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div_Xsig.SD08-May-20249.9 KiB368213

div_small.SD08-May-20241.6 KiB4921

errors.cD08-May-202417.7 KiB687436

exception.hD08-May-20241.8 KiB5232

fpu_arith.cD08-May-20243 KiB154104

fpu_asm.hD08-May-20241.1 KiB3317

fpu_aux.cD08-May-20245.4 KiB268204

fpu_emu.hD08-May-20247.2 KiB219151

fpu_entry.cD08-May-202420.7 KiB727554

fpu_etc.cD08-May-20243.1 KiB132110

fpu_proto.hD08-May-20245.8 KiB158134

fpu_system.hD08-May-20244.4 KiB13184

fpu_tags.cD08-May-20242.7 KiB11784

fpu_trig.cD08-May-202438.3 KiB1,6451,248

get_address.cD08-May-202410.5 KiB402305

load_store.cD08-May-202410 KiB323271

mul_Xsig.SD08-May-20244.2 KiB180124

poly.hD08-May-20244.6 KiB11663

poly_2xm1.cD08-May-20244.4 KiB14795

poly_atan.cD08-May-20246.3 KiB210149

poly_l2.cD08-May-20247.1 KiB246172

poly_sin.cD08-May-202410.6 KiB380239

poly_tan.cD08-May-20246.8 KiB214136

polynom_Xsig.SD08-May-20243.9 KiB13889

reg_add_sub.cD08-May-20248.7 KiB335258

reg_compare.cD08-May-202410.5 KiB480392

reg_constant.cD08-May-20243.8 KiB11974

reg_constant.hD08-May-20241,021 2714

reg_convert.cD08-May-20241.6 KiB4820

reg_divide.cD08-May-20244.9 KiB184131

reg_ld_str.cD08-May-202431.3 KiB1,221943

reg_mul.cD08-May-20243.9 KiB11776

reg_norm.SD08-May-20243.6 KiB15192

reg_round.SD08-May-202417.6 KiB712437

reg_u_add.SD08-May-20243.9 KiB170102

reg_u_div.SD08-May-202412.1 KiB475275

reg_u_mul.SD08-May-20243.6 KiB15190

reg_u_sub.SD08-May-20246 KiB275164

round_Xsig.SD08-May-20243.3 KiB14391

shr_Xsig.SD08-May-20242.5 KiB9061

status_w.hD08-May-20242.5 KiB6946

version.hD08-May-2024838 131

wm_shrx.SD08-May-20246.1 KiB208138

wm_sqrt.SD08-May-202410.8 KiB473275

README

1 +---------------------------------------------------------------------------+
2 |  wm-FPU-emu   an FPU emulator for 80386 and 80486SX microprocessors.      |
3 |                                                                           |
4 | Copyright (C) 1992,1993,1994,1995,1996,1997,1999                          |
5 |                       W. Metzenthen, 22 Parker St, Ormond, Vic 3163,      |
6 |                       Australia.  E-mail billm@melbpc.org.au              |
7 |                                                                           |
8 |    This program is free software; you can redistribute it and/or modify   |
9 |    it under the terms of the GNU General Public License version 2 as      |
10 |    published by the Free Software Foundation.                             |
11 |                                                                           |
12 |    This program is distributed in the hope that it will be useful,        |
13 |    but WITHOUT ANY WARRANTY; without even the implied warranty of         |
14 |    MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the          |
15 |    GNU General Public License for more details.                           |
16 |                                                                           |
17 |    You should have received a copy of the GNU General Public License      |
18 |    along with this program; if not, write to the Free Software            |
19 |    Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA.              |
20 |                                                                           |
21 +---------------------------------------------------------------------------+
22
23
24
25wm-FPU-emu is an FPU emulator for Linux. It is derived from wm-emu387
26which was my 80387 emulator for early versions of djgpp (gcc under
27msdos); wm-emu387 was in turn based upon emu387 which was written by
28DJ Delorie for djgpp.  The interface to the Linux kernel is based upon
29the original Linux math emulator by Linus Torvalds.
30
31My target FPU for wm-FPU-emu is that described in the Intel486
32Programmer's Reference Manual (1992 edition). Unfortunately, numerous
33facets of the functioning of the FPU are not well covered in the
34Reference Manual. The information in the manual has been supplemented
35with measurements on real 80486's. Unfortunately, it is simply not
36possible to be sure that all of the peculiarities of the 80486 have
37been discovered, so there is always likely to be obscure differences
38in the detailed behaviour of the emulator and a real 80486.
39
40wm-FPU-emu does not implement all of the behaviour of the 80486 FPU,
41but is very close.  See "Limitations" later in this file for a list of
42some differences.
43
44Please report bugs, etc to me at:
45       billm@melbpc.org.au
46or     b.metzenthen@medoto.unimelb.edu.au
47
48For more information on the emulator and on floating point topics, see
49my web pages, currently at  http://www.suburbia.net/~billm/
50
51
52--Bill Metzenthen
53  December 1999
54
55
56----------------------- Internals of wm-FPU-emu -----------------------
57
58Numeric algorithms:
59(1) Add, subtract, and multiply. Nothing remarkable in these.
