chapter 13: i/o systems hung q. ngo kyunghee university spring 2009 note: some slides and/or...
TRANSCRIPT
Chapter 13: I/O Systems
Hung Q. Ngo
KyungHee University
Spring 2009
http://uclab.khu.ac.kr/lectures/2009-1-os.html
Note: Some slides and/or pictures in the following are
adapted from slides ©2005 Silberschatz, Galvin, and Gagne. Many slides generated from my lecture notes
by Kubiatowicz.
13.2 Hung Q. Ngo Spring 2009Operating System
The Requirements of I/O• So far in this course:
– We have learned how to manage CPU, memory• What about I/O?
– Without I/O, computers are useless (disembodied brains?)
– But… thousands of devices, each slightly different» How can we standardize the interfaces to these devices?
– Devices unreliable: media failures and transmission errors» How can we make them reliable???
– Devices unpredictable and/or slow» How can we manage them if we don’t know what they
will do or how they will perform?• Some operational parameters:
– Byte/Block» Some devices provide single byte at a time (e.g.
keyboard)» Others provide whole blocks (e.g. disks, networks, etc)
– Sequential/Random» Some devices must be accessed sequentially (e.g. tape)» Others can be accessed randomly (e.g. disk, cd, etc.)
– Polling/Interrupts» Some devices require continual monitoring» Others generate interrupts when they need service
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Modern I/O Systems
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Example Device-Transfer Rates (Sun Enterprise 6000)
• Device Rates vary over many orders of magnitude– System better be able to handle this wide range– Better not have high overhead/byte for fast devices!– Better not waste time waiting for slow devices
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The Goal of the I/O Subsystem
• Provide Uniform Interfaces, Despite Wide Range of Different Devices– This code works on many different devices:
FILE fd = fopen(“/dev/something”,”rw”);
for (int i = 0; i < 10; i++) {fprintf(fd,”Count %d\n”,i);
}close(fd);
– Why? Because code that controls devices (“device driver”) implements standard interface.
• We will try to get a flavor for what is involved in actually controlling devices in rest of lecture– Can only scratch surface!
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Want Standard Interfaces to Devices
• Block Devices: e.g. disk drives, tape drives, DVD-ROM– Access blocks of data– Commands include open(), read(), write(), seek()– Raw I/O or file-system access– Memory-mapped file access possible
• Character Devices: e.g. keyboards, mice, serial ports, some USB devices– Single characters at a time– Commands include get(), put()– Libraries layered on top allow line editing
• Network Devices: e.g. Ethernet, Wireless, Bluetooth– Different enough from block/character to have own
interface– Unix and Windows include socket interface
» Separates network protocol from network operation» Includes select() functionality
– Usage: pipes, FIFOs, streams, queues, mailboxes
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How Does User Deal with Timing?
• Blocking Interface: “Wait”– When request data (e.g. read() system call), put
process to sleep until data is ready– When write data (e.g. write() system call), put
process to sleep until device is ready for data
• Non-blocking Interface: “Don’t Wait”– Returns quickly from read or write request with
count of bytes successfully transferred– Read may return nothing, write may write nothing
• Asynchronous Interface: “Tell Me Later”– When request data, take pointer to user’s buffer,
return immediately; later kernel fills buffer and notifies user
– When send data, take pointer to user’s buffer, return immediately; later kernel takes data and notifies user
13.8 Hung Q. Ngo Spring 2009Operating System
Main components of Intel Chipset: Pentium 4
• Northbridge:– Handles memory– Graphics
• Southbridge: I/O– PCI bus– Disk controllers– USB controllers– Audio– Serial I/O– Interrupt
controller– Timers
13.9 Hung Q. Ngo Spring 2009Operating System
DeviceController
readwrite
controlstatus
AddressableMemoryand/orQueuesRegisters
(port 0x20)
HardwareController
Memory MappedRegion: 0x8f008020
BusInterface
How does the processor actually talk to the device?
