549 lines
17 KiB
C
549 lines
17 KiB
C
/*
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Adaptation of Paul Stoffregen's One wire library to the NodeMcu
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The latest version of this library may be found at:
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http://www.pjrc.com/teensy/td_libs_OneWire.html
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Permission is hereby granted, free of charge, to any person obtaining
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a copy of this software and associated documentation files (the
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"Software"), to deal in the Software without restriction, including
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without limitation the rights to use, copy, modify, merge, publish,
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distribute, sublicense, and/or sell copies of the Software, and to
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permit persons to whom the Software is furnished to do so, subject to
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the following conditions:
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The above copyright notice and this permission notice shall be
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included in all copies or substantial portions of the Software.
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THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND,
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EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF
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MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND
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NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE
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LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION
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OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION
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WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
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Much of the code was inspired by Derek Yerger's code, though I don't
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think much of that remains. In any event that was..
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(copyleft) 2006 by Derek Yerger - Free to distribute freely.
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The CRC code was excerpted and inspired by the Dallas Semiconductor
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sample code bearing this copyright.
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//---------------------------------------------------------------------------
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// Copyright (C) 2000 Dallas Semiconductor Corporation, All Rights Reserved.
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//
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// Permission is hereby granted, free of charge, to any person obtaining a
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// copy of this software and associated documentation files (the "Software"),
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// to deal in the Software without restriction, including without limitation
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// the rights to use, copy, modify, merge, publish, distribute, sublicense,
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// and/or sell copies of the Software, and to permit persons to whom the
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// Software is furnished to do so, subject to the following conditions:
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//
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// The above copyright notice and this permission notice shall be included
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// in all copies or substantial portions of the Software.
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//
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// THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS
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// OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF
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// MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT.
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// IN NO EVENT SHALL DALLAS SEMICONDUCTOR BE LIABLE FOR ANY CLAIM, DAMAGES
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// OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE,
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// ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR
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// OTHER DEALINGS IN THE SOFTWARE.
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//
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// Except as contained in this notice, the name of Dallas Semiconductor
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// shall not be used except as stated in the Dallas Semiconductor
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// Branding Policy.
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//--------------------------------------------------------------------------
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*/
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#include "driver/onewire.h"
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#include "platform.h"
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#include "osapi.h"
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#define noInterrupts ets_intr_lock
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#define interrupts ets_intr_unlock
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#define delayMicroseconds os_delay_us
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// 1 for keeping the parasitic power on H
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#define owDefaultPower 1
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#if ONEWIRE_SEARCH
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// global search state
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static unsigned char ROM_NO[NUM_OW][8];
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static uint8_t LastDiscrepancy[NUM_OW];
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static uint8_t LastFamilyDiscrepancy[NUM_OW];
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static uint8_t LastDeviceFlag[NUM_OW];
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#endif
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void onewire_init(uint8_t pin)
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{
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// pinMode(pin, INPUT);
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platform_gpio_mode(pin, PLATFORM_GPIO_INPUT, PLATFORM_GPIO_PULLUP);
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#if ONEWIRE_SEARCH
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onewire_reset_search(pin);
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#endif
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}
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// Perform the onewire reset function. We will wait up to 250uS for
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// the bus to come high, if it doesn't then it is broken or shorted
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// and we return a 0;
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//
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// Returns 1 if a device asserted a presence pulse, 0 otherwise.
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//
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uint8_t onewire_reset(uint8_t pin)
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{
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uint8_t r;
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uint8_t retries = 125;
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noInterrupts();
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DIRECT_MODE_INPUT(pin);
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interrupts();
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// wait until the wire is high... just in case
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do {
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if (--retries == 0) return 0;
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delayMicroseconds(2);
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} while ( !DIRECT_READ(pin));
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noInterrupts();
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DIRECT_WRITE_LOW(pin);
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interrupts();
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delayMicroseconds(480);
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noInterrupts();
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DIRECT_MODE_INPUT(pin); // allow it to float
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delayMicroseconds(70);
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r = !DIRECT_READ(pin);
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interrupts();
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delayMicroseconds(410);
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return r;
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}
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//
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// Write a bit. Port and bit is used to cut lookup time and provide
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// more certain timing.
