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HOW TO RETURN index doc: PUT {} IN where FOR line.no IN keys doc: TREAT LINE RETURN where TREAT LINE: FOR word IN split doc[line.no]: IF word not.in keys where: PUT {} IN where[word] INSERT line.no IN where[word]
PROGRAM ONE WHEEL " Simple model of a dynamical system " written in ACSL 1, circa 1982. INITIAL CINTERVAL CINT = 0.05 ALGORITHM IALG = 4 $ "RK3" CONSTANT X1IO = 0.0, X2IO=0.0, X1DIC=0.0, X2DIC = 0.0 CONSTANT M1 = 25.0, M2=2.0, DF=100.0, K2=5000 CONSTANT TDONE = 15.0 K1 = 1000.0 END $ "OF INITIALIZATION" DYNAMIC DERIVATIVE X3= STEP(0.0) X1D = INTEG((-DF/M1)*(X1D-X2D) - (K1/M1)*(X1-X2), X1DIC) X2D = INTEG((-DF/M1)*(X1D-X2D) - (K1/M1)*(X1-X2), ... (K2/M2)*(X2-X3*5.0), X2DIC) X1 = INTEG(X1D,X1IO) X2 = INTEG(X2D,X2IO) END "OF DERIVATIVE SECTION" TERMT(T .GE. TDONE) END "OF DYNAMIC SECTION" END "OF PROGRAM"
-- simple programming with floating-point #s with Ada.Float_Text_IO; use Ada.Float_Text_IO; procedure Think is A, B : Float := 0.0; -- A and B initially zero; note the period. I, J : Integer := 1; begin A := B * 7.0; I := J * 3; B := Float(I) / A; Put(B); end Think;
/* An Alef program to parse numbers out of * the string returned from /dev/time, and * print them from a separate proc. This is * a rather lame conglomeration of several * examples from Bob Flandrea's Alef * User's Guide */ tuple(int, uint, byte*) strtoui(byte* str, int base) { int val; while(*str != 0 && whitespace(*str)) str ; if(str == nil || *str == 0) return(0, 0, str); while(*str && !whitespace(*str)) { if(!validdigit(*str, base)) return (-1, val, str 1); /* extract digit into val */ str ; } return(1, val, str); } void receive(chan(uint) c) { int s; s = <-c; print("%d\n", s); if (s == 0) terminate(nil); } void main(void) { chan(uint) c; alloc c; proc receive(c); int ret; uint val; int fd; byte *p, buf[128], *newp; fd = open("/dev/time", OREAD|OCEXEC); if (fd >= 0) { read(fd, buf, sizeof(buf)); for(p = buf; *p; p = newp) { (ret, val, newp) = strtoui(p, 10); if(ret >= 0) c <-= val; if(ret == 0) break; } } }
// the main program, calculate the mean of // some numbers begin integer N; Read Int(N); begin real array Data[1:N]; real sum, avg; integer i; sum:=0; for i:=1 step 1 until N do begin real val; Read Real(val); Data[i]:=if val<0 then -val else val end; for i:=1 step 1 until N do sum:=sum Data[i]; avg:=sum/N; Print Real(avg) end end
Here is a better example, written in the
Algol60 publication language, from
Jean Sammet courtesy of
Glyn Webster.
procedure problem (a, b); value a, b; integer a, b; begin integer k; real e; for k := 2 × (a ÷ 2) 1 step 2 until b do begin e := if prime(k) then sqrt(3 × k sin(k)) else sqrt(4 × k cos(k)); if prime(k) then putlist(k, e, 'prime') else putlist(k, e, 'nonprime') end end problem;
-- Use the Finder to close all applications -- (by Joshua D. Baer) property specialApps : {"Finder"} tell application "Finder" set allApps to name of processes end tell repeat with someParticularApp in allApps if specialApps does not contain someParticularApp then tell application someParticularApp activate quit end tell end if end repeat
;; Very simple example of interactive extension ;; for AutoCAD (Defun c:SF2ACRE () (setq SF (getreal "Enter area in square feet: ")) (setq AGREAGE (/ SF 43560.0)) (alert (strcat "\nThe area in acres is " (rtos ARGEAGE 2 2))) )
BEGIN { if ("'$#argv'"==1) Col="'$1'"; else Col=1 } {Total = $Col; }; END { printf "Total for column %d with %d items: %d\n", Col,NR,Total }
