Tom N
This is a class which contains function to interface with the MLX75320
LidarSpi.cpp
- Committer:
- TNU
- Date:
- 2016-03-04
- Revision:
- 3:9ed1d493c235
- Parent:
- 1:e3ace426cee5
- Child:
- 5:87e211a23654
File content as of revision 3:9ed1d493c235:
#include "mbed.h"
#include "LidarSpi.h"
//#include "ToolsClass.h"
#include <string.h>
#include "LidarSpi.h"
#include "MLX_BaseSPI.h"
#define SPIFREQ 8000
LidarSpi::LidarSpi(PinName mosi, PinName miso, PinName clk, PinName chipSelect, PinName dr, PinName rs, PinName tr, PinName smpl):device(mosi, miso, clk), chipS(chipSelect), dataReady(dr),resetPin(rs), trigger(tr), sampling(smpl)
{
//resetPin.write(1);
chipS.write(1);
//8 bit
//Mode 1: CPPOL=0, CLPHA=1 => Default of lidar, mbed side receiving is bad near 25Mhz
// -> mbed does not read first bit, this shifts the entire message on MISO 1 bit
//Mode 3: CLPOL=1, CLPHA=1 => Transmission on mbed side good, Lidar chip returns CRC errors on the succesful tranmissions
// -> Cant't send anything to lidar without changing lidar SPI mode
device.format(8,1); //8 bit, CLPOL=1, CLPHA=1
device.frequency(16000000);
}
int LidarSpi::BasicRead(){
return device.write(0x6B);
}
int LidarSpi::SpiSetting(long freq, int mode, Serial* pc){
int cPha= mode & 0x01;
int cPol=(mode>>1) & 0x01;
uint32_t val=0;
int res=0;
res=ReadReg(0x10E, &val,pc);
if(res<0) return -1;
val=val>>16;
val=val | (cPol<<5) | (cPha<<6);
wait_us(4);
res=WriteReg(0x10E, val, pc);
wait_us(4);
device.format(8, mode);
res=ReadReg(0x10E, &val,pc);
device.frequency(freq);
return res;
}
//int LidarSpi::BasicTransfer(uint8_t* rData, uint16_t rSz, const uint8_t* tData, uint16_t tSz, const event_callback_t callback){
// device.transfer(tData,tSz,rData,rSz,callback,event=SPI_EVENT_COMPLETE);
// //device.transfer((uint8_t*)_cmd, (2 + (DISPLAY_WIDTH / DISPLAY_BUFFER_TYPE_SIZE * sizeof(DISPLAY_BUFFER_TYPE))) , (uint8_t*)NULL, 0, _internalEventCallback, SPI_EVENT_COMPLETE) != 0)
// device.transfer();
// return 0;
//}
int LidarSpi::TxPacket(uint8_t* rData, uint16_t *rSz, uint8_t *tData, uint16_t tSz){
chipS=0;
int i =0;
for(i=0; i< tSz;i++){
*rData=device.write(*tData);
rData++;
tData++;
}
chipS=1;
*rSz=i;
return 0;
}
int LidarSpi::TxPacketWord(uint8_t* rData, uint16_t *rSz, uint8_t *tData, uint16_t tSz){
chipS=0;
int i =0;
uint16_t* recPoint=(uint16_t*)rData;
uint16_t* transPoint=(uint16_t*)tData;
for(i=0; i< tSz/2;i++){
*recPoint=device.write(*transPoint);
recPoint++;
transPoint++;
}
chipS=1;
*rSz=i*2;
return 0;
}
int LidarSpi::TxPacket(uint8_t* rData, uint16_t *rSz, uint8_t *tData, uint16_t tSz, Serial* pc){
chipS=0;
int i =0;
//pc->printf("Transmitting %d bytes...\n\r",tSz);
//pc->printf("Received: ");
for(i=0; i< tSz;i++){
//*(tData+i)=*(tData+i)+1; //<================Uncomment to write gibberish with wrong CRC
*(rData+i)=device.write(*(tData+i));
//pc->printf("%02X", *(rData+i));
//rData++;
//tData++;
}
//pc->printf("\n\r");
chipS=1;
*rSz=i;
return 0;
}
int LidarSpi::TxPacketSlow(uint8_t* rData, uint16_t *rSz, uint8_t *tData, uint16_t tSz, uint16_t usDelay){
int res=TxPacket(rData, rSz, tData, tSz);
wait_us(usDelay);
return res;
}
int LidarSpi::ReadReg(uint32_t reg, uint32_t *val)
{
int res;
uint16_t rSz;
PACK_SHORT rx[2], tx[2];
// Ensure all packets are all zeros to not send trash
memset(tx, 0, sizeof(tx));
// Encode the request and send it
res = MLX_ReqReadReg(tx, (uint32_t)reg);
if (res < 0)
return -1;
// tx[1].hdr = 0x0040;
// tx[1].crc = 0x106a;
res = MLX_EncodeStatusS(tx + 1, 0, 0);
if (res < 0)
return -2;
