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Computer Arithmetic Lecture 10

Computer Engineering Department. Computer Arithmetic Lecture 10. 000000 $s2 $s3 00000 00000 27. 000000 $s2 $s3 00000 00000 26. op rs rt rd shamt funct. MIPS Divide Instruction.

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Computer Arithmetic Lecture 10

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  1. Computer Engineering Department Computer ArithmeticLecture 10 CA&O Lecture 10 By Engr. Umbreen sabir

  2. 000000 $s2 $s3 00000 00000 27 000000 $s2 $s3 00000 00000 26 op rs rt rd shamt funct MIPS Divide Instruction • div $s2, $s3 • The division quotient is placed in processor dedicated register lo and the remainder is placed in processor registerhi • div uses signed integers and result is a signed 64-bit number. Overflow and division by 0 are checked in software • MIPS uses divu for unsigned divisions CA&O Lecture 10 By Engr. Umbreen sabir

  3. Division: Paper & Pencil 1001tenQuotient 10 101 1010–1000 –1000 Divisor1000ten 1001010tenDividend 10 Remainder (or Modulo result) A number can be subtracted, creating quotient bit on each step • Binary => 1 * divisor or 0 * divisor Dividend = Quotient x Divisor + Remainder=> | Dividend | = | Quotient | + | Divisor | We assume for now unsigned 32-bit integers. 3 versions of divide, successive refinement CA&O Lecture 10 By Engr. Umbreen sabir

  4. Initially holds divisor Initially holds 0s If Reminder63 = 1, Quotient0=0 Reminder63 = 0, Quotient0=1 Initially holds dividend Division Hardware (Version 1) • 64-bit Divisor register, 64-bit ALU, 64-bit Remainder register, 32-bit Quotient register CA&O Lecture 10 By Engr. Umbreen sabir

  5. Divide Algorithm Version 1 CA&O Lecture 10 By Engr. Umbreen sabir

  6. Observations on Divide Version 1 • 1/2 bits in divisor always 0=> 1/2 of 64-bit adder is wasted => 1/2 of divisor is wasted • Instead of shifting divisor to right, shift the remainder to left? • 1st step cannot produce a 1 in quotient bit (otherwise too big for the register) => switch order to shift first and then subtract, can save 1 iteration CA&O Lecture 10 By Engr. Umbreen sabir

  7. If Reminder63 = 1, Quotient0=0 Reminder63 = 0, Quotient0=1 Division Hardware (Version 2) • 32-bit Divisor register, 32-bit ALU, 64-bit Remainder register, 32-bit Quotient register CA&O Lecture 10 By Engr. Umbreen sabir

  8. Observations on Divide Version 2 • We can eliminate Quotient register by combining with Remainder as it is shifted left • Start by shifting the Remainder left as before. • Thereafter loop contains only two steps because the shifting of the Remainder register shifts both the remainder in the left half and the quotient in the right half • The consequence of combining the two registers together and the new order of the operations in the loop is that the remainder will be shifted left one time too many. • Thus the final correction step must shift back only the remainder in the left half of the register CA&O Lecture 10 By Engr. Umbreen sabir

  9. At the end right half holds quotient At the start dividend is here Division Hardware (Version 3) • 32-bit Divisor reg, 32 -bit ALU, 64-bit Remainder reg, (0-bit Quotient reg) CA&O Lecture 10 By Engr. Umbreen sabir

  10. Divide Algorithm Version 3 Divide 0000 0111 by 0010 (2s 1110) Iteration Divisor Remainder reg oper? 0. 00100000 0111 in. val 0a 0010 00001110 shft lf 1 1a 0010 1110 1110 Rem=Rem-Div 1b 0010 0000 1110 Rem=Rem+Div 0001 1100 sll Rem, R0=0 2a 0010 1111 1100 Rem=Rem-Div 2b 0010 0001 1100 Rem=Rem+Div 0011 1000 sll Rem, R0=0 3a 0010 0001 1000 Rem=Rem-Div 3b 0010 0011 0001 sll Rem, R0=1 4a 0010 0001 0001 Rem=Rem-Div 4b 0010 0010 0011 sll Rem, R0=1 Shift left half Of Rem right 1 0001 0011 CA&O Lecture 10 By Engr. Umbreen sabir

