Image:INTERCAL Circuitous Diagram.PNG
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This is a PNG rendering of a picture written in pic from the INTERCAL Programming Language Revised Reference Manual [1], which is licenced under GPL (Copyright (C) 1973 by Donald R. Woods and James M. Lyon, Copyright (C) 1996 by Eric S. Raymond, redistribution encouraged under GPL). Because the picture is licensed under GPL, the source code for the picture (excluding the caption, which was part of the surrounding .mm file) is below. This picture would clearly be better as SVG, but I don't have the software to translate it.
# The CIRCUITOUS DIAGRAM, Figure 1 of the INTERCAL manual.
#
# Transcribed to PIC by Eric S. Raymond from the paper original.
# The transcription is topologically correct but not geometrically perfect.
#
# I discovered late in the process that the gate spacing to gate width
# ratio should be 6/5, not 5/5. The only place the difference shows is
# in the zigzag part of the adventitious lead below gate 37, which is
# a bit narrower in this version than in the paper original.
#
# Minor liberties have been taken with the sizes of some features at the
# left and right sides to fit the diagram on a letter-sized page. The
# A/B input leads should really be a whole boxwidth wide, and the bus line
# rectangle was slightly wider and further right in the paper original.
# Also, there are only 15 "New York" terminals rather than 16, and in the
# original the bus terminal label texts were rotated 90 degrees clockwise.
#
# The whole diagram can be scaled horizontally or vertically by changing
# the boxwid and boxht variables. At default scale the values boxwid =
# 0.60 boxht = 0.525 reproduce the paper version most exactly; they get
# the gate grid and leads nearly perfect.
#
scale=6/5 # This is how we scale the whole thing to fit on 8.5x11
boxwid = 0.60
boxht = 0.525
linewid = boxwid
lineht = boxht
movewid = boxwid
moveht = boxht
# Offset of top and bottom pins from gate midline
define pinoffset {(2/3)}
define warmengate {
# Draw a Warmenhovian gate box
[
box invis;
line from last box .sw \
to last box .nw \
to 1/2 <last box .ne, last box .n> \
to 1/2 <last box .e, last box .ne> \
to 1/2 <last box .e, last box .se> \
to 1/2 <last box .se, last box .s> \
to last box .sw;
IN: last box .w;
UP: pinoffset <last box .w, last box .nw>
DN: pinoffset <last box .w, last box .sw>
OUT: last box .e;
"$1" at last box .center;
]
}
[ # Beginning of diagram object
# Draw the gate array
copy thru % move to (($1-1) * movewid * 2, ($2-1) * moveht * 2); warmengate($3) % until "END"
0 1 6
0 2 6
0 3 1
0 4 1
0 5 1
0 6 1
0 7 1
0 8 1
0 9 1
0 10 1
END
copy thru % move to ((boxwid + movewid * 7 / 5) + ($1-2) * movewid * 2, ($2-1) * moveht * 2); warmengate($3) % until "END"
1 1 1
1 2 2
1 3 2
1 4 2
1 5 2
1 6 2
1 7 2
1 8 2
1 9 2
1 10 2
2 1 1
2 2 7
2 3 4
2 4 3
2 5 3
