mac-rom-simm-programmer/tests/simm_electrical_test.c
Doug Brown 8b1cd63210 Change license to GPLv3
I can't use GPLv2 as soon as I need to start using the Nuvoton sample
code which is licensed with an Apache 2.0 license.
2023-09-10 05:02:44 -07:00

473 lines
13 KiB
C

/*
* simm_electrical_test.c
*
* Created on: Nov 26, 2011
* Author: Doug
*
* Copyright (C) 2011-2023 Doug Brown
*
* 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 3 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, see <https://www.gnu.org/licenses/>.
*
*/
#include "simm_electrical_test.h"
#include "../hal/parallel_bus.h"
#include "hardware.h"
/// The index of the highest SIMM address pin
#define SIMM_HIGHEST_ADDRESS_LINE 20
/// Mask that represents every SIMM address pin
#define SIMM_ADDRESS_PINS_MASK ((1UL << (SIMM_HIGHEST_ADDRESS_LINE + 1)) - 1)
/// The index of the highest SIMM data pin
#define SIMM_HIGHEST_DATA_LINE 31
/// Mask that represents every SIMM data pin
#define SIMM_DATA_PINS_MASK 0xFFFFFFFFUL
/// Milliseconds to wait before testing for shorts
#define DELAY_SETTLE_TIME_MS 20
/// The index reported as a short when it's a ground short
#define GROUND_FAIL_INDEX 0xFF
/// The index reported when A0 is shorted
#define FIRST_ADDRESS_LINE_FAIL_INDEX 0
/// The index reported when A20 is shorted
#define LAST_ADDRESS_LINE_FAIL_INDEX (FIRST_ADDRESS_LINE_FAIL_INDEX + SIMM_HIGHEST_ADDRESS_LINE)
/// The index reported when D0 is shorted
#define FIRST_DATA_LINE_FAIL_INDEX (LAST_ADDRESS_LINE_FAIL_INDEX + 1)
/// The index reported when D31 is shorted
#define LAST_DATA_LINE_FAIL_INDEX (FIRST_DATA_LINE_FAIL_INDEX + SIMM_HIGHEST_DATA_LINE)
/// The index reported when CS is shorted
#define CS_FAIL_INDEX (LAST_DATA_LINE_FAIL_INDEX + 1)
/// The index reported when OE is shorted
#define OE_FAIL_INDEX (CS_FAIL_INDEX + 1)
/// The index reported when WE is shorted
#define WE_FAIL_INDEX (OE_FAIL_INDEX + 1)
/// Enum representing the step we're on during the electrical test
typedef enum ElectricalTestStage
{
TestingAddressLines,//!< We are testing an address pin
TestingDataLines, //!< We are testing a data pin
TestingCS, //!< We are testing the CS pin
TestingOE, //!< We are testing the OE pin
TestingWE, //!< We are testing the WE pin
DoneTesting //!< We completed the test
} ElectricalTestStage;
static void SIMMElectricalTest_ResetGroundShorts(void);
static void SIMMElectricalTest_AddGroundShort(uint8_t index);
static bool SIMMElectricalTest_IsGroundShort(uint8_t index);
/// Pin indexes that were detected as shorted to ground. They have to be saved,
/// because they end up being detected as a short against every other pin,
/// so we have to be able to filter them out when testing non-ground shorts.
static uint32_t groundShorts[2];
/** Runs the electrical test
*
* @param errorHandler Pointer to function to call when a short is detected.
* @return The number of errors we found
*
* The two parameters to errorHandler are the two indexes that are shorted.
* (See the _FAIL_INDEX defines at the top of this file)
*/
int SIMMElectricalTest_Run(void (*errorHandler)(uint8_t, uint8_t))
{
// Returns number of errors found
int numErrors = 0;
// Reset the pins we have determined that are shorted to ground
// (We have to ignore them during the second phase of the test)
SIMMElectricalTest_ResetGroundShorts();
// First check for anything shorted to ground. Set all lines as inputs with
// a weak pull-up resistor. Then read the values back and check for any
// zeros. This would indicate a short to ground.
ParallelBus_SetAddressDir(0);
ParallelBus_SetDataDir(0);
ParallelBus_SetCSDir(false);
ParallelBus_SetOEDir(false);
ParallelBus_SetWEDir(false);
ParallelBus_SetAddressPullups(SIMM_ADDRESS_PINS_MASK);
ParallelBus_SetDataPullups(SIMM_DATA_PINS_MASK);
ParallelBus_SetCSPullup(true);
ParallelBus_SetOEPullup(true);
ParallelBus_SetWEPullup(true);
// Wait a brief moment...
