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|
/* Philips CL RC632 driver (via SPI) for OpenPCD firmware
* (C) 2006 by Harald Welte <hwelte@hmw-consulting.de>
*
* This is heavily based on the librfid RC632 driver. All primitive access
* functions such as rc632_{reg,fifo}_{read,write}() are API compatible to
* librfid in order to be able to leverage higher-level code from librfid
* to this OpenPCD firmware.
*
* AT91SAM7 PWM routines for OpenPCD / OpenPICC
* (C) 2006 by Harald Welte <hwelte@hmw-consulting.de>
*
* 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., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
*
*/
#include <string.h>
#include <errno.h>
#include <lib_AT91SAM7.h>
#include <cl_rc632.h>
#include <openpcd.h>
#include "../openpcd.h"
#include <os/fifo.h>
#include <os/dbgu.h>
#include <os/pcd_enumerate.h>
#include <os/usb_handler.h>
#include <os/req_ctx.h>
#include "rc632.h"
#include <librfid/rfid_asic.h>
#define NOTHING do {} while(0)
#if 0
#define DEBUGPSPI DEBUGP
#define DEBUGPSPIIRQ DEBUGP
#else
#define DEBUGPSPI(x, args ...) NOTHING
#define DEBUGPSPIIRQ(x, args...) NOTHING
#endif
#if 0
#define DEBUG632 DEBUGPCRF
#else
#define DEBUG632(x, args ...) NOTHING
#endif
/* SPI driver */
#ifdef OLIMEX
#define SPI_DEBUG_LOOPBACK
#endif
#define SPI_USES_DMA
#define SPI_MAX_XFER_LEN 65
static const AT91PS_SPI pSPI = AT91C_BASE_SPI;
/* SPI irq handler */
static void spi_irq(void)
{
uint32_t status = pSPI->SPI_SR;
DEBUGPSPIIRQ("spi_irq: 0x%08x ", status);
if (status & AT91C_SPI_OVRES)
DEBUGPSPIIRQ("Overrun ");
if (status & AT91C_SPI_MODF)
DEBUGPSPIIRQ("ModeFault ");
if (status & AT91C_SPI_ENDRX) {
pSPI->SPI_IDR = AT91C_SPI_ENDRX;
DEBUGPSPIIRQ("ENDRX ");
}
if (status & AT91C_SPI_ENDTX) {
pSPI->SPI_IDR = AT91C_SPI_ENDTX;
DEBUGPSPIIRQ("ENDTX ");
}
DEBUGPSPIIRQ("\r\n");
AT91F_AIC_ClearIt(AT91C_BASE_AIC, AT91C_ID_SPI);
}
#ifdef SPI_USES_DMA
static int spi_transceive(const uint8_t *tx_data, uint16_t tx_len,
uint8_t *rx_data, uint16_t *rx_len)
{
DEBUGPSPI("DMA Xfer tx=%s\r\n", hexdump(tx_data, tx_len));
if (*rx_len < tx_len) {
DEBUGPCRF("rx_len=%u smaller tx_len=%u\n", *rx_len, tx_len);
return -1;
}
/* disable RC632 interrupt because it wants to do SPI transactions */
AT91F_AIC_DisableIt(AT91C_BASE_AIC, OPENPCD_IRQ_RC632);
AT91F_SPI_ReceiveFrame(pSPI, rx_data, tx_len, NULL, 0);
AT91F_SPI_SendFrame(pSPI, tx_data, tx_len, NULL, 0);
AT91F_PDC_EnableRx(AT91C_BASE_PDC_SPI);
AT91F_PDC_EnableTx(AT91C_BASE_PDC_SPI);