res = TxPacket((uint8_t*)rx, &rSz, (uint8_t*)tx, sizeof(tx)/2);
wait_us(5);
res = TxPacket((uint8_t*)(rx+1), &rSz, (uint8_t*)(tx+1), sizeof(tx)/2);
if (res < 0)
return -3;
// Decode the response packet with register value
res = MLX_DecodeResS(rx + 1, val);
if (res < 0)
return res;
//return sizeof(tx);
return 0;
}
int LidarSpi::ReadReg(uint32_t reg, uint32_t *val, Serial* pc)
{
int res;
uint16_t rSz;
PACK_SHORT rx[2], tx[2];
// Ensure all packets are all zeros to not send trash
memset(tx, 0, sizeof(tx));
// Encode the request and send it
res = MLX_ReqReadReg(tx, (uint32_t)reg);
if (res < 0)
return -1;
// tx[1].hdr = 0x0040;
// tx[1].crc = 0x106a;
res = MLX_EncodeStatusS(tx + 1, 0, 0);
if (res < 0)
return -2;
res = TxPacket((uint8_t*)rx, &rSz, ((uint8_t*)tx), sizeof(tx)/2,pc);
wait_us(5);
res = TxPacket((uint8_t*)(rx+1), &rSz, (uint8_t*)(tx+1), sizeof(tx)/2, pc);
if (res < 0)
return -3;
pc->printf("Read register request and response\n\r");
pc->printf("MOSI ReadRegRequest:\t");
for(int i=0;i<(sizeof(tx)/2);i++){
uint8_t* pnt=(uint8_t*)tx;
pc->printf("%02X ", *(pnt+i));
}
pc->printf("\n\r");
pc->printf("MISO ReadRegRequest:\t");
for(int i=0;i<(sizeof(tx)/2);i++){
uint8_t* pnt=(uint8_t*)rx;
pc->printf("%02X ", *(pnt+i));
}
pc->printf("\n\r");
pc->printf("-- -- -- -- -- -- --\n\r");
pc->printf("MOSI ReadRegResponse:\t");
for(int i=0;i<(sizeof(tx)/2);i++){
uint8_t* pnt=(uint8_t*)(tx+1);
pc->printf("%02X ", *(pnt+i));
}
pc->printf("\n\r");
pc->printf("MISO ReadRegResponse:\t");
for(int i=0;i<(sizeof(tx)/2);i++){
uint8_t* pnt=(uint8_t*)(rx+1);
pc->printf("%02X ", *(pnt+i));
}
pc->printf("\n\r");
pc->printf("-- -- -- -- -- -- --\n\r");
// Decode the response packet with register value
res = MLX_DecodeResS(rx + 1, val);
if (res < 0)
if(res==-6) {
uint8_t isser=0;
uint16_t err=0;
MLX_DecodeStatusS(rx+1,&isser, &err);
pc->printf("Not a valid ReadRequestResponse-> Decode as short status: Result: %d, IsError: %d, Error: %d\n\r", res,isser,err);
return res;
}
else return res;
//return sizeof(tx);
return 0;
}
int LidarSpi::WriteReg(uint32_t reg, uint32_t val)
{
return WriteRegSpeed(reg, val, START_DELAY);
}
// Add a speed input so that we can control delay between packets
int LidarSpi::WriteRegSpeed(uint32_t reg, uint32_t val, uint16_t speed)
{
int res;
uint16_t rSz;
uint8_t iserr;
uint16_t error;
PACK_SHORT rx[2], tx[2];
// Ensure all packets are all zeros to not send trash
memset(tx, 0, sizeof(tx));
// Encode the request and send it
res = MLX_ReqWriteReg(tx, (uint32_t)reg, (uint32_t)val);
if (res < 0)
return res;
res = TxPacket((uint8_t*)rx, &rSz, ((uint8_t*)tx), sizeof(tx)/2);
wait_us(5);
res = TxPacket((uint8_t*)(rx+1), &rSz, (uint8_t*)(tx+1), sizeof(tx)/2);
if (res < 0)
return res;
// Decode response (a status packet)
res = MLX_DecodeStatusS(rx + 1, &iserr, &error);
if (res < 0 || iserr)
return res;
return 0;
}
int LidarSpi::WriteReg(uint32_t reg, uint32_t val, Serial* pc)
{
return WriteRegSpeed(reg, val, START_DELAY, pc);
}
// Add a speed input so that we can control delay between packets
int LidarSpi::WriteRegSpeed(uint32_t reg, uint32_t val, uint16_t speed, Serial* pc)
{
int res;
uint16_t rSz;
uint8_t iserr;
uint16_t error;
PACK_SHORT rx[2], tx[2];
// Ensure all packets are all zeros to not send trash
memset(tx, 0, sizeof(tx));
// Encode the request and send it
res = MLX_ReqWriteReg(tx, (uint32_t)reg, (uint32_t)val);
if (res < 0)
return res;
/*
res = TxPacketSlow((uint8_t*)rx, &rSz, (uint8_t*)tx, sizeof(tx), speed);
if (res < 0)
return res;
*/
