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|
"""
# TOP2049 Open Source programming suite
#
# Microchip8 common - basic file for 16bit PIC MCU
#
# Copyright (c) 2012 Pavel Stemberk <stemberk@gmail.com>
#
# 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.,
# 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA.
"""
from libtoprammer.chip import *
class Chip_Microchip16_common(Chip):
STAT_BUSY = 0x01
STAT_SDIO = 0x02
PROGCMD_SENDSIXINSTR = 0
PROGCMD_SENDREGOUTINSTR = 1
PROGCMD_ENTERPM = 2
PROGCMD_SEND9SIXINSTR = 3
codeExitResetVector = (0x000000, 0x040200, 0x000000)
codeExitResetVectorSimple = (0x040200, 0x000000)
codeInitializeW7toVISI = (0x207847, 0x000000)
codeResetDeviceInternalPC = (0x040200, 0x000000)
# EEPROM access: default on, if does not exist override it
hasEEPROM = True
eepromStartAddress = 0x7FFE00
# default delays - can be overridden
delayTdis = 0.0001
delayTprog = 0.001
delayCommandDataREGOUT = 0.0000005
delayTera = 0.01
# delayP3 = 0.000000015 # Input Data Hold Time from PGECx rise
delayP3 = 0.00000006 # this is hard-tuned value !
delayP4 = 0.000000040 # Delay between 4-Bit Command Operand and Command Operand
delayP4A = 0.000000040 # Delay between 4-Bit Command Operand and the Next 4-bit command
delayP5 = 0.000000020 # Delay between Last PGCx fall of Command Byte and First PGC rise by Programming Executive
delayP6 = 0.000000100 # Vdd rise setup time to nMCLR rise
delayP7 = 0.025 # Input data Hold Time from nMCLR rise, Vpp fall
delayP11 = 0.0025 # chip Erase Time
delayP13 = 0.00125 # row programming time
delayP16 = 0 # delay between last PGCx fall and nMCLR fall
delayP17 = 0.000000100 # nMCLR fall to Vdd fall
delayP18 = 0.001 # delay between first nMCLR fall and first PGCx rise
delayP19 = 0.001 # delay between last PGC fall for key sequence on PGDx and second nMCLR rise
deviceIDAddr = 0xFF0000
deviceIDLength = 1
deviceIdMapDict = {
0x0d00:"24f04ka201", 0x0d02:"24f04ka200", 0x4b14:"24f16kl402", 0x4b1e:"24f16kl401", 0x4b04:"24f08kl402", 0x4b0e:"24f08kl401",
0x4b00:"24f08kl302", 0x4b0a:"24f08kl301", 0x4b06:"24f08kl201", 0x4b05:"24f08kl200", 0x4b02:"24f04kl101", 0x4b01:"24f04kl100"
}
def getIHexInterpreter(self):
inter = IHexInterpreter()
inter.progmemRanges = [ AddressRange(0, 2 * self.flashPageSize) ]
inter.fuseRanges = [ AddressRange(2 * self.configWordAddr,
2 * self.configWordAddr + 1) ]
return inter
@classmethod
def getSupportFlags(cls):
flags = super(Chip_Microchip16_common, cls).getSupportFlags()
if not cls.hasEEPROM:
flags &= ~(Chip.SUPPORT_EEPROMREAD | \
Chip.SUPPORT_EEPROMWRITE)
return flags
def __init__(self,
chipPackage, chipPinVCC, chipPinsVPP, chipPinGND,
signature,
flashPageSize, flashPages,
eepromPageSize, eepromPages,
fuseBytes
):
Chip.__init__(self,
chipPackage=chipPackage,
chipPinVCC=chipPinVCC,
chipPinsVPP=chipPinsVPP,
chipPinGND=chipPinGND)
self.signature = signature
self.flashPageSize = flashPageSize # Flash page size, in words
self.flashPages = flashPages # Nr of flash pages
self.eepromPageSize = eepromPageSize # EEPROM page size, in bytes
self.eepromPages = eepromPages # Nr of EEPROM pages
self.fuseBytes = fuseBytes # Nr of fuse bytes
