#include #include #include #include #include #include #include static void ide_register_device(ide_controller_t *c, uint8_t device, fs_t *iofs); // ================================ // // HELPER FUNCTIONS FOR PCI IDE I/O // // ================================ // static void ide_write(ide_controller_t *c, uint8_t channel, uint8_t reg, uint8_t data) { if (reg > 0x07 && reg < 0x0C) { ide_write(c, channel, ATA_REG_CONTROL, 0x80 | c->channels[channel].nIEN); } if (reg < 0x08) { outb(c->channels[channel].base + reg - 0x00, data); } else if (reg < 0x0C) { outb(c->channels[channel].base + reg - 0x06, data); } else if (reg < 0x0E) { outb(c->channels[channel].ctrl + reg - 0x0A, data); } else if (reg < 0x16) { outb(c->channels[channel].bmide + reg - 0x0E, data); } if (reg > 0x07 && reg < 0x0C) { ide_write(c, channel, ATA_REG_CONTROL, c->channels[channel].nIEN); } } static uint8_t ide_read(ide_controller_t *c, uint8_t channel, uint8_t reg) { uint8_t result = 0; if (reg > 0x07 && reg < 0x0C) { ide_write(c, channel, ATA_REG_CONTROL, 0x80 | c->channels[channel].nIEN); } if (reg < 0x08) { result = inb(c->channels[channel].base + reg - 0x00); } else if (reg < 0x0C) { result = inb(c->channels[channel].base + reg - 0x06); } else if (reg < 0x0E) { result = inb(c->channels[channel].ctrl + reg - 0x0A); } else if (reg < 0x16) { result = inb(c->channels[channel].bmide + reg - 0x0E); } if (reg > 0x07 && reg < 0x0C) { ide_write(c, channel, ATA_REG_CONTROL, c->channels[channel].nIEN); } return result; } static void ide_read_buffer(ide_controller_t *c, uint8_t channel, uint8_t reg, void* buffer, size_t quads) { if (reg > 0x07 && reg < 0x0C) { ide_write(c, channel, ATA_REG_CONTROL, 0x80 | c->channels[channel].nIEN); } if (reg < 0x08) { insl(c->channels[channel].base + reg - 0x00, buffer, quads); } else if (reg < 0x0C) { insl(c->channels[channel].base + reg - 0x06, buffer, quads); } else if (reg < 0x0E) { insl(c->channels[channel].ctrl + reg - 0x0A, buffer, quads); } else if (reg < 0x16) { insl(c->channels[channel].bmide + reg - 0x0E, buffer, quads); } if (reg > 0x07 && reg < 0x0C) { ide_write(c, channel, ATA_REG_CONTROL, c->channels[channel].nIEN); } } static int ide_polling(ide_controller_t *c, uint8_t channel, bool advanced_check) { // (I) Delay 400 nanosecond for BSY to be set: for(int i = 0; i < 4; i++) ide_read(c, channel, ATA_REG_ALTSTATUS); // Reading the Alternate Status port wastes 100ns; loop four times. // (II) Wait for BSY to be cleared: while (ide_read(c, channel, ATA_REG_STATUS) & ATA_SR_BSY); if (advanced_check) { uint8_t state = ide_read(c, channel, ATA_REG_STATUS); // Read Status Register. // (III) Check For Errors: if (state & ATA_SR_ERR) return 2; // Error. // (IV) Check If Device fault: if (state & ATA_SR_DF) return 1; // Device Fault. // (V) Check DRQ: // BSY = 0; DF = 0; ERR = 0 so we should check for DRQ now. if ((state & ATA_SR_DRQ) == 0) return 3; // DRQ should be set } return 0; // ok } static uint8_t ide_print_error(ide_controller_t *c, int drive, uint8_t err) { if (err == 0) return err; dbg_printf("IDE: "); if (err == 