//----------------------------------------------------------------------------
//  Description:  This file contains functions that allow the MSP430 device to 
//  access the SPI interface of the CC1100/CC2500.  There are multiple 
//  instances of each function; the one to be compiled is selected by the 
//  system variable TI_CC_RF_SER_INTF, defined in "TI_CC_hardware_board.h".
//
//  MSP430/CC1100-2500 Interface Code Library v1.0
//
//  K. Quiring
//  Texas Instruments, Inc.
//  July 2006
//  IAR Embedded Workbench v3.41
//----------------------------------------------------------------------------


#include "include.h"
#include "TI_CC_spi.h"


//----------------------------------------------------------------------------
//  void TI_CC_SPISetup(void)
//
//  DESCRIPTION:
//  Configures the assigned interface to function as a SPI port and
//  initializes it.
//----------------------------------------------------------------------------
//  void TI_CC_SPIWriteReg(char addr, char value)
//
//  DESCRIPTION:
//  Writes "value" to a single configuration register at address "addr".
//----------------------------------------------------------------------------
//  void TI_CC_SPIWriteBurstReg(char addr, char *buffer, char count)
//
//  DESCRIPTION:
//  Writes values to multiple configuration registers, the first register being
//  at address "addr".  First data byte is at "buffer", and both addr and
//  buffer are incremented sequentially (within the CCxxxx and MSP430,
//  respectively) until "count" writes have been performed.
//----------------------------------------------------------------------------
//  char TI_CC_SPIReadReg(char addr)
//
//  DESCRIPTION:
//  Reads a single configuration register at address "addr" and returns the
//  value read.
//----------------------------------------------------------------------------
//  void TI_CC_SPIReadBurstReg(char addr, char *buffer, char count)
//
//  DESCRIPTION:
//  Reads multiple configuration registers, the first register being at address
//  "addr".  Values read are deposited sequentially starting at address
//  "buffer", until "count" registers have been read.
//----------------------------------------------------------------------------
//  char TI_CC_SPIReadStatus(char addr)
//
//  DESCRIPTION:
//  Special read function for reading status registers.  Reads status register
//  at register "addr" and returns the value read.
//----------------------------------------------------------------------------
//  void TI_CC_SPIStrobe(char strobe)
//
//  DESCRIPTION:
//  Special write function for writing to command strobe registers.  Writes
//  to the strobe at address "addr".
//----------------------------------------------------------------------------


// Delay function. # of CPU cycles delayed is similar to "cycles". Specifically,
// it's ((cycles-15) % 6) + 15.  Not exact, but gives a sense of the real-time
// delay.  Also, if MCLK ~1MHz, "cycles" is similar to # of useconds delayed.
void TI_CC_Wait(unsigned int cycles)
{
  while(cycles>15)                          // 15 cycles consumed by overhead
    cycles = cycles - 6;                    // 6 cycles consumed each iteration
}


// SPI port functions
#if TI_CC_RF_SER_INTF == TI_CC_SER_INTF_USART0


void TI_CC_SPISetup(void)
{
  TI_CC_CSn_PxOUT |= TI_CC_CSn_PIN;
  TI_CC_CSn_PxDIR |= TI_CC_CSn_PIN;         // /CS disable

  ME1 |= USPIE0;                            // Enable USART0 SPI mode
  UCTL0 |= CHAR + SYNC + MM;                // 8-bit SPI Master **SWRST**
  UTCTL0 |= CKPH + SSEL1 + SSEL0 + STC;     // SMCLK, 3-pin mode
  UBR00 = 0x02;                             // UCLK/2
  UBR10 = 0x00;                             // 0
  UMCTL0 = 0x00;                            // No modulation
  TI_CC_SPI_USART0_PxSEL |= TI_CC_SPI_USART0_SIMO | TI_CC_SPI_USART0_SOMI | TI_CC_SPI_USART0_UCLK;
                                            // SPI option select
  TI_CC_SPI_USART0_PxDIR |= TI_CC_SPI_USART0_SIMO + TI_CC_SPI_USART0_UCLK;
                                            // SPI TX out direction
  UCTL0 &= ~SWRST;                          // Initialize USART state machine
}