2 6 3
2 7 7
2 8 3
2 9 7
2 10 3
3 1 1
3 2 3
3 3 3
3 4 4
3 5 4
3 6 3
3 7 3
3 8 3
3 9 3
3 10 3
4 1 1
4 2 4
4 3 5
4 4 5
4 5 4
4 6 5
4 7 4
4 8 3
4 9 2
4 10 1
END
# Draw bus line:
BUSLINE: box with .sw at 41st [].se + (boxwid/2, 0) \
wid (boxwid / 2) \
ht (50th [].n.y - 41st [] .s.y)
copy thru % move to $1 / 40 <last box .n, last box .s>; "$2" % until "END"
9 B
11 U
13 S
17 L
19 I
21 N
23 E
30 8
END
define newyork {
line right boxwid/3
box invis "" "TO" "NEW" "YORK" ""
}
define philly {
line right boxwid/3
box invis "" "TO" "PHILA-" "DELPHIA" ""
}
for i = 0 to 14 do {
move to (i+1)/18 <BUSLINE.ne,BUSLINE.se>
newyork
}
move to (i+1)/18 <BUSLINE.ne,BUSLINE.se>
philly
define dot {circle rad 0.03 filled 1}
# Place a junction dot wherever we are
define junction % {dot at Here}; %
# Draw inputs
define inwidth {boxwid*3/4}
define drawinputs {
line left inwidth from $1.UP;
"A" at last line .end - (0.1, 0) rjust;
"$2" at last line .end - (0.05, 0.1) rjust;
move to last line .center; A$2: junction
line left inwidth from $1.DN;
"B" at last line .end - (0.1, 0) rjust;
"$2" at last line .end - (0.05, 0.1) rjust;
move to last line .center; B$2: junction
}
drawinputs(3rd [],8)
drawinputs(4th [],7)
drawinputs(5th [],6)
drawinputs(6th [],5)
drawinputs(7th [],4)
drawinputs(8th [],3)
drawinputs(9rd [],2)
# Gate 10 inputs have to be done by hand
define go {move to $1;}
# Define `gate' to *refer* to nth gate
define gate {`$1'th []}
# Go to specified pin of given gate
define pin {gate($1).$2}
# We exploit the quantization of lead placements here
# Draw from left edge of box $1 quanta of inter-box horizontal distance
define left_mv {line left boxwid * $1 / 5;}
# Draw from right edge of box $1 quanta of inter-box horizontal distance
define right_mv {line right boxwid * $1 / 5;}
# Draw from top pin of box $1 quanta of inter-box vertical distance up
define up_mv {line up (boxht * (2 - pinoffset)) * $1 / 4;}
# Draw from bottom pin of box $1 quanta of inter-box vertical distance down
define dn_mv {line down (boxht * (2 - pinoffset)) * $1 / 4;}
# Draw from here to given object, with directional constraint
define vert {line up ($1.y - Here.y);}
define horz {line right ($1.x - Here.x);}
define zig {vert($1) horz($1)}
define to_bus {line to (BUSLINE.w, Here)}
define ground {
dn_mv(1)
[
boxwid = boxwid * (3/4)
boxht = boxht / 3
box invis
line from last box .ne to last box .nw
line from 1/3 <last box.e,last box.c> to 1/3 <last box.w,last box.c>
line from 2/3 <last box.se,last box.s> to 2/3 <last box.sw,last box.s>
]
}
# Now all those connections
# Gate 1:
go(pin(1,OUT)) right_mv(3) CORNER:Here; zig(pin(12,DN))
go(CORNER) vert(pin(1,UP)) \
{junction horz(pin(11,UP))} \
up_mv(2) junction
horz(gate(32).e) right_mv(3) junction
{zig(pin(43,IN))}
horz(gate(42).e) right_mv(1) junction
{to_bus}
vert(pin(43,UP)) up_mv(2) to_bus
# Gate 2
go(pin(2,OUT)) right_mv(2) zig(pin(12,UP))
