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Front-side bus

From Wikipedia, the free encyclopedia
Within a multi-core processor, the back-side bus is often internal, with front-side bus for external communication.

The front-side bus (FSB) is a computer communication interface (bus) that was often used in Intel-chip-based computers during the 1990s and 2000s. The EV6 bus served the same function for competing AMD CPUs. Both typically carry data between the central processing unit (CPU) and a memory controller hub, known as the northbridge.[1]

Depending on the implementation, some computers may also have a back-side bus that connects the CPU to the cache. This bus and the cache connected to it are faster than accessing the system memory (or RAM) via the front-side bus. The speed of the front side bus is often used as an important measure of the performance of a computer.

The original front-side bus architecture was replaced by HyperTransport, Intel QuickPath Interconnect, and Direct Media Interface, followed by Intel Ultra Path Interconnect and AMD's Infinity Fabric.

History

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The term came into use by Intel Corporation about the time the Pentium Pro and Pentium II products were announced, in the 1990s.

"Front side" refers to the external interface from the processor to the rest of the computer system, as opposed to the back side, where the back-side bus connects the cache (and potentially other CPUs).[2]

A front-side bus (FSB) is mostly used on PC-related motherboards (including personal computers and servers). They are seldom used in embedded systems or similar small computers. The FSB design was a performance improvement over the single system bus designs of the previous decades, but these front-side buses are sometimes referred to as the "system bus".

Front-side buses usually connect the CPU and the rest of the hardware via a chipset, which Intel implemented as a northbridge and a southbridge. Other buses like the Peripheral Component Interconnect (PCI), Accelerated Graphics Port (AGP), and memory buses all connect to the chipset in order for data to flow between the connected devices. These secondary system buses usually run at speeds derived from the front-side bus clock, but are not necessarily synchronized to it.

In response to AMD's Torrenza initiative, Intel opened its FSB CPU socket to third party devices.[3] Prior to this announcement, made in Spring 2007 at Intel Developer Forum in Beijing, Intel had very closely guarded who had access to the FSB, only allowing Intel processors in the CPU socket. The first example was field-programmable gate array (FPGA) co-processors, a result of collaboration between Intel-Xilinx-Nallatech[4] and Intel-Altera-XtremeData (which shipped in 2008).[5][6][7]

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A typical chipset layout from the Pentium II/III era

CPU

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The frequency at which a processor (CPU) operates is determined by applying a clock multiplier to the front-side bus (FSB) speed in some cases. For example, a processor running at 3200 MHz might be using a 400 MHz FSB. This means there is an internal clock multiplier setting (also called bus/core ratio) of 8. That is, the CPU is set to run at 8 times the frequency of the front-side bus: 400 MHz × 8 = 3200 MHz. Different CPU speeds are achieved by varying either the FSB frequency or the CPU multiplier, this is referred to as overclocking or underclocking.

Memory

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Setting an FSB speed is related directly to the speed grade of memory a system must use. The memory bus connects the northbridge and RAM, just as the front-side bus connects the CPU and northbridge. Often, these two buses must operate at the same frequency. Increasing the front-side bus to 450 MHz in most cases also means running the memory at 450 MHz.

In newer systems, it is possible to see memory ratios of "4:5" and the like. The memory will run 5/4 times as fast as the FSB in this situation, meaning a 400 MHz bus can run with the memory at 500 MHz. This is often referred to as an 'asynchronous' system. Due to differences in CPU and system architecture, overall system performance can vary in unexpected ways with different FSB-to-memory ratios.

In image, audio, video, gaming, FPGA synthesis and scientific applications that perform a small amount of work on each element of a large data set, FSB speed becomes a major performance issue. A slow FSB will cause the CPU to spend significant amounts of time waiting for data to arrive from system memory. However, if the computations involving each element are more complex, the processor will spend longer performing these; therefore, the FSB will be able to keep pace because the rate at which the memory is accessed is reduced.

Peripheral buses

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Similar to the memory bus, the PCI and AGP buses can also be run asynchronously from the front-side bus. In older systems, these buses are operated at a set fraction of the front-side bus frequency. This fraction was set by the BIOS. In newer systems, the PCI, AGP, and PCI Express peripheral buses often receive their own clock signals, which eliminates their dependence on the front-side bus for timing.

Overclocking

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Overclocking is the practice of making computer components operate beyond their stock performance levels by manipulating the frequencies at which the component is set to run, and, when necessary, modifying the voltage sent to the component to allow it to operate at these higher frequencies with more stability.

