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ECE 15B Computer Organization Spring 2011 Dmitri Strukov Partially adapted from Computer Organization and Design, 4 th edition, Patterson and Hennessy,
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Fibonacci numbers F(n) = F(n-1)+F(n-2) F(1) = 1 F(2) = 1 n = 1 2 3 4 5 6 … F(n) = 1 1 2 3 5 8 … /* Recursive function in c */ int fib(int n) { If (n==1) return 1; If (n==2) return 1; return fib(n-1)+fib(n-2); } ECE 15B Spring 2011
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Procedures Prolog - spill all register to stack used by procedure expect for $t0-$t9 and the one used for returning values - advance stack pointer ($sp) first then write to stack Body code of the procedure Epilog - restore all used registers - adjust stack pointer at the end ($sp) ECE 15B Spring 2011
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/* Recursive function in c */ int fib(int n) { If (n==1) return 1; If (n==2) return 1; return fib(n-1)+fib(n-2); } # Recursive function in MIPS assembler #prolog FIB: addi $sp, $sp, -12 sw $a0, 0($sp) sw $s0, 4($sp) sw $ra, 8($ra) # body addi $v0, $zero, 1 addi $t0, $zero, 1 beq $a0, $t0, EPILOG#check for n==1 addi $t0, $zero, 2 beq $a0, $t0, EPILOG#check for n==2 addi $a0, $a0, -1 jal FIB#calculate fib(n-1) addi $s0, $zero, $v0# save fib(n-1) to $s0 addi $a0, $a0, -1 #calculate fib(n-2) jal FIB addi $v0, $v0, $s0 #epilog EPILOG: lw $a0, 0($sp) lw $s0, 4,($sp) lw $ra, 8,($sp) addi $sp, $sp, 12 jr $ra /* Recursive function in c */ int fib(int n) { v0 = 1; If (n==1) goto EXIT; If (n==2) goto EXIT; n = n – 1; s0 = fib(n); n = n – 1; v0 = fib(n); v0 = v0 +s0; EXIT: return v0; }
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ECE 15B Spring 2011 /* Recursive function in c */ int fib(int n) { If (n==1) return 1; If (n==2) return 1; return fib(n-1)+fib(n-2); } # Recursive function in MIPS assembler #prolog FIB: addi $sp, $sp, -12 sw $a0, 0($sp) sw $s0, 4($sp) sw $ra, 8($ra) # body addi $v0, $zero, 1 addi $t0, $zero, 1 beq $a0, $t0, EPILOG#check for n==1 addi $t0, $zero, 2 beq $a0, $t0, EPILOG#check for n==2 addi $a0, $a0, -1 jal FIB#calculate fib(n-1) addi $s0, $zero, $v0# save fib(n-1) to $s0 addi $a0, $a0, -1 #calculate fib(n-2) jal FIB addi $v0, $v0, $s0 #epilog EPILOG: lw $a0, 0($sp) lw $s0, 4,($sp) lw $ra, 8,($sp) addi $sp, $sp, 12 jr $ra /* Recursive function in c */ int fib(int n) { v0 = 1; If (n==1) goto EXIT; If (n==2) goto EXIT; n = n – 1; s0 = fib(n); n = n – 1; v0 = fib(n); v0 = v0 +s0; EXIT: return v0; }
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Now let’s see changes in the memory (stack) and register file as we execute recursive function with n = 3 First let’s review datapath and where code is stored ECE 15B Spring 2011
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Simple datapath review ECE 15B Spring 2011
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Simple datapath review ECE 15B Spring 2011 stack instructions
