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Yacht v1.1
(Yet Another Cycle Hunting Table)
-------------------------------------------------------------------------------
Forewords :
-------------------------------------------------------------------------------
This document is based on :
- 9th Edition of M68000 8-16-32-bit Microporcessor User's Manual
(Motorola, 1993) (laterly refered as M68000UM)
- Programmer's Reference Manual Rev 1
(Motorola, 1992) (laterly refered as M68000PRM)
- US Patent n°4,325,121 - Two level control store for microprogrammed data
processor
(Motorola, Apr, 13, 1982) (lately refered as USP4325121)
- Error reports / question asked by users (see below)
-------------------------------------------------------------------------------
Changes log :
-------------------------------------------------------------------------------
v1 : intitial release
v1.1 (this version) :
- Lines #0042-#0056 : rewrote parts of the vocabulary section
- Lines #0057-#0071 : added a general note section about this document
- Lines #0166-#0173 : added a note on Program Counter addressing modes
- THX Atarizoll & npomarede - http://atari-forum.com/viewtopic.php?t=26820
- Line #0347 : added missing BTST Dn,#data timing
- THX flamewing - http://gendev.spritesmind.net/forum/viewtopic.php?t=2917
- Line #0625 : fixed a typo on (xxx).L timing for CLR, NEGX, NEG, NOT
- THX byuu - http://gendev.spritesmind.net/forum/viewtopic.php?t=3040
- Line #1273 : fixed a copy / paste error on MULU / MULS #data,DN
- THX TomH - http://www.atari-forum.com/viewtopic.php?t=36648
- Lines #0821-#0839, #0936, #0957 : coherency with exception section
- THX TomH & ijor - http://www.atari-forum.com/viewtopic.php?t=36648
- Lines #1538-#1574 : fixed accurate exception timing
- THX ijor - http://www.atari-forum.com/viewtopic.php?t=36648
-------------------------------------------------------------------------------
Vocabulary :
-------------------------------------------------------------------------------
Clock Cycle : time between two adjacent pulses of the oscillator that sets the
tempo of the processor.
Microcycle : (in this document) indivisible CPU cycle of execution : takes 2
clock cycles.
Bus Cycle : exept from the Read-Modify-Write Cycle that is only used by the TAS
instruction, a bus cycle consists of eight states (if no wait cycle needed).
Each state longs half a clock cycle so a full bus cycle is 4 clock cycles long
in the best case.
-------------------------------------------------------------------------------
General note :
-------------------------------------------------------------------------------
This document is primary designed for programmers that need to know exactly how
many clock cycles are used by their code, when things are read or written in
memory and in which order.
Consequently, the purpose of this document is to correct and explain the
instruction execution times as written in M68000UM.
So, as in section 8 of M68000UM, this document "lists instruction execution
times in terms of external clock (CLK) periods. In this data, it is assumed
that both memory read and write cycles consist of four clock periods. A longer
memory cycle causes the generation of wait states that must be added to the
total instruction times."
-------------------------------------------------------------------------------
Rules of thumb :
-------------------------------------------------------------------------------
1) 68000 external data bus is 16 bit so any operation on a long word in memory
will take at least 2 full bus cycles.
2) 68000 internal data bus is 32 bit so reading/writing word or long word from
/ to a register take the same time.
3) There are 3 math units. One 16 bit ALU and two 16 bit Address Units. The ALU
was complex enough for the math instruction set while the AUs were only able to
do address related math (add, subtract).
So, The ALU is used in the execution of instructions whereas the AUs are used
to calculate the effective address(es). And, of course, the 2 16 bit AUs worked
together to make the 32 bit effective address calculations.
Therefore, to do a simple 16 bit math instruction, the ALU can do the operation
while the AUs perform address calculations during the same micro-cycle.
3a) 68000 ALU is 16 bits so any arithmetic or logic operation between 2 values
take more cycles with long words values than with words values even if source
and destination are registers.
3b) For arithmetic operations on an address register such as ADDA and SUBA, the
whole 32 bits destination address register is used regardless of the operation
size (.W or .L). As this arithmetic operation is done by the ALU and no the AUs
and in regard of the previous rule (3a), the ALU will take longer to perform
word sized operations on address registers than on data registers.
4a) in general case, the source operand is evaluated first then the destination
operand is evaluated and, at last, the instruction is executed. These 3 steps
can't be mixed. "addi.w #<data>,-(An)" is a good exemple for this rule.
4b) there are some optimized instructions for which the previous rule doesn't
apply, destination operand evaluation starts before the end of source operand
evaluation. "abcd.b -(Ay),-(Ax)" is a good exemple for this rule.
5) As SP=A7 it seems obvious than (d16,An) and (d16,SP) always have the same
timings. Same thing for (d8,An,Xn) and (d8,SP,Xn).
-------------------------------------------------------------------------------
How to read the table :
-------------------------------------------------------------------------------
Exec Time :
-----------
This table use the same rules than the M68000UM for the exec times. So, data is
shown as :
n(r/w)
where:
n is the total number of clock periods
r is the number of read cycles
w is the number of write cycles.
In addition, each exec time is spltted in two parts (when possible) :
"instruction exec time" and "effective address exec time". The two exec times
must be added in order to get the "real" exec time.
Data Bus Usage :
----------------
Each following caracter describe the state of the data bus during a microcycle.
n : nop : data bus is not used
n- : nop with idle wait, no transfers occur during this microcycle (can last 2
microcycles instead of one ?).
p : Program fetch; read from next consecutive location in program memory
W : Write MSW onto data bus when using long word
w : Write one word onto data bus (LSW if long word operation)
R : Read MSW from data bus when using long word
r : Read one word from data bus (LSW if long word operation)
S : Push (write) MSW onto stack when using long word
s : Push (write) one word onto stack (LSW if long word operation)
U : Pop (read) MSW from stack when using long word
u : Pop (read) one word from stack (LSW if long word operation)
V : Fetch vector MSW (for exceptions)
v : Fetch vector LSW (for exceptions)
i : Vector number acquisition in an IACK Cycle (for Interrupt exception)
F : Fetch SSP MSW (for /RESET exception)
f : Fetch SSP LSW (for /RESET exception)
DON'T TAKE CARE OF SPACES OR PIPES.
Exemples :
----------
Note : in the following exemples 'n' caracter will be replace by '.' when the
data bus is not used
1) MOVE.W -(An),Dn (line #347) :
Takes 10 clock cycles (data bus read 2 times, written 0 times)
Data bus usage : ..r.p
2) EORI.L #<data>,-(An) (line #179) :
Takes 30 clock cycles (data bus read 5 times, written 2 times)
Data bus usage : .p.p..R.r.p.w.W
Note on Program Counter addressing modes :
------------------------------------------
(d16,PC) and (d16,An) always behave the same. It's also true for (d8,PC,Xn)
and (d8,An,Xn). So if you want to know the exact timing of an instruction with
PC related effective address, once you ensured that addressing mode is correct
for this instruction, please refer to the according An line.
*******************************************************************************
OPERAND EFFECTIVE ADDRESS CALCULATION TIMES
*******************************************************************************
-------------------------------------------------------------------------------
<ea> | Exec Time | Data Bus Usage
------------------+-----------------+------------------------------------------
.B or .W : | |
Dn | 0(0/0) |
An | 0(0/0) |
(An) | 4(1/0) | nr
(An)+ | 4(1/0) | nr
-(An) | 6(1/0) | n nr
(d16,An) | 8(2/0) | np nr
(d8,An,Xn) | 10(2/0) | n np nr
(xxx).W | 8(2/0) | np nr
(xxx).L | 12(3/0) | np np nr
#<data> | 4(1/0) | np
.L : | |
Dn | 0(0/0) |
An | 0(0/0) |
(An) | 8(2/0) | nR nr
(An)+ | 8(2/0) | nR nr
-(An) | 10(2/0) | n nR nr
(d16,An) | 12(3/0) | np nR nr
(d8,An,Xn) | 14(3/0) | n np nR nr
(xxx).W | 12(3/0) | np nR nr
(xxx).L | 16(4/0) | np np nR nr
#<data> | 8(2/0) | np np
*******************************************************************************
Line 0000 :
ADDI, ANDI, ANDI to CCR, BCHG, BCLR, BSET, BTST, CMPI, EORI, EORI to CCR,
MOVEP, ORI, ORI to CCR, SUBI
*******************************************************************************
-------------------------------------------------------------------------------
EORI, ORI, ANDI, | Exec Time | Data Bus Usage
SUBI, ADDI | INSTR EA | 1st Operand | 2nd OP (ea) | INSTR
------------------+-----------------+-------------+---------------+------------
#<data>,<ea> : | | | |
.B or .W : | | | |
Dn | 8(2/0) 0(0/0) | np | | np
(An) | 12(2/1) 4(1/0) | np | nr | np nw
(An)+ | 12(2/1) 4(1/0) | np | nr | np nw
-(An) | 12(2/1) 6(1/0) | np | n nr | np nw
(d16,An) | 12(2/1) 8(2/0) | np | np nr | np nw
(d8,An,Xn) | 12(2/1) 10(2/0) | np | n np nr | np nw
(xxx).W | 12(2/1) 8(2/0) | np | np nr | np nw
(xxx).L | 12(2/1) 12(3/0) | np | np np nr | np nw
.L : | | |
Dn | 16(3/0) 0(0/0) | np np | | np nn
(An) | 20(3/2) 8(2/0) | np np | nR nr | np nw nW
(An)+ | 20(3/2) 8(2/0) | np np | nR nr | np nw nW
-(An) | 20(3/2) 10(2/0) | np np | n nR nr | np nw nW
(d16,An) | 20(3/2) 12(3/0) | np np | np nR nr | np nw nW
(d8,An,Xn) | 20(3/2) 14(3/0) | np np | n np nR nr | np nw nW
(xxx).W | 20(3/2) 12(3/0) | np np | np nR nr | np nw nW
(xxx).L | 20(3/2) 16(4/0) | np np | np np nR nr | np nw nW
NOTES :
.M68000UM is probably wrong with instruction timming for ANDI.L #<data>,Dn
instruction. It reads "14(3/0)" but, according to USP4325121, this
instruction is based on the same microwords than EORI.L #<data>,Dn and
ORI.L #<data>,Dn that have a "16(3/0)" timming. In addition, evaluation on
real hardware confirms the 16 cycles timing.
