Article 45474 of comp.sys.cbm: From: rhialto@mbfys.kun.nl (Olaf Seibert) Newsgroups: comp.sys.cbm Subject: PetIO.doc V1.5 14.11.95 Date: 25 Nov 1995 21:36:59 GMT Organization: University of Nijmegen, The Netherlands Lines: 2160 Distribution: world Message-ID: <49829r$oq5@wn1.sci.kun.nl> NNTP-Posting-Host: severus.mbfys.kun.nl PetIO.doc V1.5 14.11.95 ========================= Summarised by Olaf Seibert, from "Programming the PET/CBM" (by Raeto Collin West) chapter 14, The Transactor, Volume 4 Issue 05, articles posted by Veit Laule, and other sources. Now also contains the "8296 addendum". PIA 6520 and VIA 6522 --------------------- In the PET, you find the two PIAs at E810 and E820, and the VIA at E840. The PIA ------- The PIA has two 8-bit I/O ports, A and B, which are mostly identical in function. All 8 bits can be set to input (1 in the DDR) or output (0 in the DDR) independently. Bit 2 in CRx determines whether the DDRx or Px are accessed. Each port has 2 control lines: CA1, CA2, CB1, CB2. The Cx1 are input only, the Cx2 can be input or output. PIAs have two interrupt lines: IRQA and IRQB. They may go low on a change on the inputs of the Cxy lines. These interrupts may be enabled on either an 1->0 or an 0->1 transition. The selected transition is called the "active" transition. The flags which register that an active transition has occurred are reset by reading the appropriate PORT register. Register map: E810 PORT A or DDR A: Data Direction Register A E811 CRA: Control Register A E812 PORT B or DDR B: Data Direction Register B E813 CRB: Control Register B Control registers: CRA: bit meaning --- ------- 7 CA1 active transition flag. 1= 0->1, 0= 1->0 6 CA2 active transition flag. 1= 0->1, 0= 1->0 5 CA2 direction 1 = out | 0 = in 4 CA2 control Handshake=0 | Manual=1 | Active: High=1 Low=0 3 CA2 control On Read=0 | CA2 High=1 | IRQ on=1, IRQ off=0 Pulse =1 | CA2 Low=0 | 2 Port A control: DDRA = 0, IORA = 1 1 CA1 control: Active High = 1, Low = 0 0 CA1 control: IRQ on=1, off = 0 CRB works identical for CB1 and CB2, except for the differences in handshaking. The Cx2 handshake is not identical between ports. For port A, the handshake is on reading the PORT A register, for CB2 the handshake is sent on writing the PORT B register. On the listening side: BIT 3 LOW with CA2: CA2 is now controlled by two events: (i) CA1 active transition sets it high ("Data Valid") (ii) a READ operation sets it low ("Data Accepted"). On the talking side: BIT 3 LOW with CB2: CB2 is now controlled by two events: (i) CB1 active transition sets it high ("Ready For Data") (ii) a WRITE operation sets it low ("Data Valid"). Bit 2 HIGH: Causes pulse output, CA2 or CB2 going low for one cycle only after a read or write operation. This pulse may be too short for some uses. For operation with a sending and a receiving PIA one would connect talker listener ------ -------- Port B -> Port A CB2 -> CA1 with active = 1->0 (data valid) CB1 <- CA2 with active = 1->0 (data accepted and ready for more) Use of PIA signals in a PET: PIA 1 E810 PORT A 7 Diagnostic sense (pin 5 on the user port) 6 IEEE EOI in 5 Cassette sense #2 4 Cassette sense #1 3-0 Keyboard row select (through 4->10 decoder) E811 CA2 output to blank the screen (old PETs only) IEEE EOI out CA1 cassette #1 read line E812 PORT B 7-0 Contents of keyboard row Usually all or all but one bits set. E813 CB2 output to cassette #1 motor: 0=on, 1=off CB1 screen retrace detection in. This input is used to generate the 50 or 60 Hz IRQ. Also connected to VIA PB5. PIA 2 E820 PORT A Input buffer for IEEE data lines E821 CA2 IEEE NDAC out CA1 IEEE ATN in E822 PORT B Output buffer for IEEE data lines E823 CB2 IEEE DAV out CB1 IEEE SRQ in The VIA ------- The VIA is a superset of the PIA. Many of the principles apply here as well, though the organisation is slightly different. The VIA has two ports, PA and PB, 4 control lines C[AB][12], an 8-bit shift register SR and 2 timers TA and TB. Like the PIA, the Cx1 lines are input only, the Cx2 lines are I or O. Port A has two registers. One register causes handshaking with CA1 to happen, the other doesn't. Port B occurs in memory before port A. There are control registers CRA, CRB, ACR, PCR, and interrupt registers IFR and IER. The data direction registers DDRA and DDRB have their own addresses, unlike the PIA. I'll only describe the extra or different features. Timers. The VIA has two 16-bit timers T1 and T2. When written to the timers start counting down on each clock cycle, and when reaching 0000 will flag and may cause an interrupt or other special action. When the low byte of the timer is read, the interrupt flag is cleared. Writing to the high byte clears the flag and starts the timer counting. T1 has a latch register. This is a place to store the timer value before it will be used. When T1 reaches 0, the latch value is moved into the timer so that the countdown may begin all over again, if so enabled. Ports. PA and PB may be latched, so that on an active transition of CA1 the value in the PA register is retained indefinitely (or until the next active transition on that pin), and similarly with CB1 and PB. The shift register. This 8-bit register is connected to CB2. On command the SR performs 8 shifts, moving 8 bits to or from CB2 one at a time. The most significant bit is moved first (the register shifts left). The SR can be timed by T2 and at the same rate as the 6202, using the phase 2 clock phi2. Alternatively an external clock may time it. It seems there are bugs in the shift register. For instance, when doing cassette I/O, the CB2 sound, which uses the SR, must be turned off. Also (on my machine), when generating sound one must first set the shift register in "free running" mode, and then load it with a value to shift. The other way around does not seem to work. The ACR controls the timers, shift register and latch status of PA and PB. (T1 has effects on pin PB7, which are not described in the book, but I suspect they are similar to the features of the CIA in this respect. -Olaf) ACR E84B 7-6 Timer 1 control 0 = PB7 unused 0 0 = one shot 0 1 = continuous, i.e. on underflow timer restarts at latch value. (The following 3 lines are guessed, based on the Amiga's CIA description) 1 = PB7 used 1 0 = T1 underflow toggles PB7 1 1 = T1 underflow pulses PB7 5 Timer 2 control 0 = one shot 1 = count set no. of PB6 pulses 4-2 Shift register control 000 = shift reg disabled 001 = shift in by timer 2 010 = shift in by phi2 011 = shift in by external clock (PB6?) 