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//
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static void onewire_write_bit(uint8_t pin, uint8_t v)
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{
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if (v & 1) {
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onewire_read_bit(pin);
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} else {
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noInterrupts();
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DIRECT_WRITE_LOW(pin);
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delayMicroseconds(65);
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DIRECT_MODE_INPUT(pin); // drive output high by the pull-up
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interrupts();
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delayMicroseconds(5);
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}
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}
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//
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// Read a bit. Port and bit is used to cut lookup time and provide
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// more certain timing.
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//
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static uint8_t onewire_read_bit(uint8_t pin)
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{
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uint8_t r;
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noInterrupts();
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DIRECT_WRITE_LOW(pin);
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delayMicroseconds(5);
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DIRECT_MODE_INPUT(pin); // let pin float, pull up will raise
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delayMicroseconds(8);
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r = DIRECT_READ(pin);
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interrupts();
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delayMicroseconds(52);
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return r;
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}
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//
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// Write a byte. The writing code uses the active drivers to raise the
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// pin high, if you need power after the write (e.g. DS18S20 in
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// parasite power mode) then set 'power' to 1, otherwise the pin will
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// go tri-state at the end of the write to avoid heating in a short or
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// other mishap.
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//
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void onewire_write(uint8_t pin, uint8_t v, uint8_t power /* = 0 */) {
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uint8_t bitMask;
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for (bitMask = 0x01; bitMask; bitMask <<= 1) {
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onewire_write_bit(pin, (bitMask & v)?1:0);
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}
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if ( power ) {
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noInterrupts();
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DIRECT_WRITE_HIGH(pin);
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interrupts();
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}
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}
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void onewire_write_bytes(uint8_t pin, const uint8_t *buf, uint16_t count, bool power /* = 0 */) {
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uint16_t i;
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for (i = 0 ; i < count ; i++)
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onewire_write(pin, buf[i], owDefaultPower);
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if ( power ) {
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noInterrupts();
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DIRECT_WRITE_HIGH(pin);
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interrupts();
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}
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}
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//
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// Read a byte
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//
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uint8_t onewire_read(uint8_t pin) {
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uint8_t bitMask;
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uint8_t r = 0;
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for (bitMask = 0x01; bitMask; bitMask <<= 1) {
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if (onewire_read_bit(pin)) r |= bitMask;
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}
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return r;
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}
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void onewire_read_bytes(uint8_t pin, uint8_t *buf, uint16_t count) {
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uint16_t i;
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for (i = 0 ; i < count ; i++)
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buf[i] = onewire_read(pin);
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}
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//
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// Do a ROM select
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//
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void onewire_select(uint8_t pin, const uint8_t rom[8])
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{
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uint8_t i;
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onewire_write(pin, 0x55, owDefaultPower); // Choose ROM
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for (i = 0; i < 8; i++) onewire_write(pin, rom[i], owDefaultPower);
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}
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//
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// Do a ROM skip
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//
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void onewire_skip(uint8_t pin)
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{
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onewire_write(pin, 0xCC, owDefaultPower); // Skip ROM
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}
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void onewire_depower(uint8_t pin)
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{
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noInterrupts();
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DIRECT_MODE_INPUT(pin);
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interrupts();
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}
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#if ONEWIRE_SEARCH
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//
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// You need to use this function to start a search again from the beginning.
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// You do not need to do it for the first search, though you could.