-------------------------------------------------------------------------------
ORI, ANDI, EORI | Exec Time | Data Bus Usage
to CCR, to SR | INSTR | 1st Operand | INSTR
------------------+-----------------+-------------+----------------------------
#<data>,CCR | | |
.B : | 20(3/0) | np | nn nn np np
-------------------------------------------------------------------------------
| Exec Time | Data Bus Usage
CMPI | INSTR EA | 1st Operand | 2nd OP (ea) | INSTR
------------------+-----------------+-------------+-------------+--------------
#<data>,<ea> : | | | |
.B or .W : | | | |
Dn | 8(2/0) 0(0/0) | np | | np
(An) | 8(2/0) 4(1/0) | np | nr | np
(An)+ | 8(2/0) 4(1/0) | np | nr | np
-(An) | 8(2/0) 6(1/0) | np | n nr | np
(d16,An) | 8(2/0) 8(2/0) | np | np nr | np
(d8,An,Xn) | 8(2/0) 10(2/0) | np | n np nr | np
(xxx).W | 8(2/0) 8(2/0) | np | np nr | np
(xxx).L | 8(2/0) 12(3/0) | np | np np nr | np
.L : | | | |
Dn | 14(3/0) 0(0/0) | np np | | np n
(An) | 12(3/0) 8(2/0) | np np | nR nr | np
(An)+ | 12(3/0) 8(2/0) | np np | nR nr | np
-(An) | 12(3/0) 10(2/0) | np np | n nR nr | np
(d16,An) | 12(3/0) 12(3/0) | np np | np nR nr | np
(d8,An,Xn) | 12(3/0) 14(3/0) | np np | n np nR nr | np
(xxx).W | 12(3/0) 12(3/0) | np np | np nR nr | np
(xxx).L | 12(3/0) 16(4/0) | np np | np np nR nr | np
-------------------------------------------------------------------------------
| Exec Time | Data Bus Usage
BCHG, BSET | INSTR EA | 1st Operand | 2nd OP (ea) | INSTR
------------------+-----------------+-------------+---------------+------------
Dn,<ea> : | | | |
.B : | | | |
(An) | 8(1/1) 4(1/0) | | nr | np nw
(An)+ | 8(1/1) 4(1/0) | | nr | np nw
-(An) | 8(1/1) 6(1/0) | | n nr | np nw
(d16,An) | 8(1/1) 8(2/0) | | np nr | np nw
(d8,An,Xn) | 8(1/1) 10(2/0) | | n np nr | np nw
(xxx).W | 8(1/1) 8(2/0) | | np nr | np nw
(xxx).L | 8(1/1) 12(3/0) | | np np nr | np nw
Dn,Dm : | | | |
.L : | | | |
if Dn<16 | 6(1/0) 0(0/0) | | | np n
if Dn>15 | 8(1/0) 0(0/0) | | | np nn
#<data>,<ea> : | | | |
.B : | | | |
(An) | 12(2/1) 4(1/0) | np | nr | np nw
(An)+ | 12(2/1) 4(1/0) | np | nr | np nw
-(An) | 12(2/1) 6(1/0) | np | n nr | np nw
(d16,An) | 12(2/1) 8(2/0) | np | np nr | np nw
(d8,An,Xn) | 12(2/1) 10(2/0) | np | n np nr | np nw
(xxx).W | 12(2/1) 8(2/0) | np | np nr | np nw
(xxx).L | 12(2/1) 12(3/0) | np | np np nr | np nw
#<data>,Dn : | | | |
.L : | | | |
if data<16 | 10(2/0) 0(0/0) | np | | np n
if data>15 | 12(2/0) 0(0/0) | np | | np nn
-------------------------------------------------------------------------------
| Exec Time | Data Bus Usage
BCLR | INSTR EA | 1st Operand | 2nd OP (ea) | INSTR
------------------+-----------------+-------------+---------------+------------
Dn,<ea> : | | | |
.B : | | | |
(An) | 8(1/1) 4(1/0) | | nr | np nw
(An)+ | 8(1/1) 4(1/0) | | nr | np nw
-(An) | 8(1/1) 6(1/0) | | n nr | np nw
(d16,An) | 8(1/1) 8(2/0) | | np nr | np nw
(d8,An,Xn) | 8(1/1) 10(2/0) | | n np nr | np nw
(xxx).W | 8(1/1) 8(2/0) | | np nr | np nw
(xxx).L | 8(1/1) 12(3/0) | | np np nr | np nw
Dn,Dm : | | | |
.L : | | | |
if Dn<16 | 8(1/0) 0(0/0) | | | np nn
if Dn>15 | 10(1/0) 0(0/0) | | | np nn n
#<data>,<ea> : | | | |
.B : | | | |
(An) | 12(2/1) 4(1/0) | np | nr | np nw
(An)+ | 12(2/1) 4(1/0) | np | nr | np nw
-(An) | 12(2/1) 6(1/0) | np | n nr | np nw
(d16,An) | 12(2/1) 8(2/0) | np | np nr | np nw
(d8,An,Xn) | 12(2/1) 10(2/0) | np | n np nr | np nw
(xxx).W | 12(2/1) 8(2/0) | np | np nr | np nw
(xxx).L | 12(2/1) 12(3/0) | np | np np nr | np nw
#<data>,Dn : | | | |
.L : | | | |
if data<16 | 12(2/0) 0(0/0) | np | | np nn
if data>15 | 14(2/0) 0(0/0) | np | | np nn n
-------------------------------------------------------------------------------
| Exec Time | Data Bus Usage
BTST | INSTR EA | 1st Operand | 2nd OP (ea) | INSTR
------------------+-----------------+-------------+---------------+------------
Dn,<ea> : | | | |
.B : | | | |
(An) | 4(1/0) 4(1/0) | | nr | np
(An)+ | 4(1/0) 4(1/0) | | nr | np
-(An) | 4(1/0) 6(1/0) | | n nr | np
(d16,An) | 4(1/0) 8(2/0) | | np nr | np
(d8,An,Xn) | 4(1/0) 10(2/0) | | n np nr | np
(xxx).W | 4(1/0) 8(2/0) | | np nr | np
(xxx).L | 4(1/0) 12(3/0) | | np np nr | np
#<data> | 6(1/0) 4(1/0) | | np | np n
Dn,Dm : | | | |
.L : | 6(1/0) 0(0/0) | | | np n
#<data>,<ea> : | | | |
.B : | | | |
(An) | 8(2/0) 4(1/0) | np | nr | np
(An)+ | 8(2/0) 4(1/0) | np | nr | np
-(An) | 8(2/0) 6(1/0) | np | n nr | np
(d16,An) | 8(2/0) 8(2/0) | np | np nr | np
(d8,An,Xn) | 8(2/0) 10(2/0) | np | n np nr | np
(xxx).W | 8(2/0) 8(2/0) | np | np nr | np
(xxx).L | 8(2/0) 12(3/0) | np | np np nr | np
#<data>,Dn : | | | |
.L : | 10(2/0) 0(0/0) | np | | np n
-------------------------------------------------------------------------------
| Exec Time | Data Bus Usage
MOVEP | INSTR | INSTR
------------------+-----------------+------------------------------------------
Dx,(d16,Ay) : | |
.W : | 16(2/2) | np nW nw np
.L : | 24(2/4) | np nW nW nw nw np
(d16,Ay),Dx : | |
.W : | 16(4/0) | np nR nr np
.L : | 24(6/0) | np nR nR nr nr np
NOTES :
.Read and write operations are done from the MSB to the LSB on 2 words if
using ".w" (first read/write word at Ay+d16 then word at Ay+d16+2)and on
4 words if using ".l" (first read/write word at Ay+d16 then word at Ay+d16+2
then word at Ay+d16+4 and finally word at Ay+d16+6).
