/** * gekko_io.c - Gekko style disk io functions. * * Copyright (c) 2009 Rhys "Shareese" Koedijk * Copyright (c) 2010 Dimok * * This program/include file is free software; you can redistribute it and/or * modify it under the terms of the GNU General Public License as published * by the Free Software Foundation; either version 2 of the License, or * (at your option) any later version. * * This program/include file is distributed in the hope that it will be * useful, but WITHOUT ANY WARRANTY; without even the implied warranty * of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program; if not, write to the Free Software Foundation, * Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA */ #include #include #include #include #include #include #include #include #include #include #include #include "gekko_io.h" #include "bitops.h" #include "ext2_fs.h" #include "ext2fs.h" #include "ext2_internal.h" #include "disc_cache.h" #include "mem_allocate.h" #define DEV_FD(dev) ((gekko_fd *) dev->private_data) /* Prototypes */ static s64 device_gekko_io_readbytes(io_channel dev, s64 offset, s64 count, void *buf); static bool device_gekko_io_readsectors(io_channel dev, sec_t sector, sec_t numSectors, void* buffer); static s64 device_gekko_io_writebytes(io_channel dev, s64 offset, s64 count, const void *buf); static bool device_gekko_io_writesectors(io_channel dev, sec_t sector, sec_t numSectors, const void* buffer); /** * */ static errcode_t device_gekko_io_open(const char *name, int flags, io_channel *dev) { // Get the device driver descriptor gekko_fd *fd = DEV_FD((*dev)); if (!fd) { errno = EBADF; return -1; } // Get the device interface const DISC_INTERFACE* interface = fd->interface; if (!interface) { errno = ENODEV; return -1; } // Start the device interface and ensure that it is inserted if (!interface->startup()) { ext2_log_trace("device failed to start\n"); errno = EIO; return -1; } if (!interface->isInserted()) { ext2_log_trace("device media is not inserted\n"); errno = EIO; return -1; } struct ext2_super_block * super = (struct ext2_super_block *) mem_alloc(SUPERBLOCK_SIZE); //1024 bytes if(!super) { ext2_log_trace("no memory for superblock"); errno = ENOMEM; return -1; } // Check that there is a valid EXT boot sector at the start of the device if (!interface->readSectors(fd->startSector+SUPERBLOCK_OFFSET/BYTES_PER_SECTOR, SUPERBLOCK_SIZE/BYTES_PER_SECTOR, super)) { ext2_log_trace("read failure @ sector %d\n", fd->startSector); errno = EROFS; mem_free(super); return -1; } if(ext2fs_le16_to_cpu(super->s_magic) != EXT2_SUPER_MAGIC) { mem_free(super); errno = EROFS; return -1; } // Parse the boot sector fd->sectorSize = BYTES_PER_SECTOR; fd->offset = 0; fd->sectorCount = 0; switch(ext2fs_le32_to_cpu(super->s_log_block_size)) { case 1: fd->sectorCount = (sec_t) ((u64) ext2fs_le32_to_cpu(super->s_blocks_count) * (u64) 2048 / (u64) BYTES_PER_SECTOR); break; case 2: fd->sectorCount = (sec_t) ((u64) ext2fs_le32_to_cpu(super->s_blocks_count) * (u64) 4096 / (u64) BYTES_PER_SECTOR); break; case 3: fd->sectorCount = (sec_t) ((u64) ext2fs_le32_to_cpu(super->s_blocks_count) * (u64) 8192 / (u64) BYTES_PER_SECTOR); break; default: case 0: fd->sectorCount = (sec_t) ((u64) ext2fs_le32_to_cpu(super->s_blocks_count) * (u64) 1024 / (u64) BYTES_PER_SECTOR); break; } mem_free(super); // Create the cache fd->cache = cache_constructor(fd->cachePageCount, fd->cachePageSize, interface, fd->startSector + fd->sectorCount, fd->sectorSize); return 0; } /** * Flush data out and close volume */ static errcode_t device_gekko_io_close(io_channel dev) { // Get the device driver descriptor gekko_fd *fd = DEV_FD(dev); if (!fd) { errno = EBADF; return -1; } if(!