Chapter IV Computer Arithmetic (1)
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Transcript of Chapter IV Computer Arithmetic (1)
COMPUTER ARITHMETIC
Jehan-François Pâ[email protected]
Chapter Organization
• Representing negative numbers• Integer addition and subtraction• Integer multiplication and division• Floating point operations• Examples of implementation
– IBM 360, RISC, x86
A warning
• Binary addition, subtraction, multiplication and division are very easy
ADDITION AND SUBTRACTION
General concept
• Decimal addition(carry) 1_
19
+ 7
26
• Binary addition( carry) 111_
10011
+ 111
11010• 16+8+2 = 26
Realization
• Simplest solution is a battery of full adders
x3 y3 x2 y2 x1 y1 x0 y0
o s3 s2 s1 s0
Observations
• Adder add four-bit values• Output o indicates if there is an overflow
– A result that cannot be represented using 4 bits
– Happens when x + y > 15• Operation is slowed down by carry propagation
– Faster solutions (not discussed here)
Signed and unsigned additions
• Unsigned addition in 4-bit arithmetic
( carry) 11_1011
+ 0011
1110• 11 + 3 = 14(8 + 4 + 2)
• Signed addition in4-bit arithmetic
( carry) 11_1011
+ 0011
1110• -5 + 3 = -2
Signed and unsigned additions
• Same rules apply even though bit strings represent different values
• Sole difference is overflow handling
Overflow handling (I)
• No overflow in signed arithmetic
( carry) 111_1110
+ 0011
0001• -2 + 3 = 1(correct)
• Signed addition in4-bit arithmetic
( carry) 1__0110
+ 0011
1001• 6 + 3 -7(false)
Overflow handling (II)
• In signed arithmetic an overflow happens when– The sum of two positive numbers exceeds
the maximum positive value that can be represented using n bits: 2n – 1 – 1
– The sum of two negative numbers falls below the minimum negative value that can be represented using n bits: – 2n – 1
Example
• Four-bit arithmetic:– Sixteen possible values– Positive overflow happens when result > 7– Negative overflow happens when result < -8
• Eight-bit arithmetic:– 256 possible values– Positive overflow happens when result > 127– Negative overflow happens when result < -128
Overflow handling (III)
• MIPS architecture handles signed and unsigned overflows in a very different fashion:– Ignores unsigned overflows
• Implements modulo 2n arithmetic– Generates an interrupt whenever it detects a
signed overflows• Lets the OS handled the condition
Why?
• To keep the CPU as simple and regular as possible
An interesting consequence
• Most C compilers ignore overflows– C compilers must use unsigned arithmetic for
their integer operations• Fortran compilers expect overflow conditions to
be detected– Fortran compilers must use signed arithmetic
for their integer operations
Subtraction
• Can be implementing by– Specific hardware– Negating the subtrahend
Negating a number
• Toggle all bits then add one
0000 0 1111 +1 = 0000 00001 1 1110 +1 = 1111 -10010 2 1101 +1 = 1110 -20011 3 1100 +1 = 1101 -30100 4 1011 +1 = 1100 -40101 5 1010 +1 = 1011 -50110 6 1001 +1 = 1010 -6 0111 7 1000 +1 = 1001 -7
In 4-bit arithmetic (I)
1000 -8 01110111 +1 =1000+1 =1000 ??1001 -7 0110 +1 = 0111 71010 -6 0101 +1 = 0110 61011 -5 0100 +1 = 0101 51100 -4 0011 +1 = 0100 41101 -3 0010 +1 = 0011 31110 -2 0001 +1 = 0010 21111 -1 0000 +1 = 0001 1
In 4-bit arithmetic (II)
MULTIPLICATION
Decimal multiplication
(carry) 1_37
x 1274
370444
• What are the rules?– Successively multiply the
multiplicand by each digit of the multiplier starting at the right shifting the result left by an extra left position each time each time but the first
– Sum all partial results
Binary multiplication
(carry)111 _
1101x 101110100
1101001000001
• What are the rules?– Successively multiply the
multiplicand by each digit of the multiplier starting at the right shifting the result left by an extra left position each time each time but the first
– Sum all partial results• Binary multiplication is easy!
