* for multiple sector ops this equals mult_sector_num
* for standard ops this equals 1
*/
- uint32_t cur_sector_num;
+ uint64_t cur_sector_num;
};
struct ide_drive {
char model[41];
// Where we are in the data transfer
- uint32_t transfer_index;
+ uint64_t transfer_index;
// the length of a transfer
// calculated for easy access
- uint32_t transfer_length;
+ uint64_t transfer_length;
uint64_t current_lba;
uint32_t num_heads;
uint32_t num_sectors;
+
+ struct lba48_state {
+ // all start at zero
+ uint64_t lba;
+ uint16_t sector_count; // for LBA48
+ uint8_t sector_count_state; // two step write to 1f2/172 (high first)
+ uint8_t lba41_state; // two step write to 1f3
+ uint8_t lba52_state; // two step write to 1f4
+ uint8_t lba63_state; // two step write to 15
+ } lba48;
+
void * private_data;
union {
- uint8_t sector_count; // 0x1f2,0x172
- struct atapi_irq_flags irq_flags;
+ uint8_t sector_count; // 0x1f2,0x172 (ATA)
+ struct atapi_irq_flags irq_flags; // (ATAPI ONLY)
} __attribute__((packed));
+
union {
uint8_t sector_num; // 0x1f3,0x173
uint8_t lba0;
}
+static inline int is_lba28(struct ide_channel * channel) {
+ return channel->drive_head.lba_mode && channel->drive_head.rsvd1 && channel->drive_head.rsvd2;
+}
+
+static inline int is_lba48(struct ide_channel * channel) {
+ return channel->drive_head.lba_mode && !channel->drive_head.rsvd1 && !channel->drive_head.rsvd2;
+}
+
+static inline int is_chs(struct ide_channel * channel) {
+ return !channel->drive_head.lba_mode;
+}
+
static inline int get_channel_index(ushort_t port) {
if (((port & 0xfff8) == 0x1f0) ||
((port & 0xfffe) == 0x3f6) ||
}
-static inline int is_lba_enabled(struct ide_channel * channel) {
- return channel->drive_head.lba_mode;
-}
/* Drive Commands */
channel->error_reg.val = 0x01;
// clear commands
- channel->cmd_reg = 0x00;
+ channel->cmd_reg = 0; // NOP
channel->ctrl_reg.irq_disable = 0;
}
static void ide_abort_command(struct ide_internal * ide, struct ide_channel * channel) {
+
+ PrintDebug(VM_NONE,VCORE_NONE,"Aborting IDE Command\n");
+
channel->status.val = 0x41; // Error + ready
channel->error_reg.val = 0x04; // No idea...
while (1) {
uint32_t prd_entry_addr = channel->dma_prd_addr + (sizeof(struct ide_dma_prd) * index);
- int ret;
+ int ret = 0;
ret = v3_read_gpa_memory(&(ide->vm->cores[0]), prd_entry_addr, sizeof(struct ide_dma_prd), (void *)&prd_entry);
if (atapi_cmd_is_data_op(drive->cd_state.atapi_cmd)) {
if (drive->transfer_index % ATAPI_BLOCK_SIZE) {
PrintError(core->vm_info, core, "We currently don't handle ATAPI BLOCKS that span PRD descriptors\n");
- PrintError(core->vm_info, core, "transfer_index=%d, transfer_length=%d\n",
+ PrintError(core->vm_info, core, "transfer_index=%llu, transfer_length=%llu\n",
drive->transfer_index, drive->transfer_length);
return -1;
}
if ((prd_entry.end_of_table == 1) && (bytes_left > 0)) {
PrintError(core->vm_info, core, "DMA table not large enough for data transfer...\n");
- PrintError(core->vm_info, core, "\t(bytes_left=%u) (transfer_length=%u)...\n",
+ PrintError(core->vm_info, core, "\t(bytes_left=%u) (transfer_length=%llu)...\n",
bytes_left, drive->transfer_length);
PrintError(core->vm_info, core, "PRD Addr: %x, PRD Len: %d, EOT: %d\n",
prd_entry.base_addr, prd_entry.size, prd_entry.end_of_table);
#define DMA_CHANNEL_FLAG 0x08
+/*
+ Note that DMA model is as follows:
+
+ 1. Write the PRD pointer to the busmaster (DMA engine)
+ 2. Start the transfer on the device
+ 3. Tell the busmaster to start shoveling data (active DMA)
+*/
+
static int write_dma_port(struct guest_info * core, ushort_t port, void * src, uint_t length, void * private_data) {
