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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{MMIX-PIPE}
5
\def\MMIX{\.{MMIX}}
6
\def\NNIX{\hbox{\mc NNIX}}
7
\def\Hex#1{\hbox{$^{\scriptscriptstyle\#}$\tt#1}} % experimental hex constant
8
@s and normal @q unreserve a C++ keyword @>
9
@s or normal @q unreserve a C++ keyword @>
10
@s bool normal @q unreserve a C++ keyword @>
11
@s xor normal @q unreserve a C++ keyword @>
12
 
13
@* Introduction. This program is the heart of the meta-simulator for the
14
ultra-configurable \MMIX\ pipeline: It defines the |MMIX_run| routine, which
15
does most of the
16
work. Another routine, |MMIX_init|, is also defined here, and so is a header
17
file called \.{mmix\_pipe.h}. The header file is used by the main routine and
18
by other routines like |MMIX_config|, which are compiled separately.
19
 
20
Readers of this program should be familiar with the explanation of \MMIX\
21
architecture as presented in the main program module for {\mc MMMIX}.
22
 
23
A lot of subtle things can happen when instructions are executed in parallel.
24
Therefore this simulator ranks among the most interesting and instructive
25
programs in the author's experience. The author has tried his best to make
26
everything correct \dots\ but the chances for error are great. Anyone who
27
discovers a bug is therefore urged to report it as soon as possible to
28
\.{knuth-bug@@cs.stanford.edu}; then the program will be as useful as
29
possible. Rewards will be paid to bug-finders! (Except for bugs in version~0.)
30
 
31
It sort of boggles the mind when one realizes that the present program might
32
someday be translated by a \CEE/~compiler for \MMIX\ and used to simulate
33
{\it itself}.
34
 
35
@ This high-performance prototype of \MMIX\ achieves its efficiency by
36
means of ``pipelining,'' a technique of overlapping that is explained
37
for the related \.{DLX} computer in Chapter~3 of Hennessy \char`\&\ Patterson's
38
book {\sl Computer Architecture\/} (second edition). Other techniques
39
such as ``dynamic scheduling'' and ``multiple issue,'' explained in
40
Chapter~4 of that book, are used too.
41
 
42
One good way to visualize the procedure is to imagine that somebody has
43
organized a high-tech car repair shop according to similar principles.
44
There are eight independent functional units, which we can think of as
45
eight groups of auto mechanics, each specializing in a particular task;
46
each group has its own workspace with room to deal with one car at a time.
47
Group~F (the ``fetch'' group) is in charge of rounding up customers and
48
getting them to enter the assembly-line garage in an orderly fashion.
49
Group~D (the ``decode and dispatch'' group) does the initial vehicle
50
inspection and
51
writes up an order that explains what kind of servicing is required.
52
The vehicles go next to one of the four ``execution'' groups:
53
Group~X handles routine maintenance, while groups XF, XM, and XD are
54
specialists in more complex tasks that tend to take longer. (The XF
55
people are good at floating the points, while the XM and XD groups are
56
experts in multilink suspensions and differentials.) When the relevant X~group
57
has finished its work, cars drive to M~station, where they send or receive
58
messages and possibly pay money to members of the ``memory'' group. Finally
59
all necessary parts are installed by members of group~W, the ``write''
60
group, and the car leaves the shop. Everything is tightly organized so
61
that in most cases the cars move in synchronized fashion from station
62
to station, at regular 100-nanocentury intervals. % about 5.3 minutes
63
 
64
In a similar way, most \MMIX\ instructions can be handled in a five-stage
65
pipeline, F--D--X--M--W, with X replaced by XF for floating-point
66
addition or conversion, or by XM for multiplication, or by XD for
67
division or square root. Each stage ideally takes one clock cycle,
68
although XF, XM, and (especially) XD are slower. If the instructions enter
69
in a suitable pattern, we might see one instruction being fetched,
70
another being decoded, and up to four being executed, while another is accessing
71
memory, and yet another is finishing up by writing new information into
72
registers; all this is going on simultaneously during one clock cycle. Pipelining
73
with eight separate stages might therefore make the machine run
74
up to 8 times as fast as it could if each instruction were being dealt with
75
individually and without overlap. (Well, perfect speedup turns out to
76
be impossible, because of the shared M and~W stages; the theory of
77
knapsack programming, to be discussed in Section~7.7 of {\sl The Art
78
of Computer Programming}, tells us that the maximal achievable speedup is
79
at most $8-1/p-1/q-1/r$ when XF, XM, and~XD have delays bounded by $p$,
80
$q$, and~$r$ cycles. But we can achieve a factor of more than~7
81
if we are very lucky.)
82
 
83
Consider, for example, the \.{ADD} instruction. This instruction enters
84
the computer's processing unit in F stage, taking only one clock cycle if
85
it is in the cache of instructions recently seen. Then the D~stage
86
recognizes the command as an \.{ADD} and acquires the current values
87
of \$Y and \$Z; meanwhile, of course, another instruction is being fetched
88
by~F.
89
On the next clock cycle, the X stage adds the values together.
90
This prepares the way for the M stage to watch for overflow and to
91
get ready for any exceptional action that might be needed with respect
92
to the settings of special register~rA\null.
93
Finally, on the fifth clock cycle, the sum is either written into~\$X
94
or the trip handler for integer overflow is invoked.
95
Although this process has taken five clock
96
cycles (that is, $5\upsilon$),
97
the net increase in running time has been only~$1\upsilon$.
98
 
99
Of course congestion can occur, inside a computer as in a repair shop.
100
For example, auto parts might not be readily available; or a car might
101
have to sit in D station while waiting to move to XM, thereby blocking
102
somebody else from moving from F to~D.  Sometimes there won't
103
necessarily be a steady stream of customers.  In such cases the
104
employees in some parts of the shop will occasionally be idle.  But we
105
assume that they always do their jobs as fast as possible, given the
106
sequence of customers that they encounter. With a clever person
107
setting up appointments---translation: with a clever
108
programmer and/or compiler arranging \MMIX\ instructions---the
109
organization can often be expected to run at nearly peak capacity.
110
 
111
In fact, this program is designed for experiments with many kinds of
112
pipelines, potentially using additional functional units (such as
113
several independent X~groups), and potentially fetching, dispatching, and
114
executing several nonconflicting instructions simultaneously.
115
Such complications
116
make this program more difficult than a simple pipeline simulator
117
would be, but they also make it a lot more instructive because we
118
can get a better understanding of the issues involved if we are
119
required to treat them in greater generality.
120
 
121
@ Here's the overall structure of the present program module.
122
 
123
@c
124
#include 
125
#include 
126
#include 
127
#include "abstime.h"
128
@h@#
129
@
@;
130
@@;
131
@@;
132
@@;
133
@@;
134
@@;
135
@@;
136
@@;
137
 
138
@ The identifier \&{Extern} is used in {\mc MMIX-PIPE} to
139
declare variables that are accessed in other modules. Actually
140
all appearances of `\&{Extern}' are defined to be blank here, but
141
`\&{Extern}' will become `\&{extern}' in the header file.
142
 
143
@d Extern  /* blank for us, \&{extern} for them */
144
@f Extern extern
145
 
146
@=
147
Extern int verbose; /* controls the level of diagnostic output */
148
 
149
@ The header file repeats the basic definitions and declarations.
150
 
151
@(mmix-pipe.h@>=
152
#define Extern extern
153
@
@;
154
@@;
155
@@;
156
@@;
157
 
158
@ Subroutines of this program are declared first with a prototype,
159
as in {\mc ANSI C}, then with an old-style \CEE/ function definition.
160
The following preprocessor commands make this work correctly with both
161
new-style and old-style compilers.
162
@^prototypes for functions@>
163
 
164
@
=
165
#ifdef __STDC__
166
#define ARGS(list) list
167
#else
168
#define ARGS(list) ()
169
#endif
170
 
171
@ Some of the names that are natural for this program are in
172
conflict with library names on at least
173
one of the host computers in the author's tests. So we
174
bypass the library names here.
175
 
176
@
=
177
#define random my_random
178
#define fsqrt my_fsqrt
179
#define div my_div
180
 
181
@ The amount of verbosity depends on the following bit codes.
182
 
183
@
=
184
#define issue_bit (1<<0)
185
   /* show control blocks when issued, deissued, committed */
186
#define pipe_bit (1<<1)
187
   /* show the pipeline and locks on every cycle */
188
#define coroutine_bit (1<<2)
189
   /* show the coroutines when started on every cycle */
190
#define schedule_bit (1<<3)
191
   /* show the coroutines when scheduled */
192
#define uninit_mem_bit (1<<4)
193
   /* complain when reading from an uninitialized chunk of memory */
194
#define interactive_read_bit (1<<5)
195
   /* prompt user when reading from I/O location */
196
#define show_spec_bit (1<<6)
197
   /* display special read/write transactions as they happen */
198
#define show_pred_bit (1<<7)
199
   /* display branch prediction details */
200
#define show_wholecache_bit (1<<8)
201
   /* display cache blocks even when their key tag is invalid */
202
 
203
@ The |MMIX_init()| routine should be called exactly once, after
204
|MMIX_config()| has done its work but before the simulator starts to execute
205
any programs. Then |MMIX_run| can be called as often as the user likes.
206
 
207
@s octa int
208
 
209
@=
210
Extern void MMIX_init @,@,@[ARGS((void))@];
211
Extern void MMIX_run @,@,@[ARGS((int cycs, octa breakpoint))@];
212
 
213
@ @=
214
void MMIX_init()
215
{
216
  register int i,j;
217
  @;
218
}
219
@#
220
void MMIX_run(cycs,breakpoint)
221
  int cycs;
222
  octa breakpoint;
223
{
224
  @;
225
  while (cycs) {
226
    if (verbose&(issue_bit|pipe_bit|coroutine_bit|schedule_bit))
227
      printf("*** Cycle %d\n", ticks.l);
228
    @;
229
    if (verbose&pipe_bit) {
230
      print_pipe();@+ print_locks();
231
    }
232
    if (breakpoint_hit||halted) {
233
      if (breakpoint_hit)
234
        printf("Breakpoint instruction fetched at time %d\n",ticks.l-1);
235
      if (halted) printf("Halted at time %d\n", ticks.l-1);
236
      break;
237
    }
238
    cycs--;
239
  }
240
 cease:;
241
}
242
 
243
@ @=
244
typedef enum {@!false, @!true, @!wow}@+bool; /* slightly extended booleans */
245
 
246
@ @=
247
register int i,j,m;
248
bool breakpoint_hit=false;
249
bool halted=false;
250
 
251
@ Error messages that abort this program are called panic messages.
252
The macro called |confusion| will never be needed unless this program is
253
internally inconsistent.
254
 
255
@d errprint0(f) fprintf(stderr,f)
256
@d errprint1(f,a) fprintf(stderr,f,a)
257
@d errprint2(f,a,b) fprintf(stderr,f,a,b)
258
@d panic(x)@+ {@+errprint0("Panic: ");@+x;@+errprint0("!\n");@+expire();@+}
259
@d confusion(m) errprint1("This can't happen: %s",m)
260
@.This can't happen@>
261
 
262
@=
263
static void expire @,@,@[ARGS((void))@];
264
 
265
@ @=
266
static void expire() /* the last gasp before dying */
267
{
268
  if (ticks.h) errprint2("(Clock time is %dH+%d.)\n",ticks.h,ticks.l);
269
  else errprint1("(Clock time is %d.)\n",ticks.l);
270
@.Clock time is...@>
271
  exit(-2);
272
}
273
 
274
@ The data structures of this program are not precisely equivalent to
275
logical gates that could be implemented directly in silicon;
276
we will use data structures and
277
algorithms appropriate to the \CEE/ programming language. For example,
278
we'll use pointers and arrays, instead of buses and ports and latches. However,
279
the net effect of our data structures and algorithms is intended to
280
be equivalent to the net effect of a silicon implementation. The methods
281
used below are essentially equivalent to those used in real machines today,
282
except that diagnostic facilities are added so that we can readily
283
watch what is happening.
284
 
285
Each functional unit in the \MMIX\ pipeline is programmed here as a coroutine
286
in~\CEE/. At every clock cycle, we will call on each active coroutine to do one
287
phase of its operation; in terms of the repair-station analogy
288
described in the main program,
289
this corresponds to getting each group of
290
auto mechanics to do one unit of operation on a car.
291
The coroutines are performed sequentially, although
292
a real pipeline would have them act in parallel.
293
We will not ``cheat'' by letting one coroutine access a value early in its
294
cycle that another one computes late in its cycle, unless computer hardware
295
could ``cheat'' in an equivalent way.
296
 
297
@* Low-level routines. Where should we begin? It is tempting to start with a
298
global view of the simulator and then to break it down into component parts.
299
But that task is too daunting, because there are so many unknowns about what
300
basic ingredients ought to be combined when we construct the larger
301
components. So let us look first at the primitive operations on which
302
the superstructure will be built. Once we have created some infrastructure,
303
we'll be able to proceed with confidence to the larger tasks ahead.
304
 
305
@ This program for the 64-bit \MMIX\ architecture is based on 32-bit integer
306
arithmetic, because nearly every computer available to the author at the time
307
of writing (1998--1999) was limited in that way.
308
Details of the basic arithmetic appear in a separate program module
309
called {\mc MMIX-ARITH}, because the same routines are needed also
310
for the assembler and for the non-pipelined simulator. The
311
definition of type \&{tetra} should be changed, if necessary, to conform with
312
the definitions found there.
313
@^system dependencies@>
314
 
315
@=
316
typedef unsigned int tetra;
317
  /* for systems conforming to the LP-64 data model */
318
typedef struct { tetra h,l;} octa; /* two tetrabytes make one octabyte */
319
 
320
@ @=
321
static void print_octa @,@,@[ARGS((octa))@];
322
 
323
@ @=
324
static void print_octa(o)
325
  octa o;
326
{
327
  if (o.h) printf("%x%08x",o.h,o.l);@+
328
  else printf("%x",o.l);
329
}
330
 
331
@ @=
332
extern octa zero_octa; /* |zero_octa.h=zero_octa.l=0| */
333
extern octa neg_one; /* |neg_one.h=neg_one.l=-1| */
334
extern octa aux; /* auxiliary output of a subroutine */
335
extern bool overflow; /* set by certain subroutines for signed arithmetic */
336
extern int exceptions; /* bits set by floating point operations */
337
extern int cur_round; /* the current rounding mode */
338
 
339
@ Most of the subroutines in {\mc MMIX-ARITH} return an octabyte as
340
a function of two octabytes; for example, |oplus(y,z)| returns the
341
sum of octabytes |y| and~|z|. Multiplication returns the high
342
half of a product in the global variable~|aux|; division returns
343
the remainder in~|aux|.
344
 
345
@=
346
extern octa oplus @,@,@[ARGS((octa y,octa z))@];
347
  /* unsigned $y+z$ */
348
extern octa ominus @,@,@[ARGS((octa y,octa z))@];
349
  /* unsigned $y-z$ */
350
extern octa incr @,@,@[ARGS((octa y,int delta))@];
351
  /* unsigned $y+\delta$ ($\delta$ is signed) */
352
extern octa oand @,@,@[ARGS((octa y,octa z))@];
353
  /* $y\land z$ */
354
extern octa oandn @,@,@[ARGS((octa y,octa z))@];
355
  /* $y\land \bar z$ */
356
extern octa shift_left @,@,@[ARGS((octa y,int s))@];
357
  /* $y\LL s$, $0\le s\le64$ */
358
extern octa shift_right @,@,@[ARGS((octa y,int s,int uns))@];
359
  /* $y\GG s$, signed if |!uns| */
360
extern octa omult @,@,@[ARGS((octa y,octa z))@];
361
  /* unsigned $(|aux|,x)=y\times z$ */
362
extern octa signed_omult @,@,@[ARGS((octa y,octa z))@];
363
  /* signed $x=y\times z$, setting |overflow| */
364
extern octa odiv @,@,@[ARGS((octa x,octa y,octa z))@];
365
  /* unsigned $(x,y)/z$; $|aux|=(x,y)\bmod z$ */
366
extern octa signed_odiv @,@,@[ARGS((octa y,octa z))@];
367
  /* signed $y/z$, when $z\ne0$; $|aux|=y\bmod z$ */
368
extern int count_bits @,@,@[ARGS((tetra z))@];
369
  /* $x=\nu(z)$ */
370
extern tetra byte_diff @,@,@[ARGS((tetra y,tetra z))@];
371
  /* half of \.{BDIF} */
372
extern tetra wyde_diff @,@,@[ARGS((tetra y,tetra z))@];
373
  /* half of \.{WDIF} */
374
extern octa bool_mult @,@,@[ARGS((octa y,octa z,bool xor))@];
375
  /* \.{MOR} or \.{MXOR} */
376
extern octa load_sf @,@,@[ARGS((tetra z))@];
377
  /* load short float */
378
extern tetra store_sf @,@,@[ARGS((octa x))@];
379
  /* store short float */
380
extern octa fplus @,@,@[ARGS((octa y,octa z))@];
381
  /* floating point $x=y\oplus z$ */
382
extern octa fmult @,@,@[ARGS((octa y ,octa z))@];
383
  /* floating point $x=y\otimes z$ */
384
extern octa fdivide @,@,@[ARGS((octa y,octa z))@];
385
  /* floating point $x=y\oslash z$ */
386
extern octa froot @,@,@[ARGS((octa,int))@];
387
  /* floating point $x=\sqrt z$ */
388
extern octa fremstep @,@,@[ARGS((octa y,octa z,int delta))@];
389
  /* floating point $x\,{\rm rem}\,z=y\,{\rm rem}\,z$ */
390
extern octa fintegerize @,@,@[ARGS((octa z,int mode))@];
391
  /* floating point $x={\rm round}(z)$ */
392
extern int fcomp @,@,@[ARGS((octa y,octa z))@];
393
  /* $-1$, 0, 1, or 2 if $yz$, $y\parallel z$ */
394
extern int fepscomp @,@,@[ARGS((octa y,octa z,octa eps,int sim))@];
395
  /* $x=|sim|?\ [y\sim z\ (\epsilon)]:\ [y\approx z\ (\epsilon)]$ */
396
extern octa floatit @,@,@[ARGS((octa z,int mode,int unsgnd,int shrt))@];
397
  /* fix to float */
398
extern octa fixit @,@,@[ARGS((octa z,int mode))@];
399
  /* float to fix */
400
 
401
@ We had better check that our 32-bit assumption holds.
402
 
403
@=
404
if (shift_left(neg_one,1).h!=0xffffffff)
405
  panic(errprint0("Incorrect implementation of type tetra"));
406
@.Incorrect implementation...@>
407
 
408
@* Coroutines. As stated earlier, this program can be regarded as a system of
409
interacting coroutines. Coroutines---sometimes called threads---are more or
410
less independent processes that share and pass data and control back and
411
forth. They correspond to the individual workers in an organization.
412
 
413
We don't need the full power of recursive coroutines, in which new threads are
414
spawned dynamically and have independent stacks for computation; we are, after
415
all, simulating a fixed piece of hardware. The total number of coroutines we
416
deal with is established once and for all by the |MMIX_config| routine, and
417
each coroutine has a fixed amount of local data.
418
 
419
The simulation operates one clock tick at a time, by executing all
420
coroutines scheduled for time~$t$ before advancing to time~$t+1$. The
421
coroutines at time~$t$ may decide to become dormant or they may reschedule
422
themselves and/or other coroutines for future times.
423
 
424
Each coroutine has a symbolic |name| for diagnostic purposes (e.g.,
425
\.{ALU1}); a nonnegative |stage| number (e.g., 2~for the second stage
426
of a pipeline); a pointer to the next coroutine scheduled at the same time (or
427
|NULL| if the coroutine is unscheduled); a pointer to a lock variable
428
(or |NULL| if no lock is currently relevant);
429
and a reference to a control block containing the data to be processed.
430
 
431
@s control_struct int
432
 
433
@=
434
typedef struct coroutine_struct {
435
 char *name; /* symbolic identification of a coroutine */
436
 int stage; /* its rank */
437
 struct coroutine_struct *next; /* its successor */
438
 struct coroutine_struct **lockloc; /* what it might be locking */
439
 struct control_struct *ctl; /* its data */
440
} coroutine;
441
 
442
@ @=
443
static void print_coroutine_id @,@,@[ARGS((coroutine*))@];
444
static void errprint_coroutine_id @,@,@[ARGS((coroutine*))@];
445
 
446
@ @=
447
static void print_coroutine_id(c)
448
  coroutine *c;
449
{
450
  if (c) printf("%s:%d",c->name,c->stage);
451
  else printf("??");
452
}
453
@#
454
static void errprint_coroutine_id(c)
455
  coroutine *c;
456
{
457
  if (c) errprint2("%s:%d",c->name,c->stage);
458
  else errprint0("??");
459
@.??@>
460
}
461
 
462
@ Coroutine control is masterminded by a ring of queues, one each for
463
times $t$, $t+1$, \dots, $t+|ring_size|-1$, when $t$ is the current
464
clock time.
465
 
466
All scheduling is first-come-first-served, except that coroutines with higher
467
|stage| numbers have priority. We want to process the later stages of a
468
pipeline first, in this sequential implementation, for the same reason that a
469
car must drive from M~station into W~station before another car can enter
470
M~station.
471
 
472
Each queue is a circular list of \&{coroutine} nodes, linked together by their
473
|next| fields. A list head~$h$ with |stage=max_stage| comes at the end and the
474
beginning of the queue. (All |stage| numbers of legitimate coroutines
475
are less than~|max_stage|.) The queued items are |h->next|, |h->next->next|,
476
etc., from back to front, and we have |c->stage<=c->next->stage| unless |c=h|.
477
 
478
Initially all queues are empty.
479
 
480
@=
481
{@+register coroutine *p;
482
  for (p=ring;pnext=p;
483
}
484
 
485
@ To schedule a coroutine |c| with positive delay |d
486
|schedule(c,d,s)|. (The |s| parameter is used only if scheduling is
487
being logged; it does not affect the computation, but we will
488
generally set |s| to the state at which the scheduled coroutine will begin.)
489
 
490
@=
491
static void schedule @,@,@[ARGS((coroutine*,int,int))@];
492
 
493
@ @=
494
static void schedule(c,d,s)
495
  coroutine *c;
496
  int d,s;
497
{
498
  register int tt=(cur_time+d)%ring_size;
499
  register coroutine *p=&ring[tt]; /* start at the list head */
500
  if (d<=0 || d>=ring_size) /* do a sanity check */
501
   panic(confusion("Scheduling ");errprint_coroutine_id(c);
502
         errprint1(" with delay %d",d));
503
  while (p->next->stagestage) p=p->next;
504
  c->next = p->next;
505
  p->next = c;
506
  if (verbose&schedule_bit) {
507
    printf(" scheduling ");@+print_coroutine_id(c);
508
    printf(" at time %d, state %d\n",ticks.l+d,s);
509
  }
510
}
511
 
512
@ @=
513
Extern int ring_size; /* set by |MMIX_config|, must be sufficiently large */
514
Extern coroutine *ring;
515
Extern int cur_time;
516
 
517
@ The all-important |ctl| field of a coroutine, which contains the
518
data being manipulated, will be explained below. One of its key
519
components is the |state| field, which helps to specify the next
520
actions the coroutine will perform. When we schedule a coroutine for
521
a new task, we often want it to begin in state~0.
522
 
523
@=
524
static void startup @,@,@[ARGS((coroutine*,int))@];
525
 
526
@ @=
527
static void startup(c,d)
528
  coroutine *c;
529
  int d;
530
{
531
  c->ctl->state=0;
532
  schedule(c,d,0);
533
}
534
 
535
@ The following routine removes a coroutine from whatever queue it's in.
536
The case |c->next=c| is also permitted; such a self-loop can occur when a
537
coroutine goes to sleep and expects to be awakened (that is, scheduled)
538
by another coroutine. Sleeping coroutines have important data in their
539
|ctl| field; they are therefore quite different from unscheduled
540
or ``unemployed'' coroutines, which have |c->next=NULL|. An unemployed
541
coroutine is not assumed to have any valid data in its |ctl| field.
542
 
543
@=
544
static void unschedule @,@,@[ARGS((coroutine*))@];
545
 
546
@ @=
547
static void unschedule(c)
548
  coroutine *c;
549
{@+register coroutine *p;
550
  if (c->next) {
551
    for (p=c; p->next!=c; p=p->next) ;
552
    p->next = c->next;
553
    c->next=NULL;
554
    if (verbose&schedule_bit) {
555
      printf(" unscheduling ");@+print_coroutine_id(c);@+printf("\n");
556
    }
557
  }
558
}
559
 
560
@ When it is time to process all coroutines that have queued up for a
561
particular time~|t|, we empty the queue called |ring[t]| and link its items in
562
the opposite order (from front to back). The following subroutine uses the
563
well known algorithm discussed in exercise 2.2.3--7 of {\sl The Art
564
of Computer Programming}.
565
 
566
@=
567
static coroutine *queuelist @,@,@[ARGS((int))@];
568
 
569
@ @=
570
static coroutine* queuelist(t)
571
  int t;
572
{@+register coroutine *p, *q=&sentinel, *r;
573
  for (p=ring[t].next;p!=&ring[t];p=r) {
574
    r=p->next;
575
    p->next=q;
576
    q=p;
577
  }
578
  ring[t].next=&ring[t];
579
  sentinel.next=q;
580
  return q;
581
}
582
 
583
@ @=
584
coroutine sentinel; /* dummy coroutine at origin of circular list */
585
 
586
@ Coroutines often start working on tasks that are {\it speculative}, in the
587
sense that we want certain results to be ready if they prove to be
588
useful; we understand that speculative computations might not actually
589
be needed. Therefore a coroutine might need to be aborted before it
590
has finished its work.
591
 
592
All coroutines must be written in such a way that important data structures
593
remain intact even when the coroutine is abruptly terminated. In particular,
594
we need to be sure that ``locks'' on shared resources are restored to
595
an unlocked state when a coroutine holding the lock is aborted.
596
 
597
A \&{lockvar} variable is |NULL| when it is unlocked; otherwise it
598
points to the coroutine responsible for unlocking~it.
599
 
600
@d set_lock(c,l) {@+l=c;@+(c)->lockloc=&(l);@+}
601
@d release_lock(c,l) {@+l=NULL;@+ (c)->lockloc=NULL;@+}
602
 
603
@=
604
typedef coroutine *lockvar;
605
 
606
@ @=
607
Extern void print_locks @,@,@[ARGS((void))@];
608
 
609
@ @=
610
void print_locks()
611
{
612
  print_cache_locks(ITcache);
613
  print_cache_locks(DTcache);
614
  print_cache_locks(Icache);
615
  print_cache_locks(Dcache);
616
  print_cache_locks(Scache);
617
  if (mem_lock) printf("mem locked by %s:%d\n",mem_lock->name,mem_lock->stage);
618
  if (dispatch_lock) printf("dispatch locked by %s:%d\n",
619
                    dispatch_lock->name,dispatch_lock->stage);
620
  if (wbuf_lock) printf("head of write buffer locked by %s:%d\n",
621
                    wbuf_lock->name,wbuf_lock->stage);
622
  if (clean_lock) printf("cleaner locked by %s:%d\n",
623
                    clean_lock->name,clean_lock->stage);
624
  if (speed_lock) printf("write buffer flush locked by %s:%d\n",
625
                    speed_lock->name,speed_lock->stage);
626
}
627
 
628
@ Many of the quantities we deal with are speculative values
629
that might not yet have been certified as part of the ``real''
630
calculation; in fact, they might not yet have been calculated.
631
 
632
A \&{spec} consists of a 64-bit quantity |o| and a pointer~|p| to
633
a \&{specnode}. The value~|o| is meaningful only if the
634
pointer~|p| is~|NULL|; otherwise |p| points to a source of further information.
635
 
636
A \&{specnode} is a 64-bit quantity |o| together with links to other
637
\&{specnode}s
638
that are above it or below it in a doubly linked list. An additional
639
|known| bit tells whether the |o|~field has been calculated. There also is
640
a 64-bit |addr| field, to identify the list and give further information.
641
A \&{specnode} list keeps track of speculative values related to a specific
642
register or to all of main memory; we will discuss such lists in detail~later.
643
 
644
@s specnode_struct int
645
 
646
@=
647
typedef struct {
648
  octa o;
649
  struct specnode_struct *p;
650
} spec;
651
@#
652
typedef struct specnode_struct {
653
  octa o;
654
  bool known;
655
  octa addr;
656
  struct specnode_struct *up,*down;
657
} specnode;
658
 
659
@ @=
660
spec zero_spec; /* |zero_spec.o.h=zero_spec.o.l=0| and |zero_spec.p=NULL| */
661
 
662
@ @=
663
static void print_spec @,@,@[ARGS((spec))@];
664
 
665
@ @=
666
static void print_spec(s)
667
  spec s;
668
{
669
  if (!s.p) print_octa(s.o);
670
  else {
671
    printf(">");@+ print_specnode_id(s.p->addr);
672
  }
673
}
674
@#
675
static void print_specnode(s)
676
  specnode s;
677
{
678
  if (s.known) {@+print_octa(s.o);@+printf("!");@+}
679
  else if (s.o.h || s.o.l) {@+print_octa(s.o);@+printf("?");@+}
680
  else printf("?");
681
  print_specnode_id(s.addr);
682
}
683
 
684
@ The analog of an automobile in our simulator is a block of data called
685
\&{control}, which represents all the relevant facts about an \MMIX\
686
instruction.  We can think of it as the work order attached to a car's
687
windshield. Each group of employees updates the work order as the car moves
688
through the shop.
689
 
690
A \&{control} record contains the original location of an instruction,
691
and its four bytes OP~X~Y~Z. An instruction has up to four inputs, which are
692
\&{spec} records called |y|, |z|, |b| and~|ra|; it also has up to three
693
outputs, which are \&{specnode} records called |x|, |a|, and~|rl|.
694
(We usually don't mention the special input~|ra| or the special output~|rl|,
695
which refer to \.{MMIX}'s internal registers rA and~rL.) For example, the
696
main inputs to a \.{DIVU} command are \$Y, \$Z, and~rD; the outputs are the
697
quotient~\$X and the remainder~rR. The inputs to a
698
\.{STO} command are \$Y, \$Z, and~\$X; there is one ``output,'' and
699
the field~|x.addr| will be set to the physical address of the memory location
700
corresponding to virtual address $\rm \$Y+\$Z$.
701
 
702
Each \&{control} block also points to the coroutine that owns it, if any.
703
And it has various other fields that contain other tidbits of information;
704
for example, we have already mentioned
705
the |state|~field, which often governs a coroutine's actions. The |i|~field,
706
which contains an internal operation code number, is generally used together
707
with |state| to switch between alternative computational steps. If, for
708
example, the |op|~field is \.{SUB} or \.{SUBI} or \.{NEG} or \.{NEGI},
709
the internal opcode~|i| will be simply~|sub|.
710
We shall define all the fields of \&{control} records
711
now and discuss them later.
712
 
713
An actual hardware implementation of \MMIX\ wouldn't need all the information
714
we are putting into a \&{control} block. Some of that information would
715
typically be latched between stages of a pipeline; other portions would
716
probably appear in so-called ``rename registers.''
717
@^rename registers@>
718
We simulate rename registers only indirectly,
719
by counting how many registers of that
720
kind would be in use if we were mimicking low-level hardware details more
721
precisely. The |go| field is a \&{specnode} for convenience in programming,
722
although we use only its |known| and |o| subfields. It generally contains
723
the address of the subsequent instruction.
724
 
725
@s mmix_opcode int
726
@s internal_opcode int
727
 
728
@=
729
@@;
730
typedef struct control_struct {
731
 octa loc; /* virtual address where an instruction originated */
732
 mmix_opcode op;@+ unsigned char xx,yy,zz; /* the original instruction bytes */
733
 spec y,z,b,ra; /* inputs */
734
 specnode x,a,go,rl; /* outputs */
735
 coroutine *owner; /* a coroutine whose |ctl| this is */
736
 internal_opcode i; /* internal opcode */
737
 int state; /* internal mindset */
738
 bool usage; /* should rU be increased? */
739
 bool need_b; /* should we stall until |b.p==NULL|? */
740
 bool need_ra; /* should we stall until |ra.p==NULL|? */
741
 bool ren_x; /* does |x| correspond to a rename register? */
742
 bool mem_x; /* does |x| correspond to a memory write? */
743
 bool ren_a; /* does |a| correspond to a rename register? */
744
 bool set_l; /* does |rl| correspond to a new value of rL? */
745
 bool interim; /* does this instruction need to be reissued on interrupt? */
746
 unsigned int arith_exc; /* arithmetic exceptions for event bits of rA */
747
 unsigned int hist; /* history bits for use in branch prediction */
748
 int denin,denout; /* execution time penalties for subnormal handling */
749
 octa cur_O,cur_S; /* speculative rO and rS before this instruction */
750
 unsigned int interrupt; /* does this instruction generate an interrupt? */
751
 void *ptr_a, *ptr_b, *ptr_c; /* generic pointers for miscellaneous use */
752
} control;
753
 
754
@ @=
755
static void print_control_block @,@,@[ARGS((control*))@];
756
 
757
@ @=
758
static void print_control_block(c)
759
  control *c;
760
{
761
  octa default_go;
762
  if (c->loc.h || c->loc.l || c->op || c->xx || c->yy || c->zz || c->owner) {
763
    print_octa(c->loc);
764
    printf(": %02x%02x%02x%02x(%s)",c->op,c->xx,c->yy,c->zz,
765
              internal_op_name[c->i]);
766
  }
767
  if (c->usage) printf("*");
768
  if (c->interim) printf("+");
769
  if (c->y.o.h || c->y.o.l || c->y.p) {@+printf(" y=");@+print_spec(c->y);@+}
770
  if (c->z.o.h || c->z.o.l || c->z.p) {@+printf(" z=");@+print_spec(c->z);@+}
771
  if (c->b.o.h || c->b.o.l || c->b.p || c->need_b) {
772
    printf(" b=");@+print_spec(c->b);
773
    if (c->need_b) printf("*");
774
  }
775
  if (c->need_ra) {@+printf(" rA=");@+print_spec(c->ra);@+}
776
  if (c->ren_x || c->mem_x) {@+printf(" x=");@+print_specnode(c->x);@+}
777
  else if (c->x.o.h || c->x.o.l) {
778
    printf(" x=");@+print_octa(c->x.o);@+printf("%c",c->x.known? '!': '?');
779
  }
780
  if (c->ren_a) {@+printf(" a=");@+print_specnode(c->a);@+}
781
  if (c->set_l) {@+printf(" rL=");@+print_specnode(c->rl);@+}
782
  if (c->interrupt) {@+printf(" int=");@+print_bits(c->interrupt);@+}
783
  if (c->arith_exc) {@+printf(" exc=");@+print_bits(c->arith_exc<<8);@+}
784
  default_go=incr(c->loc,4);
785
  if (c->go.o.l!=default_go.l || c->go.o.h!=default_go.h) {
786
    printf(" ->");@+print_octa(c->go.o);
787
  }
788
  if (verbose&show_pred_bit) printf(" hist=%x",c->hist);
789
  if (c->i==pop) {
790
     printf(" rS="); print_octa(c->cur_S);
791
     printf(" rO="); print_octa(c->cur_O);
792
  }
793
  printf(" state=%d",c->state);
794
}
795
 
796
@* Lists. Here is a (boring) list of all the \MMIX\ opcodes, in order.
797
 
798
@=
799
typedef enum{@/
800
@!TRAP,@!FCMP,@!FUN,@!FEQL,@!FADD,@!FIX,@!FSUB,@!FIXU,@/
801
@!FLOT,@!FLOTI,@!FLOTU,@!FLOTUI,@!SFLOT,@!SFLOTI,@!SFLOTU,@!SFLOTUI,@/
802
@!FMUL,@!FCMPE,@!FUNE,@!FEQLE,@!FDIV,@!FSQRT,@!FREM,@!FINT,@/
803
@!MUL,@!MULI,@!MULU,@!MULUI,@!DIV,@!DIVI,@!DIVU,@!DIVUI,@/
804
@!ADD,@!ADDI,@!ADDU,@!ADDUI,@!SUB,@!SUBI,@!SUBU,@!SUBUI,@/
805
@!IIADDU,@!IIADDUI,@!IVADDU,@!IVADDUI,@!VIIIADDU,@!VIIIADDUI,@!XVIADDU,@!XVIADDUI,@/
806
@!CMP,@!CMPI,@!CMPU,@!CMPUI,@!NEG,@!NEGI,@!NEGU,@!NEGUI,@/
807
@!SL,@!SLI,@!SLU,@!SLUI,@!SR,@!SRI,@!SRU,@!SRUI,@/
808
@!BN,@!BNB,@!BZ,@!BZB,@!BP,@!BPB,@!BOD,@!BODB,@/
809
@!BNN,@!BNNB,@!BNZ,@!BNZB,@!BNP,@!BNPB,@!BEV,@!BEVB,@/
810
@!PBN,@!PBNB,@!PBZ,@!PBZB,@!PBP,@!PBPB,@!PBOD,@!PBODB,@/
811
@!PBNN,@!PBNNB,@!PBNZ,@!PBNZB,@!PBNP,@!PBNPB,@!PBEV,@!PBEVB,@/
812
@!CSN,@!CSNI,@!CSZ,@!CSZI,@!CSP,@!CSPI,@!CSOD,@!CSODI,@/
813
@!CSNN,@!CSNNI,@!CSNZ,@!CSNZI,@!CSNP,@!CSNPI,@!CSEV,@!CSEVI,@/
814
@!ZSN,@!ZSNI,@!ZSZ,@!ZSZI,@!ZSP,@!ZSPI,@!ZSOD,@!ZSODI,@/
815
@!ZSNN,@!ZSNNI,@!ZSNZ,@!ZSNZI,@!ZSNP,@!ZSNPI,@!ZSEV,@!ZSEVI,@/
816
@!LDB,@!LDBI,@!LDBU,@!LDBUI,@!LDW,@!LDWI,@!LDWU,@!LDWUI,@/
817
@!LDT,@!LDTI,@!LDTU,@!LDTUI,@!LDO,@!LDOI,@!LDOU,@!LDOUI,@/
818
@!LDSF,@!LDSFI,@!LDHT,@!LDHTI,@!CSWAP,@!CSWAPI,@!LDUNC,@!LDUNCI,@/
819
@!LDVTS,@!LDVTSI,@!PRELD,@!PRELDI,@!PREGO,@!PREGOI,@!GO,@!GOI,@/
820
@!STB,@!STBI,@!STBU,@!STBUI,@!STW,@!STWI,@!STWU,@!STWUI,@/
821
@!STT,@!STTI,@!STTU,@!STTUI,@!STO,@!STOI,@!STOU,@!STOUI,@/
822
@!STSF,@!STSFI,@!STHT,@!STHTI,@!STCO,@!STCOI,@!STUNC,@!STUNCI,@/
823
@!SYNCD,@!SYNCDI,@!PREST,@!PRESTI,@!SYNCID,@!SYNCIDI,@!PUSHGO,@!PUSHGOI,@/
824
@!OR,@!ORI,@!ORN,@!ORNI,@!NOR,@!NORI,@!XOR,@!XORI,@/
825
@!AND,@!ANDI,@!ANDN,@!ANDNI,@!NAND,@!NANDI,@!NXOR,@!NXORI,@/
826
@!BDIF,@!BDIFI,@!WDIF,@!WDIFI,@!TDIF,@!TDIFI,@!ODIF,@!ODIFI,@/
827
@!MUX,@!MUXI,@!SADD,@!SADDI,@!MOR,@!MORI,@!MXOR,@!MXORI,@/
828
@!SETH,@!SETMH,@!SETML,@!SETL,@!INCH,@!INCMH,@!INCML,@!INCL,@/
829
@!ORH,@!ORMH,@!ORML,@!ORL,@!ANDNH,@!ANDNMH,@!ANDNML,@!ANDNL,@/
830
@!JMP,@!JMPB,@!PUSHJ,@!PUSHJB,@!GETA,@!GETAB,@!PUT,@!PUTI,@/
831
@!POP,@!RESUME,@!SAVE,@!UNSAVE,@!SYNC,@!SWYM,@!GET,@!TRIP}@+@!mmix_opcode;
832
 