pSPI->SPI_IER = AT91C_SPI_ENDTX|AT91C_SPI_ENDRX;
while (! (pSPI->SPI_SR & AT91C_SPI_ENDRX)) ;
/* Re-enable RC632 interrupts */
AT91F_AIC_EnableIt(AT91C_BASE_AIC, OPENPCD_IRQ_RC632);
DEBUGPSPI("DMA Xfer finished rx=%s\r\n", hexdump(rx_data, tx_len));
*rx_len = tx_len;
return 0;
}
#else
/* stupid polling transceiver routine */
static int spi_transceive(const uint8_t *tx_data, uint16_t tx_len,
uint8_t *rx_data, uint16_t *rx_len)
{
uint16_t tx_cur = 0;
uint16_t rx_len_max = 0;
uint16_t rx_cnt = 0;
/* disable RC632 interrupt because it wants to do SPI transactions */
AT91F_AIC_DisableIt(AT91C_BASE_AIC, OPENPCD_IRQ_RC632);
DEBUGPSPI("spi_transceive: enter(tx_len=%u) ", tx_len);
if (rx_len) {
rx_len_max = *rx_len;
*rx_len = 0;
}
//AT91F_SPI_Enable(pSPI);
while (1) {
uint32_t sr = pSPI->SPI_SR;
uint8_t tmp;
if (sr & AT91C_SPI_RDRF) {
tmp = pSPI->SPI_RDR;
rx_cnt++;
if (rx_len && *rx_len < rx_len_max)
rx_data[(*rx_len)++] = tmp;
}
if (sr & AT91C_SPI_TDRE) {
if (tx_len > tx_cur)
pSPI->SPI_TDR = tx_data[tx_cur++];
}
if (tx_cur >= tx_len && rx_cnt >= tx_len)
break;
}
//AT91F_SPI_Disable(pSPI);
if (rx_data)
DEBUGPSPI("leave(%02x %02x)\r\n", rx_data[0], rx_data[1]);
else
DEBUGPSPI("leave()\r\n");
/* Re-enable RC632 interrupts */
AT91F_AIC_EnableIt(AT91C_BASE_AIC, OPENPCD_IRQ_RC632);
return 0;
}
#endif
/* RC632 driver */
/* static buffers used by RC632 access primitives below.
* Since we only have one */
static uint8_t spi_outbuf[SPI_MAX_XFER_LEN];
static uint8_t spi_inbuf[SPI_MAX_XFER_LEN];
#define FIFO_ADDR (RC632_REG_FIFO_DATA << 1)
#define RC632_WRITE_ADDR(x) ((x << 1) & 0x7e)
/* RC632 access primitives */
int opcd_rc632_reg_write(struct rfid_asic_handle *hdl,
uint8_t addr, uint8_t data)
{
uint16_t rx_len = 2;
DEBUG632("[0x%02x] <= 0x%02x", addr, data);
addr = RC632_WRITE_ADDR(addr);
spi_outbuf[0] = addr;
spi_outbuf[1] = data;
return spi_transceive(spi_outbuf, 2, spi_inbuf, &rx_len);
}
#define RC632_REGSET_START 0x10
#define RC632_REGSET_END 0x3f
#define RC632_REGSET_MAXSIZE (RC632_REGSET_END-RC632_REGSET_START)
static uint8_t regset_buf[RC632_REGSET_MAXSIZE * 2];
int opcd_rc632_reg_write_set(struct rfid_asic_handle *hdl,
uint8_t *regs, int len)
{
uint8_t i, j = 0;
uint16_t rx_len;
if (len > RC632_REGSET_MAXSIZE)
return -E2BIG;
for (i = RC632_REGSET_START; i <= RC632_REGSET_END; i++) {
/* skip bank registers */
if (i % 8 == 0)
continue;
regset_buf[j++] = RC632_WRITE_ADDR(i);
regset_buf[j++] = regs[i - RC632_REGSET_START];
}
rx_len = j;
