x, id=*0x%x, func=*0x%x)", aio, id, func); // TODO: detect mount point and send AIO request to the AIO thread of this mount point const auto m = fxm::get(); if (!m) { return CELL_ENXIO; } const s32 xid = (*id = ++g_fs_aio_id); m->thread->cmd_list ({ { 1, xid }, { aio, func }, }); m->thread->notify(); return CELL_OK; } s32 cellFsAioWrite(vm::ptr aio, vm::ptr id, fs_aio_cb_t func) { cellFs.warning("cellFsAioWrite(aio=*0x%x, id=*0x%x, func=*0x%x)", aio, id, func); // TODO: detect mount point and send AIO request to the AIO thread of this mount point const auto m = fxm::get(); if (!m) { return CELL_ENXIO; } const s32 xid = (*id = ++g_fs_aio_id); m->thread->cmd_list ({ { 2, xid }, { aio, func }, }); m->thread->notify(); return CELL_OK; } s32 cellFsAioCancel(s32 id) { cellFs.todo("cellFsAioCancel(id=%d) -> CELL_EINVAL", id); // TODO: cancelled requests return CELL_ECANCELED through their own callbacks return CELL_EINVAL; } s32 cellFsSetDefaultContainer(u32 id, u32 total_limit) { cellFs.todo("cellFsSetDefaultContainer(id=0x%x, total_limit=%d)", id, total_limit); return CELL_OK; } s32 cellFsSetIoBufferFromDefaultContainer(u32 fd, u32 buffer_size, u32 page_type) { cellFs.todo("cellFsSetIoBufferFromDefaultContainer(fd=%d, buffer_size=%d, page_type=%d)", fd, buffer_size, page_type); const auto file = idm::get(fd); if (!file) { return CELL_EBADF; } return CELL_OK; } s32 cellFsArcadeHddSerialNumber() { fmt::throw_exception("Unimplemented" HERE); } s32 cellFsAllocateFileAreaWithInitialData() { fmt::throw_exception("Unimplemented" HERE); } s32 cellFsAllocateFileAreaByFdWithoutZeroFill() { fmt::throw_exception("Unimplemented" HERE); } s32 cellFsSetIoBuffer() { fmt::throw_exception("Unimplemented" HERE); } s32 cellFsAllocateFileAreaByFdWithInitialData() { fmt::throw_exception("Unimplemented" HERE); } s32 cellFsTruncate2() { fmt::throw_exception("Unimplemented" HERE); } s32 cellFsChangeFileSizeWithoutAllocation() { fmt::throw_exception("Unimplemented" HERE); } s32 cellFsAllocateFileAreaWithoutZeroFill(vm::cptr path, u64 size) { cellFs.warning("cellFsAllocateFileAreaWithoutZeroFill(path=%s, size=0x%llx)", path, size); return sys_fs_truncate(path, size); } s32 cellFsChangeFileSizeByFdWithoutAllocation() { fmt::throw_exception("Unimplemented" HERE); } s32 cellFsSetDiscReadRetrySetting() { fmt::throw_exception("Unimplemented" HERE); } s32 cellFsRegisterConversionCallback() { fmt::throw_exception("Unimplemented" HERE); } s32 cellFsUnregisterL10nCallbacks() { fmt::throw_exception("Unimplemented" HERE); } s32 cellFsAclRead() { UNIMPLEMENTED_FUNC(cellFs); return CELL_OK; } s32 cellFsAclWrite() { UNIMPLEMENTED_FUNC(cellFs); return CELL_OK; } s32 cellFsFcntl() { UNIMPLEMENTED_FUNC(cellFs); return CELL_OK; } s32 cellFsLink() { UNIMPLEMENTED_FUNC(cellFs); return CELL_OK; } s32 cellFsLsnGetCDA() { UNIMPLEMENTED_FUNC(cellFs); return CELL_OK; } s32 cellFsLsnGetCDASize() { UNIMPLEMENTED_FUNC(cellFs); return CELL_OK; } s32 cellFsLsnLock() { UNIMPLEMENTED_FUNC(cellFs); return CELL_OK; } s32 cellFsLsnRead() { UNIMPLEMENTED_FUNC(cellFs); return CELL_OK; } s32 cellFsLsnRead2() { UNIMPLEMENTED_FUNC(cellFs); return CELL_OK; } s32 cellFsLsnUnlock() { UNIMPLEMENTED_FUNC(cellFs); return CELL_OK; } s32 cellFsMappedAllocate() { UNIMPLEMENTED_FUNC(cellFs); return CELL_OK; } s32 cellFsMappedFree() { UNIMPLEMENTED_FUNC(cellFs); return