833
@ @=
834
char *opcode_name[]={
835
"TRAP","FCMP","FUN","FEQL","FADD","FIX","FSUB","FIXU",@/
836
"FLOT","FLOTI","FLOTU","FLOTUI","SFLOT","SFLOTI","SFLOTU","SFLOTUI",@/
837
"FMUL","FCMPE","FUNE","FEQLE","FDIV","FSQRT","FREM","FINT",@/
838
"MUL","MULI","MULU","MULUI","DIV","DIVI","DIVU","DIVUI",@/
839
"ADD","ADDI","ADDU","ADDUI","SUB","SUBI","SUBU","SUBUI",@/
840
"2ADDU","2ADDUI","4ADDU","4ADDUI","8ADDU","8ADDUI","16ADDU","16ADDUI",@/
841
"CMP","CMPI","CMPU","CMPUI","NEG","NEGI","NEGU","NEGUI",@/
842
"SL","SLI","SLU","SLUI","SR","SRI","SRU","SRUI",@/
843
"BN","BNB","BZ","BZB","BP","BPB","BOD","BODB",@/
844
"BNN","BNNB","BNZ","BNZB","BNP","BNPB","BEV","BEVB",@/
845
"PBN","PBNB","PBZ","PBZB","PBP","PBPB","PBOD","PBODB",@/
846
"PBNN","PBNNB","PBNZ","PBNZB","PBNP","PBNPB","PBEV","PBEVB",@/
847
"CSN","CSNI","CSZ","CSZI","CSP","CSPI","CSOD","CSODI",@/
848
"CSNN","CSNNI","CSNZ","CSNZI","CSNP","CSNPI","CSEV","CSEVI",@/
849
"ZSN","ZSNI","ZSZ","ZSZI","ZSP","ZSPI","ZSOD","ZSODI",@/
850
"ZSNN","ZSNNI","ZSNZ","ZSNZI","ZSNP","ZSNPI","ZSEV","ZSEVI",@/
851
"LDB","LDBI","LDBU","LDBUI","LDW","LDWI","LDWU","LDWUI",@/
852
"LDT","LDTI","LDTU","LDTUI","LDO","LDOI","LDOU","LDOUI",@/
853
"LDSF","LDSFI","LDHT","LDHTI","CSWAP","CSWAPI","LDUNC","LDUNCI",@/
854
"LDVTS","LDVTSI","PRELD","PRELDI","PREGO","PREGOI","GO","GOI",@/
855
"STB","STBI","STBU","STBUI","STW","STWI","STWU","STWUI",@/
856
"STT","STTI","STTU","STTUI","STO","STOI","STOU","STOUI",@/
857
"STSF","STSFI","STHT","STHTI","STCO","STCOI","STUNC","STUNCI",@/
858
"SYNCD","SYNCDI","PREST","PRESTI","SYNCID","SYNCIDI","PUSHGO","PUSHGOI",@/
859
"OR","ORI","ORN","ORNI","NOR","NORI","XOR","XORI",@/
860
"AND","ANDI","ANDN","ANDNI","NAND","NANDI","NXOR","NXORI",@/
861
"BDIF","BDIFI","WDIF","WDIFI","TDIF","TDIFI","ODIF","ODIFI",@/
862
"MUX","MUXI","SADD","SADDI","MOR","MORI","MXOR","MXORI",@/
863
"SETH","SETMH","SETML","SETL","INCH","INCMH","INCML","INCL",@/
864
"ORH","ORMH","ORML","ORL","ANDNH","ANDNMH","ANDNML","ANDNL",@/
865
"JMP","JMPB","PUSHJ","PUSHJB","GETA","GETAB","PUT","PUTI",@/
866
"POP","RESUME","SAVE","UNSAVE","SYNC","SWYM","GET","TRIP"};
867
 
868
@ And here is a (likewise boring) list of all the internal opcodes.
869
The smallest numbers, less than or equal to |max_pipe_op|, correspond
870
to operations for which arbitrary pipeline delays can be configured
871
with |MMIX_config|. The largest numbers, greater than |max_real_command|,
872
correspond to internally
873
generated operations that have no official OP code; for example,
874
there are internal operations to shift the $\gamma$ pointer in the
875
register stack, and to compute page table entries.
876
 
877
@=
878
#define max_pipe_op feps
879
#define max_real_command trip
880
 
881
typedef enum{@/
882
@!mul0, /* multiplication by zero */
883
@!mul1, /* multiplication by 1--8 bits */
884
@!mul2, /* multiplication by 9--16 bits */
885
@!mul3, /* multiplication by 17--24 bits */
886
@!mul4, /* multiplication by 25--32 bits */
887
@!mul5, /* multiplication by 33--40 bits */
888
@!mul6, /* multiplication by 41--48 bits */
889
@!mul7, /* multiplication by 49--56 bits */
890
@!mul8, /* multiplication by 57--64 bits */
891
@!div, /* \.{DIV[U][I]} */
892
@!sh, /* \.{S[L,R][U][I]} */
893
@!mux, /* \.{MUX[I]} */
894
@!sadd, /* \.{SADD[I]} */
895
@!mor, /* \.{M[X]OR[I]} */
896
@!fadd, /* \.{FADD}, \.{FSUB} */
897
@!fmul, /* \.{FMUL} */
898
@!fdiv, /* \.{FDIV} */
899
@!fsqrt, /* \.{FSQRT} */
900
@!fint, /* \.{FINT} */
901
@!fix, /* \.{FIX[U]} */
902
@!flot, /* \.{[S]FLOT[U][I]} */
903
@!feps, /* \.{FCMPE}, \.{FUNE}, \.{FEQLE} */
904
@!fcmp, /* \.{FCMP} */
905
@!funeq, /* \.{FUN}, \.{FEQL} */
906
@!fsub, /* \.{FSUB} */
907
@!frem, /* \.{FREM} */
908
@!mul, /* \.{MUL[I]} */
909
@!mulu, /* \.{MULU[I]} */
910
@!divu, /* \.{DIVU[I]} */
911
@!add, /* \.{ADD[I]} */
912
@!addu, /* \.{[2,4,8,16,]ADDU[I]}, \.{INC[M][H,L]} */
913
@!sub, /* \.{SUB[I]}, \.{NEG[I]} */
914
@!subu, /* \.{SUBU[I]}, \.{NEGU[I]} */
915
@!set, /* \.{SET[M][H,L]}, \.{GETA[B]} */
916
@!or, /* \.{OR[I]}, \.{OR[M][H,L]} */
917
@!orn, /* \.{ORN[I]} */
918
@!nor, /* \.{NOR[I]} */
919
@!and, /* \.{AND[I]} */
920
@!andn, /* \.{ANDN[I]}, \.{ANDN[M][H,L]} */
921
@!nand, /* \.{NAND[I]} */
922
@!xor, /* \.{XOR[I]} */
923
@!nxor, /* \.{NXOR[I]} */
924
@!shlu, /* \.{SLU[I]} */
925
@!shru, /* \.{SRU[I]} */
926
@!shl, /* \.{SL[I]} */
927
@!shr, /* \.{SR[I]} */
928
@!cmp, /* \.{CMP[I]} */
929
@!cmpu, /* \.{CMPU[I]} */
930
@!bdif, /* \.{BDIF[I]} */
931
@!wdif, /* \.{WDIF[I]} */
932
@!tdif, /* \.{TDIF[I]} */
933
@!odif, /* \.{ODIF[I]} */
934
@!zset, /* \.{ZS[N][N,Z,P][I]}, \.{ZSEV[I]}, \.{ZSOD[I]} */
935
@!cset, /* \.{CS[N][N,Z,P][I]}, \.{CSEV[I]}, \.{CSOD[I]} */
936
@!get, /* \.{GET} */
937
@!put, /* \.{PUT[I]} */
938
@!ld, /* \.{LD[B,W,T,O][U][I]}, \.{LDHT[I]}, \.{LDSF[I]} */
939
@!ldptp, /* load page table pointer */
940
@!ldpte, /* load page table entry */
941
@!ldunc, /* \.{LDUNC[I]} */
942
@!ldvts, /* \.{LDVTS[I]} */
943
@!preld, /* \.{PRELD[I]} */
944
@!prest, /* \.{PREST[I]} */
945
@!st, /* \.{STO[U][I]}, \.{STCO[I]}, \.{STUNC[I]} */
946
@!syncd, /* \.{SYNCD[I]} */
947
@!syncid, /* \.{SYNCID[I]} */
948
@!pst, /* \.{ST[B,W,T][U][I]}, \.{STHT[I]} */
949
@!stunc, /* \.{STUNC[I]}, in write buffer */
950
@!cswap, /* \.{CSWAP[I]} */
951
@!br, /* \.{B[N][N,Z,P][B]} */
952
@!pbr, /* \.{PB[N][N,Z,P][B]} */
953
@!pushj, /* \.{PUSHJ[B]} */
954
@!go, /* \.{GO[I]} */
955
@!prego, /* \.{PREGO[I]} */
956
@!pushgo, /* \.{PUSHGO[I]} */
957
@!pop, /* \.{POP} */
958
@!resume, /* \.{RESUME} */
959
@!save, /* \.{SAVE} */
960
@!unsave, /* \.{UNSAVE} */
961
@!sync, /* \.{SYNC} */
962
@!jmp, /* \.{JMP[B]} */
963
@!noop, /* \.{SWYM} */
964
@!trap, /* \.{TRAP} */
965
@!trip, /* \.{TRIP} */
966
@!incgamma, /* increase $\gamma$ pointer */
967
@!decgamma, /* decrease $\gamma$ pointer */
968
@!incrl, /* increase rL and $\beta$ */
969
@!sav, /* intermediate stage of \.{SAVE} */
970
@!unsav, /* intermediate stage of \.{UNSAVE} */
971
@!resum /* intermediate stage of \.{RESUME} */
972
}@! internal_opcode;
973
 
974
@ @=
975
char *internal_op_name[]={
976
"mul0",
977
"mul1",
978
"mul2",
979
"mul3",
980
"mul4",
981
"mul5",
982
"mul6",
983
"mul7",
984
"mul8",
985
"div",
986
"sh",
987
"mux",
988
"sadd",
989
"mor",
990
"fadd",
991
"fmul",
992
"fdiv",
993
"fsqrt",
994
"fint",
995
"fix",
996
"flot",
997
"feps",
998
"fcmp",
999
"funeq",
1000
"fsub",
1001
"frem",
1002
"mul",
1003
"mulu",
1004
"divu",
1005
"add",
1006
"addu",
1007
"sub",
1008
"subu",
1009
"set",
1010
"or",
1011
"orn",
1012
"nor",
1013
"and",
1014
"andn",
1015
"nand",
1016
"xor",
1017
"nxor",
1018
"shlu",
1019
"shru",
1020
"shl",
1021
"shr",
1022
"cmp",
1023
"cmpu",
1024
"bdif",
1025
"wdif",
1026
"tdif",
1027
"odif",
1028
"zset",
1029
"cset",
1030
"get",
1031
"put",
1032
"ld",
1033
"ldptp",
1034
"ldpte",
1035
"ldunc",
1036
"ldvts",
1037
"preld",
1038
"prest",
1039
"st",
1040
"syncd",
1041
"syncid",
1042
"pst",
1043
"stunc",
1044
"cswap",
1045
"br",
1046
"pbr",
1047
"pushj",
1048
"go",
1049
"prego",
1050
"pushgo",
1051
"pop",
1052
"resume",
1053
"save",
1054
"unsave",
1055
"sync",
1056
"jmp",
1057
"noop",
1058
"trap",
1059
"trip",
1060
"incgamma",
1061
"decgamma",
1062
"incrl",
1063
"sav",
1064
"unsav",
1065
"resum"};
1066
 
1067
@ We need a table to convert the external opcodes to
1068
internal ones.
1069
 
1070
@=
1071
internal_opcode internal_op[256]={@/
1072
  trap,fcmp,funeq,funeq,fadd,fix,fsub,fix,@/
1073
  flot,flot,flot,flot,flot,flot,flot,flot,@/
1074
  fmul,feps,feps,feps,fdiv,fsqrt,frem,fint,@/
1075
  mul,mul,mulu,mulu,div,div,divu,divu,@/
1076
  add,add,addu,addu,sub,sub,subu,subu,@/
1077
  addu,addu,addu,addu,addu,addu,addu,addu,@/
1078
  cmp,cmp,cmpu,cmpu,sub,sub,subu,subu,@/
1079
  shl,shl,shlu,shlu,shr,shr,shru,shru,@/
1080
  br,br,br,br,br,br,br,br,@/
1081
  br,br,br,br,br,br,br,br,@/
1082
  pbr,pbr,pbr,pbr,pbr,pbr,pbr,pbr,@/
1083
  pbr,pbr,pbr,pbr,pbr,pbr,pbr,pbr,@/
1084
  cset,cset,cset,cset,cset,cset,cset,cset,@/
1085
  cset,cset,cset,cset,cset,cset,cset,cset,@/
1086
  zset,zset,zset,zset,zset,zset,zset,zset,@/
1087
  zset,zset,zset,zset,zset,zset,zset,zset,@/
1088
  ld,ld,ld,ld,ld,ld,ld,ld,@/
1089
  ld,ld,ld,ld,ld,ld,ld,ld,@/
1090
  ld,ld,ld,ld,cswap,cswap,ldunc,ldunc,@/
1091
  ldvts,ldvts,preld,preld,prego,prego,go,go,@/
1092
  pst,pst,pst,pst,pst,pst,pst,pst,@/
1093
  pst,pst,pst,pst,st,st,st,st,@/
1094
  pst,pst,pst,pst,st,st,st,st,@/
1095
  syncd,syncd,prest,prest,syncid,syncid,pushgo,pushgo,@/
1096
  or,or,orn,orn,nor,nor,xor,xor,@/
1097
  and,and,andn,andn,nand,nand,nxor,nxor,@/
1098
  bdif,bdif,wdif,wdif,tdif,tdif,odif,odif,@/
1099
  mux,mux,sadd,sadd,mor,mor,mor,mor,@/
1100
  set,set,set,set,addu,addu,addu,addu,@/
1101
  or,or,or,or,andn,andn,andn,andn,@/
1102
  jmp,jmp,pushj,pushj,set,set,put,put,@/
1103
  pop,resume,save,unsave,sync,noop,get,trip};
1104
 
1105
@ While we're into boring lists, we might as well define all the
1106
special register numbers, together with an inverse table for
1107
use in diagnostic outputs. These codes have been designed so that
1108
special registers 0--7 are unencumbered, 8--11 can't be \.{PUT} by anybody,
1109
12--18 can't be \.{PUT} by the user. Pipeline delays might occur
1110
when \.{GET} is applied to special registers 21--31 or when
1111
\.{PUT} is applied to special registers 15--20. The \.{SAVE} and
1112
\.{UNSAVE} commands store and restore special registers 0--6 and 23--27.
1113
 
1114
@
=
1115
#define rA 21 /* arithmetic status register */
1116
#define rB 0  /* bootstrap register (trip) */
1117
#define rC 8  /* cycle counter */
1118
#define rD 1  /* dividend register */
1119
#define rE 2  /* epsilon register */
1120
#define rF 22 /* failure location register */
1121
#define rG 19 /* global threshold register */
1122
#define rH 3  /* himult register */
1123
#define rI 12 /* interval counter */
1124
#define rJ 4  /* return-jump register */
1125
#define rK 15 /* interrupt mask register */
1126
#define rL 20 /* local threshold register */
1127
#define rM 5  /* multiplex mask register */
1128
#define rN 9  /* serial number */
1129
#define rO 10 /* register stack offset */
1130
#define rP 23 /* prediction register */
1131
#define rQ 16 /* interrupt request register */
1132
#define rR 6  /* remainder register */
1133
#define rS 11 /* register stack pointer */
1134
#define rT 13 /* trap address register */
1135
#define rU 17 /* usage counter */
1136
#define rV 18 /* virtual translation register */
1137
#define rW 24 /* where-interrupted register (trip) */
1138
#define rX 25 /* execution register (trip) */
1139
#define rY 26 /* Y operand (trip) */
1140
#define rZ 27 /* Z operand (trip) */
1141
#define rBB 7  /* bootstrap register (trap) */
1142
#define rTT 14 /* dynamic trap address register */
1143
#define rWW 28 /* where-interrupted register (trap) */
1144
#define rXX 29 /* execution register (trap) */
1145
#define rYY 30 /* Y operand (trap) */
1146
#define rZZ 31 /* Z operand (trap) */
1147
 
1148
@ @=
1149
char *special_name[32]={"rB","rD","rE","rH","rJ","rM","rR","rBB",
1150
 "rC","rN","rO","rS","rI","rT","rTT","rK","rQ","rU","rV","rG","rL",
1151
 "rA","rF","rP","rW","rX","rY","rZ","rWW","rXX","rYY","rZZ"};
1152
 
1153
@ Here are the bit codes that affect trips and traps. The first eight
1154
cases also apply to the upper half of~rQ; the next eight apply to~rA.
1155
 
1156
@d P_BIT (1<<0) /* instruction in privileged location */
1157
@d S_BIT (1<<1) /* security violation */
1158
@d B_BIT (1<<2) /* instruction breaks the rules */
1159
@d K_BIT (1<<3) /* instruction for kernel only */
1160
@d N_BIT (1<<4) /* virtual translation bypassed */
1161
@d PX_BIT (1<<5) /* permission lacking to execute from page */
1162
@d PW_BIT (1<<6) /* permission lacking to write on page */
1163
@d PR_BIT (1<<7) /* permission lacking to read from page */
1164
@d PROT_OFFSET 5 /* distance from |PR_BIT| to protection code position */
1165
@d X_BIT (1<<8) /* floating inexact */
1166
@d Z_BIT (1<<9) /* floating division by zero */
1167
@d U_BIT (1<<10) /* floating underflow */
1168
@d O_BIT (1<<11) /* floating overflow */
1169
@d I_BIT (1<<12) /* floating invalid operation */
1170
@d W_BIT (1<<13) /* float-to-fix overflow */
1171
@d V_BIT (1<<14) /* integer overflow */
1172
@d D_BIT (1<<15) /* integer divide check */
1173
@d H_BIT (1<<16) /* trip handler bit */
1174
@d F_BIT (1<<17) /* forced trap bit */
1175
@d E_BIT (1<<18) /* external (dynamic) trap bit */
1176
 
1177
@=
1178
char bit_code_map[]="EFHDVWIOUZXrwxnkbsp";
1179
 
1180
@ @=
1181
static void print_bits @,@,@[ARGS((int))@];
1182
 
1183
@ @=
1184
static void print_bits(x)
1185
  int x;
1186
{
1187
  register int b,j;
1188
  for (j=0,b=E_BIT;(x&(b+b-1))&&b;j++,b>>=1)
1189
    if (x&b) printf("%c",bit_code_map[j]);
1190
}
1191
 
1192
@ The lower half of rQ holds external interrupts of highest priority.
1193
Most of them are implementation-dependent, but a few are defined in general.
1194
 
1195
@
=
1196
#define POWER_FAILURE (1<<0) /* try to shut down calmly and quickly */
1197
#define PARITY_ERROR (1<<1) /* try to save the file systems */
1198
#define NONEXISTENT_MEMORY (1<<2) /* a memory address can't be used */
1199
#define REBOOT_SIGNAL (1<<4) /* it's time to start over */
1200
#define INTERVAL_TIMEOUT (1<<7) /* the timer register, rI, has reached zero */
1201
 
1202
@* Dynamic speculation.
1203
Now that we understand some basic low-level structures,
1204
we're ready to look at the larger picture.
1205
 
1206
This simulator is based on the idea of ``dynamic scheduling with register
1207
renaming,'' as introduced in the 1960s by R.~M. Tomasulo [{\sl IBM Journal
1208
@^Tomasulo, Robert Marco@>
1209
of Research and Development\/ \bf11} (1967), 25--33]. Moreover, the dynamic
1210
scheduling method is extended here to ``speculative execution,'' as
1211
implemented in several processors of the 1990s and described in section~4.6 of
1212
Hennessy and Patterson's {\sl Computer Architecture}, second edition (1995).
1213
@^Hennessy, John LeRoy@>
1214
@^Patterson, David Andrew@>
1215
The essential idea is to keep track of the pipeline contents by recording all
1216
dependencies between unfinished computations in a queue called the {\it
1217
reorder buffer}. An entry in the reorder buffer might, for example, correspond
1218
to an instruction that adds together two numbers whose values are still being
1219
computed; those numbers have been allocated space in earlier positions of the
1220
reorder buffer. The addition will take place as soon as both of its operands
1221
are known, but the sum won't be written immediately into the destination
1222
register. It will stay in the reorder buffer until reaching the {\it hot
1223
seat\/} at the front of the queue. Finally, the addition leaves the
1224
hot seat and is said to be {\it committed}.
1225
 
1226
Some instructions in the reorder buffer may in fact be executed only
1227
on speculation, meaning that they won't really be called for unless a prior
1228
branch instruction has the predicted outcome. Indeed, we can say that
1229
all instructions not yet in the hot seat are being executed speculatively,
1230
because an external interrupt might occur at any time and change the entire
1231
course of computation. Organizing the pipeline as a reorder buffer allows us
1232
to look ahead and keep busy computing values that have a good chance of being
1233
needed later, instead of waiting for slow instructions or slow memory
1234
references to be completed.
1235
 
1236
The reorder buffer is in fact a queue of \&{control} records, conceptually
1237
forming part of a circle of such records inside the simulator, corresponding
1238
to all instructions that have been dispatched or {\it issued\/} but not yet
1239
committed, in strict program order.
1240
 
1241
The best way to get an understanding of speculative execution is perhaps to
1242
imagine that the reorder buffer is large enough to hold hundreds of
1243
instructions in various stages of execution, and to think of an implementation
1244
of \MMIX\ that has dozens of functional units---more than would ever actually
1245
@^thinking big@>
1246
be built into a chip. Then one can readily visualize the kinds of control
1247
structures and checks that must be made to ensure correct execution. Without
1248
such a broad viewpoint, a programmer or hardware designer will be inclined to
1249
think only of the simple cases and to devise algorithms that lack the proper
1250
generality. Thus we have a somewhat paradoxical situation in which a difficult
1251
general problem turns out to be easier to solve than its simpler special cases,
1252
because it enforces clarity of thinking.
1253
 
1254
Instructions that have completed execution and have not yet been committed are
1255
analogous to cars that have gone through our hypothetical repair shop and are
1256
waiting for their owners to pick them up. However, all analogies break down,
1257
and the world of automobiles does not have a natural counterpart for the
1258
notion of speculative execution. That notion corresponds roughly to situations
1259
in which people are led to believe that their cars need a new piece of
1260
equipment, but they suddenly change their mind once they see the price tag,
1261
and they insist on having the equipment removed even after it has been
1262
partially or completely installed.
1263
 
1264
Speculatively executed instructions might make no sense: They might divide
1265
by zero or refer to protected memory areas, etc. Such anomalies are not
1266
considered catastrophic or even exceptional until the instruction reaches the
1267
hot~seat.
1268
 
1269
The person who designs a computer with speculative execution is an optimist,
1270
who has faith that the vast majority of the machine's predictions will come
1271
true. The person who designs a reliable implementation of such a computer
1272
is a pessimist, who understands that all predictions might come to naught.
1273
The pessimist does, however, take pains to optimize the cases that do turn out
1274
well.
1275
 
1276
@ Let's consider what happens to a single instruction, say
1277
\.{ADD} \.{\$1,\$2,\$3}, as it travels through the pipeline in a normal
1278
situation. The first time this instruction is encountered, it is placed into
1279
the I-cache (that is, the instruction cache), so that we won't have to access
1280
memory when we need to perform it again. We will assume for simplicity in this
1281
discussion that each I-cache access takes one clock cycle, although other
1282
possibilities are allowed by |MMIX_config|.
1283
 
1284
Suppose the simulated machine fetches the example \.{ADD} instruction
1285
at time 1000. Fetching is done by a coroutine whose |stage| number is~0.
1286
A cache block typically contains 8 or 16 instructions. The fetch unit
1287
of our machine is able to fetch up to |fetch_max| instructions on each clock
1288
cycle and place them in the fetch buffer, provided that there is room in the
1289
buffer and that all the instructions belong to the same cache block.
1290
 
1291
The dispatch unit of our simulator is able to issue up to |dispatch_max|
1292
instructions on each clock cycle and move them from the fetch buffer to the
1293
reorder buffer, provided that functional units are available for those
1294
instructions and there is room in the reorder buffer. A functional unit that
1295
handles \.{ADD} is usually called an ALU (arithmetic logic unit), and our
1296
simulated machine might have several of them. If they aren't all stalled
1297
in stage~1 of their pipelines, and if the reorder buffer isn't full, and if
1298
the machine isn't in the process of deissuing instructions that were
1299
mispredicted, and if
1300
fewer than |dispatch_max| instructions are ahead of the \.{ADD} in the fetch
1301
buffer, and if all such prior instructions can be issued without using up all
1302
the free ALUs, our \.{ADD} instruction will be issued at time 1001.
1303
(In fact, all of these conditions are usually true.)
1304
 
1305
We assume that $\rm L>3$, so that \$1, \$2, and~\$3 are local registers.
1306
For simplicity we'll assume in fact that the register stack is empty, so that
1307
the \.{ADD} instruction is supposed to set $\rm l[1]\gets l[2]+l[3]$. The
1308
operands l[2] and~l[3] might not be known at time 1001; they are \&{spec}
1309
values, which might point to \&{specnode} entries in the reorder buffer for
1310
previous instructions whose destinations are l[2] and~l[3].
1311
The dispatcher fills the next available control block of the reorder buffer
1312
with information for the \.{ADD}, containing appropriate \&{spec} values
1313
corresponding to l[2] and~l[3] in its |y| and~|z| fields. The |x|~field of
1314
this control block will be inserted into a doubly linked list of \&{specnode}
1315
records, corresponding to l[1] and to all instructions in the reorder buffer
1316
that have l[1] as a destination. The boolean value |x.known| will be set to
1317
|false|, meaning that this speculative value still needs to be
1318
computed. Subsequent instructions that need l[1] as a source will point to
1319
|x|, if they are issued before the sum |x.o| has been computed. Double
1320
linking is used in the \&{specnode} list because the \.{ADD} instruction might
1321
be cancelled before it is finally committed; thus deletions might occur
1322
at either end of the list for~l[1].
1323
 
1324
At time 1002, the ALU handling the \.{ADD} will stall if its inputs |y|
1325
and~|z| are not both known (namely if |y.p!=NULL| or |z.p!=NULL|).
1326
In fact, it will also stall if its third input rA is not known;
1327
the current speculative value of rA, except for its event bits,
1328
is represented in the |ra|~field of the control block, and we must
1329
have |ra.p==NULL|. In such a case the ALU will look to see if the
1330
\&{spec} values pointed to by |y.p| and/or |z.p| and/or |ra.p| become
1331
defined on this clock cycle, and it will update its own input values
1332
accordingly.
1333
 
1334
But let's assume that |y|, |z|, and |ra| are already known at time 1002.
1335
Then |x.o| will be set to |y.o+z.o| and |x.known| will become~|true|.
1336
This will make the result destined for~l[1] available to be used in other
1337
commands at time~1003.
1338
 
1339
If no overflow occurs when adding |y.o| to |z.o|, the |interrupt| and
1340
|arith_exc| fields of the control block for \.{ADD} are set to zero.  But when
1341
overflow does occur (shudder), there are two cases, based on the V-enable bit
1342
of rA, which is found in field |b.o| of the control block. If this bit is~0,
1343
the V-bit of the |arith_exc| field in the control block is set to~1; the
1344
|arith_exc| field will be ored into~rA when the \.{ADD} instruction is
1345
eventually committed.  But if the V-enable bit is~1, the trip handler should
1346
be called, interrupting the normal sequence. In such a case, the |interrupt|
1347
field of the control block is set to specify a trip, and the fetcher and
1348
dispatcher are told to forget what they have been doing; all instructions
1349
following the \.{ADD} in the reorder buffer must now be deissued. The virtual starting
1350
address of the overflow trip handler, namely location~32, is hastily passed to
1351
the fetch routine, and instructions will be fetched from that location
1352
as soon as possible. (Of course the overflow and the trip handler are
1353
still speculative until the \.{ADD} instruction is committed. Other exceptional
1354
conditions might cause the \.{ADD} itself to be terminated before it
1355
gets to the hot seat. But the pipeline keeps charging ahead, always trying to
1356
guess the most probable outcome.)
1357
 
1358
The commission unit of this simulator is able to commit and/or deissue up to
1359
|commit_max| instructions on each clock cycle. With luck, fewer than
1360
|commit_max| instructions will be ahead of our \.{ADD} instruction at
1361
time~1003, and they will all be completed normally. Then l[1]~can be set
1362
to |x.o|, and the event bits of~rA can be updated from |arith_exc|,
1363
and the \.{ADD} command can pass through the hot seat and out of the
1364
reorder buffer.
1365
 
1366
@=
1367
Extern int fetch_max, dispatch_max, peekahead, commit_max;
1368
 /* limits on instructions that can be handled per clock cycle */
1369
 
1370
@ The instruction currently occupying the hot seat is the only
1371
issued-but-not-yet-committed instruction that is guaranteed to be truly
1372
essential to the machine's computation. All other instructions in the reorder
1373
buffer are being executed on speculation; if they prove to be needed, well and
1374
good, but we might want to jettison them all if, say, an external interrupt
1375
occurs.
1376
 
1377
Thus all instructions that change the global state in complicated ways---like
1378
\.{LDVTS}, which changes the virtual address translation caches---are
1379
performed only when they reach the hot seat. Fortunately the vast majority
1380
of instructions are sufficiently simple that we can deal with them more
1381
efficiently while other computations are taking place.
1382
 
1383
In this implementation the reorder buffer is simply housed in an array of
1384
control records. The first array element is |reorder_bot|, and the last is
1385
|reorder_top|. Variable |hot| points to the control block in the hot seat, and
1386
|hot-1| to its predecessor, etc. Variable |cool| points to the next control
1387
block that will be filled in the reorder buffer. If |hot==cool| the reorder
1388
buffer is empty; otherwise it contains the control records |hot|, |hot-1|,
1389
\dots,~|cool+1|, except of course that we wrap around from |reorder_bot| to
1390
|reorder_top| when moving down in the buffer.
1391
 
1392
@=
1393
Extern control *reorder_bot, *reorder_top; /* least and greatest
1394
                   entries in the ring containing the reorder buffer */
1395
Extern control *hot, *cool; /* front and rear of the reorder buffer */
1396
Extern control *old_hot; /* value of |hot| at beginning of cycle */
1397
Extern int deissues; /* the number of instructions that need to be deissued */
1398
 
1399
@ @=
1400
hot=cool=reorder_top;
1401
deissues=0;
1402
 
1403
@ @=
1404
static void print_reorder_buffer @,@,@[ARGS((void))@];
1405
 
1406
@ @=
1407
static void print_reorder_buffer()
1408
{
1409
  printf("Reorder buffer");
1410
  if (hot==cool) printf(" (empty)\n");
1411
  else {@+register control *p;
1412
    if (deissues) printf(" (%d to be deissued)",deissues);
1413
    if (doing_interrupt) printf(" (interrupt state %d)",doing_interrupt);
1414
    printf(":\n");
1415
    for (p=hot;p!=cool; p=(p==reorder_bot? reorder_top: p-1)) {
1416
      print_control_block(p);
1417
      if (p->owner) {
1418
        printf(" ");@+ print_coroutine_id(p->owner);
1419
      }
1420
      printf("\n");
1421
    }
1422
  }
1423
  printf(" %d available rename register%s, %d memory slot%s\n",
1424
     rename_regs, rename_regs!=1? "s": "",
1425
     mem_slots, mem_slots!=1? "s": "");
1426
}
1427
 
1428
@ Here is an overview of what happens on each clock cycle.
1429
 
1430
@=
1431
{
1432
  @;
1433
  dispatch_count=0;
1434
  old_hot=hot; /* remember the hot seat position at beginning of cycle */
1435
  old_tail=tail; /* remember the fetch buffer contents at beginning of cycle */
1436
  suppress_dispatch=(deissues || dispatch_lock);
1437
  if (doing_interrupt) @@;
1438
  else @;
1439
  @;
1440
  if (!suppress_dispatch) @;
1441
  ticks=incr(ticks,1); /* and the beat moves on */
1442
  dispatch_stat[dispatch_count]++;
1443
}
1444
 
1445
@ @=
1446
int dispatch_count; /* how many dispatched on this cycle */
1447
bool suppress_dispatch; /* should dispatching be bypassed? */
1448
int doing_interrupt; /* how many cycles of interrupt preparations remain */
1449
lockvar dispatch_lock; /* lock to prevent instruction issues */
1450
 
1451
@ @=
1452
Extern int *dispatch_stat;
1453
  /* how often did we dispatch 0, 1, ... instructions? */
1454
Extern bool security_disabled; /* omit security checks for testing purposes? */
1455
 
1456
@ @=
1457
{
1458
  for (m=commit_max;m>0 && deissues>0; m--)
1459
    @;
1460
  for (;m>0;m--) {
1461
    if (hot==cool) break; /* reorder buffer is empty */
1462
    if (!security_disabled) @;
1463
    if (hot->owner) break; /* hot seat instruction isn't finished */
1464
    @;
1465
    i=hot->i;
1466
    if (hot==reorder_bot) hot=reorder_top;
1467
    else hot--;
1468
    if (i==resum) break; /* allow the resumed instruction to see the new rK */
1469
  }
1470
}
1471
 
1472
@* The dispatch stage. It would be nice to present the parts of this simulator
1473
by dealing with the fetching, dispatching, executing, and committing
1474
stages in that order. After all, instructions are first fetched,
1475
then dispatched, then executed, and finally committed.
1476
However, the fetch stage depends heavily on difficult questions of
1477
memory management that are best deferred until we have looked at
1478
the simpler parts of simulation. Therefore we will take our initial
1479
plunge into the details of this program by looking first at the dispatch phase,
1480
assuming that instructions have somehow appeared magically in the fetch buffer.
1481
 
1482
The fetch buffer, like the circular priority queue of all coroutines
1483
and the circular queue used for the reorder buffer, lives in an
1484
array that is best regarded as a ring of elements. The elements
1485
are structures of type \&{fetch}, which have five fields:
1486
A 32-bit |inst|, which is an \MMIX\ instruction; a 64-bit |loc|,
1487
which is the virtual address of that instruction; an |interrupt| field,
1488
which is nonzero if, for example, the protection bits in the relevant page
1489
table entry for this address do not permit execution access; a boolean
1490
|noted| field, which becomes |true| after the dispatch unit has peeked
1491
at the instruction to see whether it is a jump or probable branch;
1492
and a |hist| field, which records the recent branch history.
1493
(The least significant bits of~|hist| correspond to the most recent branches.)
1494
 
1495
@=
1496
typedef struct {
1497
  octa loc; /* virtual address of instruction */
1498
  tetra inst; /* the instruction itself */
1499
  unsigned int interrupt; /* bit codes that might cause interruption */
1500
  bool noted; /* have we peeked at this instruction? */
1501
  unsigned int hist; /* if we peeked, this was the |peek_hist| */
1502
} fetch;
1503
 
1504
@ The oldest and youngest entries in the fetch buffer are pointed
1505
to by |head| and |tail|, just as the oldest and youngest entries in the
1506
reorder buffer are called |hot| and |cool|. The fetch coroutine will
1507
be adding entries at the |tail| position, which starts at |old_tail|
1508
when a cycle begins, in parallel with the actions simulated by
1509
the dispatcher. Therefore the dispatcher is allowed to look only at
1510
instructions in |head|, |head-1|, \dots,~|old_tail+1|, although a few
1511
more recently fetched instructions will usually be present in the fetch
1512
buffer by the time this part of the program is executed.
1513
 
1514
@=
1515
Extern fetch *fetch_bot, *fetch_top; /* least and greatest
1516
                   entries in the ring containing the fetch buffer */
1517
Extern fetch *head, *tail; /* front and rear of the fetch buffer */
1518
 
1519
@ @=
1520
fetch *old_tail; /* rear of the fetch buffer available on the current cycle */
1521
 
1522
@ @d UNKNOWN_SPEC ((specnode*)1)
1523
 
1524
@=
1525
head=tail=fetch_top;
1526
inst_ptr.p=UNKNOWN_SPEC;
1527
 
1528
@ @=
1529
static void print_fetch_buffer @,@,@[ARGS((void))@];
1530
 
1531
@ @=
1532
static void print_fetch_buffer()
1533
{
1534
  printf("Fetch buffer");
1535
  if (head==tail) printf(" (empty)\n");
1536
  else {@+register fetch *p;
1537
    if (resuming) printf(" (resumption state %d)",resuming);
1538
    printf(":\n");
1539
    for (p=head;p!=tail; p=(p==fetch_bot? fetch_top: p-1)) {
1540
      print_octa(p->loc);
1541
      printf(": %08x(%s)",p->inst,opcode_name[p->inst>>24]);
1542
      if (p->interrupt) print_bits(p->interrupt);
1543
      if (p->noted) printf("*");
1544
      printf("\n");
1545
    }
1546
  }
1547
  printf("Instruction pointer is ");
1548
  if (inst_ptr.p==NULL) print_octa(inst_ptr.o);
1549
  else {
1550
    printf("waiting for ");
1551
    if (inst_ptr.p==UNKNOWN_SPEC) printf("dispatch");
1552
    else if (inst_ptr.p->addr.h==(tetra)-1)
1553
      print_coroutine_id(((control*)inst_ptr.p->up)->owner);
1554
    else print_specnode_id(inst_ptr.p->addr);
1555
  }
1556
  printf("\n");
1557
}
1558
 
1559
@ The best way to understand the dispatching process is once again
1560
to ``think big,'' by imagining a huge fetch buffer and the
1561
@^thinking big@>
1562
potential ability to issue dozens of instructions per cycle, although
1563
the actual numbers are typically quite small.
1564
 
1565
If the fetch buffer is not empty after |dispatch_max| instructions have
1566
been dispatched, the dispatcher also looks at up to |peekahead| further
1567
instructions to see if they are jumps or other commands that change the
1568
flow of control. Much of this action would happen in parallel on a
1569
real machine, but our simulator works sequentially.
1570
 
1571
In the following program, |true_head| records the head of the fetch buffer as
1572
instructions are actually dispatched, while |head| refers to the position
1573
currently being examined (possibly peeking into the future).
1574
 
1575
If the fetch buffer is empty at the beginning of the current clock
1576
cycle, a ``dispatch bypass'' allows the dispatcher to issue the
1577
first instruction that enters the fetch buffer on this cycle. Otherwise
1578
the dispatcher is restricted to previously fetched instructions.
1579
 
1580
@s func int
1581
 
1582
@=
1583
{@+register fetch *true_head, *new_head;
1584
  true_head=head;
1585
  if (head==old_tail && head!=tail)
1586
    old_tail=(head==fetch_bot? fetch_top: head-1);
1587
  peek_hist=cool_hist;
1588
  for (j=0;j
1589
    @
1590
              to dispatch it if |j;
1591
  head=true_head;
1592
}
1593
 
1594
@ @=
1595
{
1596
  register mmix_opcode op;
1597
  register int yz,f;
1598
  register bool freeze_dispatch=false;
1599
  register func *u=NULL;
1600
  if (head==old_tail) break; /* fetch buffer empty */
1601
  if (head==fetch_bot) new_head=fetch_top;@+else new_head=head-1;
1602
  op=head->inst>>24; @+yz=head->inst&0xffff;
1603
  @;
1604
  @;
1605
  if (f&rel_addr_bit) @;
1606
  if (head->noted) peek_hist=head->hist;
1607
  else @;
1608
  if (j>=dispatch_max || dispatch_lock || nullifying) {
1609
    head=new_head;@+ continue; /* can't dispatch, but can peek ahead */
1610
  }
1611
  if (cool==reorder_bot) new_cool=reorder_top;@+else new_cool=cool-1;
1612
  @
1613
    otherwise |goto stall|@>;
1614
  @;
1615
  @;
1616
  if ((op&0xe0)==0x40) @;
1617
  @;
1618
  cool=new_cool;@+ cool_O=new_O;@+ cool_S=new_S;
1619
  cool_hist=peek_hist;@+ continue;
1620
stall: @
1621
    and |break|@>;
1622
}
1623
 
1624
@ An instruction can be dispatched only if a functional unit
1625
is available to handle it. A functional unit consists of a 256-bit
1626
vector that specifies a subset of \MMIX's opcodes, and an array
1627
of coroutines for the pipeline stages. There are $k$ coroutines in the
1628
array, where $k$ is the maximum number of stages needed by any of the opcodes
1629
supported.
1630
 
1631
@=
1632
typedef struct func_struct{
1633
  char name[16]; /* symbolic designation */
1634
  tetra ops[8]; /* big-endian bitmap for the opcodes supported */
1635
  int k; /* number of pipeline stages */
1636
  coroutine *co; /* pointer to the first of $k$ consecutive coroutines */
1637
} @!func;
1638
 
1639
@ @=
1640
Extern func *funit; /* pointer to array of functional units */
1641
Extern int funit_count; /* the number of functional units */
1642
 
1643
@ It is convenient to have
1644
a 256-bit vector of all the supported opcodes, because we need to
1645
shut off a lot of special actions when an opcode is not supported.
1646
 
1647
@=
1648
control *new_cool; /* the reorder position following |cool| */
1649
int resuming; /* set nonzero if resuming an interrupted instruction */
1650
tetra support[8]; /* big-endian bitmap for all opcodes supported */
1651
 
1652
@ @=
1653
{@+register func *u;
1654
  for (u=funit;u<=funit+funit_count;u++)
1655
    for (i=0;i<8;i++) support[i] |= u->ops[i];
1656
}
1657
 
1658
@ @d sign_bit ((unsigned)0x80000000)
1659
 
1660
@=
1661
if (!(support[op>>5]&(sign_bit>>(op&31)))) {
1662
  /* oops, this opcode isn't supported by any function unit */
1663
  f=flags[TRAP], i=trap;
1664
}@+else f=flags[op], i=internal_op[op];
1665
if (i==trip && (head->loc.h&sign_bit)) f=0,i=noop;
1666
 
1667
@ @=
1668
if (cool->interim) {
1669
  cool->usage=false;
1670
  if (cool->op==SAVE) @@;
1671
  else if (cool->op==UNSAVE) @@;
1672
  else if (cool->i==preld || cool->i==prest)
1673
     @@;
1674
  else if (cool->i==prego) @@;
1675
}
1676
else if (cool->i<=max_real_command) {
1677
  if ((flags[cool->op]&ctl_change_bit)||cool->i==pbr)
1678
    if (inst_ptr.p==NULL && (inst_ptr.o.h&sign_bit) && !(cool->loc.h&sign_bit)
1679
           && cool->i!=trap)
1680
      cool->interrupt|=P_BIT; /* jumping from nonnegative to negative */
1681
  true_head=head=new_head; /* delete instruction from fetch buffer */
1682
  resuming=0;
1683
}
1684
if (freeze_dispatch) set_lock(u->co,dispatch_lock);
1685
cool->owner=u->co;@+ u->co->ctl=cool;
1686
startup(u->co,1); /* schedule execution of the new inst */
1687
if (verbose&issue_bit) {
1688
  printf("Issuing ");@+print_control_block(cool);
1689
  printf(" ");@+print_coroutine_id(u->co);@+printf("\n");
1690
}
1691
dispatch_count++;
1692
 
1693
@ We assign the first functional unit that supports |op| and is
1694
totally unoccupied, if possible; otherwise we assign the first
1695
functional unit that supports |op| and has stage~1 unoccupied.
1696
 
