CS 271 - Computer Architecture and Assembly Language

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large value prefixes for decimals and binary

[prefix]: [decimal multiplier] or [binary multiplier] kilo: 10^3 (k) or 2^10 (Ki) mega: 10^6 (M) or 2^20 (Mi) giga: 10^9 (G) or 2^30 (Gi) tera: 10^12 (T) or 2^40 (Ti) peta: 10^15 (P) or 2^50 (Pi) exa: 10^18 (E) or 2^60 (Ei) zetta: 10^21 (Z) or 2^70 (Zi) yotta: 10^24 (Y) or 2^80 (Yi) binary prefixes often omit the 'i' and are followed by b/B for bits/bytes

stored program

a program is an organized list of instructions and data which both reside in memory, and are NOT separated and managed independently key concept of Von Neumann computer architecture

backwards compatability

ability of new devices to support old systems

array address calculation

address of list[n] = address of list + (n - 1)(TYPE) to get to nth element of list

passing parameter by reference

address of memory location passed using OFFSET, change will be visible outside the procedure

endianness with strings and arrays

affects byte (not bit) ordering, only impacts multi-byte data types in arrays, index ordering is not impacted but each element within an array can be in strings, endianness does not have any impact

unconditional branching

always causes branching

indirect operand

array access method uses any 4-byte multi-purpose register surrounded by brackets ex: [ESI]

indexed operand

array access method uses data label of array as placeholder for array's base address ex: myArray[8], many other forms

base+offset

array access method - type of indirect operand uses register (base pointer) + immediate or register (byte offset) surrounded by brackets ex: [EBP + 4] or [EDI + EAX]

register indirect

array access method - type of indirect operand uses register surrounded by brackets which is directly incremented/decremented to reference elements ideal for iterating through arrays ex: [ESI] and ADD ESI, TYPE myArray

TYPE

array operator returns number of bytes of each element in the array

LENGTHOF

array operator returns number of elements in the array (only reads first line of multi-line declaration)

SIZEOF

array operator returns size of memory assigned in declaration of array (only reads first line of multi-line declaration) LENGTHOF x TYPE = SIZEOF

decimal

base 10 digits: 0, 1, 2, 3, 4, 5, 6, 7, 8, 9

hexadecimal

base 16 digits: 0, 1, 2, 3, 4, 5, 6, 7, 8, 9, A, B, C, D, E, F

binary

base 2 digits: 0, 1

octal

base 8 digits: 0, 1, 2, 3, 4, 5, 6, 7

post-value number representation

base indicated after last digit: binary (b), octal (o), decimal (d), hexadecimal (h) leading 0 added if first digit is non-numeric ex: 1011b, 173o, 432d, 0A1Bh

pre-value number representation

base indicated prior to value: binary (b), octal (t), decimal (n), hexadecimal (x) leading 0 required ex: 0b1011, 0t173, 0n432, 0xA1B

big vs. little endian benefits

big endian - simpler to read, easier to sign check little endian - simpler arithmetic operations, typecasting, and some types of parity checking (odd vs. even)

integer literal radix indicators

binary (b, y) octal (o, q) decimal (d, t, none - default) hexadecimal (h)

fundamental data types

bit nibble (4 bits) byte (8 bits) word (2 bytes) etc...

central processing unit (CPU)

carry weight of computational load subcomponents: system clock, registers, buses, ALU, CU, memory I/O, on-chip memory

literal

character or numeric value

components of an instruction

code label (optional) instruction mnemonic (required) operands (often required) comments (optional)

return address

code segment address where the program will return to after the called procedure finishes running

linker

combines machine language objects into a single executable file

system clock

computer's metronome guarantees synchronization of operations

arithmetic logic unit (ALU)

computes basic arithmetic (addition, subtraction, multiplication, division) and logical (and, or, not) operations

floating point unit (FPU)

computes floating point arithmetic operations

preconditions

conditions that must be satisfied before a procedure is called, a subset of which are inputs