Many motherboards allow the user to manually set the clock multiplier and FSB settings by changing jumpers or BIOS settings. Almost all CPU manufacturers now "lock" a preset multiplier setting into the chip. It is possible to unlock some locked CPUs; for instance, some AMD Athlon processors can be unlocked by connecting electrical contacts across points on the CPU's surface. Some other processors from AMD and Intel are unlocked from the factory and labeled as an "enthusiast-grade" processors by end users and retailers because of this feature. For all processors, increasing the FSB speed can be done to boost processing speed by reducing latency between CPU and the northbridge.

This practice pushes components beyond their specifications and may cause erratic behavior, overheating or premature failure. Even if the computer appears to run normally, problems may appear under a heavy load. Most PCs purchased from retailers or manufacturers, such as Hewlett-Packard or Dell, do not allow the user to change the multiplier or FSB settings due to the probability of erratic behavior or failure. Motherboards purchased separately to build a custom machine are more likely to allow the user to edit the multiplier and FSB settings in the PC's BIOS.

Evolution

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The front-side bus had the advantage of high flexibility and low cost when it was first designed. Simple symmetric multiprocessors place a number of CPUs on a shared FSB, though performance could not scale linearly due to bandwidth bottlenecks.

The front-side bus was used in all Intel Atom, Celeron, Pentium, Core 2, and Xeon processor models through about 2008[8] and was eliminated in 2009.[9] Originally, this bus was a central connecting point for all system devices and the CPU.

The potential of a faster CPU is wasted if it cannot fetch instructions and data as quickly as it can execute them. The CPU may spend significant time idle while waiting to read or write data in main memory, and high-performance processors therefore require high bandwidth and low latency access to memory. The front-side bus was criticized by AMD as being an old and slow technology that limits system performance.[10]

More modern designs use point-to-point and serial connections like AMD's HyperTransport and Intel's DMI 2.0 or QuickPath Interconnect (QPI). These implementations remove the traditional northbridge in favor of a direct link from the CPU to the system memory, high-speed peripherals, and the Platform Controller Hub, southbridge or I/O controller.[11][12][13]

In a traditional architecture, the front-side bus served as the immediate data link between the CPU and all other devices in the system, including main memory. In HyperTransport- and QPI-based systems, system memory is accessed independently by means of a memory controller integrated into the CPU, leaving the bandwidth on the HyperTransport or QPI link for other uses. This increases the complexity of the CPU design but offers greater throughput as well as superior scaling in multiprocessor systems.

Transfer rates

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The bandwidth or maximum theoretical throughput of the front-side bus is determined by the product of the width of its data path, its clock frequency (cycles per second) and the number of data transfers it performs per clock cycle. For example, a 64-bit (8-byte) wide FSB operating at a frequency of 100 MHz that performs 4 transfers per cycle has a bandwidth of 3200 megabytes per second (MB/s):

8 bytes/transfer × 100 MHz × 4 transfers/cycle = 3200 MB/s

The number of transfers per clock cycle depends on the technology used. For example, GTL+ performs 1 transfer/cycle, EV6 2 transfers/cycle, and AGTL+ 4 transfers/cycle. Intel calls the technique of four transfers per cycle Quad Pumping.

Many manufacturers publish the frequency of the front-side bus in MHz, but marketing materials often list the theoretical effective signaling rate (which is commonly called megatransfers per second or MT/s). For example, if a motherboard (or processor) has its bus set at 200 MHz and performs 4 transfers per clock cycle, the FSB is rated at 800 MT/s.

The specifications of several generations of popular processors are indicated below.