return spi_transceive(regset_buf, j, spi_inbuf, &rx_len);
}
int opcd_rc632_fifo_write(struct rfid_asic_handle *hdl,
uint8_t len, uint8_t *data, uint8_t flags)
{
uint16_t rx_len = sizeof(spi_inbuf);
if (len > sizeof(spi_outbuf)-1)
len = sizeof(spi_outbuf)-1;
spi_outbuf[0] = FIFO_ADDR;
memcpy(&spi_outbuf[1], data, len);
DEBUG632("[FIFO] <= %s", hexdump(data, len));
return spi_transceive(spi_outbuf, len+1, spi_inbuf, &rx_len);
}
int opcd_rc632_reg_read(struct rfid_asic_handle *hdl,
uint8_t addr, uint8_t *val)
{
uint16_t rx_len = 2;
addr = (addr << 1) & 0x7e;
spi_outbuf[0] = addr | 0x80;
spi_outbuf[1] = 0x00;
spi_transceive(spi_outbuf, 2, spi_inbuf, &rx_len);
*val = spi_inbuf[1];
DEBUG632("[0x%02x] => 0x%02x", addr>>1, *val);
return 0;
}
int opcd_rc632_fifo_read(struct rfid_asic_handle *hdl,
uint8_t max_len, uint8_t *data)
{
int ret;
uint8_t fifo_length;
uint8_t i;
uint16_t rx_len;
ret = opcd_rc632_reg_read(hdl, RC632_REG_FIFO_LENGTH, &fifo_length);
if (ret < 0)
return ret;
rx_len = fifo_length+1;
if (max_len < fifo_length)
fifo_length = max_len;
for (i = 0; i < fifo_length; i++)
spi_outbuf[i] = FIFO_ADDR;
spi_outbuf[0] |= 0x80;
spi_outbuf[fifo_length] = 0x00;
spi_transceive(spi_outbuf, fifo_length+1, spi_inbuf, &rx_len);
memcpy(data, spi_inbuf+1, rx_len-1);
DEBUG632("[FIFO] => %s", hexdump(data, rx_len-1));
return rx_len-1;
}
int opcd_rc632_set_bits(struct rfid_asic_handle *hdl,
uint8_t reg, uint8_t bits)
{
uint8_t val;
int ret;
ret = opcd_rc632_reg_read(hdl, reg, &val);
if (ret < 0)
return ret;
val |= bits;
return opcd_rc632_reg_write(hdl, reg, val);
}
int opcd_rc632_clear_bits(struct rfid_asic_handle *hdl,
uint8_t reg, uint8_t bits)
{
uint8_t val;
int ret;
ret = opcd_rc632_reg_read(hdl, reg, &val);
if (ret < 0)
return ret;
val &= ~bits;
return opcd_rc632_reg_write(hdl, reg, val);
}
/* RC632 interrupt handling */
static void rc632_irq(void)
{
struct req_ctx *irq_rctx;
struct openpcd_hdr *irq_opcdh;
uint8_t cause;
/* CL RC632 has interrupted us */
opcd_rc632_reg_read(NULL, RC632_REG_INTERRUPT_RQ, &cause);
/* ACK all interrupts */
//rc632_reg_write(NULL, RC632_REG_INTERRUPT_RQ, cause);
opcd_rc632_reg_write(NULL, RC632_REG_INTERRUPT_RQ, RC632_INT_TIMER);
DEBUGP("rc632_irq: ");
if (cause & RC632_INT_LOALERT) {
/* FIFO is getting low, refill from virtual FIFO */
DEBUGP("FIFO_low ");
#if 0
if (!fifo_available(&rc632.fifo))
return;
#endif
/* FIXME */
}
if (cause & RC632_INT_HIALERT) {
/* FIFO is getting full, empty into virtual FIFO */
