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415 lines
9.5 KiB
415 lines
9.5 KiB
3 months ago
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/*
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* Interface to DS18B20 Temperature Sensors
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*
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* (c) 2019 Martin Mareš <mj@ucw.cz>
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*/
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#include "util.h"
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#include "ds18b20.h"
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#include "ext-timer.h"
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#include <libopencm3/cm3/cortex.h>
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#include <libopencm3/stm32/dma.h>
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#include <libopencm3/stm32/gpio.h>
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#include <libopencm3/stm32/rcc.h>
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#include <string.h>
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/*** Configuration ***/
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// You should set the following parameters in config.h
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// #define DS_TIMER TIM3
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// #define DS_GPIO GPIOA
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// #define DS_PIN GPIO7
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// #define DS_DMA DMA1
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// #define DS_DMA_CH 6
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// #undef DS_DEBUG
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// #undef DS_DEBUG2
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// Maximum number of supported sensors
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// #define DS_NUM_SENSORS 8
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#ifdef DS_DEBUG
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#define DEBUG debug_printf
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#else
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#define DEBUG(xxx, ...) do { } while (0)
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#endif
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#ifdef DS_DEBUG2
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#define DEBUG2 debug_printf
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#else
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#define DEBUG2(xxx, ...) do { } while (0)
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#endif
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static volatile u32 ds_dma_buffer;
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static bool ds_reset(void)
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{
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DEBUG2("DS18B20: Reset\n");
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timer_disable_counter(DS_TIMER);
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timer_one_shot_mode(DS_TIMER);
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// DMA for reading pin state
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ds_dma_buffer = 0xdeadbeef;
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dma_set_memory_address(DS_DMA, DS_DMA_CH, (u32) &ds_dma_buffer);
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dma_set_peripheral_address(DS_DMA, DS_DMA_CH, (u32) &GPIO_IDR(DS_GPIO));
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dma_set_number_of_data(DS_DMA, DS_DMA_CH, 1);
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dma_enable_channel(DS_DMA, DS_DMA_CH);
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// CC1 is used to drive the DMA (read line state at specified time)
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timer_disable_oc_output(DS_TIMER, TIM_OC1);
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timer_set_oc_mode(DS_TIMER, TIM_OC1, TIM_OCM_FROZEN);
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timer_set_oc_value(DS_TIMER, TIM_OC1, 560);
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timer_set_dma_on_compare_event(DS_TIMER);
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timer_enable_dma_cc1(DS_TIMER);
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// CC2 is used to generate pulses (return line to idle state at specified time)
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timer_set_oc_mode(DS_TIMER, TIM_OC2, TIM_OCM_FORCE_HIGH);
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timer_enable_oc_output(DS_TIMER, TIM_OC2);
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timer_set_oc_value(DS_TIMER, TIM_OC2, 480);
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timer_set_oc_polarity_low(DS_TIMER, TIM_OC2);
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// Set timer period to the length of the whole transaction (1 ms)
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timer_set_period(DS_TIMER, 999);
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// XXX: We do not know why this is needed...
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static bool once;
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if (!once) {
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for (int i=0; i<10000; i++) __asm__ volatile ("nop");
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once = 1;
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}
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// Pull line down and start timer
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timer_generate_event(DS_TIMER, TIM_EGR_UG);
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timer_set_oc_mode(DS_TIMER, TIM_OC2, TIM_OCM_INACTIVE);
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timer_enable_counter(DS_TIMER);
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// Wait until the timer expires
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while (timer_is_counter_enabled(DS_TIMER))
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;
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// Counter is automatically disabled at the end of cycle
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// Disable DMA
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timer_disable_dma_cc1(DS_TIMER);
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dma_disable_channel(DS_DMA, DS_DMA_CH);
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DEBUG2("Init DMA: %08x [%u] (%u remains)\n",
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ds_dma_buffer,
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!!(ds_dma_buffer & DS_PIN),
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dma_get_number_of_data(DS_DMA, DS_DMA_CH));
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// Did the device respond?
