Keuronde/Robot_Riombotique
1
0
Fork 0
Code Issues Pull Requests Actions Packages Projects Releases Wiki Activity

Ajout de la communication et envoi des valeurs des joystick et boutons par i2c

Browse Source
This commit is contained in:
Club robotique de Riom 2024-01-21 18:59:25 +01:00
commit 6ac3a83c4e
9 changed files with 703 additions and 15 deletions
Show Stats Download Patch File Download Diff File Expand all files Collapse all files

7
CMakeLists.txt
View File

@ -12,15 +12,18 @@ pico_sdk_init()
add_executable(Mon_Projet add_executable(Mon_Projet
main.c main.c
i2c_maitre.c
i2c_slave.c
communication.c
) )
target_include_directories(Mon_Projet PRIVATE Mon_Projet_ULD_API/inc/) target_include_directories(Mon_Projet PRIVATE Mon_Projet_ULD_API/inc/)
target_link_libraries(Mon_Projet target_link_libraries(Mon_Projet
hardware_i2c hardware_i2c
hardware_uart hardware_adc
hardware_pwm hardware_pwm
hardware_adc hardware_uart
pico_stdlib pico_stdlib
pico_multicore pico_multicore
) )

107
communication.c Normal file
View File

@ -0,0 +1,107 @@
/*****
*
* Le principe est que la télécommande soit l'esclave I2C
* Pour envoyer un message, on charge le message à l'adresse 0 de la "mémoire" pour l'i2c
*
* Pour lire le message, le robot interroge la télécommande, et demande le contenu à partir de l'adresse 0 de la mémoire.
* Ainsi, en cas d'échec de la communication, le robot détectera une manette débranchée.
* Par défaut, la fonction lit 255 caractères.
*
* Copyright (c) 2024 - Club robotique de Riom
*
*
* SPDX-License-Identifier: BSD-3-Clause
*/
#include "i2c_fifo.h"
#include "i2c_slave.h"
#include "i2c_maitre.h"
#include "string.h"
/// DEBUT DE LA CONFIGURATION de L'I2C
#define I2C0_SDA_PIN 16
#define I2C0_SCL_PIN 17
#define I2C_SLAVE_ADDRESS 0x17
static const uint I2C_SLAVE_SDA_PIN = I2C0_SDA_PIN;
static const uint I2C_SLAVE_SCL_PIN = I2C0_SCL_PIN;
// The slave implements a 256 byte memory. To write a series of bytes, the master first
// writes the memory address, followed by the data. The address is automatically incremented
// for each byte transferred, looping back to 0 upon reaching the end. Reading is done
// sequentially from the current memory address.
static struct
{
uint8_t mem[256];
uint8_t mem_address;
bool mem_address_written;
} context;
// Our handler is called from the I2C ISR, so it must complete quickly. Blocking calls /
// printing to stdio may interfere with interrupt handling.
static void i2c_slave_handler(i2c_inst_t *i2c, i2c_slave_event_t event) {
switch (event) {
case I2C_SLAVE_RECEIVE: // master has written some data
if (!context.mem_address_written) {
// writes always start with the memory address
context.mem_address = i2c_read_byte(i2c);
context.mem_address_written = true;
} else {
// save into memory
context.mem[context.mem_address] = i2c_read_byte(i2c);
context.mem_address++;
}
break;
case I2C_SLAVE_REQUEST: // master is requesting data
// load from memory
i2c_write_byte(i2c, context.mem[context.mem_address]);
context.mem_address++;
break;
case I2C_SLAVE_FINISH: // master has signalled Stop / Restart
context.mem_address_written = false;
break;
default:
break;
}
}
void i2c_set_slave_mode_perso(i2c_inst_t *i2c, uint8_t addr) {
i2c->hw->enable = 0;
//while( !(i2c->hw->enable_status & 0x1) );
i2c->hw->sar = addr;
i2c->hw->con = 0;
i2c->hw->enable = 1;
}
static void setup_slave() {
gpio_init(I2C_SLAVE_SDA_PIN);
gpio_set_function(I2C_SLAVE_SDA_PIN, GPIO_FUNC_I2C);
gpio_pull_up(I2C_SLAVE_SDA_PIN);
gpio_init(I2C_SLAVE_SCL_PIN);
gpio_set_function(I2C_SLAVE_SCL_PIN, GPIO_FUNC_I2C);
gpio_pull_up(I2C_SLAVE_SCL_PIN);
i2c_slave_init(i2c0, I2C_SLAVE_ADDRESS, &i2c_slave_handler);
}
/// FIN DE LA CONFIGURATION de L'I2C
void communication_init(void){
setup_slave();
i2c_maitre_init();
}
void communication_envoyer_message(unsigned char * message, unsigned int message_length){
memcpy(context.mem, message, message_length);
}
int communication_lire_message(unsigned char * message){
i2c_lire_registre(I2C_SLAVE_ADDRESS, 0, message, 255);
}

