Add device profile for Arduino logic analyzer

Use this device profile with the alternative SUMP client. It goes in the plugins directory with the other similarly named files.
2026-05-07 08:33:09 +03:00 · 2011-08-03 19:43:09 -07:00
6 changed files with 143 additions and 29382 deletions
--- a/54
+++ b/54
@@ -5,29 +5,26 @@ This Arduino sketch implements a SUMP protocol compatible with the standard
 SUMP client as well as the alternative client from here:
 	http://www.lxtreme.nl/ols/
 The alternative client version is highly recommended.  Download version
 "ols-0.9.7" or newer for built-in device profiles.
 This SUMP protocol compatible logic analyzer for the Arduino board supports
 5 channels consisting of digital pins 8-12, which are the first 5 bits (0-4)
 of PORTB. Arduino pin 13 / bit 5 is the Arduino LED, bits 6 & 7 are the
 crystal oscillator pins.
 Uncomment CHAN5 below if you want to use the LED pin as an input and have
 6 channels.
-On the Arduino Mega board 8 channels are supported and 7k of samples.
+NOTE:
-Pins 22-29 (Port A) are used by default.
+You must DISABLE the Arduino auto reset feature to use this logic analyzer
 code. There are various methods to do this, some boards have a jumper,
 others require you to cut a trace.  You may also install a *precisely*
 120 Ohm resistor between the reset & 5V piins.  Make sure it is really
 120 Ohm or you may damage your board.
 To use this with the original or alternative SUMP clients,
 use these settings:
-Sampling rate: 4MHz (or lower) (no 2MHz on ATmega168)
+Sampling rate: 1MHz (or lower)
 Channel Groups: 0 (zero) only
-Recording Size:
+Recording Size: 1024 (or lower)
   ATmega168:  532 (or lower)
   ATmega328:  1024 (or lower)
   ATmega2560: 7168 (or lower)
 Noise Filter: doesn't matter
 RLE: disabled (unchecked)
@@ -36,38 +33,5 @@ below 1MHz.  1MHz works for a basic busy wait trigger that doesn't store
 until after the trigger fires.
 Please try it out and report back.
-Older Notes
+Release: v0.03 March 7, 2011.
 ===========================================================================
 NOTE: With v0.11 you can now sample at 4MHz & 2MHz rates in addition to the 
      previous 1MHz and lower rates.  This is done via unrolled loops which
      makes the source code huge and the binary takes much more of the flash.
      v0.11 is just slightly to big for an ATmega168's flash.  You can comment
      out either captureInline2mhz() or captureInline4mhz() and it will fit.
      [ The code automatically skips the 2MHz code now, this isn't needed. ]
 NOTE: v0.09 switched the channels BACK to pins 8-13 for trigger reliability.
      Please report any issues.  Uncomment USE_PORTD for pins 2-7.
 NOTE: The device profiles should be included with this code.  Copy them to the
      'plugins' directory of the client.  The location varies depending on the
      platform, but on the mac it is here by default:
      /Applications/LogicSniffer.app/Contents/Resources/Java/plugins
      [ These are included in ols-0.9.7 or newer so do not copy them. ]
 NOTE: If you are using the original SUMP client, then you will get a
      "device not found" error.
      You must DISABLE the Arduino auto reset feature to use this logic analyzer
      code. There are various methods to do this, some boards have a jumper,
      others require you to cut a trace.  You may also install a *precisely*
      120 Ohm resistor between the reset & 5V piins.  Make sure it is really
      120 Ohm or you may damage your board.  It is much easier to use the
      alternative SUMP client referenced above.
      [ This is not needed with ols-0.9.7 or newer. ]
      [ DO NOT use this resistor unless absolutely necessary on old clients. ]
 NOTE: This master branch now supports Arduino 1.0 only.
      Checkout branch logic_analyzer_v0_5 for Arduino 22 support.
 Release: v0.12 September 6, 2013.
--- a/logic_analyzer.pde
+++ b/logic_analyzer.pde
@@ -2,7 +2,7 @@
 *
 * SUMP Protocol Implementation for Arduino boards.
 *
- * Copyright (c) 2011,2012,2013,2014 Andrew Gillham
+ * Copyright (c) 2011 Andrew Gillham
 * All rights reserved.
 *
 * Redistribution and use in source and binary forms, with or without
@@ -25,44 +25,40 @@
 * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF
 * THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
 *
 *	$Id: logic_analyzer.pde,v 1.14 2011-03-08 07:14:42 gillham Exp $
 *
 */
 /*
 * NOTE: v0.09 switched the channels BACK to pins 8-13 for trigger reliability.
 *       Please report any issues.  Uncomment USE_PORTD for pins 2-7.
 *
 * This Arduino sketch implements a SUMP protocol compatible with the standard
 * SUMP client as well as the alternative client from here:
 *	http://www.lxtreme.nl/ols/
 *
 * This SUMP protocol compatible logic analyzer for the Arduino board supports
- * 6 channels consisting of digital pins 2-7, which are the last 6 bits (2-7)
+ * 5 channels consisting of digital pins 8-12, which are the first 5 bits (0-4)
- * of PORTD.  Bits 0 & 1 are the UART RX/TX pins.
