MITEL PDSP1601-MC

PDSP1601 MC
PDSP1601 MC
ALU and Barrel Shifter
Supersedes April 1993 version, DS3763 - 1.1
DS3763 - 2.1 November 1998
The PDSP1601 is a high performance 16-bit arithmetic
logic unit with an independent on-chip 16-bit barrel shifter.
The PDSP1601 supports Multicycle multiprecision
operation. This allows a single device to operate at 10MHz for
16-bit-bit-fields, 5MHz for 32-bit fields and 2.5MHz for 64-bit
fields. The PDSP1601 can also be cascaded to produce wider
words at the 10MHz rate using the Carry Out and Carry In pins.
The Barrel Shifter is capable of extension, for example the
PDSP1601 can used to select a 16-bit field from a 32-bit input
in 100ns.
GC100
Fig.1 Pin connections
GC pin
Function
GC pin
Function
GC pin
Function
GC pin
Function
80
81
82
83
84
85
86
87
88
89
90
91
92
93
94
95
96
97
98
99
100
VCC
RS2
C0
C1
C2
C3
C4
C5
C6
C7
GND
C8
C9
C10
C11
C12
C13
C14
C15
OE
BFP
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
VCC
CO
RA0
RA1
RA2
CI
IA0
IA1
IA2
IA3
IA4
MSB
MSS
B15
B14
B13
B12
B11
B10
B9
B8
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
B7
B6
B5
B4
B3
B2
B1
B0
CEB
CLK
GND
MSA0
MSA1
A15
A14
A13
A12
A11
A10
A9
A8
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
A7
A6
A5
A4
A3
A2
A1
A0
CEA
MSC
IS0
IS1
IS2
IS3
SV0
SV1
SV2
SV3
SVOE
RS0
RS1
FEATURES
■
■
■
■
■
■
■
■
16-bit, 32 instruction 10MHz ALU
16-bit, 10MHz Logical, Arithmetic or Barrel Shifter
Independent ALU and Shifter Operation
4 x 16-bit On Chip Scratchpad Registers
Multiprecision Operation; e.g. 200ns 64-bit
Accumulate
Three Port Structure with Three Internal Feedback
Paths Elimates I/O Bottlenecks
300mW Maximum Power Dissipation
100-pin Ceramic Quad Flatpack
APPLICATIONS
■
■
■
■
■
Digital Signal Processing
Array Processing
Graphics
Database Addressing
High Speed Arithmetic Processors
Rev
Date
A
B
C
D
MAR 1993 NOV 1998
NOTE
Polyimide is used as an inter-layer dielectric and glassivation.
ORDERING INFORMATION
PDSP1601/MC/GC1R
(Ceramic QFP Package MIL STD 883 Class B
Screening)
1
PDSP1601 MC
PIN DESCRIPTIONS
Symbol
Pin No.
(GG100
Package)
MSB
16
ALU B-input multiplexer select control.1 This input is latched internally on the rising edge
of CLK.
MSS
17
Shifter Input multiplexer select control.1 This input is latched internally on the rising edge
of CLK.
B15 - B0
18 - 25
30 - 37
B Port data Input. Data presented to this port is latched into the input register on the rising
edge of CLK. B15 is the MSB.
CEB
38
Clock enable, B Port input register. When low the clock to this register is enabled.
CLK
39
Common clock to all internal registered elements.
change on the rising edge of CLK.
Description
All registers are loaded, and outputs
MSA0 - MSA1 41 - 42
ALU A-input multiplexer select control.1 This input are latched internally on the rising edge
of CLK.
A15 - A0
43 - 50
55 - 62
A Port data Input. Data presented to this port is latched into the input register on the rising
edge of CLK. B15 is the MSB.
CEA
63
Clock enable, A Port input register. When low the clock to this register is enabled.
MSC
64
C-Port multiplexer select control.1 This input is latched internally on the rising edge
of CLK.
IS0 - IS3
65 - 68
Instruction inputs to Barrel Shifter, IS3 = MSB.1 This input is latched internally on the
rising edge of CLK.
SV0 - SV3
69 - 72
Shift Value I/O Port. This port is used as an input when shift values are supplied form
external sources, and as an output when Normalise operations are invoked. The I/O functions
are determined by the IS0 - IS3 instruction inputs, and by the SVOE control.
The shift value is latched internally on the rising edge of CLK.
SVOE
73
SV Output enable. When high the SV port can only operate as an input. When low the SV
port can act as an input or as an output, according to the IS0 - IS3 instruction. This pin should
be tied high or low, depending upon the application.
RS0, RS1
RS2
74 - 75
81
Instruction inputs to Barrel Shifter registers.1 These input are latched internally on the
rising edge of CLK.
C0 - C15
82 - 98
C Port data output. Data output on this port is selected by the C output multiplexer.
C15 is the MSB
OE
99
Output enable. The C Port outputs are in high impedance condition when this control is high
BFP
100
Block Floating Point Flag from ALU, active high.
CO
6
Carry out from MSB of ALU
RA0 - RA2
7-9
Instruction inputs to ALU registsers.1 These inputs are latched interally on the rising
edge of CLK.
CI
10
Carry in to LSB of ALU
IA0 - IA3
IA4
11 - 14
Instruction inputs to ALU.1 IA4 = MSB. These inputs are latched internally on the rising
edge of CLK.
Vcc
80, 5
+5V supply: Both Vcc pins must be connected.
GND
90 & 40
0V supply: Both GND pins must be connected.
NOTES
1.
2
All instructions are executed in the cycle commencing with the rising edge of the CLK which latches the inputs.
