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Communicating with Devices: Buses, Bridges, etc. Look to the Future. From the beginning PCs have been made with expandability and adaptability in mind.
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Look to the Future • From the beginning PCs have been made with expandability and adaptability in mind. • While certain I/O devices came standard, there was room to add others – to expand the computer’s capabilities and to adapt the PC to the particular needs. • The circuitry required by the new device is placed on the expansion card or adapter card. • We also need to connect to and communicate with the rest of the PC, this is the job of the expansion bus.
Standards • IBM developed the first PCs, the first PC bus and the first PC expansion slots. It was an 8-bit bus. They allowed others to use that technology without having to pay royalties. (However, they never released the full specifications.) • This step allowed competitors to make IBM “clones” which brought the price of PCs down. But the low price helped to establish a standard. • The standard made peripheral makers’ jobs easier. They only had to design for one interface.
Bottlenecks • The standard devices and expansion devices operate at a wide variety of speeds. We need a design that allows to whatever extent possible each device to operate at its own speed. • Actually we will have a hierarchy of standard speeds – different buses carrying data at different speeds. • The interface between devices of different speeds can be a source of slow downs (bottlenecks). • The chipset handles much of this interfacing.
Chipset • The main components of the computer (processor, memory, cache, etc.) plug into the motherboard and communicate via the chipset. • The chipset determines which type of processor can be used, how fast a processor, how much memory, what type of memory, and so on. • The chipset’s function are typically broken into two sets, one handled by the Northbridge and the other handled by the Southbridge.
Northbridge • The Northbridge handles the high-speed, high-volume data communication between the CPU, cache, memory and AGP (accelerated graphics port). • Since the Northbridge manages the processor-memory interaction (the front-side bus bottleneck), its performance is critical. • The Northbridge determines the FSB speed. Typically the processor operates at a multiplicative factor (the CPU multiplier) of the FSB speed. • It uses synchronous memory, recall SDRAM.
Southbridge • The Southbridge allows communication with a greater variety of slower devices. It connects to the secondary buses – USB, IDE, PS/2, Ethernet. • Since it handles accessing the hard disk, the Southbridge manages a bottleneck of its own, especially for memory-intensive applications.
North South
Bridge Interface • Older chipsets used the PCI (Peripheral Component Interconnect) Bus to connect the Northbridge and Southbridge. But with more devices using the PCI bus, modern chipsets have introduced a dedicated interface between the chips. • Another multiplicative speed factor is between the FSB speed and the PCI speed. • The standard PCI bus speed is 33.3 MHz, while standard FSB speeds are 100 MHz (3X) and 133 MHz (4X). • Motherboards that use this multiplicative factor are said to be synchronous.
Bus History • When Intel moved to a 16-bit data bus (with the 256), the expansion buses needed to be changed as well. • IBM developed a 16-bit bus that was backward compatible with the PC 8-bit bus. They debuted it in their Advanced Technology(AT) computer and it became known as the AT bus. • Based on the AT bus, some IBM competitors got together to lay out some specifications known as Industry Standard Architecture(ISA).
No more ISA • ISA slots were kept in PCs for reasons of backward compatibility for many years. • They have been officially dropped from what Microsoft and Intel see as a PC in their PC 2001 System Design Guide. • This move is to reduce legacy dependence. • If needed one can get PCI cards that can simulate an ISA card to interface with legacy devices.
Communication • Expansion cards, as well as other peripheral devices, can communicate with the processor and memory through one or more of the following: • I/O Addresses • Interrupt Requests Lines (IRQs) • Direct Memory Access (DMA) channels • Memory Addresses • Known as system resources.
I/O Address • The processor has an external data bus and an address bus. • One use of the address bus is to indicate the word in memory that the processor wishes to access. • A set of address bus combinations are reserved to communicate with peripherals. A given peripheral may have several addresses assigned to it, each corresponding to a different action that the processor is requesting.
Uniqueness • As is normal with addresses, each I/O address should be unique. If two devices shared an I/O address, then it would be unclear which device the processor intended to communicate with. • IBM set the early standards assigning certain standard devices set I/O addresses.
