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The IDE/ATA Interface

The IDE/ATA Interface. How can our mini-Operating System, executing in protected mode, access the hard disk? . The EDD services.

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The IDE/ATA Interface

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  1. The IDE/ATA Interface How can our mini-Operating System, executing in protected mode, access the hard disk?

  2. The EDD services • So far we have relied upon the Extended Disk Drive service-functions (available in real-mode via ‘int $0x13’) to perform any transfers of data between main memory and our computer system’s hard disk • But these service-functions in ROM-BIOS are designed to be executed in real-mode • Can we achieve their effects when PE=1?

  3. Persistent data storage • Any operating system we might design, no matter how minimal, would need to offer a way to write and to read ‘persistent data’, organized into some kind of ‘file system’ that is maintained on a secondary storage device, such as a hard disk or a diskette

  4. Hardware interfacing • Modern computer platforms are expected to provide a specially designed peripheral processor, the hard disk controller, which can be programmed by system software to carry out data-transfers between a disk and the computer’s primary memory • The programming interface for hard disk controllers continues to evolve, but a stable set of standard capabilities exists

  5. A few cautions • Our classroom and laboratory computers are shared by many users who are taking various computer sciences courses • Writing to the hard disk in a careless way can do damage to the operating systems (making a machine completely unusable) • In your early experiments you will need to use great caution to avoid corrupting vital areas of these shared hard disks!

  6. Typical Chipset Layout CPU Central Processing Unit MCH Memory Controller Hub (Northbridge) DRAM Dynamic Random Access Memory Graphics Controller NIC Network Interface Controller AC Audio Controller ICH I/O Controller Hub (Southbridge) Multimedia Controller HDC Hard Disk Controller Firmware Hub Timer Keyboard Mouse Clock

  7. Which I/O ports? • The disk-controller on our USF systems is a component within the I/O-Controller Hub • The port-addresses used for accessing it are assigned by the ROM-BIOS during the system- startup process and are stored in certain Base-Address registers within the PCI Configuration Space for Intel’s SATA Controller component of the ICH device

  8. Tools we used • We used our ‘pciprobe.cpp’ application to perform a PCI bus scan and report all the PCI devices which our system contains • We used the PCI CLASS-CODE for SATA Mass Storage devices (code 0x010601) to identify the hard-disk’s controller device • We wrote an LKM (Linux Kernel Module) that shows the PCI Configuration Space

  9. BAR field-formats 31 15 0 reserved i/o-port address 0 1 I/O Space Indicator 31 7 6 5 4 3 2 1 0 memory address 0 0 0 P R E F Type 0 Memory Space Indicator

  10. SATA Controller BARs IDE Command-Block for Primary Drive BAR0 BAR1 BAR2 BAR3 BAR4 BAR5 IDE Control-Block for Primary Drive IDE Command-Block for Secondary Drive IDE Control-Block for Secondary Drive DMA Control-Block

  11. Fixed-Size ‘blocks’ • All data-transfers to and from the hard disk are comprised of fixed-size blocks called ‘sectors’ (whose size equals 512 bytes) • On modern hard disks, these sectors are identified by sector-numbers starting at 0 • This scheme for addressing disk sectors is known as Logical Block Addressing (LBA) • So the hard disk is just an array of sectors

  12. Platform-specific parameters • Although older PCs used some standard I/O port-addresses for communicating with their Disk Controllers, newer PCs like ours allow these port-addresses to be assigned dynamically during the system’s startup • To keep our demonstration-code as short and uncluttered as possible, we will ‘hard-code’ the port-numbers our machines use

  13. The ATA/IDE Interface • All communication between our driver and the Hard Disk Controller is performed with ‘in’ and ‘out’ instructions that refer to ports • Older PCs had standard i/o port-numbers for communicating with the Disk Controller • But newer PCs assign these dynamically

  14. When reading… Data Error Sector Count LBA Low LBA Mid LBA High Device Status When writing… Data Features Sector Count LBA Low LBA Mid LBA High Device Command IDE Command Block registers

  15. When reading… Alternate Status When writing… Device Control IDE Control Block Registers INCRITS InterNational Committee on Information Technology Standards Committee T-13

  16. When reading… Primary DMA Control Primary DMA Status Primary PRD Pointer When writing… Primary DMA Control Primary DMA Status Primary PRD Pointer Bus Master DMA PRD = Physical Region Descriptor INTEL ICH7 I/O Controller Hub Datasheet SATA Controller Registers

  17. Two I/O design-paradigms • PIO: Programmed I/O for ‘reading’ • The cpu outputs parameters to the controller • The cpu waits till the data becomes available • The cpu transfers the data into main memory • DMA: Direct Memory Access for ‘reading’ • The cpu outputs parameters to the controller • The cpu activates the DMA engine to begin • The cpu deactivates the DMA engine to end

  18. PIO algorithm overview • First select the device to read from: • Wait until the controller is not busy and does not have any data that it wants to transfer • Write to Command Block’s Device register to select the disk to send the command to • Wait until the controller indicates that it is ready to receive your new command