1697
@=
1698
{@+register int t=op>>5, b=sign_bit>>(op&31);
1699
  if (cool->i==trap && op!=TRAP) { /* opcode needs to be emulated */
1700
    u=funit+funit_count; /* this unit supports just \.{TRIP} and \.{TRAP} */
1701
    goto unit_found;
1702
  }
1703
  for (u=funit;u<=funit+funit_count;u++) if (u->ops[t]&b) {
1704
    for (i=0;ik;i++) if (u->co[i].next) goto unit_busy;
1705
    goto unit_found;
1706
  unit_busy: ;
1707
  }
1708
  for (u=funit;u
1709
    if ((u->ops[t]&b) && (u->co->next==NULL)) goto unit_found;
1710
  goto stall; /* all units for this |op| are busy */
1711
}
1712
unit_found:
1713
 
1714
@ The |flags| table records special properties of each operation code
1715
in binary notation: \Hex{1}~means Z~is an immediate value, \Hex{2}~means rZ is
1716
a source operand, \Hex{4}~means Y~is an immediate value, \Hex{8}~means rY is a
1717
source operand, \Hex{10}~means rX is a source operand, \Hex{20}~means
1718
rX is a destination, \Hex{40}~means YZ is part of a relative address,
1719
\Hex{80}~means the control changes at this point.
1720
 
1721
@d X_is_dest_bit 0x20
1722
@d rel_addr_bit 0x40
1723
@d ctl_change_bit 0x80
1724
 
1725
@=
1726
unsigned char flags[256]={
1727
0x8a, 0x2a, 0x2a, 0x2a, 0x2a, 0x26, 0x2a, 0x26, /* \.{TRAP}, \dots\ */
1728
0x26, 0x25, 0x26, 0x25, 0x26, 0x25, 0x26, 0x25, /* \.{FLOT}, \dots\ */
1729
0x2a, 0x2a, 0x2a, 0x2a, 0x2a, 0x26, 0x2a, 0x26, /* \.{FMUL}, \dots\ */
1730
0x2a, 0x29, 0x2a, 0x29, 0x2a, 0x29, 0x2a, 0x29, /* \.{MUL}, \dots\ */
1731
0x2a, 0x29, 0x2a, 0x29, 0x2a, 0x29, 0x2a, 0x29, /* \.{ADD}, \dots\ */
1732
0x2a, 0x29, 0x2a, 0x29, 0x2a, 0x29, 0x2a, 0x29, /* \.{2ADDU}, \dots\ */
1733
0x2a, 0x29, 0x2a, 0x29, 0x26, 0x25, 0x26, 0x25, /* \.{CMP}, \dots\ */
1734
0x2a, 0x29, 0x2a, 0x29, 0x2a, 0x29, 0x2a, 0x29, /* \.{SL}, \dots\ */
1735
0x50, 0x50, 0x50, 0x50, 0x50, 0x50, 0x50, 0x50, /* \.{BN}, \dots\ */
1736
0x50, 0x50, 0x50, 0x50, 0x50, 0x50, 0x50, 0x50, /* \.{BNN}, \dots\ */
1737
0x50, 0x50, 0x50, 0x50, 0x50, 0x50, 0x50, 0x50, /* \.{PBN}, \dots\ */
1738
0x50, 0x50, 0x50, 0x50, 0x50, 0x50, 0x50, 0x50, /* \.{PBNN}, \dots\ */
1739
0x3a, 0x39, 0x3a, 0x39, 0x3a, 0x39, 0x3a, 0x39, /* \.{CSN}, \dots\ */
1740
0x3a, 0x39, 0x3a, 0x39, 0x3a, 0x39, 0x3a, 0x39, /* \.{CSNN}, \dots\ */
1741
0x2a, 0x29, 0x2a, 0x29, 0x2a, 0x29, 0x2a, 0x29, /* \.{ZSN}, \dots\ */
1742
0x2a, 0x29, 0x2a, 0x29, 0x2a, 0x29, 0x2a, 0x29, /* \.{ZSNN}, \dots\ */
1743
0x2a, 0x29, 0x2a, 0x29, 0x2a, 0x29, 0x2a, 0x29, /* \.{LDB}, \dots\ */
1744
0x2a, 0x29, 0x2a, 0x29, 0x2a, 0x29, 0x2a, 0x29, /* \.{LDT}, \dots\ */
1745
0x2a, 0x29, 0x2a, 0x29, 0x1a, 0x19, 0x2a, 0x29, /* \.{LDSF}, \dots\ */
1746
0x2a, 0x29, 0x0a, 0x09, 0x0a, 0x09, 0xaa, 0xa9, /* \.{LDVTS}, \dots\ */
1747
0x1a, 0x19, 0x1a, 0x19, 0x1a, 0x19, 0x1a, 0x19, /* \.{STB}, \dots\ */
1748
0x1a, 0x19, 0x1a, 0x19, 0x1a, 0x19, 0x1a, 0x19, /* \.{STT}, \dots\ */
1749
0x1a, 0x19, 0x1a, 0x19, 0x0a, 0x09, 0x1a, 0x19, /* \.{STSF}, \dots\ */
1750
0x0a, 0x09, 0x0a, 0x09, 0x0a, 0x09, 0xaa, 0xa9, /* \.{SYNCD}, \dots\ */
1751
0x2a, 0x29, 0x2a, 0x29, 0x2a, 0x29, 0x2a, 0x29, /* \.{OR}, \dots\ */
1752
0x2a, 0x29, 0x2a, 0x29, 0x2a, 0x29, 0x2a, 0x29, /* \.{AND}, \dots\ */
1753
0x2a, 0x29, 0x2a, 0x29, 0x2a, 0x29, 0x2a, 0x29, /* \.{BDIF}, \dots\ */
1754
0x2a, 0x29, 0x2a, 0x29, 0x2a, 0x29, 0x2a, 0x29, /* \.{MUX}, \dots\ */
1755
0x20, 0x20, 0x20, 0x20, 0x30, 0x30, 0x30, 0x30, /* \.{SETH}, \dots\ */
1756
0x30, 0x30, 0x30, 0x30, 0x30, 0x30, 0x30, 0x30, /* \.{ORH}, \dots\ */
1757
0xc0, 0xc0, 0xe0, 0xe0, 0x60, 0x60, 0x02, 0x01, /* \.{JMP}, \dots\ */
1758
0x80, 0x80, 0x00, 0x02, 0x01, 0x00, 0x20, 0x8a}; /* \.{POP}, \dots\ */
1759
 
1760
@ @=
1761
{
1762
  if (i==jmp) yz=head->inst&0xffffff;
1763
  if (op&1) yz-=(i==jmp? 0x1000000: 0x10000);
1764
  cool->y.o=incr(head->loc,4), cool->y.p=NULL;
1765
  cool->z.o=incr(head->loc,yz<<2), cool->z.p=NULL;
1766
}
1767
 
1768
@ The location of the next instruction to be fetched is in a \&{spec} variable
1769
called |inst_ptr|. A slightly tricky optimization of the \.{POP} instruction
1770
is made in the common case that the speculative value of~rJ is known.
1771
 
1772
@=
1773
{@+register int predicted=0;
1774
  if ((op&0xe0)==0x40) @;
1775
  head->noted=true;
1776
  head->hist=peek_hist;
1777
  if (predicted||(f&ctl_change_bit) || (i==syncid&&!(cool->loc.h&sign_bit))) {
1778
    old_tail=tail=new_head; /* discard all remaining fetches */
1779
    @;
1780
    switch (i) {
1781
 case jmp: case br: case pbr: case pushj: inst_ptr=cool->z;@+ break;
1782
 case pop:@+if (g[rJ].up->known &&
1783
          j
1784
      inst_ptr.o=incr(g[rJ].up->o,yz<<2), inst_ptr.p=NULL;@+break;
1785
      } /* otherwise fall through, will wait on |cool->go| */
1786
 case go: case pushgo: case trap: case resume: case syncid:
1787
    inst_ptr.p=UNKNOWN_SPEC;@+ break;
1788
 case trip: inst_ptr=zero_spec;@+ break;
1789
    }
1790
  }
1791
}
1792
 
1793
@ At any given time the simulated machine is in two main states, the
1794
``hot state'' corresponding to instructions that have been committed and the
1795
``cool state'' corresponding to all the speculative changes currently
1796
being considered. The dispatcher works with cool instructions and puts them
1797
into the reorder buffer, where they gradually get warmer and warmer.
1798
Intermediate instructions, between |hot| and |cool|, have intermediate
1799
temperatures.
1800
 
1801
A machine register like l[101] or g[250] is represented by a specnode whose
1802
|o|~field is the current hot value of the register. If the |up| and |down|
1803
fields of this specnode point to the node itself,
1804
the hot and cool values of the register are
1805
identical. Otherwise |up| and |down| are pointers to the coolest and hottest
1806
ends of a doubly linked list of specnodes, representing intermediate
1807
speculative values (sometimes called ``rename registers'').
1808
@^rename registers@>
1809
The rename registers are implemented as the |x| or~|a| specnodes inside control
1810
blocks, for speculative instructions that use this register as a
1811
destination. Speculative instructions that use the register as a
1812
source operand point to the next-hottest specnode on the list, until
1813
the value becomes known. The doubly linked list of specnodes is an
1814
input-restricted deque: A node is inserted at the cool end when the
1815
dispatcher issues an instruction with this register as destination;
1816
a node is removed from the cool end if an instruction needs to be deissued;
1817
a node is removed from the hot end when an instruction is committed.
1818
 
1819
The special registers rA, rB, \dots\ occupy the same array as the
1820
global registers g[32], g[33], \dots~\thinspace. For example,
1821
rB is internally the same as g[0], because |rB=0|.
1822
 
1823
@=
1824
Extern specnode g[256]; /* global registers and special registers */
1825
Extern specnode *l; /* the ring of local registers */
1826
Extern int lring_size; /* the number of on-chip local registers
1827
         (must be a power of~2) */
1828
Extern int max_rename_regs, max_mem_slots; /* capacity of reorder buffer */
1829
Extern int rename_regs, mem_slots; /* currently unused capacity */
1830
 
1831
@ @
=
1832
#define ticks @[g[rC].o@] /* the internal clock */
1833
 
1834
@ @=
1835
int lring_mask; /* for calculations modulo |lring_size| */
1836
 
1837
@ The |addr| fields in the specnode lists for registers are used
1838
to identify that register in diagnostic messages. Such addresses
1839
are negative; memory addresses are positive.
1840
 
1841
All registers are initially zero except rG, which is initially 255,
1842
and rN, which has a constant value identifying the time of compilation.
1843
(The macro \.{ABSTIME} is defined externally in the file \.{abstime.h},
1844
which should have just been created by {\mc ABSTIME}\kern.05em;
1845
{\mc ABSTIME} is
1846
a trivial program that computes the value of the standard library function
1847
|time(NULL)|. We assume that this number, which is the number of seconds in
1848
the ``{\mc UNIX} epoch,'' is less than~$2^{32}$. Beware: Our assumption will
1849
fail in February of 2106.)
1850
@^system dependencies@>
1851
 
1852
@d VERSION 1 /* version of the \MMIX\ architecture that we support */
1853
@d SUBVERSION 0 /* secondary byte of version number */
1854
@d SUBSUBVERSION 0 /* further qualification to version number */
1855
 
1856
@=
1857
rename_regs=max_rename_regs;
1858
mem_slots=max_mem_slots;
1859
lring_mask=lring_size-1;
1860
for (j=0;j<256;j++) {
1861
  g[j].addr.h=sign_bit, g[j].addr.l=j, g[j].known=true;
1862
  g[j].up=g[j].down=&g[j];
1863
}
1864
g[rG].o.l=255;
1865
g[rN].o.h=(VERSION<<24)+(SUBVERSION<<16)+(SUBSUBVERSION<<8);
1866
g[rN].o.l=ABSTIME; /* see comment and warning above */
1867
for (j=0;j
1868
  l[j].addr.h=sign_bit, l[j].addr.l=256+j, l[j].known=true;
1869
  l[j].up=l[j].down=&l[j];
1870
}
1871
 
1872
@ @=
1873
static void print_specnode_id @,@,@[ARGS((octa))@];
1874
 
1875
@ @=
1876
static void print_specnode_id(a)
1877
  octa a;
1878
{
1879
  if (a.h==sign_bit) {
1880
    if (a.l<32) printf(special_name[a.l]);
1881
    else if (a.l<256) printf("g[%d]",a.l);
1882
    else printf("l[%d]",a.l-256);
1883
  }@+else if (a.h!=(tetra)-1) {
1884
    printf("m[");@+print_octa(a);@+printf("]");
1885
  }
1886
}
1887
 
1888
@ The |specval| subroutine produces a \&{spec} corresponding to the
1889
currently coolest value of a given local or global register.
1890
 
1891
@=
1892
static spec specval @,@,@[ARGS((specnode*))@];
1893
 
1894
@ @=
1895
static spec specval(r)
1896
  specnode *r;
1897
{@+spec res;
1898
  if (r->up->known) res.o=r->up->o,res.p=NULL;
1899
  else res.p=r->up;
1900
  return res;
1901
}
1902
 
1903
@ The |spec_install| subroutine introduces a new speculative value at
1904
the cool end of a given doubly linked~list.
1905
 
1906
@=
1907
static void spec_install @,@,@[ARGS((specnode*,specnode*))@];
1908
 
1909
@ @=
1910
static void spec_install(r,t) /* insert |t| into list |r| */
1911
  specnode *r,*t;
1912
{
1913
  t->up=r->up;
1914
  t->up->down=t;
1915
  r->up=t;
1916
  t->down=r;
1917
  t->addr=r->addr;
1918
}
1919
 
1920
@ Conversely, |spec_rem| takes such a value out.
1921
 
1922
@=
1923
static void spec_rem @,@,@[ARGS((specnode*))@];
1924
 
1925
@ @=
1926
static void spec_rem(t) /* remove |t| from its list */
1927
  specnode *t;
1928
{@+register specnode *u=t->up, *d=t->down;
1929
  u->down=d;@+ d->up=u;
1930
}
1931
 
1932
@ Some special registers are so central to \MMIX's operation, they are
1933
carried along with each control block in the reorder buffer instead of being
1934
treated as source and destination registers of each instruction. For example,
1935
the register stack pointers rO and~rS are treated in this way.
1936
The normal specnodes for rO and~rS, namely |g[rO]| and~|g[rS]|,
1937
are not actually used;
1938
the cool values are called |cool_O| and |cool_S|.
1939
(Actually |cool_O| and |cool_S| correspond to the register
1940
values divided by~8, since rO and~rS are always multiples of~8.)
1941
 
1942
The arithmetic status register, rA, is also treated specially. Its
1943
event bits are kept up to date only at the ``hot'' end, by accumulating
1944
values of |arith_exc|; an instruction
1945
to \.{GET} the value of~rA will be executed only in the hot seat.
1946
The other bits of~rA, which are needed to control trip handlers and
1947
floating point rounding, are treated in the normal way.
1948
 
1949
@=
1950
Extern octa cool_O,cool_S; /* values of rO, rS before the |cool| instruction */
1951
 
1952
@ @=
1953
int cool_L,cool_G; /* values of rL and rG before the |cool| instruction */
1954
unsigned int cool_hist,peek_hist; /* history bits for branch prediction */
1955
octa new_O,new_S; /* values of rO, rS after |cool| */
1956
 
1957
@ @=
1958
cool->op=op; @+cool->i=i;
1959
cool->xx=(head->inst>>16)&0xff;@+
1960
cool->yy=(head->inst>>8)&0xff;@+
1961
cool->zz=(head->inst)&0xff;
1962
cool->loc=head->loc;
1963
cool->y=cool->z=cool->b=cool->ra=zero_spec;
1964
cool->x.o=cool->a.o=cool->rl.o=zero_octa;
1965
cool->x.known=false; cool->x.up=NULL;
1966
cool->a.known=false; cool->a.up=NULL;
1967
cool->rl.known=true; cool->rl.up=NULL;
1968
cool->need_b=cool->need_ra=
1969
  cool->ren_x=cool->mem_x=cool->ren_a=cool->set_l=false;
1970
cool->arith_exc=cool->denin=cool->denout=0;
1971
if ((head->loc.h&sign_bit) && !(g[rU].o.h&0x8000)) cool->usage=false;
1972
else cool->usage=((op&(g[rU].o.h>>16))==g[rU].o.h>>24? true: false);
1973
new_O=cool->cur_O=cool_O;@+ new_S=cool->cur_S=cool_S;
1974
cool->interrupt=head->interrupt;
1975
cool->hist=peek_hist;
1976
cool->go.o=incr(cool->loc,4);
1977
cool->go.known=false, cool->go.addr.h=-1,cool->go.up=(specnode*)cool;
1978
cool->interim=false;
1979
 
1980
@ @=
1981
if (new_cool==hot) goto stall; /* reorder buffer is full */
1982
@;
1983
@;
1984
if (f&X_is_dest_bit) @
1985
  an internal command and |goto dispatch_done| if X is marginal@>;
1986
switch (i) {
1987
@@;
1988
default: break;
1989
}
1990
dispatch_done:@;
1991
 
1992
@ The \.{UNSAVE} operation begins by loading register~rG from memory.
1993
We don't really need to know the value of~rG until twelve other registers
1994
have been unsaved, so we aren't fussy about it here.
1995
 
1996
@=
1997
if (!g[rL].up->known) goto stall;
1998
cool_L=g[rL].up->o.l;
1999
if (!g[rG].up->known && !(op==UNSAVE && cool->xx==1)) goto stall;
2000
cool_G=g[rG].up->o.l;
2001
 
2002
@ @=
2003
if (resuming)
2004
  @@;
2005
else{
2006
  if (f&0x10) @b| from register X@>@;
2007
  if (third_operand[op] && (cool->i!=trap))
2008
    @b| and/or |cool->ra| from special register@>;
2009
  if (f&0x1) cool->z.o.l=cool->zz;
2010
  else if (f&0x2) @z| from register Z@>@;
2011
  else if ((op&0xf0)==0xe0) @z| as an immediate wyde@>;
2012
  if (f&0x4) cool->y.o.l=cool->yy;
2013
  else if (f&0x8) @y| from register Y@>@;
2014
}
2015
 
2016
@ @z| from register Z@>=
2017
{
2018
  if (cool->zz>=cool_G) cool->z=specval(&g[cool->zz]);
2019
  else if (cool->zzz=specval(&l[(cool_O.l+cool->zz)&lring_mask]);
2020
}
2021
 
2022
@ @y| from register Y@>=
2023
{
2024
  if (cool->yy>=cool_G) cool->y=specval(&g[cool->yy]);
2025
  else if (cool->yyy=specval(&l[(cool_O.l+cool->yy)&lring_mask]);
2026
}
2027
 
2028
@ @b| from register X@>=
2029
{
2030
  if (cool->xx>=cool_G) cool->b=specval(&g[cool->xx]);
2031
  else if (cool->xx
2032
    cool->b=specval(&l[(cool_O.l+cool->xx)&lring_mask]);
2033
  if (f&rel_addr_bit) cool->need_b=true; /* |br|, |pbr| */
2034
}
2035
 
2036
@ If an operation requires a special register as third operand,
2037
that register is listed in the |third_operand| table.
2038
 
2039
@=
2040
unsigned char third_operand[256]={@/
2041
  0,rA,0,0,rA,rA,rA,rA, /* \.{TRAP}, \dots\ */
2042
  rA,rA,rA,rA,rA,rA,rA,rA, /* \.{FLOT}, \dots\ */
2043
  rA,rE,rE,rE,rA,rA,rA,rA, /* \.{FMUL}, \dots\ */
2044
  rA,rA,0,0,rA,rA,rD,rD, /* \.{MUL}, \dots\ */
2045
  rA,rA,0,0,rA,rA,0,0, /* \.{ADD}, \dots\ */
2046
  0,0,0,0,0,0,0,0, /* \.{2ADDU}, \dots\ */
2047
  0,0,0,0,rA,rA,0,0, /* \.{CMP}, \dots\ */
2048
  rA,rA,0,0,0,0,0,0, /* \.{SL}, \dots\ */
2049
  0,0,0,0,0,0,0,0, /* \.{BN}, \dots\ */
2050
  0,0,0,0,0,0,0,0, /* \.{BNN}, \dots\ */
2051
  0,0,0,0,0,0,0,0, /* \.{PBN}, \dots\ */
2052
  0,0,0,0,0,0,0,0, /* \.{PBNN}, \dots\ */
2053
  0,0,0,0,0,0,0,0, /* \.{CSN}, \dots\ */
2054
  0,0,0,0,0,0,0,0, /* \.{CSNN}, \dots\ */
2055
  0,0,0,0,0,0,0,0, /* \.{ZSN}, \dots\ */
2056
  0,0,0,0,0,0,0,0, /* \.{ZSNN}, \dots\ */
2057
  0,0,0,0,0,0,0,0, /* \.{LDB}, \dots\ */
2058
  0,0,0,0,0,0,0,0, /* \.{LDT}, \dots\ */
2059
  0,0,0,0,0,0,0,0, /* \.{LDSF}, \dots\ */
2060
  0,0,0,0,0,0,0,0, /* \.{LDVTS}, \dots\ */
2061
  rA,rA,0,0,rA,rA,0,0, /* \.{STB}, \dots\ */
2062
  rA,rA,0,0,0,0,0,0, /* \.{STT}, \dots\ */
2063
  rA,rA,0,0,0,0,0,0, /* \.{STSF}, \dots\ */
2064
  0,0,0,0,0,0,0,0, /* \.{SYNCD}, \dots\ */
2065
  0,0,0,0,0,0,0,0, /* \.{OR}, \dots\ */
2066
  0,0,0,0,0,0,0,0, /* \.{AND}, \dots\ */
2067
  0,0,0,0,0,0,0,0, /* \.{BDIF}, \dots\ */
2068
  rM,rM,0,0,0,0,0,0, /* \.{MUX}, \dots\ */
2069
  0,0,0,0,0,0,0,0, /* \.{SETH}, \dots\ */
2070
  0,0,0,0,0,0,0,0, /* \.{ORH}, \dots\ */
2071
  0,0,0,0,0,0,0,0, /* \.{JMP}, \dots\ */
2072
  rJ,0,0,0,0,0,0,255}; /* \.{POP}, \dots\ */
2073
 
2074
@ The |cool->b| field is busy in operations like \.{STB} or \.{STSF},
2075
which need~rA. So we use |cool->ra| instead, when rA is needed.
2076
 
2077
@b| and/or |cool->ra| from special register@>=
2078
{
2079
  if (third_operand[op]==rA || third_operand[op]==rE)
2080
    cool->need_ra=true, cool->ra=specval(&g[rA]);
2081
  if (third_operand[op]!=rA)
2082
    cool->need_b=true, cool->b=specval(&g[third_operand[op]]);
2083
}
2084
 
2085
@ @z| as an immediate wyde@>=
2086
{  switch (op&3) {
2087
case 0: cool->z.o.h=yz<<16;@+break;
2088
case 1: cool->z.o.h=yz;@+break;
2089
case 2: cool->z.o.l=yz<<16;@+break;
2090
case 3: cool->z.o.l=yz;@+break;
2091
}
2092
  if (i!=set) { /* register X should also be the Y operand */
2093
    cool->y=cool->b; cool->b=zero_spec;
2094
  }
2095
}
2096
 
2097
@ @=
2098
{
2099
  if (cool->xx>=cool_G) {
2100
    if (i!=pushgo && i!=pushj)
2101
      cool->ren_x=true,spec_install(&g[cool->xx],&cool->x);
2102
  }@+else if (cool->xx
2103
    cool->ren_x=true,
2104
      spec_install(&l[(cool_O.l+cool->xx)&lring_mask],&cool->x);
2105
  else { /* we need to increase L before issuing |head->inst| */
2106
 increase_L:@+ if (((cool_S.l-cool_O.l-cool_L-1)&lring_mask)==0)
2107
      @@;
2108
    else @;
2109
  }
2110
}
2111
 
2112
@ @=
2113
if (rename_regsren_x+cool->ren_a) goto stall;
2114
if (cool->mem_x)
2115
  if (mem_slots) mem_slots--;@+else goto stall;
2116
rename_regs-=cool->ren_x+cool->ren_a;
2117
 
2118
@ The |incrl| instruction
2119
advances $\beta$ and~rL by~1 at a time when we know that $\beta\ne\gamma$,
2120
in the ring of local registers.
2121
 
2122
@=
2123
{
2124
  cool->i=incrl;
2125
  spec_install(&l[(cool_O.l+cool_L)&lring_mask],&cool->x);
2126
  cool->need_b=cool->need_ra=false;
2127
  cool->y=cool->z=zero_spec;
2128
  cool->x.known=true; /* |cool->x.o=zero_octa| */
2129
  spec_install(&g[rL],&cool->rl);
2130
  cool->rl.o.l=cool_L+1;
2131
  cool->ren_x=cool->set_l=true;
2132
  op=SETH; /* this instruction to be handled by the simplest units */
2133
  cool->interim=true;
2134
  goto dispatch_done;
2135
}
2136
 
2137
@ The |incgamma| instruction advances $\gamma$ and rS by storing an octabyte
2138
from the local register ring to virtual memory location |cool_S<<3|.
2139
 
2140
@=
2141
{
2142
  cool->need_b=cool->need_ra=false;
2143
  cool->i=incgamma;
2144
  new_S=incr(cool_S,1);
2145
  cool->b=specval(&l[cool_S.l&lring_mask]);
2146
  cool->y.p=NULL, cool->y.o=shift_left(cool_S,3);
2147
  cool->z=zero_spec;
2148
  cool->mem_x=true, spec_install(&mem,&cool->x);
2149
  op=STOU; /* this instruction needs to be handled by load/store unit */
2150
  cool->interim=true;
2151
  goto dispatch_done;
2152
}
2153
 
2154
@ The |decgamma| instruction decreases $\gamma$ and rS by loading an octabyte
2155
from virtual memory location |(cool_S-1)<<3| into the local register ring.
2156
 
2157
@=
2158
{
2159
  cool->i=decgamma;
2160
  new_S=incr(cool_S,-1);
2161
  cool->z=cool->b=zero_spec; cool->need_b=false;
2162
  cool->y.p=NULL, cool->y.o=shift_left(new_S,3);
2163
  cool->ren_x=true, spec_install(&l[new_S.l&lring_mask],&cool->x);
2164
  op=LDOU; /* this instruction needs to be handled by load/store unit */
2165
  cool->interim=true;
2166
  cool->ptr_a=(void*)mem.up;
2167
  goto dispatch_done;
2168
}
2169
 
2170
@ Storing into memory requires a doubly linked data list of specnodes
2171
like the lists we use for local and global registers. In this case
2172
the head of the list is called |mem|, and the |addr| fields are
2173
physical addresses in memory.
2174
 
2175
@=
2176
Extern specnode mem;
2177
 
2178
@ The |addr| field of a memory specnode
2179
is all 1s until the physical address has been computed.
2180
 
2181
@=
2182
mem.addr.h=mem.addr.l=-1;
2183
mem.up=mem.down=&mem;
2184
 
2185
@ The \.{CSWAP} operation is treated as a partial store, with \$X
2186
as a secondary output. Partial store (|pst|) commands read an octabyte
2187
from memory before they write it.
2188
 
2189
@=
2190
case cswap: cool->ren_a=true;
2191
  spec_install(cool->xx>=cool_G? &g[cool->xx]:
2192
      &l[(cool_O.l+cool->xx)&lring_mask],&cool->a);
2193
  cool->i=pst;
2194
case st:@+ if ((op&0xfe)==STCO) cool->b.o.l=cool->xx;
2195
case pst:
2196
 cool->mem_x=true, spec_install(&mem,&cool->x);@+ break;
2197
case ld: case ldunc: cool->ptr_a=(void *)mem.up;@+ break;
2198
 
2199
@ When new data is \.{PUT} into special registers 15--20 (namely rK,
2200
rQ, rU, rV, rG, or~rL) it can affect many things. Therefore we stop
2201
issuing further instructions until such \.{PUT}s are committed.
2202
Moreover, we will see later that such drastic \.{PUT}s defer execution until
2203
they reach the hot seat.
2204
 
2205
@=
2206
case put:@+ if (cool->yy!=0 || cool->xx>=32) goto illegal_inst;
2207
 if (cool->xx>=8) {
2208
   if (cool->xx<=11) goto illegal_inst;
2209
   if (cool->xx<=18 && !(cool->loc.h&sign_bit)) goto privileged_inst;
2210
 }
2211
 if (cool->xx>=15 && cool->xx<=20) freeze_dispatch=true;
2212
 cool->ren_x=true, spec_install(&g[cool->xx],&cool->x);@+break;
2213
@#
2214
case get:@+ if (cool->yy || cool->zz>=32) goto illegal_inst;
2215
 if (cool->zz==rO) cool->z.o=shift_left(cool_O,3);
2216
 else if (cool->zz==rS) cool->z.o=shift_left(cool_S,3);
2217
 else cool->z=specval(&g[cool->zz]);@+break;
2218
illegal_inst: cool->interrupt |= B_BIT;@+goto noop_inst;
2219
case ldvts:@+ if (cool->loc.h&sign_bit) break;
2220
privileged_inst:  cool->interrupt |= K_BIT;
2221
noop_inst: cool->i=noop;@+break;
2222
 
2223
@ A \.{PUSHGO} instruction with $\rm X\ge G$ causes L to increase
2224
momentarily by~1, even if $\rm L=G$.
2225
But the value of~L will be decreased before the \.{PUSHGO}
2226
is complete, so it will never actually exceed~G. Moreover, we needn't
2227
insert an~|incrl| command.
2228
 
2229
@=
2230
case pushgo: inst_ptr.p=&cool->go;
2231
case pushj: {@+register int x=cool->xx;
2232
  if (x>=cool_G) {
2233
    if (((cool_S.l-cool_O.l-cool_L-1)&lring_mask)==0)
2234
      @@;
2235
    x=cool_L;@+ cool_L++;
2236
    cool->ren_x=true, spec_install(&l[(cool_O.l+x)&lring_mask],&cool->x);
2237
  }
2238
  cool->x.known=true, cool->x.o.h=0, cool->x.o.l=x;
2239
  cool->ren_a=true, spec_install(&g[rJ],&cool->a);
2240
  cool->a.known=true, cool->a.o=incr(cool->loc,4);
2241
  cool->set_l=true, spec_install(&g[rL],&cool->rl);
2242
  cool->rl.o.l=cool_L-x-1;
2243
  new_O=incr(cool_O,x+1);
2244
}@+break;
2245
case syncid: if (cool->loc.h&sign_bit) break;
2246
case go: inst_ptr.p=&cool->go;@+break;
2247
 
2248
@ We need to know the topmost ``hidden'' element of the register stack
2249
when a \.{POP} instruction is dispatched. This element is usually
2250
present in the local register ring, unless $\gamma=\alpha$.
2251
 
2252
Once it is known, let $x$ be its least significant byte. We will
2253
be decreasing rO by $x+1$, so we may have to decrease $\gamma$ repeatedly
2254
in order to maintain the condition $\rm rS\le rO$.
2255
 
2256
@=
2257
case pop:@+if (cool->xx && cool_L>=cool->xx)
2258
      cool->y=specval(&l[(cool_O.l+cool->xx-1)&lring_mask]);
2259
pop_unsave:@+if (cool_S.l==cool_O.l)
2260
    @;
2261
  {@+register tetra x; register int new_L;
2262
    register specnode *p=l[(cool_O.l-1)&lring_mask].up;
2263
    if (p->known) x=(p->o.l)&0xff;@+ else goto stall;
2264
    if ((tetra)(cool_O.l-cool_S.l)<=x)
2265
      @;
2266
    new_O=incr(cool_O,-x-1);
2267
    if (cool->i==pop) new_L=x+(cool->xx<=cool_L? cool->xx: cool_L+1);
2268
    else new_L=x;
2269
    if (new_L>cool_G) new_L=cool_G;
2270
    if (x
2271
      cool->ren_x=true, spec_install(&l[(cool_O.l-1)&lring_mask],&cool->x);
2272
    cool->set_l=true, spec_install(&g[rL],&cool->rl);
2273
    cool->rl.o.l=new_L;
2274
    if (cool->i==pop) {
2275
      cool->z.o.l=yz<<2;
2276
      if (inst_ptr.p==UNKNOWN_SPEC && new_head==tail) inst_ptr.p=&cool->go;
2277
    }
2278
    break;
2279
  }
2280
 
2281
@ @=
2282
case mulu: cool->ren_a=true, spec_install(&g[rH],&cool->a);@+break;
2283
case div: case divu: cool->ren_a=true, spec_install(&g[rR],&cool->a);@+break;
2284
 
2285
@ It's tempting to say that we could avoid taking up space in the reorder
2286
buffer when no operation needs to be done.
2287
A \.{JMP} instruction qualifies as a no-op in this sense,
2288
because the change of control occurs before the execution stage.
2289
However, even a no-op might have to be counted in the usage register~rU,
2290
so it might get into the execution stage for that reason.
2291
A no-op can also cause a protection interrupt, if it appears in a negative
2292
location. Even more importantly, a program might get into a loop that consists
2293
entirely of jumps and no-ops; then we wouldn't be able to interrupt it,
2294
because the interruption mechanism needs to find the current location
2295
in the reorder buffer! At least one functional unit therefore needs to provide
2296
explicit support for \.{JMP}, \.{JMPB}, and \.{SWYM}.
2297
 
2298
The \.{SWYM} instruction with |F_BIT| set is a special case: This is
2299
a request from the fetch coroutine for an update to the IT-cache,
2300
when the page table method isn't implemented in hardware.
2301
 
2302
@=
2303
case noop:@+if (cool->interrupt&F_BIT) {
2304
   cool->go.o=cool->y.o=cool->loc;
2305
   inst_ptr=specval(&g[rT]);
2306
 }
2307
 break;
2308
 
2309
@ @=
2310
if (cool->ren_x || cool->mem_x) spec_rem(&cool->x);
2311
if (cool->ren_a) spec_rem(&cool->a);
2312
if (cool->set_l) spec_rem(&cool->rl);
2313
if (inst_ptr.p==&cool->go) inst_ptr.p=UNKNOWN_SPEC;
2314
break;
2315
 
2316
@* The execution stages. \MMIX's {\it raison d'\^etre\/} is its ability
2317
to execute instructions. So now we want to simulate the behavior of its
2318
functional units.
2319
 
2320
Each coroutine scheduled for action at the current tick of the clock has a
2321
|stage| number corresponding to a particular subset of the \MMIX\ hardware.
2322
For example, the coroutines with |stage=2| are the second stages in the
2323
pipelines of the functional units. A coroutine with |stage=0| works
2324
in the fetch unit. Several artificially large stage numbers
2325
are used to control special coroutines that do things like write data
2326
from buffers into memory.
2327
 
2328
In this program the current coroutine of interest is called |self|; hence
2329
|self->stage| is the current stage number of interest. Another key variable,
2330
|self->ctl|, is called~|data|; this is the control block being operated on by
2331
the current coroutine. We typically are simulating an operation in which
2332
|data->x| is being computed as a function of |data->y| and |data->z|.
2333
The |data| record has many fields, as described earlier when we defined
2334
\&{control} structures; for example, |data->owner| is the same as
2335
|self|, during the execution stage, if it is nonnull.
2336
 
2337
This part of the simulator is written as if each functional unit is able to
2338
handle all 256 operations. In practice, of course, a functional unit tends to
2339
be much more specialized; the actual specialization is governed by the
2340
dispatcher, which issues an instruction only to a functional unit that
2341
supports it. Once an instruction has been dispatched, however, we can simulate
2342
it most easily if we imagine that its functional unit is universal.
2343
 
2344
Coroutines with higher |stage| numbers are processed first.
2345
The three most important variables that govern a coroutine's behavior, once
2346
|self->stage| is given, are the external operation code |data->op|, the
2347
internal operation code |data->i|, and the value of |data->state|. We
2348
typically have |data->state=0| when a coroutine is first fired~up.
2349
 
2350
@=
2351
register coroutine *self; /* the current coroutine being executed */
2352
register control *data; /* the |control| block of the current coroutine */
2353
 
2354
@ When a coroutine has done all it wants to on a single cycle,
2355
it says |goto done|. It will not be scheduled to do any further work
2356
unless the |schedule| routine has been called since it began execution.
2357
The |wait| macro is a convenient way to say ``Please schedule me to resume
2358
again at the current |data->state|'' after a specified time; for example,
2359
|wait(1)| will restart a coroutine on the next clock tick.
2360
 
2361
@d wait(t)@+ {@+schedule(self,t,data->state);@+ goto done;@+}
2362
@d pass_after(t)  schedule(self+1,t,data->state)
2363
@d sleep@+ {@+self->next=self;@+ goto done;@+} /* wait forever */
2364
@d awaken(c,t)  schedule(c,t,c->ctl->state)
2365
 
2366
@=
2367
cur_time++;@+ if (cur_time==ring_size) cur_time=0;
2368
for (self=queuelist(cur_time);self!=&sentinel;self=sentinel.next) {
2369
  sentinel.next=self->next;@+self->next=NULL; /* unschedule this coroutine */
2370
  data=self->ctl;
2371
  if (verbose&coroutine_bit) {
2372
    printf(" running ");@+print_coroutine_id(self);@+printf(" ");
2373
    print_control_block(data);@+printf("\n");
2374
  }
2375
  switch(self->stage) {
2376
 case 0:@;
2377
 case 1:@;
2378
 default:@;
2379
 @t\4@>@;
2380
  }
2381
 terminate:@+if (self->lockloc) *(self->lockloc)=NULL,self->lockloc=NULL;
2382
 done:;
2383
}
2384
 
2385
@ A special coroutine whose |stage| number is |vanish| simply goes away
2386
at its scheduled time.
2387
 
2388
@=
2389
case vanish: goto terminate;
2390
 
2391
@ @=
2392
coroutine mem_locker; /* trivial coroutine that vanishes */
2393
coroutine Dlocker; /* another */
2394
control vanish_ctl; /* such coroutines share a common control block */
2395
 
2396
@ @=
2397
mem_locker.name="Locker";
2398
mem_locker.ctl=&vanish_ctl;
2399
mem_locker.stage=vanish;
2400
Dlocker.name="Dlocker";
2401
Dlocker.ctl=&vanish_ctl;
2402
Dlocker.stage=vanish;
2403
vanish_ctl.go.o.l=4;
2404
for (j=0;jports;j++) DTcache->reader[j].ctl=&vanish_ctl;
2405
if (Dcache) for (j=0;jports;j++) Dcache->reader[j].ctl=&vanish_ctl;
2406
for (j=0;jports;j++) ITcache->reader[j].ctl=&vanish_ctl;
2407
if (Icache) for (j=0;jports;j++) Icache->reader[j].ctl=&vanish_ctl;
2408
 
2409
@ Here is a list of the |stage| numbers for special coroutines to be
2410
defined below.
2411
 
2412
@
=
2413
#define max_stage 99 /* exceeds all |stage| numbers */
2414
#define vanish 98 /* special coroutine that just goes away */
2415
#define flush_to_mem 97 /* coroutine for flushing from a cache to memory */
2416
#define flush_to_S 96 /* coroutine for flushing from a cache to the S-cache */
2417
#define fill_from_mem 95 /* coroutine for filling a cache from memory */
2418
#define fill_from_S 94 /* coroutine for filling a cache from the S-cache */
2419
#define fill_from_virt 93 /* coroutine for filling a translation cache */
2420
#define write_from_wbuf 92 /* coroutine for emptying the write buffer */
2421
#define cleanup 91 /* coroutine for cleaning the caches */
2422
 
2423
@ At the very beginning of stage 1, a functional unit will stall if necessary
2424
until its operands are available. As soon as the operands are all present, the
2425
|state| is set nonzero and execution proper begins.
2426
 
2427
@=
2428
switch1:@+ switch(data->state) {
2429
 case 0: @;
2430
 case 1: @;
2431
 case 2: @;
2432
 case 3: @;
2433
  @;
2434
}
2435
 
2436
@ If some of our input data has been computed by another coroutine on the
2437
current cycle, we grab it now but wait for the next cycle. (An actual machine
2438
wouldn't have latched the data until then.)
2439
 
2440
@=
2441
j=0;
2442
if (data->y.p) {
2443
  j++;
2444
  if (data->y.p->known) data->y.o=data->y.p->o, data->y.p=NULL;
2445
  else j+=10;
2446
}
2447
if (data->z.p) {
2448
  j++;
2449
  if (data->z.p->known) data->z.o=data->z.p->o, data->z.p=NULL;
2450
  else j+=10;
2451
}
2452
if (data->b.p) {
2453
  if (data->need_b) j++;
2454
  if (data->b.p->known) data->b.o=data->b.p->o, data->b.p=NULL;
2455
  else if (data->need_b) j+=10;
2456
}
2457
if (data->ra.p) {
2458
  if (data->need_ra) j++;
2459
  if (data->ra.p->known) data->ra.o=data->ra.p->o, data->ra.p=NULL;
2460
  else if (data->need_ra) j+=10;
2461
}
2462
if (j<10) data->state=1;
2463
if (j) wait(1); /* otherwise we fall through to case 1 */
2464
 
2465
@ Simple register-to-register instructions like \.{ADD} are assumed to take
2466
just one cycle, but others like \.{FADD} almost certainly require more time.
2467
This simulator can be configured so that \.{FADD} might take, say, four
2468
pipeline stages of one cycle each ($1+1+1+1$), or two pipeline stages of two
2469
cycles each ($2+2$), or a single unpipelined stage lasting four cycles (4),
2470
etc. In any case the simulator computes the results now, for simplicity,
2471
placing them in |data->x| and possibly also in |data->a| and/or
2472
|data->interrupt|. The results will not be officially made |known| until
2473
the proper time.
2474
 
2475
@=
2476
switch (data->i) {
2477
  @;
2478
  @;
2479
  @;
2480
}
2481
@;
2482
 
2483
@ If the internal opcode |data->i| is |max_pipe_op| or less, a special
2484
pipeline sequence like $1+1+1+1$ or $2+2$ or $15+10$, etc., has been
2485
configured. Otherwise we assume that the pipeline sequence is simply~1.
2486
 
