1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
81
82
83
84
85
86
87
88
89
90
91
92
93
94
95
96
97
98
99
100
101
102
103
104
105
106
107
108
109
110
111
112
113
114
115
116
117
118
119
120
121
122
123
124
125
126
127
128
129
130
131
132
133
134
135
136
137
138
139
140
141
142
143
144
145
146
147
148
149
150
151
152
153
154
155
156
157
158
159
160
161
162
163
164
165
166
167
168
169
170
171
172
173
174
175
176
177
178
179
180
181
182
183
184
185
186
187
188
189
190
191
192
193
194
195
196
197
198
199
200
201
202
203
204
205
206
207
208
209
210
211
212
213
214
215
216
217
218
219
220
221
222
223
224
225
226
227
228
229
230
231
232
233
234
235
236
237
238
239
240
241
242
243
244
245
246
247
248
249
250
251
252
253
254
255
256
257
258
259
260
261
262
263
264
265
266
267
268
269
270
271
272
273
274
275
276
277
278
279
280
281
282
283
284
285
286
287
288
289
290
291
292
293
294
295
296
297
298
299
300
301
302
303
304
305
306
307
308
309
310
311
312
313
314
315
316
317
318
319
320
321
322
323
324
325
326
327
328
329
330
331
332
333
334
335
336
337
338
339
340
341
342
343
344
345
346
347
348
349
350
351
352
353
354
355
356
357
358
359
360
361
362
363
364
365
366
367
368
369
370
371
372
373
374
375
376
377
378
379
380
381
382
383
384
385
386
387
388
389
390
391
392
393
394
395
396
397
398
399
400
401
402
403
404
405
406
407
408
409
410
411
412
413
414
415
416
417
418
419
420
421
422
423
424
425
426
427
428
429
430
431
432
433
434
435
436
437
438
439
440
441
442
443
444
445
446
447
448
449
450
451
452
453
454
455
456
457
458
459
460
461
462
463
464
465
466
467
468
469
470
471
472
473
474
475
476
477
478
479
480
481
482
483
484
485
486
487
488
489
490
491
492
493
494
495
496
497
498
499
500
501
502
503
504
505
506
507
508
509
510
511
512
513
514
515
516
517
518
519
520
521
522
523
524
525
526
527
528
529
530
531
532
533
534
535
536
537
538
539
540
541
542
543
544
545
546
547
548
549
550
551
552
553
554
555
556
557
558
559
560
561
562
563
564
565
566
567
568
569
570
571
572
573
574
575
576
577
578
579
580
581
582
583
584
585
586
587
588
589
590
591
592
593
594
595
596
597
598
599
600
601
602
603
604
605
606
607
608
609
610
611
612
613
614
615
616
617
618
619
620
621
622
623
624
625
626
627
628
629
630
631
632
633
634
635
636
637
638
639
640
641
642
643
644
645
646
647
648
649
650
651
652
653
654
655
656
657
658
659
660
661
662
663
664
665
666
667
668
669
670
671
672
673
674
675
676
677
678
679
680
681
682
683
684
685
686
687
688
689
690
691
692
693
694
695
696
697
698
699
700
701
702
703
704
705
706
707
708
709
710
711
712
713
714
715
716
717
718
719
720
721
722
723
724
725
726
727
728
729
730
731
732
733
734
735
736
737
738
739
740
741
742
743
744
745
746
747
748
749
750
751
752
753
754
755
756
757
758
759
760
761
762
763
764
765
766
767
768
769
770
771
772
773
774
775
776
777
778
779
780
781
782
783
784
785
786
787
788
789
790
791
792
793
794
795
796
797
798
799
800
801
802
803
804
805
806
807
808
809
810
811
812
813
814
815
816
817
818
819
820
821
822
823
824
825
826
827
828
829
830
831
832
833
834
835
836
837
838
839
840
841
842
843
844
845
846
847
848
849
850
851
852
853
854
855
856
857
858
859
860
861
862
863
864
865
866
867
868
869
870
871
872
873
874
875
876
877
878
879
880
881
882
883
884
885
886
887
888
889
890
891
892
893
894
895
896
897
898
899
900
901
902
903
904
905
906
907
908
909
910
911
912
913
914
915
916
917
918
919
920
921
922
923
924
925
926
927
928
929
930
931
932
933
934
935
936
937
938
939
940
941
942
943
944
945
946
947
948
949
950
951
952
953
954
955
956
957
958
959
960
961
962
963
964
965
966
967
968
969
970
971
972
973
974
975
976
977
978
979
980
981
982
983
984
985
986
987
988
989
990
991
992
993
994
995
996
997
998
999
1000
1001
1002
1003
1004
1005
1006
1007
1008
1009
1010
1011
1012
1013
1014
1015
1016
1017
1018
1019
1020
1021
1022
1023
1024
1025
1026
1027
1028
1029
1030
1031
1032
1033
1034
1035
1036
1037
1038
1039
1040
1041
1042
1043
1044
1045
1046
1047
1048
1049
1050
1051
1052
1053
1054
1055
1056
1057
1058
1059
1060
1061
1062
1063
1064
1065
1066
1067
1068
1069
1070
1071
1072
1073
1074
1075
1076
1077
1078
1079
1080
1081
1082
1083
1084
1085
1086
1087
1088
1089
1090
1091
1092
1093
1094
1095
1096
1097
1098
1099
1100
1101
1102
1103
1104
1105
1106
1107
1108
1109
1110
1111
1112
1113
1114
1115
1116
1117
1118
1119
1120
1121
1122
1123
1124
1125
1126
1127
1128
1129
1130
1131
1132
1133
1134
1135
1136
1137
1138
1139
1140
1141
1142
1143
1144
1145
1146
1147
1148
1149
1150
1151
1152
1153
1154
1155
1156
1157
1158
1159
1160
1161
1162
1163
1164
1165
1166
1167
1168
1169
1170
1171
1172
1173
1174
1175
1176
1177
1178
1179
1180
1181
1182
1183
1184
1185
1186
1187
1188
1189
1190
1191
1192
1193
1194
1195
1196
1197
1198
1199
1200
1201
1202
1203
1204
1205
1206
1207
1208
1209
1210
1211
1212
1213
1214
1215
1216
1217
1218
1219
1220
1221
1222
1223
1224
1225
1226
1227
1228
1229
1230
1231
1232
1233
1234
1235
1236
1237
1238
1239
1240
1241
1242
1243
1244
1245
1246
1247
1248
1249
1250
1251
1252
1253
1254
1255
1256
1257
1258
1259
1260
1261
1262
1263
1264
1265
1266
1267
1268
1269
1270
1271
1272
1273
1274
1275
1276
1277
1278
1279
1280
1281
1282
1283
1284
1285
1286
1287
1288
1289
1290
1291
1292
1293
1294
1295
1296
1297
1298
1299
1300
1301
1302
1303
1304
1305
1306
1307
1308
1309
1310
1311
1312
1313
1314
1315
1316
1317
1318
1319
1320
1321
1322
1323
1324
1325
1326
1327
1328
1329
1330
1331
1332
1333
1334
1335
1336
1337
1338
1339
1340
1341
1342
1343
1344
1345
1346
1347
1348
1349
1350
1351
1352
1353
1354
1355
1356
1357
1358
1359
1360
1361
1362
1363
1364
1365
1366
1367
1368
1369
1370
1371
1372
1373
1374
1375
1376
1377
1378
1379
1380
1381
1382
1383
1384
1385
1386
1387
1388
1389
1390
1391
1392
1393
1394
1395
1396
1397
1398
1399
1400
1401
1402
1403
1404
1405
1406
1407
1408
1409
1410
1411
1412
1413
1414
1415
1416
1417
1418
1419
1420
1421
1422
1423
1424
1425
1426
1427
1428
1429
1430
1431
1432
1433
1434
1435
1436
1437
1438
1439
1440
1441
1442
1443
1444
1445
1446
1447
1448
1449
1450
1451
1452
1453
1454
1455
1456
1457
1458
1459
1460
1461
1462
1463
1464
1465
1466
1467
1468
1469
1470
1471
1472
1473
1474
1475
1476
1477
1478
1479
1480
1481
1482
1483
1484
1485
1486
1487
1488
1489
1490
1491
1492
1493
1494
1495
1496
1497
1498
1499
1500
1501
1502
1503
1504
1505
1506
1507
1508
1509
1510
1511
1512
1513
1514
1515
1516
1517
1518
1519
1520
1521
1522
1523
1524
1525
1526
1527
1528
1529
1530
1531
1532
1533
1534
1535
1536
1537
1538
1539
1540
1541
1542
1543
1544
1545
1546
1547
1548
1549
1550
1551
1552
1553
1554
1555
1556
1557
1558
1559
1560
1561
1562
1563
1564
1565
1566
1567
1568
1569
1570
1571
1572
1573
1574
1575
1576
1577
1578
1579
1580
1581
1582
1583
1584
1585
1586
1587
1588
1589
1590
1591
1592
1593
1594
1595
1596
1597
1598
1599
1600
1601
1602
1603
1604
1605
1606
1607
1608
1609
1610
1611
1612
1613
1614
1615
1616
1617
1618
1619
1620
1621
1622
1623
1624
1625
1626
1627
1628
1629
1630
1631
1632
1633
1634
1635
1636
1637
1638
1639
1640
1641
1642
1643
1644
1645
1646
1647
1648
1649
1650
1651
1652
1653
1654
1655
1656
1657
1658
1659
1660
1661
1662
1663
1664
1665
1666
1667
1668
1669
1670
1671
1672
1673
1674
1675
1676
1677
1678
1679
1680
1681
1682
1683
1684
1685
1686
1687
1688
1689
1690
1691
1692
1693
1694
1695
1696
1697
1698
1699
1700
1701
1702
1703
1704
1705
1706
1707
1708
1709
1710
1711
1712
1713
1714
1715
1716
1717
1718
1719
1720
1721
1722
1723
1724
1725
1726
1727
1728
1729
1730
1731
1732
1733
1734
1735
1736
1737
1738
1739
1740
1741
1742
1743
1744
1745
1746
1747
1748
1749
1750
1751
1752
1753
1754
1755
1756
1757
1758
1759
1760
1761
1762
1763
1764
1765
1766
1767
1768
1769
1770
1771
1772
1773
1774
1775
1776
1777
1778
1779
1780
1781
1782
1783
1784
1785
1786
1787
1788
1789
1790
1791
1792
1793
1794
1795
1796
1797
1798
1799
1800
1801
1802
1803
1804
1805
1806
1807
1808
1809
1810
1811
1812
1813
1814
1815
1816
1817
1818
1819
1820
1821
1822
1823
1824
1825
1826
1827
1828
1829
1830
1831
1832
1833
1834
1835
1836
1837
1838
1839
1840
1841
1842
1843
1844
1845
1846
1847
1848
1849
1850
1851
1852
1853
1854
1855
1856
1857
1858
1859
1860
1861
1862
1863
1864
1865
1866
1867
1868
1869
1870
1871
1872
1873
1874
1875
1876
1877
1878
1879
1880
1881
1882
1883
1884
1885
1886
1887
1888
1889
1890
1891
1892
1893
1894
1895
1896
1897
1898
1899
1900
1901
1902
1903
1904
1905
1906
1907
1908
1909
1910
1911
1912
1913
1914
1915
1916
1917
1918
1919
1920
1921
1922
1923
1924
1925
1926
1927
1928
1929
1930
1931
1932
1933
1934
1935
1936
1937
1938
1939
1940
1941
1942
1943
1944
1945
1946
1947
1948
1949
1950
1951
1952
1953
1954
1955
1956
1957
1958
1959
1960
1961
1962
1963
1964
1965
1966
1967
1968
1969
1970
1971
1972
1973
1974
1975
1976
1977
1978
1979
1980
1981
1982
1983
1984
1985
1986
1987
1988
1989
1990
1991
1992
1993
1994
1995
1996
1997
1998
1999
2000
2001
2002
2003
2004
2005
2006
2007
2008
2009
2010
2011
2012
2013
2014
2015
2016
2017
2018
2019
2020
2021
2022
2023
2024
2025
2026
2027
2028
2029
2030
2031
2032
2033
2034
2035
2036
2037
2038
2039
2040
2041
2042
2043
2044
2045
2046
2047
2048
2049
2050
2051
2052
2053
2054
2055
2056
2057
2058
2059
2060
2061
2062
2063
2064
2065
2066
2067
2068
2069
2070
2071
2072
2073
2074
2075
2076
2077
2078
2079
2080
2081
2082
2083
2084
2085
2086
2087
2088
2089
2090
2091
2092
2093
2094
2095
2096
2097
2098
2099
2100
2101
2102
2103
2104
2105
2106
2107
2108
2109
2110
2111
2112
2113
2114
2115
2116
2117
2118
2119
2120
2121
2122
2123
2124
2125
2126
2127
2128
2129
2130
2131
2132
2133
2134
2135
2136
2137
2138
2139
2140
2141
2142
|
%%
%% %CopyrightBegin%
%%
%% Copyright Ericsson AB 1999-2012. All Rights Reserved.
%%
%% The contents of this file are subject to the Erlang Public License,
%% Version 1.1, (the "License"); you may not use this file except in
%% compliance with the License. You should have received a copy of the
%% Erlang Public License along with this software. If not, it can be
%% retrieved online at http://www.erlang.org/.
%%
%% Software distributed under the License is distributed on an "AS IS"
%% basis, WITHOUT WARRANTY OF ANY KIND, either express or implied. See
%% the License for the specific language governing rights and limitations
%% under the License.
%%
%% %CopyrightEnd%
%%
%% Purpose : Code generator for Beam.
%% The following assumptions have been made:
%%
%% 1. Matches, i.e. things with {match,M,Ret} wrappers, only return
%% values; no variables are exported. If the match would have returned
%% extra variables then these have been transformed to multiple return
%% values.
%%
%% 2. All BIF's called in guards are gc-safe so there is no need to
%% put thing on the stack in the guard. While this would in principle
%% work it would be difficult to keep track of the stack depth when
%% trimming.
%%
%% The code generation uses variable lifetime information added by
%% the v3_life module to save variables, allocate registers and
%% move registers to the stack when necessary.
%%
%% We try to use a consistent variable name scheme throughout. The
%% StackReg record is always called Bef,Int<n>,Aft.
-module(v3_codegen).
%% The main interface.
-export([module/2]).
-import(lists, [member/2,keymember/3,keysort/2,keydelete/3,
append/1,map/2,flatmap/2,filter/2,foldl/3,foldr/3,mapfoldl/3,
sort/1,reverse/1,reverse/2]).
-import(v3_life, [vdb_find/2]).
%%-compile([export_all]).
-include("v3_life.hrl").
%% Main codegen structure.
-record(cg, {lcount=1, %Label counter
bfail, %Fail label for BIFs
break, %Break label
recv, %Receive label
is_top_block, %Boolean: top block or not
functable=gb_trees:empty(), %Gb tree of local functions:
% {{Name,Arity},Label}
in_catch=false, %Inside a catch or not.
need_frame, %Need a stack frame.
ultimate_failure %Label for ultimate match failure.
}).
%% Stack/register state record.
