Difference between revisions of "Z80-DART/Z80-SIO chip"
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+ | == I/O Ports == | ||
Used in standard RS232 interfaces for the CPC ([[Amstrad_Serial_Interface]]), mapped to following Ports: | Used in standard RS232 interfaces for the CPC ([[Amstrad_Serial_Interface]]), mapped to following Ports: | ||
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FADFh Amstrad RS323 Z8470 (Z80 DART) Channel B Control/Status (R/W) | FADFh Amstrad RS323 Z8470 (Z80 DART) Channel B Control/Status (R/W) | ||
− | Chip Variants (DART, SIO/0, SIO/1, SIO/2, SIO/3, SIO/4) | + | == Chip Variants (DART, SIO/0, SIO/1, SIO/2, SIO/3, SIO/4) == |
Most CPC interfaces should contain the DART chips. Eventually some might use the SIO chips (which are including some additional features). | Most CPC interfaces should contain the DART chips. Eventually some might use the SIO chips (which are including some additional features). | ||
Revision as of 18:04, 8 January 2010
Contents
I/O Ports
Used in standard RS232 interfaces for the CPC (Amstrad_Serial_Interface), mapped to following Ports:
FADCh Amstrad RS323 Z8470 (Z80 DART) Channel A Data (R/W) FADDh Amstrad RS323 Z8470 (Z80 DART) Channel A Control/Status (R/W) FADEh Amstrad RS323 Z8470 (Z80 DART) Channel B Data (R/W) FADFh Amstrad RS323 Z8470 (Z80 DART) Channel B Control/Status (R/W)
Chip Variants (DART, SIO/0, SIO/1, SIO/2, SIO/3, SIO/4)
Most CPC interfaces should contain the DART chips. Eventually some might use the SIO chips (which are including some additional features).
- Zilog Z8470 - Z80 DART (Dual-channel Asynchronous Receiver Transmitter)
- Zilog Z8440 - Z80 SIO (Dual-channel Serial Input/Output Controller)
Note: Five different variants of the SIO chips exist: types 0/1/2 are 40pin DIP chips with slightly different features/pinouts, types 3 (QFP package) and 4 (PLCC package) are 44pin chips, both combining all features of the three 40pin chips.
Control/Status Registers
In the default state, reads/writes on the Control/Status port are accessing the RR0/WR0 registers. After writing a non-zero index value "n" to Bit0-2 of WR0, the next read/write operation on the Control/Status port will access the corresponding RRn/WRn register.
Control Registers
WR0 Write register 0
0-2 Register Index (0-5 for write, 0-2 for read) (SIO: 0-7 for write) 3-5 Command (0..7) 0=No action 1=DART: Reserved / SIO: Send Abort (SDLC) 2=Reset Ext/Status Interrupts 3=Reset Channel 4=Enable Interrupt on next Rx character 5=Reset Tx Int pending 6=Reset Error 7=Return from Int (Ch-A only) 6-7 CRC Reset Code (DART: Reserved, should be 0) (SIO: 0..3) 0=No action 1=DART: Reserved, SIO: Reset Receive CRC Checker 2=DART: Reserved, SIO: Reset Transmit CRC Generator 3=DART: Reserved, SIO: Reset Tx Underrun/End of Message latch
WR1 Write register 1
0 External Interrupts Enable 1 Tx Interrupt Enable 2 Status Affects Vector (Channel B only) (see WR2/RR2) 3-4 Rx Interrupt Mode (0..3) 0=None 1=On first Rx char 2=On all Rx chars (Parity affects vector) 3=On all Rx chars (Parity does not affect vector) 5 Wait/Ready on Receive/Transmit 6 Wait/Ready Function 7 Wait/Ready Enable
WR2 Write register 2 - Interrupt Vector (Channel B only)
