754 lines
26 KiB
Plaintext
754 lines
26 KiB
Plaintext
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.\" $FreeBSD$
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.\" $OpenBSD: dc,v 1.2 2003/09/22 19:08:27 otto Exp $
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.\"
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.\" Copyright (C) Caldera International Inc. 2001-2002.
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.\" All rights reserved.
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.\"
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.\" Redistribution and use in source and binary forms, with or without
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.\" modification, are permitted provided that the following conditions
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.\" are met:
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.\" 1. Redistributions of source code and documentation must retain the above
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.\" copyright notice, this list of conditions and the following disclaimer.
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.\" 2. Redistributions in binary form must reproduce the above copyright
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.\" notice, this list of conditions and the following disclaimer in the
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.\" documentation and/or other materials provided with the distribution.
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.\" 3. All advertising materials mentioning features or use of this software
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.\" must display the following acknowledgement:
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.\" This product includes software developed or owned by Caldera
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.\" International, Inc.
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.\" 4. Neither the name of Caldera International, Inc. nor the names of other
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.\" contributors may be used to endorse or promote products derived from
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.\" this software without specific prior written permission.
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.\"
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.\" USE OF THE SOFTWARE PROVIDED FOR UNDER THIS LICENSE BY CALDERA
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.\" INTERNATIONAL, INC. AND CONTRIBUTORS ``AS IS'' AND ANY EXPRESS OR
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.\" IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES
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.\" OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED.
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.\" IN NO EVENT SHALL CALDERA INTERNATIONAL, INC. BE LIABLE FOR ANY DIRECT,
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.\" INDIRECT INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
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.\" (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR
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.\" SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
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.\" HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT,
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.\" STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING
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.\" IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
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.\" POSSIBILITY OF SUCH DAMAGE.
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.\"
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.\" @(#)dc 8.1 (Berkeley) 6/8/93
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.\"
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.EH 'USD:5-%''DC \- An Interactive Desk Calculator'
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.OH 'DC \- An Interactive Desk Calculator''USD:5-%'
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.\".RP
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.\" ....TM 75-1271-8 39199 39199-11
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.ND
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.TL
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DC \- An Interactive Desk Calculator
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.AU "MH 2C-524" 3878
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Robert Morris
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.AU
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Lorinda Cherry
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.AI
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.\" .MH
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.AB
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DC is an interactive desk calculator program implemented
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on the
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.UX
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time-sharing system to do arbitrary-precision
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integer arithmetic.
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It has provision for manipulating scaled fixed-point numbers and
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for input and output in bases other than decimal.
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.PP
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The size of numbers that can be manipulated is limited
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only by available core storage.
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On typical implementations of
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.UX ,
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the size of numbers that
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can be handled varies from several hundred digits on the smallest
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systems to several thousand on the largest.
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.AE
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.PP
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.SH
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.PP
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.ft I
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Editor's note: the description of the implementation details of DC in this
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paper is only valid for the original version of DC.
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The current version of DC uses a different approach.
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.ft
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.PP
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DC is an arbitrary precision arithmetic package implemented
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on the
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.UX
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time-sharing system
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in the form of an interactive desk calculator.
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It works like a stacking calculator using reverse Polish notation.
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Ordinarily DC operates on decimal integers, but one may
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specify an input base, output base, and a number of fractional
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digits to be maintained.
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.PP
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A language called BC [1] has been developed which accepts
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programs written in the familiar style of higher-level
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programming languages and compiles output which is
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interpreted by DC.
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Some of the commands described below were designed
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for the compiler interface and are not easy for a human user
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to manipulate.
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.PP
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Numbers that are typed into DC are put on a push-down
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stack.
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DC commands work by taking the top number or two
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off the stack, performing the desired operation, and pushing the result
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on the stack.
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If an argument is given,
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input is taken from that file until its end,
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then from the standard input.
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.SH
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SYNOPTIC DESCRIPTION
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.PP
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Here we describe the DC commands that are intended
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for use by people. The additional commands that are
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intended to be invoked by compiled output are
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described in the detailed description.
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.PP
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Any number of commands are permitted on a line.