5
communication.h Normal file
View File

@ -0,0 +1,5 @@
#include "i2c_maitre.h"
void communication_init(void);
void communication_envoyer_message(unsigned char * message, unsigned int message_length);
enum i2c_resultat_t communication_lire_message(unsigned char * message);

53
i2c_fifo.h Normal file
View File

@ -0,0 +1,53 @@
/*
* Copyright (c) 2021 Valentin Milea <valentin.milea@gmail.com>
*
* SPDX-License-Identifier: MIT
*/
#ifndef _I2C_FIFO_H_
#define _I2C_FIFO_H_
#include <hardware/i2c.h>
#ifdef __cplusplus
extern "C" {
#endif
/** \file i2c_fifo.h
*
* \brief I2C non-blocking r/w.
*/
/**
* \brief Pop a byte from I2C Rx FIFO.
*
* This function is non-blocking and assumes the Rx FIFO isn't empty.
*
* \param i2c I2C instance.
* \return uint8_t Byte value.
*/
static inline uint8_t i2c_read_byte(i2c_inst_t *i2c) {
i2c_hw_t *hw = i2c_get_hw(i2c);
assert(hw->status & I2C_IC_STATUS_RFNE_BITS); // Rx FIFO must not be empty
return (uint8_t)hw->data_cmd;
}
/**
* \brief Push a byte into I2C Tx FIFO.
*
* This function is non-blocking and assumes the Tx FIFO isn't full.
*
* \param i2c I2C instance.
* \param value Byte value.
*/
static inline void i2c_write_byte(i2c_inst_t *i2c, uint8_t value) {
i2c_hw_t *hw = i2c_get_hw(i2c);
assert(hw->status & I2C_IC_STATUS_TFNF_BITS); // Tx FIFO must not be full
hw->data_cmd = value;
}
#ifdef __cplusplus
}
#endif
#endif // _I2C_FIFO_H_