60(2) Divide has been tuned to get reasonable performance. The algorithm
61    is not the obvious one which most people seem to use, but is designed
62    to take advantage of the characteristics of the 80386. I expect that
63    it has been invented many times before I discovered it, but I have not
64    seen it. It is based upon one of those ideas which one carries around
65    for years without ever bothering to check it out.
66(3) The sqrt function has been tuned to get good performance. It is based
67    upon Newton's classic method. Performance was improved by capitalizing
68    upon the properties of Newton's method, and the code is once again
69    structured taking account of the 80386 characteristics.
70(4) The trig, log, and exp functions are based in each case upon quasi-
71    "optimal" polynomial approximations. My definition of "optimal" was
72    based upon getting good accuracy with reasonable speed.
73(5) The argument reducing code for the trig function effectively uses
74    a value of pi which is accurate to more than 128 bits. As a consequence,
75    the reduced argument is accurate to more than 64 bits for arguments up
76    to a few pi, and accurate to more than 64 bits for most arguments,
77    even for arguments approaching 2^63. This is far superior to an
78    80486, which uses a value of pi which is accurate to 66 bits.
79
80The code of the emulator is complicated slightly by the need to
81account for a limited form of re-entrancy. Normally, the emulator will
82emulate each FPU instruction to completion without interruption.
83However, it may happen that when the emulator is accessing the user
84memory space, swapping may be needed. In this case the emulator may be
85temporarily suspended while disk i/o takes place. During this time
86another process may use the emulator, thereby perhaps changing static
87variables. The code which accesses user memory is confined to five
88files:
89    fpu_entry.c
90    reg_ld_str.c
91    load_store.c
92    get_address.c
93    errors.c
94As from version 1.12 of the emulator, no static variables are used
95(apart from those in the kernel's per-process tables). The emulator is
96therefore now fully re-entrant, rather than having just the restricted
97form of re-entrancy which is required by the Linux kernel.
98
99----------------------- Limitations of wm-FPU-emu -----------------------
100
101There are a number of differences between the current wm-FPU-emu
102(version 2.01) and the 80486 FPU (apart from bugs).  The differences
103are fewer than those which applied to the 1.xx series of the emulator.
104Some of the more important differences are listed below:
105
106The Roundup flag does not have much meaning for the transcendental
107functions and its 80486 value with these functions is likely to differ
108from its emulator value.
109
110In a few rare cases the Underflow flag obtained with the emulator will
111be different from that obtained with an 80486. This occurs when the
112following conditions apply simultaneously:
113(a) the operands have a higher precision than the current setting of the
114    precision control (PC) flags.
115(b) the underflow exception is masked.
116(c) the magnitude of the exact result (before rounding) is less than 2^-16382.
117(d) the magnitude of the final result (after rounding) is exactly 2^-16382.
118(e) the magnitude of the exact result would be exactly 2^-16382 if the
119    operands were rounded to the current precision before the arithmetic
120    operation was performed.
121If all of these apply, the emulator will set the Underflow flag but a real
12280486 will not.
123
124NOTE: Certain formats of Extended Real are UNSUPPORTED. They are
125unsupported by the 80486. They are the Pseudo-NaNs, Pseudoinfinities,
126and Unnormals. None of these will be generated by an 80486 or by the
127emulator. Do not use them. The emulator treats them differently in
128detail from the way an 80486 does.
129
130Self modifying code can cause the emulator to fail. An example of such
131code is:
132          movl %esp,[%ebx]
133	  fld1
134The FPU instruction may be (usually will be) loaded into the pre-fetch
135queue of the CPU before the mov instruction is executed. If the
136destination of the 'movl' overlaps the FPU instruction then the bytes
137in the prefetch queue and memory will be inconsistent when the FPU
138instruction is executed. The emulator will be invoked but will not be
139able to find the instruction which caused the device-not-present
140exception. For this case, the emulator cannot emulate the behaviour of
141an 80486DX.
142
143Handling of the address size override prefix byte (0x67) has not been
144extensively tested yet. A major problem exists because using it in
145vm86 mode can cause a general protection fault. Address offsets
146greater than 0xffff appear to be illegal in vm86 mode but are quite