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Blanks and new-line characters are ignored except within numbers
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and in places where a register name is expected.
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.PP
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The following constructions are recognized:
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.SH
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number
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.IP
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The value of the number is pushed onto the main stack.
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A number is an unbroken string of the digits 0-9
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and the capital letters A\-F which are treated as digits
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with values 10\-15 respectively.
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The number may be preceded by an underscore _ to input a
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negative number.
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Numbers may contain decimal points.
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.SH
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+ \- * % ^
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.IP
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The
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top two values on the stack are added
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(\fB+\fP),
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subtracted
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(\fB\-\fP),
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multiplied (\fB*\fP),
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divided (\fB/\fP),
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remaindered (\fB%\fP),
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or exponentiated (^).
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The two entries are popped off the stack;
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the result is pushed on the stack in their place.
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The result of a division is an integer truncated toward zero.
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See the detailed description below for the treatment of
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numbers with decimal points.
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An exponent must not have any digits after the decimal point.
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.SH
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s\fIx\fP
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.IP
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The
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top of the main stack is popped and stored into
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a register named \fIx\fP, where \fIx\fP may be any character.
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If
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the
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.ft B
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s
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.ft
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is capitalized,
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.ft I
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x
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.ft
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is treated as a stack and the value is pushed onto it.
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Any character, even blank or new-line, is a valid register name.
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.SH
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l\fIx\fP
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.IP
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The
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value in register
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.ft I
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x
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.ft
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is pushed onto the stack.
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The register
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.ft I
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x
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.ft
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is not altered.
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If the
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.ft B
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l
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.ft
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is capitalized,
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register
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.ft I
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x
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.ft
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is treated as a stack and its top value is popped onto the main stack.
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.LP
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All registers start with empty value which is treated as a zero
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by the command \fBl\fP and is treated as an error by the command \fBL\fP.
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.SH
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d
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.IP
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The
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top value on the stack is duplicated.
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.SH
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p
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.IP
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The top value on the stack is printed.
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The top value remains unchanged.
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.SH
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f
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.IP
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All values on the stack and in registers are printed.
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.SH
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x
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.IP
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treats the top element of the stack as a character string,
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removes it from the stack, and
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executes it as a string of DC commands.
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.SH
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[ ... ]
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.IP
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puts the bracketed character string onto the top of the stack.
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.SH
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q
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.IP
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exits the program.
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If executing a string, the recursion level is
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popped by two.
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If
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.ft B
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q
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.ft
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is capitalized,
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the top value on the stack is popped and the string execution level is popped
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by that value.
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.SH
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<\fIx\fP >\fIx\fP =\fIx\fP !<\fIx\fP !>\fIx\fP !=\fIx\fP
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.IP
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The
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top two elements of the stack are popped and compared.
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Register
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.ft I
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x
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.ft
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is executed if they obey the stated
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relation.
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Exclamation point is negation.
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.SH
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v
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.IP
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replaces the top element on the stack by its square root.
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The square root of an integer is truncated to an integer.
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For the treatment of numbers with decimal points, see
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the detailed description below.
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.SH
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!
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.IP
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interprets the rest of the line as a
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.UX
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command.
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Control returns to DC when the
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.UX
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command terminates.
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.SH
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c
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.IP
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All values on the stack are popped; the stack becomes empty.
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.SH
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i
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.IP
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The top value on the stack is popped and used as the
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number radix for further input.
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If \fBi\fP is capitalized, the value of
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the input base is pushed onto the stack.
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No mechanism has been provided for the input of arbitrary
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numbers in bases less than 1 or greater than 16.
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.SH
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o
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.IP
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The top value on the stack is popped and used as the
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number radix for further output.
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If \fBo\fP is capitalized, the value of the output
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base is pushed onto the stack.
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.SH
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k
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.IP
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The top of the stack is popped, and that value is used as
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a scale factor
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that influences the number of decimal places
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that are maintained during multiplication, division, and exponentiation.
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The scale factor must be greater than or equal to zero and
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less than 100.
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If \fBk\fP is capitalized, the value of the scale factor
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is pushed onto the stack.
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.SH
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z
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.IP
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The value of the stack level is pushed onto the stack.