PDSP1601 MC
A INPUT
B INPUT
16
16
CEA
A REG
A MUX
BFP
MSA0-1
2
B REG
A
B
CO
MSB
B MUX
IA0-4
ALU
S MUX
CEB
MSS
5
BARREL SHIFTER
CI
SHIFT
CONTROL
IS0-3
SV0-3
SVOE
RAD-2
ALU REG FILE
LEFT REG.
RS0-2
3
3
RIGHT REG.
C MUX
SHIFTER REG FILE
LEFT REG.
RIGHT REG.
MSC
OE
16
COUT
Fig.2 PDSP1601 block diagram
FUNCTIONAL DESCRIPTION
The PDSP1601 contains four main blocks: the ALU, the
Barrel Shifter and the two Register Files.
The ALU
The ALU supports 32 instructions as detailed in Table 1.
The inputs to the ALU are selected by the A and B MUXs.
Data will fall through from the selected register through the A
or B input MUXs and the ALU to the ALU output register file in
100ns.
The ALU instructions are latched, such that the instruction
will not start executing until the rising edge of CLK latches the
instruction into the device.
The ALU accepts a carry in from the CI input and supplies
a carry out to the CO output. Additionally, at the end of each
cycle, the carry out from the ALU is loaded into an internal 1
bit register, so that it is available as an input to the ALU on the
next cycle. In the manner, Multicycle, multiprecisiion
operations are supported. (See MULTICYCLE CASCADE
OPERATIONS).
BFP Flag
The ALU has a user programmable BFP flag. This flag
may be programmed to become active at any one of four
conditions. Two of these conditions are intended to support
Block Floating Point operations, in that they provide flags
indicating that the ALU result is within a factor of two or four of
overflowing the 16 bit number range. For multiprecision
operations the flag is only valid whilst the most significant 16
bit byte is being processed. In this manner the BFP flag may
be used over any extended word width.
The remaining two conditions detect either an overflow
condition or a zero result. For the overflow condition to be
active the ALU result must have overflowed into the 16th (sign)
bit, (this flag is only valid whilst the most significant 16 bit byte
is being processed). The zero condition is active if the result
from the ALU is equal to zero. For multiprecision operations
the zero flag must be active for all of the 16 bit bytes of an
extended word.
The BFP flag is programmed by executing on of the four
SBFXX instructions (see Table 1). During the execution of any
of these four instructions, the output of the ALU is forced to
zero.
Multicycle/Cascade Operation
The ALU arithmetic instructions contain two or three
options for each arithemtic operation.
The ALU is designed to operate with two's complement
arithmetic, requiring a one to be added to the LSB for all
subtract operations. The instructions set includes instructions
that will force a one into the LSB, e.g. MIAX1, AMBX1, BMAX1
(see Table 1).
These instructions are used for the least significant 16 bits
of any subtract operation.
The user has an option of cascading multiple devices, or
multicycling a single device to extend the arithmetic precision.
Should the user cascade multiple devices, then the cascaded
arithmetic instructions using the external CI input should be
employed for all but the least significant 16 bits, e.g. MIACI,
APBCI, BMACI (see Table 1).
Should the user multicycle a single device, then the
Multicycle Arithmetic instructions, using the internally
registered CO bit should be employed for all but the least
significant 16 bits, e.g. MIACO, APBCO, AMBCO, BMACO
(see Table 1).
3
PDSP1601 MC
Table 1 ALU instructions
1a. ARITHMETIC INSTRUCTIONS
Inst
00
01
02
03
04
05
06
07
08
09
0A
0B
0C
0D
0E
0F
IA4-IA0 Mnemonic
00000
00001
00010
00011
00100
00101
00110
00111
01000
01001
01010
01011
01100
01101
01110
01111
Function
Operation
CLRXX
MIAX1
MIACI
MIACO
A2SGN
A2RAL
A2RAR
A2RSX
APBCI
APBCO
AMBX1
AMBCI
AMBCO
BMAX1
BMACI
BMACO
RESET
MINUS A
MINUS A
MINUS A
A/2
A/2
A/2
A/2
A PLUS B
A PLUS B
A MINUS B
A MINUS B
A MINUS B
B MINUS A
B MINUS A
B MINUS A
CLEAR ALL REGISTERS
NA Plus 1
NA Plus CI
NA Plus CO
A/2 Sign Extend
A/2 with Ral LSB
A/2 with RAR LSB
A/2 with RSX LSB
A Plus B Plus CI
A Plus B Plus CO
A Plus NB Plus 1
A Plus NB Plus CI
A Plus NB Plus CO
NA Plus B Plus 1
NA Plus B Plus CI
NA Plus B Plus CO
Mode
--------LSBYTE
CASCADE
MULTICYCLE
MSBYTE
MULTICYCLE
MULTICYCLE
MULTICYCLE
CASCADE
MULTICYCLE
LSBYTE
CASCADE
MULTICYCLE
LSBYTE
CASCADE
MULTICYCLE
1b. LOGICAL INSTRUCTIONS
Inst
10
11
12
13
14
15
16
17
IA4-AI0 Mnemonic
ANXAB
ANANB
ANNAB
ORXAB
ORNAB
XORAB
PASXA
PASNA
10000
10001
10010
10011
10100
10101
10110