-record(sr, {reg=[], %Register table
stk=[], %Stack table
res=[]}). %Reserved regs: [{reserved,I,V}]
module({Mod,Exp,Attr,Forms}, Options) ->
put(?MODULE, Options),
{Fs,St} = functions(Forms, {atom,Mod}),
erase(?MODULE),
{ok,{Mod,Exp,Attr,Fs,St#cg.lcount}}.
functions(Forms, AtomMod) ->
mapfoldl(fun (F, St) -> function(F, AtomMod, St) end, #cg{lcount=1}, Forms).
function({function,Name,Arity,Asm0,Vb,Vdb,Anno}, AtomMod, St0) ->
try
{Asm,EntryLabel,St} = cg_fun(Vb, Asm0, Vdb, AtomMod,
{Name,Arity}, Anno, St0),
Func = {function,Name,Arity,EntryLabel,Asm},
{Func,St}
catch
Class:Error ->
Stack = erlang:get_stacktrace(),
io:fwrite("Function: ~w/~w\n", [Name,Arity]),
erlang:raise(Class, Error, Stack)
end.
%% cg_fun([Lkexpr], [HeadVar], Vdb, State) -> {[Ainstr],State}
cg_fun(Les, Hvs, Vdb, AtomMod, NameArity, Anno, St0) ->
{Fi,St1} = new_label(St0), %FuncInfo label
{Fl,St2} = local_func_label(NameArity, St1),
%%
%% The pattern matching compiler (in v3_kernel) no longer
%% provides its own catch-all clause, because the
%% call to erlang:exit/1 caused problem when cases were
%% used in guards. Therefore, there may be tests that
%% cannot fail (providing that there is not a bug in a
%% previous optimzation pass), but still need to provide
%% a label (there are instructions, such as is_tuple/2,
%% that do not allow {f,0}).
%%
%% We will generate an ultimate failure label and put it
%% at the end of function, followed by an 'if_end' instruction.
%% Note that and 'if_end' instruction does not need any
%% live x registers, so it will always be safe to jump to
%% it. (We never ever expect the jump to be taken, and in
%% must functions there will never be any references to
%% the label in the first place.)
%%
{UltimateMatchFail,St3} = new_label(St2),
%% Create initial stack/register state, clear unused arguments.
Bef = clear_dead(#sr{reg=foldl(fun ({var,V}, Reg) ->
put_reg(V, Reg)
end, [], Hvs),
stk=[]}, 0, Vdb),
{B0,_Aft,St} = cg_list(Les, 0, Vdb, Bef,
St3#cg{bfail=0,
ultimate_failure=UltimateMatchFail,
is_top_block=true}),
B = fix_bs_match_strings(B0),
{Name,Arity} = NameArity,
Asm = [{label,Fi},line(Anno),{func_info,AtomMod,{atom,Name},Arity},
{label,Fl}|B++[{label,UltimateMatchFail},if_end]],
{Asm,Fl,St}.
fix_bs_match_strings([{test,bs_match_string,F,[Ctx,BinList]}|Is])
when is_list(BinList) ->
I = {test,bs_match_string,F,[Ctx,list_to_bitstring(BinList)]},
[I|fix_bs_match_strings(Is)];
fix_bs_match_strings([I|Is]) ->
[I|fix_bs_match_strings(Is)];
fix_bs_match_strings([]) -> [].
%% cg(Lkexpr, Vdb, StackReg, State) -> {[Ainstr],StackReg,State}.
%% Generate code for a kexpr.
%% Split function into two steps for clarity, not efficiency.
cg(Le, Vdb, Bef, St) ->
cg(Le#l.ke, Le, Vdb, Bef, St).
cg({block,Es}, Le, Vdb, Bef, St) ->
block_cg(Es, Le, Vdb, Bef, St);
cg({match,M,Rs}, Le, Vdb, Bef, St) ->
match_cg(M, Rs, Le, Vdb, Bef, St);
cg({guard_match,M,Rs}, Le, Vdb, Bef, St) ->
guard_match_cg(M, Rs, Le, Vdb, Bef, St);
cg({call,Func,As,Rs}, Le, Vdb, Bef, St) ->
call_cg(Func, As, Rs, Le, Vdb, Bef, St);
cg({enter,Func,As}, Le, Vdb, Bef, St) ->
enter_cg(Func, As, Le, Vdb, Bef, St);
cg({bif,Bif,As,Rs}, Le, Vdb, Bef, St) ->
bif_cg(Bif, As, Rs, Le, Vdb, Bef, St);
cg({gc_bif,Bif,As,Rs}, Le, Vdb, Bef, St) ->
gc_bif_cg(Bif, As, Rs, Le, Vdb, Bef, St);
cg({receive_loop,Te,Rvar,Rm,Tes,Rs}, Le, Vdb, Bef, St) ->
recv_loop_cg(Te, Rvar, Rm, Tes, Rs, Le, Vdb, Bef, St);
cg(receive_next, Le, Vdb, Bef, St) ->
recv_next_cg(Le, Vdb, Bef, St);
cg(receive_accept, _Le, _Vdb, Bef, St) -> {[remove_message],Bef,St};
cg({'try',Ta,Vs,Tb,Evs,Th,Rs}, Le, Vdb, Bef, St) ->
try_cg(Ta, Vs, Tb, Evs, Th, Rs, Le, Vdb, Bef, St);
cg({try_enter,Ta,Vs,Tb,Evs,Th}, Le, Vdb, Bef, St) ->
try_enter_cg(Ta, Vs, Tb, Evs, Th, Le, Vdb, Bef, St);
cg({'catch',Cb,R}, Le, Vdb, Bef, St) ->
catch_cg(Cb, R, Le, Vdb, Bef, St);
cg({set,Var,Con}, Le, Vdb, Bef, St) ->
set_cg(Var, Con, Le, Vdb, Bef, St);
cg({return,Rs}, Le, Vdb, Bef, St) -> return_cg(Rs, Le, Vdb, Bef, St);
cg({break,Bs}, Le, Vdb, Bef, St) -> break_cg(Bs, Le, Vdb, Bef, St);
cg({guard_break,Bs,N}, Le, Vdb, Bef, St) ->
guard_break_cg(Bs, N, Le, Vdb, Bef, St);
cg({need_heap,H}, _Le, _Vdb, Bef, St) ->
{[{test_heap,H,max_reg(Bef#sr.reg)}],Bef,St}.
%% cg_list([Kexpr], FirstI, Vdb, StackReg, St) -> {[Ainstr],StackReg,St}.
cg_list(Kes, I, Vdb, Bef, St0) ->
{Keis,{Aft,St1}} =
flatmapfoldl(fun (Ke, {Inta,Sta}) ->
{Keis,Intb,Stb} = cg(Ke, Vdb, Inta, Sta),
{Keis,{Intb,Stb}}
end, {Bef,St0}, need_heap(Kes, I)),
{Keis,Aft,St1}.
%% need_heap([Lkexpr], I, St) -> [Lkexpr].
%% Insert need_heap instructions in Kexpr list. Try to be smart and
%% collect them together as much as possible.
need_heap(Kes0, I) ->
{Kes,H} = need_heap_0(reverse(Kes0), 0, []),
%% Prepend need_heap if necessary.
need_heap_need(I, H) ++ Kes.
need_heap_0([Ke|Kes], H0, Acc) ->
{Ns,H} = need_heap_1(Ke, H0),
need_heap_0(Kes, H, [Ke|Ns]++Acc);
need_heap_0([], H, Acc) ->
{Acc,H}.
need_heap_1(#l{ke={set,_,{binary,_}},i=I}, H) ->
{need_heap_need(I, H),0};
need_heap_1(#l{ke={set,_,{map,_,_}},i=I}, H) ->
{need_heap_need(I, H),0};
need_heap_1(#l{ke={set,_,Val}}, H) ->
%% Just pass through adding to needed heap.
{[],H + case Val of
{cons,_} -> 2;
{tuple,Es} -> 1 + length(Es);
_Other -> 0
end};
need_heap_1(#l{ke={bif,dsetelement,_As,_Rs},i=I}, H) ->
{need_heap_need(I, H),0};
need_heap_1(#l{ke={bif,{make_fun,_,_,_,_},_As,_Rs},i=I}, H) ->
{need_heap_need(I, H),0};
need_heap_1(#l{ke={bif,bs_init_writable,_As,_Rs},i=I}, H) ->
{need_heap_need(I, H),0};
need_heap_1(#l{ke={bif,_Bif,_As,_Rs}}, H) ->
{[],H};
need_heap_1(#l{i=I}, H) ->
{need_heap_need(I, H),0}.
need_heap_need(_I, 0) -> [];
need_heap_need(I, H) -> [#l{ke={need_heap,H},i=I}].
%% match_cg(Match, [Ret], Le, Vdb, StackReg, State) ->
%% {[Ainstr],StackReg,State}.
%% Generate code for a match. First save all variables on the stack
%% that are to survive after the match. We leave saved variables in
%% their registers as they might actually be in the right place.
match_cg(M, Rs, Le, Vdb, Bef, St0) ->
I = Le#l.i,
{Sis,Int0} = adjust_stack(Bef, I, I+1, Vdb),
{B,St1} = new_label(St0),
{Mis,Int1,St2} = match_cg(M, St1#cg.ultimate_failure,
Int0, St1#cg{break=B}),
%% Put return values in registers.
Reg = load_vars(Rs, Int1#sr.reg),
{Sis ++ Mis ++ [{label,B}],
clear_dead(Int1#sr{reg=Reg}, I, Vdb),
St2#cg{break=St1#cg.break}}.
guard_match_cg(M, Rs, Le, Vdb, Bef, St0) ->
I = Le#l.i,
{B,St1} = new_label(St0),
#cg{bfail=Fail} = St1,
{Mis,Aft,St2} = match_cg(M, Fail, Bef, St1#cg{break=B}),
%% Update the register descriptors for the return registers.
Reg = guard_match_regs(Aft#sr.reg, Rs),
{Mis ++ [{label,B}],
clear_dead(Aft#sr{reg=Reg}, I, Vdb),
St2#cg{break=St1#cg.break}}.
guard_match_regs([{I,gbreakvar}|Rs], [{var,V}|Vs]) ->
[{I,V}|guard_match_regs(Rs, Vs)];
guard_match_regs([R|Rs], Vs) ->
[R|guard_match_regs(Rs, Vs)];
guard_match_regs([], []) -> [].
%% match_cg(Match, Fail, StackReg, State) -> {[Ainstr],StackReg,State}.
%% Generate code for a match tree. N.B. there is no need pass Vdb
%% down as each level which uses this takes its own internal Vdb not
%% the outer one.
match_cg(Le, Fail, Bef, St) ->
match_cg(Le#l.ke, Le, Fail, Bef, St).
match_cg({alt,F,S}, _Le, Fail, Bef, St0) ->
{Tf,St1} = new_label(St0),
{Fis,Faft,St2} = match_cg(F, Tf, Bef, St1),
{Sis,Saft,St3} = match_cg(S, Fail, Bef, St2),
Aft = sr_merge(Faft, Saft),
{Fis ++ [{label,Tf}] ++ Sis,Aft,St3};
match_cg({select,{var,Vname}=V,Scs0}, #l{a=Anno}, Fail, Bef, St) ->
ReuseForContext = member(reuse_for_context, Anno) andalso
find_reg(Vname, Bef#sr.reg) =/= error,
Scs = case ReuseForContext of
false -> Scs0;
true -> bsm_rename_ctx(Scs0, Vname)
end,
match_fmf(fun (S, F, Sta) ->
select_cg(S, V, F, Fail, Bef, Sta) end,
Fail, St, Scs);
match_cg({guard,Gcs}, _Le, Fail, Bef, St) ->
match_fmf(fun (G, F, Sta) -> guard_clause_cg(G, F, Bef, Sta) end,
Fail, St, Gcs);
match_cg({block,Es}, Le, _Fail, Bef, St) ->
%% Must clear registers and stack of dead variables.
Int = clear_dead(Bef, Le#l.i, Le#l.vdb),
block_cg(Es, Le, Int, St).
%% bsm_rename_ctx([Clause], Var) -> [Clause]
%% We know from an annotation that the register for a binary can
%% be reused for the match context because the two are not truly
%% alive at the same time (even though the conservative life time
%% information calculated by v3_life says so).
%%
%% The easiest way to have those variables share the same register is
%% to rename the variable with the shortest life-span (the match
%% context) to the variable for the binary (which can have a very
%% long life-time because it is locked during matching). We KNOW that
%% the match state variable will only be alive during the matching.
%%
%% We must also remove all information about the match context
%% variable from all life-time information databases (Vdb).
bsm_rename_ctx([#l{ke={type_clause,binary,
[#l{ke={val_clause,{binary,{var,Old}},Ke0}}=L2]}}=L1|Cs], New) ->
Ke = bsm_rename_ctx(Ke0, Old, New, false),
[L1#l{ke={type_clause,binary,
[L2#l{ke={val_clause,{binary,{var,New}},Ke}}]}}|bsm_rename_ctx(Cs, New)];
bsm_rename_ctx([C|Cs], New) ->
[C|bsm_rename_ctx(Cs, New)];
bsm_rename_ctx([], _) -> [].
%% bsm_rename_ctx(Ke, OldName, NewName, InProt) -> Ke'
%% Rename and clear OldName from life-time information. We must
%% recurse into any block contained in a protected, but it would
%% only complicatate things to recurse into blocks not in a protected
%% (the match context variable is not live inside them).
bsm_rename_ctx(#l{ke={select,{var,V},Cs0}}=L, Old, New, InProt) ->
Cs = bsm_rename_ctx_list(Cs0, Old, New, InProt),
L#l{ke={select,{var,bsm_rename_var(V, Old, New)},Cs}};
bsm_rename_ctx(#l{ke={type_clause,Type,Cs0}}=L, Old, New, InProt) ->
Cs = bsm_rename_ctx_list(Cs0, Old, New, InProt),
L#l{ke={type_clause,Type,Cs}};
bsm_rename_ctx(#l{ke={val_clause,{bin_end,V},Ke0}}=L, Old, New, InProt) ->
Ke = bsm_rename_ctx(Ke0, Old, New, InProt),
L#l{ke={val_clause,{bin_end,bsm_rename_var(V, Old, New)},Ke}};
bsm_rename_ctx(#l{ke={val_clause,{bin_seg,V,Sz,U,Type,Fl,Vs},Ke0}}=L,
Old, New, InProt) ->
Ke = bsm_rename_ctx(Ke0, Old, New, InProt),
L#l{ke={val_clause,{bin_seg,bsm_rename_var(V, Old, New),Sz,U,Type,Fl,Vs},Ke}};
bsm_rename_ctx(#l{ke={val_clause,{bin_int,V,Sz,U,Fl,Val,Vs},Ke0}}=L,
Old, New, InProt) ->
Ke = bsm_rename_ctx(Ke0, Old, New, InProt),
L#l{ke={val_clause,{bin_int,bsm_rename_var(V, Old, New),Sz,U,Fl,Val,Vs},Ke}};
bsm_rename_ctx(#l{ke={val_clause,Val,Ke0}}=L, Old, New, InProt) ->
Ke = bsm_rename_ctx(Ke0, Old, New, InProt),
L#l{ke={val_clause,Val,Ke}};
bsm_rename_ctx(#l{ke={alt,F0,S0}}=L, Old, New, InProt) ->
F = bsm_rename_ctx(F0, Old, New, InProt),
S = bsm_rename_ctx(S0, Old, New, InProt),
L#l{ke={alt,F,S}};
bsm_rename_ctx(#l{ke={guard,Gcs0}}=L, Old, New, InProt) ->
Gcs = bsm_rename_ctx_list(Gcs0, Old, New, InProt),
L#l{ke={guard,Gcs}};
bsm_rename_ctx(#l{ke={guard_clause,G0,B0}}=L, Old, New, InProt) ->
G = bsm_rename_ctx(G0, Old, New, InProt),
B = bsm_rename_ctx(B0, Old, New, InProt),
%% A guard clause may cause unsaved variables to be saved on the stack.