res = TxPacket((uint8_t*)rx, &rSz, ((uint8_t*)tx), sizeof(tx)/2,pc);
wait_us(5);
res = TxPacket((uint8_t*)(rx+1), &rSz, (uint8_t*)(tx+1), sizeof(tx)/2, pc);
if (res < 0)
return -3;
//pc->printf("Write register request and response\n\r");
pc->printf("MOSI WriteRegRequest:\t 0x");
for(int i=0;i<(sizeof(tx)/2);i++){
uint8_t* pnt=(uint8_t*)tx;
pc->printf("%02X", *(pnt+i));
}
pc->printf("\n\r");
pc->printf("MISO WriteRegRequest:\t 0x");
for(int i=0;i<(sizeof(tx)/2);i++){
uint8_t* pnt=(uint8_t*)rx;
pc->printf("%02X", *(pnt+i));
}
pc->printf("\n\r");
pc->printf("-- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- --\n\r");
pc->printf("MOSI WriteRegResponse:\t 0x");
for(int i=0;i<(sizeof(tx)/2);i++){
uint8_t* pnt=(uint8_t*)(tx+1);
pc->printf("%02X", *(pnt+i));
}
pc->printf("\n\r");
pc->printf("MISO WriteRegResponse:\t 0x");
for(int i=0;i<(sizeof(tx)/2);i++){
uint8_t* pnt=(uint8_t*)(rx+1);
pc->printf("%02X", *(pnt+i));
}
pc->printf("\n\r");
pc->printf("==========================================================\n\r");
// Decode response (a status packet)
res = MLX_DecodeStatusS(rx + 1, &iserr, &error);
if (res < 0 || iserr){
pc->printf("Decode as short status: Result: %d, IsError: %d, Error: %d\n\r", res,iserr,error);
return res;}
return 0;
}
int LidarSpi::GetEchoes(Echo *ech, uint16_t maxN, uint16_t mode)
{
trigger.write(0);
int res, a, b;
uint16_t rSz;
uint32_t cnt;
PACK_SHORT rx[1], tx[1];
PACK_LONG2 rxL, txL;
uint8_t iserr;
uint16_t err;
uint16_t idx = 0;
uint32_t val = 0;
uint16_t buf[MAXCH*4*BYTES_PER_ECH/2];
uint16_t * u16ptr ;
// Required buffer space
if (maxN < MAXECH)
return -1;
// Echo data is transmitted in 128 word payload => PACK_LONG2
// Each echo is X bytes, divide by payload size to get number of packets
const int nEchoes = MAXCH * 4;
const int nPack = nEchoes*BYTES_PER_ECH/MLX_LONG2_DATA_SZ;
const int WORDS_PER_ECH = BYTES_PER_ECH/2;
// Ensure transmitted packet is all zeros to not send trash
memset(&txL, 0, sizeof(PACK_LONG2));
memset(tx, 0, sizeof(tx));
//res = MLXSPI::SetConfig(0); //debug
// Write 1 to PORT_ACQU register and then wait
res = ReadReg(0x146, &val); // PORT_ACQU
if (res < 0)
goto END;
val = (val >> 16) | 1;
trigger.write(1);
res = WriteReg(0x146, val); // PORT_ACQU
if (res < 0)
goto END;
// Wait till PORT_READY bit is set.
res = ReadReg(470, &val); // PORT_READY
cnt = 0;
while (((val & 0x10000) >> 16 != 1) && (cnt < 500)) {
wait_us(50);
res = ReadReg(470, &val); // PORT_READY
cnt++;
}
trigger.write(0);
// Encode the request and send it
res = MLX_ReqReadEch(tx);
if (res < 0)
goto END;
//--------------------------------------------------------------------------------------
//----SHORT PACKET EXCHANGE--------
res = TxPacketSlow((uint8*)rx, &rSz, (uint8*)tx, sizeof(tx), 4);
if (res < 0)
goto END;
//----PACKET EXCHANGE
// Optional status decoding
res = MLX_DecodeStatusS(rx, &iserr, &err);
if (res < 0 || iserr)
goto END;
// Temporary pointer to uint16 data, for simplicity purpose
u16ptr = (uint16*)rxL.data;
res = MLX_EncodeStatusL2(&txL, 0, 0); //Create echo status packet
if (res < 0){
res = -7;
goto END;
}
for (a = 0; a < nPack; ++a)
{
wait_us(10);
//Tools::Wait(10);
// Clock the remaining long packets
//--------------------------------------------------------------------------------------
//----LONG PACKET EXCHANGE--------
res=TxPacket((uint8_t*)&rxL, &rSz, (uint8_t*)&txL, sizeof(PACK_LONG2));
if (res < 0)
goto END;
// Decode the long responses, then extract data values
res = MLX_DecodeResL2(&rxL);
if (res < 0)
goto END;
// Gather all of the echo data in a buffer.
