- title "PIC16F870 Unilink(R) Interface by Werner Johansson (c) 2002-2003"\r
+ title "PIC16F870 Unilink(R) Interface by Werner Johansson, wj@yodel.net"\r
subtitl "Definitions"\r
list c=150,P=16F870,R=DEC,F=inhx8m\r
include "p16f870.inc" ; Standard equates & Macros\r
ERRORLEVEL 1,-302 ; Get rid of those annoying 302 msgs!\r
\r
+;******************************************************************************\r
+;\r
+; This program is free software; you can redistribute it and/or modify\r
+; it under the terms of the GNU General Public License as published by\r
+; the Free Software Foundation; either version 2 of the License, or\r
+; (at your option) any later version.\r
+;\r
+; This program is distributed in the hope that it will be useful,\r
+; but WITHOUT ANY WARRANTY; without even the implied warranty of\r
+; MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the\r
+; GNU General Public License for more details.\r
+;\r
+; You should have received a copy of the GNU General Public License\r
+; along with this program; if not, write to the Free Software\r
+; Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA\r
+;\r
+; Author: Werner Johansson (wj@yodel.net), with some code and ideas from \r
+; Simon Woods' GNUnilink, radix conversion utilities from piclist.com\r
+; and of course the reverse-engineered Unilink(R) command list\r
+;\r
+;******************************************************************************\r
\r
;----------------------------------------------------------------\r
; The Configuration Word\r
;----------------------------------------------------------------\r
; TODO\r
;----------------------------------------------------------------\r
-; No checksum checking is done on incoming packets\r
; Investigate whether I actually have to save PCLATH in ISH, maybe save FSR? - Not saving any of them for now\r
-; Move RS232 code into ISH\r
; Check Overrun errors from the UART\r
; Implement lots of other Unilink commands (Text display, time display etc.)\r
; Implement the Watchdog Timer (might be useful even though I haven't seen it hang yet..)\r
; Make the bit shift routine at the beginning of the ISR timeout if the clock suddenly stops (in the middle of a byte)\r
; (will keep it from hanging until the next bit gets clocked out, just ignore the faulty bits and carry on)\r
+; Implement command b0 0x (change CD to x (1-a))\r
+; Implement command 08 10 (Tel Mute on) and 08 18 (Tel Mute off)?\r
\r
;----------------------------------------------------------------\r
; HISTORY\r
;----------------------------------------------------------------\r
; Version\r
;\r
+; 0.7 Debug Serial TX in ISR now, checksum check for incoming packets in place, A/D works, solved the master reset prob\r
+; (by calling the INT handler from TMR2 ISR code (too much interrupt latency when transmitting)\r
; 0.6 Some more LCD info and clean-up of the Unilink recovery code, some problems with master resetting :(\r
; 0.5 Issues slave breaks seemingly without hickups (!)\r
; 0.4 Some fixups in the bootstrap code (I actually had to put the PIC in my PICSTART Plus programmer again :))\r
; RS-232 TX from computer connected to RC7/RX\r
; RS-232 RX to computer connected to RC6/TX\r
; RS-232 RI to computer connected to RC5\r
+; B+ connected via trimmer and resistors to AN0 (divider approx 20k5/5k to give 20.48V maximum scale)\r
;\r
-; This leaves RC0, RC1 and the analog inputs (AN0-AN4) free for now...\r
+; This leaves RC0, RC1 and four analog inputs (AN1-AN4) free for now...\r
\r
#define BUSON_IN_BIT PORTC,2\r
#define DATA_BIT PORTC,3\r
Dcount equ 6eh\r
e_LEN equ 6fh\r
\r
-\r
Counter equ 70h\r
DataCount equ 71h ; Temp storage for the bit counter used during bit shifts (Unilink TX/RX)\r
-DataStore equ 72h ; This is a kludge\r
+UnilinkCurID equ 72h ; This is a kludge\r