10111
Operation
Function
A. B
A. NB
NA. B
A+B
NA + B
A XOR B
A
NA
A AND B
A AND NB
NA AND B
A OR B
NA OR B
A XOR B
PASS A
INVERT A
1c. CONTROL INSTRUCTIONS
Inst
18
19
1A
1B
1C
1D
1E
1F
KEY
A
B
CI
CO
RAL
RAR
RSX
4
IA4-AI0 Mnemonic
11000
11001
11010
11011
11100
11101
11110
11111
SBFOV
SBFU1
SBFU2
SBFZE
OPONE
OPBYT
OPNIB
OPALT
Operation
Set BFP Flag to OVR, Force ALU output to zero
Set BFP Flag to UND 1 Force ALU output to zero
Set BFP Flag to UND 2 Force ALU output to zero
Set BFP Flag to ZERO Force ALU output to zero
Output 0001 Hex
Output 00FF Hex
Output 000F Hex
Output 5555 Hex
MNEMONICS
= A input to ALU
= B input to ALU
= External Carry in to ALU
= Internally Registered Carry out from ALU
= ALU Register (Left)
= ALU Register (Right)
= Shifter Register (Left or Right)
CLRXX
MIAXX
A2XXX
APBXX
AMBXX
BMAXX
ANX-Y
ORX-Y
XORXY
PASXX
SBFXX
OPXXX
Clear All Registers to zero
Minus A,
XX = Carry in to LSB
A Divided by 2, XXX = Source of MSB
A Plus B,
XX = Carry in to LSB
A Minus B,
XX = Carry in to LSB
B Minus A,
XX = Carry in to LSB
AND
X
= Operand 1, Y = Operand 2
OR
X
= Operand 1, Y = Operand 2
Exclusive OR
X
= Operand 1, Y = Operand 2
Pass
XX = Operand
Set BFP Flag
XX = Function
Output Constant XXX
PDSP1601 MC
Divide by Two
The Barrel Shifter
The ALU has four (A2SGN, A2RAL, A2RAR, A2RSX)
instructions used for right shifting (dividing by two) extended
precision words. These words, (up to 64 bits) may be stored
in the two on-chip register files. When the least significant 16
bit word is shifted, the vacant MSB must be filled with the LSB
from the next most significant 16 bit byte. This is achieved via
the A2RAL, A2RAR or A2RSX instructions which indicate the
source of the new MSB (see SLU INSTRUCTION SET).
When the most significant 16 bit byte is right shifted, the
MSB must be filled with a duplicate of the original MSB so as
to maintain the correct sign (Sign Extension). This operation
is achieved via the A2SGN instruction (see Table 1).
The Barrel Shifter supports 16 instructions as detailed in
Table 2. The input to the Barrel Shifter is selected by the S
MUX. Data will fall through from the selected register, through
the S MUX and the Barrel Shifter to the shifter output register
file in 100ns.
The Barrel Shifter instructions are latched, such that the
instructions will not start executing until the rising edge of CLK
latches the instruction into the device.
The Barrel Shifter is capable of Logical Arithmetic or Barrel
Shifts in either direction.
Constants
B.
The ALU has four instructions (OPONE, OPBYT, OPNIB,
OPALT) that force a constant value onto the ALU output.
These values are primarily intended to be used as masks, or
the seeds for mask generation, for example, the OPONE
instruction will set a single bit in the least significant position.
This bit may be rotated any where in the 16 bit field by the
Barrel Shifter, allowing the AND function of the ALU to perform
bit-pick operations on input data.
C.
CLR
The ALU instruction CLRXX is used as a Master Reset for
the entire device. This instruction has the effect of:
1.
2.
3.
4.
5.
Clearing ALU and Barrel Shifter register files to zero.
Clearing A and B port input registers to zero.
Clearing the R1 and R2 shift control registers to zero.
Clearing the internally registered CO bit to zero.
Programming the BFP flag to detect overflow conditions.
Inst
0
1
2
3
4
5
6
7
8
9
A
B
C
D
E
F
KEY
SV
R1
R2
PE
I
O
X
IS3-IS0 Mnemonic
0000
0001
0010
0011
0100
0101
0110
0111
1000
1001
1010
1011
1100
1101
1110
1111
LSRSV
LSLSV
BSRSV
BSLSV
LSRR1
LSRR2
LSLR1
LSLR2
LR1SV
LR2SV
ASRSV
ASRR1
ASRR1
NRMXX
NRMR1
NRMR2
A.
Logical shifts discard bits that exit the 16 bit field and fill
spaces with zeros.
Arithmetic shifts discard bits that exit the 16 bit field and
fill spaces with duplicates of the original MSB.
Barrel Shifts rotate the 16 bit fields such that bits tha exit
the 16 bit field to the left or right reappear in the vacant
spaces on the right or left.
The amount of shift applied is encoded onto the 4 bit Barrel
Shifter input as illustrated in Table 3. The type of shift and the
amount are determined by the shift control block. The shift
control block (see Fig.3) accepts and decodes the four bit ISO3 instruction. The shift control block contains a priority
encoder and two, user programmable 4 bit registers R1 and
R2.
There are four possible sources of shift value that can be
passed onto the Barrel Shifter, there are:
1.
2.
3.
4.