struct ide_internal * ide = (struct ide_internal *)private_data;
uint16_t port_offset = port & (DMA_CHANNEL_FLAG - 1);
switch (port_offset) {
case DMA_CMD_PORT:
channel->dma_cmd.val = *(uint8_t *)src;
+
+ PrintDebug(core->vm_info, core, "IDE: dma command write: 0x%x\n", channel->dma_cmd.val);
if (channel->dma_cmd.start == 0) {
channel->dma_tbl_index = 0;
} else {
+ // Launch DMA operation, interrupt at end
+
channel->dma_status.active = 1;
if (channel->dma_cmd.read == 1) {
- // DMA Read
+ // DMA Read the whole thing - dma_read will raise irq
if (dma_read(core, ide, channel) == -1) {
PrintError(core->vm_info, core, "Failed DMA Read\n");
return -1;
}
} else {
- // DMA write
+ // DMA write the whole thing - dma_write will raiase irw
if (dma_write(core, ide, channel) == -1) {
PrintError(core->vm_info, core, "Failed DMA Write\n");
return -1;
}
}
-
- channel->dma_cmd.val &= 0x09;
+
+ // DMA complete
+ // Note that guest cannot abort a DMA transfer
+ channel->dma_cmd.start = 0;
}
break;
case DMA_STATUS_PORT: {
+ // This is intended to clear status
+
uint8_t val = *(uint8_t *)src;
if (length != 1) {
- PrintError(core->vm_info, core, "Invalid read length for DMA status port\n");
+ PrintError(core->vm_info, core, "Invalid write length for DMA status port\n");
return -1;
}
- // weirdness
+ // but preserve certain bits
channel->dma_status.val = ((val & 0x60) |
(channel->dma_status.val & 0x01) |
(channel->dma_status.val & ~val & 0x06));
switch (channel->cmd_reg) {
- case ATAPI_PIDENTIFY: // ATAPI Identify Device Packet
+ case ATA_PIDENTIFY: // ATAPI Identify Device Packet (CDROM)
if (drive->drive_type != BLOCK_CDROM) {
drive_reset(drive);
ide_raise_irq(ide, channel);
}
break;
- case ATAPI_IDENTIFY: // Identify Device
+
+ case ATA_IDENTIFY: // Identify Device
if (drive->drive_type != BLOCK_DISK) {
drive_reset(drive);
}
break;
- case ATAPI_PACKETCMD: // ATAPI Command Packet
+ case ATA_PACKETCMD: // ATAPI Command Packet (CDROM)
if (drive->drive_type != BLOCK_CDROM) {
ide_abort_command(ide, channel);
}
channel->status.data_req = 1;
channel->status.error = 0;
- // reset the datxgoto-la buffer...
+ // reset the data buffer...
drive->transfer_length = ATAPI_PACKET_SIZE;
drive->transfer_index = 0;
break;
- case ATAPI_READ: // Read Sectors with Retry
- case ATAPI_READ_ONCE: // Read Sectors without Retry
- drive->hd_state.cur_sector_num = 1;
+ case ATA_READ: // Read Sectors with Retry
+ case ATA_READ_ONCE: // Read Sectors without Retry
+ case ATA_MULTREAD: // Read multiple sectors per ire
+ case ATA_READ_EXT: // Read Sectors Extended (LBA48)
+
+ if (channel->cmd_reg==ATA_MULTREAD) {
+ drive->hd_state.cur_sector_num = drive->hd_state.mult_sector_num;
+ } else {
+ drive->hd_state.cur_sector_num = 1;
+ }
if (ata_read_sectors(ide, channel) == -1) {
PrintError(core->vm_info, core, "Error reading sectors\n");
- return -1;
+ ide_abort_command(ide,channel);
}
break;
- case ATAPI_READ_EXT: // Read Sectors Extended
- drive->hd_state.cur_sector_num = 1;
+ case ATA_WRITE: // Write Sector with retry
+ case ATA_WRITE_ONCE: // Write Sector without retry
+ case ATA_MULTWRITE: // Write multiple sectors per irq
+ case ATA_WRITE_EXT: // Write Sectors Extended (LBA48)
- if (ata_read_sectors_ext(ide, channel) == -1) {
- PrintError(core->vm_info, core, "Error reading extended sectors\n");
- return -1;
+ if (channel->cmd_reg==ATA_MULTWRITE) {
+ drive->hd_state.cur_sector_num = drive->hd_state.mult_sector_num;
+ } else {
+ drive->hd_state.cur_sector_num = 1;
}
- break;
-
- case ATAPI_WRITE: {// Write Sector