postconditions

conditions that will exist after a procedure is called, a subset of which are outputs

register

container for storing data fastest access memory on the chip

passing parameter by value

contents of memory location passed, changes will not be visible outside the procedure

runtime stack

contiguous series of memory locations used to pass parameters to/from procedures and for general purpose temporary storage

direction flag (DF/UP)

control flag (bit 10 of EFLAGS) controls direction of automatic memory traversal for string instructions, set using STD for auto-decrement of ESI/EDI (moving backwards in memory), clear using CLD for auto-increment of ESI/EDI (moving forward in memory)

interrupt enable flag (EI/I)

control flag (bit 9 of EFLAGS) set to issue hardware-generated interrupts, clear to mask them

control flags

controls toggles for the program bits 9, 10 of EFLAGS

input/output (I/O) unit

controls transfer of information between memory/CPU and attached onboard/peripheral devices

cross assembler

converts between machine languages

control register

coordinates execution of instruction by running a micro-program

ways to save data

copy data to a memory variable vs. push data to the stack

listing file (.lst)

copy of the program's source code, with memory addresses (in hex) of data/code labels and instructions, along with hex opcodes

$

current location counter gives address of instruction or data label of the current line only can be used to find the length of strings or arrays

types of instructions

data movement arithmetic/logical operations comparison branching procedure flow control

when to preserve register contents

data saved by the calling procedure vs. data saved by the called procedure

stack

data structure with a LIFO (Last-In, First-Out) property operations reference the top of the stack, manipulate ESP, and update the value of ESP

instruction decoder

decodes current instruction and passes details to control register

directives

direct instructions to the assembler

INVOKE

directive calls a procedure at the address given by the expression w/ comma-delimited arguments ex: INVOKE ExitProcess, 0

LOCAL

directive creates unique data or code label local to a particular procedure or macro creates and terminates stack frame, so do not include EBP set-up/take-down instructions if using LOCAL

=

directive defines numerical constants

EQU

directive defines numerical or text constants can be used w <> to prevent expressions from being evaluated before the program is assembled

TEXTEQU

directive defines text macros which can be a literal string, the contents of an existing text macro, or an expression (if preceded by %)

ENDM

directive defines the end of a macro ex: mWriteStr ENDM

ENDP

directive defines the end of a procedure ex: main ENDP

MACRO

directive defines the start of a macro ex: mWriteStr MACRO

PROC

directive defines the start of a procedure ex: main PROC

INCLUDE

directive inserts source code from specified file into current file during assembly ex: INCLUDE Irvine32.lib

.code

directive marks beginning of the code segment ex: .code

.data

directive marks beginning of the data segment ex: .data

END

directive marks the end of the module, optionally set program entry point (otherwise execution starts on first byte of generated executable file) ex: END main

.stack

directive sets the size of the stack ex: .STACK [size] defaults to 1024

USES

directive used in conjunction with a procedure header to specify which registers to save ex: someProc PROC USES EAX EBX

components of MASM programs

directives identifiers memory locations literals data types instructions

DWORD, WORD, BYTE...

directives specify memory space to be allocation for variable storage ex: valA DWORD 40

REAL8

double precision floating point data type 64 bits - 1 sign bit, 11 exponent bits, 52 mantissa bits

even parity

each bit grouping must have an even number of 1 bits

odd parity

each bit grouping must have an odd number of 1 bits

multicomputer parallelism

each processor has its own memory, completes its own subtask, then communicates w other processors through an interconnection network ex: internet, cloud computing

protected mode

each running program is reserved a linear address space in memory of 4GB, and programs aren't allowed to access each other's allocated space, prevents direct access to EIP native operating mode

