obus/lib/obus_module.cpp

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#include "obus_can.h"
#include "obus_module.h"
#define PIN_LED_RED 4
#define PIN_LED_GREEN 7
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#define BLINK_DELAY_SLOW 1000
#define BLINK_DELAY_FAST 300
#define MAX_TIME_BETWEEN_CALLS 100
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#define COLOR_OFF ((struct color) {false, false})
#define COLOR_RED ((struct color) {true, false})
#define COLOR_GREEN ((struct color) {false, true})
#define COLOR_YELLOW ((struct color) {true, true})
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namespace obus_module {
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struct obus_can::module this_module;
uint8_t strike_count;
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bool active;
bool acked_after_last_hello = false;
uint32_t next_loop_call_deadline;
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// Current LED status
struct color { bool red; bool green; };
struct color led_color;
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// Keeps track of whether the LED is currently lit, when a blink pattern is active
bool blink_led_lit = false;
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int blink_delay = 0;
unsigned long blink_next_time = 0;
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uint32_t led_reset_time;
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void _setLed(struct color color) {
led_color = color;
blink_delay = 0;
led_reset_time = 0;
digitalWrite(PIN_LED_RED, color.red ? HIGH : LOW);
digitalWrite(PIN_LED_GREEN, color.green ? HIGH : LOW);
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}
void _ledLoop() {
// Check if we need to turn the LED back off, e.g. to reset the strike blinker
if (led_reset_time && millis() > led_reset_time) {
if (active) {
_setLed(COLOR_YELLOW);
} else {
_setLed(COLOR_OFF);
}
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led_reset_time = 0;
}
// Update blink of status LED
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if (blink_delay && millis() > blink_next_time) {
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blink_led_lit = !blink_led_lit;
if (blink_led_lit) {
digitalWrite(PIN_LED_RED, led_color.red ? HIGH : LOW);
digitalWrite(PIN_LED_GREEN, led_color.green ? HIGH : LOW);
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} else {
digitalWrite(PIN_LED_RED, false);
digitalWrite(PIN_LED_GREEN, false);
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}
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blink_next_time = millis() + blink_delay;
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}
}
void _setLedBlink(struct color color, uint16_t delay) {
led_color = color;
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blink_led_lit = false;
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blink_delay = delay;
blink_next_time = millis();
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led_reset_time = 0;
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_ledLoop();
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}
void blink_error(String message) {
bool blink = false;
while (true) {
digitalWrite(PIN_LED_RED, blink);
digitalWrite(PIN_LED_GREEN, blink);
blink = !blink;
delay(blink ? BLINK_DELAY_SLOW : BLINK_DELAY_FAST);
Serial.println(message);
}
}
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void _resetState() {
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strike_count = 0;
active = false;
next_loop_call_deadline = 0;
acked_after_last_hello = false;
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if (this_module.type == OBUS_TYPE_PUZZLE || this_module.type == OBUS_TYPE_NEEDY) {
pinMode(PIN_LED_RED, OUTPUT);
pinMode(PIN_LED_GREEN, OUTPUT);
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_setLedBlink(COLOR_GREEN, BLINK_DELAY_SLOW);
}
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}
void setup(uint8_t type, uint8_t id) {
this_module.type = type;
this_module.id = id;
_resetState();
if (!obus_can::init()) {
blink_error(F("CAN init failed"));
}
}
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void empty_callback_info(uint8_t info_id, uint8_t infomessage[7]) {
// Mark arguments as not used
(void)info_id;
(void)infomessage;
}
void empty_callback_state(uint32_t time_left, uint8_t strikes, uint8_t max_strikes, uint8_t puzzle_modules_left) {
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// Mark arguments as not used
(void)time_left;
(void)strikes;
(void)max_strikes;
(void)puzzle_modules_left;
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}
bool loopPuzzle(obus_can::message* message, void (*callback_game_start)(uint8_t puzzle_modules), void (*callback_game_stop)(), void (*callback_info)(uint8_t info_id, uint8_t infomessage[7]), void (*callback_state)(uint32_t time_left, uint8_t strikes, uint8_t max_strikes, uint8_t puzzle_modules_left)) {
// TODO this can be more efficient by only enabling error interrupts and
// reacting to the interrupt instead of checking if the flag is set in a loop
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// We will need to fork our CAN library for this, because the needed functions are private.
