OpenCores
URL https://opencores.org/ocsvn/eco32/eco32/trunk

Subversion Repositories eco32

[/] [eco32/] [trunk/] [fp/] [implementation/] [mmix/] [mmixal.w] - Blame information for rev 274

Go to most recent revision | Details | Compare with Previous | View Log

Line No. Rev Author Line
1 15 hellwig
% This file is part of the MMIXware package (c) Donald E Knuth 1999
2
@i boilerplate.w %<< legal stuff: PLEASE READ IT BEFORE MAKING ANY CHANGES!
3
 
4
\def\title{MMIXAL}
5
 
6
\def\MMIX{\.{MMIX}}
7
\def\MMIXAL{\.{MMIXAL}}
8
\def\Hex#1{\hbox{$^{\scriptscriptstyle\#}$\tt#1}} % experimental hex constant
9
\def\<#1>{\hbox{$\langle\,$#1$\,\rangle$}}\let\is=\longrightarrow
10
\def\bull{\smallbreak\textindent{$\bullet$}}
11
@s and normal @q unreserve a C++ keyword @>
12
@s or normal @q unreserve a C++ keyword @>
13
@s xor normal @q unreserve a C++ keyword @>
14
 
15
\ifx\exotic+
16
 \font\heb=heb8 at 10pt
17
 \font\rus=lhwnr8
18
 \input unicode
19
 \unicodeptsize=8pt
20
\fi
21
 
22
@* Definition of MMIXAL. This program takes input written in \MMIXAL,
23
the \MMIX\ assembly language, and translates it
24
@^assembly language@>
25
into binary files that can be loaded and executed
26
on \MMIX\ simulators. \MMIXAL\ is much simpler than the ``industrial
27
strength'' assembly languages that computer manufacturers usually provide,
28
because it is primarily intended for the simple demonstration programs
29
in {\sl The Art of Computer Programming}. Yet it tries to have enough
30
features to serve also as the back end of compilers for \CEE/ and other
31
high-level languages.
32
 
33
Instructions for using the program appear at the end of this document.
34
First we will discuss the input and output languages in detail; then we'll
35
consider the translation process, step by step; then we'll put everything
36
together.
37
 
38
@ A program in \MMIXAL\ consists of a series of {\it lines}, each of which
39
usually contains a single instruction. However, lines with no instructions are
40
possible, and so are lines with two or more instructions.
41
 
42
Each instruction has
43
three parts called its label field, opcode field, and operand field; these
44
fields are separated from each other by one or more spaces.
45
The label field, which is often empty, consists of all characters up to the
46
first blank space. The opcode field, which is never empty, runs from the first
47
nonblank after the label to the next blank space. The operand field, which
48
again might be empty, runs from the next nonblank character (if any) to the
49
first blank or semicolon that isn't part of a string or character constant.
50
If the operand field is followed by a semicolon, possibly with intervening
51
blanks, a new instruction begins immediately after the semicolon; otherwise
52
the rest of the line is ignored. The end of a line is treated as a blank space
53
for the purposes of these rules, with the additional proviso that
54
string or character constants are not allowed to extend from one line to
55
another.
56
 
57
The label field must begin with a letter or a digit; otherwise the entire
58
line is treated as a comment. Popular ways to introduce comments,
59
either at the beginning of a line or after the operand field, are to
60
precede them by the character \.\% as in \TeX, or by \.{//} as in \CPLUSPLUS/;
61
\MMIXAL\ is not very particular. However, Lisp-style comments introduced
62
by single semicolons will fail if they follow an instruction, because
63
they will be assumed to introduce another instruction.
64
 
65
@ \MMIXAL\ has no built-in macro capability, nor does it know how to
66
include header files and such things. But users can run their files
67
through a standard \CEE/ preprocessor to obtain \MMIXAL\ programs in which
68
macros and such things have been expanded. (Caution: The preprocessor also
69
removes \CEE/-style comments, unless it is told not to do so.)
70
Literate programming tools could also be used for preprocessing.
71
@^C preprocessor@>
72
@^literate programming@>
73
 
74
If a line begins with the special form `\.\# \ \',
75
this program interprets it as a {\it line directive\/} emitted by a
76
preprocessor. For example,
77
$$\leftline{\indent\.{\# 13 "foo.mms"}}$$
78
means that the following line was line 13 in the user's source file
79
\.{foo.mms}. Line directives allow us to correlate errors with the
80
user's original file; we also pass them to the output, for use by
81
simulators and debuggers.
82
@^line directives@>
83
 
84
@ \MMIXAL\ deals primarily with {\it symbols\/} and {\it constants}, which it
85
interprets and combines to form machine language instructions and data.
86
Constants are simplest, so we will discuss them first.
87
 
88
A {\it decimal constant\/} is a sequence of digits, representing a number in
89
radix~10. A~{\it hexadecimal constant\/} is a sequence of hexadecimal digits,
90
preceded by~\.\#, representing a number in radix~16:
91
$$\vbox{\halign{$#$\hfil\cr
92
\\is\.0\mid\.1\mid\.2\mid\.3\mid\.4\mid
93
        \.5\mid\.6\mid\.7\mid\.8\mid\.9\cr
94
\\is\\mid\.A\mid\.B\mid\.C\mid\.D\mid\.E\mid\.F\mid
95
        \.a\mid\.b\mid\.c\mid\.d\mid\.e\mid\.f\cr
96
\\is\\mid\\\cr
97
\\is\.\#\\mid\\\cr
98
}}$$
99
Constants whose value is $2^{64}$ or more are reduced modulo $2^{64}$.
100
 
101
@ A {\it character constant\/} is a single character enclosed in
102
single quote marks; it denotes the {\mc ASCII} or Unicode number
103
@^Unicode@>
104
corresponding to that character. For example, \.{'a'}
105
represents the constant \.{\#61}, also known as~\.{97}. The quoted character
106
can be
107
anything except the character that the \CEE/ library calls \.{\\n} or {\it
108
newline}; that character should be represented as \.{\#a}.
109
$$\vbox{\halign{$#$\hfil\cr
110
\\is\.'\\.'\cr
111
\\is\\mid\\mid\
112
\cr}}$$
113
Notice that \.{'''} represents a single quote, the code \.{\#27}; and
114
\.{'\\'} represents a backslash, the code \.{\#5c}. \MMIXAL~characters are
115
never ``quoted'' by backslashes as in the \CEE/~language.
116
 
117
In the present implementation
118
a character constant will always be at most 255, since wyde character
119
input is not supported.
120
\ifx\exotic+ But if the input were in Unicode one could write,
121
say, \.'{\heb\char"40}\.' or \.'{\rus ZH}\.' for \.{\#05d0} or
122
\.{\#0416}. \fi
123
The present program
124
does not support Unicode directly because basic software for inputting and
125
outputting 16-bit characters was still in a primitive state at the time of
126
writing. But the data structures below are designed so that a change to
127
Unicode will not be difficult when the time is ripe.
128
 
129
@ A {\it string constant\/} like \.{"Hello"} is an abbreviation for
130
a sequence of one or more character constants separated by commas:
131
\.{'H','e','l','l','o'}.
132
Any character except newline or the double quote mark~\."
133
can appear between the double quotes of a string constant.
134
\ifx\exotic+ Similarly,
135
\."\Uni1.08:24:24:-1:20% Unicode char "9ad8
136
<002000001800000806ffffff00000002004003ffe00300e00300c00300c003ffc0%
137
0300c02000043ffffe30000e31008c31ffcc3181cc31818c31818c31ff8c31818c3%
138
0007c300018>%
139
\thinspace\Uni1.08:24:24:-1:20% Unicode char "5fb7
140
<1c038018030018030631ffff30060067860446fffe86ccce0ccccc0ccccc18cccc%
141
18fffc38c00c38001878fffc58040098030818398618b18318b00b19b0081b300c1%
142
b3ffc181ff8>%
143
\thinspace\Uni1.08:24:24:-1:20% Unicode char "7eb3
144
<0601c00e01800c018018018018218231bfff61b187433186ff3186c631860c3186%
145
18334630332663b6367e341660380600300600300603b0061e3006f03006c030060%
146
0303e00300c>%
147
\kern.1em\." is an abbreviation for
148
\.'\Uni1.08:24:24:-1:20% Unicode char "9ad8
149
<002000001800000806ffffff00000002004003ffe00300e00300c00300c003ffc0%
150
0300c02000043ffffe30000e31008c31ffcc3181cc31818c31818c31ff8c31818c3%
151
0007c300018>%
152
\.{','}\Uni1.08:24:24:-1:20% Unicode char "5fb7
153
<1c038018030018030631ffff30060067860446fffe86ccce0ccccc0ccccc18cccc%
154
18fffc38c00c38001878fffc58040098030818398618b18318b00b19b0081b300c1%
155
b3ffc181ff8>%
156
\.{','}\Uni1.08:24:24:-1:20% Unicode char "7eb3
157
<0601c00e01800c018018018018218231bfff61b187433186ff3186c631860c3186%
158
18334630332663b6367e341660380600300600300603b0061e3006f03006c030060%
159
0303e00300c>%
160
\.' (namely \.{\#9ad8,\#5fb7,\#7eb3}) when Unicode is supported.
161
@^Unicode@>
162
\fi
163
 
164
@ A {\it symbol\/} in \MMIXAL\ is any sequence of letters and digits,
165
beginning with a letter. A~colon~`\.:' or underscore symbol `\.\_'
166
is regarded as a letter, for purposes of this definition.
167
All extended-ASCII characters like `{\tt \'e}',
168
whose 8-bit code exceeds 126, are also treated as letters.
169
$$\vbox{\halign{$#$\hfil\cr
170
\\is\.A\mid\.B\mid\cdots\mid\.Z\mid\.a\mid\.b\mid\cdots\mid\.z\mid
171
        \.:\mid\.\_\mid\<{character with code value $>126$}>\cr
172
\\is\\mid\\\mid\\\cr
173
}}$$
174
 
175
In future implementations, when \MMIXAL\ is used with Unicode,
176
@^Unicode@>
177
all wyde characters whose 16-bit code exceeds 126 will be regarded
178
as letters; thus \MMIXAL\ symbols will be able to involve Greek letters or
179
Chinese characters or thousands of other glyphs.
180
@ A symbol is said to
181
be {\it fully qualified\/} if it begins with a colon. Every symbol
182
that is not fully qualified is an abbreviation for the fully qualified
183
symbol obtained by placing the {\it current prefix\/} in front of it;
184
the current prefix is always fully qualified. At the beginning of an
185
\MMIXAL\ program the current prefix is simply the single character~`\.:',
186
but the user can change it with the \.{PREFIX} command. For example,
187
$$\vbox{\halign{&\quad\tt#\hfil\cr
188
ADD&x,y,z&\% means ADD :x,:y,:z\cr
189
PREFIX&Foo:&\% current prefix is :Foo:\cr
190
ADD&x,y,z&\% means ADD :Foo:x,:Foo:y,:Foo:z\cr
191
PREFIX&Bar:&\% current prefix is :Foo:Bar:\cr
192
ADD&:x,y,:z&\% means ADD :x,:Foo:Bar:y,:z\cr
193
PREFIX&:&\% current prefix reverts to :\cr
194
ADD&x,Foo:Bar:y,Foo:z&\% means ADD :x,:Foo:Bar:y,:Foo:z\cr
195
}}$$
196
This mechanism allows large programs to avoid conflicts between symbol names,
197
when parts of the program are independent and/or written by different users.
198
The current prefix conventionally ends with a colon, but this convention
199
need not be obeyed.
200
 
201
@ A {\it local symbol\/} is a decimal digit followed by one of the
202
letters \.B, \.F, or~\.H, meaning ``backward,'' ``forward,'' or ``here'':
203
$$\vbox{\halign{$#$\hfill\cr
204
\\is\\,\.B\mid\\,\.F\cr
205
\\is\\,\.H\cr
206
}}$$
207
The \.B and \.F forms are permitted only in the operand field of \MMIXAL\
208
instructions; the \.H form is permitted only in the label field. A local
209
operand such as~\.{2B} stands for the last local label~\.{2H}
210
in instructions before the current one, or 0 if \.{2H} has not yet appeared
211
as a label. A~local operand such as~\.{2F} stands
212
for the first \.{2H} in instructions after the current one. Thus, in a
213
sequence such as
214
$$\vbox{\halign{\tt#\cr 2H JMP 2F\cr 2H JMP 2B\cr}}$$
215
the first instruction jumps to the second and the second jumps to the first.
216
 
217
Local symbols are useful for references to nearby points of a program, in
218
cases where no meaningful name is appropriate. They can also be useful
219
in special situations where a redefinable symbol is needed; for example,
220
an instruction like
221
$$\.{9H IS 9B+1}$$
222
will maintain a running counter.
223
 
224
@ Each symbol receives a value called its {\it equivalent\/} when it
225
appears in the label field of an instruction; it is said to be {\it defined\/}
226
after its equivalent has been established. A few symbols, like \.{rA}
227
and \.{ROUND\_OFF} and \.{Fopen},
228
are predefined because they refer to fixed constants
229
associated with the \MMIX\ hardware or its rudimentary operating system;
230
otherwise every symbol should be
231
defined exactly once. The two appearances of `\.{2H}' in the example
232
above do not violate this rule, because the second `\.{2H}' is not the
233
same symbol as the first.
234
 
235
A predefined symbol can be redefined (given a new equivalent). After it
236
has been redefined it acts like an ordinary symbol and cannot be
237
redefined again. A complete list of the predefined symbols appears
238
in the program listing below.
239
@^predefined symbols@>
240
 
241
Equivalents are either {\it pure\/} or {\it register numbers}. A pure
242
equivalent is an unsigned octabyte, but a register number
243
equivalent is a one-byte value, between 0 and~255.
244
A dollar sign is used to change a pure number into a register number;
245
for example, `\.{\$20}' means register number~20.
246
 
247
@ Constants and symbols are combined into {\it expressions\/} in a simple way:
248
$$\vbox{\halign{$#$\hfil\cr
249
\\is\\mid\\mid\\mid
250
  \.{@@}\mid\cr
251
\hskip12pc\.(\\.)\mid\\\cr
252
\\is\\mid
253
  \\\\cr
254
\\is\\mid\\\\cr
255
\\is\.+\mid\.-\mid\.\~\mid\.\$\mid\.\&\cr
256
\\is\.*\mid\./\mid\.{//}\mid\.\%\mid\.{<<}\mid\.{>>}
257
       \mid\.\&\cr
258
\\is\.+\mid\.-\mid\.{\char'174}\mid\.\^\cr
259
}}$$
260
Each expression has a value that is either pure or a register number.
261
The character \.{@@} stands for the current location, which is always pure.
262
The unary operators
263
\.+, \.-, \.\~, \.\$, and \.\& mean, respectively, ``do nothing,''
264
``subtract from zero,'' ``complement the bits,'' ``change from pure value
265
to register number,'' and ``take the serial number.'' Only the first of these,
266
\.+, can be applied to a register number. The last unary operator, \.\&,
267
applies only to symbols, and it is of interest primarily to system programmers;
268
it converts a symbol to the unique positive integer that is used to identify
269
it in the binary file output by \MMIXAL.
270
@^serial number@>
271
 
272
Binary operators come in two flavors, strong and weak. The strong ones
273
are essentially concerned with multiplication or division: \.{x*y},
274
\.{x/y}, \.{x//y}, \.{x\%y}, \.{x<>y}, and \.{x\&y}
275
stand respectively for
276
$(x\times y)\bmod2^{64}$ (multiplication), $\lfloor x/y\rfloor$ (division),
277
$\lfloor2^{64}x/y\rfloor$ (fractional division), $x\bmod y$ (remainder),
278
$(x\times2^y)\bmod2^{64}$ (left~shift), $\lfloor x/2^y\rfloor$
279
(right shift), and $x\land y$ (bitwise and) on unsigned octabytes.
280
Division is legal only if $y>0$; fractional division is
281
legal only if $x
282
applied to register numbers.
283
 
284
The weak binary operations \.{x+y}, \.{x-y}, \.{x\char'174 y}, and
285
\.{x\^y} stand respectively for $(x+y)\bmod2^{64}$ (addition),
286
$(x-y)\bmod2^{64}$ (subtraction),
287
$x\lor y$ (bitwise or), and $x\oplus y$ (bitwise exclusive-or) on
288
unsigned octabytes. These operations can be applied to register
289
numbers only in four contexts: $\+\$, $\+\$,
290
$\-\$
291
and $\-\$. For example, if \.{x} denotes \.{\$1} and
292
\.{y} denotes \.{\$10}, then \.{x+3} and \.{3+x} denote \.{\$4}, and
293
\.{y-x} denotes the pure value \.{9}.
294
 
295
Register numbers within expressions are allowed to be
296
arbitrary octabytes, but a register number assigned as the
297
equivalent of a symbol should not exceed 255.
298
 
299
(Incidentally, one might ask why the designer of \MMIXAL\ did not simply
300
adopt the existing rules of \CEE/ for expressions. The primary reason is that
301
the designers of \CEE/ chose to give \.{<<}, \.{>>}, and \.\& a lower
302
precedence than~\.+; but in \MMIXAL\ we want to be able to write things
303
like \.{o<<24+x<<16+y<<8+z} or \.{@@+yz<<2} or \.{@@+(\#100-@@)\&\#ff}.
304
Since the conventions of \CEE/ were inappropriate, it was better
305
to make a clean break, not pretending to have a close relationship
306
with that language. The new rules are quite easily memorized,
307
because \MMIXAL\ has just two levels of precedence, and the strong binary
308
operations are all essentially multiplicative by nature
309
while the weak binary operations are essentially additive.)
310
 
311
@ A symbol is called a {\it future reference\/} until it has been defined.
312
\MMIXAL\ restricts the use of future references, so that programs can
313
be assembled quickly in one pass over the input; therefore all
314
expressions can be evaluated when the \MMIXAL\ processor first sees them.
315
 
316
The restrictions are easily stated: Future references
317
cannot be used in expressions together with unary or binary operators (except
318
the unary~\.+, which does nothing); moreover, future references
319
can appear as operands only in instructions that have relative
320
addresses (namely branches, probable branches, \.{JMP}, \.{PUSHJ},
321
\.{GETA}) or in octabyte constants (the pseudo-operation \.{OCTA}).
322
Thus, for example, one can say \.{JMP}~\.{1F} or \.{JMP}~\.{1B-4}, but not
323
\.{JMP}~\.{1F-4}.
324
 
325
@ We noted earlier that each \MMIXAL\ instruction contains
326
a label field, an opcode field, and an operand field. The label field is
327
either empty or a symbol or local label; when it is nonempty, the
328
symbol or local label receives an equivalent. The operand field is
329
either empty or a sequence of expressions separated by commas; when
330
it is empty, it is equivalent to the simple operand field~`\.0'.
331
$$\vbox{\halign{$#$\hfil\cr
332
\\is\
333
\
334
\\is\\mid\\cr
335
\\is\\mid\\.,\\cr
336
}}$$
337
 
338
The opcode field either contains a symbolic \MMIX\ operation name (like
339
\.{ADD}), or an {\it alias operation}, or a {\it pseudo-operation}.
340
Alias operations are alternate names for \MMIX\ operations whose standard
341
names are inappropriate in certain contexts.
342
Pseudo-operations do not correspond
343
directly to \MMIX\ commands, but they govern the assembly process in
344
important ways.
345
 
346
There are two alias operations:
347
 
348
\bull \.{SET} \.{\$X,\$Y} is equivalent to \.{OR} \.{\$X,\$Y,0}; it sets
349
register~X to register~Y. Similarly, \.{SET} \.{\$X,Y} (when \.Y is
350
not a register) is equivalent to \.{SETL} \.{\$X,Y}.
351
@.SET@>
352
 