(dev->flags & EXT2_FLAG_RW)) return 0; // Flush and destroy the cache (if required) if (fd->cache) { cache_flush(fd->cache); cache_destructor(fd->cache); } return 0; } /** * */ static s64 device_gekko_io_readbytes(io_channel dev, s64 offset, s64 count, void *buf) { ext2_log_trace("dev %p, offset %lli, count %lli\n", dev, offset, count); // Get the device driver descriptor gekko_fd *fd = DEV_FD(dev); if (!fd) { errno = EBADF; return -1; } // Get the device interface const DISC_INTERFACE* interface = fd->interface; if (!interface) { errno = ENODEV; return -1; } if(offset < 0) { errno = EROFS; return -1; } if(!count) return 0; sec_t sec_start = (sec_t) fd->startSector; sec_t sec_count = 1; u32 buffer_offset = (u32) (offset % fd->sectorSize); u8 *buffer = NULL; // Determine the range of sectors required for this read if (offset > 0) { sec_start += (sec_t) floor((f64) offset / (f64) fd->sectorSize); } if (buffer_offset+count > fd->sectorSize) { sec_count = (sec_t) ceil((f64) (buffer_offset+count) / (f64) fd->sectorSize); } // Don't read over the partitions limit if(sec_start+sec_count > fd->startSector+fd->sectorCount) { ext2_log_trace("Error: read requested up to sector %lli while partition goes up to %lli\n", (s64) (sec_start+sec_count), (s64) (fd->startSector+fd->sectorCount)); errno = EROFS; return -1; } // If this read happens to be on the sector boundaries then do the read straight into the destination buffer if((buffer_offset == 0) && (count % fd->sectorSize == 0)) { // Read from the device ext2_log_trace("direct read from sector %d (%d sector(s) long)\n", sec_start, sec_count); if (!device_gekko_io_readsectors(dev, sec_start, sec_count, buf)) { ext2_log_trace("direct read failure @ sector %d (%d sector(s) long)\n", sec_start, sec_count); errno = EIO; return -1; } // Else read into a buffer and copy over only what was requested } else { // Allocate a buffer to hold the read data buffer = (u8*)mem_alloc(sec_count * fd->sectorSize); if (!buffer) { errno = ENOMEM; return -1; } // Read from the device ext2_log_trace("buffered read from sector %d (%d sector(s) long)\n", sec_start, sec_count); ext2_log_trace("count: %d sec_count:%d fd->sectorSize: %d )\n", (u32)count, (u32)sec_count,(u32)fd->sectorSize); if (!device_gekko_io_readsectors(dev, sec_start, sec_count, buffer)) { ext2_log_trace("buffered read failure @ sector %d (%d sector(s) long)\n", sec_start, sec_count); mem_free(buffer); errno = EIO; return -1; } // Copy what was requested to the destination buffer memcpy(buf, buffer + buffer_offset, count); mem_free(buffer); } return count; } /** * */ static s64 device_gekko_io_writebytes(io_channel dev, s64 offset, s64 count, const void *buf) { ext2_log_trace("dev %p, offset %lli, count %lli\n", dev, offset, count); // Get the device driver descriptor gekko_fd *fd = DEV_FD(dev); if (!fd) { errno = EBADF; return -1; } if(!