- drive->hd_state.cur_sector_num = 1;
if (ata_write_sectors(ide, channel) == -1) {
PrintError(core->vm_info, core, "Error writing sectors\n");
- return -1;
+ ide_abort_command(ide,channel);
}
break;
- }
-
-
- case ATAPI_READDMA: // Read DMA with retry
- case ATAPI_READDMA_ONCE: { // Read DMA
- uint32_t sect_cnt = (drive->sector_count == 0) ? 256 : drive->sector_count;
+ case ATA_READDMA: // Read DMA with retry
+ case ATA_READDMA_ONCE: // Read DMA without retry
+ case ATA_READDMA_EXT: { // Read DMA (LBA48)
+ uint64_t sect_cnt;
- if (ata_get_lba(ide, channel, &(drive->current_lba)) == -1) {
+ if (ata_get_lba_and_size(ide, channel, &(drive->current_lba), §_cnt) == -1) {
+ PrintError(core->vm_info, core, "Error getting LBA for DMA READ\n");
ide_abort_command(ide, channel);
- return 0;
+ return length;
}
- drive->hd_state.cur_sector_num = 1;
+ drive->hd_state.cur_sector_num = 1; // Not used for DMA
drive->transfer_length = sect_cnt * HD_SECTOR_SIZE;
drive->transfer_index = 0;
- if (channel->dma_status.active == 1) {
- // DMA Read
- if (dma_read(core, ide, channel) == -1) {
- PrintError(core->vm_info, core, "Failed DMA Read\n");
- return -1;
- }
- }
+ // Now we wait for the transfer to be intiated by flipping the
+ // bus-master start bit
break;
}
- case ATAPI_WRITEDMA: { // Write DMA
- uint32_t sect_cnt = (drive->sector_count == 0) ? 256 : drive->sector_count;
+ case ATA_WRITEDMA: // Write DMA with retry
+ case ATA_WRITEDMA_ONCE: // Write DMA without retry
+ case ATA_WRITEDMA_EXT: { // Write DMA (LBA48)
+
+ uint64_t sect_cnt;
- if (ata_get_lba(ide, channel, &(drive->current_lba)) == -1) {
+ if (ata_get_lba_and_size(ide, channel, &(drive->current_lba),§_cnt) == -1) {
+ PrintError(core->vm_info,core,"Cannot get lba\n");
ide_abort_command(ide, channel);
- return 0;
+ return length;
}
- drive->hd_state.cur_sector_num = 1;
+ drive->hd_state.cur_sector_num = 1; // Not used for DMA
drive->transfer_length = sect_cnt * HD_SECTOR_SIZE;
drive->transfer_index = 0;
- if (channel->dma_status.active == 1) {
- // DMA Write
- if (dma_write(core, ide, channel) == -1) {
- PrintError(core->vm_info, core, "Failed DMA Write\n");
- return -1;
- }
- }
+ // Now we wait for the transfer to be intiated by flipping the
+ // bus-master start bit
break;
}
- case ATAPI_STANDBYNOW1: // Standby Now 1
- case ATAPI_IDLEIMMEDIATE: // Set Idle Immediate
- case ATAPI_STANDBY: // Standby
- case ATAPI_SETIDLE1: // Set Idle 1
- case ATAPI_SLEEPNOW1: // Sleep Now 1
- case ATAPI_STANDBYNOW2: // Standby Now 2
- case ATAPI_IDLEIMMEDIATE2: // Idle Immediate (CFA)
- case ATAPI_STANDBY2: // Standby 2
- case ATAPI_SETIDLE2: // Set idle 2
- case ATAPI_SLEEPNOW2: // Sleep Now 2
+
+ case ATA_STANDBYNOW1: // Standby Now 1
+ case ATA_IDLEIMMEDIATE: // Set Idle Immediate
+ case ATA_STANDBY: // Standby
+ case ATA_SETIDLE1: // Set Idle 1
+ case ATA_SLEEPNOW1: // Sleep Now 1
+ case ATA_STANDBYNOW2: // Standby Now 2
+ case ATA_IDLEIMMEDIATE2: // Idle Immediate (CFA)
+ case ATA_STANDBY2: // Standby 2
+ case ATA_SETIDLE2: // Set idle 2
+ case ATA_SLEEPNOW2: // Sleep Now 2
channel->status.val = 0;
channel->status.ready = 1;
ide_raise_irq(ide, channel);
break;
- case ATAPI_SETFEATURES: // Set Features
+ case ATA_SETFEATURES: // Set Features
// Prior to this the features register has been written to.
// This command tells the drive to check if the new value is supported (the value is drive specific)
// Common is that bit0=DMA enable
ide_raise_irq(ide, channel);
break;
- case ATAPI_SPECIFY: // Initialize Drive Parameters
- case ATAPI_RECAL: // recalibrate?