281
i2c_maitre.c Normal file
View File

@ -0,0 +1,281 @@
#include "i2c_maitre.h"
#include "hardware/gpio.h"
#include "hardware/i2c.h"
#include "pico/stdlib.h"
#include <stdio.h>
#define I2C1_SDA_PIN 18
#define I2C1_SCL_PIN 19
#define I2C_NB_MAX_TAMPON 20
enum i2c_statu_t{
I2C_STATU_LIBRE,
I2C_STATU_OCCUPE
} i2c_statu_i2c1;
uint16_t I2C_tampon_envoi[I2C_NB_MAX_TAMPON];
uint8_t I2C_tampon_reception[I2C_NB_MAX_TAMPON];
uint16_t I2C_nb_a_envoyer, I2C_nb_a_recevoir;
uint8_t adresse_7_bits;
uint32_t i2c_error_code; // value of i2c->hw->tx_abrt_source if anything wrong happen, 0 if everything was fine.
enum transaction_statu_t{
TRANSACTION_EN_COURS,
TRANSACTION_TERMINEE
} statu_emission, statu_reception;
void i2d_set_adresse_esclave(uint8_t _adresse_7bits);
void i2c_charger_tampon_envoi(uint8_t* emission, uint16_t nb_envoi, uint16_t nb_reception);
enum i2c_resultat_t i2c_transmission(uint8_t _adresse_7bits, uint8_t* emission, uint16_t nb_envoi, uint16_t nb_reception);
void i2c_maitre_init(void){
//stdio_init_all();
i2c_init(i2c1, 100 * 1000);
printf("Initialisation des broches\n");
for(int i=0; i++; i<=28){
if(gpio_get_function(i) == GPIO_FUNC_I2C){
printf("Borche I2C : %d\n", i);
gpio_set_function(i, GPIO_FUNC_NULL);
}
}
printf("%d et %d en I2C\n", I2C1_SDA_PIN, I2C1_SCL_PIN);
gpio_set_function(I2C1_SDA_PIN, GPIO_FUNC_I2C);
gpio_set_function(I2C1_SCL_PIN, GPIO_FUNC_I2C);
gpio_pull_up(I2C1_SDA_PIN);
gpio_pull_up(I2C1_SCL_PIN);
i2c_statu_i2c1 = I2C_STATU_LIBRE;
}
/// @brief Fonction à appeler régulièrement ou en interruption.
/// @param i2c
void i2c_gestion(i2c_inst_t *i2c){
// on veut gérer l'i2c avec cette fonction.
// 2 cas :
// - Soit écriture simple (plusieurs octets (W))
// - Soit écriture + lecture (Adresse (W), registre (W), données (R))
// Pour écrire 1 octet, i2c->hw->data_cmd = xxx, (avec CMD:8 à 0, )
// Pour lire 1 octet, i2c->hw->data_cmd = xxx (avec CMD:8 à 1)
// Il faut mettre CMD:9 à 1 pour le dernier octet.
// Envoi des données (ou des demandes de lecture)
static uint16_t index_envoi=0, index_reception=0;
// Acquitement des erreurs, pas 100% fonctionnel ! TODO !
if(i2c->hw->tx_abrt_source !=0){
// Seule solution trouvée pour réinitialiser l'I2C.
char a;
i2c_read_blocking(i2c, adresse_7_bits, &a, 1, false);
I2C_nb_a_envoyer = 0;
index_reception = 0;
I2C_nb_a_recevoir = 0;
statu_emission = TRANSACTION_TERMINEE;
statu_reception = TRANSACTION_TERMINEE;
i2c_statu_i2c1 = I2C_STATU_LIBRE;
}
while( (index_envoi < I2C_nb_a_envoyer) && (i2c_get_write_available(i2c)) ){
bool restart = false;
bool last = false;
if (index_envoi == 0){
// Début de l'envoi, assurons nous d'avoir la bonne adresse de l'esclave
i2c->hw->enable = 0;
i2c->hw->tar = adresse_7_bits;
i2c->hw->enable = 1;
}else{
// Passage de l'écriture à la lecture, on envoie un bit de restart.
if( !(I2C_tampon_envoi[index_envoi-1] & I2C_IC_DATA_CMD_CMD_BITS) &&
(I2C_tampon_envoi[index_envoi] & I2C_IC_DATA_CMD_CMD_BITS)){
restart = true;
}
}
if(index_envoi + 1 == I2C_nb_a_envoyer){
// Fin de la trame, nous devons envoyer un bit de stop.
last = true;
}
i2c->hw->data_cmd =
I2C_tampon_envoi[index_envoi] |
bool_to_bit(restart) << I2C_IC_DATA_CMD_RESTART_LSB |
bool_to_bit(last) << I2C_IC_DATA_CMD_STOP_LSB;
if(last){
statu_emission = TRANSACTION_TERMINEE;
index_envoi = 0;
I2C_nb_a_envoyer = 0;
//printf("I2C emission terminee\n");
}else{
index_envoi++;
}
}
// Réception des données - Lecture des données présentes dans le tampon
while( (index_reception < I2C_nb_a_recevoir) && (i2c_get_read_available(i2c)) ){
I2C_tampon_reception[index_reception] = (uint8_t) i2c->hw->data_cmd;
index_reception++;
}
if(index_reception == I2C_nb_a_recevoir){
statu_reception = TRANSACTION_TERMINEE;
index_reception = 0;
I2C_nb_a_recevoir = 0;
}
if(statu_reception == TRANSACTION_TERMINEE && statu_emission == TRANSACTION_TERMINEE){
i2c_statu_i2c1 = I2C_STATU_LIBRE;
}
}
/// @brief Charge le tampon d'émission pour pré-mâcher le travail à la fonction i2c_gestion
/// @param emission
/// @param nb_envoi
/// @param nb_reception
void i2c_charger_tampon_envoi(uint8_t* emission, uint16_t nb_envoi, uint16_t nb_reception){
// Données à envoyer
