GRI/gri_doc.txt - emulators/simh - Rivoreo Source Code Repositories

 To:	Users
 From:	Bob Supnik
 Subj:	GRI-909 Simulator Usage
 Date:	15-Feb-2004

 			COPYRIGHT NOTICE

 The following copyright notice applies to both the SIMH source and binary:

    Original code published in 1993-2004, written by Robert M Supnik
    Copyright (c) 1993-2004, Robert M Supnik

    Permission is hereby granted, free of charge, to any person obtaining a
    copy of this software and associated documentation files (the "Software"),
    to deal in the Software without restriction, including without limitation
    the rights to use, copy, modify, merge, publish, distribute, sublicense,
    and/or sell copies of the Software, and to permit persons to whom the
    Software is furnished to do so, subject to the following conditions:

    The above copyright notice and this permission notice shall be included in
    all copies or substantial portions of the Software.

    THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
    IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
    FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT.  IN NO EVENT SHALL
    ROBERT M SUPNIK BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER
    IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN
    CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.

    Except as contained in this notice, the name of Robert M Supnik shall not be
    used in advertising or otherwise to promote the sale, use or other dealings
    in this Software without prior written authorization from Robert M Supnik.

 This memorandum documents the GRI-909 simulator.


 1. Simulator Files

 sim/		scp.h
 		sim_console.h
 		sim_defs.h
 		sim_fio.h
 		sim_rev.h
 		sim_sock.h
 		sim_timer.h
 		sim_tmxr.h
 		scp.c
 		sim_console.c
 		sim_fio.c
 		sim_sock.c
 		sim_timer.c
 		sim_tmxr.c

 sim/gri/	gri_defs.h
 		gri_cpu.c
 		gri_stddev.c
 		gri_sys.c

 2. GRI-909 Features

 The GRI-909 is configured as follows:

 device		simulates
 name(s)

 CPU		GRI-909 CPU with up to 32KW of memory
 HSR		S42-004 high speed reader
 HSP		S42-004 high speed punch
 TTI		S42-001 Teletype input
 TTO		S42-002 Teletype output
 RTC		real-time clock

 The GRI-909 simulator implements the following unique stop conditions:

 	- an unimplemented operator is referenced, and register
 	  STOP_OPR is set
 	- an invalid interrupt request is made

 The LOAD commands has an optional argument to specify the load address:

 	LOAD <filename> {<starting address>}

 The LOAD command loads a paper-tape bootstrap format file at the specified
 address.  If no address is specified, loading starts at location 200.  The
 DUMP command is not supported.

 2.1 CPU

 The only CPU options are the presence of the extended arithmetic operator
 and the size of main memory.

 	SET CPU EAO		enable extended arithmetic operator
 	SET CPU NOEAO		disable extended arithmetic operator
 	SET CPU 4K		set memory size = 4K
 	SET CPU 8K		set memory size = 8K
 	SET CPU 12K		set memory size = 12K
 	SET CPU 16K		set memory size = 16K
 	SET CPU 20K		set memory size = 20K
 	SET CPU 24K		set memory size = 24K
 	SET CPU 28K		set memory size = 28K
 	SET CPU 32K		set memory size = 32K

 If memory size is being reduced, and the memory being truncated contains
 non-zero data, the simulator asks for confirmation.  Data in the truncated
 portion of memory is lost.  Initial memory size is 32K.

 CPU registers include the visible state of the processor as well as the
 control registers for the interrupt system.

 	name		size	comments

 	SC		15	sequence counter
 	AX		16	arithmetic operator input register 1
 	AY		16	arithmetic operator input register 2
 	AO		16	arithmetic operator output register
 	TRP		16	TRP register
 	MSR		16	machine status register
 	ISR		16	interrupt status register
 	BSW		16	byte swapper buffer
 	BPK		16	byte packer buffer
 	GR1..GR6	16	general registers 1 to 6
 	BOV		1	bus overflow (MSR<15>)
 	L		1	link (MSR<14>)
 	FOA		2	arithmetic operator function (MSR<9:8>)
 	AOV		1	arithmetic overflow (MSR<0>)
 	IR		16	instruction register (read only)
 	MA		16	memory address register (read only)
 	SWR		16	switch register
 	DR		16	display register
 	THW		6	thumbwheels (selects operator displayed in DR)
 	IREQ		16	interrupt requests
 	ION		1	interrupts enabled
 	INODEF		1	interrupts not deferred
 	BKP		1	breakpoint request
 	SCQ[0:63]	15	SC prior to last jump or interrupt;
 				most recent SC change first
 	STOP_OPR	1	stop on undefined operator
 	WRU		8	interrupt character

