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Create an Ethernet shield version.

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This alpha version can be connected to across the network using the OLS
client and an Ethernet shield.
This commit is contained in:
Andrew Gillham
2013-06-22 22:04:05 -07:00
parent 17d2a1a15f
commit 1b9c3e7314
1 changed files with 258 additions and 208 deletions
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466
logic_analyzer.ino
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@@ -29,6 +29,16 @@
*/
/*
* NOTE: This is an ALPHA of support for an Ethernet attached Logic Analyzer.
* Tested with an Arduino Duemilanove and W5100 based Ethernet shield.
* It may work with other combinations, but I haven't tested it.
*
* USE: Configure the mac address (if you want) and the ip address (mandatory)
* for your network and upload it. In the OLS client select network
* instead of serial and use your ip address and port 1234.
* Click capture! You should get some data back from your Arduino.
*
*
* NOTE: v0.09 switches the channels BACK to pins 8-13 for trigger reliability.
* Please report any issues. Uncomment USE_PORTD for pins 2-7.
*
@@ -82,6 +92,8 @@
*
*/
#include <SPI.h>
#include <Ethernet.h>
/*
* Function prototypes so this can compile from the cli.
* You'll need the 'arduino-core' package and to check the paths in the
@@ -98,12 +110,11 @@ void get_metadata(void);
void debugprint(void);
void debugdump(void);
/*
* Should we use PORTD or PORTB? (default is PORTB)
* PORTD support with triggers seems to work but needs more testing.
*/
//#define USE_PORTD 1
#define USE_PORTD 1
/*
* Arduino device profile: ols.profile-agla.cfg
@@ -218,10 +229,30 @@ unsigned int delayTime = 0;
unsigned long divider = 0;
boolean rleEnabled = 0;
/*
* Enter a MAC address and IP address for your Arduino.
*/
byte mac[] = {
0x40, 0x00, 0x01, 0x02, 0x03, 0x04 };
IPAddress ip(192,168,1,200);
// Initialize the Ethernet server library
// with the IP address and port you want to use
// (port 80 is default for HTTP):
EthernetServer server(1234);
EthernetClient client;
void setup()
{
Serial.begin(115200);
// start the Ethernet connection and the server:
Ethernet.begin(mac, ip);
server.begin();
Serial.print("server is at ");
Serial.println(Ethernet.localIP());
/*
* set debug pin (digital pin 8) to output right away so it settles.
* this gets toggled during sampling as a way to measure
@@ -231,16 +262,24 @@ void setup()
DEBUG_ENABLE; /* debug measurement pin */
pinMode(CHAN0, INPUT);
digitalWrite(CHAN0, LOW);
pinMode(CHAN1, INPUT);
digitalWrite(CHAN1, LOW);
pinMode(CHAN2, INPUT);
digitalWrite(CHAN2, LOW);
pinMode(CHAN3, INPUT);
digitalWrite(CHAN3, LOW);
pinMode(CHAN4, INPUT);
digitalWrite(CHAN4, LOW);
#ifdef CHAN5
pinMode(CHAN5, INPUT);
digitalWrite(CHAN5, LOW);
#endif
#if defined(__AVR_ATmega1280__) || defined(__AVR_ATmega2560__)
pinMode(CHAN6, INPUT);
digitalWrite(CHAN6, LOW);
pinMode(CHAN7, INPUT);
digitalWrite(CHAN7, LOW);
#else
#ifndef CHAN5
pinMode(ledPin, OUTPUT);
@@ -252,160 +291,170 @@ void loop()
{
int i;
if (Serial.available() > 0) {
cmdByte = Serial.read();
switch(cmdByte) {
case SUMP_RESET:
/*
// listen for incoming clients
client = server.available();
if (client) {
Serial.println("new client");
while (client.connected()) {
if (client.available()) {
cmdByte = client.read();
switch(cmdByte) {
case SUMP_RESET:
/*
* We don't do anything here as some unsupported extended commands have
* zero bytes and are mistaken as resets. This can trigger false resets
* so we don't erase the data or do anything for a reset.
*/
break;
case SUMP_QUERY:
/* return the expected bytes. */
Serial.write('1');
Serial.write('A');
Serial.write('L');
Serial.write('S');
break;
case SUMP_ARM:
/*
* zero bytes and are mistaken as resets. This can trigger false resets
* so we don't erase the data or do anything for a reset.
*/
break;
case SUMP_QUERY:
/* return the expected bytes. */
client.write('1');
client.write('A');
client.write('L');
client.write('S');
break;
case SUMP_ARM:
/*
* Zero out any previous samples before arming.
* Done here instead via reset due to spurious resets.
*/
for (i = 0 ; i < MAX_CAPTURE_SIZE; i++) {
logicdata[i] = 0;
}
/*
* Done here instead via reset due to spurious resets.