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.SH
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?
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.IP
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A line of input is taken from the input source (usually the console)
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and executed.
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.SH
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DETAILED DESCRIPTION
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.SH
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Internal Representation of Numbers
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.PP
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Numbers are stored internally using a dynamic storage allocator.
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Numbers are kept in the form of a string
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of digits to the base 100 stored one digit per byte
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(centennial digits).
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The string is stored with the low-order digit at the
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beginning of the string.
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For example, the representation of 157
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is 57,1.
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After any arithmetic operation on a number, care is taken
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that all digits are in the range 0\-99 and that
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the number has no leading zeros.
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The number zero is represented by the empty string.
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.PP
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Negative numbers are represented in the 100's complement
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notation, which is analogous to two's complement notation for binary
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numbers.
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The high order digit of a negative number is always \-1
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and all other digits are in the range 0\-99.
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The digit preceding the high order \-1 digit is never a 99.
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The representation of \-157 is 43,98,\-1.
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We shall call this the canonical form of a number.
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The advantage of this kind of representation of negative
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numbers is ease of addition. When addition is performed digit
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by digit, the result is formally correct. The result need only
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be modified, if necessary, to put it into canonical form.
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.PP
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Because the largest valid digit is 99 and the byte can
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hold numbers twice that large, addition can be carried out
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and the handling of carries done later when
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that is convenient, as it sometimes is.
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.PP
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An additional byte is stored with each number beyond
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the high order digit to indicate the number of
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assumed decimal digits after the decimal point. The representation
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of .001 is 1,\fI3\fP
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where the scale has been italicized to emphasize the fact that it
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is not the high order digit.
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The value of this extra byte is called the
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.ft B
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scale factor
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.ft
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of the number.
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.SH
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The Allocator
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.PP
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DC uses a dynamic string storage allocator
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for all of its internal storage.
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All reading and writing of numbers internally is done through
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the allocator.
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Associated with each string in the allocator is a four-word header containing pointers
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to the beginning of the string, the end of the string,
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the next place to write, and the next place to read.
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Communication between the allocator and DC
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is done via pointers to these headers.
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.PP
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The allocator initially has one large string on a list
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of free strings. All headers except the one pointing
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to this string are on a list of free headers.
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Requests for strings are made by size.
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The size of the string actually supplied is the next higher
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power of 2.
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When a request for a string is made, the allocator
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first checks the free list to see if there is
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a string of the desired size.
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If none is found, the allocator finds the next larger free string and splits it repeatedly until
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it has a string of the right size.
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Left-over strings are put on the free list.
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If there are no larger strings,
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the allocator tries to coalesce smaller free strings into
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larger ones.
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Since all strings are the result
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of splitting large strings,
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each string has a neighbor that is next to it in core
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and, if free, can be combined with it to make a string twice as long.
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This is an implementation of the `buddy system' of allocation
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described in [2].
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.PP
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Failing to find a string of the proper length after coalescing,
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the allocator asks the system for more space.
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The amount of space on the system is the only limitation
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on the size and number of strings in DC.
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If at any time in the process of trying to allocate a string, the allocator runs out of
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headers, it also asks the system for more space.
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.PP
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There are routines in the allocator for reading, writing, copying, rewinding,
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forward-spacing, and backspacing strings.
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All string manipulation is done using these routines.
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.PP
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The reading and writing routines
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increment the read pointer or write pointer so that
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the characters of a string are read or written in
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succession by a series of read or write calls.
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The write pointer is interpreted as the end of the
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information-containing portion of a string and a call
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to read beyond that point returns an end-of-string indication.
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An attempt to write beyond the end of a string
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causes the allocator to
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allocate a larger space and then copy
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the old string into the larger block.
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.SH
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Internal Arithmetic
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.PP
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All arithmetic operations are done on integers.
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The operands (or operand) needed for the operation are popped
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from the main stack and their scale factors stripped off.
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Zeros are added or digits removed as necessary to get
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a properly scaled result from the internal arithmetic routine.
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For example, if the scale of the operands is different and decimal
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|
alignment is required, as it is for
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addition, zeros are appended to the operand with the smaller
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|
scale.
