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Chapter 2 Instructions: Language of the Computer Instructions: Language of the Machine Instruction set: the vocabulary of commands understood by a given architecture. More primitive than higher level languages e.g., no sophisticated control flow Very restrictive e.g., MIPS Arithmetic Instructions We’ll be working with the MIPS instruction set architecture similar to other architectures developed since the 1980's used by NEC, Nintendo, Silicon Graphics, Sony Design goals: maximize performance and minimize cost, reduce design time MIPS arithmetic Operations and Operands All instructions have 3 operands Need to break a C statement into several assembly instructions add t0,g,h add t1,i,j ( f = (g + h) – ( I + j)) sub f,t0,t1 Operand order is fixed (destination first) Example: C code: A = B + C MIPS code: add $s0, $s1, $s2 (associated with variables by compiler) MIPS arithmetic Design Principle 1: simplicity favors regularity. Why? Of course this complicates some things... C code: A = B + C + D; E = F - A; MIPS code: add $t0, $s1, $s2 add $s0, $t0, $s3 sub $s4, $s5, $s0 Operands must be registers, only 32 registers provided Registers vs. Memory Design Principle 2: smaller is faster. Why? Arithmetic instructions operands must be registers, — only 32 registers provided Compiler associates variables with registers What about programs with lots of variables? Memory Organization Viewed as a large, single-dimension array, with an address. A memory address is an index into the array "Byte addressing" means that the index 0 points to a byte of memory. 8 bits of data 1 2 3 4 5 6 ... 8 bits of data 8 bits of data 8 bits of data 8 bits of data 8 bits of data 8 bits of data Memory Organization 0 4 8 12 ... 32 bits of data 32 bits of data 32 bits of data Registers hold 32 bits of data 32 bits of data Bytes are nice, but most data items use larger "words" For MIPS, a word is 32 bits or 4 bytes. 232 bytes with byte addresses from 0 to 232-1 230 words with byte addresses 0, 4, 8, ... 232-4 Words are aligned i.e., what are the least 2 significant bits of a word address? Instructions Load and store instructions Example: C code: A[8] = h + A[8]; MIPS code: lw $t0, 32($s3) add $t0, $s2, $t0 sw $t0, 32($s3) Store word has destination last Remember arithmetic operands are registers, not memory! Another Example What is the MIPS assembly code for A[12] = h + A[8] assuming that h is associated with register $s2 and the base address of the array A is in $s3? lw $t0,32($s3) # temporary reg $t0 gets A[8] add $t0,$s2,$t0 # $t0 gets h + A[8] sw $t0,48($s3) # stores h + A[8] into A[12] Constants Small constants are used quite frequently (50% of operands) e.g., A = A + 5; B = B + 1; C = C - 18; Solutions? Why not? put 'typical constants' in memory and load them. create hard-wired registers (like $zero) for constants like one. 3 Constants (cont’d) MIPS Instructions: addi $s3, $s3, 4 slti $s1, $t1, 10 andi $s3, $s3, 6 ori $s3, $s3, 4 Design Principle 3: Make the common case fast. So far we’ve learned: (p.59) MIPS — loading words but addressing bytes — arithmetic on registers only Instruction Meaning add $s1, $s2, $s3 sub $s1, $s2, $s3 addi $s1, $s2,100 lw $s1, 100($s2) sw $s1, 100($s2) $s1 = $s2 + $s3 $s1 = $s2 – $s3 $s1 = $s2 + 100 $s1 = Memory[$s2+100] Memory[$s2+100] = $s1 Machine Language Instructions, like registers and words of data, are also 32 bits long Example: add $t0, $s1, $s2 Registers have numbers, $t0=8, $s1=17, $s2=18 000000 10001 10010 00000 100000 shamt funct Instruction Format: op 01000 rs rt rd Can you guess what the field names stand for? MIPS Fields R-type op: basic operation of the instruction, or opcode (6 bits) rs: the first register source operand (5 bits) rt: the second register source operand (5 bits) rd: the register destination operand (5 bits) shamt: shift amount (5 bits) funct: function code (6 bits) Machine Language Consider the load-word and store-word instructions, What would the regularity