//for (b = 0; b < (MLX_LONG2_DATA_SZ / 2); ++b)
for (b = 0; b < (128 / 2); ++b)
{
//buf[a*(MLX_LONG2_DATA_SZ / 2) + b] = (((u16ptr[b] & 0x00ff) << 8) | ((u16ptr[b] & 0xff00) >> 8)); //Swap LSByte with MSByte
buf[a*(128 / 2) + b] = (((u16ptr[b] & 0x00ff) << 8) | ((u16ptr[b] & 0xff00) >> 8)); //Swap LSByte with MSByte
}
}
// Do something with the data... decode an echo, manage the empty echo case
for (b = 0; b < nEchoes; ++b) {
ech[idx].mDistance = buf[b*WORDS_PER_ECH + 1] << 16 | buf[b*WORDS_PER_ECH];
ech[idx].mAmplitude = buf[b*WORDS_PER_ECH + 3] << 16 | buf[b*WORDS_PER_ECH +2];
ech[idx].mBase = buf[b*WORDS_PER_ECH + 5] << 16 | buf[b*WORDS_PER_ECH + 4];
ech[idx].mMaxIndex = buf[b*WORDS_PER_ECH + 6];
ech[idx].mChannelIndex = (uint8) buf[b*WORDS_PER_ECH + 7];
ech[idx].mValid = buf[b*WORDS_PER_ECH + 7] >>8;
ech[idx].mAmplitudeLowScale = buf[b*WORDS_PER_ECH + 9] | buf[b*WORDS_PER_ECH + 8];
ech[idx].mSaturationWidth = buf[b*WORDS_PER_ECH + 11] | buf[b*WORDS_PER_ECH + 10];
++idx;
}
res = idx;
END:
return res;
}
int LidarSpi::GetEchoes(Echo *ech, uint16_t maxN, uint16_t mode, Serial* pc)
{
trigger.write(0);
int res, a, b;
uint16_t rSz;
uint32_t cnt;
PACK_SHORT rx[1], tx[1];
PACK_LONG2 rxL, txL;
uint8_t iserr;
uint16_t err;
uint16_t idx = 0;
uint32_t val = 0;
uint16_t buf[MAXCH*4*BYTES_PER_ECH/2];
memset(buf, 0, MAXCH*4*BYTES_PER_ECH/2);
uint16_t * u16ptr ;
// Required buffer space
if (maxN < MAXECH){
pc->printf("maxN too small\n\r");
return -1;
}
// Echo data is transmitted in 128 word payload => PACK_LONG2
// Each echo is X bytes, divide by payload size to get number of packets
const int nEchoes = MAXCH * 4;
const int nPack = nEchoes*BYTES_PER_ECH/MLX_LONG2_DATA_SZ;
const int WORDS_PER_ECH = BYTES_PER_ECH/2;
// Ensure transmitted packet is all zeros to not send trash
memset(&txL, 0, sizeof(PACK_LONG2));
memset(tx, 0, sizeof(tx));
//res = MLXSPI::SetConfig(0); //debug
// Write 1 to PORT_ACQU register and then wait
pc->printf("\tRead PORT_ACQU\n\r");
res = ReadReg(0x146, &val); // PORT_ACQU
if (res < 0){
pc->printf("ReadReg Error\n\r");
goto END;}
val = (val >> 16) | 1;
pc->printf("\tWrite 1 to PORT_ACQU\n\r");
trigger.write(1);
res = WriteReg(0x146, val); // PORT_ACQU
if (res < 0){
pc->printf("WriteReg Error\n\r");
goto END;}
// Wait till PORT_READY bit is set.
pc->printf("\tWait for PORT_READY bit\n\r");
res = ReadReg(470, &val); // PORT_READY
while(res<0){
pc->printf("Error: reread state of ready PIN\n\r");
wait_us(4);
res=ReadReg(470, &val);
}
cnt = 0;
while (((val & 0x10000) >> 16 != 1) && (cnt < 500)) {
wait_us(50);
res = ReadReg(470, &val); // PORT_READY
while(res<0){
wait_us(4);
res = ReadReg(470, &val);
}
cnt++;
}
pc->printf("Counter: %d\n\r", cnt);
// Encode the request and send it
res = MLX_ReqReadEch(tx);
if (res < 0){
pc->printf("ReqreadEch error\n\r");
goto END;}
//--------------------------------------------------------------------------------------
//----SHORT PACKET EXCHANGE--------
pc->printf("\tSend ReqReadEch\n\r");
res = TxPacketSlow((uint8*)rx, &rSz, (uint8*)tx, sizeof(tx), 4);
if (res < 0){
pc->printf("txPacketSlow Error\n\r");
goto END;}
/*
pc->printf("\tFirmware read request - processed\n\r");
pc->printf("Firmware readRequest MOSI: \t");
for(int i =0; i<sizeof(tx);i++) {
uint8_t* pnt=(uint8_t*)(&tx);
pc->printf("%02X ", *(pnt+i));
}
pc->printf("\n\r");
pc->printf("Firmware readRequest MISO: \t");
for(int i =0; i<sizeof(rx);i++) {
uint8_t* pnt=(uint8_t*)(&rx);
pc->printf("%02X ", *(pnt+i));
}
pc->printf("\n\r");
pc->printf("-- -- -- -- -- -- --\n\r");*/
//----PACKET EXCHANGE
// Optional status decoding
res = MLX_DecodeStatusS(rx, &iserr, &err);
if (res < 0 || iserr){
pc->printf("Short status decode: Iss err?\n\r");
goto END;}
// Temporary pointer to uint16 data, for simplicity purpose
u16ptr = (uint16*)rxL.data;
PACK_LONG2 prevRX;
PACK_LONG2 prevTX;
res = MLX_EncodeStatusL2(&txL, 0, 0); //Create echo status packet
memset(&prevRX,0,sizeof(prevRX));
memset(&prevTX,0,sizeof(prevTX));
pc->printf("Value of npack:%d \n\r", nPack);
for (a = 0; a < nPack; ++a)
{