100 = free run by timer 2 (setting for sound) this means keep shifting the same byte out over and over. T2 is hereby set to continuous mode. 101 = shift out by timer 2 110 = shift out by phi2 111 = shift out by external clock (PB6?) 1 Port B latch 0 = disabled 1 = enabled on CB1 transition (in/out) 0 Port A latch 0 = disabled 1 = enabled on CA1 transition (in) The Periheral Control Register PCR controls the operating modes of the control lines CA1-CB2. PCR E84C 7-5 CB2 control 7 direction 1 = output 1 0 = do handshake 1 0 0 = on write 1 0 1 = pulse? 1 1 = manual CB2 control 1 1 0 = CB1 low 1 1 1 = CB1 high 0 = input 0 0 x = Active low: 1->0 0 1 x = Active high: 0->1 0 x 0 = Clear Interrupt condition on write of 1 in IFR or r/w of ORB 0 x 1 = Clear Interrupt condition on write of 1 in IFR only 4 CB1 control 0 = active transition low 1 = active transition high 3-1 CA2 control (similar to CB2 control) 3 direction 1 = output 1 0 = do handshake 1 0 0 = on read 1 0 1 = pulse 1 1 = manual CA2 control 1 1 0 = CA1 low 1 1 1 = CA1 high 0 = input 0 0 x = Active low: 1->0 0 1 x = Active high: 0->1 0 x 0 = Clear Interrupt condition on write of 1 in IFR or r/w of ORB 0 x 1 = Clear Interrupt condition on write of 1 in IFR only 0 CA1 control 0 = active transition low 1 = active transition high The handshaking is not specifically described in the book, so I presume it is identical to that of the PIA. The interrupt conditions for the control lines can be cleared by writing a 1 bit in the corresponding bit in the IFR. Optionally for CA2 and CB2 it can also be cleared by accessing the port data register. Interrupt Flag Register IFR and Interrupt Enable Register IER. These registers are symmetrical wrt each other. The IER enables specific interrupts (i.e., allows an event to trigger an interrupt), and the IFR flags if the event took place. When writing to the IER bit 7 controls the meaning of the 1 bits in the data: when set each 1-bit sets the interrupt enable bit, when cleared it resets that interrupt enable bit. The flags in IFR can be cleared by writing a 1 in them (and bit 7 clear). IFR E84D IER E84E 7 IFR: master flag bit: 1 when any of the other bits are set IER: 0 disables, 1 enables interrupts 6 Timer 1 underflow 5 Timer 2 underflow 4 CB1 active transition 3 CB2 active transition 2 Shift register full/empty 1 CA1 active transition 0 CA2 active transition Use of VIA signals in a PET --------------------------- E840 PORT B 7 DAV in 6 NRFD in 5 screen retrace in (also connected to PIA1 CB1) 4 cassette #2 motor (note 2) 3 cassette write data out 2 ATN out 1 NRFD out 0 NDAC in E841 PORT A USER PORT with CA2 handshake (note 1) E842 DDRB 7-0 normal bits set to 0 0 0 1 1 1 1 0 E843 DDRA 7-0 USER PORT data direction register E844 Timer 1 LO E845 Timer 1 HI (set to $FF on system power-on) E846 Timer 1 latch LO E847 Timer 1 latch HI E848 Timer 2 LO E849 Timer 2 HI E84A Shift register E84B ACR Aux. control register; set to $00 at power on 7-6 timer 1 control 5 timer 2 control 4-2 shift register control 1 port B latch 0 port A latch E84C PCR Peripheral Control Register; set to $0C or $0E at power on 7-5 CB2 control (user port pin M) (note 3) 4 CB1 control (note 3) 3-1 CA2 control (graphics mode) (note 3) 0 CA1 control (note 3) E84D IFR Intertrupt Flag Register; set to $00 at power on 7 IRQ on/off 6 T1 interrupt flagged 5 T2 interrupt flagged 4 CB1 interrupt flagged 3 CB2 interrupt flagged 2 shift register interrupt flagged 1 CA1 interrupt flagged 0 CA2 interrupt flagged E84E IER Interrupt Enable Register; set to $80 at power on 7 1=enable, 0=disable 6-0 enable interrupts; same bits as in IFR. E84F PORTA USER PORT without CA2 handshake Note 1: E84F is the preferred user port register, since CA2 controls screen graphics. Note 2: The motor is on when this line is low, and off when it is high. Note 3: CA1 is connected to pin B of the user port. Pins B-L correspond to port A, which is invariably E84E. CB2 (connected to the shift register) also connects to pin M of the user port; square wave tones (see chapter 9 of "Programming the PET/CBM") use these facts. CB1 signals input from cassette #2. CA2 controls screen graphics: it is configured for output, and, when low, gives lower case characters and others. When high, the mode is upper case and graphics. VIA use by BASIC and KERNEL --------------------------- T1 and T2 are used (though the T1 latch is ignored). T2 is only used for cassette operations, to time reading and writing of bits. T1 is used to time out the IEEE-488 bus response (before setting ST) and also with cassette (although not to such an extent as T2). Both timers also contribute to RND(0), but Basic 1 uses the wrong addresses for this. T1 is also used in Basics < 4 to time the screen-scroll delay when RVS or the left-arrow key is pressed. Interrupts from T1 and T2 are used for cassette and IEEE handling. CB1 interrupts are also used with cassette. The kernel does not use interrupts from CB2, SR, CA2 and CA2. CB2 and the shift register are used for the bell sound, which exists only in Basic 4. 64 K RAM expansion in 8096 and 8296 ----------------------------------- From: UKAH@ibm3090.rz.uni-karlsruhe.de (Veit Laule) Newsgroups: comp.sys.cbm Date: Tue, 22 Nov 1994 16:38 Organization: University of Karlsruhe, Germany Message-ID: <19941122163828UKAH@ibm3090.rz.uni-karlsruhe.de> 8096 exp-mem (64K): The control register is at $FFF0/65520 You have 4 16K-banks, 0...3 $8000 $9000 $C000 $E800 $F000 $FFFF !----------------------------!!