*******************************************************************************
Line 0001 & Line 0010 & Line 0011
MOVE.B MOVE.L, MOVEA.L MOVE.W, MOVEA.W
*******************************************************************************
-------------------------------------------------------------------------------
| Exec Time | Data Bus Usage
MOVE | INSTR | 1st OP (ea) | INSTR
------------------+-----------------+---------------+--------------------------
<ea>,Dn : | | |
.B or .W : | | |
Dn | 4(1/0) | | np
An | 4(1/0) | | np
(An) | 8(2/0) | nr | np
(An)+ | 8(2/0) | nr | np
-(An) | 10(2/0) | n nr | np
(d16,An) | 12(3/0) | np nr | np
(d8,An,Xn) | 14(3/0) | n np nr | np
(xxx).W | 12(3/0) | np nr | np
(xxx).L | 16(4/0) | np np nr | np
#<data> | 8(2/0) | np | np
.L : | | |
Dn | 4(1/0) | | np
An | 4(1/0) | | np
(An) | 12(3/0) | nR nr | np
(An)+ | 12(3/0) | nR nr | np
-(An) | 14(3/0) | n nR nr | np
(d16,An) | 16(4/0) | np nR nr | np
(d8,An,Xn) | 18(4/0) | n np nR nr | np
(xxx).W | 16(4/0) | np nR nr | np
(xxx).L | 20(5/0) | np np nR nr | np
#<data> | 12(3/0) | np np | np
<ea>,(An) : | | |
.B or .W : | | |
Dn | 8(1/1) | | nw np
An | 8(1/1) | | nw np
(An) | 12(2/1) | nr | nw np
(An)+ | 12(2/1) | nr | nw np
-(An) | 14(2/1) | n nr | nw np
(d16,An) | 16(3/1) | np nr | nw np
(d8,An,Xn) | 18(3/1) | n np nr | nw np
(xxx).W | 16(3/1) | np nr | nw np
(xxx).L | 20(4/1) | np np nr | nw np
#<data> | 12(2/1) | np | nw np
.L : | | |
Dn | 12(1/2) | | nW nw np
An | 12(1/2) | | nW nw np
(An) | 20(3/2) | nR nr | nW nw np
(An)+ | 20(3/2) | nR nr | nW nw np
-(An) | 22(3/2) | n nR nr | nW nw np
(d16,An) | 24(4/2) | np nR nr | nW nw np
(d8,An,Xn) | 26(4/2) | n np nR nr | nW nw np
(xxx).W | 24(4/2) | np nR nr | nW nw np
(xxx).L | 28(5/2) | np np nR nr | nW nw np
#<data> | 20(3/2) | np np | nW nw np
<ea>,(An)+ : | | |
.B or .W : | | |
Dn | 8(1/1) | | nw np
An | 8(1/1) | | nw np
(An) | 12(2/1) | nr | nw np
(An)+ | 12(2/1) | nr | nw np
-(An) | 14(2/1) | n nr | nw np
(d16,An) | 16(3/1) | np nr | nw np
(d8,An,Xn) | 18(3/1) | n np nr | nw np
(xxx).W | 16(3/1) | np nr | nw np
(xxx).L | 20(4/1) | np np nr | nw np
#<data> | 12(2/1) | np | nw np
.L : | | |
Dn | 12(1/2) | | nW nw np
An | 12(1/2) | | nW nw np
(An) | 20(3/2) | nR nr | nW nw np
(An)+ | 20(3/2) | nR nr | nW nw np
-(An) | 22(3/2) | n nR nr | nW nw np
(d16,An) | 24(4/2) | np nR nr | nW nw np
(d8,An,Xn) | 26(4/2) | n np nR nr | nW nw np
(xxx).W | 24(4/2) | np nR nr | nW nw np
(xxx).L | 28(5/2) | np np nR nr | nW nw np
#<data> | 20(3/2) | np np | nW nw np
<ea>,-(An) : | | |
.B or .W : | | |
Dn | 8(1/1) | | np nw
An | 8(1/1) | | np nw
(An) | 12(2/1) | nr | np nw
(An)+ | 12(2/1) | nr | np nw
-(An) | 14(2/1) | n nr | np nw
(d16,An) | 16(3/1) | np nr | np nw
(d8,An,Xn) | 18(3/1) | n np nr | np nw
(xxx).W | 16(3/1) | np nr | np nw
(xxx).L | 20(4/1) | np np nr | np nw
#<data> | 12(2/1) | np | np nw
.L : | | |
Dn | 12(1/2) | | np nw nW
An | 12(1/2) | | np nw nW
(An) | 20(3/2) | nR nr | np nw nW
(An)+ | 20(3/2) | nR nr | np nw nW
-(An) | 22(3/2) | n nR nr | np nw nW
(d16,An) | 24(4/2) | np nR nr | np nw nW
(d8,An,Xn) | 26(4/2) | n np nR nr | np nw nW
(xxx).W | 24(4/2) | np nR nr | np nw nW
(xxx).L | 28(5/2) | np np nR nr | np nw nW
#<data> | 20(3/2) | np np | np nw nW
<ea>,(d16,An) : | | |
.B or .W : | | |
Dn | 12(2/1) | | np nw np
An | 12(2/1) | | np nw np
(An) | 16(3/1) | nr | np nw np
(An)+ | 16(3/1) | nr | np nw np
-(An) | 18(3/1) | n nr | np nw np
(d16,An) | 20(4/1) | np nr | np nw np
(d8,An,Xn) | 22(4/1) | n np nr | np nw np
(xxx).W | 20(4/1) | np nr | np nw np
(xxx).L | 24(5/1) | np np nr | np nw np
#<data> | 16(3/1) | np | np nw np
.L : | | |
Dn | 16(2/2) | | np nW nw np
An | 16(2/2) | | np nW nw np
(An) | 24(4/2) | nR nr | np nW nw np
(An)+ | 24(4/2) | nR nr | np nW nw np
-(An) | 26(4/2) | n nR nr | np nW nw np
(d16,An) | 28(5/2) | np nR nr | np nW nw np
(d8,An,Xn) | 30(5/2) | n np nR nr | np nW nw np
(xxx).W | 28(5/2) | np nR nr | np nW nw np
(xxx).L | 32(6/2) | np np nR nr | np nW nw np
#<data> | 24(4/2) | np np | np nW nw np
<ea>,(d8,An,Xn) : | | |
.B or .W : | | |
Dn | 14(2/1) | | n np nw np
An | 14(2/1) | | n np nw np
(An) | 18(3/1) | nr | n np nw np
(An)+ | 18(3/1) | nr | n np nw np
-(An) | 20(3/1) | n nr | n np nw np
(d16,An) | 22(4/1) | np nr | n np nw np
(d8,An,Xn) | 24(4/1) | n np nr | n np nw np
(xxx).W | 22(4/1) | np nr | n np nw np
(xxx).L | 26(5/1) | np np nr | n np nw np
#<data> | 18(3/1) | np | n np nw np
.L : | | |
Dn | 18(2/2) | | n np nW nw np
An | 18(2/2) | | n np nW nw np
(An) | 26(4/2) | nR nr | n np nW nw np
(An)+ | 26(4/2) | nR nr | n np nW nw np
-(An) | 28(4/2) | n nR nr | n np nW nw np
(d16,An) | 30(5/2) | np nR nr | n np nW nw np
(d8,An,Xn) | 32(5/2) | n np nR nr | n np nW nw np
(xxx).W | 30(5/2) | np nR nr | n np nW nw np
(xxx).L | 34(6/2) | np np nR nr | n np nW nw np
#<data> | 26(4/2) | np np | n np nW nw np
<ea>,(xxx).W : | | |
.B or .W : | | |
Dn | 12(2/1) | | np nw np
An | 12(2/1) | | np nw np
(An) | 16(3/1) | nr | np nw np
(An)+ | 16(3/1) | nr | np nw np
-(An) | 18(3/1) | n nr | np nw np
(d16,An) | 20(4/1) | np nr | np nw np
(d8,An,Xn) | 22(4/1) | n np nr | np nw np
(xxx).W | 20(4/1) | np nr | np nw np
(xxx).L | 24(5/1) | np np nr | np nw np
#<data> | 16(3/1) | np | np nw np
.L : | | |
Dn | 16(2/2) | | np nW nw np
An | 16(2/2) | | np nW nw np
(An) | 24(4/2) | nR nr | np nW nw np
(An)+ | 24(4/2) | nR nr | np nW nw np
-(An) | 26(4/2) | n nR nr | np nW nw np
(d16,An) | 28(5/2) | np nR nr | np nW nw np
(d8,An,Xn) | 30(5/2) | n np nR nr | np nW nw np
(xxx).W | 28(5/2) | np nR nr | np nW nw np
(xxx).L | 32(6/2) | np np nR nr | np nW nw np
#<data> | 24(4/2) | np np | np nW nw np
<ea>,(xxx).L : | | |
.B or .W : | | |
Dn | 16(3/1) | | np np nw np
An | 16(3/1) | | np np nw np
(An) | 20(4/1) | nr | np nw np np
(An)+ | 20(4/1) | nr | np nw np np
-(An) | 22(4/1) | n nr | np nw np np
(d16,An) | 24(5/1) | np nr | np nw np np
(d8,An,Xn) | 26(5/1) | n np nr | np nw np np
(xxx).W | 24(5/1) | np nr | np nw np np
(xxx).L | 28(6/1) | np np nr | np nw np np
#<data> | 20(4/1) | np | np np nw np
.L : | | |
Dn | 20(3/2) | | np np nW nw np
An | 20(3/2) | | np np nW nw np
(An) | 28(5/2) | nR nr | np nW nw np np
(An)+ | 28(5/2) | nR nr | np nW nw np np
-(An) | 30(5/2) | n nR nr | np nW nw np np
(d16,An) | 32(6/2) | np nR nr | np nW nw np np
(d8,An,Xn) | 34(6/2) | n np nR nr | np nW nw np np
(xxx).W | 32(6/2) | np nR nr | np nW nw np np
(xxx).L | 36(7/2) | np np nR nr | np nW nw np np
#<data> | 28(5/2) | np np | np np nW nw np
-------------------------------------------------------------------------------
| Exec Time | Data Bus Usage
MOVEA | INSTR | 1st OP (ea) | INSTR
------------------+-----------------+---------------+--------------------------
<ea>,An : | | |
.W : | | |
Dn | 4(1/0) | | np
An | 4(1/0) | | np
(An) | 8(2/0) | nr | np
(An)+ | 8(2/0) | nr | np
-(An) | 10(2/0) | n nr | np
(d16,An) | 12(3/0) | np nr | np
(d8,An,Xn) | 14(3/0) | n np nr | np
(xxx).W | 12(3/0) | np nr | np
(xxx).L | 16(4/0) | np np nr | np
#<data> | 8(2/0) | np | np
.L : | | |
Dn | 4(1/0) | | np
An | 4(1/0) | | np
(An) | 12(3/0) | nR nr | np
(An)+ | 12(3/0) | nR nr | np
-(An) | 14(3/0) | n nR nr | np
(d16,An) | 16(4/0) | np nR nr | np
(d8,An,Xn) | 18(4/0) | n np nR nr | np
(xxx).W | 16(4/0) | np nR nr | np
(xxx).L | 20(5/0) | np np nR nr | np
#<data> | 12(3/0) | np np | np
*******************************************************************************
Line 0100