 2.2 Programmed I/O Devices

 2.2.1 S42-004 High Speed Reader (HSR)

 The paper tape reader (HSR) reads data from or a disk file.  The POS
 register specifies the number of the next data item to be read.
 Thus, by changing POS, the user can backspace or advance the reader.

 The paper tape reader implements these registers:

 	name		size	comments

 	BUF		8	last data item processed
 	IRDY		1	device ready flag
 	IENB		1	device interrupt enable flag
 	POS		32	position in the input file
 	TIME		24	time from I/O initiation to interrupt
 	STOP_IOE	1	stop on I/O error

 Error handling is as follows:

 	error	     STOP_IOE	processed as

 	not attached	1	report error and stop
 			0	out of tape

 	end of file	1	report error and stop
 			0	out of tape

 	OS I/O error	x	report error and stop

 2.2.2 S42-006 High Speed Punch (HSP)

 The paper tape punch (HSP) writes data to a disk file.  The POS
 register specifies the number of the next data item to be written.
 Thus, by changing POS, the user can backspace or advance the punch.

 The paper tape punch implements these registers:

 	name		size	comments

 	BUF		8	last data item processed
 	ORDY		1	device ready flag
 	IENB		1	device interrupt enable flag
 	POS		32	position in the output file
 	TIME		24	time from I/O initiation to interrupt
 	STOP_IOE	1	stop on I/O error

 Error handling is as follows:

 	error	     STOP_IOE	processed as

 	not attached	1	report error and stop
 			0	out of tape

 	OS I/O error	x	report error and stop

 2.2.3 S42-001 Teletype Input (TTI)

 The Teletype interfaces (TTI, TTO) can be set to one of three modes:
 KSR, 7B, or 8B.  In KSR mode, lower case input and output characters
 are automatically converted to upper case, and the high order bit is
 forced to one on input.  In 7B mode, input and output characters are
 masked to 7 bits.  In 8B mode, characters are not modified.  Changing
 the mode of either interface changes both.  The default mode is KSR.

 The Teletype input (TTI) polls the console keyboard for input.  It
 implements these registers:

 	name		size	comments

 	BUF		8	last data item processed
 	IRDY		1	device ready flag
 	IENB		1	device interrupt enable flag
 	POS		32	position in the output file
 	TIME		24	keyboard polling interval

 2.2.4 S42-002 Teletype Output (TTO)

 The Teletype output (TTO) writes to the simulator console window.  It
 implements these registers:

 	name		size	comments

 	BUF		8	last data item processed
 	ORDY		1	device ready flag
 	IENB		1	device interrupt enable flag
 	POS		32	number of characters output
 	TIME		24	time from I/O initiation to interrupt

 2.2.5 Real-Time Clock (RTC)

 The real-time clock (CLK) implements these registers:

 	name		size	comments

 	RDY		1	device ready flag
 	IENB		1	interrupt enable flag
 	TIME		24	clock interval

 The real-time clock autocalibrates; the clock interval is adjusted up or
 down so that the clock tracks actual elapsed time.

 2.3 Symbolic Display and Input

 The GRI-909 simulator implements symbolic display and input.  Display is
 controlled by command line switches:

 	-a			display as ASCII character
 	-c			display as packed ASCII characters
 	-m			display instruction mnemonics

 Input parsing is controlled by the first character typed in or by command
 line switches:

 	' or -a			ASCII character
 	" or -c			two packed ASCII characters
 	alphabetic		instruction mnemonic
 	numeric			octal number

 Instruction input uses modified GRI-909 basic assembler syntax.  There are
 thirteen different instruction formats.  Operators, functions, and tests may
 be octal or symbolic; jump conditions and bus operators are always symbolic.