  11. Observations on Divide Version 3 • Same Hardware as Multiply: just need ALU to add or subtract, and 64-bit register to shift left or shift right • Hi and Lo registers in MIPS combine to act as 64-bit register for multiply and divide • Signed Divides: Simplest is to remember signs, make positive, and complement quotient and remainder if necessary • Note: Dividend and Remainder must have same sign • Note: Quotient negated if Divisor sign & Dividend sign disagreee.g., –7 ÷ 2 = –3, remainder = –1 • And 7 ÷ (– 2)= – 3, remainder = 1 • Possible for quotient to be too large: if divide 64-bit integer by 1, quotient is 64 bits (“called saturation”) CA&O Lecture 10 By Engr. Umbreen sabir

  12. Review: MIPS Instructions, so far CA&O Lecture 10 By Engr. Umbreen sabir

  13. Review: MIPS ISA, continued CA&O Lecture 10 By Engr. Umbreen sabir

  14. Review: MIPS ISA- continued CA&O Lecture 10 By Engr. Umbreen sabir

  15. Floating-Point • What can be represented in N bits? • Unsigned 0 to 2N • 2s Complement - 2N-1 to 2N-1 - 1 • With MIPS singed integers the 32-bit architecture allows us to represent numbers in the range ±2.15Χ109 • But, what about very large numbers? 9,349,398,989,787,762,244,859,087,678 • What about very small numbers? 0.0000000000000000000000045691 • Floating point representation allows much larger range at the expense of accuracy CA&O Lecture 10 By Engr. Umbreen sabir

  16. Normalized notation – single number to the left of decimal point (no leading 0s) Exponent - how many digits the decimal point is moved to left to get to 1 Sign, magnitude 23 yyyyyyy -24 1.02 x 10 -1.673 x 10 ±1.xxxxx….. 2 radix (base 2) radix (base) significand Number of xs determines accuracy Sign, magnitude Number of ys determines range Scientific Notation Decimal notation Binary notation (binary floating point) CA&O Lecture 10 By Engr. Umbreen sabir

  17. 1 8 bits 23 bits S E sign M mantissa: sign + magnitude, normalized binary significand Signed exponent 1 11 bits 20 bits S E sign M Signed exponent M 32 bits MIPS Register bit allocation • Representation of floating point means that the binary point “floats” - to get a non-0 bit before it. The binary point is not fixed. • Since number of bits in register is fixed - we need tocompromise • When exponent is too large – or too small – an exception Overflow, or underflow • Representation of 2.0tenx10-38 to 2.0tenx1038. In double-precision two registers are used. This increases the range to 2.0ten x10-308 to 2.0tenx10308.Significand now has 52 bits. CA&O Lecture 10 By Engr. Umbreen sabir

  18. S E-127 N = (-1) 2 (1.M) IEEE 754 Floating Point Standard • Representation of floating point numbers in IEEE 754 standard - assures uniformity across computer implementations. • The 1 in significand is implicit - 0ten is given as a reserved representation 00…..000two • The rest of the numbers are • Placing the sign bit and exponent first makes easier integer comparisons for sorting • Using an exponent bias allows exponent to be unsigned, smallest being 00…000two largest being 11…111two. Makes comparisons easier • Double precision bias is 1023ten.Underflow and overflow can still occur CA&O Lecture 10 By Engr. Umbreen sabir

  19. S N = (-1)(1+s1•2-1+s2•2-2+ .. +s23•2-23)2(E-bias) 1 1000 0011 111000….. 0 (27+21+20-127) N = (-1) (1+2-1+2-2+2-3)2 (131-127) N = -1.875 2 IEEE 754 - continued • If the 23 significand bits are numbered from left-to-right then the floating point number represented by these bits is • So the register containing the bits represents N = -1.87524 = -1.875  16= -30 CA&O Lecture 10 By Engr. Umbreen sabir

  20. 23 bits sp 0 1000 0010 01000….. 0 20 bits dp 0 100 0000 0010 01000….. 0 32 bits 0 0000 00 00000….. 0 Exercise • Show the IEEE 754 representation of 10ten in single and double precision 10ten = 1010two = 1.01 23 in normalized notation • The sign bit is 0, the exponent is 3+127 = 130= 1000 0010two • In double precision the exponent is3+1023= 1026 = 100 0000 0010two CA&O Lecture 10 By Engr. Umbreen sabir

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