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|
/*
* Copyright © 2012 Intel Corporation
*
* Permission is hereby granted, free of charge, to any person obtaining a
* copy of this software and associated documentation files (the "Software"),
* to deal in the Software without restriction, including without limitation
* the rights to use, copy, modify, merge, publish, distribute, sublicense,
* and/or sell copies of the Software, and to permit persons to whom the
* Software is furnished to do so, subject to the following conditions:
*
* The above copyright notice and this permission notice (including the next
* paragraph) shall be included in all copies or substantial portions of the
* Software.
*
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
* IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
* FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL
* THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
* LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING
* FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS
* IN THE SOFTWARE.
*/
/** @file brw_eu_compact.c
*
* Instruction compaction is a feature of G45 and newer hardware that allows
* for a smaller instruction encoding.
*
* The instruction cache is on the order of 32KB, and many programs generate
* far more instructions than that. The instruction cache is built to barely
* keep up with instruction dispatch ability in cache hit cases -- L1
* instruction cache misses that still hit in the next level could limit
* throughput by around 50%.
*
* The idea of instruction compaction is that most instructions use a tiny
* subset of the GPU functionality, so we can encode what would be a 16 byte
* instruction in 8 bytes using some lookup tables for various fields.
*
*
* Instruction compaction capabilities vary subtly by generation.
*
* G45's support for instruction compaction is very limited. Jump counts on
* this generation are in units of 16-byte uncompacted instructions. As such,
* all jump targets must be 16-byte aligned. Also, all instructions must be
* naturally aligned, i.e. uncompacted instructions must be 16-byte aligned.
* A G45-only instruction, NENOP, must be used to provide padding to align
* uncompacted instructions.
*
* Gen5 removes these restrictions and changes jump counts to be in units of
* 8-byte compacted instructions, allowing jump targets to be only 8-byte
* aligned. Uncompacted instructions can also be placed on 8-byte boundaries.
*
* Gen6 adds the ability to compact instructions with a limited range of
* immediate values. Compactable immediates have 12 unrestricted bits, and a
* 13th bit that's replicated through the high 20 bits, to create the 32-bit
* value of DW3 in the uncompacted instruction word.
*
* On Gen7 we can compact some control flow instructions with a small positive
* immediate in the low bits of DW3, like ENDIF with the JIP field. Other
* control flow instructions with UIP cannot be compacted, because of the
* replicated 13th bit. No control flow instructions can be compacted on Gen6
* since the jump count field is not in DW3.
*
* break JIP/UIP
* cont JIP/UIP
* halt JIP/UIP
* if JIP/UIP
* else JIP (plus UIP on BDW+)
* endif JIP
* while JIP (must be negative)
*
* Gen 8 adds support for compacting 3-src instructions.
*/
#include "brw_eu.h"
#include "brw_shader.h"
#include "intel_asm_annotation.h"
#include "common/gen_debug.h"
static const uint32_t g45_control_index_table[32] = {
0b00000000000000000,
0b01000000000000000,
0b00110000000000000,
0b00000000000000010,
0b00100000000000000,
0b00010000000000000,
0b01000000000100000,
0b01000000100000000,
0b01010000000100000,
0b00000000100000010,
0b11000000000000000,
0b00001000100000010,
0b01001000100000000,
0b00000000100000000,
0b11000000000100000,
0b00001000100000000,
0b10110000000000000,
0b11010000000100000,
0b00110000100000000,
0b00100000100000000,
0b01000000000001000,
0b01000000000000100,
0b00111100000000000,
0b00101011000000000,
0b00110000000010000,
0b00010000100000000,
0b01000000000100100,
0b01000000000101000,
0b00110000000000110,
0b00000000000001010,
0b01010000000101000,
0b01010000000100100
};
static const uint32_t g45_datatype_table[32] = {
0b001000000000100001,
0b001011010110101101,
0b001000001000110001,
0b001111011110111101,
0b001011010110101100,
0b001000000110101101,
0b001000000000100000,
0b010100010110110001,
0b001100011000101101,
0b001000000000100010,
0b001000001000110110,
0b010000001000110001,
0b001000001000110010,
0b011000001000110010,
0b001111011110111100,
0b001000000100101000,
0b010100011000110001,
0b001010010100101001,
0b001000001000101001,
0b010000001000110110,
0b101000001000110001,
0b001011011000101101,
0b001000000100001001,
0b001011011000101100,
0b110100011000110001,
0b001000001110111101,
0b110000001000110001,
0b011000000100101010,
0b101000001000101001,
0b001011010110001100,
0b001000000110100001,
0b001010010100001000