if (res < 0){
res = -7;
pc->printf("Problem creating echo status\n\r");
goto END;
}
wait_us(10);
//Tools::Wait(10);
// Clock the remaining long packets
//--------------------------------------------------------------------------------------
//----LONG PACKET EXCHANGE--------
res=TxPacket((uint8_t*)&rxL, &rSz, (uint8_t*)&txL, sizeof(PACK_LONG2));
if (res < 0){
pc->printf("Packet #%d => txPacket_long error\n\r",a);
goto END;}
// Decode the long responses, then extract data values
res = MLX_DecodeResL2(&rxL);
if ((res < 0)){
pc->printf("\n\r");
pc->printf("-- -- -- -- -- -- --\n\r");
pc->printf("Packet #%d => Decode long response error \n\r", a);
pc->printf("TXLONG MOSI Response: ");
for(int i=0;i<(sizeof(PACK_LONG2));i++){
uint8_t* pnt=(uint8_t*)(&txL);
pc->printf("%02X ", *(pnt+i));
}
pc->printf("\n\r");
pc->printf("-- -- -- -- -- -- --\n\r");
pc->printf("TXLONG MISO Response: ");
for(int i=0;i<(sizeof(PACK_LONG2));i++){
uint8_t* pnt=(uint8_t*)(&rxL);
pc->printf("%02X ", *(pnt+i));
}
pc->printf("\n\r");
pc->printf("-- -- -- -- -- -- --\n\r");
pc->printf("Packet #%d => Decode long response error \n\r", a);
goto END;}
// Gather all of the echo data in a buffer.
//for (b = 0; b < (MLX_LONG2_DATA_SZ / 2); ++b)
for (b = 0; b < (128); ++b)
{
//buf[a*(MLX_LONG2_DATA_SZ / 2) + b] = (((u16ptr[b] & 0x00ff) << 8) | ((u16ptr[b] & 0xff00) >> 8)); //Swap LSByte with MSByte
buf[a*(128) + b] = (((u16ptr[b] & 0x00ff) << 8) | ((u16ptr[b] & 0xff00) >> 8)); //Swap LSByte with MSByte
}
//prevTX=txL;
//prevRX=rxL;
}
// Do something with the data... decode an echo, manage the empty echo case
for (b = 0; b < nEchoes; ++b) {
ech[idx].mDistance = buf[b*WORDS_PER_ECH + 1] << 16 | buf[b*WORDS_PER_ECH];
ech[idx].mAmplitude = buf[b*WORDS_PER_ECH + 3] << 16 | buf[b*WORDS_PER_ECH +2];
ech[idx].mBase = buf[b*WORDS_PER_ECH + 5] << 16 | buf[b*WORDS_PER_ECH + 4];
ech[idx].mMaxIndex = buf[b*WORDS_PER_ECH + 6];
ech[idx].mChannelIndex = (uint8) buf[b*WORDS_PER_ECH + 7];
ech[idx].mValid = buf[b*WORDS_PER_ECH + 7] >>8;
ech[idx].mAmplitudeLowScale = buf[b*WORDS_PER_ECH + 9] | buf[b*WORDS_PER_ECH + 8];
ech[idx].mSaturationWidth = buf[b*WORDS_PER_ECH + 11] | buf[b*WORDS_PER_ECH + 10];
++idx;
}
res = idx;
trigger.write(0);
END:
trigger.write(0);
return res;
}
int LidarSpi::GetTrace ( uint16_t *buf, uint16_t maxN, uint16_t nSam, uint16_t idx, Serial* pc){
trigger.write(0);
int res, a, b, i;
uint32_t cnt;
uint16_t rSz;
PACK_SHORT rx[1], tx[1];
PACK_LONG1 rxL, txL;
uint8_t iserr;
uint16_t err;
uint32_t val = 0;
uint16_t * u16ptr;
pc->printf("Buffer space required: %d\n\r", MAXTRCLEN);
// Required buffer space
if (maxN < MAXTRCLEN){
pc-printf("NOT ENOUGH BUFFER SPACEn\r");
return -1;}
// Divide by payload size to get number of packets
// const int nPack = MAXTRCLEN / MLX_LONG_DATA_SZ;
// WTA: change nPack to a variable, initially 64
int nPack = MAXTRCLEN / MLX_LONG1_DATA_SZ;
pc->printf("npack: %d", nPack);
// Ensure transmitted packet is all zeros to not send trash
memset(&txL, 0, sizeof(PACK_LONG1));
memset(tx, 0, sizeof(tx));
// memset(rx, 0, sizeof(rx));
res = ReadReg(336, &val); // PORT_CHSEL
if (res < 0)
goto END;
val >>= 16;
pc->printf("chsel = %d\n", val);
cnt = 0;
// Count how many channels are selected
for (i = 0; i < 16; i++) {
if (val & 0x1)
cnt++;
val >>= 1;
}
nPack *= cnt;
nPack /= 16;
res = ReadReg(332, &val); // PORT_OVR_ACCUM_ACQ_OVR
// pc->printf("PORT_OVR = %d\n", (val >> 16));
val = (val >> 16) & 3; // Get bits 0 and 1
if (res < 0){
pc->printf("ReadReg Error1\n\r");
goto END;}
if (val == 0){ //00 = 1
nPack /= 4;
}
else if (val == 1){ //01 = 2
nPack /= 4;
}
else if (val == 2){ //10 = 4
nPack /= 2;
}
else if (val == 3){ //11 = 8
nPack /= 1;
}
else {
pc->printf("GetTrace: bad value\n");
}
// Write 1 to PORT_ACQU register and then wait
res = ReadReg(0x146, &val); // PORT_ACQU
if (res < 0){
pc->printf("ReadReg Error2\n\r");
goto END;}
val = (val>>16) | 1;
trigger.write(1);
res = WriteReg(0x146, val); // PORT_ACQU
if (res < 0){
pc->printf("WriteReg Error3\n\r");
goto END;}
// Wait till PORT_READY bit is set.
