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Author	SHA1	Message	Date
Hal Finkel	c58ce4132a	[PowerPC] Improve instruction selection bit-permuting operations (64-bit) This is the second installment of improvements to instruction selection for "bit permutation" instruction sequences. r224318 added logic for instruction selection for 32-bit bit permutation sequences, and this adds lowering for 64-bit sequences. The 64-bit sequences are more complicated than the 32-bit ones because: a) the 64-bit versions of the 32-bit rotate-and-mask instructions work by replicating the lower 32-bits of the value-to-be-rotated into the upper 32 bits -- and integrating this into the cost modeling for the various bit group operations is non-trivial b) unlike the 32-bit instructions in 32-bit mode, the rotate-and-mask instructions cannot, in one instruction, specify the mask starting index, the mask ending index, and the rotation factor. Also, forming arbitrary 64-bit constants is more complicated than in 32-bit mode because the number of instructions necessary is value dependent. Plus, support for 'late masking' was added: it is sometimes more efficient to treat the overall value as if it had no mandatory zero bits when planning the bit-group insertions, and then mask them in at the very end. Unfortunately, as the structure of the bit groups is different in the two cases, the more feasible implementation technique was to generate both instruction sequences, and then pick the shorter one. And finally, we now generate reasonable code for i64 bswap: rldicl 5, 3, 16, 0 rldicl 4, 3, 8, 0 rldicl 6, 3, 24, 0 rldimi 4, 5, 8, 48 rldicl 5, 3, 32, 0 rldimi 4, 6, 16, 40 rldicl 6, 3, 48, 0 rldimi 4, 5, 24, 32 rldicl 5, 3, 56, 0 rldimi 4, 6, 40, 16 rldimi 4, 5, 48, 8 rldimi 4, 3, 56, 0 vs. what we used to produce: li 4, 255 rldicl 5, 3, 24, 40 rldicl 6, 3, 40, 24 rldicl 7, 3, 56, 8 sldi 8, 3, 8 sldi 10, 3, 24 sldi 12, 3, 40 rldicl 0, 3, 8, 56 sldi 9, 4, 32 sldi 11, 4, 40 sldi 4, 4, 48 andi. 5, 5, 65280 andis. 6, 6, 255 andis. 7, 7, 65280 sldi 3, 3, 56 and 8, 8, 9 and 4, 12, 4 and 9, 10, 11 or 6, 7, 6 or 5, 5, 0 or 3, 3, 4 or 7, 9, 8 or 4, 6, 5 or 3, 3, 7 or 3, 3, 4 which is 12 instructions, instead of 25, and seems optimal (at least in terms of code size). llvm-svn: 225056	2015-01-01 02:53:29 +00:00
Hal Finkel	8adf2254ef	[PowerPC] Improve instruction selection bit-permuting operations (32-bit) The PowerPC backend, somewhat embarrassingly, did not generate an optimal-length sequence of instructions for a 32-bit bswap. While adding a pattern for the bswap intrinsic to fix this would not have been terribly difficult, doing so would not have addressed the real problem: we had been generating poor code for many bit-permuting operations (by which I mean things like byte-swap that permute the bits of one or more inputs around in various ways). Here are some initial steps toward solving this deficiency. Bit-permuting operations are represented, at the SDAG level, using ISD::ROTL, SHL, SRL, AND and OR (mostly with constant second operands). Looking back through these operations, we can build up a description of the bits in the resulting value in terms of bits of one or more input values (and constant zeros). For each bit, we compute the rotation amount from the original value, and then group consecutive (value, rotation factor) bits into groups. Groups sharing these attributes are then collected and sorted, and we can then instruction select the entire permutation using a combination of masked rotations (rlwinm), imm ands (andi/andis), and masked rotation inserts (rlwimi). The result is that instead of lowering an i32 bswap as: rlwinm 5, 3, 24, 16, 23 rlwinm 4, 3, 24, 0, 7 rlwimi 4, 3, 8, 8, 15 rlwimi 5, 3, 8, 24, 31 rlwimi 4, 5, 0, 16, 31 we now produce: rlwinm 4, 3, 8, 0, 31 rlwimi 4, 3, 24, 16, 23 rlwimi 4, 3, 24, 0, 7 and for the 'test6' example in the PowerPC/README.txt file: unsigned test6(unsigned x) { return ((x & 0x00FF0000) >> 16) \| ((x & 0x000000FF) << 16); } we used to produce: lis 4, 255 rlwinm 3, 3, 16, 0, 31 ori 4, 4, 255 and 3, 3, 4 and now we produce: rlwinm 4, 3, 16, 24, 31 rlwimi 4, 3, 16, 8, 15 and, as a nice bonus, this fixes the FIXME in test/CodeGen/PowerPC/rlwimi-and.ll. This commit does not include instruction-selection for i64 operations, those will come later. llvm-svn: 224318	2014-12-16 05:51:41 +00:00

Author

SHA1

Message

Date

Hal Finkel

c58ce4132a

[PowerPC] Improve instruction selection bit-permuting operations (64-bit)