};
static const uint16_t g45_subreg_table[32] = {
0b000000000000000,
0b000000010000000,
0b000001000000000,
0b000100000000000,
0b000000000100000,
0b100000000000000,
0b000000000010000,
0b001100000000000,
0b001010000000000,
0b000000100000000,
0b001000000000000,
0b000000000001000,
0b000000001000000,
0b000000000000001,
0b000010000000000,
0b000000010100000,
0b000000000000111,
0b000001000100000,
0b011000000000000,
0b000000110000000,
0b000000000000010,
0b000000000000100,
0b000000001100000,
0b000100000000010,
0b001110011000110,
0b001110100001000,
0b000110011000110,
0b000001000011000,
0b000110010000100,
0b001100000000110,
0b000000010000110,
0b000001000110000
};
static const uint16_t g45_src_index_table[32] = {
0b000000000000,
0b010001101000,
0b010110001000,
0b011010010000,
0b001101001000,
0b010110001010,
0b010101110000,
0b011001111000,
0b001000101000,
0b000000101000,
0b010001010000,
0b111101101100,
0b010110001100,
0b010001101100,
0b011010010100,
0b010001001100,
0b001100101000,
0b000000000010,
0b111101001100,
0b011001101000,
0b010101001000,
0b000000000100,
0b000000101100,
0b010001101010,
0b000000111000,
0b010101011000,
0b000100100000,
0b010110000000,
0b010000000100,
0b010000111000,
0b000101100000,
0b111101110100
};
static const uint32_t gen6_control_index_table[32] = {
0b00000000000000000,
0b01000000000000000,
0b00110000000000000,
0b00000000100000000,
0b00010000000000000,
0b00001000100000000,
0b00000000100000010,
0b00000000000000010,
0b01000000100000000,
0b01010000000000000,
0b10110000000000000,
0b00100000000000000,
0b11010000000000000,
0b11000000000000000,
0b01001000100000000,
0b01000000000001000,
0b01000000000000100,
0b00000000000001000,
0b00000000000000100,
0b00111000100000000,
0b00001000100000010,
0b00110000100000000,
0b00110000000000001,
0b00100000000000001,
0b00110000000000010,
0b00110000000000101,
0b00110000000001001,
0b00110000000010000,
0b00110000000000011,
0b00110000000000100,
0b00110000100001000,
0b00100000000001001
};
static const uint32_t gen6_datatype_table[32] = {
0b001001110000000000,
0b001000110000100000,
0b001001110000000001,
0b001000000001100000,
0b001010110100101001,
0b001000000110101101,
0b001100011000101100,
0b001011110110101101,
0b001000000111101100,
0b001000000001100001,
0b001000110010100101,
0b001000000001000001,
0b001000001000110001,
0b001000001000101001,
0b001000000000100000,
0b001000001000110010,
0b001010010100101001,
0b001011010010100101,
0b001000000110100101,
0b001100011000101001,
0b001011011000101100,
0b001011010110100101,
0b001011110110100101,
0b001111011110111101,
0b001111011110111100,
0b001111011110111101,
0b001111011110011101,
0b001111011110111110,
0b001000000000100001,
0b001000000000100010,
0b001001111111011101,
0b001000001110111110,
};
static const uint16_t gen6_subreg_table[32] = {
0b000000000000000,
0b000000000000100,
0b000000110000000,
0b111000000000000,
0b011110000001000,
0b000010000000000,
0b000000000010000,
0b000110000001100,
0b001000000000000,
0b000001000000000,
0b000001010010100,
0b000000001010110,
0b010000000000000,
0b110000000000000,
0b000100000000000,
0b000000010000000,
0b000000000001000,
0b100000000000000,
0b000001010000000,
0b001010000000000,
0b001100000000000,
0b000000001010100,
0b101101010010100,
0b010100000000000,
0b000000010001111,
0b011000000000000,
0b111110000000000,
0b101000000000000,
0b000000000001111,
0b000100010001111,
0b001000010001111,
0b000110000000000,
};
static const uint16_t gen6_src_index_table[32] = {
0b000000000000,
0b010110001000,
0b010001101000,
0b001000101000,
0b011010010000,
0b000100100000,
0b010001101100,
0b010101110000,
0b011001111000,
0b001100101000,
0b010110001100,
0b001000100000,
0b010110001010,
0b000000000010,
0b010101010000,
0b010101101000,
0b111101001100,
0b111100101100,
0b011001110000,
0b010110001001,
0b010101011000,
0b001101001000,
0b010000101100,
0b010000000000,
0b001101110000,
0b001100010000,
0b001100000000,
0b010001101010,
0b001101111000,
0b000001110000,
0b001100100000,
0b001101010000,
};
static const uint32_t gen7_control_index_table[32] = {
0b0000000000000000010,
0b0000100000000000000,
0b0000100000000000001,
0b0000100000000000010,
0b0000100000000000011,
0b0000100000000000100,
0b0000100000000000101,
0b0000100000000000111,
0b0000100000000001000,
0b0000100000000001001,
0b0000100000000001101,
0b0000110000000000000,
0b0000110000000000001,
0b0000110000000000010,
0b0000110000000000011,
0b0000110000000000100,
0b0000110000000000101,
0b0000110000000000111,
0b0000110000000001001,
0b0000110000000001101,
0b0000110000000010000,
0b0000110000100000000,
0b0001000000000000000,
0b0001000000000000010,
0b0001000000000000100,
0b0001000000100000000,
0b0010110000000000000,
0b0010110000000010000,
0b0011000000000000000,
0b0011000000100000000,
0b0101000000000000000,
0b0101000000100000000
};
static const uint32_t gen7_datatype_table[32] = {
0b001000000000000001,
0b001000000000100000,
0b001000000000100001,
0b001000000001100001,
