Blackfin Compute Unit

1
ENEL619.23 DSP Architectures

• BlackFin Compute Unit

2
Overview

• Architecture Overview
• Register Map
• ALU features and sample instructions
• Multiplier features and sample instructions
• Shifter features and sample instructions

3
References

• ADSP-BF535 Blackfin Processor Hardware Reference,
  Rev 2, April 2004, Analog Devices. Section 2
• Blackfin Processor Instruction Set Reference, Rev
  2, May 2003, Analog Devices. Sections 8 10,
  14 15
• A number of the figures in this presentation are
  based on figures found in the ADSP-BF535 Blackfin
  Processor Hardware Reference.

4
Compute Unit Architecture
2 Mulitpliers
Register File
1 set of Video ALUs
1 Shifter
2 ALUs
5
Register File

• DATA REGISTER SYNTAX
• R0, R1 etc refer to 32 bit registers
• R0.L refers to the low 16 bits of the R0 32 bit
  reg
• R0.H refers to the high 16 bits of the R0
  register
• ACCUMULATOR SYNTAX
• A0.L gt low 16 bits
• A0.H gt next 16 bits
• A0.W gt least significant 32 bit word
• A0.X gt MS 8 bit extension

6
ALU Data FLow
2 x 32 bit paths to dual Multiplier/ALU units
2 x 32 bit paths back to register file
7
ALU Features
Single 16 bit OPS
31
Rm
Rp
Rn
Dual 16 bit Cross
Single 32 bit OPS
31
Rm
Rp
Rn
8
ALU Sample Instructions
Single 16 bit ops
Dual 16 bit ops
Single 32 bit ops
Does not work
Must have this option
Operator order is important must come before -

• A B registers must stay on the same side of the
  for both
• Instructions
• For dual and quad 16 bit operations the (CO)
  option causes the
• destination registers to cross

9
Multiply Data Flow
2 x 32 bit paths to dual Multiplier/ALU units
Multiplier share the same operand/result buses as
the ALU
2 x 40 bit accumulator
2 x 32 bit paths back to register file
10
Multiply Features

• Multiplies are signed fractional by default
• Signed fractional multiply result is
  automatically left
• shifted 1 bit.
• Signed fractional multiply ! signed integer
  multiply
• Rounding available on fractional number
  multiplies and
• special option of integer number multiplies

11
Rounding
2 cases
Rounding adds 0x8000 to the 32 bit multiplier
result or accumulator value before extracting a
16 bit value to the destination register
12
Fractional Multiply
Fractional Multiply ! Integer Multiply
Fractional Multiply ! Integer Multiply

• When extracting a 16 bit fractional value from an
  accumulator
• the high 16 bits is taken
• Where in the destination register it goes depends
  on which
• accumulator is being extracted from

13
Integer Multiply
Fractional Multiply ! Integer Multiply

• When extracting a 16 bit integer value from an
  accumulator
• the low 16 bits is taken.
• Where in the destination register the 16 bit
  value goes depends
• on which accumulator is being extracted from

14
Multiply Sample Instructions
16 bit extraction from ACC 0
16 bit extraction from ACC 1
Multi-issue MAC Instruction Examples
32 bit extraction
A1 R1.H R2.L , A0 R1.L R2.L R3.H (A1
R1.H R2.L) , R3.L (A0 R1.L R2.L) Any
combination of .H and .L in the 2 operands is
allowed R3 (A1 R1.HR2.L), R2 (A0 R1.L
R2.L) Where destination registers must be
paired as follows R1,0, R3,2,
R5,4 and R7,6 R3.H (A1 R1.H R2.L), A0
R1.L R2.L
15
Shifter Sample Instructions
16
Parallel Instruction Examples

• In general there are 16 and 32 bit versions of
  the arithmetic instructions
• Most of the 32 bit instructions can be executed
  in parallel with 2 x 16 bit memory/index
  operations
• Exceptions are DIVS, DIVQ and MULTIPLY with 32
  bit operands
• means parallel
• Examples
• A1R2.LR1.L,A0R2.HR1.HR2.HWI2
  I3R3\
• R2R2R4, R4R2--R4 I0M0R1I0