res = ReadReg(470, &val); // PORT_READY
cnt = 0;
/*
while (((val & 0x10000) >> 16 != 1) && (cnt < 500)) {
wait_us(50);
res = ReadReg(470, &val); // PORT_READY
cnt++;
}*/
while((!dataReady.read())&& (cnt<500)){
wait_us(50);
cnt++;
}
trigger.write(0);
pc-printf("Count: %d\n\r", cnt);
// Encode the request and send it
res = MLX_ReqReadTrc(tx);
if (res < 0)
goto END;
//--------------------------------------------------------------------------------------
//----SHORT PACKET EXCHANGE--------
res = TxPacketSlow((uint8_t*)rx, &rSz, (uint8_t*)tx, sizeof(tx), 0);
if (res < 0)
goto END;
//----PACKET EXCHANGE
//--------------------------------------------------------------------------------------
// Optional status decoding
res = MLX_DecodeStatusS(rx, &iserr, &err);
if (res < 0 || iserr)
goto END;
// Temporary pointer to uint16 data, for simplicity purpose
u16ptr = (uint16_t*)rxL.data;
//device.format(16,1);
//trigger.write(1);
for (a = 0; a < nPack; ++a)
{
res = MLX_EncodeStatusL1(&txL, 0, 0);
if (res < 0){
res = -7;
goto END;
}
//Tools::Wait(10);
wait_us(10);
// Clock the remaining long packets
res = TxPacket((uint8_t*)&rxL, &rSz, (uint8_t*)&txL, sizeof(PACK_LONG1));
// pc->printf("\nRXL%d = 0x%02x%02x%02x...[x294 bytes]...%02x%02x%02x\n", a + 1, rxL.buf[0], rxL.buf[1], rxL.buf[2], rxL.buf[297], rxL.buf[298], rxL.buf[299]);
// pc->printf("\nRXL%d = 0x%02x%02x%02x%02x%02x%02x\n", a + 1, rxL.buf[2], rxL.buf[3], rxL.buf[4], rxL.buf[5], rxL.buf[6], rxL.buf[7]);
if (res < 0){
res = -8;
goto END;
}
// Decode the long responses, then extract data values
res = MLX_DecodeResL1(&rxL);
if ((res < 0)){
pc->printf("LONG READ ERROR: Stopped at the %d long message\n", a);
pc->printf("TXLONG MOSI Response: ");
for(int i=0;i<(sizeof(PACK_LONG1));i++){
uint8_t* pnt=(uint8_t*)(&txL);
pc->printf("%02X ", *(pnt+i));
}
pc->printf("\n\r");
pc->printf("-- -- -- -- -- -- --\n\r");
pc->printf("TXLONG MISO Response: ");
for(int i=0;i<(sizeof(PACK_LONG1));i++){
uint8_t* pnt=(uint8_t*)(&rxL);
pc->printf("%02X ", *(pnt+i));
}
pc->printf("\n\r");
pc->printf("-- -- -- -- -- -- --\n\r");
//printf("last RXL = \n");
//for (i = 0; i < 300; i++) {
// pc->printf("%02x", rxL.buf[i]);
// if (((i + 1) % 8) == 0)
// pc->printf("\n");
//}
//printf("\n");
res = -9;
goto END;
}
// Copy the returned data into the user buffer
// WTA: only half the MLX_LONG_DATA_SZ because we copy 2 bytes at a time
for (b = 0; b < (MLX_LONG1_DATA_SZ / 2); ++b)
{
//WTA: removed MLX_HDR_SZ
buf[a*(MLX_LONG1_DATA_SZ / 2) + b] = u16ptr[b];
}
}
trigger.write(0);
device.format(8,1);
END:
device.format(8,1);
return res;
}
int LidarSpi::GetTraceOne ( uint16_t *buf, uint16_t maxN, uint16_t nSam, uint16_t idx,int index , Serial* pc){
int res, a, b, i;
uint32_t cnt;
uint16_t rSz;
PACK_SHORT rx[1], tx[1];
PACK_LONG1 rxL, txL;
uint8_t iserr;
uint16_t err;
uint32_t val = 0;
uint16_t * u16ptr;
//pc->printf("Buffer space required: %d\n\r", MAXTRCLEN);
// Required buffer space
if (maxN < MAXTRCLEN){
pc-printf("NOT ENOUGH BUFFER SPACEn\r");
return -1;}
// Divide by payload size to get number of packets
// const int nPack = MAXTRCLEN / MLX_LONG_DATA_SZ;
// WTA: change nPack to a variable, initially 64
int nPack = MAXTRCLEN / MLX_LONG1_DATA_SZ;
//pc->printf("npack: %d", nPack);