Binary multiplication table
X 0 1
0 0 0
1 0 1
Algorithm
• Clear contents of 64-bit product register• For (i = 0; i <32; i++) {
– If (LSB of multiplier_register ==1)• Add contents of multiplicand register to product
register– Shift right one position multiplier register– Shift left one position multiplicand register
• } / / for loop
Multiplier: First version
Multiplier
Product (64 bits)
Shift Left
64-bitALU
Multiplicand (64 bits)
Shift Right
Control
Multiplier: First version
Multiplier
Product (64 bits)
Shift Left
64-bitALU
Multiplicand (64 bits)
Shift Right
Control
As we learnedin grade school To get next bit
( LSB to MSB)
Explanations
• Multiplicand register must be 64-bit wide because 32-bit multiplicand will be shifted 32 times to the left– Requires a 64-bit ALU
• Product register must be 64-bit wide to accommodate the result
• Contents of multiplier register is shifted 32 times to the right so that each bit successively becomes its least significant bit (LSB)
Example (I)
• Multiply 0011 by 0011• Start
Multiplicand Multiplier Product0011 0011 0000
• First additionMultiplicand Multiplier Product0011 0011 0011
Example (II)
• Shift right and leftMultiplicand Multiplier Product0110 0001 0011
• Second additionMultiplicand Multiplier Product0110 0001 1001– 0110 + 011 = 1001
Example (III)
• Shift right and leftMultiplicand Multiplier Product1100 0000 1001
• Multiplier is all zeroes: we are done
First Optimization
• Must have a 64-bit ALU– More complex than a 32-bit ALU
• Solution is not to shift the multiplicand– After each cycle, the LSB being added
remains unchanged– Will save that bit elsewhere and shift the
product register one position to the left after each iteration
Binary multiplication
1101x 101110100
1101001000101
• Observe that the least significant bit added during each cycle remains unchanged
Algorithm• Clear contents of 64-bit product register• For (i = 0; i <32; i++) {
– If (LSB of multiplier_register ==1)• Add contents of multiplicand register to
product register– Save LSB of product register– Shift right one position both multiplier
register and product register• } / / for loop
Multiplier: Second version
Multiplier
Product (64 bits)Shift Right and Save
32-bitALU
Multiplicand
Shift Right
Control+ Test
Decimal Example (I)
• Multiply 27 by 12• Start
Multiplicand Multiplier Product Result27 12 -- --
• First digitMultiplicand Multiplier Product Result27 12 54 --
Decimal Example (II)
• Shift right multiplier and productMultiplicand Multiplier Product Result27 1 5 4
• Second digitMultiplicand Multiplier Product Result27 1 32 4
Decimal Example (III)
• Shift right multiplier and productMultiplicand Multiplier Product Result27 0 3 24
• Multiplier equals zeroResult is obtained by concatenating contents of product and result registers– 324
How did it work?
