binutils-gdb/gdb/testsuite/gdb.arch/mips-fpregset-core.c
Maciej W. Rozycki d8dab6c3bb MIPS/Linux: Correct o32 core file FGR interpretation
Our interpretation of the layout of floating-point general registers
(FGRs) in o32 MIPS/Linux core files is different from how the kernel
makes them, affecting the CP0 Status.FR=0 aka FP32 mode (we don't
currently support the CP0 Status.FR=1 aka FP64 mode with the o32 ABI).

In the FP32 mode pairs of consecutive even/odd-numbered 32-bit registers
are placed together as 64-bit values in even-indexed 64-bit slots
corresponding to the even index, leaving the odd-indexed 64-bit slots
unused.  These 64-bit values are stored according to the endianness in
effect, which is how the MIPS II SDC1 instruction would store them.

It has always been like that with the Linux kernel for MIPS II and
higher ISA processors, which are the vast majority ever supported, as it
is indeed SDC1 that the kernel uses to store FGRs in a floating-point
context.

With MIPS I processors, which lack the SDC1 instruction, a layout that
we expect used to be used long ago, but it was corrected for consistency
with newer processors back in 2002, with `linux-mips.org' (LMO) commit
42533948caac ("Major pile of FP emulator changes."), the fix corrected
with LMO commit 849fa7a50dff ("R3k FPU ptrace() handling fixes."), and
then broken and fixed over and over again, until last time fixed with
commit 80cbfad79096 ("MIPS: Correct MIPS I FP context layout").

Consequently the values we see in FP32 core files or produce with the
`gcore' command are different from those obtained from the same FP
context of a live process, e.g. with a big-endian configuration these
live values:

(gdb) info registers float
f0:  0x4b5c6d7e flt: 14445950          dbl: 1.7446153562345001e-274
f1:  0x0718293a flt: 1.14473244e-34
f2:  0xc3d4e5f6 flt: -425.79657        dbl: -1.046160437414959e-233
f3:  0x8f90a1b2 flt: -1.42617791e-29
f4:  0x4c5d6e7f flt: 58046972          dbl: 1.1908587841220294e-269
f5:  0x08192a3b flt: 4.60914044e-34
f6:  0xc4d5e6f7 flt: -1711.21765       dbl: -6.2784661835068965e-306
f7:  0x8091a2b3 flt: -1.33745124e-38
f8:  0x45566778 flt: 3430.4668         dbl: 1.6530355595710607e-303
f9:  0x01122334 flt: 2.68412219e-38
f10: 0xcddeeff0 flt: -467533312        dbl: -2.1174864564135575e-262
f11: 0x899aabbc flt: -3.72356497e-33
f12: 0x46576879 flt: 13786.1182        dbl: 1.143296486773654e-298
f13: 0x02132435 flt: 1.08102453e-37
f14: 0xcedfe0f1 flt: -1.87803046e+09   dbl: -1.4399511533369862e-257
f15: 0x8a9bacbd flt: -1.4990934e-32
f16: 0x4758697a flt: 55401.4766        dbl: 7.8856820439568725e-294
f17: 0x03142536 flt: 4.3536007e-37
f18: 0xcfd0e1f2 flt: -7.00893696e+09   dbl: -9.7791926757340559e-253
f19: 0x8b9cadbe flt: -6.03504325e-32
f20: 0x48596a7b flt: 222633.922        dbl: 5.4255001483306113e-289
f21: 0x04152637 flt: 1.75324132e-36
f22: 0xc0d1e2f3 flt: -6.55895376       dbl: -6.6332401002310683e-248
f23: 0x8c9daebf flt: -2.42948516e-31
f24: 0x495a6b7c flt: 894647.75         dbl: 3.7244369058749787e-284
f25: 0x05162738 flt: 7.06016945e-36
f26: 0xc1d2e3f4 flt: -26.3613052       dbl: -4.4941535759306202e-243
f27: 0x8d9eafb0 flt: -9.77979703e-31
f28: 0x4a5b6c7d flt: 3595039.25        dbl: 2.5514593711161396e-279
f29: 0x06172839 flt: 2.84294945e-35
f30: 0xc2d3e4f5 flt: -105.947182       dbl: -3.035646690850097e-238
f31: 0x8e9fa0b1 flt: -3.93512664e-30
fcsr: 0x0
fir: 0xf30000
(gdb)

show up in a core file as these:

(gdb) info registers float
f0:  0x0718293a flt: 1.14473244e-34    dbl: nan
f1:  0x7ff80000 flt: nan
f2:  0x8f90a1b2 flt: -1.42617791e-29   dbl: nan
f3:  0x7ff80000 flt: nan
f4:  0x08192a3b flt: 4.60914044e-34    dbl: nan
f5:  0x7ff80000 flt: nan
f6:  0x8091a2b3 flt: -1.33745124e-38   dbl: nan
f7:  0x7ff80000 flt: nan
f8:  0x01122334 flt: 2.68412219e-38    dbl: nan
f9:  0x7ff80000 flt: nan
f10: 0x899aabbc flt: -3.72356497e-33   dbl: nan
f11: 0x7ff80000 flt: nan
f12: 0x02132435 flt: 1.08102453e-37    dbl: nan
f13: 0x7ff80000 flt: nan
f14: 0x8a9bacbd flt: -1.4990934e-32    dbl: nan
f15: 0x7ff80000 flt: nan
f16: 0x03142536 flt: 4.3536007e-37     dbl: nan
f17: 0x7ff80000 flt: nan
f18: 0x8b9cadbe flt: -6.03504325e-32   dbl: nan
f19: 0x7ff80000 flt: nan
f20: 0x04152637 flt: 1.75324132e-36    dbl: nan
f21: 0x7ff80000 flt: nan
f22: 0x8c9daebf flt: -2.42948516e-31   dbl: nan
f23: 0x7ff80000 flt: nan
f24: 0x05162738 flt: 7.06016945e-36    dbl: nan
f25: 0x7ff80000 flt: nan
f26: 0x8d9eafb0 flt: -9.77979703e-31   dbl: nan
f27: 0x7ff80000 flt: nan
f28: 0x06172839 flt: 2.84294945e-35    dbl: nan
f29: 0x7ff80000 flt: nan
f30: 0x8e9fa0b1 flt: -3.93512664e-30   dbl: nan
f31: 0x7ff80000 flt: nan
(gdb)

Notice how values from odd-numbered registers are shown in corresponding
even-numbered registers and how dummy 0x7ff80000 NaN values, which the
kernel places in unused slots, are reported in odd-numbered registers.

Correct our intepretation then, to match the kernel's.  As it happens
the o32 FGR core file representation matches that used by the `ptrace'
PTRACE_GETFPREGS request, which means our 64-bit handlers can be readily
used, as they already correctly handle the differences between o32 FP32
mode vs n32/n64 representations.

Adjust comments accordingly throughout, in particular remove a reference
to the r3000/tx39 MIPS I processor peculiarity, long irrelevant.

Add a test case to verify correctness.  Avoid GCC bugs and limitations
in the test case where possible; the test case still fails to build with
GCC 8 and the o32 FP64 mode (i.e. with `-mips32r2 -mfp64' options)
giving:

mips-fpregset-core.c: In function 'main':
mips-fpregset-core.c:66:3: error: inconsistent operand constraints in an 'asm'
   asm (
   ^~~

(GCC PR target/85909), but that is not a concern for us as yet, because
as noted above we do not currently support the o32 FP64 mode anyway.