// Ensure transmitted packet is all zeros to not send trash
memset(&txL, 0, sizeof(PACK_LONG1));
memset(tx, 0, sizeof(tx));
// memset(rx, 0, sizeof(rx));
res = ReadReg(336, &val); // PORT_CHSEL
if (res < 0)
goto END;
val >>= 16;
//pc->printf("chsel = %d\n", val);
cnt = 0;
// Count how many channels are selected
for (i = 0; i < 16; i++) {
if (val & 0x1)
cnt++;
val >>= 1;
}
nPack *= cnt;
nPack /= 16;
res = ReadReg(332, &val); // PORT_OVR_ACCUM_ACQ_OVR
// pc->printf("PORT_OVR = %d\n", (val >> 16));
val = (val >> 16) & 3; // Get bits 0 and 1
if (res < 0){
pc->printf("ReadReg Error1\n\r");
goto END;}
if (val == 0){ //00 = 1
nPack /= 4;
}
else if (val == 1){ //01 = 2
nPack /= 4;
}
else if (val == 2){ //10 = 4
nPack /= 2;
}
else if (val == 3){ //11 = 8
nPack /= 1;
}
else {
pc->printf("GetTrace: bad value\n");
}
// Write 1 to PORT_ACQU register and then wait
res = ReadReg(0x146, &val); // PORT_ACQU
if (res < 0){
pc->printf("ReadReg Error2\n\r");
goto END;}
val = (val>>16) | 1;
res = WriteReg(0x146, val); // PORT_ACQU
if (res < 0){
pc->printf("WriteReg Error3\n\r");
goto END;}
// Wait till PORT_READY bit is set.
res = ReadReg(470, &val); // PORT_READY
cnt = 0;
while (((val & 0x10000) >> 16 != 1) && (cnt < 500)) {
wait_us(50);
res = ReadReg(470, &val); // PORT_READY
cnt++;
}
// Encode the request and send it
res = MLX_ReqReadTrc(tx);
if (res < 0)
goto END;
//--------------------------------------------------------------------------------------
//----SHORT PACKET EXCHANGE--------
res = TxPacketSlow((uint8_t*)rx, &rSz, (uint8_t*)tx, sizeof(tx), 0);
if (res < 0)
goto END;
pc->printf("MOSI ReqReadTrace:\t 0x");
for(int i=0;i<(sizeof(tx));i++){
uint8_t* pnt=(uint8_t*)tx;
pc->printf("%02X", *(pnt+i));
}
pc->printf("\n");
pc->printf("MISO ReqReadTrace:\t 0x");
for(int i=0;i<(sizeof(tx));i++){
uint8_t* pnt=(uint8_t*)rx;
pc->printf("%02X", *(pnt+i));
}
pc->printf("\n");
pc->printf("-- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- --\n");
//----PACKET EXCHANGE
//--------------------------------------------------------------------------------------
// Optional status decoding
res = MLX_DecodeStatusS(rx, &iserr, &err);
if (res < 0 || iserr)
goto END;
// Temporary pointer to uint16 data, for simplicity purpose
u16ptr = (uint16_t*)rxL.data;
//device.format(16,1);
trigger.write(1);
for (a = 0; a < nPack; ++a)
{
res = MLX_EncodeStatusL1(&txL, 0, 0);
if (res < 0){
res = -7;
goto END;
}
//Tools::Wait(10);
wait_us(10);
// Clock the remaining long packets
res = TxPacket((uint8_t*)&rxL, &rSz, (uint8_t*)&txL, sizeof(PACK_LONG1));
// pc->printf("\nRXL%d = 0x%02x%02x%02x...[x294 bytes]...%02x%02x%02x\n", a + 1, rxL.buf[0], rxL.buf[1], rxL.buf[2], rxL.buf[297], rxL.buf[298], rxL.buf[299]);
// pc->printf("\nRXL%d = 0x%02x%02x%02x%02x%02x%02x\n", a + 1, rxL.buf[2], rxL.buf[3], rxL.buf[4], rxL.buf[5], rxL.buf[6], rxL.buf[7]);
if (res < 0){
res = -8;
goto END;
}
// Decode the long responses, then extract data values
res = MLX_DecodeResL1(&rxL);
if ((res < 0)){
pc->printf("LONG READ ERROR: Stopped at the %d long message\n", a);
pc->printf("TXLONG MOSI Response: ");
for(int i=0;i<(sizeof(PACK_LONG1));i++){
uint8_t* pnt=(uint8_t*)(&txL);
pc->printf("%02X ", *(pnt+i));
}
pc->printf("\n\r");
pc->printf("-- -- -- -- -- -- --\n\r");
pc->printf("TXLONG MISO Response: ");