353
\bull \.{LDA} \.{\$X,\$Y,\$Z} is equivalent to \.{ADDU} \.{\$X,\$Y,\$Z};
354
it loads the address of memory location $\rm \$Y+\$Z$ into register~X.
355
Similarly, \.{LDA} \.{\$X,\$Y,Z} is equivalent to \.{ADDU} \.{\$X,\$Y,Z}.
356
@.LDA@>
357
 
358
\smallskip
359
The symbolic operation names for genuine \MMIX\ operations
360
should not include the suffix~\.I for an immediate operation or the suffix~\.B
361
for a backward jump; \MMIXAL\ determines such things automatically.
362
Thus, one never writes \.{ADDI} or \.{JMPB} in the source input to
363
\MMIXAL, although such opcodes might appear when a simulator or
364
debugger or disassembler is presenting a numeric instruction in symbolic form.
365
$$\vbox{\halign{$#$\hfil\cr
366
\\is\\mid\\cr
367
\hskip12pc\mid\\cr
368
\\is\.{TRAP}\mid\.{FCMP}\mid\cdots\mid\.{TRIP}\cr
369
\\is\.{SET}\mid\.{LDA}\cr
370
\\is\.{IS}\mid\.{LOC}\mid\.{PREFIX}\mid
371
   \.{GREG}\mid\.{LOCAL}\mid\.{BSPEC}\mid\.{ESPEC}\cr
372
\hskip12pc\mid\.{BYTE}\mid\.{WYDE}\mid\.{TETRA}\mid\.{OCTA}\cr
373
}}$$
374
 
375
@ \MMIX\ operations like \.{ADD} require exactly three expressions as
376
operands. The first two must be register numbers. The third must be either a
377
register number or a pure number between 0 and~255; in the latter case,
378
\.{ADD} becomes \.{ADDI} in the assembled output. Thus, for example,
379
the command ``set register~1 to the sum of register~2 and register~3'' could be
380
expressed as
381
$$\.{ADD \$1,\$2,\$3}$$
382
or as, say,
383
$$\.{ADD x,y,y+1}$$
384
if the equivalent of \.x is \.{\$1} and the equivalent of \.y is \.{\$2}.
385
The command ``subtract 5 from register~1'' could be expressed as
386
$$\.{SUB \$1,\$1,5}$$
387
or as
388
$$\.{SUB x,x,5}$$
389
but not as `\.{SUBI} \.{\$1,\$1,5}' or `\.{SUBI} \.{x,x,5}'.
390
 
391
\MMIX\ operations like \.{FLOT} require either three operands
392
(register, pure, register/pure) or only two (register, register/pure).
393
In the first case the middle operand is the rounding mode, which is
394
best expressed in terms of the predefined symbolic values
395
\.{ROUND\_CURRENT}, \.{ROUND\_OFF}, \.{ROUND\_UP}, \.{ROUND\_DOWN},
396
\.{ROUND\_NEAR}, for $(0,1,2,3,4)$ respectively. In the second case
397
the middle operand is understood to be zero (namely,
398
\.{ROUND\_CURRENT}).
399
@:ROUND_OFF}\.{ROUND\_OFF@>
400
@:ROUND_UP}\.{ROUND\_UP@>
401
@:ROUND_DOWN}\.{ROUND\_DOWN@>
402
@:ROUND_NEAR}\.{ROUND\_NEAR@>
403
@:ROUND_CURRENT}\.{ROUND\_CURRENT@>
404
 
405
\MMIX\ operations like \.{SETL} or \.{INCH}, which involve a wyde
406
intermediate constant, require exactly two operands, (register, pure).
407
The value of the second operand should fit in two bytes.
408
 
409
\MMIX\ operations like \.{BNZ}, which mention a register and a
410
relative address, also require two operands. The first operand
411
should be a register number. The second operand should yield a result~$r$
412
in the range $-2^{16}\le r<2^{16}$ when the current location is subtracted
413
from it and the result is divided by~4. The second operand might also
414
be undefined; in that case, the eventual value must satisfy the
415
restriction stated for defined values. The opcodes \.{GETA} and
416
\.{PUSHJ} are similar, except that the first operand to \.{PUSHJ}
417
might also be pure (see below). The \.{JMP} operation is also
418
similar, but it has only one operand, and it allows the larger
419
address range $-2^{24}\le r<2^{24}$.
420
 
421
\MMIX\ operations that refer to memory, like \.{LDO} and \.{STHT} and \.{GO},
422
are treated like \.{ADD}
423
if they have three operands, except that the first operand should be
424
pure (not a register number) in the case of \.{PRELD}, \.{PREGO},
425
\.{PREST}, \.{STCO}, \.{SYNCD}, and \.{SYNCID}. These opcodes
426
also accept a special two-operand form, in which the second operand
427
stands for a {\it base address\/} and an immediate offset (see below).
428
 
429
The first operand of \.{PUSHJ} and \.{PUSHGO} can be either a pure
430
number or a register number. In the first case (`\.{PUSHJ}~\.{2,Sub}'
431
or `\.{PUSHGO}~\.{2,Sub}')
432
the programmer might be thinking ``let's push down two registers'';
433
in the second case (`\.{PUSHJ}~\.{\$2,Sub}' or `\.{PUSHGO}~\.{\$2,Sub}')
434
the programmer might be thinking ``let's make register~2 the hole
435
position for this subroutine call.'' Both cases result in the same
436
assembled output.
437
 
438
The remaining \MMIX\ opcodes are idiosyncratic:
439
$$\def\\{{\rm\quad or\quad}}
440
\vbox{\halign{\tt#\hfill\cr
441
NEG r,p,z;\cr
442
PUT s,z;\cr
443
GET r,s;\cr
444
POP p,yz;\cr
445
RESUME xyz;\cr
446
SAVE r,0;\cr
447
UNSAVE r;\cr
448
SYNC xyz;\cr
449
TRAP x,y,z\\TRAP x,yz\\TRAP xyz;\cr
450
}}$$
451
\.{SWYM} and \.{TRIP} are like \.{TRAP}. Here \.s is an integer
452
between 0 and~31, preferably given by one of the predefined
453
symbols \.{rA}, \.{rB}, \dots~for special register codes;
454
\.r is a register number; \.p is a pure byte; \.x, \.y, and \.z are
455
either register numbers or pure bytes; \.{yz} and \.{xyz} are pure
456
values that fit respectively in two and three bytes.
457
 
458
All of these rules can be summarized by saying that \MMIXAL\ treats each
459
\MMIX\ opcode in the most natural way. When there are three operands,
460
they affect fields X,~Y, and~Z of the assembled \MMIX\ instruction;
461
when there are two operands, they affect fields X and~YZ;
462
when there is just one operand, it affects field XYZ.
463
 
464
@ In all cases when the opcode corresponds to an \MMIX\ operation,
465
the \MMIXAL\ instruction tells the assembler to carry out four steps:
466
(1)~Align the current location
467
so that it is a multiple of~4, by adding 1, 2, or~3 if necessary;
468
(2)~Define the equivalent of the label field to be the
469
current location, if the label is nonempty;
470
(3)~Evaluate the operands and assemble the specified \MMIX\ instruction into
471
the current location;
472
(4)~Increase the current location by~4.
473
 
474
@ Now let's consider the pseudo-operations, starting with the simplest cases.
475
 
476
\bull\
477
defines the value of the label to be the value of the expression,
478
which must not be a future reference. The expression may be
479
either pure or a register number.
480
 
481
\bull\
482
first defines the label to be the value of the current location, if the label
483
is nonempty. Then the current location is changed to the value of the
484
expression, which must be pure.
485
 
486
\smallskip For example, `\.{LOC} \.{\#1000}' will start assembling subsequent
487
instructions or data in location whose hexa\-decimal value is \Hex{1000}.
488
`\.X~\.{LOC}~\.{@@+500}' defines \.X to be the address of the first
489
of 500 bytes in memory; assembly will continue at location $\.X+500$.
490
The operation of aligning the current location to a multiple of~256,
491
if it is not already aligned in that way, can be expressed as
492
`\.{LOC}~\.{@@+(256-@@)\&255}'.
493
 
494
A less trivial example arises if we want to emit instructions and data into
495
two separate areas of memory, but we want to intermix them in the
496
\MMIXAL\ source file. We could start by defining \.{8H} and \.{9H}
497
to be the starting addresses of the instruction and data segments,
498
respectively. Then, a sequence of instructions could be enclosed
499
in `\.{LOC}~\.{8B}; \dots; \.{8H}~\.{IS}~\.{@@}'; a sequence of
500
data could be enclosed in `\.{LOC}~\.{9B}; \dots; \.{9H}~\.{IS}~\.{@@}'.
501
Any number of such sequences could then be combined.
502
Instead of the two pseudo-instructions `\.{8H}~\.{IS}~\.{@@;} \.{LOC}~\.{9B}'
503
one could in fact write simply `\.{8H}~\.{LOC}~\.{9B}' when
504
switching from instructions to data.
505
 
506
\bull \.{PREFIX} \
507
redefines the current prefix to be the given symbol (fully qualified).
508
The label field should be blank.
509
 
510
@ The next pseudo-operations assemble bytes, wydes, tetrabytes, or
511
octabytes of data.
512
 
513
\bull \
514
defines the label to be the current location, if the label field is nonempty;
515
then it assembles one byte for each expression in the expression list, and
516
advances the current location by the number of bytes. The expressions
517
should all be pure numbers that fit in one byte.
518
 
519
String constants are often used in such expression lists.
520
For example, if the current location is \Hex{1000}, the instruction
521
\.{BYTE}~\.{"Hello",0} assembles six bytes containing the constants
522
\.{'H'}, \.{'e'}, \.{'l'}, \.{'l'}, \.{'o'}, and~\.0 into locations
523
\Hex{1000}, \dots,~\Hex{1005}, and advances the current location
524
to \Hex{1006}.
525
 
526
\bull \
527
is similar, but it first makes the current location even, by adding~1 to it
528
if necessary. Then it defines the label (if a nonempty label is present),
529
and assembles each expression as a two-byte value. The current location
530
is advanced by twice the number of expressions in the list. The
531
expressions should all be pure numbers that fit in two bytes.
532
 
533
\bull \
534
is similar, but it aligns the current location to a multiple of~4
535
before defining the label; then it
536
assembles each expression as a four-byte value. The current location
537
is advanced by $4n$ if there are $n$~expressions in the list. Each
538
expression should be a pure number that fits in four bytes.
539
 
540
\bull \
541
is similar, but it first aligns the current location to a multiple of~8;
542
it assembles each expression as an eight-byte value. The current location
543
is advanced by $8n$ if there are $n$~expressions in the list. Any or all
544
of the expressions may be future references, but they should all
545
be defined as pure numbers eventually.
546
 
547
@ Global registers are important for accessing memory in \MMIX\ programs.
548
They could be allocated by hand, and defined with \.{IS} instructions,
549
but \MMIXAL\ provides a mechanism that is usually much more convenient:
550
 
551
\bull \
552
allocates a new global register, and assigns its number as the
553
equivalent of the label.
554
At the beginning of assembly, the current global threshold~G is~\$255.
555
Each distinct \.{GREG} instruction decreases~G by~1; the final value of~G will
556
be the initial value of~rG when the assembled program is loaded.
557
 
558
The value of the expression will be loaded into the global register
559
at the beginning of the program. {\it If this value is nonzero, it
560
should remain constant throughout the program execution\/}; such
561
global registers are considered to be {\it base addresses}. Two or
562
more base addresses with the same constant value are assigned to the
563
same global register number.
564
 
565
Base addresses can simplify memory accesses in an important way.
566
Suppose, for example, five octabyte values appear in a data segment,
567
and their addresses are called \.{AA}, \.{BB}, \.{CC}, \.{DD}, and
568
\.{EE}:
569
$$\.{AA LOC @@+8;BB LOC @@+8;CC LOC @@+8;DD LOC @@+8;EE LOC @@+8}$$
570
Then if you say \.{Base GREG AA}, you will be able to write simply
571
`\.{LDO}~\.{\$1,AA}' to bring \.{AA} into register~\.{\$1}, and
572
`\.{LDO}~\.{\$2,CC}' to bring \.{CC} into register~\.{\$2}.
573
 
574
Here's how it works: Whenever a memory operation such as
575
\.{LDO} or \.{STB} or \.{GO} has only two operands, the second
576
operand should be a pure number whose value can be expressed
577
as $b+\delta$, where $0\le\delta<256$ and $b$ is the value of
578
a base address in one of the preceding \.{GREG} commands. The \MMIXAL\
579
processor will find the closest base address and manufacture an
580
appropriate command. For example, the instruction `\.{LDO}~\.{\$2,CC}' in the
581
example of the preceding paragraph would be converted automatically to
582
`\.{LDO}~\.{\$2,Base,16}'.
583
 
584
If no base address is close enough, an error message will be
585
generated, unless this program is run with the \.{-x} option
586
on the command line. The \.{-x} option inserts additional instructions
587
if necessary, using global register~255, so that any address is
588
accessible. For example,
589
if there is no base address that allows \.{LDO}~\.{\$2,FF} to be
590
implemented in a single instruction, but if \.{FF} equals \.{Base+1000},
591
then the \.{-x} option would assemble two instructions,
592
$$\.{SETL \$255,1000; LDO \$2,Base,\$255}$$
593
in place of \.{LDO}~\.{\$2,FF}. Caution:~The \.{-x} feature makes the
594
number of actual \MMIX\ instructions hard to predict, so extreme care must
595
be used if your style of coding includes relative branch instructions
596
in dangerous forms like `\.{BNZ}~\.{x,@@+8}'.
597
 
598
This base address convention can be used also with the alias
599
operation~\.{LDA}. For example, `\.{LDA}~\.{\$3,CC}' loads the
600
@.LDA@>
601
address of \.{CC} into register~3, by assembling the instruction
602
`\.{ADDU}~\.{\$3,Base,16}'.
603
 
604
\MMIXAL\ also allows a two-operand form for memory operations such as
605
$$\hbox{\.{LDO} \.{\$1,\$2}}$$
606
to be an abbreviation for `\.{LDO} \.{\$1,\$2,0}'.
607
 
608
When \MMIXAL\ programs use subroutines with a memory stack in addition
609
to the built-in register stack, they usually begin with the
610
instructions `\.{sp}~\.{GREG}~\.{0;fp}~\.{GREG}~\.0'; these instructions
611
allocate a {\it stack pointer\/} \.{sp=\$254} and a {\it frame pointer\/}
612
\.{fp=\$253}. However, subroutine libraries are free to implement any
613
conventions for global registers and stacks that they like.
614
@^stack pointer@>
615
@^frame pointer@>
616
 
617
@ Short programs rarely run out of global registers, but long programs
618
need a mechanism to check that \.{GREG} hasn't been used too often.
619
The following pseudo-instruction provides the necessary safety valve:
620
 
621
\bull \.{LOCAL} \
622
ensures that the expression will be a local register in the program
623
being assembled. The expression should be a register number, and
624
the label field should be blank. At the close of
625
assembly, \MMIXAL\ will report an error if the final value of~G does
626
not exceed all register numbers that are declared local in this way.
627
 
628
A \.{LOCAL} instruction need not be given unless the register number
629
is 32 or~more. (\MMIX\ always considers \.{\$0} through \.{\$31} to be
630
local, so \MMIXAL\ implicitly acts as if the
631
instruction `\.{LOCAL}~\.{\$31}' were present.)
632
 
633
@ Finally, there are two pseudo-instructions to pass information
634
and hints to the loading routine and/or to debuggers that will be
635
using the assembled program.
636
 
637
\bull \.{BSPEC} \
638
begins ``special mode''; the \ should have a value that
639
fits in two bytes, and the label field should be blank.
640
 
641
\bull \.{ESPEC}
642
ends ``special mode''; the operand field is ignored, and the label
643
field should be blank.
644
 
645
\smallskip\noindent
646
All material assembled between \.{BSPEC} and \.{ESPEC} is passed
647
directly to the output, but not loaded as part of the assembled program.
648
Ordinary \MMIX\ instructions cannot appear in special mode; only the
649
pseudo-operations \.{IS}, \.{PREFIX}, \.{BYTE}, \.{WYDE}, \.{TETRA},
650
\.{OCTA}, \.{GREG}, and \.{LOCAL} are allowed. The operand of
651
\.{BSPEC} should have a value that fits in two bytes; this value
652
identifies the kind of data that follows. (For example, \.{BSPEC}~\.0
653
might introduce information about subroutine calling conventions at the
654
current location, and \.{BSPEC}~\.1 might introduce line numbers from
655
a high-level-language program that was compiled into the code at
656
the current place.
657
System routines often need to pass such information through an assembler
658
to the operating system, hence \MMIXAL\ provides a general-purpose conduit.)
659
 
660
@ A program should begin at the special symbolic location \.{Main}
661
@.Main@>
662
(more precisely, at the address corresponding to
663
the fully qualified symbol \.{:Main}).
664
This symbol always has serial number~1, and it must always be defined.
665
@^serial number@>
666
 
667
Locations should not receive assembled data more than once.
668
(More precisely, the loader will load the bitwise~xor of all the
669
data assembled for each byte position; but the general rule ``do not load
670
two things into the same byte'' is safest.)
671
All locations that do not receive assembled data are initially zero,
672
except that the loading routine will put register stack data into
673
segment~3, and the operating system may put command-line data and
674
debugger data into segment~2.
675
(The rudimentary \MMIX\ operating system starts a program
676
with the number of command-line arguments in~\$0, and a pointer to
677
the beginning of an array of argument pointers in~\$1.)
678
Segments 2 and 3 should not get assembled data, unless the
679
user is a true hacker who is willing to take the risk that such data
680
might crash the system.
681
 
682
@* Binary MMO output. When the \MMIXAL\ processor assembles a file
683
called \.{foo.mms}, it produces a binary output file called \.{foo.mmo}.
684
(The suffix \.{mms} stands for ``\MMIX\ symbolic,'' and \.{mmo} stands
685
for ``\MMIX\ object.'') Such \.{mmo} files have a simple structure
686
consisting of a sequence of tetrabytes. Some of the tetrabytes are
687
instructions to a loading routine; others are data to be loaded.
688
@^object files@>
689
 
690
Loader instructions are distinguished from tetrabytes of data by their
691
first (most significant) byte, which has the special escape-code value
692
\Hex{98}, called |mm| in the program below. This code value corresponds
693
to \MMIX's opcode \.{LDVTS}, which is unlikely to occur in tetras of
694
data. The second byte~X of a loader instruction is the loader opcode,
695
called the {\it lopcode}. The third and fourth bytes, Y~and~Z, are
696
operands. Sometimes they are combined into a single 16-bit operand called~YZ.
697
@^lopcodes@>
698
 