2487
Suppose the pipeline sequence is $t_1+t_2+\cdots+t_k$. Each $t_j$ is
2488
positive and less than~256, so we represent the sequence as a
2489
string |pipe_seq[data->i]| of unsigned ``characters,'' terminated by~0.
2490
Given such a string, we want to do the following: Wait $(t_1-1)$ cycles
2491
and pass |data| to stage~2; wait $t_2$ cycles and pass |data| to stage~3;
2492
\dots; wait $t_{k-1}$ cycles and pass |data| to stage~$k$; wait $t_k$ cycles
2493
and make the results |known|.
2494
 
2495
The value of |denin| is added to $t_1$; the value of |denout| is
2496
added to~$t_k$.
2497
 
2498
@=
2499
data->state=3;
2500
if (data->i<=max_pipe_op) {@+register unsigned char *s=pipe_seq[data->i];
2501
  j=s[0]+data->denin;
2502
  if (s[1]) data->state=2; /* more than one stage */
2503
  else j+=data->denout;
2504
  if (j>1) wait(j-1);
2505
}
2506
goto switch1;
2507
 
2508
@ When we're in stage $j$, the coroutine for stage $j+1$ of the same functional
2509
unit is |self+1|.
2510
 
2511
@=
2512
pass_data:@+
2513
if ((self+1)->next) wait(1); /* stall if the next stage is occupied */
2514
{@+register unsigned char *s=pipe_seq[data->i];
2515
  j=s[self->stage];
2516
  if (s[self->stage+1]==0) j+=data->denout,data->state=3;
2517
          /* the next stage is the last */
2518
  pass_after(j);
2519
}
2520
passit: (self+1)->ctl=data;
2521
data->owner=self+1;
2522
goto done;
2523
 
2524
@ @=
2525
switch2:@+if (data->b.p && data->b.p->known)
2526
    data->b.o=data->b.p->o, data->b.p=NULL;
2527
 switch(data->state) {
2528
 case 0: panic(confusion("switch2"));
2529
 case 1: @;
2530
 case 2: goto pass_data;
2531
 case 3: goto fin_ex;
2532
  @;
2533
}
2534
 
2535
@ The default pipeline times use only one stage; they
2536
can be overridden by |MMIX_config|. The total number of stages
2537
supported by this simulator is limited to 90, since
2538
it must never interfere with the |stage| numbers for special coroutines
2539
defined below. (The author doesn't feel guilty about making this restriction.)
2540
 
2541
@=
2542
#define pipe_limit 90
2543
Extern unsigned char pipe_seq[max_pipe_op+1][pipe_limit+1];
2544
 
2545
@ The simplest of all register-to-register operations is |set|,
2546
which occurs for commands like \.{SETH} as well as for commands
2547
like \.{GETA}. (We might as well start with the easy cases and work our
2548
way up.)
2549
 
2550
@=
2551
case set: data->x.o=data->z.o;@+break;
2552
 
2553
@ Here are the basic boolean operations, which account for 24 of \MMIX's
2554
256 opcodes.
2555
 
2556
@=
2557
case or: data->x.o.h=data->y.o.h | data->z.o.h;
2558
   data->x.o.l=data->y.o.l | data->z.o.l; break;
2559
case orn: data->x.o.h=data->y.o.h |~data->z.o.h;
2560
   data->x.o.l=data->y.o.l |~data->z.o.l; break;
2561
case nor: data->x.o.h=~(data->y.o.h | data->z.o.h);
2562
   data->x.o.l=~(data->y.o.l | data->z.o.l); break;
2563
case and: data->x.o.h=data->y.o.h & data->z.o.h;
2564
   data->x.o.l=data->y.o.l & data->z.o.l; break;
2565
case andn: data->x.o.h=data->y.o.h &~data->z.o.h;
2566
   data->x.o.l=data->y.o.l &~data->z.o.l; break;
2567
case nand: data->x.o.h=~(data->y.o.h & data->z.o.h);
2568
   data->x.o.l=~(data->y.o.l & data->z.o.l); break;
2569
case xor: data->x.o.h=data->y.o.h ^ data->z.o.h;
2570
   data->x.o.l=data->y.o.l ^ data->z.o.l; break;
2571
case nxor: data->x.o.h=data->y.o.h ^~data->z.o.h;
2572
   data->x.o.l=data->y.o.l ^~data->z.o.l; break;
2573
 
2574
@ The implementation of \.{ADDU} is only slightly more difficult.
2575
It would be trivial except for the fact that internal opcode
2576
|addu| is used not only for the \.{ADDU[I]} and \.{INC[M][H,L]} operations,
2577
in which we simply want to add |data->y.o| to |data->z.o|, but also for
2578
operations like \.{4ADDU}.
2579
 
2580
@=
2581
case addu: data->x.o=oplus((data->op&0xf8)==0x28?@|
2582
          shift_left(data->y.o,1+((data->op>>1)&0x3)): data->y.o, data->z.o);
2583
 break;
2584
case subu: data->x.o=ominus(data->y.o,data->z.o);@+ break;
2585
 
2586
@ Signed addition and subtraction produce the same results as their
2587
unsigned counterparts, but overflow must also be detected. Overflow
2588
occurs when adding |y| to~|z| if and only if |y| and~|z| have the
2589
same sign but their sum has a different sign. Overflow occurs in
2590
the calculation |x=y-z| if and only if it occurs in the calculation~|y=x+z|.
2591
 
2592
@=
2593
case add: data->x.o=oplus(data->y.o,data->z.o);
2594
  if (((data->y.o.h ^ data->z.o.h)&sign_bit)==0 &&
2595
      ((data->y.o.h ^ data->x.o.h)&sign_bit)!=0) data->interrupt|=V_BIT;
2596
  break;
2597
case sub: data->x.o=ominus(data->y.o,data->z.o);
2598
  if (((data->x.o.h ^ data->z.o.h)&sign_bit)==0 &&
2599
      ((data->y.o.h ^ data->x.o.h)&sign_bit)!=0) data->interrupt|=V_BIT;
2600
  break;
2601
 
2602
@ The shift commands might take more than one cycle, or they might even be
2603
pipelined, if the default value of |pipe_seq[sh]| is changed. But we compute
2604
shifts all at once here, because other parts of the simulator will take care
2605
of the pipeline timing. (Notice that |shlu| is changed to |sh|, for this
2606
reason. Similar changes to the internal op codes are made for other operators
2607
below.)
2608
 
2609
@d shift_amt (data->z.o.h || data->z.o.l>=64? 64: data->z.o.l)
2610
 
2611
@=
2612
case shlu: data->x.o=shift_left(data->y.o,shift_amt);@+data->i=sh;@+ break;
2613
case shl: data->x.o=shift_left(data->y.o,shift_amt);@+data->i=sh;
2614
 {@+octa tmpo;
2615
    tmpo=shift_right(data->x.o,shift_amt,0);
2616
   if (tmpo.h!=data->y.o.h || tmpo.l!=data->y.o.l) data->interrupt|=V_BIT;
2617
 }@+break;
2618
case shru: data->x.o=shift_right(data->y.o,shift_amt,1);@+data->i=sh;@+ break;
2619
case shr:  data->x.o=shift_right(data->y.o,shift_amt,0);@+data->i=sh;@+ break;
2620
 
2621
@ The \.{MUX} operation has three operands, namely |data->y|, |data->z|,
2622
and |data->b|; the third operand is the current (speculative) value of~rM, the
2623
special mask register. Otherwise \.{MUX} is unexceptional.
2624
 
2625
@=
2626
case mux: data->x.o.h=(data->y.o.h&data->b.o.h)+(data->z.o.h&~data->b.o.h);
2627
          data->x.o.l=(data->y.o.l&data->b.o.l)+(data->z.o.l&~data->b.o.l);
2628
  break;
2629
 
2630
@ Comparisons are a breeze.
2631
 
2632
@=
2633
case cmp:@+if ((data->y.o.h&sign_bit)>(data->z.o.h&sign_bit)) goto cmp_neg;
2634
  if ((data->y.o.h&sign_bit)<(data->z.o.h&sign_bit)) goto cmp_pos;
2635
case cmpu:@+if (data->y.o.hz.o.h) goto cmp_neg;
2636
  if (data->y.o.h>data->z.o.h) goto cmp_pos;
2637
  if (data->y.o.lz.o.l) goto cmp_neg;
2638
  if (data->y.o.l>data->z.o.l) goto cmp_pos;
2639
 cmp_zero: break; /* |data->x| is zero */
2640
 cmp_pos: data->x.o.l=1;@+ break; /* |data->x.o.h| is zero */
2641
 cmp_neg: data->x.o=neg_one;@+ break;
2642
 
2643
@ The other operations will be deferred until later, now that we understand
2644
the basic ideas. But one more piece of code ought to be
2645
written before we move on, because
2646
it completes the execution stage for the simple cases already considered.
2647
 
2648
The |ren_x| and |ren_a| fields tell us whether the |x| and/or |a|
2649
fields contain valid information that should become officially known.
2650
 
2651
@=
2652
fin_ex:@+if (data->ren_x) data->x.known=true;
2653
else if (data->mem_x) data->x.known=true, data->x.addr.l&=-8;
2654
if (data->ren_a) data->a.known=true;
2655
if (data->loc.h&sign_bit)
2656
  data->ra.o.l=0; /* no trips enabled for the operating system */
2657
if (data->interrupt&0xffff) @;
2658
die: data->owner=NULL;@+goto terminate; /* this coroutine now fades away */
2659
 
2660
@* The commission/deissue stage. Control blocks leave the reorder buffer
2661
either at the hot end (when they're committed) or at the cool end
2662
(when they're deissued). We hope most of them are committed, but
2663
from time to time our speculation is incorrect and we must deissue
2664
a sequence of instructions that prove to be unwanted. Deissuing must
2665
take priority over committing, because the dispatcher cannot do anything
2666
until the machine's cool state has stabilized.
2667
 
2668
Deissuing changes the cool state by undoing the most recently issued
2669
instructions, in reverse order. Committing changes the hot state by
2670
doing the least recently issued instructions, in their original order.
2671
Both operations are similar, so we assume that they take the same time;
2672
at most |commit_max| instructions are deissued and/or committed on
2673
each clock cycle.
2674
 
2675
@=
2676
{
2677
  cool=(cool==reorder_top? reorder_bot: cool+1);
2678
  if (verbose&issue_bit) {
2679
    printf("Deissuing ");@+print_control_block(cool);
2680
    if (cool->owner) {@+printf(" ");@+print_coroutine_id(cool->owner);@+}
2681
    printf("\n");
2682
  }
2683
  if (cool->ren_x) rename_regs++,spec_rem(&cool->x);
2684
  if (cool->ren_a) rename_regs++,spec_rem(&cool->a);
2685
  if (cool->mem_x) mem_slots++,spec_rem(&cool->x);
2686
  if (cool->set_l) spec_rem(&cool->rl);
2687
  if (cool->owner) {
2688
    if (cool->owner->lockloc)
2689
      *(cool->owner->lockloc)=NULL, cool->owner->lockloc=NULL;
2690
    if (cool->owner->next) unschedule(cool->owner);
2691
  }
2692
  cool_O=cool->cur_O;@+ cool_S=cool->cur_S;
2693
  deissues--;
2694
}
2695
 
2696
@ @=
2697
{
2698
  if (nullifying) @@;
2699
  else {
2700
    if (hot->i==get && hot->zz==rQ)
2701
      new_Q=oandn(g[rQ].o,hot->x.o);
2702
    else if (hot->i==put && hot->xx==rQ)
2703
      hot->x.o.h |= new_Q.h, hot->x.o.l |= new_Q.l;
2704
    if (hot->mem_x) @;
2705
    if (verbose&issue_bit) {
2706
      printf("Committing ");@+print_control_block(hot);@+printf("\n");
2707
    }
2708
    if (hot->ren_x) rename_regs++,hot->x.up->o=hot->x.o,spec_rem(&(hot->x));
2709
    if (hot->ren_a) rename_regs++,hot->a.up->o=hot->a.o,spec_rem(&(hot->a));
2710
    if (hot->set_l) hot->rl.up->o=hot->rl.o,spec_rem(&(hot->rl));
2711
    if (hot->arith_exc) g[rA].o.l |= hot->arith_exc;
2712
    if (hot->usage) {
2713
      g[rU].o.l++;@+ if (g[rU].o.l==0) {
2714
        g[rU].o.h++;@+ if ((g[rU].o.h&0x7fff)==0) g[rU].o.h-=0x8000;
2715
      }
2716
    }
2717
  }
2718
  if (hot->interrupt>=H_BIT) @;
2719
}
2720
 
2721
@ A load or store instruction is ``nullified'' if it is about to be captured
2722
by a trap interrupt. In such cases it will be the only item in the reorder
2723
buffer; thus nullifying is sort of a cross between deissuing and
2724
committing. (It is important to have stopped dispatching when nullification
2725
is necessary, because instructions such as |incgamma| and
2726
|decgamma| change~rS, and we need to change it back when an unexpected
2727
interruption occurs.)
2728
 
2729
@=
2730
{
2731
  if (verbose&issue_bit) {
2732
    printf("Nullifying ");@+print_control_block(hot);@+printf("\n");
2733
  }
2734
  if (hot->ren_x) rename_regs++,spec_rem(&hot->x);
2735
  if (hot->ren_a) rename_regs++,spec_rem(&hot->a);
2736
  if (hot->mem_x) mem_slots++,spec_rem(&hot->x);
2737
  if (hot->set_l) spec_rem(&hot->rl);
2738
  cool_O=hot->cur_O, cool_S=hot->cur_S;
2739
  nullifying=false;
2740
}
2741
 
2742
@ Interrupt bits in rQ might be lost if they are set between a \.{GET}
2743
and a~\.{PUT}. Therefore we don't allow \.{PUT} to zero out bits that
2744
have become~1 since the most recently committed \.{GET}.
2745
 
2746
@=
2747
octa new_Q; /* when rQ increases in any bit position, so should this */
2748
 
2749
@ An instruction will not be committed immediately if it violates the basic
2750
security rule of \MMIX: An instruction in a nonnegative location
2751
should not be performed unless all eight of the internal interrupts
2752
have been enabled in the interrupt mask register~rK.
2753
Conversely, an instruction in a negative location should not be performed
2754
if the |P_BIT| is enabled in~rK.
2755
 
2756
Such instructions take one extra cycle before they are committed.
2757
The nonnegative-location case turns on the |S_BIT| of both rK and~rQ\null,
2758
leading to an immediate interrupt (unless the current instruction
2759
is |trap|, |put|, or~|resume|).
2760
 
2761
@=
2762
{
2763
  if (hot->loc.h&sign_bit) {
2764
    if ((g[rK].o.h&P_BIT) && !(hot->interrupt&P_BIT)) {
2765
      hot->interrupt |= P_BIT;
2766
      g[rQ].o.h |= P_BIT;
2767
      new_Q.h |= P_BIT;
2768
      if (verbose&issue_bit) {
2769
        printf(" setting rQ=");@+print_octa(g[rQ].o);@+printf("\n");
2770
      }
2771
      break;
2772
    }
2773
  }@+else if ((g[rK].o.h&0xff)!=0xff && !(hot->interrupt&S_BIT)) {
2774
    hot->interrupt |= S_BIT;
2775
    g[rQ].o.h |= S_BIT;
2776
    new_Q.h |= S_BIT;
2777
    g[rK].o.h |= S_BIT;
2778
    if (verbose&issue_bit) {
2779
      printf(" setting rQ=");@+print_octa(g[rQ].o);
2780
      printf(", rK=");@+print_octa(g[rK].o);@+printf("\n");
2781
    }
2782
    break;
2783
  }
2784
}
2785
 
2786
@* Branch prediction. An \MMIX\ programmer distinguishes statically between
2787
``branches'' and ``probable branches,'' but many modern computers attempt to
2788
do better by implementing dynamic branch prediction. (See, for example,
2789
section~4.3 of Hennessy and Patterson's {\sl Computer Architecture},
2790
second edition.) Experience has shown that dynamic branch prediction can
2791
@^Hennessy, John LeRoy@>
2792
@^Patterson, David Andrew@>
2793
significantly improve the performance of speculative execution, by
2794
reducing the number of instructions that need to be deissued.
2795
 
2796
This simulator has an optional |bp_table| containing $2^{\mkern1mua+b+c}$ entries of
2797
$n$~bits each, where $n$ is between 1 and~8. Usually $n$ is 1 or~2 in
2798
practice, but 8 bits are allocated per entry for convenience in this program.
2799
The |bp_table| is consulted and updated on every branch instruction
2800
(every \.{B}~or \.{PB} instruction, but not~\.{JMP}), for advice on
2801
past history of similar situations. It is indexed by the $a$ least
2802
significant bits of the address of the instruction, the $b$ most recent
2803
bits of global branch history, and the next $c$ bits of both address
2804
and history (exclusive-ored).
2805
 
2806
A |bp_table| entry begins at zero and is regarded as a signed $n$-bit number.
2807
If it is nonnegative, we will follow the prediction in the instruction,
2808
namely to predict a branch taken only in the \.{PB} case. If it is
2809
negative, we will predict the opposite of the instruction's recommendation.
2810
The $n$-bit number is increased (if possible) if the instruction's
2811
prediction was correct, decreased (if possible) if the instruction's
2812
prediction was incorrect.
2813
 
2814
(Incidentally, a large value of~$n$ is not necessarily a good idea.
2815
For example, if $n=8$ the machine might need 128 steps to
2816
recognize that a branch taken the first 150 times is not taken
2817
the next 150 times. And if we modify the update criteria to avoid this
2818
problem, we obtain a scheme that is rarely better than a simple scheme
2819
with smaller~$n$.)
2820
 
2821
The values $a$, $b$, $c$, and $n$ in this discussion are called
2822
|bp_a|, |bp_b|, |bp_c|, and |bp_n| in the program.
2823
 
2824
@=
2825
Extern int bp_a,bp_b,bp_c,bp_n; /* parameters for branch prediction */
2826
Extern char *bp_table; /* either |NULL| or an array of $2^{\mkern1mua+b+c}$ items */
2827
 
2828
@ Branch prediction is made when we are either about to issue an
2829
instruction or peeking ahead. We look at the |bp_table|, but we
2830
don't want to update it yet.
2831
 
2832
@=
2833
{
2834
  predicted=op&0x10; /* start with the instruction's recommendation */
2835
  if (bp_table) {@+register int h;
2836
    m=((head->loc.l&bp_cmask)<loc.l&bp_amask);
2837
    m=((cool_hist&bp_bcmask)<>2);
2838
    h=bp_table[m];
2839
    if (h&bp_npower) predicted^=0x10;
2840
  }
2841
  if (predicted) peek_hist=(peek_hist<<1)+1;
2842
  else peek_hist<<=1;
2843
}
2844
 
2845
@ We update the |bp_table| when an instruction is issued.
2846
And we store the opposite table
2847
value in |cool->x.o.l|, just in case our prediction turns out to be wrong.
2848
 
2849
@=
2850
if (bp_table) {@+register int reversed,h,h_up,h_down;
2851
  reversed=op&0x10;
2852
  if (peek_hist&1) reversed^=0x10;
2853
  m=((head->loc.l&bp_cmask)<loc.l&bp_amask);
2854
  m=((cool_hist&bp_bcmask)<>2);
2855
  h=bp_table[m];
2856
  h_up=(h+1)&bp_nmask;@+ if (h_up==bp_npower) h_up=h;
2857
  if (h==bp_npower) h_down=h;@+ else h_down=(h-1)&bp_nmask;
2858
  if (reversed) {
2859
    bp_table[m]=h_down, cool->x.o.l=h_up;
2860
    cool->i=pbr+br-cool->i; /* reverse the sense */
2861
    bp_rev_stat++;
2862
  }@+else {
2863
    bp_table[m]=h_up, cool->x.o.l=h_down; /* go with the flow */
2864
    bp_ok_stat++;
2865
  }
2866
  if (verbose&show_pred_bit) {
2867
    printf(" predicting ");@+print_octa(cool->loc);
2868
    printf(" %s; bp[%x]=%d\n",reversed? "NG": "OK",m,
2869
          bp_table[m]-((bp_table[m]&bp_npower)<<1));
2870
  }
2871
  cool->x.o.h=m;
2872
}
2873
 
2874
@ The calculations in the previous sections need several precomputed constants,
2875
depending on the parameters $a$, $b$, $c$, and~$n$.
2876
 
2877
@=
2878
bp_amask=((1<
2879
bp_cmask=((1<
2880
bp_bcmask=(1<<(bp_b+bp_c))-1; /* least $b+c$ bits of history info */
2881
bp_nmask=(1<
2882
bp_npower=1<<(bp_n-1); /* $2^{n-1}$, the sign bit of an $n$-bit number */
2883
 
2884
@ @=
2885
int bp_amask,bp_cmask,bp_bcmask,bp_nmask,bp_npower;
2886
int bp_rev_stat,bp_ok_stat; /* how often we overrode and agreed */
2887
int bp_bad_stat,bp_good_stat; /* how often we failed and succeeded */
2888
 
2889
@ After a branch or probable branch instruction has been issued and
2890
the value of the relevant register has been computed in the
2891
reorder buffer as |data->b.o|, we're ready to determine if the
2892
prediction was correct or not.
2893
 
2894
@=
2895
case br: case pbr: j=register_truth(data->b.o,data->op);
2896
  if (j) data->go.o=data->z.o;@+ else data->go.o=data->y.o;
2897
  if (j==(data->i==pbr)) bp_good_stat++;
2898
  else { /* oops, misprediction */
2899
    bp_bad_stat++;
2900
    @;
2901
  }
2902
  goto fin_ex;
2903
 
2904
@ The |register_truth| subroutine is used by \.B, \.{PB}, \.{CS}, and
2905
\.{ZS} commands to decide whether an octabyte satisfies the
2906
conditions of the opcode, |data->op|.
2907
 
2908
@=
2909
static int register_truth @,@,@[ARGS((octa,mmix_opcode))@];
2910
 
2911
@ @=
2912
static int register_truth(o,op)
2913
  octa o;
2914
  mmix_opcode op;
2915
{@+register int b;
2916
  switch ((op>>1) & 0x3) {
2917
 case 0: b=o.h>>31;@+break; /* negative? */
2918
 case 1: b=(o.h==0 && o.l==0);@+break; /* zero? */
2919
 case 2: b=(o.h
2920
 case 3: b=o.l&0x1;@+break; /* odd? */
2921
}
2922
  if (op&0x8) return b^1;
2923
  else return b;
2924
}
2925
 
2926
@ The |issued_between| subroutine determines how many speculative instructions
2927
were issued between a given control block in the reorder buffer and
2928
the current |cool| pointer, when |cc=cool|.
2929
 
2930
@=
2931
static int issued_between @,@,@[ARGS((control*,control*))@];
2932
 
2933
@ @=
2934
static int issued_between(c,cc)
2935
  control *c,*cc;
2936
{
2937
  if (c>cc) return c-1-cc;
2938
  return (c-reorder_bot)+(reorder_top-cc);
2939
}
2940
 
2941
@ If more than one functional unit is able to process branch instructions and
2942
if two of them simultaneously discover misprediction, or if misprediction is
2943
detected by one unit just as another unit is generating an interrupt, we
2944
assume that an arbitration takes place so that only the hottest one actually
2945
deissues the cooler instructions.
2946
 
2947
Changes to the |bp_table| aren't undone when they were made on speculation in
2948
an instruction being deissued; nor do we worry about cases where the same
2949
|bp_table| entry is being updated by two or more active coroutines. After all,
2950
the |bp_table| is just a heuristic, not part of the real computation.
2951
We correct the |bp_table| only if we discover that a prediction was wrong, so
2952
that we will be less likely to make the same mistake later.
2953
 
2954
@=
2955
i=issued_between(data,cool);
2956
if (i
2957
deissues=i;
2958
old_tail=tail=head;@+resuming=0; /* clear the fetch buffer */
2959
@;
2960
inst_ptr.o=data->go.o, inst_ptr.p=NULL;
2961
if (!(data->loc.h&sign_bit)) {
2962
  if (inst_ptr.o.h&sign_bit) data->interrupt |= P_BIT;
2963
  else data->interrupt &=~P_BIT;
2964
}
2965
if (bp_table) {
2966
  bp_table[data->x.o.h]=data->x.o.l; /* this is what we should have stored */
2967
  if (verbose&show_pred_bit) {
2968
    printf(" mispredicted ");@+print_octa(data->loc);
2969
    printf("; bp[%x]=%d\n",data->x.o.h,
2970
          data->x.o.l-((data->x.o.l&bp_npower)<<1));
2971
  }
2972
}
2973
cool_hist=(j? (data->hist<<1)+1: data->hist<<1);
2974
 
2975
@ @=
2976
Extern void print_stats @,@,@[ARGS((void))@];
2977
 
2978
@ @=
2979
void print_stats()
2980
{
2981
  register int j;
2982
  if (bp_table)
2983
    printf("Predictions: %d in agreement, %d in opposition; %d good, %d bad\n",
2984
                 bp_ok_stat,bp_rev_stat,bp_good_stat,bp_bad_stat);
2985
  else printf("Predictions: %d good, %d bad\n",bp_good_stat,bp_bad_stat);
2986
  printf("Instructions issued per cycle:\n");
2987
  for (j=0;j<=dispatch_max;j++)
2988
    printf("  %d   %d\n",j,dispatch_stat[j]);
2989
}
2990
 
2991
@* Cache memory. It's time now to consider \MMIX's MMU, the memory management
2992
unit. This part of the machine deals with the critical problem of getting data
2993
to and from the computational units. In a RISC architecture all interaction
2994
between main memory and the computer registers is specified by load and store
2995
instructions; thus memory accesses are much easier to deal with than they
2996
would be on a machine with more complex kinds of interaction. But memory
2997
management is still difficult, if we want to do it well, because main memory
2998
typically operates at a much slower speed than the registers do. High-speed
2999
implementations of \MMIX\ introduce intermediate ``caches'' of storage in
3000
order to keep the most important data accessible, and cache maintenance can be
3001
complicated when all the details are taken into account.
3002
(See, for example, Chapter 5 of Hennessy and Patterson's
3003
{\sl Computer Architecture}, second edition.)
3004
@^Hennessy, John LeRoy@>
3005
@^Patterson, David Andrew@>
3006
@^caches@>
3007
 
3008
This simulator can be configured to have up to three auxiliary caches between
3009
registers and memory: An I-cache for instructions, a D-cache for data, and an
3010
S-cache for both instructions and data. The S-cache, also called a {\it
3011
secondary cache}, is supported only if both I-cache and D-cache are present.
3012
Arbitrary access times for each cache can be specified independently;
3013
we might assume, for example, that data items in the I-cache or D-cache can
3014
be sent to a register in one or two clock cycles, but the access time for the
3015
S-cache might be say 5 cycles, and main memory might require 20 cycles or more.
3016
Our speculative pipeline can have many functional units handling load
3017
and store instructions, but only one load or store instruction can be
3018
updating the D-cache or S-cache or main memory at a time. (However, the
3019
D-cache can have several read ports; furthermore, data might
3020
be passing between the S-cache and memory while other data is passing
3021
between the reorder buffer and the D-cache.)
3022
 
3023
Besides the optional I-cache, D-cache, and S-cache, there are required caches
3024
called the IT-cache and DT-cache, for translation of virtual addresses to
3025
physical addresses. A translation cache is often called a ``translation
3026
@^TLB@>
3027
@^translation caches@>
3028
lookaside buffer'' or TLB; but we call it a cache since it is implemented in
3029
nearly the same way as an I-cache.
3030
 
3031
@ Consider a cache that has blocks of $2^b$~bytes each and
3032
associativity~$2^a$; here $b\ge3$ and $a\ge0$. The I-cache, D-cache, and
3033
S-cache are addressed by 48-bit physical addresses, as if they were part of
3034
main memory; but the IT and DT caches are addressed by 64-bit keys, obtained
3035
from a virtual address by blanking out the lower $s$ bits and inserting the
3036
value of~$n$, where the page size~$s$ and the process number~$n$ are found
3037
in~rV. We will consider all caches to be addressed by 64-bit keys, so that
3038
both cases are handled with the same basic methods.
3039
 
3040
Given a 64-bit key,
3041
we ignore the low-order $b$~bits and use the next $c$~bits
3042
to address the {\it cache set\/}; then the remaining $64-b-c$ bits should
3043
match one of $2^a$ {\it tags\/} in that set. The case $a=0$ corresponds to a
3044
so-called {\it direct-mapped\/} cache; the case $c=0$ corresponds to a
3045
so-called {\it fully associative\/} cache. With $2^c$ sets of $2^a$ blocks
3046
each, and $2^b$ bytes per block, the cache contains $2^{a+b+c}$ bytes of data,
3047
in addition to the space needed for tags. Translation caches have $b=3$ and
3048
they also usually have $c=0$.
3049
 
3050
If a tag matches the specified bits, we ``hit'' in the cache and can
3051
use and/or update the data found there. Otherwise we ``miss,'' and
3052
we probably want to replace one of the cache blocks by the block containing
3053
the item sought. The item chosen for replacement is called a {\it victim}.
3054
The choice of victim is forced when the cache is direct-mapped, but four
3055
strategies for victim selection are available when we must choose from
3056
among $2^a$ entries for $a>0$:
3057
 
3058
\smallskip\textindent{$\bullet$} ``Random'' selection chooses the victim
3059
by extracting the least significant $a$~bits of the clock.
3060
 
3061
\smallskip\textindent{$\bullet$} ``Serial'' selection chooses 0, 1, \dots,
3062
$2^a-1$, 0, 1, \dots, $2^a-1$, 0, \dots~on successive trials.
3063
 
3064
\smallskip\textindent{$\bullet$} ``LRU (Least Recently Used)'' selection
3065
chooses the victim that ranks last if items are ranked inversely to the time
3066
that has elapsed since their previous use.
3067
 
3068
\smallskip\textindent{$\bullet$} ``Pseudo-LRU'' selection chooses the
3069
victim by a rough approximation to LRU that is simpler to implement
3070
in hardware. It requires a bit table $r_1\ldots r_{2^a-1}$.
3071
Whenever we use an item
3072
with binary address $(i_1\ldots i_a)_2$ in the set, we adjust the
3073
bit table as follows:
3074
$$r_1\gets1-i_1,\quad r_{1i_1}\gets1-i_2,\quad\ldots,\quad
3075
r_{1i_1\ldots i_{a-1}}\gets1-i_a;$$
3076
here the subscripts on~$r$ are binary numbers. (For example, when $a=3$,
3077
the use of element $(010)_2$ sets $r_1\gets1$, $r_{10}\gets0$, $r_{101}\gets1$,
3078
where $r_{101}$ means the same as $r_5$.) To select a victim, we start with
3079
$l\gets1$ and then repeatedly set $l\gets2l+r_l$, $a$~times; then we
3080
choose element $l-2^a$. When $a=1$, this scheme is equivalent to LRU.
3081
When $a=2$, this scheme was implemented in the Intel 80486 chip.
3082
 
3083
@=
3084
typedef enum {@!random,@!serial,@!pseudo_lru,@!lru} replace_policy;
3085
 
3086
@ A cache might also include a ``victim'' area, which contains the
3087
last $2^v$ victim blocks removed from the main cache area. The victim
3088
area can be searched in parallel with the specified cache set, thereby
3089
increasing the chance of a hit without making the search go slower.
3090
Each of the three replacement policies can be used also in the victim cache.
3091
 
3092
@ A cache also has a {\it granularity\/} $2^g$, where $b\ge g\ge3$.  This
3093
means that we maintain, for each cache block, a set of $2^{b-g}$ ``dirty
3094
bits,'' which identify the $2^g$-byte groups that have possibly changed since
3095
they were last read from memory. Thus if $g=b$, an entire cache block is
3096
either dirty or clean; if $g=3$, the dirtiness of each octabyte is maintained
3097
separately.
3098
 
3099
Two policies are available when new data is written into all or part
3100
of a cache block. We can {\it write-through}, meaning that we send all new data
3101
to memory immediately and never mark anything dirty; or we can {\it
3102
write-back}, meaning that we update the memory from the cache only when
3103
absolutely necessary. Furthermore we can {\it write-allocate},
3104
meaning that we keep the new data in the cache, even if the cache block being
3105
written has to be fetched first because of a miss; or we can {\it
3106
write-around}, meaning that we keep the new data only if it was part of an
3107
existing cache block.
3108
 
3109
(In this discussion, ``memory'' is shorthand for ``the next level
3110
of the memory hierarchy''; if there is an S-cache, the I-cache and
3111
D-cache write new data to the S-cache, not directly to memory. The I-cache,
3112
IT-cache, and DT-cache are read-only, so they do not need the facilities
3113
discussed in this section. Moreover, the D-cache and S-cache can be assumed to
3114
have the same granularity.)
3115
 
3116
@
=
3117
#define WRITE_BACK 1 /* use this if not write-through */
3118
#define WRITE_ALLOC 2 /* use this if not write-around */
3119
 
3120
@ We have seen that many flavors of cache can be simulated. They are
3121
represented by \&{cache} structures, containing arrays of \&{cacheset}
3122
structures that contain arrays of \&{cacheblock} structures
3123
for the individual blocks. We use a full byte to store each |dirty| bit,
3124
and we use full integer words to store |rank| fields for LRU processing, etc.;
3125
memory economy is less important than simplicity in this simulator.
3126
 
3127
@=
3128
typedef struct{
3129
  octa tag; /* bits of key not included in the cache block address */
3130
  char *dirty; /* array of $2^{g-b}$ dirty bits, one per granule */
3131
  octa *data; /* array of $2^{b-3}$ octabytes, the data in a cache block */
3132
  int rank; /* auxiliary information for non-|random| policies */
3133
} cacheblock;
3134
@#
3135
typedef cacheblock *cacheset; /* array of $2^a$ or $2^v$ blocks */
3136
@#
3137
typedef struct{
3138
  int a,b,c,g,v; /* lg of associativity, blocksize, setsize, granularity,
3139
         and victimsize */
3140
  int aa,bb,cc,gg,vv; /* associativity, blocksize, setsize, granularity,
3141
         and victimsize (all powers of~2) */
3142
  int tagmask; /* $-2^{b+c}$ */
3143
  replace_policy repl,vrepl; /* how to choose victims and victim-victims */
3144
  int mode; /* optional |WRITE_BACK| and/or |WRITE_ALLOC| */
3145
  int access_time; /* cycles to know if there's a hit */
3146
  int copy_in_time; /* cycles to copy a new block into the cache */
3147
  int copy_out_time; /* cycles to copy an old block from the cache */
3148
  cacheset *set; /* array of $2^c$ sets of arrays of cache blocks */
3149
  cacheset victim; /* the victim cache, if present */
3150
  coroutine filler; /* a coroutine for copying new blocks into the cache */
3151
  control filler_ctl; /* its control block */
3152
  coroutine flusher; /* a coroutine for writing dirty old data
3153
                           from the cache */
3154
  control flusher_ctl; /* its control block */
3155
  cacheblock inbuf; /* filling comes from here */
3156
  cacheblock outbuf; /* flushing goes to here */
3157
  lockvar lock; /* nonzero when the cache is being changed significantly */
3158
  lockvar fill_lock; /* nonzero when filler should pass data back */
3159
  int ports; /* how many coroutines can be reading the cache? */
3160
  coroutine *reader; /* array of coroutines that might be reading
3161
                                    simultaneously */
3162
  char *name; /* |"Icache"|, for example */
3163
} cache;
3164
 
3165
@ @=
3166
Extern cache *Icache, *Dcache, *Scache, *ITcache, *DTcache;
3167
 
3168
@ Now we are ready to define some basic subroutines for cache maintenance.
3169
Let's begin with a trivial routine that tests if a given cache block is dirty.
3170
 
3171
@=
3172
static bool is_dirty @,@,@[ARGS((cache*,cacheblock*))@];
3173
 
3174
@ @=
3175
static bool is_dirty(c,p)
3176
  cache *c; /* the cache containing it */
3177
  cacheblock *p; /* a cache block */
3178
{
3179
  register int j;
3180
  register char *d=p->dirty;
3181
  for (j=0;jbb;d++,j+=c->gg) if (*d) return true;
3182
  return false;
3183
}
3184
 
3185
@ For diagnostic purposes we might want to display an entire cache block.
3186
 
3187
@=
3188
static void print_cache_block @,@,@[ARGS((cacheblock,cache*))@];
3189
 
3190
@ @=
3191
static void print_cache_block(p,c)
3192
  cacheblock p;
3193
  cache *c;
3194
{@+register int i,j,b=c->bb>>3,g=c->gg>>3;
3195
  printf("%08x%08x: ",p.tag.h,p.tag.l);
3196
  for (i=j=0; j
3197
    printf("%08x%08x%c",p.data[j].h,p.data[j].l,p.dirty[i]?'*':' ');
3198
  printf(" (%d)\n",p.rank);
3199
}
3200
 
3201
@ @=
3202
static void print_cache_locks @,@,@[ARGS((cache*))@];
3203
 
3204
@ @=
3205
static void print_cache_locks(c)
3206
  cache *c;
3207
{
3208
  if (c) {
3209
    if (c->lock) printf("%s locked by %s:%d\n",
3210
                    c->name,c->lock->name,c->lock->stage);
3211
    if (c->fill_lock) printf("%sfill locked by %s:%d\n",
3212
                    c->name,c->fill_lock->name,c->fill_lock->stage);
3213
  }
3214
}
3215
 
3216
@ The |print_cache| routine prints the entire contents of a cache. This can be
3217
a huge amount of data, but it can be very useful when debugging. Fortunately,
3218
the task of debugging favors the use of small caches, since interesting cases
3219
arise more often when a cache is fairly small.
3220
 
3221
@=
3222
Extern void print_cache @,@,@[ARGS((cache*,bool))@];
3223
 
3224
@ @=
3225
void print_cache(c,dirty_only)
3226
  cache *c;
3227
  bool dirty_only;
3228
{
3229
  if (c) {@+register int i,j;
3230
    printf("%s of %s:",dirty_only?"Dirty blocks":"Contents",c->name);
3231
    if (c->filler.next) {
3232
      printf(" (filling ");
3233
      print_octa(c->name[1]=='T'? c->filler_ctl.y.o: c->filler_ctl.z.o);
3234
      printf(")");
3235
    }
3236
    if (c->flusher.next) {
3237
      printf(" (flushing ");
3238
      print_octa(c->outbuf.tag);
3239
      printf(")");
3240
    }
3241
    printf("\n");
3242
    @;
3243
  }
3244
}
3245
 
3246
@ We don't print the cache blocks that have an invalid tag, unless
3247
requested to be verbose.
3248
 
3249
@=
3250
for (i=0;icc;i++) for (j=0;jaa;j++)
3251
  if ((!(c->set[i][j].tag.h&sign_bit)||(verbose&show_wholecache_bit))&&@|
3252
       (!dirty_only || is_dirty(c,&c->set[i][j]))) {
3253
    printf("[%d][%d] ",i,j);
3254
    print_cache_block(c->set[i][j],c);
3255
  }
3256
for (j=0;jvv;j++)
3257
  if ((!(c->victim[j].tag.h&sign_bit)||(verbose&show_wholecache_bit))&&@|
3258
       (!dirty_only || is_dirty(c,&c->victim[j]))) {
3259
    printf("V[%d] ",j);
3260
    print_cache_block(c->victim[j],c);
3261
  }
3262
 
3263
@ The |clean_block| routine simply initializes a given cache block.
3264
 
3265
@=
3266
Extern void clean_block @,@,@[ARGS((cache*,cacheblock*))@];
3267
 
3268
@ @=
3269
void clean_block(c,p)
3270
  cache *c;
3271
  cacheblock *p;
3272
{
3273
  register int j;
3274
  p->tag.h=sign_bit, p->tag.l=0;
3275
  for (j=0;jbb>>3;j++) p->data[j]=zero_octa;
3276
  for (j=0;jbb>>c->g;j++) p->dirty[j]=false;
3277
}
3278
 
3279
@ The |zap_cache| routine invalidates all tags of a given cache,
3280
effectively restoring it to its initial condition.
3281
 
3282
@=
3283
Extern void zap_cache @,@,@[ARGS((cache*))@];
3284
 
3285
@ We clear the |dirty| entries here, just to be tidy, although
3286
they could actually be left in arbitrary condition when the tags are invalid.
3287
 
3288
@=
3289
void zap_cache(c)
3290
  cache *c;
3291
{
3292
  register int i,j;
3293
  for (i=0;icc;i++) for (j=0;jaa;j++) {
3294
    clean_block(c,&(c->set[i][j]));
3295
  }
3296
  for (j=0;jvv;j++) {
3297
    clean_block(c,&(c->victim[j]));
3298
  }
3299
}
3300
 
3301
@ The |get_reader| subroutine finds the index of
3302
an available reader coroutine for a given cache, or returns a negative value
3303
if no readers are available.
3304
 
3305
@=
3306
static int get_reader @,@,@[ARGS((cache*))@];
3307
 
3308
@ @=
3309
static int get_reader(c)
3310
  cache *c;
3311
{@+ register int j;
3312
  for (j=0;jports;j++)
3313
    if (c->reader[j].next==NULL) return j;
3314
  return -1;
3315
}
3316
 
3317
@ The subroutine |copy_block(c,p,cc,pp)| copies the dirty
3318
items from block~|p| of cache~|c| into block~|pp| of cache~|cc|, assuming
3319
that the destination cache has a sufficiently large block size.
3320
(In other words, we assume that |cc->b>=c->b|.) We also assume that both
3321
blocks have compatible tags, and that both caches have the same granularity.
3322
 
3323
@=
3324
static void copy_block @,@,@[ARGS((cache*,cacheblock*,cache*,cacheblock*))@];
3325
 