+ case ATA_SPECIFY: // Initialize Drive Parameters
+ case ATA_RECAL: // recalibrate?
channel->status.error = 0;
channel->status.ready = 1;
channel->status.seek_complete = 1;
ide_raise_irq(ide, channel);
break;
- case ATAPI_SETMULT: { // Set multiple mode (IDE Block mode)
- // This makes the drive transfer multiple sectors before generating an interrupt
- uint32_t tmp_sect_num = drive->sector_num; // GCC SUCKS
- if (tmp_sect_num > MAX_MULT_SECTORS) {
- ide_abort_command(ide, channel);
- break;
- }
+ case ATA_SETMULT: { // Set multiple mode (IDE Block mode)
+ // This makes the drive transfer multiple sectors before generating an interrupt
if (drive->sector_count == 0) {
+ PrintError(core->vm_info,core,"Attempt to set multiple to zero\n");
drive->hd_state.mult_sector_num= 1;
+ ide_abort_command(ide,channel);
+ break;
} else {
drive->hd_state.mult_sector_num = drive->sector_count;
}
break;
}
- case ATAPI_DEVICE_RESET: // Reset Device
+ case ATA_DEVICE_RESET: // Reset Device
drive_reset(drive);
channel->error_reg.val = 0x01;
channel->status.busy = 0;
channel->status.error = 0;
break;
- case ATAPI_CHECKPOWERMODE1: // Check power mode
+ case ATA_CHECKPOWERMODE1: // Check power mode
drive->sector_count = 0xff; /* 0x00=standby, 0x80=idle, 0xff=active or idle */
channel->status.busy = 0;
channel->status.ready = 1;
channel->status.error = 0;
break;
- case ATAPI_MULTREAD: // read multiple sectors
- drive->hd_state.cur_sector_num = drive->hd_state.mult_sector_num;
default:
PrintError(core->vm_info, core, "Unimplemented IDE command (%x)\n", channel->cmd_reg);
- return -1;
+ ide_abort_command(ide, channel);
+ break;
}
return length;
}
-static int write_data_port(struct guest_info * core, ushort_t port, void * src, uint_t length, void * priv_data) {
- struct ide_internal * ide = priv_data;
- struct ide_channel * channel = get_selected_channel(ide, port);
- struct ide_drive * drive = get_selected_drive(channel);
-
- PrintDebug(core->vm_info, core, "IDE: Writing Data Port %x (val=%x, len=%d)\n",
- port, *(uint32_t *)src, length);
- memcpy(drive->data_buf + drive->transfer_index, src, length);
- drive->transfer_index += length;
- // Transfer is complete, dispatch the command
- if (drive->transfer_index >= drive->transfer_length) {
- switch (channel->cmd_reg) {
-
- case ATAPI_WRITE: // Write Sectors
-
- channel->status.busy = 1;
- channel->status.data_req = 0;
-
- if (ata_write(ide, channel, drive->data_buf, drive->transfer_length/HD_SECTOR_SIZE) == -1) {
- PrintError(core->vm_info, core, "Error writing to disk\n");
- return -1;
- }
-
- PrintDebug(core->vm_info, core, "IDE: Write sectors complete\n");
-
- channel->status.error = 0;
- channel->status.busy = 0;
-
- ide_raise_irq(ide, channel);
- break;
-
- case ATAPI_PACKETCMD: // ATAPI packet command
- if (atapi_handle_packet(core, ide, channel) == -1) {
- PrintError(core->vm_info, core, "Error handling ATAPI packet\n");
- return -1;
- }
- break;
- default:
- PrintError(core->vm_info, core, "Unhandld IDE Command %x\n", channel->cmd_reg);
- return -1;
- }
- }
-
- return length;
-}
-
-
-static int read_hd_data(uint8_t * dst, uint_t length, struct ide_internal * ide, struct ide_channel * channel) {
+static int read_hd_data(uint8_t * dst, uint64_t length, struct ide_internal * ide, struct ide_channel * channel) {
struct ide_drive * drive = get_selected_drive(channel);
- int data_offset = drive->transfer_index % HD_SECTOR_SIZE;
+ uint64_t data_offset = drive->transfer_index % HD_SECTOR_SIZE;
+ PrintDebug(VM_NONE,VCORE_NONE, "Read HD data: transfer_index %llu transfer length %llu current sector numer %llu\n",
+ drive->transfer_index, drive->transfer_length,
+ drive->hd_state.cur_sector_num);
if (drive->transfer_index >= drive->transfer_length) {
- PrintError(VM_NONE, VCORE_NONE, "Buffer overrun... (xfer_len=%d) (cur_idx=%x) (post_idx=%d)\n",
+ PrintError(VM_NONE, VCORE_NONE, "Buffer overrun... (xfer_len=%llu) (cur_idx=%llu) (post_idx=%llu)\n",
drive->transfer_length, drive->transfer_index,
drive->transfer_index + length);
return -1;
}
-
+
+ if (data_offset + length > HD_SECTOR_SIZE) {
+ PrintError(VM_NONE,VCORE_NONE,"Read spans sectors (data_offset=%llu length=%llu)!\n",data_offset,length);
+ }
+
+ // For index==0, the read has been done in ata_read_sectors
if ((data_offset == 0) && (drive->transfer_index > 0)) {
+ // advance to next sector and read it
+
drive->current_lba++;
if (ata_read(ide, channel, drive->data_buf, 1) == -1) {
(drive->transfer_index == drive->transfer_length)) {
if (drive->transfer_index < drive->transfer_length) {
// An increment is complete, but there is still more data to be transferred...