self.isInPmMode = False
self.BufferedBytes = 0
self.Image = ""
def enterPM(self, lowVoltageIcspEntry=True):
if self.isInPmMode:
return
"Enter HV programming mode. Vdd first entry mode"
self.applyVCC(False)
self.applyVPP(False)
self.applyGND(False)
self.setPins(0, 0)
self.top.cmdSetVCCVoltage(self.voltageVDD)
self.top.cmdSetVPPVoltage((self.voltageVPP, self.voltageVDD)[lowVoltageIcspEntry])
self.applyGND(True)
self.applyVCC(True)
self.top.hostDelay(self.delayP6)
self.applyVPP(True)
self.setTopProgrammerDelays();
if lowVoltageIcspEntry:
self.top.hostDelay(self.delayP6)
self.applyVPP(False)
self.top.hostDelay(self.delayP18)
self.sendCommand(self.PROGCMD_ENTERPM)
if lowVoltageIcspEntry:
self.top.hostDelay(self.delayP19)
self.applyVPP(True)
self.top.hostDelay(self.delayP7)
self.sendSIX(0x0, True)
self.executeCode(self.codeExitResetVectorSimple)
# self.testPORTA()
self.isInPmMode = True
def checkSignature(self):
signature = self.readSignature()
if signature != self.signature:
msg = "Unexpected device signature. " + \
"Want %02X%02X%02X, but got %02X%02X%02X" % \
(byte2int(self.signature[0]), byte2int(self.signature[1]),
byte2int(self.signature[2]),
byte2int(signature[0]), byte2int(signature[1]),
byte2int(signature[2]))
if self.top.getForceLevel() >= 1:
self.printWarning(msg)
else:
self.throwError(msg)
def old_readSignature(self):
self.progressMeterInit("Reading signature", 0)
self.enterPM()
self.Image = ""
self.BufferedBytes = 0
self.executeCode(self.codeExitResetVector)
self.executeCode(self.getCodeInitializeTBLPAG(self.deviceIDAddr, 6))
self.executeCode(self.codeInitializeW7toVISI)
self.read2words()
self.progressMeterFinish()
return self.top.cmdReadBufferReg(4)
def erase(self):
self.__erase()
def __erase(self, keepEEPROM=False):
def er(NVMCON):
self.executeCode(self.codeExitResetVector)
# Set the NVMCON to erase entire PGM
self.executeCode(self.getCodeSetNVMCON(NVMCON))
# Set the TBLPAG and perform dummy table write to select the erased memory
self.executeCode(self.getCodeInitializeTBLPAG(0, 0))
self.executeCode((0xBB0800, 0x000000, 0x000000))
# Initiate the erase cycle
self.executeCode((0xA8E761, 0x000000, 0x000000))
while self.isWRset():
pass
self.progressMeterInit("Erasing chip", 0)
self.enterPM()
er(0x4064)
if(not keepEEPROM and self.eepromPageSize != 0):
er(0x4050)
self.progressMeterFinish()
self.exitPM()
def readProgmem(self):
def unpackImage():
out = ""
for halfPackAddr in range(0, len(self.Image), 6):
out += self.Image[halfPackAddr:halfPackAddr + 3] + "\0"
out += self.Image[halfPackAddr + 4:halfPackAddr + 6] + self.Image[halfPackAddr + 3] + "\0"
return out
nrWords = self.flashPages * self.flashPageSize
# return self.readSequentialBlock(0x0 , nrWords/2, "Reading Progmem")
# something wrong for packed PM reading below
self.enterPM()
self.progressMeterInit("Reading flash", nrWords / 2)
self.BufferedBytes = 0
self.Image = ""
self.executeCode(self.codeExitResetVector)
self.executeCode(self.getCodeInitializeTBLPAG(0, 6))
self.executeCode(self.codeInitializeW7toVISI)
for wordAddrHalf in range(0, nrWords / 2):
self.executeCode((0xBA0B96, 0x0, 0x0))
self.readREGOUTword()
