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Parallel I/O

Parallel I/O. Introduction. This section focuses on performing parallel input and output operations on the 68HC11 3 operation types – Simple, blind data transfers – Strobed transfers – Transfers with handshaking Contd.

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Parallel I/O

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  1. Parallel I/O

  2. Introduction This section focuses on performing parallel input and output operations on the 68HC11 3 operation types – Simple, blind data transfers – Strobed transfers – Transfers with handshaking Contd

  3. Look at examples of each transfer operation Reading: – Text, Chap 9: » Read: 9.1, 9.4-9.8.1 » Scan: 9.2, 9.3 – E9: Section 6 SEGMENT code

  4. Recall the block diagram of the 68HC11

  5. Simple I/O operations These I/O operations take place under the direction of the processor Operations are performed without regard to the status of the I/O port – the port is always assumed to be "ready“ contd

  6. Since the current status of the port is not known, it is possible to – Read the same value in more than once on input operations – Overwrite the current value in an output port that is waiting to be transferred "Good" examples of use: – Input initialization values from a port -- port is in known state as a result of system reset – I/O when overwrites or multiple reads don't matter -- writing to the hex display’s port in the labs, for example

  7. Simple I/O example -- keypad interface – Consider the simple 12-key keypad shown below

  8. High-level procedure to detect key closures • » Drive Row 1 input low • » Read Columns -- any =0? • » Repeat this process for all remaining rows until • “see” a column=0 • » If no column=0, then no key has been depressed • CONTD

  9. Knowing which row and column were low permits • you to calculate the key number that was pressed • » Can use a simple equation (similar to the • approach of Listing 9.5) • – Key# = col# + (3*row#) -3 • – Assumes row and col numbers start with 1 • – Listing 9.5 is for 2-of-7 keyboard! • » Or use a lookup table (similar to the approach in • Listing 9.10) • – Assumes row and col use same port (port C

  10. – Key debounce • » Need to avoid the multiple make/break closures • associated with key bounce • » “Simple” approach is ID the key closed and then • wait for a period of time to see if the key is still • closed (therefore not bouncing) • » Then and only then, return the key value • » The waiting period will vary from switch to • switch -- 10s to 100s of ms • CONTD

  11. – How will the system react if you hold a key down for • a long time? • » Should an action (in response to a key closure) be • repeated over and over despite there being only 1 • switch closure “action” • » Should the action take place only once and then • wait for the key “break” before recognizing • another closure? • » Consider routines to recognize key makes and • breaks

  12. Strobed I/O This method of performing I/O operations uses a control line, the strobe, to notify the receiving unit of the availability of data at its (input) port CONTD

  13. Strobed I/O • The process: • – Device performing the write places data onto data • bus (its output port) • – Strobe signal is asserted (for 2 cycles in 68HC11) Contd…

  14. – Strobe signal causes an I/O interrupt to occur or a flag to be set -- in either case the receiving device is signaled that new data has arrived – It is up to the receiving device to read the new data at its input port in a "timely" fashion

  15. Problem • – If a second data item arrives at the input port and is • strobed in (latched) before the input device has read • the first item, the first item will be overwritten and • lost

  16. 68HC11 register support for strobed I/O • – DDRC -- data direction register for port C • – PORTCL -- port C input latch -- data is latched • on STRA edge • – PORTC -- input pins for port C -- not latched • – PORTB -- latched output data port B -- outputs • data using STRB • – PIOC -- parallel I/O control register • – PORTD -- bits 6 and 7 are STRA and STRB

  17. Strobed input operations using port C – Data is placed at the input pins of port C – STRA is asserted by peripheral device, causing » Data to be latched into PORTCL » STAF flag to be asserted » Interrupt initiated, if interrupts are enabled – Data is read into to processor from PORTCL – To clear STAF, read PIOC first then PORTCL

  18. Strobed Output – Peripheral device is connected to Port B – When the MCU writes to Port B, . . . » Data is placed on Port B pins » STRB is asserted for 2 clock cycles – Peripheral device should use STRB to latch the data – STRB can be configured as active-high or active-low

  19. Handshaking I/O • In this mode, the sending and receiving • devices exchange positive sent/received • signals to one another • – Insures that each transmitted word is received • before the next word is transmitted

  20. Transfers can occur in either the pulsed or • the interlocked method • – Pulsed input operations • » Peripheral pulses STRA to indicate that data • is present • » When 68HC11 reads the data (from • PORTCL), it automatically generates an • acknowledgment strobe on STRB for 2 • Cycles • CONTD SHR