+ * of PORTB. Arduino pin 13 / bit 5 is the Arduino LED, bits 6 & 7 are the
 * crystal oscillator pins.
 * Uncomment CHAN5 below if you want to use the LED pin as an input and have
 * 6 channels.
 *
- * On the Arduino Mega board 8 channels are supported and 7k of samples.
+ * NOTE:
- * Pins 22-29 (Port A) are used by default, you can change the 'CHANPIN' below
+ * You must DISABLE the Arduino auto reset feature to use this logic analyzer
- * if something else works better for you.
+ * code. There are various methods to do this, some boards have a jumper,
 * others require you to cut a trace.  You may also install a *precisely*
 * 120 Ohm resistor between the reset & 5V piins.  Make sure it is really
 * 120 Ohm or you may damage your board.
 *
 * To use this with the original or alternative SUMP clients,
 * use these settings:
 * 
- * Sampling rate: 4MHz (or lower) (no 2MHz on ATmega168)
+ * Sampling rate: 1MHz (or lower)
 * Channel Groups: 0 (zero) only
- * Recording Size:
+ * Recording Size: 1024 (or lower)
 *    ATmega168:  532 (or lower)
 *    ATmega328:  1024 (or lower)
 *    ATmega2560: 7168 (or lower)
 * Noise Filter: doesn't matter
 * RLE: disabled (unchecked)
 *    NOTE: Preliminary RLE support for 50Hz or less exists, please test it.
 *
 * Triggering is still a work in progress, but generally works for samples
 * below 1MHz.  1MHz works for a basic busy wait trigger that doesn't store
 * until after the trigger fires.
 * Please try it out and report back.
 *
- * Release: v0.12 September 6, 2013.
+ * Release: v0.02 February 28, 2011.
 *
 */
@@ -82,62 +78,16 @@ void get_metadata(void);
 void debugprint(void);
 void debugdump(void);
 /*
- * Should we use PORTD or PORTB?  (default is PORTB)
+ * Uncomment CHAN5 to use it as an additional input.
- * PORTD support with triggers seems to work but needs more testing.
+ * You'll need to change the number of channels in the device profile as well.
 */
 //#define USE_PORTD 1
 #if defined(USE_PORTD)
 #define SHIFTBITS 2
 #elif defined(__AVR_ATmega32U4__)
 #define SHIFTBITS 1
 #endif
 /*
 * Arduino device profile:      ols.profile-agla.cfg
 * Arduino Mega device profile: ols.profile-aglam.cfg
 */
 #if defined(__AVR_ATmega1280__) || defined(__AVR_ATmega2560__)
 #define CHANPIN PINA
 #define CHAN0 22
 #define CHAN1 23
 #define CHAN2 24
 #define CHAN3 25
 #define CHAN4 26
 #define CHAN5 27
 #define CHAN6 28
 #define CHAN7 29
 #else
 #if defined(USE_PORTD)
 #define CHANPIN PIND
 #define CHAN0 2
 #define CHAN1 3
 #define CHAN2 4
 #define CHAN3 5
 #define CHAN4 6
 #define CHAN5 7
 #else
 #define CHANPIN PINB
 #if defined(__AVR_ATmega32U4__)
 #define CHAN0 SCK
 #define CHAN1 MOSI
 #define CHAN2 MISO
 #define CHAN3 8
 #define CHAN4 9
 #define CHAN5 10
 #define CHAN6 11
 #else
 #define CHAN0 8
 #define CHAN1 9
 #define CHAN2 10
 #define CHAN3 11
 #define CHAN4 12
-/* Comment out CHAN5 if you don't want to use the LED pin for an input */
+//#define CHAN5 13
 #define CHAN5 13
 #endif /* AVR_ATmega32U4 */
 #endif /* USE_PORTD */
 #endif /* Mega1280 or Mega2560 */
 #define ledPin 13
 /* XON/XOFF are not supported. */
@@ -152,48 +102,24 @@ void debugdump(void);
 #define SUMP_TRIGGER_VALUES 0xC1
 #define SUMP_TRIGGER_CONFIG 0xC2
-/* Most flags (except RLE) are ignored. */
+/* flags are ignored. */
 #define SUMP_SET_DIVIDER 0x80
 #define SUMP_SET_READ_DELAY_COUNT 0x81
 #define SUMP_SET_FLAGS 0x82
 #define SUMP_SET_RLE 0x0100
 /* extended commands -- self-test unsupported, but metadata is returned. */
 #define SUMP_SELF_TEST 0x03
 #define SUMP_GET_METADATA 0x04
-/* ATmega168:  532 (or lower)
+/*
- * ATmega328:  1024 (or lower)
+ * Capture size of 1024 bytes works on the ATmega328.