CHK, CLR, EXT, ILLEGAL, JMP, JSR, LEA , LINK, MV fr/to CCR/SR, MOVEM, NBCD,
NEG, NEGX, NOP, NOT, PEA, RTR, RTS, SWAP, STOP, TAS, TRAP, TRAPV, TST, UNLK
*******************************************************************************
-------------------------------------------------------------------------------
CLR, | Exec Time | Data Bus Usage
NEGX, NEG, NOT | INSTR EA | 1st OP (ea) | INSTR
------------------+-----------------+---------------+--------------------------
<ea> : | | |
.B or .W : | | |
Dn | 4(1/0) 0(0/0) | | np
(An) | 8(1/1) 4(1/0) | nr | np nw
(An)+ | 8(1/1) 4(1/0) | nr | np nw
-(An) | 8(1/1) 6(1/0) | n nr | np nw
(d16,An) | 8(1/1) 8(2/0) | np nr | np nw
(d8,An,Xn) | 8(1/1) 10(2/0) | n np nr | np nw
(xxx).W | 8(1/1) 8(2/0) | np nr | np nw
(xxx).L | 8(1/1) 12(3/0) | np np nr | np nw
.L : | | |
Dn | 6(1/0) 0(0/0) | | np n
(An) | 12(1/2) 8(2/0) | nR nr | np nw nW
(An)+ | 12(1/2) 8(2/0) | nR nr | np nw nW
-(An) | 12(1/2) 10(2/0) | n nR nr | np nw nW
(d16,An) | 12(1/2) 12(3/0) | np nR nr | np nw nW
(d8,An,Xn) | 12(1/2) 14(3/0) | n np nR nr | np nw nW
(xxx).W | 12(1/2) 12(3/0) | np nR nr | np nw nW
(xxx).L | 12(1/2) 16(4/0) | np np nR nr | np nw nW
-------------------------------------------------------------------------------
MOVE | Exec Time | Data Bus Usage
from SR | INSTR EA | 2nd Op (ea) | INSTR
------------------+-----------------+---------------+--------------------------
SR,<ea> : | | |
.W : | | |
Dn | 6(1/0) 0(0/0) | | np n
(An) | 8(1/1) 4(1/0) | nr | np nw
(An)+ | 8(1/1) 4(1/0) | nr | np nw
-(An) | 8(1/1) 6(1/0) | n nr | np nw
(d16,An) | 8(1/1) 8(2/0) | np nr | np nw
(d8,An,Xn) | 8(1/1) 10(2/0) | n np nr | np nw
(xxx).W | 8(1/1) 8(2/0) | np nr | np nw
(xxx).L | 8(1/1) 12(3/0) | np np nr | np nw
-------------------------------------------------------------------------------
MOVE | Exec Time | Data Bus Usage
to CCR, to SR | INSTR EA | 1st OP (ea) | INSTR
------------------+-----------------+---------------+--------------------------
<ea>,CCR : | | |
.W : | | |
Dn | 12(1/0) 0(0/0) | | nn np np
(An) | 12(1/0) 4(1/0) | nr | nn np np
(An)+ | 12(1/0) 4(1/0) | nr | nn np np
-(An) | 12(1/0) 6(1/0) | n nr | nn np np
(d16,An) | 12(1/0) 8(2/0) | np nr | nn np np
(d8,An,Xn) | 12(1/0) 10(2/0) | n np nr | nn np np
(xxx).W | 12(1/0) 8(2/0) | np nr | nn np np
(xxx).L | 12(1/0) 12(3/0) | np np nr | nn np np
#<data> | 12(1/0) 4(1/0) | np | nn np np
-------------------------------------------------------------------------------
| Exec Time | Data Bus Usage
NBCD | INSTR | 1st OP (ea) | INSTR
------------------+-----------------+---------------+--------------------------
<ea> : | | |
.B : | | |
Dn | 6(1/0) 0(0/0) | | np n
(An) | 8(1/1) 4(1/0) | nr | np nw
(An)+ | 8(1/1) 4(1/0) | nr | np nw
-(An) | 8(1/1) 6(1/0) | n nr | np nw
(d16,An) | 8(1/1) 8(2/0) | np nr | np nw
(d8,An,Xn) | 8(1/1) 10(2/0) | n np nr | np nw
(xxx).W | 8(1/1) 8(2/0) | np nr | np nw
(xxx).L | 8(1/1) 12(3/0) | np np nr | np nw
-------------------------------------------------------------------------------
| Exec Time | Data Bus Usage
PEA | INSTR | INSTR
------------------+-----------------+------------------------------------------
<ea> : | |
.L : | |
(An) | 12(1/2) | np nS ns
(d16,An) | 16(2/2) | np np nS ns
(d8,An,Xn) | 20(2/2) | n np n np nS ns
(xxx).W | 16(2/2) | np nS ns np
(xxx).L | 20(3/2) | np np nS ns np
-------------------------------------------------------------------------------
| Exec Time | Data Bus Usage
SWAP | INSTR | INSTR
------------------+-----------------+------------------------------------------
Dn : | |
.W : | 4(1/0) | np
-------------------------------------------------------------------------------
| Exec Time | Data Bus Usage
MOVEM | INSTR | INSTR
------------------+-----------------+------------------------------------------
M --> R | |
.W | |
(An) | 12+4m(3+m/0) | np (nr)* nr np
(An)+ | 12+4m(3+m/0) | np (nr)* nr np
(d16,An) | 16+4m(4+m/0) | np np (nr)* nr np
(d8,An,Xn) | 18+4m(4+m/0) | np n np (nr)* nr np
(xxx).W | 16+4m(4+m/0) | np np (nr)* nr np
(xxx).L | 20+4m(5+m/0) | np np np (nr)* nr np
.L | |
(An) | 12+8m(3+2m/0) | np nR (nr nR)* np
(An)+ | 12+8m(3+2m/0) | np nR (nr nR)* np
(d16,An) | 16+8m(4+2m/0) | np np nR (nr nR)* np
(d8,An,Xn) | 18+8m(4+2m/0) | np n np nR (nr nR)* np
(xxx).W | 16+8m(4+2m/0) | np np nR (nr nR)* np
(xxx).L | 20+8m(5+2m/0) | np np np nR (nr nR)* np
R --> M | |
.W | |
(An) | 8+4m(2/m) | np (nw)* np
-(An) | 8+4m(2/m) | np (nw)* np
(d16,An) | 12+4m(3/m) | np np (nw)* np
(d8,An,Xn) | 14+4m(3/m) | np n np (nw)* np
(xxx).W | 12+4m(3/m) | np np (nw)* np
(xxx).L | 16+4m(4/m) | np np np (nw)* np
.L | |
(An) | 8+8m(2/2m) | np (nW nw)* np
-(An) | 8+8m(2/2m) | np (nw nW)* np
(d16,An) | 12+8m(3/2m) | np np (nW nw)* np
(d8,An,Xn) | 14+8m(3/2m) | np n np (nW nw)* np
(xxx).W | 12+8m(3/2m) | np np (nW nw)* np
(xxx).L | 16+8m(4/2m) | np np np (nW nw)* np
NOTES :
.'m' is the number of registers to move.
.'(nr)*' should be replaced by m consecutive 'nr'
.'(nw)*' should be replaced by m consecutive 'nw'
.'(nR nr)*' should be replaced by m consecutive 'nR nr'
.'(nW nw)*' (or '(nw nW)*') should be replaced by m consecutive 'nW nw' (or m
consecutive 'nw nW').
.In M --> R mode, an extra bus read cycle occurs. This extra access can cause
errors (for exemple if occuring beyond the bounds of physical memory).
.In M --> R mode, MOVEM.W sign-extends words moved to data registers.
-------------------------------------------------------------------------------
| Exec Time | Data Bus Usage
EXT | INSTR | 1st Operand | INSTR
------------------+-----------------+---------------+--------------------------
Dn : | | |
.W : | 4(1/0) | | np
.L : | 4(1/0) | | np
-------------------------------------------------------------------------------
| Exec Time | Data Bus Usage
TST | INSTR EA | 1st OP (ea) | INSTR
------------------+-----------------+---------------+--------------------------
<ea> : | | |
.B or .W : | | |
Dn | 4(1/0) 0(0/0) | | np
(An) | 4(1/0) 4(1/0) | nr | np
(An)+ | 4(1/0) 4(1/0) | nr | np
-(An) | 4(1/0) 6(1/0) | n nr | np
(d16,An) | 4(1/0) 8(2/0) | np nr | np
(d8,An,Xn) | 4(1/0) 10(2/0) | n np nr | np
(xxx).W | 4(1/0) 8(2/0) | np nr | np
(xxx).L | 4(1/0) 12(3/0) | np np nr | np
.L | | |
Dn | 4(1/0) 0(0/0) | | np
(An) | 4(1/0) 8(2/0) | nR nr | np
(An)+ | 4(1/0) 8(2/0) | nR nr | np
-(An) | 4(1/0) 10(2/0) | n nR nr | np
(d16,An) | 4(1/0) 12(3/0) | np nR nr | np
(d8,An,Xn) | 4(1/0) 14(3/0) | n np nR nr | np
(xxx).W | 4(1/0) 12(3/0) | np nR nr | np
(xxx).L | 4(1/0) 16(4/0) | np np nR nr | np
-------------------------------------------------------------------------------
| Exec Time | Data Bus Usage
TAS | INSTR EA | 1st OP (ea) | INSTR
------------------+-----------------+---------------+--------------------------
<ea> : | | |
.B : | | |
Dn | 4(1/0) 0(0/0) | | np
(An) | 10(1/1) 4(1/0) | nr | n nw np
(An)+ | 10(1/1) 4(1/0) | nr | n nw np
-(An) | 10(1/1) 6(1/0) | n nr | n nw np
(d16,An) | 10(1/1) 8(2/0) | np nr | n nw np
(d8,An,Xn) | 10(1/1) 10(2/0) | n np nr | n nw np
(xxx).W | 10(1/1) 8(1/0) | | n nw np
(xxx).L | 10(1/1) 12(2/0) | | n nw np
NOTES :
.M68000UM is probably wrong with instruction timming when <ea> is different
from Dn. It reads "14(3/0)" but according to the same book the read-modify-
write bus cycle used by this instruction is only 10 clock cycles long which
seems coherent with the microwords decomposition in USP4325121. Last,
evaluation on real hardware confirms the 10 cycles timing.