- PrintDebug(VM_NONE, VCORE_NONE, "Integral Complete, still transferring more sectors\n");
+ PrintDebug(VM_NONE, VCORE_NONE, "Increment Complete, still transferring more sectors\n");
channel->status.data_req = 1;
-
- drive->irq_flags.c_d = 0;
} else {
PrintDebug(VM_NONE, VCORE_NONE, "Final Sector Transferred\n");
// This was the final read of the request
channel->status.data_req = 0;
-
-
- drive->irq_flags.c_d = 1;
- drive->irq_flags.rel = 0;
}
channel->status.ready = 1;
- drive->irq_flags.io_dir = 1;
channel->status.busy = 0;
ide_raise_irq(ide, channel);
return length;
}
+static int write_hd_data(uint8_t * src, uint64_t length, struct ide_internal * ide, struct ide_channel * channel) {
+ struct ide_drive * drive = get_selected_drive(channel);
+ uint64_t data_offset = drive->transfer_index % HD_SECTOR_SIZE;
+
+ PrintDebug(VM_NONE,VCORE_NONE, "Write HD data: transfer_index %llu transfer length %llu current sector numer %llu\n",
+ drive->transfer_index, drive->transfer_length,
+ drive->hd_state.cur_sector_num);
-static int read_cd_data(uint8_t * dst, uint_t length, struct ide_internal * ide, struct ide_channel * channel) {
+ if (drive->transfer_index >= drive->transfer_length) {
+ PrintError(VM_NONE, VCORE_NONE, "Buffer overrun... (xfer_len=%llu) (cur_idx=%llu) (post_idx=%llu)\n",
+ drive->transfer_length, drive->transfer_index,
+ drive->transfer_index + length);
+ return -1;
+ }
+
+ if (data_offset + length > HD_SECTOR_SIZE) {
+ PrintError(VM_NONE,VCORE_NONE,"Write spans sectors (data_offset=%llu length=%llu)!\n",data_offset,length);
+ }
+
+ // Copy data into our buffer - there will be room due to
+ // (a) the ata_write test below is flushing sectors
+ // (b) if we somehow get a sector-stradling write (an error), this will
+ // be OK since the buffer itself is >1 sector in memory
+ memcpy(drive->data_buf + data_offset, src, length);
+
+ drive->transfer_index += length;
+
+ if ((data_offset+length) >= HD_SECTOR_SIZE) {
+ // Write out the sector we just finished
+ if (ata_write(ide, channel, drive->data_buf, 1) == -1) {
+ PrintError(VM_NONE, VCORE_NONE, "Could not write next disk sector\n");
+ return -1;
+ }
+
+ // go onto next sector
+ drive->current_lba++;
+ }
+
+ /* This is the trigger for interrupt injection.
+ * For write single sector commands we interrupt after every sector
+ * For multi sector reads we interrupt only at end of the cluster size (mult_sector_num)
+ * cur_sector_num is configured depending on the operation we are currently running
+ * We also trigger an interrupt if this is the last byte to transfer, regardless of sector count
+ */
+ if (((drive->transfer_index % (HD_SECTOR_SIZE * drive->hd_state.cur_sector_num)) == 0) ||
+ (drive->transfer_index == drive->transfer_length)) {
+ if (drive->transfer_index < drive->transfer_length) {
+ // An increment is complete, but there is still more data to be transferred...
