$BOOTVECTOR
Inhaltsverzeichnis |
Action
This compiler directive will force the compiler to create an interrupt vector table(IVR).
Syntax
$BOOTVECTOR
Remarks
By default an IVR is always created for normal applications. There is no good reason not to create an IVR for a normal application.
When making a boot loader application things are different. A boot loader application resides in upper flash memory inside the boot area. And when the boot loader applications runs, it has special rights so it can update the flash memory which resides in the lower flash memory.
The boot loader area size depends on the processor but is usual small. An interrupt vector table can use up to 250 bytes or more and it would be a waste of space in many cases. So by default the $LOADER directive which is used to create a boot loader application, will not create an IVR. The downside is that when you do not have an IVR you can not use interrupts.
The $BOOTVECTOR directive will force the compiler to create an IVR when the $LOADER directive is used. This way your boot loader application will include an IVR and you can use interrupts in your code.
The $BOOTVECTOR directive will only work when the processor has an option to move the IVR to the boot area using the IVSEL bit.
By default the interrupts are located after address 0. Address 0 is the reset vector and usually contains a jump to the real code. Behind the reset address, a table with jumps to the interrupt routines is located. That the code contains an IVR is not enough : in case of a boot loader the interrupt table must be moved to the boot area. For this purpose most processors have a register and bit to switch the IVR between the normal address 0 and the boot loader address.
In BASCOM you can use : Config Intvectorselection = Enabled to set the selection to the boot area.
When the boot loader application finishes, it is best to use a watchdog timeout to reset the processor so the intvector selection is set to the default address 0.
Or you can use Config Intvectorselection = Disabled in your main (normal) application before you enable the interrupts.
So in short you only need to add the $BOOTVECTOR directive and Config Intvectorselection = Enabled to your code. And do not forget to switch back the intvectorselection in the main application!
See also
$LOADER , CONFIG INTVECTORSELECTION
Example
'----------------------------------------------------------------- ' (c) 1995-2013, MCS ' BootEDB-IVSEL.bas ' This Bootloader is for the BASCOM-EDB ' VERSION 4 of the BOOTLOADER. ' IMPORTANT : ' When changing the vector table in the boot loader you MUST ' reset the vector table in your code using : ' Config Intvectorselection = Disabled ' otherwise your code points to the wrong table '----------------------------------------------------------------- 'The loader is supported by the IDE $prog &HFF , &HE2 , &HDF , &HF8 ' generated. Take care that the chip supports all fuse bytes.'---------------------------------------------------------------- $crystal = 8000000 $baud = 38400 'this loader uses serial com 'It is VERY IMPORTANT that the baud rate matches the one of the boot loader 'do not try to use buffered com as we can not use interrupts 'This bootloader uses buffers serial input Config Serialin = Buffered , Size = 250 'in order to use interrupts in a bootloader, the processor must support IVSEL 'since the vector table occupies space some processors will not support it. $bootvector ' put int table into bootloader section so we can use interrupts Config Intvectorselection = Enabled ' enabled means that the vector table points to the boot section 'since this boot loader uses interrupts we need to activate them but : 'AFTER the interrupt vector table is enabled Enable Interrupts $regfile = "m88def.dat" Const Loaderchip = 88 #if Loaderchip = 88 'Mega88 $loader = $c00 'this address you can find in the datasheet 'the loader address is the same as the boot vector address Const Maxwordbit = 5 Const Maxpages = 96 - 1 ' total WORD pages available for program Config Com1 = Dummy , Synchrone = 0 , Parity = None , Stopbits = 1 , Databits = 8 , Clockpol = 0 #endif Const Maxword =(2 ^ Maxwordbit) * 2 '128 Const Maxwordshift = Maxwordbit + 1 Const Cdbg = 0 ' leave this to 0 #if Cdbg Print Maxword Print Maxwordshift ' Print Maxpages #endif 'Dim the used variables Dim Bstatus As Byte , Bretries As Byte , Bblock As Byte , Bblocklocal As Byte Dim Bcsum1 As Byte , Bcsum2 As Byte , Buf(128) As Byte , Csum As Byte Dim J As Byte , Spmcrval As Byte ' self program command byte value Dim Z As Long 'this is the Z pointer word Dim Vl As Byte , Vh As Byte ' these bytes are used for the data values Dim Wrd As Word , Page As Word 'these vars contain the page and word address Dim Bkind As Byte , Bstarted As Byte 'Mega 88 : 32 words, 128 pages 'in this loader we may not disable interrupts ! 