Instruction cycle

A diagram of the instruction cycle.

An instruction cycle (sometimes called a fetch–decode–execute cycle) is the basic operational process of a computer. It is the process by which a computer retrieves a program instruction from its memory, determines what actions the instruction dictates, and carries out those actions. This cycle is repeated continuously by a computer's central processing unit (CPU), from boot-up to when the computer is shut down.

In simpler CPUs the instruction cycle is executed sequentially, each instruction being processed before the next one is started. In most modern CPUs the instruction cycles are instead executed concurrently, and often in parallel, through an instruction pipeline: the next instruction starts being processed before the previous instruction has finished, which is possible because the cycle is broken up into separate steps.

Components

Program counter (PC): An incrementing counter that keeps track of the memory address of the instruction that is to be executed next or in other words, holds the address of the instruction to be executed next.
Memory address register (MAR): Holds the address of a block of memory for reading from or writing to.
Memory data register (MDR): A two-way register that holds data fetched from memory (and ready for the CPU to process) or data waiting to be stored in memory. (This is also known as the memory buffer register (MBR).)
Instruction register (IR): A temporary holding ground for the instruction that has just been fetched from memory.
Control unit (CU): Decodes the program instruction in the IR, selecting machine resources, such as a data source register and a particular arithmetic operation, and coordinates activation of those resources.
Arithmetic logic unit (ALU): Performs mathematical and logical operations.

Steps

Each computer's CPU can have different cycles based on different instruction sets, but will be similar to the following cycle:

Fetch the instruction: The next instruction is fetched from the memory address that is currently stored in the program counter (PC), and stored in the instruction register (IR). At the end of the fetch operation, the PC points to the next instruction that will be read at the next cycle.
Decode the instruction: During this cycle the encoded instruction present in the IR (instruction register) is interpreted by the decoder.
Read the effective address: In case of a memory instruction (direct or indirect) the execution phase will be in the next clock pulse. If the instruction has an indirect address, the effective address is read from main memory, and any required data is fetched from main memory to be processed and then placed into data registers (Clock Pulse: T₃). If the instruction is direct, nothing is done at this clock pulse. If this is an I/O instruction or a Register instruction, the operation is performed (executed) at clock Pulse.
Execute the instruction: The control unit of the CPU passes the decoded information as a sequence of control signals to the relevant function units of the CPU to perform the actions required by the instruction such as reading values from registers, passing them to the ALU to perform mathematical or logic functions on them, and writing the result back to a register. If the ALU is involved, it sends a condition signal back to the CU. The result generated by the operation is stored in the main memory, or sent to an output device. Based on the condition of any feedback from the ALU, Program Counter may be updated to a different address from which the next instruction will be fetched.

The cycle is then repeated.

Initiating the cycle

The cycle begins as soon as power is applied to the system, with an initial PC value that is predefined by the system's architecture (for instance, in Intel IA-32 CPUs, the predefined PC value is 0xfffffff0). Typically this address points to a set of instructions in read-only memory (ROM), which begins the process of loading (or booting) the operating system.^[1]

Fetching the instruction

Step 1 of the Instruction Cycle is called the Fetch Cycle. This step is the same for each instruction:

The CPU sends PC to the MAR and sends a READ command on the control bus
In response to the read command (with address equal to PC), the memory returns the data stored at the memory location indicated by PC on the databus
The CPU copies the data from the databus into its MDR (also known as MBR, see section Components above)
A fraction of a second later, the CPU copies the data from the MDR to the Instruction Register (IR)
The PC is incremented so that it points to the following instruction in memory. This step prepares the CPU for the next cycle.

The Control Unit fetches the instruction's address from the Memory Unit.

Decoding the instruction

Step 2 of the instruction Cycle is called the Decode Cycle. The decoding process allows the CPU to determine what instruction is to be performed, so that the CPU can tell how many operands it needs to fetch in order to perform the instruction. The opcode fetched from the memory is decoded for the next steps and moved to the appropriate registers. The decoding is done by the CPU's Control Unit.

Reading the effective address

Step 3 is evaluating which operation it is. If this is a Memory operation - in this step the computer checks if it's a direct or indirect memory operation:

Direct memory instruction - Nothing is being done.
Indirect memory instruction - The effective address is being read from the memory.

If this is an I/O or Register instruction - the computer checks its kind and executes the instruction.

Executing the instruction

Step 4 of the Instruction Cycle is the Execute Cycle. Here, the function of the instruction is performed. If the instruction involves arithmetic or logic, the Arithmetic Logic Unit is utilized. This is the only stage of the instruction cycle that is useful from the perspective of the end user. Everything else is overhead required to make the execute phase happen.

References

↑ Bosky Agarwal (2004). "Instruction Fetch Execute Cycle" (PDF). Archived from the original (PDF) on June 11, 2009. Retrieved 2012-10-14.

CPU technologies

Architecture	Von Neumann Harvard (Modified) Dataflow TTA

Instruction set	ASIP CISC RISC EDGE (TRIPS) VLIW (EPIC) MISC OISC NISC ZISC Comparison

Word size	1-bit 4-bit 8-bit 9-bit 10-bit 12-bit 15-bit 16-bit 18-bit 22-bit 24-bit 25-bit 26-bit 27-bit 31-bit 32-bit 33-bit 34-bit 36-bit 39-bit 40-bit 48-bit 50-bit 60-bit 64-bit 128-bit 256-bit 512-bit Variable

Execution	Instruction pipelining Bubble Operand forwarding Out-of-order execution Register renaming Speculative execution Branch predictor Memory dependence prediction Hazards

Parallel level	Bit Bit-serial Word Instruction Scalar Superscalar Task Thread Process Data Vector Memory

Multithreading	Temporal Simultaneous Preemptive Cooperative

Flynn's taxonomy	SISD SIMD MISD MIMD SPMD Addressing mode

Core count	Single-core processor Multi-core processor Manycore processor

Types	Digital signal processor (DSP) GPGPU Microcontroller Physics processing unit System on a chip (SoC) Cellular

Components	Address generation unit (AGU) Arithmetic logic unit (ALU) Barrel shifter Floating-point unit (FPU) Back-side bus Multiplexer Demultiplexer Registers Memory management unit (MMU) Translation lookaside buffer (TLB) Cache Register file Microcode Control unit Clock rate

Power management	APM ACPI Dynamic frequency scaling Dynamic voltage scaling Clock gating

Hardware security	Non-executable memory (NX bit) Bounds checking (Intel MPX) Hardware restriction (firmware) Software Guard Extensions (Intel SGX) Trusted Execution Technology Secure cryptoprocessor Hardware security module Hengzhi chip

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