principle have us do? New principle: Good design demands good compromises. I-Type Instruction Introduce a new type of instruction format I-type for data transfer instructions other format was R-type for register Example: lw $t0, 32($s2) 35 18 8 op rs rt 32 16 bit number Another example: addi (R-type or I-Type?) Where's the compromise? Translating MIPS Assembly Language into Machine Language(p 65-66) Example (Figure 2.6 MIPS Instruction Encoding) A[300] = h + A[300] lw $t0,1200($t1) add $t0,$s2,$t0 sw $t0,1200($t1) MIPS Instruction Encoding: MIPS Reference Data Card Stored Program Concept Instructions are bits Programs are stored in memory — to be read or written just like data Fetch & Execute Cycle Instructions are fetched and put into a special register Bits in the register "control" the subsequent actions Fetch the “next” instruction and continue Logical Operations Useful to operate on fields of bits within a word or on individual bits. Logical operations C operators Java operators MIPS Shift left << << sll Shift right >> >>> srl Bit-by-bit AND & & and,andi Bit-by-bit OR | | or,ori Bit-by-bit NOT ~ ~ nor shamt sll $t2,$s0,4#reg $t2 = reg $s0 op rs rt rd shamt funct 0 0 16 10 4 << 4 bits 0 Shift amount = 4 (What is the max shift amount?) Shifting left by i bits gives the same result as multiplying by 2i Instructions for Making Decisions Decision making instructions alter the control flow, i.e., change the "next" instruction to be executed MIPS conditional branch instructions: bne $t0, $t1, Label beq $t0, $t1, Label Example: if (i==j) h = i + j; bne $s0, $s1, Label add $s3, $s0, $s1 Label: .... If-then-else conditional branches MIPS unconditional branch instructions: j label Example: if (i==j) h=g+h; else f=g-h; bne $s3, $s4, Else add $s0, $s1, $s2 j Exit Else:sub $s0, $s1, $s2 Exit: Loops while loop in C: while (save[i]==k) i+=1; i $s3, k$s5, base of the array save is in $s6. Loop: sll Exit: $t1,$s3,2 # reg $t1=4*i add $t1,$t1,$s6 # $t1= address of save[i] lw $t0,0($t1) bne $t0, $s5, Exit # go to Exit if save[i]!=k addi $s3,$s3,1 # i=i+1 j Loop # go to Loop # reg t0=save[i] Control Flow We have: beq, bne, what about Branch-if-less-than? New instruction: if $s3 < $s4 then $t0 = 1 slt $t0, $s3, $s4 else $t0 = 0 slti $t0,$s2,10 # $t0=1 if $s2 < 10 Can use the above instructions to build "blt $s1, $s2, Label" — can now build general control structures Note that the assembler needs a register to do this, there are policy of use conventions for registers ($zero) Case/Switch Statement Two possible approaches Convert the switch statement into a chain of ifthen-else statements Build a jump address table MIPS instruction: jr (jump register) Unconditional jump to the address specified in the register. So far (p.77): Instruction Meaning add $s1,$s2,$s3 sub $s1,$s2,$s3 lw $s1,100($s2) sw $s1,100($s2) and $s1,$s2,$s3 or $s1,$s2,$s3 nor $s1,$s2,$s3 andi $s1,$s2,100 ori $s1,$s2,100 sll $s1,$s2,10 srl $s1,$s2,10 bne $s4,$s5,L beq $s4,$s5,L slt $s1,$s2,$s3 slti $s1,$s2,100 j Label $s1 = $s2 + $s3 $s1 = $s2 – $s3 $s1 = Memory[$s2+100] Memory[$s2+100] = $s1 $s1 = $s2 & $s3 $s1 = $s2 | $s3 $s1 = ~($s2 | $s3) $s1 = $s2 & 100 $s1 = $s2 ! $100 $s1=s2<<10 $s1=s2>>10 Next instr. is at Label if $s4!= $s5 Next instr. is at Label if $s4 = $s5 if ($s2<$s3) $s1=1, else $s1=0 if ($s2<100) $s1=1, else $s1=0 Next instr. is at Label Formats R op rs rt I op rs rt J op rd shamt funct 16 bit address/constant 26 bit address Supporting Procedures in Computer Hardware Six steps the program must follow in an execution of a procedure 1. 2. 3. 4. 5. 