FPU components

eight 10-byte registers named R0-R7, organized as a pushdown stack TOP indicates top register ST(0)-ST(7) correspond to the top through bottom of stack

signal noise

electrical interference

electronic representation of bits

energy states (voltage levels) within circuits, with values over X assigned to 1 and values under X assigned to 0

post-test loop

equivalent to a do-while loop will execute 1 or more times

counted loop

equivalent to a for loop will execute until ECX is 0, ECX is decremented after every loop

procedure

equivalent to a function/method in high-level programming languages

pre-test loop

equivalent to a while loop will execute 0 or more times

conditional branching

equivalent to if/elif/else statements

parallelism

execution of multiple parts of code at the same time

REAL10

extended precision floating point data type 80 bits - 1 sign bit, 15 exponent bits, 64 mantissa bits

parity bit

extra bit added to each bit grouping, set to either 0 or 1 to make the grouping match the system parity

stack and heap shared space

finite space in stack segment stack starts at end and grows toward the beginning heap starts at beginning and grows toward the end

FADD

floating point instruction add source to destination

FABS

floating point instruction clear sign of ST(0), so gives absolute value

FST / FIST

floating point instruction copy top of FPU stack to operand, does not pop value so ST(0) remains unchanged

FDIV

floating point instruction divide destination by source

FDIVR

floating point instruction divide source by destination

FCHS

floating point instruction invert sign of ST(0)

FMUL

floating point instruction multiply source by destination

FSTP / FISTP

floating point instruction pop top of FPU stack to operand, shifts ST(n)

FLD / FILD

floating point instruction pushes value from operand to FPU stack

FSUBR

floating point instruction subtract destination from source

FSUB

floating point instruction subtract source from destination

FSQRT

floating point instruction take square root of destination

base number systems

for base n, each digit represents a multiple of a power of n positions are numbered right to left, starting at 0, corresponding to their power of n

EBP

general purpose register special purpose: stack pointer, points to the base of a stack frame (should not be used for anything else)

ESP

general purpose register special purpose: stack pointer, points to the top of the runtime stack aka last value pushed or added to the stack (should not be used for anything else)

EDI

general purpose register special purpose: used by memory transfer functions as the destination address (should not be used for anything else)

ESI

general purpose register special purpose: used by memory transfer functions as the source address (should not be used for anything else)

general purpose registers

general storage of values, pointers, operands, etc. most have additional special purposes, except for EBX list: EAX, EBX, ECX, EDX, ESI, EDI, ESP, EBP

complex instruction set computer (CISC)

has ISA that creates a micro-program for each instruction which is then executed

reduced instruction set computer (RISC)

has ISA that directly executes instructions and has a smaller set of instructions

instruction register (IR)

holds code describing the current instruction being executed

instruction pointer (IP)

holds memory address of the next instruction to be executed

memory address register (MAR)

holds memory address where the read/write will occur this value goes to the address bus

memory data register (MDR)

holds value to be written to / read from memory this value goes to / comes from the data bus

code label

identifiers that refer to memory locations in the code segment, allowing us to use the code label instead of the address offset when referring to a specific instruction or block of instructions

data label

identifiers that refer to memory locations in the data segment, allowing us to use the data label instead of the address offset when referring to a specific variable

status flags

indicate results of arithmetic instructions bits 0, 2, 4, 6, 7, 11 of EFLAGS

initializer

initial value put into the allocated memory space for the data label ? indicates leaving the memory location uninitialized

CLD

instruction clears direction flag, primitives will automatically increment their pointer

POP

instruction copies value at top of stack into operand then increments ESP value is not removed, still there until overwritten cannot POP to immediate

LOOP

instruction decrements ECX then JNZ to address of operand destination address must be within [-127, 128] bytes of the instruction address

PUSH

instruction decrements ESP then copies operand onto the stack change in ESP memory address equal to size of operand (in bytes)

FINIT

instruction initializes FPU stack, must be executed before any floating point instructions

CMP

instruction performs implied subtraction of second operand from first operand, changes EFLAGS instead but does not overwrite operand values used in conditional branching

RET

instruction pops top of stack into EIP (when given no operands) w operand n... adds n bytes to ESP after EIP assigned, used to de-reference any parameters passed to the stack before the CALL

CALL

instruction pushes EIP corresponding to return address onto the stack then jumps to beginning of named procedure