1) { dbg_printf("- Device Fault\n "); err = 19; } else if (err == 2) { uint8_t st = ide_read(c, c->devices[drive].channel, ATA_REG_ERROR); if (st & ATA_ER_AMNF) { dbg_printf("- No Address Mark Found\n "); err = 7; } if (st & ATA_ER_TK0NF) { dbg_printf("- No Media or Media Error\n "); err = 3; } if (st & ATA_ER_ABRT) { dbg_printf("- Command Aborted\n "); err = 20; } if (st & ATA_ER_MCR) { dbg_printf("- No Media or Media Error\n "); err = 3; } if (st & ATA_ER_IDNF) { dbg_printf("- ID mark not Found\n "); err = 21; } if (st & ATA_ER_MC) { dbg_printf("- No Media or Media Error\n "); err = 3; } if (st & ATA_ER_UNC) { dbg_printf("- Uncorrectable Data Error\n "); err = 22; } if (st & ATA_ER_BBK) { dbg_printf("- Bad Sectors\n "); err = 13; } } else if (err == 3) { dbg_printf("- Reads Nothing\n "); err = 23; } else if (err == 4) { dbg_printf("- Write Protected\n "); err = 8; } else if (err == 5) { dbg_printf("- Interrupted\n "); } dbg_printf("- [%s %s] %s\n", (const char *[]){"Primary", "Secondary"}[c->devices[drive].channel], (const char *[]){"Master", "Slave"}[c->devices[drive].drive], c->devices[drive].model); return err; } // ============ // // IRQ HANDLERS // // ============ // STATIC_MUTEX(on_pciirq); STATIC_MUTEX(on_irq14); STATIC_MUTEX(on_irq15); static thread_t *wait_irq14 = 0, *wait_irq15 = 0, *wait_pciirq = 0; void irq14_handler(registers_t *regs) { if (wait_irq14) { thread_t *t = wait_irq14; wait_irq14 = 0; resume_on(t); } } void irq15_handler(registers_t *regs) { if (wait_irq15) { thread_t *t = wait_irq15; wait_irq15 = 0; resume_on(t); } } void pciirq_handler(int pci_id) { if (wait_pciirq) { thread_t *t = wait_pciirq; wait_pciirq = 0; resume_on(t); } } static void ide_prewait_irq(ide_controller_t *c, int channel) { int irq = c->channels[channel].irq; if (irq == 14) { mutex_lock(&on_irq14); wait_irq14 = current_thread; } else if (irq == 15) { mutex_lock(&on_irq15); wait_irq15 = current_thread; } else { mutex_lock(&on_pciirq); wait_pciirq = current_thread; } } static bool ide_wait_irq(ide_controller_t *c, int channel) { bool ret = true; int st = enter_critical(CL_NOINT); int irq = c->channels[channel].irq; if (irq == 14) { if (wait_irq14) ret = wait_on(current_thread); mutex_unlock(&on_irq14); } else if (irq == 15) { if (wait_irq15) ret = wait_on(current_thread); mutex_unlock(&on_irq15); } else { if (wait_pciirq) ret = wait_on(current_thread); mutex_unlock(&on_pciirq); } exit_critical(st); return ret; } // ===================================== // // ACTUAL READING AND WRITING OF SECTORS // // ===================================== // static uint8_t ide_ata_access(ide_controller_t *c, int direction, uint8_t drive, uint32_t lba, uint8_t numsects, void* ptr) { uint32_t channel = c->devices[drive].channel; // Read the Channel. uint32_t slavebit = c->devices[drive].drive; // Read the Drive [Master/Slave] uint32_t bus = c->channels[channel].base; // Bus Base, like 0x1F0 which is also data port. const uint32_t words = 256; // Almost every ATA drive has a sector-size of 512-byte. uint16_t cyl; uint8_t head, sect, err; // (I) Select