  21. » This mode is selected by initializing the PLS • bit (bit 2 of the PIOC) to 1 • – Interlocked input operations • » Here, STRB acts as a READY signal • » Asserted = 68HC11 ready to receive data • » Negated = 68HC11 is not ready -- do not • send data now SAR

  22. Output operations with handshaking • – Port C is used for output handshake operations, along • with STRB and STRA • – STRB is the output "data available" strobe • – STRA is the acknowledgment / input ready strobe • line • – PIOC bit 3, OIN, set to 1 for output operations

  23. – Pulsed operations • » 68HC11 writes data to PORTCL and • automatically asserts STRB for 2 cycles • » Peripheral device reads data upon receipt of the • STRB strobe • » Peripheral asserts its READY line (68HC11's • input STRA line) to signal receipt of data • » PIOC bit 2, PLS set to 1 for pulsed mode • – Interlocked mode • » Upon writing data to PORTCL, STRB is asserted • » STRB negated only upon ACK

  24. Handshaking example: • Centronics parallel printer interface • – The "Centronics" definition of a printer port • interface has become the standard parallel • printer interface

  25. – Using the 68HC11 as the output device (to the • printer) requires a software interface • (note the errors in the text!)

  26. ; I/O service routines to control "Centronics" interface ; part of printer control system. Also demonstrates ; software handshaking because port C configured ; for simple input strobe. Main program would call ; service routines to store input data in a RAM print ; buffer for later output to print mechanism. CONTD

  27. ;;; CONNECTIONS ; Computer Printer Port MCU as Printer Controller ; DATA -----------------> Port C ; STB -----------------> STRA ; ACK <----------------- PD2 ; BUSY <----------------- PD CONTD

  28. PIOC CONFIGURATION DETAILS ; INVB=x STRB not used ; EGA=0 STRA/ACK active on falling edge ; PLS=x Pulsed/Interlocked not used ; OIN=x Output/input handshake not used ; HNDS=0 Simple strobe mode ; CWOM=0 Normal CMOS outputs ; STAI=0 Disable interrupt ; STAF=x Sets on falling STRA line ; To clear STAF, read PIOC, then read PORTCL

  29. ORG $100 ; Subroutine INIT_INTRF ; Initializes parallel interface part ; of printer upon power-up reset. ; Calling Registers: ; IX = Address of register block ; No Return Registers except CCR affected CONTD

  30. INIT_INTRF: psha ; preserve registers ldaa PIOC,X ; clear STAF if set ldaa PORTCL,X bset PORTD,X $0C ; PD2, 3 output and bset DDRD,X $0C ; BUSY, ACK high ldaa #00 ; configure PIOC staa PIOC,X pula ; restore registers rts ; and return

  31. ; Subroutine INPUT ; Reads parallel port to get byte sent ; by an external device ; Calling registers ; IX = Address of register block ; Return registers ; ACCA = input data byte ; CCR affected

  32. INPUT: • bclr PORTD,X $0C ; BUSY low and pulse ACK • nop ; for approx 5 us (E=2MHz) • bset PORTD,X $04 ; set ACK high again • CIN: • brclr PIOC,X $80 CIN ; wait for STB pulse • ldaa PORTCL,X ; get input and clear STAF • bset PORTD,X $08 ; set BUSY high • rts ; return

  33. Parallel subsystem summary • Ports B and C are available for I/O only in the • single chip mode -- can be replaced by the PRU • when in expanded mode • Port A • – 3 input, 3 output, 2 bi-directional pins • – Bits DDRA7 and DDRA3 in PACTL set direction • for A7 and A3

  34. Port C • – Data register is PORTC • – Latched register is PORTCL • – Each bit is bi-directional • » Direction set using register DDRC • Port D • – 6 bi-directional pins, directions set by DDRD • – Pin 6 = STRA, Pin 7 = STRB • » These pins become AS and R/W* in expanded multiplexed • mode

  35. Port E • – 8-bit input only • Conditions on reset • – All data direction bits set to 0 (input) • – Output port bits set to 0 • – Input port bits high impedance

  36. Strobed I/O • – Strobed output via Port B, strobed input via Port C • – Detected edge on STRA causes input data to be • latched in PORTCL and flag set (and interrupt, if • enabled) • – Writing data to Port B also pulses STRB • Handshake I/O • – Port C used for either input or output operation • – Input: read data from PORTCL • – Output: write data to PORTCL

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