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IRQs • While I/O addressing allows the processor to initiate communication with a peripheral, the IRQ allows the peripheral to initiate communication with the processor. The processor must be “interrupted.” • The processor has one pin to indicate that it has been interrupted. When it reaches a point at which it can process the interruption, it needs to trace back and determine which device interrupted it. This is the purpose of the IRQs.
After the processor has been interrupted, it uses the I/O Address approach to initiate communication with the interrupt controller which will help the processor determine which device made the request. Interrupt Controller
Another type of addressing • IRQs are another form of addressing. • There are far fewer of IRQs than there are I/O addresses and so it is more likely that IRQ conflicts will occur. • Under certain circumstances it is possible for two devices to share an IRQ line provided the two devices are never active simultaneously (e.g. a fax and a modem that use the same phone line). • Early on IBM assigned to IRQs to some standard devices.
Ports • To accommodate that many devices would need I/O addresses, an IRQ and a set of rules for communicating, two standards were established – one for serial communication (the COM ports) and another for parallel communication (the LPT ports).
DMA • Direct Memory Access (DMA) allows devices to interact with the memory without the processor having to get involved. • The processor delegates some of its traffic control duties. • Now we have a situation in which a number of devices may want to use the buses to access memory, so we need another addressing/ requesting system. • Note with our cache hierarchy, we hope that the processor accesses the memory infrequently (less than 5% of the time).
Bus Mastering • Choosing to show the floppy’s DMA channel was not just a random example. The floppy uses classic (third-party) DMA. • Third-party DMA was slow. • In first-party DMA, a.k.a. bus mastering, the device (e.g. hard disk drive) controls the interaction with memory. • The devices “sense” if some other device is accesses memory.
Buses that have come and gone • Micro-Channel Architecture (MCA) extends to 32-bit width, increased speed, was self-configuring BUT was not backward compatible and was proprietary • Extended ISA (EISA) was 32-bit, self-configuring, backward compatible, open standard BUT slow • Video Electronics Standards Association Local Bus (VL-Bus or VESA Bus) was fast because it worked with the North bridge instead of the South Bridge BUT was NOT self-configuring.
And the Winner is PCI • Peripheral Component Interconnect (PCI) • Intel introduced the PCI bus structure pretty much at the same time it introduced the Pentium. • Like the VESA bus, it interfaces with the Northbridge so it is fast. • It is also self-configuring. • It allows for bus mastering. • It was effectively free (provided automatically by Intel). • It allowed data bursting. • It was scalable. • While introduced by Intel, it works with other processors including Machintosh.
PCI Card Connectors A PCI card has 47 pins with no bus mastering and has 49 pins with bus mastering.
Putting a card in • Keep the card in its anti-static bag until you are ready to insert it. • Turn off and unplug the PC. • If you don’t have a wrist strap to protect against electrostatic discharge (ESD) then after removing the card from the bag touch the PC’s power supply. The smallest shock could ruin the card or the motherboard. • Insert the card straight in or at most a slight angle. • Screw the card to the box with a connection screw – it keeps the card in place and can help ground it.
Putting a card in (Cont.) • Close the computer, plug it in and start. • You should get a message from the operating system that it has detected new hardware. • It will search for a driver and/or request that you insert a CD with the driver. • You may need to reboot depending on the device. • You should look for the new device in the device manager to make sure there are no conflicts.
Plug and Play • Plug and Play (PnP) is a feature in which the system configures a device automatically rather than the user having to set jumpers and choose resources, etc. • For PnP one needs: • A PnP BIOS • A PnP operating system • A PnP device • All PCI devices are PnP • A device which is not PnP is called a “legacy” device.
How Plug and Play Works • Initially the PnP devices are put on hold and resources are assigned to legacy devices. • Then the system starts querying the PnP devices about the resources each wants. • A PnP device will provide a list of resources it could use. • For example, it would not specify IRQ 3 but rather specify that it could use IRQ 3 or IRQ 5 or IRQ 7. • A file with PnP information, called the Extended System Configuration Data (ESCD), is kept.
AGP • Specification developed by Intel, even faster than PCI and more directly connected to the Northbridge is the AGP (Accelerated Graphics Port). • It is dedicated to graphics. It will have its own slot to be used only for this purpose.
References • All-in-One A+ Certification, M. Meyers and S. Jernigan • http://www.pcguide.com • PC Hardware in a Nutshell, R. Thompson and B. Thompson