# Microchip's bug in the documentation
# TBLRDH.B [W6++], [W7++] is correct instead of TBLRDH [W6++], [W7]
self.executeCode((0x0, 0xBADBB6, 0x0, 0x0, 0xBAD3D6, 0x0, 0x0))
self.readREGOUTword()
self.executeCode((0x0, 0xBA0BB6, 0x0, 0x0))
self.readREGOUTword()
self.executeCode(self.codeExitResetVector)
self.progressMeter(wordAddrHalf)
self.progressMeterFinish()
self.flushBufferToImage()
self.exitPM()
# return self.Image
return unpackImage()
def _t_readEEPROM(self):
nrWords = self.eepromPages * self.eepromPageSize
self.enterPM()
self.progressMeterInit("Reading EEPROM", nrWords)
self.BufferedBytes = 0
self.Image = ""
self.executeCode(self.codeExitResetVector)
self.executeCode(self.getCodeInitializeTBLPAG(0x7F0000 | 0, 6))
self.executeCode((0x207847, 0x0))
for wordAddr in range(0, nrWords):
self.executeCode((0xBA0B96, 0x0, 0x0))
self.readREGOUTword()
self.executeCode(self.codeExitResetVector)
self.progressMeter(wordAddr)
self.progressMeterFinish()
self.flushBufferToImage()
return self.Image
def readEEPROM(self):
nrWords = self.eepromPages * self.eepromPageSize
return self.readSequentialBlock(self.eepromStartAddress , nrWords, "Reading EEPROM")
def readFuse(self):
return self.readSequentialBlock(self.configWordAddr, self.fuseBytes / 2, "Reading Config Words")
6402
def tmp_readSignature(self):
self.enterPM()
self.executeCode(self.codeExitResetVector)
self.executeCode((0x200FF0, 0x880190, 0x200006, 0x0, 0x0, 0x207847, 0x0, 0xBA0BB6, 0x0, 0x0, 0x0))
self.Image = ""
self.readREGOUTword()
self.executeCode(self.codeExitResetVector)
self.flushBufferToImage()
signature = self.top.cmdReadBufferReg()[0:2]
devId = (byte2int(signature[1]) << 8) | byte2int(signature[0])
if(devId in self.deviceIdMapDict):
print("device: {:s}".format(self.deviceIdMapDict.get(devId)))
else:
print("WARNING: device id {:o} not found in local dictionary".format(devId))
return self.Image
def readSignature(self):
signature = self.readSequentialBlock(self.deviceIDAddr, self.deviceIDLength, "Reading Signature")
devId = (byte2int(signature[1]) << 8) | byte2int(signature[0])
if(devId in self.deviceIdMapDict):
print("device: {:s}".format(self.deviceIdMapDict.get(devId)))
else:
print("WARNING: device id {:x} not found in local dictionary".format(devId))
return signature
def testPORTA(self):
self.executeCode((0x0, 0x23CFF4, 0x881644, 0x0, 0xEB8200, 0x881654, 0x0, 0x0))
def readSequentialBlock(self, startAddr, nWords, infoText):
self.enterPM()
self.progressMeterInit(infoText, nWords)
self.BufferedBytes = 0
self.Image = ""
self.executeCode(self.codeExitResetVector)
self.executeCode(self.getCodeInitializeTBLPAG(startAddr, 6))
self.executeCode(self.codeInitializeW7toVISI)
for wordAddr in range(0, nWords):
# print "wAddr:{:x}".format(wordAddr)
self.executeCode((0xBA0BB6, 0x0, 0x0))
self.readREGOUTword()
self.executeCode((0x0,))
self.progressMeter(wordAddr)
self.executeCode(self.codeExitResetVectorSimple)
self.progressMeterFinish()
self.flushBufferToImage()
self.exitPM()
return self.Image
def writeProgmem(self, image):
def writePackedInstructionWords(addr, _16bytes):
"""
writes 4 double word size instructions to program memory.
Most high instruction byte has 0x00 value and thus is ignored.