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//
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void onewire_reset_search(uint8_t pin)
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{
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// reset the search state
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LastDiscrepancy[pin] = 0;
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LastDeviceFlag[pin] = FALSE;
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LastFamilyDiscrepancy[pin] = 0;
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int i;
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for(i = 7; ; i--) {
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ROM_NO[pin][i] = 0;
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if ( i == 0) break;
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}
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}
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// Setup the search to find the device type 'family_code' on the next call
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// to search(*newAddr) if it is present.
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//
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void onewire_target_search(uint8_t pin, uint8_t family_code)
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{
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// set the search state to find SearchFamily type devices
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ROM_NO[pin][0] = family_code;
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uint8_t i;
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for (i = 1; i < 8; i++)
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ROM_NO[pin][i] = 0;
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LastDiscrepancy[pin] = 64;
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LastFamilyDiscrepancy[pin] = 0;
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LastDeviceFlag[pin] = FALSE;
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}
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//
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// Perform a search. If this function returns a '1' then it has
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// enumerated the next device and you may retrieve the ROM from the
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// OneWire::address variable. If there are no devices, no further
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// devices, or something horrible happens in the middle of the
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// enumeration then a 0 is returned. If a new device is found then
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// its address is copied to newAddr. Use OneWire::reset_search() to
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// start over.
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//
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// --- Replaced by the one from the Dallas Semiconductor web site ---
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//--------------------------------------------------------------------------
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// Perform the 1-Wire Search Algorithm on the 1-Wire bus using the existing
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// search state.
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// Return TRUE : device found, ROM number in ROM_NO buffer
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// FALSE : device not found, end of search
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//
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uint8_t onewire_search(uint8_t pin, uint8_t *newAddr)
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{
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uint8_t id_bit_number;
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uint8_t last_zero, rom_byte_number, search_result;
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uint8_t id_bit, cmp_id_bit;
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unsigned char rom_byte_mask, search_direction;
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// initialize for search
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id_bit_number = 1;
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last_zero = 0;
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rom_byte_number = 0;
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rom_byte_mask = 1;
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search_result = 0;
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// if the last call was not the last one
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if (!LastDeviceFlag[pin])
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{
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// 1-Wire reset
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if (!onewire_reset(pin))
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{
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// reset the search
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LastDiscrepancy[pin] = 0;
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LastDeviceFlag[pin] = FALSE;
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LastFamilyDiscrepancy[pin] = 0;
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return FALSE;
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}
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// issue the search command
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onewire_write(pin, 0xF0, owDefaultPower);
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// loop to do the search
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do
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{
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// read a bit and its complement
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id_bit = onewire_read_bit(pin);
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cmp_id_bit = onewire_read_bit(pin);
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// check for no devices on 1-wire
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if ((id_bit == 1) && (cmp_id_bit == 1))
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break;
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else
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{
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// all devices coupled have 0 or 1
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if (id_bit != cmp_id_bit)
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search_direction = id_bit; // bit write value for search
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else
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{
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// if this discrepancy if before the Last Discrepancy
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// on a previous next then pick the same as last time
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if (id_bit_number < LastDiscrepancy[pin])
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search_direction = ((ROM_NO[pin][rom_byte_number] & rom_byte_mask) > 0);
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else
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// if equal to last pick 1, if not then pick 0
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search_direction = (id_bit_number == LastDiscrepancy[pin]);
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// if 0 was picked then record its position in LastZero
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if (search_direction == 0)
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{
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last_zero = id_bit_number;