• CPU interacts with a Controller– Contains a set of registers that
can be read and written– May contain memory for request
queues or bit-mapped images • Regardless of the complexity of the connections
and buses, processor accesses registers in two ways: – I/O instructions: in/out instructions
» Example from the Intel architecture: out 0x21,AL– Memory mapped I/O: load/store instructions
» Registers/memory appear in physical address space» I/O accomplished with load and store instructions
Address+Data
Interrupt Request
Processor Memory Bus
CPU
RegularMemory
InterruptController
BusAdaptor
BusAdaptor
Other Devicesor Buses
13.10 Hung Q. Ngo Spring 2009Operating System
Device I/O Port Locations on PCs (partial)
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Example: Memory-Mapped Display Controller• Memory-Mapped:
– Hardware maps control registers and display memory into physical address space» Addresses set by hardware
jumpers or programming at boot time
– Simply writing to display memory (also called the “frame buffer”) changes image on screen» Addr: 0x8000F000—0x8000FFFF
– Writing graphics description to command-queue area » Say enter a set of triangles that
describe some scene» Addr: 0x80010000—0x8001FFFF
– Writing to the command register may cause on-board graphics hardware to do something» Say render the above scene» Addr: 0x0007F004
• Can protect with page tables
DisplayMemory
0x8000F000
0x80010000
Physical AddressSpace
Status0x0007F000Command0x0007F004
GraphicsCommand
Queue
0x80020000
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Transfering Data To/From Controller
• Programmed I/O:– Each byte transferred via processor in/out or
load/store– Pro: Simple hardware, easy to program– Con: Consumes processor cycles proportional to
data size• Direct Memory Access:
– Give controller access to memory bus– Bypasses CPU to transfer data directly between
I/O device and memory
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DMA
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A Kernel I/O Structure
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I/O Systems Layers
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Device Drivers• Device Driver: Device-specific code in the
kernel that interacts directly with the device hardware– Supports a standard, internal interface– Same kernel I/O system can interact easily with
different device drivers– Special device-specific configuration supported
with the ioctl() system call• Device Drivers typically divided into two
pieces:– Top half: accessed in call path from system calls
» Implements a set of standard, cross-device calls like open(), close(), read(), write(), ioctl(), strategy()
» This is the kernel’s interface to the device driver» Top half will start I/O to device, may put thread to
sleep until finished– Bottom half: run as interrupt routine
» Gets input or transfers next block of output» May wake sleeping threads if I/O now complete
13.17 Hung Q. Ngo Spring 2009Operating System
Life Cycle of An I/O Request
Device DriverTop Half
Device DriverBottom Half
DeviceHardware
Kernel I/OSubsystem
UserProgram
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I/O Device Notifying the OS•The OS needs to know when:
–The I/O device has completed an operation–The I/O operation has encountered an error
•I/O Interrupt:–Device generates an interrupt whenever it needs service
–Handled in bottom half of device driver» Often run on special kernel-level stack
–Pro: handles unpredictable events well–Con: interrupts relatively high overhead
•Polling:–OS periodically checks a device-specific status register» I/O device puts completion information in status
register» Could use timer to invoke lower half of drivers
occasionally–Pro: low overhead–Con: may waste many cycles on polling if infrequent or unpredictable I/O operations
•Actual devices combine both polling and interrupts–For instance: High-bandwidth network device: » Interrupt for first incoming packet» Poll for following packets until hardware empty
13.19 Hung Q. Ngo Spring 2009Operating System
Interrupts
• CPU Interrupt-request lines triggered by I/O device• Interrupt handler receives interrupts• Maskable to ignore or delay some interrupts• Interrupt vector to dispatch interrupt to correct
handler– Based on priority– Some nonmaskable
• Interrupt mechanism also used for exceptions
13.20 Hung Q. Ngo Spring 2009Operating System
Interrupt-Driven I/O Cycle
(Interrupt-request lines)
Page faultPage fault
Interrupt suspends current process & jumps to the page-fault handler in the
kernel
Interrupt suspends current process & jumps to the page-fault handler in the
kernel
Handler saves process state,
moves it to wait queue, performs
page-cache management,
schedules an I/O op. to fetch the page
Handler saves process state,
moves it to wait queue, performs
page-cache management,
schedules an I/O op. to fetch the pageHandler schedules
another process to resume execution, then return from
interrupt
Handler schedules another process to resume execution, then return from
interrupt
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Intel Pentium Processor Event-Vector Table
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Summary
• I/O Devices Types:– Many different speeds (0.1 bytes/sec to
GBytes/sec)– Different Access Patterns:
» Block Devices, Character Devices, Network Devices– Different Access Timing:
» Blocking, Non-blocking, Asynchronous• I/O Controllers: Hardware that controls actual
device– Processor Accesses through I/O instructions,
load/store to special physical memory– Report their results through either interrupts or a
status register that processor looks at occasionally (polling)
• Device Driver: Device-specific code in kernel
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Disk I/O Operations
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Disk Structure
• Disk drives are addressed as large 1-dimensional arrays of logical blocks, where the logical block is the smallest unit of transfer.