class ACCOUNT feature balance: INTEGER; owner: PERSON; minimum_balance: INTEGER is 1000 open (who: PERSON) is -- Assign the account to owner who. do owner := who end deposit (sum: INTEGER) is -- Deposit sum into the account. do add (sum) end withdraw (sum: INTEGER) is -- Withdraw sum from the account. do add (-sum) end may_withdraw (sum: INTEGER): BOOLEAN is -- Is there enough money to withdraw sum? do Result := (balance >= sum + minimum_balance) end feature {NONE} add (sum: INTEGER) is -- Add sum to the balance. do balance := balance + sum end end -- class ACCOUNT
;; Simple Elisp example (defconst date-pattern-1 "\\(1?[0-9]\\)/\\([123]?[0-9]\\)/\\([0-9][0-9]\\)" "Regexp for one style of data string") (defun replace-all-dates () "Replace 1/27/93 dates with 27-1-93 dates" (interactive) (let ((mcount 0)) (while (re-search-forward date-pattern-1 nil t) (replace-match "\\2-\\1-\\3" nil nil) (setq mcount (+ 1 mcount))) (message (format "Replaced %d dates" mcount))) )
-module(sort). -export([sort/1]). sort([]) -> []; sort([Pivot|Rest]) -> {Smaller, Bigger} = split(Pivot, Rest), lists:append(sort(Smaller), [Pivot|sort(Bigger)]). split(Pivot, L) -> split(Pivot, L, [], []). split(Pivot, [], Smaller, Bigger) -> {Smaller, Bigger}; split(Pivot, [Hd|Tl], Smaller, Bigger) when Hd < Pivot -> split(Pivot, Tl, [Hd|Smaller], Bigger); split(Pivot, [Hd|Tl], Smaller, Bigger) when Hd >= Pivot -> split(Pivot, T, Smaller, [Hd|Bigger]).
Alternative version using Erlang 4.4 features:
-module(sort). -export([sort/1]). sort([Pivot|T]) -> sort([ X || X <- T, X < Pivot]) ++ [Pivot] ++ sort([ X || X <- T, X >= Pivot]); sort([]) -> [].
MODULE Lambda. CONSTRUCT Person/0. FUNCTION Jane, Mary, John: One -> Person. FUNCTION Mother : Person * Person -> Boolean. Mother(x,y) => x=Jane & y=Mary. FUNCTION Wife : Person * Person -> Boolean. Wife(x,y) => x=John & y=Jane. FUNCTION PrimitiveRel : (Person * Person -> Boolean) -> Boolean. PrimitiveRel(r) => r=Mother \/ r=Wife. FUNCTION Rel : (Person * Person -> Boolean) -> Boolean. Rel(r) => PrimitiveRel(r) \/ (SOME [r1,r2] (r = LAMBDA [u] (SOME [z] (r1(Fst(u),z) & r2(z,Snd(u)))) & PrimitiveRel(r1) & PrimitiveRel(r2))).
module AVERAGE: input INCREMENT_AVERAGE(integer); output AVERAGE_VALUE(integer); var TOTAL := 0, NUMBER := 0, : integer in every immediate INCREMENT_AVERAGE do TOTAL := TOTAL + ? INCREMENT_AVERAGE; NUMBER := NUMBER + 1; emit AVERAGE_VALUE (TOTAL / NUMBER) end end.
-- Prime sieve benchmark, adapted from Euphoria 2.0beta demos constant ON = 1, OFF = 0, SIZE = 5000, BATCH = 20 function sieve() sequence flags integer prime, start, count, still_prime count = 0 flags = repeat(ON, SIZE) for i = 1 to SIZE do still_prime = flags[i] if still_prime then prime = 2 * i prime = prime + 1 start = prime + i for k = start to SIZE by prime do flags[k] = OFF end for count = count + 1 end if end for return count end function atom t, cycles, p cycles = 0 t = time() while time() < t + 30 do -- test for 30 seconds for iter = 1 to BATCH do p = sieve() end for cycles = cycles + BATCH end while t = time() - t printf(1, "%6.1f sieves per second\n", cycles / t)
func cmplxplot(z, u) /* DOCUMENT cmplxplot, z, u * plots a scalar complex function of a complex variable. */ { resx=100; resy=100; s=[[sqrt(2./3.),0,1/sqrt(3)],[-1/sqrt(2*3.0),1/sqrt(2.),1/sqrt(3)], [-1/sqrt(2*3.0),-1/sqrt(2.),1/sqrt(3)]]; phi=span(-pi,pi,256); vec=array(double,3,256); vec(1,)=cos(phi); vec(2,)=sin(phi); vec(3,)=1/sqrt(2)(-); f=s(+,)*vec(+,); palette,bytscl(f(2,),top=255),bytscl(f(1,),top=255),bytscl(f(3,),top=255); xmin=min(u.re); xmax=max(u.re); ymin=min(u.im); ymax=max(u.im); zi=array(complex,resx,resy); zi.re=interp2(span(ymin,ymax,resy)(-:1:resx,),span(xmin,xmax,resx)(,-:1:resy), z.re,u.im,u.re); zi.im=interp2(span(ymin,ymax,resy)(-:1:resx,),span(xmin,xmax,resx)(,-:1:resy), z.im,u.im,u.re); // Caution: on some platforms atan(0,0) crashes ! arr=bytscl(atan(zi.im,zi.re+1e-200),cmin=-pi,cmax=pi); pli,arr, xmin,ymin,xmax,ymax; plc,abs(z),u.im,u.re,marks=0; }
