mirror of
https://github.com/TomNisbet/TommyPROM.git
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212 lines
5.1 KiB
C++
212 lines
5.1 KiB
C++
#include "Configure.h"
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#include "PromAddressDriver.h"
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PromDevice28C::PromDevice28C(unsigned long size, word blockSize, unsigned maxWriteTime, bool polling)
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: PromDevice(size, blockSize, maxWriteTime, polling)
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{
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}
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void PromDevice28C::begin()
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{
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// Define the data bus as input initially so that it does not put out a
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// signal that could collide with output on the data pins of the EEPROM.
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setDataBusMode(INPUT);
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// Define the EEPROM control pins as output, making sure they are all
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// in the disabled state.
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digitalWrite(OE, HIGH);
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pinMode(OE, OUTPUT);
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digitalWrite(CE, HIGH);
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pinMode(CE, OUTPUT);
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digitalWrite(WE, HIGH);
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pinMode(WE, OUTPUT);
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// This chip uses the shift register hardware for addresses, so initialize that.
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PromAddressDriver::begin();
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}
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// Write the special six-byte code to turn off Software Data Protection.
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void PromDevice28C::disableSoftwareWriteProtect()
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{
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disableOutput();
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disableWrite();
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setDataBusMode(OUTPUT);
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setByte(0xaa, 0x5555);
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setByte(0x55, 0x2aaa);
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setByte(0x80, 0x5555);
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setByte(0xaa, 0x5555);
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setByte(0x55, 0x2aaa);
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setByte(0x20, 0x5555);
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setDataBusMode(INPUT);
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disableChip();
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}
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// Write the special three-byte code to turn on Software Data Protection.
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void PromDevice28C::enableSoftwareWriteProtect()
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{
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disableOutput();
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disableWrite();
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setDataBusMode(OUTPUT);
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setByte(0xaa, 0x5555);
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setByte(0x55, 0x2aaa);
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setByte(0xa0, 0x5555);
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setDataBusMode(INPUT);
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disableChip();
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}
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// BEGIN PRIVATE METHODS
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//
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// Use the PromAddressDriver to set a 16 bit address in the two address shift registers.
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void PromDevice28C::setAddress(word address)
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{
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PromAddressDriver::setAddress(address);
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}
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// Read a byte from a given address
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byte PromDevice28C::readByte(word address)
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{
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byte data = 0;
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setAddress(address);
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setDataBusMode(INPUT);
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disableOutput();
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disableWrite();
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enableChip();
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enableOutput();
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data = readDataBus();
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disableOutput();
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disableChip();
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return data;
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}
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// Burn a byte to the chip and verify that it was written.
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bool PromDevice28C::burnByte(byte value, word address)
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{
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bool status = false;
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disableOutput();
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disableWrite();
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setAddress(address);
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setDataBusMode(OUTPUT);
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writeDataBus(value);
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enableChip();
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delayMicroseconds(1);
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enableWrite();
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delayMicroseconds(1);
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disableWrite();
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status = waitForWriteCycleEnd(value);
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disableChip();
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return status;
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}
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bool PromDevice28C::burnBlock(byte data[], word len, word address)
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{
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bool status = false;
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if (len == 0) return true;
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disableOutput();
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disableWrite();
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enableChip();
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// Write all of the bytes in the block out to the chip. The chip will
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// program them all at once as long as they are written fast enough.
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setDataBusMode(OUTPUT);
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for (word ix = 0; (ix < len); ix++)
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{
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setAddress(address + ix);
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writeDataBus(data[ix]);
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delayMicroseconds(1);
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enableWrite();
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delayMicroseconds(1);
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disableWrite();
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}
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status = waitForWriteCycleEnd(data[len - 1]);
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disableChip();
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return status;
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}
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bool PromDevice28C::waitForWriteCycleEnd(byte lastValue)
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{
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if (mSupportsDataPoll)
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{
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// Verify programming complete by reading the last value back until it matches the
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// value written twice in a row. The D7 bit will read the inverse of last written
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// data and the D6 bit will toggle on each read while in programming mode.
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//
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// Note that the max readcount is set to the device's maxReadTime (in uSecs)
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// divided by two because there are two 1 uSec delays in the loop. In reality,
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// the loop could run for longer because this does not account for the time needed
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// to run all of the loop code. In actual practice, the loop will terminate much
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// earlier because it will detect the end of the write well before the max time.
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setDataBusMode(INPUT);
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delayMicroseconds(1);
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for (int readCount = mMaxWriteTime * 1000 / 2; (readCount > 0); readCount--)
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{
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enableOutput();
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delayMicroseconds(1);
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byte b1 = readDataBus();
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disableOutput();
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enableOutput();
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delayMicroseconds(1);
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byte b2 = readDataBus();
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disableOutput();
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if ((b1 == b2) && (b1 == lastValue))
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{
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return true;
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}
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}
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return false;
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}
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else
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{
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// No way to detect success. Just wait the max write time.
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delayMicroseconds(mMaxWriteTime * 1000L);
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return true;
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}
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}
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// Set an address and data value and toggle the write control. This is used
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// to write control sequences, like the software write protect. This is not a
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// complete byte write function because it does not set the chip enable or the
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// mode of the data bus.
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void PromDevice28C::setByte(byte value, word address)
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{
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setAddress(address);
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writeDataBus(value);
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delayMicroseconds(1);
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enableChip();
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enableWrite();
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delayMicroseconds(1);
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disableWrite();
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disableChip();
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}
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