• We learned– 2712 = 2710 + 272
= 2710 + 54 = 270 + 54
• Algorithm uses another decomposition– 2712 = 2710 + 272
= 2710 + 50 + 4 = (2710 + 50) + 4 = 320 + 4
Example (I)
• Multiply 0011 by 0011• Start
Multiplicand Multiplier Product Result0011 0011 -- --
• First bitMultiplicand Multiplier Product Result0011 0011 0011 --
Example (II)
• Shift right multiplier and productMultiplicand Multiplier Product Result0011 0001 0001 1-
• Second bitMultiplicand Multiplier Product Result0011 0001 0100 1-
Product register contains 0011 + 001 = 0100
Example (III)
• Shift right multiplier and productMultiplicand Multiplier Product Result0011 0000 010 01-
• Multiplier equals zeroResult is obtained by concatenating contents of product and result registers– 1001 = 9
Second Optimization
• Both multiplier and product must be shifted to one position to the right after each iteration
• Both are now 32-bit quantities
• Can store both quantities in the product register
Multiplier: Third version
Multiplier + ProductShift Right and Save
32-bitALU
Multiplicand
Control+ Test
Third Optimization
• Multiplication requires 32 additions and 32 shift operations
• Can have two or more partial multiplications– One using bits 0-15 of multiplier– A second using bits 16-31
then add together the partial results
Multiplying negative numbers
• Can use the same algorithm as before but we must extend the sign bit of the product
Related MIPS instructions (I)
• Integer multiplication uses a separate pair of registers (hi and lo)
• mult $s0, $s1– multiply contents of register $s0 by contents
of register $s1 and store results in register pair hi-lo
• multu $s0, $s1– same but unsigned
Related MIPS instructions (II)
• mflo $s9– Move contents of register lo to register $s0
• mfhi $s9– Move contents of register hi to register $s0
DIVISION
Division
• Implemented by successive subtractions• Result must verify the equality
Dividend = Multiplier× Quotient + Remainder
Decimal division (long division• What are the rules?
– Repeatedly try to subtract smaller multiple of divisor from dividend
– Record multiple (or zero)– At each step, repeat with a lower
power of ten– Stop when remainder is smaller
than divisor
303
7 2126
-210
26 -21
5
Binary division • What are the rules?
– Repeatedly try to subtract powers of two of divisor from dividend
– Mark 1 for success, 0 for failure– At each step, shift divisor one
position to the right– Stop when remainder is smaller
than divisor
011
11 1011
-11
1011 >-11
101
>>-11
10
X
X
Same division in decimal• What are the rules?
– Repeatedly try to subtract powers of two of divisor from dividend
– Mark 1 for success, 0 for failure– At each step, shift divisor one
position to the right– Stop when remainder is smaller
than divisor
2+1=3
3 11
-12
11 >-6
5
>-3
2
X
X
Observations
• Binary division is actually simpler– We start with a left-shifted version of divisor– We try to subtract it from dividend
• No need to find out which multiple to subtract– We mark 1 for success, 0 for failure– We shift divisor one position left after every
attempt
How to start the division
• One 64-bit register for successive remainders
• One 64-bit register for divisor
– Start with quotient in upper half
• One 32-bit register for the quotient
Initialized with dividend
Quotient
All zeroes
How we proceed (I)-
• After each step we shift the quotient to the right one position at a time
Divisor
Divisor
Div isor
Divisor
How we proceed (II)
• After each step we shift the contents of the quotient register one position to the left– To make space for the new 0 or 1 being
inserted
001
0110110
Division Algorithm• For i in range(0,33) : # from 0 to 32
– Subtract contents of divisor register fromremainder register
– If remainder 0 :• Shift quotient register to the left• Set new rightmost bit to 1
Else :• Undo subtraction• Shift quotient register to the left • Set new rightmost bit to 0
– Shift right one position contents of divisor register
A simple divider
Quotient
Remainder (64 bits)
Shift Left
64-bitALU
Divisor (64 bits)
Shift Right
Control+ Test
Signed division
• Easiest solution is to remember the sign of the operands and adjust the sign of the quotient and remainder accordingly