DEBUGP("FIFO_high ");
/* FIXME */
}
/* All interrupts below can be reported directly to the host */
if (cause & RC632_INT_TIMER)
DEBUGP("Timer ");
if (cause & RC632_INT_IDLE)
DEBUGP("Idle ");
if (cause & RC632_INT_RX)
DEBUGP("RxComplete ");
if (cause & RC632_INT_TX)
DEBUGP("TxComplete ");
irq_rctx = req_ctx_find_get(0, RCTX_STATE_FREE,
RCTX_STATE_RC632IRQ_BUSY);
if (!irq_rctx) {
DEBUGPCRF("NO RCTX!");
/* disable rc632 interrupt until RCTX is free */
AT91F_AIC_DisableIt(AT91C_BASE_AIC, OPENPCD_IRQ_RC632);
return;
}
irq_opcdh = (struct openpcd_hdr *) irq_rctx->data;
/* initialize static part of openpcd_hdr for USB IRQ reporting */
irq_opcdh->cmd = OPENPCD_CMD_IRQ;
irq_opcdh->flags = 0x00;
irq_opcdh->reg = 0x07;
irq_opcdh->val = cause;
req_ctx_set_state(irq_rctx, RCTX_STATE_UDP_EP3_PENDING);
DEBUGPCR("");
}
void rc632_unthrottle(void)
{
AT91F_AIC_EnableIt(AT91C_BASE_AIC, OPENPCD_IRQ_RC632);
}
void rc632_power(uint8_t up)
{
DEBUGPCRF("powering %s RC632", up ? "up" : "down");
if (up)
AT91F_PIO_ClearOutput(AT91C_BASE_PIOA,
OPENPCD_PIO_RC632_RESET);
else
AT91F_PIO_SetOutput(AT91C_BASE_PIOA,
OPENPCD_PIO_RC632_RESET);
}
void rc632_reset(void)
{
volatile int i;
rc632_power(0);
for (i = 0; i < 0xffff; i++)
{}
rc632_power(1);
/* wait for startup phase to finish */
while (1) {
uint8_t val;
opcd_rc632_reg_read(NULL, RC632_REG_COMMAND, &val);
if (val == 0x00)
break;
}
/* turn off register paging */
opcd_rc632_reg_write(NULL, RC632_REG_PAGE0, 0x00);
}
static int rc632_usb_in(struct req_ctx *rctx)
{
struct openpcd_hdr *poh = (struct openpcd_hdr *) rctx->data;
uint16_t len = rctx->tot_len-sizeof(*poh);
/* initialize transmit length to header length */
rctx->tot_len = sizeof(*poh);
switch (poh->cmd) {
case OPENPCD_CMD_READ_REG:
opcd_rc632_reg_read(NULL, poh->reg, &poh->val);
DEBUGP("READ REG(0x%02x)=0x%02x ", poh->reg, poh->val);
/* register read always has to provoke a response */
poh->flags &= OPENPCD_FLAG_RESPOND;
break;
case OPENPCD_CMD_READ_FIFO:
/* FIFO read always has to provoke a response */
poh->flags &= OPENPCD_FLAG_RESPOND;
{
uint16_t req_len = poh->val, remain_len = req_len, pih_len;
#if 0
if (req_len > MAX_PAYLOAD_LEN) {
pih_len = MAX_PAYLOAD_LEN;
remain_len -= pih_len;
opcd_rc632_fifo_read(NULL, pih_len, poh->data);
rctx->tot_len += pih_len;
DEBUGP("READ FIFO(len=%u)=%s ", req_len,
hexdump(poh->data, pih_len));
req_ctx_set_state(rctx, RCTX_STATE_UDP_EP2_PENDING);
udp_refill_ep(2);
/* get and initialize second rctx */