{ Table data structure, adapted from an example in "Multiparadigm Data Structures in Leda" by Tim Budd, 1993 Assumes the list data structure is already defined. } class Association [X, Y : equality] of equality[Association]; var key : X; value : Y; function equals(argValue : Association[X, Y])->boolean; begin return key = argValue.key; end; end; class Table [X, Y : equality] { of equality[Association] }; var data : List[Association[X, Y]]; function add (newKey : X, newValue : Y); begin if ~ defined(data) then data := List[Association[X, Y]](); data.add(Association[X, Y](newKey, newValue)); end; function onEach (theFun : function(X, Y)); begin if defined(data) then data.onEach(function (item : Association[X, Y]); begin theFun(item.key, item.value); end); end; function items (byRef key : X, byRef value : Y)->relation; var element : Association[X, Y]; begin return defined(data) & data.items(element) & unify[X](key, element.key) & unify[Y](value, element.value); end; function includesKey (key : X)->boolean; var value : Y; begin if items(key, value) then return true; return false; end; function at (key : X)->Y; var value : Y; begin if items(key, value) then return value; return NIL; end; function atPut (key : X, value : Y); var element : Association[X, Y]; begin if defined(data) & data.items(element) & element.key = key then element.value := value else add(key, value); end; end;
global(sieve)? global(limit)? main :- write("N=?"), read_token(limit & int), next_prime(2), nl. remove_multiples(P,M) :- cond(M < limit, (sieve.M <-multiple_of(P),remove_multiples(P,M+P)) ). next_prime(P) :- P < limit, !, SP=sieve.P, ( SP=prime(P), !, write(P,' '), remove_multiples(P,2*P) ; succeed ), next_prime(P+1). next_prime(P).
# A simple program to sum up some numbers # presented on the command line, from # Bob Pike's forthcoming book on Limbo. implement Sum; include "sys.m"; sys: Sys; include "draw.m"; Sum: module { init: fn(context: ref Draw->Context, argl: list of string); }; init(context: ref Draw->Context, argl: list of string) { sys = load Sys Sys->PATH; argl = tl argl; # ignore command name if(len argl == 0){ sys->print("usage: sum numbers....\n"); return; } sum := 0.0; while(argl != nil){ arg := hd argl; sys->print("%s", arg); sum += real arg; argl = tl argl; if(argl != nil) sys->print(" + "); } sys->print(" = %g\n", sum); }
;; Simple factorial routine ;; (until I get a better example written) (defun fact1 (num) (cond ((not (integerp num)) nil) ((<= num 1) 1) (t (* num (fact1 (- num 1))))) )
; Recursive procedure to line, fractalized to DrawFractalLine :level :length ifelse :level < 1 [ fd :length] [ DrawFractalLine (sum -1 :level) (quotient :length 3.00) left 60 DrawFractalLine (sum -1 :level) (quotient :length 3.00) right 120 DrawFractalLine (sum -1 :level) (quotient :length 3.00) left 60 DrawFractalLine (sum -1 :level) (quotient :length 3.00) ] end ; procedure to clear screen and position turtle to SetupTurtle cs setpos [-160 -10] right 60 clean end ; setup turtle then draw Koch's snowflake(5) SetupTurtle setpensize [2 2] repeat 3 [DrawFractalLine 5 330 right 120]