- * ATmega2560: 7168 (or lower)
+ *
 */
 #if defined(__AVR_ATmega1280__) || defined(__AVR_ATmega2560__)
 #define DEBUG_CAPTURE_SIZE 7168
 #define CAPTURE_SIZE 7168
 #elif defined(__AVR_ATmega32U4__)
 #define DEBUG_CAPTURE_SIZE 1536
 #define CAPTURE_SIZE 1536
 #elif defined(__AVR_ATmega328P__)
 #define DEBUG_CAPTURE_SIZE 1024
 #define CAPTURE_SIZE 1024
 #else
 #define DEBUG_CAPTURE_SIZE 532
 #define CAPTURE_SIZE 532
 #endif
 #ifdef USE_PORTD
 #define DEBUG_ENABLE DDRB = DDRB | B00000001
 #define DEBUG_ON PORTB = B00000001
 #define DEBUG_OFF PORTB = B00000000
 #else
 #define DEBUG_ENABLE DDRD = DDRD | B10000000
 #define DEBUG_ON PORTD = B10000000
 #define DEBUG_OFF PORTD = B00000000
 #endif
 #define DEBUG
 #ifdef DEBUG
-#define MAX_CAPTURE_SIZE DEBUG_CAPTURE_SIZE
+#define MAX_CAPTURE_SIZE 1024
 #else
-#define MAX_CAPTURE_SIZE CAPTURE_SIZE
+#define MAX_CAPTURE_SIZE 1024
 #endif /* DEBUG */
 /*
@@ -218,23 +144,18 @@ unsigned int trigger_values = 0;
 unsigned int useMicro = 0;
 unsigned int delayTime = 0;
 unsigned long divider = 0;
 boolean rleEnabled = 0;
 void setup()
 {
  Serial.begin(115200);
  while (!Serial) {
    ; // wait for serial port to connect. Needed for Leonardo only
  }
  /*
-   * set debug pin (digital pin 8) to output right away so it settles.
+   * set debug pin to output right away so it settles.
   * this gets toggled during sampling as a way to measure
   * the sample time.  this is used during development to
   * properly pad out the sampling routines.
   */
-  DEBUG_ENABLE; /* debug measurement pin */
+  DDRD = DDRD | B10000000; /* debug measurement pin */
  pinMode(CHAN0, INPUT);
  pinMode(CHAN1, INPUT);
@@ -243,41 +164,9 @@ void setup()
  pinMode(CHAN4, INPUT);
 #ifdef CHAN5
  pinMode(CHAN5, INPUT);
-#endif
+#else
 #ifdef CHAN6
  pinMode(CHAN6, INPUT);
 #endif
 #ifdef CHAN7
  pinMode(CHAN7, INPUT);
 #endif
 #ifndef CHAN5
  pinMode(ledPin, OUTPUT);
-#endif
+#endif /* CHAN5 */
 #if 0
  /*
   * This sets up timer2 at 100KHz to toggle a pin.  This is useful
   * for debugging as it gives an internally precise signal source.
   * This doesn't work on the Arduino Mega.  Use on the Uno or older.
   * We're using the same clock source for the timer & our sampling.
   */
  /* Set OC2A (digital pin 11) to output so we can toggle it. */
  pinMode(11, OUTPUT);
  /* reset timer to zero */
  TCNT2 = 0;
  TCCR2A = 0;
  TCCR2B = 0;
  OCR2A = 0;
  /* Set CTC mode and toggle on compare. */
  TCCR2A = _BV (COM2A0) | _BV (WGM21);
  /* 79 = 100KHz, 15 = 500KHz, 7 = 1MHz */
  OCR2A = 79;
  TCCR2B = _BV (CS20);
 #endif
 }
 void loop()
@@ -296,10 +185,10 @@ void loop()
      break;
    case SUMP_QUERY:
      /* return the expected bytes. */
-      Serial.write('1');
+      Serial.print('1', BYTE);
-      Serial.write('A');
+      Serial.print('A', BYTE);
-      Serial.write('L');
+      Serial.print('L', BYTE);
-      Serial.write('S');
+      Serial.print('S', BYTE);
      break;
    case SUMP_ARM:
      /*
@@ -315,18 +204,7 @@ void loop()
       * so in that case (delayTime == 1 and triggers enabled) use
       * captureMicro() instead of triggerMicro().
       */
-
+      if (useMicro) {
      if (divider == 24) {
        /* 4.0MHz */
        captureInline4mhz();
      } 
      else if (divider == 49) {
        /* 2.0MHz */
 #if defined(__AVR_ATmega168P__)
        captureInline2mhz();
 #endif
      } 
      else if (useMicro) {
        if (trigger && (delayTime != 1)) {
          triggerMicro();
        } 
@@ -344,11 +222,7 @@ void loop()
       * we can just use it directly as our trigger mask.
       */
      getCmd();
 #ifdef SHIFTBITS
      trigger = cmdBytes[0] << SHIFTBITS;
 #else
      trigger = cmdBytes[0];
 #endif
      break;
    case SUMP_TRIGGER_VALUES:
      /*
@@ -356,11 +230,7 @@ void loop()
       * defines whether we're looking for it to be high or low.
