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gex-core/units/1wire/unit_1wire.c

389 lines
12 KiB

//
// Created by MightyPork on 2018/01/29.
//
#include "comm/messages.h"
#include "unit_base.h"
#include "utils/avrlibc.h"
#include "unit_1wire.h"
// 1WIRE master
#define OW_INTERNAL
#include "_ow_internal.h"
// ------------------------------------------------------------------------
/** Load from a binary buffer stored in Flash */
static void U1WIRE_loadBinary(Unit *unit, PayloadParser *pp)
{
struct priv *priv = unit->data;
uint8_t version = pp_u8(pp);
(void)version;
priv->port_name = pp_char(pp);
priv->pin_number = pp_u8(pp);
if (version >= 1) {
priv->parasitic = pp_bool(pp);
}
}
/** Write to a binary buffer for storing in Flash */
static void U1WIRE_writeBinary(Unit *unit, PayloadBuilder *pb)
{
struct priv *priv = unit->data;
pb_u8(pb, 1); // version
pb_char(pb, priv->port_name);
pb_u8(pb, priv->pin_number);
pb_bool(pb, priv->parasitic);
}
// ------------------------------------------------------------------------
/** Parse a key-value pair from the INI file */
static error_t U1WIRE_loadIni(Unit *unit, const char *key, const char *value)
{
bool suc = true;
struct priv *priv = unit->data;
if (streq(key, "pin")) {
suc = parse_pin(value, &priv->port_name, &priv->pin_number);
}
else if (streq(key, "parasitic")) {
priv->parasitic = str_parse_yn(value, &suc);
}
else {
return E_BAD_KEY;
}
if (!suc) return E_BAD_VALUE;
return E_SUCCESS;
}
/** Generate INI file section for the unit */
static void U1WIRE_writeIni(Unit *unit, IniWriter *iw)
{
struct priv *priv = unit->data;
iw_comment(iw, "Data pin");
iw_entry(iw, "pin", "%c%d", priv->port_name, priv->pin_number);
7 years ago
iw_comment(iw, "Parasitic (bus-powered) mode");
iw_entry(iw, "parasitic", str_yn(priv->parasitic));
}
// ------------------------------------------------------------------------
static void U1WIRE_TimerCb(TimerHandle_t xTimer)
{
Unit *unit = pvTimerGetTimerID(xTimer);
assert_param(unit);
struct priv *priv = unit->data;
assert_param(priv->busy);
if (priv->parasitic) {
// this is the end of the 750ms measurement time
goto halt_ok;
} else {
bool ready = ow_read_bit(unit);
if (ready) {
goto halt_ok;
}
uint32_t time = PTIM_GetTime();
if (time - priv->busyStart > 1000) {
// dbg("Wait timed out. Stopping polling timer.");
xTimerStop(xTimer, 100);
com_respond_error(priv->busyRequestId, E_HW_TIMEOUT);
priv->busy = false;
}
}
return;
halt_ok:
xTimerStop(xTimer, 100);
com_respond_ok(priv->busyRequestId);
priv->busy = false;
}
/** Allocate data structure and set defaults */
static error_t U1WIRE_preInit(Unit *unit)
{
struct priv *priv = unit->data = calloc_ck(1, sizeof(struct priv));
if (priv == NULL) return E_OUT_OF_MEM;
// the timer is not started until needed
priv->busyWaitTimer = xTimerCreate("1w_tim", // name
750, // interval (will be changed when starting it)
true, // periodic (we use this only for the polling variant, the one-shot will stop the timer in the CB)
unit, // user data
U1WIRE_TimerCb); // callback
if (priv->busyWaitTimer == NULL) return E_OUT_OF_MEM;
// some defaults
priv->pin_number = 0;
priv->port_name = 'A';
priv->parasitic = false;
return E_SUCCESS;
}
/** Finalize unit set-up */
static error_t U1WIRE_init(Unit *unit)
{
bool suc = true;
struct priv *priv = unit->data;
// --- Parse config ---
priv->ll_pin = hw_pin2ll(priv->pin_number, &suc);
priv->port = hw_port2periph(priv->port_name, &suc);
