Assembly Language for Beginners

(Jeff_L) #1

9.4. FORTUNE PROGRAM INDEXING FILE


A tall, dark stranger will have more fun than you.
%
...


So it is just phrases, sometimes multiline ones, divided by percent sign. The task offortuneprogram is to
find random phrase and to print it. In order to achieve this, it must scan the whole text file, count phrases,
choose random and print it. But the text file can get bigger, and even on modern computers, this naive
algorithm is a bit uneconomical to computer resources. The straightforward way is to keep binary index
file containing offset of each phrase in text file. With index file,fortuneprogram can work much faster:
just to choose random index element, take offset from there, set offset in text file and read phrase from it.
This is actually done infortuneprogram. Let’s inspect what is in its index file inside (these are .dat files
in the same directory) in hexadecimal editor. This program is open-source of course, but intentionally, I
will not peek into its source code.


% od -t x1 --address-radix=x fortunes.dat
000000 00 00 00 02 00 00 01 af 00 00 00 bb 00 00 00 0f
000010 00 00 00 00 25 00 00 00 00 00 00 00 00 00 00 2b
000020 00 00 00 60 00 00 00 8f 00 00 00 df 00 00 01 14
000030 00 00 01 48 00 00 01 7c 00 00 01 ab 00 00 01 e6
000040 00 00 02 20 00 00 02 3b 00 00 02 7a 00 00 02 c5
000050 00 00 03 04 00 00 03 3d 00 00 03 68 00 00 03 a7
000060 00 00 03 e1 00 00 04 19 00 00 04 2d 00 00 04 7f
000070 00 00 04 ad 00 00 04 d5 00 00 05 05 00 00 05 3b
000080 00 00 05 64 00 00 05 82 00 00 05 ad 00 00 05 ce
000090 00 00 05 f7 00 00 06 1c 00 00 06 61 00 00 06 7a
0000a0 00 00 06 d1 00 00 07 0a 00 00 07 53 00 00 07 9a
0000b0 00 00 07 f8 00 00 08 27 00 00 08 59 00 00 08 8b
0000c0 00 00 08 a0 00 00 08 c4 00 00 08 e1 00 00 08 f9
0000d0 00 00 09 27 00 00 09 43 00 00 09 79 00 00 09 a3
0000e0 00 00 09 e3 00 00 0a 15 00 00 0a 4d 00 00 0a 5e
0000f0 00 00 0a 8a 00 00 0a a6 00 00 0a bf 00 00 0a ef
000100 00 00 0b 18 00 00 0b 43 00 00 0b 61 00 00 0b 8e
000110 00 00 0b cf 00 00 0b fa 00 00 0c 3b 00 00 0c 66
000120 00 00 0c 85 00 00 0c b9 00 00 0c d2 00 00 0d 02
000130 00 00 0d 3b 00 00 0d 67 00 00 0d ac 00 00 0d e0
000140 00 00 0e 1e 00 00 0e 67 00 00 0e a5 00 00 0e da
000150 00 00 0e ff 00 00 0f 43 00 00 0f 8a 00 00 0f bc
000160 00 00 0f e5 00 00 10 1e 00 00 10 63 00 00 10 9d
000170 00 00 10 e3 00 00 11 10 00 00 11 46 00 00 11 6c
000180 00 00 11 99 00 00 11 cb 00 00 11 f5 00 00 12 32
000190 00 00 12 61 00 00 12 8c 00 00 12 ca 00 00 13 87
0001a0 00 00 13 c4 00 00 13 fc 00 00 14 1a 00 00 14 6f
0001b0 00 00 14 ae 00 00 14 de 00 00 15 1b 00 00 15 55
0001c0 00 00 15 a6 00 00 15 d8 00 00 16 0f 00 00 16 4e
...


Without any special aid we could see that there are four 4-byte elements on each 16-byte line. Perhaps,
it’s our index array. I’m trying to load the whole file in Wolfram Mathematica as 32-bit integer array:


In[]:= BinaryReadList["c:/tmp1/fortunes.dat", "UnsignedInteger32"]


Out[]= {33554432, 2936078336, 3137339392, 251658240, 0, 37, 0, \
721420288, 1610612736, 2399141888, 3741319168, 335609856, 1208025088, \
2080440320, 2868969472, 3858825216, 537001984, 989986816, 2046951424, \
3305242624, 67305472, 1023606784, 1745027072, 2801991680, 3775070208, \
419692544, 755236864, 2130968576, 2902720512, 3573809152, 84213760, \
990183424, 1678049280, 2181365760, 2902786048, 3456434176, \
4144300032, 470155264, 1627783168, 2047213568, 3506831360, 168230912, \
1392967680, 2584150016, 4161208320, 654835712, 1493696512, \
2332557312, 2684878848, 3288858624, 3775397888, 4178051072, \
...


Nope, something wrong. Numbers are suspiciously big. But let’s back toodoutput: each 4-byte element
has two zero bytes and two non-zero bytes, so the offsets (at least at the beginning of the file) are 16-
bit at maximum. Probably different endianness is used in the file? Default endiannes in Mathematica is
little-endian, as used in Intel CPUs. Now I’m changing it to big-endian:


In[]:= BinaryReadList["c:/tmp1/fortunes.dat", "UnsignedInteger32",
ByteOrdering -> 1]

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