--------------------------------------! Bank 0 or 2 Bank 1 or 3 !--------! !-------! screen io Control Register $FFF0: bit 7: 0 normal 8032 configuration (screen, ROMs, IO, ROMs) 80 expansion memory bit 6: 0 RAM $E800-$EFFF (only when bit7=1) 40 IO peek through bit 5: 0 exp-mem $8000-$8FFF (-"-) 20 screen peek through bit 4: 10 not used bit 3: 0 bank 1 $C000-$FFFF 08 bank 3 bit 2: 0 bank 0 $8000-$BFFF 04 bank 2 bit 1: 02 write protect bank 1/3 bit 0: 01 write protect bank 0/2 when bit7=0, all other bits are ignored The missing 32K can't be accessed witout hardware modifications. You can only use the 2K "behind" the screen $8800-$8FFF (exact: 34768- 36863), available in the normal configuration. The register is write-only, and the value is written through to the previously selected ram bank. 6545/6845 CRT (6545 used in CBM 8xxx + FAT FOURTY, ------------- 6845 used in CBM 6/7x0 (B-series)) This info taken from Transactor Volume 4, Issue 05 and an article by Veit Laule. Note that the Transactor lists the 6545 with the B series info. Date: Wed, 14 Dec 1994 17:41 Message-ID: <19941214174145UKAH@ibm3090.rz.uni-karlsruhe.de> This chip is only available with the wide-screen (12 inch) models. 40 column models clock this chip at 1MHz, 80 column models at 2 MHz. E880: register select E881: register contents Reg# Meaning --------------- R0 Horizontal total number of characters on line (Nht) including horizontal retrace (true value = number + 1) R1 Horizontal total number of characters displayed (Nhd) R2 Distance (in characters) from left to right margin of screen + 1 R3 Sync width. Low nibble is vertical sync width (in lines) (0=16). High nibble is horizontal sync (in characters). R4 Number of display lines including retrace (Nvt) (7 bits) R5 Vertical position of the edge of the screen (5 bits) R6 Number of display lines on screen (Nvd) (7 bits) R7 Height of upper edge from bottom of screen (in lines displayed) (7 bits) R8 different between 6545 and 6845, not used 6545: Interlace and Skew: Bit 0: 1=interlace mode, 0=non interlaced mode Bit 1: if bit 0 = 1then interlace and video mode Bit 2: not used (not true?). Bit 3: not used. Bit 4: 1=scan from 32770 (8002) in memory Bit 5: 1=scan from 32772 (8004) in memory Bit 6: cursor (not implemented on the PET) Bit 7: cursor (not implemented on the PET) R9 Number of lines between top of one display line and the next (-1) (5 bits) R10 Cursor (not implemented on the PET) cursor start line, bits 4-0 bit 6 bit 5 Cursor Operating Mode ------------------------------------- 0 0 display cursor continuously 0 1 blank cursor 1 0 blink cursor at 1/16 field rate 1 1 blink cursor at 1/32 field rate R11 Cursor end line (5 bits) (not implemented on the PET) R12 Control register: Bit 0: 1=add 256 to screen start address ( 512 for 80-columns) Bit 1: 1=add 512 to screen start address (1024 for 80-columns) Bit 2: invert flyback Bit 3: invert video signal Bit 4: use top half of 4K character generator Bit 5: (not implemented on the PET) Bit 6: (not implemented on the PET) Bit 7: not used. Note: In my 8296 I could not confirm bits 2-7. R13 Value + 32786 (8000) is address of first character (multiply by 2 for 80-column models) R14 Cursor location HI (not implemented on the PET) R15 Cursor location LO (not implemented on the PET) R16 Light pen position HI (read only) R17 Light pen position LO (read only) R18 Update address high, 6bit (only 6545) R19 low -"- R0-R13, R18, R19 are writeonly R16, R17 are readonly R16-R19 are not used R10, R11, R14, R15 are only used in the CBM 6/700 (hardware cursor) RIOT 6532 --------- Source: TOuCHE manual: the keyboard for the Apple-II clone from the Computer Hobbyvereniging Eindhoven. (They got DDRA and DDRB reversed.) The RIOT is used at least in the diskdrives of type 2040, 3040, 4040, 8050, 8250. They contain two RIOTs (at $0200 and $0280) and a VIA (at $????). The RIOT (RAM, I/O and Timer) has 128 bytes of RAM, 2 8-bit bidirectional I/O ports, and a timer that can count down at 4 different rates. Reg. Name Description --------------------------- 0 PA Port A data 1 DDRA Port A Data Direction Register 2 PB Port B data 3 DDRB Port B Data Direction Register 4 Timer Timer read register 14,0E T1 1 clocks per decrement 15,0F T8 8 16,10 T64 64 17,11 T1024 1024 The Data and DDR registers are as usual. The input is a buffer, the output is a latch. The Timer register reads out the timer value; its initial value is set by writing into the T1..T1024 registers. Which one is used determines the number of clock cycles between decrements of the Timer register. The chip also has an IRQ line but the cited source does not say anything further about it. The 8050 fdc rom usage suggests an irq is generated on timer underflow, with no special setup required. Pinout: 1 0V 21 PB3 2 A5 Address lines 22 PB2 3 A4 (see also pin 40) 23 PB1 4 A3 24 PB0 5 A2 25 IRQn 6 A1 26 D7 Data bus lines 7 A0 27 D6 8 PA0 Port A data 28 D5 9 PA1 29 D4 10 PA2 30 D3 11 PA3 31 D2 12 PA4 32 D1 13 PA5 33 D0 14 PA6 34 RESn Reset 15 PA7 35 R/Wn 16 PB7 Port B data 36 RSn RAM Select 17 PB6 37 CSn 18 PB5 38 CS Circuit Select 19 PB4 39 PHI2 Clock 20 +5V 40 A6 Address line IEEE Port Pinouts ----------------- This info taken from Transactor Volume 4, Issue 05. rear view for IEEE and User port: 1 2 3 4 5 6 7 8 9 10 11 12 --- --- --- --- --- --- --- --- --- --- --- --- =================================================== --- --- --- --- --- --- --- --- --- --- --- --- A B C D E F H J K L M N Contact spacing: 3.96 mm from centre to centre. The User port is the second port from the left, the IEEE-488 port is the third port. The left port is a cassette port, but cassette #1 and #2 have moved around in various models. The other port is either inside the case for older models or at the right-hand side for newer models. Some machines (at least the 8032 SK) has a proper IEEE-488 connector for the IEEE-488 port instead of the more common card edge connector. Those machines also have such a connector for the user port but mounted upside-down. PET