' Find agents owned by the current user ' and remove them (Adapted from examples at ' www.lotus.com) Dim session As New NotesSession Dim db As NotesDatabase Dim agentArray(1 To 10) As NotesAgent Dim count as Integer Dim answer as string count = 0 Set db = session.CurrentDatabase Forall a In db.Agents If ( a.Owner = session.UserName ) Then Set agentArray(count) = a count = count + 1 If (count > 10) Then Exit Forall End If End If End Forall answer = Inputbox$( "You have " & count & " agents. Delete them?" ) If (answer = "y") Or (answer = "yes") Then Forall a in agentArray Call a.Remove End Foreall End If
-- Simple Lua program that implements the -- bisection method for solving non-linear equations function bisect(f,a,b,fa,fb) write(n," a=",a," fa=",fa," b=",b," fb=",fb,"\n") local c=(a+b)/2 if abs(a-b) < delta then return c end n=n+1 local fc=f(c) if fa*fc < 0 then return bisect(f,a,c,fa,fc) else return bisect(f,c,b,fc,fb) end end -- find root of f in the inverval [a,b]. -- bisection requires that f(a)*f(b) < 0 function solve(f,a,b) delta=1e-6 -- tolerance n=0 local z=bisect(f,a,b,f(a),f(b)) write(format("after %d steps, root is %.10g\n",n,z)) end -- test the bisection code with -- a function: x^3 - x - 1 function f(x) return x*x*x - x - 1 end solve(f,1,2)
h where h = 1 fby merge(merge(2 * h, 3 * h), 5 * h); merge(x,y) = if xx <= yy then xx else yy fi where xx = x upon xx <= yy; yy = y upon yy <= xx; end; end;
/* A program to count words in input files * (from examples at the ICI web site) */ static count_tokens(in) { auto count; count = 0; while (gettoken(in)) ++count; return count; } if (argc < 2) printf("%d\n", count_tokens(stdin)); else { auto f, fn, total; total = 0; forall (fn in interval(argv, 1)) { if (fn == "-") count = count_tokens(stdin); else { auto count; count = count_tokens(f = fopen(fn)); close(f); } printf("%s %d\n", fn, count); total += count; } if (argc > 2) printf("Total %d\n", total); }
# Example from New Mexico Tech Icon # tutorial by John Shipman procedure Quadratic_Roots ( a, b, c ) # Generates the real roots of ax^2+bx+c=0. local d # Discriminant d := b ^ 2 - 4.0 * a * c; # Compute the discriminant if d > 0 then { #-- Two roots suspend ( - b + sqrt ( d ) ) / ( 2.0 * a ); suspend ( - b - sqrt ( d ) ) / ( 2.0 * a ); } #-- Two roots else if d = 0 then suspend - b / ( 2.0 * a ); fail; # No more roots end procedure main () local root # Holds each root generated by the solver local count # Counts the number of roots returned count := 0; every root := Quadratic_Roots ( 1, -4, 3 ) do { #-- The braces {} group the next two statements together write ( "One solution is: x = ", root ); count +:= 1; # Count the roots generated } write ( "The number of solutions was ", count ); end
INTERCAL's main advantage over other programming languages is its simplicity. It has few capabilities, and thus there are few restrictions to be kept in mind. Since it is an exceedingly easy language to learn, one might expect it would be a good language for initiating novice programmers. Perhaps surprising, than [sic], is the fact that it would be more likely to initiate the novice into a search for another line of work.