• The 1-dimensional array of logical blocks is mapped into the sectors of the disk sequentially.– Sector 0 is the first sector of the first track
on the outermost cylinder.– Mapping proceeds in order through that
track, then the rest of the tracks in that cylinder, and then through the rest of the cylinders from outermost to innermost.
13.25 Hung Q. Ngo Spring 2009Operating System
Disk Scheduling
• The operating system is responsible for using hardware efficiently — for the disk drives, this means having a fast access time and disk bandwidth.
• Access time has two major components– Seek time is the time for the disk are to move
the heads to the cylinder containing the desired sector.
– Rotational latency is the additional time waiting for the disk to rotate the desired sector to the disk head.
• Minimize seek time• Seek time seek distance• Disk bandwidth is the total number of bytes
transferred, divided by the total time between the first request for service and the completion of the last transfer.
13.26 Hung Q. Ngo Spring 2009Operating System
Disk Scheduling (Cont.)
• Several algorithms exist to schedule the servicing of disk I/O requests.
• We illustrate them with a request queue (0-199).
98, 183, 37, 122, 14, 124, 65, 67
Head pointer 53
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FCFS
Illustration shows total head movement of 640 cylinders.
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SSTF
• Selects the request with the minimum seek time from the current head position.
• SSTF scheduling is a form of SJF scheduling; may cause starvation of some requests.
• Illustration shows total head movement of 236 cylinders.
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SCAN
• The disk arm starts at one end of the disk, and moves toward the other end, servicing requests until it gets to the other end of the disk, where the head movement is reversed and servicing continues.
• Sometimes called the elevator algorithm.• Illustration shows total head movement of 208
cylinders.
13.30 Hung Q. Ngo Spring 2009Operating System
C-SCAN
• Provides a more uniform wait time than SCAN.• The head moves from one end of the disk to the
other. servicing requests as it goes. When it reaches the other end, however, it immediately returns to the beginning of the disk, without servicing any requests on the return trip.
• Treats the cylinders as a circular list that wraps around from the last cylinder to the first one.
13.31 Hung Q. Ngo Spring 2009Operating System
C-LOOK
• Version of C-SCAN• Arm only goes as far as the last
request in each direction, then reverses direction immediately, without first going all the way to the end of the disk.
13.32 Hung Q. Ngo Spring 2009Operating System
Selecting a Disk-Scheduling Algorithm
• SSTF is common and has a natural appeal• SCAN and C-SCAN perform better for
systems that place a heavy load on the disk.• Performance depends on the number and
types of requests.• Requests for disk service can be influenced
by the file-allocation method.• The disk-scheduling algorithm should be
written as a separate module of the operating system, allowing it to be replaced with a different algorithm if necessary.
• Either SSTF or LOOK is a reasonable choice for the default algorithm.