This is the second installment of improvements to instruction selection for "bit
permutation" instruction sequences. r224318 added logic for instruction
selection for 32-bit bit permutation sequences, and this adds lowering for
64-bit sequences. The 64-bit sequences are more complicated than the 32-bit
ones because:
  a) the 64-bit versions of the 32-bit rotate-and-mask instructions
     work by replicating the lower 32-bits of the value-to-be-rotated into the
     upper 32 bits -- and integrating this into the cost modeling for the various
     bit group operations is non-trivial
  b) unlike the 32-bit instructions in 32-bit mode, the rotate-and-mask instructions
     cannot, in one instruction, specify the
     mask starting index, the mask ending index, and the rotation factor. Also,
     forming arbitrary 64-bit constants is more complicated than in 32-bit mode
     because the number of instructions necessary is value dependent.

Plus, support for 'late masking' was added: it is sometimes more efficient to
treat the overall value as if it had no mandatory zero bits when planning the
bit-group insertions, and then mask them in at the very end. Unfortunately, as
the structure of the bit groups is different in the two cases, the more
feasible implementation technique was to generate both instruction sequences,
and then pick the shorter one.

And finally, we now generate reasonable code for i64 bswap:

        rldicl 5, 3, 16, 0
        rldicl 4, 3, 8, 0
        rldicl 6, 3, 24, 0
        rldimi 4, 5, 8, 48
        rldicl 5, 3, 32, 0
        rldimi 4, 6, 16, 40
        rldicl 6, 3, 48, 0
        rldimi 4, 5, 24, 32
        rldicl 5, 3, 56, 0
        rldimi 4, 6, 40, 16
        rldimi 4, 5, 48, 8
        rldimi 4, 3, 56, 0

vs. what we used to produce:

        li 4, 255
        rldicl 5, 3, 24, 40
        rldicl 6, 3, 40, 24
        rldicl 7, 3, 56, 8
        sldi 8, 3, 8
        sldi 10, 3, 24
        sldi 12, 3, 40
        rldicl 0, 3, 8, 56
        sldi 9, 4, 32
        sldi 11, 4, 40
        sldi 4, 4, 48
        andi. 5, 5, 65280
        andis. 6, 6, 255
        andis. 7, 7, 65280
        sldi 3, 3, 56
        and 8, 8, 9
        and 4, 12, 4
        and 9, 10, 11
        or 6, 7, 6
        or 5, 5, 0
        or 3, 3, 4
        or 7, 9, 8
        or 4, 6, 5
        or 3, 3, 7
        or 3, 3, 4

which is 12 instructions, instead of 25, and seems optimal (at least in terms
of code size).

llvm-svn: 225056

2015-01-01 02:53:29 +00:00

Hal Finkel

8adf2254ef

[PowerPC] Improve instruction selection bit-permuting operations (32-bit)

The PowerPC backend, somewhat embarrassingly, did not generate an
optimal-length sequence of instructions for a 32-bit bswap. While adding a
pattern for the bswap intrinsic to fix this would not have been terribly
difficult, doing so would not have addressed the real problem: we had been
generating poor code for many bit-permuting operations (by which I mean things
like byte-swap that permute the bits of one or more inputs around in various
ways). Here are some initial steps toward solving this deficiency.

Bit-permuting operations are represented, at the SDAG level, using ISD::ROTL,
SHL, SRL, AND and OR (mostly with constant second operands). Looking back
through these operations, we can build up a description of the bits in the
resulting value in terms of bits of one or more input values (and constant
zeros). For each bit, we compute the rotation amount from the original value,
and then group consecutive (value, rotation factor) bits into groups. Groups
sharing these attributes are then collected and sorted, and we can then
instruction select the entire permutation using a combination of masked
rotations (rlwinm), imm ands (andi/andis), and masked rotation inserts
(rlwimi).

The result is that instead of lowering an i32 bswap as:

	rlwinm 5, 3, 24, 16, 23
	rlwinm 4, 3, 24, 0, 7
	rlwimi 4, 3, 8, 8, 15
	rlwimi 5, 3, 8, 24, 31
	rlwimi 4, 5, 0, 16, 31

we now produce:

	rlwinm 4, 3, 8, 0, 31
	rlwimi 4, 3, 24, 16, 23
	rlwimi 4, 3, 24, 0, 7

and for the 'test6' example in the PowerPC/README.txt file:

 unsigned test6(unsigned x) {
   return ((x & 0x00FF0000) >> 16) | ((x & 0x000000FF) << 16);
 }

we used to produce:

	lis 4, 255
	rlwinm 3, 3, 16, 0, 31
	ori 4, 4, 255
	and 3, 3, 4

and now we produce:

	rlwinm 4, 3, 16, 24, 31
	rlwimi 4, 3, 16, 8, 15

and, as a nice bonus, this fixes the FIXME in
test/CodeGen/PowerPC/rlwimi-and.ll.

This commit does not include instruction-selection for i64 operations, those
will come later.

llvm-svn: 224318

2014-12-16 05:51:41 +00:00

2 Commits