+ PrintDebug(VM_NONE, VCORE_NONE, "Increment Complete, still transferring more sectors\n");
+ channel->status.data_req = 1;
+ } else {
+ PrintDebug(VM_NONE, VCORE_NONE, "Final Sector Transferred\n");
+ // This was the final read of the request
+ channel->status.data_req = 0;
+ }
+
+ channel->status.ready = 1;
+ channel->status.busy = 0;
+
+ ide_raise_irq(ide, channel);
+ }
+
+ return length;
+}
+
+
+
+static int read_cd_data(uint8_t * dst, uint64_t length, struct ide_internal * ide, struct ide_channel * channel) {
struct ide_drive * drive = get_selected_drive(channel);
- int data_offset = drive->transfer_index % ATAPI_BLOCK_SIZE;
+ uint64_t data_offset = drive->transfer_index % ATAPI_BLOCK_SIZE;
// int req_offset = drive->transfer_index % drive->req_len;
if (drive->cd_state.atapi_cmd != 0x28) {
- PrintDebug(VM_NONE, VCORE_NONE, "IDE: Reading CD Data (len=%d) (req_len=%d)\n", length, drive->req_len);
- PrintDebug(VM_NONE, VCORE_NONE, "IDE: transfer len=%d, transfer idx=%d\n", drive->transfer_length, drive->transfer_index);
+ PrintDebug(VM_NONE, VCORE_NONE, "IDE: Reading CD Data (len=%llu) (req_len=%u)\n", length, drive->req_len);
+ PrintDebug(VM_NONE, VCORE_NONE, "IDE: transfer len=%llu, transfer idx=%llu\n", drive->transfer_length, drive->transfer_index);
}
if (drive->transfer_index >= drive->transfer_length) {
- PrintError(VM_NONE, VCORE_NONE, "Buffer Overrun... (xfer_len=%d) (cur_idx=%d) (post_idx=%d)\n",
+ PrintError(VM_NONE, VCORE_NONE, "Buffer Overrun... (xfer_len=%llu) (cur_idx=%llu) (post_idx=%llu)\n",
drive->transfer_length, drive->transfer_index,
drive->transfer_index + length);
return -1;
}
-static int ide_read_data_port(struct guest_info * core, ushort_t port, void * dst, uint_t length, void * priv_data) {
+
+static int read_data_port(struct guest_info * core, ushort_t port, void * dst, uint_t length, void * priv_data) {
struct ide_internal * ide = priv_data;
struct ide_channel * channel = get_selected_channel(ide, port);
struct ide_drive * drive = get_selected_drive(channel);
- // PrintDebug(core->vm_info, core, "IDE: Reading Data Port %x (len=%d)\n", port, length);
+ //PrintDebug(core->vm_info, core, "IDE: Reading Data Port %x (len=%d)\n", port, length);
- if ((channel->cmd_reg == 0xec) ||
- (channel->cmd_reg == 0xa1)) {
+ if ((channel->cmd_reg == ATA_IDENTIFY) ||
+ (channel->cmd_reg == ATA_PIDENTIFY)) {
return read_drive_id((uint8_t *)dst, length, ide, channel);
}
return length;
}
+// For the write side, we care both about
+// direct PIO writes to a drive as well as
+// writes that pass a packet through to an CD
+static int write_data_port(struct guest_info * core, ushort_t port, void * src, uint_t length, void * priv_data) {
+ struct ide_internal * ide = priv_data;
+ struct ide_channel * channel = get_selected_channel(ide, port);
+ struct ide_drive * drive = get_selected_drive(channel);
+
+ PrintDebug(core->vm_info, core, "IDE: Writing Data Port %x (val=%x, len=%d)\n",
+ port, *(uint32_t *)src, length);
+
+ if (drive->drive_type == BLOCK_CDROM) {
+ if (channel->cmd_reg == ATA_PACKETCMD) {
+ // short command packet - no check for space...