699
@d mm 0x98
700
 
701
@ A small, contrived example will help explain the basic ideas of \.{mmo}
702
format. Consider the following input file, called \.{test.mms}:
703
$$\obeyspaces\vbox{\halign{\tt#\hfil\cr
704
\% A peculiar example of MMIXAL\cr
705
\     LOC   Data\_Segment      \% location \#2000000000000000\cr
706
\     OCTA  1F                \% a future reference\cr
707
a    GREG  @@                 \% \$254 is base address for ABCD\cr
708
ABCD BYTE  "ab"              \% two bytes of data\cr
709
\     LOC   \#123456789        \% switch to the instruction segment\cr
710
Main JMP   1F                \% another future reference\cr
711
\     LOC   @@+\#4000           \% skip past 16384 bytes\cr
712
2H   LDB   \$3,ABCD+1         \% use the base address\cr
713
\     BZ    \$3,1F; TRAP       \% and refer to the future again\cr
714
\# 3 "foo.mms"                \% this comment is a line directive\cr
715
\     LOC   2B-4*10           \% move 10 tetras before previous location\cr
716
1H   JMP   2B                \% resolve previous references to 1F\cr
717
\     BSPEC 5                 \% begin special data of type 5\cr
718
\     TETRA {\AM}a<<8             \% four bytes of special data\cr
719
\     WYDE  a-\$0              \% two more bytes of special data\cr
720
\     ESPEC                   \% end a special data packet\cr
721
\     LOC   ABCD+2            \% resume the data segment\cr
722
\     BYTE  "cd",\#98          \% assemble three more bytes of data\cr
723
}}$$
724
It defines a silly program that essentially puts \.{'b'} into register~3;
725
the program halts when it gets to an all-zero \.{TRAP} instruction
726
following the~\.{BZ}. But the assembled output of this file illustrates most
727
of the features of \MMIX\ objects, and in fact \.{test.mms} was the
728
first test file tried by the author when the \MMIXAL\ processor was originally
729
written.
730
 
731
The binary output file \.{test.mmo} assembled from \.{test.mms} consists
732
of the following tetrabytes, shown in hexadecimal notation with brief
733
comments.  Fuller explanations
734
appear with the descriptions of individual lopcodes below.
735
$$
736
\halign{\hskip.5in\tt#&\quad#\hfil\cr
737
98090101&|lop_pre| $1,1$ (preamble, version 1, 1 tetra)\cr
738
36f4a363&(the file creation time)\cr
739
% Sat Mar 20 23:44:35 1999
740
98012001&|lop_loc| $\Hex{20},1$ (data segment, 1 tetra)\cr
741
00000000&(low tetrabyte of address in data segment)\cr
742
00000000&(high tetrabyte of \.{OCTA} \.{1F})\cr
743
00000000&(low tetrabyte, will be fixed up later)\cr
744
61620000&(\.{"ab"}, padded with trailing zeros)\cr
745
\noalign{\penalty-200}
746
98010002&|lop_loc| $0,2$ (instruction segment, 2 tetras)\cr
747
00000001&(high tetrabyte of address in instruction segment)\cr
748
2345678c&(low tetrabyte of address, after alignment)\cr
749
98060002&|lop_file| $0,2$ (file name 0, 2 tetras)\cr
750
74657374&(\.{"test"})\cr
751
2e6d6d73&(\.{".mms"})\cr
752
98070007&|lop_line| 7 (line 7 of the current file)\cr
753
f0000000&(\.{JMP} \.{1F}, will be fixed up later)\cr
754
98024000&|lop_skip| \Hex{4000} (advance 16384 bytes)\cr
755
98070009&|lop_line| 9 (line 9 of the current file)\cr
756
8103fe01&(\.{LDB} \.{\$3,b,1}, uses base address \.b)\cr
757
42030000&(\.{BZ} \.{\$3,1F}, will be fixed later)\cr
758
9807000a&|lop_line| 10 (stay on line 10)\cr
759
00000000&(\.{TRAP})\cr
760
98010002&|lop_loc| $0,2$ (instruction segment, 2 tetras)\cr
761
00000001&(high tetrabyte of address in instruction segment)\cr
762
2345a768&(low tetrabyte of address \.{1H})\cr
763
98050010&|lop_fixrx| 16 (fix 16-bit relative address)\cr
764
0100fff5&(fixup for location \.{@@-4*-11})\cr
765
98040ff7&|lop_fixr| \Hex{ff7} (fix \.{@@-4*\#ff7})\cr
766
98032001&|lop_fixo| $\Hex{20},1$ (data segment, 1 tetra)\cr
767
00000000&(low tetrabyte of data segment address to fix)\cr
768
98060102&|lop_file| $1,2$ (file name 1, 2 tetras)\cr
769
666f6f2e&(\.{"foo."})\cr
770
6d6d7300&(\.{"mms",0})\cr
771
98070004&|lop_line| 4 (line 4 of the current file)\cr
772
f000000a&(\.{JMP} \.{2B})\cr
773
98080005&|lop_spec| 5 (begin special data of type 5)\cr
774
00000200&(\.{TETRA} \.{\&a<<8})\cr
775
00fe0000&(\.{WYDE} \.{a-\$0})\cr
776
98012001&|lop_loc| $\Hex{20},1$ (data segment, 1 tetra)\cr
777
0000000a&(low tetrabyte of address in data segment)\cr
778
00006364&(\.{"cd"} with leading zeros, because of alignment)\cr
779
98000001&|lop_quote| (don't treat next tetrabyte as a lopcode)\cr
780
98000000&(\.{BYTE} \.{\#98}, padded with trailing zeros)\cr
781
980a00fe&|lop_post| \$254 (begin postamble, G is 254)\cr
782
20000000&(high tetrabyte of the initial contents of \$254)\cr
783
00000008&(low tetrabyte of base address \$254)\cr
784
00000001&(high tetrabyte of the initial contents of \$255)\cr
785
2345678c&(low tetrabyte of \$255, is address of \.{Main})\cr
786
980b0000&|lop_stab| (begin symbol table)\cr
787
203a5040&(compressed form for symbol table as a ternary trie)\cr
788
50404020\cr
789
41204220\cr
790
43094408\cr
791
83404020&(\.{ABCD} = \Hex{2000000000000008}, serial 3)\cr
792
4d206120\cr
793
69056e01\cr
794
2345678c\cr
795
81400f61&(\.{Main} = \Hex{000000012345678c}, serial 1)\cr
796
fe820000&(\.{a} = \$254, serial 2)\cr
797
980c000a&|lop_end| (end symbol table, 10 tetras)\cr
798
}$$
799
 
800
@ When a tetrabyte of the \.{mmo} file does not begin with the escape code,
801
it is loaded into the current location~$\lambda$, and $\lambda$ is increased
802
to the next higher multiple of~4.
803
(If $\lambda$ is not a multiple of~4, the tetrabyte actually goes
804
into location $\lambda\land(-4)=4\lfloor\lambda/4\rfloor$, according
805
to \MMIX's usual conventions.) The current line number is also increased
806
by~1, if it is nonzero.
807
 
808
When a tetrabyte does begin with the escape code, its next byte
809
is the lopcode defining a loader instruction. There are thirteen lopcodes:
810
 
811
\bull |lop_quote|: $\rm X=\Hex{00}$, $\rm YZ=1$. Treat the next tetra as
812
an ordinary tetrabyte, even if it begins with the escape code.
813
 
814
\bull |lop_loc|: $\rm X=\Hex{01}$, $\rm Y=high$ byte, $\rm Z=tetra$ count
815
($\rm Z=1$~or~2). Set the current location to the 64-bit address defined
816
by the next Z tetras, plus $\rm 2^{56}Y$. Usually $\rm Y=0$ (for the
817
instruction segment) or $\rm Y=\Hex{20}$ (for the data segment).
818
If $\rm Z=2$, the high tetra appears first.
819
 
820
\bull |lop_skip|: $\rm X=\Hex{02}$, $\rm YZ=delta$. Increase the
821
current location by~YZ.
822
 
823
\bull |lop_fixo|: $\rm X=\Hex{03}$, $\rm Y=high$ byte, $\rm Z=tetra$ count
824
($\rm Z=1$~or~2). Load the value of the current location~$\lambda$ into
825
octabyte~P, where P~is the 64-bit address defined by the next Z tetras
826
plus $\rm2^{56}Y$ as in |lop_loc|. (The octabyte at~P was previously assembled
827
as zero because of a future reference.)
828
 
829
\bull |lop_fixr|: $\rm X=\Hex{04}$, $\rm YZ=delta$. Load YZ into the YZ~field
830
of the tetrabyte in location~P, where P~is
831
$\rm\lambda-4YZ$, namely the address that precedes the current location
832
by YZ~tetrabytes. (This tetrabyte was previously loaded with an \MMIX\
833
instruction that takes a relative address: a branch, probable branch,
834
\.{JMP}, \.{PUSHJ}, or~\.{GETA}. Its YZ~field was previously
835
assembled as zero because of a future reference.)
836
 
837
\bull |lop_fixrx|: $\rm X=\Hex{05}$, $\rm Y=0$, $\rm Z=16$ or 24.
838
Proceed as in |lop_fixr|,
839
but load $\delta$ into tetrabyte $\rm P=\lambda-4\delta$ instead of loading
840
YZ into $\rm P=\lambda-4YZ$. Here $\delta$ is the value of the tetrabyte
841
following the |lop_fixrx| instruction; its leading byte will either
842
 
843
{\it negative\/} number $(\delta\land\Hex{ffffff})-2^{\rm Z}$ when
844
calculating the address~P. (The latter case arises only rarely,
845
but it is needed when fixing up a relative ``future'' reference that
846
ultimately leads to a ``backward'' instruction. The value of~$\delta$ that
847
is xored into location~P in such cases will change \.{BZ} to \.{BZB},
848
or \.{JMP} to \.{JMPB}, etc.; we have $\rm Z=24$ when fixing a~\.{JMP},
849
$\rm Z=16$ otherwise.)
850
 
851
\bull |lop_file|: $\rm X=\Hex{06}$, $\rm Y=file$ number, $\rm Z=tetra$ count.
852
Set the current file number to~Y and the current line number to~zero. If this
853
file number has occurred previously, Z~should be zero; otherwise Z~should be
854
positive, and the next Z tetrabytes are the characters of the file name in
855
big-endian order.
856
Trailing zeros follow the file name if its length is not a multiple of~4.
857
 
858
\bull |lop_line|: $\rm X=\Hex{07}$, $\rm YZ=line$ number. Set the current line
859
number to~YZ\null. If the line number is nonzero, the current file and current
860
line should correspond to the source location that generated the next data to
861
be loaded, for use in diagnostic messages. (The \MMIXAL\ processor gives
862
precise line numbers to the sources of tetrabytes in segment~0, which tend to
863
be instructions, but not to the sources of tetrabytes assembled in other
864
segments.)
865
 
866
\bull |lop_spec|: $\rm X=\Hex{08}$, $\rm YZ=type$. Begin special data of
867
type~YZ\null. The subsequent tetrabytes, continuing until the next loader
868
operation other than |lop_quote|, comprise the special data. A |lop_quote|
869
instruction allows tetrabytes of special data to begin with the escape code.
870
 
871
\bull |lop_pre|: $\rm X=\Hex{09}$, $\rm Y=1$, $\rm Z=tetra$ count. A~|lop_pre|
872
instruction, which defines the ``preamble,'' must be the first tetrabyte of
873
every \.{mmo} file. The Y~field specifies the version number of \.{mmo}
874
format, currently~1; other version numbers may be defined later, but
875
version~1 should always be supported as described in the present document.
876
The Z~tetrabytes following a |lop_pre| command provide additional information
877
that might be of interest to system routines. If $\rm Z>0$, the first tetra
878
of additional information records the time that this \.{mmo} file was
879
created, measured in seconds since 00:00:00 Greenwich Mean Time on
880
1~Jan~1970.
881
 
882
\bull |lop_post|: $\rm X=\Hex{0a}$, $\rm Y=0$, $\rm Z=G$ (must be 32~or~more).
883
This instruction begins the {\it postamble}, which follows all instructions
884
and data to be loaded. It causes the loaded program to begin with rG equal to
885
the stated value of~G, and with \$G, $\rm G+1$, \dots,~\$255 initially set to
886
the values of the next $\rm(256-G)*2$ tetrabytes. These tetrabytes specify
887
$\rm 256-G$ octabytes in big-endian fashion (high half first).
888
 
889
\bull |lop_stab|: $\rm X=\Hex{0b}$, $\rm YZ=0$. This instruction must appear
890
immediately after the $\rm(256-G)*2$ tetrabytes following~|lop_post|. It is
891
followed by the symbol table, which lists the equivalents of all user-defined
892
symbols in a compact form that will be described later.
893
 
894
\bull |lop_end|: $\rm X=\Hex{0c}$, $\rm YZ=tetra$ count. This instruction
895
must be the very last tetrabyte of each \.{mmo} file. Furthermore,
896
exactly YZ tetrabytes must appear between it and the |lop_stab| command.
897
(Therefore a program can easily find the symbol table without reading
898
forward through the entire \.{mmo} file.)
899
 
900
\smallskip
901
A separate routine called \.{MMOtype} is available to translate
902
binary \.{mmo} files into human-readable form.
903
 
904
@d lop_quote 0x0 /* the quotation lopcode */
905
@d lop_loc 0x1 /* the location lopcode */
906
@d lop_skip 0x2 /* the skip lopcode */
907
@d lop_fixo 0x3 /* the octabyte-fix lopcode */
908
@d lop_fixr 0x4 /* the relative-fix lopcode */
909
@d lop_fixrx 0x5 /* extended relative-fix lopcode */
910
@d lop_file 0x6 /* the file name lopcode */
911
@d lop_line 0x7 /* the file position lopcode */
912
@d lop_spec 0x8 /* the special hook lopcode */
913
@d lop_pre 0x9 /* the preamble lopcode */
914
@d lop_post 0xa /* the postamble lopcode */
915
@d lop_stab 0xb /* the symbol table lopcode */
916
@d lop_end 0xc /* the end-it-all lopcode */
917
 
918
@ Many readers will have noticed that \MMIXAL\ has no facilities for
919
relocatable output, nor does \.{mmo} format support such features. The
920
author's first drafts of \MMIXAL\ and \.{mmo} did allow relocatable objects,
921
with external linkages, but the rules were substantially more complicated and
922
therefore inconsistent with the goals of {\sl The Art of Computer Programming}.
923
The present design might actually prove to be superior to the current
924
practice, now that computer memory is significantly cheaper than it
925
used to be, because one-pass assembly and loading are extremely fast when
926
relocatability and external linkages are disallowed. Different program modules
927
can be assembled together about as fast as they could be linked together under
928
a relocatable scheme, and they can communicate with each other in much more
929
flexible ways. Debugging tools are enhanced when open-source libraries are
930
combined with user programs, and such libraries will certainly improve in
931
quality when their source form is accessible to a larger community of users.
932
 
933
@* Basic data types.
934
This program for the 64-bit \MMIX\ architecture is based on 32-bit integer
935
arithmetic, because nearly every computer available to the author at the time
936
of writing was limited in that way.
937
Details of the basic arithmetic appear in a separate program module
938
called {\mc MMIX-ARITH}, because the same routines are needed also
939
for the simulators. The definition of type \&{tetra} should be changed, if
940
necessary, to conform with the definitions found in {\mc MMIX-ARITH}.
941
@^system dependencies@>
942
 
943
@=
944
typedef unsigned int tetra;
945
  /* assumes that an int is exactly 32 bits wide */
946
typedef struct { tetra h,l;} octa; /* two tetrabytes make one octabyte */
947
typedef enum {@!false,@!true}@+@!bool;
948
 
949
@ @=
950
extern octa zero_octa; /* |zero_octa.h=zero_octa.l=0| */
951
extern octa neg_one; /* |neg_one.h=neg_one.l=-1| */
952
extern octa aux; /* auxiliary output of a subroutine */
953
extern bool overflow; /* set by certain subroutines for signed arithmetic */
954
 
955
@ Most of the subroutines in {\mc MMIX-ARITH} return an octabyte as
956
a function of two octabytes; for example, |oplus(y,z)| returns the
957
sum of octabytes |y| and~|z|. Division inputs the high
958
half of a dividend in the global variable~|aux| and returns
959
the remainder in~|aux|.
960
 
961
@=
962
extern octa oplus @,@,@[ARGS((octa y,octa z))@];
963
  /* unsigned $y+z$ */
964
extern octa ominus @,@,@[ARGS((octa y,octa z))@];
965
  /* unsigned $y-z$ */
966
extern octa incr @,@,@[ARGS((octa y,int delta))@];
967
  /* unsigned $y+\delta$ ($\delta$ is signed) */
968
extern octa oand @,@,@[ARGS((octa y,octa z))@];
969
  /* $y\land z$ */
970
extern octa shift_left @,@,@[ARGS((octa y,int s))@];
971
  /* $y\LL s$, $0\le s\le64$ */
972
extern octa shift_right @,@,@[ARGS((octa y,int s,int uns))@];
973
  /* $y\GG s$, signed if |!uns| */
974
extern octa omult @,@,@[ARGS((octa y,octa z))@];
975
  /* unsigned $(|aux|,x)=y\times z$ */
976
extern octa odiv @,@,@[ARGS((octa x,octa y,octa z))@];
977
  /* unsigned $(x,y)/z$; $|aux|=(x,y)\bmod z$ */
978
 
979
@ Here's a rudimentary check to see if arithmetic is in trouble.
980
 
981
@=
982
acc=shift_left(neg_one,1);
983
if (acc.h!=0xffffffff) panic("Type tetra is not implemented correctly");
984
@.Type tetra...@>
985
 
986
@ Future versions of this program will work with symbols formed from Unicode
987
characters, but the present code limits itself to an 8-bit subset.
988
@^Unicode@>
989
The type \&{Char} is defined here in order to ease the later transition:
990
At present, \&{Char} is the same as \&{unsigned} \&{char}, but
991
\&{Char} can be changed to a 16-bit type in the Unicode version.
992
 
993
Other changes will also be necessary when the transition to Unicode is made;
994
for example, some calls of |fprintf| will become calls of |fwprintf|,
995
and some occurrences of \.{\%s} will become \.{\%ls} in print formats.
996
The switchable type name \&{Char} provides at least a first step
997
towards a brighter future with Unicode.
998
 
999
@=
1000
typedef unsigned char Char; /* bytes that will become wydes some day */
1001
 
1002
@ While we're talking about classic systems versus future systems, we
1003
might as well define the |ARGS| macro, which makes function prototypes
1004
available on {\mc ANSI \CEE/} systems without making them
1005
uncompilable on older systems. Each subroutine below is declared first
1006
with a prototype, then with an old-style definition.
1007
 
1008
@=
1009
#ifdef __STDC__
1010
#define ARGS(list) list
1011
#else
1012
#define ARGS(list) ()
1013
#endif
1014
 
1015
@* Basic input and output. Input goes into a buffer that is normally
1016
limited to 72 characters. This limit can be raised, by using the
1017
\.{-b} option when invoking the assembler; but short buffers will keep listings
1018
from becoming unwieldy, because a symbolic listing adds 19 characters per~line.
1019
 
1020
@=
1021
if (buf_size<72) buf_size=72;
1022
buffer=(Char*)calloc(buf_size+1,sizeof(Char));
1023
lab_field=(Char*)calloc(buf_size+1,sizeof(Char));
1024
op_field=(Char*)calloc(buf_size,sizeof(Char));
1025
operand_list=(Char*)calloc(buf_size,sizeof(Char));
1026
err_buf=(Char*)calloc(buf_size+60,sizeof(Char));
1027
if (!buffer || !lab_field || !op_field || !operand_list || !err_buf)
1028
  panic("No room for the buffers");
1029
@.No room...@>
1030
 
1031
@ @=
1032
Char *buffer; /* raw input of the current line */
1033
Char *buf_ptr; /* current position within |buffer| */
1034
Char *lab_field; /* copy of the label field of the current instruction */
1035
Char *op_field; /* copy of the opcode field of the current instruction */
1036
Char *operand_list; /* copy of the operand field of the current instruction */
1037
Char *err_buf; /* place where dynamic error messages are sprinted */
1038
 
1039
@ @=
1040
if (!fgets(buffer,buf_size+1,src_file)) break;
1041
line_no++;
1042
line_listed=false;
1043
j=strlen(buffer);
1044
if (buffer[j-1]=='\n') buffer[j-1]='\0'; /* remove the newline */
1045
else if ((j=fgetc(src_file))!=EOF)
1046
  @;
1047
if (buffer[0]=='#') @;
1048
buf_ptr=buffer;
1049
 