• A little problem:5 2 = 2 and the remainder is 1-5 2 = -2 and the remainder is -1
The sign of the remainder must match the sign of the quotient
Related MIPS instructions
• Integer division uses the same pair of registers (hi and lo) as integer multiplication
• div $s0, $s1– divide contents of register $s0 by contents of
register $s, leave the quotient in register lo and the remainder in register hi
• divu $s0, $s1– same but unsigned
TRANSITION SLIDE
• Here end the materials that were on the first fall 2012 midterm
• Here start the materials that will be on the fall 2012 midterm
To be moved to the right place
FLOATING POINT OPERATIONS
Floating point numbers
• Used to represent real numbers• Very similar to scientific notation
3.5×106, 0.82×10–5, 75×106, …• Both decimal numbers in scientific notation and
floating point numbers can be normalized:3.5×106, 8.2×10–6, 7.5×107, …
Fractional binary numbers
• 0.1 is ½ or 0.5ten
• 0.01 is 0.1 is 1/4 or 0.25ten
• 0.11 is ½ + ¼ = ¾ or 0.75ten
• 1.1 is 1½ or 1.5ten
• 10.01 is 2 + ¼ or 2.5ten
• 11.11 is ______ or _____
Normalizing binary numbers
• 0.1 becomes 1.0×2-1
• 0.01 becomes 1.0×2-2
• 0.11 becomes 1.1×2-1
• 1.1 is already normalized and equal to1.0×20
• 10.01 becomes 1.001×21
• 11.11 becomes 1______×2_____
Representation
• Sign + exponent + coefficient
• IEEE Standard 754– 1 + 8 + 23 = 32 bits– 1+ 11 + 52 = 64 bits (double precision)
SExp Coefficient
The sign bit
• 0 indicates a positive number• 1 a negative number
The exponent (I)
– 8 bits for single precision– 11 bits for double precision
• With 8 bits, we can represent exponents between -126 and + 127– All-zeroes value is reserved for the zeroes and
denormalized numbers– All-ones value are reserved for the infinities and
NaNs (Not a Number)
The exponent (II)
• Exponents are represented using a biased notation– Stored value = actual exponent + bias
• For 8 bit exponents, bias is 127– Stored value of 1 corresponds to –126– Stored value of 254 corresponds to +127
0 and 255 are reserved for special values
The exponent (III)
• Biased notation simplifies comparisons:• If two normalized floating point numbers
have different exponents, the one with the bigger exponent is the bigger of the two
Special values (I)
• Signed zeroes:– IEEE 754 distinguishes between +0 and –0– Represented by
• Sign bit: 0 or 1• Biased exponent: all zeroes• Coefficient: all zeroes
Special values (II)
• Denormalized numbers:– Numbers whose coefficient cannot be
normalized• Smaller than 2–126
– Will have a coefficient with leading zeroes and exponent field equal to zero• Reduces the number of significant digits• Lowers accuracy
Special values (III)
• Infinities:– + and –– Represented by
• Sign bit: 0 or 1• Biased exponent: all ones• Coefficient: all zeroes
Special values (IV)
• NaN:– For Not a Number– Often result from illegal divisions:
0/0, ∞/∞, ∞/–∞, –∞/∞, and –∞/–∞ – Represented by
• Sign bit: 0 or 1• Biased exponent: all ones• Coefficient: non zero
The coefficient
• Also known as fraction or significand• Most significant bit is always one
– Implicit and not represented
• Biased exponent is 127ten
• True coefficient is implicit one followed by all zeroes
001…1000000000000000000000000
Decoding a floating point number
• Sign indicated by first bit• Subtract 127 from biased exponent to obtain
power of two: <be> – 127
• Use coefficient to construct a normalized binary value with a binary point:
1.<coefficient>• Number being represented is
1.<coefficient> × 2<be> – 127
First example
• Sign bit is zero:Number is positive
• Biased exponent is 127Power of two is zero
• Normalized binary value is1.0000000
• Number is 1×20 = 1
0 01…1 00000000000000000000000000000
Second example
• Sign bit is zero:Number is positive
• Biased exponent is 128Power of two is 1
• Normalized binary value is1.1000000
• Number is 1.1×21 = 11 = 3ten
0 10…0 10000000000000000000000000000
Third example
• Sign bit is 1:Number is negative
• Biased exponent is 126Power of two is –1
• Normalized binary value is1.1100000
• Number is –1.11×2–1 = –0.111 = –7/8ten
101…1011000000000000000000000000000
Can we do it now?