# Gate 3
go(A8) up_mv(1) horz(gate(13).e) right_mv(3) zig(pin(23,IN))
go(B8) dn_mv(1) horz(gate(13))
right_mv(1) dn_mv(1)
horz(gate(23).e) right_mv(2) dn_mv(2) horz(pin(32,UP))
go(pin(3,OUT)) right_mv(2)
vert(gate(3).UP) up_mv(3)
horz(gate(13).e) right_mv(2)
vert(gate(15,UP)) up_mv(4) #??? don't know why 4 is necessary
horz(gate(16).w) left_mv(1)
vert(gate(6).w) up_mv(4)
left_mv(2) zig(pin(7,OUT))
# Gate 4
go(A7) up_mv(1) horz(gate(14).e) right_mv(1) zig(pin(24,UP))
go(B7) dn_mv(1) horz(gate(4))
right_mv(1) dn_mv(1)
horz(gate(14).e) right_mv(3)
vert(pin(26,UP)) up_mv(1)
horz(gate(25)) up_mv(2)
horz(gate(25).e) right_mv(4)
vert(pin(38,UP)) up_mv(1)
horz(gate(48).e) right_mv(1)
vert(pin(47,DN)) dn_mv(1)
horz(gate(47).w) left_mv(3)
vert(gate(46).DN) dn_mv(2) right_mv(2)
vert(gate(45).DN) dn_mv(2) left_mv(3)
vert(gate(44).DN) right_mv(3) dn_mv(2)
horz(gate(33).w) left_mv(1)
vert(gate(33).DN) dn_mv(3)
horz(gate(32).e) up_mv(2)
horz(gate(42).e) dn_mv(2) line down boxwid/5
to_bus
go(pin(4,OUT)) right_mv(3) junction
{zig(pin(13,UP))}
vert(pin(4,UP)) up_mv(3) junction
{right_mv(3) zig(pin(15,IN))}
left_mv(2) vert(pin(7,UP)) up_mv(3)
right_mv(3) zig(pin(19,DN))
# Gate 5
go(A6) up_mv(1) horz(gate(15).e) right_mv(1) vert(pin(15,UP)) junction
{horz(pin(25,UP))}
vert(pin(15,DN)) dn_mv(1)
horz(gate(25).e) right_mv(1)
zig(pin(34,UP))
go(B6) dn_mv(2) horz(gate(25).e) dn_mv(1) right_mv(4)
vert(pin(24,DN)) dn_mv(1)
horz(gate(34).e) right_mv(1)
vert(pin(32,DN)) dn_mv(1)
right_mv(3) zig(pin(42,IN))
go(pin(5,OUT)) right_mv(5) junction
{vert(pin(14,IN)) junction {horz(pin(14,IN))} zig(pin(13,IN)) }
vert(pin(17,DN)) junction {horz(pin(17,DN))} zig(pin(18,DN))
# Gate 6
go(A5) up_mv(1) horz(gate(16).e) right_mv(1) zig(pin(26,UP))
go(B5) dn_mv(2) horz(gate(26).e) right_mv(3) zig(pin(34,IN))
go(pin(6,OUT)) right_mv(4) junction
{horz(pin(16,IN))}
vert(pin(15,DN)) junction
{horz(pin(15,DN))}
vert(pin(14,DN)) junction
{horz(pin(14,DN))}
zig(pin(13,DN))
# Gate 7
go(A4) up_mv(1) horz(gate(27).e) right_mv(3) vert(pin(37,IN)) junction
{horz(pin(37,IN))}
vert(pin(37,DN)) dn_mv(2) right_mv(1) junction
{zig(pin(36,IN))}
horz(gate(37).e) right_mv(3)
zig(pin(45,IN))
go(B4) dn_mv(2) horz(gate(17).e) right_mv(4)
vert(pin(26,DN)) dn_mv(1)
horz(gate(26).e) dn_mv(2)
right_mv(4) vert(pin(35,DN)) dn_mv(1)
horz(gate(35).e) right_mv(2) junction
{zig(pin(45,UP))} {zig(pin(44,UP))}
# Gate 8
go(A3) up_mv(1) horz(gate(28).e) right_mv(1) zig(pin(38,UP))
go(B3) dn_mv(2) horz(gate(28).e) right_mv(2) zig(pin(37,UP))
go(pin(8,OUT)) right_mv(6) junction
{zig(pin(17,IN))}
up_mv(4) left_mv(1) vert(pin(19,UP)) junction
{horz(pin(19,UP))}
zig(pin(20,UP))
# Gate 9
go(A2) up_mv(1) horz(gate(19).e) right_mv(1) zig(pin(28,UP))
go(B2) dn_mv(2) horz(gate(39).e) right_mv(1)
vert(pin(38,DN)) dn_mv(2) right_mv(2) zig(pin(47,IN))
go(pin(9,OUT)) right_mv(3) junction
{zig(pin(20,DN))}
{horz(pin(19,IN))}