PLEASE NOTE THIS PROGRAM PRINTS A LIST PLEASE DO NOT ASSUME THAT THE NUMBERS ARE COMPOSITE PLEASE NOTE THIS PROGRAM WAS SWIPED FROM LOUIS HOWELL DO READ OUT #2 DO .10 <- #1 PLEASE COME FROM (23) DO .11 <- !10$#1'~'#32767$#1' DO .12 <- #1 PLEASE COME FROM (16) DO .13 <- !12$#1'~'#32767$#1' DO .1 <- .11 DO .2 <- .13 DO (2030) NEXT DO (11) NEXT (15) DO (13) NEXT (13) DO .3 <- "?!4~.4'$#2"~#3 DO (14) NEXT PLEASE FORGET #1 DO .1 <- .12 DO (1020) NEXT (16) DO .12 <- .1 (12) DO .3 <- '?.2$.3'~'#0$#65535' DO .3 <- '?"'&"!2~.3'~'"?'?.3~.3'$#32768"~"#0$#65535"'"$ ".3~.3"'~#1"$#2'~#3 (14) PLEASE RESUME .3 (11) DO (12) NEXT DO FORGET #1 PLEASE READ OUT .11 DO COME FROM (15) DO .1 <- .10 DO (1020) NEXT DO .10 <- .1 (23) DO (21) NEXT (22) PLEASE RESUME "?!10~#32768'$#2"~#3 (21) DO (22) NEXT DO FORGET #1 PLEASE GIVE UP (2010) PLEASE ABSTAIN FROM (2004) (2000) PLEASE STASH .2 DO .2 <- #1 DO (2001) NEXT (2001) PLEASE FORGET #1 DO .1 <- '?.1$.2'~'#0$#65535' DO (2002) NEXT DO .2 <- !2$#0'~'#32767$#1' DO (2001) NEXT (2003) PLEASE RESUME "?!1~.2'$#1"~#3 (2002) DO (2003) NEXT PLEASE RETRIEVE .2 (2004) PLEASE RESUME #2 PLEASE DO REINSTATE (2004) PLEASE RESUME '?"!1~.1'~#1"$#2'~#6 (2020) PLEASE STASH .2 + .3 DO (1021) NEXT (2030) DO STASH .1 + .5 DO .3 <- #0 DO .5 <- '?"!2~.2'~#1"$#1'~#3 PLEASE DO (2031) NEXT DO .4 <- #1 PLEASE DO (2033) NEXT (2033) DO FORGET #1 DO .5 <- '?".2~#32768"$#2'~#3 DO (2032) NEXT DO .2 <- !2$#0'~'#32767$#1' PLEASE DO .4 <- !4$#0'~'#32767$#1' DO (2033) NEXT (2032) DO (1001) NEXT (2036) PLEASE FORGET #1 DO .5 <- '?.1$.2'~'#0$#65535' DO .5 <- '?"'&"!2~.5'~'"?'?.5~.5'$#32768"~"#0$#65535"'"$ ".5~.5"'~#1"$#2'~#3 DO (2034) NEXT DO .5 <- .3 DO (1010) NEXT PLEASE DO .1 <- .3 DO .3 <- 'V.4$.5'~'#0$#65535' DO (2035) NEXT (2034) PLEASE DO (1001) NEXT (2035) DO FORGET #1 DO .5 <- "?'.4~#1'$#2"~#3 DO (2031) NEXT DO .2 <- .2~#65534 DO .4 <- .4~#65534 PLEASE DO (2036) NEXT (2031) DO (1001) NEXT PLEASE DO .4 <- .1 PLEASE RETRIEVE .1 + .5 PLEASE RESUME #2
# Some S code to plot concentric convex hulls # around some data, from the documentation for # the chull function. drawhull <- function(xvec, yvec, ltype) { polygon(xvec, yvec, density=0, lty=ltype) } p <- chull(corn.rain, corn.yield, peel=T) which <- rep(seq(p$count), p$count) s <- split(p$hull, which) plot(corn.rain, corn.yield, pch="X") for(i in seq(s)) { j <- s[[i]] if (length(j) > 2) drawhull(corn.rain[j], corn.yield[j], i) }
-- Still working on a good code example here... -- A simple class from the Sather Essential manual class POINT is attr x,y:INT; create(x,y:INT):POINT is res:POINT := new; res.x := x; res.y := y; return res; end; add(xval,yval:INT):POINT is xsum:INT := x xval; ysum:INT := y yval; res:POINT := #POINT(xsum, ysum); return res; end; offset_by(val:INT):POINT is return add(val,val); end; end;
;;; takes two sorted lists merges them (define (merge! a b less?) (define (loop r a b) (if (less? (car b) (car a)) (begin (set-cdr! r b) (if (null? (cdr b)) (set-cdr! b a) (loop b a (cdr b)) )) ;; (car a) <= (car b) (begin (set-cdr! r a) (if (null? (cdr a)) (set-cdr! a b) (loop a (cdr a) b)) )) ) (cond ((null? a) b) ((null? b) a) ((less? (car b) (car a)) (if (null? (cdr b)) (set-cdr! b a) (loop b a (cdr b))) b) (else ; (car a) <= (car b) (if (null? (cdr a)) (set-cdr! a b) (loop a (cdr a) b)) a)))
$ A SETL program to do the sieve of $ Erastothenes (probably badly, but its my first $ SETL program) program sieve; read(mx); primes := {}; (for x in [3..mx] | odd x) primes with:= x; end; (for x in [3..ceil(mx / 2)] | odd x) primes := sieve1(x, primes); end; print(primes); proc sieve1(rd n, rd pset); (for x in pset | n < x and x mod n = 0) pset less:= x; end; return pset; end proc sieve1; end program sieve;
#!/bin/sh # Simple shell script to count files of size # greater than 1k if [ -z "$1" ] then pat="*" else pat="$1" fi cnt=0 for fname in $pat do if [ -r $fname -a ! -d $fname ] then size=`cat $fname | wc -c` if [ $size -gt 1024 ] then echo $fname ' ' $size cnt=`expr $cnt 1` fi fi done echo "${pat}: Files bigger than 1K: $cnt" exit