0b001000000010111101,
0b001000001011111101,
0b001000001110100001,
0b001000001110100101,
0b001000001110111101,
0b001000010000100001,
0b001000110000100000,
0b001000110000100001,
0b001001010010100101,
0b001001110010100100,
0b001001110010100101,
0b001111001110111101,
0b001111011110011101,
0b001111011110111100,
0b001111011110111101,
0b001111111110111100,
0b000000001000001100,
0b001000000000111101,
0b001000000010100101,
0b001000010000100000,
0b001001010010100100,
0b001001110010000100,
0b001010010100001001,
0b001101111110111101,
0b001111111110111101,
0b001011110110101100,
0b001010010100101000,
0b001010110100101000
};
static const uint16_t gen7_subreg_table[32] = {
0b000000000000000,
0b000000000000001,
0b000000000001000,
0b000000000001111,
0b000000000010000,
0b000000010000000,
0b000000100000000,
0b000000110000000,
0b000001000000000,
0b000001000010000,
0b000010100000000,
0b001000000000000,
0b001000000000001,
0b001000010000001,
0b001000010000010,
0b001000010000011,
0b001000010000100,
0b001000010000111,
0b001000010001000,
0b001000010001110,
0b001000010001111,
0b001000110000000,
0b001000111101000,
0b010000000000000,
0b010000110000000,
0b011000000000000,
0b011110010000111,
0b100000000000000,
0b101000000000000,
0b110000000000000,
0b111000000000000,
0b111000000011100
};
static const uint16_t gen7_src_index_table[32] = {
0b000000000000,
0b000000000010,
0b000000010000,
0b000000010010,
0b000000011000,
0b000000100000,
0b000000101000,
0b000001001000,
0b000001010000,
0b000001110000,
0b000001111000,
0b001100000000,
0b001100000010,
0b001100001000,
0b001100010000,
0b001100010010,
0b001100100000,
0b001100101000,
0b001100111000,
0b001101000000,
0b001101000010,
0b001101001000,
0b001101010000,
0b001101100000,
0b001101101000,
0b001101110000,
0b001101110001,
0b001101111000,
0b010001101000,
0b010001101001,
0b010001101010,
0b010110001000
};
static const uint32_t gen8_control_index_table[32] = {
0b0000000000000000010,
0b0000100000000000000,
0b0000100000000000001,
0b0000100000000000010,
0b0000100000000000011,
0b0000100000000000100,
0b0000100000000000101,
0b0000100000000000111,
0b0000100000000001000,
0b0000100000000001001,
0b0000100000000001101,
0b0000110000000000000,
0b0000110000000000001,
0b0000110000000000010,
0b0000110000000000011,
0b0000110000000000100,
0b0000110000000000101,
0b0000110000000000111,
0b0000110000000001001,
0b0000110000000001101,
0b0000110000000010000,
0b0000110000100000000,
0b0001000000000000000,
0b0001000000000000010,
0b0001000000000000100,
0b0001000000100000000,
0b0010110000000000000,
0b0010110000000010000,
0b0011000000000000000,
0b0011000000100000000,
0b0101000000000000000,
0b0101000000100000000
};
static const uint32_t gen8_datatype_table[32] = {
0b001000000000000000001,
0b001000000000001000000,
0b001000000000001000001,
0b001000000000011000001,
0b001000000000101011101,
0b001000000010111011101,
0b001000000011101000001,
0b001000000011101000101,
0b001000000011101011101,
0b001000001000001000001,
0b001000011000001000000,
0b001000011000001000001,
0b001000101000101000101,
0b001000111000101000100,
0b001000111000101000101,
0b001011100011101011101,
0b001011101011100011101,
0b001011101011101011100,
0b001011101011101011101,
0b001011111011101011100,
0b000000000010000001100,
0b001000000000001011101,
0b001000000000101000101,
0b001000001000001000000,
0b001000101000101000100,
0b001000111000100000100,
0b001001001001000001001,
0b001010111011101011101,
0b001011111011101011101,
0b001001111001101001100,
0b001001001001001001000,
0b001001011001001001000
};
static const uint16_t gen8_subreg_table[32] = {
0b000000000000000,
0b000000000000001,
0b000000000001000,
0b000000000001111,
0b000000000010000,
0b000000010000000,
0b000000100000000,
0b000000110000000,
0b000001000000000,
0b000001000010000,
0b000001010000000,
0b001000000000000,
0b001000000000001,
0b001000010000001,
0b001000010000010,
0b001000010000011,
0b001000010000100,
0b001000010000111,
0b001000010001000,
0b001000010001110,
0b001000010001111,
0b001000110000000,
0b001000111101000,
0b010000000000000,
0b010000110000000,
0b011000000000000,
0b011110010000111,
0b100000000000000,
0b101000000000000,
0b110000000000000,
0b111000000000000,
0b111000000011100
};
static const uint16_t gen8_src_index_table[32] = {
0b000000000000,
0b000000000010,
0b000000010000,
0b000000010010,
0b000000011000,
0b000000100000,
0b000000101000,
0b000001001000,
0b000001010000,
0b000001110000,
0b000001111000,
0b001100000000,
0b001100000010,
0b001100001000,
0b001100010000,
0b001100010010,
0b001100100000,
0b001100101000,
0b001100111000,
0b001101000000,
0b001101000010,
0b001101001000,
0b001101010000,
0b001101100000,
0b001101101000,
0b001101110000,
0b001101110001,
0b001101111000,
0b010001101000,
0b010001101001,
0b010001101010,
0b010110001000
};
/* This is actually the control index table for Cherryview (26 bits), but the
* only difference from Broadwell (24 bits) is that it has two extra 0-bits at
* the start.