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// check for Last discrepancy in family
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if (last_zero < 9)
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LastFamilyDiscrepancy[pin] = last_zero;
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}
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}
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// set or clear the bit in the ROM byte rom_byte_number
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// with mask rom_byte_mask
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if (search_direction == 1)
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ROM_NO[pin][rom_byte_number] |= rom_byte_mask;
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else
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ROM_NO[pin][rom_byte_number] &= ~rom_byte_mask;
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// serial number search direction write bit
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onewire_write_bit(pin, search_direction);
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// increment the byte counter id_bit_number
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// and shift the mask rom_byte_mask
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id_bit_number++;
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rom_byte_mask <<= 1;
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// if the mask is 0 then go to new SerialNum byte rom_byte_number and reset mask
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if (rom_byte_mask == 0)
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{
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rom_byte_number++;
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rom_byte_mask = 1;
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}
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}
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}
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while(rom_byte_number < 8); // loop until through all ROM bytes 0-7
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// if the search was successful then
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if (!(id_bit_number < 65))
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{
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// search successful so set LastDiscrepancy,LastDeviceFlag,search_result
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LastDiscrepancy[pin] = last_zero;
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// check for last device
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if (LastDiscrepancy[pin] == 0)
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LastDeviceFlag[pin] = TRUE;
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search_result = TRUE;
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}
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}
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// if no device found then reset counters so next 'search' will be like a first
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if (!search_result || !ROM_NO[pin][0])
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{
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LastDiscrepancy[pin] = 0;
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LastDeviceFlag[pin] = FALSE;
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LastFamilyDiscrepancy[pin] = 0;
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search_result = FALSE;
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}
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else
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{
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for (rom_byte_number = 0; rom_byte_number < 8; rom_byte_number++)
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{
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newAddr[rom_byte_number] = ROM_NO[pin][rom_byte_number];
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}
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}
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return search_result;
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}
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#endif
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#if ONEWIRE_CRC
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// The 1-Wire CRC scheme is described in Maxim Application Note 27:
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// "Understanding and Using Cyclic Redundancy Checks with Maxim iButton Products"
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//
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#if ONEWIRE_CRC8_TABLE
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// This table comes from Dallas sample code where it is freely reusable,
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// though Copyright (C) 2000 Dallas Semiconductor Corporation
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static const uint8_t dscrc_table[] = {
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0, 94,188,226, 97, 63,221,131,194,156,126, 32,163,253, 31, 65,
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157,195, 33,127,252,162, 64, 30, 95, 1,227,189, 62, 96,130,220,
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35,125,159,193, 66, 28,254,160,225,191, 93, 3,128,222, 60, 98,
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190,224, 2, 92,223,129, 99, 61,124, 34,192,158, 29, 67,161,255,
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70, 24,250,164, 39,121,155,197,132,218, 56,102,229,187, 89, 7,
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219,133,103, 57,186,228, 6, 88, 25, 71,165,251,120, 38,196,154,
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101, 59,217,135, 4, 90,184,230,167,249, 27, 69,198,152,122, 36,
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248,166, 68, 26,153,199, 37,123, 58,100,134,216, 91, 5,231,185,
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140,210, 48,110,237,179, 81, 15, 78, 16,242,172, 47,113,147,205,
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17, 79,173,243,112, 46,204,146,211,141,111, 49,178,236, 14, 80,
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175,241, 19, 77,206,144,114, 44,109, 51,209,143, 12, 82,176,238,
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50,108,142,208, 83, 13,239,177,240,174, 76, 18,145,207, 45,115,
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202,148,118, 40,171,245, 23, 73, 8, 86,180,234,105, 55,213,139,
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87, 9,235,181, 54,104,138,212,149,203, 41,119,244,170, 72, 22,
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233,183, 85, 11,136,214, 52,106, 43,117,151,201, 74, 20,246,168,
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116, 42,200,150, 21, 75,169,247,182,232, 10, 84,215,137,107, 53};
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#ifndef pgm_read_byte
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#define pgm_read_byte(addr) (*(const uint8_t *)(addr))
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#endif
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//
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// Compute a Dallas Semiconductor 8 bit CRC. These show up in the ROM
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// and the registers. (note: this might better be done without to
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// table, it would probably be smaller and certainly fast enough
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// compared to all those delayMicrosecond() calls. But I got
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// confused, so I use this table from the examples.)