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|
After performing the required arithmetic operation,
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|
the proper scale factor is appended to the end of the number before
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it is pushed on the stack.
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|
.PP
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||
|
A register called \fBscale\fP plays a part
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|
in the results of most arithmetic operations.
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|
\fBscale\fP is the bound on the number of decimal places retained in
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|
arithmetic computations.
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|
\fBscale\fP may be set to the number on the top of the stack
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|
truncated to an integer with the \fBk\fP command.
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\fBK\fP may be used to push the value of \fBscale\fP on the stack.
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\fBscale\fP must be greater than or equal to 0 and less than 100.
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The descriptions of the individual arithmetic operations will
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include the exact effect of \fBscale\fP on the computations.
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.SH
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|
Addition and Subtraction
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||
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.PP
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The scales of the two numbers are compared and trailing
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zeros are supplied to the number with the lower scale to give both
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numbers the same scale. The number with the smaller scale is
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multiplied by 10 if the difference of the scales is odd.
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|
The scale of the result is then set to the larger of the scales
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of the two operands.
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.PP
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||
|
Subtraction is performed by negating the number
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to be subtracted and proceeding as in addition.
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|
.PP
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|
Finally, the addition is performed digit by digit from the
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low order end of the number. The carries are propagated
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in the usual way.
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|
The resulting number is brought into canonical form, which may
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|
require stripping of leading zeros, or for negative numbers
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|
replacing the high-order configuration 99,\-1 by the digit \-1.
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||
|
In any case, digits which are not in the range 0\-99 must
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be brought into that range, propagating any carries or borrows
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||
|
that result.
|
||
|
.SH
|
||
|
Multiplication
|
||
|
.PP
|
||
|
The scales are removed from the two operands and saved.
|
||
|
The operands are both made positive.
|
||
|
Then multiplication is performed in
|
||
|
a digit by digit manner that exactly mimics the hand method
|
||
|
of multiplying.
|
||
|
The first number is multiplied by each digit of the second
|
||
|
number, beginning with its low order digit. The intermediate
|
||
|
products are accumulated into a partial sum which becomes the
|
||
|
final product.
|
||
|
The product is put into the canonical form and its sign is
|
||
|
computed from the signs of the original operands.
|
||
|
.PP
|
||
|
The scale of the result is set equal to the sum
|
||
|
of the scales of the two operands.
|
||
|
If that scale is larger than the internal register
|
||
|
.ft B
|
||
|
scale
|
||
|
.ft
|
||
|
and also larger than both of the scales of the two operands,
|
||
|
then the scale of the result is set equal to the largest
|
||
|
of these three last quantities.
|
||
|
.SH
|
||
|
Division
|
||
|
.PP
|
||
|
The scales are removed from the two operands.
|
||
|
Zeros are appended or digits removed from the dividend to make
|
||
|
the scale of the result of the integer division equal to
|
||
|
the internal quantity
|
||
|
\fBscale\fP.
|
||
|
The signs are removed and saved.
|
||
|
.PP
|
||
|
Division is performed much as it would be done by hand.
|
||
|
The difference of the lengths of the two numbers
|
||
|
is computed.
|
||
|
If the divisor is longer than the dividend,
|
||
|
zero is returned.
|
||
|
Otherwise the top digit of the divisor is divided into the top
|
||
|
two digits of the dividend.
|
||
|
The result is used as the first (high-order) digit of the
|
||
|
quotient.
|
||
|
It may turn out be one unit too low, but if it is, the next
|
||
|
trial quotient will be larger than 99 and this will be
|
||
|
adjusted at the end of the process.
|
||
|
The trial digit is multiplied by the divisor and the result subtracted
|
||
|
from the dividend and the process is repeated to get
|
||
|
additional quotient digits until the remaining
|
||
|
dividend is smaller than the divisor.
|
||
|
At the end, the digits of the quotient are put into
|
||
|
the canonical form, with propagation of carry as needed.
|
||
|
The sign is set from the sign of the operands.
|
||
|
.SH
|
||
|
Remainder
|
||
|
.PP
|
||
|
The division routine is called and division is performed
|
||
|
exactly as described. The quantity returned is the remains of the
|
||
|
dividend at the end of the divide process.