*
* The low 24 bits have the same mappings on both hardware.
*/
static const uint32_t gen8_3src_control_index_table[4] = {
0b00100000000110000000000001,
0b00000000000110000000000001,
0b00000000001000000000000001,
0b00000000001000000000100001
};
/* This is actually the control index table for Cherryview (49 bits), but the
* only difference from Broadwell (46 bits) is that it has three extra 0-bits
* at the start.
*
* The low 44 bits have the same mappings on both hardware, and since the high
* three bits on Broadwell are zero, we can reuse Cherryview's table.
*/
static const uint64_t gen8_3src_source_index_table[4] = {
0b0000001110010011100100111001000001111000000000000,
0b0000001110010011100100111001000001111000000000010,
0b0000001110010011100100111001000001111000000001000,
0b0000001110010011100100111001000001111000000100000
};
static const uint32_t *control_index_table;
static const uint32_t *datatype_table;
static const uint16_t *subreg_table;
static const uint16_t *src_index_table;
static bool
set_control_index(const struct gen_device_info *devinfo,
brw_compact_inst *dst, const brw_inst *src)
{
uint32_t uncompacted = devinfo->gen >= 8 /* 17b/G45; 19b/IVB+ */
? (brw_inst_bits(src, 33, 31) << 16) | /* 3b */
(brw_inst_bits(src, 23, 12) << 4) | /* 12b */
(brw_inst_bits(src, 10, 9) << 2) | /* 2b */
(brw_inst_bits(src, 34, 34) << 1) | /* 1b */
(brw_inst_bits(src, 8, 8)) /* 1b */
: (brw_inst_bits(src, 31, 31) << 16) | /* 1b */
(brw_inst_bits(src, 23, 8)); /* 16b */
/* On gen7, the flag register and subregister numbers are integrated into
* the control index.
*/
if (devinfo->gen == 7)
uncompacted |= brw_inst_bits(src, 90, 89) << 17; /* 2b */
for (int i = 0; i < 32; i++) {
if (control_index_table[i] == uncompacted) {
brw_compact_inst_set_control_index(devinfo, dst, i);
return true;
}
}
return false;
}
static bool
set_datatype_index(const struct gen_device_info *devinfo, brw_compact_inst *dst,
const brw_inst *src)
{
uint32_t uncompacted = devinfo->gen >= 8 /* 18b/G45+; 21b/BDW+ */
? (brw_inst_bits(src, 63, 61) << 18) | /* 3b */
(brw_inst_bits(src, 94, 89) << 12) | /* 6b */
(brw_inst_bits(src, 46, 35)) /* 12b */
: (brw_inst_bits(src, 63, 61) << 15) | /* 3b */
(brw_inst_bits(src, 46, 32)); /* 15b */
for (int i = 0; i < 32; i++) {
if (datatype_table[i] == uncompacted) {
brw_compact_inst_set_datatype_index(devinfo, dst, i);
return true;
}
}
return false;
}
static bool
set_subreg_index(const struct gen_device_info *devinfo, brw_compact_inst *dst,
const brw_inst *src, bool is_immediate)
{
uint16_t uncompacted = /* 15b */
(brw_inst_bits(src, 52, 48) << 0) | /* 5b */
(brw_inst_bits(src, 68, 64) << 5); /* 5b */
if (!is_immediate)
uncompacted |= brw_inst_bits(src, 100, 96) << 10; /* 5b */
for (int i = 0; i < 32; i++) {
if (subreg_table[i] == uncompacted) {
brw_compact_inst_set_subreg_index(devinfo, dst, i);
return true;
}
}
return false;
}
static bool
get_src_index(uint16_t uncompacted,
uint16_t *compacted)
{
for (int i = 0; i < 32; i++) {
if (src_index_table[i] == uncompacted) {
*compacted = i;
return true;
}
}
return false;
}
static bool
set_src0_index(const struct gen_device_info *devinfo,
brw_compact_inst *dst, const brw_inst *src)
{
uint16_t compacted;
uint16_t uncompacted = brw_inst_bits(src, 88, 77); /* 12b */
if (!get_src_index(uncompacted, &compacted))
return false;