-------------------------------------------------------------------------------
| Exec Time | Data Bus Usage
CHK | INSTR EA | 1st OP (ea) | INSTR
--------------+----------------+---------------+-------------------------------
no trap : | | |
<ea>,Dn : | | /
.W : | | /
Dn |10(1/0) 0(0/0) | |np nn n
(An) |10(1/0) 4(1/0) | nr |np nn n
(An)+ |10(1/0) 4(1/0) | nr |np nn n
-(An) |10(1/0) 6(1/0) |n nr |np nn n
(d16,An) |10(1/0) 8(2/0) | np nr |np nn n
(d8,An,Xn) |10(1/0) 10(2/0) |n np nr |np nn n
(xxx).W |10(1/0) 8(2/0) | np nr |np nn n
(xxx).L |10(1/0) 12(2/0) | np np nr |np nn n
#<data> |10(1/0) 4(1/0) | np |np nn n
trap : | | |
<ea>,Dn : | | |
.W : | | |
Dn > Src : | | |
Dn |38(5/3) 0(0/0) | |np nn ns ns nS nV nv np n np
(An) |38(5/3) 4(1/0) | nr |np nn ns ns nS nV nv np n np
(An)+ |38(5/3) 4(1/0) | nr |np nn ns ns nS nV nv np n np
-(An) |38(5/3) 6(1/0) |n nr |np nn ns ns nS nV nv np n np
(d16,An) |38(5/3) 8(2/0) | np nr |np nn ns ns nS nV nv np n np
(d8,An,Xn)|38(5/3) 10(2/0) |n np nr |np nn ns ns nS nV nv np n np
(xxx).W |38(5/3) 8(2/0) | np nr |np nn ns ns nS nV nv np n np
(xxx).L |38(5/3) 12(2/0) | np np nr |np nn ns ns nS nV nv np n np
#<data> |38(5/3) 4(1/0) | np |np nn ns ns nS nV nv np n np
Dn <0 : | | |
Dn |40(5/3) 0(0/0) | |np n nn ns ns nS nV nv np n np
(An) |40(5/3) 4(1/0) | nr |np n nn ns ns nS nV nv np n np
(An)+ |40(5/3) 4(1/0) | nr |np n nn ns ns nS nV nv np n np
-(An) |40(5/3) 6(1/0) |n nr |np n nn ns ns nS nV nv np n np
(d16,An) |40(5/3) 8(2/0) | np nr |np n nn ns ns nS nV nv np n np
(d8,An,Xn)|40(5/3) 10(2/0) |n np nr |np n nn ns ns nS nV nv np n np
(xxx).W |40(5/3) 8(2/0) | np nr |np n nn ns ns nS nV nv np n np
(xxx).L |40(5/3) 12(2/0) | np np nr |np n nn ns ns nS nV nv np n np
#<data> |40(5/3) 4(1/0) | np |np n nn ns ns nS nV nv np n np
NOTES :
. for more informations about the "trap" lines see exceptions section below.
-------------------------------------------------------------------------------
| Exec Time | Data Bus Usage
LEA | INSTR | INSTR
------------------+-----------------+------------------------------------------
<ea>,An : | |
.L : | |
(An) | 4(1/0) | np
(d16,An) | 8(2/0) | np np
(d8,An,Xn) | 12(2/0) | n np n np
(xxx).W | 8(2/0) | np np
(xxx).L | 12(3/0) | np np np
-------------------------------------------------------------------------------
| Exec Time | Data Bus Usage
JSR | INSTR | INSTR
------------------+-----------------+------------------------------------------
<ea> : | |
(An) | 16(2/2) | np nS ns np
(d16,An) | 18(2/2) | n np nS ns np
(d8,An,Xn) | 22(2/2) | n nn np nS ns np
(xxx).W | 18(2/2) | n np nS ns np
(xxx).L | 20(3/2) | np np nS ns np
-------------------------------------------------------------------------------
| Exec Time | Data Bus Usage
JMP | INSTR | INSTR
------------------+-----------------+------------------------------------------
<ea> : | |
(An) | 8(2/0) | np np
(d16,An) | 10(2/0) | n np np
(d8,An,Xn) | 14(2/0) | n nn np np
(xxx).W | 10(2/0) | n np np
(xxx).L | 12(3/0) | np np np
NOTES :
.M68000UM is probably wrong with bus read accesses for JMP (d8,An,Xn),Dn
instruction. It reads "14(3/0)" but, according to USP4325121 and with a
little common sense, 2 bus read accesses are far enough.
-------------------------------------------------------------------------------
| Exec Time | Data Bus Usage
MOVE USP | INSTR | INSTR
------------------+-----------------+------------------------------------------
An,USP : | 4(1/0) | np
USP,An : | 4(1/0) | np
-------------------------------------------------------------------------------
| Exec Time | Data Bus Usage
RESET | INSTR | INSTR
------------------+-----------------+------------------------------------------
| 132(1/0) | nn (??-)* np
NOTES :
.(??)* is for 124 cycles when the CPU will asserts the /RSTO signal in order
to reset all external devices. Normally, the CPU won't use the bus during
these cycles.
.RESET instruction have nothing to do with /RESET exception.
-------------------------------------------------------------------------------
| Exec Time | Data Bus Usage
NOP | INSTR | INSTR
------------------+-----------------+------------------------------------------
| 4(1/0) | np
-------------------------------------------------------------------------------
| Exec Time | Data Bus Usage
STOP | INSTR | INSTR
------------------+-----------------+------------------------------------------
| 4(0/0) | n
NOTES :
.At this point, there is no real clues of how the second microcyle of this *
instruction is spent.
-------------------------------------------------------------------------------
| Exec Time | Data Bus Usage
RTE, RTR | INSTR | INSTR
------------------+-----------------+------------------------------------------
| 20(5/0) | nU nu nu np np
NOTES :
.M68000UM is probably wrong with bus read accesses for RTR instruction.
It reads "20(2/0)" but, according to USP4325121 and with a little common
sense, 2 bus read accesses aren't enough for reading status register and
program counter values from the stack and prefetching.
-------------------------------------------------------------------------------
| Exec Time | Data Bus Usage
RTS | INSTR | INSTR
------------------+-----------------+------------------------------------------
| 16(4/0) | nU nu np np
-------------------------------------------------------------------------------
| Exec Time | Data Bus Usage
TRAPV | INSTR | INSTR
------------------+-----------------+------------------------------------------
no trap | 4(1/0) | np
trap | 34(5/3) | np ns nS ns nV nv np n np
NOTES :
. for more informations about the "trap" line see exceptions section below.
-------------------------------------------------------------------------------
| Exec Time | Data Bus Usage
LINK | INSTR | 2nd Operand | INSTR
------------------+-----------------+---------------+--------------------------
An,#<data> : | |
.W : | 16(2/2) | np nS ns np
-------------------------------------------------------------------------------
| Exec Time | Data Bus Usage
UNLNK | INSTR | INSTR
------------------+-----------------+------------------------------------------
An : | 12(3/0) | nU nu np
-------------------------------------------------------------------------------
| Exec Time | Data Bus Usage
ILLEGAL, TRAP | INSTR | INSTR
------------------+-----------------+------------------------------------------
| 34(4/3) | nn ns ns nS nV nv np n np
NOTES :
.For more informations about this instruction see exceptions section below.
*******************************************************************************
Line 0101
ADDQ, DBcc, Scc, SUBQ
*******************************************************************************
-------------------------------------------------------------------------------
| Exec Time | Data Bus Usage
ADDQ, SUBQ | INSTR EA | 1st OP (ea) | INSTR
------------------+-----------------+---------------+--------------------------
#<data>,<ea> : | | |
.B or .W : | | |
Dn | 4(1/0) 0(0/0) | | np
An | 8(1/0) 0(0/0) | | np nn
(An) | 8(1/1) 4(1/0) | nr | np nw
(An)+ | 8(1/1) 4(1/0) | nr | np nw
-(An) | 8(1/1) 6(1/0) | n nr | np nw
(d16,An) | 8(1/1) 8(2/0) | np nr | np nw
(d8,An,Xn) | 8(1/1) 10(2/0) | n np nr | np nw
(xxx).W | 8(1/1) 8(2/0) | np nr | np nw
(xxx).L | 8(1/1) 12(3/0) | np np nr | np nw
.L : | | |
Dn | 8(1/0) 0(0/0) | | np nn
An | 8(1/0) 0(0/0) | | np nn
(An) | 12(1/2) 8(2/0) | nR nr | np nw nW
(An)+ | 12(1/2) 8(2/0) | nR nr | np nw nW
-(An) | 12(1/2) 10(2/0) | n nR nr | np nw nW
(d16,An) | 12(1/2) 12(3/0) | np nR nr | np nw nW
(d8,An,Xn) | 12(1/2) 14(3/0) | n np nR nr | np nw nW
(xxx).W | 12(1/2) 12(3/0) | np nR nr | np nw nW
(xxx).L | 12(1/2) 16(4/0) | np np nR nr | np nw nW
NOTES :
.M68000UM is probably wrong with instruction timing for ADDQ.W #<data>,An
instruction. It reads "4(1/0)" but, according to USP4325121, this
instruction is based on the same microwords than ADDQ.L #<data>,Dn and
ADDQ.L #<data>,An that have a "8(3/0)" timing. That makes sense because of
the calculation of a 32 bit address on 16 bits ALU. In addition, evaluation
on real hardware confirms the 8 cycles timing and, last, it makes addq and
subbq coherent in term of timing.