3326
@ @=
3327
static void copy_block(c,p,cc,pp)
3328
  cache *c,*cc;
3329
  cacheblock *p,*pp;
3330
{
3331
  register int j,jj,i,ii,lim; register int off=p->tag.l&(cc->bb-1);
3332
  if (c->g!=cc->g || p->tag.h!=pp->tag.h || p->tag.l-off!=pp->tag.l)
3333
    panic(confusion("copy block"));
3334
  for (j=0,jj=off>>c->g;jbb>>c->g;j++,jj++) if (p->dirty[j]) {
3335
    pp->dirty[jj]=true;
3336
    for (i=j<<(c->g-3),ii=jj<<(c->g-3),lim=(j+1)<<(c->g-3);
3337
              idata[ii]=p->data[i];
3338
  }
3339
}
3340
 
3341
@ The |choose_victim| subroutine selects the victim to be replaced when we
3342
need to change a cache~set. We need only one bit of the |rank| fields to
3343
implement the $r$~table when |policy=pseudo_lru|,
3344
and we don't need |rank| at all when |policy=random|. Of course we use an
3345
$a$-bit counter to implement |policy=serial|. In the other case,
3346
|policy=lru|, we need an $a$-bit |rank| field; the least recently used entry
3347
has rank~0, and the most recently used entry has rank~$2^a-1=|aa|-1$.
3348
 
3349
@=
3350
static cacheblock* choose_victim @,@,@[ARGS((cacheset,int,replace_policy))@];
3351
 
3352
@ @=
3353
static cacheblock* choose_victim(s,aa,policy)
3354
  cacheset s;
3355
  int aa; /* setsize */
3356
  replace_policy policy;
3357
{
3358
  register cacheblock *p;
3359
  register int l,m;
3360
  switch (policy) {
3361
 case random: return &s[ticks.l&(aa-1)];
3362
 case serial: l=s[0].rank;@+ s[0].rank=(l+1)&(aa-1);@+ return &s[l];
3363
 case lru: for (p=s;p
3364
    if (p->rank==0) return p;
3365
  panic(confusion("lru victim")); /* what happened? nobody has rank zero */
3366
 case pseudo_lru: for (l=1,m=aa>>1; m; m>>=1) l=l+l+s[l].rank;
3367
   return &s[l-aa];
3368
  }
3369
}
3370
 
3371
@ The |note_usage| subroutine updates the |rank| entries to record the
3372
fact that a particular block in a cache set is now being used.
3373
 
3374
@=
3375
static void note_usage @,@,@[ARGS((cacheblock*,cacheset,int,replace_policy))@];
3376
 
3377
@ @=
3378
static void note_usage(l,s,aa,policy)
3379
  cacheblock *l; /* a cache block that's probably worth preserving */
3380
  cacheset s; /* the set that contains $l$ */
3381
  int aa; /* setsize */
3382
  replace_policy policy;
3383
{
3384
  register cacheblock *p;
3385
  register int j,m,r;
3386
  if (aa==1 || policy<=serial) return;
3387
  if (policy==lru) {
3388
    r=l->rank;
3389
    for (p=s;prank>r) p->rank--;
3390
    l->rank=aa-1;
3391
  } else { /* |policy==pseudo_lru| */
3392
    r=l-s;
3393
    for (j=1,m=aa>>1;m;m>>=1)
3394
      if (r&m) s[j].rank=0,j=j+j+1;
3395
      else s[j].rank=1, j=j+j;
3396
  }
3397
  return;
3398
}
3399
 
3400
@ The |demote_usage| subroutine is sort of the opposite of |note_usage|;
3401
it changes the rank of a given block to {\it least\/} recently used.
3402
 
3403
@=
3404
static void demote_usage @,@,@[ARGS((cacheblock*,cacheset,int,replace_policy))@];
3405
 
3406
@ @=
3407
static void demote_usage(l,s,aa,policy)
3408
  cacheblock *l; /* a cache block we probably don't need */
3409
  cacheset s; /* the set that contains $l$ */
3410
  int aa; /* setsize */
3411
  replace_policy policy;
3412
{
3413
  register cacheblock *p;
3414
  register int j,m,r;
3415
  if (aa==1 || policy<=serial) return;
3416
  if (policy==lru) {
3417
    r=l->rank;
3418
    for (p=s;prankrank++;
3419
    l->rank=0;
3420
  } else { /* |policy==pseudo_lru| */
3421
    r=l-s;
3422
    for (j=1,m=aa>>1;m;m>>=1)
3423
      if (r&m) s[j].rank=1,j=j+j+1;
3424
      else s[j].rank=0, j=j+j;
3425
  }
3426
  return;
3427
}
3428
 
3429
@ The |cache_search| routine looks for a given key $\alpha$
3430
in a given cache, and returns a cache block if there's a hit; otherwise
3431
it returns~|NULL|. If the search hits, the set in which the block was
3432
found is stored in global variable |hit_set|. Notice that we need to check
3433
more bits of the tag when we search in the victim area.
3434
 
3435
@d cache_addr(c,alf) c->set[(alf.l&~(c->tagmask))>>c->b]
3436
 
3437
@=
3438
static cacheblock* cache_search @,@,@[ARGS((cache*,octa))@];
3439
 
3440
@ @=
3441
static cacheblock* cache_search(c,alf)
3442
  cache *c; /* the cache to be searched */
3443
  octa alf; /* the key */
3444
{
3445
  register cacheset s;
3446
  register cacheblock* p;
3447
  s=cache_addr(c,alf); /* the set corresponding to |alf| */
3448
  for (p=s;paa;p++)
3449
    if (((p->tag.l ^ alf.l)&c->tagmask)==0 && p->tag.h==alf.h) goto hit;
3450
  s=c->victim;
3451
  if (!s) return NULL; /* cache miss, and no victim area */
3452
  for (p=s;pvv;p++)
3453
    if (((p->tag.l^alf.l)&(-c->bb))==0 && p->tag.h==alf.h) goto hit;
3454
  return NULL; /* double miss */
3455
 hit: hit_set=s;@+ return p;
3456
}
3457
 
3458
@ @=
3459
cacheset hit_set;
3460
 
3461
@ If |p=cache_search(c,alf)| hits and if we call |use_and_fix(c,p)|
3462
immediately afterwards, cache~|c| is updated to record the usage of
3463
key~|alf|. A hit in the victim area moves the cache block to the main area,
3464
unless the |filler| routine of cache~|c| is active.
3465
A pointer to the (possibly moved) cache block is returned.
3466
 
3467
@=
3468
static cacheblock* use_and_fix @,@,@[ARGS((cache*,cacheblock*))@];
3469
 
3470
@ @=
3471
static cacheblock *use_and_fix(c,p)
3472
  cache *c;
3473
  cacheblock *p;
3474
{
3475
  if (hit_set!=c->victim) note_usage(p,hit_set,c->aa,c->repl);
3476
  else { note_usage(p,hit_set,c->vv,c->vrepl); /* found in victim cache */
3477
    if (!c->filler.next) {
3478
      register cacheset s=cache_addr(c,p->tag);
3479
      register cacheblock *q=choose_victim(s,c->aa,c->repl);
3480
      note_usage(q,s,c->aa,c->repl);
3481
      @;
3482
      return q;
3483
    }
3484
  }
3485
  return p;
3486
}
3487
 
3488
@ We can simply permute the pointers inside the cacheblock structures of a
3489
cache, instead of copying the data, if we are careful not to let any of those
3490
pointers escape into other data structures.
3491
 
3492
@=
3493
{
3494
  octa t;
3495
  register char *d=p->dirty;
3496
  register octa *dd=p->data;
3497
  t=p->tag;@+p->tag=q->tag;@+q->tag=t;
3498
  p->dirty=q->dirty;@+q->dirty=d;
3499
  p->data=q->data;@+q->data=dd;
3500
}
3501
 
3502
@ The |demote_and_fix| routine is analogous to |use_and_fix|,
3503
except that we don't want to promote the data we found.
3504
 
3505
@=
3506
static cacheblock* demote_and_fix @,@,@[ARGS((cache*,cacheblock*))@];
3507
 
3508
@ @=
3509
static cacheblock *demote_and_fix(c,p)
3510
  cache *c;
3511
  cacheblock *p;
3512
{
3513
  if (hit_set!=c->victim) demote_usage(p,hit_set,c->aa,c->repl);
3514
  else demote_usage(p,hit_set,c->vv,c->vrepl);
3515
  return p;
3516
}
3517
 
3518
@ The subroutine |load_cache(c,p)| is called at a moment when
3519
|c->lock| has been set and |c->inbuf| has been filled with clean data
3520
to be placed in the cache block~|p|.
3521
 
3522
@=
3523
static void load_cache @,@,@[ARGS((cache*,cacheblock*))@];
3524
 
3525
@ @=
3526
static void load_cache(c,p)
3527
  cache *c;
3528
  cacheblock *p;
3529
{
3530
  register int i;
3531
  register octa *d;
3532
  for (i=0;ibb>>c->g;i++) p->dirty[i]=false;
3533
  d=p->data;@+ p->data=c->inbuf.data;@+ c->inbuf.data=d;
3534
  p->tag=c->inbuf.tag;
3535
  hit_set=cache_addr(c,p->tag);@+
3536
  use_and_fix(c,p); /* |p| not moved */
3537
}
3538
 
3539
@ The subroutine |flush_cache(c,p,keep)| is called at a ``quiet''
3540
moment when |c->flusher.next=NULL|.
3541
It puts cache block~|p| into |c->outbuf| and
3542
fires up the |c->flusher| coroutine, which will take care of
3543
sending the data to lower levels of the memory hierarchy.
3544
Cache block~|p| is also marked clean.
3545
 
3546
@=
3547
static void flush_cache @,@,@[ARGS((cache*,cacheblock*,bool))@];
3548
 
3549
@ @=
3550
static void flush_cache(c,p,keep)
3551
  cache *c;
3552
  cacheblock *p; /* a block inside cache |c| */
3553
  bool keep; /* should we preserve the data in |p|? */
3554
{
3555
    register octa *d;
3556
    register char *dd;
3557
    register int j;
3558
    c->outbuf.tag=p->tag;
3559
    if (keep)@+ for (j=0;jbb>>3;j++) c->outbuf.data[j]=p->data[j];
3560
    else d=c->outbuf.data, c->outbuf.data=p->data, p->data=d;
3561
    dd=c->outbuf.dirty, c->outbuf.dirty=p->dirty, p->dirty=dd;
3562
    for (j=0;jbb>>c->g;j++) p->dirty[j]=false;
3563
    startup(&c->flusher,c->copy_out_time); /* will not be aborted */
3564
}
3565
 
3566
@ The |alloc_slot| routine is called when we wish to put new information
3567
into a cache after a cache miss. It returns a pointer to a cache block
3568
in the main area where the new information should be put. The tag of
3569
that cache block is invalidated; the calling routine should take care
3570
of filling it and giving it a valid tag in due time. The cache's |filler|
3571
routine should not be active when |alloc_slot| is called.
3572
 
3573
Inserting new information might also require writing old information
3574
into the next level of the memory hierarchy, if the block being replaced
3575
is dirty. This routine returns |NULL| in such cases if the cache is
3576
flushing a previously discarded block.
3577
Otherwise it schedules the |flusher| coroutine.
3578
 
3579
This routine returns |NULL| also if the given key happens to be in the
3580
cache. Such cases are rare, but the following scenario shows that
3581
they aren't impossible: Suppose the DT-cache access time is 5, the D-cache
3582
access time is~1, and two processes simultaneously look for the
3583
same physical address. One process hits in DT-cache but misses in D-cache,
3584
waiting 5 cycles before trying |alloc_slot| in the D-cache; meanwhile
3585
the other process missed in D-cache but didn't need to use the DT-cache,
3586
so it might have updated the D-cache.
3587
 
3588
A key value is never negative. Therefore we can invalidate the tag in
3589
the chosen slot by forcing it to be negative.
3590
 
3591
@=
3592
static cacheblock* alloc_slot @,@,@[ARGS((cache*,octa))@];
3593
 
3594
@ @=
3595
static cacheblock* alloc_slot(c,alf)
3596
  cache *c;
3597
  octa alf; /* key that probably isn't in the cache */
3598
{
3599
  register cacheset s;
3600
  register cacheblock *p,*q;
3601
  if (cache_search(c,alf)) return NULL;
3602
  s=cache_addr(c,alf); /* the set corresponding to |alf| */
3603
  if (c->victim) p=choose_victim(c->victim,c->vv,c->vrepl);
3604
  else p=choose_victim(s,c->aa,c->repl);
3605
  if (is_dirty(c,p)) {
3606
    if (c->flusher.next) return NULL;
3607
    flush_cache(c,p,false);
3608
  }
3609
  if (c->victim) {
3610
    q=choose_victim(s,c->aa,c->repl);
3611
    @;
3612
    q->tag.h |= sign_bit; /* invalidate the tag */
3613
    return q;
3614
  }
3615
  p->tag.h |= sign_bit;@+ return p;
3616
}
3617
 
3618
@* Simulated memory. How should we deal with the potentially gigantic
3619
memory of~\MMIX? We can't simply declare an array~$m$ that has
3620
$2^{48}$ bytes. (Indeed, up to $2^{63}$ bytes are needed, if we
3621
consider also the physical addresses $\ge2^{48}$ that are reserved for
3622
memory-mapped input/output.)
3623
 
3624
We could regard memory as a special kind of cache,
3625
in which every access is required to hit. For example, such an ``M-cache''
3626
could be fully associative, with $2^a$ blocks each
3627
having a different tag; simulation could proceed until more than~$2^a-1$ tags
3628
are required. But then the predefined value of~$a$ might well be so large that
3629
the sequential search of our |cache_search| routine would be too slow.
3630
 
3631
Instead, we will allocate memory in chunks of $2^{16}$ bytes at a time,
3632
as needed, and we will use hashing to search for the relevant chunk
3633
whenever a physical address is given. If the address is $2^{48}$ or greater,
3634
special routines called |spec_read| and |spec_write|, supplied by the
3635
user, will be called upon to do the reading or writing. Otherwise
3636
the 48-bit address consists of a 32-bit {\it chunk address\/} and a
3637
16-bit {\it chunk offset}.
3638
 
3639
Chunk addresses that are not used take no space in this simulator. But if,
3640
say, 1000 such patterns occur, the simulator will dynamically allocate
3641
approximately 65MB for the portions of main memory that are used.
3642
Parameter |mem_chunks_max| specifies the largest number of different chunk
3643
addresses that are supported. This parameter does not constrain the range of
3644
simulated physical addresses, which cover the entire 256 large-terabyte range
3645
permitted by~\MMIX.
3646
 
3647
@=
3648
typedef struct {
3649
  tetra tag; /* 32-bit chunk address */
3650
  octa *chunk; /* either |NULL| or an array of $2^{13}$ octabytes */
3651
} chunknode;
3652
 
3653
@ The parameter |hash_prime| should be a prime number larger than the
3654
parameter
3655
|mem_chunks_max|, preferably more than twice as large but not much bigger
3656
than~that. The default values |mem_chunks_max=1000| and |hash_prime=2003| are
3657
set by |MMIX_config| unless the user specifies otherwise.
3658
 
3659
@=
3660
Extern int mem_chunks; /* this many chunks are allocated so far */
3661
Extern int mem_chunks_max; /* up to this many different chunks per run */
3662
Extern int hash_prime; /* larger than |mem_chunks_max|, but not enormous */
3663
Extern chunknode *mem_hash; /* the simulated main memory */
3664
 
3665
@ The separately compiled procedures |spec_read()| and |spec_write()| have the
3666
same calling conventions as the general procedures
3667
|mem_read()| and |mem_write()|.
3668
 
3669
@=
3670
extern octa spec_read @,@,@[ARGS((octa addr))@]; /* for memory mapped I/O */
3671
extern void spec_write @,@,@[ARGS((octa addr,octa val))@]; /* likewise */
3672
 
3673
@ If the program tries to read from a chunk that hasn't been allocated,
3674
the value zero is returned, optionally with a comment to the user.
3675
 
3676
Chunk address 0 is always allocated first. Then we can assume that
3677
a matching chunk tag implies a nonnull |chunk| pointer.
3678
 
3679
This routine sets |last_h| to the chunk found, so that we can rapidly read
3680
other words that we know must belong to the same chunk. For this purpose
3681
it is convenient to let |mem_hash[hash_prime]| be a chunk full of zeros,
3682
representing uninitialized memory.
3683
 
3684
@=
3685
Extern octa mem_read @,@,@[ARGS((octa addr))@];
3686
 
3687
@ @=
3688
octa mem_read(addr)
3689
  octa addr;
3690
{
3691
  register tetra off,key;
3692
  register int h;
3693
  if (addr.h>=(1<<16)) return spec_read(addr);
3694
  off=(addr.l&0xffff)>>3;
3695
  key=(addr.l&0xffff0000)+addr.h;
3696
  for (h=key%hash_prime;mem_hash[h].tag!=key;h--) {
3697
    if (mem_hash[h].chunk==NULL) {
3698
      if (verbose&uninit_mem_bit)
3699
        errprint2("uninitialized memory read at %08x%08x",addr.h,addr.l);
3700
@.uninitialized memory...@>
3701
      h=hash_prime;@+ break; /* zero will be returned */
3702
    }
3703
    if (h==0) h=hash_prime;
3704
  }
3705
  last_h=h;
3706
  return mem_hash[h].chunk[off];
3707
}
3708
 
3709
@ @=
3710
Extern int last_h; /* the hash index that was most recently correct */
3711
 
3712
@ @=
3713
Extern void mem_write @,@,@[ARGS((octa addr,octa val))@];
3714
 
3715
@ @=
3716
void mem_write(addr,val)
3717
  octa addr,val;
3718
{
3719
  register tetra off,key;
3720
  register int h;
3721
  if (addr.h>=(1<<16)) {@+spec_write(addr,val);@+return;@+}
3722
  off=(addr.l&0xffff)>>3;
3723
  key=(addr.l&0xffff0000)+addr.h;
3724
  for (h=key%hash_prime;mem_hash[h].tag!=key;h--) {
3725
    if (mem_hash[h].chunk==NULL) {
3726
      if (++mem_chunks>mem_chunks_max)
3727
        panic(errprint1("More than %d memory chunks are needed",
3728
@.More...chunks are needed@>
3729
                 mem_chunks_max));
3730
      mem_hash[h].chunk=(octa *)calloc(1<<13,sizeof(octa));
3731
      if (mem_hash[h].chunk==NULL)
3732
        panic(errprint1("I can't allocate memory chunk number %d",
3733
@.I can't allocate...@>
3734
                 mem_chunks));
3735
      mem_hash[h].tag=key;
3736
      break;
3737
    }
3738
    if (h==0) h=hash_prime;
3739
  }
3740
  last_h=h;
3741
  mem_hash[h].chunk[off]=val;
3742
}
3743
 
3744
@ The memory is characterized by several parameters, depending on the
3745
characteristics of the memory bus being simulated. Let |bus_words|
3746
be the number of octabytes read or written simultaneously (usually
3747
|bus_words| is 1 or~2; it must be a power of~2). The number of clock
3748
cycles needed to read or write |c*bus_words| octabytes that all belong to the
3749
same cache block is assumed to be |mem_addr_time+c*mem_read_time| or
3750
|mem_addr_time+c*mem_write_time|, respectively.
3751
 
3752
@=
3753
Extern int mem_addr_time; /* cycles to transmit an address on memory bus */
3754
Extern int bus_words; /* width of memory bus, in octabytes */
3755
Extern int mem_read_time; /* cycles to read from main memory */
3756
Extern int mem_write_time; /* cycles to write to main memory */
3757
Extern lockvar mem_lock; /* is nonnull when the bus is busy */
3758
 
3759
@ One of the principal ways to write memory is to invoke
3760
a |flush_to_mem| coroutine,
3761
which is the |Scache->flusher| if there is an S-cache, or the
3762
|Dcache->flusher| if there is a D-cache but no S-cache.
3763
 
3764
When such a coroutine is started, its |data->ptr_a| will be |Scache|
3765
or~|Dcache|. The data to be written will just have been copied to the cache's
3766
|outbuf|.
3767
 
3768
@=
3769
case flush_to_mem: {@+register cache *c=(cache *)data->ptr_a;
3770
 switch (data->state) {
3771
  case 0:@+ if (mem_lock) wait(1);
3772
    data->state=1;
3773
  case 1: set_lock(self,mem_lock);
3774
    data->state=2;
3775
    @outbuf| and wait for the bus@>;
3776
  case 2: goto terminate; /* this frees |mem_lock| and |c->outbuf| */
3777
 }
3778
}
3779
 
3780
@ @outbuf| and wait for the bus@>=
3781
{
3782
  register int off,last_off,count,first,ii;
3783
  register int del=c->gg>>3; /* octabytes per granule */
3784
  octa addr;
3785
  addr=c->outbuf.tag;@+ off=(addr.l&0xffff)>>3;
3786
  for (i=j=0,first=1,count=0;jbb>>c->g;j++) {
3787
    ii=i+del;
3788
    if (!c->outbuf.dirty[j]) i=ii,off+=del,addr.l+=del<<3;
3789
    else@+ while (i
3790
      if (first) {
3791
        count++;@+ last_off=off;@+ first=0;
3792
        mem_write(addr,c->outbuf.data[i]);
3793
      }@+else {
3794
        if ((off^last_off)&(-bus_words)) count++;
3795
        last_off=off;
3796
        mem_hash[last_h].chunk[off]=c->outbuf.data[i];
3797
      }
3798
      i++;@+ off++;@+ addr.l+=8;
3799
    }
3800
  }
3801
  wait(mem_addr_time+count*mem_write_time);
3802
}
3803
 
3804
@* Cache transfers. We have seen that the |Dcache->flusher| sends
3805
data directly to the main memory if there is no S-cache.
3806
But if both D-cache and S-cache exist, the |Dcache->flusher| is a
3807
more complicated coroutine of type |flush_to_S|. In this case we need
3808
to deal with the fact that the S-cache blocks might be larger than
3809
the D-cache blocks; furthermore, the S-cache might have a
3810
write-around and/or write-through policy, etc. But one simplifying
3811
fact does help us: We know that the flusher coroutine will not be
3812
aborted until it has run to completion.
3813
 
3814
Some machines, such as the Alpha 21164, have an additional cache between
3815
the S-cache and memory, called the B-cache (the ``backup cache''). A B-cache
3816
could be simulated by extending the logic used here; but such extensions
3817
of the present program are left to the interested reader.
3818
 
3819
@=
3820
case flush_to_S: {@+register cache *c=(cache *)data->ptr_a;
3821
  register int block_diff=Scache->bb-c->bb;
3822
  p=(cacheblock*)data->ptr_b;
3823
 switch (data->state) {
3824
  case 0:@+ if (Scache->lock) wait(1);
3825
    data->state=1;
3826
  case 1: set_lock(self,Scache->lock);
3827
    data->ptr_b=(void*)cache_search(Scache,c->outbuf.tag);
3828
    if (data->ptr_b) data->state=4;
3829
    else if (Scache->mode & WRITE_ALLOC) data->state=(block_diff? 2: 3);
3830
    else data->state=6;
3831
    wait(Scache->access_time);
3832
  case 2: @inbuf| with clean memory data@>;
3833
  case 3: @;
3834
    if (block_diff) @inbuf| to slot |p|@>;
3835
  case 4: copy_block(c,&(c->outbuf),Scache,p);
3836
    hit_set=cache_addr(Scache,c->outbuf.tag);@+ use_and_fix(Scache,p);
3837
                   /* |p| not moved */
3838
    data->state=5;@+ wait(Scache->copy_in_time);
3839
  case 5:@+ if ((Scache->mode&WRITE_BACK)==0) { /* write-through */
3840
      if (Scache->flusher.next) wait(1);
3841
      flush_cache(Scache,p,true);
3842
    }
3843
    goto terminate;
3844
  case 6:@;
3845
 }
3846
}
3847
 
3848
@ @=
3849
if (Scache->filler.next) wait(1); /* perhaps an unnecessary precaution? */
3850
p=alloc_slot(Scache,c->outbuf.tag);
3851
if (!p) wait(1);
3852
data->ptr_b=(void*)p;
3853
p->tag=c->outbuf.tag;@+ p->tag.l=c->outbuf.tag.l&(-Scache->bb);
3854
 
3855
@ We only need to read |block_diff| bytes, but it's easier to
3856
read them all and to charge only for reading the ones we needed.
3857
 
3858
@inbuf| with clean memory data@>=
3859
{@+register int count=block_diff>>3;
3860
  register int off,delay;
3861
  octa addr;
3862
  if (mem_lock) wait(1);
3863
  addr.h=c->outbuf.tag.h;@+ addr.l=c->outbuf.tag.l&-Scache->bb;
3864
  off=(addr.l&0xffff)>>3;
3865
  for (j=0;jbb>>3;j++)
3866
    if (j==0) Scache->inbuf.data[j]=mem_read(addr);
3867
    else Scache->inbuf.data[j]=mem_hash[last_h].chunk[j+off];
3868
  set_lock(&mem_locker,mem_lock);
3869
  delay=mem_addr_time+(int)((count+bus_words-1)/(bus_words))*mem_read_time;
3870
  startup(&mem_locker,delay);
3871
  data->state=3;@+ wait(delay);
3872
}
3873
 
3874
@ @inbuf| to slot |p|@>=
3875
{
3876
  register octa *d=p->data;
3877
  p->data=Scache->inbuf.data;@+Scache->inbuf.data=d;
3878
}
3879
 
3880
@ Here we assume that the granularity is~8.
3881
 
3882
@=
3883
if (Scache->flusher.next) wait(1);
3884
Scache->outbuf.tag.h=c->outbuf.tag.h;
3885
Scache->outbuf.tag.l=c->outbuf.tag.l&(-Scache->bb);
3886
for (j=0;jbb>>Scache->g;j++) Scache->outbuf.dirty[j]=false;
3887
copy_block(c,&(c->outbuf),Scache,&(Scache->outbuf));
3888
startup(&Scache->flusher,Scache->copy_out_time);
3889
goto terminate;
3890
 
3891
@ The S-cache gets new data from memory by invoking a |fill_from_mem|
3892
coroutine; the I-cache or D-cache may also invoke a |fill_from_mem| coroutine,
3893
if there is no S-cache. When such a coroutine is invoked, it holds
3894
|mem_lock|, and its caller has gone to sleep.
3895
A physical memory address is given in |data->z.o|,
3896
and |data->ptr_a| specifies either |Icache| or |Dcache|.
3897
Furthermore, |data->ptr_b| specifies a block within that
3898
cache, determined by the |alloc_slot| routine. The coroutine
3899
simulates reading the contents of the specified memory location,
3900
places the result in the |x.o| field of its caller's control block,
3901
and wakes up the caller. It proceeds to fill the cache's |inbuf| and,
3902
ultimately, the specified cache block, before waking the caller again.
3903
 
3904
Let |c=data->ptr_b|. The caller is then |c->fill_lock|, if this variable is
3905
nonnull. However, the caller might not wish to be awoken or to receive
3906
the data (for example, if it has been aborted). In such cases |c->fill_lock|
3907
will be~|NULL|; the filling action continues without the wakeup calls.
3908
If |c=Scache|, the S-cache will be locked and the caller will not
3909
have been aborted.
3910
 
3911
@=
3912
case fill_from_mem: {@+register cache *c=(cache *)data->ptr_a;
3913
  register coroutine *cc=c->fill_lock;
3914
 switch (data->state) {
3915
  case 0: data->x.o=mem_read(data->z.o);
3916
    if (cc) {
3917
      cc->ctl->x.o=data->x.o;
3918
      awaken(cc,mem_read_time);
3919
    }
3920
    data->state=1;
3921
    @inbuf| and wait for the bus@>;
3922
  case 1: release_lock(self,mem_lock);
3923
    data->state=2;
3924
  case 2:@+if (c!=Scache) {
3925
      if (c->lock) wait(1);
3926
      set_lock(self,c->lock);
3927
    }
3928
    if (cc) awaken(cc,c->copy_in_time); /* the second wakeup call */
3929
    load_cache(c,(cacheblock*)data->ptr_b);
3930
    data->state=3;@+ wait(c->copy_in_time);
3931
  case 3: goto terminate;
3932
 }
3933
}
3934
 
3935
@ If |c|'s cache size is no larger than the memory bus, we wait an extra
3936
cycle, so that there will be two wakeup calls.
3937
 
3938
@inbuf|...@>=
3939
{
3940
  register int count, off;
3941
  c->inbuf.tag=data->z.o;@+ c->inbuf.tag.l &= -c->bb;
3942
  count=c->bb>>3, off=(c->inbuf.tag.l&0xffff)>>3;
3943
  for (i=0;iinbuf.data[i]=mem_hash[last_h].chunk[off];
3944
  if (count<=bus_words) wait(1+mem_read_time)@;
3945
  else wait((int)(count/bus_words)*mem_read_time);
3946
}
3947
 
3948
@ The |fill_from_S| coroutine has the same conventions as |fill_from_mem|,
3949
except that the data comes directly from the S-cache if it is present there.
3950
This is the |filler| coroutine for the I-cache and D-cache if an S-cache
3951
is present.
3952
 
3953
@=
3954
case fill_from_S: {@+register cache *c=(cache *)data->ptr_a;
3955
  register coroutine *cc=c->fill_lock;
3956
  p=(cacheblock*)data->ptr_c;
3957
  switch (data->state) {
3958
  case 0: p=cache_search(Scache,data->z.o);
3959
    if (p) goto S_non_miss;
3960
    data->state=1;
3961
  case 1: @;
3962
    data->state=2;@+sleep;
3963
  case 2:@+if (cc) {
3964
      cc->ctl->x.o=data->x.o;
3965
            /* this data has been supplied by |Scache->filler| */
3966
      awaken(cc,Scache->access_time); /* we propagate it back */
3967
    }
3968
    data->state=3;@+sleep; /* when we awake, the S-cache will have our data */
3969
  S_non_miss:@+if (cc) {
3970
      cc->ctl->x.o=p->data[(data->z.o.l&(Scache->bb-1))>>3];
3971
      awaken(cc,Scache->access_time);
3972
    }
3973
  case 3: @inbuf|@>;
3974
    data->state=4;@+wait(Scache->access_time);
3975
  case 4:@+ if (c->lock) wait(1);
3976
    set_lock(self,c->lock);
3977
    Scache->lock=NULL; /* we had been holding that lock */
3978
    load_cache(c,(cacheblock*)data->ptr_b);
3979
    data->state=5;@+ wait(c->copy_in_time);
3980
  case 5:@+if (cc) awaken(cc,1); /* second wakeup call */
3981
    goto terminate;
3982
  }
3983
}
3984
 
3985
@ We are already holding the |Scache->lock|, but we're about to take on the
3986
|Scache->fill_lock| too (with the understanding that one is ``stronger''
3987
than the other). For a short time the |Scache->lock| will point to us
3988
but we will point to |Scache->fill_lock|; this will not cause difficulty,
3989
because the present coroutine is not abortable.
3990
 
3991
@=
3992
if (Scache->filler.next || mem_lock) wait(1);
3993
p=alloc_slot(Scache,data->z.o);
3994
if (!p) wait(1);
3995
set_lock(&Scache->filler,mem_lock);
3996
set_lock(self,Scache->fill_lock);
3997
data->ptr_c=Scache->filler_ctl.ptr_b=(void *)p;
3998
Scache->filler_ctl.z.o=data->z.o;
3999
startup(&Scache->filler,mem_addr_time);
4000
 
4001
@ The S-cache blocks might be wider than the blocks of the I-cache or
4002
D-cache, so the copying in this step isn't quite trivial.
4003
 
4004
@inbuf|@>=
4005
{@+register int off;
4006
  c->inbuf.tag=data->z.o;@+c->inbuf.tag.l &=-c->bb;
4007
  for (j=0,off=(c->inbuf.tag.l&(Scache->bb-1))>>3;jbb>>3;j++,off++)
4008
    c->inbuf.data[j]=p->data[off];
4009
  release_lock(self,Scache->fill_lock);
4010
  set_lock(self,Scache->lock);
4011
}
4012
 
4013
@ The instruction \.{PRELD} \.{X,\$Y,\$Z} generates $\lfloor{\rm X}/2^b\rfloor$
4014
commands if there are $2^b$ bytes per block in the D-cache. These
4015
commands will try to preload blocks $\rm\$Y+\$Z$, ${\rm\$Y}+{\rm\$Z}+2^b$,
4016
\dots, into the cache if it is not too busy.
4017
 
4018
Similar considerations apply to the instructions \.{PREGO} \.{X,\$Y,\$Z}
4019
and \.{PREST} \.{X,\$Y,\$Z}.
4020
 
4021
@=
4022
case preld: case prest:@+ if (!Dcache) goto noop_inst;
4023
  if (cool->xx>=Dcache->bb) cool->interim=true;
4024
  cool->ptr_a=(void *)mem.up;@+ break;
4025
case prego:@+ if (!Icache) goto noop_inst;
4026
  if (cool->xx>=Icache->bb) cool->interim=true;
4027
  cool->ptr_a=(void *)mem.up;@+ break;
4028
 
4029
@ If the block size is 64, a command like \.{PREST}~\.{200,\$Y,\$Z}
4030
is actually issued as four commands \.{PREST}~\.{200,\$Y,\$Z;}
4031
\.{PREST}~\.{191,\$Y,\$Z;}  \.{PREST}~\.{127,\$Y,\$Z;}
4032
\.{PREST}~\.{63,\$Y,\$Z}. An interruption will then be able to resume
4033
properly. In the pipeline, the instruction \.{PREST}~\.{200,\$Y,\$Z}
4034
is considered to affect bytes $\rm\$Y+\$Z+192$ through $\rm\$Y+\$Z+200$,
4035
or fewer bytes if $\rm\$Y+\$Z$ is not a multiple of~64. (Remember that
4036
these instructions are only hints; we act on them only if it is
4037
reasonably convenient to do so.)
4038
 
4039
@=
4040
head->inst = (head->inst&~((Dcache->bb-1)<<16))-0x10000;
4041
 
4042
@ @=
4043
head->inst = (head->inst&~((Icache->bb-1)<<16))-0x10000;
4044
 
4045
@ Another coroutine, called |cleanup|, is occasionally called into
4046
action to remove dirty data from the D-cache and S-cache. If it is
4047
invoked by starting in state 0, with its |i| field set to |sync|, it
4048
will clean everything. It can also be
4049
invoked in state~4, with its |i| field set to |syncd| and with a physical
4050
address in its |z.o| field; then it simply makes sure that no D-cache
4051
or S-cache blocks associated with that address are dirty.
4052
 
4053
Field |x.o.h| should be set to zero if items are expected to remain
4054
in the cache after being cleaned; otherwise field |x.o.h| should be
4055
set to |sign_bit|.
4056
 
4057
The coroutine that invokes |cleanup| should hold |clean_lock|. If that
4058
coroutine dies, because of an interruption, the |cleanup| coroutine
4059
will terminate prematurely.
4060
 
4061
We assume that the D-cache and S-cache have some sort of way to
4062
identify their first dirty block, if any, in |access_time| cycles.
4063
 
4064
@=
4065
coroutine clean_co;
4066
control clean_ctl;
4067
lockvar clean_lock;
4068
 
4069
@ @=
4070
clean_co.ctl=&clean_ctl;
4071
clean_co.name="Clean";
4072
clean_co.stage=cleanup;
4073
clean_ctl.go.o.l=4;
4074
 
4075
@ @=
4076
case cleanup: p=(cacheblock*)data->ptr_b;
4077
  switch(data->state) {
4078
@;
4079
@;
4080
case 10: goto terminate;
4081
}
4082
 
4083
@ @=
4084
case 0:@+ if (Dcache->lock || (j=get_reader(Dcache)<0)) wait(1);
4085
  startup(&Dcache->reader[j],Dcache->access_time);
4086
  set_lock(self,Dcache->lock);
4087
  i=j=0;
4088
Dclean_loop: p=(icc? &(Dcache->set[i][j]): &(Dcache->victim[j]));
4089
  if (p->tag.h&sign_bit) goto Dclean_inc;
4090
  if (!is_dirty(Dcache,p)) {
4091
    p->tag.h|=data->x.o.h;@+goto Dclean_inc;
4092
  }
4093
  data->y.o.h=i, data->y.o.l=j;
4094
Dclean: data->state=1;@+
4095
  data->ptr_b=(void*)p;@+
4096
  wait(Dcache->access_time);
4097
case 1:@+if (Dcache->flusher.next) wait(1);
4098
  flush_cache(Dcache,p,data->x.o.h==0);
4099
  p->tag.h|=data->x.o.h;
4100
  release_lock(self,Dcache->lock);
4101
  data->state=2;@+
4102
  wait(Dcache->copy_out_time);
4103
case 2:@+ if (!clean_lock) goto done; /* premature termination */
4104
  if (Dcache->flusher.next) wait(1);
4105
  if (data->i!=sync) goto Sprep;
4106
  data->state=3;
4107
case 3:@+ if (Dcache->lock || (j=get_reader(Dcache)<0)) wait(1);
4108
  startup(&Dcache->reader[j],Dcache->access_time);
4109
  set_lock(self,Dcache->lock);
4110
  i=data->y.o.h, j=data->y.o.l;
4111
Dclean_inc: j++;
4112
  if (icc && j==Dcache->aa) j=0, i++;
4113
  if (i==Dcache->cc && j==Dcache->vv) {
4114
    data->state=5;@+
4115
    wait(Dcache->access_time);
4116
  }
4117
  goto Dclean_loop;
4118
case 4:@+ if (Dcache->lock || (j=get_reader(Dcache)<0)) wait(1);
4119
  startup(&Dcache->reader[j],Dcache->access_time);
4120
  set_lock(self,Dcache->lock);
4121
  p=cache_search(Dcache,data->z.o);
4122
  if (p) {
4123
    demote_and_fix(Dcache,p);
4124
    if (is_dirty(Dcache,p)) goto Dclean;
4125
  }
4126
  data->state=9;@+
4127
  wait(Dcache->access_time);
4128
 
4129
@ @=
4130
case 5:@+ if (self->lockloc) *(self->lockloc)=NULL, self->lockloc=NULL;
4131
  if (!Scache) goto done;
4132
  if (Scache->lock) wait(1);
4133
  set_lock(self,Scache->lock);
4134
  i=j=0;
4135
Sclean_loop: p=(icc? &(Scache->set[i][j]): &(Scache->victim[j]));
4136
  if (p->tag.h&sign_bit) goto Sclean_inc;
4137
  if (!is_dirty(Scache,p)) {
4138
    p->tag.h|=data->x.o.h;@+goto Sclean_inc;
4139
  }
4140
  data->y.o.h=i, data->y.o.l=j;
4141
Sclean: data->state=6;@+
4142
  data->ptr_b=(void*)p;@+
4143
  wait(Scache->access_time);
4144
case 6:@+if (Scache->flusher.next) wait(1);
4145
  flush_cache(Scache,p,data->x.o.h==0);
4146
  p->tag.h|=data->x.o.h;
4147
  release_lock(self,Scache->lock);
4148
  data->state=7;@+
4149
  wait(Scache->copy_out_time);
4150
case 7:@+ if (!clean_lock) goto done; /* premature termination */
4151
  if (Scache->flusher.next) wait(1);
4152
  if (data->i!=sync) goto done;
4153
  data->state=8;
4154
case 8:@+ if (Scache->lock) wait(1);
4155
  set_lock(self,Scache->lock);
4156
  i=data->y.o.h, j=data->y.o.l;
4157
Sclean_inc: j++;
4158
  if (icc && j==Scache->aa) j=0, i++;
4159
  if (i==Scache->cc && j==Scache->vv) {
4160
    data->state=10;@+
4161
    wait(Scache->access_time);
4162
  }
4163
  goto Sclean_loop;
4164
Sprep: data->state=9;
4165
case 9:@+if (self->lockloc) release_lock(self,Dcache->lock);
4166
  if (!Scache) goto done;
4167
  if (Scache->lock) wait(1);
4168
  set_lock(self,Scache->lock);
4169
  p=cache_search(Scache,data->z.o);
4170
  if (p) {
4171
    demote_and_fix(Scache,p);
4172
    if (is_dirty(Scache,p)) goto Sclean;
4173
  }
4174
  data->state=10;@+
4175
  wait(Scache->access_time);
4176
 
4177
@* Virtual address translation. Special arrays of coroutines and control
4178
blocks come into play when we need to implement \MMIX's rather complicated
4179
page table mechanism for virtual address translation. In effect, we have up to
4180
ten control blocks {\it outside\/} of the reorder buffer that are capable of
4181
executing instructions just as if they were part of that buffer. The
4182
``opcodes'' of these non-abortable instructions are special internal
4183
operations called |ldptp| and |ldpte|, for loading page table pointers and
4184
page table entries.
4185
 
4186
Suppose, for example, that we need to translate a virtual address for the
4187
DT-cache in which the virtual page address $(a_4a_3a_2a_1a_0)_{1024}$ of
4188
segment~$i$ has $a_4=a_3=0$ and $a_2\ne0$. Then the rules say that we should
4189
first find a page table pointer $p_2$ in physical location
4190
$2^{13}(r+b_i+2)+8a_2$, then another page table pointer~$p_1$ in location
4191
$p_2+8a_1$, and finally the page table entry~$p_0$ in location $p_1+8a_0$. The
4192
simulator achieves this by setting up three coroutines $c_0$, $c_1$, $c_2$
4193
whose control blocks correspond to the pseudo-instructions
4194
$$\vbox{\halign{\tt#\hfil\cr
4195
LDPTP $x$,[$2^{63}+2^{13}(r+b_i+2)$],$8a_2$\cr
4196
LDPTP $x$,$x$,$8a_1$\cr
4197
LDPTE $x$,$x$,$8a_0$\cr}}$$
4198
where $x$ is a hidden internal register and the other quantities are immediate
4199
values. Slight changes to the normal functionality of \.{LDO} give us the
4200
actions needed to implement \.{LDPTP} and \.{LDPTE}. Coroutine~$c_j$
4201
corresponds to the instruction that involves $a_j$ and computes~$p_j$; when
4202
$c_0$ has computed its value~$p_0$, we know how to translate the original
4203
virtual address.
4204
 