147acceptable (and work) in real mode. A small test program developed to
148check the addressing, and which runs successfully in real mode,
149crashes dosemu under Linux and also brings Windows down with a general
150protection fault message when run under the MS-DOS prompt of Windows
1513.1. (The program simply reads data from a valid address).
152
153The emulator supports 16-bit protected mode, with one difference from
154an 80486DX.  A 80486DX will allow some floating point instructions to
155write a few bytes below the lowest address of the stack.  The emulator
156will not allow this in 16-bit protected mode: no instructions are
157allowed to write outside the bounds set by the protection.
158
159----------------------- Performance of wm-FPU-emu -----------------------
160
161Speed.
162-----
163
164The speed of floating point computation with the emulator will depend
165upon instruction mix. Relative performance is best for the instructions
166which require most computation. The simple instructions are adversely
167affected by the FPU instruction trap overhead.
168
169
170Timing: Some simple timing tests have been made on the emulator functions.
171The times include load/store instructions. All times are in microseconds
172measured on a 33MHz 386 with 64k cache. The Turbo C tests were under
173ms-dos, the next two columns are for emulators running with the djgpp
174ms-dos extender. The final column is for wm-FPU-emu in Linux 0.97,
175using libm4.0 (hard).
176
177function      Turbo C        djgpp 1.06        WM-emu387     wm-FPU-emu
178
179   +          60.5           154.8              76.5          139.4
180   -          61.1-65.5      157.3-160.8        76.2-79.5     142.9-144.7
181   *          71.0           190.8              79.6          146.6
182   /          61.2-75.0      261.4-266.9        75.3-91.6     142.2-158.1
183
184 sin()        310.8          4692.0            319.0          398.5
185 cos()        284.4          4855.2            308.0          388.7
186 tan()        495.0          8807.1            394.9          504.7
187 atan()       328.9          4866.4            601.1          419.5-491.9
188
189 sqrt()       128.7          crashed           145.2          227.0
190 log()        413.1-419.1    5103.4-5354.21    254.7-282.2    409.4-437.1
191 exp()        479.1          6619.2            469.1          850.8
192
193
194The performance under Linux is improved by the use of look-ahead code.
195The following results show the improvement which is obtained under
196Linux due to the look-ahead code. Also given are the times for the
197original Linux emulator with the 4.1 'soft' lib.
198
199 [ Linus' note: I changed look-ahead to be the default under linux, as
200   there was no reason not to use it after I had edited it to be
201   disabled during tracing ]
202
203            wm-FPU-emu w     original w
204            look-ahead       'soft' lib
205   +         106.4             190.2
206   -         108.6-111.6      192.4-216.2
207   *         113.4             193.1
208   /         108.8-124.4      700.1-706.2
209
210 sin()       390.5            2642.0
211 cos()       381.5            2767.4
212 tan()       496.5            3153.3
213 atan()      367.2-435.5     2439.4-3396.8
214
215 sqrt()      195.1            4732.5
216 log()       358.0-387.5     3359.2-3390.3
217 exp()       619.3            4046.4
218
219
220These figures are now somewhat out-of-date. The emulator has become
221progressively slower for most functions as more of the 80486 features
222have been implemented.
223
224
225----------------------- Accuracy of wm-FPU-emu -----------------------
226
227
228The accuracy of the emulator is in almost all cases equal to or better
229than that of an Intel 80486 FPU.
230
231The results of the basic arithmetic functions (+,-,*,/), and fsqrt
232match those of an 80486 FPU. They are the best possible; the error for
233these never exceeds 1/2 an lsb. The fprem and fprem1 instructions
234return exact results; they have no error.
235
236
237The following table compares the emulator accuracy for the sqrt(),
238trig and log functions against the Turbo C "emulator". For this table,
239each function was tested at about 400 points. Ideal worst-case results
240would be 64 bits. The reduced Turbo C accuracy of cos() and tan() for
241arguments greater than pi/4 can be thought of as being related to the
242precision of the argument x; e.g. an argument of pi/2-(1e-10) which is
243accurate to 64 bits can result in a relative accuracy in cos() of
244about 64 + log2(cos(x)) = 31 bits.
245
246
247Function      Tested x range            Worst result                Turbo C
248                                        (relative bits)
249
250sqrt(x)       1 .. 2                    64.1                         63.2
251atan(x)       1e-10 .. 200              64.2                         62.8
