/netbsd-current/external/gpl3/gdb.old/dist/gdb/testsuite/gdb.compile/ |
H A D | compile-cplus-array-decay.cc | 21 int integers[10]; local 24 for (auto &i : integers)
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/netbsd-current/external/gpl3/gdb/dist/gdb/testsuite/gdb.compile/ |
H A D | compile-cplus-array-decay.cc | 21 int integers[10]; local 24 for (auto &i : integers)
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/netbsd-current/external/gpl3/gdb/dist/gdb/testsuite/gdb.go/ |
H A D | chan.go | 16 integers := generate() 17 for i := 0; i < 100; i++ { // Print the first hundred integers. 18 fmt.Println(<-integers) // set breakpoint 2 here
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/netbsd-current/tests/usr.bin/indent/ |
H A D | lex_number.c | 8 int integers[] = { variable
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/netbsd-current/external/mpl/bind/dist/bin/tests/system/wildcard/ |
H A D | tests_wildcard.py | 44 from hypothesis.strategies import binary, integers namespace 80 rdtype=integers(min_value=0, max_value=65535).filter(is_nonexpanding_rdtype),
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/netbsd-current/external/gpl3/gdb.old/dist/gdb/testsuite/gdb.pascal/ |
H A D | integers.pas | 18 program integers;
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/netbsd-current/external/gpl3/gdb/dist/gdb/testsuite/gdb.pascal/ |
H A D | integers.pas | 18 program integers;
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/netbsd-current/crypto/external/bsd/heimdal/dist/lib/asn1/ |
H A D | check-gen.c | 1431 TESTInteger integers[4] = { 1, 2, 3, 4 }; 1435 TESTSeqSizeOf1 ssof1f1 = { 1, integers }; 1436 TESTSeqSizeOf1 ssof1ok1 = { 2, integers }; 1437 TESTSeqSizeOf1 ssof1f2 = { 3, integers }; 1445 TESTSeqSizeOf2 ssof2ok1 = { 1, integers }; 1446 TESTSeqSizeOf2 ssof2ok2 = { 2, integers }; 1447 TESTSeqSizeOf2 ssof2f2 = { 3, integers }; 1456 TESTSeqSizeOf3 ssof3ok1 = { 1, integers }; 1457 TESTSeqSizeOf3 ssof3ok2 = { 2, integers }; 1465 TESTSeqSizeOf4 ssof4ok2 = { 1, integers }; [all...] |
/netbsd-current/usr.bin/make/unit-tests/ |
H A D | varmod-order-numeric.mk | 14 # To get 53-bit integers even in C90, it would be possible to switch to
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H A D | cond-cmp-numeric-eq.mk | 52 # Because an IEEE 754 double can only hold integers with a mantissa of 53
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/netbsd-current/external/gpl3/gcc.old/dist/libgcc/config/microblaze/ |
H A D | mulsi3.S | 28 # Multiply operation for 32 bit integers.
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H A D | muldi3_hard.S | 28 # Multiply operation for 64 bit integers, for devices with hard multiply
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H A D | umodsi3.S | 28 # Unsigned modulo operation for 32 bit integers.
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H A D | modsi3.S | 28 # modulo operation for 32 bit integers.
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H A D | divsi3.S | 28 # Divide operation for 32 bit integers.
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H A D | moddi3.S | 28 # modulo operation for 64 bit integers.
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/netbsd-current/external/gpl3/gcc/dist/libgcc/config/microblaze/ |
H A D | muldi3_hard.S | 28 # Multiply operation for 64 bit integers, for devices with hard multiply
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H A D | mulsi3.S | 28 # Multiply operation for 32 bit integers.
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H A D | modsi3.S | 28 # modulo operation for 32 bit integers.
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H A D | divsi3.S | 28 # Divide operation for 32 bit integers.
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H A D | umodsi3.S | 28 # Unsigned modulo operation for 32 bit integers.
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H A D | moddi3.S | 28 # modulo operation for 64 bit integers.
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/netbsd-current/external/lgpl3/gmp/dist/demos/perl/ |
H A D | GMP.pm | 149 This module provides access to GNU MP arbitrary precision integers, 160 This class provides arbitrary precision integers. A new mpz can be 245 can be an integer, float, string, mpz, mpq or mpf, or a pair of integers or 541 GMP::Mpz will treat constants as mpz's if they're integers, or ordinary 548 GMP::Mpq is similar, treating integers as mpq's and leaving floats to the
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/netbsd-current/external/bsd/ntp/dist/sntp/libevent/test/ |
H A D | regress.c | 2259 ev_uint32_t integers[TEST_MAX_INT] = { local 2271 evtag_encode_int(tmp, integers[i]); 2274 (unsigned)integers[i], newlen - oldlen)); 2275 big_int = integers[i]; 2282 tt_uint_op(integer, ==, integers[i]); 2284 tt_assert((big_int / 1000000000) == integers[i]); 2337 ev_uint32_t integers[TEST_MAX_INT] = { local 2348 evtag_encode_tag(tmp, integers[i]); 2351 (unsigned)integers[i], newlen - oldlen)); 2356 tt_uint_op(integer, ==, integers[ [all...] |
/netbsd-current/external/bsd/libevent/dist/test/ |
H A D | regress.c | 2435 ev_uint32_t integers[TEST_MAX_INT] = { 2447 evtag_encode_int(tmp, integers[i]); 2450 (unsigned)integers[i], newlen - oldlen)); 2451 big_int = integers[i]; 2458 tt_uint_op(integer, ==, integers[i]); 2460 tt_assert((big_int / 1000000000) == integers[i]); 2513 ev_uint32_t integers[TEST_MAX_INT] = { 2524 evtag_encode_tag(tmp, integers[i]); 2527 (unsigned)integers[i], newlen - oldlen)); 2532 tt_uint_op(integer, ==, integers[ [all...] |