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Assembly

Assembly. תכנות באסמבלי. Assembly vs. Higher level languages. There are NO variables’ type definitions. All kinds of data are stored in the same registers. We need to know what we are working it in order to use the right instructions. Memory = a large, byte-addressable array.

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Assembly

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  1. Assembly תכנות באסמבלי

  2. Assembly vs. Higher level languages • There are NO variables’ type definitions. • All kinds of data are stored in the same registers. • We need to know what we are working it in order to use the right instructions. • Memory = a large, byte-addressable array. • Only a limited set of registers is used to store data while running the program. • If we need more room we must save the data into memory and later reread it. • No special structures (instructions) for “if” / “switch” / “loops” (for, while, do-while), or even functions!

  3. תזכורת: תהליך קומפילציה

  4. תמיכת שפת C בכתיבת מרובת קבצים • כתיבת מודולים הוטמעה בשפת C בכך שבניית התוכנה נעשית בשני שלבים: • הידור(compilation) של כל קובץ מקור (.c ) בנפרד • קישור(linking) של כל הקבצים ביחד • 4

  5. Linux Compilation Process Five stages : Preprocessing, Parsing, Translation, Assembling, and Linking All 5 stages are implemented by one program in UNIX, gcc gcc is the C compiler of choice for most UNIX. Actually just a front end that executes various other programs corresponding to each stage in the compilation process. To get it to print out the commands it executes at each step, use gcc -v.

  6. How to - Disassembly of code • Compilation of code: • gcc -c code.c • We get the file: code.o • Disassembly: • objdump -d code.o • We get an assembly-like code that represents the c code appeared in file code.c • Or: • gcc -s code.c • We get a code.s file that contains an assembly code created by the compiler.

  7. Standard data types Assembly In Assembly: size = type of variable.

  8. Words, double words …. • Due to its origins as a 16-bit architecture that expanded into a 32-bit one, Intel uses the term “word” to refer to a 16-bit data type and not a 32-bit data type as we mentioned before. Backward Compatibility. • 32-bit quantities as “double words”. • 64-bit quantities as “quad words”. • Most instructions we will encounter operate on bytes or double words. • Each instruction has 3 variants, depending on its suffix (‘b’ – byte / ‘w’ – word / ‘l’ – double word).

  9. The Registers • An IA32 CPU contains a set of eight registers storing 32-bit values. These registers are used to store integer data as well as pointers. • The registers names all begin with %e (extend), but otherwise they have peculiar names. • In the original 8086 CPU each register had a specific target (and hence it got its name). Today most of these targets are less significant. • Some instructions use fixed registers as sources and/or destinations. • Within procedures there are different conventions for saving and restoring the first three registers (%eax, %ecx, and %edx), than for the next three (%ebx, %edi, and %esi). • %ebp and %esp contain pointers to important places in the program stack.

  10. The File Register

  11. Partial access to a register • The low-order two bytes of the first four registers can be independently read or written by the byte operation instructions. This feature was provided to allow backward compatibility. • When a byte instruction updates one of these single-byte “register elements,” the remaining three bytes of the register do not change. • Same goes for the low-order 16 bits of each register, using word operation instructions.

  12. Operand Forms

  13. Move to / from memory Instructions

  14. Important Suffixes • ‘l’ - double word. • ‘w’ - word. • ‘b’ - byte • ‘s’ - single (for floating point)

  15. movl Operand Combinations Source Destination C Analog Cannot do memory-memory transfers with single instruction !!! Reg movl $0x4,%eax temp = 0x4; Imm Mem movl $-147,(%eax) *p = -147; Reg movl %eax,%edx temp2 = temp1; movl Reg Mem movl %eax,(%edx) *p = temp; Mem Reg movl (%eax),%edx temp = *p;

  16. Important prefixes • i – immediate (constant) value. • r – register. • m – memory. • rrmovl = move double word from one register to the other. • irmovw = move the word given as immediate value into the register.

  17. movb & movw • The movb instruction is similar, but it moves just a single byte. When one of the operands is a register, it must be one of the eight single-byte register elements. • Similarly, the movw instruction moves two bytes. When one of its operands is a register, it must be one of the eight two-byte register elements. • Both the movsbl and the movzbl instructions serve to copy a byte and to set the remaining bits in the destination: • movsbl - signed extension. • movzbl - zero extension.