%% Since the match state variable Old is an alias for New (uses the
%% same register), it is neither in the stack nor register descriptor
%% lists and we would crash when we didn't find it unless we remove
%% it from the database.
bsm_forget_var(L#l{ke={guard_clause,G,B}}, Old);
bsm_rename_ctx(#l{ke={protected,Ts0,Rs}}=L, Old, New, _InProt) ->
InProt = true,
Ts = bsm_rename_ctx_list(Ts0, Old, New, InProt),
bsm_forget_var(L#l{ke={protected,Ts,Rs}}, Old);
bsm_rename_ctx(#l{ke={match,Ms0,Rs}}=L, Old, New, InProt) ->
Ms = bsm_rename_ctx(Ms0, Old, New, InProt),
L#l{ke={match,Ms,Rs}};
bsm_rename_ctx(#l{ke={guard_match,Ms0,Rs}}=L, Old, New, InProt) ->
Ms = bsm_rename_ctx(Ms0, Old, New, InProt),
L#l{ke={guard_match,Ms,Rs}};
bsm_rename_ctx(#l{ke={test,_,_}}=L, _, _, _) -> L;
bsm_rename_ctx(#l{ke={bif,_,_,_}}=L, _, _, _) -> L;
bsm_rename_ctx(#l{ke={gc_bif,_,_,_}}=L, _, _, _) -> L;
bsm_rename_ctx(#l{ke={set,_,_}}=L, _, _, _) -> L;
bsm_rename_ctx(#l{ke={call,_,_,_}}=L, _, _, _) -> L;
bsm_rename_ctx(#l{ke={block,_}}=L, Old, _, false) ->
%% This block is not inside a protected. The match context variable cannot
%% possibly be live inside the block.
bsm_forget_var(L, Old);
bsm_rename_ctx(#l{ke={block,Bl0}}=L, Old, New, true) ->
%% A block in a protected. We must recursively rename the variable
%% inside the block.
Bl = bsm_rename_ctx_list(Bl0, Old, New, true),
bsm_forget_var(L#l{ke={block,Bl}}, Old);
bsm_rename_ctx(#l{ke={guard_break,Bs,Locked0}}=L0, Old, _New, _InProt) ->
Locked = Locked0 -- [Old],
L = L0#l{ke={guard_break,Bs,Locked}},
bsm_forget_var(L, Old).
bsm_rename_ctx_list([C|Cs], Old, New, InProt) ->
[bsm_rename_ctx(C, Old, New, InProt)|
bsm_rename_ctx_list(Cs, Old, New, InProt)];
bsm_rename_ctx_list([], _, _, _) -> [].
bsm_rename_var(Old, Old, New) -> New;
bsm_rename_var(V, _, _) -> V.
%% bsm_forget_var(#l{}, Variable) -> #l{}
%% Remove a variable from the variable life-time database.
bsm_forget_var(#l{vdb=Vdb}=L, V) ->
L#l{vdb=keydelete(V, 1, Vdb)}.
%% block_cg([Kexpr], Le, Vdb, StackReg, St) -> {[Ainstr],StackReg,St}.
%% block_cg([Kexpr], Le, StackReg, St) -> {[Ainstr],StackReg,St}.
block_cg(Es, Le, _Vdb, Bef, St) ->
block_cg(Es, Le, Bef, St).
block_cg(Es, Le, Bef, #cg{is_top_block=false}=St) ->
cg_block(Es, Le#l.i, Le#l.vdb, Bef, St);
block_cg(Es, Le, Bef, St0) ->
{Is0,Aft,St} = cg_block(Es, Le#l.i, Le#l.vdb, Bef,
St0#cg{is_top_block=false,need_frame=false}),
Is = top_level_block(Is0, Aft, max_reg(Bef#sr.reg), St),
{Is,Aft,St#cg{is_top_block=true}}.
cg_block([], _I, _Vdb, Bef, St0) ->
{[],Bef,St0};
cg_block(Kes0, I, Vdb, Bef, St0) ->
{Kes2,Int1,St1} =
case basic_block(Kes0) of
{Kes1,LastI,Args,Rest} ->
Ke = hd(Kes1),
Fb = Ke#l.i,
cg_basic_block(Kes1, Fb, LastI, Args, Vdb, Bef, St0);
{Kes1,Rest} ->
cg_list(Kes1, I, Vdb, Bef, St0)
end,
{Kes3,Int2,St2} = cg_block(Rest, I, Vdb, Int1, St1),
{Kes2 ++ Kes3,Int2,St2}.
basic_block(Kes) -> basic_block(Kes, []).
basic_block([Le|Les], Acc) ->
case collect_block(Le#l.ke) of
include -> basic_block(Les, [Le|Acc]);
{block_end,As} ->
case Acc of
[] ->
%% If the basic block does not contain any set instructions,
%% it serves no useful purpose to do basic block optimizations.
{[Le],Les};
_ ->
{reverse(Acc, [Le]),Le#l.i,As,Les}
end;
no_block -> {reverse(Acc, [Le]),Les}
end.
%% sets that may garbage collect are not allowed in basic blocks.
collect_block({set,_,{binary,_}}) -> no_block;
collect_block({set,_,{map,_,_}}) -> no_block;
collect_block({set,_,_}) -> include;
collect_block({call,{var,_}=Var,As,_Rs}) -> {block_end,As++[Var]};
collect_block({call,Func,As,_Rs}) -> {block_end,As++func_vars(Func)};
collect_block({enter,{var,_}=Var,As})-> {block_end,As++[Var]};
collect_block({enter,Func,As}) -> {block_end,As++func_vars(Func)};
collect_block({return,Rs}) -> {block_end,Rs};
collect_block({break,Bs}) -> {block_end,Bs};
collect_block(_) -> no_block.
func_vars({remote,M,F}) when element(1, M) =:= var;
element(1, F) =:= var ->
[M,F];
func_vars(_) -> [].
%% cg_basic_block([Kexpr], FirstI, LastI, As, Vdb, StackReg, State) ->
%% {[Ainstr],StackReg,State}.
cg_basic_block(Kes, Fb, Lf, As, Vdb, Bef, St0) ->
Res = make_reservation(As, 0),
Regs0 = reserve(Res, Bef#sr.reg, Bef#sr.stk),
Stk = extend_stack(Bef, Lf, Lf+1, Vdb),
Int0 = Bef#sr{reg=Regs0,stk=Stk,res=Res},
X0_v0 = x0_vars(As, Fb, Lf, Vdb),
{Keis,{Aft,_,St1}} =
flatmapfoldl(fun(Ke, St) -> cg_basic_block(Ke, St, Lf, Vdb) end,
{Int0,X0_v0,St0}, need_heap(Kes, Fb)),
{Keis,Aft,St1}.
cg_basic_block(#l{ke={need_heap,_}}=Ke, {Inta,X0v,Sta}, _Lf, Vdb) ->
{Keis,Intb,Stb} = cg(Ke, Vdb, Inta, Sta),
{Keis, {Intb,X0v,Stb}};
cg_basic_block(Ke, {Inta,X0_v1,Sta}, Lf, Vdb) ->
{Sis,Intb} = save_carefully(Inta, Ke#l.i, Lf+1, Vdb),
{X0_v2,Intc} = allocate_x0(X0_v1, Ke#l.i, Intb),
Intd = reserve(Intc),
{Keis,Inte,Stb} = cg(Ke, Vdb, Intd, Sta),
{Sis ++ Keis, {Inte,X0_v2,Stb}}.
make_reservation([], _) -> [];
make_reservation([{var,V}|As], I) -> [{I,V}|make_reservation(As, I+1)];
make_reservation([A|As], I) -> [{I,A}|make_reservation(As, I+1)].
reserve(Sr) -> Sr#sr{reg=reserve(Sr#sr.res, Sr#sr.reg, Sr#sr.stk)}.
reserve([{I,V}|Rs], [free|Regs], Stk) -> [{reserved,I,V}|reserve(Rs, Regs, Stk)];
reserve([{I,V}|Rs], [{I,V}|Regs], Stk) -> [{I,V}|reserve(Rs, Regs, Stk)];
reserve([{I,V}|Rs], [{I,Var}|Regs], Stk) ->
case on_stack(Var, Stk) of
true -> [{reserved,I,V}|reserve(Rs, Regs, Stk)];
false -> [{I,Var}|reserve(Rs, Regs, Stk)]
end;
reserve([{I,V}|Rs], [{reserved,I,_}|Regs], Stk) ->
[{reserved,I,V}|reserve(Rs, Regs, Stk)];
%reserve([{I,V}|Rs], [Other|Regs], Stk) -> [Other|reserve(Rs, Regs, Stk)];
reserve([{I,V}|Rs], [], Stk) -> [{reserved,I,V}|reserve(Rs, [], Stk)];
reserve([], Regs, _) -> Regs.
extend_stack(Bef, Fb, Lf, Vdb) ->
Stk0 = clear_dead_stk(Bef#sr.stk, Fb, Vdb),
Saves = [V || {V,F,L} <- Vdb,
F < Fb,
L >= Lf,
not on_stack(V, Stk0)],
Stk1 = foldl(fun (V, Stk) -> put_stack(V, Stk) end, Stk0, Saves),
Bef#sr.stk ++ lists:duplicate(length(Stk1) - length(Bef#sr.stk), free).
save_carefully(Bef, Fb, Lf, Vdb) ->
Stk = Bef#sr.stk,
%% New variables that are in use but not on stack.
New = [VFL || {V,F,L} = VFL <- Vdb,
F < Fb,
L >= Lf,
not on_stack(V, Stk)],
Saves = [V || {V,_,_} <- keysort(2, New)],
save_carefully(Saves, Bef, []).
save_carefully([], Bef, Acc) -> {reverse(Acc),Bef};
save_carefully([V|Vs], Bef, Acc) ->
case put_stack_carefully(V, Bef#sr.stk) of
error -> {reverse(Acc),Bef};
Stk1 ->
SrcReg = fetch_reg(V, Bef#sr.reg),
Move = {move,SrcReg,fetch_stack(V, Stk1)},
{x,_} = SrcReg, %Assertion - must be X register.
save_carefully(Vs, Bef#sr{stk=Stk1}, [Move|Acc])
end.
x0_vars([], _Fb, _Lf, _Vdb) -> [];
x0_vars([{var,V}|_], Fb, _Lf, Vdb) ->
{V,F,_L} = VFL = vdb_find(V, Vdb),
x0_vars1([VFL], Fb, F, Vdb);
x0_vars([X0|_], Fb, Lf, Vdb) ->
x0_vars1([{X0,Lf,Lf}], Fb, Lf, Vdb).
x0_vars1(X0, Fb, Xf, Vdb) ->
Vs0 = [VFL || {_V,F,L}=VFL <- Vdb,
F >= Fb,
L < Xf],
Vs1 = keysort(3, Vs0),
keysort(2, X0++Vs1).
allocate_x0([], _, Bef) -> {[],Bef#sr{res=[]}};
allocate_x0([{_,_,L}|Vs], I, Bef) when L =< I ->
allocate_x0(Vs, I, Bef);
allocate_x0([{V,_F,_L}=VFL|Vs], _, Bef) ->
{[VFL|Vs],Bef#sr{res=reserve_x0(V, Bef#sr.res)}}.
reserve_x0(V, [_|Res]) -> [{0,V}|Res];
reserve_x0(V, []) -> [{0,V}].
top_level_block(Keis, #sr{stk=[]}, _MaxRegs, #cg{need_frame=false}) ->
Keis;
top_level_block(Keis, Bef, MaxRegs, _St) ->
%% This top block needs an allocate instruction before it, and a
%% deallocate instruction before each return.
FrameSz = length(Bef#sr.stk),
MaxY = FrameSz-1,
Keis1 = flatmap(fun ({call_only,Arity,Func}) ->
[{call_last,Arity,Func,FrameSz}];
({call_ext_only,Arity,Func}) ->
[{call_ext_last,Arity,Func,FrameSz}];
({apply_only,Arity}) ->
[{apply_last,Arity,FrameSz}];
(return) ->
[{deallocate,FrameSz},return];
(Tuple) when is_tuple(Tuple) ->
[turn_yregs(tuple_size(Tuple), Tuple, MaxY)];
(Other) ->
[Other]
end, Keis),
[{allocate_zero,FrameSz,MaxRegs}|Keis1].
%% turn_yregs(Size, Tuple, MaxY) -> Tuple'
%% Renumber y register so that {y,0} becomes {y,FrameSize-1},
%% {y,FrameSize-1} becomes {y,0} and so on. This is to make nested
%% catches work. The code generation algorithm gives a lower register
%% number to the outer catch, which is wrong.
turn_yregs(0, Tp, _) -> Tp;
turn_yregs(El, Tp, MaxY) ->
turn_yregs(El-1,setelement(El,Tp,turn_yreg(element(El,Tp),MaxY)),MaxY).
turn_yreg({yy,YY},MaxY) -> {y,MaxY-YY};
turn_yreg({list,Ls},MaxY) -> {list, turn_yreg(Ls,MaxY)};
turn_yreg(Ts,MaxY) when is_list(Ts) -> [turn_yreg(T,MaxY)||T<-Ts];
turn_yreg(Other,_MaxY) -> Other.
%% select_cg(Sclause, V, TypeFail, ValueFail, StackReg, State) ->
%% {Is,StackReg,State}.