-------------------------------------------------------------------------------
| Exec Time | Data Bus Usage
DBcc | INSTR | INSTR
------------------+-----------------+------------------------------------------
Dn,<label> : | |
branch taken | 10(2/0) | n np np
branch not taken| |
cc true | 12(2/0) | n n np np
counter exp | 14(3/0) | n np np np
NOTES :
.DBcc does not exist in USP4325121. Only does a primitive instruction DCNT
tht doesn't succeded to reach the production version of M68000 CPU.
Nervertheless, looking at DCNT and Bcc micro/nanowords can lead to a
realistic idea of how DBcc should work. At least, this re-enginering of DBcc
matches the timing written in M68000UM for this instruction.
FLOWCHART :
cc n /cc
+-------------------+-------------------+
n z np /z
| +---------+---------+
+---------------------------->np |
| |
np<-----------------+
-------------------------------------------------------------------------------
| Exec Time | Data Bus Usage
Scc | INSTR EA | 1st OP (ea) | INSTR
------------------+-----------------+---------------+--------------------------
<ea> : | | |
.B : | | |
cc false | | |
Dn | 4(1/0) 0(0/0) | | np
(An) | 8(1/1) 4(1/0) | nr | np nw
(An)+ | 8(1/1) 4(1/0) | nr | np nw
-(An) | 8(1/1) 6(1/0) | n nr | np nw
(d16,An) | 8(1/1) 8(2/0) | np nr | np nw
(d8,An,Xn) | 8(1/1) 10(2/0) | n np nr | np nw
(xxx).W | 8(1/1) 8(2/0) | np nr | np nw
(xxx).L | 8(1/1) 12(3/0) | np np nr | np nw
cc true | | |
Dn | 6(1/0) 0(0/0) | | np n
(An) | 8(1/1) 4(1/0) | nr | np nw
(An)+ | 8(1/1) 4(1/0) | nr | np nw
-(An) | 8(1/1) 6(1/0) | n nr | np nw
(d16,An) | 8(1/1) 8(2/0) | np nr | np nw
(d8,An,Xn) | 8(1/1) 10(2/0) | n np nr | np nw
(xxx).W | 8(1/1) 8(2/0) | np nr | np nw
(xxx).L | 8(1/1) 12(3/0) | np np nr | np nw
*******************************************************************************
Line 0110
Bcc, BRA, BSR
*******************************************************************************
-------------------------------------------------------------------------------
| Exec Time | Data Bus Usage
BRA | INSTR | INSTR
------------------+-----------------+------------------------------------------
<label> : | |
.B, .S or .W : | 10(2/0) | n np np
-------------------------------------------------------------------------------
| Exec Time | Data Bus Usage
BSR | INSTR | INSTR
------------------+-----------------+------------------------------------------
<label> : | |
.B .S or .W : | 18(2/2) | n nS ns np np
-------------------------------------------------------------------------------
| Exec Time | Data Bus Usage
Bcc | INSTR | INSTR
------------------+-----------------+------------------------------------------
<label> : | |
.B or .S : | |
branch taken | 10(2/0) | n np np
branch not taken| 8(1/0) | nn np
.W : | |
branch taken | 10(2/0) | n np np
branch not taken| 12(2/0) | nn np np
*******************************************************************************
Line 0111
MOVEQ
*******************************************************************************
-------------------------------------------------------------------------------
| Exec Time | Data Bus Usage
MOVEQ | INSTR | 1st OP (ea) | INSTR
------------------+-----------------+---------------+--------------------------
#<data>,Dn : | |
.L : | 4(1/0) | np
*******************************************************************************
Line 1000 & Line 1100
DIVS, DIVU, OR, SBCD ABCD, AND, EXG, MULS, MULU
*******************************************************************************
-------------------------------------------------------------------------------
| Exec Time | Data Bus Usage
ABCD, SBCD | INSTR | INSTR
------------------+-----------------+------------------------------------------
Dy,Dx : | |
.B : | 6(1/0) | np n
-(Ay),-(Ax) : | |
.B : | 18(3/1) | n nr nr np nw
-------------------------------------------------------------------------------
| Exec Time | Data Bus Usage
AND, OR | INSTR EA | 1st OP (ea) | INSTR
------------------+-----------------+---------------+--------------------------
<ea>,Dn : | | |
.B or .W : | | |
Dn | 4(1/0) 0(0/0) | | np
(An) | 4(1/0) 4(1/0) | nr | np
(An)+ | 4(1/0) 4(1/0) | nr | np
-(An) | 4(1/0) 6(1/0) | n nr | np
(d16,An) | 4(1/0) 8(2/0) | np nr | np
(d8,An,Xn) | 4(1/0) 10(2/0) | n np nr | np
(xxx).W | 4(1/0) 8(2/0) | np nr | np
(xxx).L | 4(1/0) 12(3/0) | np np nr | np
#<data> | 4(1/0) 4(1/0) | np | np
.L : | | |
Dn | 8(1/0) 0(0/0) | | np nn
(An) | 6(1/0) 8(2/0) | nR nr | np n
(An)+ | 6(1/0) 8(2/0) | nR nr | np n
-(An) | 6(1/0) 10(2/0) | n nR nr | np n
(d16,An) | 6(1/0) 12(3/0) | np nR nr | np n
(d8,An,Xn) | 6(1/0) 14(3/0) | n np nR nr | np n
(xxx).W | 6(1/0) 12(3/0) | np nR nr | np n
(xxx).L | 6(1/0) 16(4/0) | np np nR nr | np n
#<data> | 8(1/0) 8(2/0) | np np | np nn
Dn,<ea> : | | |
.B or .W : | | |
(An) | 8(1/1) 4(1/0) | nr | np nw
(An)+ | 8(1/1) 4(1/0) | nr | np nw
-(An) | 8(1/1) 6(1/0) | n nr | np nw
(d16,An) | 8(1/1) 8(2/0) | np nr | np nw
(d8,An,Xn) | 8(1/1) 10(2/0) | n np nr | np nw
(xxx).W | 8(1/1) 8(2/0) | np nr | np nw
(xxx).L | 8(1/1) 12(3/0) | np np nr | np nw
.L : | |
(An) | 12(1/2) 8(2/0) | nR nr | np nw nW
(An)+ | 12(1/2) 8(2/0) | nR nr | np nw nW
-(An) | 12(1/2) 10(2/0) | n nR nr | np nw nW
(d16,An) | 12(1/2) 12(3/0) | np nR nr | np nw nW
(d8,An,Xn) | 12(1/2) 14(3/0) | n np nR nr | np nw nW
(xxx).W | 12(1/2) 12(3/0) | np nR nr | np nw nW
(xxx).L | 12(1/2) 16(4/0) | np np nR nr | np nw nW
-------------------------------------------------------------------------------
| Exec Time | Data Bus Usage
DIVU | INSTR EA | 1st OP (ea) | INSTR
------------------+-----------------+---------------+--------------------------
<ea>,Dn : / | |
.W : | | |
Dn | 76+?(1/0) 0(0/0) | | nn n [seq.] n nn np
(An) | 76+?(1/0) 4(1/0) | nr | nn n [seq.] n nn np
(An)+ | 76+?(1/0) 4(1/0) | nr | nn n [seq.] n nn np
-(An) | 76+?(1/0) 6(1/0) | n nr | nn n [seq.] n nn np
(d16,An) | 76+?(1/0) 8(2/0) | np nr | nn n [seq.] n nn np
(d8,An,Xn) | 76+?(1/0) 10(2/0) | n np nr | nn n [seq.] n nn np
(xxx).W | 76+?(1/0) 8(2/0) | np nr | nn n [seq.] n nn np
(xxx).L | 76+?(1/0) 12(2/0) | np np nr | nn n [seq.] n nn np
#<data> | 76+?(1/0) 8(2/0) | np np | nn n [seq.] n nn np
NOTES :
.Overflow always cost 10 cycles (n nn np).
.For more informations about division by zero see exceptions section below.
.[seq.] refers to 15 consecutive blocks to be chosen in the following 3 :
(nn), (nnn-) or (nnn-n).
(see following flowchart for details).
.Best case : 76 cycles (nn n [nn]*15 n nn np)
.Worst case : 136 (140 ?) cycles.
FLOWCHART :
n
n Divide by zero
+--------------------+--------------------+
Overflow n n
+-----------+----------+ n
np n<---------------------+-+-+ nw
n | | | nw
No more bits | pMSB=0 pMSB=1 | | | nw
+-----+-----+-----------+ | | | np
n MSB=0 n- MSB=1 | | | | np
np +---+---+ +----+ | | np
| n | | np
| +--------------+ |
+------------------------+
.for each iteration of the loop : shift dividend to the left by 1 bit then
substract divisor to the MSW of new dividend, discard after test if result
is negative keep it if positive.