6. Place parameters in a place where the procedure can access them Transfer control to the procedure Acquire the storage resources needed for the procedure Perform the desired task Place the result value in a place where the calling program can access it Return control to the point of origin. MIPS Registers MIPS registers: $a0-a3: four argument registers in which to pass parameters $ v0-$v1: two value registers in which to return values $ra: one return address register to return to the point of origin MIPS instruction: jal ProcedureAddress (jump and link) Using More Registers Use stack MIPS allocates a register for the stack: the stack pointer ($sp) Example: p81-82. Policy of Use Conventions Name Register number $zero 0 $v0-$v1 2-3 $a0-$a3 4-7 $t0-$t7 8-15 $s0-$s7 16-23 $t8-$t9 24-25 $gp 28 $sp 29 $fp 30 $ra 31 Usage the constant value 0 values for results and expression evaluation arguments temporaries saved more temporaries global pointer stack pointer frame pointer return address Communicating with People Load and store bytes lb $t0,0($sp) sb $t0,0($gp) Example: String Copy Procedure Unicode: 16 bits to represent a character load halfwords lh $t0,0($sp) sh $t0,0($gp) String Copy Procedure C version void strcpy char x[], char y[] { int i; i=0; while ((x[i]=y[i])!=‘\0’ i+=1; } String Copy Procedure (MIPS) strcpy: addi sw add L1: add lb add sb beq addi j L2:lw addi jr $sp,$sp,-4 #adjust stack for 1 more item $s0,0($sp) #save $s0 $s0,$zero,$zero #i=0+0 $t1,$s0,$a1 # address of y[i] in $t1 $t2,0($t1) #$t2=y[i] $t3,$s0,$a0 #address of x[i] in $t3 $t2,0($t3) #x[i]=y[i] $t2,$zero,L2 # if y[i]==0 goto L2 $s0,$s0,1 #i=i+1 L1 # goto L1 $s0,0($sp) #y[i]==0; end of string, restore #old $s0 $sp,$sp,4 #pop 1 word off stack $ra #return MIPS Addressing for 32-bit Immediates and Addresses We'd like to be able to load a 32 bit constant into a register Must use two instructions, new "load upper immediate" instruction lui $t0, 1010101010101010 filled with zeros 1010101010101010 0000000000000000 Then must get the lower order bits right, i.e., ori $t0, $t0, 1010101010101010 1010101010101010 0000000000000000 0000000000000000 1010101010101010 1010101010101010 1010101010101010 ori Assembly Language vs. Machine Language Assembly provides convenient symbolic representation Machine language is the underlying reality much easier than writing down numbers e.g., destination first e.g., destination is no longer first Assembly can provide 'pseudoinstructions' e.g., “move $t0, $t1” exists only in Assembly would be implemented using “add $t0,$t1,$zero” When considering performance you should count real instructions Overview of MIPS Simple instructions, all 32 bits wide Very structured, no unnecessary baggage Only three instruction formats R op rs rt rd I op rs rt 16 bit address J op shamt 26 bit address Rely on compiler to achieve performance — what are the compiler's goals? Help compiler where we can funct Addressing in Branches and Jumps Instructions: bne $t4,$t5,Label beq $t4,$t5,Label j Label Next instruction is at Label if $t4!= $t5 Next instruction is at Label if $t4 = $t5 Next instruction is at Label Formats: I op J op rs rt 16 bit address 26 bit address Addresses are not 32 bits — How do we handle this with load and store instructions? Addresses in Branches Instructions: bne $t4,$t5,Label beq $t4,$t5,Label Formats: I op rs rt 16 bit address Could specify a register (like lw and sw) and add it to address Next instruction is at Label if $t4!=$t5 Next instruction is at Label if $t4=$t5 use Instruction Address Register (PC = program counter) most branches are local (principle of locality) Jump instructions just use high order bits of PC address boundaries of 256 MB MIPS Addressing Modes 1. Immediate addressing op rs rt Immediate 2. Register addressing op rs rt rd ... funct Registers Register 3. Base addressing op rs rt Memory Address + Register Byte Halfword 4. PC-relative addressing op rs rt Memory Address PC + Word 5. Pseudodirect addressing op Address PC Memory Word Word Decoding Machine Code P102 Example: 00af8020hex 0000 0000 1010 1111 1000 0000 0010 0000 000000 00101 01111 10000 00000 100000 add $s0,$a1,$t7 To summarize: MIPS operands Name 32 registers Example Comments $s0-$s7, $t0-$t9, $zero, Fast locations for data. In MIPS, data must be in registers to perform $a0-$a3, $v0-$v1, $gp, arithmetic. MIPS register $zero always equals 0. Register $at is $fp, $sp, $ra, $at reserved for the