252cos(x)        0 .. pi/2-(1e-10)         64.4 (x <= pi/4)             62.4
253                                        64.1 (x = pi/2-(1e-10))      31.9
254sin(x)        1e-10 .. pi/2             64.0                         62.8
255tan(x)        1e-10 .. pi/2-(1e-10)     64.0 (x <= pi/4)             62.1
256                                        64.1 (x = pi/2-(1e-10))      31.9
257exp(x)        0 .. 1                    63.1 **                      62.9
258log(x)        1+1e-6 .. 2               63.8 **                      62.1
259
260** The accuracy for exp() and log() is low because the FPU (emulator)
261does not compute them directly; two operations are required.
262
263
264The emulator passes the "paranoia" tests (compiled with gcc 2.3.3 or
265later) for 'float' variables (24 bit precision numbers) when precision
266control is set to 24, 53 or 64 bits, and for 'double' variables (53
267bit precision numbers) when precision control is set to 53 bits (a
268properly performing FPU cannot pass the 'paranoia' tests for 'double'
269variables when precision control is set to 64 bits).
270
271The code for reducing the argument for the trig functions (fsin, fcos,
272fptan and fsincos) has been improved and now effectively uses a value
273for pi which is accurate to more than 128 bits precision. As a
274consequence, the accuracy of these functions for large arguments has
275been dramatically improved (and is now very much better than an 80486
276FPU). There is also now no degradation of accuracy for fcos and fptan
277for operands close to pi/2. Measured results are (note that the
278definition of accuracy has changed slightly from that used for the
279above table):
280
281Function      Tested x range          Worst result
282                                     (absolute bits)
283
284cos(x)        0 .. 9.22e+18              62.0
285sin(x)        1e-16 .. 9.22e+18          62.1
286tan(x)        1e-16 .. 9.22e+18          61.8
287
288It is possible with some effort to find very large arguments which
289give much degraded precision. For example, the integer number
290           8227740058411162616.0
291is within about 10e-7 of a multiple of pi. To find the tan (for
292example) of this number to 64 bits precision it would be necessary to
293have a value of pi which had about 150 bits precision. The FPU
294emulator computes the result to about 42.6 bits precision (the correct
295result is about -9.739715e-8). On the other hand, an 80486 FPU returns
2960.01059, which in relative terms is hopelessly inaccurate.
297
298For arguments close to critical angles (which occur at multiples of
299pi/2) the emulator is more accurate than an 80486 FPU. For very large
300arguments, the emulator is far more accurate.
301
302
303Prior to version 1.20 of the emulator, the accuracy of the results for
304the transcendental functions (in their principal range) was not as
305good as the results from an 80486 FPU. From version 1.20, the accuracy
306has been considerably improved and these functions now give measured
307worst-case results which are better than the worst-case results given
308by an 80486 FPU.
309
310The following table gives the measured results for the emulator. The
311number of randomly selected arguments in each case is about half a
312million.  The group of three columns gives the frequency of the given
313accuracy in number of times per million, thus the second of these
314columns shows that an accuracy of between 63.80 and 63.89 bits was
315found at a rate of 133 times per one million measurements for fsin.
316The results show that the fsin, fcos and fptan instructions return
317results which are in error (i.e. less accurate than the best possible
318result (which is 64 bits)) for about one per cent of all arguments
319between -pi/2 and +pi/2.  The other instructions have a lower
320frequency of results which are in error.  The last two columns give
321the worst accuracy which was found (in bits) and the approximate value
322of the argument which produced it.
323
324                                frequency (per M)
325                               -------------------   ---------------
326instr   arg range    # tests   63.7   63.8    63.9   worst   at arg
327                               bits   bits    bits    bits
328-----  ------------  -------   ----   ----   -----   -----  --------
329fsin     (0,pi/2)     547756      0    133   10673   63.89  0.451317
330fcos     (0,pi/2)     547563      0    126   10532   63.85  0.700801
331fptan    (0,pi/2)     536274     11    267   10059   63.74  0.784876
332fpatan  4 quadrants   517087      0      8    1855   63.88  0.435121 (4q)
333fyl2x     (0,20)      541861      0      0    1323   63.94  1.40923  (x)
334fyl2xp1 (-.293,.414)  520256      0      0    5678   63.93  0.408542 (x)
335f2xm1     (-1,1)      538847      4    481    6488   63.79  0.167709
336
337