The Priority Encoder
The SV input
The R1 register
The R2 register
Operation
I/O
Logical Shift Right by SV
Logical Shift Left by SV
Barrel Shift Right by SV
Barrel Shift Left by SV
Logical Shift Right by R1
Logical Shift Left by R1
Logical Shift Right by R2
Logical Shift Left by R2
Load Register 1 From SV
Load Register 2 From SV
Arithmetic Shift Right by SV
Arithmetic Shift Right by R1
Arithmetic Shift Right by R2
Normalise Output PE
Normalise Output PE, Load R1
Normalise Output PE, Load R2
I
I
I
I
X
X
X
X
I
I
I
X
X
O
O
O
Table 2 Barrel shifter instructions
MNEMONICS
= Shift Value
= Register 1
= Register 2
= Priority Encoder Output
=> SV Port operates as an Input
=> SV Port operates as an Output
=> SV Port in a High Impedance State
LSXYY
BSXYY
ASXYY
LXXYY
NRMYY
Logical Shift,
X
= Direction YY = Source of Shift Value
Barrel Shift,
X
= Direction YY = Source of Shift Value
Arithmetic Shift, X
= Direction YY = Source of Shift Value
Load
XX = Target YY = Source
Normalise by PE, Output PE value on SV Port, Load YY Reg
5
PDSP1601 MC
SV3
SV2
SV1
SV0
Shift
0
0
0
0
0
0
0
0
1
1
1
1
1
1
1
1
0
0
0
0
1
1
1
1
0
0
0
0
1
1
1
1
0
0
1
1
0
0
1
1
0
0
1
1
0
0
1
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
0
1
No shift
1 place
2 places
3 places
4 places
5 places
6 places
7 places
8 places
9 places
10 places
11 places
12 places
13 places
14 places
15 places
(1)
Priority encode the 16 bit input to the Barrel Shifter and
place the 4 bit value in either of the R1 or R2 registers and
output the value on the SV port (if enabled by SVOE).
(2)
Shift the 16 bit input by the amount indicated by the
Priority Encoder such that the output from the Barrel Shifter is
a normalised value.
SV Input
If the SV port is selected as the source of the shift value,
then the input to the Barrel Shifter is shifted by the value stored
in the internal SV register.
SVOE
The SV port acts as an input or an output depending upon
the IS0-3 instruction. If the user does not wish to use the
normalise instructions, then the SV port mat be forced to be
input only by typing SVOE control high. In this mode the SV
port may be considered an extension of the instruction inputs.
Table 3 Barrel shifter codes
Priority Encoder
R1 and R2 Registers
If the priority encoder is selected as the source of the shift
value (instructions:- NRMXX, NRMR1, MRMRZ), then within
one 200ns cycle or two 100ns cycles, the shift circuitry will:
The R1 and R2 registers may be loaded from the Priority
Encoder (NRMR1 and NRMR2) or from the SV input (LR1SV,
LR2SV).
Whilst the latter two instructions are executing, the Barrel
Shifter will pass its input to the output unshifted.
16
INSTRUCTION
DECODE
4
IS0-3
PRIORITY ENCODER
4
4
MUX
SV
MUX
MUX
SVOE
R1
R2
Fig.3 Shift control block
6
PDSP1601 MC
The Register Files
There are two on-chip register files (ALU and Shifter), each
containing two 16 bit registers and each supporting 8
instructions (see Table 4). The instructions fo the ALU register
file and the Barrel Shifter Register file are the same.
The Inputs to the register files come from either the ALU or
the Barrel Shifter, and are loaded into the Register files on the
rising edge of CLK.
The register file instructions are latched such that the
instruction will not start executing until the rising edge of the
CLK latches the instruction into the device.
The register file instructions (see Table 4) allow input data
to be loaded into either, neither or both of the registers. Data
is loaded at the end of the cycle in which the instruction is
executing.
The register file instructions allow the output to be sourced
from either of the two registers, the selected output will be valid
during the cycle in which the instruction is executing.
ALU REGISTER INSTRUCTIONS
Inst
RA2-RA0
Mnemonic
0
1
2
3
4
5
6
7
000
001
010
011
100
101
110
111
LLRRR
LRRLR
LLRLR
LRRRR
LBRLR
NOPRR
NOPLR
NOPPS
Operation
Load Left Reg Output Right Reg
Load Right Reg Output Left Reg
Load Left Register, Output Left Reg
Load Right Register, Output Right Reg
Load Both Register, Output Left Reg
No load Operation, Output Right Reg
No load Operation, Output Left Reg
No load Operation, Pass ALU Result
SHIFTER REGISTER INSTRUCTIONS
Inst
RA2-RA0
Mnemonic
0
1
2
3
4
5
6
7
000
001
010
011
100
101
110
111
LLRRR
LRRLR
LLRLR
LRRRR
LBRLR
NOPRR
NOPLR
NOPPS
Operation
Load Left Reg Output Right Reg
Load Right Reg Output Left Reg
Load Left Register, Output Left Reg
Load Right Register, Output Right Reg
Load Both Register, Output Left Reg
No load Operation, Output Right Reg
No load Operation, Output Left Reg
No load Operation, Pass Barrel Shifter Result
Table 4 ALU and shift register instructions mnemonics
MNEMONICS
LXXYY Load XX = Target,
YY = Source of Output
LBOXX Load Both Registers, XX = Source of Output
NOPXX No Load Operation, XX = Source of Output
7
PDSP1601 MC
Multiplexers
There are four user selectable on-chip multiplexers (AMUX, B-MUX, S-MUX and C-MUX).
These four multiplexers support instructions as tabulated
in Table 5.
A-MUX
B-MUX
S-MUX
C-MUX
MARAX
MAAPR
MABPR
MARSX
The MUX instructions are latched such that the instruction
will not start executing until the rising edge of CLK latches the
instruction onto the device.