JMP

instruction sets EIP to address specified by the operand used in unconditional branching

STD

instruction sets direction flag, primitives will automatically decrement their pointer

pipelining

instruction broken down into parts and hardware provides separate units that each perform a specific part

EIP

instruction pointer register that contains the offset in the current code segment of the next instruction to be executed cannot be directly accessed

types of hardware parallelism

instruction-level parallelism (pipelining, instruction caching) processor-level parallelism (multiprocessors, multicomputers)

Jcond

instructions JMP to address of operand if condition is satisfied used in conditional branching

PUSHA / POPA

instructions push/pop all of the 16-bit versions of the general purpose registers onto/from the stack order of push: AX, CX, DX, BX, SP, BP, SI, DI

PUSHAD / POPAD

instructions push/pop all of the 32-bit general purpose registers onto/from the stack order of push: EAX, ECX, EDX, EBX, ESP, EBP, ESI, EDI

PUSHFD / POPFD

instructions push/pop the 32-bit EFLAGS register onto/from the stack

on-chip memory (L1 cache)

largest memory that resides on the CPU very fast but very expensive, so generally small

little endian

least significant byte stored first in memory ex: x86-64 systems

block starting symbol (bss) segment

location in memory of additional static data for variables or constants

code segment

location in memory of current program

data segment

location in memory of data from current program

stack segment

location in memory of runtime stack and heap for current program

language hierarchy

lvl 4: natural languages lvl 3: programming languages lvl 2: assembly languages lvl 1: machine language lvl 0: machine hardware one-to-one correspondence of assembly languages to machine languages

control unit (CU)

manages flow of execution subcomponents: IP, IR, instruction decoder, control register, status register

big endian

most significant byte stored first in memory ex: networks

multiprocessor parallelism

multiple processors each complete their own subtask and communicate through shared memory

multiprocessor vs. multicomputer parallelism

multiprocessor system is hard to build but relatively easy to program multicomputer system is relatively easy to build but hard to program

input-output parameter

must be passed by reference data will be used and memory containing data will be modified by procedure

output parameter

must be passed by reference memory containing data will be modified by procedure

identifiers

names of variables, functions, labels, etc.

identifier restrictions

no spaces not case sensitive can start w and include letters, underscore, @, ?, $ can include numerical digits after the first character cannot be a reserved word

real-address mode

only one program can run at a time, any memory address within its 1 MB memory space is accessible including those directly linked to hardware provides compatibility with legacy programs

implied operand

operand that is used implicitly without being defined usually in single-operand instructions

OFFSET

operator returns pointer to a memory variable

PTR

operator used when destination operand is de-referenced pointer bc it does not have an implicit type ex: MOV DWORD PTR [EDI], 10 instead of MOV [EDI], 10

DUP

operator that replaces the initializer for a data label and allocates space for the storage of multiple items usually used when defining empty strings or arrays n DUP(m) for n contiguous elements initialized to m

software parallelism

parallelizability of algorithms depends on... number of processors available trades b/t increased efficiency and costly network overhead of parallel activities sequential vs. parallel code

potentially parallelizable part

part of program that can be parallelized, either partially or completely

inherently sequential part

part of program that cannot be parallelized

bus

physical pipelines for transfer of data transfer rates correspond to bus width

RISC benefits

physically smaller, so same performance for cheaper lower complexity of CPU circuitry, so long-term reliability lower power consumption, so more environmentally friendly lower operating temperature, so reduce costs of heat dissipation components

segment registers

pointers to specific segments of memory, whose usage depends on the mode of operation

ways to push data to the stack

preserving/restoring all registers using PUSHAD/POPAD vs. selectively preserving/restoring used registers using PUSH/POP (*preferred*)

ECX

primary general purpose register special purpose: counter

EDX

primary general purpose register special purpose: implied extension for EAX for ALU operations that extend beyond 32-bits

EAX

primary general purpose register special purpose: implied operand in many ALU operations