DisplayCounter equ 73h\r
UnilinkAttenuation equ 74h ; The amount of attenuation the volume control is currently set to\r
+NumH equ 75h\r
+NumL equ 76h\r
+TenK equ 77h\r
+Thou equ 78h\r
+Hund equ 79h\r
+Tens equ 7ah\r
+Ones equ 7bh\r
+UnilinkReInits equ 7ch\r
IRQPCLATH equ 7dh ; ISH storage\r
IRQSTATUS equ 7eh ; Needs to be located in a shared area accessible from all register banks\r
IRQW equ 7fh ; \r
; clrf PCLATH ; Go to low memory\r
; Maybe save FSR here as well (if there's a need for it in the non-ISR code)\r
\r
+ call IRQCheckINT ; Implemented as a subroutine as there's a need to call it repeatedly from the other ISRs\r
+\r
+ btfss PIR1,TMR2IF ; Check if it's the TMR2 interrupt (0.5ms timing)\r
+ goto IRQNotTMR2 ; No it's not, check the other sources\r
+\r
+ incf Counter,f ; Increment the general purpose counter (increments every 0.5ms)\r
+\r
+; Slave break opportunity detection here - the logic works as follows:\r
+; Look for a data low period of at least 5 ms (10 loops)\r
+; Look for a data high period of at least 2 ms (4 loops)\r
+; If the Slave Break request bit has been set, issue a slave break by holding the data line low for 4ms (8 loops)\r
+; If a bit would be received (CLK activates) the packet handler automatically clears out the SlaveBreakState, which means start all over\r
+\r
+ call IRQCheckINT ; Check the Unilink INT as well\r
+\r
+ btfsc SlaveBreakState,5 ; Check if already pulling the data line low\r
+ goto IRQTMR2SlaveBreak\r
+\r
+ btfsc SlaveBreakState,7 ; Looking for low or high data\r
+ goto IRQTMR2HighData\r
+ btfss DATA_BIT ; Looking for a low data line, if it's low, increment state, if it's high, reset state\r
+ goto IRQTMR2LowDataOK\r
+ clrf SlaveBreakState ; Got a high data line while waiting for a low one, reset state\r
+\r
+ call IRQCheckINT ; Check the Unilink INT as well\r
+\r
+ goto IRQAfterTMR2 ; Leave ISR\r
+\r
+IRQTMR2HighData\r
+ call IRQCheckINT ; Check the Unilink INT as well\r
+\r
+ btfsc DATA_BIT ; Looking for a high data line, if it's high - increment state, otherwise wait\r
+ goto IRQTMR2HighDataOK\r
+ movlw 080h\r
+ btfsc SlaveBreakState,6 ; Test the "first time around" bit\r
+ clrw ; Not the beginning of the state, have to restart the entire thing now, not just this state\r
+ andwf SlaveBreakState,f ; Mask out the 1 upper control bits and restart this state\r
+ goto IRQAfterTMR2\r
+\r
+IRQTMR2HighDataOK\r
+IRQTMR2LowDataOK\r
+ call IRQCheckINT ; Check the Unilink INT as well\r
+\r
+ bsf SlaveBreakState,6 ; Set the "first time around" bit\r
+ \r
+ movf SlaveBreakState,w\r
+ andlw 1fh\r
+\r
+ btfss SlaveBreakState,7 ; Checking whether it's low or high\r
+ goto IRQTMR2FoundLow\r
+\r
+ xorlw 4 ; It's high now, and if 4 periods have passed we can activate slave break\r
+ skpz\r
+ goto IRQAfterTMR2\r
+\r
+; Issue slave break here\r
+\r
+ clrf SlaveBreakState\r
+\r
+; incf Counter,f\r
+\r
+ btfss DisplayStatus,7 ; Only do this if high bit is set\r
+ goto IRQAfterTMR2\r
+\r
+ movlw 20h\r
+ movwf SlaveBreakState\r
+ bcf DATA_BIT\r
+ bsf STATUS,RP0\r
+ bcf DATA_BIT\r
+ bcf STATUS,RP0\r
+ goto IRQAfterTMR2\r
+\r
+IRQTMR2FoundLow\r
+ xorlw 10\r
+ skpz\r
+ goto IRQAfterTMR2\r
+\r
+ call IRQCheckINT ; Check the Unilink INT as well\r
+\r
+ movlw 80h ; Prepare for state 2, looking for data line high\r
+ movwf SlaveBreakState\r
+ goto IRQAfterTMR2\r
+ \r
+IRQTMR2SlaveBreak\r
+ call IRQCheckINT ; Check the Unilink INT as well\r
+\r
+ movf SlaveBreakState,w\r
+ andlw 01fh\r
+ xorlw 8\r
+ skpz\r
+ goto IRQAfterTMR2\r
+ bsf STATUS,RP0\r
+ bsf DATA_BIT\r
+ bcf STATUS,RP0\r
+ clrf SlaveBreakState\r
+\r
+IRQAfterTMR2\r
+ btfss SlaveBreakState,4 ; Only increment to 0x10\r
+ incf SlaveBreakState,f\r
+ bcf PIR1,TMR2IF ; Clear the IRQ source bit to re-enable TMR2 interrupts again\r
+\r
+IRQNotTMR2\r
+\r