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Where is the code stored? ECE 15B Spring 2011 stack Code (????) static data dynamic data (heap) RF[$sp] 0 ANS: In main memory
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Instruction memory ECE 15B Spring 2011 stack code static data dynamic data (heap) IM: Physically different memory Logically mapped to main memory
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Direct mapped cache implementation of instruction memory ECE 15B Spring 2011 Main Main memory Instruction memory At any point in time IM has a copy of a portion of main memory Separate memory (tag) to store which location is currently mapped 0 16 24 Tag (28 bit) If upper portion of PC (28 bit) matches tag then IM has right values (hit), otherwise stop execution and load right portion
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Recursive function execution: step by step ECE 15B Spring 2011 0x0100addi $a0, $zero, 3 0x0104 jal FIB 0x0108 next instruction XXXXXXXXXXXXXXXXXXXXXX FIB: 0x1000addi $sp, $sp, -12 0x1004sw $a0, 0($sp) 0x1008sw $s0, 4($sp) 0x100Csw $ra, 8($ra) 0x1010addi $v0, $zero, 1 0x1014addi $t0, $zero, 1 0x1018beq $a0, $t0, EPILOG 0x101Caddi $t0, $zero, 2 0x1020beq $a0, $t0, EPILOG 0x1024addi $a0, $a0, -1 0x1028jal FIB 0x102Caddi $s0, $zero, $v0 0x1030addi $a0, $a0, -1 0x1034 jal FIB 0x1038addi $v0, $v0, $s0 EPILOG: 0x103Clw $a0, 0($sp) 0x1040lw $s0, 4,($sp) 0x1044lw $ra, 8,($sp) 0x1048addi $sp, $sp, 12 0x104Cjr $ra indexvalue $v00 $a03 $t00 $s00 $sp0xFFFF0000 $ra0x0108 indexvalue 0xFFFF00000x00000000 0xFFFF00FC 0xFFFF00F8 0xFFFF00F4 RF (right after execution of initial jal FIB at 0x0104) MM (initial values in stack)
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Recursive function execution: step by step ECE 15B Spring 2011 0x0100addi $a0, $zero, 3 0x0104 jal FIB 0x0108 next instruction XXXXXXXXXXXXXXXXXXXXXX FIB: 0x1000addi $sp, $sp, -12 0x1004sw $a0, 0($sp) 0x1008sw $s0, 4($sp) 0x100Csw $ra, 8($ra) 0x1010addi $v0, $zero, 1 0x1014addi $t0, $zero, 1 0x1018beq $a0, $t0, EPILOG 0x101Caddi $t0, $zero, 2 0x1020beq $a0, $t0, EPILOG 0x1024addi $a0, $a0, -1 0x1028jal FIB 0x102Caddi $s0, $zero, $v0 0x1030addi $a0, $a0, -1 0x1034 jal FIB 0x1038addi $v0, $v0, $s0 EPILOG: 0x103Clw $a0, 0($sp) 0x1040lw $s0, 4,($sp) 0x1044lw $ra, 8,($sp) 0x1048addi $sp, $sp, 12 0x104Cjr $ra indexvalue $v01 $a02 $t02 $s00 $sp0xFFFF00F4 $ra0x102C indexvalue 0xFFFF01000x00000000 0xFFFF00FC0x0108 0xFFFF00F80 0xFFFF00F43 RF (after execution jal FIB at 0x1028) MM - stack
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Recursive function execution: step by step ECE 15B Spring 2011 0x0100addi $a0, $zero, 3 0x0104 jal FIB 0x0108 next instruction XXXXXXXXXXXXXXXXXXXXXX FIB: 0x1000addi $sp, $sp, -12 0x1004sw $a0, 0($sp) 0x1008sw $s0, 4($sp) 0x100Csw $ra, 8($ra) 0x1010addi $v0, $zero, 1 0x1014addi $t0, $zero, 1 0x1018beq $a0, $t0, EPILOG 0x101Caddi $t0, $zero, 2 0x1020beq $a0, $t0, EPILOG 0x1024addi $a0, $a0, -1 0x1028jal FIB 0x102Caddi $s0, $zero, $v0 0x1030addi $a0, $a0, -1 0x1034 jal FIB 0x1038addi $v0, $v0, $s0 EPILOG: 0x103Clw $a0, 0($sp) 0x1040lw $s0, 4,($sp) 0x1044lw $ra, 8,($sp) 0x1048addi $sp, $sp, 12 0x104Cjr $ra indexvalue $v01 $a02 $t02 $s00 $sp0xFFFF00E8 $ra0x102C indexvalue 0xFFFF01000x00000000 0xFFFF00FC0x0108 0xFFFF00F80 0xFFFF00F43 0xFFFF00F00x102C 0xFFFF00EC0 0xFFFF00E82 RF (after execution beq at 0x1020) MM - stack