(dev->flags & EXT2_FLAG_RW)) return -1; // Get the device interface const DISC_INTERFACE* interface = fd->interface; if (!interface) { errno = ENODEV; return -1; } if(count < 0 || offset < 0) { errno = EROFS; return -1; } if(count == 0) return 0; sec_t sec_start = (sec_t) fd->startSector; sec_t sec_count = 1; u32 buffer_offset = (u32) (offset % fd->sectorSize); u8 *buffer = NULL; // Determine the range of sectors required for this write if (offset > 0) { sec_start += (sec_t) floor((f64) offset / (f64) fd->sectorSize); } if ((buffer_offset+count) > fd->sectorSize) { sec_count = (sec_t) ceil((f64) (buffer_offset+count) / (f64) fd->sectorSize); } // Don't write over the partitions limit if(sec_start+sec_count > fd->startSector+fd->sectorCount) { ext2_log_trace("Error: write requested up to sector %lli while partition goes up to %lli\n", (s64) (sec_start+sec_count), (s64) (fd->startSector+fd->sectorCount)); errno = EROFS; return -1; } // If this write happens to be on the sector boundaries then do the write straight to disc if((buffer_offset == 0) && (count % fd->sectorSize == 0)) { // Write to the device ext2_log_trace("direct write to sector %d (%d sector(s) long)\n", sec_start, sec_count); if (!device_gekko_io_writesectors(dev, sec_start, sec_count, buf)) { ext2_log_trace("direct write failure @ sector %d (%d sector(s) long)\n", sec_start, sec_count); errno = EIO; return -1; } // Else write from a buffer aligned to the sector boundaries } else { // Allocate a buffer to hold the write data buffer = (u8 *) mem_alloc(sec_count * fd->sectorSize); if (!buffer) { errno = ENOMEM; return -1; } // Read the first and last sectors of the buffer from disc (if required) // NOTE: This is done because the data does not line up with the sector boundaries, // we just read in the buffer edges where the data overlaps with the rest of the disc if(buffer_offset != 0) { if (!device_gekko_io_readsectors(dev, sec_start, 1, buffer)) { ext2_log_trace("read failure @ sector %d\n", sec_start); mem_free(buffer); errno = EIO; return -1; } } if((buffer_offset+count) % fd->sectorSize != 0) { if (!device_gekko_io_readsectors(dev, sec_start + sec_count - 1, 1, buffer + ((sec_count-1) * fd->sectorSize))) { ext2_log_trace("read failure @ sector %d\n", sec_start + sec_count - 1); mem_free(buffer); errno = EIO; return -1; } } // Copy the data into the write buffer memcpy(buffer + buffer_offset, buf, count); // Write to the device ext2_log_trace("buffered write to sector %d (%d sector(s) long)\n", sec_start, sec_count); if (!device_gekko_io_writesectors(dev, sec_start, sec_count, buffer)) { ext2_log_trace("buffered write failure @ sector %d\n", sec_start); mem_free(buffer); errno = EIO; return -1; } // Free the buffer mem_free(buffer); } return count; } /** * Read function wrap for I/O manager */ static errcode_t device_gekko_io_read64(io_channel dev, unsigned long long block, int count, void *buf) { gekko_fd *fd = DEV_FD(dev); s64 size = (count < 0) ? -count : count * dev->block_size; fd->io_stats.bytes_read += size; ext2_loff_t location = ((ext2_loff_t) block * dev->block_size) + fd->offset; s64 read = device_gekko_io_readbytes(dev, location, size, buf); if(read != size) return EXT2_ET_SHORT_READ; else if(read < 0) return EXT2_ET_BLOCK_BITMAP_READ; return EXT2_ET_OK; } static errcode_t device_gekko_io_read(io_channel dev, unsigned long block, int count, void *buf) { return device_gekko_io_read64(dev, block, count, buf); } /** * Write function wrap for I/O manager */ static errcode_t device_gekko_io_write64(io_channel dev, unsigned long long block, int count, const void *buf) { gekko_fd *fd = DEV_FD(dev); s64 size = (count < 0) ? -count : count * dev->block_size; fd->io_stats.bytes_written += size; ext2_loff_t location = ((ext2_loff_t) block * dev->block_size) + fd->offset; s64 writen = device_gekko_io_writebytes(dev, location, size, buf); if(writen != size) return EXT2_ET_SHORT_WRITE; else if(writen < 0) return EXT2_ET_BLOCK_BITMAP_WRITE; return EXT2_ET_OK; } static errcode_t device_gekko_io_write(io_channel dev, unsigned long block, int count, const void *buf) { return device_gekko_io_write64(dev, block, count, buf); } static bool device_gekko_io_readsectors(io_channel dev, sec_t sector, sec_t numSectors, void* buffer) { // Get the device driver descriptor gekko_fd *fd = DEV_FD(dev); if (!fd) { errno = EBADF; return false; } // Read the sectors from disc (or cache, if enabled) if (fd->cache) return cache_readSectors(fd->cache, sector, numSectors, buffer); else return fd->interface->readSectors(sector, numSectors, buffer); return false; } static bool device_gekko_io_writesectors(io_channel dev, sec_t sector, sec_t numSectors, const void* buffer) { // Get the device driver descriptor gekko_fd *fd = DEV_FD(dev); if (!fd) { errno = EBADF; return false; } // Write the sectors to disc (or cache, if enabled) if (fd->cache) return cache_writeSectors(fd->cache, sector, numSectors, buffer); else return fd->interface->writeSectors(sector, numSectors, buffer); return false; } /** * */ static errcode_t device_gekko_io_sync(io_channel dev) { gekko_fd *fd = DEV_FD(dev); ext2_log_trace("dev %p\n", dev); // Check that the device can be written to if(!(dev->flags & EXT2_FLAG_RW)) return -1; // Flush any sectors in the disc cache (if required) if (fd->cache) { if (!cache_flush(fd->cache)) { errno = EIO; return EXT2_ET_BLOCK_BITMAP_WRITE; } } return EXT2_ET_OK; } /** * */ static errcode_t device_gekko_io_stat(io_channel dev, io_stats *stats) { EXT2_CHECK_MAGIC(dev, EXT2_ET_MAGIC_IO_CHANNEL); gekko_fd *fd = DEV_FD(dev); if (stats) *stats = &fd->io_stats; return EXT2_ET_OK; } static errcode_t device_gekko_set_blksize(io_channel dev, int blksize) { EXT2_CHECK_MAGIC(dev, EXT2_ET_MAGIC_IO_CHANNEL); if (dev->block_size != blksize) { dev->block_size = blksize; return device_gekko_io_sync(dev); } return EXT2_ET_OK; } /** * Set options. */ static errcode_t device_gekko_set_option(io_channel dev, const char *option, const char *arg) { unsigned long long tmp; char *end; gekko_fd *fd = DEV_FD(dev); if (!fd) { errno = EBADF; return -1; } EXT2_CHECK_MAGIC(dev, EXT2_ET_MAGIC_IO_CHANNEL); if (!strcmp(option, "offset")) { if (!arg) return EXT2_ET_INVALID_ARGUMENT; tmp = strtoull(arg, &end, 0); if (*end) return EXT2_ET_INVALID_ARGUMENT; fd->offset = tmp; if (fd->offset < 0) return EXT2_ET_INVALID_ARGUMENT; return 0; } return EXT2_ET_INVALID_ARGUMENT; } static errcode_t device_gekko_discard(io_channel channel, unsigned long long block, unsigned long long count) { //!TODO as soon as it is implemented in the official lib return 0; } /** * Device operations for working with gekko style devices and files. */ const struct struct_io_manager struct_gekko_io_manager = { EXT2_ET_MAGIC_IO_MANAGER, "Wii/GC I/O Manager", device_gekko_io_open, device_gekko_io_close, device_gekko_set_blksize, device_gekko_io_read, device_gekko_io_write, device_gekko_io_sync, 0, device_gekko_set_option, device_gekko_io_stat, device_gekko_io_read64, device_gekko_io_write64, device_gekko_discard, }; io_manager gekko_io_manager = (io_manager) &struct_gekko_io_manager;