1050
@ @=
1051
{
1052
  while(j!='\n' && j!= EOF) j=fgetc(src_file);
1053
  if (!long_warning_given) {
1054
    long_warning_given=true;
1055
    err("*trailing characters of long input line have been dropped");
1056
@.trailing characters...@>
1057
    fprintf(stderr,
1058
       "(say `-b ' to increase the length of my input buffer)\n");
1059
  }@+else err("*trailing characters dropped");
1060
}
1061
 
1062
@ @=
1063
int cur_file; /* index of the current file in |filename| */
1064
int line_no; /* current position in the file */
1065
bool line_listed; /* have we listed the buffer contents? */
1066
bool long_warning_given; /* have we given the hint about \.{-b}? */
1067
 
1068
@ We keep track of source file name and line number at all times, for
1069
error reporting and for synchronization data in the object file.
1070
Up to 256 different source file names can be remembered.
1071
 
1072
@=
1073
Char *filename[257];
1074
  /* source file names, including those in line directives */
1075
int filename_count; /* how many |filename| entries have we filled? */
1076
 
1077
@ If the current line is a line directive, it will also be treated
1078
as a comment by the assembler.
1079
 
1080
@=
1081
{
1082
  for (p=buffer+1;isspace(*p);p++);
1083
  for (j=*p++-'0';isdigit(*p);p++) j=10*j+*p-'0';
1084
  for (;isspace(*p);p++);
1085
  if (*p=='\"') {
1086
    if (!filename[filename_count]) {
1087
      filename[filename_count]=(Char*)calloc(FILENAME_MAX+1,sizeof(Char));
1088
      if (!filename[filename_count])
1089
        panic("Capacity exceeded: Out of filename memory");
1090
@.Capacity exceeded...@>
1091
    }
1092
    for (p++,q=filename[filename_count];*p && *p!='\"';p++,q++) *q=*p;
1093
    if (*p=='\"' && *(p-1)!='\"') { /* yes, it's a line directive */
1094
      *q='\0';
1095
      for (k=0;strcmp(filename[k],filename[filename_count])!=0;k++);
1096
      if (k==filename_count) filename_count++;
1097
      cur_file=k;
1098
      line_no=j-1;
1099
    }
1100
  }
1101
}
1102
 
1103
@ Archaic versions of the \CEE/ library do not define |FILENAME_MAX|.
1104
 
1105
@=
1106
#ifndef FILENAME_MAX
1107
#define FILENAME_MAX 256
1108
#endif
1109
 
1110
@ @=
1111
register Char *p,*q; /* the place where we're currently scanning */
1112
 
1113
@ The next several subroutines are useful for preparing a listing of
1114
the assembled results. In such a listing, which the user can request
1115
with a command-line option, we fill the leftmost 19 columns with
1116
a representation of the output that has been assembled from the
1117
input in the buffer. Sometimes the assembled output requires
1118
more than one line, because we have room to output only a tetrabyte per line.
1119
 
1120
The |flush_listing_line| subroutine is called when we have finished
1121
generating one line's worth of assembled material. Its parameter is
1122
a string to be printed between the assembled material and the
1123
buffer contents, if the input line hasn't yet been echoed. The length
1124
of this string should be 19 minus the number of characters already printed
1125
on the current line of the listing.
1126
 
1127
@=
1128
void flush_listing_line @,@,@[ARGS((char*))@];@+@t}\6{@>
1129
void flush_listing_line(s)
1130
  char *s;
1131
{
1132
  if (line_listed) fprintf(listing_file,"\n");
1133
  else {
1134
    fprintf(listing_file,"%s%s\n",s,buffer);
1135
    line_listed=true;
1136
  }
1137
}
1138
 
1139
@ Only the three least significant hex digits of a location are shown on
1140
the listing, unless the other digits have changed. The following subroutine
1141
prints an extra line when a change needs to be shown.
1142
 
1143
@=
1144
void update_listing_loc @,@,@[ARGS((int))@];@+@t}\6{@>
1145
void update_listing_loc(k)
1146
  int k; /* the location to display, mod 4 */
1147
{
1148
  if (cur_loc.h!=listing_loc.h || ((cur_loc.l^listing_loc.l)&0xfffff000)) {
1149
    fprintf(listing_file,"%08x%08x:",cur_loc.h,(cur_loc.l&-4)|k);
1150
    flush_listing_line("  ");
1151
  }
1152
  listing_loc.h=cur_loc.h;@+
1153
  listing_loc.l=(cur_loc.l&-4)|k;
1154
}
1155
 
1156
@ @=
1157
octa cur_loc; /* current location of assembled output */
1158
octa listing_loc; /* current location on the listing */
1159
unsigned char hold_buf[4]; /* assembled bytes */
1160
unsigned char held_bits; /* which bytes of |hold_buf| are active? */
1161
unsigned char listing_bits; /* which of them haven't been listed yet? */
1162
bool spec_mode; /* are we between |BSPEC| and |ESPEC|? */
1163
tetra spec_mode_loc; /* number of bytes in the current special output */
1164
 
1165
@ When bytes are assembled, they are placed into the |hold_buf|.
1166
More precisely, a byte assembled for a location that is |j|~plus a
1167
multiple of~4 is placed into |hold_buf[j]|; two auxiliary variables,
1168
|held_bits| and |listing_bits|, are then increased by |1<
1169
Furthermore, |listing_bits|
1170
is increased by |0x10<
1171
resolved later.
1172
 
1173
The bytes are held until we need to output them.
1174
The |listing_clear| routine lists any that have been held
1175
but not yet shown. It should be called only when |listing_bits!=0|.
1176
 
1177
@=
1178
void listing_clear @,@,@[ARGS((void))@];@+@t}\6{@>
1179
void listing_clear()
1180
{
1181
  register int j,k;
1182
  for (k=0;k<4;k++) if (listing_bits&(1<
1183
  if (spec_mode) fprintf(listing_file,"         ");
1184
  else {
1185
    update_listing_loc(k);
1186
    fprintf(listing_file," ...%03x: ",(listing_loc.l&0xffc)|k);
1187
  }
1188
  for (j=0;j<4;j++)
1189
    if (listing_bits&(0x10<
1190
    else if (listing_bits&(1<
1191
    else fprintf(listing_file,"  ");
1192
  flush_listing_line("  ");
1193
  listing_bits=0;
1194
}
1195
 
1196
@ Error messages are written to |stderr|. If the message begins with
1197
`\.*' it is merely a warning; if it begins with `\.!' it is fatal;
1198
otherwise the error is probably serious enough to make manual correction
1199
necessary, yet it is not tragic. Errors and warnings appear
1200
also on the optional listing file.
1201
 
1202
@d err(m) {@+report_error(m);@+if (m[0]!='*') goto bypass;@+}
1203
@d derr(m,p) {@+sprintf(err_buf,m,p);
1204
   report_error(err_buf);@+if (err_buf[0]!='*') goto bypass;@+}
1205
@d dderr(m,p,q) {@+sprintf(err_buf,m,p,q);
1206
   report_error(err_buf);@+if (err_buf[0]!='*') goto bypass;@+}
1207
@d panic(m) {@+sprintf(err_buf,"!%s",m);@+report_error(err_buf);@+}
1208
@d dpanic(m,p) {@+err_buf[0]='!';@+sprintf(err_buf+1,m,p);@+
1209
                                          report_error(err_buf);@+}
1210
 
1211
@=
1212
void report_error @,@,@[ARGS((char*))@];@+@t}\6{@>
1213
void report_error(message)
1214
  char *message;
1215
{
1216
  if (!filename[cur_file]) filename[cur_file]="(nofile)";
1217
  if (message[0]=='*')
1218
    fprintf(stderr,"\"%s\", line %d warning: %s\n",
1219
                 filename[cur_file],line_no,message+1);
1220
  else if (message[0]=='!')
1221
    fprintf(stderr,"\"%s\", line %d fatal error: %s\n",
1222
                 filename[cur_file],line_no,message+1);
1223
  else {
1224
    fprintf(stderr,"\"%s\", line %d: %s!\n",
1225
                 filename[cur_file],line_no,message);
1226
    err_count++;
1227
  }
1228
  if (listing_file) {
1229
    if (!line_listed) flush_listing_line("****************** ");
1230
    if (message[0]=='*') fprintf(listing_file,
1231
            "************ warning: %s\n",message+1);
1232
    else if (message[0]=='!') fprintf(listing_file,
1233
            "******** fatal error: %s!\n",message+1);
1234
    else fprintf(listing_file,
1235
            "********** error: %s!\n",message);
1236
  }
1237
  if (message[0]=='!') exit(-2);
1238
}
1239
 
1240
@ @=
1241
int err_count; /* this many errors were found */
1242
 
1243
@ Output to the binary |obj_file| occurs four bytes at a time. The
1244
bytes are assembled in small buffers, not output as single tetrabytes,
1245
because we want the output to be big-endian even when the assembler
1246
is running on a little-endian machine.
1247
@^big-endian versus little-endian@>
1248
@^little-endian versus big-endian@>
1249
 
1250
@d mmo_write(buf) if (fwrite(buf,1,4,obj_file)!=4)
1251
     dpanic("Can't write on %s",obj_file_name)
1252
@.Can't write...@>
1253
 
1254
@=
1255
void mmo_clear @,@,@[ARGS((void))@];
1256
void mmo_out @,@,@[ARGS((void))@];
1257
unsigned char lop_quote_command[4]={mm,lop_quote,0,1};
1258
void mmo_clear() /* clears |hold_buf|, when |held_bits!=0| */
1259
{
1260
  if (hold_buf[0]==mm) mmo_write(lop_quote_command);
1261
  mmo_write(hold_buf);
1262
  if (listing_file && listing_bits) listing_clear();
1263
  held_bits=0;
1264
  hold_buf[0]=hold_buf[1]=hold_buf[2]=hold_buf[3]=0;
1265
  mmo_cur_loc=incr(mmo_cur_loc,4);@+ mmo_cur_loc.l&=-4;
1266
  if (mmo_line_no) mmo_line_no++;
1267
}
1268
@#
1269
unsigned char mmo_buf[4];
1270
int mmo_ptr;
1271
void mmo_out() /* output the contents of |mmo_buf| */
1272
{
1273
  if (held_bits) mmo_clear();
1274
  mmo_write(mmo_buf);
1275
}
1276
 
1277
@ @=
1278
void mmo_tetra @,@,@[ARGS((tetra))@];
1279
void mmo_byte @,@,@[ARGS((unsigned char))@];
1280
void mmo_lop @,@,@[ARGS((char,unsigned char,unsigned char))@];
1281
void mmo_lopp @,@,@[ARGS((char,unsigned short))@];
1282
void mmo_tetra(t) /* output a tetrabyte */
1283
  tetra t;
1284
{
1285
  mmo_buf[0]=t>>24;@+ mmo_buf[1]=(t>>16)&0xff;
1286
  mmo_buf[2]=(t>>8)&0xff;@+ mmo_buf[3]=t&0xff;
1287
  mmo_out();
1288
}
1289
@#
1290
void mmo_byte(b)
1291
  unsigned char b;
1292
{
1293
  mmo_buf[(mmo_ptr++)&3]=b;
1294
  if (!(mmo_ptr&3)) mmo_out();
1295
}
1296
@#
1297
void mmo_lop(x,y,z) /* output a loader operation */
1298
  char x;
1299
  unsigned char y,z;
1300
{
1301
  mmo_buf[0]=mm;@+ mmo_buf[1]=x;@+ mmo_buf[2]=y;@+ mmo_buf[3]=z;
1302
  mmo_out();
1303
}
1304
@#
1305
void mmo_lopp(x,yz) /* output a loader operation with two-byte operand */
1306
  char x;
1307
  unsigned short yz;
1308
{
1309
  mmo_buf[0]=mm;@+ mmo_buf[1]=x;@+
1310
  mmo_buf[2]=yz>>8;@+ mmo_buf[3]=yz&0xff;
1311
  mmo_out();
1312
}
1313
 
1314
@ The |mmo_loc| subroutine makes the current location in the object file
1315
equal to |cur_loc|.
1316
 
1317
@=
1318
void mmo_loc @,@,@[ARGS((void))@];@+@t}\6{@>
1319
void mmo_loc()
1320
{
1321
  octa o;
1322
  if (held_bits) mmo_clear();
1323
  o=ominus(cur_loc,mmo_cur_loc);
1324
  if (o.h==0 && o.l<0x10000) {
1325
    if (o.l) mmo_lopp(lop_skip,o.l);
1326
  }@+else {
1327
    if (cur_loc.h&0xffffff) {
1328
      mmo_lop(lop_loc,0,2);
1329
      mmo_tetra(cur_loc.h);
1330
    }@+else mmo_lop(lop_loc,cur_loc.h>>24,1);
1331
    mmo_tetra(cur_loc.l);
1332
  }
1333
  mmo_cur_loc=cur_loc;
1334
}
1335
 
1336
@ Similarly, the |mmo_sync| subroutine makes sure that the current file and
1337
line number in the output file agree with |cur_file| and |line_no|.
1338
 
1339
@=
1340
void mmo_sync @,@,@[ARGS((void))@];@+@t}\6{@>
1341
void mmo_sync()
1342
{
1343
  register int j; register unsigned char *p;
1344
  if (cur_file!=mmo_cur_file) {
1345
    if (filename_passed[cur_file]) mmo_lop(lop_file,cur_file,0);
1346
    else {
1347
      mmo_lop(lop_file,cur_file,(strlen(filename[cur_file])+3)>>2);
1348
      for (j=0,p=filename[cur_file];*p;p++,j=(j+1)&3) {
1349
        mmo_buf[j]=*p;
1350
        if (j==3) mmo_out();
1351
      }
1352
      if (j) {
1353
        for (;j<4;j++) mmo_buf[j]=0;
1354
        mmo_out();
1355
      }
1356
    filename_passed[cur_file]=1;
1357
    }
1358
    mmo_cur_file=cur_file;
1359
    mmo_line_no=0;
1360
  }
1361
  if (line_no!=mmo_line_no) {
1362
    if (line_no>=0x10000)
1363
      panic("I can't deal with line numbers exceeding 65535");
1364
@.I can't deal with...@>
1365
    mmo_lopp(lop_line,line_no);
1366
    mmo_line_no=line_no;
1367
  }
1368
}
1369
 
1370
@ @=
1371
octa mmo_cur_loc; /* current location in the object file */
1372
int mmo_line_no; /* current line number in the \.{mmo} output so far */
1373
int mmo_cur_file; /* index of the current file in the \.{mmo} output so far */
1374
char filename_passed[256]; /* has a filename been recorded in the output? */
1375
 
1376
@ Here is a basic subroutine that assembles |k| bytes starting at |cur_loc|.
1377
The value of |k| should be 1, 2, or~4, and |cur_loc| should be a multiple
1378
of~|k|. The |x_bits| parameter tells which bytes, if any, are part of
1379
a future reference.
1380
 
1381
@=
1382
void assemble @,@,@[ARGS((char,tetra,unsigned char))@];@+@t}\6{@>
1383
void assemble(k,dat,x_bits)
1384
  char k;
1385
  tetra dat;
1386
  unsigned char x_bits;
1387
{
1388
  register int j,jj,l;
1389
  if (spec_mode) l=spec_mode_loc;
1390
  else {
1391
    l=cur_loc.l;
1392
    @;
1393
    if (!held_bits && !(cur_loc.h&0xe0000000)) mmo_sync();
1394
  }
1395
  for (j=0;j
1396
    jj=(l+j)&3;
1397
    hold_buf[jj]=(dat>>(8*(k-1-j)))&0xff;
1398
    held_bits|=1<
1399
    listing_bits|=1<
1400
  }
1401
  listing_bits|=x_bits;
1402
  if (((l+k)&3)==0) {
1403
    if (listing_file) listing_clear();
1404
    mmo_clear();
1405
  }
1406
  if (spec_mode) spec_mode_loc+=k; else cur_loc=incr(cur_loc,k);
1407
}
1408
 
1409
@ @=
1410
if (cur_loc.h!=mmo_cur_loc.h || ((cur_loc.l^mmo_cur_loc.l)&0xfffffffc))
1411
  mmo_loc();
1412
 
1413
@* The symbol table. Symbols are stored and retrieved by means of
1414
a {\it ternary search trie}, following ideas of Bentley and
1415
Sedgewick. (See {\sl ACM--SIAM Symp.\ on Discrete Algorithms\/ \bf8} (1997),
1416
360--369; R.~Sedgewick, {\sl Algorithms in C\/} (Reading, Mass.:\
1417
Addison--Wesley, 1998), \S15.4.) Each trie node stores a character,
1418
@^Bentley, Jon Louis@>
1419
@^Sedgewick, Robert@>
1420
and there are branches to subtries for the cases where a given character
1421
is less than, equal to, or greater than the character in the trie.
1422
There also is a pointer to a symbol table entry if a symbol ends at
1423
the current node.
1424
 
1425
@s sym_tab_struct int
1426
 
1427
@=
1428
typedef struct ternary_trie_struct {
1429
  unsigned short ch; /* the (possibly wyde) character stored here */
1430
  struct ternary_trie_struct *left, *mid, *right; /* downward
1431
                                                 in the ternary trie */
1432
  struct sym_tab_struct *sym; /* equivalents of symbols */
1433
} trie_node;
1434
 
1435
@ We allocate trie nodes in chunks of 1000 at a time.
1436
 
1437
@=
1438
trie_node* new_trie_node @,@,@[ARGS((void))@];@+@t}\6{@>
1439
trie_node* new_trie_node()
1440
{
1441
  register trie_node *t=next_trie_node;
1442
  if (t==last_trie_node) {
1443
    t=(trie_node*)calloc(1000,sizeof(trie_node));
1444
    if (!t) panic("Capacity exceeded: Out of trie memory");
1445
@.Capacity exceeded...@>
1446
    last_trie_node=t+1000;
1447
  }
1448
  next_trie_node=t+1;
1449
  return t;
1450
}
1451
 
1452
@ @=
1453
trie_node *trie_root; /* root of the trie */
1454
trie_node *op_root; /* root of subtrie for opcodes */
1455
trie_node *next_trie_node, *last_trie_node; /* allocation control */
1456
trie_node *cur_prefix; /* root of subtrie for unqualified symbols */
1457
 
1458
@ The |trie_search| subroutine starts at a given node of the trie and finds
1459
a given string in its middle subtrie, inserting new nodes if necessary.
1460
The string ends with the first nonletter or nondigit; the location
1461
of the terminating character is stored in global variable~|terminator|.
1462
 
1463
@d isletter(c) (isalpha(c)||c=='_'||c==':'||c>126)
1464
 
1465
@=
1466
trie_node *trie_search @,@,@[ARGS((trie_node*,Char*))@];
1467
Char *terminator; /* where the search ended */
1468
trie_node *trie_search(t,s)
1469
  trie_node *t;
1470
  Char *s;
1471
{
1472
  register trie_node *tt=t;
1473
  register Char *p=s;
1474
  while (1) {
1475
    if (!isletter(*p) && !isdigit(*p)) {
1476
      terminator=p;@+return tt;
1477
    }
1478
    if (tt->mid) {
1479
      tt=tt->mid;
1480
      while (*p!=tt->ch) {
1481
        if (*pch) {
1482
          if (tt->left) tt=tt->left;
1483
          else {
1484
            tt->left=new_trie_node();@+tt=tt->left;@+goto store_new_char;
1485
          }
1486
        }@+else {
1487
          if (tt->right) tt=tt->right;
1488
          else {
1489
            tt->right=new_trie_node();@+tt=tt->right;@+goto store_new_char;
1490
          }
1491
        }
1492
      }
1493
      p++;
1494
    }@+else {
1495
      tt->mid=new_trie_node();@+tt=tt->mid;
1496
  store_new_char: tt->ch=*p++;
1497
    }
1498
  }
1499
}
1500
 