DelayMS(DELAY_SETTLE_TIME_MS);
// Now loop through every pin and check it.
uint8_t curPin = 0;
uint8_t i;
// Read the address pins back first
uint32_t readback = ParallelBus_ReadAddress();
// Check each bit for a LOW which would indicate a short to ground
for (i = 0; i <= SIMM_HIGHEST_ADDRESS_LINE; i++)
{
// Did we find a low bit?
if (!(readback & 1))
{
// That means this pin is shorted to ground.
// So notify the caller that we have a ground short on this pin
if (errorHandler)
{
errorHandler(curPin, GROUND_FAIL_INDEX);
}
// Add it to our internal list of ground shorts also.
SIMMElectricalTest_AddGroundShort(curPin);
// And of course increment the error counter.
numErrors++;
}
// No matter what, though, move on to the next bit and pin.
readback >>= 1;
curPin++;
}
// Repeat the exact same process for the data pins
readback = ParallelBus_ReadData();
for (i = 0; i <= SIMM_HIGHEST_DATA_LINE; i++)
{
if (!(readback & 1))
{
if (errorHandler)
{
errorHandler(curPin, GROUND_FAIL_INDEX);
}
SIMMElectricalTest_AddGroundShort(curPin);
numErrors++;
}
readback >>= 1;
curPin++;
}
// Check chip select in the same way...
if (!ParallelBus_ReadCS())
{
if (errorHandler)
{
errorHandler(curPin, GROUND_FAIL_INDEX);
}
SIMMElectricalTest_AddGroundShort(curPin);
numErrors++;
}
curPin++;
// Output enable...
if (!ParallelBus_ReadOE())
{
if (errorHandler)
{
errorHandler(curPin, GROUND_FAIL_INDEX);
}
SIMMElectricalTest_AddGroundShort(curPin);
numErrors++;
}
curPin++;
// Write enable...
if (!ParallelBus_ReadWE())
{
if (errorHandler)
{
errorHandler(curPin, GROUND_FAIL_INDEX);
}
SIMMElectricalTest_AddGroundShort(curPin);
numErrors++;
}
curPin++; // Doesn't need to be here, but for consistency I'm leaving it.
// OK, now we know which lines are shorted to ground. We need to keep that
// in mind, because those lines will now show as shorted to ALL other
// lines...ignore them during tests to find other independent shorts
// Now, check each individual line vs. all other lines on the SIMM for any
// shorts between them
ElectricalTestStage curStage = TestingAddressLines;
// Counter of what address or data pin we're on. Not used for control lines.
uint8_t addrDataPin = 0;
// What pin we are currently testing all other pins against.
uint8_t testPin = 0;
// More explanation: addrDataPin is only a counter inside the address or
// data pins. testPin is a total counter of ALL pins.
while (curStage != DoneTesting)
{
// Set one pin to output a 0.
// Set all other pins as inputs with pull-ups.
// Then read back all the other pins. If any of them read back as 0,
// it means they are shorted to the pin we set as an output.
// If we're testing address lines right now, set the current address
// line as an output (and make it output a LOW). Set all other address
// lines as inputs with pullups.
if (curStage == TestingAddressLines)
{
// Mask of the address pin we're testing
uint32_t addressLineMask = (1UL << addrDataPin);
// Set it as an output and all other address pins as inputs.
ParallelBus_SetAddressDir(addressLineMask);
ParallelBus_SetAddress(0);
ParallelBus_SetAddressPullups(~addressLineMask);
}
else
{
// If not testing an address line, set all address pins as inputs
// with pullups. All the other stages follow the same pattern so I
// won't bother commenting them.
ParallelBus_SetAddressDir(0);
ParallelBus_SetAddressPullups(SIMM_ADDRESS_PINS_MASK);
}
// Do the same thing for data lines...
if (curStage == TestingDataLines)
{
uint32_t dataLineMask = (1UL << addrDataPin);
ParallelBus_SetDataDir(dataLineMask);
ParallelBus_SetData(0);
ParallelBus_SetDataPullups(~dataLineMask);
}
else
{
ParallelBus_SetDataDir(0);
ParallelBus_SetDataPullups(SIMM_DATA_PINS_MASK);
}
// Chip select...
if (curStage == TestingCS)
{
ParallelBus_SetCSDir(true);
ParallelBus_SetCS(false);
}
else
{
ParallelBus_SetCSDir(false);
ParallelBus_SetCSPullup(true);
}
// Output enable...
if (curStage == TestingOE)
{
ParallelBus_SetOEDir(true);
ParallelBus_SetOE(false);
}
else
{
ParallelBus_SetOEDir(false);
ParallelBus_SetOEPullup(true);
}
// And write enable.
if (curStage == TestingWE)
{
ParallelBus_SetWEDir(true);
ParallelBus_SetWE(false);
}
else
{
ParallelBus_SetWEDir(false);
ParallelBus_SetWEPullup(true);
}
// OK, so now we have set up all lines as needed. Exactly one pin is
// outputting a 0, and all other pins are inputs with pull-ups enabled.