       */
      getCmd();
 #ifdef SHIFTBITS
      trigger_values = cmdBytes[0] << SHIFTBITS;
 #else
      trigger_values = cmdBytes[0];
 #endif
      break;
    case SUMP_TRIGGER_CONFIG:
      /* read the rest of the command bytes, but ignore them. */
@@ -399,9 +269,8 @@ void loop()
        delayCount = MAX_CAPTURE_SIZE;
      break;
    case SUMP_SET_FLAGS:
-      /* read the rest of the command bytes and check if RLE is enabled. */
+      /* read the rest of the command bytes, but ignore them. */
      getCmd();
      rleEnabled = ((cmdBytes[1] & B1000000) != 0);
      break;
    case SUMP_GET_METADATA:
      /*
@@ -434,7 +303,9 @@ void loop()
       * you can use the Arduino serial monitor and send a '1' and get
       * a debug printout.  useless except for development.
       */
 #ifndef CHAN5
      blinkled();
 #endif /* !CHAN5 */
      debugprint();
      break;
    case '2':
@@ -451,12 +322,14 @@ void loop()
  }
 }
 #ifndef CHAN5
 void blinkled() {
  digitalWrite(ledPin, HIGH);
  delay(200);
  digitalWrite(ledPin, LOW);
  delay(200);
 }
 #endif /* !CHAN5 */
 /*
 * Extended SUMP commands are 5 bytes.  A command byte followed by 4 bytes
@@ -500,14 +373,14 @@ void getCmd() {
 */
 void captureMicro() {
-  unsigned int i;
+  int i;
  /*
-   * basic trigger, wait until all trigger conditions are met on port.
+   * basic trigger, wait until all trigger conditions are met on port B.
   * this needs further testing, but basic tests work as expected.
   */
  if (trigger) {
-    while ((trigger_values ^ CHANPIN) & trigger);
+    while ((trigger_values ^ PINB) & trigger);
  }
  /*
@@ -522,41 +395,39 @@ void captureMicro() {
   * this is used during development to measure the sample intervals.
   * it is best to just leave the toggling in place so we don't alter
   * any timing unexpectedly.
-   * Arduino digital pin 8 is being used here.
+   * Arduino pin 7 is being used here.
   */
-  DEBUG_ENABLE;
+  DDRD = DDRD | B10000000;
-#ifdef DEBUG
+  PORTD = B10000000;
  DEBUG_ON;
  delayMicroseconds(20);
-  DEBUG_OFF;
+  PORTD = B00000000;
  delayMicroseconds(20);
-  DEBUG_ON;
+  PORTD = B10000000;
  delayMicroseconds(20);
-  DEBUG_OFF;
+  PORTD = B00000000;
  delayMicroseconds(20);
 #endif
  if (delayTime == 1) {
    /*
     * 1MHz sample rate = 1 uS delay so we can't use delayMicroseconds
     * since our loop takes some time.  The delay is padded out by hand.
     */
-    DEBUG_ON; /* debug timing measurement */
+    PORTD = B10000000; /* debug timing measurement */
    for (i = 0 ; i < readCount; i++) {
-      logicdata[i] = CHANPIN;
+      logicdata[i] = PINB;
      __asm__("nop\n\t""nop\n\t""nop\n\t""nop\n\t""nop\n\t");
      __asm__("nop\n\t""nop\n\t""nop\n\t""nop\n\t");
    }
-    DEBUG_OFF; /* debug timing measurement */
+    PORTD = B00000000; /* debug timing measurement */
  } 
  else if (delayTime == 2) {
    /*
     * 500KHz sample rate = 2 uS delay, still pretty fast so we pad this
     * one by hand too.
     */
-    DEBUG_ON; /* debug timing measurement */
+    PORTD = B10000000; /* debug timing measurement */
    for (i = 0 ; i < readCount; i++) {
-      logicdata[i] = CHANPIN;
+      logicdata[i] = PINB;
      __asm__("nop\n\t""nop\n\t""nop\n\t""nop\n\t");
      __asm__("nop\n\t""nop\n\t""nop\n\t""nop\n\t");
      __asm__("nop\n\t""nop\n\t""nop\n\t""nop\n\t");
@@ -564,7 +435,7 @@ void captureMicro() {
      __asm__("nop\n\t""nop\n\t""nop\n\t""nop\n\t");
      __asm__("nop\n\t""nop\n\t""nop\n\t""nop\n\t");
    }
-    DEBUG_OFF; /* debug timing measurement */
+    PORTD = B00000000; /* debug timing measurement */
  } 
  else {
    /*
@@ -573,13 +444,13 @@ void captureMicro() {
     * a better logic analyzer)
     * start of real measurement
     */
-    DEBUG_ON; /* debug timing measurement */
+    PORTD = B10000000; /* debug timing measurement */
    for (i = 0 ; i < readCount; i++) {
-      logicdata[i] = CHANPIN;
+      logicdata[i] = PINB;
      delayMicroseconds(delayTime - 1);
      __asm__("nop\n\t""nop\n\t");
    }
-    DEBUG_OFF; /* debug timing measurement */
+    PORTD = B00000000; /* debug timing measurement */
  }
  /* re-enable interrupts now that we're done sampling. */
@@ -590,11 +461,7 @@ void captureMicro() {
   * is done for any triggers, this is effectively the 0/100 buffer split.