"""
print("writingPackedInstr init, addr: {:x}\n".format(addr))
self.executeCode(self.getCodeInitializeTBLPAG(addr, 7))
cnt = 0
for wIdx in (0, 8):
# LSW0
WD = (byte2int(_16bytes[wIdx + 1]) << 8) | byte2int(_16bytes[wIdx + 0])
self.executeCode(((0x200000 | (WD << 4) | cnt),))
cnt += 1
# MSB1 MSB0
WD = (byte2int(_16bytes[wIdx + 6]) << 8) | byte2int(_16bytes[wIdx + 2])
self.executeCode(((0x200000 | (WD << 4) | cnt),))
cnt += 1
# LSW1
WD = (byte2int(_16bytes[wIdx + 5]) << 8) | byte2int(_16bytes[wIdx + 4])
self.executeCode(((0x200000 | (WD << 4) | cnt),))
cnt += 1
self.executeCode((0xEB0300, 0x0))
print("writingPackedInstr med\n")
# Set the Read Pointer and load the (next set of) write latches
for i in range(0, 2):
self.executeCode((0xBB0BB6, 0x0, 0x0, 0xBBDBB6, 0x0, 0x0, 0xBBEBB6, 0x0, 0x0, 0xBB1BB6, 0x0, 0x0))
print("writingPackedInstr done\n")
def writeSeq():
# Initiate the write cycle
self.executeCode((0xA8E761, 0x0, 0x0))
while self.isWRset():
pass
self.executeCode((0x040200, 0x0))
nrWords = self.flashPages * self.flashPageSize
if len(image) > (nrWords * 4) or len(image) % 4 != 0:
self.throwError("Invalid flash image size %d (expected <=%d and double word aligned)" % \
(len(image), nrWords * 4))
self.progressMeterInit("Writing flash", len(image) // 12)
self.enterPM()
self.executeCode(self.codeExitResetVector)
self.executeCode(self.getCodeSetNVMCON(0x4004))
for packAddr in range(0, len(image) // 16):
self.progressMeter(packAddr)
writePackedInstructionWords(packAddr * 8, image[16 * packAddr:][:16])
if(0 == ((packAddr + 1) % 8)):
writeSeq()
writeSeq()
self.progressMeterFinish()
self.exitPM()
def writeEEPROM(self, image):
nrWords = self.eepromPages * self.eepromPageSize
if len(image) > nrWords * 2:
self.throwError("Invalid flash image size {:d} (expected <={:d})".format(len(image), 2 * nrWords))
self.enterPM()
self.progressMeterInit("Writing eeprom", len(image) / 2)
self.executeCode(self.codeExitResetVector)
self.executeCode(self.getCodeSetNVMCON(0x4004))
for addr in range(0, len(image) / 2):
self.progressMeter(addr)
WD = (byte2int(image[addr * 2 + 1]) << 8) | byte2int(image[addr * 2 + 0])
if WD != 0xFFFF:
self.executeCode(self.getCodeInitializeTBLPAG(self.eepromStartAddress | (2 * addr), 7))
# Load W0 with data word program and load the wire latch
self.executeCode((0x200000 | (WD << 4), 0xBB1B80, 0x0, 0x0))
# Initiate the write cycle
self.executeCode((0xA8E761, 0x0, 0x0))
while self.isWRset():
pass
self.executeCode(self.codeExitResetVectorSimple)
self.progressMeterFinish()
self.exitPM()
def writeFuse(self, image):
if len(image) != self.fuseBytes:
self.throwError("Invalid Fuses image size %d (expected %d)" % \
(len(image), self.fuseBytes))
self.progressMeterInit("Writing fuses", 0)
# print "image1:%x,,%x,,%x" % (byte2int(image[0]),byte2int(image[1]),byte2int(image[1])<<8)
CW = []
for tBytes in zip(image[::2], image[1::2]):
CW.append((byte2int(tBytes[1]) << 8) | byte2int(tBytes[0]))
self.writeConfigWord(CW)
self.progressMeterFinish()
def writeConfigWord(self, listConfigWord16):
self.enterPM()
self.executeCode(self.codeExitResetVector)