.MSB = most significant bit : bit at the far left of the dividend
.pMSB = previous MSB : MSB used in the previous iteration of the loop
-------------------------------------------------------------------------------
| Exec Time | Data Bus Usage
DIVS | INSTR EA | 1st OP (ea) | INSTR
------------------+-----------------+---------------+--------------------------
<ea>,Dn : / / /
.W : / / /
Dn |120+?(1/0) 0(0/0)| | nn nnn (n)n [seq] nnn-nnn n(n(n))np
(An) |120+?(1/0) 4(1/0)| nr| nn nnn (n)n [seq] nnn-nnn n(n(n))np
(An)+ |120+?(1/0) 4(1/0)| nr| nn nnn (n)n [seq] nnn-nnn n(n(n))np
-(An) |120+?(1/0) 6(1/0)|n nr| nn nnn (n)n [seq] nnn-nnn n(n(n))np
(d16,An) |120+?(1/0) 8(2/0)| np nr| nn nnn (n)n [seq] nnn-nnn n(n(n))np
(d8,An,Xn)|120+?(1/0) 10(2/0)|n np nr| nn nnn (n)n [seq] nnn-nnn n(n(n))np
(xxx).W |120+?(1/0) 8(2/0)| np nr| nn nnn (n)n [seq] nnn-nnn n(n(n))np
(xxx).L |120+?(1/0) 12(2/0)| np np nr| nn nnn (n)n [seq] nnn-nnn n(n(n))np
#<data> |120+?(1/0) 8(2/0)| np np | nn nnn (n)n [seq] nnn-nnn n(n(n))np
NOTES :
.Overflow cost 16 or 18 cycles depending on dividend sign (n nn nn (n)n np).
.For more informations about division by zero see exceptions section below.
.[seq.] refers to 15 consecutive blocks to be chosen in the following 2 :
(nnn-n) or (nn-n).
(see following flowchart for details).
.Best case : 120-122 cycles depending on dividend sign.
.Worst case : 156 (158 ?) cycles.
FLOWCHART :
n
n Divide by zero
+--------+--------------------------------+
n n
n n
Dividend<0 n Dividend>0 nw
+-----+-----+ nw
n | nw
+---------->n np
| Overflow np
+-----------------+ +----+----+ np
| +----------+ +----->n np np
| | +---------->n
| | n-
| | MSB=1 MSB=0 n No more bits
| | +-----------+--------+--------+
| +-+ | n
+---------------+ divisor<0 n divisor>0
+----------+-----------+
n dividend<0 n dividend>0
n +----------+----+
np n np
n
np
.for each iteration of the loop : shift quotient to the left by 1 bit.
.MSB = most significant bit : bit at the far left of the quotient.
-------------------------------------------------------------------------------
| Exec Time | Data Bus Usage
EXG | INSTR | INSTR
------------------+-----------------+------------------------------------------
.L : | |
Dx,Dy | 6(1/0) | np n
Ax,Ay | 6(1/0) | np n
Dx,Ay | 6(1/0) | np n
-------------------------------------------------------------------------------
| Exec Time | Data Bus Usage
MULU,MULS | INSTR EA | 1st OP (ea) | INSTR
------------------+-----------------+---------------+--------------------------
<ea>,Dn : / | |
.W : / | |
Dn | 38+2m(1/0) 0(0/0) | | np n*
(An) | 38+2m(1/0) 4(1/0) | nr | np n*
(An)+ | 38+2m(1/0) 4(1/0) | nr | np n*
-(An) | 38+2m(1/0) 6(1/0) | n nr | np n*
(d16,An) | 38+2m(1/0) 8(2/0) | np nr | np n*
(d8,An,Xn) | 38+2m(1/0) 10(2/0) | n np nr | np n*
(xxx).W | 38+2m(1/0) 8(2/0) | np nr | np n*
(xxx).L | 38+2m(1/0) 12(2/0) | np np nr | np n*
#<data> | 38+2m(1/0) 4(1/0) | np | np n*
NOTES :
.for MULU 'm' = the number of ones in the source
- Best case 38 cycles with $0
- Worst case : 70 cycles with $FFFF
.for MULS 'm' = concatenate the 16-bit pointed by <ea> with a zero as the LSB
'm' is the resultant number of 10 or 01 patterns in the 17-bit source.
- Best case : 38 cycles with $0 or $FFFF
- Worst case : 70 cycles with $5555
.in both cases : 'n*' should be replaced by 17+m consecutive 'n'
FLOWCHART :
np
LSB=1 | LSB=0
+------------+------------+
| |
+->n------------------------>n<----+
| | | LSB=0 or
| No more bits | | 2LSB=00,11
LSB=1 or +---------------+------------+-----+
2LSB=01,10 |
n
.LSB = less significant bit : bit at the far right of the source.
.2LSB = 2 less significant bits : 2 last bits at the far right of the source.
*******************************************************************************
Line 1001 & Line 1101
SUB, SUBA, SUBX ADD, ADDA, ADDX
*******************************************************************************
-------------------------------------------------------------------------------
| Exec Time | Data Bus Usage
ADD, SUB | INSTR EA | 1st Operand | 2nd OP (ea) | INSTR
------------------+-----------------+-------------+---------------+------------
<ea>,Dn : | | \ |
.B or .W : | | | |
Dn | 4(1/0) 0(0/0) | | | np
An | 4(1/0) 0(0/0) | | | np
(An) | 4(1/0) 4(1/0) | nr | | np
(An)+ | 4(1/0) 4(1/0) | nr | | np
-(An) | 4(1/0) 6(1/0) | n nr | | np
(d16,An) | 4(1/0) 8(2/0) | np nr | | np
(d8,An,Xn) | 4(1/0) 10(2/0) | n np nr | | np
(xxx).W | 4(1/0) 8(2/0) | np nr | | np
(xxx).L | 4(1/0) 12(3/0) | np np nr | | np
#<data> | 4(1/0) 4(1/0) np | np
.L : | | | |
Dn | 8(1/0) 0(0/0) | | | np nn
An | 8(1/0) 0(0/0) | | | np nn
(An) | 6(1/0) 8(2/0) | nR nr | | np n
(An)+ | 6(1/0) 8(2/0) | nR nr | | np n
-(An) | 6(1/0) 10(2/0) | n nR nr | | np n
(d16,An) | 6(1/0) 12(3/0) | np nR nr | | np n
(d8,An,Xn) | 6(1/0) 14(3/0) | n np nR nr | | np n
(xxx).W | 6(1/0) 12(3/0) | np nR nr | | np n
(xxx).L | 6(1/0) 16(4/0) | np np nR nr | | np n
#<data> | 8(1/0) 8(2/0) | np np | np nn
Dn,<ea> : | | / |
.B or .W : | | | |
(An) | 8(1/1) 4(1/0) | | nr | np nw
(An)+ | 8(1/1) 4(1/0) | | nr | np nw
-(An) | 8(1/1) 6(1/0) | | n nr | np nw
(d16,An) | 8(1/1) 8(2/0) | | np nr | np nw
(d8,An,Xn) | 8(1/1) 10(2/0) | | n np nr | np nw
(xxx).W | 8(1/1) 8(2/0) | | np nr | np nw
(xxx).L | 8(1/1) 12(3/0) | | np np nr | np nw
.L : | | | |
(An) | 12(1/2) 8(2/0) | | nr | np nw nW
(An)+ | 12(1/2) 8(2/0) | | nr | np nw nW
-(An) | 12(1/2) 10(2/0) | | n nR nr | np nw nW
(d16,An) | 12(1/2) 12(3/0) | | np nR nr | np nw nW
(d8,An,Xn) | 12(1/2) 14(3/0) | | n np nR nr | np nw nW
(xxx).W | 12(1/2) 12(3/0) | | np nR nr | np nw nW
(xxx).L | 12(1/2) 16(4/0) | | np np nR nr | np nw nW
-------------------------------------------------------------------------------
| Exec Time | Data Bus Usage
ADDA, SUBA | INSTR EA | 1st OP (ea) | INSTR
------------------+-----------------+---------------+--------------------------
<ea>,An : | | |
.B or .W : | | |
Dn | 8(1/0) 0(0/0) | | np nn
An | 8(1/0) 0(0/0) | | np nn
(An) | 8(1/0) 4(1/0) | nr | np nn
(An)+ | 8(1/0) 4(1/0) | nr | np nn
-(An) | 8(1/0) 6(1/0) | n nr | np nn
(d16,An) | 8(1/0) 8(2/0) | np nr | np nn
(d8,An,Xn) | 8(1/0) 10(2/0) | n np nr | np nn
(xxx).W | 8(1/0) 8(2/0) | np nr | np nn
(xxx).L | 8(1/0) 12(3/0) | np np nr | np nn
#<data> | 8(1/0) 4(1/0) | np | np nn
.L : | | |
Dn | 8(1/0) 0(0/0) | | np nn
An | 8(1/0) 0(0/0) | | np nn
(An) | 6(1/0) 8(2/0) | nR nr | np n
(An)+ | 6(1/0) 8(2/0) | nR nr | np n
-(An) | 6(1/0) 10(2/0) | n nR nr | np n
(d16,An) | 6(1/0) 12(3/0) | np nR nr | np n
(d8,An,Xn) | 6(1/0) 14(3/0) | n np nR nr | np n
(xxx).W | 6(1/0) 12(3/0) | np nR nr | np n
(xxx).L | 6(1/0) 16(4/0) | np np nR nr | np n
#<data> | 8(1/0) 8(2/0) | np np | np nn
-------------------------------------------------------------------------------
| Exec Time | Data Bus Usage
ADDX, SUBX | INSTR | INSTR
------------------+-----------------+------------------------------------------
Dy,Dx : | |
.B or .W : | 4(1/0) | np
.L : | 8(1/0) | np nn
-(Ay),-(Ax) : | |
.B or .W : | 18(3/1) | n nr nr np nw
.L : | 30(5/2) | n nr nR nr nR nw np nW
*******************************************************************************
Line 1010
Reserved
*******************************************************************************
*******************************************************************************
Line 1011