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Recursive function execution: step by step ECE 15B Spring 2011 0x0100addi $a0, $zero, 3 0x0104 jal FIB 0x0108 next instruction XXXXXXXXXXXXXXXXXXXXXX FIB: 0x1000addi $sp, $sp, -12 0x1004sw $a0, 0($sp) 0x1008sw $s0, 4($sp) 0x100Csw $ra, 8($ra) 0x1010addi $v0, $zero, 1 0x1014addi $t0, $zero, 1 0x1018beq $a0, $t0, EPILOG 0x101Caddi $t0, $zero, 2 0x1020beq $a0, $t0, EPILOG 0x1024addi $a0, $a0, -1 0x1028jal FIB 0x102Caddi $s0, $zero, $v0 0x1030addi $a0, $a0, -1 0x1034 jal FIB 0x1038addi $v0, $v0, $s0 EPILOG: 0x103Clw $a0, 0($sp) 0x1040lw $s0, 4,($sp) 0x1044lw $ra, 8,($sp) 0x1048addi $sp, $sp, 12 0x104Cjr $ra indexvalue $v01 $a02 $t02 $s00 $sp0xFFFF00F4 $ra0x102C indexvalue 0xFFFF01000x00000000 0xFFFF00FC0x0108 0xFFFF00F80 0xFFFF00F43 0xFFFF00F00x102C 0xFFFF00EC0 0xFFFF00E82 RF (after execution jr at 0x104C) MM - stack
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Recursive function execution: step by step ECE 15B Spring 2011 0x0100addi $a0, $zero, 3 0x0104 jal FIB 0x0108 next instruction XXXXXXXXXXXXXXXXXXXXXX FIB: 0x1000addi $sp, $sp, -12 0x1004sw $a0, 0($sp) 0x1008sw $s0, 4($sp) 0x100Csw $ra, 8($ra) 0x1010addi $v0, $zero, 1 0x1014addi $t0, $zero, 1 0x1018beq $a0, $t0, EPILOG 0x101Caddi $t0, $zero, 2 0x1020beq $a0, $t0, EPILOG 0x1024addi $a0, $a0, -1 0x1028jal FIB 0x102Caddi $s0, $zero, $v0 0x1030addi $a0, $a0, -1 0x1034 jal FIB 0x1038addi $v0, $v0, $s0 EPILOG: 0x103Clw $a0, 0($sp) 0x1040lw $s0, 4,($sp) 0x1044lw $ra, 8,($sp) 0x1048addi $sp, $sp, 12 0x104Cjr $ra indexvalue $v01 $a01 $t02 $s01 $sp0xFFFF00F4 $ra0x1038 indexvalue 0xFFFF01000x00000000 0xFFFF00FC0x0108 0xFFFF00F80 0xFFFF00F43 0xFFFF00F00x102C 0xFFFF00EC0 0xFFFF00E82 RF (after execution jal at 0x1034) MM - stack
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Recursive function execution: step by step ECE 15B Spring 2011 0x0100addi $a0, $zero, 3 0x0104 jal FIB 0x0108 next instruction XXXXXXXXXXXXXXXXXXXXXX FIB: 0x1000addi $sp, $sp, -12 0x1004sw $a0, 0($sp) 0x1008sw $s0, 4($sp) 0x100Csw $ra, 8($ra) 0x1010addi $v0, $zero, 1 0x1014addi $t0, $zero, 1 0x1018beq $a0, $t0, EPILOG 0x101Caddi $t0, $zero, 2 0x1020beq $a0, $t0, EPILOG 0x1024addi $a0, $a0, -1 0x1028jal FIB 0x102Caddi $s0, $zero, $v0 0x1030addi $a0, $a0, -1 0x1034 jal FIB 0x1038addi $v0, $v0, $s0 EPILOG: 0x103Clw $a0, 0($sp) 0x1040lw $s0, 4,($sp) 0x1044lw $ra, 8,($sp) 0x1048addi $sp, $sp, 12 0x104Cjr $ra indexvalue $v01 $a01 $t01 $s01 $sp0xFFFF00E8 $ra0x1038 indexvalue 0xFFFF01000x00000000 0xFFFF00FC0x0108 0xFFFF00F80 0xFFFF00F43 0xFFFF00F00x1038 0xFFFF00EC1 0xFFFF00E81 RF (after execution beq at 0x1018) MM - stack
