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uart.c
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uart.c
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/*****************************************************************************
* *
* DFU/SD/SDHC Bootloader for LPC17xx *
* *
* by Triffid Hunter *
* *
* *
* This firmware is Copyright (C) 2009-2010 Michael Moon aka Triffid_Hunter *
* *
* This program is free software; you can redistribute it and/or modify *
* it under the terms of the GNU General Public License as published by *
* the Free Software Foundation; either version 2 of the License, or *
* (at your option) any later version. *
* *
* This program is distributed in the hope that it will be useful, *
* but WITHOUT ANY WARRANTY; without even the implied warranty of *
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the *
* GNU General Public License for more details. *
* *
* You should have received a copy of the GNU General Public License *
* along with this program; if not, write to the Free Software *
* Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA *
* *
*****************************************************************************/
#include "uart.h"
#include "LPC17xx.h"
#include "lpc17xx_pinsel.h"
#include "lpc17xx_gpio.h"
#include "lpc17xx_clkpwr.h"
#include "config.h"
// #include "debug.h"
// void dbgled(int l);
// void setled(int, int);
#ifndef ENTER_ISR
#define ENTER_ISR() do {} while (0)
#endif
#ifndef LEAVE_ISR
#define LEAVE_ISR() do {} while (0)
#endif
/* Buf mask */
#define __BUF_MASK (UART_RING_BUFSIZE-1)
/* Check buf is full or not */
#define __BUF_IS_FULL(head, tail) ((tail&__BUF_MASK)==((head+1)&__BUF_MASK))
/* Check buf will be full in next receiving or not */
#define __BUF_WILL_FULL(head, tail) ((tail&__BUF_MASK)==((head+2)&__BUF_MASK))
/* Check buf is empty */
#define __BUF_IS_EMPTY(head, tail) ((head&__BUF_MASK)==(tail&__BUF_MASK))
/* Reset buf */
#define __BUF_RESET(bufidx) (bufidx=0)
#define __BUF_INCR(bufidx) (bufidx=(bufidx+1)&__BUF_MASK)
#define RB_MASK (UART_RINGBUFFER_SIZE - 1)
#define RB_FULL(rb) ((rb.tail & RB_MASK) == ((rb.head + 1) & RB_MASK))
#define RB_EMPTY(rb) ((rb.head & RB_MASK) == ( rb.tail & RB_MASK))
#define RB_ZERO(rb) do { rb.head = rb.tail = 0; } while (0)
#define RB_INCR(ht) do { ht = (ht + 1) & RB_MASK; } while (0)
#define RB_PUSH(rb, val) do { rb.data[rb.head++] = val; rb.head &= RB_MASK; } while (0)
#define RB_POP( rb, val) do { val = rb.data[rb.tail++]; rb.tail &= RB_MASK; } while (0)
#define RB_PEEK(rb, val) do { val = rb.data[rb.tail++]; } while (0)
#define RB_DROP(rb) do { rb.tail = (rb.tail + 1) & RB_MASK; } while (0)
#define RB_CANREAD(rb) (((UART_RINGBUFFER_SIZE + rb.head) - rb.tail ) & RB_MASK)
#define RB_CANWRITE(rb) (((UART_RINGBUFFER_SIZE + rb.tail) - (rb.head + 1)) & RB_MASK)
LPC_UART_TypeDef * u;
// UART Ring buffers
UART_RINGBUFFER_T txbuf;
UART_RINGBUFFER_T rxbuf;
// Current Tx Interrupt enable state
__IO FlagStatus TxIntStat;
volatile uint8_t blocking;
#define true 1
#define false 0
int port;
void UART_init(PinName rxpin, PinName txpin, int baud)
{
UART_pin_init(rxpin, txpin);
UART_baud(baud);
}