|
||
|
Since division truncates toward zero, remainders have the same
|
||
|
sign as the dividend.
|
||
|
The scale of the remainder is set to
|
||
|
the maximum of the scale of the dividend and
|
||
|
the scale of the quotient plus the scale of the divisor.
|
||
|
.SH
|
||
|
Square Root
|
||
|
.PP
|
||
|
The scale is stripped from the operand.
|
||
|
Zeros are added if necessary to make the
|
||
|
integer result have a scale that is the larger of
|
||
|
the internal quantity
|
||
|
\fBscale\fP
|
||
|
and the scale of the operand.
|
||
|
.PP
|
||
|
The method used to compute sqrt(y) is Newton's method
|
||
|
with successive approximations by the rule
|
||
|
.EQ
|
||
|
x sub {n+1} ~=~ half ( x sub n + y over x sub n )
|
||
|
.EN
|
||
|
The initial guess is found by taking the integer square root
|
||
|
of the top two digits.
|
||
|
.SH
|
||
|
Exponentiation
|
||
|
.PP
|
||
|
Only exponents with zero scale factor are handled. If the exponent is
|
||
|
zero, then the result is 1. If the exponent is negative, then
|
||
|
it is made positive and the base is divided into one. The scale
|
||
|
of the base is removed.
|
||
|
.PP
|
||
|
The integer exponent is viewed as a binary number.
|
||
|
The base is repeatedly squared and the result is
|
||
|
obtained as a product of those powers of the base that
|
||
|
correspond to the positions of the one-bits in the binary
|
||
|
representation of the exponent.
|
||
|
Enough digits of the result
|
||
|
are removed to make the scale of the result the same as if the
|
||
|
indicated multiplication had been performed.
|
||
|
.SH
|
||
|
Input Conversion and Base
|
||
|
.PP
|
||
|
Numbers are converted to the internal representation as they are read
|
||
|
in.
|
||
|
The scale stored with a number is simply the number of fractional digits input.
|
||
|
Negative numbers are indicated by preceding the number with a \fB\_\fP (an
|
||
|
underscore).
|
||
|
The hexadecimal digits A\-F correspond to the numbers 10\-15 regardless of input base.
|
||
|
The \fBi\fP command can be used to change the base of the input numbers.
|
||
|
This command pops the stack, truncates the resulting number to an integer,
|
||
|
and uses it as the input base for all further input.
|
||
|
The input base is initialized to 10 but may, for example be changed to
|
||
|
8 or 16 to do octal or hexadecimal to decimal conversions.
|
||
|
The command \fBI\fP will push the value of the input base on the stack.
|
||
|
.SH
|
||
|
Output Commands
|
||
|
.PP
|
||
|
The command \fBp\fP causes the top of the stack to be printed.
|
||
|
It does not remove the top of the stack.
|
||
|
All of the stack and internal registers can be output
|
||
|
by typing the command \fBf\fP.
|
||
|
The \fBo\fP command can be used to change the output base.
|
||
|
This command uses the top of the stack, truncated to an integer as
|
||
|
the base for all further output.
|
||
|
The output base in initialized to 10.
|
||
|
It will work correctly for any base.
|
||
|
The command \fBO\fP pushes the value of the output base on the stack.
|
||
|
.SH
|
||
|
Output Format and Base
|
||
|
.PP
|
||
|
The input and output bases only affect
|
||
|
the interpretation of numbers on input and output; they have no
|
||
|
effect on arithmetic computations.
|
||
|
Large numbers are output with 70 characters per line;
|
||
|
a \\ indicates a continued line.
|
||
|
All choices of input and output bases work correctly, although not all are
|
||
|
useful.
|
||
|
A particularly useful output base is 100000, which has the effect of
|
||
|
grouping digits in fives.
|
||
|
Bases of 8 and 16 can be used for decimal-octal or decimal-hexadecimal
|
||
|
conversions.
|
||
|
.SH
|
||
|
Internal Registers
|
||
|
.PP
|
||
|
Numbers or strings may be stored in internal registers or loaded on the stack
|
||
|
from registers with the commands \fBs\fP and \fBl\fP.