vert(pin(16,DN)) junction
{horz(pin(16,DN))}
zig(pin(15,UP))
# Gate 10
line left inwidth from 10th[].UP;
"A" at last line .end - (0.1, 0) rjust;
"1" at last line .end - (0.05, 0.1) rjust;
move to last line .center; A1: junction
line left inwidth from 10th [].DN;
"B" at last line .end - (0.1, 0) rjust;
"1" at last line .end - (0.05, 0.1) rjust;
move to 1/2 <last line .center, last line .start>; B1: junction
go(A1) vert(pin(10,DN)) dn_mv(1) horz(gate(20).e) right_mv(2) zig(pin(30,UP))
go(B1) dn_mv(2) horz(gate(30).e) right_mv(1) junction
{zig(pin(39,UP))}
right_mv(3) zig(pin(40,DN))
go(pin(10,OUT)) right_mv(2) junction
{horz(pin(20,IN))}
vert(pin(18,UP)) junction
{horz(pin(18,UP))}
vert(pin(16,UP)) junction
{horz(pin(16,UP))}
zig(pin(14,UP))
# Gate 11
go(pin(11, DN)) left_mv(3) vert(pin(11,UP)) up_mv(1) \
horz(gate(31).e) right_mv(1) zig(pin(41,DN))
go(pin(11,OUT)) right_mv(2) zig(pin(21,DN))
# Gate 12
go(pin(12,OUT)) right_mv(3) junction
{horz(pin(22,IN))}
vert(pin(12,UP)) up_mv(1)
horz(gate(12).w) left_mv(3)
zig(pin(12,IN))
# Gate 13
go(pin(13,OUT)) right_mv(1) zig(pin(23,UP))
# Gate 14
go(pin(14,OUT)) horz(pin(24,IN))
# Gate 15
go(pin(15,OUT)) horz(pin(25,IN))
# Gate 16
go(pin(16,OUT)) right_mv(2) junction
{horz(pin(26,IN))}
vert(pin(27,UP)) junction
{horz(pin(27,UP))}
zig(pin(29,DN))
# Gate 17
go(pin(17,OUT)) horz(pin(27,IN))
# Gate 18
go(pin(18,OUT)) right_mv(3) junction
{horz(pin(28,IN))}
zig(pin(27,DN))
# Gate 19
go(pin(19,OUT)) horz(pin(29,IN))
# Gate 20
go(pin(20,OUT)) right_mv(3) junction
{horz(pin(30,IN))}
zig(pin(29,UP))
# Gate 21
go(pin(21,UP)) left_mv(2) vert(pin(21,DN)) ground
go(pin(21,OUT)) right_mv(2) junction
{zig(pin(31,DN))}
up_mv(2) junction
# Gate 22
go(pin(22,UP)) left_mv(3) up_mv(2) junction
go(pin(22,DN)) left_mv(4)
vert(pin(22,UP)) up_mv(3) right_mv(3)
vert(pin(23,UP)) up_mv(3)
horz(gate(23).e) right_mv(2)
vert(pin(25,UP)) left_mv(1)
vert(pin(28,DN)) right_mv(1)
zig(pin(40,IN))
go(pin(22,OUT)) right_mv(3) junction
{horz(pin(32,IN))}
{zig(pin(33,IN))}
zig(pin(31,UP))
# Gate 23
go(pin(23,OUT)) right_mv(1)
vert(gate(23).DN) dn_mv(1)
horz(gate(33)) right_mv(1)
dn_mv(1) to_bus
# Gate 24
go(pin(24,OUT)) right_mv(1) zig(pin(33,UP))
# Gate 25
go(pin(25,OUT)) horz(pin(35,IN))
# Gate 26
go(pin(26,OUT)) right_mv(2) vert(pin(26,DN)) dn_mv(1) junction
{to_bus}
zig(pin(35,UP))
# Gate 27
go(pin(27,OUT)) right_mv(2) zig(pin(36,UP))
# Gate 28
go(pin(28,OUT)) right_mv(3) junction
{horz(pin(38,IN))}
vert(pin(38, DN)) dn_mv(1) to_bus
# Gate 29
go(pin(29,OUT)) right_mv(3) junction
{horz(pin(39,IN))}
{vert(pin(39, DN)) dn_mv(1) to_bus}
zig(pin(40,UP))
# Gate 30
go(pin(30,OUT)) right_mv(1)
vert(pin(30,DN)) dn_mv(1)
horz(gate(40).e) right_mv(2)
zig(pin(50,UP))
# Gate 31
go(pin(31,OUT)) right_mv(2) zig(pin(41,UP))
# Gate 32
go(pin(32,OUT)) right_mv(2) vert(pin(32,UP)) junction
{horz(pin(42,UP))}
up_mv(1) to_bus