'Disable Interrupts 'we do not use ints 'Waitms 100 'wait 100 msec sec 'We start with receiving a file. The PC must send this binary file 'some constants used in serial com Const Nak = &H15 Const Cack = &H06 Const Can = &H18 'we use some leds as indication in this sample , you might want to remove it Config Pind.7 = Output Portd.7 = 0 $timeout = 200000 'we use a timeout 'When you get LOADER errors during the upload, increase the timeout value 'for example at 16 Mhz, use 200000 Bretries = 5 'we try 5 times Testfor123: #if Cdbg Print "Try " ; Bretries Print "Wait" #endif Bstatus = Waitkey() 'wait for the loader to send a byte #if Cdbg Print "Got " #endif Print Chr(bstatus); If Bstatus = 123 Then 'did we received value 123 ? Bkind = 0 'normal flash loader Goto Loader Elseif Bstatus = 124 Then ' EEPROM Bkind = 1 ' EEPROM loader Goto Loader Elseif Bstatus <> 0 Then Decr Bretries If Bretries <> 0 Then Goto Testfor123 'we test again End If For J = 1 To 10 'this is a simple indication that we start the normal reset vector Toggle Portd.7 : Waitms 100 Next #if Cdbg Print "RESET" #endif Goto _reset 'goto the normal reset vector at address 0 'this is the loader routine. It is a Xmodem-checksum reception routine Loader: #if Cdbg Print "Clear buffer" #endif Do Bstatus = Waitkey() Loop Until Bstatus = 0 For J = 1 To 3 'this is a simple indication that we start the normal reset vector Toggle Portd.7 : Waitms 250 Next If Bkind = 0 Then Spmcrval = 3 : Gosub Do_spm ' erase the first page Spmcrval = 17 : Gosub Do_spm ' re-enable page End If Bretries = 10 'number of retries Do Bblocklocal = 1 Bstarted = 0 ' we were not started yet Csum = 0 'checksum is 0 when we start Print Chr(nak); ' firt time send a nack Do Bstatus = Waitkey() 'wait for statuse byte Select Case Bstatus Case 1: ' start of heading, PC is ready to send Csum = 1 'checksum is 1 Bblock = Waitkey() : Csum = Csum + Bblock 'get block Bcsum1 = Waitkey() : Csum = Csum + Bcsum1 'get checksum first byte For J = 1 To 128 'get 128 bytes Buf(j) = Waitkey() : Csum = Csum + Buf(j) Next Bcsum2 = Waitkey() 'get second checksum byte If Bblocklocal = Bblock Then 'are the blocks the same? If Bcsum2 = Csum Then 'is the checksum the same? Gosub Writepage 'yes go write the page Print Chr(cack); 'acknowledge Incr Bblocklocal 'increase local block count Else 'no match so send nak Print Chr(nak); End If Else Print Chr(nak); 'blocks do not match End If Case 4: ' end of transmission , file is transmitted If Wrd > 0 Then 'if there was something left in the page Wrd = 0 'Z pointer needs wrd to be 0 Spmcrval = 5 : Gosub Do_spm 'write page Spmcrval = 17 : Gosub Do_spm ' re-enable page End If Print Chr(cack); ' send ack and ready Portd.7 = 0 ' simple indication that we are finished and ok Waitms 20 Goto _reset ' start new program Case &H18: ' PC aborts transmission Goto _reset ' ready Case 123 : Exit Do 'was probably still in the buffer Case 124 : Exit Do Case Else Exit Do ' no valid data End Select Loop If Bretries > 0 Then 'attempte left? Waitms 1000 Decr Bretries 'decrease attempts Else Goto _reset 'reset chip End If Loop 'write one or more pages Writepage: If Bkind = 0 Then For J = 1 To 128 Step 2 'we write 2 bytes into a page Vl = Buf(j) : Vh = Buf(j + 1) 'get Low and High bytes ! lds r0, {vl} 'store them into r0 and r1 registers ! lds r1, {vh} Spmcrval = 1 : Gosub Do_spm 'write value into page at word address Wrd = Wrd + 2 ' word address increases with 2 because LS bit of Z is not used If Wrd = Maxword Then ' page is full Wrd = 0 'Z pointer needs wrd to be 0 Spmcrval = 5 : Gosub Do_spm 'write page Spmcrval = 17 : Gosub Do_spm ' re-enable page If Page < Maxpages Then 'only if we are not erasing the bootspace Page = Page + 1 'next page Spmcrval = 3 : Gosub Do_spm ' erase next page Spmcrval = 17 : Gosub Do_spm ' re-enable page Else Portd.7 = 0 : Waitms 200 End If End If Next Else 'eeprom For J = 1 To 128 Writeeeprom Buf(j) , Wrd Wrd = Wrd + 1 Next End If Toggle Portd.7 : Waitms 10 : Toggle Portd.7 'indication that we write Return Do_spm: Bitwait Spmcsr.0 , Reset ' check for previous SPM complete Bitwait Eecr.1 , Reset 'wait for eeprom Z = Page 'make equal to page Shift Z , Left , Maxwordshift 'shift to proper place Z = Z + Wrd 'add word ! lds r30,{Z} ! lds r31,{Z+1} #if Loaderchip = 128 ! lds r24,{Z+2} ! sts rampz,r24 ' we need to set rampz also for the M128 #endif Spmcsr = Spmcrval 'assign register ! spm 'this is an asm instruction ! nop ! nop Return 'How you need to use this program: '1- compile this program '2- program into chip with sample elctronics programmer '3- select MCS Bootloader from programmers '4- compile a new program for example M88.bas '5- press F4 and reset your micro ' the program will now be uploaded into the chip with Xmodem Checksum ' you can write your own loader.too 'A stand alone command line loader is also available
| Languages | English |
|---|