|
||
|
The command \fBs\fIx\fR pops the top of the stack and
|
||
|
stores the result in register \fBx\fP.
|
||
|
\fIx\fP can be any character.
|
||
|
\fBl\fIx\fR puts the contents of register \fBx\fP on the top of the stack.
|
||
|
The \fBl\fP command has no effect on the contents of register \fIx\fP.
|
||
|
The \fBs\fP command, however, is destructive.
|
||
|
.SH
|
||
|
Stack Commands
|
||
|
.PP
|
||
|
The command \fBc\fP clears the stack.
|
||
|
The command \fBd\fP pushes a duplicate of the number on the top of the stack
|
||
|
on the stack.
|
||
|
The command \fBz\fP pushes the stack size on the stack.
|
||
|
The command \fBX\fP replaces the number on the top of the stack
|
||
|
with its scale factor.
|
||
|
The command \fBZ\fP replaces the top of the stack
|
||
|
with its length.
|
||
|
.SH
|
||
|
Subroutine Definitions and Calls
|
||
|
.PP
|
||
|
Enclosing a string in \fB[ ]\fP pushes the ascii string on the stack.
|
||
|
The \fBq\fP command quits or in executing a string, pops the recursion levels by two.
|
||
|
.SH
|
||
|
Internal Registers \- Programming DC
|
||
|
.PP
|
||
|
The load and store
|
||
|
commands together with \fB[ ]\fP to store strings, \fBx\fP to execute
|
||
|
and the testing commands `<', `>', `=', `!<', `!>', `!=' can be used to program
|
||
|
DC.
|
||
|
The \fBx\fP command assumes the top of the stack is an string of DC commands
|
||
|
and executes it.
|
||
|
The testing commands compare the top two elements on the stack and if the relation holds, execute the register
|
||
|
that follows the relation.
|
||
|
For example, to print the numbers 0-9,
|
||
|
.DS
|
||
|
[lip1+ si li10>a]sa
|
||
|
0si lax
|
||
|
.DE
|
||
|
.SH
|
||
|
Push-Down Registers and Arrays
|
||
|
.PP
|
||
|
These commands were designed for used by a compiler, not by
|
||
|
people.
|
||
|
They involve push-down registers and arrays.
|
||
|
In addition to the stack that commands work on, DC can be thought
|
||
|
of as having individual stacks for each register.
|
||
|
These registers are operated on by the commands \fBS\fP and \fBL\fP.
|
||
|
\fBS\fIx\fR pushes the top value of the main stack onto the stack for
|
||
|
the register \fIx\fP.
|
||
|
\fBL\fIx\fR pops the stack for register \fIx\fP and puts the result on the main
|
||
|
stack.
|
||
|
The commands \fBs\fP and \fBl\fP also work on registers but not as push-down
|
||
|
stacks.
|
||
|
\fBl\fP doesn't effect the top of the
|
||
|
register stack, and \fBs\fP destroys what was there before.
|
||
|
.PP
|
||
|
The commands to work on arrays are \fB:\fP and \fB;\fP.
|
||
|
\fB:\fIx\fR pops the stack and uses this value as an index into
|
||
|
the array \fIx\fP.
|
||
|
The next element on the stack is stored at this index in \fIx\fP.
|
||
|
An index must be greater than or equal to 0 and
|
||
|
less than 2048.
|
||
|
\fB;\fIx\fR is the command to load the main stack from the array \fIx\fP.
|
||
|
The value on the top of the stack is the index
|
||
|
into the array \fIx\fP of the value to be loaded.
|
||
|
.SH
|
||
|
Miscellaneous Commands
|
||
|
.PP
|
||
|
The command \fB!\fP interprets the rest of the line as a
|
||
|
.UX
|
||
|
command and passes it to
|
||
|
.UX
|
||
|
to execute.
|
||
|
One other compiler command is \fBQ\fP.
|
||
|
This command uses the top of the stack as the number of levels of recursion to skip.
|
||
|
.SH
|
||
|
DESIGN CHOICES
|
||
|
.PP
|
||
|
The real reason for the use of a dynamic storage allocator was
|
||
|
that a general purpose program could be (and in fact has been)
|
||
|
used for a variety of other tasks.