 Function out, general
 	Syntax: 		FO function,operator
 	Function symbols:	INP, IRDY, ORDY, STRT
 	Example:		FO ORDY,TTO

 Function out, named
 	Syntax:			FO{M|I|A} function
 	Function symbols:	M: CLL, CML, STL, HLT; I: ICF, ICO;
 				A: ADD, AND, XOR, OR
 	Example:		FOA XOR

 Sense function, general
 	Syntax:			SF operator,{NOT} tests
 	Test symbols:		IRDY, ORDY
 	Example:		SF HSR,IRDY

 Sense function, named
 	Syntax:			SF{M|A} {NOT} tests
 	Test symbols:		M: POK BOV LNK; A: SOV AOV
 	Example:		SFM NOT BOV

 Register to register
 	Syntax:			RR{C} src,{bus op,}dst
 	Bus op symbols:		P1, L1, R1
 	Example:		RRC AX,P1,AY

 Zero to register
 	Syntax:			ZR{C} {bus op,}dst
 	Bus op symbols:		P1, L1, R1
 	Example:		ZR P1,GR1

 Register to self
 	Syntax:			RS{C} dst{,bus op}
 	Bus op symbols:		P1, L1, R1
 	Example:		RS AX,L1

 Jump unconditional or named condition
 	Syntax:			J{U|O|N}{D} address
 	Example:		JUD 1400

 Jump conditional
 	Syntax:			JC{D} src,cond,address
 	Cond symbols:		NEVER,ALWAYS,ETZ,NEZ,LTZ,GEZ,LEZ,GTZ
 	Example:		JC AX,LEZ,200

 Register to memory
 	syntax:			RM{I|D|ID} src,{bus op,}address
 	Bus op symbols:		P1, L1, R1
 	Example:		RMD AX,P1,1315

 Zero to memory
 	Syntax:			ZM{I|D|ID} {bus op,}address
 	Bus op symbols:		P1, L1, R1
 	Example:		ZM P1,5502

 Memory to register
 	Syntax:			MR{I|D|ID} address,{bus op,}dst
 	Bus op symbols:		P1, L1, R1
 	Example:		MRI 1405,GR6

 Memory to self:
 	Syntax:			MS{I|D|ID} address{,bus op}
 	Bus op symbols:		P1, L1, R1
 	Example:		MS 3333,P1
	To: Users
	From: Bob Supnik
	Subj: GRI-909 Simulator Usage
	Date: 15-Feb-2004

	COPYRIGHT NOTICE

	The following copyright notice applies to both the SIMH source and binary:

	Original code published in 1993-2004, written by Robert M Supnik
	Copyright (c) 1993-2004, Robert M Supnik

	Permission is hereby granted, free of charge, to any person obtaining a
	copy of this software and associated documentation files (the "Software"),
	to deal in the Software without restriction, including without limitation
	the rights to use, copy, modify, merge, publish, distribute, sublicense,
	and/or sell copies of the Software, and to permit persons to whom the
	Software is furnished to do so, subject to the following conditions:

	The above copyright notice and this permission notice shall be included in
	all copies or substantial portions of the Software.

	THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
	IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
	FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL
	ROBERT M SUPNIK BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER
	IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN
	CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.

	Except as contained in this notice, the name of Robert M Supnik shall not be
	used in advertising or otherwise to promote the sale, use or other dealings
	in this Software without prior written authorization from Robert M Supnik.

	This memorandum documents the GRI-909 simulator.