4205
The \.{LDPTP} and \.{LDPTE} commands return zero
4206
if their $y$~operand is zero or if the page table does not properly match~rV.
4207
 
4208
@d LDPTP PREGO /* internally this won't cause confusion */
4209
@d LDPTE GO
4210
 
4211
@=
4212
control IPTctl[5], DPTctl[5]; /* control blocks for I and D page translation */
4213
coroutine IPTco[10], DPTco[10]; /* each coroutine is a two-stage pipeline */
4214
char *IPTname[5]={"IPT0","IPT1","IPT2","IPT3","IPT4"};
4215
char *DPTname[5]={"DPT0","DPT1","DPT2","DPT3","DPT4"};
4216
 
4217
@ @=
4218
for (j=0;j<5;j++) {
4219
  DPTco[2*j].ctl=&DPTctl[j];@+  IPTco[2*j].ctl=&IPTctl[j];
4220
  if (j>0) DPTctl[j].op=IPTctl[j].op=LDPTP,DPTctl[j].i=IPTctl[j].i=ldptp;
4221
  else DPTctl[0].op=IPTctl[0].op=LDPTE,DPTctl[0].i=IPTctl[0].i=ldpte;
4222
  IPTctl[j].loc=DPTctl[j].loc=neg_one;
4223
  IPTctl[j].go.o=DPTctl[j].go.o=incr(neg_one,4);
4224
  IPTctl[j].ptr_a=DPTctl[j].ptr_a=(void*)&mem;
4225
  IPTctl[j].ren_x=DPTctl[j].ren_x=true;
4226
  IPTctl[j].x.addr.h=DPTctl[j].x.addr.h=-1;
4227
  IPTco[2*j].stage=DPTco[2*j].stage=1;
4228
  IPTco[2*j+1].stage=DPTco[2*j+1].stage=2;
4229
  IPTco[2*j].name=IPTco[2*j+1].name=IPTname[j];
4230
  DPTco[2*j].name=DPTco[2*j+1].name=DPTname[j];
4231
}
4232
ITcache->filler_ctl.ptr_c=(void*)&IPTco[0];@+
4233
DTcache->filler_ctl.ptr_c=(void*)&DPTco[0];
4234
 
4235
@ Page table calculations are invoked by a coroutine of type |fill_from_virt|,
4236
which is used to fill the IT-cache or DT-cache. The calling conventions of
4237
|fill_from_virt| are analogous to those of |fill_from_mem| or |fill_from_S|:
4238
A virtual address is supplied in |data->y.o|, and |data->ptr_a| points
4239
to a cache (|ITcache| or |DTcache|), while |data->ptr_b| is a block in that
4240
cache. We wake up the caller, who holds the cache's |fill_lock|, as soon as
4241
the translation of the given address has been calculated, unless the caller
4242
has been aborted. (No second wakeup call is necessary.)
4243
 
4244
@=
4245
case fill_from_virt: {@+register cache *c=(cache *)data->ptr_a;
4246
  register coroutine *cc=c->fill_lock;
4247
  register coroutine *co=(coroutine*)data->ptr_c;
4248
                          /* |&IPTco[0]| or |&DPTco[0]| */
4249
  octa aaaaa;
4250
 switch (data->state) {
4251
  case 0: @;
4252
    data->state=1;
4253
  case 1:@+if (data->b.p) {
4254
      if (data->b.p->known) data->b.o=data->b.p->o, data->b.p=NULL;
4255
      else wait(1);
4256
    }
4257
    @inbuf| and give the caller a sneak
4258
              preview@>;
4259
    data->state=2;
4260
  case 2:@+if (c->lock) wait(1);
4261
    set_lock(self,c->lock);
4262
    load_cache(c,(cacheblock*)data->ptr_b);
4263
    data->state=3;@+ wait(c->copy_in_time);
4264
  case 3: data->b.o=zero_octa;@+goto terminate;
4265
 }
4266
}
4267
 
4268
@ The current contents of rV, the special virtual translation register, are
4269
kept unpacked in several global variables |page_r|, |page_s|, etc., for
4270
convenience. Whenever rV changes, we recompute all these variables.
4271
 
4272
@=
4273
int page_n; /* the 10-bit |n| field of rV, times 8 */
4274
int page_r; /* the 27-bit |r| field of rV */
4275
int page_s; /* the 8-bit |s| field of rV */
4276
int page_b[5]; /* the 4-bit |b| fields of rV; |page_b[0]=0| */
4277
octa page_mask; /* the least significant |s| bits */
4278
bool page_bad=true; /* does rV violate the rules? */
4279
 
4280
@ @=
4281
{@+octa rv;
4282
  rv=data->z.o;
4283
  page_bad=(rv.l&7? true: false);
4284
  page_n=rv.l&0x1ff8;
4285
  rv=shift_right(rv,13,1);
4286
  page_r=rv.l&0x7ffffff;
4287
  rv=shift_right(rv,27,1);
4288
  page_s=rv.l&0xff;
4289
  if (page_s<13 || page_s>48) page_bad=true;
4290
  else if (page_s<32) page_mask.h=0,page_mask.l=(1<
4291
  else page_mask.h=(1<<(page_s-32))-1,page_mask.l=0xffffffff;
4292
  page_b[4]=(rv.l>>8)&0xf;
4293
  page_b[3]=(rv.l>>12)&0xf;
4294
  page_b[2]=(rv.l>>16)&0xf;
4295
  page_b[1]=(rv.l>>20)&0xf;
4296
}
4297
 
4298
@ Here's how we compute a tag of the IT-cache or DT-cache
4299
from a virtual address, and how we compute a physical address
4300
from a translation found in the cache.
4301
 
4302
@d trans_key(addr) incr(oandn(addr,page_mask),page_n)
4303
 
4304
@=
4305
static octa phys_addr @,@,@[ARGS((octa,octa))@];
4306
 
4307
@ @=
4308
static octa phys_addr(virt,trans)
4309
  octa virt,trans;
4310
{@+octa t;
4311
  t=trans;@+ t.l &= -8; /* zero out the protection bits */
4312
  return oplus(t,oand(virt,page_mask));
4313
}
4314
 
4315
@ Cheap (and slow) versions of \MMIX\ leave the page table calculations
4316
to software. If the global variable |no_hardware_PT| is set true,
4317
|fill_from_virt| begins its actions in state~1, not state~0. (See the
4318
|RESUME_TRANS| operation.)
4319
 
4320
@=
4321
Extern bool no_hardware_PT;
4322
 
4323
@ Note: The operating system is supposed to ensure that changes to the page
4324
table entries do not appear in the pipeline when a translation cache is being
4325
updated. The internal \.{LDPTP} and \.{LDPTE} instructions use only the
4326
``hot state'' of the memory system.
4327
@^operating system@>
4328
 
4329
@=
4330
aaaaa=data->y.o;
4331
i=aaaaa.h>>29; /* the segment number */
4332
aaaaa.h&=0x1fffffff; /* the address within segment $i$ */
4333
aaaaa=shift_right(aaaaa,page_s,1); /* the page address */
4334
for (j=0;aaaaa.l!=0 || aaaaa.h!=0; j++) {
4335
  co[2*j].ctl->z.o.h=0, co[2*j].ctl->z.o.l=(aaaaa.l&0x3ff)<<3;
4336
  aaaaa=shift_right(aaaaa,10,1);
4337
}
4338
if (page_b[i+1]
4339
  ; /* nothing needs to be done, since |data->b.o| is zero */
4340
else {
4341
  if (j==0) j=1,co[0].ctl->z.o=zero_octa;
4342
  @;
4343
}
4344
 
4345
@ The first stage of coroutine $c_j$ is |co[2*j]|. It will pass the $j$th
4346
control block to the second stage, |co[2*j+1]|, which will load page table
4347
information from memory (or hopefully from the D-cache).
4348
 
4349
@=
4350
j--;
4351
aaaaa.l=page_r+page_b[i]+j;
4352
co[2*j].ctl->y.p=NULL;
4353
co[2*j].ctl->y.o=shift_left(aaaaa,13);
4354
co[2*j].ctl->y.o.h+=sign_bit;
4355
for (;;j--) {
4356
  co[2*j].ctl->x.o=zero_octa;@+ co[2*j].ctl->x.known=false;
4357
  co[2*j].ctl->owner=&co[2*j];
4358
  startup(&co[2*j],1);
4359
  if (j==0) break;
4360
  co[2*(j-1)].ctl->y.p=&co[2*j].ctl->x;
4361
}
4362
data->b.p=&co[0].ctl->x;
4363
 
4364
@ At this point the translation of the given virtual address |data->y.o| is
4365
the octabyte |data->b.o|. Its least significant three bits are the
4366
protection code~$p=p_rp_wp_x$; its page address field is scaled by~$2^s$. It
4367
is entirely zero, including the protection bits, if there was a
4368
page table failure.
4369
 
4370
@inbuf| and give the caller a sneak preview@>=
4371
c->inbuf.tag=trans_key(data->y.o);
4372
c->inbuf.data[0]=data->b.o;
4373
if (cc) {
4374
  cc->ctl->z.o=data->b.o;
4375
  awaken(cc,1);
4376
}
4377
 
4378
@* The write buffer. The dispatcher has arranged things so that speculative
4379
stores into memory are recorded in a doubly linked list leading upward from
4380
|mem|. When such instructions finally are committed, they enter the ``write
4381
buffer,'' which holds octabytes that are ready to be written into designated
4382
physical memory addresses (or into the D-cache and/or S-cache). The ``hot
4383
state'' of the computation is reflected not only by the registers and caches
4384
but also by the instructions that are pending in the write buffer.
4385
 
4386
@=
4387
typedef struct{
4388
  octa o; /* data to be stored */
4389
  octa addr; /* its physical address */
4390
  tetra stamp; /* when last committed (mod $2^{32}$) */
4391
  internal_opcode i; /* is this write special? */
4392
} write_node;
4393
 
4394
@ We represent the buffer in the usual way as a circular list, with elements
4395
|write_tail+1|, |write_tail+2|, \dots,~|write_head|.
4396
 
4397
The data will sit at least |holding_time| cycles before it leaves
4398
the write buffer. This speeds things up when different fields of the same
4399
octabyte are being stored by different instructions.
4400
 
4401
@=
4402
Extern write_node *wbuf_bot, *wbuf_top;
4403
 /* least and greatest write buffer nodes */
4404
Extern write_node *write_head, *write_tail;
4405
 /* front and rear of the write buffer */
4406
Extern lockvar wbuf_lock; /* is the data in |write_head| being written? */
4407
Extern int holding_time; /* minimum holding time */
4408
Extern lockvar speed_lock; /* should we ignore |holding_time|? */
4409
 
4410
@ @=
4411
coroutine write_co; /* coroutine that empties the write buffer */
4412
control write_ctl; /* its control block */
4413
 
4414
@ @=
4415
write_co.ctl=&write_ctl;
4416
write_co.name="Write";
4417
write_co.stage=write_from_wbuf;
4418
write_ctl.ptr_a=(void*)&mem;
4419
write_ctl.go.o.l=4;
4420
startup(&write_co,1);
4421
write_head=write_tail=wbuf_top;
4422
 
4423
@ @=
4424
static void print_write_buffer @,@,@[ARGS((void))@];
4425
 
4426
@ @=
4427
static void print_write_buffer()
4428
{
4429
  printf("Write buffer");
4430
  if (write_head==write_tail) printf(" (empty)\n");
4431
  else {@+register write_node *p;
4432
    printf(":\n");
4433
    for (p=write_head;p!=write_tail; p=(p==wbuf_bot? wbuf_top: p-1)) {
4434
      printf("m[");@+print_octa(p->addr);@+printf("]=");@+print_octa(p->o);
4435
      if (p->i==stunc) printf(" unc");
4436
      else if (p->i==sync) printf(" sync");
4437
      printf(" (age %d)\n",ticks.l-p->stamp);
4438
    }
4439
  }
4440
}
4441
 
4442
@ The entire present state of the pipeline computation can be visualized
4443
by printing first the write buffer, then the reorder buffer, then the
4444
fetch buffer. This shows the progression of results from oldest to youngest,
4445
from sizzling hot to ice cold.
4446
 
4447
@=
4448
Extern void print_pipe @,@,@[ARGS((void))@];
4449
 
4450
@ @=
4451
void print_pipe()
4452
{
4453
  print_write_buffer();
4454
  print_reorder_buffer();
4455
  print_fetch_buffer();
4456
}
4457
 
4458
@ The |write_search| routine looks to see if any instructions ahead of a given
4459
place in the |mem| list of the reorder buffer are storing into a given
4460
physical address, or if there's a pending instruction in the write buffer for
4461
that address. If so, it returns a pointer to the value to be written. If not,
4462
it returns~|NULL|. If the answer is currently unknown, because at least one
4463
possibly relevant physical address has not yet been computed, the subroutine
4464
returns the special code value~|DUNNO|.
4465
 
4466
The search starts at the |x.up| field of a control block for a store
4467
instruction, otherwise at the |ptr_a| field of the control block,
4468
unless |ptr_a| points to a committed instruction.
4469
 
4470
The |i| field in the write buffer is usually |st| or |pst|, inherited from
4471
a store or partial store command. It may also be |sync| (from \.{SYNC}~\.1
4472
or \.{SYNC}~\.3) or |stunc| (from \.{STUNC}).
4473
 
4474
@d DUNNO ((octa *)1) /* an impossible non-|NULL| pointer */
4475
 
4476
@=
4477
static octa* write_search @,@,@[ARGS((control*,octa))@];
4478
 
4479
@ @=
4480
static octa *write_search(ctl,addr)
4481
  control *ctl;
4482
  octa addr;
4483
{@+register specnode *p=(ctl->mem_x? ctl->x.up: (specnode*)ctl->ptr_a);
4484
  register write_node *q=write_tail;
4485
  addr.l &=-8;
4486
  if (p==&mem) goto qloop;
4487
  if (p > &hot->x && ctl <= hot) goto qloop; /* already committed */
4488
  if (p < &ctl->x && (ctl <= hot || p > &hot->x)) goto qloop;
4489
  for (; p!=&mem; p=p->up) {
4490
    if (p->addr.h==(tetra)-1) return DUNNO;
4491
    if ((p->addr.l&-8)==addr.l && p->addr.h==addr.h)
4492
      return (p->known? &(p->o): DUNNO);
4493
  }
4494
qloop:@+ for (;;) {
4495
    if (q==write_head) return NULL;
4496
    if (q==wbuf_top) q=wbuf_bot;@+ else q++;
4497
    if (q->addr.l==addr.l && q->addr.h==addr.h) return &(q->o);
4498
  }
4499
}
4500
 
4501
@ When we're committing new data to memory, we can update an existing item in
4502
the write buffer if it has the same physical address, unless that item is
4503
already in the process of being written out. Increasing the value of
4504
|holding_time| will increase the chance that this economy is possible, but
4505
it will also increase the number of buffered items when writes are to
4506
different locations.
4507
 
4508
A store instruction that sets any of the eight interrupt bits
4509
\.{rwxnkbsp} will not affect memory, even if it doesn't cause an interrupt.
4510
 
4511
When ``store'' is followed by ``store uncached'' at the same address,
4512
or vice versa, we believe the most recent hint.
4513
 
4514
@=
4515
{@+register write_node *q=write_tail;
4516
  if (hot->interrupt&(F_BIT+0xff)) goto done_with_write;
4517
  if (hot->i!=sync) for (;;) {
4518
    if (q==write_head) break;
4519
    if (q==wbuf_top) q=wbuf_bot;@+ else q++;
4520
    if (q->i==sync) break;
4521
    if (q->addr.l==hot->x.addr.l && q->addr.h==hot->x.addr.h
4522
             && (q!=write_head || !wbuf_lock)) goto addr_found;
4523
  }
4524
  {@+ register write_node *p=(write_tail==wbuf_bot? wbuf_top: write_tail-1);
4525
    if (p==write_head) break; /* the write buffer is full */
4526
    q=write_tail;@+ write_tail=p;
4527
    q->addr=hot->x.addr;
4528
  }
4529
addr_found: q->o=hot->x.o;
4530
  q->stamp=ticks.l;
4531
  q->i=hot->i;
4532
done_with_write: spec_rem(&(hot->x));
4533
  mem_slots++;
4534
}
4535
 
4536
@ A special coroutine whose duty is to empty the write buffer is always
4537
active. It holds the |wbuf_lock| while it is writing the contents of
4538
|write_head|. It holds |Dcache->fill_lock| while waiting for the D-cache
4539
to fill a block.
4540
 
4541
@=
4542
case write_from_wbuf:
4543
  p=(cacheblock*)data->ptr_b;
4544
  switch(data->state) {
4545
  case 4: @;
4546
    data->state=5;
4547
  case 5:@+if (write_head==wbuf_bot) write_head=wbuf_top;@+ else write_head--;
4548
 write_restart: data->state=0;
4549
  case 0:@+ if (self->lockloc) *(self->lockloc)=NULL,self->lockloc=NULL;
4550
    if (write_head==write_tail) wait(1); /* write buffer is empty */
4551
    if (write_head->i==sync) @;
4552
    if (ticks.l-write_head->stamp
4553
      wait(1); /* data too raw */
4554
    if (!Dcache || (write_head->addr.h&0xffff0000)) goto mem_direct;
4555
          /* not cached */
4556
    if (Dcache->lock || (j=get_reader(Dcache)<0)) wait(1); /* D-cache busy */
4557
    startup(&Dcache->reader[j],Dcache->access_time);
4558
    @
4559
                if there's a cache hit@>;
4560
    data->state=((Dcache->mode&WRITE_ALLOC) && write_head->i!=stunc? 1: 3);
4561
    wait(Dcache->access_time);
4562
  case 1: @addr|
4563
           into the D-cache@>;
4564
    data->state=2;@+sleep;
4565
  case 2: data->state=0;@+sleep; /* wake up when the D-cache has the block */
4566
  case 3: @;
4567
  mem_direct: @;
4568
}
4569
 
4570
@ @=
4571
register cacheblock *p,*q;
4572
 
4573
@ The granularity is guaranteed to be 8 in write-around mode
4574
(see |MMIX_config|). Although an uncached store will not be stored in the
4575
D-cache (unless it hits in the D-cache), it will go into a secondary cache.
4576
 
4577
@=
4578
if (Dcache->flusher.next) wait(1);
4579
Dcache->outbuf.tag.h=write_head->addr.h;
4580
Dcache->outbuf.tag.l=write_head->addr.l&(-Dcache->bb);
4581
for (j=0;jbb>>Dcache->g;j++) Dcache->outbuf.dirty[j]=false;
4582
Dcache->outbuf.data[(write_head->addr.l&(Dcache->bb-1))>>3]=write_head->o;
4583
Dcache->outbuf.dirty[(write_head->addr.l&(Dcache->bb-1))>>Dcache->g]=true;
4584
set_lock(self,wbuf_lock);
4585
startup(&Dcache->flusher,Dcache->copy_out_time);
4586
data->state=5;@+ wait(Dcache->copy_out_time);
4587
 
4588
@ @=
4589
if (mem_lock) wait(1);
4590
set_lock(self,wbuf_lock);
4591
set_lock(&mem_locker,mem_lock); /* a coroutine of type |vanish| */
4592
startup(&mem_locker,mem_addr_time+mem_write_time);
4593
mem_write(write_head->addr,write_head->o);
4594
data->state=5;@+ wait(mem_addr_time+mem_write_time);
4595
 
4596
@ A subtlety needs to be mentioned here: While we're trying to
4597
update the D-cache, another instruction might be filling the
4598
same cache block (although not because of the same physical address).
4599
Therefore we |goto write_restart| here instead of saying |wait(1)|.
4600
 
4601
@addr| into the D-cache@>=
4602
if (Dcache->filler.next) goto write_restart;
4603
if ((Scache&&Scache->lock) || (!Scache&&mem_lock)) goto write_restart;
4604
p=alloc_slot(Dcache,write_head->addr);
4605
if (!p) goto write_restart;
4606
if (Scache) set_lock(&Dcache->filler,Scache->lock)@;
4607
else set_lock(&Dcache->filler,mem_lock);
4608
set_lock(self,Dcache->fill_lock);
4609
data->ptr_b=Dcache->filler_ctl.ptr_b=(void *)p;
4610
Dcache->filler_ctl.z.o=write_head->addr;
4611
startup(&Dcache->filler,Scache? Scache->access_time: mem_addr_time);
4612
 
4613
@ Here it is assumed that |Dcache->access_time| is enough to search
4614
the D-cache and update one octabyte in case of a hit. The D-cache is
4615
not locked, since other coroutines that might be simultaneously reading
4616
the D-cache are not going to use the octabyte that changes.
4617
Perhaps the simulator is being too lenient here.
4618
 
4619
@=
4620
p=cache_search(Dcache,write_head->addr);
4621
if (p) {
4622
  p=use_and_fix(Dcache,p);
4623
  set_lock(self,wbuf_lock);
4624
  data->ptr_b=(void *)p;
4625
  p->data[(write_head->addr.l&(Dcache->bb-1))>>3]=write_head->o;
4626
  p->dirty[(write_head->addr.l&(Dcache->bb-1))>>Dcache->g]=true;
4627
  data->state=4;@+ wait(Dcache->access_time);
4628
}
4629
 
4630
@ @=
4631
if ((Dcache->mode&WRITE_BACK)==0) { /* write-through */
4632
  if (Dcache->flusher.next) wait(1);
4633
  flush_cache(Dcache,p,true);
4634
}
4635
 
4636
@ @=
4637
{
4638
  set_lock(self,wbuf_lock);
4639
  data->state=5;
4640
  wait(1);
4641
}
4642
 
4643
@* Loading and storing. A RISC machine is often said to have a ``load/store
4644
architecture,'' perhaps because loading and storing are among the most
4645
difficult things a RISC machine is called upon to do.
4646
 
4647
We want memory accesses
4648
to be efficient, so we try to access the D-cache at the same time as we are
4649
translating a virtual address via the DT-cache. Usually we hit in both
4650
caches, but numerous cases must be dealt with when we miss. Is there
4651
an elegant way to handle all the contingencies? Alas, the author of this
4652
program was unable to think of anything better than to throw lots
4653
of code at the problem --- knowing full well that such a spaghetti-like
4654
approach is fraught with possibilities for error.
4655
 
4656
Instructions like \.{LDO} $x,y,z$ operate in two pipeline stages. The first
4657
stage computes the virtual address $y+z$, waiting if necessary until $y$
4658
and~$z$ are both known; then it starts to access the necessary caches.
4659
In the second stage we ascertain the corresponding physical address and
4660
hopefully find the data in the cache (or in the speculative |mem| list or the
4661
write buffer).
4662
 
4663
An instruction like \.{STB} $x,y,z$ shares some of the computation of
4664
\.{LDO}~$x,y,z$, because only one byte is being stored but the other seven
4665
bytes must be found in the cache. In this case, however, $x$~is treated as an
4666
input, and |mem| is the output. The second stage of a store command can begin
4667
even though $x$ is not known during the first stage.
4668
 
4669
Here's what we do at the beginning of stage~1.
4670
 
4671
@d ld_st_launch 7 /* state when load/store command has its memory address */
4672
 
4673
@=
4674
case preld: case prest: case prego:
4675
  data->z.o=incr(data->z.o,data->xx&-(data->i==prego? Icache: Dcache)->bb);
4676
  /* (I hope the adder is fast enough) */
4677
case ld: case ldunc: case ldvts:
4678
case st: case pst: case syncd: case syncid:
4679
start_ld_st: data->y.o=oplus(data->y.o,data->z.o);
4680
  data->state=ld_st_launch;@+ goto switch1;
4681
case ldptp: case ldpte:@+if (data->y.o.h) goto start_ld_st;
4682
  data->x.o=zero_octa;@+ data->x.known=true;@+ goto die; /* page table fault */
4683
 
4684
@ @d PRW_BITS (data->ii==pst? PR_BIT+PW_BIT:
4685
                  (data->i==syncid && (data->loc.h&sign_bit))? 0: PW_BIT)
4686
 
4687
@=
4688
case ld_st_launch:@+if ((self+1)->next)
4689
    wait(1); /* second stage must be clear */
4690
  @;
4691
  if (data->y.o.h&sign_bit)
4692
    @;
4693
  if (page_bad) {
4694
    if (data->i==st || (data->ii>syncid))
4695
       data->interrupt|=PRW_BITS;
4696
    goto fin_ex;
4697
  }
4698
  if (DTcache->lock || (j=get_reader(DTcache))<0) wait(1);
4699
  startup(&DTcache->reader[j],DTcache->access_time);
4700
  @;
4701
  pass_after(DTcache->access_time);@+ goto passit;
4702
 
4703
@ When stage 2 of a load/store command begins, the state will depend
4704
on what transpired in stage~1.
4705
For example, |data->state| will be |DT_miss| if the virtual address key
4706
can't be found in the DT-cache; then stage~2 will have to compute the
4707
physical address the hard way.
4708
 
4709
The |data->state| will be |DT_hit| if
4710
the physical address is known via the DT-cache, but the data may or may not
4711
be in the D-cache. The |data->state| will be |hit_and_miss| if the DT-cache
4712
hits and the D-cache doesn't. And |data->state| will be |ld_ready| if
4713
|data->x.o| is the desired octabyte (for example, if both caches hit).
4714
 
4715
@d DT_miss 10 /* second stage |state| when DT-cache doesn't hold the key */
4716
@d DT_hit 11 /* second stage |state| when physical address is known */
4717
@d hit_and_miss 12 /* second stage |state| when D-cache misses */
4718
@d ld_ready 13 /* second stage |state| when data has been read */
4719
@d st_ready 14 /* second stage |state| when data needn't be read */
4720
@d prest_win 15 /* second stage |state| when we can fill a block with zeroes */
4721
 
4722
@=
4723
p=cache_search(DTcache,trans_key(data->y.o));
4724
if (!Dcache || Dcache->lock || (j=get_reader(Dcache))<0 ||
4725
     (data->i>=st && data->i<=syncid))
4726
  @;
4727
startup(&Dcache->reader[j],Dcache->access_time);
4728
if (p) @@;
4729
else data->state=DT_miss;
4730
 
4731
@ We assume that it is possible to look up a virtual address in the DT-cache
4732
at the same time as we look for a corresponding physical address in the
4733
D-cache, provided that the lower $b+c$ bits of the two addresses are the same.
4734
(They will always be the same if |b+c<=page_s|; otherwise the operating system
4735
can try to make them the same by ``page coloring'' whenever possible.) If both
4736
caches hit, the physical address is known in
4737
@^page coloring@>
4738
max(|DTcache->access_time,Dcache->access_time|) cycles.
4739
 
4740
If the lower $b+c$ bits of the virtual and physical addresses differ,
4741
the machine will not know this until the DT-cache has hit.
4742
Therefore we simulate the operation of accessing the D-cache, but we go to
4743
|DT_hit| instead of to |hit_and_miss| because the D-cache will
4744
experience a spurious miss.
4745
 
4746
@d max(x,y) ((x)<(y)? (y):(x))
4747
 
4748
@=
4749
{@+octa *m;
4750
  @;
4751
  data->z.o=phys_addr(data->y.o,p->data[0]);
4752
  m=write_search(data,data->z.o);
4753
  if (m==DUNNO) data->state=DT_hit;
4754
  else if (m) data->x.o=*m, data->state=ld_ready;
4755
  else if (Dcache->b+Dcache->c>page_s &&@|
4756
      ((data->y.o.l^data->z.o.l)&((Dcache->bb<c)-(1<
4757
    data->state=DT_hit; /* spurious D-cache lookup */
4758
  else {
4759
    q=cache_search(Dcache,data->z.o);
4760
    if (q) {
4761
      if (data->i==ldunc) q=demote_and_fix(Dcache,q);
4762
      else q=use_and_fix(Dcache,q);
4763
      data->x.o=q->data[(data->z.o.l&(Dcache->bb-1))>>3];
4764
      data->state=ld_ready;
4765
    }@+else data->state=hit_and_miss;
4766
  }
4767
  pass_after(max(DTcache->access_time,Dcache->access_time));
4768
  goto passit;
4769
}
4770
 
4771
@ The protection bits $p_rp_wp_x$ in a translation cache are shifted
4772
four positions right from the interrupt codes |PR_BIT|, |PW_BIT|, |PX_BIT|.
4773
If the data is protected, we abort the load/store operation immediately;
4774
this protects the privacy of other users.
4775
 
4776
@=
4777
p=use_and_fix(DTcache,p);
4778
j=PRW_BITS;
4779
if (((p->data[0].l<
4780
  if (data->i==syncd || data->i==syncid) goto sync_check;
4781
  if (data->i!=preld && data->i!=prest)
4782
    data->interrupt|=j&~(p->data[0].l<
4783
  goto fin_ex;
4784
}
4785
 
4786
@ @=
4787
{@+octa *m;
4788
  if (p) {
4789
    @;
4790
    data->z.o=phys_addr(data->y.o,p->data[0]);
4791
    if (data->i>=st && data->i<=syncid) data->state=st_ready;
4792
    else {
4793
      m=write_search(data,data->z.o);
4794
      if (m && m!= DUNNO) data->x.o=*m, data->state=ld_ready;
4795
      else data->state=DT_hit;
4796
    }
4797
  }@+ else data->state=DT_miss;
4798
  pass_after(DTcache->access_time);@+ goto passit;
4799
}
4800
 
4801
@ @=
4802
{@+octa *m;
4803
  if (!(data->loc.h&sign_bit)) {
4804
    if (data->i==syncd || data->i==syncid) goto sync_check;
4805
    if (data->i!=preld && data->i!=prest) data->interrupt |= N_BIT;
4806
    goto fin_ex;
4807
  }
4808
  data->z.o=data->y.o;@+ data->z.o.h -= sign_bit;
4809
  if (data->i>=st && data->i<=syncid) {
4810
    data->state=st_ready;@+pass_after(1);@+goto passit;
4811
  }
4812
  m=write_search(data,data->z.o);
4813
  if (m) {
4814
    if (m==DUNNO) data->state=DT_hit;
4815
    else data->x.o=*m, data->state=ld_ready;
4816
  }@+ else if ((data->z.o.h&0xffff0000) || !Dcache) {
4817
    if (mem_lock) wait(1);
4818
    set_lock(&mem_locker,mem_lock);
4819
    data->x.o=mem_read(data->z.o);
4820
    data->state=ld_ready;
4821
    startup(&mem_locker,mem_addr_time+mem_read_time);
4822
    pass_after(mem_addr_time+mem_read_time);@+ goto passit;
4823
  }
4824
  if (Dcache->lock || (j=get_reader(Dcache))<0) {
4825
    data->state=DT_hit;@+pass_after(1);@+ goto passit;
4826
  }
4827
  startup(&Dcache->reader[j],Dcache->access_time);
4828
  q=cache_search(Dcache,data->z.o);
4829
  if (q) {
4830
    if (data->i==ldunc) q=demote_and_fix(Dcache,q);
4831
    else q=use_and_fix(Dcache,q);
4832
    data->x.o=q->data[(data->z.o.l&(Dcache->bb-1))>>3];
4833
    data->state=ld_ready;
4834
  }@+else data->state=hit_and_miss;
4835
  pass_after(Dcache->access_time);@+ goto passit;
4836
}
4837
 
4838
@ The program for the second stage is, likewise, rather long-winded, yet quite
4839
similar to the cache manipulations we have already seen several times.
4840
 
4841
Several instructions might be trying to fill the DT-cache for the same page.
4842
(A similar situation faced us in the |write_from_wbuf| coroutine.)
4843
The second stage therefore needs to do some
4844
translation cache searching just as the first stage did. In this
4845
stage, however, we don't go all out for speed, because DT-cache misses
4846
are rare.
4847
 
4848
@d DT_retry 8 /* second stage |state| when DT-cache should be searched again */
4849
@d got_DT 9   /* second stage |state| when DT-cache entry has been computed */
4850
 
4851
@=
4852
square_one: data->state=DT_retry;
4853
 case DT_retry:@+if (DTcache->lock || (j=get_reader(DTcache))<0) wait(1);
4854
   startup(&DTcache->reader[j],DTcache->access_time);
4855
   p=cache_search(DTcache,trans_key(data->y.o));
4856
   if (p) {
4857
     @;
4858
     data->z.o=phys_addr(data->y.o,p->data[0]);
4859
     if (data->i>=st && data->i<=syncid) data->state=st_ready;
4860
     else data->state=DT_hit;
4861
   }@+ else data->state=DT_miss;
4862
   wait(DTcache->access_time);
4863
 case DT_miss:@+if (DTcache->filler.next)
4864
     if (data->i==preld || data->i==prest) goto fin_ex;@+ else goto square_one;
4865
   if (no_hardware_PT)
4866
     if (data->i==preld || data->i==prest) goto fin_ex;@+else goto emulate_virt;
4867
   p=alloc_slot(DTcache,trans_key(data->y.o));
4868
   if (!p) goto square_one;
4869
   data->ptr_b=DTcache->filler_ctl.ptr_b=(void *)p;
4870
   DTcache->filler_ctl.y.o=data->y.o;
4871
   set_lock(self,DTcache->fill_lock);
4872
   startup(&DTcache->filler,1);
4873
   data->state=got_DT;
4874
   if (data->i==preld || data->i==prest) goto fin_ex;@+else sleep;
4875
 case got_DT: release_lock(self,DTcache->fill_lock);
4876
   j=PRW_BITS;
4877
   if (((data->z.o.l<
4878
     if (data->i==syncd || data->i==syncid) goto sync_check;
4879
     data->interrupt |= j&~(data->z.o.l<
4880
     goto fin_ex;
4881
   }
4882
   data->z.o=phys_addr(data->y.o,data->z.o);
4883
   if (data->i>=st && data->i<=syncid) goto finish_store;
4884
    /* otherwise we fall through to |ld_retry| below */
4885
 
4886
@ The second stage might also want to fill the D-cache (and perhaps
4887
the S-cache) as we get the data.
4888
 
4889
Several load instructions might be trying to fill the same cache block.
4890
So we should go back and look in the D-cache again if we miss and
4891
cannot allocate a slot immediately.
4892
 
4893
A \.{PRELD} or \.{PREST} instruction, which is just a ``hint,'' doesn't do
4894
anything more if the caches are already busy.
4895
 
4896
@=
4897
ld_retry: data->state=DT_hit;
4898
 case DT_hit:@+ if (data->i==preld || data->i==prest) goto fin_ex;
4899
  @;
4900
  if ((data->z.o.h&0xffff0000) || !Dcache)
4901
      @;
4902
  if (Dcache->lock || (j=get_reader(Dcache))<0) wait(1);
4903
  startup(&Dcache->reader[j],Dcache->access_time);
4904
  q=cache_search(Dcache,data->z.o);
4905
  if (q) {
4906
    if (data->i==ldunc) q=demote_and_fix(Dcache,q);
4907
    else q=use_and_fix(Dcache,q);
4908
    data->x.o=q->data[(data->z.o.l&(Dcache->bb-1))>>3];
4909
    data->state=ld_ready;
4910
  }@+else data->state=hit_and_miss;
4911
  wait(Dcache->access_time);
4912
 case hit_and_miss:@+if (data->i==ldunc) goto avoid_D;
4913
    @z.o| in the D-cache@>;
4914
 
4915
@ @z.o| in the D-cache@>=
4916
@;
4917
if (Dcache->filler.next) goto ld_retry;
4918
if ((Scache&&Scache->lock) || (!Scache&&mem_lock)) goto ld_retry;
4919
q=alloc_slot(Dcache,data->z.o);
4920
if (!q) goto ld_retry;
4921
if (Scache) set_lock(&Dcache->filler,Scache->lock)@;
4922
else set_lock(&Dcache->filler,mem_lock);
4923
set_lock(self,Dcache->fill_lock);
4924
data->ptr_b=Dcache->filler_ctl.ptr_b=(void *)q;
4925
Dcache->filler_ctl.z.o=data->z.o;
4926
startup(&Dcache->filler,Scache? Scache->access_time: mem_addr_time);
4927
data->state=ld_ready;
4928
if (data->i==preld || data->i==prest) goto fin_ex;@+else sleep;
4929
 
4930
@ If a |prest| instruction makes it to the hot seat,
4931
we have been assured by the user of |PREST| that the current
4932
values of bytes in virtual addresses |data->y.o-(data->xx&-Dcache->bb)| through
4933
|data->y.o+(data->xx&(Dcache->bb-1))|
4934
are irrelevant. Hence we can pretend that we know they are zero. This
4935
is advantageous if it saves us from filling a cache block from
4936
the S-cache or from memory.
4937
 
4938
@=
4939
if (data->i==prest &&@|
4940
   (data->xx>=Dcache->bb || ((data->y.o.l&(Dcache->bb-1))==0)) &&@|
4941
   ((data->y.o.l+(data->xx&(Dcache->bb-1))+1)^data->y.o.l)>=Dcache->bb)
4942
  goto prest_span;
4943
 
4944
@ @=
4945
prest_span: data->state=prest_win;
4946
case prest_win:@+ if (data!=old_hot || Dlocker.next) wait(1);
4947
  if (Dcache->lock) goto fin_ex;
4948
  q=alloc_slot(Dcache,data->z.o); /* OK if |Dcache->filler| is busy */
4949
  if (q) {
4950
    clean_block(Dcache,q);
4951
    q->tag=data->z.o;@+q->tag.l &=-Dcache->bb;
4952
    set_lock(&Dlocker,Dcache->lock);
4953
    startup(&Dlocker,Dcache->copy_in_time);
4954
  }
4955
  goto fin_ex;
4956
 
4957
@ @=
4958
{
4959
avoid_D:@+ if (mem_lock) wait(1);
4960
  set_lock(&mem_locker,mem_lock);
4961
  startup(&mem_locker, mem_addr_time+mem_read_time);
4962
  data->x.o=mem_read(data->z.o);
4963
  data->state=ld_ready;@+ wait(mem_addr_time+mem_read_time);
4964
}
4965
 
4966
@ @=
4967
{
4968
  octa *m=write_search(data,data->z.o);
4969
  if (m==DUNNO) wait(1);
4970
  if (m) {
4971
    data->x.o=*m;
4972
    data->state=ld_ready;
4973
    wait(1);
4974
  }
4975
}
4976
 
4977
@ The requested octabyte will arrive sooner or later in |data->x.o|.
4978
Then a load instruction is almost done, except that we might need
4979
to massage the input a little bit.
4980
 
4981
@=
4982
case ld_ready:@+if (self->lockloc)
4983
    *(self->lockloc)=NULL, self->lockloc=NULL;
4984
  if (data->i>=st) goto finish_store;
4985
  switch(data->op>>1) {
4986
    case LDB>>1: case LDBU>>1: j=(data->z.o.l&0x7)<<3;@+i=56;@+goto fin_ld;
4987
    case LDW>>1: case LDWU>>1: j=(data->z.o.l&0x6)<<3;@+i=48;@+goto fin_ld;
4988
    case LDT>>1: case LDTU>>1: j=(data->z.o.l&0x4)<<3;@+i=32;
4989
 fin_ld: data->x.o=shift_right(shift_left(data->x.o,j),i,data->op&0x2);
4990
    default: goto fin_ex;
4991
    case LDHT>>1:@+if (data->z.o.l&4) data->x.o.h=data->x.o.l;
4992
      data->x.o.l=0;@+ goto fin_ex;
4993
    case LDSF>>1:@+if (data->z.o.l&4) data->x.o.h=data->x.o.l;
4994
      if ((data->x.o.h&0x7f800000)==0 && (data->x.o.h&0x7fffff)) {
4995
        data->x.o=load_sf(data->x.o.h);
4996
        data->state=3;@+wait(denin_penalty);
4997
      }
4998
      else data->x.o=load_sf(data->x.o.h);@+goto fin_ex;
4999
    case LDPTP>>1:@+
5000
      if ((data->x.o.h&sign_bit)==0 || (data->x.o.l&0x1ff8)!=page_n)
5001
        data->x.o=zero_octa;
5002
      else data->x.o.l &= -(1<<13);
5003
      goto fin_ex;
5004
    case LDPTE>>1:@+if ((data->x.o.l&0x1ff8)!=page_n) data->x.o=zero_octa;
5005
      else data->x.o=incr(oandn(data->x.o,page_mask),data->x.o.l&0x7);
5006
      data->x.o.h &= 0xffff;@+ goto fin_ex;
5007
    case UNSAVE>>1: @;
5008
  }
5009
 
5010
@ @=
5011
 finish_store: data->state=st_ready;
5012
case st_ready:@+ switch (data->i) {
5013
 case st: case pst: @;
5014
 case syncd: data->b.o.l=(Dcache? Dcache->bb: 8192);@+goto do_syncd;
5015
 case syncid: data->b.o.l=(Icache? Icache->bb: 8192);
5016
   if (Dcache && Dcache->bbb.o.l) data->b.o.l=Dcache->bb;
5017
   goto do_syncid;
5018
}
5019
 
5020
@ Store instructions have an extra complication, because some of them need
5021
to check for overflow.
5022
 
5023
@=
5024
data->x.addr=data->z.o;
5025
if (data->b.p) wait(1);
5026
switch(data->op>>1) {
5027
 case STUNC>>1: data->i=stunc;
5028
 default: data->x.o=data->b.o;@+goto fin_ex;
5029
 case STSF>>1: set_round;@+ data->b.o.h=store_sf(data->b.o);
5030
    data->interrupt |= exceptions;
5031
    if ((data->b.o.h&0x7f800000)==0 && (data->b.o.h&0x7fffff)) {
5032
      if (data->z.o.l&4) data->x.o.l=data->b.o.h;
5033
      else data->x.o.h=data->b.o.h;
5034
      data->state=3;@+wait(denout_penalty);
5035
    }
5036
 case STHT>>1:@+if (data->z.o.l&4) data->x.o.l=data->b.o.h;
5037
  else data->x.o.h=data->b.o.h;
5038
  goto fin_ex;
5039
 case STB>>1: case STBU>>1: j=(data->z.o.l&0x7)<<3;@+i=56;@+goto fin_st;
5040
 case STW>>1: case STWU>>1: j=(data->z.o.l&0x6)<<3;@+i=48;@+goto fin_st;
5041
 case STT>>1: case STTU>>1: j=(data->z.o.l&0x4)<<3;@+i=32;
5042
  fin_st: @b.o| into the proper field of |data->x.o|,
5043
                 checking for arithmetic exceptions if signed@>;
5044
  goto fin_ex;
5045
 case CSWAP>>1: @;
5046
 case SAVE>>1: @;
5047
  }
5048
 