EBX

primary general purpose register special purpose: none

SCASB / SCASW / SCASD

primitive instruction compare accumulator to memory addressed by EDI, then updates pointer

CMPSB / CMPSW / CMPSD

primitive instruction compare memory addressed by ESI to memory addressed by EDI, then updates pointers

MOVSB / MOVSW / MOVSD

primitive instruction copy data from memory addressed by ESI into memory addressed by EDI, then updates pointers

LODSB / LODSW / LODSD

primitive instruction load memory address by ESI into accumulator, then updates pointer

STOSB / STOSW / STOSD

primitive instruction store accumulator contents into memory addressed by EDI, then updates pointer

RISC design principles

prioritize single-cycle instruction execution instructions executed directly by hardware use of instruction cache only two memory access instructions - LOAD and STORE simplification of instructions few addressing modes

called procedure

procedure that is the operand of the CALL instruction

control module

procedure that provides an outline for the program and calls other procedures

calling procedure

procedure where the CALL instruction is used

system management mode

processor will switch to a separate address space so vital memory isn't affected, program execution halted until end enables special configurations to be implemented

IA-32 architecture modes of operation

protected mode real-address mode system management mode

loader

reads an executable file and stores contents into memory for execution

memory I/O

reads/writes information in main memory using MAR and MDR

types of operands

reg - register mem - memory location imm - immediate accum - AL, AX, or EAX segreg - segment register shortlabel - location in the code segment w/i -127 to 128 bytes of current location nearlabel - location in the current code segment farlabel - location in an external code segment instruction - instruction

instruction set architecture (ISA)

registers, instructions, and operands which define an assembly language

REP

repeat prefix runs instruction then decrements ECX, repeat as long as ECX > 0

REPNZ / REPNE

repeat prefix runs instruction then decrements ECX, repeat as long as ECX > 0 and zero flag is clear only SCAS* and CMPS* modify zero flag

REPZ / REPE

repeat prefix runs instruction then decrements ECX, repeat as long as ECX > 0 and zero flag is set only SCAS* and CMPS* modify zero flag

stack trace

report of the active stack frames at a certain point during the execution of the program

CS

segment register points to beginning of code segment

DS

segment register points to beginning of data segment

ES

segment register points to data storage

FS

segment register points to data storage

GS

segment register points to data storage

SS

segment register points to stack segment

call stack

series of activation records from nested procedures stacked on top of each other

status register

set of flags corresponding to processed data or indicating ways in which data will be processed

instruction mnemonic

short, descriptive phrase that indicates which instruction is being executed

virtual machine

simulates another computer's architecture

REAL4

single precision floating point data type 32 bits - 1 sign bit, 8 exponent bits, 23 mantissa bits

sub-register access method

special property of general purpose registers that allows direct access of a subset of their bits for the 8 general purpose registers, access the lower 16 bits by removing E from register name (AX, BX, CX, DX, SI, DI, SP, BP) for the 4 primary general purpose registers, access the lowest (AL, BL, CL, DL) or highest (AH, BH, CH, DH) bytes of the 16-bit versions

instruction caching

speeds up rate of fetching instructions and reduces idle time by fetching multiple instructions at a time efficient for sequential areas of programming, but anywhere w branching/repetition/etc causes work to be done caching instructions that will never be executed

pushdown stack

stack with limited capacity that overwrites the bottom element if exceeded, any of the registers can be accessed directly using ST(n)

single-line comment

starts with ; and includes all following text on that line

multi-line comment

starts with COMMENT followed by a special character and includes all text until the special character is encountered again ex: COMMENT !

