IA32 programming for Linux Concepts and requirements for writing Linux assembly language programs for Pentium CPUs A source program’s format • • • • • • • Source-file: a pure ASCII-character textfile Is created using a text-editor (such as ‘vi’) You cannot use a ‘word processor’ (why?) Program consists of series of ‘statements’ Each program-statement fits on one line Program-statements all have same layout Design in 1950s was for IBM punch-cards Statement Layout (1950s) • Each ‘statement’ was comprised of four ‘fields’ • Fields appear in a prescribed left-to-right order • These four fields were named (in order): -- the ‘label’ field -- the ‘opcode’ field -- the ‘operand’ field -- the ‘comment’ field • In many cases some fields could be left blank • Extreme case (very useful): whole line is blank! The ‘as’ program • • • • • • • The ‘assembler’ is a computer program It accepts a specified text-file as its input It must be able to ‘parse’ each statement It can produce onscreen ‘error messages’ It can generate an ELF-format output file (That file is known as an ‘object module’) It can also generate a ‘listing file’ (optional) The ‘label’ field • A label is a ‘symbol’ followed by a colon (‘:’) • The programmer invents his own ‘symbols’ • Symbols can use letters and digits, plus a very small number of ‘special’ characters ( ‘.’, ‘_’, ‘$’ ) • A ‘symbol’ is allowed to be of arbitrarily length • The Linux assembler (‘as’) was designed for translating source-text produced by a high-level language compiler (such as ‘cc’) • But humans can also write such files directly The ‘opcode’ field • Opcodes are predefined symbols that are recognized by the GNU assembler • There are two categories of ‘opcodes’ (called ‘instructions’ and ‘directives’) • ‘Instructions’ represent operations that the CPU is able to perform (e.g., ‘add’, ‘inc’) • ‘Directives’ are commands that guide the work of the assembler (e.g., ‘.globl’, ‘.int’) Instructions vs Directives • Each ‘instruction’ gets translated by ‘as’ into a machine-language statement that will be fetched and executed by the CPU when the program runs (i.e., at ‘runtime’) • Each ‘directive’ modifies the behavior of the assembler (i.e., at ‘assembly time’) • With GNU assembly language, they are easy to distinguish: directives begin with ‘.’ A list of the Pentium opcodes • An ‘official’ list of the instruction codes can be found in Intel’s programmer manuals: http://developer.intel.com • But it’s three volumes, nearly 1000 pages (it describes ‘everything’ about Pentiums) • An ‘unofficial’ list of (most) Intel instruction codes can fit on one sheet, front and back: http://www.jegerlehner/intel/ The AT&T syntax • The GNU assembler uses AT&T syntax (instead of official Intel/Microsoft syntax) so the opcode names differ slightly from names that you will see on those lists: Intel-syntax --------------ADD INC CMP AT&T-syntax ---------------------addb/addw/addl incb/incw/incl cmpb/cmpw/cmpl The UNIX culture • Linux is intended to be a version of UNIX (so that UNIX-trained users already know Linux) • UNIX was developed at AT&T (in early 1970s) and AT&T’s computers were built by DEC, thus UNIX users learned DEC’s assembley language • Intel was early ally of DEC’s competitor, IBM, which deliberately used ‘incompatible’ designs • Also: an ‘East Coast’ versus ‘West Coast’ thing (California, versus New York and New Jersey) Bytes, Words, Longwords • CPU Instructions usually operate on data-items • Only certain sizes of data are supported: BYTE: one byte consists of 8 bits WORD: consists of two bytes (16 bits) LONGWORD: uses four bytes (32 bits) • With AT&T’s syntax, an instruction’s name also incorporates its effective data-size (as a suffix) • With Intel syntax, data-size usually isn’t explicit, but is inferred by context (i.e., from operands) The ‘operand’ field • Operands can be of several types: -- a CPU register may hold the datum -- a memory location may hold the datum -- an instruction can have ‘built-in’ data -- frequently there are multiple data-items -- and sometimes there are no data-items • An instruction’s operands usually are ‘explicit’, but in a few cases they also could be ‘implicit’ Examples of operands • Some instruction that have two operands: movl %ebx, %ecx addl $4, %esp • Some instructions that have one operand: incl %eax pushl $fmt • An instruction that lacks explicit operands: ret The ‘comment’ field • An assembly language program often can be hard for a human being to understand • Even a program’s author may not be able to recall his programming idea after awhile • So programmer ‘comments’ can be vital • A comments begin with the ‘#’ character • The assembler disregards all comments (but they will appear in program listings) ‘Directives’ • • • • • • Sometimes called ‘pseudo-instructions’ They tell the assembler what to do The assembler will recognize them Their names begin with a dot (‘.’) Examples: ‘.section’, ‘.global’, ‘.int,’ … The names of valid directives appears in the table-of-contents of the GNU manual New program example • Let’s look at a demo program (‘squares.s’) • It prints out a mathematical table showing some numbers and their squares • But it doesn’t use any multiplications! • It uses an algorithm based on algebra: (n+1)2 - n2 = n + n + 1 If you already know the square of a given number n , you can get the square of the next number n+1 by just doing additions A program with a ‘loop’ • Here’s our program idea (expressed in C) int num = 1, val = 1; do { printf( “ %d %d \n”, num, val ); val += num + num + 1; num += 1; } while ( num <= 20 ); Some new ‘directives’ • ‘.equ’ – equates a symbol to a value: .equ max, 20 • ‘.globl’ – just an alternative to ‘.global’: .globl main Some new ‘instructions’ • ‘inc’ – adds one to the specified operand: incl arg • ‘cmp’ – compares two specified operands: cmpl $max, arg • ‘jle’ – jump (to a specified instruction) if condition ‘less than or equal to’ is true: jle again In-class Exercise • Can you write a program that prints out a table showing powers of 2 (very useful for computer science students to have handy) • Can you see how to do it without using any ‘multiply’ operations – just additions? • Hint: study the ‘squares.s’ source-code • Then write your own ‘powers.s’ solution • Turn in printouts (source and its output)