%% Selecting type and value needs two failure labels, TypeFail is the
%% label to jump to of the next type test when this type fails, and
%% ValueFail is the label when this type is correct but the value is
%% wrong. These are different as in the second case there is no need
%% to try the next type, it will always fail.
select_cg(#l{ke={type_clause,cons,[S]}}, {var,V}, Tf, Vf, Bef, St) ->
select_cons(S, V, Tf, Vf, Bef, St);
select_cg(#l{ke={type_clause,nil,[S]}}, {var,V}, Tf, Vf, Bef, St) ->
select_nil(S, V, Tf, Vf, Bef, St);
select_cg(#l{ke={type_clause,binary,[S]}}, {var,V}, Tf, Vf, Bef, St) ->
select_binary(S, V, Tf, Vf, Bef, St);
select_cg(#l{ke={type_clause,bin_seg,S}}, {var,V}, Tf, _Vf, Bef, St) ->
select_bin_segs(S, V, Tf, Bef, St);
select_cg(#l{ke={type_clause,bin_int,S}}, {var,V}, Tf, _Vf, Bef, St) ->
select_bin_segs(S, V, Tf, Bef, St);
select_cg(#l{ke={type_clause,bin_end,[S]}}, {var,V}, Tf, _Vf, Bef, St) ->
select_bin_end(S, V, Tf, Bef, St);
select_cg(#l{ke={type_clause,map,S}}, {var,V}, Tf, Vf, Bef, St) ->
select_map(S, V, Tf, Vf, Bef, St);
select_cg(#l{ke={type_clause,Type,Scs}}, {var,V}, Tf, Vf, Bef, St0) ->
{Vis,{Aft,St1}} =
mapfoldl(fun (S, {Int,Sta}) ->
{Val,Is,Inta,Stb} = select_val(S, V, Vf, Bef, Sta),
{{Is,[Val]},{sr_merge(Int, Inta),Stb}}
end, {void,St0}, Scs),
OptVls = combine(lists:sort(combine(Vis))),
{Vls,Sis,St2} = select_labels(OptVls, St1, [], []),
{select_val_cg(Type, fetch_var(V, Bef), Vls, Tf, Vf, Sis), Aft, St2}.
select_val_cg(tuple, R, [Arity,{f,Lbl}], Tf, Vf, [{label,Lbl}|Sis]) ->
[{test,is_tuple,{f,Tf},[R]},{test,test_arity,{f,Vf},[R,Arity]}|Sis];
select_val_cg(tuple, R, Vls, Tf, Vf, Sis) ->
[{test,is_tuple,{f,Tf},[R]},{select_tuple_arity,R,{f,Vf},{list,Vls}}|Sis];
select_val_cg(map, R, [_Val,{f,Lbl}], Fail, Fail, [{label,Lbl}|Sis]) ->
[{test,is_map,{f,Fail},[R]}|Sis];
select_val_cg(map, R, [_Val,{f,Lbl}|_], Tf, _Vf, [{label,Lbl}|Sis]) ->
[{test,is_map,{f,Tf},[R]}|Sis];
select_val_cg(Type, R, [Val, {f,Lbl}], Fail, Fail, [{label,Lbl}|Sis]) ->
[{test,is_eq_exact,{f,Fail},[R,{Type,Val}]}|Sis];
select_val_cg(Type, R, [Val, {f,Lbl}], Tf, Vf, [{label,Lbl}|Sis]) ->
[{test,select_type_test(Type),{f,Tf},[R]},
{test,is_eq_exact,{f,Vf},[R,{Type,Val}]}|Sis];
select_val_cg(Type, R, Vls0, Tf, Vf, Sis) ->
Vls1 = map(fun ({f,_Lbl} = F) -> F;
(Value) -> {Type,Value}
end, Vls0),
[{test,select_type_test(Type),{f,Tf},[R]}, {select_val,R,{f,Vf},{list,Vls1}}|Sis].
select_type_test(integer) -> is_integer;
select_type_test(atom) -> is_atom;
select_type_test(float) -> is_float.
combine([{Is,Vs1}, {Is,Vs2}|Vis]) -> combine([{Is,Vs1 ++ Vs2}|Vis]);
combine([V|Vis]) -> [V|combine(Vis)];
combine([]) -> [].
select_labels([{Is,Vs}|Vis], St0, Vls, Sis) ->
{Lbl,St1} = new_label(St0),
select_labels(Vis, St1, add_vls(Vs, Lbl, Vls), [[{label,Lbl}|Is]|Sis]);
select_labels([], St, Vls, Sis) ->
{Vls,append(Sis),St}.
add_vls([V|Vs], Lbl, Acc) ->
add_vls(Vs, Lbl, [V, {f,Lbl}|Acc]);
add_vls([], _, Acc) -> Acc.
select_cons(#l{ke={val_clause,{cons,Es},B},i=I,vdb=Vdb}, V, Tf, Vf, Bef, St0) ->
{Eis,Int,St1} = select_extract_cons(V, Es, I, Vdb, Bef, St0),
{Bis,Aft,St2} = match_cg(B, Vf, Int, St1),
{[{test,is_nonempty_list,{f,Tf},[fetch_var(V, Bef)]}] ++ Eis ++ Bis,Aft,St2}.
select_nil(#l{ke={val_clause,nil,B}}, V, Tf, Vf, Bef, St0) ->
{Bis,Aft,St1} = match_cg(B, Vf, Bef, St0),
{[{test,is_nil,{f,Tf},[fetch_var(V, Bef)]}] ++ Bis,Aft,St1}.
select_binary(#l{ke={val_clause,{binary,{var,V}},B},i=I,vdb=Vdb},
V, Tf, Vf, Bef, St0) ->
Int0 = clear_dead(Bef#sr{reg=Bef#sr.reg}, I, Vdb),
{Bis,Aft,St1} = match_cg(B, Vf, Int0, St0),
CtxReg = fetch_var(V, Int0),
Live = max_reg(Bef#sr.reg),
{[{test,bs_start_match2,{f,Tf},Live,[CtxReg,V],CtxReg},
{bs_save2,CtxReg,{V,V}}|Bis],
Aft,St1};
select_binary(#l{ke={val_clause,{binary,{var,Ivar}},B},i=I,vdb=Vdb},
V, Tf, Vf, Bef, St0) ->
Regs = put_reg(Ivar, Bef#sr.reg),
Int0 = clear_dead(Bef#sr{reg=Regs}, I, Vdb),
{Bis,Aft,St1} = match_cg(B, Vf, Int0, St0),
CtxReg = fetch_var(Ivar, Int0),
Live = max_reg(Bef#sr.reg),
{[{test,bs_start_match2,{f,Tf},Live,[fetch_var(V, Bef),Ivar],CtxReg},
{bs_save2,CtxReg,{Ivar,Ivar}}|Bis],
Aft,St1}.
%% New instructions for selection of binary segments.
select_bin_segs(Scs, Ivar, Tf, Bef, St) ->
match_fmf(fun(S, Fail, Sta) ->
select_bin_seg(S, Ivar, Fail, Bef, Sta) end,
Tf, St, Scs).
select_bin_seg(#l{ke={val_clause,{bin_seg,Ctx,Size,U,T,Fs0,Es},B},i=I,vdb=Vdb,a=A},
Ivar, Fail, Bef, St0) ->
Fs = [{anno,A}|Fs0],
{Mis,Int,St1} = select_extract_bin(Es, Size, U, T, Fs, Fail,
I, Vdb, Bef, Ctx, B, St0),
{Bis,Aft,St2} = match_cg(B, Fail, Int, St1),
CtxReg = fetch_var(Ctx, Bef),
Is = if
Mis =:= [] ->
%% No bs_restore2 instruction needed if no match instructions.
Bis;
true ->
[{bs_restore2,CtxReg,{Ctx,Ivar}}|Mis++Bis]
end,
{Is,Aft,St2};
select_bin_seg(#l{ke={val_clause,{bin_int,Ctx,Sz,U,Fs,Val,Es},B},i=I,vdb=Vdb},
Ivar, Fail, Bef, St0) ->
{Mis,Int,St1} = select_extract_int(Es, Val, Sz, U, Fs, Fail,
I, Vdb, Bef, Ctx, St0),
{Bis,Aft,St2} = match_cg(B, Fail, Int, St1),
CtxReg = fetch_var(Ctx, Bef),
Is = case Mis ++ Bis of
[{test,bs_match_string,F,[OtherCtx,Bin1]},
{bs_save2,OtherCtx,_},
{bs_restore2,OtherCtx,_},
{test,bs_match_string,F,[OtherCtx,Bin2]}|Is0] ->
%% We used to do this optimization later, but it
%% turns out that in huge functions with many
%% bs_match_string instructions, it's a big win
%% to do the combination now. To avoid copying the
%% binary data again and again, we'll combine bitstrings
%% in a list and convert all of it to a bitstring later.
[{test,bs_match_string,F,[OtherCtx,[Bin1,Bin2]]}|Is0];
Is0 ->
Is0
end,
{[{bs_restore2,CtxReg,{Ctx,Ivar}}|Is],Aft,St2}.
select_extract_int([{var,Tl}], Val, {integer,Sz}, U, Fs, Vf,
I, Vdb, Bef, Ctx, St) ->
Bits = U*Sz,
Bin = case member(big, Fs) of
true ->
<<Val:Bits>>;
false ->
true = member(little, Fs), %Assertion.
<<Val:Bits/little>>
end,
Bits = bit_size(Bin), %Assertion.
CtxReg = fetch_var(Ctx, Bef),
Is = if
Bits =:= 0 ->
[{bs_save2,CtxReg,{Ctx,Tl}}];
true ->
[{test,bs_match_string,{f,Vf},[CtxReg,Bin]},
{bs_save2,CtxReg,{Ctx,Tl}}]
end,
{Is,clear_dead(Bef, I, Vdb),St}.
select_extract_bin([{var,Hd},{var,Tl}], Size0, Unit, Type, Flags, Vf,
I, Vdb, Bef, Ctx, _Body, St) ->
SizeReg = get_bin_size_reg(Size0, Bef),
{Es,Aft} =
case vdb_find(Hd, Vdb) of
{_,_,Lhd} when Lhd =< I ->
%% The extracted value will not be used.
CtxReg = fetch_var(Ctx, Bef),
Live = max_reg(Bef#sr.reg),
Skip = build_skip_instr(Type, Vf, CtxReg, Live,
SizeReg, Unit, Flags),
{[Skip,{bs_save2,CtxReg,{Ctx,Tl}}],Bef};
{_,_,_} ->
Reg = put_reg(Hd, Bef#sr.reg),
Int1 = Bef#sr{reg=Reg},
Rhd = fetch_reg(Hd, Reg),
CtxReg = fetch_reg(Ctx, Reg),
Live = max_reg(Bef#sr.reg),
{[build_bs_instr(Type, Vf, CtxReg, Live, SizeReg,
Unit, Flags, Rhd),
{bs_save2,CtxReg,{Ctx,Tl}}],Int1}
end,
{Es,clear_dead(Aft, I, Vdb),St};
select_extract_bin([{var,Hd}], Size0, Unit, binary, Flags, Vf,
I, Vdb, Bef, Ctx, Body, St) ->
SizeReg = get_bin_size_reg(Size0, Bef),
{Es,Aft} =
case vdb_find(Hd, Vdb) of
{_,_,Lhd} when Lhd =< I ->
CtxReg = fetch_var(Ctx, Bef),
{case SizeReg =:= {atom,all} andalso is_context_unused(Body) of
true when Unit =:= 1 ->
[];
true ->
[{test,bs_test_unit,{f,Vf},[CtxReg,Unit]}];
false ->
[{test,bs_skip_bits2,{f,Vf},
[CtxReg,SizeReg,Unit,{field_flags,Flags}]}]
end,Bef};
{_,_,_} ->
case is_context_unused(Body) of
false ->
Reg = put_reg(Hd, Bef#sr.reg),
Int1 = Bef#sr{reg=Reg},
Rhd = fetch_reg(Hd, Reg),
CtxReg = fetch_reg(Ctx, Reg),
Name = bs_get_binary2,
Live = max_reg(Bef#sr.reg),
{[{test,Name,{f,Vf},Live,
[CtxReg,SizeReg,Unit,{field_flags,Flags}],Rhd}],
Int1};
true ->
%% Since the matching context will not be used again,
%% we can reuse its register. Reusing the register
%% opens some interesting optimizations in the
%% run-time system.
Reg0 = Bef#sr.reg,
CtxReg = fetch_reg(Ctx, Reg0),
Reg = replace_reg_contents(Ctx, Hd, Reg0),
Int1 = Bef#sr{reg=Reg},
Name = bs_get_binary2,
Live = max_reg(Int1#sr.reg),
{[{test,Name,{f,Vf},Live,
[CtxReg,SizeReg,Unit,{field_flags,Flags}],CtxReg}],
Int1}
end
end,
{Es,clear_dead(Aft, I, Vdb),St}.
%% is_context_unused(Ke) -> true | false
%% Simple heurististic to determine whether the code that follows will
%% use the current matching context again. (The information of liveness
%% calculcated by v3_life is too conservative to be useful for this purpose.)
%% 'true' means that the code that follows will definitely not use the context
%% again (because it is a block, not guard or matching code); 'false' that we
%% are not sure (there is either a guard, or more matching, either which may
%% reference the context again).
is_context_unused(#l{ke=Ke}) -> is_context_unused(Ke);
is_context_unused({block,_}) -> true;
is_context_unused(_) -> false.
select_bin_end(#l{ke={val_clause,{bin_end,Ctx},B}},
Ivar, Tf, Bef, St0) ->
{Bis,Aft,St2} = match_cg(B, Tf, Bef, St0),
CtxReg = fetch_var(Ctx, Bef),
{[{bs_restore2,CtxReg,{Ctx,Ivar}},
{test,bs_test_tail2,{f,Tf},[CtxReg,0]}|Bis],Aft,St2}.
get_bin_size_reg({var,V}, Bef) ->
fetch_var(V, Bef);
get_bin_size_reg(Literal, _Bef) ->
Literal.
build_bs_instr(Type, Vf, CtxReg, Live, SizeReg, Unit, Flags, Rhd) ->
{Format,Name} = case Type of
integer -> {plain,bs_get_integer2};
float -> {plain,bs_get_float2};
binary -> {plain,bs_get_binary2};
utf8 -> {utf,bs_get_utf8};
utf16 -> {utf,bs_get_utf16};
utf32 -> {utf,bs_get_utf32}
end,
case Format of
plain ->
{test,Name,{f,Vf},Live,
[CtxReg,SizeReg,Unit,{field_flags,Flags}],Rhd};
utf ->
{test,Name,{f,Vf},Live,
[CtxReg,{field_flags,Flags}],Rhd}
end.
build_skip_instr(Type, Vf, CtxReg, Live, SizeReg, Unit, Flags) ->
{Format,Name} = case Type of
utf8 -> {utf,bs_skip_utf8};
utf16 -> {utf,bs_skip_utf16};
utf32 -> {utf,bs_skip_utf32};
_ -> {plain,bs_skip_bits2}
end,
case Format of
plain ->
{test,Name,{f,Vf},[CtxReg,SizeReg,Unit,{field_flags,Flags}]};
utf ->
{test,Name,{f,Vf},[CtxReg,Live,{field_flags,Flags}]}
end.
select_val(#l{ke={val_clause,{tuple,Es},B},i=I,vdb=Vdb}, V, Vf, Bef, St0) ->
{Eis,Int,St1} = select_extract_tuple(V, Es, I, Vdb, Bef, St0),
{Bis,Aft,St2} = match_cg(B, Vf, Int, St1),
{length(Es),Eis ++ Bis,Aft,St2};
select_val(#l{ke={val_clause,{_,Val},B}}, _V, Vf, Bef, St0) ->
{Bis,Aft,St1} = match_cg(B, Vf, Bef, St0),
{Val,Bis,Aft,St1}.
%% select_extract_tuple(Src, [V], I, Vdb, StackReg, State) ->
%% {[E],StackReg,State}.
%% Extract tuple elements, but only if they do not immediately die.
select_extract_tuple(Src, Vs, I, Vdb, Bef, St) ->
F = fun ({var,V}, {Int0,Elem}) ->
case vdb_find(V, Vdb) of
{V,_,L} when L =< I -> {[], {Int0,Elem+1}};
_Other ->
Reg1 = put_reg(V, Int0#sr.reg),
Int1 = Int0#sr{reg=Reg1},
Rsrc = fetch_var(Src, Int1),
{[{get_tuple_element,Rsrc,Elem,fetch_reg(V, Reg1)}],
{Int1,Elem+1}}
end
end,
{Es,{Aft,_}} = flatmapfoldl(F, {Bef,0}, Vs),
{Es,Aft,St}.
select_map(Scs, V, Tf, Vf, Bef, St0) ->
Reg = fetch_var(V, Bef),
{Is,Aft,St1} =
match_fmf(fun(#l{ke={val_clause,{map,Es},B},i=I,vdb=Vdb}, Fail, St1) ->
select_map_val(V, Es, B, Fail, I, Vdb, Bef, St1)
end, Vf, St0, Scs),
{[{test,is_map,{f,Tf},[Reg]}|Is],Aft,St1}.
select_map_val(V, Es, B, Fail, I, Vdb, Bef, St0) ->
{Eis,Int,St1} = select_extract_map(V, Es, Fail, I, Vdb, Bef, St0),
{Bis,Aft,St2} = match_cg(B, Fail, Int, St1),
{Eis++Bis,Aft,St2}.
select_extract_map(Src, Vs, Fail, I, Vdb, Bef, St) ->
F = fun ({map_pair,Key,{var,V}}, Int0) ->
Rsrc = fetch_var(Src, Int0),
case vdb_find(V, Vdb) of
{V,_,L} when L =< I ->
{[{test,has_map_field,{f,Fail},[Rsrc,Key]}],Int0};
_Other ->
Reg1 = put_reg(V, Int0#sr.reg),
Int1 = Int0#sr{reg=Reg1},
{[{get_map_element,{f,Fail},
Rsrc,Key,fetch_reg(V, Reg1)}],
Int1}
end
end,
{Es,Aft} = flatmapfoldl(F, Bef, Vs),
{Es,Aft,St}.
select_extract_cons(Src, [{var,Hd}, {var,Tl}], I, Vdb, Bef, St) ->
{Es,Aft} = case {vdb_find(Hd, Vdb), vdb_find(Tl, Vdb)} of
{{_,_,Lhd}, {_,_,Ltl}} when Lhd =< I, Ltl =< I ->
%% Both head and tail are dead. No need to generate
%% any instruction.