for(int i=0;i<(sizeof(PACK_LONG1));i++){
uint8_t* pnt=(uint8_t*)(&rxL);
pc->printf("%02X ", *(pnt+i));
}
pc->printf("\n\r");
pc->printf("-- -- -- -- -- -- --\n\r");
//printf("last RXL = \n");
//for (i = 0; i < 300; i++) {
// pc->printf("%02x", rxL.buf[i]);
// if (((i + 1) % 8) == 0)
// pc->printf("\n");
//}
//printf("\n");
res = -9;
goto END;
}
// Copy the returned data into the user buffer
// WTA: only half the MLX_LONG_DATA_SZ because we copy 2 bytes at a time
for (b = 0; b < (MLX_LONG1_DATA_SZ / 2); ++b)
{
//WTA: removed MLX_HDR_SZ
buf[a*(MLX_LONG1_DATA_SZ / 2) + b] = u16ptr[b];
}
if(a<64){
pc->printf("Trace packet %d MOSI: \n\t\t\t\t\t0x", a);
for(int i=0;i<(sizeof(PACK_LONG1));i++){
uint8_t* pnt=(uint8_t*)(&txL);
pc->printf("%02X", *(pnt+i));
if(((i %30) ==0)&&(i>0))pc->printf("\n\t\t\t\t\t");
}
pc->printf("\n\r");
pc->printf("Trace packet %d MISO: \n\t\t\t\t\t0x", a);
for(int i=0;i<(sizeof(PACK_LONG1));i++){
uint8_t* pnt=(uint8_t*)(&rxL);
pc->printf("%02X", *(pnt+i));
if(((i %30) ==0)&&(i>0))pc->printf("\n\t\t\t\t\t");
}
pc->printf("\n\r");
pc->printf("-- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- --\n\r");
}
}
trigger.write(0);
device.format(8,1);
END:
device.format(8,1);
return res;
}
int LidarSpi::LoadPatch ( uint16_t address, uint8_t *buf, uint16_t nBytes){
int res;
uint16_t rSz;
PACK_SHORT rx[1], tx[1];
PACK_LONG2 rxL, txL;
uint8_t iserr;
uint16_t err;
//uint32_t val = 0;
uint16_t nWordsRemaining;
uint16_t nPack;
uint16_t nWords = nBytes / 2;
// Ensure all packets are all zeros to not send trash
memset(tx, 0, sizeof(tx));
memset(&rxL, 0, sizeof(rxL));
//The Number of words to be transferred can be a multiple of LONG_DATA_SZ. Incase it is not
//multiple of LONG_DATA_SZ, we do last packet with partial data and remaining words as 0
nPack = nWords / (MLX_LONG2_DATA_SZ / 2) + (nWords % (MLX_LONG2_DATA_SZ / 2) == 0 ? 0 :1);
// Encode the request and send it
res = MLX_ReqWriteFW(tx, nPack, address);
if (res < 0)
goto END;
res = TxPacketSlow((uint8_t*)rx, &rSz, (uint8_t*)tx, sizeof(tx), 0);
if (res < 0)
goto END;
// Optional status decoding
res = MLX_DecodeStatusS(rx, &iserr, &err);
if (res < 0 || iserr)
goto END;
nWordsRemaining = nWords;
for (uint a = 0; a < nPack; ++a)
{
uint size;
if (nWordsRemaining > (MLX_LONG2_DATA_SZ / 2))
size = MLX_LONG2_DATA_SZ / 2;
else
size = nWordsRemaining;
res = MLX_WriteDataL2(&txL, size, a, &buf[a*MLX_LONG2_DATA_SZ]);
if (res < 0){
res = -7;
goto END;
}
//Tools::Wait(10);
// Clock the remaining long packets
res = TxPacket((uint8_t*)&rxL, &rSz, (uint8_t*)&txL, sizeof(PACK_LONG2));
// Decode the long responses
res = MLX_DecodeResL2(&rxL);
if (res < 0){
printf("LONG WRITE ERROR: Stopped at the %d long message\n", a);
res = -9;
goto END;
}
nWordsRemaining = nWords - size;
}
//LAST STATUS LONG PACKET FROM 75320 to get status of last write long
res = MLX_EncodeStatusL2(&txL, 0, 0);
if (res < 0) {
res = -7;
goto END;
}
//Tools::Wait(10);
// Clock the remaining long packets
res = TxPacket((uint8_t*)&rxL, &rSz, (uint8_t*)&txL, sizeof(PACK_LONG2));
if (res < 0)
goto END;
// Change jump table pointer.
res = WriteReg(0x1000, 0x7000); // write addr: 0x1000 value:0x7000
if (res < 0)
goto END;
END:
return res;
}
void LidarSpi::Trigger(int level){
trigger.write(level);
}