+; Finally restore CPU state and return from the ISR\r
+\r
+; If I have to save the FSR in the beginning I also need to restore it here...\r
+\r
+; movf IRQPCLATH,w\r
+; movwf PCLATH ; Restore PCLATH\r
+ swapf IRQSTATUS,w\r
+ movwf STATUS ; Restore STATUS\r
+ swapf IRQW,f\r
+ swapf IRQW,w ; Restore W\r
+ retfie ; Interrupt return\r
+\r
+;----------------------------------------------------------------\r
+; IRQCheckINT - This part is the actual Unilink tranceiver, have to call it often as there are only ~20 spare cycles\r
+; (which is only a problem if we're going to transmit, but the check can be done anyway, it's cheap if no bit is there)\r
+\r
+IRQCheckINT\r
btfss INTCON,INTF ; Check if it's the INT edge interrupt (Unilink CLK)\r
- goto IRQNotINT ; No it's not, check the other sources\r
+ return ; No it's not, return again after only four cycles\r
\r
; If there's activity on the clock line (the clock goes high) the CPU will stay in here until eight bits have been clocked in\r
; - this reduces context switching (and it's just a few hundred cpu cycles after all (20us*8 bits=160us=800 instruction\r
\r
IRQINTRecvDone\r
clrf SlaveBreakState ; First of all, clear the break state - this got in the way, restart detection..\r
+\r
+ movf INDF,w\r
+ call BootTXB ; Send the byte to the serial port\r
+\r
movf UnilinkTXRX,w ; Find out which byte # that was received\r
andlw 0fh ; Mask\r
bnz IRQINTRecvNotFirst ; Not the first byte\r
andlw 0fh ; and mask - this results in a zero result when finished receiving\r
bnz IRQINTRecvIncomplete ; Packet not ready yet\r
\r
-; Here a packet is actually received, should check the checksum(s) as well, but I don't care right now\r
-; (I need music in my car! :))\r
+; Here a packet is actually received, should check the checksum(s) now\r
+\r
+ movf UnilinkRAD,w ; QnD checksum check\r
+ addwf UnilinkTAD,w\r
+ addwf UnilinkCMD1,w\r
+ addwf UnilinkCMD2,w\r
+ xorwf UnilinkParity1,w ; This should be zero\r
+ bnz IRQINTParseComplete ; Don't allow packet parsing on corrupt packets\r
+\r
+ btfss UnilinkCMD1,7 ; Test whether there's more parity to check (medium or long packet)\r
+ goto IRQINTParser ; No, skip directly to parsing logic\r
+\r
+ movf UnilinkParity1,w ; QnD checksum check for the remaining part of the packet\r
+ addwf UnilinkData1,w\r
+ addwf UnilinkData2,w\r
+ addwf UnilinkData3,w\r
+ addwf UnilinkData4,w\r
+\r
+ btfss UnilinkCMD1,6 ; Test for a long packet\r
+ goto IRQINTBypassLongPacket\r
+\r
+ xorwf UnilinkParity2M,w ; Fix for the medium packet parity check a few lines down...\r
+ addwf UnilinkData5,w\r
+ addwf UnilinkData6,w\r
+ addwf UnilinkData7,w\r
+ addwf UnilinkData8,w\r
+ addwf UnilinkData9,w\r
+ xorwf UnilinkParity2,w ; This should be zero when xor:ed with the Parity2M\r
+\r
+IRQINTBypassLongPacket\r
+ xorwf UnilinkParity2M,w ; This should be zero for valid medium and long packets\r
+ bnz IRQINTParseComplete\r
+\r
+IRQINTParser\r
+\r
; This is inefficient, I know, I'll improve it later... (Not that it matters, there's plenty of time here\r
; (there won't be any more communication for at least another 4.8ms))\r
\r
\r
call ClearUnilinkStatus ; Clear everything Unilink (ID, BUSON_OUT)\r
\r
+ incf UnilinkReInits,f ; increment the debug counter\r
+\r
goto IRQINTParseComplete ; Don't send any reply to this (clear the packet buffer though)\r
\r
IRQINTParseNot0100\r
bnz IRQINTParseNot0102\r
\r
movf UnilinkID,w ; Do I have an ID already?\r
- bnz IRQINTParseNot0102 ; Yep, I don't want another one!\r
+ bnz IRQINTParseComplete ; Yep, I don't want another one!\r
\r
-; clrf UnilinkParity1\r
call ClearUnilinkBuffer ; Zero it out completely\r
\r
movlw 10h ; Sending to Master\r
addwf UnilinkParity2M,f\r
movwf UnilinkData4\r
\r
-; clrf UnilinkData6\r
goto IRQINTParseBypassClear ; Don't clear the data, the buffer will be sent as the next packet\r