instruction

statement that makes processor process information

control structure

statements that control the flow of execution of the program

carry flag (CF/CY)

status flag (bit 0 of EFLAGS) set if unsigned arithmetic operation generates a carry/borrow of the most-significant bit of the result

overflow flag (OF/OV)

status flag (bit 11 of EFLAGS) set if signed arithmetic operation generates a result that is too large a positive number or too small a negative number to fit in the destination operand

parity flag (PF/PE)

status flag (bit 2 of EFLAGS) set if the least-significant byte of the result contains an even number of 1 bits

auxiliary carry flag (AF/AC)

status flag (bit 4 of EFLAGS) set if binary-coded decimal arithmetic operation generates a carry/borrow of bit 3 of the result

zero flag (ZF/ZR)

status flag (bit 6 of EFLAGS) set if result is zero

sign flag (SF/PL)

status flag (bit 7 of EFLAGS) set equal to the sign bit of the result

EFLAGS

status/control register used to control/report on the status of the processor

[reg]

syntax to deference a pointer and give the value at that address instead

activation record / stack frame

the return address, argument, local variables, and preserved registers of a procedure which are all pushed onto the stack

computer memory model

to access data... 1. place memory address on address bus 2. trigger memory read 3. wait a clock cycle for the information to be copied onto the data bus 4. move data into its destination so it can be processed by another component data is copied, so must go back and trigger a memory write if changes are to be saved bottleneck at step 3 b/c data bus used for both instructions and data, so additional tiers of cache memory exist

parity

total number of 1 bits (including the added parity bit) in a grouping

precision vs. range in floating point numbers

tradeoff between precision (up to 1.4 x 10^-45) and range (up to +/- 3.4 x 10^38) exponents in [0, 126] indicate more precision exponent of 127 is perfectly centered exponent in [128, 255] indicate more range

caching

transferring information from a farther, slower memory location to a closer, faster one

input/output (I/O) bus

transfers data between CPU and attached onboard/peripheral devices

data bus

transfers instructions/data between RAM and CPU

address bus

transfers memory addresses between RAM and CPU

assembler

translates assembly language code to machine language objects

compiler

translates programming language code to assembly language code

branching structure

type of control structure moves execution of the program to a specified point in the code segment

repetition structure

type of control structure repeats execution of a certain segment of the program

control bus

uses signals to coordinate all devices attached to the system

input parameter

usually passed by value, but may be passed by reference (ex: arrays) data will be used by procedure

return value

value determined by the called procedure and communicated back to the calling procedure

argument (actual parameter)

value/reference that is passed to a procedure

parameter (formal parameter)

value/reference that is received by a procedure

bit error

variation of energy state that causes the converter to incorrectly assign a bit value surprisingly common, especially in high data-rate or long distance signal transmission

source operand

where data is copied from usually the second operand in two-operand instructions

destination operand

where result is stored usually the first operand in two-operand instructions

range of unsigned integers w/ n bits

0 to 2^n - 1

RISC instruction execution cycle

1. FETCH instruction 2. EXECUTE instruction

CISC instruction execution cycle

1. FETCH next instruction to be executed (IP incremented immediately after) 2. DECODE instruction (and fetch operands if required) 3. EXECUTE instruction by feeding it and any operands into the control unit (and store result into output operand)

comparison of when/how to preserve/restore registers

1. calling procedure uses memory 2. calling procedure uses the stack both require calling procedure to track used registers which does not promote good procedure modularity 3. called procedure uses memory good modularity but requires additional memory allocation and usage of global variable 4. called procedure uses runtime stack (*preferred*) good modularity, no global variables, efficient in resource usage

ways to pass data to/from procedures

1. shared memory usage of global variables has a high risk of side effects 2. pass parameters in registers (ex: Irvine Library) violates "register states preserved" property of good modularization, very limited number of registers that can be used 3. pass parameters on the stack (*preferred*) reduces code clutter, good modularity, can be used by high-level programming languages

range of signed integers w/ n bits

-2^(n-1) to 2^(n-1) - 1

number, size, and type of registers

8x 32-bit general purpose registers 6x 16-bit segment registers 1x 32-bit program status and control register 1x 32-bit instruction pointer register

ways to define constants

= EQU TEXTEQU

CISC primary components

CPU RAM I/O Unit

CISC vs. RISC

RISC programs are longer and bc fewer built-in instructions (memory), but execute quicker bc no micro-program overhead (performance)


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