MSA1
MSA2
Output
0
0
1
1
0
1
0
1
ALU REGISTER FILE OUPUT
A-PORT INPUT
B-PORT INPUT
SHIFTER REGISTER FILE OUTPUT
MSB
Output
0
1
B-PORT INPUT
SHIFTER REGISTER FILE OUTPUT
MSS
Output
0
1
B-PORT INPUT
SHIFTER REGISTER FILE OUTPUT
MSC
Output
0
1
ALU REGISTER FILE OUTPUT
SHIFTER REGISTER FILE OUTPUT
Table 5
8
PDSP1601 MC
INSTRUCTION SET
ALU Arithmetic Instructions
Mnemonic
Op Code
Function
CLRXX
<00>
On the rising edge of CLK at the end of the cycle in which this instruction is executing, the
A Port, B Port, ALU, Barrel Shifter, and Shift Control Registers will be loaded with zeros.
The internal registered CO will also be set to zero, and the BFP flag will be set to activate
on overflow conditions.
MIAX1
<01>
The A input to the ALU is inverted and a one is added to the LSB.
MIACI
<02>
The A input to the ALU is inverted and the CI input is added to the LSB.
MIACO
<03>
The A input to the ALU is inverted and the CO output from the ALU on the previous cycle
is added to the LSB.
A2SGN
<04>
The A input to the ALU is right shifted one bit position. The LSB is discarded, and the vacant
MSB is filled by duplicating the original MSB (Sign Extension).
A2RAL
<05>
The A input to the ALU is right shifted one bit position. The LSB is discarded, and the vacant
MSB is filled with the LSB from the ALU left register.
A2RAR
<06>
The A input to the ALU is right shifted one bit position. The LSB is discarded, and the vacant
MSB is filled with the LSB from the ALU right register.
A2RSX
<07>
The A input to the ALU is right shifted one bit position. The LSB is discarded, and the vacant
MSB is filled with the LSB from the B input to the ALU.
APBCI
<08>
The A input to the ALU is added to the B input, and the CI input is added to the LSB.
APBCO
<09>
The A input to the ALU is added to the B input, and the CO out from the ALU on the previous
cycle is added to the LSB.
AMBX1
<0A>
The A input to the ALU is added to the inverted B input, and a one is added to the LSB.
AMBCI
<0B>
The A input to the ALU is added to the inverted B input, and the CI input is added to the
LSB.
AMBCO
<0C>
The A input to the ALU is added to the inverted B input, and the CO out from the ALU on
the previous cycle is added to the LSB.
BMAX1
<0D>
The inverted A input to the ALU is added to the B input, and a one is added to the LSB.
BMACI
<0E>
The inverted A input to the ALU is added to the B input, and the CI input is added to the
LSB.
BMACO
<0F>
The inverted A input to the ALU is added to the B input, and the CO out from the ALU on
the previous cycle is added to the LSB.
ALU Logical Instructions
Mnemonic
Op Code
ANXAB
<10>
The A input to the ALU is logically 'ANDed' with the B input.
ANANB
<11>
The A input to the ALU is logically 'ANDed' with the inverse of the B input.
ANNAB
<12>
The inverse of the A input to the ALU is logically 'ANDed' with the B input.
ORXAB
<13>
The A input to the ALU is logically 'ORed' with the B input.
ORNAB
<14>
The inverse A input to the ALU is logically 'ORed' with the B input.
XORAB
<15>
The A input to the ALU is logically Exclusive-ORed with the B input.
PASXA
<16>
The A input to the ALU is passed to the output.
PASNA
<17>
The inverse of the A input to the ALU is passed to the output.
Function
9
PDSP1601 MC
ALU Control Instructions
Mnemonic
Op Code
Function
SBFOV
<18>
The BFP flag is programmed to activate when an ALU operation causes an overflow of the
16 bit number range. This flag is logically the exclusive-or of the carry into and out of the
MSB of the ALU. For the most significant Byte this flag indicates that the result of an
arithmetic two's complement operation has overflowed into the sign bit. The output of the
ALU is forced to zero for the duration of this instruction.
SBFU1
<19>
The BFP flag is programmed to activate when an ALU operation comes within a factor of
two of causing an overflow of the 16 bit number range. For the most significant Byte this
flag indicates that the result of an arithmetic two's complement operation is within a factor
of two of overflowing into the sign bit. The output of the ALU is forced to zero for the duration
of this instruction.
SBFU2
<1A>
The BFP flag is programmed to activate when an ALU operation comes within a factor of
four of causing an overflow of the 16 bit number range. For the most significant Byte this
flag indicates that the result of an arithmetic two's complement operation is within a factor
of four of overflowing into the sign bit. The output of the ALU is forced to zero for the duration
of this instruction.
SBFZE
<1B>
The BFP flag is programmed to activate when an ALU operation causes a result of zero.
The output of the ALU is forced to zero for the duration of this instruction. During the
execution of this instruction the BFP flag will become active.
OPONE
<1C>
The ALU will output the binary value 0000000000000001, the MSB on the left.
OPBYT
<1D>
The ALU will output the binary value 0000000011111111, the MSB on the left.
OPNIB
<1E>
The ALU will output the binary value 0000000000001111, the MSB on the left.
OPALT
<1F>
The ALU will output the binary value 0101010101010101, the MSB on the left.
Barrel Shifter Instructions
Mnemonic
Op Code
Function
LSRSV
<0>
The 16 bit input to the Barrel Shifter is right shifted by the number of places indicated by
the magnitude of the four bit number present in the SV register. The LSBs are discarded,
and the vacant MSBs are filled with zeros.
LSLSV
<1>
The 16 bit input to the Barrel Shifter is left shifted by the number of places indicated by the
magnitude of the four bit number present in the SV register. The MSBs are discarded, and
the vacant LSBs are filled with zeros.