5049
@ @b.o| into the proper field...@>=
5050
{
5051
  octa mask;
5052
  if (!(data->op&2)) {@+octa before,after;
5053
    before=data->b.o;@+after=shift_right(shift_left(data->b.o,i),i,0);
5054
    if (before.l!=after.l || before.h!=after.h) data->interrupt|=V_BIT;
5055
  }
5056
  mask=shift_right(shift_left(neg_one,i),j,1);
5057
  data->b.o=shift_right(shift_left(data->b.o,i),j,1);
5058
  data->x.o.h^=mask.h&(data->x.o.h^data->b.o.h);
5059
  data->x.o.l^=mask.l&(data->x.o.l^data->b.o.l);
5060
}
5061
 
5062
@ The \.{CSWAP} operation has four inputs $\rm(\$X, \$Y, \$Z, rP)$ as well as
5063
three outputs $\rm(\$X,M_8[A],rP)$. To keep from exceeding the capacity
5064
of the control blocks in our pipeline, we wait until this instruction reaches
5065
the hot seat, thereby allowing us non-speculative access to~rP.
5066
 
5067
@=
5068
if (data!=old_hot) wait(1);
5069
if (data->x.o.h==g[rP].o.h && data->x.o.l==g[rP].o.l) {
5070
  data->a.o.l=1; /* |data->a.o.h| is zero */
5071
  data->x.o=data->b.o;
5072
}@+else {
5073
  g[rP].o=data->x.o; /* |data->a.o| is zero */
5074
  if (verbose&issue_bit) {
5075
    printf(" setting rP=");@+print_octa(g[rP].o);@+printf("\n");
5076
  }
5077
}
5078
data->i=cswap; /* cosmetic change, affects the trace output only */
5079
goto fin_ex;
5080
 
5081
@* The fetch stage. Now that we've mastered the most difficult memory
5082
operations, we can relax and apply our knowledge to the slightly simpler task
5083
of filling the fetch buffer. Fetching is like loading/storing, except that we
5084
use the I-cache instead of the D-cache. It's slightly simpler because the
5085
I-cache is read-only. Further simplifications would be possible if there
5086
were no \.{PREGO} instruction, because there is only one fetch unit.
5087
However, we want to implement \.{PREGO} with reasonable efficiency, in order
5088
to see if that instruction is worthwhile; so we include the complications of
5089
simultaneous I-cache and IT-cache readers, which we
5090
have already implemented for the D-cache and DT-cache.
5091
 
5092
The fetch coroutine is always present, as the one and only coroutine with
5093
|stage| number~zero.
5094
 
5095
In normal circumstances, the fetch coroutine accesses a cache block containing
5096
the instruction whose virtual address is given by |inst_ptr| (the instruction
5097
pointer), and transfers up to |fetch_max| instructions from that block to the
5098
fetch buffer. Complications arise if the instruction isn't in the cache, or if
5099
we can't translate the virtual address because of a miss in the IT-cache.
5100
Moreover, |inst_ptr| is a \&{spec} variable whose value might not even be
5101
known; if |inst_ptr.p| is nonnull, we don't know what to fetch.
5102
@^program counter@>
5103
 
5104
@=
5105
Extern spec inst_ptr; /* the instruction pointer (aka program counter) */
5106
Extern octa *fetched; /* buffer for incoming instructions */
5107
 
5108
@ The fetch coroutine usually begins a cycle in state |fetch_ready|, with
5109
the most recently fetched octabytes in positions |fetch_lo|, |fetch_lo+1|,
5110
\dots, |fetch_hi-1| of a buffer called |fetched|. Once that buffer has been
5111
exhausted, the coroutine reverts to state~0; with luck, the buffer might have
5112
more data by the time the next cycle rolls around.
5113
 
5114
@=
5115
int fetch_lo, fetch_hi; /* the active region of that buffer */
5116
coroutine fetch_co;
5117
control fetch_ctl;
5118
 
5119
@ @=
5120
fetch_co.ctl=&fetch_ctl;
5121
fetch_co.name="Fetch";
5122
fetch_ctl.go.o.l=4;
5123
startup(&fetch_co,1);
5124
 
5125
@ @=
5126
if (fetch_co.lockloc) *(fetch_co.lockloc)=NULL,fetch_co.lockloc=NULL;
5127
unschedule(&fetch_co);
5128
startup(&fetch_co,1);
5129
 
5130
@ Some of the actions here are done not only by the fetcher but also by the
5131
first and second stages of a |prego| operation.
5132
 
5133
@d wait_or_pass(t) if (data->i==prego) {@+pass_after(t);@+goto passit;@+}
5134
                   else wait(t)
5135
 
5136
@=
5137
switch0:@+ switch(data->state) {
5138
 new_fetch: data->state=0;
5139
 case 0: @;
5140
   data->y.o=inst_ptr.o;
5141
   data->state=1;@+ data->interrupt=0;@+ data->x.o=data->z.o=zero_octa;
5142
 case 1: start_fetch:@+ if (data->y.o.h&sign_bit)
5143
    @;
5144
  if (page_bad) goto bad_fetch;
5145
  if (ITcache->lock || (j=get_reader(ITcache))<0) wait(1);
5146
  startup(&ITcache->reader[j],ITcache->access_time);
5147
  @;
5148
  wait_or_pass(ITcache->access_time);
5149
  @@;
5150
}
5151
 
5152
@ @=
5153
if (data->i==prego) goto start_fetch;
5154
 
5155
@ @=
5156
if (inst_ptr.p) {
5157
  if (inst_ptr.p!=UNKNOWN_SPEC && inst_ptr.p->known)
5158
    inst_ptr.o=inst_ptr.p->o, inst_ptr.p=NULL;
5159
  wait(1);
5160
}
5161
 
5162
@ @d got_IT 19   /* |state| when IT-cache entry has been computed */
5163
@d IT_miss 20 /* |state| when IT-cache doesn't hold the key */
5164
@d IT_hit 21 /* |state| when physical instruction address is known */
5165
@d Ihit_and_miss 22 /* |state| when I-cache misses */
5166
@d fetch_ready 23 /* |state| when instructions have been read */
5167
@d got_one 24 /* |state| when a ``preview'' octabyte is ready */
5168
 
5169
@=
5170
p=cache_search(ITcache,trans_key(data->y.o));
5171
if (!Icache || Icache->lock || (j=get_reader(Icache))<0)
5172
  @;
5173
startup(&Icache->reader[j],Icache->access_time);
5174
if (p) @@;
5175
else data->state=IT_miss;
5176
 
5177
@ We assume that it is possible to look up a virtual address in the IT-cache
5178
at the same time as we look for a corresponding physical address in the
5179
I-cache, provided that the lower $b+c$ bits of the two addresses are the same.
5180
(See the remarks about ``page coloring,'' when we made similar assumptions
5181
about the DT-cache and D-cache.)
5182
@^page coloring@>
5183
 
5184
@=
5185
{
5186
  @;
5187
  data->z.o=phys_addr(data->y.o,p->data[0]);
5188
  if (Icache->b+Icache->c>page_s &&@|
5189
      ((data->y.o.l^data->z.o.l)&((Icache->bb<c)-(1<
5190
    data->state=IT_hit; /* spurious I-cache lookup */
5191
  else {
5192
    q=cache_search(Icache,data->z.o);
5193
    if (q) {
5194
      q=use_and_fix(Icache,q);
5195
      @;
5196
      data->state=fetch_ready;
5197
    }@+else data->state=Ihit_and_miss;
5198
  }
5199
  wait_or_pass(max(ITcache->access_time,Icache->access_time));
5200
}
5201
 
5202
@ @=
5203
p=use_and_fix(ITcache,p);
5204
if (!(p->data[0].l&(PX_BIT>>PROT_OFFSET))) goto bad_fetch;
5205
 
5206
@ At this point |inst_ptr.o| equals |data->y.o|.
5207
 
5208
@=
5209
if (data->i!=prego) {
5210
  for (j=0;jbb;j++) fetched[j]=q->data[j];
5211
  fetch_lo=(inst_ptr.o.l&(Icache->bb-1))>>3;
5212
  fetch_hi=Icache->bb>>3;
5213
}
5214
 
5215
@ @=
5216
{
5217
  if (p) {
5218
    @;
5219
    data->z.o=phys_addr(data->y.o,p->data[0]);
5220
    data->state=IT_hit;
5221
  }@+ else data->state=IT_miss;
5222
  wait_or_pass(ITcache->access_time);
5223
}
5224
 
5225
@ @=
5226
{
5227
  if (data->i==prego && !(data->loc.h&sign_bit)) goto fin_ex;
5228
  data->z.o=data->y.o;@+ data->z.o.h -= sign_bit;
5229
 known_phys:@+  if (data->z.o.h&0xffff0000) goto bad_fetch;
5230
  if (!Icache) @;
5231
  if (Icache->lock || (j=get_reader(Icache))<0) {
5232
    data->state=IT_hit;@+ wait_or_pass(1);
5233
  }
5234
  startup(&Icache->reader[j],Icache->access_time);
5235
  q=cache_search(Icache,data->z.o);
5236
  if (q) {
5237
    q=use_and_fix(Icache,q);
5238
    @;
5239
    data->state=fetch_ready;
5240
  }@+else data->state=Ihit_and_miss;
5241
  wait_or_pass(Icache->access_time);
5242
}
5243
 
5244
@ @=
5245
{@+octa addr;
5246
  addr=data->z.o;
5247
  if (mem_lock) wait(1);
5248
  set_lock(&mem_locker,mem_lock);
5249
  startup(&mem_locker,mem_addr_time+mem_read_time);
5250
  addr.l&=-(bus_words<<3);
5251
  fetched[0]=mem_read(addr);
5252
  for (j=1;j
5253
    fetched[j]=mem_hash[last_h].chunk[((addr.l&0xffff)>>3)+j];
5254
  fetch_lo=(data->z.o.l>>3)&(bus_words-1);@+ fetch_hi=bus_words;
5255
  data->state=fetch_ready;
5256
  wait(mem_addr_time+mem_read_time);
5257
}
5258
 
5259
@ @=
5260
 case IT_miss:@+if (ITcache->filler.next)
5261
     if (data->i==prego) goto fin_ex;@+else wait(1);
5262
   if (no_hardware_PT) @;
5263
   p=alloc_slot(ITcache,trans_key(data->y.o));
5264
   if (!p) /* hey, it was present after all */
5265
     if (data->i==prego) goto fin_ex;@+else goto new_fetch;
5266
   data->ptr_b=ITcache->filler_ctl.ptr_b=(void *)p;
5267
   ITcache->filler_ctl.y.o=data->y.o;
5268
   set_lock(self,ITcache->fill_lock);
5269
   startup(&ITcache->filler,1);
5270
   data->state=got_IT;
5271
   if (data->i==prego) goto fin_ex;@+else sleep;
5272
 case got_IT: release_lock(self,ITcache->fill_lock);
5273
   if (!(data->z.o.l&(PX_BIT>>PROT_OFFSET))) goto bad_fetch;
5274
   data->z.o=phys_addr(data->y.o,data->z.o);
5275
 fetch_retry: data->state=IT_hit;
5276
 case IT_hit:@+if (data->i==prego) goto fin_ex;@+else goto known_phys;
5277
 case Ihit_and_miss:
5278
    @z.o| in the I-cache@>;
5279
 
5280
@ @=
5281
case IT_miss: case Ihit_and_miss: case IT_hit: case fetch_ready: goto switch0;
5282
 
5283
@ @z.o| in the I-cache@>=
5284
if (Icache->filler.next) goto fetch_retry;
5285
if ((Scache&&Scache->lock) || (!Scache&&mem_lock)) goto fetch_retry;
5286
q=alloc_slot(Icache,data->z.o);
5287
if (!q) goto fetch_retry;
5288
if (Scache) set_lock(&Icache->filler,Scache->lock)@;
5289
else set_lock(&Icache->filler,mem_lock);
5290
set_lock(self,Icache->fill_lock);
5291
data->ptr_b=Icache->filler_ctl.ptr_b=(void *)q;
5292
Icache->filler_ctl.z.o=data->z.o;
5293
startup(&Icache->filler,Scache? Scache->access_time: mem_addr_time);
5294
data->state=got_one;
5295
if (data->i==prego) goto fin_ex;@+else sleep;
5296
 
5297
@ The I-cache filler will wake us up with the octabyte we want, before
5298
it has filled the entire cache block. In that case we can fetch one
5299
or two instructions before the rest of the block has been loaded.
5300
 
5301
@=
5302
bad_fetch:@+ if (data->i==prego) goto fin_ex;
5303
  data->interrupt |= PX_BIT;
5304
swym_one: fetched[0].h=fetched[0].l=SWYM<<24;
5305
  goto fetch_one;
5306
case got_one: fetched[0]=data->x.o; /* a ``preview'' of the new cache data */
5307
fetch_one:  fetch_lo=0;@+fetch_hi=1;
5308
  data->state=fetch_ready;
5309
case fetch_ready:@+if (self->lockloc)
5310
    *(self->lockloc)=NULL, self->lockloc=NULL;
5311
  if (data->i==prego) goto fin_ex;
5312
  for (j=0;j
5313
    register fetch *new_tail;
5314
    if (tail==fetch_bot) new_tail=fetch_top;
5315
    else new_tail=tail-1;
5316
    if (new_tail==head) break; /* fetch buffer is full */
5317
    @;
5318
    tail=new_tail;
5319
    if (sleepy) {
5320
      sleepy=false;@+ sleep;
5321
    }
5322
    inst_ptr.o=incr(inst_ptr.o,4);
5323
    if (fetch_lo==fetch_hi) goto new_fetch;
5324
  }
5325
  wait(1);
5326
 
5327
@ @=
5328
{
5329
  if (cache_search(ITcache,trans_key(inst_ptr.o))) goto new_fetch;
5330
  data->interrupt|=F_BIT;
5331
  sleepy=true;
5332
  goto swym_one;
5333
}
5334
 
5335
@ @=
5336
bool sleepy; /* have we just emitted the page table emulation call? */
5337
 
5338
@ At this point we check for egregiously invalid instructions. (Sometimes
5339
the dispatcher will actually allow such instructions to occupy
5340
the fetch buffer, for internally generated commands.)
5341
 
5342
@=
5343
tail->loc=inst_ptr.o;
5344
if (inst_ptr.o.l&4) tail->inst=fetched[fetch_lo++].l;
5345
else tail->inst=fetched[fetch_lo].h;
5346
@^big-endian versus little-endian@>
5347
@^little-endian versus big-endian@>
5348
tail->interrupt=data->interrupt;
5349
i=tail->inst>>24;
5350
if (i>=RESUME && i<=SYNC && (tail->inst&bad_inst_mask[i-RESUME]))
5351
  tail->interrupt |= B_BIT;
5352
tail->noted=false;
5353
if (inst_ptr.o.l==breakpoint.l && inst_ptr.o.h==breakpoint.h)
5354
  breakpoint_hit=true;
5355
 
5356
@ The commands |RESUME|, |SAVE|, |UNSAVE|, and |SYNC| should not have
5357
nonzero bits in the positions defined here.
5358
 
5359
@=
5360
int bad_inst_mask[4]={0xfffffe,0xffff,0xffff00,0xfffff8};
5361
 
5362
@* Interrupts. The scariest thing about the design of a pipelined machine is
5363
the existence of interrupts, which disrupt the smooth flow of a computation in
5364
ways that are difficult to anticipate. Fortunately, however, the discipline of
5365
a reorder buffer, which forces instructions to be committed in order,
5366
allows us to deal with interrupts in a fairly natural way. Our solution to the
5367
problems of dynamic scheduling and speculative execution therefore solves the
5368
interrupt problem as well.
5369
@^interrupts@>
5370
 
5371
\MMIX\ has three kinds of interrupts, which show up as bit codes in the
5372
|interrupt| field when an instruction is ready to be committed:
5373
|H_BIT| invokes a trip handler, for \.{TRIP} instructions and
5374
arithmetic exceptions; |F_BIT| invokes a forced-trap handler, for \.{TRAP}
5375
instructions and unimplemented instructions that need to be emulated
5376
in software; |E_BIT| invokes a dynamic-trap handler, for external
5377
interrupts like I/O signals or for internal interrupts caused by
5378
improper instructions.
5379
In all three cases, the pipeline control has already been redirected to fetch
5380
new instructions starting at the correct handler address by the time an
5381
interrupted instruction is ready to be committed.
5382
 
5383
@ Most instructions come to the following part of the program, if they
5384
have finished execution with any~1s among the eight trip bits or the
5385
eight trap bits.
5386
 
5387
If the trip bits aren't all zero, we want to update the event bits
5388
of~rA, or perform an enabled trip handler, or both. If the trap bits
5389
are nonzero, we need to hold onto them until we get to the hot seat,
5390
when they will be joined with the bits of~rQ and probably cause an interrupt.
5391
A load or store instruction with nonzero trap bits will be nullified,
5392
not committed.
5393
 
5394
Underflow that is exact and not enabled is ignored, in accordance with
5395
the IEEE standard conventions. (This applies also to underflow
5396
triggered by |RESUME_SET|.)
5397
 
5398
@d is_load_store(i) (i>=ld && i<=cswap)
5399
 
5400
@=
5401
{
5402
  if ((data->interrupt&0xff) && is_load_store(data->i)) goto state_5;
5403
  j=data->interrupt&0xff00;
5404
  data->interrupt -= j;
5405
  if ((j&(U_BIT+X_BIT))==U_BIT && !(data->ra.o.l & U_BIT)) j&=~U_BIT;
5406
  data->arith_exc=(j&~data->ra.o.l)>>8;
5407
  if (j&data->ra.o.l) @;
5408
  if (data->interrupt&0xff) goto state_5;
5409
}
5410
 
5411
@ Since execution is speculative, an exceptional condition might not
5412
be part of the ``real'' computation. Indeed, the present coroutine
5413
might have already been deissued.
5414
 
5415
@=
5416
{
5417
  i=issued_between(data,cool);
5418
  if (i
5419
  deissues=i;
5420
  old_tail=tail=head;@+resuming=0; /* clear the fetch buffer */
5421
  @;
5422
  cool_hist=data->hist;
5423
  for (i=j&data->ra.o.l,m=16;!(i&D_BIT);i<<=1,m+=16);
5424
  data->go.o.h=0, data->go.o.l=m;
5425
  inst_ptr.o=data->go.o, inst_ptr.p=NULL;
5426
  data->interrupt |= H_BIT;
5427
  goto state_4;
5428
}
5429
 
5430
@ @=
5431
i=issued_between(data,cool);
5432
if (i
5433
deissues=i;
5434
old_tail=tail=head;@+resuming=0; /* clear the fetch buffer */
5435
@;
5436
cool_hist=data->hist;
5437
inst_ptr.p=UNKNOWN_SPEC;
5438
data->interrupt |= F_BIT;
5439
 
5440
@ We need to stop dispatching when calling a trip handler from within
5441
the reorder buffer,
5442
lest we issue an instruction that uses
5443
|g[255]| or |rB| as an operand.
5444
 
5445
@=
5446
emulate_virt: @;
5447
state_4: data->state=4;
5448
case 4:@+if (dispatch_lock) wait(1);
5449
  set_lock(self,dispatch_lock);
5450
state_5: data->state=5;
5451
case 5:@+if (data!=old_hot) wait(1);
5452
  if ((data->interrupt&F_BIT) && data->i!=trap) {
5453
    inst_ptr.o=g[rT].o, inst_ptr.p=NULL;
5454
    if (is_load_store(data->i)) nullifying=true;
5455
  }
5456
  if (data->interrupt&0xff) {
5457
    g[rQ].o.h |= data->interrupt&0xff;
5458
    new_Q.h |= data->interrupt&0xff;
5459
    if (verbose&issue_bit) {
5460
      printf(" setting rQ=");@+print_octa(g[rQ].o);@+printf("\n");
5461
    }
5462
  }
5463
  goto die;
5464
 
5465
@ The instructions of the previous section appear in the switch for
5466
coroutine stage~1 only. We need to use them also in later stages.
5467
 
5468
@=
5469
case 4: goto state_4;
5470
case 5: goto state_5;
5471
 
5472
@ @=
5473
case trap:@+ if ((flags[op]&X_is_dest_bit) &&
5474
                cool->xxxx>=cool_L)
5475
    goto increase_L;
5476
  if (!g[rT].up->known || !g[rJ].up->known) goto stall;
5477
  inst_ptr=specval(&g[rT]); /* traps and emulated ops */
5478
  cool->need_b=true, cool->b=specval(&g[255]);
5479
case trip: if (!g[rJ].up->known) goto stall;
5480
  cool->ren_x=true, spec_install(&g[255],&cool->x);
5481
  cool->x.known=true, cool->x.o=g[rJ].up->o;
5482
  if (i==trip) cool->go.o=zero_octa;
5483
  cool->ren_a=true, spec_install(&g[i==trap? rBB: rB],&cool->a);@+break;
5484
 
5485
@ @=
5486
case trap: data->interrupt |= F_BIT;@+ data->a.o=data->b.o;@+ goto fin_ex;
5487
case trip: data->interrupt |= H_BIT;@+ data->a.o=data->b.o;@+ goto fin_ex;
5488
 
5489
@ The following check is performed at the beginning of every cycle.
5490
An instruction in the hot seat can be externally interrupted only if
5491
it is ready to be committed and not already marked for tripping
5492
or trapping.
5493
 
5494
@=
5495
g[rI].o=incr(g[rI].o,-1);
5496
if (g[rI].o.l==0 && g[rI].o.h==0) {
5497
  g[rQ].o.l |= INTERVAL_TIMEOUT, new_Q.l |= INTERVAL_TIMEOUT;
5498
    if (verbose&issue_bit) {
5499
      printf(" setting rQ=");@+print_octa(g[rQ].o);@+printf("\n");
5500
    }
5501
  }
5502
trying_to_interrupt=false;
5503
if (((g[rQ].o.h&g[rK].o.h)||(g[rQ].o.l&g[rK].o.l)) && cool!=hot &&@|
5504
     !(hot->interrupt&(E_BIT+F_BIT+H_BIT)) && !doing_interrupt &&@|
5505
     !(hot->i==resum)) {
5506
  if (hot->owner) trying_to_interrupt=true;
5507
  else {
5508
    hot->interrupt |= E_BIT;
5509
    @;
5510
    inst_ptr.o=g[rTT].o;@+inst_ptr.p=NULL;
5511
  }
5512
}
5513
 
5514
@ @=
5515
bool trying_to_interrupt; /* encouraging interruptible operations to pause */
5516
bool nullifying; /* stopping dispatch to nullify a load/store command */
5517
 
5518
@ It's possible that the command in the hot seat has been deissued,
5519
but only if the simulator has done so at the user's request. Otherwise
5520
the test `|i>=deissues|' here will always succeed.
5521
 
5522
The value of |cool_hist| becomes flaky here. We could try to keep it
5523
strictly up to date, but the unpredictable nature of external interrupts
5524
suggests that we are better off leaving it alone. (It's only a heuristic
5525
for branch prediction, and a sufficiently strong prediction will survive
5526
one-time glitches due to interrupts.)
5527
 
5528
@=
5529
i=issued_between(hot,cool);
5530
if (i>=deissues) {
5531
  deissues=i;
5532
  tail=head;@+resuming=0; /* clear the fetch buffer */
5533
  @;
5534
  if (is_load_store(hot->i)) nullifying=true;
5535
}
5536
 
5537
@ Even though an interrupted instruction has officially been either
5538
``committed'' or ``nullified,'' it stays in the hot seat for
5539
two or three extra cycles,
5540
while we save enough of the machine state to resume the computation later.
5541
 
5542
%Notice, incidentally, that |H_BIT| and |E_BIT| might both be present
5543
%simultaneously. In such cases we first prepare for a trip handler, but
5544
%interrupt that for a dynamic trap handler. (Ah, the joys of computer
5545
%architecture.)
5546
 
5547
@=
5548
{
5549
  if (!(hot->interrupt&H_BIT)) g[rK].o=zero_octa; /* trap */
5550
  if (((hot->interrupt&H_BIT)&&hot->i!=trip) ||@|
5551
      ((hot->interrupt&F_BIT)&&hot->i!=trap) ||@|
5552
      (hot->interrupt&E_BIT)) doing_interrupt=3, suppress_dispatch=true;
5553
  else doing_interrupt=2; /* trip or trap started by dispatcher */
5554
  break;
5555
}
5556
 
5557
@ If a memory failure occurs, we should set rF here, either in
5558
case~2 or case~1. The simulator doesn't do anything with~rF at present.
5559
 
5560
@=
5561
switch (doing_interrupt--) {
5562
 case 3: @;
5563
  @+break;
5564
 case 2: @;@+break;
5565
 case 1: @;
5566
  if (hot==reorder_bot) hot=reorder_top;@+ else hot--;
5567
  break;
5568
}
5569
 
5570
@ @=
5571
j=hot->interrupt&H_BIT;
5572
g[j?rB:rBB].o=g[255].o;
5573
g[255].o=g[rJ].o;
5574
if (verbose&issue_bit) {
5575
  if (j) {
5576
    printf(" setting rB=");@+print_octa(g[rB].o);
5577
  }@+else {
5578
    printf(" setting rBB=");@+print_octa(g[rBB].o);
5579
  }
5580
  printf(", $255=");@+print_octa(g[255].o);@+printf("\n");
5581
}
5582
 
5583
@ Here's where we manufacture the ``ropcodes'' for resumption.
5584
 
5585
@d RESUME_AGAIN 0 /* repeat the command in rX as if in location $\rm rW-4$ */
5586
@d RESUME_CONT 1 /* same, but substitute rY and rZ for operands */
5587
@d RESUME_SET 2 /* set r[X] to rZ */
5588
@d RESUME_TRANS 3 /* install $\rm(rY,rZ)$ into IT-cache or DT-cache,
5589
        then |RESUME_AGAIN| */
5590
@d pack_bytes(a,b,c,d) ((((((unsigned)(a)<<8)+(b))<<8)+(c))<<8)+(d)
5591
 
5592
@=
5593
j=pack_bytes(hot->op,hot->xx,hot->yy,hot->zz);
5594
if (hot->interrupt&H_BIT) { /* trip */
5595
  g[rW].o=incr(hot->loc,4);
5596
  g[rX].o.h=sign_bit, g[rX].o.l=j;
5597
  if (verbose&issue_bit) {
5598
    printf(" setting rW=");@+print_octa(g[rW].o);
5599
    printf(", rX=");@+print_octa(g[rX].o);@+printf("\n");
5600
  }
5601
}@+else { /* trap */
5602
  g[rWW].o=hot->go.o;
5603
  g[rXX].o.l=j;
5604
  if (hot->interrupt&F_BIT) { /* forced */
5605
    if (hot->i!=trap) j=RESUME_TRANS; /* emulate page translation */
5606
    else if (hot->op==TRAP) j=0x80; /* |TRAP| */
5607
    else if (flags[internal_op[hot->op]]&X_is_dest_bit)
5608
      j=RESUME_SET; /* emulation */
5609
    else j=0x80; /* emulation when r[X] is not a destination */
5610
  }@+else { /* dynamic */
5611
    if (hot->interim)
5612
      j=(hot->i==frem || hot->i==syncd || hot->i==syncid? RESUME_CONT:
5613
             RESUME_AGAIN);
5614
    else if (is_load_store(hot->i)) j=RESUME_AGAIN;
5615
    else j=0x80; /* normal external interruption */
5616
  }
5617
  g[rXX].o.h=(j<<24)+(hot->interrupt&0xff);
5618
  if (verbose&issue_bit) {
5619
    printf(" setting rWW=");@+print_octa(g[rWW].o);
5620
    printf(", rXX=");@+print_octa(g[rXX].o);@+printf("\n");
5621
  }
5622
}
5623
 
5624
@ @=
5625
j=hot->interrupt&H_BIT;
5626
if ((hot->interrupt&F_BIT) && hot->op==SWYM) g[rYY].o=hot->go.o;
5627
else g[j?rY:rYY].o=hot->y.o;
5628
if (hot->i==st || hot->i==pst) g[j?rZ:rZZ].o=hot->x.o;
5629
else g[j?rZ:rZZ].o=hot->z.o;
5630
if (verbose&issue_bit) {
5631
  if (j) {
5632
    printf(" setting rY=");@+print_octa(g[rY].o);
5633
    printf(", rZ=");@+print_octa(g[rZ].o);@+printf("\n");
5634
  }@+else {
5635
    printf(" setting rYY=");@+print_octa(g[rYY].o);
5636
    printf(", rZZ=");@+print_octa(g[rZZ].o);@+printf("\n");
5637
  }
5638
}
5639
 
5640
@ Whew; we've successfully interrupted the computation. The remaining
5641
task is to restart it again, as transparently as possible.
5642
 
5643
The \.{RESUME} instruction waits for the pipeline to drain, because
5644
it has to do such drastic things. For example, an interrupt may be
5645
occurring at this very moment, changing the registers needed for resumption.
5646
 
5647
@=
5648
case resume:@+ if (cool!=old_hot) goto stall;
5649
  inst_ptr=specval(&g[cool->zz? rWW:rW]);
5650
  if (!(cool->loc.h&sign_bit)) {
5651
    if (cool->zz) cool->interrupt |= K_BIT;
5652
    else if (inst_ptr.o.h&sign_bit) cool->interrupt |= P_BIT;
5653
  }
5654
  if (cool->interrupt) {
5655
    inst_ptr.o=incr(cool->loc,4);@+cool->i=noop;
5656
  }@+ else {
5657
    cool->go.o=inst_ptr.o;
5658
    if (cool->zz) {
5659
      @loc| is rT@>;
5660
      cool->ren_a=true, spec_install(&g[rK],&cool->a);
5661
      cool->a.known=true, cool->a.o=g[255].o;
5662
      cool->ren_x=true, spec_install(&g[255],&cool->x);
5663
      cool->x.known=true, cool->x.o=g[rBB].o;
5664
    }
5665
    cool->b= specval(&g[cool->zz? rXX:rX]);
5666
    if (!(cool->b.o.h&sign_bit)) @;
5667
  }@+break;
5668
 
5669
@ Here we set |cool->i=resum|, since we want to issue another instruction
5670
after the \.{RESUME} itself.
5671
 
5672
The restrictions on inserted instructions are designed to ensure that
5673
those instructions will be the very next ones issued. (If, for example,
5674
an |incgamma| instruction were necessary, it might cause a page fault
5675
and we'd lose the operand values for |RESUME_SET| or |RESUME_CONT|.)
5676
 
5677
A subtle point arises here: If |RESUME_TRANS| is being used to compute
5678
the page translation of virtual address zero, we don't want to execute
5679
the dummy \.{SWYM} instruction from virtual address $-4$! So we avoid
5680
the \.{SWYM} altogether.
5681
 
5682
@=
5683
{
5684
  cool->xx=cool->b.o.h>>24, cool->i=resum;
5685
  head->loc=incr(inst_ptr.o,-4);
5686
  switch(cool->xx) {
5687
 case RESUME_SET: cool->b.o.l=(SETH<<24)+(cool->b.o.l&0xff0000);
5688
  head->interrupt|=cool->b.o.h&0xff00;
5689
  resuming=2;
5690
 case RESUME_CONT: resuming+=1+cool->zz;
5691
  if (((cool->b.o.l>>24)&0xfa)!=0xb8) { /* not |syncd| or |syncid| */
5692
    m=cool->b.o.l>>28;
5693
    if ((1<
5694
    m=(cool->b.o.l>>16)&0xff;
5695
    if (m>=cool_L && m
5696
  }
5697
 case RESUME_AGAIN: resume_again: head->inst=cool->b.o.l;
5698
  m=head->inst>>24;
5699
  if (m==RESUME) goto bad_resume; /* avoid uninterruptible loop */
5700
  if (!cool->zz &&
5701
    m>RESUME && m<=SYNC && (head->inst&bad_inst_mask[m-RESUME]))
5702
      head->interrupt|=B_BIT;
5703
  head->noted=false;@+break;
5704
 case RESUME_TRANS:@+if (cool->zz) {
5705
    cool->y=specval(&g[rYY]), cool->z=specval(&g[rZZ]);
5706
    if ((cool->b.o.l>>24)!=SWYM) goto resume_again;
5707
    cool->i=resume;@+break; /* see ``subtle point'' above */
5708
  }
5709
 default: bad_resume: cool->interrupt |= B_BIT, cool->i=noop;
5710
  resuming=0;@+break;
5711
  }
5712
}
5713
 
5714
@ @=
5715
{
5716
  if (resuming&1) {
5717
    cool->y=specval(&g[rY]);
5718
    cool->z=specval(&g[rZ]);
5719
  }@+else {
5720
    cool->y=specval(&g[rYY]);
5721
    cool->z=specval(&g[rZZ]);
5722
  }
5723
  if (resuming>=3) { /* |RESUME_SET| */
5724
    cool->need_ra=true, cool->ra=specval(&g[rA]);
5725
  }
5726
  cool->usage=false;
5727
}
5728
 
5729
@ @d do_resume_trans 17 /* |state| for performing |RESUME_TRANS| actions */
5730
 
5731
@=
5732
case resume: case resum:@+if (data->xx!=RESUME_TRANS) goto fin_ex;
5733
 data->ptr_a=(void*)((data->b.o.l>>24)==SWYM? ITcache: DTcache);
5734
 data->state=do_resume_trans;
5735
 data->z.o=incr(oandn(data->z.o,page_mask),data->z.o.l&7);
5736
 data->z.o.h &= 0xffff;
5737
 goto resume_trans;
5738
 
5739
@ @=
5740
case do_resume_trans: resume_trans: {@+register cache*c=(cache*)data->ptr_a;
5741
   if (c->lock) wait(1);
5742
   if (c->filler.next) wait(1);
5743
   p=alloc_slot(c,trans_key(data->y.o));
5744
   if (p) {
5745
     c->filler_ctl.ptr_b=(void*)p;
5746
     c->filler_ctl.y.o=data->y.o;
5747
     c->filler_ctl.b.o=data->z.o;
5748
     c->filler_ctl.state=1;
5749
     schedule(&c->filler,c->access_time,1);
5750
   }
5751
   goto fin_ex;
5752
 }
5753
 
5754
 
5755
@* Administrative operations.
5756
The internal instructions that handle the register stack simply reduce
5757
to things we already know how to do. (Well, the internal instructions
5758
for saving and unsaving do sometimes lead to special cases, based on
5759
|data->op|; for the most part, though, the necessary mechanisms are
5760
already present.)
5761
 
5762
@=
5763
case noop:@+if (data->interrupt&F_BIT) goto emulate_virt;
5764
case jmp: case pushj: case incrl: case unsave: goto fin_ex;
5765
case sav:@+if (!(data->mem_x)) goto fin_ex;
5766
case incgamma: case save: data->i=st; goto switch1;
5767
case decgamma: case unsav: data->i=ld; goto switch1;
5768
 
5769
@ We can \.{GET} special registers $\ge21$ (that is, rA, rF, rP, rW--rZ,
5770
or rWW--rZZ) only in the hot seat, because those registers are
5771
implicit outputs of many instructions.
5772
 
5773
The same applies to rK, since it is changed by \.{TRAP} and
5774
by emulated instructions.
5775
 
5776
@=
5777
case get:@+ if (data->zz>=21 || data->zz==rK) {
5778
   if (data!=old_hot) wait(1);
5779
   data->z.o=g[data->zz].o;
5780
 }
5781
 data->x.o=data->z.o;@+goto fin_ex;
5782
 
5783
@ A \.{PUT} is, similarly, delayed in the cases that hold |dispatch_lock|.
5784
This program does not restrict the 1~bits that might be
5785
\.{PUT} into~rQ, although the contents of that register can have
5786
drastic implications.
5787
 
5788
@=
5789
case put:@+if (data->xx>=15 && data->xx<=20) {
5790
   if (data!=old_hot) wait(1);
5791
   switch (data->xx) {
5792
  case rV: @;@+break;
5793
  case rQ: new_Q.h |= data->z.o.h &~ g[rQ].o.h;@+
5794
           new_Q.l |= data->z.o.l &~ g[rQ].o.l;
5795
           data->z.o.l |= new_Q.l;@+
5796
           data->z.o.h |= new_Q.h;@+break;
5797
  case rL:@+ if (data->z.o.h!=0) data->z.o.h=0, data->z.o.l=g[rL].o.l;
5798
     else if (data->z.o.l>g[rL].o.l) data->z.o.l=g[rL].o.l;
5799
  default: break;
5800
  case rG: @;@+break;
5801
   }
5802
 }@+else if (data->xx==rA && (data->z.o.h!=0 || data->z.o.l>=0x40000))
5803
   data->interrupt |= B_BIT;
5804
 data->x.o=data->z.o;@+goto fin_ex;
5805
 
5806
@ When rG decreases, we assume that up to |commit_max| marginal registers can
5807
be zeroed during each clock cycle. (Remember that we're currently in the hot
5808
seat, and holding |dispatch_lock|.)
5809
 
5810
@=
5811
if (data->z.o.h!=0 || data->z.o.l>=256 ||
5812
      data->z.o.lz.o.l<32)
5813
  data->interrupt |= B_BIT;
5814
else if (data->z.o.l
5815
    data->interim=true; /* potentially interruptible */
5816
    for (j=0;j
5817
      g[rG].o.l--;
5818
      g[g[rG].o.l].o=zero_octa;
5819
      if (data->z.o.l==g[rG].o.l) break;
5820
    }
5821
    if (j==commit_max) {
5822
      if (!trying_to_interrupt) wait(1);
5823
    }@+else data->interim=false;
5824
  }
5825
 
5826
@ Computed jumps put the desired destination address into the |go| field.
5827
 
5828
@=
5829
case go: data->x.o=data->go.o;@+ goto add_go;
5830
case pop: data->x.o=data->y.o; data->y.o=data->b.o; /* move rJ to |y| field */
5831
case pushgo: add_go: data->go.o=oplus(data->y.o,data->z.o);
5832
  if ((data->go.o.h&sign_bit) && !(data->loc.h&sign_bit))
5833
    data->interrupt |= P_BIT;
5834
  data->go.known=true;@+goto fin_ex;
5835
 
5836
@ The instruction \.{UNSAVE} $z$ generates a sequence of internal instructions
5837
that accomplish the actual unsaving. This sequence is controlled by the
5838
instruction currently in the fetch buffer, which changes its X and~Y fields
5839
until all global registers have been loaded. The first instructions of the
5840
sequence are \.{UNSAVE}~$0,0,z$; \.{UNSAVE}~$1,rZ,z-8$;
5841
\.{UNSAVE}~$1,rY,z-16$; \dots;
5842
\.{UNSAVE}~$1,rB,z-96$; \.{UNSAVE}~$2,255,z-104$; \.{UNSAVE}~$2,254,z-112$;
5843
etc. If an interrupt occurs before these instructions have all been committed,
5844
the execution register will contain enough information to restart the process.
5845
 
5846
After the global registers have all been loaded, \.{UNSAVE} continues by
5847
acting rather like~\.{POP}. An interrupt occurring during this last stage
5848
will find $\rm rS
5849
restoring the local registers again. But no information will be lost,
5850
even though the register from which we began unsaving has long since
5851
been replaced.
5852
 
5853
@=
5854
case unsave:@+if (cool->interrupt&B_BIT) cool->i=noop;
5855
 else {
5856
   cool->interim=true;
5857
   op=LDOU; /* this instruction needs to be handled by load/store unit */
5858
   cool->i=unsav;
5859
   switch(cool->xx) {
5860
 case 0:@+ if (cool->z.p) goto stall;
5861
  @;@+break;
5862
 case 1: case 2: @;@+break;
5863
 case 3: cool->i=unsave, cool->interim=false, op=UNSAVE;
5864
   goto pop_unsave;
5865
 default: cool->interim=false,cool->i=noop,cool->interrupt|=B_BIT;@+break;
5866
   }
5867
 }
5868
break; /* this takes us to |dispatch_done| */
5869
 
5870
@ @=
5871
cool->ren_x=true, spec_install(&g[cool->yy],&cool->x);
5872
new_O=new_S=incr(cool_O,-1);
5873
cool->z.o=shift_left(new_O,3);
5874
cool->ptr_a=(void*)mem.up;
5875
 
5876
@ @=
5877
cool->ren_x=true, spec_install(&g[rG],&cool->x);
5878
cool->ren_a=true, spec_install(&g[rA],&cool->a);
5879
new_O=new_S=shift_right(cool->z.o,3,1);
5880
cool->set_l=true, spec_install(&g[rL],&cool->rl);
5881
cool->ptr_a=(void*)mem.up;
5882
 
5883
@ @=
5884
switch (cool->xx) {
5885
 case 0: head->inst=pack_bytes(UNSAVE,1,rZ,0);@+ break;
5886
 case 1:@+ if (cool->yy==rP) head->inst=pack_bytes(UNSAVE,1,rR,0);
5887
  else if (cool->yy==0) head->inst=pack_bytes(UNSAVE,2,255,0);
5888
  else head->inst=pack_bytes(UNSAVE,1,cool->yy-1,0);@+ break;
5889
 case 2:@+ if (cool->yy==cool_G) head->inst=pack_bytes(UNSAVE,3,0,0);
5890
  else head->inst=pack_bytes(UNSAVE,2,cool->yy-1,0);@+ break;
5891
}
5892
 