brw_compact_inst_set_src0_index(devinfo, dst, compacted);
return true;
}
static bool
set_src1_index(const struct gen_device_info *devinfo, brw_compact_inst *dst,
const brw_inst *src, bool is_immediate)
{
uint16_t compacted;
if (is_immediate) {
compacted = (brw_inst_imm_ud(devinfo, src) >> 8) & 0x1f;
} else {
uint16_t uncompacted = brw_inst_bits(src, 120, 109); /* 12b */
if (!get_src_index(uncompacted, &compacted))
return false;
}
brw_compact_inst_set_src1_index(devinfo, dst, compacted);
return true;
}
static bool
set_3src_control_index(const struct gen_device_info *devinfo,
brw_compact_inst *dst, const brw_inst *src)
{
assert(devinfo->gen >= 8);
uint32_t uncompacted = /* 24b/BDW; 26b/CHV */
(brw_inst_bits(src, 34, 32) << 21) | /* 3b */
(brw_inst_bits(src, 28, 8)); /* 21b */
if (devinfo->gen >= 9 || devinfo->is_cherryview)
uncompacted |= brw_inst_bits(src, 36, 35) << 24; /* 2b */
for (unsigned i = 0; i < ARRAY_SIZE(gen8_3src_control_index_table); i++) {
if (gen8_3src_control_index_table[i] == uncompacted) {
brw_compact_inst_set_3src_control_index(devinfo, dst, i);
return true;
}
}
return false;
}
static bool
set_3src_source_index(const struct gen_device_info *devinfo,
brw_compact_inst *dst, const brw_inst *src)
{
assert(devinfo->gen >= 8);
uint64_t uncompacted = /* 46b/BDW; 49b/CHV */
(brw_inst_bits(src, 83, 83) << 43) | /* 1b */
(brw_inst_bits(src, 114, 107) << 35) | /* 8b */
(brw_inst_bits(src, 93, 86) << 27) | /* 8b */
(brw_inst_bits(src, 72, 65) << 19) | /* 8b */
(brw_inst_bits(src, 55, 37)); /* 19b */
if (devinfo->gen >= 9 || devinfo->is_cherryview) {
uncompacted |=
(brw_inst_bits(src, 126, 125) << 47) | /* 2b */
(brw_inst_bits(src, 105, 104) << 45) | /* 2b */
(brw_inst_bits(src, 84, 84) << 44); /* 1b */
} else {
uncompacted |=
(brw_inst_bits(src, 125, 125) << 45) | /* 1b */
(brw_inst_bits(src, 104, 104) << 44); /* 1b */
}
for (unsigned i = 0; i < ARRAY_SIZE(gen8_3src_source_index_table); i++) {
if (gen8_3src_source_index_table[i] == uncompacted) {
brw_compact_inst_set_3src_source_index(devinfo, dst, i);
return true;
}
}
return false;
}
static bool
has_unmapped_bits(const struct gen_device_info *devinfo, const brw_inst *src)
{
/* EOT can only be mapped on a send if the src1 is an immediate */
if ((brw_inst_opcode(devinfo, src) == BRW_OPCODE_SENDC ||
brw_inst_opcode(devinfo, src) == BRW_OPCODE_SEND) &&
brw_inst_eot(devinfo, src))
return true;
/* Check for instruction bits that don't map to any of the fields of the
* compacted instruction. The instruction cannot be compacted if any of
* them are set. They overlap with:
* - NibCtrl (bit 47 on Gen7, bit 11 on Gen8)
* - Dst.AddrImm[9] (bit 47 on Gen8)
* - Src0.AddrImm[9] (bit 95 on Gen8)
* - Imm64[27:31] (bits 91-95 on Gen7, bit 95 on Gen8)
* - UIP[31] (bit 95 on Gen8)
*/
if (devinfo->gen >= 8) {
assert(!brw_inst_bits(src, 7, 7));
return brw_inst_bits(src, 95, 95) ||
brw_inst_bits(src, 47, 47) ||
brw_inst_bits(src, 11, 11);
} else {
assert(!brw_inst_bits(src, 7, 7) &&
!(devinfo->gen < 7 && brw_inst_bits(src, 90, 90)));
return brw_inst_bits(src, 95, 91) ||
brw_inst_bits(src, 47, 47);
}
}
static bool
has_3src_unmapped_bits(const struct gen_device_info *devinfo,
const brw_inst *src)
{
/* Check for three-source instruction bits that don't map to any of the
* fields of the compacted instruction. All of them seem to be reserved
* bits currently.
