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187 lines
5.0 KiB
187 lines
5.0 KiB
/* Ian Fleet 2018 |
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All files, software, schematics and designs are provided as-is with no warranty. |
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All files, software, schematics and designs are for experimental/hobby use. |
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Under no circumstances should any part be used for critical systems where safety, |
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life or property depends upon it. You are responsible for all use. |
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You are free to use, modify, derive or otherwise extend for your own purposes |
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*/ |
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// This example emulates a DS2413 device on an Arduino UNO or ATTINY85 |
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// note : physical DS2413 devices found in 2018 are often clones with |
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// a device code different to the Maxim datasheet |
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#include "Arduino.h" |
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#include "OneWireSlave.h" |
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#include "comptime.h" |
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// This is the pin that will be used for one-wire data |
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// On Arduino Uno, you can use pin 2 or pin 3 |
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Pin oneWireData(2); // PB2 only attiny85 pin with rising/falling interrupts |
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//Pin led(0); |
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// This sample emulates a DS2413 device , so we start by defining the available commands |
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const byte DS2413_FAMILY_ID = 0x3A; // Maxim DS2413 device code |
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const byte CLONE_FAMILY_ID = 0x85; // clone device code |
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const byte DS2413_ACCESS_READ = 0xF5; |
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const byte DS2413_ACCESS_WRITE = 0x5A; |
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const byte DS2413_ACK_SUCCESS = 0xAA; |
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// generate unique id |
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const byte owROM[7] = { DS2413_FAMILY_ID, SERIAL_NUMBER}; |
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// will be calculated in begin:---------------^^^^ |
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// or use fixed id - make sure it doesn't conflict with another device |
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//const byte owROM[7] = { 0x3A, 0x00, 0x55, 0xAA, 0x00, 0x11, 0x22 }; |
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#define PIOA 3 // (pin 3) |
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#define PIOB 4 // (pin 4) |
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uint8_t latch = 0; |
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uint8_t statusbyte1 = 0; |
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uint8_t statusbyte2 = 0; |
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enum DeviceState |
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{ |
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DS_WaitingReset, |
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DS_WaitingCommand, |
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DS_WaitingStatus1, |
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DS_WaitingStatus2, |
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}; |
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volatile DeviceState state = DS_WaitingReset; |
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// scratchpad |
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volatile byte scratchpad[2]; |
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volatile byte response[2]; |
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// This function will be called each time the OneWire library has an event to notify (reset, error, byte received) |
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void owReceive(OneWireSlave::ReceiveEvent evt, byte data); |
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////////////////////////////////////////// |
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void setup() |
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{ |
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// led.outputMode(); |
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// led.writeLow(); |
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// OSCCAL = 85; |
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// Setup the OneWire library |
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OWSlave.setReceiveCallback(&owReceive); |
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OWSlave.begin(owROM, oneWireData.getPinNumber()); |
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} |
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////////////////////////////////////////// |
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void loop() |
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{ |
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delay(10); |
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cli();//disable interrupts |
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// Be sure to not block interrupts for too long, OneWire timing is very tight for some operations. 1 or 2 microseconds (yes, microseconds, not milliseconds) can be too much depending on your master controller, but then it's equally unlikely that you block exactly at the moment where it matters. |
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// This can be mitigated by using error checking and retry in your high-level communication protocol. A good thing to do anyway. |
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sei();//enable interrupts |
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} |
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////////////////////////////////////////// |
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static uint8_t getstatus() { |
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uint8_t c = 0; |
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if (latch & 0x01) c |= 0x02; |
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if (digitalRead(PIOA)) c |= 0x01; |
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if (latch & 0x02) c |= 0x08; |
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if (digitalRead(PIOB)) c |= 0x04; |
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uint8_t x = (~c) << 4; |
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return x + c; |
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} |
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////////////////////////////////////////// |
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static void port(int PIO, bool stat) { |
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if (stat) { |
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digitalWrite(PIO, HIGH); |
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pinMode(PIO, INPUT); |
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} else { |
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pinMode(PIO, OUTPUT); |
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digitalWrite(PIO, LOW); |
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} |
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} |
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////////////////////////////////////////// |
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static void set(uint8_t val) { |
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latch = val; |
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port(PIOA, latch & 1); |
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port(PIOB, latch & 2); |
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//TODO copy latch to EEPROM |
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} |
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////////////////////////////////////////// |
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void owReceive(OneWireSlave::ReceiveEvent evt, byte data) |
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{ |
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switch (evt) |
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{ |
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case OneWireSlave::RE_Byte: |
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switch (state) |
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{ |
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case DS_WaitingCommand: |
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switch (data) |
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{ |
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case DS2413_ACCESS_WRITE: |
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state = DS_WaitingStatus1; |
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break; |
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case DS2413_ACCESS_READ: |
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state = DS_WaitingReset; |
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scratchpad[0] = getstatus(); |
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OWSlave.beginWrite((const byte*)scratchpad, 1, 0); |
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break; |
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//case : |
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// break; |
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} |
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break; |
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case DS_WaitingStatus1: |
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statusbyte1 = data; |
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state = DS_WaitingStatus2; |
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break; |
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case DS_WaitingStatus2: |
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statusbyte2 = data; |
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if (statusbyte1 != ~statusbyte2) { |
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set(statusbyte1); |
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response[0] = DS2413_ACK_SUCCESS; |
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} else { |
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response[0] = 0x11; // mark error - real DS2413 does not do this |
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} |
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response[1] = getstatus(); |
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OWSlave.beginWrite((const byte*)response, 2, 0); |
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state = DS_WaitingCommand; |
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break; |
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} |
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break; |
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case OneWireSlave::RE_Reset: |
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state = DS_WaitingCommand; |
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break; |
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case OneWireSlave::RE_Error: |
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state = DS_WaitingReset; |
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break; |
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} |
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}
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