rctx = req_ctx_find_get(0, RCTX_STATE_FREE,
RCTX_STATE_MAIN_PROCESSING);
if (!rctx) {
DEBUGPCRF("FATAL_NO_RCTX!!!\n");
break;
}
poh = (struct openpcd_hdr *) rctx->data;
rctx->tot_len = sizeof(*poh);
pih_len = remain_len;
opcd_rc632_fifo_read(NULL, pih_len, poh->data);
rctx->tot_len += pih_len;
DEBUGP("READ FIFO(len=%u)=%s ", pih_len,
hexdump(poh->data, pih_len));
/* don't set state of second rctx, main function
* body will do this after switch statement */
} else {
#endif
poh->val = opcd_rc632_fifo_read(NULL, req_len, poh->data);
rctx->tot_len += poh->val;
DEBUGP("READ FIFO(len=%u)=%s ", poh->val,
hexdump(poh->data, poh->val));
//}
}
break;
case OPENPCD_CMD_WRITE_REG:
DEBUGP("WRITE_REG(0x%02x, 0x%02x) ", poh->reg, poh->val);
opcd_rc632_reg_write(NULL, poh->reg, poh->val);
break;
case OPENPCD_CMD_WRITE_REG_SET:
DEBUGP("WRITE_REG_SET(%s) ", hexdump(poh->data, len));
opcd_rc632_reg_write_set(NULL, poh->data, len);
break;
case OPENPCD_CMD_WRITE_FIFO:
DEBUGP("WRITE FIFO(len=%u): %s ", len,
hexdump(poh->data, len));
opcd_rc632_fifo_write(NULL, len, poh->data, 0);
break;
case OPENPCD_CMD_READ_VFIFO:
DEBUGP("READ VFIFO ");
goto not_impl;
break;
case OPENPCD_CMD_WRITE_VFIFO:
DEBUGP("WRITE VFIFO ");
goto not_impl;
break;
case OPENPCD_CMD_REG_BITS_CLEAR:
DEBUGP("CLEAR BITS ");
poh->val = opcd_rc632_clear_bits(NULL, poh->reg, poh->val);
break;
case OPENPCD_CMD_REG_BITS_SET:
DEBUGP("SET BITS ");
poh->val = opcd_rc632_set_bits(NULL, poh->reg, poh->val);
break;
case OPENPCD_CMD_DUMP_REGS:
DEBUGP("DUMP REGS ");
goto not_impl;
break;
default:
DEBUGP("UNKNOWN ");
return USB_ERR(USB_ERR_CMD_UNKNOWN);
}
return (poh->flags & OPENPCD_FLAG_RESPOND) ? USB_RET_RESPOND : 0;
not_impl:
DEBUGP("NOT IMPLEMENTED YET ");
return USB_ERR(USB_ERR_CMD_NOT_IMPL);
}
void rc632_init(void)
{
//fifo_init(&rc632.fifo, 256, NULL, &rc632);
DEBUGPCRF("entering");
AT91F_SPI_CfgPMC();
AT91F_PIO_CfgPeriph(AT91C_BASE_PIOA,
AT91C_PA11_NPCS0|AT91C_PA12_MISO|
AT91C_PA13_MOSI |AT91C_PA14_SPCK, 0);
AT91F_AIC_ConfigureIt(AT91C_BASE_AIC, AT91C_ID_SPI,
OPENPCD_IRQ_PRIO_SPI,
AT91C_AIC_SRCTYPE_INT_HIGH_LEVEL, &spi_irq);
AT91F_AIC_EnableIt(AT91C_BASE_AIC, AT91C_ID_SPI);
AT91F_SPI_EnableIt(pSPI, AT91C_SPI_MODF|AT91C_SPI_OVRES);
#ifdef SPI_USES_DMA
AT91F_SPI_EnableIt(pSPI, AT91C_SPI_ENDRX|AT91C_SPI_ENDTX);
#endif
#ifdef SPI_DEBUG_LOOPBACK
AT91F_SPI_CfgMode(pSPI, AT91C_SPI_MSTR|AT91C_SPI_PS_FIXED|
AT91C_SPI_MODFDIS|AT91C_SPI_LLB);
#else
AT91F_SPI_CfgMode(pSPI, AT91C_SPI_MSTR|AT91C_SPI_PS_FIXED|