*/
if (devinfo->gen >= 9 || devinfo->is_cherryview) {
assert(!brw_inst_bits(src, 127, 127) &&
!brw_inst_bits(src, 7, 7));
} else {
assert(devinfo->gen >= 8);
assert(!brw_inst_bits(src, 127, 126) &&
!brw_inst_bits(src, 105, 105) &&
!brw_inst_bits(src, 84, 84) &&
!brw_inst_bits(src, 36, 35) &&
!brw_inst_bits(src, 7, 7));
}
return false;
}
static bool
brw_try_compact_3src_instruction(const struct gen_device_info *devinfo,
brw_compact_inst *dst, const brw_inst *src)
{
assert(devinfo->gen >= 8);
if (has_3src_unmapped_bits(devinfo, src))
return false;
#define compact(field) \
brw_compact_inst_set_3src_##field(devinfo, dst, brw_inst_3src_##field(devinfo, src))
compact(opcode);
if (!set_3src_control_index(devinfo, dst, src))
return false;
if (!set_3src_source_index(devinfo, dst, src))
return false;
compact(dst_reg_nr);
compact(src0_rep_ctrl);
brw_compact_inst_set_3src_cmpt_control(devinfo, dst, true);
compact(debug_control);
compact(saturate);
compact(src1_rep_ctrl);
compact(src2_rep_ctrl);
compact(src0_reg_nr);
compact(src1_reg_nr);
compact(src2_reg_nr);
compact(src0_subreg_nr);
compact(src1_subreg_nr);
compact(src2_subreg_nr);
#undef compact
return true;
}
/* Compacted instructions have 12-bits for immediate sources, and a 13th bit
* that's replicated through the high 20 bits.
*
* Effectively this means we get 12-bit integers, 0.0f, and some limited uses
* of packed vectors as compactable immediates.
*/
static bool
is_compactable_immediate(unsigned imm)
{
/* We get the low 12 bits as-is. */
imm &= ~0xfff;
/* We get one bit replicated through the top 20 bits. */
return imm == 0 || imm == 0xfffff000;
}
/**
* Applies some small changes to instruction types to increase chances of
* compaction.
*/
static brw_inst
precompact(const struct gen_device_info *devinfo, brw_inst inst)
{
if (brw_inst_src0_reg_file(devinfo, &inst) != BRW_IMMEDIATE_VALUE)
return inst;
/* The Bspec's section titled "Non-present Operands" claims that if src0
* is an immediate that src1's type must be the same as that of src0.
*
* The SNB+ DataTypeIndex instruction compaction tables contain mappings
* that do not follow this rule. E.g., from the IVB/HSW table:
*
* DataTypeIndex 18-Bit Mapping Mapped Meaning
* 3 001000001011111101 r:f | i:vf | a:ud | <1> | dir |
*
* And from the SNB table:
*
* DataTypeIndex 18-Bit Mapping Mapped Meaning
* 8 001000000111101100 a:w | i:w | a:ud | <1> | dir |
*
* Neither of these cause warnings from the simulator when used,
* compacted or otherwise. In fact, all compaction mappings that have an
* immediate in src0 use a:ud for src1.
*
* The GM45 instruction compaction tables do not contain mapped meanings
* so it's not clear whether it has the restriction. We'll assume it was
* lifted on SNB. (FINISHME: decode the GM45 tables and check.)
*
* Don't do any of this for 64-bit immediates, since the src1 fields
* overlap with the immediate and setting them would overwrite the
* immediate we set.
*/
if (devinfo->gen >= 6 &&
!(devinfo->is_haswell &&
brw_inst_opcode(devinfo, &inst) == BRW_OPCODE_DIM) &&
!(devinfo->gen >= 8 &&
(brw_inst_src0_type(devinfo, &inst) == BRW_REGISTER_TYPE_DF ||
brw_inst_src0_type(devinfo, &inst) == BRW_REGISTER_TYPE_UQ ||
brw_inst_src0_type(devinfo, &inst) == BRW_REGISTER_TYPE_Q))) {
enum brw_reg_file file = brw_inst_src1_reg_file(devinfo, &inst);
brw_inst_set_src1_file_type(devinfo, &inst, file, BRW_REGISTER_TYPE_UD);
}
/* Compacted instructions only have 12-bits (plus 1 for the other 20)
* for immediate values. Presumably the hardware engineers realized
* that the only useful floating-point value that could be represented
* in this format is 0.0, which can also be represented as a VF-typed
* immediate, so they gave us the previously mentioned mapping on IVB+.
*
* Strangely, we do have a mapping for imm:f in src1, so we don't need
* to do this there.
*
* If we see a 0.0:F, change the type to VF so that it can be compacted.
*/
if (brw_inst_imm_ud(devinfo, &inst) == 0x0 &&
brw_inst_src0_type(devinfo, &inst) == BRW_REGISTER_TYPE_F &&
brw_inst_dst_type(devinfo, &inst) == BRW_REGISTER_TYPE_F &&
brw_inst_dst_hstride(devinfo, &inst) == BRW_HORIZONTAL_STRIDE_1) {
enum brw_reg_file file = brw_inst_src0_reg_file(devinfo, &inst);
brw_inst_set_src0_file_type(devinfo, &inst, file, BRW_REGISTER_TYPE_VF);
}
/* There are no mappings for dst:d | i:d, so if the immediate is suitable
* set the types to :UD so the instruction can be compacted.