• Sign bit is 0:Number is ___________
• Biased exponent is 129Power of two is _______
• Normalized binary value is1.__________
• Number is _________________________
0 129ten 10100000000000000000000000000
Encoding a floating point number
• Use sign to pick sign bit• Normalize the number:
Convert it to form 1.<more bits> × 2<exp>
• Add 127 to exponent <exp> to obtainbiased exponent <be>
• Coefficient <coeff> is equal to fractional part <more bits> of number
First example• Represent 7:
– Convert to binary: 111– Normalize: 1.11×22
– Sign bit is 0– Biased exponent is 127 + 2 = 10000001two
– Coefficient is 1100…0
010…0111000000000000000000000000000
Second example• Represent 1/2
– Convert to binary: 0.1– Normalize: 1.0×2-1
– Sign bit is 0– Biased exponent is 127 – 1 = 01111110two
– Coefficient is 00…0
001…1000000000000000000000000000000
Third example• Represent –2
– Convert to binary: 10– Normalize: 1.0×21
– Sign bit is 1– Biased exponent is 127 + 1 = 10000000two
– Coefficient is 00…0
110…0000000000000000000000000000000
Fourth example• Represent 9/4
– Convert to binary: 1001×2–2
– Normalize: 1.001×21
– Sign bit is 0– Biased exponent is 127 + 1 = 10000000two
– Coefficient is 0010…0
110…0000100000000000000000000000000
Can we do it now?• Represent 6.25:
– Convert to binary: ________– Normalize: 1.______×2_______
– Sign bit is _____– Biased exponent is 127 + ___ = ______ten
– Coefficient is_________
Range
• Can represent numbers between1.00…0×2–126 and 1.11…1×2127
– Say between 2–126 and 2128
• Observing that 210 103
we divide the exponents by 10 and multiply them by 3 to obtain the interval expressed in powers of 10– Approximate range is 10–38 to 1038
Accuracy
• We have 24 significant bits– Theoretical precision of 1/224, that is, roughly
1/107
• Cannot add correctly billions or trillions• Actual situation is worse if we do too many
computations– 1,000,000 – 999,999.4875 = ???
Guard bits
• Do all arithmetic operations with two additional bits to reduce rounding errors
Double precision arithmetic (I)
• Use 64-bit double words• Allows us to have
– One bit for sign– Eleven bits for exponent
• 2,048 possible values– Fifty-two bits for coefficient
• Plus the implicit leading bit
Double precision arithmetic (II)
• Exponents are still represented using a biased notation– Stored value = actual exponent + bias
• For 11-bit exponents, bias is 1023– Stored value of 1 corresponds to –1,022– Stored value of 2,046 corresponds to +1,023– Stored values of 0 and 2,047 are reserved for
special cases
Double precision arithmetic (III)
• Can now represent numbers between1.00…0×2–1,022 and 1.11…1×21,203
– Say between 2–1,022 and 21,204
– Approximate range is 10–307 to 10307
• In reality, more like 10–308 to 10308
Double precision arithmetic (IV)
• We now have 53 significant bits– Theoretical precision of 1/253. that is, roughly
1/1016
• Can now add correctly billions or trillions
If that is now enough, …
• Can use 128-bit quad words• Allows us to have
– One bit for sign– Fifteen bits for exponent
• From –16382 to +16383 – One hundred twelve bits for coefficient
• Plus the implicit leading bit
Decimal floating point addition (I)
• 5.25×103 + 1.22×102 = ?
• Denormalize number with smaller exponent:5.25×103 + 0.122×103
• Add the numbers:5.25×103 + 0.122×103 = 5.372×103
• Result is normalized
Decimal floating point addition (II)
• 9.25×103 + 8.22×102 = ?