1501
@ Symbol table nodes hold the serial numbers and
1502
equivalents of defined symbols. They also
1503
hold ``fixup information'' for undefined symbols; this will allow the
1504
loader to correct any previously assembled instructions that refer to such
1505
symbols when they are eventually defined.
1506
 
1507
In the symbol table node for a defined symbol, the |link| field
1508
has one of the special codes |DEFINED| or |REGISTER| or |PREDEFINED|, and the
1509
|equiv| field holds the defined value. The |serial| number
1510
is a unique identifier for all user-defined symbols.
1511
 
1512
In the symbol table node for an undefined symbol, the |equiv| field
1513
is ignored. The |link| field
1514
points to the first node of fixup information; that node is, in turn,
1515
a symbol table node that might link to other fixups. The |serial| number
1516
in a fixup node is either 0 or 1 or 2, meaning respectively ``fixup the
1517
octabyte pointed to by |equiv|'' or ``fixup the relative address in the YZ
1518
field of the instruction pointed to by |equiv|'' or ``fixup the relative
1519
address in the XYZ field of the instruction pointed to by |equiv|.''
1520
 
1521
@s sym_node int
1522
@s bool int
1523
 
1524
@d DEFINED (sym_node*)1 /* code value for octabyte equivalents */
1525
@d REGISTER (sym_node*)2 /* code value for register-number equivalents */
1526
@d PREDEFINED (sym_node*)3 /* code value for not-yet-used equivalents */
1527
@d fix_o 0 /* |serial| code for octabyte fixup */
1528
@d fix_yz 1 /* |serial| code for relative fixup */
1529
@d fix_xyz 2 /* |serial| code for \.{JMP} fixup */
1530
 
1531
@=
1532
typedef struct sym_tab_struct {
1533
  int serial; /* serial number of symbol; type number for fixups */
1534
  struct sym_tab_struct *link; /* |DEFINED| status or link to fixup */
1535
  octa equiv; /* the equivalent value */
1536
} sym_node;
1537
 
1538
@ The allocation of new symbol table nodes proceeds in chunks, like the
1539
allocation of trie nodes. But in this case we also have the possibility
1540
of reusing old fixup nodes that are no longer needed.
1541
 
1542
@d recycle_fixup(pp) pp->link=sym_avail, sym_avail=pp
1543
 
1544
@=
1545
sym_node* new_sym_node @,@,@[ARGS((bool))@];@+@t}\6{@>
1546
sym_node* new_sym_node(serialize)
1547
  bool serialize; /* should the new node receive a unique serial number? */
1548
{
1549
  register sym_node *p=sym_avail;
1550
  if (p) {
1551
    sym_avail=p->link;@+p->link=NULL;@+p->serial=0;@+p->equiv=zero_octa;
1552
  }@+else {
1553
    p=next_sym_node;
1554
    if (p==last_sym_node) {
1555
      p=(sym_node*)calloc(1000,sizeof(sym_node));
1556
      if (!p) panic("Capacity exceeded: Out of symbol memory");
1557
@.Capacity exceeded...@>
1558
      last_sym_node=p+1000;
1559
    }
1560
    next_sym_node=p+1;
1561
  }
1562
  if (serialize) p->serial=++serial_number;
1563
  return p;
1564
}
1565
 
1566
@ @=
1567
int serial_number;
1568
sym_node *sym_root; /* root of the sym */
1569
sym_node *next_sym_node, *last_sym_node; /* allocation control */
1570
sym_node *sym_avail; /* stack of recycled symbol table nodes */
1571
 
1572
@ We initialize the trie by inserting all the predefined symbols.
1573
Opcodes are given the prefix \.{\^}, to distinguish them from
1574
ordinary symbols; this character nicely divides uppercase letters from
1575
lowercase letters.
1576
 
1577
@=
1578
trie_root=new_trie_node();
1579
cur_prefix=trie_root;
1580
op_root=new_trie_node();
1581
trie_root->mid=op_root;
1582
trie_root->ch=':';
1583
op_root->ch='^';
1584
@;
1585
@;
1586
@;
1587
 
1588
@ Most of the assembly work can be table driven, based on bits that
1589
are stored as the ``equivalents'' of opcode symbols like \.{\^ADD}.
1590
 
1591
@d rel_addr_bit 0x1 /* is YZ or XYZ relative? */
1592
@d immed_bit 0x2 /* should opcode be immediate if Z or YZ not register? */
1593
@d zar_bit 0x4 /* should register status of Z be ignored? */
1594
@d zr_bit 0x8 /* must Z be a register? */
1595
@d yar_bit 0x10 /* should register status of Y be ignored? */
1596
@d yr_bit 0x20 /* must Y be a register? */
1597
@d xar_bit 0x40 /* should register status of X be ignored? */
1598
@d xr_bit 0x80 /* must X be a register? */
1599
@d yzar_bit 0x100 /* should register status of YZ be ignored? */
1600
@d yzr_bit 0x200 /* must YZ be a register? */
1601
@d xyzar_bit 0x400 /* should register status of XYZ be ignored? */
1602
@d xyzr_bit 0x800 /* must XYZ be a register? */
1603
@d one_arg_bit 0x1000 /* is it OK to have zero or one operand? */
1604
@d two_arg_bit 0x2000 /* is it OK to have exactly two operands? */
1605
@d three_arg_bit 0x4000 /* is it OK to have exactly three operands? */
1606
@d many_arg_bit 0x8000 /* is it OK to have more than three operands? */
1607
@d align_bits 0x30000 /* how much alignment: byte, wyde, tetra, or octa? */
1608
@d no_label_bit 0x40000 /* should the label be blank? */
1609
@d mem_bit 0x80000 /* must YZ be a memory reference? */
1610
@d spec_bit 0x100000 /* is this opcode allowed in \.{SPEC} mode? */
1611
 
1612
@=
1613
typedef struct {
1614
 Char *name; /* symbolic opcode */
1615
 short code; /* numeric opcode */
1616
 int bits; /* treatment of operands */
1617
} op_spec;
1618
@#
1619
typedef enum {
1620
@!SET=0x100,@!IS,@!LOC,@!PREFIX,@!BSPEC,@!ESPEC,@!GREG,@!LOCAL,@/
1621
@!BYTE,@!WYDE,@!TETRA,@!OCTA}@+@!pseudo_op;
1622
 
1623
@ @=
1624
op_spec op_init_table[]={@/
1625
{"TRAP", 0x00, 0x27554},
1626
@.TRAP@>
1627
{"FCMP", 0x01, 0x240a8},
1628
@.FCMP@>
1629
{"FUN", 0x02, 0x240a8},
1630
@.FUN@>
1631
{"FEQL", 0x03, 0x240a8},@/
1632
@.FEQL@>
1633
{"FADD", 0x04, 0x240a8},
1634
@.FADD@>
1635
{"FIX", 0x05, 0x26288},
1636
@.FIX@>
1637
{"FSUB", 0x06, 0x240a8},
1638
@.FSUB@>
1639
{"FIXU", 0x07, 0x26288},@/
1640
@.FIXU@>
1641
{"FLOT", 0x08, 0x26282},
1642
@.FLOT@>
1643
{"FLOTU", 0x0a, 0x26282},
1644
@.FLOTU@>
1645
{"SFLOT", 0x0c, 0x26282},
1646
@.SFLOT@>
1647
{"SFLOTU", 0x0e, 0x26282},@/
1648
@.SFLOTU@>
1649
{"FMUL", 0x10, 0x240a8},
1650
@.FMUL@>
1651
{"FCMPE", 0x11, 0x240a8},
1652
@.FCMPE@>
1653
{"FUNE", 0x12, 0x240a8},
1654
@.FUNE@>
1655
{"FEQLE", 0x13, 0x240a8},@/
1656
@.FEQLE@>
1657
{"FDIV", 0x14, 0x240a8},
1658
@.FDIV@>
1659
{"FSQRT", 0x15, 0x26288},
1660
@.FSQRT@>
1661
{"FREM", 0x16, 0x240a8},
1662
@.FREM@>
1663
{"FINT", 0x17, 0x26288},@/
1664
@.FINT@>
1665
{"MUL", 0x18, 0x240a2},
1666
@.MUL@>
1667
{"MULU", 0x1a, 0x240a2},
1668
@.MULU@>
1669
{"DIV", 0x1c, 0x240a2},
1670
@.DIV@>
1671
{"DIVU", 0x1e, 0x240a2},@/
1672
@.DIVU@>
1673
{"ADD", 0x20, 0x240a2},
1674
@.ADD@>
1675
{"ADDU", 0x22, 0x240a2},
1676
@.ADDU@>
1677
{"SUB", 0x24, 0x240a2},
1678
@.SUB@>
1679
{"SUBU", 0x26, 0x240a2},@/
1680
@.SUBU@>
1681
{"2ADDU", 0x28, 0x240a2},
1682
@.2ADDU@>
1683
{"4ADDU", 0x2a, 0x240a2},
1684
@.4ADDU@>
1685
{"8ADDU", 0x2c, 0x240a2},
1686
@.8ADDU@>
1687
{"16ADDU", 0x2e, 0x240a2},@/
1688
@.16ADDU@>
1689
{"CMP", 0x30, 0x240a2},
1690
@.CMP@>
1691
{"CMPU", 0x32, 0x240a2},
1692
@.CMPU@>
1693
{"NEG", 0x34, 0x26082},
1694
@.NEG@>
1695
{"NEGU", 0x36, 0x26082},@/
1696
@.NEGU@>
1697
{"SL", 0x38, 0x240a2},
1698
@.SL@>
1699
{"SLU", 0x3a, 0x240a2},
1700
@.SLU@>
1701
{"SR", 0x3c, 0x240a2},
1702
@.SR@>
1703
{"SRU", 0x3e, 0x240a2},@/
1704
@.SRU@>
1705
{"BN", 0x40, 0x22081},
1706
@.BN@>
1707
{"BZ", 0x42, 0x22081},
1708
@.BZ@>
1709
{"BP", 0x44, 0x22081},
1710
@.BP@>
1711
{"BOD", 0x46, 0x22081},@/
1712
@.BOD@>
1713
{"BNN", 0x48, 0x22081},
1714
@.BNN@>
1715
{"BNZ", 0x4a, 0x22081},
1716
@.BNZ@>
1717
{"BNP", 0x4c, 0x22081},
1718
@.BNP@>
1719
{"BEV", 0x4e, 0x22081},@/
1720
@.BEV@>
1721
{"PBN", 0x50, 0x22081},
1722
@.PBN@>
1723
{"PBZ", 0x52, 0x22081},
1724
@.PBZ@>
1725
{"PBP", 0x54, 0x22081},
1726
@.PBP@>
1727
{"PBOD", 0x56, 0x22081},@/
1728
@.PBOD@>
1729
{"PBNN", 0x58, 0x22081},
1730
@.PBNN@>
1731
{"PBNZ", 0x5a, 0x22081},
1732
@.PBNZ@>
1733
{"PBNP", 0x5c, 0x22081},
1734
@.PBNP@>
1735
{"PBEV", 0x5e, 0x22081},@/
1736
@.PBEV@>
1737
{"CSN", 0x60, 0x240a2},
1738
@.CSN@>
1739
{"CSZ", 0x62, 0x240a2},
1740
@.CSZ@>
1741
{"CSP", 0x64, 0x240a2},
1742
@.CSP@>
1743
{"CSOD", 0x66, 0x240a2},@/
1744
@.CSOD@>
1745
{"CSNN", 0x68, 0x240a2},
1746
@.CSNN@>
1747
{"CSNZ", 0x6a, 0x240a2},
1748
@.CSNZ@>
1749
{"CSNP", 0x6c, 0x240a2},
1750
@.CSNP@>
1751
{"CSEV", 0x6e, 0x240a2},@/
1752
@.CSEV@>
1753
{"ZSN", 0x70, 0x240a2},
1754
@.ZSN@>
1755
{"ZSZ", 0x72, 0x240a2},
1756
@.ZSZ@>
1757
{"ZSP", 0x74, 0x240a2},
1758
@.ZSP@>
1759
{"ZSOD", 0x76, 0x240a2},@/
1760
@.ZSOD@>
1761
{"ZSNN", 0x78, 0x240a2},
1762
@.ZSNN@>
1763
{"ZSNZ", 0x7a, 0x240a2},
1764
@.ZSNZ@>
1765
{"ZSNP", 0x7c, 0x240a2},
1766
@.ZSNP@>
1767
{"ZSEV", 0x7e, 0x240a2},@/
1768
@.ZSEV@>
1769
{"LDB", 0x80, 0xa60a2},
1770
@.LDB@>
1771
{"LDBU", 0x82, 0xa60a2},
1772
@.LDBU@>
1773
{"LDW", 0x84, 0xa60a2},
1774
@.LDW@>
1775
{"LDWU", 0x86, 0xa60a2},@/
1776
@.LDWU@>
1777
{"LDT", 0x88, 0xa60a2},
1778
@.LDT@>
1779
{"LDTU", 0x8a, 0xa60a2},
1780
@.LDTU@>
1781
{"LDO", 0x8c, 0xa60a2},
1782
@.LDO@>
1783
{"LDOU", 0x8e, 0xa60a2},@/
1784
@.LDOU@>
1785
{"LDSF", 0x90, 0xa60a2},
1786
@.LDSF@>
1787
{"LDHT", 0x92, 0xa60a2},
1788
@.LDHT@>
1789
{"CSWAP", 0x94, 0xa60a2},
1790
@.CSWAP@>
1791
{"LDUNC", 0x96, 0xa60a2},@/
1792
@.LDUNC@>
1793
{"LDVTS", 0x98, 0xa60a2},
1794
@.LDVTS@>
1795
{"PRELD", 0x9a, 0xa6022},
1796
@.PRELD@>
1797
{"PREGO", 0x9c, 0xa6022},
1798
@.PREGO@>
1799
{"GO", 0x9e, 0xa60a2},@/
1800
@.GO@>
1801
{"STB", 0xa0, 0xa60a2},
1802
@.STB@>
1803
{"STBU", 0xa2, 0xa60a2},
1804
@.STBU@>
1805
{"STW", 0xa4, 0xa60a2},
1806
@.STW@>
1807
{"STWU", 0xa6, 0xa60a2},@/
1808
@.STWU@>
1809
{"STT", 0xa8, 0xa60a2},
1810
@.STT@>
1811
{"STTU", 0xaa, 0xa60a2},
1812
@.STTU@>
1813
{"STO", 0xac, 0xa60a2},
1814
@.STO@>
1815
{"STOU", 0xae, 0xa60a2},@/
1816
@.STOU@>
1817
{"STSF", 0xb0, 0xa60a2},
1818
@.STSF@>
1819
{"STHT", 0xb2, 0xa60a2},
1820
@.STHT@>
1821
{"STCO", 0xb4, 0xa6022},
1822
@.STCO@>
1823
{"STUNC", 0xb6, 0xa60a2},@/
1824
@.STUNC@>
1825
{"SYNCD", 0xb8, 0xa6022},
1826
@.SYNCD@>
1827
{"PREST", 0xba, 0xa6022},
1828
@.PREST@>
1829
{"SYNCID", 0xbc, 0xa6022},
1830
@.SYNCID@>
1831
{"PUSHGO", 0xbe, 0xa6062},@/
1832
@.PUSHGO@>
1833
{"OR", 0xc0, 0x240a2},
1834
@.OR@>
1835
{"ORN", 0xc2, 0x240a2},
1836
@.ORN@>
1837
{"NOR", 0xc4, 0x240a2},
1838
@.NOR@>
1839
{"XOR", 0xc6, 0x240a2},@/
1840
@.XOR@>
1841
{"AND", 0xc8, 0x240a2},
1842
@.AND@>
1843
{"ANDN", 0xca, 0x240a2},
1844
@.ANDN@>
1845
{"NAND", 0xcc, 0x240a2},
1846
@.NAND@>
1847
{"NXOR", 0xce, 0x240a2},@/
1848
@.NXOR@>
1849
{"BDIF", 0xd0, 0x240a2},
1850
@.BDIF@>
1851
{"WDIF", 0xd2, 0x240a2},
1852
@.WDIF@>
1853
{"TDIF", 0xd4, 0x240a2},
1854
@.TDIF@>
1855
{"ODIF", 0xd6, 0x240a2},@/
1856
@.ODIF@>
1857
{"MUX", 0xd8, 0x240a2},
1858
@.MUX@>
1859
{"SADD", 0xda, 0x240a2},
1860
@.SADD@>
1861
{"MOR", 0xdc, 0x240a2},
1862
@.MOR@>
1863
{"MXOR", 0xde, 0x240a2},@/
1864
@.MXOR@>
1865
{"SETH", 0xe0, 0x22080},
1866
@.SETH@>
1867
{"SETMH", 0xe1, 0x22080},
1868
@.SETMH@>
1869
{"SETML", 0xe2, 0x22080},
1870
@.SETML@>
1871
{"SETL", 0xe3, 0x22080},@/
1872
@.SETL@>
1873
{"INCH", 0xe4, 0x22080},
1874
@.INCH@>
1875
{"INCMH", 0xe5, 0x22080},
1876
@.INCMH@>
1877
{"INCML", 0xe6, 0x22080},
1878
@.INCML@>
1879
{"INCL", 0xe7, 0x22080},@/
1880
@.INCL@>
1881
{"ORH", 0xe8, 0x22080},
1882
@.ORH@>
1883
{"ORMH", 0xe9, 0x22080},
1884
@.ORMH@>
1885
{"ORML", 0xea, 0x22080},
1886
@.ORML@>
1887
{"ORL", 0xeb, 0x22080},@/
1888
@.ORL@>
1889
{"ANDNH", 0xec, 0x22080},
1890
@.ANDNH@>
1891
{"ANDNMH", 0xed, 0x22080},
1892
@.ANDNMH@>
1893
{"ANDNML", 0xee, 0x22080},
1894
@.ANDNML@>
1895
{"ANDNL", 0xef, 0x22080},@/
1896
@.ANDNL@>
1897
{"JMP", 0xf0, 0x21001},
1898
@.JMP@>
1899
{"PUSHJ", 0xf2, 0x22041},
1900
@.PUSHJ@>
1901
{"GETA", 0xf4, 0x22081},
1902
@.GETA@>
1903
{"PUT", 0xf6, 0x22002},@/
1904
@.PUT@>
1905
{"POP", 0xf8, 0x23000},
1906
@.POP@>
1907
{"RESUME", 0xf9, 0x21000},
1908
@.RESUME@>
1909
{"SAVE", 0xfa, 0x22080},
1910
@.SAVE@>
1911
{"UNSAVE", 0xfb, 0x23a00},@/
1912
@.UNSAVE@>
1913
{"SYNC", 0xfc, 0x21000},
1914
@.SYNC@>
1915
{"SWYM", 0xfd, 0x27554},
1916
@.SWYM@>
1917
{"GET", 0xfe, 0x22080},
1918
@.GET@>
1919
{"TRIP", 0xff, 0x27554},@/
1920
@.TRIP@>
1921
{"SET",SET, 0x22180},
1922
@.SET@>
1923
{"LDA", 0x22, 0xa60a2},@/
1924
@.LDA@>
1925
{"IS", IS, 0x101400},
1926
@.IS@>
1927
{"LOC", LOC, 0x1400},
1928
@.LOC@>
1929
{"PREFIX", PREFIX, 0x141000},@/
1930
@.PREFIX@>
1931
{"BYTE", BYTE, 0x10f000},
1932
@.BYTE@>
1933
{"WYDE", WYDE, 0x11f000},
1934
@.WYDE@>
1935
{"TETRA", TETRA, 0x12f000},
1936
@.TETRA@>
1937
{"OCTA", OCTA, 0x13f000},@/
1938
@.OCTA@>
1939
{"BSPEC", BSPEC, 0x41400},
1940
@.BSPEC@>
1941
{"ESPEC", ESPEC, 0x141000},@/
1942
@.ESPEC@>
1943
{"GREG", GREG, 0x101000},
1944
@.GREG@>
1945
{"LOCAL", LOCAL, 0x141800}};
1946
@.LOCAL@>
1947
int op_init_size; /* the number of items in |op_init_table| */
1948
 