*/
if (is_compactable_immediate(brw_inst_imm_ud(devinfo, &inst)) &&
brw_inst_cond_modifier(devinfo, &inst) == BRW_CONDITIONAL_NONE &&
brw_inst_src0_type(devinfo, &inst) == BRW_REGISTER_TYPE_D &&
brw_inst_dst_type(devinfo, &inst) == BRW_REGISTER_TYPE_D) {
enum brw_reg_file src_file = brw_inst_src0_reg_file(devinfo, &inst);
enum brw_reg_file dst_file = brw_inst_dst_reg_file(devinfo, &inst);
brw_inst_set_src0_file_type(devinfo, &inst, src_file, BRW_REGISTER_TYPE_UD);
brw_inst_set_dst_file_type(devinfo, &inst, dst_file, BRW_REGISTER_TYPE_UD);
}
return inst;
}
/**
* Tries to compact instruction src into dst.
*
* It doesn't modify dst unless src is compactable, which is relied on by
* brw_compact_instructions().
*/
bool
brw_try_compact_instruction(const struct gen_device_info *devinfo,
brw_compact_inst *dst, const brw_inst *src)
{
brw_compact_inst temp;
assert(brw_inst_cmpt_control(devinfo, src) == 0);
if (is_3src(devinfo, brw_inst_opcode(devinfo, src))) {
if (devinfo->gen >= 8) {
memset(&temp, 0, sizeof(temp));
if (brw_try_compact_3src_instruction(devinfo, &temp, src)) {
*dst = temp;
return true;
} else {
return false;
}
} else {
return false;
}
}
bool is_immediate =
brw_inst_src0_reg_file(devinfo, src) == BRW_IMMEDIATE_VALUE ||
brw_inst_src1_reg_file(devinfo, src) == BRW_IMMEDIATE_VALUE;
if (is_immediate &&
(devinfo->gen < 6 ||
!is_compactable_immediate(brw_inst_imm_ud(devinfo, src)))) {
return false;
}
if (has_unmapped_bits(devinfo, src))
return false;
memset(&temp, 0, sizeof(temp));
#define compact(field) \
brw_compact_inst_set_##field(devinfo, &temp, brw_inst_##field(devinfo, src))
compact(opcode);
compact(debug_control);
if (!set_control_index(devinfo, &temp, src))
return false;
if (!set_datatype_index(devinfo, &temp, src))
return false;
if (!set_subreg_index(devinfo, &temp, src, is_immediate))
return false;
if (devinfo->gen >= 6) {
compact(acc_wr_control);
} else {
compact(mask_control_ex);
}
compact(cond_modifier);
if (devinfo->gen <= 6)
compact(flag_subreg_nr);
brw_compact_inst_set_cmpt_control(devinfo, &temp, true);
if (!set_src0_index(devinfo, &temp, src))
return false;
if (!set_src1_index(devinfo, &temp, src, is_immediate))
return false;
brw_compact_inst_set_dst_reg_nr(devinfo, &temp,
brw_inst_dst_da_reg_nr(devinfo, src));
brw_compact_inst_set_src0_reg_nr(devinfo, &temp,
brw_inst_src0_da_reg_nr(devinfo, src));
if (is_immediate) {
brw_compact_inst_set_src1_reg_nr(devinfo, &temp,
brw_inst_imm_ud(devinfo, src) & 0xff);
} else {
brw_compact_inst_set_src1_reg_nr(devinfo, &temp,
brw_inst_src1_da_reg_nr(devinfo, src));
}
#undef compact
*dst = temp;
return true;
}
static void
set_uncompacted_control(const struct gen_device_info *devinfo, brw_inst *dst,
brw_compact_inst *src)
{
uint32_t uncompacted =
control_index_table[brw_compact_inst_control_index(devinfo, src)];
if (devinfo->gen >= 8) {
brw_inst_set_bits(dst, 33, 31, (uncompacted >> 16));
brw_inst_set_bits(dst, 23, 12, (uncompacted >> 4) & 0xfff);
brw_inst_set_bits(dst, 10, 9, (uncompacted >> 2) & 0x3);
brw_inst_set_bits(dst, 34, 34, (uncompacted >> 1) & 0x1);
brw_inst_set_bits(dst, 8, 8, (uncompacted >> 0) & 0x1);
} else {
brw_inst_set_bits(dst, 31, 31, (uncompacted >> 16) & 0x1);
brw_inst_set_bits(dst, 23, 8, (uncompacted & 0xffff));
if (devinfo->gen == 7)
brw_inst_set_bits(dst, 90, 89, uncompacted >> 17);
}
}
static void
set_uncompacted_datatype(const struct gen_device_info *devinfo, brw_inst *dst,
brw_compact_inst *src)
{
uint32_t uncompacted =
datatype_table[brw_compact_inst_datatype_index(devinfo, src)];
if (devinfo->gen >= 8) {
brw_inst_set_bits(dst, 63, 61, (uncompacted >> 18));
brw_inst_set_bits(dst, 94, 89, (uncompacted >> 12) & 0x3f);
brw_inst_set_bits(dst, 46, 35, (uncompacted >> 0) & 0xfff);
} else {
