Difference between revisions of "ECLair"

From Hackstrich
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| colspan=4, align=center | '''Level Sensitive Signals'''
 
| colspan=4, align=center | '''Level Sensitive Signals'''

Revision as of 23:17, 25 December 2012

ECLair is a long-term project to build an ECL minicomputer.

Project Status

  • 2012-12-25: Worked out details on the paging system, started schematicizing it.
  • 2012-12-23: Worked out the right way to fix the sequencing issue/dependency between microcode signals, now the level-sensitive signals (bits 0-23) latch first, then the edge-sensitive signals (bits 24-63) latch, then the edge-sensitive signals are reset back to 0 so they don't mis-trigger when the level-sensitive signals change again on the next cycle. This means all edge-sensitive signals need to be active-high, but that hasn't been an issue so far.
  • 2012-12-22: Hacked on the sequencing issue more, no real progress.
  • 2012-12-21: Reordered microcode bits into 24 bits for edge-sensitive signals and 40 for level-sensitive signals. Redesigned the microcode sequencer to use a latch and an always-populated next_addr bit field rather than a counter, which solves many problems around jumping and runt cycles. Still don't have sequencing of the two classes of microcode bits worked out, it's proving a much harder problem than I'd expected.
  • 2012-12-20: Implemented realistic propagation delays for most parts (main EPROM and ALU not done yet), and fixed a bunch of bugs related to previous lack of delays. Have a hacked-in delay for cs_jump right now, next step is to split the microcode into 24 "edge-sensitive signal bits" and 40 "level-sensitive signal bits", and clock the former slightly after the latter. This will avoid needing two separate microcode instructions to set up level-sensitive signals then trigger the edge-sensitive ones. Will mean a complete reorganization order-wise of the microcode though.
  • 2012-12-19: Finished implementing 8/16-bit width selection and got the bugs worked out. Now have 8-bit and 16-bit immediate loads, and 8-bit don't trash the other 8 bits of the destination register. Still need to get 8-bit high-byte load implemented. Next step though is probably to rethink the hold_last function in the microcode assembler, should probably make it more intelligent to only hold level sensitive signals and leave the edge-sensitive ones out.
  • 2012-12-18: Half-implemented 8/16-bit width selection using a microcode bit. Doesn't work yet.
  • 2012-12-17: Implemented a data path from IR[7:6] to the register latch signals, so that all register-related operations can be simplified in microcode. Moved the ldi* instructions to use this new path, everything is tested and working. Next step is probably to get the 8/16-bit split working, so that 8-bit operations don't erase the other byte of the word.
  • 2012-12-16: MDR-XY data path implemented, Load Immediate 8-bit values to A and B instructions written, add 16-bit A=A+B written, all working.
  • 2012-12-15: Found bug in the datasheet of the MC10H181, fixed it and now the ALU checks out completely. Started integrating it into the CPU. Next step is to finish the MDR-XY data path so that Load Immediate instruction can be implemented, then Add can be implemented/tested.
  • 2012-12-14: Verilog transcription of ALU almost complete, but malfunctioning in the carry logic of the second bit. Will be using MC10H181 w/ MC10H179 CLA generator.
  • 2012-12-09: Started working on ALU design/verilog transcription.
  • 2012-12-08: Added decode support for ROM/RAM/device memory, got everything working so that now an instruction is fetched from ROM at startup and is jumped to in microcode. Started work on the X/Y registers, and started work on a microcode generator so I can stop typing in individual bits.
  • 2012-12-05: Got the part that's been diagrammed into Verilog and working. Now fetches instructions (from a constant right now, not RAM yet) and does jumps to their location in microcode.
  • 2012-12-04: Started the logical diagram and the microcode layout.
  • 2012-12-01/02: Spent the weekend reading Bit-Slice Microprocessor Design.
  • 2012-11-24: Basic ideas/architecture starting to get put together.

Architecture Overview

  • Many blinkie lights and switches on the front panel
  • MECL-based (10KH/10KE levels/speeds)
  • 25MHz main clock (hopefully)
  • 8-bit data width
  • 24-bit physical address, 16-bit virtual address
  • DMA support (for front panel)
  • Microcoded, running control store in SRAM for speed
    • Unless I can find equally-fast EPROMs
    • Copied to SRAM from EPROM before the system releases reset on powerup

Memory Map

  • 24bit / 16MB address space
  • 14MB for RAM, 1MB for ROM, 1MB for memory-mapped devices
  • 0x000000 - 0xEFFFFF - ROM
  • 0x100000 - 0x0FFFFF - RAM
  • 0x200000 - 0x1FFFFF - RAM
  • 0x300000 - 0x2FFFFF - RAM
  • 0x400000 - 0x3FFFFF - RAM
  • 0x500000 - 0x4FFFFF - RAM
  • 0x600000 - 0x5FFFFF - RAM
  • 0x700000 - 0x6FFFFF - RAM
  • 0x800000 - 0x7FFFFF - RAM
  • 0x900000 - 0x8FFFFF - RAM
  • 0xA00000 - 0x9FFFFF - RAM
  • 0xB00000 - 0xAFFFFF - RAM
  • 0xC00000 - 0xBFFFFF - RAM
  • 0xD00000 - 0xCFFFFF - RAM
  • 0xE00000 - 0xDFFFFF - RAM
  • 0xF00000 - 0xFFFFFF - Devices

Page Table

  • 64 process slots available in page table
  • Each process gets access to 64 pages
  • Each page is 1K long
  • Bit 15 (MSB) in page table entry is 1 if page is present
  • Bit 14 is in page table entry 1 if page is writable
  • Address Routing
    • Virtual address - 16 bits
      • Bits 15-10 - Page Select - passed to page table address bits 11-6
      • Bits 9-0 - Address - passed to ADDR LSB as-is
    • Physical address - 24 bits
      • Bits 23-10 - Page - passed from page table data bits 13-0
      • Bits 9-0 - Address - passed from virtual address bits 9-0

Microcode Layout

Bit # Width Function Details
Edge Sensitive Signals
0 1 AVAILABLE
1 1 MDR Load Low Byte Latches data or Z (determined by bit 11) into low byte of MDR
2 1 MDR Load High Byte Latches data or Z (determined by bit 11) into high byte of MDR
3 1 MAR Load MAR latch load (source specified by bit 10)
4 1 IR Load IR latch load from data bus
5 1 PC Increment Increment PC by 1
6 1 PC Load PC counter load from Z
7-9 3 Register Load from Z 000 - None
001 - A
010 - B
011 - C
100 - D
101 - SP
111 - Value from IR[6..7] (only A-D)
10 1 X Load
11 1 Y Load
12 1 Z Load
13 1 PID Load
Level Sensitive Signals
24 1 AVAILABLE
25-32 8 Next CS Address 0 = Use IR
33 1 MAR Source low = Z, high = PC
34 1 MDR Source low = Z, high = data bus
35 1 ALU Mode 0 = Arithmetic, 1 = Logic
36-39 4 ALU Operation 1111 - Z=X
40-42 3 X/Y Register Source 000 - Immediate Zero
001 - A
010 - B
011 - C
100 - D
101 - SP
110 - MAR
111 - MDR
43 1 RAM Read
44 1 RAM Write
45 1 Operation Width 0 = 8-bit, 1 = 16-bit