{[], Bef};
_ ->
%% At least one of head and tail will be used,
%% but we must always fetch both. We will call
%% clear_dead/2 to allow reuse of the register
%% in case only of them is used.
Reg0 = put_reg(Tl, put_reg(Hd, Bef#sr.reg)),
Int0 = Bef#sr{reg=Reg0},
Rsrc = fetch_var(Src, Int0),
Rhd = fetch_reg(Hd, Reg0),
Rtl = fetch_reg(Tl, Reg0),
Int1 = clear_dead(Int0, I, Vdb),
{[{get_list,Rsrc,Rhd,Rtl}], Int1}
end,
{Es,Aft,St}.
guard_clause_cg(#l{ke={guard_clause,G,B},vdb=Vdb}, Fail, Bef, St0) ->
{Gis,Int,St1} = guard_cg(G, Fail, Vdb, Bef, St0),
{Bis,Aft,St} = match_cg(B, Fail, Int, St1),
{Gis ++ Bis,Aft,St}.
%% guard_cg(Guard, Fail, Vdb, StackReg, State) ->
%% {[Ainstr],StackReg,State}.
%% A guard is a boolean expression of tests. Tests return true or
%% false. A fault in a test causes the test to return false. Tests
%% never return the boolean, instead we generate jump code to go to
%% the correct exit point. Primops and tests all go to the next
%% instruction on success or jump to a failure label.
guard_cg(#l{ke={protected,Ts,Rs},i=I,vdb=Pdb}, Fail, _Vdb, Bef, St) ->
protected_cg(Ts, Rs, Fail, I, Pdb, Bef, St);
guard_cg(#l{ke={block,Ts},i=I,vdb=Bdb}, Fail, _Vdb, Bef, St) ->
guard_cg_list(Ts, Fail, I, Bdb, Bef, St);
guard_cg(#l{ke={test,Test,As},i=I,vdb=_Tdb}, Fail, Vdb, Bef, St) ->
test_cg(Test, As, Fail, I, Vdb, Bef, St);
guard_cg(G, _Fail, Vdb, Bef, St) ->
%%ok = io:fwrite("cg ~w: ~p~n", [?LINE,{G,Fail,Vdb,Bef}]),
{Gis,Aft,St1} = cg(G, Vdb, Bef, St),
%%ok = io:fwrite("cg ~w: ~p~n", [?LINE,{Aft}]),
{Gis,Aft,St1}.
%% protected_cg([Kexpr], [Ret], Fail, I, Vdb, Bef, St) -> {[Ainstr],Aft,St}.
%% Do a protected. Protecteds without return values are just done
%% for effect, the return value is not checked, success passes on to
%% the next instruction and failure jumps to Fail. If there are
%% return values then these must be set to 'false' on failure,
%% control always passes to the next instruction.
protected_cg(Ts, [], Fail, I, Vdb, Bef, St0) ->
%% Protect these calls, revert when done.
{Tis,Aft,St1} = guard_cg_list(Ts, Fail, I, Vdb, Bef,
St0#cg{bfail=Fail}),
{Tis,Aft,St1#cg{bfail=St0#cg.bfail}};
protected_cg(Ts, Rs, _Fail, I, Vdb, Bef, St0) ->
{Pfail,St1} = new_label(St0),
{Psucc,St2} = new_label(St1),
{Tis,Aft,St3} = guard_cg_list(Ts, Pfail, I, Vdb, Bef,
St2#cg{bfail=Pfail}),
%%ok = io:fwrite("cg ~w: ~p~n", [?LINE,{Rs,I,Vdb,Aft}]),
%% Set return values to false.
Mis = map(fun ({var,V}) -> {move,{atom,false},fetch_var(V, Aft)} end, Rs),
{Tis ++ [{jump,{f,Psucc}},
{label,Pfail}] ++ Mis ++ [{label,Psucc}],
Aft,St3#cg{bfail=St0#cg.bfail}}.
%% test_cg(TestName, Args, Fail, I, Vdb, Bef, St) -> {[Ainstr],Aft,St}.
%% Generate test instruction. Use explicit fail label here.
test_cg(Test, As, Fail, I, Vdb, Bef, St) ->
Args = cg_reg_args(As, Bef),
Aft = clear_dead(Bef, I, Vdb),
{[beam_utils:bif_to_test(Test, Args, {f,Fail})],Aft,St}.
%% guard_cg_list([Kexpr], Fail, I, Vdb, StackReg, St) ->
%% {[Ainstr],StackReg,St}.
guard_cg_list(Kes, Fail, I, Vdb, Bef, St0) ->
{Keis,{Aft,St1}} =
flatmapfoldl(fun (Ke, {Inta,Sta}) ->
{Keis,Intb,Stb} =
guard_cg(Ke, Fail, Vdb, Inta, Sta),
{Keis,{Intb,Stb}}
end, {Bef,St0}, need_heap(Kes, I)),
{Keis,Aft,St1}.
%% match_fmf(Fun, LastFail, State, [Clause]) -> {Is,Aft,State}.
%% This is a special flatmapfoldl for match code gen where we
%% generate a "failure" label for each clause. The last clause uses
%% an externally generated failure label, LastFail. N.B. We do not
%% know or care how the failure labels are used.
match_fmf(F, LastFail, St, [H]) ->
F(H, LastFail, St);
match_fmf(F, LastFail, St0, [H|T]) ->
{Fail,St1} = new_label(St0),
{R,Aft1,St2} = F(H, Fail, St1),
{Rs,Aft2,St3} = match_fmf(F, LastFail, St2, T),
{R ++ [{label,Fail}] ++ Rs,sr_merge(Aft1, Aft2),St3}.
%% call_cg(Func, [Arg], [Ret], Le, Vdb, StackReg, State) ->
%% {[Ainstr],StackReg,State}.
%% enter_cg(Func, [Arg], Le, Vdb, Bef, St) -> {[Ainstr],Aft,St}.
%% Call and enter first put the arguments into registers and save any
%% other registers, then clean up and compress the stack and set the
%% frame size. Finally the actual call is made. Call then needs the
%% return values filled in.
call_cg({var,_V} = Var, As, Rs, Le, Vdb, Bef, St0) ->
{Sis,Int} = cg_setup_call(As++[Var], Bef, Le#l.i, Vdb),
%% Put return values in registers.
Reg = load_vars(Rs, clear_regs(Int#sr.reg)),
%% Build complete code and final stack/register state.
Arity = length(As),
{Frees,Aft} = free_dead(clear_dead(Int#sr{reg=Reg}, Le#l.i, Vdb)),
{Sis ++ Frees ++ [line(Le),{call_fun,Arity}],Aft,
need_stack_frame(St0)};
call_cg({remote,Mod,Name}, As, Rs, Le, Vdb, Bef, St0)
when element(1, Mod) =:= var;
element(1, Name) =:= var ->
{Sis,Int} = cg_setup_call(As++[Mod,Name], Bef, Le#l.i, Vdb),
%% Put return values in registers.
Reg = load_vars(Rs, clear_regs(Int#sr.reg)),
%% Build complete code and final stack/register state.
Arity = length(As),
St = need_stack_frame(St0),
%%{Call,St1} = build_call(Func, Arity, St0),
{Frees,Aft} = free_dead(clear_dead(Int#sr{reg=Reg}, Le#l.i, Vdb)),
{Sis ++ Frees ++ [line(Le),{apply,Arity}],Aft,St};
call_cg(Func, As, Rs, Le, Vdb, Bef, St0) ->
case St0 of
#cg{bfail=Fail} when Fail =/= 0 ->
%% Inside a guard. The only allowed function call is to
%% erlang:error/1,2. We will generate the following code:
%%
%% jump FailureLabel
%% move {atom,ok} DestReg
%%
%% The 'move' instruction will never be executed, but we
%% generate it anyway in case the beam_validator is run
%% on unoptimized code.
{remote,{atom,erlang},{atom,error}} = Func, %Assertion.
[{var,DestVar}] = Rs,
Int0 = clear_dead(Bef, Le#l.i, Vdb),
Reg = put_reg(DestVar, Int0#sr.reg),
Int = Int0#sr{reg=Reg},
Dst = fetch_reg(DestVar, Reg),
{[{jump,{f,Fail}},{move,{atom,ok},Dst}],
clear_dead(Int, Le#l.i, Vdb),St0};
#cg{} ->
%% Ordinary function call in a function body.
{Sis,Int} = cg_setup_call(As, Bef, Le#l.i, Vdb),
%% Put return values in registers.
Reg = load_vars(Rs, clear_regs(Int#sr.reg)),
%% Build complete code and final stack/register state.
Arity = length(As),
{Call,St1} = build_call(Func, Arity, St0),
{Frees,Aft} = free_dead(clear_dead(Int#sr{reg=Reg}, Le#l.i, Vdb)),
{Sis ++ Frees ++ [line(Le)|Call],Aft,St1}
end.
build_call({remote,{atom,erlang},{atom,'!'}}, 2, St0) ->
{[send],need_stack_frame(St0)};
build_call({remote,{atom,Mod},{atom,Name}}, Arity, St0) ->
{[{call_ext,Arity,{extfunc,Mod,Name,Arity}}],need_stack_frame(St0)};
build_call(Name, Arity, St0) when is_atom(Name) ->
{Lbl,St1} = local_func_label(Name, Arity, need_stack_frame(St0)),
{[{call,Arity,{f,Lbl}}],St1}.
free_dead(#sr{stk=Stk0}=Aft) ->
{Instr,Stk} = free_dead(Stk0, 0, [], []),
{Instr,Aft#sr{stk=Stk}}.
free_dead([dead|Stk], Y, Instr, StkAcc) ->
%% Note: kill/1 is equivalent to init/1 (translated by beam_asm).
%% We use kill/1 to help further optimisation passes.
free_dead(Stk, Y+1, [{kill,{yy,Y}}|Instr], [free|StkAcc]);
free_dead([Any|Stk], Y, Instr, StkAcc) ->
free_dead(Stk, Y+1, Instr, [Any|StkAcc]);
free_dead([], _, Instr, StkAcc) -> {Instr,reverse(StkAcc)}.
enter_cg({var,_V} = Var, As, Le, Vdb, Bef, St0) ->
{Sis,Int} = cg_setup_call(As++[Var], Bef, Le#l.i, Vdb),
%% Build complete code and final stack/register state.
Arity = length(As),
{Sis ++ [line(Le),{call_fun,Arity},return],
clear_dead(Int#sr{reg=clear_regs(Int#sr.reg)}, Le#l.i, Vdb),
need_stack_frame(St0)};
enter_cg({remote,Mod,Name}, As, Le, Vdb, Bef, St0)
when element(1, Mod) =:= var;
element(1, Name) =:= var ->
{Sis,Int} = cg_setup_call(As++[Mod,Name], Bef, Le#l.i, Vdb),
%% Build complete code and final stack/register state.
Arity = length(As),
St = need_stack_frame(St0),
{Sis ++ [line(Le),{apply_only,Arity}],
clear_dead(Int#sr{reg=clear_regs(Int#sr.reg)}, Le#l.i, Vdb),
St};
enter_cg(Func, As, Le, Vdb, Bef, St0) ->
{Sis,Int} = cg_setup_call(As, Bef, Le#l.i, Vdb),
%% Build complete code and final stack/register state.
Arity = length(As),
{Call,St1} = build_enter(Func, Arity, St0),
Line = enter_line(Func, Arity, Le),
{Sis ++ Line ++ Call,
clear_dead(Int#sr{reg=clear_regs(Int#sr.reg)}, Le#l.i, Vdb),
St1}.
build_enter({remote,{atom,erlang},{atom,'!'}}, 2, St0) ->
{[send,return],need_stack_frame(St0)};
build_enter({remote,{atom,Mod},{atom,Name}}, Arity, St0) ->
St1 = case trap_bif(Mod, Name, Arity) of
true -> need_stack_frame(St0);
false -> St0
end,
{[{call_ext_only,Arity,{extfunc,Mod,Name,Arity}}],St1};
build_enter(Name, Arity, St0) when is_atom(Name) ->
{Lbl,St1} = local_func_label(Name, Arity, St0),
{[{call_only,Arity,{f,Lbl}}],St1}.
enter_line({remote,{atom,Mod},{atom,Name}}, Arity, Le) ->
case erl_bifs:is_safe(Mod, Name, Arity) of
false ->
%% Tail-recursive call, possibly to a BIF.
%% We'll need a line instruction in case the
%% BIF call fails.
[line(Le)];
true ->
%% Call to a safe BIF. Since it cannot fail,
%% we don't need any line instruction here.
[]
end;
enter_line(_, _, _) ->
%% Tail-recursive call to a local function. A line
%% instruction will not be useful.
[].
%% local_func_label(Name, Arity, State) -> {Label,State'}
%% local_func_label({Name,Arity}, State) -> {Label,State'}
%% Get the function entry label for a local function.
local_func_label(Name, Arity, St) ->
local_func_label({Name,Arity}, St).
local_func_label(Key, #cg{functable=Tab}=St0) ->
case gb_trees:lookup(Key, Tab) of
{value,Label} ->
{Label,St0};
none ->
{Label,St} = new_label(St0),
{Label,St#cg{functable=gb_trees:insert(Key, Label, Tab)}}
end.
%% need_stack_frame(State) -> State'
%% Make a note in the state that this function will need a stack frame.
need_stack_frame(#cg{need_frame=true}=St) -> St;
need_stack_frame(St) -> St#cg{need_frame=true}.
%% trap_bif(Mod, Name, Arity) -> true|false
%% Trap bifs that need a stack frame.
trap_bif(erlang, link, 1) -> true;
trap_bif(erlang, unlink, 1) -> true;
trap_bif(erlang, monitor_node, 2) -> true;
trap_bif(erlang, group_leader, 2) -> true;
trap_bif(erlang, exit, 2) -> true;
trap_bif(_, _, _) -> false.
%% bif_cg(Bif, [Arg], [Ret], Le, Vdb, StackReg, State) ->
%% {[Ainstr],StackReg,State}.
bif_cg(bs_context_to_binary=Instr, [Src0], [], Le, Vdb, Bef, St0) ->
[Src] = cg_reg_args([Src0], Bef),
case is_register(Src) of
false ->
{[],clear_dead(Bef, Le#l.i, Vdb), St0};
true ->
{[{Instr,Src}],clear_dead(Bef, Le#l.i, Vdb), St0}
end;
bif_cg(dsetelement, [Index0,Tuple0,New0], _Rs, Le, Vdb, Bef, St0) ->
[New,Tuple,{integer,Index1}] = cg_reg_args([New0,Tuple0,Index0], Bef),
Index = Index1-1,
{[{set_tuple_element,New,Tuple,Index}],
clear_dead(Bef, Le#l.i, Vdb), St0};
bif_cg({make_fun,Func,Arity,Index,Uniq}, As, Rs, Le, Vdb, Bef, St0) ->
%% This behaves more like a function call.