IEEE Pin# Pin# Mnemonic Definition ----------------------------------- 1 1 DIO1 Data Input/Output Line #1 (PIA2 PA in, PIA2 PB out) 2 2 DIO2 Data Input/Output Line #2 3 3 DIO3 Data Input/Output Line #3 4 4 DIO4 Data Input/Output Line #4 5 5 EOI End Or Identify (PIA1 PA6 in, PIA1 CA2 out) 6 6 DAV Data Valid (VIA PB7 in, PIA2 CB2 out) 7 7 NRFD Not Ready For Data (VIA PB6 in, VIA PB1 out) 8 8 NDAC Not Data Accepted (VIA PB1 in, PIA2 CA2 out) 9 9 IFC Interface Clear 10 10 SRQ Service Request (PIA2 CB1 in only) 11 11 ATN Attention (VIA PB2 out, PIA2 CB1) 12 12 GND Chassis Ground (IEEE cable shield) A 13 DIO5 Data Input/Output Line #5 (PIA2 PA in, PIA2 PB out) B 14 DIO6 Data Input/Output Line #6 C 15 DIO7 Data Input/Output Line #7 D 16 DIO8 Data Input/Output Line #8 E 17 REN Remote Enable F 18 GND DAV Ground H 19 GND NRFD Ground J 20 GND NDAC Ground K 21 GND IFC Ground L 22 GND SRQ Ground M 23 GND ATN Ground N 24 GND Data Ground (DIO1-8) User port --------- Pin# Function Description ------------------------- 1 Ground System Ground 2 TV Video Video Out for external displays 3 SRQ Connected to IEEE-488 SRQ (PIA2 CB1 in only) 4 EOI Connected to IEEE-488 EOI (PIA1 PA6 in, PIA1 CA2 out) 5 Diagnostic Sense (PIA1 PA7) Held low causes power up to diagnostic routines or monitor 6 Read 1 Connected to cassette #1 read line (PIA1 CA1) 7 Read 2 Connected to cassette #2 read line (VIA CB1) 8 Write Diagnostic cassette write verify (VIA PA3) 9 Vert TV Vertical for external displays 10 Horiz TV Horizontal for external displays 11 GND 12 GND A GND B CA1 Edge sensitive input for 6522 VIA C PB0 PB0-7 are independently programmable D PB1 for Input or Output E PB2 F PB3 H PB4 J PB5 K PB6 L PB7 M CB2 Special IO pin of VIA, connected to shift register N GND Digital ground Cassette port ------------- 1 2 3 4 5 6 --- --- --- --- --- --- ========================== --- --- --- --- --- --- A B C D E F Contact spacing: 3.96 mm from centre to centre. Pin# Name Description ---------------------- A-1 GND Digital Ground B-2 +5V +5 Volts to operate cassette circuitry only C-3 Motor Computer controlled +6V for cassette motor D-4 Read Read line from cassette E-5 Write Write line to cassette F-6 Sense Monitors closure of any locking type cassette switch Keyboard matrix =============== There are two different keyboards: the graphics keyboard and the business keyboard. After analysis of the 50 and 60 Hz versions of the 8032 business roms, there are apparently even difference between the keyboards of those versions. The 60 Hz values are listed below the 50 Hz ones, if they differ. In Basic 4.0 CRTC the (PETSCII) values listed in the table below are recorded in location 151 [this makes distinguishing between the normal 0 key and the one on the numeric keypad impossible]; in older versions (and 4.0 without CRTC) the position in the table is recorded. The position is 8 * (9 - row) + (7 - column) + 1, i.e. starting at 1, incrementing left to right and top to bottom. The keyboard is scanned by writing the row number into the row select port ($E810), then reading the column bits ($E812). Each bit that reads 0 represents a pressed key. ; 00 = Shift ; 10 = Repeat ; 80 flags unshiftable key ; FF = No key Business keyboard decoding table: ----+------------------------ row | 7 6 5 4 3 2 1 0 ----+------------------------ 9 | 16 04 3A 03 39 36 33 DF | ^V -- : ^C 9 6 3 <- ^V = TAB + <- + DEL, ^C = STOP, | <- = left arrow 8 | B1 2F 15 13 4D 20 58 12 | k1 / ^U ^S m sp x ^R k9 = keypad 9, ^U = RVS + A + L, | ^S = HOME, sp = space, ^R = RVS 7 | B2 10 0F B0 2C 4E 56 5A ^O = Z + A + L, rp = repeat | k2 rp ^O k0 , n v z | 6 | B3 00 19 AE 2E 42 43 00 | k3 rs ^Y k. . b c ls ^Y = left shift + TAB + I, k. = keypad . | ls = left shift, rs = right shift 5 | B4 DB 4F 11 55 54 45 51 ^Q = cursor down | k4 [ o ^Q u t e q | 5D] 4 | 14 50 49 DC 59 52 57 09 | ^T p i \ y r w ^I ^T = DEL, ^I = TAB | C0@ 3 | B6 C0 4C 0D 4A 47 44 41 | k6 @ l ^M j g d a ^M = return | 5B[ 2 | B5 3B 4B DD 48 46 53 9B | k5 ; k ] h f s ^[ ^[ = ESC | 5C\ 3B; 1 | B9 06 DE B7 B0 37 34 31 | k9 -- ^ k7 0 7 4 1 | 0 | 05 0E 1D B8 2D 38 35 32 | . ^N ^] k8 - 8 5 2 ^N = both shifts + 2, ^] = cursor right ----+------------------------ Graphics keyboard decoding table: ----+------------------------ row | 7 6 5 4 3 2 1 0 ----+------------------------ 9 | 3D 2E FF 03 3C 20 5B 12 | = . -- ^C < sp [ ^S ^C = STOP, ^S = HOME | 8 | 2D 30 00 3E FF 5D 40 00 | - 0 rs > -- ] @ ls rs = right shift, ls = left shift | 7 | 2B 32 FF 3F 2C 4E 56 58 | + 2 -- ? , n v x | 6 | 33 31 0D 3B 4D 42 43 5A | 3 1 ^M ; m b c z ^M = return | 5 | 2A 35 FF 3A 4B 48 46 53 | * 5 -- : k h f s | 4 | 36 34 FF 4C 4A 47 44 41 | 6 4 -- l j g d a | 3 | 2F 38 FF 50 49 59 52 57 | / 8 -- p i y r w | 2 | 39 37 5E 4F 55 54 45 51 | 9 7 ^ o u t e q | 1 | 14 11 FF 29 5C 27 24 22 | ^T ^Q -- ) \ ' $ " ^T = DEL, ^Q = cursor down | 0 | 1d 13 5F 28 26 25 23 21 | ^] ^S <- ( & % # ! ^] = cursor right, ^S = home ----+------------------------ The original gfx keyboard reflects the matrix perfectly: ! " # $ % ' & \ ( ) <- ^s ^q ^] ^t q w e r t y u i o p ^ 7 8 9 / a s d f g h j k l : ^m 4 5 6 * z x c v b n m , ; ? ^m 1 2 3 + LS ^r @ [ ] SPACE < > ^c RS 0 . - = The shift key always set the high bit, producing a graphic character. CONTROL CODES ============= F: only on 4.0 fat-40, i.e. NOT on upgrade 4.0 roms. 8: only on 4.0 80 columns. 