|
||
|
The allocator has some value for input and for compiling (i.e.
|
||
|
the bracket [...] commands) where it cannot be known in advance
|
||
|
how long a string will be.
|
||
|
The result was that at a modest
|
||
|
cost in execution time, all considerations of string allocation
|
||
|
and sizes of strings were removed from the remainder of the program
|
||
|
and debugging was made easier. The allocation method
|
||
|
used wastes approximately 25% of available space.
|
||
|
.PP
|
||
|
The choice of 100 as a base for internal arithmetic
|
||
|
seemingly has no compelling advantage. Yet the base cannot
|
||
|
exceed 127 because of hardware limitations and at the cost
|
||
|
of 5% in space, debugging was made a great deal easier and
|
||
|
decimal output was made much faster.
|
||
|
.PP
|
||
|
The reason for a stack-type arithmetic design was
|
||
|
to permit all DC commands from addition to subroutine execution
|
||
|
to be implemented in essentially the same way. The result
|
||
|
was a considerable degree of logical separation of the final
|
||
|
program into modules with very little communication between
|
||
|
modules.
|
||
|
.PP
|
||
|
The rationale for the lack of interaction between the scale and the bases
|
||
|
was to provide an understandable means of proceeding after
|
||
|
a change of base or scale when numbers had already been entered.
|
||
|
An earlier implementation which had global notions of
|
||
|
scale and base did not work out well.
|
||
|
If the value of
|
||
|
.ft B
|
||
|
scale
|
||
|
.ft
|
||
|
were to be interpreted in the current
|
||
|
input or output base,
|
||
|
then a change of base or scale in the midst of a
|
||
|
computation would cause great confusion in the interpretation
|
||
|
of the results.
|
||
|
The current scheme has the advantage that the value of
|
||
|
the input and output bases
|
||
|
are only used for input and output, respectively, and they
|
||
|
are ignored in all other operations.
|
||
|
The value of
|
||
|
scale
|
||
|
is not used for any essential purpose by any part of the program
|
||
|
and it is used only to prevent the number of
|
||
|
decimal places resulting from the arithmetic operations from
|
||
|
growing beyond all bounds.
|
||
|
.PP
|
||
|
The design rationale for the choices for the scales of
|
||
|
the results of arithmetic were that in no case should
|
||
|
any significant digits be thrown away if, on appearances, the
|
||
|
user actually wanted them. Thus, if the user wants
|
||
|
to add the numbers 1.5 and 3.517, it seemed reasonable to give
|
||
|
him the result 5.017 without requiring him to unnecessarily
|
||
|
specify his rather obvious requirements for precision.
|
||
|
.PP
|
||
|
On the other hand, multiplication and exponentiation produce
|
||
|
results with many more digits than their operands and it
|
||
|
seemed reasonable to give as a minimum the number of decimal
|
||
|
places in the operands but not to give more than that
|
||
|
number of digits
|
||
|
unless the user asked for them by specifying a value for \fBscale\fP.
|
||
|
Square root can be handled in just the same way as multiplication.
|
||
|
The operation of division gives arbitrarily many decimal places
|
||
|
and there is simply no way to guess how many places the user
|
||
|
wants.
|
||
|
In this case only, the user must
|
||
|
specify a \fBscale\fP to get any decimal places at all.
|
||
|
.PP
|
||
|
The scale of remainder was chosen to make it possible
|
||
|
to recreate the dividend from the quotient and remainder.
|
||
|
This is easy to implement; no digits are thrown away.
|
||
|
.SH
|
||
|
References
|
||
|
.IP [1]
|
||
|
L. L. Cherry, R. Morris,
|
||
|
.ft I
|
||
|
BC \- An Arbitrary Precision Desk-Calculator Language.
|
||
|
.ft
|
||
|
.IP [2]
|
||
|
K. C. Knowlton,
|
||
|
.ft I
|
||
|
A Fast Storage Allocator,
|
||
|
.ft
|
||
|
Comm. ACM \fB8\fP, pp. 623-625 (Oct. 1965).
|