{Sis,Int} = cg_setup_call(As, Bef, Le#l.i, Vdb),
Reg = load_vars(Rs, clear_regs(Int#sr.reg)),
{FuncLbl,St1} = local_func_label(Func, Arity, St0),
MakeFun = {make_fun2,{f,FuncLbl},Index,Uniq,length(As)},
{Sis ++ [MakeFun],
clear_dead(Int#sr{reg=Reg}, Le#l.i, Vdb),
St1};
bif_cg(bs_init_writable=I, As, Rs, Le, Vdb, Bef, St) ->
%% This behaves like a function call.
{Sis,Int} = cg_setup_call(As, Bef, Le#l.i, Vdb),
Reg = load_vars(Rs, clear_regs(Int#sr.reg)),
{Sis++[I],clear_dead(Int#sr{reg=Reg}, Le#l.i, Vdb),St};
bif_cg(Bif, As, [{var,V}], Le, Vdb, Bef, St0) ->
Ars = cg_reg_args(As, Bef),
%% If we are inside a catch and in a body (not in guard) and the
%% BIF may fail, we must save everything that will be alive after
%% the catch (because the code after the code assumes that all
%% variables that are live are stored on the stack).
%%
%% Currently, we are somewhat pessimistic in
%% that we save any variable that will be live after this BIF call.
MayFail = not erl_bifs:is_safe(erlang, Bif, length(As)),
{Sis,Int0} = case St0#cg.in_catch andalso
St0#cg.bfail =:= 0 andalso
MayFail of
true -> adjust_stack(Bef, Le#l.i, Le#l.i+1, Vdb);
false -> {[],Bef}
end,
Int1 = clear_dead(Int0, Le#l.i, Vdb),
Reg = put_reg(V, Int1#sr.reg),
Int = Int1#sr{reg=Reg},
Dst = fetch_reg(V, Reg),
BifFail = {f,St0#cg.bfail},
%% We need a line instructions for BIFs that may fail in a body.
Line = case BifFail of
{f,0} when MayFail ->
[line(Le)];
_ ->
[]
end,
{Sis++Line++[{bif,Bif,BifFail,Ars,Dst}],
clear_dead(Int, Le#l.i, Vdb), St0}.
%% gc_bif_cg(Bif, [Arg], [Ret], Le, Vdb, StackReg, State) ->
%% {[Ainstr],StackReg,State}.
gc_bif_cg(Bif, As, [{var,V}], Le, Vdb, Bef, St0) ->
Ars = cg_reg_args(As, Bef),
%% If we are inside a catch and in a body (not in guard) and the
%% BIF may fail, we must save everything that will be alive after
%% the catch (because the code after the code assumes that all
%% variables that are live are stored on the stack).
%%
%% Currently, we are somewhat pessimistic in
%% that we save any variable that will be live after this BIF call.
{Sis,Int0} =
case St0#cg.in_catch andalso St0#cg.bfail =:= 0 of
true -> adjust_stack(Bef, Le#l.i, Le#l.i+1, Vdb);
false -> {[],Bef}
end,
Int1 = clear_dead(Int0, Le#l.i, Vdb),
Reg = put_reg(V, Int1#sr.reg),
Int = Int1#sr{reg=Reg},
Dst = fetch_reg(V, Reg),
BifFail = {f,St0#cg.bfail},
Line = case BifFail of
{f,0} -> [line(Le)];
{f,_} -> []
end,
{Sis++Line++[{gc_bif,Bif,BifFail,max_reg(Bef#sr.reg),Ars,Dst}],
clear_dead(Int, Le#l.i, Vdb), St0}.
%% recv_loop_cg(TimeOut, ReceiveVar, ReceiveMatch, TimeOutExprs,
%% [Ret], Le, Vdb, Bef, St) -> {[Ainstr],Aft,St}.
recv_loop_cg(Te, Rvar, Rm, Tes, Rs, Le, Vdb, Bef, St0) ->
{Sis,Int0} = adjust_stack(Bef, Le#l.i, Le#l.i, Vdb),
Int1 = Int0#sr{reg=clear_regs(Int0#sr.reg)},
%% Get labels.
{Rl,St1} = new_label(St0),
{Tl,St2} = new_label(St1),
{Bl,St3} = new_label(St2),
St4 = St3#cg{break=Bl,recv=Rl}, %Set correct receive labels
{Ris,Raft,St5} = cg_recv_mesg(Rvar, Rm, Tl, Int1, St4),
{Wis,Taft,St6} = cg_recv_wait(Te, Tes, Le#l.i, Int1, St5),
Int2 = sr_merge(Raft, Taft), %Merge stack/registers
Reg = load_vars(Rs, Int2#sr.reg),
{Sis ++ [line(Le)] ++ Ris ++ [{label,Tl}] ++ Wis ++ [{label,Bl}],
clear_dead(Int2#sr{reg=Reg}, Le#l.i, Vdb),
St6#cg{break=St0#cg.break,recv=St0#cg.recv}}.
%% cg_recv_mesg( ) -> {[Ainstr],Aft,St}.
cg_recv_mesg({var,R}, Rm, Tl, Bef, St0) ->
Int0 = Bef#sr{reg=put_reg(R, Bef#sr.reg)},
Ret = fetch_reg(R, Int0#sr.reg),
%% Int1 = clear_dead(Int0, I, Rm#l.vdb),
Int1 = Int0,
{Mis,Int2,St1} = match_cg(Rm, none, Int1, St0),
{[{label,St1#cg.recv},{loop_rec,{f,Tl},Ret}|Mis],Int2,St1}.
%% cg_recv_wait(Te, Tes, I, Vdb, Int2, St3) -> {[Ainstr],Aft,St}.
cg_recv_wait({atom,infinity}, Tes, I, Bef, St0) ->
%% We know that the 'after' body will never be executed.
%% But to keep the stack and register information up to date,
%% we will generate the code for the 'after' body, and then discard it.
Int1 = clear_dead(Bef, I, Tes#l.vdb),
{_,Int2,St1} = cg_block(Tes#l.ke, Tes#l.i, Tes#l.vdb,
Int1#sr{reg=clear_regs(Int1#sr.reg)}, St0),
{[{wait,{f,St1#cg.recv}}],Int2,St1};
cg_recv_wait({integer,0}, Tes, _I, Bef, St0) ->
{Tis,Int,St1} = cg_block(Tes#l.ke, Tes#l.i, Tes#l.vdb, Bef, St0),
{[timeout|Tis],Int,St1};
cg_recv_wait(Te, Tes, I, Bef, St0) ->
Reg = cg_reg_arg(Te, Bef),
%% Must have empty registers here! Bug if anything in registers.
Int0 = clear_dead(Bef, I, Tes#l.vdb),
{Tis,Int,St1} = cg_block(Tes#l.ke, Tes#l.i, Tes#l.vdb,
Int0#sr{reg=clear_regs(Int0#sr.reg)}, St0),
{[{wait_timeout,{f,St1#cg.recv},Reg},timeout] ++ Tis,Int,St1}.
%% recv_next_cg(Le, Vdb, StackReg, St) -> {[Ainstr],StackReg,St}.
%% Use adjust stack to clear stack, but only need it for Aft.
recv_next_cg(Le, Vdb, Bef, St) ->
{Sis,Aft} = adjust_stack(Bef, Le#l.i, Le#l.i+1, Vdb),
{[{loop_rec_end,{f,St#cg.recv}}] ++ Sis,Aft,St}. %Joke
%% try_cg(TryBlock, [BodyVar], TryBody, [ExcpVar], TryHandler, [Ret],
%% Le, Vdb, StackReg, St) -> {[Ainstr],StackReg,St}.
try_cg(Ta, Vs, Tb, Evs, Th, Rs, Le, Vdb, Bef, St0) ->
{B,St1} = new_label(St0), %Body label
{H,St2} = new_label(St1), %Handler label
{E,St3} = new_label(St2), %End label
TryTag = Ta#l.i,
Int1 = Bef#sr{stk=put_catch(TryTag, Bef#sr.stk)},
TryReg = fetch_stack({catch_tag,TryTag}, Int1#sr.stk),
{Ais,Int2,St4} = cg(Ta, Vdb, Int1, St3#cg{break=B,in_catch=true}),
Int3 = Int2#sr{stk=drop_catch(TryTag, Int2#sr.stk)},
St5 = St4#cg{break=E,in_catch=St3#cg.in_catch},
{Bis,Baft,St6} = cg(Tb, Vdb, Int3#sr{reg=load_vars(Vs, Int3#sr.reg)}, St5),
{His,Haft,St7} = cg(Th, Vdb, Int3#sr{reg=load_vars(Evs, Int3#sr.reg)}, St6),
Int4 = sr_merge(Baft, Haft), %Merge stack/registers
Aft = Int4#sr{reg=load_vars(Rs, Int4#sr.reg)},
{[{'try',TryReg,{f,H}}] ++ Ais ++
[{label,B},{try_end,TryReg}] ++ Bis ++
[{label,H},{try_case,TryReg}] ++ His ++
[{label,E}],
clear_dead(Aft, Le#l.i, Vdb),
St7#cg{break=St0#cg.break}}.
try_enter_cg(Ta, Vs, Tb, Evs, Th, Le, Vdb, Bef, St0) ->
{B,St1} = new_label(St0), %Body label
{H,St2} = new_label(St1), %Handler label
TryTag = Ta#l.i,
Int1 = Bef#sr{stk=put_catch(TryTag, Bef#sr.stk)},
TryReg = fetch_stack({catch_tag,TryTag}, Int1#sr.stk),
{Ais,Int2,St3} = cg(Ta, Vdb, Int1, St2#cg{break=B,in_catch=true}),
Int3 = Int2#sr{stk=drop_catch(TryTag, Int2#sr.stk)},
St4 = St3#cg{in_catch=St2#cg.in_catch},
{Bis,Baft,St5} = cg(Tb, Vdb, Int3#sr{reg=load_vars(Vs, Int3#sr.reg)}, St4),
{His,Haft,St6} = cg(Th, Vdb, Int3#sr{reg=load_vars(Evs, Int3#sr.reg)}, St5),
Int4 = sr_merge(Baft, Haft), %Merge stack/registers
Aft = Int4,
{[{'try',TryReg,{f,H}}] ++ Ais ++
[{label,B},{try_end,TryReg}] ++ Bis ++
[{label,H},{try_case,TryReg}] ++ His,
clear_dead(Aft, Le#l.i, Vdb),
St6#cg{break=St0#cg.break}}.
%% catch_cg(CatchBlock, Ret, Le, Vdb, Bef, St) -> {[Ainstr],Aft,St}.
catch_cg(C, {var,R}, Le, Vdb, Bef, St0) ->
{B,St1} = new_label(St0),
CatchTag = Le#l.i,
Int1 = Bef#sr{stk=put_catch(CatchTag, Bef#sr.stk)},
CatchReg = fetch_stack({catch_tag,CatchTag}, Int1#sr.stk),
{Cis,Int2,St2} = cg_block(C, Le#l.i, Le#l.vdb, Int1,
St1#cg{break=B,in_catch=true}),
[] = Int2#sr.reg, %Assertion.
Aft = Int2#sr{reg=[{0,R}],stk=drop_catch(CatchTag, Int2#sr.stk)},
{[{'catch',CatchReg,{f,B}}] ++ Cis ++
[{label,B},{catch_end,CatchReg}],
clear_dead(Aft, Le#l.i, Vdb),
St2#cg{break=St1#cg.break,in_catch=St1#cg.in_catch}}.
%% set_cg([Var], Constr, Le, Vdb, Bef, St) -> {[Ainstr],Aft,St}.
%% We have to be careful how a 'set' works. First the structure is
%% built, then it is filled and finally things can be cleared. The
%% annotation must reflect this and make sure that the return
%% variable is allocated first.
%%
%% put_list and put_map are atomic instructions, both of
%% which can safely resuse one of the source registers as target.
set_cg([{var,R}], {cons,Es}, Le, Vdb, Bef, St) ->
[S1,S2] = cg_reg_args(Es, Bef),
Int0 = clear_dead(Bef, Le#l.i, Vdb),
Int1 = Int0#sr{reg=put_reg(R, Int0#sr.reg)},
Ret = fetch_reg(R, Int1#sr.reg),
{[{put_list,S1,S2,Ret}], Int1, St};
set_cg([{var,R}], {binary,Segs}, Le, Vdb, Bef,
#cg{in_catch=InCatch, bfail=Bfail}=St) ->
%% At run-time, binaries are constructed in three stages:
%% 1) First the size of the binary is calculated.
%% 2) Then the binary is allocated.
%% 3) Then each field in the binary is constructed.
%% For simplicity, we use the target register to also hold the
%% size of the binary. Therefore the target register must *not*
%% be one of the source registers.
%% First allocate the target register.
Int0 = Bef#sr{reg=put_reg(R, Bef#sr.reg)},
Target = fetch_reg(R, Int0#sr.reg),
%% Also allocate a scratch register for size calculations.
Temp = find_scratch_reg(Int0#sr.reg),
%% First generate the code that constructs each field.
Fail = {f,Bfail},
PutCode = cg_bin_put(Segs, Fail, Bef),
{Sis,Int1} =
case InCatch of
true -> adjust_stack(Int0, Le#l.i, Le#l.i+1, Vdb);
false -> {[],Int0}
end,
MaxRegs = max_reg(Bef#sr.reg),
Aft = clear_dead(Int1, Le#l.i, Vdb),
%% Now generate the complete code for constructing the binary.
Code = cg_binary(PutCode, Target, Temp, Fail, MaxRegs, Le#l.a),
{Sis++Code,Aft,St};
set_cg([{var,R}], {map,SrcMap,Es}, Le, Vdb, Bef,
#cg{in_catch=InCatch,bfail=Bfail}=St) ->
Fail = {f,Bfail},
{Sis,Int0} =
case InCatch of
true -> adjust_stack(Bef, Le#l.i, Le#l.i+1, Vdb);
false -> {[],Bef}
end,
Line = line(Le#l.a),
SrcReg = case SrcMap of
{var,SrcVar} -> fetch_var(SrcVar, Int0);
_ -> SrcMap
end,
% MapPairs in put_map must be sorted in ascending Key Order
% Key literals must be unique when arriving here in v3_codegen
SortedEs = lists:sort(fun
({map_pair,{_T1,K1},_},{map_pair,{_T2,K2},_}) when K1 < K2 -> true;
({map_pair,{_,_},_},{map_pair,{_,_},_}) -> false
end, Es),
List = flatmap(fun
({map_pair,K,{var,V}}) -> [K,fetch_var(V, Int0)];
({map_pair,K,E}) -> [K,E]
end, SortedEs),
Live = max_reg(Bef#sr.reg),
Int1 = clear_dead(Int0, Le#l.i, Vdb),
Aft = Bef#sr{reg=put_reg(R, Int1#sr.reg)},
Target = fetch_reg(R, Aft#sr.reg),
Code = [Line,{put_map,Fail,SrcReg,Target,Live,{list,List}}],
{Sis++Code,Aft,St};
set_cg([{var,R}], Con, Le, Vdb, Bef, St) ->
%% Find a place for the return register first.