4B: only on 4.0 upgrade, B keyboard (maybe also on N keybd but I don't have a ROM to verify this) +------+------------------------------+------------------------------------+ |ctrl- | unshifted | shifted (unshifted + 128) | +------+------------------------------+------------------------------------+ | C 3 | stop | load/run, dload"*/run, or dL"*/run | | G 7 | bell | double bell | | I 9 | tab (4B,F,8) | set/clear tab (4B,F,8) | | M 13 | return | fake return | | N 14 | text mode (F,8) | graphics mode (F,8) | | O 15 | set top of window (8) | set bottom of window (8) | | P 16 | erase end of line (F) | see note (no function) | | Q 17 | cursor down | cursor up | | R 18 | reverse field on | reverse field off | | S 19 | cursor home | clear screen | | T 20 | delete char left of cursor | insert space at cursor | | U 21 | delete line (8) | insert line (8) | | V 22 | erase end of line (8) | erase begin of line (F,8) | | Y 25 | scroll up (8) | scroll down (8) | | [ 26 | escape: end inst & quote mode| (no function) | | ] 28 | cursor right | cursor left | | | | 255 pi (converted to 94) | +------+------------------------------+------------------------------------+ Note: on the 4.0-40-crtc version the code for "erase end of line" is different from the 4.0-80 code. Note that the decimal notation of the former (16, or $10) equals the hex notation of the latter ($16, or 22). This suggests a typo while editing the assembly source for the other version. CBM 8296 ======== What follows was typed in by yours truely from a photocopy of an "original". I hope I have reproduced the contents faithfully, even though this is a bit hard with some tables. Most text is in typewriter font, right-aligned, but some is in a proportional font and I had to rearrange some of that text. I left the small indications of German origin. Text between [square brackets] is mine. -Olaf CBM 8296 SUPPLEMENT to the 8032 Manual Seite 1. Introduction 1 2. Memory system 1 2.1 Memory mapping 1 2.2 Control register 3 2.3 Modification of memory system 4 2.4 User Jumper 5 3. Video-RAM 6 4. Hardware expansion via J4, J9 7 4.1 Memory expansion bus J4, J9 7 4.2 Power supply for hardware expansion 7 5. Programming the expansion memory bank 8 5.1 I/O handling 8 5.2 Interrupt processing 9 5.3 Interrupt Handler Program 9 Annex A Memory map 12 B.1 Connectors 8296 13 B.2 Connectors, modification as compared with 8032 17 C Software addendum 18 1. Introduction The CBM 8296 is an expanded version of the CBM 8032, and is fully software compatible with the CBM 8096. Where the hardware is con- cerned, there are some amendments and additional options, since the CBM 8296 has a total of 128 k RAM. The plug arrangements are also slightly different. 2. Memory system The CBM 8296 has two RAM banks, each with 64 k bytes, designated here the main memory and the expansion memory. The main memory is activated on switch-on, and the computer reacts like a standard CBM 8032. 2.1 Memory Mapping Expansion memory can be mapped into main memory addresses $8000 through $FFFF. See Figure 2-1. Only two of the 16k expansion blocks can reside in main memory at one time. This provides an additional 32k bytes of memory to the user. Selection of the expansion blocks is by bits 2 and 3 of the expansion memory control register. Each 16k block has a 16k alternate that can be selected by bits 2 and 3 of the control register. Main memory addresses $8000 through $BFFF can only be mapped by expansion blocks 0 or 1. Main memory addresses $C000 through $FFFF can only be mapped by expansion blocks 2 or 3. - 1 - 0 +----------------+ 0000 | | | | | | | | | | | | | | | | 16K +----------------+ 4000 | | | | | | | | | | | | | | | | 32K +----------------+ 8000 ............. +--------------+ +--------------+ | Screen | | | | | +----------------+ 9000 | | | | | | ADDRESSES | BLOCK 0 | | BLOCK 1 | | | 8000 TO BFFF | 16K | | 16K | | | (32K TO 48K) | | | | | | | | | | | | BFFF | | | | 48K +----------------+ C000 ............. +--------------+ +--------------+ | | | | | | +----------------+ | | | | | | ADDRESSES | BLOCK 2 | | BLOCK 3 | 58K +----------------+ C000 TO FFFF | 16K | | 16K | | | E800 (48K TO 64K) | | | | 60K |......I/O.......| F000 | | | | | | FFFF | | | | 64K +----------------+ +--------------+ +--------------+ Figure 2-1. Expansion memory mapping - 2 - 2.2 Control Register Control of the expansion memory is through a memory control register located at address $FFF0. The memory control register provides selection of 16k-byte blocks, write protection, enabling the expansion memory, I/O peek through and screen peek through. Because the memory control register is write only, a copy of the register should be kept in the lower 32k of main memory. Figure 2-2 depicts the functions of the memory control register. The paragraphs following it describe these functions in detail. Address $FFF0 --------------------------------------------------- 7 6 5 4 3 2 1 0 --------------------------------------------------- | | | | | | | | | | | | Enable --+ | | | | +-- Write Protect | | | | $8000 - $BFFF | | | | I/O peek through+ | | Select +--------- Write Protect $E800-$EFFF | | 16K $C000 - $FFFF | | Block: 0 0: 2 and 0 Screen peek through ---+ | 0 1: 2 and 1 $8000-$8FFF | 1 0: 3 and 0 | 1 1: 3 and 1 Reserved ---------------------+ Figure 2-2. Expansion Memory Control Register Control Register Bit 7 - When equal to 1, enables the expansion memory. When bit 7 equal to 0, expansion memory is disabled. Bit 7 defaults to 0 on power up. Control Register Bit 6 - When equal to 1, I/O peek through is enabled. Control Register Bit 5 - When equal to 1, screen peek through is enabled. Control Register Bit 4 - Reserved. Control Register Bit 3 - When equal to 1, block 3 (16k-byte) is selected. When equal to 0, block 2 (16k-byte) is selected. Control Register Bit 2 - When equal to 1, block 1 (16k-byte) is selected. When equal to 0, block 0 (16k-byte) is selected. Control Register Bit 1 - When equal to 1, addresses $C000 through $FFFF on the /Expansion Memory Board only/ are write protected. I/O is not write protected if I/O peek through is enabled. When equal to 0, the addresses are not write protected. Control Register Bit 0 - When equal to 1, addresses $8000 through $BFFF on the /Expansion Memory Board only/ are write protected. The screen is not write protected if screen peek through is enabled. When equal to 0, the addresses are not write protected. - 3 - 2.3. Modifications to the main memory system By contrast with the CBM 8032, each address in the 64 k main memory is covered by RAM. A write command into any address (apart from I/O) causes the corresponding RAM address to be written at, and a