CELL_OK; } s32 cellFsSymbolicLink() { UNIMPLEMENTED_FUNC(cellFs); return CELL_OK; } DECLARE(ppu_module_manager::cellFs)("sys_fs", []() { REG_FUNC(sys_fs, cellFsAccess); REG_FUNC(sys_fs, cellFsOpen); REG_FUNC(sys_fs, cellFsOpen2); REG_FUNC(sys_fs, cellFsSdataOpen); REG_FUNC(sys_fs, cellFsSdataOpenByFd); REG_FUNC(sys_fs, cellFsSdataOpenWithVersion); REG_FUNC(sys_fs, cellFsRead).flags = MFF_PERFECT; REG_FUNC(sys_fs, cellFsWrite).flags = MFF_PERFECT; REG_FUNC(sys_fs, cellFsClose).flags = MFF_PERFECT; REG_FUNC(sys_fs, cellFsOpendir); REG_FUNC(sys_fs, cellFsReaddir).flags = MFF_PERFECT; REG_FUNC(sys_fs, cellFsClosedir).flags = MFF_PERFECT; REG_FUNC(sys_fs, cellFsStat); REG_FUNC(sys_fs, cellFsFstat).flags = MFF_PERFECT; REG_FUNC(sys_fs, cellFsMkdir); REG_FUNC(sys_fs, cellFsRename); REG_FUNC(sys_fs, cellFsChmod); REG_FUNC(sys_fs, cellFsChown); REG_FUNC(sys_fs, cellFsFsync); REG_FUNC(sys_fs, cellFsRmdir); REG_FUNC(sys_fs, cellFsUnlink); REG_FUNC(sys_fs, cellFsLseek).flags = MFF_PERFECT; REG_FUNC(sys_fs, cellFsFtruncate).flags = MFF_PERFECT; REG_FUNC(sys_fs, cellFsTruncate); REG_FUNC(sys_fs, cellFsFGetBlockSize).flags = MFF_PERFECT; REG_FUNC(sys_fs, cellFsFGetBlockSize2); REG_FUNC(sys_fs, cellFsAioInit); REG_FUNC(sys_fs, cellFsAioFinish); REG_FUNC(sys_fs, cellFsAioRead); REG_FUNC(sys_fs, cellFsAioWrite); REG_FUNC(sys_fs, cellFsAioCancel); REG_FUNC(sys_fs, cellFsGetBlockSize); REG_FUNC(sys_fs, cellFsGetBlockSize2); REG_FUNC(sys_fs, cellFsGetFreeSize); REG_FUNC(sys_fs, cellFsReadWithOffset); REG_FUNC(sys_fs, cellFsWriteWithOffset); REG_FUNC(sys_fs, cellFsGetDirectoryEntries); REG_FUNC(sys_fs, cellFsStReadInit); REG_FUNC(sys_fs, cellFsStReadFinish); REG_FUNC(sys_fs, cellFsStReadGetRingBuf); REG_FUNC(sys_fs, cellFsStReadGetStatus); REG_FUNC(sys_fs, cellFsStReadGetRegid); REG_FUNC(sys_fs, cellFsStReadStart); REG_FUNC(sys_fs, cellFsStReadStop); REG_FUNC(sys_fs, cellFsStRead); REG_FUNC(sys_fs, cellFsStReadGetCurrentAddr); REG_FUNC(sys_fs, cellFsStReadPutCurrentAddr); REG_FUNC(sys_fs, cellFsStReadWait); REG_FUNC(sys_fs, cellFsStReadWaitCallback); REG_FUNC(sys_fs, cellFsSetDefaultContainer); REG_FUNC(sys_fs, cellFsSetIoBufferFromDefaultContainer); REG_FUNC(sys_fs, cellFsUtime); REG_FUNC(sys_fs, cellFsArcadeHddSerialNumber); REG_FUNC(sys_fs, cellFsAllocateFileAreaWithInitialData); REG_FUNC(sys_fs, cellFsAllocateFileAreaByFdWithoutZeroFill); REG_FUNC(sys_fs, cellFsSetIoBuffer); REG_FUNC(sys_fs, cellFsAllocateFileAreaByFdWithInitialData); REG_FUNC(sys_fs, cellFsTruncate2); REG_FUNC(sys_fs, cellFsChangeFileSizeWithoutAllocation); REG_FUNC(sys_fs, cellFsAllocateFileAreaWithoutZeroFill).flags = MFF_FORCED_HLE; REG_FUNC(sys_fs, cellFsChangeFileSizeByFdWithoutAllocation); REG_FUNC(sys_fs, cellFsSetDiscReadRetrySetting); REG_FUNC(sys_fs, cellFsRegisterConversionCallback); REG_FUNC(sys_fs, cellFsUnregisterL10nCallbacks); REG_FUNC(sys_fs, cellFsAclRead); REG_FUNC(sys_fs, cellFsAclWrite); REG_FUNC(sys_fs, cellFsFcntl); REG_FUNC(sys_fs, cellFsFdatasync); REG_FUNC(sys_fs, cellFsLink); REG_FUNC(sys_fs, cellFsLsnGetCDA); REG_FUNC(sys_fs, cellFsLsnGetCDASize); REG_FUNC(sys_fs, cellFsLsnLock); REG_FUNC(sys_fs, cellFsLsnRead); REG_FUNC(sys_fs, cellFsLsnRead2); REG_FUNC(sys_fs, cellFsLsnUnlock); REG_FUNC(sys_fs, cellFsMappedAllocate); REG_FUNC(sys_fs, cellFsMappedFree); REG_FUNC(sys_fs, cellFsSymbolicLink); });