Preamble '' A simple telephone system model - CACI Products Company '' files: TELPHN1.SRC Normally mode is integer Processes include GENERATOR Every INCOMING.CALL has a CALL.ID Define NUMBER.BUSY and LOST.CALLS as integer variables End ''Preamble Main Activate a GENERATOR now Start simulation Print 1 line with LOST.CALLS thus 15 phone calls were made and ** were lost due to busy lines End ''Main Process GENERATOR For I = 1 to 15 do Activate a INCOMING.CALL now Let CALL.ID(INCOMING.CALL) = I Wait uniform.f (2.0, 6.0, 1) minutes Loop End ''GENERATOR Process INCOMING.CALL If NUMBER.BUSY < 2 Add 1 to NUMBER.BUSY Wait uniform.f(6.0, 10.0, 2) minutes Subtract 1 from NUMBER.BUSY Else Add 1 to LOST.CALLS Endif End ''INCOMING.CALL
Class Line(a,b,c); real a,b,c; begin boolean procedure parallelto(l); ref(Line) l; if l =/= none then parallelto := abs(a*l.b - b* l.a) < 0.00001; ref(Point) procedure meets(l); ref(Line) l; begin real t; if l =/= none and ~parallelto(l) then begin t := 1/(l.a * b - l.b * a); *** complicated expressions omitted below *** meets :- new Point(..., ...); end; end; ***meets*** real d; d := sqrt(a**2 b**2); if d = 0.0 then error else begin d := 1/d; a := a * d; b := b * d; c := c * d; end; end *** Line***
// an example from the Sina/st 3.1 distribution main comment ' Bring a salute to our globe'; temps hello: HelloWorld; begin hello.show end // main #Category 'Sina-Hello world'; class HelloWorld interface methods show returns nil; inputfilters disp: Dispatch = {inner.*}; end; // interface HelloWorld class HelloWorld implementation methods show begin self.printLine('Hello, world!'); return end; // show end; // implementation HelloWorld
% A simple example of using SISAL arrays, % adapted from various sample exercises in the % SISAL tutorial by John Feo. define main type Matrix = array [ array [ real ] ] % generate a square matrix where element [n,m] % is set to n m function gensquare(siz : integer returns Matrix ) for i in 1,siz cross j in 1,siz returns array of real(i) real(j) end for end function % perform one step of a relaxation, average each % element with its eight nearest neighbors function relax ( a : Matrix returns Matrix ) for row in a at i cross elt in row at j avg := (elt a[i, j-1] a[i, j 1] a[i 1, j-1] a[i 1, j] a[i 1, j 1] a[i-1, j-1] a[i-1, j] a[i-1, j 1]) / 9.0 returns array of avg end for end function % test the generator and relax function function main(returns Matrix) let a1 := gensquare(5) in a1 end let end function
GEN, PEGDEN, SERIAL WORK AREAS QUEUE MODEL, 7/14/77, 1; LIMITS,2,1,50; NETWORK; CREATE, EXPON(.4), , 1; QUEUE(1), 0, 4, BALK(SUB); ACT/1,EXPON(0.25); QUEUE(2), 0, 2, BLOCK; ACT/2,EXPON(0.50); COLCT, INT(1), TIME IN SYSTEM, 20/0/.25 TERM; SUB COLCT,BET,TIME BETWEEN BALKS; TERM; INIT,0,300; FIN;
' Smalltalk class to constraint a 2D point to a fixed grid ' (from Horan & Hopkins, Smalltalk: An Introduction...) Point subclass: #GriddedPoint instanceVariableNames: '' classVariableNames: '' poolDictionaries: '' category: 'Exercise11.5'! !GriddedPoint methodsFor: 'accessing'! x: xInteger "Set the x coordinate gridded to 10 (using rounding, alternatively I could use truncating)." super x: (xInteger roundTo: 10)! y: yInteger "Set the y coordinate gridded to 10 (using rounding, alternatively I could use truncating)." super y: (yInteger roundTo: 10)! ! !GriddedPoint methodsFor: 'private'! setX: xPoint setY: yPoint "Initialize the instance variables rounding to 10." super setX: (xPoint roundTo: 10) setY: (yPoint roundTo: 10)! !