Int = Bef#sr{reg=put_reg(R, Bef#sr.reg)},
Ret = fetch_reg(R, Int#sr.reg),
Ais = case Con of
{tuple,Es} ->
[{put_tuple,length(Es),Ret}] ++ cg_build_args(Es, Bef);
Other ->
[{move,cg_reg_arg(Other, Int),Ret}]
end,
{Ais,clear_dead(Int, Le#l.i, Vdb),St}.
%%%
%%% Code generation for constructing binaries.
%%%
cg_binary([{bs_put_binary,Fail,{atom,all},U,_Flags,Src}|PutCode],
Target, Temp, Fail, MaxRegs, Anno) ->
Line = line(Anno),
Live = cg_live(Target, MaxRegs),
SzCode = cg_bitstr_size(PutCode, Target, Temp, Fail, Live),
BinFlags = {field_flags,[]},
Code = [Line|SzCode] ++
[case member(single_use, Anno) of
true ->
{bs_private_append,Fail,Target,U,Src,BinFlags,Target};
false ->
{bs_append,Fail,Target,0,MaxRegs,U,Src,BinFlags,Target}
end] ++ PutCode,
cg_bin_opt(Code);
cg_binary(PutCode, Target, Temp, Fail, MaxRegs, Anno) ->
Line = line(Anno),
Live = cg_live(Target, MaxRegs),
{InitOp,SzCode} = cg_binary_size(PutCode, Target, Temp, Fail, Live),
Code = [Line|SzCode] ++ [{InitOp,Fail,Target,0,MaxRegs,
{field_flags,[]},Target}|PutCode],
cg_bin_opt(Code).
cg_live({x,X}, MaxRegs) when X =:= MaxRegs -> MaxRegs+1;
cg_live({x,X}, MaxRegs) when X < MaxRegs -> MaxRegs.
%% Generate code that calculate the size of the bitstr to be
%% built in BITS.
cg_bitstr_size(PutCode, Target, Temp, Fail, Live) ->
{Bits,Es} = cg_bitstr_size_1(PutCode, 0, []),
reverse(cg_gen_binsize(Es, Target, Temp, Fail, Live,
[{move,{integer,Bits},Target}])).
cg_bitstr_size_1([{bs_put_utf8,_,_,Src}|Next], Bits, Acc) ->
cg_bitstr_size_1(Next, Bits, [{'*',{bs_utf8_size,Src},8}|Acc]);
cg_bitstr_size_1([{bs_put_utf16,_,_,Src}|Next], Bits, Acc) ->
cg_bitstr_size_1(Next, Bits, [{'*',{bs_utf16_size,Src},8}|Acc]);
cg_bitstr_size_1([{bs_put_utf32,_,_,_}|Next], Bits, Acc) ->
cg_bitstr_size_1(Next, Bits+32, Acc);
cg_bitstr_size_1([{_,_,S,U,_,Src}|Next], Bits, Acc) ->
case S of
{integer,N} -> cg_bitstr_size_1(Next, Bits+N*U, Acc);
{atom,all} -> cg_bitstr_size_1(Next, Bits, [{bit_size,Src}|Acc]);
_ when U =:= 1 -> cg_bitstr_size_1(Next, Bits, [S|Acc]);
_ -> cg_bitstr_size_1(Next, Bits, [{'*',S,U}|Acc])
end;
cg_bitstr_size_1([], Bits, Acc) -> {Bits,Acc}.
%% Generate code that calculate the size of the bitstr to be
%% built in BYTES or BITS (depending on what is easiest).
cg_binary_size(PutCode, Target, Temp, Fail, Live) ->
{InitInstruction,Szs} = cg_binary_size_1(PutCode, 0, []),
SizeExpr = reverse(cg_gen_binsize(Szs, Target, Temp, Fail, Live, [{move,{integer,0},Target}])),
{InitInstruction,SizeExpr}.
cg_binary_size_1([{bs_put_utf8,_Fail,_Flags,Src}|T], Bits, Acc) ->
cg_binary_size_1(T, Bits, [{8,{bs_utf8_size,Src}}|Acc]);
cg_binary_size_1([{bs_put_utf16,_Fail,_Flags,Src}|T], Bits, Acc) ->
cg_binary_size_1(T, Bits, [{8,{bs_utf16_size,Src}}|Acc]);
cg_binary_size_1([{bs_put_utf32,_Fail,_Flags,_Src}|T], Bits, Acc) ->
cg_binary_size_1(T, Bits+32, Acc);
cg_binary_size_1([{_Put,_Fail,S,U,_Flags,Src}|T], Bits, Acc) ->
cg_binary_size_2(S, U, Src, T, Bits, Acc);
cg_binary_size_1([], Bits, Acc) ->
Bytes = Bits div 8,
RemBits = Bits rem 8,
Sizes0 = sort([{1,{integer,RemBits}},{8,{integer,Bytes}}|Acc]),
Sizes = filter(fun({_,{integer,0}}) -> false;
(_) -> true end, Sizes0),
case Sizes of
[{1,_}|_] ->
{bs_init_bits,cg_binary_bytes_to_bits(Sizes, [])};
[{8,_}|_] ->
{bs_init2,[E || {8,E} <- Sizes]};
[] ->
{bs_init_bits,[]}
end.
cg_binary_size_2({integer,N}, U, _, Next, Bits, Acc) ->
cg_binary_size_1(Next, Bits+N*U, Acc);
cg_binary_size_2({atom,all}, U, E, Next, Bits, Acc) ->
if
U rem 8 =:= 0 ->
cg_binary_size_1(Next, Bits, [{8,{byte_size,E}}|Acc]);
true ->
cg_binary_size_1(Next, Bits, [{1,{bit_size,E}}|Acc])
end;
cg_binary_size_2(Reg, 1, _, Next, Bits, Acc) ->
cg_binary_size_1(Next, Bits, [{1,Reg}|Acc]);
cg_binary_size_2(Reg, 8, _, Next, Bits, Acc) ->
cg_binary_size_1(Next, Bits, [{8,Reg}|Acc]);
cg_binary_size_2(Reg, U, _, Next, Bits, Acc) ->
cg_binary_size_1(Next, Bits, [{1,{'*',Reg,U}}|Acc]).
cg_binary_bytes_to_bits([{8,{integer,N}}|T], Acc) ->
cg_binary_bytes_to_bits(T, [{integer,8*N}|Acc]);
cg_binary_bytes_to_bits([{8,{byte_size,Reg}}|T], Acc) ->
cg_binary_bytes_to_bits(T, [{bit_size,Reg}|Acc]);
cg_binary_bytes_to_bits([{8,Reg}|T], Acc) ->
cg_binary_bytes_to_bits(T, [{'*',Reg,8}|Acc]);
cg_binary_bytes_to_bits([{1,Sz}|T], Acc) ->
cg_binary_bytes_to_bits(T, [Sz|Acc]);
cg_binary_bytes_to_bits([], Acc) ->
cg_binary_bytes_to_bits_1(sort(Acc)).
cg_binary_bytes_to_bits_1([{integer,I},{integer,J}|T]) ->
cg_binary_bytes_to_bits_1([{integer,I+J}|T]);
cg_binary_bytes_to_bits_1([H|T]) ->
[H|cg_binary_bytes_to_bits_1(T)];
cg_binary_bytes_to_bits_1([]) -> [].
cg_gen_binsize([{'*',{bs_utf8_size,Src},B}|T], Target, Temp, Fail, Live, Acc) ->
Size = {bs_utf8_size,Fail,Src,Temp},
Add = {bs_add,Fail,[Target,Temp,B],Target},
cg_gen_binsize(T, Target, Temp, Fail, Live,
[Add,Size|Acc]);
cg_gen_binsize([{'*',{bs_utf16_size,Src},B}|T], Target, Temp, Fail, Live, Acc) ->
Size = {bs_utf16_size,Fail,Src,Temp},
Add = {bs_add,Fail,[Target,Temp,B],Target},
cg_gen_binsize(T, Target, Temp, Fail, Live,
[Add,Size|Acc]);
cg_gen_binsize([{'*',A,B}|T], Target, Temp, Fail, Live, Acc) ->
cg_gen_binsize(T, Target, Temp, Fail, Live,
[{bs_add,Fail,[Target,A,B],Target}|Acc]);
cg_gen_binsize([{bit_size,B}|T], Target, Temp, Fail, Live, Acc) ->
cg_gen_binsize([Temp|T], Target, Temp, Fail, Live,
[{gc_bif,bit_size,Fail,Live,[B],Temp}|Acc]);
cg_gen_binsize([{byte_size,B}|T], Target, Temp, Fail, Live, Acc) ->
cg_gen_binsize([Temp|T], Target, Temp, Fail, Live,
[{gc_bif,byte_size,Fail,Live,[B],Temp}|Acc]);
cg_gen_binsize([{bs_utf8_size,B}|T], Target, Temp, Fail, Live, Acc) ->
cg_gen_binsize([Temp|T], Target, Temp, Fail, Live,
[{bs_utf8_size,Fail,B,Temp}|Acc]);
cg_gen_binsize([{bs_utf16_size,B}|T], Target, Temp, Fail, Live, Acc) ->
cg_gen_binsize([Temp|T], Target, Temp, Fail, Live,
[{bs_utf16_size,Fail,B,Temp}|Acc]);
cg_gen_binsize([E0|T], Target, Temp, Fail, Live, Acc) ->
cg_gen_binsize(T, Target, Temp, Fail, Live,
[{bs_add,Fail,[Target,E0,1],Target}|Acc]);
cg_gen_binsize([], _, _, _, _, Acc) -> Acc.
%% cg_bin_opt(Code0) -> Code
%% Optimize the size calculations for binary construction.
cg_bin_opt([{move,Size,D},{bs_append,Fail,D,Extra,Regs,U,Bin,Flags,D}|Is]) ->
cg_bin_opt([{bs_append,Fail,Size,Extra,Regs,U,Bin,Flags,D}|Is]);
cg_bin_opt([{move,Size,D},{bs_private_append,Fail,D,U,Bin,Flags,D}|Is]) ->
cg_bin_opt([{bs_private_append,Fail,Size,U,Bin,Flags,D}|Is]);
cg_bin_opt([{move,{integer,0},D},{bs_add,_,[D,{integer,_}=S,1],Dst}|Is]) ->
cg_bin_opt([{move,S,Dst}|Is]);
cg_bin_opt([{move,{integer,0},D},{bs_add,Fail,[D,S,U],Dst}|Is]) ->
cg_bin_opt([{bs_add,Fail,[{integer,0},S,U],Dst}|Is]);
cg_bin_opt([{move,{integer,Bytes},D},{Op,Fail,D,Extra,Regs,Flags,D}|Is])
when Op =:= bs_init2; Op =:= bs_init_bits ->
cg_bin_opt([{Op,Fail,Bytes,Extra,Regs,Flags,D}|Is]);
cg_bin_opt([{move,Src1,Dst},{bs_add,Fail,[Dst,Src2,U],Dst}|Is]) ->
cg_bin_opt([{bs_add,Fail,[Src1,Src2,U],Dst}|Is]);
cg_bin_opt([I|Is]) ->
[I|cg_bin_opt(Is)];
cg_bin_opt([]) -> [].
cg_bin_put({bin_seg,[],S0,U,T,Fs,[E0,Next]}, Fail, Bef) ->
S1 = cg_reg_arg(S0, Bef),
E1 = cg_reg_arg(E0, Bef),
{Format,Op} = case T of
integer -> {plain,bs_put_integer};
utf8 -> {utf,bs_put_utf8};
utf16 -> {utf,bs_put_utf16};
utf32 -> {utf,bs_put_utf32};
binary -> {plain,bs_put_binary};
float -> {plain,bs_put_float}
end,
case Format of
plain ->
[{Op,Fail,S1,U,{field_flags,Fs},E1}|cg_bin_put(Next, Fail, Bef)];
utf ->
[{Op,Fail,{field_flags,Fs},E1}|cg_bin_put(Next, Fail, Bef)]
end;
cg_bin_put({bin_end,[]}, _, _) -> [].
cg_build_args(As, Bef) ->
[{put,cg_reg_arg(A, Bef)} || A <- As].
%% return_cg([Val], Le, Vdb, Bef, St) -> {[Ainstr],Aft,St}.
%% break_cg([Val], Le, Vdb, Bef, St) -> {[Ainstr],Aft,St}.
%% These are very simple, just put return/break values in registers
%% from 0, then return/break. Use the call setup to clean up stack,
%% but must clear registers to ensure sr_merge works correctly.
return_cg(Rs, Le, Vdb, Bef, St) ->
{Ms,Int} = cg_setup_call(Rs, Bef, Le#l.i, Vdb),
{Ms ++ [return],Int#sr{reg=clear_regs(Int#sr.reg)},St}.
break_cg(Bs, Le, Vdb, Bef, St) ->
{Ms,Int} = cg_setup_call(Bs, Bef, Le#l.i, Vdb),
{Ms ++ [{jump,{f,St#cg.break}}],
Int#sr{reg=clear_regs(Int#sr.reg)},St}.
guard_break_cg(Bs, Locked, #l{i=I}, Vdb, #sr{reg=Reg0}=Bef, St) ->
RegLocked = get_locked_regs(Reg0, Locked),
#sr{reg=Reg1} = Int = clear_dead(Bef#sr{reg=RegLocked}, I, Vdb),
Reg2 = trim_free(Reg1),
NumLocked = length(Reg2),
Moves0 = gen_moves(Bs, Bef, NumLocked, []),
Moves = order_moves(Moves0, find_scratch_reg(RegLocked)),
{BreakVars,_} = mapfoldl(fun(_, RegNum) ->
{{RegNum,gbreakvar},RegNum+1}
end, length(Reg2), Bs),
Reg = Reg2 ++ BreakVars,
Aft = Int#sr{reg=Reg},
{Moves ++ [{jump,{f,St#cg.break}}],Aft,St}.
get_locked_regs([R|Rs0], Preserve) ->
case {get_locked_regs(Rs0, Preserve),R} of
{[],{_,V}} ->
case lists:member(V, Preserve) of
true -> [R];
false -> []
end;
{[],_} ->
[];
{Rs,_} ->
[R|Rs]
end;
get_locked_regs([], _) -> [].
%% cg_reg_arg(Arg0, Info) -> Arg
%% cg_reg_args([Arg0], Info) -> [Arg]
%% Convert argument[s] into registers. Literal values are returned unchanged.
cg_reg_args(As, Bef) -> [cg_reg_arg(A, Bef) || A <- As].
cg_reg_arg({var,V}, Bef) -> fetch_var(V, Bef);
cg_reg_arg(Literal, _) -> Literal.
%% cg_setup_call([Arg], Bef, Cur, Vdb) -> {[Instr],Aft}.
%% Do the complete setup for a call/enter.
cg_setup_call(As, Bef, I, Vdb) ->
{Ms,Int0} = cg_call_args(As, Bef, I, Vdb),
%% Have set up arguments, can now clean up, compress and save to stack.
Int1 = Int0#sr{stk=clear_dead_stk(Int0#sr.stk, I, Vdb),res=[]},
{Sis,Int2} = adjust_stack(Int1, I, I+1, Vdb),
{Ms ++ Sis,Int2}.
%% cg_call_args([Arg], SrState) -> {[Instr],SrState}.
%% Setup the arguments to a call/enter/bif. Put the arguments into
%% consecutive registers starting at {x,0} moving any data which
%% needs to be saved. Return a modified SrState structure with the
%% new register contents. N.B. the resultant register info will
%% contain non-variable values when there are non-variable values.
%%
%% This routine is complicated by unsaved values in x registers.