# Gate 33
go(pin(33,OUT)) right_mv(2) zig(pin(43,UP))
# Gate 34
go(pin(34,OUT)) right_mv(3) junction
{horz(pin(44,IN))}
vert(pin(44, DN)) dn_mv(1) to_bus
# Gate 35
go(pin(35,OUT)) right_mv(1) dn_mv(1) right_mv(2) dn_mv(1) to_bus
# Gate 36
go(pin(36,OUT)) horz(pin(46,IN))
# Gate 37
go(pin(37,OUT)) right_mv(2) vert(pin(48,UP)) junction
{horz(pin(48,UP))}
zig(pin(49,DN))
# Gate 38
go(pin(38,OUT)) right_mv(3) junction
{horz(pin(48,IN))}
vert(pin(48,DN)) right_mv(1) dn_mv(3) left_mv(3)
vert(pin(47,UP)) junction
{horz(pin(47,UP))}
zig(pin(46,UP))
# Gate 39
go(pin(39,OUT)) right_mv(3) junction
{horz(pin(49,IN))}
{vert(pin(49, DN)) dn_mv(2) to_bus}
zig(pin(50,IN))
# Gate 40
go(pin(40,OUT)) right_mv(1)
vert(pin(40,DN))
dn_mv(2) junction
{horz(gate(40).w); dn_mv(1); horz(gate(40).e); right_mv(1)}
dn_mv(1) junction
zig(pin(49,UP))
# Gate 41
# (should be right_mv(2) but we've squeezed the bus line a bit left)
go(pin(41,OUT)) right_mv(1) vert(pin(41,DN)) ground
# Gate 42
go(pin(42,OUT)) to_bus
# Gate 43
go(pin(43,OUT)) to_bus
# Gate 44
go(pin(44,OUT)) to_bus
# Gate 45
go(pin(45,OUT)) to_bus
# Gate 46
go(pin(46,OUT)) to_bus
# Gate 47
go(pin(47,OUT)) to_bus
# Gate 48
go(pin(48,OUT)) to_bus
# Gate 49
go(pin(49,OUT)) to_bus
# Gate 50
go(pin(50,OUT)) to_bus
# The adventitious lead
go(pin(17,OUT)) right_mv(1)
{vert(pin(17,UP)) up_mv(3) horz(gate(17))}
vert(pin(17,DN)) dn_mv(1)
horz(gate(27).w) dn_mv(1) horz(gate(27).e)
dn_mv(1) horz(gate(36).w)
up_mv(2) right_mv(1) dn_mv(2)
right_mv(1) up_mv(2) right_mv(1) dn_mv(2)
right_mv(1) up_mv(2) right_mv(1)
vert(pin(37,DN)) right_mv(4) dn_mv(2)
right_mv(3) dn_mv(1) left_mv(3)
vert(pin(46,DN)) left_mv(3) dn_mv(3)
horz(gate(36).w) up_mv(1) horz(gate(36)) right_mv(1)
] # End of diagram object
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|---|---|---|---|
| Source |
INTERCAL Programming Language Revised Reference Manual [2] |
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| Date |
Original (on paper) created in 1972 or 1973, converted to PIC (by Eric S. Raymond) in 1996, converted to PNG 11 October 2006, uploaded to en:Wikipedia 11 October 2006, to Commons 24 October 2006. |
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| Author |
User Ais523 on en.wikipedia |
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| Permission |
|
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| Other versions |
Originally from en.wikipedia; description page is (was) here * 09:02, 11 October 2006 [[:en:User:Ais523|Ais523]] 744×1010 (85,021 bytes) <span class="comment">({{GPL}} This is a PNG rendering of a picture written in pic from the INTERCAL Programming Language Revised Reference Manual [http://www.catb.org/~esr/intercal/intercal.ps.gz], which is licenced under GPL (Copyright (C) 1973 by Donald R. Woods and James M.)</span> |
(Uploaded using CommonsHelper or PushForCommons)
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