\r
IRQINTParseNot0102\r
xorwf UnilinkID,w ; Is it for me?\r
bnz IRQINTParseNot0112 ; Nope\r
\r
-; clrf UnilinkParity1\r
call ClearUnilinkBuffer\r
movlw 10h ; Sending to Master\r
addwf UnilinkParity1,f\r
\r
addwf UnilinkParity1,f\r
movwf UnilinkCMD2\r
-; clrf UnilinkData1\r
goto IRQINTParseBypassClear ; Don't clear the data, the buffer will be sent as the next packet\r
\r
IRQINTParseNot0112\r
btfss DisplayStatus,7 ; If not displaying, skip this\r
goto IRQINTParseComplete\r
\r
-; clrf UnilinkParity1\r
call ClearUnilinkBuffer\r
movlw 70h ; Sending to Display Group\r
addwf UnilinkParity1,f\r
movf UnilinkParity1,w ; Carry the parity forward\r
movwf UnilinkParity2M\r
\r
-; movlw 01h\r
movf DisplayStatus,w\r
addwf UnilinkParity2M,f\r
movwf UnilinkData1\r
movlw 01h\r
addwf UnilinkParity2M,f\r
movwf UnilinkData3\r
+\r
; movlw 0c0h\r
movf DisplayStatus,w\r
andlw 0f0h\r
+\r
addwf UnilinkParity2M,f\r
movwf UnilinkData4\r
\r
-; clrf UnilinkData6\r
-\r
incf DisplayStatus,f ; Temporary debug info\r
bsf DisplayStatus,7\r
\r
btfss DisplayStatus,7 ; First of all check if there should be anything displayed\r
goto IRQINTParseComplete ; No, not at this time\r
\r
-; clrf UnilinkParity1\r
call ClearUnilinkBuffer\r
movlw 10h ; Sending to Master\r
addwf UnilinkParity1,f\r
addwf UnilinkParity2M,f\r
movwf UnilinkData4\r
\r
-; clrf UnilinkData6\r
-\r
goto IRQINTParseBypassClear ; Don't clear the data, the buffer will be sent as the next packet\r
\r
;******************************************************************************\r
; Bit frig - works out which bit to set in the response to Master Poll\r
-\r
-; W register is input of which stage you are on (0x00, 0x20, 0x30, 0x40 etc)\r
+; This is taken more or less verbatim from Simon Woods' GNUnilink code!\r
+;\r
+; W register is input of which stage you are on (0x00, 0x20, 0x40 etc)\r
; and is returned with the byte to write (0x00 if wrong stage).\r
\r
Bit_Frig:\r
xorwf UnilinkBit, 0\r
- andlw 0xe0 ; Strip off low bits\r
+ andlw 0xe0 ; Strip off low bits\r
\r
- btfsc STATUS, Z ; Do we have a hit?\r
+ btfsc STATUS, Z ; Do we have a hit?\r
goto Bit_Frig_Hit\r
\r
movlw 0x00\r
return\r
\r
Bit_Frig_Hit:\r
- btfss UnilinkBit, 4 ; Do we need to swap nybbles?\r
+ btfss UnilinkBit, 4 ; Do we need to swap nybbles?\r
goto Bit_Frig_Swap\r
\r
movf UnilinkBit, 0\r
xorlw 02h\r
bnz IRQINTParseNot02\r
\r
- bsf BUSON_OUT_BIT ; Now activate the cascade BUSON pin, to allow others to be discovered\r
+ movf UnilinkID,w ; Do I have an ID already?\r
+ bnz IRQINTParseComplete ; Yep, I don't want another one!\r
+\r
+ movf UnilinkRAD,w ; So I don't have any ID yet, see what the master is trying to set\r
+ andlw 0f0h ; Check the device group\r
+ xorlw 0d0h ; Verify it's a MD changer\r
+ bnz IRQINTParseComplete ; No, something else, skip this\r
\r
movf UnilinkRAD,w ; Get the ID the master has given me\r
movwf UnilinkID ; Store my id\r
movf UnilinkCMD2,w ; Get the bitmask\r
movwf UnilinkBit ; And store it (this is needed when doing slave breaks and actually responding)\r
\r
-; clrf UnilinkParity1\r
call ClearUnilinkBuffer\r
movlw 10h ; Sending to Master\r
addwf UnilinkParity1,f\r
addwf UnilinkParity2M,f\r
movwf UnilinkData4\r
\r
-; clrf UnilinkData6\r
+ bsf BUSON_OUT_BIT ; Now activate the cascade BUSON pin, to allow others after us to be discovered\r
+\r
goto IRQINTParseBypassClear ; Don't clear the data, the buffer will be sent as the next packet\r
\r
IRQINTParseNot02\r
xorlw 087h\r
bnz IRQINTParseNot87\r
\r
+; This part could use some more packet sniffing (really), it's sketchy to say the least.. :(\r
+; The idea here is that the 18 10 87 2a PP 12 00 80 00 PP ZZ command is sent on power-up from my headunit if green color and\r
+; if amber it looks like 18 10 87 2a PP 02 00 80 00 PP ZZ, giving away that high nibble (or bit 4) of D1 sets the color\r