read command reads from RAM between $0000 and $8FFF; above $9000 from the empty [EP]ROM sockets, from the ROM or from the I/O devices. RAM $0000 - $FFFF Empty socket $9000 - $AFFF ROM $B000 - $FFFF. except $E8XX I/O $E800 - $E8FF The memory system for CPU read accesses can be modified by means of the signals /RAM SEL 9, /RAM SEL A, and /RAM ON (J4, Pins 12, 13, 14) in accordance with the following table: [The first line represents the normal config. In my machine I have jumpered J4 (the expansion bus) pins 12 and 13 to ground which gives me 8K of additional RAM which is not cleared on reset. Ground pins are available in the adjecent row.] [/NO ROM = 1; see page 12 for more cases] +-----+--------+------------+-------------------------------------------------+ | |Control | | | | |Register| | main memory $8000 - $FFFF [UB1-UB8] | | | | | [$0000 - $7FFF is always RAM from UB1-UB8] | | |$FFF0 | | | +-----+--------+------------+-------------------------------------------------+ | | I/O |___ ___ ___ | E000 | | ___ | peek|RAM RAM RAM | E800 F000 -E7FF B000 A000 9000 8000 | | NO_ | thr.|___ ___ ___ | E900 | | ROM |CR7 CR6 |ON S.9 S.A |-E8FF -FFFF -EFFF -DFFF -AFFF -9FFF -8FFF | +-----+--------+------------+-------------------------------------------------+ | | | | | | 1 | 0 X | 1 1 1 | I/O Kernal Editor BASIC EPROM EPROM SCREEN | | | | | | | 1 | 0 X | 1 1 0 | I/O Kernal Editor BASIC RAM EPROM SCREEN | | | | | +-----+ | | 1 | 0 X | 1 0 1 | I/O Kernal Editor BASIC EPROM RAM SCREEN | | | | | +-----+ | | 1 | 0 X | 1 0 0 | I/O Kernal Editor BASIC RAM RAM SCREEN | | | | | +-----+ | | 1 | 0 X | 0 1 1 | I/O Kernal Editor RAM RAM RAM SCREEN | | | | | +------+ | | 1 | 0 X | 0 0 1 | I/O Kernal RAM RAM RAM RAM SCREEN | | | | | +------+ | | 1 | 0 1 | 0 X 0 | I/O RAM RAM RAM RAM RAM SCREEN | | | | |+----+ | | 1 | 0 0 | 0 X 0 | RAM RAM RAM RAM RAM RAM SCREEN | | | | | | +-----+--------+------------+-------------------------------------------------+ SCREEN: 2000 bytes for screen memory, and 2096 bytes of available RAM. - 4 - 2.4. User Jumper These three signals can be either fixed or programmable via user jumpers. Bits 0, 1 and 2 are used for control under program control. [In my machine these jumpers are not true jumpers. You must solder two very tiny locations on the motherboard together to close the jumpers. Also these locations are rather far apart in the midst of various other tiny traces. I opted to use J4 instead which has JU1 and JU2 effectively accessible.] Jumper Description of function _________ JU1 RAM SEL A = LOW _________ JU2 RAM SEL 9 = LOW _________ JU3 RAM SEL A to Port A0 _________ JU4 RAM SEL 9 to Port A1 ______ JU5 RAM ON to Port A2 To use the user jumpers JU3 to JU5, Pins 0, 1 and 2 of the user port must be programmed to output. DR = 59459 ($E843) DA = 59471 ($E84F) POKE DR, PEEK (DR) OR 7 The desired combination of bits (0 ... 7) can then be poked into the port register DA. N.B. When using JU3, JU4 and JU5, make sure that the user port is not written at accidentally. This can happen for instance in a number of text processing programs, which emulate a Centronics interface via the user port. ______ The signal RAM ON must be high at the start, as it is not otherwise possible to complete the POWER ON routine in the ROM. - 5 - 3. Video RAM As previously, the video RAM is at $8000 - $87CF. With the CBM 8296 however, the CRT controller has access to the full range of addresses from $8000 - $9FFF. This produces 3 further screen pages, which can be used for program menues, help lists and the like. The four screen pages can be written at any time. The operating system uses the first page only. Page turning on display is achieved by altering the VIDEO RAM start address in the CRT controller (reg. 12): POKE 59520, 12 POKE 59521, x wherein x=0 for page 1 ($8000-$87CF, switch on figure) x=4 for page 2 ($8800-$8FCF) x=8 for page 3 ($9000-$97CF) x=12 for page 4 ($9800-$9FCF) Activating the switchover text-modus and graphic-modus brings the screen page 1 back each time to display. To use pages 3 and 4, the IC socket UE10 [$9XXX] must be free, or the /RAM SEL 9 signal set at LOW. Otherwise the ROM in the UE10 trans- mits data at the same time. For CPU read access to screen pages 3 and 4, /RAM SEL 9 must again be set at LOW (see 2.). Other parameters of the screen controller should be modified by comparison with the standard operating conditions (text or graphic) only with extreme caution. The dynamic RAM memories used require a cyclical refresh, which is produced by the CRT controller. To be sure of the refresh, the CRT controller must give at least 256 symbols in an interval of 4 ms. - 6 - 4. Hardware expansions via J4, J9 4.1. Memory expansion bus J4, J9 Hardware expansions can be linked via the memory expansion bus (J4, J9). The data buffer for the expansion bus is, as with the CBM 8032, always switched in as an output. If the CPU is to read from the expansion bus, close user jumper JU6 for the range $A000 to $AFFF, and user jumper JU7 for the range $9000 to $9FFF. The ROM sockets UE10 or UE9 must of course than remain free. The expansion bus cannot be read in the range $8000 to $8FFF. [ There are also JU8 (connected through a resistor) and JU9... ] A further way of gaining access to the expansion bus is provided by the line /SEL EXP (J4, Pin 15). Low-level on this line switches the data bus buffer of the expansion bus to input on a read command, independently of the address on the CPU. Care should therefore be taken to avoid bus conflicts when using SEL EXP. Make sure that only one data source (RAM, ROM I/O or expansion bus) is activated. _______ The control like SEL EXP must be switched with a collector gate. Jumpers JU6 and JU7 may also be closed. _________ _________ If the RAM SEL 9 or RAM SEL A line is activated, the RAM is switched in to this address range, and the expansion bus is switched out. 4.2. Power supply for hardware expansions. Connectors J10 and J11 are available for this purpose. As previously, ground and +9V DC unregulated are available at J11 (0.8 A max.). J10 is modified as compared with the CBM 8032, and now connected to 8V AC (1 A max.) and ground. Not more than 1A may be taken out via J10 and J11. - 7 - 5. Programming the expansion memory bank The user may choose to write his own programs to operate the expansion memory. A sample program is included in this chapter. 