for(unsigned int index=0; index<nb_envoi; index++){
I2C_tampon_envoi[index] = (uint16_t) emission[index];
}
// Données à lire
for(unsigned int index=0; index<nb_reception; index++){
I2C_tampon_envoi[nb_envoi + index] = (uint16_t) 0x0100;
}
}
/// @brief Stock l'adresse de l'esclave avec lequel communiquer
/// @param _adresse_7bits
void i2d_set_adresse_esclave(uint8_t _adresse_7bits){
adresse_7_bits =_adresse_7bits;
}
/// @brief Initialise la transmission I2, sur l'i2c1. Une transmission se compose de 2 trames I2C, une pour écrire (Adresse + données), une pour lire
/// Si nb_reception = 0, alors la trame pour lire ne sera pas envoyée.
/// @param emission : données à envoyer
/// @param nb_envoi : nombre de données à envoyer
/// @param nb_reception : nombre de données à recevoir
/// @return I2C_EN_COURS, I2C_SUCCES ou I2C_ECHEC
enum i2c_resultat_t i2c_transmission(uint8_t _adresse_7bits, uint8_t* emission, uint16_t nb_envoi, uint16_t nb_reception){
static enum m_statu_t{
I2C_STATU_INIT,
I2C_STATU_EN_COURS,
}m_statu = I2C_STATU_INIT;
switch(m_statu){
case I2C_STATU_INIT:
// I2C libre ?
if(i2c_statu_i2c1 == I2C_STATU_OCCUPE){
return I2C_EN_COURS;
}
// Alors il est à nous !
i2c_statu_i2c1 = I2C_STATU_OCCUPE;
statu_emission = TRANSACTION_EN_COURS;
statu_reception = TRANSACTION_EN_COURS;
i2c_error_code = 0;
i2d_set_adresse_esclave(_adresse_7bits);
i2c_charger_tampon_envoi(emission, nb_envoi, nb_reception);
// Nous devons envoyer aussi une commande pour chaque octet à recevoir.
I2C_nb_a_envoyer = nb_envoi + nb_reception;
I2C_nb_a_recevoir = nb_reception;
// On appelle la fonction gestion pour gagner du temps.
i2c_gestion(i2c1);
m_statu = I2C_STATU_EN_COURS;
break;
case I2C_STATU_EN_COURS:
if(i2c_statu_i2c1 == I2C_STATU_LIBRE){
m_statu = I2C_STATU_INIT;
if(i2c_error_code){
return I2C_ECHEC;
}else{
return I2C_SUCCES;
}
}
break;
}
return I2C_EN_COURS;
}
/// @brief Lit le registre d'un composant se comportant comme une EPROM I2C.
/// @return I2C_SUCCES, I2C_EN_COURS ou I2C_ECHEC
enum i2c_resultat_t i2c_lire_registre_nb(uint8_t adresse_7_bits, uint8_t registre, uint8_t * reception, uint8_t len){
uint8_t emission[1];
emission[0] = registre;
enum i2c_resultat_t i2c_resultat;
i2c_resultat = i2c_transmission(adresse_7_bits, emission, 1, len);
if(i2c_resultat == I2C_SUCCES){
for(uint32_t i = 0; i < len; i++){
reception[i] = I2C_tampon_reception[i];
}
return I2C_SUCCES;
}else if(i2c_resultat == I2C_ECHEC){
return I2C_ECHEC;
}
return I2C_EN_COURS;
}
/// @brief Initialise une transaction I2C.
/// Renvoie I2C_SUCCES si l'intégralité du message est chargé en envoi,
/// Renvoie I2C_EN_COURS si la fonction doit encore être appelée pour finir d'envoyer le message
/// Renvoie I2C_ECHEC en cas d'erreur I2C.
enum i2c_resultat_t i2c_ecrire_registre_nb(uint8_t adresse_7_bits, uint8_t registre, uint8_t * _emission, uint8_t len){
uint8_t emission[I2C_NB_MAX_TAMPON];
emission[0] = registre;
for(uint32_t i = 0; i < len; i++){
emission[i+1] = _emission[i];
}
enum i2c_resultat_t i2c_resultat;
return i2c_transmission(adresse_7_bits, emission, 1 + len, 0);
}
/// @brief Pour l'instant bloquant, mais devrait passer en non bloquant bientôt => Non, voir i2c_lire_registre_nb
/// @param adresse_7_bits
/// @param
/// @return I2C_SUCCES (1) ou I2C_ECHEC (2)
int i2c_lire_registre(char adresse_7_bits, char registre, unsigned char * reception, char len){
int statu;
char emission[1];
emission[0] = registre;
statu = i2c_write_blocking (i2c1, adresse_7_bits, emission, 1, 0);
if(statu == PICO_ERROR_GENERIC){
printf("I2C - Envoi registre Echec\n");
return I2C_ECHEC;
}
statu = i2c_read_blocking (i2c1, adresse_7_bits, reception, len, 0);
if(statu == PICO_ERROR_GENERIC){
printf("I2C - Lecture registre Echec\n");
return I2C_ECHEC;
}
return I2C_SUCCES;
}
int i2c_ecrire_registre(char adresse_7_bits, char registre, char valeur_registre){
int statu;
char emission[2];
emission[0] = registre;
emission[1] = valeur_registre;
statu = i2c_write_blocking (i2c1, adresse_7_bits, emission, 2, 0);
if(statu == PICO_ERROR_GENERIC){
printf("Erreur ecrire registre\n");
return I2C_ECHEC;
}
printf("i2c Registre %x, valeur %x\n", registre, valeur_registre);
return I2C_SUCCES;
}