* Find biggest words and numbers in a test string * (from Griswold,Poage,& Polonsky, 1971) BIGP = (*P $ TRY *GT(SIZE(TRY,SIZE(BIG))) $ BIG FAIL STR = 'IN 1964 NFL ATTENDANCE JUMPED TO 4,807884; ' 'AN INCREASE OF 401,810.' P = SPAN('0123456789,') BIG = STR BIGP OUTPUT = 'LONGEST NUMBER IS ' BIG P = SPAN('ABCDEFGHIJKLMNOPQRSTUVWXYZ') BIG = STR BIGP OUTPUT = 'LONGEST WORD IS ' BIG END
{ Sort program adapted from "Intermediate Pascal" } { by Joe Dorward. Illustrates arrays and types. } program sort_array(input,output); const max = 9; type integer_array = array[1..max] of integer; var I, J, K, swaps, temp : integer; test_array : integer_array; begin test_array[1] := 4; test_array[2] := 7; test_array[3] := 9; test_array[4] := 3; test_array[5] := 15; test_array[6] := 2; test_array[7] := 08; test_array[8] := 05; test_array[9] := 12; writeln(' *** Initial Array ***'); writeln(' --- --- --- --- --- --- --- --- --- '); for I := 1 to (max-1) do write('|',test_array[I]:2,' '); writeln('|',test_array[max]:2,' |'); for I := 1 to max do for J := (I 1) to max do { set J to start one ahead of I } if test_array[J] < test_array[I] then begin swaps := swaps 1; temp := test_array[J]; test_array[J] := test_array[I]; test_array[I] := temp; writeln; writeln('* * Condition After ',swaps:1,' swaps * *'); writeln(' --- --- --- --- --- --- --- --- --- '); for K := 1 to (max-1) do write('|',test_array[K]:2,' '); write('|',test_array[max]:2,' |'); end; writeln(' * Sorting Complete *'); end.
#!/usr/bin/perl # Simple program to extract column 3 from a file # and total up the numbers. $total = 0; sub sumcolumn { my $col = shift; my $lin = shift; my @fields; if ($lin) { @fields = split(/:/,$lin); $total = $fields[2]; } } while (<>) { sumcolumn(3,$_); } print "Total of column 3 is $total\n";
<?
mysql_connect("localhost","","") or die("Unable to connect to SQL server");
@mysql_select_db("php3") or die("Unable to select database");
$result = mysql_query("select * from customerTable limit 100");
?>
<table border="1">
<tr>
<?
while ($field=mysql_fetch_field($result)) {
echo "<th>";
echo "$field->name";
echo "</th>";
}
echo "</tr>";
while ($row = mysql_fetch_row($result)) {
echo "<tr>";
for ($i=0; $i<mysql_num_fields($result); $i ) {
echo "<td>";
echo "$row[$i]";
echo "</td>";
}
echo "</tr>\n";
}
echo "</table>";
The example below implements the Sieve of Erastosthenes (from the examples shipped with Pict 4.1).
now (reset checks) def interval (min:Int max:Int):(List Int) = if (>> min max) then nil else (cons min (interval (inc min) max)) def sieve (max:Int):(List Int) = ( def again (l:(List Int)):(List Int) = if (null l) then nil else (val n = (car l) if (>> (* n n) max) then l else (cons n (again (list.filter #Int l \(x) = (<> (mod x n) 0))))) (again (interval 2 max)) ) def prPrime (idx:Int x:Int):[] = if (== (mod idx 10) 9) then ((int.pr x); (nl)) else ((int.pr x); (pr " ")) (list.itApply (sieve 4000) prPrime);
// This program implements a fifo that can be used to send // data between two threads. (From the Pike 0.6 manual, sec 10) inherit Thread.Condition : r_cond; inherit Thread.Condition: w_cond; inherit Thread.Mutex: lock; mixed *buffer = allocate(128); int r_ptr, w_ptr; int query_messages() { return w_ptr - r_ptr; } // This function reads one mixed value from the fifo. // If no values are available it blocks until a write has been done. mixed read() { mixed tmp; object key=lock::lock(); while(!query_messages()) r_cond::wait(key); tmp=buffer[r_ptr % sizeof(buffer)]; w_cond::signal(); return tmp; } // This function pushes one mixed value on the fifo. // If the fifo is full it blocks until a value has been read. void write(mixed v) { object key=lock::lock(); while(query_messages() == sizeof(buffer)) w_cond::wait(key); buffer[w_ptr % sizeof(buffer)]=v; r_cond::signal(); }