   */
  for (i = 0 ; i < readCount; i++) {
-#ifdef SHIFTBITS
+    Serial.print(logicdata[i], BYTE);
    Serial.write(logicdata[i] >> SHIFTBITS);
 #else
    Serial.write(logicdata[i]);
 #endif
  }
 }
@@ -616,60 +483,21 @@ void captureMicro() {
 * this basic functionality.
 */
 void captureMilli() {
-  unsigned int i = 0;
+  int i;
-  if(rleEnabled) {
+  /*
-    /*
+   * very basic trigger, just like in captureMicros() above.
-     * very basic trigger, just like in captureMicros() above.
+   */
-     */
+  if (trigger) {
-    if (trigger) {
+    while ((trigger_values ^ PINB) & trigger);
-      while ((trigger_values ^ (CHANPIN & B01111111)) & trigger);
+  }
    }
-    byte lastSample = 0;
+  for (i = 0 ; i < readCount; i++) {
-    byte sampleCount = 0;
+    logicdata[i] = PINB;
-
+    delay(delayTime);
    while(i < readCount) {
      /*
       * Implementation of the RLE unlimited protocol: timings might be off a little
       */
      if(lastSample == (CHANPIN & B01111111) && sampleCount < 127) {
        sampleCount++;
        delay(delayTime);
        continue;
      }
      if(sampleCount != 0) {
        logicdata[i] = B10000000 | sampleCount;
        sampleCount = 0;
        i++;
        continue;
      }
      logicdata[i] = (CHANPIN & B01111111);
      lastSample = (CHANPIN & B01111111);
      delay(delayTime);
      i++;
    }
  } 
  else {
    /*
     * very basic trigger, just like in captureMicros() above.
     */
    if (trigger) {
      while ((trigger_values ^ CHANPIN) & trigger);
    }
    for (i = 0 ; i < readCount; i++) {
      logicdata[i] = CHANPIN;
      delay(delayTime);
    }
  }
  for (i = 0 ; i < readCount; i++) {
-#ifdef SHIFTBITS
+    Serial.print(logicdata[i], BYTE);
    Serial.write(logicdata[i] >> SHIFTBITS);
 #else
    Serial.write(logicdata[i]);
 #endif
  }
 }
@@ -682,7 +510,7 @@ void captureMilli() {
 * 
 */
 void triggerMicro() {
-  unsigned int i = 0;
+  int i = 0;
  logicIndex = 0;
  triggerIndex = 0;
@@ -699,19 +527,17 @@ void triggerMicro() {
   * this is used during development to measure the sample intervals.
   * it is best to just leave the toggling in place so we don't alter
   * any timing unexpectedly.
-   * Arduino digital pin 8 is being used here.
+   * Arduino pin 7 is being used here.
   */
-  DEBUG_ENABLE;
+  DDRD = DDRD | B10000000;
-#ifdef DEBUG
+  PORTD = B10000000;
  DEBUG_ON;
  delayMicroseconds(20);
-  DEBUG_OFF;
+  PORTD = B00000000;
  delayMicroseconds(20);
-  DEBUG_ON;
+  PORTD = B10000000;
  delayMicroseconds(20);
-  DEBUG_OFF;
+  PORTD = B00000000;
  delayMicroseconds(20);
 #endif
  if (delayTime == 1) {
    /*
@@ -731,13 +557,13 @@ void triggerMicro() {
    /*
     * 500KHz case.  We should be able to manage this in time.
     *
-     * busy loop reading CHANPIN until we trigger.
+     * busy loop reading PINB until we trigger.