+; Also interesting is that the exact same commands gets sent when pressing the power-off button, this makes slaves pause\r
+; playing, and then a few seconds later the unit shuts down with the following command:\r
+; 18 10 87 22 PP 02 00 80 00 PP ZZ or\r
+; 18 10 87 22 PP 12 00 80 00 PP ZZ depending on the color of the backlight\r
+; This makes me think that bit 3 in CMD2 reflects the actual power state of the headunit (actually sleeping or bus active)\r
+; Anyway I use this to set/clear the RI pin used for WakeOnRing on my laptop\r
+; Also I de-select to make everything pause and clear the display status (if we're doing slave breaks after power status\r
+; the headunit will never enter sleep!)\r
+; From what I have gathered the bit mapping of DATA1 is as follows:\r
+; 7 6 5 4 3 2 1 0\r
+; X - Backlight color changed if 1\r
+; ? ?\r
+; X - Backlight color, 0=Amber, 1=Green\r
+; X - Dimmer setting changed if 1\r
+; X X - Dimmer setting, 01=Dimmer Auto, 10=Dimmer On, 00=Dimmer Off, 11=???\r
+; X - Beep setting, 0=Beep on(!), 1=Beep off\r
+;\r
+; Also bit field of CMD2 for now:\r
+; 7 6 5 4 3 2 1 0\r
+; X X - These two bits are set when changing color, beep etc, but now when actually powering on/off the system???\r
+; X - Always set to 1 on my headunit\r
+; X - Always set to 0 on my headunit\r
+; X - Set to 1 when power is on, 0 when powering off (last command sent before bus dies is 87 22 on my unit)\r
+; X - Always set to 0 on my headunit\r
+; X - Always set to 1 on my headunit\r
+; X - Always set to 0 on my headunit\r
+\r
; Test for power-on bit (it seems like bit 3 (0x08h) of CMD2 is set when the power is on)\r
btfsc UnilinkCMD2,3\r
goto IRQINTParse87PowerOn\r
\r
IRQINTParse87PowerOn\r
bcf RS232_RI_BIT ; Clear this to make RI pin go high (waking the computer)\r
+\r
+ btfsc UnilinkCMD2,7 ; Test high bit if it's just a "set" command, if yes don't clear status\r
+ goto IRQINTParseComplete\r
+\r
+ bcf UnilinkSelected,7 ; Also de-select us (this gets sent when powering off but before the actual power down)\r
+ clrf DisplayStatus\r
+\r
goto IRQINTParseComplete\r
\r
IRQINTParseNot87\r
bnz IRQINTParseNotF0\r
\r
movf UnilinkCMD2,w\r
+ movwf UnilinkCurID ; Store it for display and debugging\r
+\r
xorwf UnilinkID,w ; Check if it's selecting me\r
bnz IRQINTParseF0Deselect\r
\r
IRQINTRecvIncomplete\r
\r
IRQINTRecvNullByte\r
- movf INDF,w\r
- movwf DataStore ; Store it so the non-irq code can snoop\r
+; movf INDF,w\r
+; movwf DataStore ; Store it so the non-irq code can snoop\r
\r
IRQAfterINT\r
bcf INTCON,INTF ; Clear the IRQ source bit to re-enable INT interrupts again\r
\r
IRQNotINT\r
-\r
- btfss PIR1,TMR2IF ; Check if it's the TMR2 interrupt (0.5ms timing)\r
- goto IRQNotTMR2 ; No it's not, check the other sources\r
-\r
- incf Counter,f ; Increment the general purpose counter (increments every 0.5ms)\r
-\r
-; Slave break opportunity detection here - the logic works as follows:\r
-; Look for a data low period of at least 5 ms (10 loops)\r
-; Look for a data high period of at least 2 ms (4 loops)\r
-; If the Slave Break request bit has been set, issue a slave break by holding the data line low for 4ms (8 loops)\r
-; If a bit would be received (CLK activates) the packet handler automatically clears out the SlaveBreakState, which means start all over\r
-\r
- btfsc SlaveBreakState,5 ; Check if already pulling the data line low\r
- goto IRQTMR2SlaveBreak\r
-\r
- btfsc SlaveBreakState,7 ; Looking for low or high data\r
- goto IRQTMR2HighData\r
- btfss DATA_BIT ; Looking for a low data line, if it's low, increment state, if it's high, reset state\r
- goto IRQTMR2LowDataOK\r
- clrf SlaveBreakState ; Got a high data line while waiting for a low one, reset state\r
- goto IRQAfterTMR2 ; Leave ISR\r
-\r
-IRQTMR2HighData\r