• Denormalize number with smaller exponent:9.25×103 + 0.822×103
• Add the numbers:9.25×103 + 0.822×103 = 10.072×103
• Normalize the result:10.072×103 = 1.0072×104
Binary floating point addition (I)
• Say 1001 + 10 or 1.001×23 + 1.0×21
• Denormalize number with smaller exponent:1.001×23 + 0.01×23
• Add the numbers:1.001×23 + 0.01×23 = 1.011×23
• Result is normalized
Binary floating point addition (II)
• Say 101 + 11 or 1.01×22 + 1.1×21
• Denormalize number with smaller exponent: 1.01×22 + 0.11×22
• Add the numbers:1.01×22 + 0.11×22 = 10.00×22
• Normalize the results10.00×22 = 1.000×23
Binary floating point subtraction
• Say 101 – 11 or 1.01×22 – 1.1×21
• Denormalize number with smaller exponent: 1.01×22 – 0.11×22
• Perform the subtraction:1.01×22 – 0.11×22 = 0.10×22
• Normalize the results0.10×22 = 1.0×21
Decimal floating point multiplication
• Exponent of product is the sum of the exponents of multiplicand and multiplier
• Coefficient of product is the product of the coefficients of multiplicand and multiplier
• Compute sign using usual rules of arithmetic• May have to renormalize the product
Decimal floating point multiplication
• 6×103 × 2.5×102 = ?
• Exponent of product is:3 + 2 = 5
• Multiply the coefficients:6 ×2.5 = 15
• Result will be positive• Normalize the result:
15×105 = 1.5×106
Binary floating point multiplication
• Exponent of product is the sum of the exponents of multiplicand and multiplier
• Coefficient of product is the product of the coefficients of multiplicand and multiplier
• Compute sign using usual rules of arithmetic• May have to renormalize the product
Binary floating point multiplication
• Say 110 ×11 or 1.1×22 × 1.1×21
• Exponent of product is:2 + 1 = 3
• Multiply the coefficients:1.1 × 1.1 = 10.01
• Result will be positive• Normalize the result:
10.01×23 = 1.001×24
FP division
• Very tricky• One good solution is to multiply the dividend by
the inverse of the divisor
A trap
• Addition does not necessarily commute:• –9×1037 + 9×1037 + 4×10-37
• Observe that• (–9×1037 + 9×1037) + 4×10-37 = 4×10-37
while• –9×1037 + (9×1037+ 4×10-37) = 0
due to the limited accuracy of FP numbers
IMPLEMENTATIONS
The floating-point unit (I)
• Floating-point instructions were an optional feature– User had to buy a separate floating-point unit
aka floating point coprocessor• Before Intel 80486, all Intel x86
architectures the option to install a separate floating-point chip(8087, 80287, 80387)
The floating-point unit (II)
• Default solution was to simulate the missing floating-point instructions through assembly routines
• As a result, many processor architectures use separate banks of registers for integer arithmetic and floating point arithmetic
The floating-point unit (III)
• Some older architectures implemented– Single-precision operations in hardware
through the FPU– Double-precision operations by software
• Made double-precession operations much costlier than single-precision operations.