%% We'll move away any unsaved values that are in the registers
%% to be overwritten by the arguments.
cg_call_args(As, Bef, I, Vdb) ->
Regs0 = load_arg_regs(Bef#sr.reg, As),
Unsaved = unsaved_registers(Regs0, Bef#sr.stk, I, I+1, Vdb),
{UnsavedMoves,Regs} = move_unsaved(Unsaved, Bef#sr.reg, Regs0),
Moves0 = gen_moves(As, Bef),
Moves = order_moves(Moves0, find_scratch_reg(Regs)),
{UnsavedMoves ++ Moves,Bef#sr{reg=Regs}}.
%% load_arg_regs([Reg], Arguments) -> [Reg]
%% Update the register descriptor to include the arguments (from {x,0}
%% and upwards). Values in argument register are overwritten.
%% Values in x registers above the arguments are preserved.
load_arg_regs(Regs, As) -> load_arg_regs(Regs, As, 0).
load_arg_regs([_|Rs], [{var,V}|As], I) -> [{I,V}|load_arg_regs(Rs, As, I+1)];
load_arg_regs([_|Rs], [A|As], I) -> [{I,A}|load_arg_regs(Rs, As, I+1)];
load_arg_regs([], [{var,V}|As], I) -> [{I,V}|load_arg_regs([], As, I+1)];
load_arg_regs([], [A|As], I) -> [{I,A}|load_arg_regs([], As, I+1)];
load_arg_regs(Rs, [], _) -> Rs.
%% Returns the variables must be saved and are currently in the
%% x registers that are about to be overwritten by the arguments.
unsaved_registers(Regs, Stk, Fb, Lf, Vdb) ->
[V || {V,F,L} <- Vdb,
F < Fb,
L >= Lf,
not on_stack(V, Stk),
not in_reg(V, Regs)].
in_reg(V, Regs) -> keymember(V, 2, Regs).
%% Move away unsaved variables from the registers that are to be
%% overwritten by the arguments.
move_unsaved(Vs, OrigRegs, NewRegs) ->
move_unsaved(Vs, OrigRegs, NewRegs, []).
move_unsaved([V|Vs], OrigRegs, NewRegs0, Acc) ->
NewRegs = put_reg(V, NewRegs0),
Src = fetch_reg(V, OrigRegs),
Dst = fetch_reg(V, NewRegs),
move_unsaved(Vs, OrigRegs, NewRegs, [{move,Src,Dst}|Acc]);
move_unsaved([], _, Regs, Acc) -> {Acc,Regs}.
%% gen_moves(As, Sr)
%% Generate the basic move instruction to move the arguments
%% to their proper registers. The list will be sorted on
%% destinations. (I.e. the move to {x,0} will be first --
%% see the comment to order_moves/2.)
gen_moves(As, Sr) -> gen_moves(As, Sr, 0, []).
gen_moves([{var,V}|As], Sr, I, Acc) ->
case fetch_var(V, Sr) of
{x,I} -> gen_moves(As, Sr, I+1, Acc);
Reg -> gen_moves(As, Sr, I+1, [{move,Reg,{x,I}}|Acc])
end;
gen_moves([A|As], Sr, I, Acc) ->
gen_moves(As, Sr, I+1, [{move,A,{x,I}}|Acc]);
gen_moves([], _, _, Acc) -> lists:keysort(3, Acc).
%% order_moves([Move], ScratchReg) -> [Move]
%% Orders move instruction so that source registers are not
%% destroyed before they are used. If there are cycles
%% (such as {move,{x,0},{x,1}}, {move,{x,1},{x,1}}),
%% the scratch register is used to break up the cycle.
%% If possible, the first move of the input list is placed
%% last in the result list (to make the move to {x,0} occur
%% just before the call to allow the Beam loader to coalesce
%% the instructions).
order_moves(Ms, Scr) -> order_moves(Ms, Scr, []).
order_moves([{move,_,_}=M|Ms0], ScrReg, Acc0) ->
{Chain,Ms} = collect_chain(Ms0, [M], ScrReg),
Acc = reverse(Chain, Acc0),
order_moves(Ms, ScrReg, Acc);
order_moves([], _, Acc) -> Acc.
collect_chain(Ms, Path, ScrReg) ->
collect_chain(Ms, Path, [], ScrReg).
collect_chain([{move,Src,Same}=M|Ms0], [{move,Same,_}|_]=Path, Others, ScrReg) ->
case lists:keyfind(Src, 3, Path) of
false ->
collect_chain(reverse(Others, Ms0), [M|Path], [], ScrReg);
_ -> % We have a cycle.
{break_up_cycle(M, Path, ScrReg),reverse(Others, Ms0)}
end;
collect_chain([M|Ms], Path, Others, ScrReg) ->
collect_chain(Ms, Path, [M|Others], ScrReg);
collect_chain([], Path, Others, _) ->
{Path,Others}.
break_up_cycle({move,Src,_}=M, Path, ScrReg) ->
[{move,ScrReg,Src},M|break_up_cycle1(Src, Path, ScrReg)].
break_up_cycle1(Dst, [{move,Src,Dst}|Path], ScrReg) ->
[{move,Src,ScrReg}|Path];
break_up_cycle1(Dst, [M|Path], LastMove) ->
[M|break_up_cycle1(Dst, Path, LastMove)].
%% clear_dead(Sr, Until, Vdb) -> Aft.
%% Remove all variables in Sr which have died AT ALL so far.
clear_dead(Sr, Until, Vdb) ->
Sr#sr{reg=clear_dead_reg(Sr, Until, Vdb),
stk=clear_dead_stk(Sr#sr.stk, Until, Vdb)}.
clear_dead_reg(Sr, Until, Vdb) ->
Reg = map(fun ({_I,V} = IV) ->
case vdb_find(V, Vdb) of
{V,_,L} when L > Until -> IV;
_ -> free %Remove anything else
end;
({reserved,_I,_V} = Reserved) -> Reserved;
(free) -> free
end, Sr#sr.reg),
reserve(Sr#sr.res, Reg, Sr#sr.stk).
clear_dead_stk(Stk, Until, Vdb) ->
map(fun ({V} = T) ->
case vdb_find(V, Vdb) of
{V,_,L} when L > Until -> T;
_ -> dead %Remove anything else
end;
(free) -> free;
(dead) -> dead
end, Stk).
%% sr_merge(Sr1, Sr2) -> Sr.
%% Merge two stack/register states keeping the longest of both stack
%% and register. Perform consistency check on both, elements must be
%% the same. Allow frame size 'void' to make easy creation of
%% "empty" frame.
sr_merge(#sr{reg=R1,stk=S1,res=[]}, #sr{reg=R2,stk=S2,res=[]}) ->
#sr{reg=longest(R1, R2),stk=longest(S1, S2),res=[]};
sr_merge(void, S2) -> S2#sr{res=[]}.
longest([H|T1], [H|T2]) -> [H|longest(T1, T2)];
longest([dead|T1], [free|T2]) -> [dead|longest(T1, T2)];
longest([free|T1], [dead|T2]) -> [dead|longest(T1, T2)];
longest([dead|_] = L, []) -> L;
longest([], [dead|_] = L) -> L;
longest([free|_] = L, []) -> L;
longest([], [free|_] = L) -> L;
longest([], []) -> [].
trim_free([R|Rs0]) ->
case {trim_free(Rs0),R} of
{[],free} -> [];
{Rs,R} -> [R|Rs]
end;
trim_free([]) -> [].
%% adjust_stack(Bef, FirstBefore, LastFrom, Vdb) -> {[Ainstr],Aft}.
%% Do complete stack adjustment by compressing stack and adding
%% variables to be saved. Try to optimise ordering on stack by
%% having reverse order to their lifetimes.
%%
%% In Beam, there is a fixed stack frame and no need to do stack compression.
adjust_stack(Bef, Fb, Lf, Vdb) ->
Stk0 = Bef#sr.stk,
{Stk1,Saves} = save_stack(Stk0, Fb, Lf, Vdb),
{saves(Saves, Bef#sr.reg, Stk1),
Bef#sr{stk=Stk1}}.
%% save_stack(Stack, FirstBefore, LastFrom, Vdb) -> {[SaveVar],NewStack}.
%% Save variables which are used past current point and which are not
%% already on the stack.
save_stack(Stk0, Fb, Lf, Vdb) ->
%% New variables that are in use but not on stack.
New = [VFL || {V,F,L} = VFL <- Vdb,
F < Fb,
L >= Lf,
not on_stack(V, Stk0)],
%% Add new variables that are not just dropped immediately.
%% N.B. foldr works backwards from the end!!
Saves = [V || {V,_,_} <- keysort(3, New)],
Stk1 = foldr(fun (V, Stk) -> put_stack(V, Stk) end, Stk0, Saves),
{Stk1,Saves}.
%% saves([SaveVar], Reg, Stk) -> [{move,Reg,Stk}].
%% Generate move instructions to save variables onto stack. The
%% stack/reg info used is that after the new stack has been made.
saves(Ss, Reg, Stk) ->
[{move,fetch_reg(V, Reg),fetch_stack(V, Stk)} || V <- Ss].
%% fetch_var(VarName, StkReg) -> r{R} | sp{Sp}.
%% find_var(VarName, StkReg) -> ok{r{R} | sp{Sp}} | error.
%% Fetch/find a variable in either the registers or on the
%% stack. Fetch KNOWS it's there.
fetch_var(V, Sr) ->
case find_reg(V, Sr#sr.reg) of
{ok,R} -> R;
error -> fetch_stack(V, Sr#sr.stk)
end.
load_vars(Vs, Regs) ->
foldl(fun ({var,V}, Rs) -> put_reg(V, Rs) end, Regs, Vs).
%% put_reg(Val, Regs) -> Regs.
%% find_reg(Val, Regs) -> ok{r{R}} | error.
%% fetch_reg(Val, Regs) -> r{R}.
%% Functions to interface the registers.
% put_regs(Vs, Rs) -> foldl(fun put_reg/2, Rs, Vs).
put_reg(V, Rs) -> put_reg_1(V, Rs, 0).
put_reg_1(V, [free|Rs], I) -> [{I,V}|Rs];
put_reg_1(V, [{reserved,I,V}|Rs], I) -> [{I,V}|Rs];
put_reg_1(V, [R|Rs], I) -> [R|put_reg_1(V, Rs, I+1)];
put_reg_1(V, [], I) -> [{I,V}].
fetch_reg(V, [{I,V}|_]) -> {x,I};
fetch_reg(V, [_|SRs]) -> fetch_reg(V, SRs).
find_reg(V, [{I,V}|_]) -> {ok,{x,I}};
find_reg(V, [_|SRs]) -> find_reg(V, SRs);
find_reg(_, []) -> error.
%% For the bit syntax, we need a scratch register if we are constructing
%% a binary that will not be used.
find_scratch_reg(Rs) -> find_scratch_reg(Rs, 0).
find_scratch_reg([free|_], I) -> {x,I};
find_scratch_reg([_|Rs], I) -> find_scratch_reg(Rs, I+1);
find_scratch_reg([], I) -> {x,I}.
replace_reg_contents(Old, New, [{I,Old}|Rs]) -> [{I,New}|Rs];
replace_reg_contents(Old, New, [R|Rs]) -> [R|replace_reg_contents(Old, New, Rs)].
%%clear_regs(Regs) -> map(fun (R) -> free end, Regs).
clear_regs(_) -> [].
max_reg(Regs) ->
foldl(fun ({I,_}, _) -> I;
(_, Max) -> Max end,
-1, Regs) + 1.
%% put_stack(Val, [{Val}]) -> [{Val}].
%% fetch_stack(Var, Stk) -> sp{S}.
%% find_stack(Var, Stk) -> ok{sp{S}} | error.
%% Functions to interface the stack.
put_stack(Val, []) -> [{Val}];
put_stack(Val, [dead|Stk]) -> [{Val}|Stk];
put_stack(Val, [free|Stk]) -> [{Val}|Stk];
put_stack(Val, [NotFree|Stk]) -> [NotFree|put_stack(Val, Stk)].
put_stack_carefully(Val, Stk0) ->
case catch put_stack_carefully1(Val, Stk0) of
error -> error;
Stk1 when is_list(Stk1) -> Stk1
end.
put_stack_carefully1(_, []) -> throw(error);
put_stack_carefully1(Val, [dead|Stk]) -> [{Val}|Stk];
put_stack_carefully1(Val, [free|Stk]) -> [{Val}|Stk];
put_stack_carefully1(Val, [NotFree|Stk]) ->
[NotFree|put_stack_carefully1(Val, Stk)].
fetch_stack(Var, Stk) -> fetch_stack(Var, Stk, 0).
fetch_stack(V, [{V}|_], I) -> {yy,I};
fetch_stack(V, [_|Stk], I) -> fetch_stack(V, Stk, I+1).
% find_stack(Var, Stk) -> find_stack(Var, Stk, 0).
% find_stack(V, [{V}|Stk], I) -> {ok,{yy,I}};
% find_stack(V, [O|Stk], I) -> find_stack(V, Stk, I+1);
% find_stack(V, [], I) -> error.
on_stack(V, Stk) -> keymember(V, 1, Stk).
is_register({x,_}) -> true;
is_register({yy,_}) -> true;
is_register(_) -> false.
%% put_catch(CatchTag, Stack) -> Stack'
%% drop_catch(CatchTag, Stack) -> Stack'
%% Special interface for putting and removing catch tags, to ensure that
%% catches nest properly. Also used for try tags.
put_catch(Tag, Stk0) -> put_catch(Tag, reverse(Stk0), []).
put_catch(Tag, [], Stk) ->
put_stack({catch_tag,Tag}, Stk);
put_catch(Tag, [{{catch_tag,_}}|_]=RevStk, Stk) ->
reverse(RevStk, put_stack({catch_tag,Tag}, Stk));
put_catch(Tag, [Other|Stk], Acc) ->
put_catch(Tag, Stk, [Other|Acc]).
drop_catch(Tag, [{{catch_tag,Tag}}|Stk]) -> [free|Stk];
drop_catch(Tag, [Other|Stk]) -> [Other|drop_catch(Tag, Stk)].
%% new_label(St) -> {L,St}.
new_label(#cg{lcount=Next}=St) ->
{Next,St#cg{lcount=Next+1}}.
%% line(Le) -> {line,[] | {location,File,Line}}
%% Create a line instruction, containing information about
%% the current filename and line number. A line information
%% instruction should be placed before any operation that could
%% cause an exception.
line(#l{a=Anno}) ->
line(Anno);
line([Line,{file,Name}]) when is_integer(Line) ->
line_1(Name, Line);
line([_|_]=A) ->
{Name,Line} = find_loc(A, no_file, 0),
line_1(Name, Line);
line([]) ->
{line,[]}.
line_1(no_file, _) ->
{line,[]};
line_1(_, 0) ->
%% Missing line number or line number 0.
{line,[]};
line_1(Name, Line) ->
{line,[{location,Name,Line}]}.
find_loc([Line|T], File, _) when is_integer(Line) ->
find_loc(T, File, Line);
find_loc([{file,File}|T], _, Line) ->
find_loc(T, File, Line);
find_loc([_|T], File, Line) ->
find_loc(T, File, Line);
find_loc([], File, Line) -> {File,Line}.
flatmapfoldl(F, Accu0, [Hd|Tail]) ->
{R,Accu1} = F(Hd, Accu0),
{Rs,Accu2} = flatmapfoldl(F, Accu1, Tail),
{R++Rs,Accu2};
flatmapfoldl(_, Accu, []) -> {[],Accu}.
|