5893
@ @=
5894
if (data->xx==0) {
5895
  data->a.o=data->x.o;@+data->a.o.h &=0xffffff; /* unsaved rA */
5896
  data->x.o.l=data->x.o.h>>24;@+data->x.o.h=0; /* unsaved rG */
5897
  if (data->a.o.h || (data->a.o.l&0xfffc0000)) {
5898
    data->a.o.h=0, data->a.o.l&=0x3ffff;@+ data->interrupt |= B_BIT;
5899
  }
5900
  if (data->x.o.l<32) {
5901
    data->x.o.l=32;@+ data->interrupt |= B_BIT;
5902
  }
5903
}
5904
goto fin_ex;
5905
 
5906
@ Of course \.{SAVE} is handled essentially like \.{UNSAVE}, but backwards.
5907
 
5908
@=
5909
case save:@+if (cool->xxinterrupt|=B_BIT;
5910
 if (cool->interrupt&B_BIT) cool->i=noop;
5911
 else if (((cool_S.l-cool_O.l-cool_L-1)&lring_mask)==0)
5912
      @@;
5913
 else {
5914
   cool->interim=true;
5915
   cool->i=sav;
5916
   switch(cool->zz) {
5917
 case 0: @;@+break;
5918
 case 1:@+if (cool_O.l!=cool_S.l) @@;
5919
   cool->zz=2;@+ cool->yy=cool_G;
5920
 case 2: case 3: @;@+break;
5921
 default: cool->interim=false,cool->i=noop,cool->interrupt|=B_BIT;@+break;
5922
   }
5923
 }
5924
break;
5925
 
5926
@ If an interrupt occurs during the first phase, say between two |incgamma|
5927
instructions, the value |cool->zz=1| will get things restarted properly.
5928
(Indeed, if context is saved and unsaved during the interrupt, many
5929
|incgamma| instructions may no longer be necessary.)
5930
 
5931
@=
5932
cool->zz=1;
5933
cool->ren_x=true, spec_install(&l[(cool_O.l+cool_L)&lring_mask],&cool->x);
5934
cool->x.known=true, cool->x.o.h=0, cool->x.o.l=cool_L;
5935
cool->set_l=true, spec_install(&g[rL],&cool->rl);
5936
new_O=incr(cool_O,cool_L+1);
5937
 
5938
@ @=
5939
op=STOU; /* this instruction needs to be handled by load/store unit */
5940
cool->mem_x=true, spec_install(&mem,&cool->x);
5941
cool->z.o=shift_left(cool_O,3);
5942
new_O=new_S=incr(cool_O,1);
5943
if (cool->zz==3 && cool->yy>rZ) @@;
5944
else cool->b=specval(&g[cool->yy]);
5945
 
5946
@ The final \.{SAVE} instruction not only stores rG and rA, it also
5947
places the final address in global register~X.
5948
 
5949
@=
5950
{
5951
  cool->i=save;
5952
  cool->interim=false;
5953
  cool->ren_a=true, spec_install(&g[cool->xx],&cool->a);
5954
}
5955
 
5956
@ @=
5957
switch (cool->zz) {
5958
 case 1: head->inst=pack_bytes(SAVE,cool->xx,0,1);@+ break;
5959
 case 2:@+ if (cool->yy==255) head->inst=pack_bytes(SAVE,cool->xx,0,3);
5960
  else head->inst=pack_bytes(SAVE,cool->xx,cool->yy+1,2);@+break;
5961
 case 3:@+ if (cool->yy==rR) head->inst=pack_bytes(SAVE,cool->xx,rP,3);
5962
  else head->inst=pack_bytes(SAVE,cool->xx,cool->yy+1,3);@+break;
5963
}
5964
 
5965
@ @=
5966
{
5967
  if (data->interim) data->x.o=data->b.o;
5968
  else {
5969
    if (data!=old_hot) wait(1); /* we need the hottest value of rA */
5970
    data->x.o.h=g[rG].o.l<<24;
5971
    data->x.o.l=g[rA].o.l;
5972
    data->a.o=data->y.o;
5973
  }
5974
  goto fin_ex;
5975
}
5976
 
5977
@* More register-to-register ops.
5978
Now that we've finished most of the hard stuff,
5979
we can relax and fill in the holes that we left in the
5980
all-register parts of the execution stages.
5981
 
5982
First let's complete the fixed point arithmetic operations,
5983
by dispensing with multiplication and division.
5984
 
5985
@=
5986
case mulu: data->x.o=omult(data->y.o,data->z.o);
5987
  data->a.o=aux;
5988
  goto quantify_mul;
5989
case mul: data->x.o=signed_omult(data->y.o,data->z.o);
5990
  if (overflow) data->interrupt |= V_BIT;
5991
quantify_mul: aux=data->z.o;
5992
  for (j=mul0;aux.l||aux.h;j++) aux=shift_right(aux,8,1);
5993
  data->i=j;@+break; /* |j| is |mul0| or |mul1| or \dots~or |mul8| */
5994
case divu: data->x.o=odiv(data->b.o,data->y.o,data->z.o);
5995
  data->a.o=aux;@+data->i=div;@+break;
5996
case div:@+ if (data->z.o.l==0 && data->z.o.h==0) {
5997
    data->interrupt |= D_BIT;@+ data->a.o=data->y.o;
5998
    data->i=set; /* divide by zero needn't wait in the pipeline */
5999
  }@+else {
6000
    data->x.o=signed_odiv(data->y.o,data->z.o);
6001
    if (overflow) data->interrupt |= V_BIT;
6002
    data->a.o=aux;
6003
  }@+break;
6004
 
6005
@ Next let's polish off the bitwise and bytewise operations.
6006
 
6007
@=
6008
case sadd: data->x.o.l=count_bits(data->y.o.h&~data->z.o.h)
6009
                      +count_bits(data->y.o.l&~data->z.o.l);@+ break;
6010
case mor: data->x.o=bool_mult(data->y.o,data->z.o,data->op&0x2);@+ break;
6011
case bdif: data->x.o.h=byte_diff(data->y.o.h,data->z.o.h);
6012
           data->x.o.l=byte_diff(data->y.o.l,data->z.o.l);@+ break;
6013
case wdif: data->x.o.h=wyde_diff(data->y.o.h,data->z.o.h);
6014
           data->x.o.l=wyde_diff(data->y.o.l,data->z.o.l);@+ break;
6015
case tdif:@+ if (data->y.o.h>data->z.o.h)
6016
             data->x.o.h=data->y.o.h-data->z.o.h;
6017
 tdif_l:@+ if (data->y.o.l>data->z.o.l)
6018
             data->x.o.l=data->y.o.l-data->z.o.l;@+ break;
6019
case odif:@+ if (data->y.o.h>data->z.o.h)
6020
    data->x.o=ominus(data->y.o,data->z.o);
6021
  else if (data->y.o.h==data->z.o.h) goto tdif_l;
6022
  break;
6023
 
6024
 
6025
@ The conditional set (\.{CS}) instructions are, rather surprisingly,
6026
more difficult to implement than the zero~set (\.{ZS}) instructions,
6027
although the \.{ZS} instructions do more. The reason is that dynamic
6028
instruction dependencies are more complicated with \.{CS}. Consider, for
6029
example, the instructions
6030
$$\advance\abovedisplayskip-.5\baselineskip
6031
  \advance\belowdisplayskip-.5\baselineskip
6032
\hbox{\tt LDO x,a,b; \ FDIV y,c,d; \ CSZ y,x,0; \ INCL y,1.}$$
6033
If the value of \.x is zero, the \.{INCL} instruction need not wait for the
6034
division to be completed. (We do not, however, abort the division in such a
6035
case; it might invoke a trip handler, or change the inexact bit, etc. Our
6036
policy is to treat common cases efficiently and to treat all cases correctly,
6037
but not to treat all cases with maximum efficiency.)
6038
 
6039
@=
6040
case zset:@+if (register_truth(data->y.o,data->op)) data->x.o=data->z.o;
6041
  /* otherwise |data->x.o| is already zero */
6042
  goto fin_ex;
6043
case cset:@+if (register_truth(data->y.o,data->op))
6044
    data->x.o=data->z.o, data->b.p=NULL;
6045
  else if (data->b.p==NULL) data->x.o=data->b.o;
6046
  else {
6047
    data->state=0;@+data->need_b=true;@+goto switch1;
6048
  }@+break;
6049
 
6050
@ Floating point computations are mostly handled by the routines in
6051
{\mc MMIX-ARITH}, which record anomalous events in the global
6052
variable |exceptions|. But we consider the operation trivial if an
6053
input is infinite or NaN; and we may need to increase the execution
6054
time when subnormals are present.
6055
 
6056
@d ROUND_OFF 1
6057
@d ROUND_UP 2
6058
@d ROUND_DOWN 3
6059
@d ROUND_NEAR 4
6060
@d is_subnormal(x) ((x.h&0x7ff00000)==0 && ((x.h&0xfffff) || x.l))
6061
@d is_trivial(x) ((x.h&0x7ff00000)==0x7ff00000)
6062
@d set_round cur_round=(data->ra.o.l<0x10000? ROUND_NEAR: data->ra.o.l>>16)
6063
 
6064
@=
6065
case fadd: set_round;@+data->x.o=fplus(data->y.o,data->z.o);
6066
 fin_bflot:@+ if (is_subnormal(data->y.o)) data->denin=denin_penalty;
6067
 fin_uflot:@+ if (is_subnormal(data->x.o)) data->denout=denout_penalty;
6068
 fin_flot:@+ if (is_subnormal(data->z.o)) data->denin=denin_penalty;
6069
   data->interrupt|=exceptions;
6070
   if (is_trivial(data->y.o) || is_trivial(data->z.o)) goto fin_ex;
6071
   if (data->i==fsqrt && (data->z.o.h&sign_bit)) goto fin_ex;
6072
   break;
6073
case fsub: data->a.o=data->z.o;
6074
  if (fcomp(data->z.o,zero_octa)!=2) data->a.o.h ^= sign_bit;
6075
  set_round;@+data->x.o=fplus(data->y.o,data->a.o);
6076
  data->i=fadd; /* use pipeline times for addition */
6077
  goto fin_bflot;
6078
case fmul: set_round;@+ data->x.o=fmult(data->y.o,data->z.o);@+ goto fin_bflot;
6079
case fdiv: set_round;@+ data->x.o=fdivide(data->y.o,data->z.o);@+
6080
  goto fin_bflot;
6081
case fsqrt: set_round;@+ data->x.o=froot(data->z.o,data->y.o.l);@+
6082
  goto fin_uflot;
6083
case fint: set_round;@+ data->x.o=fintegerize(data->z.o,data->y.o.l);@+
6084
  goto fin_uflot;
6085
case fix: set_round;@+ data->x.o=fixit(data->z.o,data->y.o.l);
6086
  if (data->op&0x2) exceptions&=~W_BIT; /* unsigned case doesn't overflow */
6087
  goto fin_flot;
6088
case flot: set_round;@+
6089
  data->x.o=floatit(data->z.o,data->y.o.l,data->op&0x2, data->op&0x4);
6090
  data->interrupt|=exceptions;@+break;
6091
 
6092
@ @=
6093
case fsqrt: case fint: case fix: case flot:@+ if (cool->y.o.l>4)
6094
    goto illegal_inst;
6095
  break;
6096
 
6097
@ @=
6098
case feps: j=fepscomp(data->y.o,data->z.o,data->b.o,data->op!=FEQLE);
6099
  if (j==2) data->i=fcmp;
6100
  else if (is_subnormal(data->y.o) || is_subnormal(data->z.o))
6101
    data->denin=denin_penalty;
6102
  switch (data->op) {
6103
 case FUNE:@+ if (j==2) goto cmp_pos;@+ else goto cmp_zero;
6104
 case FEQLE: goto cmp_fin;
6105
 case FCMPE:@+ if (j) goto cmp_zero_or_invalid;
6106
  }
6107
case fcmp: j=fcomp(data->y.o,data->z.o);
6108
  if (j<0) goto cmp_neg;
6109
 cmp_fin:@+ if (j==1) goto cmp_pos;
6110
 cmp_zero_or_invalid:@+ if (j==2) data->interrupt |= I_BIT;
6111
  goto cmp_zero;
6112
case funeq:@+ if (fcomp(data->y.o,data->z.o)==(data->op==FUN? 2:0))
6113
    goto cmp_pos;
6114
  else goto cmp_zero;
6115
 
6116
@ @=
6117
Extern int frem_max;
6118
Extern int denin_penalty, denout_penalty;
6119
 
6120
@ The floating point remainder operation is especially interesting
6121
because it can be interrupted when it's in the hot seat.
6122
 
6123
@=
6124
case frem:@+if(is_trivial(data->y.o) || is_trivial(data->z.o))
6125
    {
6126
      data->x.o=fremstep(data->y.o,data->z.o,2500);@+ goto fin_ex;
6127
    }
6128
  if ((self+1)->next) wait(1);
6129
  data->interim=true;
6130
  j=1;
6131
  if (is_subnormal(data->y.o)||is_subnormal(data->z.o)) j+=denin_penalty;
6132
  pass_after(j);
6133
  goto passit;
6134
 
6135
 
6136
@ @=
6137
j=1;
6138
if (data->i==frem) {
6139
  data->x.o=fremstep(data->y.o,data->z.o,frem_max);
6140
  if (exceptions&E_BIT) {
6141
    data->y.o=data->x.o;
6142
    if (trying_to_interrupt && data==old_hot) goto fin_ex;
6143
  }@+else {
6144
    data->state=3;
6145
    data->interim=false;
6146
    data->interrupt |= exceptions;
6147
    if (is_subnormal(data->x.o)) j+=denout_penalty;
6148
  }
6149
  wait(j);
6150
}
6151
 
6152
@* System operations. Finally we need to implement some operations for the
6153
operating system; then the hardware simulation will be done!
6154
 
6155
A \.{LDVTS} instruction is delayed until it reaches the hot seat, because
6156
it changes the IT and DT caches. The operating system should use \.{SYNC}
6157
after \.{LDVTS} if the effects are needed immediately; the system is also
6158
responsible for ensuring that the page table permission bits agree with
6159
the \.{LDVTS} permission bits when the latter are nonzero. (Also, if
6160
write permission is taken away from a page, the operating system must
6161
have previously used \.{SYNCD} to write out any dirty bytes that might
6162
have been cached from that page; \.{SYNCD} will be inoperative after write
6163
permission goes away.)
6164
 
6165
@=
6166
if (data->i==ldvts) @;
6167
 
6168
@ @=
6169
{
6170
  if (data!=old_hot) wait(1);
6171
  if (DTcache->lock || (j=get_reader(DTcache))<0) wait(1);
6172
  startup(&DTcache->reader[j],DTcache->access_time);
6173
  data->z.o.h=0, data->z.o.l=data->y.o.l&0x7;
6174
  p=cache_search(DTcache,data->y.o); /* N.B.: Not |trans_key(data->y.o)| */
6175
  if (p) {
6176
    data->x.o.l=2;
6177
    if (data->z.o.l) {
6178
      p=use_and_fix(DTcache,p);
6179
      p->data[0].l=(p->data[0].l&-8)+data->z.o.l;
6180
    }@+else {
6181
      p=demote_and_fix(DTcache,p);
6182
      p->tag.h|=sign_bit; /* invalidate the tag */
6183
    }
6184
  }
6185
  pass_after(DTcache->access_time);@+goto passit;
6186
}
6187
 
6188
@ @=
6189
case ld_st_launch:@+ if (ITcache->lock || (j=get_reader(ITcache))<0) wait(1);
6190
  startup(&ITcache->reader[j],ITcache->access_time);
6191
  p=cache_search(ITcache,data->y.o); /* N.B.: Not |trans_key(data->y.o)| */
6192
  if (p) {
6193
    data->x.o.l|=1;
6194
    if (data->z.o.l) {
6195
      p=use_and_fix(ITcache,p);
6196
      p->data[0].l=(p->data[0].l&-8)+data->z.o.l;
6197
    }@+else {
6198
      p=demote_and_fix(ITcache,p);
6199
      p->tag.h|=sign_bit; /* invalidate the tag */
6200
    }
6201
  }
6202
  data->state=3;@+wait(ITcache->access_time);
6203
 
6204
@ The \.{SYNC} operation interacts with the pipeline in interesting ways.
6205
\.{SYNC}~\.0 and \.{SYNC}~\.4 are the simplest; they just lock the
6206
dispatch and wait until they get to the hot seat, after which the
6207
pipeline has drained. \.{SYNC}~\.1 and \.{SYNC}~\.3 put a ``barrier''
6208
into the write buffer so that subsequent store instructions will not merge with
6209
previous stores. \.{SYNC}~\.2 and \.{SYNC}~\.3 lock the dispatch until
6210
all previous load instructions have left the pipeline. \.{SYNC}~\.5,
6211
\.{SYNC}~\.6, and \.{SYNC}~\.7 remove things from caches once they
6212
get to the hot seat.
6213
 
6214
@=
6215
case sync:@+ if (cool->zz>3) {
6216
  if (!(cool->loc.h&sign_bit)) goto privileged_inst;
6217
  if (cool->zz==4) freeze_dispatch=true;
6218
}@+else {
6219
  if (cool->zz!=1) freeze_dispatch=true;
6220
  if (cool->zz&1) cool->mem_x=true, spec_install(&mem,&cool->x);
6221
}@+break;
6222
 
6223
@ @=
6224
case sync:@+ switch (data->zz) {
6225
 case 0: case 4:@+ if (data!=old_hot) wait(1);
6226
  halted=(data->zz!=0);@+goto fin_ex;
6227
 case 2: case 3: @;
6228
  release_lock(self,dispatch_lock);
6229
 case 1: data->x.addr=zero_octa;@+goto fin_ex;
6230
 case 5:@+ if (data!=old_hot) wait(1);
6231
  @;
6232
 case 6:@+ if (data!=old_hot) wait(1);
6233
  @;
6234
 case 7:@+ if (data!=old_hot) wait(1);
6235
  @;
6236
}
6237
 
6238
@ @=
6239
{
6240
  register control *cc;
6241
  for (cc=data;cc!=hot;) {
6242
    cc=(cc==reorder_top? reorder_bot: cc+1);
6243
    if (cc->owner && (cc->i==ld || cc->i==ldunc || cc->i==pst)) wait(1);
6244
  }
6245
}
6246
 
6247
@ Perhaps the delay should be longer here.
6248
 
6249
@=
6250
if (DTcache->lock || (j=get_reader(DTcache))<0) wait(1);
6251
startup(&DTcache->reader[j],DTcache->access_time);
6252
set_lock(self,DTcache->lock);
6253
zap_cache(DTcache);
6254
data->state=10;@+wait(DTcache->access_time);
6255
 
6256
@ @=
6257
if (!Icache) {
6258
  data->state=11;@+goto switch1;
6259
}
6260
if (Icache->lock || (j=get_reader(Icache))<0) wait(1);
6261
startup(&Icache->reader[j],Icache->access_time);
6262
set_lock(self,Icache->lock);
6263
zap_cache(Icache);
6264
data->state=11;@+wait(Icache->access_time);
6265
 
6266
@ @=
6267
case 10:@+ if (self->lockloc) *(self->lockloc)=NULL,self->lockloc=NULL;
6268
 if (ITcache->lock || (j=get_reader(ITcache))<0) wait(1);
6269
 startup(&ITcache->reader[j],ITcache->access_time);
6270
 set_lock(self,ITcache->lock);
6271
 zap_cache(ITcache);
6272
 data->state=3;@+wait(ITcache->access_time);
6273
case 11:@+ if (self->lockloc) *(self->lockloc)=NULL,self->lockloc=NULL;
6274
 if (wbuf_lock) wait(1);
6275
 write_head=write_tail, write_ctl.state=0; /* zap the write buffer */
6276
 if (!Dcache) {
6277
   data->state=12;@+ goto switch1;
6278
 }
6279
 if (Dcache->lock || (j=get_reader(Dcache))<0) wait(1);
6280
 startup(&Dcache->reader[j],Dcache->access_time);
6281
 set_lock(self,Dcache->lock);
6282
 zap_cache(Dcache);
6283
 data->state=12;@+wait(Dcache->access_time);
6284
case 12:@+ if (self->lockloc) *(self->lockloc)=NULL,self->lockloc=NULL;
6285
 if (!Scache) goto fin_ex;
6286
 if (Scache->lock) wait(1);
6287
 set_lock(self,Scache->lock);
6288
 zap_cache(Scache);
6289
 data->state=3;@+wait(Scache->access_time);
6290
 
6291
@ @=
6292
if (self->lockloc) *(self->lockloc)=NULL,self->lockloc=NULL;
6293
@;
6294
if (clean_co.next || clean_lock) wait(1);
6295
set_lock(self,clean_lock);
6296
clean_ctl.i=sync;@+
6297
clean_ctl.state=0;@+
6298
clean_ctl.x.o.h=0;
6299
startup(&clean_co,1);
6300
data->state=13;
6301
data->interim=true;
6302
wait(1);
6303
 
6304
@ @=
6305
if (write_head!=write_tail) {
6306
  if (!speed_lock) set_lock(self,speed_lock);
6307
  wait(1);
6308
}
6309
 
6310
@ The cleanup process might take a huge amount of time, so we must allow
6311
it to be interrupted. (Servicing the interruption might, of course,
6312
put more stuff into the cache.)
6313
 
6314
@=
6315
case 13:@+ if (!clean_co.next) {
6316
   data->interim=false;@+ goto fin_ex; /* it's done! */
6317
 }
6318
 if (trying_to_interrupt) goto fin_ex; /* accept an interruption */
6319
 wait(1);
6320
 
6321
@ Now we consider \.{SYNCD} and \.{SYNCID}. When control comes to this
6322
part of the program, |data->y.o| is a virtual address and |data->z.o|
6323
is the corresponding physical address; |data->xx+1| is the number of
6324
bytes we are supposed to be syncing; |data->b.o.l| is the number of
6325
bytes we can handle at once (either |Icache->bb| or |Dcache->bb| or 8192).
6326
 
6327
We need a more elaborate scheme to implement \.{SYNCD} and \.{SYNCID}
6328
than we have used for the ``hint'' instructions \.{PRELD}, \.{PREGO},
6329
and \.{PREST}, because \.{SYNCD} and \.{SYNCID} are not merely hints.
6330
They cannot be converted into a sequence of cache-block-size commands at
6331
dispatch time, because we cannot be sure that the starting virtual address
6332
will be aligned with the beginning of a cache block. We need to realize
6333
that the bytes specified by \.{SYNCD} or \.{SYNCID} might cross a
6334
virtual page boundary---possibly with different protection bits
6335
on each page. We need to allow for interrupts. And we also need to
6336
keep the fetch buffer empty until a user's \.{SYNCID} has completely
6337
brought the memory up to date.
6338
 
6339
@=
6340
do_syncid: data->state=30;
6341
case 30:@+ if (data!=old_hot) wait(1);
6342
 if (!Icache) {
6343
   data->state=(data->loc.h&sign_bit? 31:33);@+goto switch2;
6344
 }
6345
 @z.o|, if any@>;
6346
 data->state=(data->loc.h&sign_bit? 31: 33);@+wait(Icache->access_time);
6347
case 31:@+ if (self->lockloc) *(self->lockloc)=NULL,self->lockloc=NULL;
6348
 @;
6349
 if (((data->b.o.l-1)&~data->y.o.l)xx) data->interim=true;
6350
 if (!Dcache) goto next_sync;
6351
 @z.o|, if any@>;
6352
 data->state=32;@+wait(Dcache->access_time);
6353
case 32:@+ if (self->lockloc) *(self->lockloc)=NULL,self->lockloc=NULL;
6354
 if (!Scache) goto next_sync;
6355
 @z.o|, if any@>;
6356
 data->state=35;@+wait(Scache->access_time);
6357
do_syncd: data->state=33;
6358
case 33:@+ if (data!=old_hot) wait(1);
6359
 if (self->lockloc) *(self->lockloc)=NULL,self->lockloc=NULL;
6360
 @;
6361
 if (((data->b.o.l-1)&~data->y.o.l)xx) data->interim=true;
6362
 if (!Dcache)
6363
   if (data->i==syncd) goto fin_ex;@+ else goto next_sync;
6364
 @z.o|, if any@>;
6365
 data->state=34;
6366
case 34:@+if (!clean_co.next) goto next_sync;
6367
 if (trying_to_interrupt && data->interim && data==old_hot) {
6368
   data->z.o=zero_octa; /* anticipate |RESUME_CONT| */
6369
   goto fin_ex; /* accept an interruption */
6370
 }
6371
 wait(1);
6372
next_sync: data->state=35;
6373
case 35:@+ if (self->lockloc) *(self->lockloc)=NULL,self->lockloc=NULL;
6374
 if (data->interim) @;
6375
 data->go.known=true;
6376
 goto fin_ex;
6377
 
6378
@ @z.o|, if any@>=
6379
if (Icache->lock || (j=get_reader(Icache))<0) wait(1);
6380
startup(&Icache->reader[j],Icache->access_time);
6381
set_lock(self,Icache->lock);
6382
p=cache_search(Icache,data->z.o);
6383
if (p) {
6384
  demote_and_fix(Icache,p);
6385
  clean_block(Icache,p);
6386
}
6387
 
6388
@ @z.o|, if any@>=
6389
if (Dcache->lock || (j=get_reader(Dcache))<0) wait(1);
6390
startup(&Dcache->reader[j],Dcache->access_time);
6391
set_lock(self,Dcache->lock);
6392
p=cache_search(Dcache,data->z.o);
6393
if (p) {
6394
  demote_and_fix(Dcache,p);
6395
  clean_block(Dcache,p);
6396
}
6397
 
6398
@ @z.o|, if any@>=
6399
if (Scache->lock) wait(1);
6400
set_lock(self,Scache->lock);
6401
p=cache_search(Scache,data->z.o);
6402
if (p) {
6403
  demote_and_fix(Scache,p);
6404
  clean_block(Scache,p);
6405
}
6406
 
6407
@ @z.o|, if any@>=
6408
if (clean_co.next || clean_lock) wait(1);
6409
set_lock(self,clean_lock);
6410
clean_ctl.i=syncd;
6411
clean_ctl.state=4;
6412
clean_ctl.x.o.h=data->loc.h&sign_bit;
6413
clean_ctl.z.o=data->z.o;
6414
schedule(&clean_co,1,4);
6415
 
6416
@ We use the fact that cache block sizes are divisors of 8192.
6417
 
6418
@=
6419
{
6420
  data->interim=false;
6421
  data->xx -= ((data->b.o.l-1)&~data->y.o.l)+1;
6422
  data->y.o=incr(data->y.o,data->b.o.l);
6423
  data->y.o.l &= -data->b.o.l;
6424
  data->z.o.l = (data->z.o.l&-8192)+(data->y.o.l&8191);
6425
  if ((data->y.o.l&8191)==0) goto square_one;
6426
      /* maybe crossed a page boundary */
6427
  if (data->i==syncd) goto do_syncd;@+else goto do_syncid;
6428
}
6429
 
6430
@ If the first page lacks proper protection, we still must try the
6431
second, in the rare case that a page boundary is spanned.
6432
 
6433
@=
6434
sync_check:@+ if ((data->y.o.l ^ (data->y.o.l+data->xx))>=8192) {
6435
   data->xx -= (8191&~data->y.o.l)+1;
6436
   data->y.o=incr(data->y.o,8192);
6437
   data->y.o.l &= -8192;
6438
   goto square_one;
6439
 }
6440
 goto fin_ex;
6441
 
6442
@* Input and output. We're done implementing the hardware, but there's
6443
still a small matter of software remaining, because we sometimes
6444
want to pretend that a real operating
6445
system is present without actually having one loaded. This simulator
6446
therefore implements a special feature: If \.{RESUME}~\.1 is issued in
6447
location~rT, the ten special I/O traps of {\mc MMIX-SIM} are performed
6448
instantaneously behind the scenes.
6449
 
6450
Of course all claims of accurate simulation go out the door when this
6451
feature is used.
6452
 
6453
@d max_sys_call Ftell
6454
 
6455
@=
6456
typedef enum{
6457
@!Halt,@!Fopen,@!Fclose,@!Fread,@!Fgets,@!Fgetws,
6458
@!Fwrite,@!Fputs,@!Fputws,@!Fseek,@!Ftell} @!sys_call;
6459
 
6460
@ @loc| is rT@>=
6461
if (cool->loc.l==g[rT].o.l && cool->loc.h==g[rT].o.h) {
6462
  register unsigned char yy,zz; octa ma,mb;
6463
  if (g[rXX].o.l&0xffff0000) goto magic_done;
6464
  yy=g[rXX].o.l>>8, zz=g[rXX].o.l&0xff;
6465
  if (yy>max_sys_call) goto magic_done;
6466
   @
6467
           if needed@>;
6468
  switch (yy) {
6469
case Halt: @;@+break;
6470
case Fopen: g[rBB].o=mmix_fopen(zz,mb,ma);@+break;
6471
case Fclose: g[rBB].o=mmix_fclose(zz);@+break;
6472
case Fread: g[rBB].o=mmix_fread(zz,mb,ma);@+break;
6473
case Fgets: g[rBB].o=mmix_fgets(zz,mb,ma);@+break;
6474
case Fgetws: g[rBB].o=mmix_fgetws(zz,mb,ma);@+break;
6475
case Fwrite: g[rBB].o=mmix_fwrite(zz,mb,ma);@+break;
6476
case Fputs: g[rBB].o=mmix_fputs(zz,g[rBB].o);@+break;
6477
case Fputws: g[rBB].o=mmix_fputws(zz,g[rBB].o);@+break;
6478
case Fseek: g[rBB].o=mmix_fseek(zz,g[rBB].o);@+break;
6479
case Ftell: g[rBB].o=mmix_ftell(zz);@+break;
6480
}
6481
magic_done: g[255].o=neg_one; /* this will enable interrupts */
6482
}
6483
 
6484
@ @=
6485
if (!zz) halted=true;
6486
else if (zz==1) {
6487
  octa trap_loc;
6488
  trap_loc=incr(g[rWW].o,-4);
6489
  if (!(trap_loc.h || trap_loc.l>=0x90))
6490
    print_trip_warning(trap_loc.l>>4,incr(g[rW].o,-4));
6491
}
6492
 
6493
@ @=
6494
char arg_count[]={1,3,1,3,3,3,3,2,2,2,1};
6495
 
6496
@ The input/output operations invoked by \.{TRAP}s are
6497
done by subroutines in an auxiliary program module called {\mc MMIX-IO}.
6498
Here we need only declare those subroutines, and write three primitive
6499
interfaces on which they depend.
6500
 
6501
@ @=
6502
extern octa mmix_fopen @,@,@[ARGS((unsigned char,octa,octa))@];
6503
extern octa mmix_fclose @,@,@[ARGS((unsigned char))@];
6504
extern octa mmix_fread @,@,@[ARGS((unsigned char,octa,octa))@];
6505
extern octa mmix_fgets @,@,@[ARGS((unsigned char,octa,octa))@];
6506
extern octa mmix_fgetws @,@,@[ARGS((unsigned char,octa,octa))@];
6507
extern octa mmix_fwrite @,@,@[ARGS((unsigned char,octa,octa))@];
6508
extern octa mmix_fputs @,@,@[ARGS((unsigned char,octa))@];
6509
extern octa mmix_fputws @,@,@[ARGS((unsigned char,octa))@];
6510
extern octa mmix_fseek @,@,@[ARGS((unsigned char,octa))@];
6511
extern octa mmix_ftell @,@,@[ARGS((unsigned char))@];
6512
extern void print_trip_warning @,@,@[ARGS((int,octa))@];
6513
 
6514
@ @=
6515
int mmgetchars @,@,@[ARGS((char*,int,octa,int))@];
6516
void mmputchars @,@,@[ARGS((unsigned char*,int,octa))@];
6517
char stdin_chr @,@,@[ARGS((void))@];
6518
octa magic_read @,@,@[ARGS((octa))@];
6519
void magic_write @,@,@[ARGS((octa,octa))@];
6520
 
6521
@ We need to cut through all the complications of buffers and
6522
caches in order to do magical I/O. The |magic_read| routine finds
6523
the current octabyte in a given physical address by looking at the
6524
write buffer, D-cache, S-cache, and memory until finding it.
6525
 
6526
@=
6527
octa magic_read(addr)
6528
  octa addr;
6529
{
6530
  register write_node *q;
6531
  register cacheblock *p;
6532
  for (q=write_tail;;) {
6533
    if (q==write_head) break;
6534
    if (q==wbuf_top) q=wbuf_bot;@+ else q++;
6535
    if ((q->addr.l&-8)==(addr.l&-8) && q->addr.h==addr.h) return q->o;
6536
  }
6537
  if (Dcache) {
6538
    p=cache_search(Dcache,addr);
6539
    if (p) return p->data[(addr.l&(Dcache->bb-1))>>3];
6540
    if (((Dcache->outbuf.tag.l^addr.l)&-Dcache->bb)==0 &&
6541
          Dcache->outbuf.tag.h==addr.h)
6542
      return Dcache->outbuf.data[(addr.l&(Dcache->bb-1))>>3];
6543
    if (Scache) {
6544
      p=cache_search(Scache,addr);
6545
      if (p) return p->data[(addr.l&(Scache->bb-1))>>3];
6546
      if (((Scache->outbuf.tag.l^addr.l)&-Scache->bb)==0 &&
6547
            Scache->outbuf.tag.h==addr.h)
6548
        return Scache->outbuf.data[(addr.l&(Scache->bb-1))>>3];
6549
    }
6550
  }
6551
  return mem_read(addr);
6552
}
6553
 
6554
@ The |magic_write| routine changes the octabyte in a given physical
6555
address by changing it wherever it appears in a buffer or cache.
6556
Any ``dirty'' or ``least recently used'' status remains unchanged.
6557
(Yes, this {\it is\/} magic.)
6558
 
6559
@=
6560
void magic_write(addr,val)
6561
  octa addr,val;
6562
{
6563
  register write_node *q;
6564
  register cacheblock *p;
6565
  for (q=write_tail;;) {
6566
    if (q==write_head) break;
6567
    if (q==wbuf_top) q=wbuf_bot;@+ else q++;
6568
    if ((q->addr.l&-8)==(addr.l&-8) && q->addr.h==addr.h) q->o=val;
6569
  }
6570
  if (Dcache) {
6571
    p=cache_search(Dcache,addr);
6572
    if (p) p->data[(addr.l&(Dcache->bb-1))>>3]=val;
6573
    if (((Dcache->inbuf.tag.l^addr.l)&-Dcache->bb)==0 &&
6574
          Dcache->inbuf.tag.h==addr.h)
6575
      Dcache->inbuf.data[(addr.l&(Dcache->bb-1))>>3]=val;
6576
    if (((Dcache->outbuf.tag.l^addr.l)&-Dcache->bb)==0 &&
6577
          Dcache->outbuf.tag.h==addr.h)
6578
      Dcache->outbuf.data[(addr.l&(Dcache->bb-1))>>3]=val;
6579
    if (Scache) {
6580
      p=cache_search(Scache,addr);
6581
      if (p) p->data[(addr.l&(Scache->bb-1))>>3]=val;
6582
      if (((Scache->inbuf.tag.l^addr.l)&-Scache->bb)==0 &&
6583
            Scache->inbuf.tag.h==addr.h)
6584
        Scache->inbuf.data[(addr.l&(Scache->bb-1))>>3]=val;
6585
      if (((Scache->outbuf.tag.l^addr.l)&-Scache->bb)==0 &&
6586
            Scache->outbuf.tag.h==addr.h)
6587
        Scache->outbuf.data[(addr.l&(Scache->bb-1))>>3]=val;
6588
    }
6589
  }
6590
  mem_write(addr,val);
6591
}
6592
 
6593
@ The conventions of our imaginary operating system require us to
6594
apply the trivial memory mapping in which segment~$i$ appears in
6595
a $2^{32}$-byte page of physical addresses starting at $2^{32}i$.
6596
 
6597
@=
6598
if (arg_count[yy]==3) {
6599
  octa arg_loc;
6600
  arg_loc=g[rBB].o;
6601
  if (arg_loc.h&0x9fffffff) mb=zero_octa;
6602
  else arg_loc.h>>=29, mb=magic_read(arg_loc);
6603
  arg_loc=incr(g[rBB].o,8);
6604
  if (arg_loc.h&0x9fffffff) ma=zero_octa;
6605
  else arg_loc.h>>=29, ma=magic_read(arg_loc);
6606
}
6607
 
6608
@ The subroutine |mmgetchars(buf,size,addr,stop)| reads characters
6609
starting at address |addr| in the simulated memory and stores them
6610
in |buf|, continuing until |size| characters have been read or
6611
some other stopping criterion has been met. If |stop<0| there is
6612
no other criterion; if |stop=0| a null character will also terminate
6613
the process; otherwise |addr| is even, and two consecutive null bytes
6614
starting at an even address will terminate the process. The number
6615
of bytes read and stored, exclusive of terminating nulls, is returned.
6616
 
6617
@=
6618
int mmgetchars(buf,size,addr,stop)
6619
  char *buf;
6620
  int size;
6621
  octa addr;
6622
  int stop;
6623
{
6624
  register char *p;
6625
  register int m;
6626
  octa a,x;
6627
  if (((addr.h&0x9fffffff)||(incr(addr,size-1).h&0x9fffffff))&&size) {
6628
    fprintf(stderr,"Attempt to get characters from off the page!\n");
6629
@.Attempt to get characters...@>
6630
    return 0;
6631
  }
6632
  for (p=buf,m=0,a=addr,a.h>>=29; m
6633
    x=magic_read(a);
6634
    if ((a.l&0x7) || m>size-8) @@;
6635
    else @@;
6636
  }
6637
  return size;
6638
}
6639
 
6640
@ @=
6641
{
6642
  if (a.l&0x4) *p=(x.l>>(8*((~a.l)&0x3)))&0xff;
6643
  else *p=(x.h>>(8*((~a.l)&0x3)))&0xff;
6644
  if (!*p && stop>=0) {
6645
    if (stop==0) return m;
6646
    if ((a.l&0x1) && *(p-1)=='\0') return m-1;
6647
  }
6648
  p++,m++,a=incr(a,1);
6649
}
6650
 
6651
@ @=
6652
{
6653
  *p=x.h>>24;
6654
  if (!*p && (stop==0 || (stop>0 && x.h<0x10000))) return m;
6655
  *(p+1)=(x.h>>16)&0xff;
6656
  if (!*(p+1) && stop==0) return m+1;
6657
  *(p+2)=(x.h>>8)&0xff;
6658
  if (!*(p+2) && (stop==0 || (stop>0 && (x.h&0xffff)==0))) return m+2;
6659
  *(p+3)=x.h&0xff;
6660
  if (!*(p+3) && stop==0) return m+3;
6661
  *(p+4)=x.l>>24;
6662
  if (!*(p+4) && (stop==0 || (stop>0 && x.l<0x10000))) return m+4;
6663
  *(p+5)=(x.l>>16)&0xff;
6664
  if (!*(p+5) && stop==0) return m+5;
6665
  *(p+6)=(x.l>>8)&0xff;
6666
  if (!*(p+6) && (stop==0 || (stop>0 && (x.l&0xffff)==0))) return m+6;
6667
  *(p+7)=x.l&0xff;
6668
  if (!*(p+7) && stop==0) return m+7;
6669
  p+=8,m+=8,a=incr(a,8);
6670
}
6671
 
6672
@ The subroutine |mmputchars(buf,size,addr)| puts |size| characters
6673
into the simulated memory starting at address |addr|.
6674
 
6675
@=
6676
void mmputchars(buf,size,addr)
6677
  unsigned char *buf;
6678
  int size;
6679
  octa addr;
6680
{
6681
  register unsigned char *p;
6682
  register int m;
6683
  octa a,x;
6684
  if (((addr.h&0x9fffffff)||(incr(addr,size-1).h&0x9fffffff))&&size) {
6685
    fprintf(stderr,"Attempt to put characters off the page!\n");
6686
@.Attempt to put characters...@>
6687
    return;
6688
  }
6689
  for (p=buf,m=0,a=addr,a.h>>=29; m
6690
    if ((a.l&0x7) || m>size-8) @@;
6691
    else @;
6692
  }
6693
}
6694
 
6695
@ @=
6696
{
6697
  register int s=8*((~a.l)&0x3);
6698
  x=magic_read(a);
6699
  if (a.l&0x4) x.l^=(((x.l>>s)^*p)&0xff)<
6700
  else x.h^=(((x.h>>s)^*p)&0xff)<
6701
  magic_write(a,x);
6702
  p++,m++,a=incr(a,1);
6703
}
6704
 
6705
@ @=
6706
{
6707
  x.h=(*p<<24)+(*(p+1)<<16)+(*(p+2)<<8)+*(p+3);
6708
  x.l=(*(p+4)<<24)+(*(p+5)<<16)+(*(p+6)<<8)+*(p+7);
6709
  magic_write(a,x);
6710
  p+=8,m+=8,a=incr(a,8);
6711
}
6712
 
6713
@ When standard input is being read by the simulated program at the same time
6714
as it is being used for interaction, we try to keep the two uses separate
6715
by maintaining a private buffer for the simulated program's \.{StdIn}.
6716
Online input is usually transmitted from the keyboard to a \CEE/ program
6717
a line at a time; therefore an
6718
|fgets| operation works much better than |fread| when we prompt
6719
for new input. But there is a slight complication, because |fgets|
6720
might read a null character before coming to a newline character.
6721
We cannot deduce the number of characters read by |fgets| simply
6722
by looking at |strlen(stdin_buf)|.
6723
 
6724
@=
6725
char stdin_chr()
6726
{
6727
  register char* p;
6728
  while (stdin_buf_start==stdin_buf_end) {
6729
    printf("StdIn> ");@+fflush(stdout);
6730
@.StdIn>@>
6731
    fgets(stdin_buf,256,stdin);
6732
    stdin_buf_start=stdin_buf;
6733
    for (p=stdin_buf;p
6734
    stdin_buf_end=p+1;
6735
  }
6736
  return *stdin_buf_start++;
6737
}
6738
 
6739
@ @=
6740
char stdin_buf[256]; /* standard input to the simulated program */
6741
char *stdin_buf_start; /* current position in that buffer */
6742
char *stdin_buf_end; /* current end of that buffer */
6743
 
6744
@* Index.

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