*/
for (i = 0 ; i < MAX_CAPTURE_SIZE; i++) {
logicdata[i] = 0;
}
/*
* depending on the sample rate we need to delay in microseconds
* or milliseconds. We can't do the complex trigger at 1MHz
* so in that case (delayTime == 1 and triggers enabled) use
* captureMicro() instead of triggerMicro().
*/
if (useMicro) {
if (trigger && (delayTime != 1)) {
triggerMicro();
}
else {
captureMicro();
}
}
else {
captureMilli();
}
break;
case SUMP_TRIGGER_MASK:
/*
* or milliseconds. We can't do the complex trigger at 1MHz
* so in that case (delayTime == 1 and triggers enabled) use
* captureMicro() instead of triggerMicro().
*/
if (useMicro) {
if (trigger && (delayTime != 1)) {
triggerMicro();
}
else {
captureMicro();
}
}
else {
captureMilli();
}
break;
case SUMP_TRIGGER_MASK:
/*
* the trigger mask byte has a '1' for each enabled trigger so
* we can just use it directly as our trigger mask.
*/
getCmd();
* we can just use it directly as our trigger mask.
*/
getCmd();
#ifdef USE_PORTD
trigger = cmdBytes[0] << 2;
trigger = cmdBytes[0] << 2;
#else
trigger = cmdBytes[0];
trigger = cmdBytes[0];
#endif
break;
case SUMP_TRIGGER_VALUES:
/*
break;
case SUMP_TRIGGER_VALUES:
/*
* trigger_values can be used directly as the value of each bit
* defines whether we're looking for it to be high or low.
*/
getCmd();
* defines whether we're looking for it to be high or low.
*/
getCmd();
#ifdef USE_PORTD
trigger_values = cmdBytes[0] << 2;
trigger_values = cmdBytes[0] << 2;
#else
trigger_values = cmdBytes[0];
trigger_values = cmdBytes[0];
#endif
break;
case SUMP_TRIGGER_CONFIG:
/* read the rest of the command bytes, but ignore them. */
getCmd();
break;
case SUMP_SET_DIVIDER:
/*
break;
case SUMP_TRIGGER_CONFIG:
/* read the rest of the command bytes, but ignore them. */
getCmd();
break;
case SUMP_SET_DIVIDER:
/*
* the shifting needs to be done on the 32bit unsigned long variable
* so that << 16 doesn't end up as zero.
*/
getCmd();
divider = cmdBytes[2];
divider = divider << 8;
divider += cmdBytes[1];
divider = divider << 8;
divider += cmdBytes[0];
setupDelay();
break;
case SUMP_SET_READ_DELAY_COUNT:
/*
* so that << 16 doesn't end up as zero.
*/
getCmd();
divider = cmdBytes[2];
divider = divider << 8;
divider += cmdBytes[1];
divider = divider << 8;
divider += cmdBytes[0];
setupDelay();
break;
case SUMP_SET_READ_DELAY_COUNT:
/*
* this just sets up how many samples there should be before
* and after the trigger fires. The readCount is total samples
* to return and delayCount number of samples after the trigger.
* this sets the buffer splits like 0/100, 25/75, 50/50
* for example if readCount == delayCount then we should
* return all samples starting from the trigger point.
* if delayCount < readCount we return (readCount - delayCount) of
* samples from before the trigger fired.
*/
getCmd();
readCount = 4 * (((cmdBytes[1] << 8) | cmdBytes[0]) + 1);
if (readCount > MAX_CAPTURE_SIZE)
readCount = MAX_CAPTURE_SIZE;
delayCount = 4 * (((cmdBytes[3] << 8) | cmdBytes[2]) + 1);
if (delayCount > MAX_CAPTURE_SIZE)
delayCount = MAX_CAPTURE_SIZE;
break;
case SUMP_SET_FLAGS:
/* read the rest of the command bytes and check if RLE is enabled. */
getCmd();
rleEnabled = ((cmdBytes[1] & B1000000) != 0);
break;
case SUMP_GET_METADATA:
/*
* and after the trigger fires. The readCount is total samples
* to return and delayCount number of samples after the trigger.
* this sets the buffer splits like 0/100, 25/75, 50/50
* for example if readCount == delayCount then we should
* return all samples starting from the trigger point.
* if delayCount < readCount we return (readCount - delayCount) of
* samples from before the trigger fired.