5.1 I/O Handling I/O in the CBM 8032 consists of the following five devices: 1. A 6520 PIA at $E810 2. A 6520 PIA at $E820 3. A 6522 VIA at $E840 4. A CRT controller at $E880 5. Screen memory at $8000 through $87FF These five I/O devices may be accessed in two ways. The first way is to simply switch out the expansion memory and restore main memory. This may be already accomplished by the memory manager software when a CBM I/O subroutine is called. The second way (necessary when a RAM-loaded application program accesses I/O) uses the I/O peek through feature. Bit 6 of the control register enables I/O peek through. +----------------------------------------------------------------+ | NOTE | | When using the I/O peek through, ensure that the currently | | running subroutine does not reside over the top of the | | peek through. | +----------------------------------------------------------------+ Accessing screen memory is accomplished in the same way as accessing the other I/O devices. When accessed, screen memory is seen as 25 lines of 80 columns. The data is stored row-wise as sequential bytes. The CRT display circuitry cannot directly display out of the expansion RAM. A suggested memory manager function is to page whole screen-fulls of data out of the expansion RAM. - 8 - 5.2 Interrupt Processing The 6502 microprocessor is designed for a simple architecture in which the lower 32k of the address space is RAM and the upper 32k is ROM. This allows the microprocessor to fetch the starting address of the first instruction out of ROM upon reset. The result is that three hardware vectors are stored in addresses $FFFA - $FFFF. The memory manager must accomplish the following functions. 1. Ensure that there is a valid address at each ROM address in the two 16k expansion blocks that are active. The only exception is if interrupts are disabled by a SEI instruction executed before bit 7 is set to a 1. 2. To avoid being interrupted while changing a vector, execute a SEI. 3. The ROM interrupt vectors in the CBM point to routines in ROM which are not accessible when the expansion memory is selected. For that reason, the memory manager should a) set the vectors to point at a routine that switches to main memory mode, b) call the interrupt service routine, and c) restore the expansion memory mode. 5.3 Interrupt Handler Program The following sample program (Refer to Table 5-1) handles interrupt and passes control to the ROM routines for processing. The global variable MEMMAP contains the current contents of the control register. The user program must first call the INIT routine to load the 6502 interrupt vectors into the expansion RAM. After that, interrupts are pre-processed by the subroutines NMI and IRQ. Interrupts are excited by RTIP. - 9 - Table 5-1. Interrupt Handler Program ; INITIALIZE INTERRUPT PROCESS ; ; ASSUME MEMMAP SETUP ; INIT SEI LDA MEMMAP STA $FFF0 ; ; INIT USER IRQ VECTOR ; LDA #IRQ STA $FFFF ; INIT USER NMI VECTOR ; LDA #NMI STA $FFFB CLI ; RTS ; PROCESS IRQ ; IRQ STA TMPA PRESERVE .A ; PLA PHA STA TMPPS ; LDA #%00000000 STA $FFF0 ; ; PUSH RETURN FROM INTERRUPT ADDRESS ; LDA #>RTIP PHA LDA #RTIP PHA LDA # RUN Your CRT should display the following message: - 19 - 64K ADD-ON-LOADER 2-12-81 SYSTEM NAME? The cursor will be blinking for you to enter one of the following system names followed by : BASIC2.0 BASIC4.0/40 BASIC4.0/80 In a few moments your 8032 will print the logon message from the program you selected. B A S I C 2 . 0 This is the 40-column BASIC found in all the 3016 and 3032 business keyboard machines. It was produced by dumping the ROMs and adding the following patch to re-initialize the CRT controller: D71A EA EA [ NOP NOP ] D745 A2 04 [ LDX #4 ] D747 BD 5E D7 [ LDA $D75E,X ] D74A BC 59 D7 [ LDY $D759,X ] D74D 8C 80 E8 [ STY $E880 ] D750 8D 81 E8 [ STA $E881 ] D753 CA [ DEX ] D754 10 F1 [ BPL $D747 ] D756 4C DE E1 [ JMP $E1DE ] D759 01 02 03 07 09 D75E 14 20 28 21 07 FCD5 20 45 D7 [ JSR $D745 ] f i g u r e C-1 B A S I C 4 . 0 / 4 0 This is the 40-column BASIC found in all the 4016 and 4032 business keyboard machines. It was produced by dumping the ROMs and adding the following patch to re-initialize the CRT controller: [ Actually, I think this ROM version is the "upgrade" ROM for 3008, 3016, 3032 machines without CRTC. ] - 20 - FD1B 20 5D FD [ JSR $FD5D ] FD5D A2 04 [ LDX #4 ] FD5F BD 76 FD [ LDA $FD76,X ] FD62 BC 71 FD [ LDY $FD71,X ] FD65 8C 80 E8 [ STY $E880 ] FD68 8D 81 E8 [ STA $E881 ] FD6B CA [ DEX ] FD6C 10 F1 [ BPL FD5F7 ] FD6E 4C 00 E0 [ JMP $E000 ] FD71 01 02 03 07 09 FD76 14 20 28 21 07 f i g u r e C-2 B A S I C 4 . 0 / 4 0 This version of BASIC is that supplied in the 8032 60hz versions. If you have a 50hz machine you probably do not need this version anyway because it is already in ROM. E x p a n s i o n M e m o r y M o n i t o r P r o g r a m The expansion memory monitor source program is provided on the diskette supplied with this manual. A listing of the program is provided as an addition to this manual. To run the monitor program: 1. Load the program into the lower 32K of RAM by typing: dload "add-on-mon" 2. Type: run The following paragraphs describe the commands used in the expansion monitor program. The commands allow the programmer to examine or alter expansion memory, examine or alter 6502 registers, execute programs, load or save disk files and load the expansion control register. - 21 - : Format: : Address [list of bytes] Purpose: Alter bytes in memory. Remarks: This command is automatically printed onto the CRT display preceding the address and data after execution of the display memory (M) command. To alter