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//
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uint8_t onewire_crc8(const uint8_t *addr, uint8_t len)
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{
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uint8_t crc = 0;
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while (len--) {
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crc = pgm_read_byte(dscrc_table + (crc ^ *addr++));
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}
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return crc;
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}
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#else
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//
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// Compute a Dallas Semiconductor 8 bit CRC directly.
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// this is much slower, but much smaller, than the lookup table.
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//
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uint8_t onewire_crc8(const uint8_t *addr, uint8_t len)
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{
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uint8_t crc = 0;
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while (len--) {
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uint8_t inbyte = *addr++;
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uint8_t i;
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for (i = 8; i; i--) {
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uint8_t mix = (crc ^ inbyte) & 0x01;
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crc >>= 1;
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if (mix) crc ^= 0x8C;
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inbyte >>= 1;
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}
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}
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return crc;
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}
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#endif
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#if ONEWIRE_CRC16
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// Compute the 1-Wire CRC16 and compare it against the received CRC.
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// Example usage (reading a DS2408):
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// // Put everything in a buffer so we can compute the CRC easily.
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// uint8_t buf[13];
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// buf[0] = 0xF0; // Read PIO Registers
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// buf[1] = 0x88; // LSB address
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// buf[2] = 0x00; // MSB address
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// WriteBytes(net, buf, 3); // Write 3 cmd bytes
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// ReadBytes(net, buf+3, 10); // Read 6 data bytes, 2 0xFF, 2 CRC16
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// if (!CheckCRC16(buf, 11, &buf[11])) {
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// // Handle error.
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// }
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//
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// @param input - Array of bytes to checksum.
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// @param len - How many bytes to use.
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// @param inverted_crc - The two CRC16 bytes in the received data.
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// This should just point into the received data,
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// *not* at a 16-bit integer.
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// @param crc - The crc starting value (optional)
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// @return True, iff the CRC matches.
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|
bool onewire_check_crc16(const uint8_t* input, uint16_t len, const uint8_t* inverted_crc, uint16_t crc)
|
|
{
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|
crc = ~onewire_crc16(input, len, crc);
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|
return (crc & 0xFF) == inverted_crc[0] && (crc >> 8) == inverted_crc[1];
|
|
}
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|
|
|
// Compute a Dallas Semiconductor 16 bit CRC. This is required to check
|
|
// the integrity of data received from many 1-Wire devices. Note that the
|
|
// CRC computed here is *not* what you'll get from the 1-Wire network,
|
|
// for two reasons:
|
|
// 1) The CRC is transmitted bitwise inverted.
|
|
// 2) Depending on the endian-ness of your processor, the binary
|
|
// representation of the two-byte return value may have a different
|
|
// byte order than the two bytes you get from 1-Wire.
|
|
// @param input - Array of bytes to checksum.
|
|
// @param len - How many bytes to use.
|
|
// @param crc - The crc starting value (optional)
|
|
// @return The CRC16, as defined by Dallas Semiconductor.
|
|
uint16_t onewire_crc16(const uint8_t* input, uint16_t len, uint16_t crc)
|
|
{
|
|
static const uint8_t oddparity[16] =
|
|
{ 0, 1, 1, 0, 1, 0, 0, 1, 1, 0, 0, 1, 0, 1, 1, 0 };
|
|
|
|
uint16_t i;
|
|
for (i = 0 ; i < len ; i++) {
|
|
// Even though we're just copying a byte from the input,
|
|
// we'll be doing 16-bit computation with it.
|
|
uint16_t cdata = input[i];
|
|
cdata = (cdata ^ crc) & 0xff;
|
|
crc >>= 8;
|
|
|
|
if (oddparity[cdata & 0x0F] ^ oddparity[cdata >> 4])
|
|
crc ^= 0xC001;
|
|
|
|
cdata <<= 6;
|
|
crc ^= cdata;
|
|
cdata <<= 1;
|
|
crc ^= cdata;
|
|
}
|
|
return crc;
|
|
}
|
|
#endif
|
|
|
|
#endif
|