assembler to handle large constants. Memory[0], 2 30 Accessed only by data transfer instructions. MIPS uses byte addresses, so memory Memory[4], ..., words and spilled registers, such as those saved on procedure calls. add MIPS assembly language Example Meaning add $s1, $s2, $s3 $s1 = $s2 + $s3 Three operands; data in registers subtract sub $s1, $s2, $s3 $s1 = $s2 - $s3 Three operands; data in registers $s1 = $s2 + 100 $s1 = Memory[$s2 + 100] Memory[$s2 + 100] = $s1 $s1 = Memory[$s2 + 100] Memory[$s2 + 100] = $s1 Used to add constants Category Arithmetic sequential words differ by 4. Memory holds data structures, such as arrays, Memory[4294967292] Instruction addi $s1, $s2, 100 lw $s1, 100($s2) load word sw $s1, 100($s2) store word lb $s1, 100($s2) load byte sb $s1, 100($s2) store byte load upper immediate lui $s1, 100 add immediate Data transfer Conditional branch Unconditional jump $s1 = 100 * 2 16 Comments Word from memory to register Word from register to memory Byte from memory to register Byte from register to memory Loads constant in upper 16 bits branch on equal beq $s1, $s2, 25 if ($s1 == $s2) go to PC + 4 + 100 Equal test; PC-relative branch branch on not equal bne $s1, $s2, 25 if ($s1 != $s2) go to PC + 4 + 100 Not equal test; PC-relative set on less than slt $s1, $s2, $s3 if ($s2 < $s3) $s1 = 1; else $s1 = 0 Compare less than; for beq, bne set less than immediate slti jump j jr jal jump register jump and link $s1, $s2, 100 if ($s2 < 100) $s1 = 1; Compare less than constant else $s1 = 0 2500 $ra 2500 Jump to target address go to 10000 $ra For switch, procedure return go to $ra = PC + 4; go to 10000 For procedure call Alternative Architectures Design alternative: provide more powerful operations goal is to reduce number of instructions executed danger is a slower cycle time and/or a higher CPI Sometimes referred to as “RISC vs. CISC” virtually all new instruction sets since 1982 have been RISC VAX: minimize code size, make assembly language easy instructions from 1 to 54 bytes long! We’ll look at PowerPC and 80x86 PowerPC Indexed addressing example: What do we have to do in MIPS? #$t1=Memory[$a0+$s3] Update addressing update a register as part of load (for marching through arrays) example: lwu $t0,4($s3) #$t0=Memory[$s3+4];$s3=$s3+4 What do we have to do in MIPS? lw $t1,$a0+$s3 Others: load multiple/store multiple a special counter register “bc Loop” decrement counter, if not 0 goto loop The Intel IA-32 1978: The Intel 8086 is announced (16 bit architecture) 1980: The 8087 floating point coprocessor is added 1982: The 80286 increases address space to 24 bits, +instructions 1985: The 80386 extends to 32 bits, new addressing modes 1989-1995: The 80486, Pentium, Pentium Pro add a few instructions (mostly designed for higher performance) 1997: MMX is added 1999: Add 70 instructions labeled SSE (Streaming SIMD Extensions) 2001:Add 144 instructions labeled SSE2 2003: AMD 64 2004: EM64T “This history illustrates the impact of the “golden handcuffs” of compatibility “adding new features as someone might add clothing to a packed bag” “an architecture that is difficult to explain and impossible to love” A dominant architecture: 80x86 See your textbook for a more detailed description Complexity: Instructions from 1 to 17 bytes long one operand must act as both a source and destination one operand can come from memory complex addressing modes e.g., “base or scaled index with 8 or 32 bit displacement” Saving grace: the most frequently used instructions are not too difficult to build compilers avoid the portions of the architecture that are slow “what the 80x86 lacks in style is made up in quantity, making it beautiful from the right perspective” Summary Instruction complexity is only one variable Design Principles: lower instruction count vs. higher CPI / lower clock rate simplicity favors regularity smaller is faster good design demands compromise make the common case fast Instruction set architecture a very important abstraction indeed!