BSRSV
<2>
The 16 bit input to the Barrel Shifter is rotated to the right shifted by the number of places
indicated by the magnitude of the four bit number present in the SV register. The LSBs that
exit the 16 bit field to the right, reappear in the vacant MSBs on the left.
BSLSV
<3>
The 16 bit input to the Barrel Shifter is rotated to the left shifted by the number of places
indicated by the magnitude of the four bit number present in the SV register. The MSBs
that exit the 16 bit field to the left, reappear in the vacant LSBs on the right.
LSRR1
<4>
The 16 bit input to the Barrel Shifter is right shifted by the number of places indicated by
the magnitude of the four bit number present in the R1 register. The LSBs are discarded,
and the vacant MSBs are filled with zeros.
LSLR1
<5>
The 16 bit input to the Barrel Shifter is left shifted by the number of places indicated by the
magnitude of the four bit number present in the R1 register. The MSBs are discarded, and
the vacant LSBs are filled with zeros.
LSRR2
<6>
The 16 bit input to the Barrel Shifter is right shifted by the number of places indicated by
the magnitude of the four bit number present in the R2 register. The LSBs are discarded,
and the vacant MSBs are filled with zeros.
LSLR2
<7>
The 16 bit input to the Barrel Shifter is left shifted by the number of places indicated by the
magnitude of the four bit number present in the R2 register. The MSBs are discarded, and
the vacant LSBs are filled with zeros.
10
PDSP1601 MC
Mnemonic
Op Code
Function
LR1SV
<8>
On the rising edge of CLK at the end of the cycle in which this instruction is executing, the
R1 register will be loaded with the data present on the SV port. The input to the Barrel
Shifter will be passed onto the output unshifted.
LR2SV
<9>
On the rising edge of CLK at the end of the cycle in which this instruction is executing, the
R2 register will be loaded with the data present on the SV port. The input to the Barrel
Shifter will be passed onto the output unshifted.
ASRSV
<A>
The 16 bit input to the Barrel Shifter is right shifted by the number of places indicated by
the magnitude of the four bit number present in the SV register. The LSBs are discarded,
and the vacant MSBs are filled with duplicates of the original MSB. (Sign Extension).
ASRR1
<B>
The 16 bit input to the Barrel Shifter is right shifted by the number of places indicated by
the magnitude of the four bit number resident within the R1 register. The LSBs are
discarded, and the vacant MSBs are filled with duplicates of the original MSB.
(Sign Extension).
ASRR2
<C>
The 16 bit input to the Barrel Shifter is right shifted by the number of places indicated by
the magnitude of the four bit number resident within the R2 register. The LSBs are
discarded, and the vacant MSBs are filled with duplicates of the original MSB.
(Sign Extension).
NRMXX
<D>
The 16 bit input to the Barrel Shifter is left shifted by the number of places indicated by the
magnitude of the four bit number output from the Priority Encoder. This value is also output
on the SV port (provided SVOE is low).
The effect of this operation is to left shift the input by the necessary amount
(max 15 places) to result in the MSB and the next most significant bit being different. This
has the effect of eliminating unnecessary Sign Bits, and hence Normalising the input data.
The MSBs shifted out to the left are discarded, and the vacant LSBs on the right are filled
with zeros.
NRMR1
<E>
The 16 bit input to the Barrel Shifter is left shifted by the number of places indicated by the
magnitude of the four bit number output from the Priority Encoder. This value is also loaded
into the R1 register at the end of the cycle, and is output on the SV port (provided SVOE
is low).
The effect of this operation is to left shift the input by the necessary amount
(max 15 places) to result in the MSB and the next most significant bit being different. This
has the effect of eliminating unnecessary Sign Bits, and hence Normalising the input data.
The MSBs shifted out to the left are discarded, and the vacant LSBs on the right are filled
with zeros.
NRMR2
<F>
The 16 bit input to the Barrel Shifter is left shifted by the number of places indicated by the
magnitude of the four bit number output from the Priority Encoder. This value is also loaded
into the R2 register at the end of the cycle, and is output on the SV port (provided SVOE
is low).
The effect of this operation is to left shift the input by the necessary amount
(max 15 places) to result in the MSB and the next most significant bit being different. This
has the effect of eliminating unnecessary Sign Bits, and hence Normalising the input data.
The MSBs shifted out to the left are discarded, and the vacant LSBs on the right are filled
with zeros.
11
PDSP1601 MC
Barrel Shifterl or ALU Register Instructions
Mnemonic
Op Code
Function
LLRRR
<0>
After the rising edge of CLK at the beginning of the cycle in which this instruction is
executed, the contents of the Right register will appear on the output. On the rising edge
of CLK at the end of the cycle, the data on the register inputs will be loaded into the Left
Register.
LRRLR
<1>
After the rising edge of CLK at the beginning of the cycle in which this instruction is
executed, the contents of the Left register will appear on the output. On the rising edge
of CLK at the end of the cycle, the data on the register inputs will be loaded into the Right
Register.
LLRLR
<2>
After the rising edge of CLK at the beginning of the cycle in which this instruction is
executed, the contents of the Left register will appear on the output. On the rising edge
of CLK at the end of the cycle, the data on the register inputs will be loaded into the Left
Register.
LRRRR
<3>
After the rising edge of CLK at the beginning of the cycle in which this instruction is
executed, the contents of the Right register will appear on the output. On the rising edge
of CLK at the end of the cycle, the data on the register inputs will be loaded into the Right
Register.