void TI_CC_SPIWriteReg(char addr, char value)
{
    TI_CC_CSn_PxOUT &= ~TI_CC_CSn_PIN;      // /CS enable
    while (TI_CC_SPI_USART0_PxIN&TI_CC_SPI_USART0_SOMI);// Wait for CCxxxx ready
    IFG1 &= ~URXIFG0;                       // Clear flag from first dummy byte
    U0TXBUF = addr;                         // Send address
    while (!(IFG1&URXIFG0));                // Wait for TX to finish
    IFG1 &= ~URXIFG0;                       // Clear flag from first dummy byte
    U0TXBUF = value;                        // Send value
    while (!(IFG1&URXIFG0));                // Wait for end of data TX
    TI_CC_CSn_PxOUT |= TI_CC_CSn_PIN;       // /CS disable
}

void TI_CC_SPIWriteBurstReg(char addr, char *buffer, char count)
{
    char i;

    TI_CC_CSn_PxOUT &= ~TI_CC_CSn_PIN;      // /CS enable
    while (TI_CC_SPI_USART0_PxIN&TI_CC_SPI_USART0_SOMI);// Wait for CCxxxx ready
    U0TXBUF = addr | TI_CCxxx0_WRITE_BURST; // Send address
    while (!(IFG1&UTXIFG0));                // Wait for TX to finish
    for (i = 0; i < count; i++)
    {
      U0TXBUF = buffer[i];                  // Send data
      while (!(IFG1&UTXIFG0));              // Wait for TX to finish
    }
    IFG1 &= ~URXIFG0;
    while(!(IFG1&URXIFG0));
    TI_CC_CSn_PxOUT |= TI_CC_CSn_PIN;       // /CS disable
}

char TI_CC_SPIReadReg(char addr)
{
  char x;

  TI_CC_CSn_PxOUT &= ~TI_CC_CSn_PIN;        // /CS enable
  while (TI_CC_SPI_USART0_PxIN&TI_CC_SPI_USART0_SOMI);// Wait for CCxxxx ready
  U0TXBUF = (addr | TI_CCxxx0_READ_SINGLE); // Send address
  while (!(IFG1&URXIFG0));                  // Wait for TX to finish
  IFG1 &= ~URXIFG0;                         // Clear flag set during last write
  U0TXBUF = 0;                              // Dummy write so we can read data
  while (!(IFG1&URXIFG0));                  // Wait for RX to finish
  x = U0RXBUF;                              // Read data
  TI_CC_CSn_PxOUT |= TI_CC_CSn_PIN;         // /CS disable

  return x;
}

void TI_CC_SPIReadBurstReg(char addr, char *buffer, char count)
{
  unsigned int i;

  TI_CC_CSn_PxOUT &= ~TI_CC_CSn_PIN;        // /CS enable
  while (TI_CC_SPI_USART0_PxIN&TI_CC_SPI_USART0_SOMI);// Wait for CCxxxx ready
  IFG1 &= ~URXIFG0;                         // Clear flag
  U0TXBUF = (addr | TI_CCxxx0_READ_BURST);  // Send address
  while (!(IFG1&UTXIFG0));                  // Wait for TXBUF ready
  U0TXBUF = 0;                              // Dummy write to read 1st data byte
  // Addr byte is now being TX'ed, with dummy byte to follow immediately after
  while (!(IFG1&URXIFG0));                  // Wait for end of addr byte TX
  IFG1 &= ~URXIFG0;                         // Clear flag
  while (!(IFG1&URXIFG0));                  // Wait for end of 1st data byte TX
  // First data byte now in RXBUF
  for (i = 0; i < (count-1); i++)
  {
    U0TXBUF = 0;                            //Initiate next data RX, meanwhile..
    buffer[i] = U0RXBUF;                    // Store data from last data RX
    while (!(IFG1&URXIFG0));                // Wait for end of data RX
  }
  buffer[count-1] = U0RXBUF;                // Store last RX byte in buffer
  TI_CC_CSn_PxOUT |= TI_CC_CSn_PIN;         // /CS disable
}