one from LBA28, LBA48 or CHS; uint8_t lba_mode /* 0: CHS, 1:LBA28, 2: LBA48 */; uint8_t lba_io[6]; if (lba >= 0x10000000) { // Sure Drive should support LBA in this case, or you are // giving a wrong LBA. // LBA48: lba_mode = 2; lba_io[0] = (lba & 0x000000FF) >> 0; lba_io[1] = (lba & 0x0000FF00) >> 8; lba_io[2] = (lba & 0x00FF0000) >> 16; lba_io[3] = (lba & 0xFF000000) >> 24; lba_io[4] = 0; lba_io[5] = 0; head = 0; // Lower 4-bits of HDDEVSEL are not used here. } else if (c->devices[drive].cap & 0x200) { // Drive supports LBA? // LBA28: lba_mode = 1; lba_io[0] = (lba & 0x00000FF) >> 0; lba_io[1] = (lba & 0x000FF00) >> 8; lba_io[2] = (lba & 0x0FF0000) >> 16; lba_io[3] = 0; // These Registers are not used here. lba_io[4] = 0; // These Registers are not used here. lba_io[5] = 0; // These Registers are not used here. head = (lba & 0xF000000) >> 24; } else { // CHS: lba_mode = 0; sect = (lba % 63) + 1; cyl = (lba + 1 - sect) / (16 * 63); lba_io[0] = sect; lba_io[1] = (cyl >> 0) & 0xFF; lba_io[2] = (cyl >> 8) & 0xFF; lba_io[3] = 0; lba_io[4] = 0; lba_io[5] = 0; head = (lba + 1 - sect) % (16 * 63) / (63); // Head number is written to HDDEVSEL lower 4-bits. } // (II) See if drive supports DMA or not; bool dma = false; // We don't support DMA // (III) Wait if the drive is busy; while (ide_read(c, channel, ATA_REG_STATUS) & ATA_SR_BSY); // Wait if busy. // (IV) Select Drive from the controller; if (lba_mode == 0) { ide_write(c, channel, ATA_REG_HDDEVSEL, 0xA0 | (slavebit << 4) | head); // Drive & CHS. } else { ide_write(c, channel, ATA_REG_HDDEVSEL, 0xE0 | (slavebit << 4) | head); // Drive & LBA } // (V) Write Parameters; if (lba_mode == 2) { ide_write(c, channel, ATA_REG_SECCOUNT1, 0); ide_write(c, channel, ATA_REG_LBA3, lba_io[3]); ide_write(c, channel, ATA_REG_LBA4, lba_io[4]); ide_write(c, channel, ATA_REG_LBA5, lba_io[5]); } ide_write(c, channel, ATA_REG_SECCOUNT0, numsects); ide_write(c, channel, ATA_REG_LBA0, lba_io[0]); ide_write(c, channel, ATA_REG_LBA1, lba_io[1]); ide_write(c, channel, ATA_REG_LBA2, lba_io[2]); // (VI) Select the command and send it; // Routine that is followed: // If ( DMA & LBA48) DO_DMA_EXT; // If ( DMA & LBA28) DO_DMA_LBA; // If ( DMA & LBA28) DO_DMA_CHS; // If (!DMA & LBA48) DO_PIO_EXT; // If (!DMA & LBA28) DO_PIO_LBA; // If (!DMA & !LBA#) DO_PIO_CHS; uint8_t cmd; if (lba_mode == 0 && !dma && direction == 0) cmd = ATA_CMD_READ_PIO; if (lba_mode == 1 && !dma && direction == 0) cmd = ATA_CMD_READ_PIO; if (lba_mode == 2 && !dma && direction == 0) cmd = ATA_CMD_READ_PIO_EXT; if (lba_mode == 0 && dma && direction == 0) cmd = ATA_CMD_READ_DMA; if (lba_mode == 1 && dma && direction == 0) cmd = ATA_CMD_READ_DMA; if (lba_mode == 2 && dma && direction == 0) cmd = ATA_CMD_READ_DMA_EXT; if (lba_mode == 0 && !dma && direction == 1) cmd = ATA_CMD_WRITE_PIO; if (lba_mode == 1 && !dma && direction == 1) cmd = ATA_CMD_WRITE_PIO; if (lba_mode == 2 && !dma && direction == 1) cmd = ATA_CMD_WRITE_PIO_EXT; if (lba_mode == 0 && dma && direction == 1) cmd = ATA_CMD_WRITE_DMA; if (lba_mode == 1 && dma && direction == 1) cmd = ATA_CMD_WRITE_DMA; if (lba_mode == 2 && dma && direction == 1) cmd = ATA_CMD_WRITE_DMA_EXT; ide_write(c, channel, ATA_REG_COMMAND, cmd); // Send the Command. if (dma) { if (direction == 0) { // DMA Read. ASSERT(false); } else { // DMA Write. ASSERT(false); } } else { if (direction == 0) { // PIO Read. for (int i = 0; i < numsects; i++) { err = ide_polling(c, channel, true); if (err) return err; // Polling, set error and exit if there is. insw(bus, ptr, words); ptr += (words*2); } } else { // PIO Write. for (int i = 0; i < numsects; i++) { ide_polling(c, channel, false); // Polling. outsw(bus, ptr, words); ptr += (words*2); } ide_write(c, channel, ATA_REG_COMMAND, (char []){ATA_CMD_CACHE_FLUSH, ATA_CMD_CACHE_FLUSH, ATA_CMD_CACHE_FLUSH_EXT}[lba_mode]); ide_polling(c, channel, false); // Polling. } } return 0; } static uint8_t ide_atapi_read(ide_controller_t *c, uint8_t drive, uint32_t lba, uint8_t numsects, void* ptr) { uint32_t channel = c->devices[drive].channel; uint32_t slavebit = c->devices[drive].drive; uint32_t bus = c->channels[channel].base; const uint32_t words = 1024; // Sector Size. ATAPI drives have a sector size of 2048 bytes. uint8_t err; // Enable IRQs: c->channels[channel].nIEN = 0; ide_write(c, channel, ATA_REG_CONTROL, 0); // (I): Setup SCSI Packet: uint8_t atapi_packet[12]; atapi_packet[ 0] = ATAPI_CMD_READ; atapi_packet[ 1] = 0x0; atapi_packet[ 2] = (lba >> 24) & 0xFF; atapi_packet[ 3] = (lba >> 16) & 0xFF; atapi_packet[ 4] = (lba >> 8) & 0xFF; atapi_packet[ 5] = (lba >> 0) & 0xFF; atapi_packet[ 6] = 0x0; atapi_packet[ 7] = 0x0; atapi_packet[ 8] = 0x0; atapi_packet[ 9] = numsects; atapi_packet[10] = 0x0; atapi_packet[11] = 0x0; // (II): Select the drive: ide_write(c, channel, ATA_REG_HDDEVSEL, slavebit << 4); // (III): Delay 400 nanoseconds for select to complete: for(int i = 0; i < 4; i++) ide_read(c, channel, ATA_REG_ALTSTATUS); // Reading the Alternate Status port wastes 100ns. // (IV): Inform the Controller that we use PIO mode: ide_write(c, channel, ATA_REG_FEATURES, 0); // PIO mode. // (V): Tell the Controller the size of buffer: ide_write(c, channel, ATA_REG_LBA1, (words * 2) & 0xFF); // Lower Byte of Sector Size. ide_write(c, channel, ATA_REG_LBA2, (words * 2) >> 8); // Upper Byte of Sector Size. // (VI): Send the Packet Command: ide_write(c, channel, ATA_REG_COMMAND, ATA_CMD_PACKET); // Send the Command. // (VII): Waiting for the driver to finish or return an error code: err = ide_polling(c, channel, true); if (err) return err; // Polling and return if error. // (VIII): Sending the packet data: ide_prewait_irq(c, channel); outsw(bus, atapi_packet, 6); // (IX): Receiving Data: for (int i = 0; i < numsects; i++) { if (!ide_wait_irq(c, channel)) goto must_terminate; // Wait for an IRQ. ide_prewait_irq(c, channel); err = ide_polling(c, channel, 1); if (err) return err; // Polling and return if error. insw(bus, ptr, words); ptr += (words * 2); } // (X): Waiting for an IRQ: if (!ide_wait_irq(c, channel)) goto must_terminate; // (XI): Waiting for BSY & DRQ to clear: while (ide_read(c, channel, ATA_REG_STATUS) & (ATA_SR_BSY | ATA_SR_DRQ)); return 0; must_terminate: // TODO : end communication with device... dbg_printf("TODO (pciide may be stuck)\n"); return 5; } static uint8_t ide_read_sectors(ide_controller_t *c, uint8_t drive, uint32_t lba, uint8_t numsects, void* ptr) { // 1: Check if the drive presents: if (drive > 3 || !c->devices[drive].present) return 1; // Drive Not Found! // 2: Check if inputs are valid: if (((lba + numsects) >= c->devices[drive].size) && (c->devices[drive].type == IDE_ATA)) return 2; // Seeking to invalid position. // 3: Read in PIO Mode through Polling & IRQs: if (c->devices[drive].type == IDE_ATA) { uint8_t err = ide_ata_access(c, ATA_READ, drive, lba, numsects, ptr); return ide_print_error(c, drive, err); } else if (c->devices[drive].type == IDE_ATAPI) { uint8_t err = 0; // for (int i = 0; i < numsects; i++) // err = ide_atapi_read(c, drive, lba + i, 1, ptr + (i*2048)); err = ide_atapi_read(c, drive, lba, numsects, ptr); return ide_print_error(c, drive, err); } else { return 1; } } static uint8_t ide_write_sectors(ide_controller_t *c, uint8_t drive, uint8_t numsects, uint32_t lba, void* ptr) { // 1: Check if the drive presents: if (drive > 3 || !c->devices[drive].present) return 1; // 2: Check if inputs are valid: if (((lba + numsects) > c->devices[drive].size) && (c->devices[drive].type == IDE_ATA)) return 2; // Seeking to invalid position. // 3: Read in PIO Mode through Polling & IRQs: if (c->devices[drive].type == IDE_ATA) { uint8_t err = ide_ata_access(c, ATA_WRITE, drive, lba, numsects, ptr); return ide_print_error(c, drive, err); } else if (c->devices[drive].type == IDE_ATAPI) { return 4; // Write-Protected. } else { return 1; } } // ============== // // SETUP ROUTINES // // ============== // static void ide_init(int pci_id, ide_controller_t *c, fs_t *iofs) { pci_devices[pci_id].data = c; c->pci_id = pci_id; // Set IRQ to PCI_IRQ_STORAGE uint8_t prog_if = pci_read_config_byte(pci_id, PCI_CONFIG_PROG_IF); if (prog_if == 0x8A || prog_if == 0x80) { c->channels[ATA_PRIMARY].irq = IRQ14; c->channels[ATA_SECONDARY].irq = IRQ15; } else { pci_set_irq(pci_id, PCI_IRQ_STORAGE); c->channels[ATA_PRIMARY].irq = PCI_IRQ_STORAGE; c->channels[ATA_SECONDARY].irq = PCI_IRQ_STORAGE; } // Set IRQ handler pci_devices[pci_id].irq_handler = pciirq_handler; // Detect IO ports uint32_t bar0 = pci_read_config_long(pci_id, PCI_CONFIG_BAR0); uint32_t bar1 = pci_read_config_long(pci_id, PCI_CONFIG_BAR1); uint32_t bar2 = pci_read_config_long(pci_id, PCI_CONFIG_BAR2); uint32_t bar3 = pci_read_config_long(pci_id, PCI_CONFIG_BAR3); uint32_t bar4 = pci_read_config_long(pci_id, PCI_CONFIG_BAR4); c->channels[ATA_PRIMARY ].base = (bar0 ? (bar0 & 0xFFFFFFFC) : 0x1F0); c->channels[ATA_PRIMARY ].ctrl = (bar1 ? (bar1 & 0xFFFFFFFC) : 0x3F6); c->channels[ATA_SECONDARY].base = (bar2 ? (bar2 & 0xFFFFFFFC) : 0x170); c->channels[ATA_SECONDARY].ctrl = (bar3 ? (bar3 & 0xFFFFFFFC) : 0x376); c->channels[ATA_PRIMARY ].bmide = (bar4 & 0xFFFFFFFC) + 0; // Bus Master IDE c->channels[ATA_SECONDARY].bmide = (bar4 & 0xFFFFFFFC) + 8; // Bus Master IDE // Disable IRQs: ide_write(c, ATA_PRIMARY , ATA_REG_CONTROL, 2); ide_write(c, ATA_SECONDARY, ATA_REG_CONTROL, 2); // Detect drives for (int i = 0; i < 4; i++) { c->devices[i].present = 0; } int count = 0; for (int i = 0; i < 2; i++) { for (int j = 0; j < 2; j++) { uint8_t err = 0, type = IDE_ATA, status; union { char b[512]; uint16_t w[256]; uint32_t l[128]; } ide_buf; // (I) Select Drive: ide_write(c, i, ATA_REG_HDDEVSEL, 0xA0 | (j << 4)); usleep(1000); // (II) Send ATA Identify Command: ide_write(c, i, ATA_REG_COMMAND, ATA_CMD_IDENTIFY); usleep(1000); // (III) Polling: if (ide_read(c, i, ATA_REG_STATUS) == 0) continue; // If Status = 0, No Device. while(1) { status = ide_read(c, i, ATA_REG_STATUS); if ((status & ATA_SR_ERR)) { // If Err, Device is not ATA. err = 1; break; } if (!(status & ATA_SR_BSY) && (status & ATA_SR_DRQ)) break; // Everything is right. } // (IV) Probe for ATAPI Devices: if (err != 0) { uint8_t cl = ide_read(c, i, ATA_REG_LBA1); uint8_t ch = ide_read(c, i, ATA_REG_LBA2); if ((cl == 0x14 && ch == 0xEB) || (cl == 0x69 && ch == 0x96)) { type = IDE_ATAPI; } else { continue; // Unknown Type (may not be a device). } ide_write(c, i, ATA_REG_COMMAND, ATA_CMD_IDENTIFY_PACKET); usleep(1000); } // (V) Read Identification Space of the Device: ide_read_buffer(c, i, ATA_REG_DATA, ide_buf.b, 128); // (VI) Read Device Parameters: c->devices[count].present = 1; c->devices[count].type = type; c->devices[count].channel = i; c->devices[count].drive = j; c->devices[count].sig = ide_buf.w[ATA_IDENT_DEVICETYPE / 2]; c->devices[count].cap = ide_buf.w[ATA_IDENT_CAPABILITIES / 2]; c->devices[count].cmdset = ide_buf.l[ATA_IDENT_COMMANDSETS / 4]; // (VII) Get Size: if (c->devices[count].cmdset & (1 << 26)) { // Device uses 48-Bit Addressing: c->devices[count].size = ide_buf.l[ATA_IDENT_MAX_LBA_EXT / 4]; } else { // Device uses CHS or 28-bit Addressing: c->devices[count].size = ide_buf.l[ATA_IDENT_MAX_LBA / 4]; } // (VIII) String indicates model of device (like Western Digital HDD and SONY DVD-RW...): for(int k = 0; k < 40; k += 2) { c->devices[count].model[k] = ide_buf.b[ATA_IDENT_MODEL + k + 1]; c->devices[count].model[k + 1] = ide_buf.b[ATA_IDENT_MODEL + k]; } c->devices[count].model[40] = 0; // Terminate String. count++; } } dbg_printf("PCI IDE controller (PCI device %d)\n", pci_id); for (int i = 0; i < 4; i++) { if (c->devices[i].present) { dbg_printf(" Found %s Drive (%d sectors) - %s (irq %d)\n", (const char *[]){"ATA", "ATAPI"}[c->devices[i].type], c->devices[i].size, c->devices[i].model, c->channels[c->devices[i].channel].irq); ide_register_device(c, i, iofs); } } } void pciide_detect(fs_t *iofs) { idt_set_irq_handler(IRQ14, irq14_handler); idt_set_irq_handler(IRQ15, irq15_handler); for (int i = 0; i < PCI_MAX_DEVICES; i++) { if (pci_devices[i].vendor_id != 0xFFFF && pci_devices[i].base_class == PCI_BC_STORAGE && pci_devices[i].sub_class == PCI_SC_IDE) { ide_controller_t *c = (ide_controller_t*)malloc(sizeof(ide_controller_t)); if (c == 0) return; memset(c, 