Intel processors

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CPU FSB Frequency (MHz) Transfers/Cycle Bus Width Transfer Rate (MB/sec)
Pentium 50 - 66 1 64-bit 400 - 528
Pentium Overdrive 25 - 66 1 32 or 64-bit 200 - 528
Pentium Pro 60 / 66 1 64-bit 480 - 528
Pentium MMX 60 / 66 1 64-bit 480 - 528
Pentium MMX Overdrive 50 / 60 / 66 1 64-bit 400 - 528
Pentium II 66 / 100 1 64-bit 528 / 800
Pentium II Xeon 100 1 64-bit 800
Pentium II Overdrive 60 / 66 1 64-bit 480 - 528
Pentium III 100 / 133 1 64-bit 800 / 1064
Pentium III Xeon 100 / 133 1 64-bit 800 / 1064
Pentium III-M 100 / 133 1 64-bit 800 / 1064
Pentium 4 100 / 133 4 64-bit 3200 - 4256
Pentium 4-M 100 4 64-bit 3200
Pentium 4 HT 133 / 200 4 64-bit 4256 / 6400
Pentium 4 HT Extreme Edition 200 / 266 4 64-bit 6400 / 8512
Pentium D 133 / 200 4 64-bit 4256 - 6400
Pentium Extreme Edition 200 / 266 4 64-bit 6400 / 8512
Pentium M 100 / 133 4 64-bit 3200 / 4256
Pentium Dual-Core 200 / 266 4 64-bit 6400 / 8512
Pentium Dual-Core Mobile 133 - 200 4 64-bit 6400 - 8512
Celeron 66 - 200 1-4 64-bit 528 - 6400
Celeron Mobile 133 - 200 1-4 64-bit 4256 - 6400
Celeron D 133 4 64-bit 4256
Celeron M 66 - 200 1-4 64-bit 528 - 6400
Celeron Dual-Core 200 4 64-bit 6400
Celeron Dual-Core Mobile 133 - 200 4 64-bit 4256 - 6400
Itanium 133 2 64-bit 2133
Itanium 2 200 - 333 2 128-bit 6400 - 10666
Xeon 100 - 400 4 64-bit 3200 - 12800
Core Solo 133 / 166 4 64-bit 4256 / 5312
Core Duo 133 / 166 4 64-bit 4256 / 5312
Core 2 Solo 133 - 200 4 64-bit 4256 - 6400
Core 2 Duo 200 - 333 4 64-bit 6400 - 10656
Core 2 Duo Mobile 133 - 266 4 64-bit 4256 - 8512
Core 2 Quad 266 / 333 4 64-bit 8512 / 10656
Core 2 Quad Mobile 266 4 64-bit 8512
Core 2 Extreme 266 - 400 4 64-bit 8512 - 12800
Core 2 Extreme Mobile 200 / 266 4 64-bit 6400 / 8512
Atom 100 - 166 4 64-bit 3200 - 5312

AMD processors

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CPU FSB Frequency (MHz) Transfers/Cycle Bus Width Transfer Rate (MB/sec)
K5 50 - 66 1 64-bit 400 - 528
K6 66 1 64-bit 528
K6-II 66 - 100 1 64-bit 528 - 800
K6-III 66 / 100 1 64-bit 528 - 800
Athlon 100 / 133 2 64-bit 1600 - 2128
Athlon XP 100 / 133 / 166 / 200 2 64-bit 1600 - 3200
Athlon MP 100 / 133 2 64-bit 1600 - 2128
Mobile Athlon 4 100 2 64-bit 1600
Athlon XP-M 100 / 133 2 64-bit 1600 - 2128
Duron 100 / 133 2 64-bit 1600 - 2128
Sempron 166 / 200 2 64-bit 2656 - 3200

References

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  1. ^ Scott Mueller (2003). Upgrading and repairing PCs (15th ed.). Que Publishing. p. 314. ISBN 978-0-7897-2974-3.
  2. ^ Todd Langley and Rob Kowalczyk (January 2009). "Introduction to Intel Architecture: The Basics" (PDF). White paper. Intel Corporation. Archived from the original (PDF) on June 7, 2011. Retrieved May 28, 2011.
  3. ^ Charlie Demerjian (April 17, 2007). "Intel opens up its front side bus to the world+dog: IDF Spring 007 Xilinx heralds the bombshell". The Inquirer. Archived from the original on October 7, 2012. Retrieved May 28, 2011.
  4. ^ "Nallatech Launches Early Access Program for the Industry's First FSB-FPGA Module". Business Wire news release. Nallatech. September 18, 2007. Retrieved June 14, 2011.
  5. ^ "XtremeData Offers Stratix III FPGA-Based Intel FSB Module". Business Wire news release. Chip Design magazine. September 18, 2007. Archived from the original on July 23, 2011. Retrieved June 14, 2011.
  6. ^ Ashlee Vance (April 17, 2007). "High fiber diet gives Intel 'regularity' needed to beat AMD". The Register. Retrieved May 28, 2011.
  7. ^ "XtremeData Begins Shipping 1066 MHz Altera Stratix III FPGA-Based Intel FSB Module". Business Wire news release. XtremeData. June 17, 2008. Retrieved June 14, 2011.
  8. ^ "Intel X38 Tango - is High FSB Overclocking Worth It?".
  9. ^ "Core i7 975 review (Page 4)". 2 June 2009.
  10. ^ Allan McNaughton (September 29, 2003). "AMD HyperTransport Bus: Transport Your Application to Hyper Performance". AMD. Archived from the original on March 25, 2012. Retrieved June 14, 2011.
  11. ^ "An Introduction to the Intel QuickPath Interconnect" (PDF). Intel Corporation. January 30, 2009. Retrieved June 14, 2011.
  12. ^ "Intel launches all-new PC architecture with Core i5/I7 CPUs". 8 September 2009.
  13. ^ "Core i7 975 review (Page 4)". 2 June 2009.