IBM 360 FP INSTRUCTIONS
Overview
• FPU offers a very familiar user interface– Eight general purpose FP registers
• Distinct from the integer registers– Two-operand instructions in both RR and RX
formats• Includes single-precision and double-precision
versions or addition, subtraction, multiplication and division
Examples of RR instructions
• AFR f1, f2 add contents of floating-point register f2 into f1
• ADR f1,f2 add contents of double-precisionregister f2 into f1
• LFR f1, f2 load contents of floating-point register f2 into f1
• Also had load positive, load negative, load complement instructions for floating-point and double-precision operands
Examples of RX instructions
• AF r1, d(r2) add contents of word at address
d + contents(r2) into register r1
• AD r1,d(r2) …
MIPS FP INSTRUCTIONS
Overview
• Thirty-two specialized single-precision registers:$f0, $f1, … $f31
• Each pair of single-precision registers forms a double-precision register
• *.s instructions apply to single precision format• *.d instructions apply to double precision format• Most instructions are in the R format
R-format instructions (I)
• add.s f1, f2, f3 f1 = r2 + f3 (single precision)• add.d f2, f4, f6 (f2, f2+1) = (f4, f4+1) + (f6, f6 +1)
(double precision applies to register pairs)
• sub.s f1, f2, f3 f1 = f2 – f3 (single precision)• sub.d f2, f4, f6 (double precision)• mul.s f1, f2, f3 f1 = f2×f3 (single precision)• mul.d f2, f4, f6 (double precision)
R-format instructions (II)
• div.s f1, f2, f3 f1 = f2 /f3 (single precision)• div.d f2, f4, f6 (double precision)• c.x.s f1, f2 FP condition = f1 x f2 ? 1 ! 0
where x can be equal, not equal,less than, less than or equal, greater than, greater than or
equal• c.x.d f2, f4 (double precision)
I-format instructions (I)
• bclt a jump to address computed by adding 4×a to the current value ofthe PC if the FP condition is true
• bclf a jump to address computed by adding 4×a to the current value ofthe PC if the FP condition is false
I-format instructions (I)
• lwcl f1, a(r1) load floating-point word at addressa + contents(r1) into f1
• ldcl f2, a(r1) (double precision)• swcl f1, a(r1) store floating-point value in f1
into word at addressa + contents(r1)
• sdcl f2, a(r1) (double precision)
The "c" in the opcodes stands for coprocessor!
x86 FP INSTRUCTIONS
Overview
• Original x86 FP coprocessor had a stack architecture
• Stack registers were 80-bit wide as well as all internal registers– Better accuracy
• Provided single and double precision operations
Stack operations (I)
• Three types of operations:– Loads store an operand on the top of the stack– Arithmetic and comparison operations find
two operands of the top of the stack and replace them by the result of the operation
– Stores move the top of stack register into memory
Example
• a = b + c
– Load b on top of stack
– Load c on top of stack
– Add c to b
– Store result into a
b---b
b---b---
c
---b
b + c---
---
Stack operations (II)
• Instruction set also allowed– Operations on top of stack register and the ith
register below– Immediate operands– Operations on top of stack register and a
memory location• Poor performance of FP unit architecture
motivated an extension to the x86 instruction set
Intel SSE2 FP Architecture (I)
• SSE2 Extension (2001) provided 8 floating point registers– Could hold either single precision or double
precision values– Number extended to 16 by AMD, followed by
Intel
Intel SSE2 FP Architecture (II)
• Registers are now 128-bit wide– Can hold
• One quad precision value• Two double precision values• Four single precision values
• Can perform same operation in parallel on all single/double precision values stored in the same register
Wow!
REVIEW QUESTIONS
Review questions
• How would you represent 0.5 in double precision?
• How would you convert this double-precision value into a single precision format?
• When doing accounting, we could do all the computations in cents using integer arithmetic. What would we win? What would we lose?
Solutions
• How would you represent 0.5 in double precision?
– Normalized representation: 1.0 2-1
– Sign: 0– Biased exponent: 1023 – 1 = 1022– Coefficient: All zeroes
• Because the 1 is implicit
Solutions
• How would you convert this double-precision value into a single precision format?
– Same normalized representation: 1.0 2-1
– Same sign: 0– New biased exponent: 127 – 1 = 126– Same coefficient: All zeroes
• Because the 1 is implicit
Solutions
• When doing accounting, we could do all the computations in cents using integer arithmetic. What would we win? What would we lose?
– Big plus:• The results would be exact
– Big minus:• Could not handle numbers bigger than
$20,000,000 in 32-bit signed arithmetic
Why $20,000,000?
• 32-bit unsigned arithmetic can represent numbers from 0 to 232 – 1
• 32-bit unsigned arithmetic can represent numbers from -231 to 231 – 1– Roughly from -2000,000,000 to 2,000,000,000
• Must divide by 100 as we were using cents!
TRANSITION SLIDE
• Here end the materials that were on the first fall 2012 midterm