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if (ds_dma_buffer & DS_PIN) {
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DEBUG("DS18B20: Initialization failed\n");
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return 0;
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} else
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return 1;
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}
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static void ds_send_bit(bool bit)
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{
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timer_set_period(DS_TIMER, 99); // Each write slot takes 100 μs
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timer_set_oc_mode(DS_TIMER, TIM_OC2, TIM_OCM_FORCE_HIGH);
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timer_set_oc_value(DS_TIMER, TIM_OC2, (bit ? 3 : 89)); // 1: 3μs pulse, 0: 89μs pulse
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timer_generate_event(DS_TIMER, TIM_EGR_UG);
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timer_set_oc_mode(DS_TIMER, TIM_OC2, TIM_OCM_INACTIVE);
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timer_enable_counter(DS_TIMER);
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while (timer_is_counter_enabled(DS_TIMER))
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;
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}
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static void ds_send_byte(byte b)
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{
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DEBUG2("DS write: %02x\n", b);
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for (uint m = 1; m < 0x100; m <<= 1)
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ds_send_bit(b & m);
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}
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static bool ds_recv_bit(void)
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{
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timer_set_period(DS_TIMER, 79); // Each read slot takes 80μs
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timer_set_oc_value(DS_TIMER, TIM_OC2, 2); // Generate 2μs pulse to start read slot
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timer_set_oc_value(DS_TIMER, TIM_OC1, 8); // Sample data 8μs after start of slot
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timer_enable_dma_cc1(DS_TIMER);
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ds_dma_buffer = 0xdeadbeef;
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dma_set_number_of_data(DS_DMA, DS_DMA_CH, 1);
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dma_enable_channel(DS_DMA, DS_DMA_CH);
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timer_set_oc_mode(DS_TIMER, TIM_OC2, TIM_OCM_FORCE_HIGH);
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timer_generate_event(DS_TIMER, TIM_EGR_UG);
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timer_set_oc_mode(DS_TIMER, TIM_OC2, TIM_OCM_INACTIVE);
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timer_enable_counter(DS_TIMER);
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while (timer_is_counter_enabled(DS_TIMER))
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;
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// DEBUG2("XXX %08x\n", ds_dma_buffer);
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bool out = ds_dma_buffer & DS_PIN;
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dma_disable_channel(DS_DMA, DS_DMA_CH);
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timer_disable_dma_cc1(DS_TIMER);
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return out;
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}
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static byte ds_recv_byte(void)
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{
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uint out = 0;
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for (uint m = 1; m < 0x100; m <<= 1) {
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if (ds_recv_bit())
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out |= m;
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}
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DEBUG2("DS read: %02x\n", out);
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return out;
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}
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static byte ds_buf[10];
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static byte ds_crc_block(uint n)
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{
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/// XXX: This might be worth optimizing
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uint crc = 0;
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for (uint i = 0; i < n; i++) {
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byte b = ds_buf[i];
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for (uint j = 0; j < 8; j++) {
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uint k = (b & 1) ^ (crc >> 7);
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crc = (crc << 1) & 0xff;
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if (k)
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crc ^= 0x31;
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b >>= 1;
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}
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}
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return crc;
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}
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static bool ds_recv_block(uint n)
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{
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for (uint i = 0; i < n; i++)
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ds_buf[i] = ds_recv_byte();
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byte crc = ds_crc_block(n);
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if (crc) {
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DEBUG("DS18B20: Invalid CRC %02x\n", crc);
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return 0;
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}
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return 1;
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}
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struct ds_sensor ds_sensors[DS_NUM_SENSORS];
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#if DS_NUM_SENSORS == 1
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static void ds_enumerate(void)
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{
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if (!ds_reset())
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return;
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ds_send_byte(0x33); // READ_ROM
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if (!ds_recv_block(8))
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return;
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DEBUG("DS18B20: Found sensor ");
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for (uint i = 0; i < 8; i++) {
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DEBUG("%02x", ds_buf[i]);
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ds_sensors[0].address[i] = ds_buf[i];
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}
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DEBUG("\n");
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}
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#else
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static void ds_enumerate(void)
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{
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/*
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* The enumeration algorithm roughly follows the one described in the
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* Book of iButton Standards (Maxim Integrated Application Note 937).
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*
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* It simulates depth-first search on the trie of all device IDs.
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* In each pass, it walks the trie from the root and recognizes branching nodes.
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*
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* The old_choice variable remembers the deepest left branch taken in the
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* previous pass, new_choice is the same for the current pass.