LBRLR
<4>
After the rising edge of CLK at the beginning of the cycle in which this instruction is
executed, the contents of the Left register will appear on the output. On the rising edge
of CLK at the end of the cycle, the data on the register inputs will be loaded into both Left
and Right Registers.
NOPRR
<5>
After the rising edge of CLK at the beginning of the cycle in which this instruction is
executed, the contents of the Right register will appear on the output. On the rising edge
of CLK at the end of the cycle no load operation will occur, the register contents will remain
unchanged.
NOPLR
<6>
After the rising edge of CLK at the beginning of the cycle in which this instruction is
executed, the contents of the Left register will appear on the output. On the rising edge
of CLK at the end of the cycle no load operation will occur, the register contents will remain
unchanged.
NOPPS
<7>
After the rising edge of CLK at the beginning of the cycle in which this instruction is
executed, the input to the register will appear on the output. On the rising edge
of CLK at the end of the cycle no load operation will occur, the register contents will remain
unchanged.
12
PDSP1601 MC
TYPICAL APPLICATION
(2)
The LS byte is logically right shifted, n-places, the
LSBs being discarded and the MSBs being filled with zeros.
This shifted data is loaded into the shifter register file left
register.
Select a 16 bit field from each word in a block of 32 bit
words with a 10MHz throughput.
The 16 bit field indicated is to be selected from each 32 bit
word.
MS Byte
8
MS Bit
During this cycle the previous contents of this register are
passed through the ALU to the ALU register file left register.
LS Byte
8
8
8
16 bits
(3)
While the MS byte of the next 32 bit word is shifted in
the Barrel Shifter, the two previous results, resident within the
left registers of the ALU and Shifter Register files are 'ORed'
by the ALU, the result being the desired 16 bit field is loaded
into the ALU register file right register ready to be output on the
next cycle.
nbits
The 32 bit words are fed into the B port of the PDSP1601
in two cycles, MS byte first.
The PDSP1601 shift control is initiated by programming
the R1 and R2 registers with n and 16-n respectively.
The shift operation is implemented in three steps:-
The instructions from initialisation are given in Table 6.
(1)
The MS byte is logically left shifted (16-n) places, the
MSBs being discarded and the LSB spaces being filled with
zeros. This shifted data is loaded into the shifter register file
left register.
CLK
CEB
MSA
MSB
MSS
MSC
IA
IS
SV
RA
RS
1/
2/
3/
4/
5/
6/
1
1
0
0
0
0
MARSX
MARSX
MARSX
MARSX
MARSX
MARAX
1
1
1
1
1
1
0
0
0
0
0
0
0
0
0
0
0
0
CLRXX
PASXA
PASXA
PASXA
PASXA
ORXAB
X
LR1SV
LR2SV
LSLR2
LSRR1
LSLR2
X
n
(16-n)
X
X
X
NOPLR
NOPLR
NOPLR
NOPLR
LLRRR
LRRLR
NOPLR
NOPLR
NOPLR
LLRLR
LLRLR
LLRLR
7/
0
MARSX
1
0
0
PASXA
LSRR1
X
LLRRR
LLRLR
8/
0
MARAX
1
0
0
ORXAB
LSLR2
X
LRRLR
LLRLR
Comment
Clear
Load R1 with n
Load R2 with (16-n)
Shift 1st MS byte
Shift 1st LS byte
OR 1st bytes and
shift 2nd MS byte
Shift 2nd LS byte
and output first result
Shift 3rd LS byte
Repeat instruction pair 5/ and 6/ until all 16 bit fields have been selected.
Table 6
ABSOLUTE MAXIMUM RATINGS (Note 1)
Supply voltage Vcc
-0.5V to 7.0V
-0.9V to Vcc + 0.9V
Input voltage VIN
Output voltage VOUT
-0.9V to Vcc + 0.9V
Clamp diode current per pin IK (see note 2)
±18mA
Static discharge voltage (HMB)
500V
Storage temperature TS
-65°C to +150°C
Ambient temperature with
power applied Tamb
Military
-40°C to +125°C
Package power dissipation PTOT
GC
1000mW
NOTES
1. Exceeding these ratings may cause permanent damage.
Functional operation under these conditions is not implied.
2. Maximum dissipation or 1 second should not be exceeded, only
one output to be tested at any one time.
THERMAL CHARACTERISTICS
Package type
ΘJC °C/W
GC
12
13
PDSP1601 MC
ELECTRICAL CHARACTERISTICS
Operating Conditions (unless otherwise stated)
TAMB (Military) = -55°C to +125°C, VCC = 5.0V±10%, Ground = 0V
Static Characteristics
Symbol
Characteristic
Min.
*
*
*
*
Output high voltage
Output low voltage
Input high voltage
Input low voltage
*
*
*
†
†
Input leakage current
Vcc current
Output leakage current
Output S/C current
Input capacitance
VOH
VOL
VIH
VIL
VIH
VIL
IIL
ICC
IOZ
ISC
CIN
Value
Typ.
Units
Sub
group
Conditions
V
V
V
V
V
V
µA
mA
µA
mA
pF
1, 2, 3
1, 2, 3
1, 2, 3
1, 2, 3
1, 2, 3
1, 2, 3
1, 2, 3
1, 2, 3
1, 2, 3
IOH = 8mA
IOL = -8mA
Max.