void UART_pin_init(PinName rxpin, PinName txpin)
{
blocking = true;
PINSEL_CFG_Type PinCfg;
PinCfg.OpenDrain = 0;
PinCfg.Pinmode = 0;
if (txpin == P0_2 && rxpin == P0_3) {
port = 0;
u = LPC_UART0;
PinCfg.Funcnum = 1;
}
else if (txpin == P0_0 && rxpin == P0_1) {
port = 3;
u = LPC_UART3;
PinCfg.Funcnum = 2;
}
else if (txpin == P0_10 && rxpin == P0_11) {
port = 2;
u = LPC_UART2;
PinCfg.Funcnum = 1;
}
else if (txpin == P0_15 && rxpin == P0_16) {
port = 1;
u = (LPC_UART_TypeDef *) LPC_UART1;
PinCfg.Funcnum = 1;
}
else if (txpin == P0_25 && rxpin == P0_26) {
port = 3;
u = LPC_UART3;
PinCfg.Funcnum = 3;
}
else if (txpin == P2_0 && rxpin == P2_1) {
port = 1;
u = (LPC_UART_TypeDef *) LPC_UART1;
PinCfg.Funcnum = 2;
}
else if (txpin == P2_8 && rxpin == P2_9) {
port = 2;
u = LPC_UART2;
PinCfg.Funcnum = 2;
}
else if (txpin == P4_28 && rxpin == P4_29) {
port = 3;
u = LPC_UART3;
PinCfg.Funcnum = 3;
}
else {
//TODO: software serial
port = -1;
return;
}
PinCfg.Portnum = (txpin >> 5) & 7;
PinCfg.Pinnum = (txpin & 0x1F);
PINSEL_ConfigPin(&PinCfg);
PinCfg.Portnum = (rxpin >> 5) & 7;
PinCfg.Pinnum = (rxpin & 0x1F);
PINSEL_ConfigPin(&PinCfg);
}
typedef struct {
uint32_t baud;
uint8_t pd;
uint16_t dl;
uint8_t mulval;
uint8_t divaddval;
} uart_regs;
// prevent system_LPC17xx from polluting our namespace
#undef __LPC17XX__
// pull in system_LPC17xx so we can see __CORE_CLK
#include <system_LPC17xx.c>
#define __LPC17XX__
// check if we can use precalculated values
#if ((defined APPBAUD) && (__CORE_CLK == 120000000) && (APPBAUD == 2000000))
static inline int baud_space_search(uint32_t target_baud, uart_regs *r)
{
r->baud = 2000000;
r->pd = 0;
r->dl = 3;
r->mulval = 4;
r->divaddval = 1;
return 0;
}
#else
/* definition to expand macro then apply to pragma message */
// #define _STR(x) #x
// #define STR(x) _STR(x)
// #pragma message STR(APPBAUD)
// #pragma message STR(__CORE_CLK)
static uint32_t const uabs(const uint32_t a, const uint32_t b)
{
if (a>=b)
return a-b;
return b-a;
}
static uint32_t const calc_baud(uint32_t pclk, uint32_t dl, uint32_t divaddval, uint32_t mulval)
{
// 65535 * 14 * 16 is less than 2**24 so we have a spare 8 bits of precision
// we can use them to increase our accuracy quite a bit
// pclk is less than 2**27, so we have 5 spare bits for the numerator
// this means we can do (numerator * 2**5) / (denominator * 2**8) * 2**3 to get the highest accuracy possible with 32 bit integers
// denominator is 16 * (dl * (1 + (divadd / mul)) which can be expanded to
// dl*16 + dl*16*divadd/mul which gives far more opportunity for using all our precision
uint32_t dx = ((dl * 16 * 32 * 8) + ((dl * 16 * divaddval * 32 * 8) / mulval));
return ((pclk * 32) / dx) * 8;
}
static int baud_space_search(uint32_t target_baud, uart_regs *r)
{
uint32_t pd, dl, mulval, divaddval;
int i = 0;
r->baud = 0;
for (pd = ((target_baud < 1000000)?3:1); pd < 4; pd--)
{
uint32_t pclk = SystemCoreClock / (1<<pd);
for (mulval = 1; mulval < 16; mulval++)
{
for (divaddval = 0; divaddval < mulval; divaddval++)
{
i++;
// baud = pclk / (16 * dl * (1 + (DivAdd / Mul))
// solving for dl, we get dl = mul * pclk / (16 * baud * (divadd + mul))