  18. MOVSBL and MOVZBL MOVSBL sign-extends a single byte, and copies it into a double-word destination MOVZBL expands a single byte to 32 bits with 24 leading zeros, and copies it into a double-word destination Example: %eax = 0x12345678 %edx = 0xAAAABBBB MOVB %dh, %al %eax = 0x123456BB MOVSBL %dh, %eax %eax = 0xFFFFFFBB MOVZBL %dh, %eax %eax = 0x000000BB

  19. Another example (Assume initially that %dh = 8D, %eax = 98765432) • movb %dh,%al %eax = 9876548D • movsbl %dh,%eax %eax = FFFFFF8D • movzbl %dh,%eax %eax = 0000008D

  20. C vs. Assemblyexample

  21. Arithmetic & Logical Operations

  22. Arithmetic & Logical Operations (2) • With the exception of leal, each of these instructions has a counterpart that operates on words (16 bits) and on bytes (by replacing the suffix). • Again, cannot do memory-memory transfers with single instruction

  23. “Load Effective Address” (leal) • The “Load Effective Address” (leal) instruction is actually a variant of the movl instruction. • Its first operand appears to be a memory reference, but instead of reading from the designated location, the instruction copies the effective address to the destination. Doesn’t access memory !!! • This instruction can be used to generate pointers for later memory references without accessing memory.

  24. leal (2) • The leal Instruction can be used to compactly describe common arithmetic operations. • If register %edx contains value x, then the instruction: leal 7(%edx,%edx,4), %eax will set register %eax to 5x + 7. • It is commonly used to perform simple arithmetic: • (%eax = x; %ecx = y) • leal 6(%eax), %edx • leal (%eax,%ecx), %edx • leal (%eax,%ecx,4), %edx • leal 7(%eax,%eax,8), %edx • leal 0xA(,%ecx,4), %edx • leal 9(%eax,%ecx,2), %edx = x+6 = x+y = x+4y = 9x+7 = 4y+10 =x+2y+9

  25. Logical Shift Logical Shift -  every bit in the operand is simply moved a given number of bit positions, and the vacant bit-positions are filled in, usually with zeros. Useful as multiplication or division of unsigned integers by powers of two.

  26. Arithmetic Right Shift A bitwise operation that shifts all of the bits of its operand Every bit in the operand is simply moved a given number of bit positions, and the vacant bit-positions are filled in with the leftmost bit. When shifting to the right - leftmost bit- sign bit - sort of sign extension.  Dividing by 2n

  27. Shift • Either logical or arithmetic • k is a number between 0 and 31, or the single-byte register %cl • Suppose that x and n are stored at memory locations with offsets 8 and 12, respectively, relative to the address in register %ebp • get n • get x • x <<= 2 • x >>= n  movl 12(%ebp), %ecx  movl 8(%ebp), %eax  sall $2,%eax  sarl %cl,%eax

  28. C vs. Assembly example

  29. mul & div Instructions

  30. Imull Example mov +4823424, eax mov -423, ebx imul ebx ; What happens is : EDX:EAX = FFFFFFFFh:86635D80h תמר שרוט, נועם חזון

  31. Cltd - converts the signed long in EAX to a signed double long in EDX:EAX by extending the most-significant bit (sign bit) of EAX into all bits of EDX iDiv - The idiv instruction divides the contents of the 64 bit integer EDX:EAX (EDX as the most significant four bytes and EAX as the least significant four bytes) by the specified operand value. The quotient result of the division is stored into EAX, while the remainder is placed in EDX. תמר שרוט, נועם חזון

  32. Code example (x at %ebp+8, y at %ebp+12) • movl 8(%ebp),%eax Put x in %eax • imull 12(%ebp) Multiply by y • pushl %edx Push high-order 32 bits • pushl %eax Push low-order 32 bits

  33. Yet, another example (x at %ebp+8, y at %ebp+12) • movl 8(%ebp),%eax Put x in %eax • cltd Sign extend into %edx • idivl 12(%ebp) Divide by y • pushl %eax Push x / y • pushl %edx Push x % y

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