1949
@ @=
1950
op_init_size=(sizeof op_init_table)/sizeof(op_spec);
1951
for (j=0;j
1952
  tt=trie_search(op_root,op_init_table[j].name);
1953
  pp=tt->sym=new_sym_node(false);
1954
  pp->link=PREDEFINED;
1955
  pp->equiv.h=op_init_table[j].code, pp->equiv.l=op_init_table[j].bits;
1956
}
1957
 
1958
@ @=
1959
register trie_node *tt;
1960
register sym_node *pp,*qq;
1961
 
1962
@ @=
1963
for (j=0;j<32;j++) {
1964
  tt=trie_search(trie_root,special_name[j]);
1965
  pp=tt->sym=new_sym_node(false);
1966
  pp->link=PREDEFINED;
1967
  pp->equiv.l=j;
1968
}
1969
 
1970
@ @=
1971
Char *special_name[32]={"rB","rD","rE","rH","rJ","rM","rR","rBB",
1972
 "rC","rN","rO","rS","rI","rT","rTT","rK","rQ","rU","rV","rG","rL",
1973
 "rA","rF","rP","rW","rX","rY","rZ","rWW","rXX","rYY","rZZ"};
1974
@^predefined symbols@>
1975
 
1976
@ @=
1977
typedef struct {
1978
  Char* name;
1979
  tetra h,l;
1980
}@+predef_spec;
1981
 
1982
@ @=
1983
predef_spec predefs[]={
1984
{"ROUND_CURRENT",0,0},
1985
@:ROUND_CURRENT}\.{ROUND\_CURRENT@>
1986
{"ROUND_OFF",0,1},
1987
@:ROUND_OFF}\.{ROUND\_OFF@>
1988
{"ROUND_UP",0,2},
1989
@:ROUND_UP}\.{ROUND\_UP@>
1990
{"ROUND_DOWN",0,3},
1991
@:ROUND_DOWN}\.{ROUND\_DOWN@>
1992
{"ROUND_NEAR",0,4},@/
1993
@:ROUND_NEAR}\.{ROUND\_NEAR@>
1994
{"Inf",0x7ff00000,0},@/
1995
@.Inf@>
1996
{"Data_Segment",0x20000000,0},
1997
@:Data_Segment}\.{Data\_Segment@>
1998
{"Pool_Segment",0x40000000,0},
1999
@:Pool_Segment}\.{Pool\_Segment@>
2000
{"Stack_Segment",0x60000000,0},@/
2001
@:Stack_Segment}\.{Stack\_Segment@>
2002
{"D_BIT",0,0x80},
2003
@:D_BIT}\.{D\_BIT@>
2004
{"V_BIT",0,0x40},
2005
@:V_BIT}\.{V\_BIT@>
2006
{"W_BIT",0,0x20},
2007
@:W_BIT}\.{W\_BIT@>
2008
{"I_BIT",0,0x10},
2009
@:I_BIT}\.{I\_BIT@>
2010
{"O_BIT",0,0x08},
2011
@:O_BIT}\.{O\_BIT@>
2012
{"U_BIT",0,0x04},
2013
@:U_BIT}\.{U\_BIT@>
2014
{"Z_BIT",0,0x02},
2015
@:Z_BIT}\.{Z\_BIT@>
2016
{"X_BIT",0,0x01},@/
2017
@:X_BIT}\.{X\_BIT@>
2018
{"D_Handler",0,0x10},
2019
@:D_Handler}\.{D\_Handler@>
2020
{"V_Handler",0,0x20},
2021
@:V_Handler}\.{V\_Handler@>
2022
{"W_Handler",0,0x30},
2023
@:W_Handler}\.{W\_Handler@>
2024
{"I_Handler",0,0x40},
2025
@:I_Handler}\.{I\_Handler@>
2026
{"O_Handler",0,0x50},
2027
@:O_Handler}\.{O\_Handler@>
2028
{"U_Handler",0,0x60},
2029
@:U_Handler}\.{U\_Handler@>
2030
{"Z_Handler",0,0x70},
2031
@:Z_Handler}\.{Z\_Handler@>
2032
{"X_Handler",0,0x80},@/
2033
@:X_Handler}\.{X\_Handler@>
2034
{"StdIn",0,0},
2035
@.StdIn@>
2036
{"StdOut",0,1},
2037
@.StdOut@>
2038
{"StdErr",0,2},@/
2039
@.StdErr@>
2040
{"TextRead",0,0},
2041
@.TextRead@>
2042
{"TextWrite",0,1},
2043
@.TextWrite@>
2044
{"BinaryRead",0,2},
2045
@.BinaryRead@>
2046
{"BinaryWrite",0,3},
2047
@.BinaryWrite@>
2048
{"BinaryReadWrite",0,4},@/
2049
@.BinaryReadWrite@>
2050
{"Halt",0,0},
2051
@.Halt@>
2052
{"Fopen",0,1},
2053
@.Fopen@>
2054
{"Fclose",0,2},
2055
@.Fclose@>
2056
{"Fread",0,3},
2057
@.Fread@>
2058
{"Fgets",0,4},
2059
@.Fgets@>
2060
{"Fgetws",0,5},
2061
@.Fgetws@>
2062
{"Fwrite",0,6},
2063
@.Fwrite@>
2064
{"Fputs",0,7},
2065
@.Fputs@>
2066
{"Fputws",0,8},
2067
@.Fputws@>
2068
{"Fseek",0,9},
2069
@.Fseek@>
2070
{"Ftell",0,10}};
2071
@.Ftell@>
2072
int predef_size;
2073
@^predefined symbols@>
2074
 
2075
@ @=
2076
predef_size=(sizeof predefs)/sizeof(predef_spec);
2077
for (j=0;j
2078
  tt=trie_search(trie_root,predefs[j].name);
2079
  pp=tt->sym=new_sym_node(false);
2080
  pp->link=PREDEFINED;
2081
  pp->equiv.h=predefs[j].h, pp->equiv.l=predefs[j].l;
2082
}
2083
 
2084
@ We place \.{Main} into the trie at the beginning of assembly,
2085
so that it will show up as an undefined symbol if the user
2086
specifies no starting point.
2087
@.Main@>
2088
 
2089
@=
2090
trie_search(trie_root,"Main")->sym=new_sym_node(true);
2091
 
2092
@ At the end of assembly we traverse the entire symbol table, visiting each
2093
symbol in lexicographic order and transmitting the trie structure to the
2094
output file. We detect any undefined future references at this time.
2095
 
2096
The order of traversal has a simple recursive pattern: To traverse the subtrie
2097
rooted at~|t|, we
2098
$$\vbox{\halign{#\hfil\cr
2099
traverse |t->left|, if the left subtrie is nonempty;\cr
2100
visit |t->sym|, if this symbol table entry is present;\cr
2101
traverse |t->mid|, if the middle subtrie is nonempty;\cr
2102
traverse |t->right|, if the right subtrie is nonempty.\cr
2103
}}$$
2104
This pattern leads to a compact representation in the \.{mmo} file, usually
2105
requiring fewer than two bytes per trie node plus the bytes needed to encode
2106
the equivalents and serial numbers. Each node of the trie is encoded as a
2107
``master byte'' followed by the encodings of the left subtrie,
2108
character, equivalent, middle subtrie, and right subtrie.
2109
The master byte is the sum of
2110
$$\vbox{\halign{#\hfil\cr
2111
\Hex{80}, if the character occupies two bytes instead of one;\cr
2112
\Hex{40}, if the left subtrie is nonempty;\cr
2113
\Hex{20}, if the middle subtrie is nonempty;\cr
2114
\Hex{10}, if the right subtrie is nonempty;\cr
2115
\Hex{01} to \Hex{08}, if the symbol's equivalent is one to eight bytes long;\cr
2116
\Hex{09} to \Hex{0e}, if the symbol's equivalent is $2^{61}$ plus one
2117
  to six bytes;\cr
2118
\Hex{0f}, if the symbol's equivalent is \$0 plus one byte;\cr}}$$
2119
the character is omitted if the middle subtrie and the equivalent are
2120
both empty. The ``equivalent'' of an undefined symbol is zero, but
2121
stated as two bytes long.
2122
Symbol equivalents are followed by the serial number, represented as a
2123
sequence of one or more bytes in radix~128; the final byte of the serial
2124
number is tagged by adding~128. (Thus, serial number $2^{14}-1$ is
2125
encoded as \Hex{7fff}; serial number $2^{14}$ is \Hex{010080}.)
2126
 
2127
@ First we prune the trie by removing all predefined symbols that the
2128
user did not redefine.
2129
 
2130
@=
2131
trie_node* prune @,@,@[ARGS((trie_node*))@];@+@t}\6{@>
2132
trie_node* prune(t)
2133
  trie_node* t;
2134
{
2135
  register int useful=0;
2136
  if (t->sym) {
2137
    if (t->sym->serial) useful=1;
2138
    else t->sym=NULL;
2139
  }
2140
  if (t->left) {
2141
    t->left=prune(t->left);
2142
    if (t->left) useful=1;
2143
  }
2144
  if (t->mid) {
2145
    t->mid=prune(t->mid);
2146
    if (t->mid) useful=1;
2147
  }
2148
  if (t->right) {
2149
    t->right=prune(t->right);
2150
    if (t->right) useful=1;
2151
  }
2152
  if (useful) return t;
2153
  else return NULL;
2154
}
2155
 
2156
@ Then we output the trie by following the recursive traversal pattern.
2157
 
2158
@=
2159
void out_stab @,@,@[ARGS((trie_node*))@];@+@t}\6{@>
2160
void out_stab(t)
2161
  trie_node* t;
2162
{
2163
  register int m=0,j;
2164
  register sym_node *pp;
2165
  if (t->ch>0xff) m+=0x80;
2166
  if (t->left) m+=0x40;
2167
  if (t->mid) m+=0x20;
2168
  if (t->right) m+=0x10;
2169
  if (t->sym) {
2170
    if (t->sym->link==REGISTER) m+=0xf;
2171
    else if (t->sym->link==DEFINED)
2172
      @sym->equiv|@>@;
2173
    else if (t->sym->link || t->sym->serial==1) @;
2174
  }
2175
  mmo_byte(m);
2176
  if (t->left) out_stab(t->left);
2177
  if (m&0x2f) @mid|@>;
2178
  if (t->right) out_stab(t->right);
2179
}
2180
 
2181
@ A global variable called |sym_buf| holds all characters on middle branches to
2182
the current trie node; |sym_ptr| is the first currently unused
2183
character in |sym_buf|.
2184
@^Unicode@>
2185
 
2186
@mid|@>=
2187
{
2188
  if (m&0x80) mmo_byte(t->ch>>8);
2189
  mmo_byte(t->ch&0xff);
2190
  *sym_ptr++=(m&0x80? '?': t->ch); /* Unicode? not yet */
2191
  m&=0xf;@+ if (m && t->sym->link) {
2192
    if (listing_file) @;
2193
    if (m==15) m=1;
2194
    else if (m>8) m-=8;
2195
    for (;m>0;m--)
2196
      if (m>4) mmo_byte((t->sym->equiv.h>>(8*(m-5)))&0xff);
2197
      else mmo_byte((t->sym->equiv.l>>(8*(m-1)))&0xff);
2198
    for (m=0;m<4;m++) if (t->sym->serial<(1<<(7*(m+1)))) break;
2199
    for (;m>=0;m--)
2200
      mmo_byte(((t->sym->serial>>(7*m))&0x7f)+(m? 0: 0x80));
2201
  }
2202
  if (t->mid) out_stab(t->mid);
2203
  sym_ptr--;
2204
}
2205
 
2206
@ @sym->equiv|@>=
2207
{@+register tetra x;
2208
  if ((t->sym->equiv.h&0xffff0000)==0x20000000)
2209
    m+=8, x=t->sym->equiv.h-0x20000000; /* data segment */
2210
  else x=t->sym->equiv.h;
2211
  if (x) m+=4;@+ else x=t->sym->equiv.l;
2212
  for (j=1;j<4;j++) if (x<(1<<(8*j))) break;
2213
  m+=j;
2214
}
2215
 
2216
@ We make room for symbols up to 999 bytes long. Strictly speaking,
2217
the program should check if this limit is exceeded; but really!
2218
 
2219
@=
2220
Char sym_buf[1000];
2221
Char *sym_ptr;
2222
 
2223
@ The initial `\.:' of each fully qualified symbol is omitted here, since most
2224
users of \MMIXAL\ will probably not need the \.{PREFIX} feature. One
2225
consequence of this omission is that the one-character symbol~`\.:'
2226
itself, which is allowed by the rules of \MMIXAL, is printed as the null
2227
string.
2228
 
2229
@=
2230
{
2231
  *sym_ptr='\0';
2232
  fprintf(listing_file," %s = ",sym_buf+1);
2233
  pp=t->sym;
2234
  if (pp->link==DEFINED)
2235
    fprintf(listing_file,"#%08x%08x",pp->equiv.h,pp->equiv.l);
2236
  else if (pp->link==REGISTER)
2237
    fprintf(listing_file,"$%03d",pp->equiv.l);
2238
  else fprintf(listing_file,"?");
2239
  fprintf(listing_file," (%d)\n",pp->serial);
2240
}
2241
 
2242
@ @=
2243
{
2244
  *sym_ptr=(m&0x80? '?': t->ch); /* Unicode? not yet */
2245
  *(sym_ptr+1)='\0';
2246
  fprintf(stderr,"undefined symbol: %s\n",sym_buf+1);
2247
@.undefined symbol@>
2248
  err_count++;
2249
  m+=2;
2250
}
2251
 
2252
@ @=
2253
op_root->mid=NULL; /* annihilate all the opcodes */
2254
prune(trie_root);
2255
sym_ptr=sym_buf;
2256
if (listing_file) fprintf(listing_file,"\nSymbol table:\n");
2257
mmo_lop(lop_stab,0,0);
2258
out_stab(trie_root);
2259
while (mmo_ptr&3) mmo_byte(0);
2260
mmo_lopp(lop_end,mmo_ptr>>2);
2261
 
2262
@* Expressions. The most intricate part of the assembly process is
2263
the task of scanning and evaluating expressions in the operand field.
2264
Fortunately, \MMIXAL's expressions have a simple structure that can
2265
be handled easily with a stack-based approach.
2266
 
2267
Two stacks hold pending data as the operand field is scanned and evaluated.
2268
The |op_stack| contains operators that have not yet been performed; the
2269
|val_stack| contains values that have not yet been used. After an entire
2270
operand list has been scanned, the |op_stack| will be empty and the
2271
|val_stack| will hold the operand values needed to assemble the current
2272
instruction.
2273
 
2274
@ Entries on |op_stack| have one of the constant values defined here, and they
2275
have one of the precedence levels defined here.
2276
 
2277
Entries on |val_stack| have |equiv|, |link|, and |status| fields; the |link|
2278
points to a trie node if the expression is a symbol that has not yet
2279
been subjected to any operations.
2280
 
2281
@=
2282
typedef enum {@!negate,@!serialize,@!complement,@!registerize,@!inner_lp,@|
2283
 @!plus,@!minus,@!times,@!over,@!frac,@!mod,@!shl,@!shr,@!and,@!or,@!xor,@|
2284
 @!outer_lp,@!outer_rp,@!inner_rp} @!stack_op;
2285
typedef enum {@!zero,@!weak,@!strong,@!unary} @!prec;
2286
typedef enum {@!pure,@!reg_val,@!undefined} @!stat;
2287
typedef struct {
2288
  octa equiv; /* current value */
2289
  trie_node *link; /* trie reference for symbol */
2290
  stat status; /* |pure|, |reg_val|, or |undefined| */
2291
} val_node;
2292
 
2293
@ @d top_op op_stack[op_ptr-1] /* top entry on the operator stack */
2294
@d top_val val_stack[val_ptr-1] /* top entry on the value stack */
2295
@d next_val val_stack[val_ptr-2] /* next-to-top entry of the value stack */
2296
 
2297
@=
2298
stack_op *op_stack; /* stack for pending operators */
2299
int op_ptr; /* number of items on |op_stack| */
2300
val_node *val_stack; /* stack for pending operands */
2301
int val_ptr; /* number of items on |val_stack| */
2302
prec precedence[]={unary,unary,unary,unary,zero,@|
2303
 weak,weak,strong,strong,strong,strong,strong,strong,strong,weak,weak,@|
2304
 zero,zero,zero}; /* precedences of the respective |stack_op| values */
2305
stack_op rt_op; /* newly scanned operator */
2306
octa acc; /* temporary accumulator */
2307
 
2308
@ @=
2309
op_stack=(stack_op*)calloc(buf_size,sizeof(stack_op));
2310
val_stack=(val_node*)calloc(buf_size,sizeof(val_node));
2311
if (!op_stack || !val_stack) panic("No room for the stacks");
2312
@.No room...@>
2313
 
2314
@ The operand field of an instruction will have been copied into a separate
2315
\&{Char} array called |operand_list| when we reach this part of the program.
2316
 
2317
@=
2318
p=operand_list;
2319
val_ptr=0; /* |val_stack| is empty */
2320
op_stack[0]=outer_lp, op_ptr=1;
2321
   /* |op_stack| contains an ``outer left parenthesis'' */
2322
while (1) {
2323
  @;
2324
 scan_close: @;
2325
  while (precedence[top_op]>=precedence[rt_op])
2326
    @;
2327
 hold_op: op_stack[op_ptr++]=rt_op;
2328
}
2329
operands_done:@;
2330
 
2331
@ A comment that follows an empty operand list needs to be detected here.
2332
 
2333
@=
2334
scan_open:@+if (isletter(*p)) @@;
2335
else if (isdigit(*p)) {
2336
  if (*(p+1)=='F') @@;
2337
  else if (*(p+1)=='B') @@;
2338
  else @;
2339
}@+else@+ switch(*p++) {
2340
 case '#': @;@+break;
2341
 case '\'': @;@+break;
2342
 case '\"': @;@+break;
2343
 case '@@': @;@+break;
2344
 case '-': op_stack[op_ptr++]=negate;
2345
 case '+': goto scan_open;
2346
 case '&': op_stack[op_ptr++]=serialize;@+goto scan_open;
2347
 case '~': op_stack[op_ptr++]=complement;@+goto scan_open;
2348
 case '$': op_stack[op_ptr++]=registerize;@+goto scan_open;
2349
 case '(': op_stack[op_ptr++]=inner_lp;@+goto scan_open;
2350
 default: if (p==operand_list+1) { /* treat operand list as empty */
2351
    operand_list[0]='0', operand_list[1]='\0', p=operand_list;
2352
    goto scan_open;
2353
  }
2354
 if (*(p-1)) derr("syntax error at character `%c'",*(p-1));
2355
 derr("syntax error after character `%c'",*(p-2));
2356
@.syntax error...@>
2357
}
2358
 
