//                         USART 1 (WiFi)
////////////////////////////////////////////////////////////////////////////////////////
/* enter necessary header files for proper interrupt vector and UART/USART visibility */
////////////////////////////////////////////////////////////////////////////////////////
 
#include<stdio.h>
#include "sw_fifo_1.h"
#include "stm32f4xx_hal.h"

static void uart1RxIntHandler();
static void uart1TxIntHandler();
static void uart_1_send_byte(uint8_t byte);


volatile uint8_t uart1_rx_fifo_not_empty_flag = 0;
volatile uint8_t uart1_rx_fifo_full_flag      = 0;
volatile uint8_t uart1_rx_fifo_ovf_flag       = 0; 
volatile uint8_t uart1_tx_fifo_full_flag      = 0;
volatile uint8_t uart1_tx_fifo_ovf_flag       = 0;
volatile uint8_t uart1_tx_fifo_not_empty_flag = 0;

// ********************************************** USART 1 **********************************************
// ************************************** PUBLIC FUNCTIONS *********************************************


void uart1Interrupt(void) {

  if( USART1->SR & USART_SR_TXE ) {
      uart1TxIntHandler();
    }
    if( USART1->SR & USART_SR_RXNE ) {
      uart1RxIntHandler();
    }
}

int fputc_1(int iChar, FILE *f)
{
    unsigned char c=iChar;
    
    if(uart1_tx_fifo_full_flag) return iChar;   // Exit if the buffer is full
    
    uart_1_send_byte(c);

    return iChar;
}

int fgetc_1(FILE *f)
{
  __IO int i=0;
  
  i++;
    return 1;
}

void send_usart1(unsigned char c) {
  
  if(uart1_tx_fifo_full_flag) return;   // Exit if the buffer is full
  
  uart_1_send_byte(c);  
}



// ********************************************** USART 1 ************************************************



 
typedef struct {
  uint8_t  data_buf[FIFO_1_BUFFER_SIZE]; // FIFO buffer
  uint16_t i_first;                    // index of oldest data byte in buffer
  uint16_t i_last;                     // index of newest data byte in buffer
  uint16_t num_bytes;                  // number of bytes currently in buffer
}sw_fifo_1_typedef;
 
sw_fifo_1_typedef rx_fifo_1 = { {0}, 0, 0, 0 }; // declare a receive software buffer
sw_fifo_1_typedef tx_fifo_1 = { {0}, 0, 0, 0 }; // declare a transmit software buffer
 
 
/***************************************************************************************************************/
// UART receive interrupt sub-routine
//  - interrupts when valid data exists in rx hardware buffer
//  - checks if there's room in the rx software buffer
//  - if there's room, it transfers the received data into the sw buffer
//  - automatically handles "uart_rx_buffer_full_flag"
//  - sets overflow flag upon software buffer overflow (doesn't overwrite existing data)
//////////////////////////////////////////////
static void uart1RxIntHandler() {
//////////////////////////////////////////////
   
  
  if(rx_fifo_1.num_bytes == FIFO_1_BUFFER_SIZE) {      // if the sw buffer is full
    uart1_rx_fifo_ovf_flag = 1;                     // set the overflow flag
  }else if(rx_fifo_1.num_bytes < FIFO_1_BUFFER_SIZE) { // if there's room in the sw buffer
     
     
    rx_fifo_1.data_buf[rx_fifo_1.i_last] = USART1->DR; /* enter pointer to UART rx hardware buffer here */ // store the received data as the newest data element in the sw buffer
     
    rx_fifo_1.i_last++;                              // increment the index of the most recently added element
    rx_fifo_1.num_bytes++;                           // increment the bytes counter
  }
  if(rx_fifo_1.num_bytes == FIFO_1_BUFFER_SIZE) {      // if sw buffer just filled up
    uart1_rx_fifo_full_flag = 1;                    // set the RX FIFO full flag
  }
  if(rx_fifo_1.i_last == FIFO_1_BUFFER_SIZE) {         // if the index has reached the end of the buffer,
    rx_fifo_1.i_last = 0;                            // roll over the index counter
  }
  uart1_rx_fifo_not_empty_flag = 1;                 // set received-data flag
}
/***************************************************************************************************************/
 
 
/***************************************************************************************************************/
// UART transmit interrupt sub-routine
//  - interrupts when the tx hardware buffer is empty
//  - checks if data exists in the tx software buffer
//  - if data exists, it places the oldest element of the sw buffer into the tx hardware buffer
//  - if the sw buffer is emptied, it disables the "hw buffer empty" interrupt
//  - automatically handles "uart_tx_buffer_full_flag"
//////////////////////////////////////////////
static void uart1TxIntHandler() {
 
  if(tx_fifo_1.num_bytes == FIFO_1_BUFFER_SIZE) { // if the sw buffer is full
    uart1_tx_fifo_full_flag = 0;               // clear the buffer full flag because we are about to make room
  }
  if(tx_fifo_1.num_bytes > 0) {                 // if data exists in the sw buffer
     