// we double the numerator, add 1 to the result then halve to effectivel round up when dl % 1 > 0.5
dl = (((2 * mulval * pclk) / (16 * target_baud * (divaddval + mulval))) + 1) / 2;
// dl is a 16 bit field, if result needs more then we search again
if (dl > 65535)
continue;
// datasheet says if DLL==DLM==0, then 1 is used instead since divide by zero is ungood
if (dl == 0)
dl = 1;
// datasheet says if DIVADDVAL > 0 then DL must be >= 2
if ((divaddval > 0) && (dl < 2))
dl = 2;
uint32_t b = calc_baud(pclk, dl, divaddval, mulval);
if (uabs(b, target_baud) < uabs(r->baud, target_baud))
{
r->baud = b;
r->pd = pd;
r->dl = dl;
r->mulval = mulval;
r->divaddval = divaddval;
// printf("\t\t{%7d,%4d,%6d,%3d,%3d},\t// Actual baud: %7d, error %c%4.2f%%, %d iterations\n", target_baud, 1<<best.pd, best.dl, best.mulval, best.divaddval, b, ((b > target_baud)?'+':((b < target_baud)?'-':' ')), (uabs(target_baud, b) * 100.0) / target_baud, i);
if (b == target_baud)
return i;
// within 0.08%
if ((uabs(r->baud, target_baud) * 1536 / target_baud) < 1)
return i;
}
}
}
// don't check higher pclk if we're within 0.5%
if ((uabs(r->baud, target_baud) * 200 / target_baud) < 1)
return i;
}
return i;
}
#endif
int UART_baud(int baud)
{
TxIntStat = RESET;
RB_ZERO(txbuf);
RB_ZERO(rxbuf);
uart_regs r = { 0, 0, 0, 0, 0 };
baud_space_search(baud, &r);
uint8_t pclkdiv;
IRQn_Type c = 255;
switch (r.pd)
{
case 0:
pclkdiv = CLKPWR_PCLKSEL_CCLK_DIV_1;
break;
case 1:
pclkdiv = CLKPWR_PCLKSEL_CCLK_DIV_2;
break;
case 2:
pclkdiv = CLKPWR_PCLKSEL_CCLK_DIV_4;
break;
default:
case 3:
pclkdiv = CLKPWR_PCLKSEL_CCLK_DIV_8;
break;
}
// PCLKSEL0
#define PCLK_UART0 6
#define PCLK_UART1 8
// PCLKSEL1
#define PCLK_UART2 16
#define PCLK_UART3 18
switch(port)
{
case 0:
LPC_SC->PCONP |= CLKPWR_PCONP_PCUART0;
LPC_SC->PCLKSEL0 = (LPC_SC->PCLKSEL0 & ~(3 << PCLK_UART0)) | pclkdiv << PCLK_UART0;
c = UART0_IRQn;
break;
case 1:
LPC_SC->PCONP |= CLKPWR_PCONP_PCUART1;
LPC_SC->PCLKSEL0 = (LPC_SC->PCLKSEL0 & ~(3 << PCLK_UART1)) | pclkdiv << PCLK_UART1;
c = UART1_IRQn;
break;
case 2:
LPC_SC->PCONP |= CLKPWR_PCONP_PCUART2;
LPC_SC->PCLKSEL1 = (LPC_SC->PCLKSEL1 & ~(3 << PCLK_UART2)) | pclkdiv << PCLK_UART2;
c = UART2_IRQn;
break;
case 3:
LPC_SC->PCONP |= CLKPWR_PCONP_PCUART3;
LPC_SC->PCLKSEL1 = (LPC_SC->PCLKSEL1 & ~(3 << PCLK_UART3)) | pclkdiv << PCLK_UART3;
c = UART3_IRQn;
break;
}
u->LCR |= UART_LCR_DLAB_EN;
u->DLM = (r.dl >> 8) & 0xFF;
u->DLL = (r.dl & 0xFF);
u->LCR &= ~(UART_LCR_DLAB_EN) & UART_LCR_BITMASK;
u->FDR = (r.divaddval & 0xF) | ((r.mulval & 0xF) << 4);
u->FCR = (UART_FCR_FIFO_EN | UART_FCR_RX_RS | UART_FCR_TX_RS);
u->LCR = UART_LCR_WLEN8;
u->ICR = 0;
u->TER |= UART_TER_TXEN;
if (c < 128)
NVIC_EnableIRQ(c);
return baud;
}
void UART_deinit(void) {
switch(port)
{
case 0:
NVIC_DisableIRQ(UART0_IRQn);
break;
case 1:
NVIC_DisableIRQ(UART1_IRQn);
break;
case 2:
NVIC_DisableIRQ(UART2_IRQn);
break;
case 3:
NVIC_DisableIRQ(UART3_IRQn);
break;
}
}
uint32_t UART_send(const uint8_t *data, uint32_t buflen) {
uint32_t bytes = 0;
// only fiddle interrupt status outside interrupt context
uint8_t intr = __get_IPSR() & 0x1F;
if (intr == 0) __disable_irq();
while ((buflen > 0) && (!RB_FULL(txbuf) || blocking))
{
if (intr == 0) __enable_irq();