15
i2c_maitre.h Normal file
View File

@ -0,0 +1,15 @@
#include "pico/stdlib.h"
#include "hardware/i2c.h"
enum i2c_resultat_t {
I2C_EN_COURS,
I2C_SUCCES,
I2C_ECHEC
};
void i2c_maitre_init(void);
void i2c_gestion(i2c_inst_t *i2c);
enum i2c_resultat_t i2c_lire_registre_nb(uint8_t adresse_7_bits, uint8_t registre, uint8_t * reception, uint8_t len);
enum i2c_resultat_t i2c_ecrire_registre_nb(uint8_t adresse_7_bits, uint8_t registre, uint8_t * _emission, uint8_t len);
int i2c_ecrire_registre(char adresse_7_bits, char registre, char valeur_registre);
int i2c_lire_registre(char adresse_7_bits, char registre, unsigned char * reception, char len);

108
i2c_slave.c Normal file
View File

@ -0,0 +1,108 @@
/*
* Copyright (c) 2021 Valentin Milea <valentin.milea@gmail.com>
*
* SPDX-License-Identifier: MIT
*/
#include "i2c_slave.h"
#include "hardware/irq.h"
typedef struct i2c_slave_t
{
i2c_inst_t *i2c;
i2c_slave_handler_t handler;
bool transfer_in_progress;
} i2c_slave_t;
static i2c_slave_t i2c_slaves[2];
static inline void finish_transfer(i2c_slave_t *slave) {
if (slave->transfer_in_progress) {
slave->handler(slave->i2c, I2C_SLAVE_FINISH);
slave->transfer_in_progress = false;
}
}
static void __not_in_flash_func(i2c_slave_irq_handler)(i2c_slave_t *slave) {
i2c_inst_t *i2c = slave->i2c;
i2c_hw_t *hw = i2c_get_hw(i2c);
uint32_t intr_stat = hw->intr_stat;
if (intr_stat == 0) {
return;
}
if (intr_stat & I2C_IC_INTR_STAT_R_TX_ABRT_BITS) {
hw->clr_tx_abrt;
finish_transfer(slave);
}
if (intr_stat & I2C_IC_INTR_STAT_R_START_DET_BITS) {
hw->clr_start_det;
finish_transfer(slave);
}
if (intr_stat & I2C_IC_INTR_STAT_R_STOP_DET_BITS) {
hw->clr_stop_det;
finish_transfer(slave);
}
if (intr_stat & I2C_IC_INTR_STAT_R_RX_FULL_BITS) {
slave->transfer_in_progress = true;
slave->handler(i2c, I2C_SLAVE_RECEIVE);
}
if (intr_stat & I2C_IC_INTR_STAT_R_RD_REQ_BITS) {
hw->clr_rd_req;
slave->transfer_in_progress = true;
slave->handler(i2c, I2C_SLAVE_REQUEST);
}
}
static void __not_in_flash_func(i2c0_slave_irq_handler)() {
i2c_slave_irq_handler(&i2c_slaves[0]);
}
static void __not_in_flash_func(i2c1_slave_irq_handler)() {
i2c_slave_irq_handler(&i2c_slaves[1]);
}
void i2c_slave_init(i2c_inst_t *i2c, uint8_t address, i2c_slave_handler_t handler) {
assert(i2c == i2c0 || i2c == i2c1);
assert(handler != NULL);
uint i2c_index = i2c_hw_index(i2c);
i2c_slave_t *slave = &i2c_slaves[i2c_index];
slave->i2c = i2c;
slave->handler = handler;
// Note: The I2C slave does clock stretching implicitly after a RD_REQ, while the Tx FIFO is empty.
// There is also an option to enable clock stretching while the Rx FIFO is full, but we leave it
// disabled since the Rx FIFO should never fill up (unless slave->handler() is way too slow).
i2c_set_slave_mode(i2c, true, address);
i2c_hw_t *hw = i2c_get_hw(i2c);
// unmask necessary interrupts