    USART1->DR = tx_fifo_1.data_buf[tx_fifo_1.i_first]; // place oldest data element in the TX hardware buffer
     
    tx_fifo_1.i_first++;                        // increment the index of the oldest element
    tx_fifo_1.num_bytes--;                      // decrement the bytes counter
  }
  if(tx_fifo_1.i_first == FIFO_1_BUFFER_SIZE) {   // if the index has reached the end of the buffer,
    tx_fifo_1.i_first = 0;                      // roll over the index counter
  }
  if(tx_fifo_1.num_bytes == 0) {                // if no more data exists
 
    uart1_tx_fifo_not_empty_flag = 0;          // clear flag
 
    USART1->CR1 &= ~(USART_CR1_TXEIE);        // Disable TX Empty Interrupt     
  }
}
/***************************************************************************************************************/
 
 
/***************************************************************************************************************/
// UART data transmit function
//  - checks if there's room in the transmit sw buffer
//  - if there's room, it transfers data byte to sw buffer
//  - automatically handles "uart_tx_buffer_full_flag"
//  - sets the overflow flag upon software buffer overflow (doesn't overwrite existing data)
//  - if this is the first data byte in the buffer, it enables the "hw buffer empty" interrupt
static void uart_1_send_byte(uint8_t byte) {
   
  ///////////////////////////////////////////////////////////
  /* disable interrupts while manipulating buffer pointers */
  ///////////////////////////////////////////////////////////
  unsigned int istate = USART1->CR1 & USART_CR1_TXEIE;
  USART1->CR1 &= ~(USART_CR1_TXEIE);        // Disable TX Empty Interrupt  
  
 
  if(tx_fifo_1.num_bytes == FIFO_1_BUFFER_SIZE) {      // no room in the sw buffer
    uart1_tx_fifo_ovf_flag = 1;                     // set the overflow flag
  }else if(tx_fifo_1.num_bytes < FIFO_1_BUFFER_SIZE) { // if there's room in the sw buffer
    tx_fifo_1.data_buf[tx_fifo_1.i_last] = byte;       // transfer data byte to sw buffer
    tx_fifo_1.i_last++;                              // increment the index of the most recently added element
    tx_fifo_1.num_bytes++;                           // increment the bytes counter
  }
  if(tx_fifo_1.num_bytes == FIFO_1_BUFFER_SIZE) {      // if sw buffer is full
    uart1_tx_fifo_full_flag = 1;                    // set the TX FIFO full flag
  }
  if(tx_fifo_1.i_last == FIFO_1_BUFFER_SIZE) {         // if the "new data" index has reached the end of the buffer,
    tx_fifo_1.i_last = 0;                            // roll over the index counter
  }

  
    
  ///////////////////////
  /* enable interrupts */
  ///////////////////////
  if( istate ) 
    USART1->CR1 |=   USART_CR1_TXEIE;
 
  if(tx_fifo_1.num_bytes > 0) {                      // if there is data in the buffer
 
    uart1_tx_fifo_not_empty_flag = 1;               // set flag
     
    USART1->CR1 |= USART_CR1_TXEIE;               // Enable TX Empty Interrupt     
     
  }
}

int uart1serialAvailable() {
  return rx_fifo_1.num_bytes;
}

/***************************************************************************************************************/
// UART data receive function
//  - checks if data exists in the receive sw buffer
//  - if data exists, it returns the oldest element contained in the buffer
//  - automatically handles "uart_rx_buffer_full_flag"
//  - if no data exists, it clears the uart_rx_flag
unsigned char uart_1_get_byte(void) {          
      
  ///////////////////////////////////////////////////////////
  /* disable interrupts while manipulating buffer pointers */
  ///////////////////////////////////////////////////////////
  USART1->CR1 &= ~(USART_CR1_RXNEIE);        // Disable RX Empty Interrupt 
   
  uint8_t byte = 0;
  if(rx_fifo_1.num_bytes == FIFO_1_BUFFER_SIZE) { // if the sw buffer is full
    uart1_rx_fifo_full_flag = 0;               // clear the buffer full flag because we are about to make room
  }
  if(rx_fifo_1.num_bytes > 0) {                 // if data exists in the sw buffer
    byte = rx_fifo_1.data_buf[rx_fifo_1.i_first]; // grab the oldest element in the buffer
    rx_fifo_1.i_first++;                        // increment the index of the oldest element
    rx_fifo_1.num_bytes--;                      // decrement the bytes counter
  }else{                                      // RX sw buffer is empty
    uart1_rx_fifo_not_empty_flag = 0;          // clear the rx flag
  }
  if(rx_fifo_1.i_first == FIFO_1_BUFFER_SIZE) {   // if the index has reached the end of the buffer,
    rx_fifo_1.i_first = 0;                      // roll over the index counter
  }
 
  ///////////////////////
  /* enable interrupts */
  ///////////////////////
  USART1->CR1 |= USART_CR1_RXNEIE;
 
  return (unsigned char)byte;                                // return the data byte
}