2359
@ @=
2360
{
2361
  if (*p==':') tt=trie_search(trie_root,p+1);
2362
  else tt=trie_search(cur_prefix,p);
2363
  p=terminator;
2364
 symbol_found: val_ptr++;
2365
  pp=tt->sym;
2366
  if (!pp) pp=tt->sym=new_sym_node(true);
2367
  top_val.link=tt, top_val.equiv=pp->equiv;
2368
  if (pp->link==PREDEFINED) pp->link=DEFINED;
2369
  top_val.status=(pp->link==DEFINED? pure: pp->link==REGISTER? reg_val:
2370
      undefined);
2371
}
2372
 
2373
@ @=
2374
{
2375
  tt=&forward_local_host[*p-'0'];@+ p+=2;@+ goto symbol_found;
2376
}
2377
 
2378
@ @=
2379
{
2380
  tt=&backward_local_host[*p-'0'];@+ p+=2;@+ goto symbol_found;
2381
}
2382
 
2383
@ Statically allocated variables |forward_local_host[j]| and
2384
|backward_local_host[j]| masquerade as nodes of the trie.
2385
 
2386
@=
2387
trie_node forward_local_host[10], backward_local_host[10];
2388
sym_node forward_local[10], backward_local[10];
2389
 
2390
@ Initially \.{0H}, \.{1H}, \dots, \.{9H} are defined to be zero.
2391
 
2392
@=
2393
for (j=0;j<10;j++) {
2394
  forward_local_host[j].sym=&forward_local[j];
2395
  backward_local_host[j].sym=&backward_local[j];
2396
  backward_local[j].link=DEFINED;
2397
}
2398
 
2399
@ We have already checked to make sure that the character constant is legal.
2400
 
2401
@=
2402
acc.h=0, acc.l=*p;
2403
p+=2;
2404
goto constant_found;
2405
 
2406
@ @=
2407
acc.h=0, acc.l=*p;
2408
if (*p=='\"') {
2409
  p++; acc.l=0; err("*null string is treated as zero");
2410
@.null string...@>
2411
}@+else if (*(p+1)=='\"') p+=2;
2412
else *p='\"', *--p=',';
2413
goto constant_found;
2414
 
2415
@ @=
2416
acc.h=0, acc.l=*p-'0';
2417
for (p++;isdigit(*p);p++) {
2418
  acc=oplus(acc,shift_left(acc,2));
2419
  acc=incr(shift_left(acc,1),*p-'0');
2420
}
2421
constant_found: val_ptr++;
2422
top_val.link=NULL;
2423
top_val.equiv=acc;
2424
top_val.status=pure;
2425
 
2426
@ @=
2427
if (!isxdigit(*p)) err("illegal hexadecimal constant");
2428
@.illegal hexadecimal constant@>
2429
acc.h=acc.l=0;
2430
for (;isxdigit(*p);p++) {
2431
  acc=incr(shift_left(acc,4),*p-'0');
2432
  if (*p>='a') acc=incr(acc,'0'-'a'+10);
2433
  else if (*p>='A') acc=incr(acc,'0'-'A'+10);
2434
}
2435
goto constant_found;
2436
 
2437
@ @=
2438
acc=cur_loc;
2439
goto constant_found;
2440
 
2441
@ @=
2442
switch(*p++) {
2443
 case '+': rt_op=plus;@+break;
2444
 case '-': rt_op=minus;@+break;
2445
 case '*': rt_op=times;@+break;
2446
 case '/':@+if (*p!='/') rt_op=over;
2447
   else p++,rt_op=frac;@+break;
2448
 case '%': rt_op=mod;@+break;
2449
 case '<': rt_op=shl;@+goto sh_check;
2450
 case '>': rt_op=shr;
2451
  sh_check:@+if (*p++==*(p-1)) break;
2452
  derr("syntax error at `%c'",*(p-2));
2453
@.syntax error...@>
2454
 case '&': rt_op=and;@+break;
2455
 case '|': rt_op=or;@+break;
2456
 case '^': rt_op=xor;@+break;
2457
 case ')': rt_op=inner_rp;@+break;
2458
 case '\0': case ',': rt_op=outer_rp;@+break;
2459
 default: derr("syntax error at `%c'",*(p-1));
2460
}
2461
 
2462
@ @=
2463
switch(op_stack[--op_ptr]) {
2464
 case inner_lp:@+if (rt_op==inner_rp) goto scan_close;
2465
  err("*missing right parenthesis");@+break;
2466
@.missing right parenthesis@>
2467
 case outer_lp:@+if (rt_op==outer_rp) {
2468
     if (top_val.status==reg_val && (top_val.equiv.l>0xff||top_val.equiv.h)) {
2469
       err("*register number too large, will be reduced mod 256");
2470
@.register number...@>
2471
       top_val.equiv.h=0, top_val.equiv.l &= 0xff;
2472
     }
2473
     if (!*(p-1)) goto operands_done;
2474
     else rt_op=outer_lp;@+goto hold_op; /* comma */
2475
   }@+else {
2476
     op_ptr++;
2477
     err("*missing left parenthesis");
2478
@.missing left parenthesis@>
2479
     goto scan_close;
2480
   }
2481
 @t\4@>@@;
2482
 @t\4@>@@;
2483
}
2484
 
2485
@ Now we come to the part where equivalents are changed by unary
2486
or binary operators found in the expression being scanned.
2487
 
2488
The most typical operator, and in some ways the fussiest one
2489
to deal with, is binary addition. Once we've written the code for
2490
this case, the other cases almost take care of themselves.
2491
 
2492
@=
2493
case plus:@+if (top_val.status==undefined)
2494
  err("cannot add an undefined quantity");
2495
@.cannot add...@>
2496
 if (next_val.status==undefined)
2497
  err("cannot add to an undefined quantity");
2498
 if (top_val.status==reg_val && next_val.status==reg_val)
2499
  err("cannot add two register numbers");
2500
 next_val.equiv=oplus(next_val.equiv,top_val.equiv);
2501
 fin_bin: next_val.status=(top_val.status==next_val.status? pure: reg_val);
2502
 val_ptr--;
2503
 delink: top_val.link=NULL;@+break;
2504
 
2505
@ @d unary_check(verb) if (top_val.status!=pure)
2506
                 derr("can %s pure values only",verb)
2507
 
2508
@=
2509
case negate: unary_check("negate");
2510
@.can negate...@>
2511
 top_val.equiv=ominus(zero_octa,top_val.equiv);@+goto delink;
2512
case complement: unary_check("complement");
2513
@.can complement...@>
2514
 top_val.equiv.h=~top_val.equiv.h, top_val.equiv.l=~top_val.equiv.l;
2515
 goto delink;
2516
case registerize: unary_check("registerize");
2517
@.can registerize...@>
2518
 top_val.status=reg_val;@+goto delink;
2519
case serialize:@+if (!top_val.link)
2520
   err("can take serial number of symbol only");
2521
@.can take serial number...@>
2522
 top_val.equiv.h=0, top_val.equiv.l=top_val.link->sym->serial;
2523
 top_val.status=pure;@+goto delink;
2524
 
2525
@ @d binary_check(verb)
2526
    if (top_val.status!=pure || next_val.status!=pure)
2527
      derr("can %s pure values only",verb)
2528
 
2529
@=
2530
case minus:@+if (top_val.status==undefined)
2531
  err("cannot subtract an undefined quantity");
2532
@.cannot subtract...@>
2533
 if (next_val.status==undefined)
2534
  err("cannot subtract from an undefined quantity");
2535
 if (top_val.status==reg_val && next_val.status!=reg_val)
2536
  err("cannot subtract register number from pure value");
2537
 next_val.equiv=ominus(next_val.equiv,top_val.equiv);@+goto fin_bin;
2538
case times: binary_check("multiply");
2539
@.can multiply...@>
2540
  next_val.equiv=omult(next_val.equiv,top_val.equiv);@+goto fin_bin;
2541
case over: case mod: binary_check("divide");
2542
@.can divide...@>
2543
 if (top_val.equiv.l==0 && top_val.equiv.h==0)
2544
   err("*division by zero");
2545
@.division by zero@>
2546
 next_val.equiv=odiv(zero_octa,next_val.equiv,top_val.equiv);
2547
 if (op_stack[op_ptr]==mod) next_val.equiv=aux;
2548
 goto fin_bin;
2549
case frac: binary_check("compute a ratio of");
2550
@.can compute...@>
2551
 if (next_val.equiv.h>=top_val.equiv.h &&
2552
  (next_val.equiv.l>=top_val.equiv.l || next_val.equiv.h>top_val.equiv.h))
2553
    err("*illegal fraction");
2554
@.illegal fraction@>
2555
 next_val.equiv=odiv(next_val.equiv,zero_octa,top_val.equiv);@+goto fin_bin;
2556
case shl: case shr: binary_check("compute a bitwise shift of");
2557
 if (top_val.equiv.h || top_val.equiv.l>63) next_val.equiv=zero_octa;
2558
 else if (op_stack[op_ptr]==shl)
2559
   next_val.equiv=shift_left(next_val.equiv,top_val.equiv.l);
2560
 else next_val.equiv=shift_right(next_val.equiv,top_val.equiv.l,true);
2561
 goto fin_bin;
2562
case and: binary_check("compute bitwise and of");
2563
 next_val.equiv.h&=top_val.equiv.h, next_val.equiv.l&=top_val.equiv.l;
2564
 goto fin_bin;
2565
case or: binary_check("compute bitwise or of");
2566
 next_val.equiv.h|=top_val.equiv.h, next_val.equiv.l|=top_val.equiv.l;
2567
 goto fin_bin;
2568
case xor: binary_check("compute bitwise xor of");
2569
 next_val.equiv.h^=top_val.equiv.h, next_val.equiv.l^=top_val.equiv.l;
2570
 goto fin_bin;
2571
 
2572
@* Assembling an instruction.
2573
Now let's move up from the expression level to the instruction level. We get to
2574
this part of the program at the beginning of a line, or after a
2575
semicolon at the end of an instruction earlier on the current line.
2576
Our current position in the buffer is the value of |buf_ptr|.
2577
 
2578
@=
2579
p=buf_ptr;@+ buf_ptr="";
2580
@;
2581
@;
2582
@;
2583
buf_ptr=p;
2584
if (spec_mode && !(op_bits&spec_bit))
2585
  derr("cannot use `%s' in special mode",op_field);
2586
@.cannot use...@>
2587
if ((op_bits&no_label_bit) && lab_field[0]) {
2588
  derr("*label field of `%s' instruction is ignored",op_field);
2589
  lab_field[0]='\0';
2590
}
2591
@.label field...ignored@>
2592
if (op_bits&align_bits) @;
2593
@;
2594
if (opcode==GREG) @;
2595
if (lab_field[0]) @;
2596
@;
2597
bypass:@;
2598
 
2599
@ @=
2600
if (!*p) goto bypass;
2601
q=lab_field;
2602
if (!isspace(*p)) {
2603
  if (!isdigit(*p)&&!isletter(*p)) goto bypass; /* comment */
2604
  for (*q++=*p++;isdigit(*p)||isletter(*p);p++,q++) *q=*p;
2605
  if (*p && !isspace(*p)) derr("label syntax error at `%c'",*p);
2606
@.label syntax error...@>
2607
}
2608
*q='\0';
2609
if (isdigit(lab_field[0]) && (lab_field[1]!='H' || lab_field[2]))
2610
  derr("improper local label `%s'",lab_field);
2611
@.improper local label...@>
2612
for (p++;isspace(*p);p++);
2613
 
2614
@ We copy the opcode field to a special buffer because we might
2615
want to refer to the symbolic opcode in error messages.
2616
 
2617
@=
2618
q=op_field;@+
2619
while (isletter(*p)||isdigit(*p)) *q++=*p++;
2620
*q='\0';
2621
if (!isspace(*p) && *p && op_field[0]) derr("opcode syntax error at `%c'",*p);
2622
@.opcode syntax error...@>
2623
pp=trie_search(op_root,op_field)->sym;
2624
if (!pp) {
2625
  if (op_field[0]) derr("unknown operation code `%s'",op_field);
2626
@.unknown operation code@>
2627
  if (lab_field[0]) derr("*no opcode; label `%s' will be ignored",lab_field);
2628
@.no opcode...@>
2629
  goto bypass;
2630
}
2631
opcode=pp->equiv.h, op_bits=pp->equiv.l;
2632
while (isspace(*p)) p++;
2633
 
2634
@ @=
2635
tetra opcode; /* numeric code for \MMIX\ operation or \MMIXAL\ pseudo-op */
2636
tetra op_bits; /* flags describing an operator's special characteristics */
2637
 
2638
@ We copy the operand field to a special buffer so that we can
2639
change string constants while scanning them later.
2640
 
2641
@=
2642
q=operand_list;
2643
while (*p) {
2644
  if (*p==';') break;
2645
  if (*p=='\'') {
2646
    *q++=*p++;
2647
    if (!*p) err("incomplete character constant");
2648
@.incomplete...constant@>
2649
    *q++=*p++;
2650
    if (*p!='\'') err("illegal character constant");
2651
@.illegal character constant@>
2652
  }@+else if (*p=='\"') {
2653
    for (*q++=*p++;*p && *p!='\"';p++,q++) *q=*p;
2654
    if (!*p) err("incomplete string constant");
2655
  }
2656
  *q++=*p++;
2657
  if (isspace(*p)) break;
2658
}
2659
while (isspace(*p)) p++;
2660
if (*p==';') p++;
2661
else p=""; /* if not followed by semicolon, rest of the line is a comment */
2662
if (q==operand_list) *q++='0'; /* change empty operand field to `\.0' */
2663
*q='\0';
2664
 
2665
@ It is important to do the alignment in this step before defining
2666
the label or evaluating the operand field.
2667
 
2668
@=
2669
{
2670
  j=(op_bits&align_bits)>>16;
2671
  acc.h=-1, acc.l=-(1<
2672
  cur_loc=oand(incr(cur_loc,(1<
2673
}
2674
 
2675
@ @=
2676
{
2677
  if (val_stack[0].equiv.l || val_stack[0].equiv.h) {
2678
    for (j=greg;j<255;j++)
2679
      if (greg_val[j].l==val_stack[0].equiv.l &&
2680
          greg_val[j].h==val_stack[0].equiv.h) {
2681
        cur_greg=j; goto got_greg;
2682
      }
2683
  }
2684
  if (greg==32) err("too many global registers");
2685
@.too many global registers@>
2686
  greg--;
2687
  greg_val[greg]=val_stack[0].equiv;@+  cur_greg=greg;
2688
got_greg:;
2689
}
2690
 
2691
@ If the label is, say \.{2H}, we will already have used the old
2692
value of \.{2B} when evaluating the operands. Furthermore, an
2693
operand of \.{2F} will have been treated as undefined, which it
2694
still is.
2695
 
2696
Symbols can be defined more than once, but only if each definition
2697
gives them the same equivalent value.
2698
 
2699
A warning message is given when a predefined symbol is being redefined,
2700
if its predefined value has already been used.
2701
 
2702
@=
2703
{
2704
  sym_node *new_link=DEFINED;
2705
  acc=cur_loc;
2706
  if (opcode==IS) {
2707
    cur_loc=val_stack[0].equiv;
2708
    if (val_stack[0].status==reg_val) new_link=REGISTER;
2709
  }@+else if (opcode==GREG) cur_loc.h=0, cur_loc.l=cur_greg, new_link=REGISTER;
2710
  @;
2711
  if (pp->link==DEFINED || pp->link==REGISTER) {
2712
    if (pp->equiv.l!=cur_loc.l||pp->equiv.h!=cur_loc.h || pp->link!=new_link) {
2713
      if (pp->serial) derr("symbol `%s' is already defined",lab_field);
2714
@.symbol...already defined@>
2715
      pp->serial=++serial_number;
2716
      derr("*redefinition of predefined symbol `%s'",lab_field);
2717
@.redefinition...@>
2718
    }
2719
  }@+ else if (pp->link==PREDEFINED) pp->serial=++serial_number;
2720
  else if (pp->link) {
2721
    if (new_link==REGISTER) err("future reference cannot be to a register");
2722
@.future reference cannot...@>
2723
    do @@;@+while (pp->link);
2724
  }
2725
  if (isdigit(lab_field[0])) pp=&backward_local[lab_field[0]-'0'];
2726
  pp->equiv=cur_loc;@+ pp->link=new_link;
2727
  @;
2728
  if (listing_file && (opcode==IS || opcode==LOC))
2729
    @;
2730
  cur_loc=acc;
2731
}
2732
 
2733
@ @=
2734
if (!isdigit(lab_field[0]))
2735
  for (j=0;j
2736
    if (val_stack[j].status==undefined && val_stack[j].link->sym==pp) {
2737
      val_stack[j].status=(new_link==REGISTER? reg_val: pure);
2738
      val_stack[j].equiv=cur_loc;
2739
    }
2740
 
2741
@ @=
2742
if (isdigit(lab_field[0])) pp=&forward_local[lab_field[0]-'0'];
2743
else {
2744
  if (lab_field[0]==':') tt=trie_search(trie_root,lab_field+1);
2745
  else tt=trie_search(cur_prefix,lab_field);
2746
  pp=tt->sym;
2747
  if (!pp) pp=tt->sym=new_sym_node(true);
2748
}
2749
 
2750
@ @=
2751
{
2752
  qq=pp->link;
2753
  pp->link=qq->link;
2754
  mmo_loc();
2755
  if (qq->serial==fix_o) @@;
2756
  else @;
2757
  recycle_fixup(qq);
2758
}
2759
 
2760
@ @=
2761
{
2762
  if (qq->equiv.h&0xffffff) {
2763
    mmo_lop(lop_fixo,0,2);
2764
    mmo_tetra(qq->equiv.h);
2765
  }@+else mmo_lop(lop_fixo,qq->equiv.h>>24,1);
2766
  mmo_tetra(qq->equiv.l);
2767
}
2768
 
2769
@ @=
2770
{
2771
  octa o;
2772
  o=ominus(cur_loc,qq->equiv);
2773
  if (o.l&3)
2774
    dderr("*relative address in location #%08x%08x not divisible by 4",
2775
@.relative address...@>
2776
      qq->equiv.h,qq->equiv.l);
2777
  o=shift_right(o,2,0);@+
2778
  k=0;
2779
  if (o.h==0)
2780
    if (o.l<0x10000) mmo_lopp(lop_fixr,o.l);
2781
    else if (qq->serial==fix_xyz && o.l<0x1000000) {
2782
      mmo_lop(lop_fixrx,0,24);@+mmo_tetra(o.l);
2783
    }@+else k=1;
2784
  else if (o.h==0xffffffff)
2785
    if (qq->serial==fix_xyz && o.l>=0xff000000) {
2786
      mmo_lop(lop_fixrx,0,24);@+mmo_tetra(o.l&0x1ffffff);
2787
    }@+else if (qq->serial==fix_yz && o.l>=0xffff0000) {
2788
      mmo_lop(lop_fixrx,0,16);@+mmo_tetra(o.l&0x100ffff);
2789
    }@+else k=1;
2790
  else k=1;
2791
  if (k) dderr("relative address in location #%08x%08x is too far away",
2792
               qq->equiv.h,qq->equiv.l);
2793
}
2794
 
2795
@ @=
2796
if (new_link==DEFINED) {
2797
  fprintf(listing_file,"(%08x%08x)",cur_loc.h,cur_loc.l);
2798
  flush_listing_line(" ");
2799
}@+else {
2800
  fprintf(listing_file,"($%03d)",cur_loc.l&0xff);
2801
  flush_listing_line("             ");
2802
}
2803
 