0-7 Interrupt Vector (Bit1-3=no effect when WR1.Bit2=1, see RR2 for details)
WR3 Write register 3 - Rx Control
0 Rx Enable 1 DART: Reserved (must be 0), SIO: Sync Char Load Inhibit 2 DART: Reserved (must be 0), SIO: Address Search Mode 3 DART: Reserved (must be 0), SIO: Receiver CRC Enable 4 DART: Reserved (must be 0), SIO: Enter Hunt Phase 5 Enable automatic hardware handshaking using RTS/CTS 6-7 Rx data bits (0..3 = 5bits, 7bits, 6bits, 8bits)
WR4 Write register 4 - Rx/Tx Control
0 Rx/Tx Parity bit (0=None, 1=Enable) 1 Rx/Tx Parity type (0=Odd, 1=Even) 2-3 Rx/Tx Stop bits (0..3=Reserved, 1bit, 1.5bits, 2bits) (SIO: 0=Sync Modes) 4-5 DART: Reserved (must be 0), SIO: Sync Mode (enabled when Bit2-3=zero) 0=8bit SYNC Character (SIO only, not DART) 1=16bit SYNC Character (SIO only, not DART) 2=SDLC Mode (0111 1110 Flag) (SIO only, not DART) 3=External SYNC Mode (SIO only, not DART) 6-7 Rx/Tx DART clock mode (0..3=X1, X16, X32, X64)
WR5 Write register 5 - Tx Control
0 DART: Reserved (must be 0), SIO: Tx CRC Enable 1 RTS enabled/disabled 2 DART: Reserved (must be 0), SIO: Rx/Tx CRC Type (0=SDLC, 1=CRC-16) 3 Tx Enable 4 Tx Send break 6-5 Tx data bits (0..3 = 5bits, 7bits, 6bits, 8bits) 7 DTR enabled/disabled
WR6 Write register 6 - Sync Character or SDLC address (Z80 SIO only)
0-7 DART: N/A, SIO: LSBs of 8bit/16bit sync char, or SDLC address
WR7 Write register 7 - Sync Character or SDLC flag (Z80 SIO only)
0-7 DART: N/A, SIO: MSBs of 16bit sync char, or SDLC flag (should be 7Eh)
Status Registers
RR0 Read register 0 (General Status Bits)
0 Rx character available (3-stage RXFIFO not emtpy) 1 interrupt pending (Channel A only) (always 0 on Channel B) 2 Tx buffer empty (1-stage RXFIFO emtpy) 3 DCD (carrier detect) 4 DART: RI (ring indicate), SIO: Sync/Hunt 5 CTS 6 DART: Not used, SIO: Transmit Underrun/End of Message 7 break received, SIO: Break/Abort
RR1 Read register 1 (Used with Special Receive Condition Mode)
0 Tx all sent (1-stage TXFIFO and TX-shift register empty) 1-3 DART: Not used, SIO: Residue Codes 4 Rx parity error 5 Rx overrun error 6 framing error SIO: CRC or Framing Error 7 DART: Not used, SIO: End of Frame
RR2 Read register 2 (Interrupt Vector) (Channel B only)
0-7 Interrupt Vector (as set via WR2) (Bit1-3=variable when WR1.Bit2=1) 0 Channel B Transmit Buffer Empty (1-stage TXFIFO empty) 1 Channel B External/Status Change 2 Channel B Receive Character Available (3-stage RXFIFO not empty) 3 Channel B Parity/Rx Overrun/Framing Error, or End-of-Frame (SDLC) 4-7 Same as above, but for Channel A
RR3-7 Read registers 3..7 - Reserved
- Reserved / don't use
Data Registers
Rx Data Register
has a 3-stage FIFO, plus 1 rx shift register (4-stages in total)
Tx Data Register
has a 1-stage FIFO, plus 1 tx shift register (2-stages in total)
Interrupt Notes
Interrupts can occur on both channel A and channel B, certain bits (like interrupt enable flags) can be configured separately for each channel, other bits are shared for both channels: the interrupt vector can be accessed via RR2/WR2 of channel B only the interrupt pending flag can be read via RR0.Bit1 of channel A only
No info if the interrupt signal is connected to the CPC hardware, probably... it isn't?