Resource rsc = hw_pin2resource(priv->port_name, priv->pin_number, &suc);
if (!suc) return E_BAD_CONFIG;
// --- Claim resources ---
TRY(rsc_claim(unit, rsc));
// --- Init hardware ---
LL_GPIO_SetPinMode(priv->port, priv->ll_pin, LL_GPIO_MODE_OUTPUT);
LL_GPIO_SetPinOutputType(priv->port, priv->ll_pin, LL_GPIO_OUTPUT_PUSHPULL);
LL_GPIO_SetPinSpeed(priv->port, priv->ll_pin, LL_GPIO_SPEED_FREQ_HIGH);
LL_GPIO_SetPinPull(priv->port, priv->ll_pin, LL_GPIO_PULL_UP); // pull-up for OD state
return E_SUCCESS;
}
/** Tear down the unit */
static void U1WIRE_deInit(Unit *unit)
{
struct priv *priv = unit->data;
// Release all resources
rsc_teardown(unit);
// Delete the software timer
assert_param(pdPASS == xTimerDelete(priv->busyWaitTimer, 1000));
// Free memory
free_ck(unit->data);
}
// ------------------------------------------------------------------------
enum PinCmd_ {
CMD_CHECK_PRESENCE = 0, // simply tests that any devices are attached
CMD_SEARCH_ADDR = 1, // perform a scan of the bus, retrieving all found device ROMs
CMD_SEARCH_ALARM = 2, // like normal scan, but retrieve only devices with alarm
CMD_READ_ADDR = 3, // read the ROM code from a single device (for single-device bus)
CMD_SKIP_WRITE = 10, // write multiple bytes using the SKIP_ROM command
CMD_SKIP_READ = 11, // write and read multiple bytes using the SKIP_ROM command
CMD_MATCH_WRITE = 12, // write multiple bytes using a ROM address
CMD_MATCH_READ = 13, // write and read multiple bytes using a ROM address
CMD_POLL_FOR_1 = 20,
CMD_TEST = 100,
};
/** send the match-rom with address from a payload parser, or skip-rom */
static void cmd_match_skip(Unit *unit, uint8_t command, PayloadParser *pp)
{
uint64_t addr;
if (command == CMD_MATCH_WRITE || command == CMD_MATCH_READ) {
addr = pp_u64(pp);
ow_write_u8(unit, OW_ROM_MATCH);
ow_write_u64(unit, addr);
}
else {
ow_write_u8(unit, OW_ROM_SKIP);
}
}
/** Handle a request message */
static error_t U1WIRE_handleRequest(Unit *unit, TF_ID frame_id, uint8_t command, PayloadParser *pp)
{
struct priv *priv = unit->data;
bool presence;
uint64_t addr;
int remain;
if (priv->busy) return E_BUSY;
switch (command) {
case CMD_SEARCH_ADDR:
// TODO
return E_NOT_IMPLEMENTED;
case CMD_SEARCH_ALARM:
// TODO
return E_NOT_IMPLEMENTED;
/** Simply check presence of any devices on the bus. Responds with SUCCESS or HW_TIMEOUT */
case CMD_CHECK_PRESENCE:
// reset
presence = ow_reset(unit);
// build response
com_respond_u8(frame_id, (uint8_t) presence);
return E_SUCCESS;
/** Read address of the single device on the bus - returns u64 */
case CMD_READ_ADDR:
// reset
presence = ow_reset(unit);
if (!presence) return E_HW_TIMEOUT;
// command
ow_write_u8(unit, OW_ROM_READ);
// read the ROM code
addr = ow_read_u64(unit);
// build response
PayloadBuilder pb = pb_start(unit_tmp512, UNIT_TMP_LEN, NULL);
pb_u64(&pb, addr);
com_respond_pb(frame_id, MSG_SUCCESS, &pb);
return E_SUCCESS;
/**
* Write payload to the bus, no confirmation (unless requested).
*
* Payload:
* - Match variant: addr:u64, rest:write_data
* - Skip variant: all:write_data
*/
case CMD_MATCH_WRITE:
case CMD_SKIP_WRITE:
// reset
presence = ow_reset(unit);
if (!presence) return E_HW_TIMEOUT;
// MATCH_ROM+addr, or SKIP_ROM
cmd_match_skip(unit, command, pp);
// write the rest of the payload
remain = pp_length(pp);
for (int i = 0; i < remain; i++) {
ow_write_u8(unit, pp_u8(pp));
}
return E_SUCCESS;
/**
* Write and read.