  19. PIO overview (continued) • Place the command’s parameters into the appropriate Command Block registers • Put command-code in Command register • Then wait until the controller indicates that it has read the requested sector’s data and is ready for you to transfer it into memory • Use a loop to input 256 words (one sector) from the Command Block’s Data register

  20. PIO overview (conclusion) • After you have transferred a sector, check the Controller Status to see if there were any errors (if so read the Error register) • To implement this algorithm, we need to look at the meaning of some individual bits in the Status register (and Error register)

  21. Status register (cmd+7) 7 6 5 4 3 2 1 0 BSY DRDY DF DRQ ERR Legend: BSY (Device still Busy with prior command): 1=yes, 0=no DRDY (Device is Ready for a new command): 1=yes, 0=no DF (Device Fault – command cannot finish): 1=yes, 0=no DRQ (Data-transfer is currently Requested): 1=yes, 0=no ERR (Error information is in Error Register): 1 = yes, 0=no

  22. Device register (cmd+6) 7 6 5 4 3 2 1 0 1 LBA (=1) 1 DEV (0/1) Sector-ID[ 27..24 ] Legend: LBA (Logical Block Addressing): 1=yes, 0=no DEV (Device selection): 1=slave, 0=master Sector-ID: Most significant 4-bits of 28-bit Sector-Address

  23. Error register (cmd+1) 7 6 5 4 3 2 1 0 UNC MC IDNF MCR ABRT NM Legend: UNC (Data error was UnCorrectable): 1=yes, 0=no MC (Media was Changed): 1=yes, 0=no IDNF (ID Not Found): 1=yes, 0=no MCR (Media Change was Requested): 1=yes, 0=no ABRT (Command was Aborted): 1 = yes, 0=no NM (No Media was present): 1=yes, 0=no

  24. Device Control register (ctl+2) 7 6 5 4 3 2 1 0 HOB 0 0 0 0 SRST nIEN 0 Legend: HOB (High-Order Byte): 1=yes, 0=no SRST (Software Reset requested): 1=yes, 0=no nIEN (negate Interrupt Enabled): 1=yes, 0=no NOTE: The HOB-bit is unimplemented on our machines; it is for large-capacity disks that require 44-bit sector-addresses

  25. Advantage of DMA • For a multiprogramming operating system that employs ‘timesharing’ to concurrently execute multiple tasks, there is an obvious advantage in ‘offloading’ the data-transfer step to a peripheral processor • It frees the CPU to do work on other tasks during the time-interval when the data is actually being transferred

  26. DMA Command register 7 6 5 4 3 2 1 0 0 0 0 0 Read/ Write 0 0 Start /Stop Legend: Start/Stop: 1 = Start DMA transfer; 0 = Stop DMA transfer Read/Write: 1 = Read to memory; 0 = Write from memory

  27. DMA Status register 7 6 5 4 3 2 1 0 PRDIS - - 0 0 INT ERR ACT Legend: ACT (DMA engine is currectly Active): 1 = yes; 0 = no ERR (The controller encountered an Error): 1=yes; 0=no INT (The controller generated an Interrupt: 1=yes; 0=no PRDIS: (PRD Interrupt Status): 1=active, 0=inactive Software clears these labeled bits by writing 1’s to them

  28. PRD Pointer register 31 0 Physical memory-address of the PRD Table (must be quadword aligned) Each PRD (Physical Region Descriptor) consists of these three fields: Base-address of the physical region bytes 3..0 Reserved (0) E O T Size of the region bytes 7..4 NOTE: The total size of the PRD Table cannot exceed 64KB

  29. DMA algorithm overview • First select the device to read from: • Wait until the controller is not busy and does not have any data that it wants to transfer • Write to Command Block’s Device register to select the disk to send the command to • Wait until the controller indicates that it is ready to receive your new command • NOTE: This step is the same as for PIO

  30. DMA overview (continued) • Engage the DMA engine for writing to memory by outputting 0x08 to the DMA Command Port • Clear the labeled bits in the DMA Status register • Place the command’s parameters into the appropriate IDE Command Block registers • Put command-code in IDE Command register • Activate the DMA data-transfer by outputting 0x09 to the DMA Command register • Then wait until the DMA Status register indicates that the DMA data-transfer has been completed

  31. DMA algorithm (concluded) • Turn off the DMA engine by writing 0x08 to the DMA Command register (to clear ACT) • Clear the labeled bits in the DMA Status register (by writing ‘1’s to those bits) • Read the IDE Status register (to clear any interrupt from the IDE Controller), and if bit 0 is set (indicating some error-information is available), then read IDE Error register

  32. DMA demo: ‘satademo.s’ • We created this example showing how to program the Disk-Drive controller while in protected mode to read in the hard disk’s Master Boot Record and then display its four Partition-Table entries • It shows how to read a disk-sector using the hardware’s DMA capability

  33. In-class exercise • Use our ‘satainfo.c’ Linux module to learn which i/o-port addresses are assigned to Intel’s SATA Controller on the machines in our classroom • Then modify the code in our ‘satademo.s’ source-file so that it can be used to display the Partition-Table’s entries for a machine in our classroom

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