	1. Simulator Files

	sim/ scp.h
	sim_console.h
	sim_defs.h
	sim_fio.h
	sim_rev.h
	sim_sock.h
	sim_timer.h
	sim_tmxr.h
	scp.c
	sim_console.c
	sim_fio.c
	sim_sock.c
	sim_timer.c
	sim_tmxr.c

	sim/gri/ gri_defs.h
	gri_cpu.c
	gri_stddev.c
	gri_sys.c

	2. GRI-909 Features

	The GRI-909 is configured as follows:

	device simulates
	name(s)

	CPU GRI-909 CPU with up to 32KW of memory
	HSR S42-004 high speed reader
	HSP S42-004 high speed punch
	TTI S42-001 Teletype input
	TTO S42-002 Teletype output
	RTC real-time clock

	The GRI-909 simulator implements the following unique stop conditions:

	- an unimplemented operator is referenced, and register
	STOP_OPR is set
	- an invalid interrupt request is made

	The LOAD commands has an optional argument to specify the load address:

	LOAD <filename> {<starting address>}

	The LOAD command loads a paper-tape bootstrap format file at the specified
	address. If no address is specified, loading starts at location 200. The
	DUMP command is not supported.

	2.1 CPU

	The only CPU options are the presence of the extended arithmetic operator
	and the size of main memory.

	SET CPU EAO enable extended arithmetic operator
	SET CPU NOEAO disable extended arithmetic operator
	SET CPU 4K set memory size = 4K
	SET CPU 8K set memory size = 8K
	SET CPU 12K set memory size = 12K
	SET CPU 16K set memory size = 16K
	SET CPU 20K set memory size = 20K
	SET CPU 24K set memory size = 24K
	SET CPU 28K set memory size = 28K
	SET CPU 32K set memory size = 32K

	If memory size is being reduced, and the memory being truncated contains
	non-zero data, the simulator asks for confirmation. Data in the truncated
	portion of memory is lost. Initial memory size is 32K.

	CPU registers include the visible state of the processor as well as the
	control registers for the interrupt system.

	name size comments

	SC 15 sequence counter
	AX 16 arithmetic operator input register 1
	AY 16 arithmetic operator input register 2
	AO 16 arithmetic operator output register
	TRP 16 TRP register
	MSR 16 machine status register
	ISR 16 interrupt status register
	BSW 16 byte swapper buffer
	BPK 16 byte packer buffer
	GR1..GR6 16 general registers 1 to 6
	BOV 1 bus overflow (MSR<15>)
	L 1 link (MSR<14>)
	FOA 2 arithmetic operator function (MSR<9:8>)
	AOV 1 arithmetic overflow (MSR<0>)
	IR 16 instruction register (read only)
	MA 16 memory address register (read only)
	SWR 16 switch register
	DR 16 display register
	THW 6 thumbwheels (selects operator displayed in DR)
	IREQ 16 interrupt requests
	ION 1 interrupts enabled
	INODEF 1 interrupts not deferred
	BKP 1 breakpoint request
	SCQ[0:63] 15 SC prior to last jump or interrupt;
	most recent SC change first
	STOP_OPR 1 stop on undefined operator
	WRU 8 interrupt character

	2.2 Programmed I/O Devices

	2.2.1 S42-004 High Speed Reader (HSR)

	The paper tape reader (HSR) reads data from or a disk file. The POS
	register specifies the number of the next data item to be read.
	Thus, by changing POS, the user can backspace or advance the reader.

	The paper tape reader implements these registers:

	name size comments

	BUF 8 last data item processed
	IRDY 1 device ready flag
	IENB 1 device interrupt enable flag
	POS 32 position in the input file
	TIME 24 time from I/O initiation to interrupt
	STOP_IOE 1 stop on I/O error

	Error handling is as follows:

	error STOP_IOE processed as

	not attached 1 report error and stop
	0 out of tape

	end of file 1 report error and stop
	0 out of tape

	OS I/O error x report error and stop

	2.2.2 S42-006 High Speed Punch (HSP)

	The paper tape punch (HSP) writes data to a disk file. The POS
	register specifies the number of the next data item to be written.
	Thus, by changing POS, the user can backspace or advance the punch.

	The paper tape punch implements these registers:

	name size comments

	BUF 8 last data item processed
	ORDY 1 device ready flag
	IENB 1 device interrupt enable flag
	POS 32 position in the output file
	TIME 24 time from I/O initiation to interrupt
	STOP_IOE 1 stop on I/O error

	Error handling is as follows:

	error STOP_IOE processed as

	not attached 1 report error and stop
	0 out of tape

	OS I/O error x report error and stop

	2.2.3 S42-001 Teletype Input (TTI)

	The Teletype interfaces (TTI, TTO) can be set to one of three modes:
	KSR, 7B, or 8B. In KSR mode, lower case input and output characters
	are automatically converted to upper case, and the high order bit is
	forced to one on input. In 7B mode, input and output characters are
	masked to 7 bits. In 8B mode, characters are not modified. Changing
	the mode of either interface changes both. The default mode is KSR.