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Recursive function execution: step by step ECE 15B Spring 2011 0x0100addi $a0, $zero, 3 0x0104 jal FIB 0x0108 next instruction XXXXXXXXXXXXXXXXXXXXXX FIB: 0x1000addi $sp, $sp, -12 0x1004sw $a0, 0($sp) 0x1008sw $s0, 4($sp) 0x100Csw $ra, 8($ra) 0x1010addi $v0, $zero, 1 0x1014addi $t0, $zero, 1 0x1018beq $a0, $t0, EPILOG 0x101Caddi $t0, $zero, 2 0x1020beq $a0, $t0, EPILOG 0x1024addi $a0, $a0, -1 0x1028jal FIB 0x102Caddi $s0, $zero, $v0 0x1030addi $a0, $a0, -1 0x1034 jal FIB 0x1038addi $v0, $v0, $s0 EPILOG: 0x103Clw $a0, 0($sp) 0x1040lw $s0, 4,($sp) 0x1044lw $ra, 8,($sp) 0x1048addi $sp, $sp, 12 0x104Cjr $ra indexvalue $v01 $a01 $t01 $s01 $sp0xFFFF00F4 $ra0x1038 indexvalue 0xFFFF01000x00000000 0xFFFF00FC0x0108 0xFFFF00F80 0xFFFF00F43 0xFFFF00F00x1038 0xFFFF00EC1 0xFFFF00E81 RF (after execution jr at 0x104C) MM - stack
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Recursive function execution: step by step ECE 15B Spring 2011 0x0100addi $a0, $zero, 3 0x0104 jal FIB 0x0108 next instruction XXXXXXXXXXXXXXXXXXXXXX FIB: 0x1000addi $sp, $sp, -12 0x1004sw $a0, 0($sp) 0x1008sw $s0, 4($sp) 0x100Csw $ra, 8($ra) 0x1010addi $v0, $zero, 1 0x1014addi $t0, $zero, 1 0x1018beq $a0, $t0, EPILOG 0x101Caddi $t0, $zero, 2 0x1020beq $a0, $t0, EPILOG 0x1024addi $a0, $a0, -1 0x1028jal FIB 0x102Caddi $s0, $zero, $v0 0x1030addi $a0, $a0, -1 0x1034 jal FIB 0x1038addi $v0, $v0, $s0 EPILOG: 0x103Clw $a0, 0($sp) 0x1040lw $s0, 4,($sp) 0x1044lw $ra, 8,($sp) 0x1048addi $sp, $sp, 12 0x104Cjr $ra indexvalue $v02 $a03 $t01 $s00 $sp0xFFFF00F4 $ra0x0108 indexvalue 0xFFFF01000x00000000 0xFFFF00FC0x0108 0xFFFF00F80 0xFFFF00F43 0xFFFF00F00x1038 0xFFFF00EC1 0xFFFF00E81 RF (after execution jr at 0x104C) MM - stack
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Recursive function execution: step by step ECE 15B Spring 2011 0x0100addi $a0, $zero, 3 0x0104 jal FIB 0x0108 next instruction XXXXXXXXXXXXXXXXXXXXXX FIB: 0x1000addi $sp, $sp, -12 0x1004sw $a0, 0($sp) 0x1008sw $s0, 4($sp) 0x100Csw $ra, 8($ra) 0x1010addi $v0, $zero, 1 0x1014addi $t0, $zero, 1 0x1018beq $a0, $t0, EPILOG 0x101Caddi $t0, $zero, 2 0x1020beq $a0, $t0, EPILOG 0x1024addi $a0, $a0, -1 0x1028jal FIB 0x102Caddi $s0, $zero, $v0 0x1030addi $a0, $a0, -1 0x1034 jal FIB 0x1038addi $v0, $v0, $s0 EPILOG: 0x103Clw $a0, 0($sp) 0x1040lw $s0, 4,($sp) 0x1044lw $ra, 8,($sp) 0x1048addi $sp, $sp, 12 0x104Cjr $ra indexvalue $v0 2 $a03 $t01 $s00 $sp0xFFFF00F4 $ra0x0108 indexvalue 0xFFFF01000x00000000 0xFFFF00FC0x0108 0xFFFF00F80 0xFFFF00F43 0xFFFF00F00x1038 0xFFFF00EC1 0xFFFF00E81 RF (at the end of program) MM - stack
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Is code optimal? * No need to spill registers when n = 1 and n = 2 * F(n-2) is calculated independently of F(n-1). Better version could be (which is linear in time with n): int fib(int a, int b, int n) { if (n==2) return a; else return fib(a+b, a, n‐1); } …. and use fib(1,1,n) * Even better to use for-loop or do-while ? ECE 15B Spring 2011
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