*
* Payload:
* - Match variant: addr:u64, read_len:u16, rest:write_data
* - Skip variant: read_len:u16, rest:write_data
*/
case CMD_MATCH_READ:
case CMD_SKIP_READ:;
// reset
presence = ow_reset(unit);
if (!presence) return E_HW_TIMEOUT;
// MATCH_ROM+addr, or SKIP_ROM
cmd_match_skip(unit, command, pp);
// paylod prefix - number of bytes to read
uint16_t rcount = pp_u16(pp);
// write the rest of the payload
remain = pp_length(pp);
for (int i = 0; i < remain; i++) {
ow_write_u8(unit, pp_u8(pp));
}
// read the requested number of bytes
for (int i = 0; i < rcount; i++) {
unit_tmp512[i] = ow_read_u8(unit);
}
// build response
com_respond_buf(frame_id, MSG_SUCCESS, (const uint8_t *) unit_tmp512, rcount);
return E_SUCCESS;
/**
* This is the delay function for DS1820 measurements.
*
* Parasitic: Returns success after the required 750ms
* Non-parasitic: Returns SUCCESS after device responds '1', HW_TIMEOUT after 1s
*/
case CMD_POLL_FOR_1:
if (priv->parasitic) {
assert_param(pdPASS == xTimerChangePeriod(priv->busyWaitTimer, 750, 100));
} else {
// every 10 ticks
assert_param(pdPASS == xTimerChangePeriod(priv->busyWaitTimer, 10, 100));
}
assert_param(pdPASS == xTimerStart(priv->busyWaitTimer, 100));
priv->busy = true;
priv->busyStart = PTIM_GetTime();
priv->busyRequestId = frame_id;
return E_SUCCESS; // We will respond when the timer expires
//
// case CMD_TEST:;
// bool presence = ow_reset(unit);
// if (!presence) return E_HW_TIMEOUT;
//
// ow_write_u8(unit, OW_ROM_SKIP);
//
// ow_write_u8(unit, OW_DS1820_CONVERT_T);
// while (!ow_read_bit(unit));
//
// // TODO use knowledge of the use/non-use of parasitic mode to pick the optimal strategy (non-parasitic allows polling)
//
// // osDelay(750);
// // TODO this will be done with an async timer
// // If parasitive power is not used, we could poll and check the status bit
//
// presence = ow_reset(unit);
// if (!presence) return E_HW_TIMEOUT;
// ow_write_u8(unit, OW_ROM_SKIP);
//
// ow_write_u8(unit, OW_DS1820_READ_SCRATCH);
//
// uint16_t temp = ow_read_u16(unit);
// uint16_t threg = ow_read_u16(unit);
// uint16_t reserved = ow_read_u16(unit);
// uint8_t cnt_remain = ow_read_u8(unit);
// uint8_t cnt_per_c = ow_read_u8(unit);
// uint8_t crc = ow_read_u8(unit);
// // TODO check CRC
//
// pb = pb_start(unit_tmp512, UNIT_TMP_LEN, NULL);
// pb_u16(&pb, temp);
// pb_u8(&pb, cnt_remain);
// pb_u8(&pb, cnt_per_c);
//
// dbg("respond ...");
// com_respond_buf(frame_id, MSG_SUCCESS, pb.start, pb_length(&pb));
// return E_SUCCESS;
default:
return E_UNKNOWN_COMMAND;
}
}
// ------------------------------------------------------------------------
/** Unit template */
const UnitDriver UNIT_1WIRE = {
.name = "1WIRE",
.description = "1-Wire master",
// Settings
.preInit = U1WIRE_preInit,
.cfgLoadBinary = U1WIRE_loadBinary,
.cfgWriteBinary = U1WIRE_writeBinary,
.cfgLoadIni = U1WIRE_loadIni,
.cfgWriteIni = U1WIRE_writeIni,
// Init
.init = U1WIRE_init,
.deInit = U1WIRE_deInit,
// Function
.handleRequest = U1WIRE_handleRequest,
};