// For status/strobe addresses, the BURST bit selects between status registers
// and command strobes.
char TI_CC_SPIReadStatus(char addr)
{
  char x;

  TI_CC_CSn_PxOUT &= ~TI_CC_CSn_PIN;        // /CS enable
  while (TI_CC_SPI_USART0_PxIN & TI_CC_SPI_USART0_SOMI);// Wait for CCxxxx ready
  IFG1 &= ~URXIFG0;                         // Clear flag set during last write
  U0TXBUF = (addr | TI_CCxxx0_READ_BURST);  // Send address
  while (!(IFG1&URXIFG0));                  // Wait for TX to finish
  IFG1 &= ~URXIFG0;                         // Clear flag set during last write
  U0TXBUF = 0;                              // Dummy write so we can read data
  while (!(IFG1&URXIFG0));                  // Wait for RX to finish
  x = U0RXBUF;                              // Read data
  TI_CC_CSn_PxOUT |= TI_CC_CSn_PIN;         // /CS disable

  return x;
}

void TI_CC_SPIStrobe(char strobe)
{
  TI_CC_CSn_PxOUT &= ~TI_CC_CSn_PIN;        // /CS enable
  while (TI_CC_SPI_USART0_PxIN&TI_CC_SPI_USART0_SOMI);// Wait for CCxxxx ready
  U0TXBUF = strobe;                         // Send strobe
  // Strobe addr is now being TX'ed
  IFG1 &= ~URXIFG0;                         // Clear flag
  while (!(IFG1&URXIFG0));                  // Wait for end of addr TX
  TI_CC_CSn_PxOUT |= TI_CC_CSn_PIN;         // /CS disable
}

void TI_CC_PowerupResetCCxxxx(void)
{
  TI_CC_CSn_PxOUT |= TI_CC_CSn_PIN;
  TI_CC_Wait(30);
  TI_CC_CSn_PxOUT &= ~TI_CC_CSn_PIN;
  TI_CC_Wait(30);
  TI_CC_CSn_PxOUT |= TI_CC_CSn_PIN;
  TI_CC_Wait(45);

  TI_CC_CSn_PxOUT &= ~TI_CC_CSn_PIN;        // /CS enable
  while (TI_CC_SPI_USART0_PxIN&TI_CC_SPI_USART0_SOMI);// Wait for CCxxxx ready
  U0TXBUF = TI_CCxxx0_SRES;                 // Send strobe
  // Strobe addr is now being TX'ed
  IFG1 &= ~URXIFG0;                         // Clear flag
  while (!(IFG1&URXIFG0));                  // Wait for end of addr TX
  while (TI_CC_SPI_USART0_PxIN&TI_CC_SPI_USART0_SOMI);
  TI_CC_CSn_PxOUT |= TI_CC_CSn_PIN;         // /CS disable
}


#elif TI_CC_RF_SER_INTF == TI_CC_SER_INTF_USART1


void TI_CC_SPISetup(void)
{
  TI_CC_CSn_PxOUT |= TI_CC_CSn_PIN;
  TI_CC_CSn_PxDIR |= TI_CC_CSn_PIN;         // /CS disable

  ME2 |= USPIE1;                            // Enable USART1 SPI mode
  UCTL1 |= CHAR + SYNC + MM;                // 8-bit SPI Master **SWRST**
  UTCTL1 |= CKPL + SSEL1 + SSEL0 + STC;     // SMCLK, 3-pin mode
  UBR01 = 0x02;                             // UCLK/2
  UBR11 = 0x00;                             // 0
  UMCTL1 = 0x00;                            // No modulation
  TI_CC_SPI_USART1_PxSEL |= TI_CC_SPI_USART1_SIMO | TI_CC_SPI_USART1_SOMI | TI_CC_SPI_USART1_UCLK;
                                            // SPI option select
  TI_CC_SPI_USART1_PxDIR |= TI_CC_SPI_USART1_SIMO + TI_CC_SPI_USART1_UCLK;
                                            // SPI TXD out direction
  UCTL1 &= ~SWRST;                          // Initialize USART state machine
}