- btfsc DATA_BIT ; Looking for a high data line, if it's high - increment state, otherwise wait\r
- goto IRQTMR2HighDataOK\r
- movlw 080h\r
- btfsc SlaveBreakState,6 ; Test the "first time around" bit\r
- clrw ; Not the beginning of the state, have to restart the entire thing now, not just this state\r
- andwf SlaveBreakState,f ; Mask out the 1 upper control bits and restart this state\r
- goto IRQAfterTMR2\r
-\r
-IRQTMR2HighDataOK\r
-IRQTMR2LowDataOK\r
- bsf SlaveBreakState,6 ; Set the "first time around" bit\r
- \r
- movf SlaveBreakState,w\r
- andlw 1fh\r
-\r
- btfss SlaveBreakState,7 ; Checking whether it's low or high\r
- goto IRQTMR2FoundLow\r
-\r
- xorlw 4 ; It's high now, and if 4 periods have passed we can activate slave break\r
- skpz\r
- goto IRQAfterTMR2\r
-\r
-; Issue slave break here\r
-\r
- clrf SlaveBreakState\r
-\r
-; incf Counter,f\r
-\r
- btfss DisplayStatus,7 ; Only do this if high bit is set\r
- goto IRQAfterTMR2\r
-\r
- movlw 20h\r
- movwf SlaveBreakState\r
- bcf DATA_BIT\r
- bsf STATUS,RP0\r
- bcf DATA_BIT\r
- bcf STATUS,RP0\r
- goto IRQAfterTMR2\r
-\r
-IRQTMR2FoundLow\r
- xorlw 10\r
- skpz\r
- goto IRQAfterTMR2\r
- movlw 80h ; Prepare for state 2, looking for data line high\r
- movwf SlaveBreakState\r
- goto IRQAfterTMR2\r
- \r
-IRQTMR2SlaveBreak\r
- movf SlaveBreakState,w\r
- andlw 01fh\r
- xorlw 8\r
- skpz\r
- goto IRQAfterTMR2\r
- bsf STATUS,RP0\r
- bsf DATA_BIT\r
- bcf STATUS,RP0\r
- clrf SlaveBreakState\r
-\r
-IRQAfterTMR2\r
- btfss SlaveBreakState,4 ; Only increment to 0x10\r
- incf SlaveBreakState,f\r
- bcf PIR1,TMR2IF ; Clear the IRQ source bit to re-enable TMR2 interrupts again\r
-\r
-IRQNotTMR2\r
-\r
-; Finally restore CPU state and return from the ISR\r
-\r
-; If I have to save the FSR in the beginning I also need to restore it here...\r
-\r
-; movf IRQPCLATH,w\r
-; movwf PCLATH ; Restore PCLATH\r
- swapf IRQSTATUS,w\r
- movwf STATUS ; Restore STATUS\r
- swapf IRQW,f\r
- swapf IRQW,w ; Restore W\r
- retfie ; Interrupt return\r
+ return\r
\r
;----------------------------------------------------------------\r
; ClearUnilinkStatus - Zeroes out the Unilink state (used when initializing)\r
ClearUnilinkStatus\r
\r
clrf UnilinkID ; Clear the existing Unilink ID, if any\r
+ clrf UnilinkCurID ; Clear the currently selected ID as well\r
bcf BUSON_OUT_BIT ; Clear the cascade BUSON pin, not activated again until we have a new ID\r
clrf DisplayStatus ; No crazy display updates when resetting.. :)\r
clrf UnilinkSelected ; We're not selected anymore\r
\r
clrf UnilinkCmdLen ; No command length while waiting for a new packet\r
\r
+ clrf SlaveBreakState ; Slave Break Processing has to start all over\r
+\r
return\r
\r
;----------------------------------------------------------------\r
movlw high LookUp ; Set the high PC bits to indicate data lookup page\r
movwf PCLATH\r
\r
- movlw 0ffh\r
+ movlw 0ffh ; Set infinite attenuation to begin with\r
movwf UnilinkAttenuation\r
\r
+ clrf UnilinkReInits ; Clear the bus re-initialization counter\r
+\r
+ bsf STATUS,RP0 ; Reg bank 1\r
+ movlw 080h ; Right adjusted A/D, all analog inputs, no Vrefs\r
+ movwf ADCON1\r
+ bcf STATUS,RP0\r
+\r
+ movlw 081h ; Activate A/D, ch 0, Fosc/32 (for 20MHz operation)\r
+ movwf ADCON0\r
+\r
+ bsf ADCON0,2 ; Start the first A/D operation\r
+\r
movlw 8 ; Display page timing (approx 8/sec)\r
movwf DisplayCounter\r
\r
\r
MainDontPrintCmd\r
\r
-; Default text (see data declarations for actual text)\r
-; UnilinkID @ 11-12\r
+; Default text\r
+; UnilinkID @ 13-14\r
; UnilinkAttenuation @ 16-17\r
-; UnilinkSelected @ 53-54\r
+; UnilinkSelected @ 28-29\r
+; UnilinkReInits @ 38,39\r
+; UnilinkCurID @ 54-55\r
; DisplayStatus @ 62-63\r
+; BattVoltage @ 66,67,69,70 (thou,hund,tens,unit)\r
\r
bcf LCD_RS_BIT ; LCD Command mode\r
- movlw 80h+11 ; DisplayRam 11\r
+ movlw 80h+13 ; DisplayRam 13\r
call TxLCDB\r