	The Teletype input (TTI) polls the console keyboard for input. It
	implements these registers:

	name size comments

	BUF 8 last data item processed
	IRDY 1 device ready flag
	IENB 1 device interrupt enable flag
	POS 32 position in the output file
	TIME 24 keyboard polling interval

	2.2.4 S42-002 Teletype Output (TTO)

	The Teletype output (TTO) writes to the simulator console window. It
	implements these registers:

	name size comments

	BUF 8 last data item processed
	ORDY 1 device ready flag
	IENB 1 device interrupt enable flag
	POS 32 number of characters output
	TIME 24 time from I/O initiation to interrupt

	2.2.5 Real-Time Clock (RTC)

	The real-time clock (CLK) implements these registers:

	name size comments

	RDY 1 device ready flag
	IENB 1 interrupt enable flag
	TIME 24 clock interval

	The real-time clock autocalibrates; the clock interval is adjusted up or
	down so that the clock tracks actual elapsed time.

	2.3 Symbolic Display and Input

	The GRI-909 simulator implements symbolic display and input. Display is
	controlled by command line switches:

	-a display as ASCII character
	-c display as packed ASCII characters
	-m display instruction mnemonics

	Input parsing is controlled by the first character typed in or by command
	line switches:

	' or -a ASCII character
	" or -c two packed ASCII characters
	alphabetic instruction mnemonic
	numeric octal number

	Instruction input uses modified GRI-909 basic assembler syntax. There are
	thirteen different instruction formats. Operators, functions, and tests may
	be octal or symbolic; jump conditions and bus operators are always symbolic.

	Function out, general
	Syntax: FO function,operator
	Function symbols: INP, IRDY, ORDY, STRT
	Example: FO ORDY,TTO

	Function out, named
	Syntax: FO{M\|I\|A} function
	Function symbols: M: CLL, CML, STL, HLT; I: ICF, ICO;
	A: ADD, AND, XOR, OR
	Example: FOA XOR

	Sense function, general
	Syntax: SF operator,{NOT} tests
	Test symbols: IRDY, ORDY
	Example: SF HSR,IRDY

	Sense function, named
	Syntax: SF{M\|A} {NOT} tests
	Test symbols: M: POK BOV LNK; A: SOV AOV
	Example: SFM NOT BOV

	Register to register
	Syntax: RR{C} src,{bus op,}dst
	Bus op symbols: P1, L1, R1
	Example: RRC AX,P1,AY

	Zero to register
	Syntax: ZR{C} {bus op,}dst
	Bus op symbols: P1, L1, R1
	Example: ZR P1,GR1

	Register to self
	Syntax: RS{C} dst{,bus op}
	Bus op symbols: P1, L1, R1
	Example: RS AX,L1

	Jump unconditional or named condition
	Syntax: J{U\|O\|N}{D} address
	Example: JUD 1400

	Jump conditional
	Syntax: JC{D} src,cond,address
	Cond symbols: NEVER,ALWAYS,ETZ,NEZ,LTZ,GEZ,LEZ,GTZ
	Example: JC AX,LEZ,200

	Register to memory
	syntax: RM{I\|D\|ID} src,{bus op,}address
	Bus op symbols: P1, L1, R1
	Example: RMD AX,P1,1315

	Zero to memory
	Syntax: ZM{I\|D\|ID} {bus op,}address
	Bus op symbols: P1, L1, R1
	Example: ZM P1,5502

	Memory to register
	Syntax: MR{I\|D\|ID} address,{bus op,}dst
	Bus op symbols: P1, L1, R1
	Example: MRI 1405,GR6

	Memory to self:
	Syntax: MS{I\|D\|ID} address{,bus op}
	Bus op symbols: P1, L1, R1
	Example: MS 3333,P1