Chapter 13 Instruction Sets: Addressing Modes and Formats PDF

Summary

This document provides an overview of instruction sets and addressing modes in computer architecture, covering x86 and ARM architectures, instruction formats, and allocation of bits within instructions. The document explains different addressing modes, including immediate, direct, indirect, register, register indirect, displacement, and stack addressing. Useful for those studying computer science, or related fields.

Full Transcript

+ Chapter 13
Instruction Sets: Addressing
Modes and Formats
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 Addressing Modes
Immediate

Direct

Indirect

Register

Register indirect

Displacement

Stack

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 Table 13.1
Basic Addressing Modes

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+ Immediate Addressing

Simplest form of addressing

Operand = A

This mode can be used to define and use constants or set initial
values of variables
Typically the number will be stored in twos complement form
The leftmost bit of the operand field is used as a sign bit

Advantage:
No memory reference other than the instruction fetch is required to
obtain the operand, thus saving one memory or cache cycle in the
instruction cycle

Disadvantage:
The size of the number is restricted to the size of the address field,
which, in most instruction sets, is small compared with the word length

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 Direct Addressing
Address field
contains the
effective address
of the operand

Effective address
(EA) = address
field (A)

Was common in
earlier
generations of
computers

Requires only one
memory
reference and no
special calculation

Limitation is that
it provides only a
limited address
space

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+
Indirect Addressing
Reference to the address of a word in memory which contains a
full-length address of the operand
EA = (A)
Parentheses are to be interpreted as meaning contents of
Advantage:
For a word length of N an address space of 2N is now available
Disadvantage:
Instruction execution requires two memory references to fetch the
operand
One to get its address and a second to get its value

A rarely used variant of indirect addressing is multilevel or
cascaded indirect addressing
EA = (... (A)... )
Disadvantage is that three or more memory references could be
required to fetch an operand

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 Register Addressing

Address field
refers to a
register rather
EA = R
than a main
memory
address

Advantages: Disadvantage:
Only a small The address space
address field is is very limited
needed in the
instruction
No time-
consuming
memory
references are
required

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+
Register Indirect Addressing

Analogous to indirect addressing
The only difference is whether the address field refers to a
memory location or a register

EA = (R)
Address space limitation of the address field is
overcome by having that field refer to a word-length
location containing an address
Uses one less memory reference than indirect
addressing

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+
Displacement Addressing

Combines the capabilities of direct addressing and register
indirect addressing

EA = A + (R)

Requires that the instruction have two address fields, at least one
of which is explicit
The value contained in one address field (value = A) is used directly
The other address field refers to a register whose contents are added to
A to produce the effective address

Most common uses:
Relative addressing
Base-register addressing
Indexing

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 Relative Addressing

The implicitly referenced register is the program counter
(PC)
The next instruction address is added to the address field to produce
the EA
Typically the address field is treated as a twos complement number for
this operation
Thus the effective address is a displacement relative to the address of
the instruction
Exploits the concept of locality

Saves address bits in the instruction if most memory
references are relatively near to the instruction being
executed

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+
Base-Register Addressing

The referenced register contains a main memory address and
the address field contains a displacement from that address

The register reference may be explicit or implicit

Exploits the locality of memory references

Convenient means of implementing segmentation

In some implementations a single segment base register is
employed and is used implicitly

In others the programmer may choose a register to hold the
base address of a segment and the instruction must
reference it explicitly

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 Indexing
The address field references a main memory address and the referenced
register contains a positive displacement from that address

The method of calculating the EA is the same as for base-register addressing

An important use is to provide an efficient mechanism for performing iterative
operations

Autoindexing
Automatically increment or decrement the index register after each reference to it
EA = A + (R)
(R)  (R) + 1

Postindexing
Indexing is performed after the indirection
EA = (A) + (R)

Preindexing
Indexing is performed before the indirection
EA = (A + (R))

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+
Stack Addressing

A stack is a linear array of locations
Sometimes referred to as a pushdown list or last-in-first-out queue

A stack is a reserved block of locations
Items are appended to the top of the stack so that the block is partially filled

Associated with the stack is a pointer whose value is the address of
the top of the stack
The stack pointer is maintained in a register
Thus references to stack locations in memory are in fact register indirect
addresses

Is a form of implied addressing
The machine instructions need not include a memory
reference but implicitly operate on the top of the stack

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 Table 13.2
x86 Addressing Modes

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+ ARM Data Processing Instruction
Addressing
and Branch Instructions
Data processing instructions
Use either register addressing or a mixture of register and
immediate addressing
For register addressing the value in one of the register
operands may be scaled using one of the five shift
operators

Branch instructions
The only form of addressing for branch instructions is
immediate
Instruction contains 24 bit value
Shifted 2 bits left so that the address is on a word
boundary
Effective range ± 32MB from from the program counter
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 Instruction Formats

Must include
Define the an opcode
For most
layout of the and,
instruction
bits of an implicitly or
sets more
instruction, explicitly,
than one
in terms of indicate the
instruction
its addressing
format is
constituent mode for
used
fields each
operand

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+
Instruction Length
Most basic design issue
Affects, and is affected by:
Memory size
Memory organization
Bus structure
Processor complexity
Processor speed

Should be equal to the memory-transfer length or one
should be a multiple of the other
Should be a multiple of the character length, which is
usually 8 bits, and of the length of fixed-point numbers

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 Allocation of Bits

Number of Register
Number of
addressing versus
operands
modes memory

Number of
Address Address
register
range granularity
sets

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+
Variable-Length Instructions

Variations can be provided efficiently and compactly
Increases the complexity of the processor
Does not remove the desirability of making all of the
instruction lengths integrally related to word length
Because the processor does not know the length of the next
instruction to be fetched a typical strategy is to fetch a
number of bytes or words equal to at least the longest
possible instruction
Sometimes multiple instructions are fetched

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+
Thumb-2 Instruction Set

The only instruction set available on the Cortex-M microcontroller
products
Is a major enhancement to the Thumb instruction set architecture
(ISA)
Introduces 32-bit instructions that can be intermixed freely with the
older 16-bit Thumb instructions
Most 32-bit Thumb instructions are unconditional, whereas almost all
ARM instructions can be conditional
Introduces a new If-Then (IT) instruction that delivers much of the
functionality of the condition field in ARM instructions
Delivers overall code density comparable with Thumb, together with
the performance levels associated with the ARM ISA
Before Thumb-2 developers had to choose between Thumb for size
and ARM for performance

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© 2016 Pearson Education, Inc., Hoboken, NJ. All rights reserved.
© 2016 Pearson Education, Inc., Hoboken, NJ. All rights reserved.
+ Summary Instruction Sets:
Addressing Modes
and Formats
Chapter 13
x86 addressing modes
Addressing modes ARM addressing modes
Immediate addressing
Direct addressing Instruction formats
Indirect addressing Instruction length
Register addressing Allocation of bits
Register indirect Variable-length
addressing instructions
Displacement addressing X86 instruction formats
Stack addressing
ARM instruction formats
Assembly language

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