memory, use the screen editor to change the displayed bytes and press the key. The bytes are altered in the addresses specified by the expansion control register. ; Format: ;PC,IRQ,SR,AC,SR,YR,SP [2nd SR should be XR] Purpose: Loads list into 6502 registers. Remarks: The list of data following this command is loaded into the 6502 hardware registers when a G command is given. This command is automatically printed on the screen preceding the current list of data when an R command is executed. The list can be editeed and re-entered in the same manner as the alter memory command. See the R command for contents of the list. R Format: R Purpose: Displays the 6502 registers. Remarks: This command displays the contents of a list loaded into the 6502 hardware registers when execution is transferred from the monitor. A sample display follows: R PC IRQ SR AC XR YR SP ;0400 E262 01 00 FF FF FE The abbreviations are defined as follows: PC = program counter IRQ = interrupt vector SR = status register AC = accumulator XR = X-index register YR = Y-index register SP = stack pointer - 22 - M Format: M Address [Address] Purpose: Displays bytes from memory Remarks: Bytes are displayed from the addresses specified by the expansion control register. If one address is specified, 8 bytes are read and displayed on the screen, starting at that address. For more than one adress, a range of bytes is displayed, but always the next even multiple of 8 bytes from the first. The STOP key stops the listing. M 0400 : 0400 00 00 00 AA AA AA AA AA M Format: G [Address] Purpose: Start execution. Remarks: If an address is not specified, the monitor dispatches to the location contained in the PC of the register display. If an address is specified, execution dispatches to that address. If a BRK (00) has been inserted in the user code, execution will return to the monitor and a register display given with the message "BREAK". On display, the registers are loaded with the contents of the register display. L Format: L "name", Device Purpose: Load memory Remarks: Device number must be 4 or greater for CBM disks. The starting load address is implicit in the program load file. The STOP key will break a program LOAD. S Format: S "name", Device, Address, Address Purpose: Save memory Remarks: A file name must be specified in quotation marks followed by a device number, a starting save address and an ending save address. The STOP key will break a memory save. - 23 - @ Format: @ [disk command] Purpose: Displays disk status buffer Remarks: The command immediately followed by will read the disk status buffer and print its contents on the screen. The device is set at 8 and the command channel is 15. @ 00,ok,00,00 If a string follows the @, then that string is transmitted to device 8 channel 15 as a command. @ INITIALIZE 0 name Format: name Purpose: Load and execute file from disk Remarks: When a command cannot be matched to the list of known commands, an attempt is successful, the monitor jumos to execute it. [ some text seems missing in this sentence] * Format: * byte Purpose: Load expansion memory control register (mapper). Remarks: Puts the byte value following the command into the expansion control register. When a byte value is not specified, a zero is stored. This value restores the machine to ROM operation. E X P A N D E D - B A S I C : This program is a pseud-cache memory system for use with the 8032 and the 64k add-on memory board only. It is loaded into high memory, ($7800-$7BE0): DLOAD"EXPANDED-BASIC" It is activated by SYS 30720 This routine works nearly the same as the DOS-support program - 24 - provided with some Commodore disk systems. It moves the top of memory for BASIC down to $7800 and resets all the variables. Its commands are implemented by using an escape character sequence detected by a tap into the CHRGET routine in BASIC's zero page. The EXPANDED-BASIC program is completely protected from normal BASIC programs--however it is vulnerable to POKE and machine code programs. Because the 8032 ROM code is not modified, it is not possible to add space directly to a BASIC program. The EXPANDED-BASIC program allows a user to store or "cache" programs and data in the expansion RAM for ultra high-speed access in overlaying programs. The following commands are available: RECALL Format: !R,0:"filename",s(u)(p),[device] Purpose: Cache a file from disk. Remarks: The file can be USR, SEQ or PRG. The device number defaults to 8. The ST variable is set in the same manner as a file OPEN for read. LOAD Format: !L,"program name" Purpose: Move data from add-on to BASIC text area. Remarks: This command clears the current program and loads the named program. Will not work from a program--only direct. OVERLAY Format: !O,"program name" Purpose: Move data from add-on to BASIC text area. Remarks: This command overlays the current program. Variables and data are preserved. [ I think that like with the normal overlaying scheme, the first-loaded program must be at least as big as all overlays used ] - 25 - [ That was the last page of my photocopy of a photocopy of the 8296 addendum. I suppose I wouldn't be so stupid as to forget copying the last page, but there must be one missing: there should be descriptions of !E and !Q. On the other hand it might even be missing from the very original, since !E would have fit on page 25. I reconstruct the essential information here. ] EXECUTE Format: !E,"program name" Purpose: Execute a cached program. Remarks: This command overlays the current program and RUNs it. Variables and data are cleared. Basically equivalent to !L but for use within a program. QUIT Format: !Q Purpose: Quit the memory manager. Remarks: The tap into the CHRGET routine is restored to the power-up default. None of the expansion manager commands are recognised anymore from now on. [ end of the 8296 addendum ] : vi:set tw=75 -Olaf. -- ___ Copyright 1995 Olaf 'Rhialto' Seibert. All Rights Reserved. \X/ You are not allowed to read this using any kind of Micro$oft product.