     * we always start capturing at the start of the buffer
     * and use it as a circular buffer
     */
-    DEBUG_ON; /* debug timing measurement */
+    PORTD = B10000000; /* debug timing measurement */
-    while ((trigger_values ^ (logicdata[logicIndex] = CHANPIN)) & trigger) {
+    while ((trigger_values ^ (logicdata[logicIndex] = PINB)) & trigger) {
-      /* DEBUG_OFF; */
+      /* PORTD = B00000000; */
      /* increment index. */
      logicIndex++;
      if (logicIndex >= readCount) {
@@ -749,11 +575,11 @@ void triggerMicro() {
       * __asm__("nop\n\t""nop\n\t""nop\n\t");
       */
      __asm__("nop\n\t");
-      /* DEBUG_ON; */
+      /* PORTD = B10000000; */
    }
    /* this pads the immediate trigger case to 2.0 uS, just as an example. */
    __asm__("nop\n\t""nop\n\t""nop\n\t""nop\n\t");
-    DEBUG_OFF; /* debug timing measurement */
+    PORTD = B00000000; /* debug timing measurement */
    /* 
     * One sample size delay. ends up being 2 uS combined with assignment
@@ -768,7 +594,7 @@ void triggerMicro() {
    triggerIndex = logicIndex;
    /* keep sampling for delayCount after trigger */
-    DEBUG_ON; /* debug timing measurement */
+    PORTD = B10000000; /* debug timing measurement */
    /*
     * this is currently taking:
     * 1025.5 uS for 512 samples. (512 samples, 0/100 split)
@@ -778,12 +604,12 @@ void triggerMicro() {
      if (logicIndex >= readCount) {
        logicIndex = 0;
      }
-      logicdata[logicIndex++] = CHANPIN;
+      logicdata[logicIndex++] = PINB;
      __asm__("nop\n\t""nop\n\t""nop\n\t""nop\n\t""nop\n\t");
      __asm__("nop\n\t""nop\n\t""nop\n\t""nop\n\t""nop\n\t");
      __asm__("nop\n\t""nop\n\t""nop\n\t""nop\n\t");
    }
-    DEBUG_OFF; /* debug timing measurement */
+    PORTD = B00000000; /* debug timing measurement */
    delayMicroseconds(100);
  } 
  else {
@@ -791,28 +617,22 @@ void triggerMicro() {
     * Less than 500KHz case.  This uses delayMicroseconds() and some padding
     * to get precise timing, at least for the after trigger samples.
     *
-     * busy loop reading CHANPIN until we trigger.
+     * busy loop reading PINB until we trigger.
     * we always start capturing at the start of the buffer
     * and use it as a circular buffer
     *
     */
-    DEBUG_ON; /* debug timing measurement */
+    PORTD = B10000000; /* debug timing measurement */
-    while ((trigger_values ^ (logicdata[logicIndex] = CHANPIN)) & trigger) {
+    while ((trigger_values ^ (logicdata[logicIndex] = PINB)) & trigger) {
-      /* DEBUG_OFF; */
+      /* PORTD = B00000000; */
      /* increment index. */
      logicIndex++;
      if (logicIndex >= readCount) {
        logicIndex = 0;
      }
-      else {
+      /* PORTD = B10000000; */
        /* pad the same number of cycles as the above assignment (needs verification) */
        __asm__("nop\n\t""nop\n\t""nop\n\t""nop\n\t");
      }
      delayMicroseconds(delayTime - 3);
      __asm__("nop\n\t""nop\n\t""nop\n\t""nop\n\t""nop\n\t");
      /* DEBUG_ON; */
    }
-    DEBUG_OFF; /* debug timing measurement */
+    PORTD = B00000000; /* debug timing measurement */
    /* 'logicIndex' now points to trigger sample, keep track of it */
    triggerIndex = logicIndex;
@@ -821,24 +641,21 @@ void triggerMicro() {
     * This needs adjustment so that we have the right spacing between the
     * before trigger samples and the after trigger samples.
     */
-    delayMicroseconds(delayTime - 2);
+    delayMicroseconds(delayTime);
    __asm__("nop\n\t""nop\n\t""nop\n\t""nop\n\t");
    __asm__("nop\n\t""nop\n\t""nop\n\t""nop\n\t");
    __asm__("nop\n\t""nop\n\t""nop\n\t");
    /* keep sampling for delayCount after trigger */
-    DEBUG_ON; /* debug timing measurement */
+    PORTD = B10000000; /* debug timing measurement */
    for (i = 0 ; i < delayCount; i++) {
      if (logicIndex >= readCount) {
        logicIndex = 0;
      }
-      logicdata[logicIndex++] = CHANPIN;
+      logicdata[logicIndex++] = PINB;
      delayMicroseconds(delayTime - 3);