bsf LCD_RS_BIT\r
\r
call TxLCDHEX\r
\r
bcf LCD_RS_BIT ; LCD Command mode\r
- movlw 80h+40h+13 ; DisplayRam 53\r
+ movlw 80h+28 ; DisplayRam 28\r
call TxLCDB\r
bsf LCD_RS_BIT\r
\r
call TxLCDHEX\r
\r
bcf LCD_RS_BIT ; LCD Command mode\r
+ movlw 80h+38 ; DisplayRam 38\r
+ call TxLCDB\r
+ bsf LCD_RS_BIT\r
+\r
+ movf UnilinkReInits,w\r
+ call TxLCDHEX\r
+\r
+ bcf LCD_RS_BIT ; LCD Command mode\r
+ movlw 80h+40h+14 ; DisplayRam 54\r
+ call TxLCDB\r
+ bsf LCD_RS_BIT\r
+\r
+ movf UnilinkCurID,w\r
+ call TxLCDHEX\r
+\r
+ bcf LCD_RS_BIT ; LCD Command mode\r
movlw 80h+40h+22 ; DisplayRam 62\r
call TxLCDB\r
bsf LCD_RS_BIT\r
movf DisplayStatus,w\r
call TxLCDHEX\r
\r
+ btfsc ADCON0,2 ; Test if A/D is ready\r
+ goto MainADNotReady\r
+\r
+ bsf STATUS,RP0\r
+ movf ADRESL,w ; Add to our result\r
+ bcf STATUS,RP0\r
+ addwf NumL,f\r
+ skpnc\r
+ incf NumH,f\r
+ movf ADRESL,w\r
+ addwf NumH,f ; And the high byte\r
+\r
+ movlw 20h\r
+ addwf NumH,f\r
+ skpc ; When this overflows we know there are 8 samples collected\r
+ goto MainADStartAD\r
+\r
+; Now shift the added results two steps down (/4) as there are 8 added samples here, and filter high bits\r
+ movlw 1fh\r
+ andwf NumH,f\r
+ clrc\r
+ rrf NumH,f\r
+ rrf NumL,f\r
+ clrc\r
+ rrf NumH,f\r
+ rrf NumL,f\r
+ \r
+ movf Counter,w\r
+ bnz MainADSkipDisplay\r
+\r
+ bcf LCD_RS_BIT ; LCD Command mode\r
+ movlw 80h+40h+26 ; DisplayRam 66\r
+ call TxLCDB\r
+ bsf LCD_RS_BIT\r
+\r
+ call BCDConvert\r
+ movf Thou,w\r
+ addlw 30h\r
+ call TxLCDB\r
+ movf Hund,w\r
+ addlw 30h\r
+ call TxLCDB\r
+ movlw '.'\r
+ call TxLCDB\r
+ movf Tens,w\r
+ addlw 30h\r
+ call TxLCDB\r
+ movf Ones,w\r
+ addlw 30h\r
+ call TxLCDB\r
+\r
+MainADSkipDisplay\r
+\r
+ clrf NumL\r
+ clrf NumH\r
+\r
+MainADStartAD\r
+ bsf ADCON0,2 ; Start a new conversion\r
+\r
+MainADNotReady\r
+\r
; This part handles display "scroll" by shifting one screen at a time\r
\r
btfss Counter,7 ; Test high bit\r
\r
; Display scroll part ends here...\r
\r
- movf DataCount,w ; Load bit counter (if 0 then byte is available)\r
- skpz\r
- goto MainLoop\r
+; movf DataCount,w ; Load bit counter (if 0 then byte is available)\r
+; skpz\r
+; goto MainLoop\r
\r
- decf DataCount,f ; Set it non-zero\r
+; decf DataCount,f ; Set it non-zero\r
\r
- movf DataStore,w\r
- call BootTXB ; Send to terminal\r
+; movf DataStore,w\r
+; call BootTXB ; Send to terminal\r
goto MainLoop\r
\r
\r
;----------------------------------------------------------------\r
; IRQInit - Sets up the IRQ Handler\r
; Set up Timer2 to generate 2000 interrupts per second, used for timing - 1/16 prescaler and a PR2 reg of 156 (0x9c) is set\r
+; Also enable INT interrupts for Unilink CLK processing\r
\r
IRQInit\r
\r
-; Start with clearing the Unilink packet buffer before enabling any interrupts, otherwise the first packet might become corrupt\r
-; TODO: Replace this with FSR access\r
- clrf UnilinkSelected\r
- clrf DisplayStatus\r
- clrf UnilinkID\r
- clrf UnilinkBit\r
- clrf UnilinkCmdLen\r
- clrf UnilinkRAD\r
- clrf UnilinkTAD\r
- clrf UnilinkCMD1\r
- clrf UnilinkCMD2\r
- clrf UnilinkParity1\r
- clrf UnilinkData1\r
- clrf UnilinkData2\r
- clrf UnilinkData3\r
- clrf UnilinkData4\r
- clrf UnilinkData5\r
- clrf UnilinkData6\r
- clrf UnilinkData7\r
- clrf UnilinkData8\r
- clrf UnilinkData9\r
- clrf UnilinkParity2\r
- clrf UnilinkZero\r
-\r
- clrf DataStore\r
- movlw UnilinkRAD ; Get the pointer to the first byte in the receive buffer\r
- movwf UnilinkTXRX ; Store it\r
-\r
- clrf SlaveBreakState ; Zero out the status, we're starting from the beginning\r
+ call ClearUnilinkStatus\r
+ call ClearUnilinkBuffer\r
\r
; Fix the output state of RI and BUSON_OUT to a safe default\r
\r
return\r
\r
;----------------------------------------------------------------\r
+;\r
+; Binary-to-BCD. Written by John Payson.\r