2804
@ @=
2805
future_bits=0;
2806
if (op_bits&many_arg_bit) @@;
2807
else@+switch (val_ptr) {
2808
case 1:@+if (!(op_bits&one_arg_bit))
2809
    derr("opcode `%s' needs more than one operand",op_field);
2810
@.opcode...operand(s)@>
2811
  @;
2812
case 2:@+if (!(op_bits&two_arg_bit))
2813
    if (op_bits&one_arg_bit)
2814
      derr("opcode `%s' must not have two operands",op_field)@;
2815
    else derr("opcode `%s' must have more than two operands",op_field);
2816
  @;
2817
case 3:@+if (!(op_bits&three_arg_bit))
2818
    derr("opcode `%s' must not have three operands",op_field);
2819
  @;
2820
default: derr("too many operands for opcode `%s'",op_field);
2821
@.too many operands...@>
2822
}
2823
 
2824
@ The many-operand operators are |BYTE|, |WYDE|, |TETRA|, and |OCTA|.
2825
 
2826
@=
2827
for (j=0;j
2828
  @;
2829
  k=1<<(opcode-BYTE);
2830
  if ((val_stack[j].equiv.h && opcode
2831
           (val_stack[j].equiv.l>0xffff && opcode
2832
           (val_stack[j].equiv.l>0xff && opcode
2833
    if (k==1) err("*constant doesn't fit in one byte")@;
2834
@.constant doesn't fit...@>
2835
    else derr("*constant doesn't fit in %d bytes",k);
2836
  if (k<8) assemble(k,val_stack[j].equiv.l,0);
2837
  else if (val_stack[j].status==undefined)
2838
    assemble(4,0,0xf0), assemble(4,0,0xf0);
2839
  else assemble(4,val_stack[j].equiv.h,0), assemble(4,val_stack[j].equiv.l,0);
2840
}
2841
 
2842
@ @=
2843
if (val_stack[j].status==reg_val)
2844
  err("*register number used as a constant")@;
2845
@.register number...@>
2846
else if (val_stack[j].status==undefined) {
2847
  if (opcode!=OCTA) err("undefined constant");
2848
@.undefined constant@>
2849
  pp=val_stack[j].link->sym;
2850
  qq=new_sym_node(false);
2851
  qq->link=pp->link;
2852
  pp->link=qq;
2853
  qq->serial=fix_o;
2854
  qq->equiv=cur_loc;
2855
}
2856
 
2857
@ @=
2858
@;
2859
@;
2860
assemble_X: @;
2861
assemble_inst: assemble(4,(opcode<<24)+xyz,future_bits);
2862
break;
2863
 
2864
@ Individual fields of an instruction are placed into
2865
global variables |z|, |y|, |x|, |yz|, and/or |xyz|.
2866
 
2867
@=
2868
tetra z,y,x,yz,xyz; /* pieces for assembly */
2869
int future_bits; /* places where there are future references */
2870
 
2871
@ @=
2872
if (val_stack[2].status==undefined) err("Z field is undefined");
2873
@.Z field is undefined@>
2874
if (val_stack[2].status==reg_val) {
2875
  if (!(op_bits&(immed_bit+zr_bit+zar_bit)))
2876
    derr("*Z field of `%s' should not be a register number",op_field);
2877
@.Z field...register number@>
2878
}@+ else if (op_bits&immed_bit) opcode++; /* immediate */
2879
else if (op_bits&zr_bit)
2880
  derr("*Z field of `%s' should be a register number",op_field);
2881
if (val_stack[2].equiv.h || val_stack[2].equiv.l>0xff)
2882
  err("*Z field doesn't fit in one byte");
2883
@.Z field doesn't fit...@>
2884
z=val_stack[2].equiv.l&0xff;
2885
 
2886
@ @=
2887
if (val_stack[1].status==undefined) err("Y field is undefined");
2888
@.Y field is undefined@>
2889
if (val_stack[1].status==reg_val) {
2890
  if (!(op_bits&(yr_bit+yar_bit)))
2891
    derr("*Y field of `%s' should not be a register number",op_field);
2892
@.Y field...register number@>
2893
}@+ else if (op_bits&yr_bit)
2894
  derr("*Y field of `%s' should be a register number",op_field);
2895
if (val_stack[1].equiv.h || val_stack[1].equiv.l>0xff)
2896
  err("*Y field doesn't fit in one byte");
2897
@.Y field doesn't fit...@>
2898
y=val_stack[1].equiv.l&0xff;@+
2899
yz=(y<<8)+z;
2900
 
2901
@ @=
2902
if (val_stack[0].status==undefined) err("X field is undefined");
2903
@.X field is undefined@>
2904
if (val_stack[0].status==reg_val) {
2905
  if (!(op_bits&(xr_bit+xar_bit)))
2906
    derr("*X field of `%s' should not be a register number",op_field);
2907
@.X field...register number@>
2908
}@+ else if (op_bits&xr_bit)
2909
  derr("*X field of `%s' should be a register number",op_field);
2910
if (val_stack[0].equiv.h || val_stack[0].equiv.l>0xff)
2911
  err("*X field doesn't fit in one byte");
2912
@.X field doesn't fit...@>
2913
x=val_stack[0].equiv.l&0xff;@+
2914
xyz=(x<<16)+yz;
2915
 
2916
@ @=
2917
if (val_stack[1].status==undefined) {
2918
  if (op_bits&rel_addr_bit)
2919
    @@;
2920
  else err("YZ field is undefined");
2921
@.YZ field is undefined@>
2922
}@+else if (val_stack[1].status==reg_val) {
2923
  if (!(op_bits&(immed_bit+yzr_bit+yzar_bit)))
2924
    derr("*YZ field of `%s' should not be a register number",op_field);
2925
@.YZ field...register number@>
2926
  if (opcode==SET) val_stack[1].equiv.l<<=8,opcode=0xc1; /* change to \.{OR} */
2927
  else if (op_bits&mem_bit)
2928
    val_stack[1].equiv.l<<=8,opcode++; /* silently append \.{,0} */
2929
}@+ else { /* |val_stack[1].status==pure| */
2930
  if (op_bits&mem_bit)
2931
    @;
2932
  if (opcode==SET) opcode=0xe3; /* change to \.{SETL} */
2933
  else if (op_bits&immed_bit) opcode++; /* immediate */
2934
  else if (op_bits&yzr_bit) {
2935
    derr("*YZ field of `%s' should be a register number",op_field);
2936
  }
2937
  if (op_bits&rel_addr_bit)
2938
    @;
2939
}
2940
if (val_stack[1].equiv.h || val_stack[1].equiv.l>0xffff)
2941
  err("*YZ field doesn't fit in two bytes");
2942
@.YZ field doesn't fit...@>
2943
yz=val_stack[1].equiv.l&0xffff;
2944
goto assemble_X;
2945
 
2946
@ @=
2947
{
2948
  pp=val_stack[1].link->sym;
2949
  qq=new_sym_node(false);
2950
  qq->link=pp->link;
2951
  pp->link=qq;
2952
  qq->serial=fix_yz;
2953
  qq->equiv=cur_loc;
2954
  yz=0;
2955
  future_bits=0xc0;
2956
  goto assemble_X;
2957
}
2958
 
2959
@ @=
2960
{
2961
  octa source, dest;
2962
  if (val_stack[1].equiv.l&3)
2963
    err("*relative address is not divisible by 4");
2964
@.relative address...@>
2965
  source=shift_right(cur_loc,2,0);
2966
  dest=shift_right(val_stack[1].equiv,2,0);
2967
  acc=ominus(dest,source);
2968
  if (!(acc.h&0x80000000)) {
2969
    if (acc.l>0xffff || acc.h)
2970
      err("relative address is more than #ffff tetrabytes forward");
2971
  }@+else {
2972
    acc=incr(acc,0x10000);
2973
    opcode++;
2974
    if (acc.l>0xffff || acc.h)
2975
      err("relative address is more than #10000 tetrabytes backward");
2976
  }
2977
  yz=acc.l;
2978
  goto assemble_X;
2979
}
2980
 
2981
@ @=
2982
{
2983
  octa o;
2984
  o=val_stack[1].equiv, k=0;
2985
  for (j=greg;j<255;j++) if (greg_val[j].h || greg_val[j].l) {
2986
    acc=ominus(val_stack[1].equiv,greg_val[j]);
2987
    if (acc.h<=o.h && (acc.l<=o.l || acc.h
2988
  }
2989
  if (o.l<=0xff && !o.h && k) yz=(k<<8)+o.l, opcode++;
2990
  else if (!expanding) err("no base address is close enough to the address A")@;
2991
@.no base address...@>
2992
  else @;
2993
  goto assemble_X;
2994
}
2995
 
2996
@ @d SETH 0xe0
2997
@d ORH 0xe8
2998
@d ORL 0xeb
2999
 
3000
@=
3001
{
3002
  for (j=SETH;j<=ORL;j++) {
3003
    switch (j&3) {
3004
     case 0: yz=o.h>>16;@+break; /* \.{SETH} */
3005
     case 1: yz=o.h&0xffff;@+break; /* \.{SETMH} or \.{ORMH} */
3006
     case 2: yz=o.l>>16;@+break; /* \.{SETML} or \.{ORML} */
3007
     case 3: yz=o.l&0xffff;@+break; /* \.{SETL} or \.{ORL} */
3008
     }
3009
    if (yz) {
3010
      assemble(4,(j<<24)+(255<<16)+yz,0);
3011
      j |= ORH;
3012
    }
3013
  }
3014
  if (k) yz=(k<<8)+255; /* Y = \$$k$, Z = \$255 */
3015
  else yz=255<<8, opcode++; /* Y = \$255, Z = 0 */
3016
}
3017
 
3018
@ @=
3019
if (val_stack[0].status==undefined) {
3020
  if (op_bits&rel_addr_bit)
3021
    @@;
3022
  else if (opcode!=PREFIX) err("the operand is undefined");
3023
@.the operand is undefined@>
3024
}@+else if (val_stack[0].status==reg_val) {
3025
  if (!(op_bits&(xyzr_bit+xyzar_bit)))
3026
    derr("*operand of `%s' should not be a register number",op_field);
3027
@.operand...register number@>
3028
}@+ else { /* |val_stack[0].status==pure| */
3029
  if (op_bits&xyzr_bit)
3030
    derr("*operand of `%s' should be a register number",op_field);
3031
  if (op_bits&rel_addr_bit)
3032
    @;
3033
}
3034
if (opcode>0xff) @;
3035
if (val_stack[0].equiv.h || val_stack[0].equiv.l>0xffffff)
3036
  err("*XYZ field doesn't fit in three bytes");
3037
@.XYZ field doesn't fit...@>
3038
xyz=val_stack[0].equiv.l&0xffffff;
3039
goto assemble_inst;
3040
 
3041
@ @=
3042
{
3043
  pp=val_stack[0].link->sym;
3044
  qq=new_sym_node(false);
3045
  qq->link=pp->link;
3046
  pp->link=qq;
3047
  qq->serial=fix_xyz;
3048
  qq->equiv=cur_loc;
3049
  xyz=0;
3050
  future_bits=0xe0;
3051
  goto assemble_inst;
3052
}
3053
 
3054
@ @=
3055
{
3056
  octa source, dest;
3057
  if (val_stack[0].equiv.l&3)
3058
    err("*relative address is not divisible by 4");
3059
@.relative address...@>
3060
  source=shift_right(cur_loc,2,0);
3061
  dest=shift_right(val_stack[0].equiv,2,0);
3062
  acc=ominus(dest,source);
3063
  if (!(acc.h&0x80000000)) {
3064
    if (acc.l>0xffffff || acc.h)
3065
      err("relative address is more than #ffffff tetrabytes forward");
3066
  }@+else {
3067
    acc=incr(acc,0x1000000);
3068
    opcode++;
3069
    if (acc.l>0xffffff || acc.h)
3070
      err("relative address is more than #1000000 tetrabytes backward");
3071
  }
3072
  xyz=acc.l;
3073
  goto assemble_inst;
3074
}
3075
 
3076
@ @=
3077
switch(opcode) {
3078
 case LOC: cur_loc=val_stack[0].equiv;
3079
 case IS: goto bypass;
3080
 case PREFIX:@+if (!val_stack[0].link) err("not a valid prefix");
3081
@.not a valid prefix@>
3082
   cur_prefix=val_stack[0].link;@+goto bypass;
3083
 case GREG:@+if (listing_file) @;
3084
   goto bypass;
3085
 case LOCAL:@+if (val_stack[0].equiv.l>lreg) lreg=val_stack[0].equiv.l;
3086
   if (listing_file) {
3087
     fprintf(listing_file,"($%03d)",val_stack[0].equiv.l);
3088
     flush_listing_line("             ");
3089
   }
3090
   goto bypass;
3091
 case BSPEC:@+if (val_stack[0].equiv.l>0xffff || val_stack[0].equiv.h)
3092
     err("*operand of `BSPEC' doesn't fit in two bytes");
3093
@.operand of `BSPEC'...@>
3094
   mmo_loc();@+mmo_sync();
3095
   mmo_lopp(lop_spec,val_stack[0].equiv.l);
3096
   spec_mode=true;@+spec_mode_loc=0;@+ goto bypass;
3097
 case ESPEC: spec_mode=false;@+goto bypass;
3098
}
3099
 
3100
@ @=
3101
octa greg_val[256]; /* initial values of global registers */
3102
 
3103
@ @=
3104
if (val_stack[0].equiv.l || val_stack[0].equiv.h) {
3105
  fprintf(listing_file,"($%03d=#%08x",cur_greg,val_stack[0].equiv.h);
3106
  flush_listing_line("    ");
3107
  fprintf(listing_file,"         %08x)",val_stack[0].equiv.l);
3108
  flush_listing_line(" ");
3109
}@+else {
3110
  fprintf(listing_file,"($%03d)",cur_greg);
3111
  flush_listing_line("             ");
3112
}
3113
 
3114
@* Running the program. On a \UNIX/-like system, the command
3115
$$\.{mmixal [options] sourcefilename}$$
3116
will assemble the \MMIXAL\ program in file \.{sourcefilename},
3117
writing any error messages on the standard error file. (Nothing is written to
3118
the standard output.) The options, which may appear in any order, are:
3119
 
3120
\bull\.{-o objectfilename}\quad Send the output to a binary file called
3121
\.{objectfilename}.
3122
If no \.{-o} specification is given, the object file name is obtained from the
3123
input file name by changing the final letter from `\.s' to~`\.o', or by
3124
appending `\.{.mmo}' if \.{sourcefilename} doesn't end with~\.s.
3125
 
3126
\bull\.{-l listingname}\quad Output a listing of the assembled input and
3127
output to a text file called \.{listingname}.
3128
 
3129
\bull\.{-x}\quad Expand memory-oriented commands that cannot be assembled
3130
as single instructions, by assembling auxiliary instructions that make
3131
temporary use of global register~\$255.
3132
 
3133
\bull\.{-b bufsize}\quad Allow up to \.{bufsize} characters per line of input.
3134
 
3135
@ Here, finally, is the overall structure of this program.
3136
 
3137
@c
3138
#include 
3139
#include 
3140
#include 
3141
#include 
3142
#include 
3143
@#
3144
@@;
3145
@@;
3146
@@;
3147
@@;
3148
@#
3149
int main(argc,argv)
3150
  int argc;@+
3151
  char *argv[];
3152
{
3153
  register int j,k; /* all-purpose integers */
3154
  @;
3155
  @;
3156
  @;
3157
  while(1) {
3158
    @;
3159
    while(1) {
3160
      @;
3161
      if (!*buf_ptr) break;
3162
    }
3163
    if (listing_file) {
3164
      if (listing_bits) listing_clear();
3165
      else if (!line_listed) flush_listing_line("                   ");
3166
    }
3167
  }
3168
  @;
3169
}
3170
 
3171
@ The space after |"-b"| is optional, because
3172
{\mc MMIX-SIM} does not use a space in this context.
3173
 
3174
@=
3175
for (j=1;j
3176
  if (argv[j][1]=='x') expanding=1;
3177
  else if (argv[j][1]=='o') j++,strcpy(obj_file_name,argv[j]);
3178
  else if (argv[j][1]=='l') j++,strcpy(listing_name,argv[j]);
3179
  else if (argv[j][1]=='b' && sscanf(argv[j+1],"%d",&buf_size)==1) j++;
3180
  else break;
3181
}@+else if (argv[j][1]!='b' || sscanf(argv[j]+1,"%d",&buf_size)!=1) break;
3182
if (j!=argc-1) {
3183
  fprintf(stderr,"Usage: %s %s sourcefilename\n",
3184
@.Usage: ...@>
3185
    argv[0],"[-x] [-l listingname] [-b buffersize] [-o objectfilename]");
3186
  exit(-1);
3187
}
3188
src_file_name=argv[j];
3189
 
3190
@ @=
3191
src_file=fopen(src_file_name,"r");
3192
if (!src_file) dpanic("Can't open the source file %s",src_file_name);
3193
@.Can't open...@>
3194
if (!obj_file_name[0]) {
3195
  j=strlen(src_file_name);
3196
  if (src_file_name[j-1]=='s') {
3197
    strcpy(obj_file_name,src_file_name);@+ obj_file_name[j-1]='o';
3198
  } else sprintf(obj_file_name,"%s.mmo",src_file_name);
3199
}
3200
obj_file=fopen(obj_file_name,"wb");
3201
if (!obj_file) dpanic("Can't open the object file %s",obj_file_name);
3202
if (listing_name[0]) {
3203
  listing_file=fopen(listing_name,"w");
3204
  if (!listing_file) dpanic("Can't open the listing file %s",listing_name);
3205
}
3206
 
3207
@ @=
3208
char *src_file_name; /* name of the \MMIXAL\ input file */
3209
char obj_file_name[FILENAME_MAX+1]; /* name of the binary output file */
3210
char listing_name[FILENAME_MAX+1]; /* name of the optional listing file */
3211
FILE *src_file, *obj_file, *listing_file;
3212
int expanding; /* are we expanding instructions when base address fail? */
3213
int buf_size; /* maximum number of characters per line of input */
3214
 
3215
@ @=
3216
@;
3217
filename[0]=src_file_name;
3218
filename_count=1;
3219
@;
3220
 
3221
@ @=
3222
mmo_lop(lop_pre,1,1);
3223
mmo_tetra(time(NULL));
3224
mmo_cur_file=-1;
3225
 
3226
@ @=
3227
if (lreg>=greg)
3228
  dpanic("Danger: Must reduce the number of GREGs by %d",lreg-greg+1);
3229
@.Danger@>
3230
@;
3231
@;
3232
@;
3233
if (err_count) {
3234
  if (err_count>1) fprintf(stderr,"(%d errors were found.)\n",err_count);
3235
  else fprintf(stderr,"(One error was found.)\n");
3236
}
3237
exit(err_count);
3238
 
3239
@ @=
3240
int greg=255; /* global register allocator */
3241
int cur_greg; /* global register just allocated */
3242
int lreg=32; /* local register allocator */
3243
 
3244
@ @=
3245
mmo_lop(lop_post,0,greg);
3246
greg_val[255]=trie_search(trie_root,"Main")->sym->equiv;
3247
for (j=greg;j<256;j++) {
3248
  mmo_tetra(greg_val[j].h);
3249
  mmo_tetra(greg_val[j].l);
3250
}
3251
 
3252
@ @=
3253
for (j=0;j<10;j++) if (forward_local[j].link)
3254
  err_count++,fprintf(stderr,"undefined local symbol %dF\n",j);
3255
@.undefined local symbol@>
3256
 
3257
@* Index.
3258
 

powered by: WebSVN 2.1.0

© copyright 1999-2024 OpenCores.org, equivalent to Oliscience, all rights reserved. OpenCores®, registered trademark.