if (RB_FULL(txbuf)) {
if (blocking && (intr == 0))
{
while (RB_FULL(txbuf))
__WFI();
}
else {
RB_DROP(txbuf);
}
}
if (intr == 0) __disable_irq();
RB_PUSH(txbuf, *data++);
if (intr == 0) __enable_irq();
bytes++;
buflen--;
if (intr == 0) __disable_irq();
}
if (intr == 0) __enable_irq();
if (TxIntStat == RESET) {
UART_tx_isr();
}
return bytes;
}
uint32_t UART_recv(uint8_t *buf, uint32_t buflen) {
uint32_t bytes = 0;
// only fiddle interrupt status outside interrupt context
uint8_t intr = __get_IPSR() & 0x1F;
if (intr == 0) __disable_irq();
while ((buflen > 0) && (!(RB_EMPTY(rxbuf))))
{
RB_POP(rxbuf, *buf++);
if (intr == 0) __enable_irq();
bytes++;
buflen--;
if (intr == 0) __disable_irq();
}
if (intr == 0) __enable_irq();
return bytes;
}
int UART_cansend(void) {
return RB_CANWRITE(txbuf);
}
int UART_canrecv(void) {
return RB_CANREAD(rxbuf);
}
int UART_busy(void) {
if (u->LSR & UART_LSR_TEMT)
return 0;
return RB_CANREAD(txbuf);
}
void UART_isr(void)
{
uint32_t intsrc, ls;
/* Determine the interrupt source */
intsrc = UART_GetIntId(u) & UART_IIR_INTID_MASK;
// Receive Line Status
if (intsrc == UART_IIR_INTID_RLS)
{
// Check line status
ls = UART_GetLineStatus(u);
// Mask out the Receive Ready and Transmit Holding empty status
ls &= (UART_LSR_OE | UART_LSR_PE | UART_LSR_FE | UART_LSR_BI | UART_LSR_RXFE);
// If any error exist
if (ls)
{
UART_err_isr(ls & 0xFF);
}
}
// Receive Data Available or Character time-out
if ((intsrc == UART_IIR_INTID_RDA) || (intsrc == UART_IIR_INTID_CTI))
{
UART_rx_isr();
}
// Transmit Holding Empty
if (intsrc == UART_IIR_INTID_THRE)
{
UART_tx_isr();
}
}
void UART_tx_isr(void) {
// Disable THRE interrupt
UART_IntConfig(u, UART_INTCFG_THRE, DISABLE);
/* Wait for FIFO buffer empty, transfer UART_TX_FIFO_SIZE bytes
* of data or break whenever ring buffers are empty */
/* Wait until THR empty */
while (UART_CheckBusy(u) == SET);
while (!RB_EMPTY(txbuf))
{
RB_POP(txbuf, u->THR);
}
/* If there is no more data to send, disable the transmit
* interrupt - else enable it or keep it enabled */
if (RB_EMPTY(txbuf)) {
UART_IntConfig(u, UART_INTCFG_THRE, DISABLE);
// Reset Tx Interrupt state
TxIntStat = RESET;
}
else{
// Set Tx Interrupt state
TxIntStat = SET;
UART_IntConfig(u, UART_INTCFG_THRE, ENABLE);
}
}
void UART_rx_isr(void) {
uint8_t c;
uint32_t r;
while(1){
// If data received
r = u->LSR;
if (r & UART_LSR_RDR){
c = u->RBR;
/* Check if buffer is more space
* If no more space, remaining character will be trimmed out
*/
if (!RB_FULL(rxbuf)){
RB_PUSH(rxbuf, c);
}
}
// no more data
else {
break;
}
}
}
void UART_err_isr(uint8_t bLSErrType) {
// uint8_t test;
// Loop forever
while (1){
// For testing purpose
// test = bLSErrType;
}
}
// extern "C" {
void UART0_IRQHandler(void)
{
ENTER_ISR();
// if (UART_irqrouter[0])
// UART_irqrouter[0]->isr();
UART_isr();
LEAVE_ISR();
}
/*
void UART1_IRQHandler(void)
{
ENTER_ISR();
if (UART_irqrouter[1])
UART_irqrouter[1]->isr();
LEAVE_ISR();
}
void UART2_IRQHandler(void)
{
ENTER_ISR();
if (UART_irqrouter[2])
UART_irqrouter[2]->isr();
LEAVE_ISR();
}
void UART3_IRQHandler(void)
{
ENTER_ISR();
if (UART_irqrouter[3])
UART_irqrouter[3]->isr();
LEAVE_ISR();
}
// }*/