CMP, CMPA, CMPM, EOR
*******************************************************************************
-------------------------------------------------------------------------------
| Exec Time | Data Bus Usage
CMP | INSTR EA | 1st OP (ea) | INSTR
------------------+-----------------+---------------+--------------------------
<ea>,Dn : | | |
.B or .W : | | |
Dn | 4(1/0) 0(0/0) | | np
An | 4(1/0) 0(0/0) | | np
(An) | 4(1/0) 4(1/0) | nr | np
(An)+ | 4(1/0) 4(1/0) | nr | np
-(An) | 4(1/0) 6(1/0) | n nr | np
(d16,An) | 4(1/0) 8(2/0) | np nr | np
(d8,An,Xn) | 4(1/0) 10(2/0) | n np nr | np
(xxx).W | 4(1/0) 8(2/0) | np nr | np
(xxx).L | 4(1/0) 12(3/0) | np np nr | np
#<data> | 4(1/0) 4(1/0) | np | np
.L : | | |
Dn | 6(1/0) 0(0/0) | | np n
An | 6(1/0) 0(0/0) | | np n
(An) | 6(1/0) 8(1/0) | nR nr | np n
(An)+ | 6(1/0) 8(1/0) | nR nr | np n
-(An) | 6(1/0) 10(1/0) | n nR nr | np n
(d16,An) | 6(1/0) 12(2/0) | np nR nr | np n
(d8,An,Xn) | 6(1/0) 14(2/0) | n np nR nr | np n
(xxx).W | 6(1/0) 12(2/0) | np nR nr | np n
(xxx).L | 6(1/0) 16(3/0) | np np nR nr | np n
#<data> | 6(1/0) 8(2/0) | np np | np n
-------------------------------------------------------------------------------
| Exec Time | Data Bus Usage
CMPA | INSTR EA | 1st OP (ea) | INSTR
------------------+-----------------+---------------+--------------------------
<ea>,An : | | |
.B or .W : | | |
Dn | 6(1/0) 0(0/0) | | np n
An | 6(1/0) 0(0/0) | | np n
(An) | 6(1/0) 4(1/0) | nr | np n
(An)+ | 6(1/0) 4(1/0) | nr | np n
-(An) | 6(1/0) 6(1/0) | n nr | np n
(d16,An) | 6(1/0) 8(2/0) | np nr | np n
(d8,An,Xn) | 6(1/0) 10(2/0) | n np nr | np n
(xxx).W | 6(1/0) 8(2/0) | np nr | np n
(xxx).L | 6(1/0) 12(3/0) | np np nr | np n
#<data> | 6(1/0) 4(1/0) | np | np n
.L : | | |
Dn | 6(1/0) 0(0/0) | | np n
An | 6(1/0) 0(0/0) | | np n
(An) | 6(1/0) 8(1/0) | nR nr | np n
(An)+ | 6(1/0) 8(1/0) | nR nr | np n
-(An) | 6(1/0) 10(1/0) | n nR nr | np n
(d16,An) | 6(1/0) 12(2/0) | np nR nr | np n
(d8,An,Xn) | 6(1/0) 14(2/0) | n np nR nr | np n
(xxx).W | 6(1/0) 12(2/0) | np nR nr | np n
(xxx).L | 6(1/0) 16(3/0) | np np nR nr | np n
#<data> | 6(1/0) 8(2/0) | np np | np n
-------------------------------------------------------------------------------
| Exec Time | Data Bus Usage
CMPM | INSTR | INSTR
------------------+-----------------+------------------------------------------
(Ay)+,(Ax)+ | |
.B or .W : | 12(3/0) | nr nr np
.L : | 20(5/0) | nR nr nR nr np
-------------------------------------------------------------------------------
| Exec Time | Data Bus Usage
EOR | INSTR EA | 1st OP (ea) | INSTR
------------------+-----------------+---------------+--------------------------
Dn,<ea> : | | |
.B or .W : | | |
Dn | 4(1/0) 0(0/0) | | np
(An) | 8(1/1) 4(1/0) | nr | np nw
(An)+ | 8(1/1) 4(1/0) | nr | np nw
-(An) | 8(1/1) 6(1/0) | n nr | np nw
(d16,An) | 8(1/1) 8(2/0) | np nr | np nw
(d8,An,Xn) | 8(1/1) 10(2/0) | n np nr | np nw
(xxx).W | 8(1/1) 8(2/0) | np nr | np nw
(xxx).L | 8(1/1) 12(3/0) | np np nr | np nw
.L : | | |
Dn | 8(1/0) 0(0/0) | | np nn
(An) | 12(1/2) 8(2/0) | nR nr | np nw nW
(An)+ | 12(1/2) 8(2/0) | nR nr | np nw nW
-(An) | 12(1/2) 10(2/0) | n nR nr | np nw nW
(d16,An) | 12(1/2) 12(3/0) | np nR nr | np nw nW
(d8,An,Xn) | 12(1/2) 14(3/0) | n np nR nr | np nw nW
(xxx).W | 12(1/2) 12(3/0) | np nR nr | np nw nW
(xxx).L | 12(1/2) 16(4/0) | np np nR nr | np nw nW
*******************************************************************************
Line 1110
ASL, ASR, LSL, LSR, ROL, ROR, ROXL, ROXR
*******************************************************************************
-------------------------------------------------------------------------------
ASL, ASR, | Exec Time | Data Bus Usage
LSL, LSR, | |
ROL, ROR, | |
ROXL, ROXR | INSTR EA | 1st OP (ea) | INSTR
------------------+-----------------+---------------+--------------------------
Dx,Dy : | | |
.B or .W : | 6+2m(1/0) | | np n* n
.L : | 8+2m(1/0) | | np n* nn
#<data>,Dy : | | |
.B or .W : | 6+2m(1/0) | | np n n*
.L : | 8+2m(1/0) | | np nn n*
<ea> : | | |
.B or .W : | | |
(An) | 8(1/1) 4(1/0) | nr | np nw
(An)+ | 8(1/1) 4(1/0) | nr | np nw
-(An) | 8(1/1) 6(1/0) | n nr | np nw
(d16,An) | 8(1/1) 8(2/0) | np nr | np nw
(d8,An,Xn) | 8(1/1) 10(2/0) | n np nr | np nw
(xxx).W | 8(1/1) 8(2/0) | np nr | np nw
(xxx).L | 8(1/1) 12(3/0) | np np nr | np nw
NOTES :
.'m' is the shift count.
.'n*' should be replaced by m consecutive 'n'
*******************************************************************************
Line 1111
Reserved
*******************************************************************************
*******************************************************************************
EXCEPTION PROCESSING EXECUTION TIMES
*******************************************************************************
-------------------------------------------------------------------------------
| Periods | Data Bus Usage
----------------------+----------+---------------------------------------------
| |
Group 0 : | |
Address error | 50(4/7) | nn ns ns nS ns ns ns nS nV nv np n np
Bus error | 50(4/7) | nn ns ns nS ns ns ns nS nV nv np n np
/RESET | 40(6/0) | (n-)*5 nn nF nf nV nv np n np
Group 1 : | |
Trace | 34(4/3) | nn ns nS ns nV nv np n np
Interrupt | 44(5/3) | n nn ns ni n- n nS ns nV nv np n np
Privilege Violation | 34(4/3) | nn ns ns nS nV nv np n np
Illegal Instruction | 34(4/3) | nn ns ns nS nV nv np n np
Group 2 : | |
CHK Instruction | 40(4/3)+ | np (n-) nn ns ns nS nV nv np n np
Divide by Zero | 38(4/3)+ | nn nn ns ns nS nV nv np n np
TRAP instruction | 34(4/3) | nn ns ns nS nV nv np n np
TRAPV instruction | 34(5/3) | np ns nS ns nV nv np n np
NOTES:
.for CHK and Divide by zero, you must add effective address calculation time
to the period (according to instruction section above).
.for CHK, Divide by Zero, Illegal, Trap and TRAPV :
.The numbers of clock periods, for the "trap" lines, include the times for
all stacking, the vector fetch and the fetch of the first instruction of
THE handler routine.
.First are pushed on the stack the program counter low word (at sp-2) and
the status register (at sp-6) then, finally, the program counter high word
(at sp-4).
./RESET line indicates the time from when /RESET and /HALT are first sampled
as negated to when instruction execution starts. For a subsequent external
reset, asserting these signals for 10 clock cycles or longer is mandatory to
initiate reset sequence. During these 10 clock cycles the CPU is in halted
state (see below). However, an external reset signal that is asserted while
the CPU is executing a reset instruction is ignored. Since the processor
asserts the /RESET signal for 124 clock cycles during execution of a reset
instruction, an external reset should assert /RESET for at least 132 clock
periods.
*******************************************************************************
HALTED STATE
*******************************************************************************
-------------------------------------------------------------------------------
| Periods | Data Bus Usage
----------------------+----------+---------------------------------------------
| ?(0/0) | (n-)*
NOTES :
.this state is entered when a major failure happens and can only be exited
by reseting the CPU. Between these two events fit as many (n-) as necessary.
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