      __asm__("nop\n\t""nop\n\t""nop\n\t""nop\n\t");
      __asm__("nop\n\t""nop\n\t""nop\n\t""nop\n\t");
      __asm__("nop\n\t""nop\n\t""nop\n\t");
    }
-    DEBUG_OFF; /* debug timing measurement */
+    PORTD = B00000000; /* debug timing measurement */
    delayMicroseconds(100);
  }
@@ -859,11 +676,7 @@ void triggerMicro() {
    if (logicIndex >= readCount) {
      logicIndex = 0;
    }
-#ifdef SHIFTBITS
+    Serial.print(logicdata[logicIndex++], BYTE);
    Serial.write(logicdata[logicIndex++] >> SHIFTBITS);
 #else
    Serial.write(logicdata[logicIndex++]);
 #endif
  }
 }
@@ -899,75 +712,43 @@ void setupDelay() {
 */
 void get_metadata() {
  /* device name */
-  Serial.write((uint8_t)0x01);
+  Serial.print(0x01, BYTE);
-  Serial.write('A');
+  Serial.print('A', BYTE);
-  Serial.write('G');
+  Serial.print('G', BYTE);
-  Serial.write('L');
+  Serial.print('L', BYTE);
-  Serial.write('A');
+  Serial.print('A', BYTE);
-#if defined(__AVR_ATmega1280__) || defined(__AVR_ATmega2560__)
+  Serial.print('v', BYTE);
-  Serial.write('M');
+  Serial.print('0', BYTE);
-#elif defined(__AVR_ATmega32U4__)
+  Serial.print(0x00, BYTE);
  Serial.write('L');
 #endif /* Mega */
  Serial.write('v');
  Serial.write('0');
  Serial.write((uint8_t)0x00);
-  /* firmware version */
+  /* sample memory (1024) */
-  Serial.write((uint8_t)0x02);
+  Serial.print(0x21, BYTE);
-  Serial.write('0');
+  Serial.print(0x00, BYTE);
-  Serial.write('.');
+  Serial.print(0x00, BYTE);
-  Serial.write('1');
+  Serial.print(0x04, BYTE);
-  Serial.write('2');
+  Serial.print(0x00, BYTE);
  Serial.write((uint8_t)0x00);
-  /* sample memory */
+  /* sample rate (1MHz) */
-  Serial.write((uint8_t)0x21);
+  Serial.print(0x23, BYTE);
-  Serial.write((uint8_t)0x00);
+  Serial.print(0x00, BYTE);
-  Serial.write((uint8_t)0x00);
+  Serial.print(0x0F, BYTE);
-#if defined(__AVR_ATmega1280__) || defined(__AVR_ATmega2560__)
+  Serial.print(0x42, BYTE);
-  /* 7168 bytes */
+  Serial.print(0x40, BYTE);
-  Serial.write((uint8_t)0x1C);
+
-  Serial.write((uint8_t)0x00);
+  /* number of probes (5 by default) */
-#elif defined(__AVR_ATmega32U4__)
+  Serial.print(0x40, BYTE);
-  /* 1024 bytes */
+#ifdef CHAN5
-  Serial.write((uint8_t)0x04);
+  Serial.print(0x06, BYTE);
  Serial.write((uint8_t)0x00);
 #elif defined(__AVR_ATmega328P__)
  /* 1024 bytes */
  Serial.write((uint8_t)0x04);
  Serial.write((uint8_t)0x00);
 #else
-  /* 532 bytes */
+  Serial.print(0x05, BYTE);
-  Serial.write((uint8_t)0x02);
+#endif /* CHAN5 */
  Serial.write((uint8_t)0x14);
 #endif /* Mega */
  /* sample rate (4MHz) */
  Serial.write((uint8_t)0x23);
  Serial.write((uint8_t)0x00);
  Serial.write((uint8_t)0x3D);
  Serial.write((uint8_t)0x09);
  Serial.write((uint8_t)0x00);
  /* number of probes (6 by default on Arduino, 8 on Mega) */
  Serial.write((uint8_t)0x40);
 #ifdef CHAN7
  Serial.write((uint8_t)0x08);
 #elif CHAN6
  Serial.write((uint8_t)0x07);
 #elif CHAN5
  Serial.write((uint8_t)0x06);
 #else
  Serial.write((uint8_t)0x05);
 #endif
  /* protocol version (2) */
-  Serial.write((uint8_t)0x41);
+  Serial.print(0x41, BYTE);
-  Serial.write((uint8_t)0x02);
+  Serial.print(0x02, BYTE);
  /* end of data */
-  Serial.write((uint8_t)0x00);  
+  Serial.print(0x00, BYTE);  
 }
 /*
@@ -995,8 +776,6 @@ void debugprint() {
  Serial.println(logicIndex, DEC);
  Serial.print("triggerIndex = ");
  Serial.println(triggerIndex, DEC);
  Serial.print("rleEnabled = ");
  Serial.println(rleEnabled, DEC);
  Serial.println("Bytes:");
@@ -1006,7 +785,7 @@ void debugprint() {
    } 
    else {
      Serial.print(savebytes[i], HEX);
-      Serial.write(' ');
+      Serial.print(' ', BYTE);
    }
  }
  Serial.println("done...");
@@ -1023,11 +802,7 @@ void debugdump() {
  Serial.print("\r\n");
  for (i = 0 ; i < MAX_CAPTURE_SIZE; i++) {
 #ifdef SHIFTBITS
    Serial.print(logicdata[i] >> SHIFTBITS, HEX);
 #else
    Serial.print(logicdata[i], HEX);
 #endif
    Serial.print(" ");
    if (j == 32) {
      Serial.print("\r\n");