0, sizeof(ide_controller_t)); ide_init(i, c, iofs); } } } // ======================== // // INTERFACING WITH THE VFS // // ======================== // static int next_ata_id = 0; static int next_atapi_id = 0; typedef struct { ide_controller_t *c; uint32_t block_size; // ATA: 512, ATAPI: 2048 uint8_t device; uint8_t type; } ide_vfs_dev_t; static bool ide_vfs_open(fs_node_ptr n, int mode); static bool ide_vfs_stat(fs_node_ptr n, stat_t *st); static size_t ide_vfs_read(fs_node_ptr f, size_t offset, size_t len, char* buf); static size_t ide_vfs_write(fs_node_ptr f, size_t offset, size_t len, const char* buf); static int ide_vfs_ioctl(fs_node_ptr f, int command, void* data); static void ide_vfs_close(fs_node_ptr f); static fs_node_ops_t ide_vfs_node_ops = { .open = ide_vfs_open, .stat = ide_vfs_stat, .walk = 0, .delete = 0, .move = 0, .create = 0, .dispose = 0, .read = ide_vfs_read, .write = ide_vfs_write, .ioctl = ide_vfs_ioctl, .close = ide_vfs_close, .readdir = 0, }; void ide_register_device(ide_controller_t *c, uint8_t device, fs_t *iofs) { ide_vfs_dev_t *d = (ide_vfs_dev_t*)malloc(sizeof(ide_vfs_dev_t)); if (d == 0) return; d->c = c; d->device = device; d->type = c->devices[device].type; d->block_size = (d->type == IDE_ATAPI ? 2048 : 512); char name[40]; if (d->type == IDE_ATAPI) { snprintf(name, 40, "/atapi%d", next_atapi_id); next_atapi_id++; } else { snprintf(name, 40, "/ata%d", next_ata_id); next_ata_id++; } bool add_ok = nullfs_add_node(iofs, name, d, &ide_vfs_node_ops); if (add_ok) { dbg_printf(" Registered as %s.\n", name); } else { free(d); } } bool ide_vfs_open(fs_node_ptr n, int mode) { ide_vfs_dev_t *d = (ide_vfs_dev_t*)n; int ok_modes = (FM_READ | (d->type == IDE_ATA ? FM_WRITE : 0) | FM_IOCTL); if (mode & ~ok_modes) return false; return true; } bool ide_vfs_stat(fs_node_ptr n, stat_t *st) { ide_vfs_dev_t *d = (ide_vfs_dev_t*)n; st->type = FT_BLOCKDEV; st->access = (d->type == IDE_ATA ? FM_WRITE : 0) | FM_READ | FM_IOCTL; st->size = d->c->devices[d->device].size * d->block_size; return true; } size_t ide_vfs_read(fs_node_ptr f, size_t offset, size_t len, char* buf) { ide_vfs_dev_t *d = (ide_vfs_dev_t*)f; if (offset % d->block_size != 0) return 0; if (len % d->block_size != 0) return 0; uint8_t err = ide_read_sectors(d->c, d->device, offset / d->block_size, len / d->block_size, buf); if (err != 0) return 0; return len; } size_t ide_vfs_write(fs_node_ptr f, size_t offset, size_t len, const char* buf) { ide_vfs_dev_t *d = (ide_vfs_dev_t*)f; if (offset % d->block_size != 0) return 0; if (len % d->block_size != 0) return 0; uint8_t err = ide_write_sectors(d->c, d->device, offset / d->block_size, len / d->block_size, (char*)buf); if (err != 0) return 0; return len; } int ide_vfs_ioctl(fs_node_ptr f, int command, void* data) { ide_vfs_dev_t *d = (ide_vfs_dev_t*)f; int ret = 0; if (command == IOCTL_BLOCKDEV_GET_BLOCK_SIZE) ret = d->block_size; if (command == IOCTL_BLOCKDEV_GET_BLOCK_COUNT) ret = d->c->devices[d->device].size; return ret; } void ide_vfs_close(fs_node_ptr f) { // nothing to do } /* vim: set ts=4 sw=4 tw=0 noet :*/