	gdb/
	* mips-linux-tdep.h (mips_supply_fpregset, mips_fill_fpregset):
	Remove prototypes.
	* mips-linux-nat.c (supply_fpregset): Always call
	`mips64_supply_fpregset' rather than `mips_supply_fpregset'.
	(fill_fpregset): Always call `mips64_fill_fpregset' rather than
	`mips_fill_fpregset'.
	* mips-linux-tdep.c (mips_supply_fpregset)
	(mips_supply_fpregset_wrapper, mips_fill_fpregset)
	(mips_fill_fpregset_wrapper): Remove functions.
	(mips64_supply_fpregset, mips64_fill_fpregset): Update comments.
	(mips_linux_fpregset): Remove variable.
	(mips_linux_iterate_over_regset_sections): Use
	`mips64_linux_fpregset' in place of `mips_linux_fpregset'.
	(mips_linux_o32_sigframe_init): Remove comment.

	gdb/testsuite/
	* gdb.arch/mips-fpregset-core.exp: New test.
	* gdb.arch/mips-fpregset-core.c: New test source.
2018-05-25 12:37:45 +01:00

83 lines
2.5 KiB
C

/* This test is part of GDB, the GNU debugger.
Copyright 2018 Free Software Foundation, Inc.
This program is free software; you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation; either version 3 of the License, or
(at your option) any later version.
This program is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with this program. If not, see <http://www.gnu.org/licenses/>. */
#include <stdint.h>
int __attribute__ ((nomips16))
main (void)
{
/* We need to use a complex type to avoid hitting GCC's limit of
the number of `asm' operands:
mips-fpregset-core.f: In function 'main':
mips-fpregset-core.f:66:3: error: more than 30 operands in 'asm'
asm (
^~~
and still have complete 32 FGR coverage with FP64 ABIs. Using
a complex type breaks o32 GCC though, so use plain `double' with
FP32. */
#if _MIPS_FPSET == 32
typedef double _Complex float_t;
#else
typedef double float_t;
#endif
union
{
uint64_t i[32];
float_t f[256 / sizeof (float_t)];
}
u =
{ .i =
{
0x0112233445566778, 0x899aabbccddeeff0,
0x0213243546576879, 0x8a9bacbdcedfe0f1,
0x031425364758697a, 0x8b9cadbecfd0e1f2,
0x0415263748596a7b, 0x8c9daebfc0d1e2f3,
0x05162738495a6b7c, 0x8d9eafb0c1d2e3f4,
0x061728394a5b6c7d, 0x8e9fa0b1c2d3e4f5,
0x0718293a4b5c6d7e, 0x8f90a1b2c3d4e5f6,
0x08192a3b4c5d6e7f, 0x8091a2b3c4d5e6f7,
0x091a2b3c4d5e6f70, 0x8192a3b4c5d6e7f8,
0x0a1b2c3d4e5f6071, 0x8293a4b5c6d7e8f9,
0x0b1c2d3e4f506172, 0x8394a5b6c7d8e9fa,
0x0c1d2e3f40516273, 0x8495a6b7c8d9eafb,
0x0d1e2f3041526374, 0x8596a7b8c9daebfc,
0x0e1f203142536475, 0x8697a8b9cadbecfd,
0x0f10213243546576, 0x8798a9bacbdcedfe,
0x0011223344556677, 0x8899aabbccddeeff
}
};
asm (
".globl\tbreak_here\n\t"
".aent\tbreak_here\n"
"break_here:\n\t"
"lb\t$0,0($0)\n"
:
: [f0] "f" (u.f[0]), [f2] "f" (u.f[1]),
[f4] "f" (u.f[2]), [f6] "f" (u.f[3]),
[f8] "f" (u.f[4]), [f10] "f" (u.f[5]),
[f12] "f" (u.f[6]), [f14] "f" (u.f[7]),
[f16] "f" (u.f[8]), [f18] "f" (u.f[9]),
[f20] "f" (u.f[10]), [f22] "f" (u.f[11]),
[f24] "f" (u.f[12]), [f26] "f" (u.f[13]),
[f28] "f" (u.f[14]), [f30] "f" (u.f[15]));
return 0;
}