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*/
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DEBUG("DS18B20: Enumerate\n");
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uint num_sensors = 0;
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byte *addr = ds_buf;
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byte old_choice = 0;
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for (;;) {
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if (!ds_reset()) {
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DEBUG("DS18B20: Enumeration found no sensor\n");
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return;
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}
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ds_send_byte(0xf0); // SEARCH_ROM
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byte new_choice = 0;
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for (byte i=0; i<64; i++) {
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bool have_one = ds_recv_bit();
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bool have_zero = ds_recv_bit();
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bool old_bit = addr[i/8] & (1U << (i%8));
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bool new_bit;
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switch (2*have_one + have_zero) {
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case 3:
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// This should not happen
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DEBUG("DS18B20: Enumeration failed\n");
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return;
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case 1:
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// Only 0
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new_bit = 0;
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break;
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case 2:
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// Only 1
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new_bit = 1;
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break;
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default:
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// Both
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if (i == old_choice)
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new_bit = 1;
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else if (i > old_choice) {
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new_bit = 0;
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new_choice = i;
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} else {
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new_bit = old_bit;
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if (!new_bit)
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new_choice = i;
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}
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}
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if (new_bit)
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addr[i/8] |= 1U << (i%8);
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else
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addr[i/8] &= ~(1U << (i%8));
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ds_send_bit(new_bit);
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}
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if (num_sensors >= DS_NUM_SENSORS) {
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DEBUG("DS18B20: Too many sensors\n");
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return;
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}
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DEBUG("DS18B20: Found sensor #%u: ", num_sensors);
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for (byte i=0; i<8; i++)
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DEBUG("%02x", addr[i]);
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if (ds_crc_block(8)) {
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DEBUG(" - invalid CRC!\n");
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} else if (ds_buf[0] == 0x28) {
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DEBUG("\n");
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memcpy(ds_sensors[num_sensors].address, ds_buf, 8);
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num_sensors++;
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} else {
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DEBUG(" - wrong type\n");
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}
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old_choice = new_choice;
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if (!old_choice)
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break;
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}
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}
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#endif
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void ds_init(void)
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{
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DEBUG("DS18B20: Init\n");
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for (uint i = 0; i < DS_NUM_SENSORS; i++) {
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memset(ds_sensors[i].address, 0, 8);
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ds_sensors[i].current_temp = DS_TEMP_UNKNOWN;
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}
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dma_set_read_from_peripheral(DS_DMA, DS_DMA_CH);
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dma_set_priority(DS_DMA, DS_DMA_CH, DMA_CCR_PL_VERY_HIGH);
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dma_disable_peripheral_increment_mode(DS_DMA, DS_DMA_CH);
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dma_enable_memory_increment_mode(DS_DMA, DS_DMA_CH);
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dma_set_peripheral_size(DS_DMA, DS_DMA_CH, DMA_CCR_PSIZE_16BIT);
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dma_set_memory_size(DS_DMA, DS_DMA_CH, DMA_CCR_MSIZE_16BIT);
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timer_set_prescaler(DS_TIMER, CPU_CLOCK_MHZ - 1); // 1 tick = 1 μs
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timer_set_mode(DS_TIMER, TIM_CR1_CKD_CK_INT, TIM_CR1_CMS_EDGE, TIM_CR1_DIR_UP);
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timer_disable_preload(DS_TIMER);
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gpio_set_mode(DS_GPIO, GPIO_MODE_OUTPUT_50_MHZ, GPIO_CNF_OUTPUT_ALTFN_OPENDRAIN, DS_PIN);
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ds_enumerate();
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// FIXME: Configure precision?
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}
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#if DS_NUM_SENSORS == 1
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#define ds_current_id 0
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#else
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static byte ds_current_id;
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#endif
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static bool ds_activate(void)
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{
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if (!ds_reset()) {
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DEBUG("DS18B20: Reset failed\n");
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return false;
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}
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#if DS_NUM_SENSORS == 1
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ds_send_byte(0xcc); // SKIP_ROM
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#else
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ds_send_byte(0x55); // MATCH_ROM
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for (uint i = 0; i < 8; i++)
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ds_send_byte(ds_sensors[ds_current_id].address[i]);
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#endif
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return true;
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}
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void ds_step(void)
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{
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static byte ds_running;
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static byte ds_timeout;
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if (!ds_running) {
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// Start measurement
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#if DS_NUM_SENSORS != 1
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uint maxn = DS_NUM_SENSORS;
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do {
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if (!maxn--)
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return;
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ds_current_id++;
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if (ds_current_id >= DS_NUM_SENSORS) {
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ds_current_id = 0;
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}
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} while (!ds_sensors[ds_current_id].address[0]);
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#endif
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if (!ds_activate()) {
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ds_sensors[ds_current_id].current_temp = DS_TEMP_UNKNOWN;
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return;
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}
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ds_send_byte(0x44); // CONVERT_T
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ds_running = 1;
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ds_timeout = 255;
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} else {
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// Still running?
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if (!ds_recv_bit()) {
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if (!ds_timeout--) {
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DEBUG("DS18B20 #%u: Timeout\n", ds_current_id);
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ds_sensors[ds_current_id].current_temp = DS_TEMP_UNKNOWN;
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ds_running = 0;
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}
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return;
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}
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ds_running = 0;
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// Read scratch pad
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if (!ds_activate())
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return;
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ds_send_byte(0xbe); // READ_SCRATCHPAD
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if (!ds_recv_block(9)) {
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ds_sensors[ds_current_id].current_temp = DS_TEMP_UNKNOWN;
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return;
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}
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int t = (int16_t) (ds_buf[0] | (ds_buf[1] << 8));
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t = t * 1000 / 16;
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DEBUG("DS18B20 #%u: %d.%03d degC\n", ds_current_id, t / 1000, t % 1000);
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ds_sensors[ds_current_id].current_temp = t;
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}
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}
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