AT91C_SPI_MODFDIS);
#endif
/* CPOL = 0, NCPHA = 1, CSAAT = 0, BITS = 0000, SCBR = 10 (4.8MHz),
* DLYBS = 0, DLYBCT = 0 */
#ifdef SPI_USES_DMA
AT91F_SPI_CfgCs(pSPI, 0, AT91C_SPI_BITS_8|AT91C_SPI_NCPHA|(10<<8));
#else
/* 320 kHz in case of I/O based SPI */
AT91F_SPI_CfgCs(pSPI, 0, AT91C_SPI_BITS_8|AT91C_SPI_NCPHA|(0x7f<<8));
#endif
AT91F_SPI_Enable(pSPI);
/* Register rc632_irq */
AT91F_AIC_ConfigureIt(AT91C_BASE_AIC, OPENPCD_IRQ_RC632,
OPENPCD_IRQ_PRIO_RC632,
AT91C_AIC_SRCTYPE_INT_HIGH_LEVEL, &rc632_irq);
AT91F_AIC_EnableIt(AT91C_BASE_AIC, OPENPCD_IRQ_RC632);
AT91F_PIO_CfgOutput(AT91C_BASE_PIOA, OPENPCD_PIO_RC632_RESET);
rc632_reset();
/* configure IRQ pin */
opcd_rc632_reg_write(NULL, RC632_REG_IRQ_PIN_CONFIG,
RC632_IRQCFG_CMOS|RC632_IRQCFG_INV);
/* enable interrupts */
opcd_rc632_reg_write(NULL, RC632_REG_INTERRUPT_EN, RC632_INT_TIMER);
/* configure AUX to test signal four */
opcd_rc632_reg_write(NULL, RC632_REG_TEST_ANA_SELECT, 0x04);
usb_hdlr_register(&rc632_usb_in, OPENPCD_CMD_CLS_RC632);
};
#if 0
void rc632_exit(void)
{
usb_hdlr_unregister(OPENPCD_CMD_CLS_RC632);
AT91F_AIC_DisableIt(AT91C_BASE_AIC, OPENPCD_IRQ_RC632);
AT91F_AIC_DisableIt(AT91C_BASE_AIC, AT91C_ID_SPI);
AT91F_SPI_Disable(pSPI);
}
#endif
#ifdef DEBUG
static int rc632_reg_write_verify(struct rfid_asic_handle *hdl,
uint8_t reg, uint8_t val)
{
uint8_t tmp;
opcd_rc632_reg_write(hdl, reg, val);
opcd_rc632_reg_read(hdl, reg, &tmp);
DEBUGPCRF("reg=0x%02x, write=0x%02x, read=0x%02x ", reg, val, tmp);
return (val == tmp);
}
int rc632_dump(void)
{
uint8_t i;
uint16_t rx_len = sizeof(spi_inbuf);
for (i = 0; i <= 0x3f; i++) {
uint8_t reg = i;
if (reg == RC632_REG_FIFO_DATA)
reg = 0x3e;
spi_outbuf[i] = reg << 1;
spi_inbuf[i] = 0x00;
}
/* MSB of first byte of read spi transfer is high */
spi_outbuf[0] |= 0x80;
/* last byte of read spi transfer is 0x00 */
spi_outbuf[0x40] = 0x00;
spi_inbuf[0x40] = 0x00;
spi_transceive(spi_outbuf, 0x41, spi_inbuf, &rx_len);
for (i = 0; i < 0x3f; i++) {
if (i == RC632_REG_FIFO_DATA)
DEBUGPCR("REG 0x02 = NOT READ");
else
DEBUGPCR("REG 0x%02x = 0x%02x", i, spi_inbuf[i+1]);
}
return 0;
}
int rc632_test(struct rfid_asic_handle *hdl)
{
if (rc632_reg_write_verify(hdl, RC632_REG_RX_WAIT, 0x55) != 1)
return -1;
if (rc632_reg_write_verify(hdl, RC632_REG_RX_WAIT, 0xAA) != 1)
return -1;
return 0;
}
#else /* DEBUG */
int rc632_test(struct rfid_asic_handle *hdl) {}
int rc632_dump(void) {}
#endif /* DEBUG */
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