@@ -1039,14 +814,3 @@ void debugdump() {
 #endif /* DEBUG */
--- a/logic_analyzer_inline_2mhz.ino
+++ b/logic_analyzer_inline_2mhz.ino
--- a/logic_analyzer_inline_4mhz.ino
+++ b/logic_analyzer_inline_4mhz.ino
--- a/ols.profile-agla.cfg
+++ b/ols.profile-agla.cfg
@@ -7,11 +7,11 @@ device.description = Arduino Generic Logic Analyzer
 # The device interface, SERIAL only
 device.interface = SERIAL
 # The device's native clockspeed, in Hertz.
-device.clockspeed = 16000000
+device.clockspeed = 100000000
 # Whether or not double-data-rate is supported by the device (also known as the "demux"-mode).
 device.supports_ddr = false
 # Supported sample rates in Hertz, separated by comma's
-device.samplerates = 10, 20, 50, 100, 200, 500, 1000, 2000, 5000, 10000, 20000, 50000, 100000, 200000, 500000, 1000000, 2000000, 4000000
+device.samplerates = 10, 20, 50, 100, 200, 500, 1000, 2000, 5000, 10000, 20000, 50000, 100000, 200000, 500000, 1000000
 # What capture clocks are supported
 device.captureclock = INTERNAL
 # The supported capture sizes, in bytes
@@ -19,7 +19,7 @@ device.capturesizes = 64, 128, 256, 512, 1024
 # Whether or not the noise filter is supported
 device.feature.noisefilter = false
 # Whether or not Run-Length encoding is supported
-device.feature.rle = true
+device.feature.rle = false
 # Whether or not a testing mode is supported
 device.feature.testmode = false
 # Whether or not triggers are supported
@@ -30,7 +30,7 @@ device.trigger.stages = 1
 device.trigger.complex = false
 # The total number of channels usable for capturing
-device.channel.count = 6
+device.channel.count = 5
 # The number of channels groups, together with the channel count determines the channels per group
 device.channel.groups = 1
 # Whether the capture size is limited by the enabled channel groups
@@ -39,15 +39,13 @@ device.capturesize.bound = false
 device.channel.numberingschemes = DEFAULT
 # Is a delay after opening the port and device detection needed? (0 = no delay, >0 = delay in milliseconds)
-device.open.portdelay = 2000
+device.open.portdelay = 500
 # The receive timeout for the device (in milliseconds, 100 = default, <=0 = no timeout)
 device.receive.timeout = 100
 # Does the device need a high or low DTR-line to operate correctly? (high = true, low = false)
 device.open.portdtr = true
 # Which metadata keys correspond to this device profile? Value is a comma-separated list of (double quoted) names...
 device.metadata.keys = "AGLAv0"
-# In which order are samples sent back from the device? false = last sample first, true = first sample first
+# In which order are samples sent back from the device? true = last sample first, false = first sample first
-device.samples.reverseOrder = true
+device.samples.reverseOrder = false
 ###EOF###
--- a/ols.profile-aglam.cfg
+++ b/ols.profile-aglam.cfg
@@ -1,53 +0,0 @@
 # Configuration for Arduino Mega Logic Analyzer profile
 # The short (single word) type of the device described in this profile
 device.type = AGLAM
 # A longer description of the device
 device.description = Arduino Mega Logic Analyzer
 # The device interface, SERIAL only
 device.interface = SERIAL
 # The device's native clockspeed, in Hertz.
 device.clockspeed = 16000000
 # Whether or not double-data-rate is supported by the device (also known as the "demux"-mode).
 device.supports_ddr = false
 # Supported sample rates in Hertz, separated by comma's
 device.samplerates = 10, 20, 50, 100, 200, 500, 1000, 2000, 5000, 10000, 20000, 50000, 100000, 200000, 500000, 1000000, 2000000, 4000000
 # What capture clocks are supported
 device.captureclock = INTERNAL
 # The supported capture sizes, in bytes
 device.capturesizes = 64, 128, 256, 512, 1024, 2048, 4096, 7168
 # Whether or not the noise filter is supported
 device.feature.noisefilter = false
 # Whether or not Run-Length encoding is supported
 device.feature.rle = false
 # Whether or not a testing mode is supported
 device.feature.testmode = false
 # Whether or not triggers are supported
 device.feature.triggers = true
 # The number of trigger stages
 device.trigger.stages = 1
 # Whether or not "complex" triggers are supported
 device.trigger.complex = false
 # The total number of channels usable for capturing
 device.channel.count = 8
 # The number of channels groups, together with the channel count determines the channels per group
 device.channel.groups = 1
 # Whether the capture size is limited by the enabled channel groups
 device.capturesize.bound = false
 # Which numbering does the device support
 device.channel.numberingschemes = DEFAULT
 # Is a delay after opening the port and device detection needed? (0 = no delay, >0 = delay in milliseconds)
 device.open.portdelay = 2000
 # The receive timeout for the device (in milliseconds, 100 = default, <=0 = no timeout)
 device.receive.timeout = 100
 # Does the device need a high or low DTR-line to operate correctly? (high = true, low = false)
 device.open.portdtr = true
 # Which metadata keys correspond to this device profile? Value is a comma-separated list of (double quoted) names...
 device.metadata.keys = "AGLAMv0"
 # In which order are samples sent back from the device? false = last sample first, true = first sample first
 device.samples.reverseOrder = true
 ###EOF###