# init WritePointer (W7) for the TBLWT instruction, Set the NVMCON reg. to prog. Config. regs.
self.executeCode((0x200007, 0x24004A, 0x883B0A))
# init TBLPAG
# another bug in Microchip's doc - s/0x200F86/0x200F80/
self.executeCode((0x200F80, 0x880190))
for configWord16 in listConfigWord16:
print ("write CW 0x{:x}".format(configWord16))
# Load the Config reg data to W6
self.executeCode(((0x200006 | (configWord16 << 4)),))
# Write the Config. reg. data to the write latch and increment Write Pointer
self.executeCode((0x0, 0xBB1B86, 0x0, 0x0))
# Initiate the write cycle
self.executeCode((0xA8E761, 0x0, 0x0))
while self.isWRset():
pass
self.executeCode(self.codeExitResetVectorSimple)
self.top.flushCommands()
self.progressMeterFinish()
def exitPM(self):
"Exit programming mode. Vdd last exit mode"
self.top.flushCommands()
self.setPins(0, 0)
self.top.hostDelay(self.delayP16)
self.applyVPP(False)
self.top.hostDelay(self.delayP17)
self.applyVCC(False)
self.applyGND(False)
self.isInPmMode = False
def setSDI(self, sdi):
'''
16 -set 24 bit sdi value
'''
for addr in (0x13, 0x14, 0x15):
self.top.cmdFPGAWrite(addr, sdi & 0xFF)
sdi = sdi >> 8
def sendCommand(self, command):
'''
16 - send command
CMD_SENDSIXINSTR 0
CMD_SENDREGOUTINSTR 1
CMD_ENTERPM 2
'''
self.top.cmdFPGAWrite(0x12, command)
def readREGOUTword(self):
def incBbAndCheckFillImage():
self.BufferedBytes += 1
if self.BufferedBytes == self.top.getBufferRegSize():
self.Image += self.top.cmdReadBufferReg(self.BufferedBytes)
self.BufferedBytes = 0
self.busyWait()
# self.top.hostDelay(0.000001)
self.sendCommand(self.PROGCMD_SENDREGOUTINSTR)
self.busyWait()
# self.top.hostDelay(0.000001)
self.readSDOBufferLow()
incBbAndCheckFillImage()
self.readSDOBufferHigh()
incBbAndCheckFillImage()
def flushBufferToImage(self):
if self.BufferedBytes > 0:
self.Image += self.top.cmdReadBufferReg(self.BufferedBytes)
self.BufferedBytes = 0
def sendSIX(self, instr, is9SIX=False):
self.busyWait()
self.setSDI(instr)
self.sendCommand((self.PROGCMD_SENDSIXINSTR, self.PROGCMD_SEND9SIXINSTR)[is9SIX])
def read2words(self):
self.executeCode((0xBA0B96, 0x000000, 0x000000))
self.readREGOUTword()
self.executeCode((0x0000000, 0xBA8BB6, 0x000000, 0x000000, 0xBAD3D6, 0x000000, 0x000000))
self.readREGOUTword()
self.executeCode((0x000000, 0xBA0BB6, 0x000000, 0x000000))
self.readREGOUTword()
self.executeCode((0x000000,))
def executeCode(self, code):
for instr in code:
self.sendSIX(instr)
def setPins(self, ICSPCLK=0, SDIOVALUE=0, SDIODRIVEN=1):
'''
16 - setPins
'''
data = 0
if ICSPCLK:
data |= 1
if SDIODRIVEN:
data |= 2
if SDIOVALUE:
data |= 4
self.top.cmdFPGAWrite(0x19, data)
def getStatusFlags(self):
'''
[0] - BUSY
[1] - SDO
'''
self.flushBufferToImage()
self.top.cmdFPGARead(0x12)
stat = self.top.cmdReadBufferReg()
return byte2int(stat[0])
def readSDOBufferHigh(self):
self.top.cmdFPGARead(0x10)
def readSDOBufferLow(self):
self.top.cmdFPGARead(0x13)
def rawSDIOState(self):
return bool(self.getStatusFlags() & self.STAT_SDIO)
def isBusy(self):
return bool(self.getStatusFlags() & self.STAT_BUSY)
def setTopProgrammerDelays(self):
# print("tdel5:{:d}".format(int(math.ceil(self.delayP3 / 42e-9))))
# print("tdly:{:d}".format(int(math.ceil(self.delayCommandDataREGOUT / 42e-9))))
self.top.cmdFPGAWrite(0x10, int(math.ceil(self.delayP3 / 42e-9)))
self.top.cmdFPGAWrite(0x11, int(math.ceil(self.delayCommandDataREGOUT / 42e-9)))
def busyWait(self):
# We do not poll the busy flag, because that would result
# in a significant slowdown. We delay long enough for the
# command to finish execution, instead.
self.top.hostDelay(0.0000005)
return
for i in range(0, 100):
if not self.isBusy():
return
self.top.hostDelay(0.000001)
self.throwError("Timeout in busywait.")
def getCodeInitializeTBLPAG(self, addr, wIdx=0):
mlw = (addr & 0xFFFF) << 4
mmb = (addr >> 12) & 0x000FF0
return (0x200000 | mmb, 0x880190, 0x200000 | mlw | (wIdx & 0x0F))
def getCodeSetNVMCON(self, NVMCON):
return (0x20000A | ((NVMCON & 0xFFFF) << 4), 0x883B0A)
def isWRset(self):
self.executeCode(self.codeExitResetVectorSimple)
self.executeCode((0x803B02, 0x883C22, 0x000000))
self.BufferedBytes = 0
self.Image = ""
self.readREGOUTword()
self.flushBufferToImage()
self.executeCode((0x000000,))
return byte2int(self.Image[1]) & 0x80
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