+ memcpy(drive->data_buf + drive->transfer_index, src, length);
+ drive->transfer_index += length;
+ if (drive->transfer_index >= drive->transfer_length) {
+ if (atapi_handle_packet(core, ide, channel) == -1) {
+ PrintError(core->vm_info, core, "Error handling ATAPI packet\n");
+ return -1;
+ }
+ }
+ } else {
+ PrintError(core->vm_info,core,"Unknown command %x on CD ROM\n",channel->cmd_reg);
+ return -1;
+ }
+ } else if (drive->drive_type == BLOCK_DISK) {
+ if (write_hd_data((uint8_t *)src, length, ide, channel) == -1) {
+ PrintError(core->vm_info, core, "IDE: Could not write HD Data\n");
+ return -1;
+ }
+ } else {
+ // nothing ... do not support writable cd
+ }
+
+ return length;
+}
+
static int write_port_std(struct guest_info * core, ushort_t port, void * src, uint_t length, void * priv_data) {
struct ide_internal * ide = priv_data;
struct ide_channel * channel = get_selected_channel(ide, port);
case PRI_SECT_CNT_PORT:
case SEC_SECT_CNT_PORT:
+ // update CHS and LBA28 state
channel->drives[0].sector_count = *(uint8_t *)src;
channel->drives[1].sector_count = *(uint8_t *)src;
+
+ // update LBA48 state
+ if (is_lba48(channel)) {
+ uint16_t val = *(uint8_t*)src; // top bits zero;
+ if (!channel->drives[0].lba48.sector_count_state) {
+ channel->drives[0].lba48.sector_count = val<<8;
+ } else {
+ channel->drives[0].lba48.sector_count |= val;
+ }
+ channel->drives[0].lba48.sector_count_state ^= 1;
+ if (!channel->drives[1].lba48.sector_count_state) {
+ channel->drives[1].lba48.sector_count = val<<8;
+ } else {
+ channel->drives[1].lba48.sector_count |= val;
+ }
+ channel->drives[0].lba48.sector_count_state ^= 1;
+ }
+
break;
case PRI_SECT_NUM_PORT:
case SEC_SECT_NUM_PORT:
+ // update CHS and LBA28 state
channel->drives[0].sector_num = *(uint8_t *)src;
channel->drives[1].sector_num = *(uint8_t *)src;
+
+ // update LBA48 state
+ if (is_lba48(channel)) {
+ uint64_t val = *(uint8_t *)src; // lob off top 7 bytes;
+ if (!channel->drives[0].lba48.lba41_state) {
+ channel->drives[0].lba48.lba |= val<<24;
+ } else {
+ channel->drives[0].lba48.lba |= val;
+ }
+ channel->drives[0].lba48.lba41_state ^= 1;
+ if (!channel->drives[1].lba48.lba41_state) {
+ channel->drives[1].lba48.lba |= val<<24;
+ } else {
+ channel->drives[1].lba48.lba |= val;
+ }
+ channel->drives[1].lba48.lba41_state ^= 1;
+ }
+
break;
case PRI_CYL_LOW_PORT:
case SEC_CYL_LOW_PORT:
+ // update CHS and LBA28 state
channel->drives[0].cylinder_low = *(uint8_t *)src;
channel->drives[1].cylinder_low = *(uint8_t *)src;
+
+ // update LBA48 state
+ if (is_lba48(channel)) {
+ uint64_t val = *(uint8_t *)src; // lob off top 7 bytes;
+ if (!channel->drives[0].lba48.lba52_state) {
+ channel->drives[0].lba48.lba |= val<<32;
+ } else {
+ channel->drives[0].lba48.lba |= val<<8;
+ }
+ channel->drives[0].lba48.lba52_state ^= 1;
+ if (!channel->drives[1].lba48.lba52_state) {
+ channel->drives[1].lba48.lba |= val<<32;
+ } else {
+ channel->drives[1].lba48.lba |= val<<8;
+ }
+ channel->drives[1].lba48.lba52_state ^= 1;
+ }
+
break;
case PRI_CYL_HIGH_PORT:
case SEC_CYL_HIGH_PORT:
+ // update CHS and LBA28 state
channel->drives[0].cylinder_high = *(uint8_t *)src;
channel->drives[1].cylinder_high = *(uint8_t *)src;
+
+ // update LBA48 state
+ if (is_lba48(channel)) {
+ uint64_t val = *(uint8_t *)src; // lob off top 7 bytes;
+ if (!channel->drives[0].lba48.lba63_state) {
+ channel->drives[0].lba48.lba |= val<<40;
+ } else {
+ channel->drives[0].lba48.lba |= val<<16;
+ }
+ channel->drives[0].lba48.lba63_state ^= 1;
+ if (!channel->drives[1].lba48.lba63_state) {
+ channel->drives[1].lba48.lba |= val<<40;
+ } else {
+ channel->drives[1].lba48.lba |= val<<16;
+ }
+ channel->drives[1].lba48.lba63_state ^= 1;
+ }
+
break;
case PRI_DRV_SEL_PORT:
case SEC_DRV_SEL_PORT: {
- channel->drive_head.val = *(uint8_t *)src;
+ struct ide_drive_head_reg nh, oh;
+
+ oh.val = channel->drive_head.val;
+ channel->drive_head.val = nh.val = *(uint8_t *)src;
+
+ // has LBA flipped?