2.4
0.4
2.5
0.8
Vdd -1
0.5
+10
60
+50
80
-10
-50
12
5
CLOCK, OE
CLOCK, OE
GND < VIN < VCC
Tamb = -40°C to +85°C
GND < VOUT < VCC
VCC = Max
Switching Characteristics
Value
Characteristics
†
†
†
†
†
†
†
†
†
†
†
†
†
†
†
†
†
†
†
*
†
†
CLK rising edge to C-PORT
CLK rising edge to CO
CLK rising edge to BFP
Setup CEA or CEB to CLK rising edge
Hold CEA or CEB to CLK rising edge
Setup A or B port inputs to CLK rising edge
Hold A or B port inputs to CLK rising edge
Setup MSA0-1, MSB, MSS, MSC, RA2-0, RS0-2, IA0-4,
IS0-3, to CLK rising edge
Hold RS0-2, IA0-4 to CLK rising edge
Hold IS0-3 to CLK rising edge
Hold MSA0-1, MSB, MSS, MSC, RA0-2 to CLK rising edge
Setup SV to CLK rising edge
Hold SV to CLK rising edge
CLK rising edge to SV
OE
C-PORT
Z
OE
C-PORT
Z
OE
C-PORT Z
OE
C-PORT Z
Clock period (ALU & Barrel Shifter, serial mode)
Clock period (ALU & Barrel Shifter, parallel mode)
Clock high time
Clock low time
PDSP1601
Min.
Max.
5
5
5
30
40
100
100
0
40
0
40
0
3
0
40
5
200
100
40
40
All parameter marked * are tested during production.
Parameters marked † are guaranteed by design and characterisation
14
3
100
40
40
40
40
Units
Sub
group
2 x LSTTL + 20pF
1 x LSTTL + 5pF
1 x LSTTL + 5pF
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
sn
Conditions
Input mode
Input mode
20pF load, SV O P mode
2 x LSTTL + 20pF
2 x LSTTL + 20pF
2 x LSTTL + 20pF
2 x LSTTL + 20pF
9, 10, 11
PDSP1601 MC
Part No:
PDSP1601 MC ALU and Barrel Shifter
Package Type:
GC100
Pin No.
Volt.
Pin No.
Volt.
Pin No.
Volt.
Pin No.
Volt.
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
N/C
N/C
N/C
N/C
V1
N/C
0V
0V
0V
V1
V1
V1
V1
V1
V1
0V
0V
0V
0V
0V
0V
0V
0V
0V
0V
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
N/C
N/C
N/C
N/C
V1
V1
V1
V1
V1
V1
V1
V1
V1
V1
0V
0V
V1
V1
V1
V1
V1
V1
V1
V1
V1
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
N/C
N/C
N/C
N/C
0V
0V
0V
0V
0V
0V
0V
0V
V1
V1
V1
V1
0V
0V
V1 180K
V1 180K
0V 180K
0V 180K
V1
V1
0V
76
77
78
79
80
81
82
83
84
85
86
87
88
89
90
91
92
93
94
95
96
97
98
99
100
N/C
N/C
N/C
N/C
N/C
0V
N/C
N/C
N/C
N/C
N/C
N/C
N/C
N/C
0V
N/C
N/C
N/C
N/C
N/C
N/C
N/C
N/C
V1
N/C
VDD max = +5.0V = V1
N/C = not connected
Fig.4 Life Test/Burn-in connections
NOTE: PDA is 5% and based on groups 1 and 7
15
http://www.mitelsemi.com
World Headquarters - Canada
Tel: +1 (613) 592 2122
Fax: +1 (613) 592 6909
North America
Tel: +1 (770) 486 0194
Fax: +1 (770) 631 8213
Asia/Pacific
Tel: +65 333 6193
Fax: +65 333 6192
Europe, Middle East,
and Africa (EMEA)
Tel: +44 (0) 1793 518528
Fax: +44 (0) 1793 518581
Information relating to products and services furnished herein by Mitel Corporation or its subsidiaries (collectively “Mitel”) is believed to be reliable. However, Mitel assumes no
liability for errors that may appear in this publication, or for liability otherwise arising from the application or use of any such information, product or service or for any infringement of
patents or other intellectual property rights owned by third parties which may result from such application or use. Neither the supply of such information or purchase of product or
service conveys any license, either express or implied, under patents or other intellectual property rights owned by Mitel or licensed from third parties by Mitel, whatsoever.
Purchasers of products are also hereby notified that the use of product in certain ways or in combination with Mitel, or non-Mitel furnished goods or services may infringe patents or
other intellectual property rights owned by Mitel.
This publication is issued to provide information only and (unless agreed by Mitel in writing) may not be used, applied or reproduced for any purpose nor form part of any order or
contract nor to be regarded as a representation relating to the products or services concerned. The products, their specifications, services and other information appearing in this
publication are subject to change by Mitel without notice. No warranty or guarantee express or implied is made regarding the capability, performance or suitability of any product or
service. Information concerning possible methods of use is provided as a guide only and does not constitute any guarantee that such methods of use will be satisfactory in a specific
piece of equipment. It is the user’s responsibility to fully determine the performance and suitability of any equipment using such information and to ensure that any publication or
data used is up to date and has not been superseded. Manufacturing does not necessarily include testing of all functions or parameters. These products are not suitable for use in
any medical products whose failure to perform may result in significant injury or death to the user. All products and materials are sold and services provided subject to Mitel’s
conditions of sale which are available on request.
M Mitel (design) and ST-BUS are registered trademarks of MITEL Corporation
Mitel Semiconductor is an ISO 9001 Registered Company
Copyright 1999 MITEL Corporation
All Rights Reserved
Printed in CANADA
TECHNICAL DOCUMENTATION - NOT FOR RESALE