// Also, we can't do this by default, because the INT pin is normally not connected to the board
if (obus_can::is_error_condition()) {
blink_error(F("E CAN error"));
}
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// Force the user of the library to periodically call loop
if (next_loop_call_deadline != 0 && millis() > next_loop_call_deadline) {
blink_error(F("E Missed loop deadline"));
}
next_loop_call_deadline = millis() + MAX_TIME_BETWEEN_CALLS;
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bool received_message = false;
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if (obus_can::receive(message)) {
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received_message = true;
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if (is_from_controller(message->from)) {
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uint32_t seed;
switch (message->msg_type) {
case OBUS_MSGTYPE_C_GAMESTART:
if (acked_after_last_hello) {
active = true;
_setLed(COLOR_YELLOW);
callback_game_start(message->gamestatus.puzzle_modules_left);
}
break;
case OBUS_MSGTYPE_C_HELLO:
_resetState();
obus_can::send_m_hello(this_module);
break;
case OBUS_MSGTYPE_C_SOLVED:
case OBUS_MSGTYPE_C_TIMEOUT:
case OBUS_MSGTYPE_C_STRIKEOUT:
if (acked_after_last_hello) {
active = false;
_setLed(COLOR_OFF);
callback_game_stop();
}
break;
case OBUS_MSGTYPE_C_ACK:
if (message->payload_address.type == this_module.type && message->payload_address.id == this_module.id) {
acked_after_last_hello = true;
}
break;
case OBUS_MSGTYPE_C_STATE:
callback_state(message->gamestatus.time_left, message->gamestatus.strikes, message->gamestatus.max_strikes, message->gamestatus.puzzle_modules_left);
break;
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case OBUS_MSGTYPE_C_INFOSTART:
// Add module type and id to seed, to remove correlation in randomness between modules
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seed = message->infostart.seed + ((uint32_t) this_module.type << 8) + ((uint32_t) this_module.id);
// randomSeed has no effect when called with 0 as seed, so we use
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// a fallback value that is unlikely to collide with other frequently used seeds
if (seed == 0) {
seed--;
}
randomSeed(seed);
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break;
default:
break;
}
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} else if (message->from.type == OBUS_TYPE_INFO) {
uint8_t infobuffer[7] = {0};
memcpy(infobuffer, message->infomessage.data, message->infomessage.len);
callback_info(message->from.id, infobuffer);
}
}
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_ledLoop();
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return received_message;
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}
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bool loopNeedy(obus_can::message* message, void (*callback_game_start)(uint8_t puzzle_modules), void (*callback_game_stop)(), void (*callback_info)(uint8_t info_id, uint8_t infomessage[7]), void (*callback_state)(uint32_t time_left, uint8_t strikes, uint8_t max_strikes, uint8_t puzzle_modules_left)) {
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// For now this is the same function
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return loopPuzzle(message, callback_game_start, callback_game_stop, callback_info, callback_state);
}
bool loopInfo(obus_can::message* message, int (*info_generator)(uint8_t*)) {
bool interesting_message = false;
if (obus_can::receive(message)) {
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if (is_from_controller(message->from)) {
switch (message->msg_type) {
case OBUS_MSGTYPE_C_INFOSTART:
{
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randomSeed(message->infostart.seed);
uint8_t info_message[OBUS_PAYLD_INFO_MAXLEN];
int len = info_generator(info_message);
obus_can::send_i_infomessage(this_module, info_message, len);
}
break;
case OBUS_MSGTYPE_C_STATE:
interesting_message = true;
break;
default:
break;
}
}
}
return interesting_message;
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}
void strike() {
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if (!active) {
return;
}
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strike_count++;
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_setLedBlink(COLOR_RED, BLINK_DELAY_FAST);
led_reset_time = millis() + 2000;
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obus_can::send_m_strike(this_module, strike_count);
}
void solve() {
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if (!active) {
return;
}
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obus_can::send_m_solved(this_module);
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active = false;
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_setLed(COLOR_GREEN);
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}
bool is_active() {
return active;
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}
}