+ if ((oh.val & 0xe0) != (nh.val & 0xe0)) {
+ // reset LBA48 state
+ channel->drives[0].lba48.sector_count_state=0;
+ channel->drives[0].lba48.lba41_state=0;
+ channel->drives[0].lba48.lba52_state=0;
+ channel->drives[0].lba48.lba63_state=0;
+ channel->drives[1].lba48.sector_count_state=0;
+ channel->drives[1].lba48.lba41_state=0;
+ channel->drives[1].lba48.lba52_state=0;
+ channel->drives[1].lba48.lba63_state=0;
+ }
- // make sure the reserved bits are ok..
- // JRL TODO: check with new ramdisk to make sure this is right...
- channel->drive_head.val |= 0xa0;
drive = get_selected_drive(channel);
V3_CHKPT_SAVE(ctx, "PRD_ADDR", ch->dma_prd_addr, savefailout);
V3_CHKPT_SAVE(ctx, "DMA_TBL_IDX", ch->dma_tbl_index, savefailout);
+
+
v3_chkpt_close_ctx(ctx); ctx=0;
for (drive_num = 0; drive_num < 2; drive_num++) {
PrintError(VM_NONE, VCORE_NONE, "Invalid drive type %d\n",drive->drive_type);
goto savefailout;
}
+
+ V3_CHKPT_SAVE(ctx, "LBA48_LBA", drive->lba48.lba, savefailout);
+ V3_CHKPT_SAVE(ctx, "LBA48_SECTOR_COUNT", drive->lba48.sector_count, savefailout);
+ V3_CHKPT_SAVE(ctx, "LBA48_SECTOR_COUNT_STATE", drive->lba48.sector_count_state, savefailout);
+ V3_CHKPT_SAVE(ctx, "LBA48_LBA41_STATE", drive->lba48.lba41_state, savefailout);
+ V3_CHKPT_SAVE(ctx, "LBA48_LBA52_STATE", drive->lba48.lba52_state, savefailout);
+ V3_CHKPT_SAVE(ctx, "LBA48_LBA63_STATE", drive->lba48.lba63_state, savefailout);
v3_chkpt_close_ctx(ctx); ctx=0;
}
PrintError(VM_NONE, VCORE_NONE, "Invalid drive type %d\n",drive->drive_type);
goto loadfailout;
}
+
+ V3_CHKPT_LOAD(ctx, "LBA48_LBA", drive->lba48.lba, loadfailout);
+ V3_CHKPT_LOAD(ctx, "LBA48_SECTOR_COUNT", drive->lba48.sector_count, loadfailout);
+ V3_CHKPT_LOAD(ctx, "LBA48_SECTOR_COUNT_STATE", drive->lba48.sector_count_state, loadfailout);
+ V3_CHKPT_LOAD(ctx, "LBA48_LBA41_STATE", drive->lba48.lba41_state, loadfailout);
+ V3_CHKPT_LOAD(ctx, "LBA48_LBA52_STATE", drive->lba48.lba52_state, loadfailout);
+ V3_CHKPT_LOAD(ctx, "LBA48_LBA63_STATE", drive->lba48.lba63_state, loadfailout);
+
}
}
// goodout:
}
ide->southbridge = (struct v3_southbridge *)(southbridge->private_data);
+ } else {
+ PrintError(vm,VCORE_NONE,"Strange - you don't have a PCI bus\n");
}
PrintDebug(vm, VCORE_NONE, "IDE: Creating IDE bus x 2\n");
PrintDebug(vm, VCORE_NONE, "Connecting to IDE IO ports\n");
ret |= v3_dev_hook_io(dev, PRI_DATA_PORT,
- &ide_read_data_port, &write_data_port);
+ &read_data_port, &write_data_port);
ret |= v3_dev_hook_io(dev, PRI_FEATURES_PORT,
&read_port_std, &write_port_std);
ret |= v3_dev_hook_io(dev, PRI_SECT_CNT_PORT,
&read_port_std, &write_cmd_port);
ret |= v3_dev_hook_io(dev, SEC_DATA_PORT,
- &ide_read_data_port, &write_data_port);
+ &read_data_port, &write_data_port);
ret |= v3_dev_hook_io(dev, SEC_FEATURES_PORT,
&read_port_std, &write_port_std);
ret |= v3_dev_hook_io(dev, SEC_SECT_CNT_PORT,
struct pci_device * pci_dev = NULL;
int i;
- PrintDebug(vm, VCORE_NONE, "Connecting IDE to PCI bus\n");
+ V3_Print(vm, VCORE_NONE, "Connecting IDE to PCI bus\n");
for (i = 0; i < 6; i++) {
bars[i].type = PCI_BAR_NONE;