// Read back all the lines, and if any pin reads back as 0, it means
// that pin is shorted to the pin we are testing (overpowering its
// pullup). However, because we test each pin against every other pin,
// any short would appear twice. Once as "pin 1 is shorted to pin 2"
// and once as "pin 2 is shorted to pin 1". To avoid that annoyance, I
// only check each combination of two pins once. You'll see below how I
// do this by testing to ensure curPin > testPin.
// Allow everything to settle
DelayMS(DELAY_SETTLE_TIME_MS);
// Now keep a count of how many pins we have actually checked during
// THIS test iteration. This is the "fail index" of the current pin.
curPin = 0;
// Read back the address data to see if any shorts were found
readback = ParallelBus_ReadAddress();
// Count any shorted pins
for (i = 0; i <= SIMM_HIGHEST_ADDRESS_LINE; i++)
{
// Failure here?
if ((curPin > testPin) && // We haven't already checked this combination of pins (don't test pin against itself either)
!(readback & 1) && // It's showing as low (which indicates a short)
!SIMMElectricalTest_IsGroundShort(curPin)) // And it's not recorded as a short to ground
{
// Send it out as an error notification and increase error counter
if (errorHandler)
{
errorHandler(testPin, curPin);
}
numErrors++;
}
// No matter what, move on to the next bit and pin
readback >>= 1;
curPin++;
}
// Same thing for data pins
readback = ParallelBus_ReadData();
// Count any shorted pins
for (i = 0; i <= SIMM_HIGHEST_DATA_LINE; i++)
{
// Failure here?
if ((curPin > testPin) && // We haven't already checked this combination of pins (don't test pin against itself either)
!(readback & 1) && // It's showing as low (which indicates a short)
!SIMMElectricalTest_IsGroundShort(curPin)) // And it's not recorded as a short to ground
{
if (errorHandler)
{
errorHandler(testPin, curPin);
}
numErrors++;
}
readback >>= 1;
curPin++;
}
// And chip select...
if ((curPin > testPin) &&
!ParallelBus_ReadCS() &&
!SIMMElectricalTest_IsGroundShort(curPin))
{
if (errorHandler)
{
errorHandler(testPin, curPin);
}
numErrors++;
}
curPin++;
// Output enable...
if ((curPin > testPin) &&
!ParallelBus_ReadOE() &&
!SIMMElectricalTest_IsGroundShort(curPin))
{
if (errorHandler)
{
errorHandler(testPin, curPin);
}
numErrors++;
}
curPin++;
// And write enable
if ((curPin > testPin) &&
!ParallelBus_ReadWE() &&
!SIMMElectricalTest_IsGroundShort(curPin))
{
if (errorHandler)
{
errorHandler(testPin, curPin);
}
numErrors++;
}
curPin++; // Not needed, kept for consistency
// Finally, move on to the next stage if needed.
if (curStage == TestingAddressLines)
{
// If we've exhausted all address lines, move on to the next stage
// (and reset the pin counter to 0)
if (++addrDataPin > SIMM_HIGHEST_ADDRESS_LINE)
{
curStage++;
addrDataPin = 0;
}
}
else if (curStage == TestingDataLines)
{
// If we've exhausted all data lines, move on to the next stage
// (don't bother resetting the pin counter -- the other stages don't use it)
if (++addrDataPin > SIMM_HIGHEST_DATA_LINE)
{
curStage++;
}
}
else
{
curStage++;
}
// Move on to test the next pin
testPin++;
}
// Restore to a normal state by calling ParallelBus_Init again.
ParallelBus_Init();
// Now that the final state is restored, return the number of errors found
return numErrors;
}
/** Resets our list of pins that are shorted to ground
*
*/
static void SIMMElectricalTest_ResetGroundShorts(void)
{
groundShorts[0] = 0;
groundShorts[1] = 0;
}
/** Adds a pin to the list of ground shorts
*
* @param index The index of the pin in the electrical test
*/
static void SIMMElectricalTest_AddGroundShort(uint8_t index)
{
if (index < 32)
{
groundShorts[0] |= (1UL << index);
}
else if (index < 64)
{
groundShorts[1] |= (1UL << (index - 32));
}
// None are >= 64, no further handling needed
}
/** Determines if a pin has already been saved as a ground short
*
* @param index The index of the pin in the electrical test
* @return True if this pin has been determined as a short to GND, false if not
*/
static bool SIMMElectricalTest_IsGroundShort(uint8_t index)
{
if (index < 32)
{
return ((groundShorts[0] & (1UL << index)) != 0);
}
else if (index < 64)
{
return ((groundShorts[1] & (1UL << (index - 32))) != 0);
}
else
{
return false;
}
}