void TI_CC_SPIWriteReg(char addr, char value)
{
    TI_CC_CSn_PxOUT &= ~TI_CC_CSn_PIN;      // /CS enable
    while (TI_CC_SPI_USART1_PxIN&TI_CC_SPI_USART1_SOMI);// Wait for CCxxxx ready
    IFG2 &= ~URXIFG1;                       // Clear flag
    U1TXBUF = addr;                         // Send address
    //while (!(IFG2&URXIFG1));                // Wait for TX to finish
    //IFG2 &= ~URXIFG1;                       // Clear flag
    while(!(U1TCTL&TXEPT));                 // Wait for TX to finish
    U1TXBUF = value;                        // Load data for TX after addr
    //while (!(IFG2&URXIFG1));                // Wait for end of addr TX
    while(!(U1TCTL&TXEPT));                 // Wait for end of addr TX
    TI_CC_CSn_PxOUT |= TI_CC_CSn_PIN;       // /CS disable
}

void TI_CC_SPIWriteBurstReg(char addr, char *buffer, char count)
{
    char i;

    TI_CC_CSn_PxOUT &= ~TI_CC_CSn_PIN;      // /CS enable
    while (TI_CC_SPI_USART1_PxIN&TI_CC_SPI_USART1_SOMI);// Wait for CCxxxx ready
    U1TXBUF = addr | TI_CCxxx0_WRITE_BURST; // Send address
    while (!(IFG2&UTXIFG1));                // Wait for TX to finish
    for (i = 0; i < count; i++)
    {
      U1TXBUF = buffer[i];                  // Send data
      while (!(IFG2&UTXIFG1));              // Wait for TX to finish
    }
    //IFG2 &= ~URXIFG1;
    //while(!(IFG2&URXIFG1));
    while(!(U1TCTL&TXEPT));
    TI_CC_CSn_PxOUT |= TI_CC_CSn_PIN;       // /CS disable
}

char TI_CC_SPIReadReg(char addr)
{
  char x;

  TI_CC_CSn_PxOUT &= ~TI_CC_CSn_PIN;        // /CS enable
  while (TI_CC_SPI_USART1_PxIN&TI_CC_SPI_USART1_SOMI);// Wait for CCxxxx ready
  //IFG2 &= ~URXIFG1;                         // Clear flag set during addr TX
  U1TXBUF = (addr | TI_CCxxx0_READ_SINGLE); // Send address
  //while (!(IFG2&URXIFG1));                  // Wait for TXBUF ready
  //IFG2 &= ~URXIFG1;                         // Clear flag set during addr TX
  while(!(U1TCTL&TXEPT));                   // Wait for addr to be sent
  U1TXBUF = 0;                              // Load dummy byte for TX after addr
  //while (!(IFG2&URXIFG1));                  // Wait for end of dummy byte TX
  while(!(U1TCTL&TXEPT));                   // Wait for end of dummy byte TX
  x = U1RXBUF;                              // Read data
  TI_CC_CSn_PxOUT |= TI_CC_CSn_PIN;         // /CS disable

  return x;
}

void TI_CC_SPIReadBurstReg(char addr, char *buffer, char count)
{
  unsigned int i;

  TI_CC_CSn_PxOUT &= ~TI_CC_CSn_PIN;        // /CS enable
  while (TI_CC_SPI_USART1_PxIN&TI_CC_SPI_USART1_SOMI);// Wait for CCxxxx ready
  //IFG2 &= ~URXIFG1;                         // Clear flag
  U1TXBUF = (addr | TI_CCxxx0_READ_BURST);  // Send address
  while (!(IFG2&UTXIFG1));                  // Wait for TXBUF ready
  U1TXBUF = 0;                              // Dummy write to read 1st data byte
  // Addr byte is now being TX'ed, with dummy byte to follow immediately after
  //while (!(IFG2&URXIFG1));                  // Wait for end of addr byte TX