338Tests performed on an 80486 FPU showed results of lower accuracy. The
339following table gives the results which were obtained with an AMD
340486DX2/66 (other tests indicate that an Intel 486DX produces
341identical results).  The tests were basically the same as those used
342to measure the emulator (the values, being random, were in general not
343the same).  The total number of tests for each instruction are given
344at the end of the table, in case each about 100k tests were performed.
345Another line of figures at the end of the table shows that most of the
346instructions return results which are in error for more than 10
347percent of the arguments tested.
348
349The numbers in the body of the table give the approx number of times a
350result of the given accuracy in bits (given in the left-most column)
351was obtained per one million arguments. For three of the instructions,
352two columns of results are given: * The second column for f2xm1 gives
353the number cases where the results of the first column were for a
354positive argument, this shows that this instruction gives better
355results for positive arguments than it does for negative.  * In the
356cases of fcos and fptan, the first column gives the results when all
357cases where arguments greater than 1.5 were removed from the results
358given in the second column. Unlike the emulator, an 80486 FPU returns
359results of relatively poor accuracy for these instructions when the
360argument approaches pi/2. The table does not show those cases when the
361accuracy of the results were less than 62 bits, which occurs quite
362often for fsin and fptan when the argument approaches pi/2. This poor
363accuracy is discussed above in relation to the Turbo C "emulator", and
364the accuracy of the value of pi.
365
366
367bits   f2xm1  f2xm1 fpatan   fcos   fcos  fyl2x fyl2xp1  fsin  fptan  fptan
36862.0       0      0      0      0    437      0      0      0      0    925
36962.1       0      0     10      0    894      0      0      0      0   1023
37062.2      14      0      0      0   1033      0      0      0      0    945
37162.3      57      0      0      0   1202      0      0      0      0   1023
37262.4     385      0      0     10   1292      0     23      0      0   1178
37362.5    1140      0      0    119   1649      0     39      0      0   1149
37462.6    2037      0      0    189   1620      0     16      0      0   1169
37562.7    5086     14      0    646   2315     10    101     35     39   1402
37662.8    8818     86      0    984   3050     59    287    131    224   2036
37762.9   11340   1355      0   2126   4153     79    605    357    321   1948
37863.0   15557   4750      0   3319   5376    246   1281    862    808   2688
37963.1   20016   8288      0   4620   6628    511   2569   1723   1510   3302
38063.2   24945  11127     10   6588   8098   1120   4470   2968   2990   4724
38163.3   25686  12382     69   8774  10682   1906   6775   4482   5474   7236
38263.4   29219  14722     79  11109  12311   3094   9414   7259   8912  10587
38363.5   30458  14936    393  13802  15014   5874  12666   9609  13762  15262
38463.6   32439  16448   1277  17945  19028  10226  15537  14657  19158  20346
38563.7   35031  16805   4067  23003  23947  18910  20116  21333  25001  26209
38663.8   33251  15820   7673  24781  25675  24617  25354  24440  29433  30329
38763.9   33293  16833  18529  28318  29233  31267  31470  27748  29676  30601
388
389Per cent with error:
390        30.9           3.2          18.5    9.8   13.1   11.6          17.4
391Total arguments tested:
392       70194  70099 101784 100641 100641 101799 128853 114893 102675 102675
393
394
395------------------------- Contributors -------------------------------
396
397A number of people have contributed to the development of the
398emulator, often by just reporting bugs, sometimes with suggested
399fixes, and a few kind people have provided me with access in one way
400or another to an 80486 machine. Contributors include (to those people
401who I may have forgotten, please forgive me):
402
403Linus Torvalds
404Tommy.Thorn@daimi.aau.dk
405Andrew.Tridgell@anu.edu.au
406Nick Holloway, alfie@dcs.warwick.ac.uk
407Hermano Moura, moura@dcs.gla.ac.uk
408Jon Jagger, J.Jagger@scp.ac.uk
409Lennart Benschop
410Brian Gallew, geek+@CMU.EDU
411Thomas Staniszewski, ts3v+@andrew.cmu.edu
412Martin Howell, mph@plasma.apana.org.au
413M Saggaf, alsaggaf@athena.mit.edu
414Peter Barker, PETER@socpsy.sci.fau.edu
415tom@vlsivie.tuwien.ac.at
416Dan Russel, russed@rpi.edu
417Daniel Carosone, danielce@ee.mu.oz.au
418cae@jpmorgan.com
419Hamish Coleman, t933093@minyos.xx.rmit.oz.au
420Bruce Evans, bde@kralizec.zeta.org.au
421Timo Korvola, Timo.Korvola@hut.fi
422Rick Lyons, rick@razorback.brisnet.org.au
423Rick, jrs@world.std.com
424
425...and numerous others who responded to my request for help with
426a real 80486.
427
428