hw->intr_mask = I2C_IC_INTR_MASK_M_RX_FULL_BITS | I2C_IC_INTR_MASK_M_RD_REQ_BITS | I2C_IC_RAW_INTR_STAT_TX_ABRT_BITS | I2C_IC_INTR_MASK_M_STOP_DET_BITS | I2C_IC_INTR_MASK_M_START_DET_BITS;
// enable interrupt for current core
uint num = I2C0_IRQ + i2c_index;
irq_set_exclusive_handler(num, i2c_index == 0 ? i2c0_slave_irq_handler : i2c1_slave_irq_handler);
irq_set_enabled(num, true);
}
void i2c_slave_deinit(i2c_inst_t *i2c) {
assert(i2c == i2c0 || i2c == i2c1);
uint i2c_index = i2c_hw_index(i2c);
i2c_slave_t *slave = &i2c_slaves[i2c_index];
assert(slave->i2c == i2c); // should be called after i2c_slave_init()
slave->i2c = NULL;
slave->handler = NULL;
slave->transfer_in_progress = false;
uint num = I2C0_IRQ + i2c_index;
irq_set_enabled(num, false);
irq_remove_handler(num, i2c_index == 0 ? i2c0_slave_irq_handler : i2c1_slave_irq_handler);
i2c_hw_t *hw = i2c_get_hw(i2c);
hw->intr_mask = I2C_IC_INTR_MASK_RESET;
i2c_set_slave_mode(i2c, false, 0);
}

66
i2c_slave.h Normal file
View File

@ -0,0 +1,66 @@
/*
* Copyright (c) 2021 Valentin Milea <valentin.milea@gmail.com>
*
* SPDX-License-Identifier: MIT
*/
#ifndef _I2C_SLAVE_H_
#define _I2C_SLAVE_H_
#include <hardware/i2c.h>
#include <pico/stdlib.h>
#ifdef __cplusplus
extern "C" {
#endif
/** \file i2c_slave.h
*
* \brief I2C slave setup.
*/
/**
* \brief I2C slave event types.
*/
typedef enum i2c_slave_event_t
{
I2C_SLAVE_RECEIVE, /**< Data from master is available for reading. Slave must read from Rx FIFO. */
I2C_SLAVE_REQUEST, /**< Master is requesting data. Slave must write into Tx FIFO. */
I2C_SLAVE_FINISH, /**< Master has sent a Stop or Restart signal. Slave may prepare for the next transfer. */
} i2c_slave_event_t;
/**
* \brief I2C slave event handler
*
* The event handler will run from the I2C ISR, so it should return quickly (under 25 us at 400 kb/s).
* Avoid blocking inside the handler and split large data transfers across multiple calls for best results.
* When sending data to master, up to `i2c_get_write_available()` bytes can be written without blocking.
* When receiving data from master, up to `i2c_get_read_available()` bytes can be read without blocking.
*
* \param i2c Slave I2C instance.
* \param event Event type.
*/
typedef void (*i2c_slave_handler_t)(i2c_inst_t *i2c, i2c_slave_event_t event);
/**
* \brief Configure I2C instance for slave mode.
*
* \param i2c I2C instance.
* \param address 7-bit slave address.
* \param handler Called on events from I2C master. It will run from the I2C ISR, on the CPU core
* where the slave was initialized.
*/
void i2c_slave_init(i2c_inst_t *i2c, uint8_t address, i2c_slave_handler_t handler);
/**
* \brief Restore I2C instance to master mode.
*
* \param i2c I2C instance.
*/
void i2c_slave_deinit(i2c_inst_t *i2c);
#ifdef __cplusplus
}
#endif
#endif // _I2C_SLAVE_H_