*/
getCmd();
readCount = 4 * (((cmdBytes[1] << 8) | cmdBytes[0]) + 1);
if (readCount > MAX_CAPTURE_SIZE)
readCount = MAX_CAPTURE_SIZE;
delayCount = 4 * (((cmdBytes[3] << 8) | cmdBytes[2]) + 1);
if (delayCount > MAX_CAPTURE_SIZE)
delayCount = MAX_CAPTURE_SIZE;
break;
case SUMP_SET_FLAGS:
/* read the rest of the command bytes and check if RLE is enabled. */
getCmd();
rleEnabled = ((cmdBytes[1] & B1000000) != 0);
break;
case SUMP_GET_METADATA:
/*
* We return a description of our capabilities.
* Check the function's comments below.
*/
get_metadata();
break;
case SUMP_SELF_TEST:
/* ignored. */
break;
* Check the function's comments below.
*/
get_metadata();
break;
case SUMP_SELF_TEST:
/* ignored. */
break;
#ifdef DEBUG
/*
/*
* a couple of debug commands used during development.
*/
case '0':
/*
*/
case '0':
/*
* This resets the debug buffer pointer, effectively clearing the
* previous commands out of the buffer. Clear the sample data as well.
* Just send a '0' from the Arduino IDE's Serial Monitor.
*/
savecount=0;
for (i = 0 ; i < MAX_CAPTURE_SIZE; i++) {
logicdata[i] = 0;
}
break;
case '1':
/*
* previous commands out of the buffer. Clear the sample data as well.
* Just send a '0' from the Arduino IDE's Serial Monitor.
*/
savecount=0;
for (i = 0 ; i < MAX_CAPTURE_SIZE; i++) {
logicdata[i] = 0;
}
break;
case '1':
/*
* This is used to see what commands were sent to the device.
* you can use the Arduino serial monitor and send a '1' and get
* a debug printout. useless except for development.
*/
blinkled();
debugprint();
break;
case '2':
/*
* you can use the Arduino serial monitor and send a '1' and get
* a debug printout. useless except for development.
*/
blinkled();
debugprint();
break;
case '2':
/*
* This dumps the sample data to the serial port. Used for debugging.
*/
debugdump();
break;
*/
debugdump();
break;
#endif /* DEBUG */
default:
/* ignore any unrecognized bytes. */
break;
}
}
default:
/* ignore any unrecognized bytes. */
break;
} /* switch */
} /* if client.available() */
} /* while */
delay(1);
client.stop();
Serial.println("client disconnected?");
} /* if client */
}
void blinkled() {
@@ -424,10 +473,10 @@ void blinkled() {
*/
void getCmd() {
delay(10);
cmdBytes[0] = Serial.read();
cmdBytes[1] = Serial.read();
cmdBytes[2] = Serial.read();
cmdBytes[3] = Serial.read();
cmdBytes[0] = client.read();
cmdBytes[1] = client.read();
cmdBytes[2] = client.read();
cmdBytes[3] = client.read();
#ifdef DEBUG
if (savecount < 120 ) {
@@ -546,9 +595,9 @@ void captureMicro() {
*/
for (i = 0 ; i < readCount; i++) {
#ifdef USE_PORTD
Serial.write(logicdata[i] >> 2);
client.write(logicdata[i] >> 2);
#else
Serial.write(logicdata[i]);
client.write(logicdata[i]);
#endif
}
}
@@ -621,9 +670,9 @@ void captureMilli() {
}
for (i = 0 ; i < readCount; i++) {
#ifdef USE_PORTD
Serial.write(logicdata[i] >> 2);
client.write(logicdata[i] >> 2);
#else
Serial.write(logicdata[i]);
client.write(logicdata[i]);
#endif
}
}
@@ -813,9 +862,9 @@ void triggerMicro() {
logicIndex = 0;
}
#ifdef USE_PORTD
Serial.write(logicdata[logicIndex++] >> 2);
client.write(logicdata[logicIndex++] >> 2);
#else
Serial.write(logicdata[logicIndex++]);
client.write(logicdata[logicIndex++]);
#endif
}
}
@@ -852,69 +901,69 @@ void setupDelay() {
*/
void get_metadata() {
/* device name */
Serial.write((uint8_t)0x01);
Serial.write('A');
Serial.write('G');
Serial.write('L');
Serial.write('A');
client.write((uint8_t)0x01);
client.write('A');
client.write('G');
client.write('L');
client.write('A');
#if defined(__AVR_ATmega1280__) || defined(__AVR_ATmega2560__)
Serial.write('M');
client.write('M');
#endif /* Mega */
Serial.write('v');
Serial.write('0');
Serial.write((uint8_t)0x00);
client.write('v');
client.write('0');
client.write((uint8_t)0x00);
/* firmware version */
Serial.write((uint8_t)0x02);