+; Taken from piclist.com - why re-invent the wheel when writing open-sourced code?\r
+;\r
+; Enter with 16-bit binary number in NumH:NumL.\r
+; Exits with BCD equivalent in TenK:Thou:Hund:Tens:Ones.\r
+;\r
+\r
+BCDConvert: ; Takes number in NumH:NumL\r
+ ; Returns decimal in\r
+ ; TenK:Thou:Hund:Tens:Ones\r
+ swapf NumH,w\r
+ andlw 0Fh ;*** PERSONALLY, I'D REPLACE THESE 2\r
+ addlw 0F0h ;*** LINES WITH "IORLW 11110000B" -AW\r
+ movwf Thou\r
+ addwf Thou,f\r
+ addlw 0E2h\r
+ movwf Hund\r
+ addlw 032h\r
+ movwf Ones\r
+\r
+ movf NumH,w\r
+ andlw 0Fh\r
+ addwf Hund,f\r
+ addwf Hund,f\r
+ addwf Ones,f\r
+ addlw 0E9h\r
+ movwf Tens\r
+ addwf Tens,f\r
+ addwf Tens,f\r
+\r
+ swapf NumL,w\r
+ andlw 0Fh\r
+ addwf Tens,f\r
+ addwf Ones,f\r
+\r
+ rlf Tens,f\r
+ rlf Ones,f\r
+ comf Ones,f\r
+ rlf Ones,f\r
+\r
+ movf NumL,w\r
+ andlw 0Fh\r
+ addwf Ones,f\r
+ rlf Thou,f\r
+\r
+ movlw 07h\r
+ movwf TenK\r
+\r
+ ; At this point, the original number is\r
+ ; equal to TenK*10000+Thou*1000+Hund*100+Tens*10+Ones\r
+ ; if those entities are regarded as two's compliment\r
+ ; binary. To be precise, all of them are negative\r
+ ; except TenK. Now the number needs to be normal-\r
+ ; ized, but this can all be done with simple byte\r
+ ; arithmetic.\r
+\r
+ movlw 0Ah ; Ten\r
+Lb1:\r
+ addwf Ones,f\r
+ decf Tens,f\r
+ btfss 3,0\r
+ goto Lb1\r
+Lb2:\r
+ addwf Tens,f\r
+ decf Hund,f\r
+ btfss 3,0\r
+ goto Lb2\r
+Lb3:\r
+ addwf Hund,f\r
+ decf Thou,f\r
+ btfss 3,0\r
+ goto Lb3\r
+Lb4:\r
+ addwf Thou,f\r
+ decf TenK,f\r
+ btfss 3,0\r
+ goto Lb4\r
+\r
+ retlw 0\r
+\r
+;----------------------------------------------------------------\r
; TxLCD16B\r
; Send a string to the LCD.\r
\r
org 600h\r
\r
; Default text\r
-; UnilinkID @ 11-12\r
+; UnilinkID @ 13-14\r
; UnilinkAttenuation @ 16-17\r
-; UnilinkSelected @ 53-54\r
+; UnilinkSelected @ 28-29\r
+; UnilinkReInits @ 38,39\r
+; UnilinkCurID @ 54-55\r
; DisplayStatus @ 62-63\r
+; BattVoltage @ 66,67,69,70 (thou,hund,tens,unit)\r
\r
DefaultText1\r
- DT "----- WJ", "ID:xx Se", "xx dB at", "LCDPage3", "LCDPage4"\r
- DT " Unilink", "lect:xx ", "t Dsp:xx", " Right 3", " Right 4"\r
+ DT "----- WJ", "MyID:xx ", "xx dB at", "Sel:xx B", "Inits:xx"\r
+ DT " Unilink", "CurID:xx", "t Dsp:xx", "atxx.xxV", " <WJ>"\r
\r
\r
LookUp movwf PCL ; Go to it (this assumes PCLATH == 06h)\r
call BootTXStr\r
\r
; movlw 0e8h ; Initialize timeout timer (e8 is about 3 secs)\r
- movlw 0fdh ; Initialize timeout timer (e8 is about 3 secs)\r
+ movlw 0fdh ; Initialize timeout timer (fd is short enough to get the headunit to recognize us)\r
movwf BootTimerL\r
movwf BootTimerM\r
movwf BootTimerH\r
\r
; To produce compact code the end zero byte has to be in the LSB (that means an even number of chars in every string)\r
BootStartText\r
+; "WJBoot - press ESC to flash\x00"\r
DW 0x2bca,0x216f,0x37f4,0x102d,0x1070,0x3965,0x39f3,0x1045,0x29c3,0x1074,0x37a0,0x336c,0x30f3,0x3400\r
-; DE "WJBoot - press ESC to flash\x00"\r
BootFlashText\r
+; "\r\nSend INHX8 file now...\r\x00"\r
DW 0x068a,0x29e5,0x3764,0x1049,0x2748,0x2c38,0x1066,0x34ec,0x32a0,0x376f,0x3bae,0x172e,0x0680\r
-; DE "\r\nSend INHX8 file now...\r\x00"\r
BootRunText\r
+; "\r\nExiting loader\r\x00"\r
DW 0x068a,0x22f8,0x34f4,0x34ee,0x33a0,0x366f,0x30e4,0x32f2,0x0680\r
-; DE "\r\nExiting loader\r\x00"\r
\r
\r
;----------------------------------------------------------------------\r
\r
org 2100h\r
; de 0ffh, 0ffh, 0ffh, 0ffh, 0ffh, 0ffh, 0ffh, 0ffh\r
+; de 0ffh, 0ffh, 0ffh, 0ffh, 0ffh, 0ffh, 0ffh, 0ffh\r
+; de 0ffh, 0ffh, 0ffh, 0ffh, 0ffh, 0ffh, 0ffh, 0ffh\r
+; de 0ffh, 0ffh, 0ffh, 0ffh, 0ffh, 0ffh, 0ffh, 0ffh\r
+; de 0ffh, 0ffh, 0ffh, 0ffh, 0ffh, 0ffh, 0ffh, 0ffh\r
+; de 0ffh, 0ffh, 0ffh, 0ffh, 0ffh, 0ffh, 0ffh, 0ffh\r
+; de 0ffh, 0ffh, 0ffh, 0ffh, 0ffh, 0ffh, 0ffh, 0ffh\r
+; de 0ffh, 0ffh, 0ffh, 0ffh, 0ffh, 0ffh, 0ffh, 0ffh\r
\r
END\r