76
main.c
View File

@ -3,17 +3,22 @@
* *
* SPDX-License-Identifier: BSD-3-Clause * SPDX-License-Identifier: BSD-3-Clause
*/ */
#include "communication.h"
#include "pico/stdlib.h" #include "pico/stdlib.h"
#include "hardware/pwm.h" #include "hardware/pwm.h"
#include <stdio.h> #include <stdio.h>
#include "hardware/adc.h" #include "hardware/adc.h"
#define LED_VERTE 25 #define LED_VERTE 25
#define PIN_VITESSE_M1 2 #define PIN_VITESSE_M1 2
#define PIN_SENS_A_M1 0 #define PIN_SENS_A_M1 0
#define PIN_SENS_B_M1 1 #define PIN_SENS_B_M1 1
uint16_t result1 = 0; int result0, result1;
uint16_t result0 = 0; int joystic_clicker;
int pince;
int ascenceur;
int M1_INITIALISE() int M1_INITIALISE()
{ {
gpio_init(PIN_VITESSE_M1); gpio_init(PIN_VITESSE_M1);
@ -71,7 +76,7 @@ int AdcRead0()
int AdcRead1() int AdcRead1()
{ {
adc_select_input(1); adc_select_input(1);
uint16_t resultadc= adc_read(); uint16_t resultadc = adc_read();
return resultadc; return resultadc;
} }
@ -82,8 +87,16 @@ int AdcRead1()
void main() void main()
{ {
char message [256];
stdio_init_all(); stdio_init_all();
// Communication
communication_init();
// Pour envoyer un message
// communication_envoyer_message(message, 254);
// CLignottement LED // CLignottement LED
gpio_set_function(LED_VERTE, GPIO_FUNC_PWM); gpio_set_function(LED_VERTE, GPIO_FUNC_PWM);
pwm_set_wrap(4, 100); pwm_set_wrap(4, 100);
@ -97,20 +110,57 @@ void main()
while (1) while (1)
{ {
// Voie Y
result0 = AdcRead0();
printf(">result:%d\n",result0-2048);
// Voie X // Voie X
result1 = AdcRead1(); result1 = AdcRead1();
printf(">result1:%d\n",result1-2048);
printf("test\n",result0); message[0] = result1/16;
// Voie Y
result0 = AdcRead0();
message[1] = result0/16;
//clic sur le joystic
gpio_init(1);
gpio_pull_up(1);
gpio_set_dir(1, GPIO_IN);
joystic_clicker = gpio_get(1);
if (!joystic_clicker)
{
message[2] = result1/16;
message[1] = 128;
message[0] = 128;
}
else
{
message[2] = 128;
}
//pince
gpio_init(2);
gpio_set_dir(2, GPIO_IN);
gpio_pull_up(2);
pince = gpio_get(2);
message [3] = pince;
gpio_init(6);
gpio_set_dir(6, GPIO_IN);
gpio_pull_up(6);
ascenceur = gpio_get(6);
message[4] = ascenceur;
printf(">x:%d\n", message[0]);
printf(">Y:%d\n", message[1]);
printf(">Rz:%d\n", message[2]);
printf(">pince:%d\n", message[3]);
printf(">ascenceur:%d\n", message[4]);
sleep_ms(100); sleep_ms(100);
communication_envoyer_message(message, 254);
} }
M1_INITIALISE(); M1_INITIALISE();
while(1) while(1)
{ {
M1_AVANCE(); M1_AVANCE();
@ -120,4 +170,4 @@ void main()
} }
} }