Serial.write('0');
Serial.write('.');
Serial.write('0');
Serial.write('9');
Serial.write((uint8_t)0x00);
client.write((uint8_t)0x02);
client.write('0');
client.write('.');
client.write('0');
client.write('9');
client.write((uint8_t)0x00);
/* sample memory */
Serial.write((uint8_t)0x21);
Serial.write((uint8_t)0x00);
Serial.write((uint8_t)0x00);
client.write((uint8_t)0x21);
client.write((uint8_t)0x00);
client.write((uint8_t)0x00);
#if defined(__AVR_ATmega1280__) || defined(__AVR_ATmega2560__)
/* 7168 bytes */
Serial.write((uint8_t)0x1C);
Serial.write((uint8_t)0x00);
client.write((uint8_t)0x1C);
client.write((uint8_t)0x00);
#elif defined(__AVR_ATmega328P__)
/* 1024 bytes */
Serial.write((uint8_t)0x04);
Serial.write((uint8_t)0x00);
client.write((uint8_t)0x04);
client.write((uint8_t)0x00);
#else
/* 532 bytes */
Serial.write((uint8_t)0x02);
Serial.write((uint8_t)0x14);
client.write((uint8_t)0x02);
client.write((uint8_t)0x14);
#endif /* Mega */
/* sample rate (1MHz) */
Serial.write((uint8_t)0x23);
Serial.write((uint8_t)0x00);
Serial.write((uint8_t)0x0F);
Serial.write((uint8_t)0x42);
Serial.write((uint8_t)0x40);
client.write((uint8_t)0x23);
client.write((uint8_t)0x00);
client.write((uint8_t)0x0F);
client.write((uint8_t)0x42);
client.write((uint8_t)0x40);
/* number of probes (6 by default on Arduino, 8 on Mega) */
Serial.write((uint8_t)0x40);
client.write((uint8_t)0x40);
#if defined(__AVR_ATmega1280__) || defined(__AVR_ATmega2560__)
Serial.write((uint8_t)0x08);
client.write((uint8_t)0x08);
#else
#ifdef CHAN5
Serial.write((uint8_t)0x06);
client.write((uint8_t)0x06);
#else
Serial.write((uint8_t)0x05);
client.write((uint8_t)0x05);
#endif /* CHAN5 */
#endif /* Mega */
/* protocol version (2) */
Serial.write((uint8_t)0x41);
Serial.write((uint8_t)0x02);
client.write((uint8_t)0x41);
client.write((uint8_t)0x02);
/* end of data */
Serial.write((uint8_t)0x00);
client.write((uint8_t)0x00);
}
/*
@@ -927,36 +976,36 @@ void debugprint() {
int i;
#if 0
Serial.print("divider = ");
Serial.println(divider, DEC);
Serial.print("delayTime = ");
Serial.println(delayTime, DEC);
Serial.print("trigger_values = ");
Serial.println(trigger_values, BIN);
client.print("divider = ");
client.println(divider, DEC);
client.print("delayTime = ");
client.println(delayTime, DEC);
client.print("trigger_values = ");
client.println(trigger_values, BIN);
#endif
Serial.print("readCount = ");
Serial.println(readCount, DEC);
Serial.print("delayCount = ");
Serial.println(delayCount, DEC);
Serial.print("logicIndex = ");
Serial.println(logicIndex, DEC);
Serial.print("triggerIndex = ");
Serial.println(triggerIndex, DEC);
Serial.print("rleEnabled = ");
Serial.println(rleEnabled, DEC);
client.print("readCount = ");
client.println(readCount, DEC);
client.print("delayCount = ");
client.println(delayCount, DEC);
client.print("logicIndex = ");
client.println(logicIndex, DEC);
client.print("triggerIndex = ");
client.println(triggerIndex, DEC);
client.print("rleEnabled = ");
client.println(rleEnabled, DEC);
Serial.println("Bytes:");
client.println("Bytes:");
for (i = 0 ; i < savecount; i++) {
if (savebytes[i] == 0x20) {
Serial.println();
client.println();
}
else {
Serial.print(savebytes[i], HEX);
Serial.write(' ');
client.print(savebytes[i], HEX);
client.write(' ');
}
}
Serial.println("done...");
client.println("done...");
}
/*
@@ -967,17 +1016,17 @@ void debugdump() {
int i;
int j = 1;
Serial.print("\r\n");
client.print("\r\n");
for (i = 0 ; i < MAX_CAPTURE_SIZE; i++) {
#ifdef USE_PORTD
Serial.print(logicdata[i] >> 2, HEX);
client.print(logicdata[i] >> 2, HEX);
#else
Serial.print(logicdata[i], HEX);
client.print(logicdata[i], HEX);
#endif
Serial.print(" ");
client.print(" ");
if (j == 32) {
Serial.print("\r\n");
client.print("\r\n");
j = 0;
}
j++;
@@ -991,3 +1040,4 @@ void debugdump() {