R : An example for converting a number to english *LOOP T :ENTER A NUMBER, OR ZERO TO QUIT. C :$NUM= A :#Z E(Z=0) : U :*WRITNUM T :$NUM : J :*LOOP *WRITNUM U(Z<10) :*UNITS E(Z<10) : J(Z>999):*THOU J(Z>99) :*HUND J(Z>19) :*TWENTY C(Z=10) :$NUM=$NUM TEN C(Z=11) :$NUM=$NUM ELEVEN C(Z=12) :$NUM=$NUM TWELVE C(Z=13) :$NUM=$NUM THIRTEEN C(Z=14) :$NUM=$NUM FOURTEEN C(Z=15) :$NUM=$NUM FIFTEEN C(Z=16) :$NUM=$NUM SIXTEEN C(Z=17) :$NUM=$NUM SEVENTEEN C(Z=18) :$NUM=$NUM EIGHTEEN C(Z=19) :$NUM=$NUM NINETEEN E: *UNITS C(Z=1) :$NUM=$NUM ONE C(Z=2) :$NUM=$NUM TWO C(Z=3) :$NUM=$NUM THREE C(Z=4) :$NUM=$NUM FOUR C(Z=5) :$NUM=$NUM FIVE C(Z=6) :$NUM=$NUM SIX C(Z=7) :$NUM=$NUM SEVEN C(Z=8) :$NUM=$NUM EIGHT C(Z=9) :$NUM=$NUM NINE E: *TWENTY C:Y=Z%10 C:Z=Z-Y C(Z=20) :$NUM=$NUM TWENTY C(Z=30) :$NUM=$NUM THIRTY C(Z=40) :$NUM=$NUM FORTY C(Z=50) :$NUM=$NUM FIFTY C(Z=60) :$NUM=$NUM SIXTY C(Z=70) :$NUM=$NUM SEVENTY C(Z=80) :$NUM=$NUM EIGHTY C(Z=90) :$NUM=$NUM NINETY C:Z=Y E(Z=0) : J:*WRITNUM *HUND C :Y=Z%100 C :Z=(Z-Y)/100 U :*UNITS C :$NUM=$NUM HUNDRED C :Z=Y E(Z=0) : J :*WRITNUM *THOU C :X=Z%1000 C :Z=(Z-X)/1000 U :*WRITNUM C :$NUM=$NUM THOUSAND C :Z=X E(Z=0) : J :*HUND
FINDSTRINGS: PROCEDURE OPTIONS(MAIN) /* READ A STRING, THEN PRINT EVERY */ /* SUBSEQUENT LINE WITH A MATCH */ DECLARE PAT VARYING CHARACTER(100), LINEBUF VARYING CHARACTER(100), (LINENO, NDFILE, IX) FIXED BINARY; NDFILE = 0; ON ENDFILE(SYSIN) NDFILE=1; GET EDIT(PAT) (A); LINENO = 1; DO WHILE (NDFILE=0); GET EDIT(LINEBUF) (A); IF LENGTH(LINEBUF) > 0 THEN DO; IX = INDEX(LINEBUF, PAT); IF IX > 0 THEN DO; PUT SKIP EDIT (LINENO,LINEBUF)(F(2),A) END; END; LINENO = LINENO 1; END; END FINDSTRINGS;
%!PS-Adobe-2.0 % Draw a string at an angle at a point /printat { % str x y angle => - gsave 4 1 roll translate exch rotate 0 0 moveto show grestore } def % find the center of the page /pagecenter { % - => cx cy clippath pathbbox 4 1 roll exch sub 2. div 3 1 roll sub 2. div } def % set up font and constants /Times-Bold findfont 36 scalefont setfont pagecenter /cy exch def /cx exch def /steps 9 def /basegray 0.75 def /incrgray basegray steps div def /baseangle 360 steps div def /incrangle 360 steps div def % draw a string as a rosette steps { basegray setgray (PostScript) cx cy baseangle printat /basegray basegray incrgray sub def /baseangle baseangle incrangle add def } repeat % done with this page showpage
% Quicksort in Prolog, by Keesey adapted from Bratko gtq(X,Y) :- X @> Y. quicksort( [],[] ). quicksort( [X | Tail], Sorted) :- split( X, Tail, Small, Big), quicksort( Small, SortedSmall), quicksort( Big, SortedBig), conc( SortedSmall, [X | SortedBig], Sorted). split( _, [], [], []). split( X,[Y | Tail], [Y | Small], Big) :- gtq( X, Y),!, split( X, Tail, Small, Big). split( X, [Y | Tail], Small, [Y | Big] ) :- split( X, Tail, Small, Big). conc([],L,L). conc( [X | L1], L2, [X | L3]) :- conc( L1, L2, L3).
# standard binary search tree from # a tree data structure package by Dan Stubbs # class binary_tree: def __init__ (self): self.tree = None def insert (self, key): if self.tree: self._insert (self.tree, key) else: self.tree = node(key) def _insert (self, tree, key): if key < tree.key: if tree.left: self._insert (tree.left, key) else: tree.left = node(key) else: if tree.right: self._insert (tree.right, key) else: tree.right = node(key)
Descriptions in this dictionary are ©1997-99 Neal Ziring. Some examples copyright of their respective authors. Some technologies and languages are trademarked. Permission to copy descriptions is granted as long as authorship credit is preserved.
Comments on this dictionary, corrections and suggestions, are all welcome. Please use email, the address is ziring@home.com
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Dictionary and script maintained by Neal Ziring, last major modifications 3/18/98. Most recent additions to dictionary and master list, 1/00.