We're interested in which datapath control signals are active in each of the two phases.
All datapath control signals are latched at the end of phi2, i.e. the start of a full cycle. We describe their timing from that point onward, working broadly from left to right. (Which is right to left on Balazs' schematic)
External busses and signals
DOR is latched from DB during phi1, and driven in phi2, if a write is done (and, on the 6501, when the asynchronous DBE is on).
DL is latched during phi2, and then put on ADL, ADH, or DB on the next phi1 and phi2.
ABL and ABH can be loaded from ADL and ADH respectively during phi1.
R/#W is set during phi1 as well.
- ADL/ABL, ADH/ABH
- We already saw these. Effective on phi1.
- 0/ADL0, 0/ADL1, 0/ADL2, 0/ADH0, 0/ADH(1-7)
- These set the interrupt vector fetch address, and the zero page and stack high address. Effective on phi1 and phi2.
The register file
- Y/SB, X/SB, SB/Y, SB/X
- Move the X and Y registers from/to the SB. Effective on phi1.
- SB/S, S/S, effective on phi1.
- S/SB, S/ADL, effective on phi1 and phi2.
- The S register is actually two latches in series. This makes it possible to read a value from SB and write a value to ADL at the same time. On phi2, the value from the "in" latch is forwarded to the "out" latch (and onto the driven bus, if any).
(Note the two "tuning fork" structures, which have contacts either on the top or bottom, which select whether X, Y, A write SB and DB only during phi1, or slightly longer, during "not phi2". We think this might be a timing fix, or an option left open until after silicon showed which choice worked best)
- SB/ADD, 0/ADD, nDB/ADD, DB/ADD, ADL/ADD
- Two options for one side, three for the other. Effective on phi1.
ALU operation selection
- ANDS, EORS, ORS, 1/ADDC, SRS, SUMS, DAA, DSA
- Select the ALU operation. Effective on phi2 and the next phi1. During phi1 it will compute garbage.
(The overflow and carry out signals AVR and ACR are output from the ALU back to the control logic, latched at the end of phi2. The decimal carries are latched then as well).
ALU output register
The ALU output register (ADD) is written during phi2. The value can be used the next cycle:
- ADD/SB7, ADD/SB(0-6), ADD/ADL, effective on phi1 and phi2.
- The ADL output is for address calculations. For output to SB, the top bit is handled separately for rotate right instructions: the ALU always computes a zero there; by not driving it to the bus a one will be read.
- SB/AC, effective on phi1.
- Lines 1-3,5-7 are fed through the decimal adjust first, to finish the proper BCD add/subtract result if necessary, before writing it to the accumulator.
- AC/SB, AC/DB, effective on phi1
- write the A reg back to one of the busses.
The Program Counter
- ADH/PCH, PCH/PCH, PCL/PCL, ADL/PCL
- select whether to use the current PC, or take a new value from the internal address busses. Effective on phi1.
- PCH/DB, PCL/DB, PCH/ADH, PCL/ADL
- write the PC to one of the busses. Effective on phi1 and phi2. On phi1, it's the old value, on phi2, the new.
- I/PC, effective during phi2 and the next phi1
- increment the PC, or not.
- Write the flag values to the DB; effective on phi1 and phi2. The DB can be read to set the flag values as well; it is read during phi1.
- SB/DB, SB/ADH
- Connect two busses together. Effective on phi1 and phi2.
Several of the internal busses are driven high during phi2, as a sort of precharge. In fact commonly they are also driven by data signals during phi2, causing an intermediate voltage to appear on the bus.
A note on signal naming
- SSB, SADL, SBS, SS
will be found as
As Balazs used another naming scheme in his very useful but incomplete schematic, we should also cross-reference his names.
|R1x7||Y/SB||dpc0_YSB||drive sb from y|
|R1x6||SB/Y||dpc1_SBY||load y from sb|
|R1x5||X/SB||dpc2_XSB||drive sb from x|
|R1x4||SB/X||dpc3_SBX||load x from sb|
|R1x2||S/SB||dpc4_SSB||drive sb from stack pointer|
|R1x1||S/ADL||dpc5_SADL||drive adl from stack pointer|
|R1x3||SB/S||dpc6_SBS||load stack pointer from sb|
|?||S/S||dpc7_SS||recirculate stack pointer|
|R2x1||notDB/ADD||dpc8_nDBADD||alu b side: select not-idb input|
|R2x2||DB/ADD||dpc9_DBADD||alu b side: select idb input|
|R2x3||ADL/ADD||dpc10_ADLADD||alu b side: select adl input|
|R2x4 (??)||SB/ADD||dpc11_SBADD||alu a side: select sb|
|R2x5||0/ADD||dpc12_0ADD||alu a side: select zero|
|R2x6||ORS||dpc13_ORS||alu op: a or b|
|R2x7||SRS||dpc14_SRS||alu op: logical right shift|
|R2x8||ANDS||dpc15_ANDS||alu op: a and b|
|R2x9||EORS||dpc16_EORS||alu op: a xor b (?)|
|R2x12||SUMS||dpc17_SUMS||alu op: a plus b (?)|
|?||DAA||dpc18_#DAA||decimal related (inverted)|
|R2x14,7||ADD/SB(7)||dpc19_ADDSB7||alu to sb bit 7 only|
|R2x14||ADD/SB(0-6)||dpc20_ADDSB06||alu to sb bits 6-0 only|
|R2x15||ADD/ADL||dpc21_ADDADL||alu to adl|
|R2x20,6||DSA||dpc22_#DSA||decimal related/SBC only (inverted)|
|R3x4||SB/AC||dpc23_SBAC||(optionally decimal-adjusted) sb to acc|
|R3x1||AC/SB||dpc24_ACSB||acc to sb|
|R3x3||SB/DB||dpc25_SBDB||sb pass-connects to idb (bi-directionally)|
|R3x2||AC/DB||dpc26_ACDB||acc to idb|
|R3x0||SB/ADH||dpc27_SBADH||sb pass-connects to adh (bi-directionally)|
|R3x5,0||0/ADH0||dpc28_0ADH0||zero to adh0 bit0 only|
|R3x5||0/ADH(1-7)||dpc29_0ADH17||zero to adh bits 7-1 only|
|R4x2||ADH/PCH||dpc30_ADHPCH||load pch from adh|
|R4x3||PCH/PCH||dpc31_PCHPCH||load pch from pch incremented|
|R4x4||PCH/ADH||dpc32_PCHADH||drive adh from pch incremented|
|R4x1||PCH/DB||dpc33_PCHDB||drive idb from pch incremented|
|!!||PCLC||dpc34_PCLC||pch carry in and pcl FF detect?|
|Carry||PCHC||dpc35_PCHC||pcl 0x?F detect - half-carry|
|notCarry||I/PC||dpc36_#IPC||pcl carry in (inverted)|
|R5x1||PCL/DB||dpc37_PCLDB||drive idb from pcl incremented|
|R5x4||PCL/ADL||dpc38_PCLADL||drive adl from pcl incremented|
|R5x3||PCL/PCL||dpc39_PCLPCL||load pcl from pcl incremented|
|R5x2||ADL/PCL||dpc40_ADLPCL||load pcl from adl|
|Dkx2||DL/ADL||dpc41_DL/ADL||pass-connect adl to mux node driven by idl|
|Dkx3||DL/ADH||dpc42_DL/ADH||pass-connect adh to mux node driven by idl|
|Dkx1||DL/DB||dpc43_DL/DB||pass-connect idb to mux node driven by idl|