brw_inst_set_bits(dst, 63, 61, (uncompacted >> 15));
brw_inst_set_bits(dst, 46, 32, (uncompacted & 0x7fff));
}
}
static void
set_uncompacted_subreg(const struct gen_device_info *devinfo, brw_inst *dst,
brw_compact_inst *src)
{
uint16_t uncompacted =
subreg_table[brw_compact_inst_subreg_index(devinfo, src)];
brw_inst_set_bits(dst, 100, 96, (uncompacted >> 10));
brw_inst_set_bits(dst, 68, 64, (uncompacted >> 5) & 0x1f);
brw_inst_set_bits(dst, 52, 48, (uncompacted >> 0) & 0x1f);
}
static void
set_uncompacted_src0(const struct gen_device_info *devinfo, brw_inst *dst,
brw_compact_inst *src)
{
uint32_t compacted = brw_compact_inst_src0_index(devinfo, src);
uint16_t uncompacted = src_index_table[compacted];
brw_inst_set_bits(dst, 88, 77, uncompacted);
}
static void
set_uncompacted_src1(const struct gen_device_info *devinfo, brw_inst *dst,
brw_compact_inst *src, bool is_immediate)
{
if (is_immediate) {
signed high5 = brw_compact_inst_src1_index(devinfo, src);
/* Replicate top bit of src1_index into high 20 bits of the immediate. */
brw_inst_set_imm_ud(devinfo, dst, (high5 << 27) >> 19);
} else {
uint16_t uncompacted =
src_index_table[brw_compact_inst_src1_index(devinfo, src)];
brw_inst_set_bits(dst, 120, 109, uncompacted);
}
}
static void
set_uncompacted_3src_control_index(const struct gen_device_info *devinfo,
brw_inst *dst, brw_compact_inst *src)
{
assert(devinfo->gen >= 8);
uint32_t compacted = brw_compact_inst_3src_control_index(devinfo, src);
uint32_t uncompacted = gen8_3src_control_index_table[compacted];
brw_inst_set_bits(dst, 34, 32, (uncompacted >> 21) & 0x7);
brw_inst_set_bits(dst, 28, 8, (uncompacted >> 0) & 0x1fffff);
if (devinfo->gen >= 9 || devinfo->is_cherryview)
brw_inst_set_bits(dst, 36, 35, (uncompacted >> 24) & 0x3);
}
static void
set_uncompacted_3src_source_index(const struct gen_device_info *devinfo,
brw_inst *dst, brw_compact_inst *src)
{
assert(devinfo->gen >= 8);
uint32_t compacted = brw_compact_inst_3src_source_index(devinfo, src);
uint64_t uncompacted = gen8_3src_source_index_table[compacted];
brw_inst_set_bits(dst, 83, 83, (uncompacted >> 43) & 0x1);
brw_inst_set_bits(dst, 114, 107, (uncompacted >> 35) & 0xff);
brw_inst_set_bits(dst, 93, 86, (uncompacted >> 27) & 0xff);
brw_inst_set_bits(dst, 72, 65, (uncompacted >> 19) & 0xff);
brw_inst_set_bits(dst, 55, 37, (uncompacted >> 0) & 0x7ffff);
if (devinfo->gen >= 9 || devinfo->is_cherryview) {
brw_inst_set_bits(dst, 126, 125, (uncompacted >> 47) & 0x3);
brw_inst_set_bits(dst, 105, 104, (uncompacted >> 45) & 0x3);
brw_inst_set_bits(dst, 84, 84, (uncompacted >> 44) & 0x1);
} else {
brw_inst_set_bits(dst, 125, 125, (uncompacted >> 45) & 0x1);
brw_inst_set_bits(dst, 104, 104, (uncompacted >> 44) & 0x1);
}
}
static void
brw_uncompact_3src_instruction(const struct gen_device_info *devinfo,
brw_inst *dst, brw_compact_inst *src)
{
assert(devinfo->gen >= 8);
#define uncompact(field) \
brw_inst_set_3src_##field(devinfo, dst, brw_compact_inst_3src_##field(devinfo, src))
uncompact(opcode);
set_uncompacted_3src_control_index(devinfo, dst, src);
set_uncompacted_3src_source_index(devinfo, dst, src);
uncompact(dst_reg_nr);
uncompact(src0_rep_ctrl);
brw_inst_set_3src_cmpt_control(devinfo, dst, false);
uncompact(debug_control);
uncompact(saturate);
uncompact(src1_rep_ctrl);
uncompact(src2_rep_ctrl);
uncompact(src0_reg_nr);
uncompact(src1_reg_nr);
uncompact(src2_reg_nr);
uncompact(src0_subreg_nr);
uncompact(src1_subreg_nr);
uncompact(src2_subreg_nr);
#undef uncompact
}
void
brw_uncompact_instruction(const struct gen_device_info *devinfo, brw_inst *dst,
brw_compact_inst *src)
{
memset(dst, 0, sizeof(*dst));
if (devinfo->gen >= 8 &&
is_3src(devinfo, brw_compact_inst_3src_opcode(devinfo, src))) {
brw_uncompact_3src_instruction(devinfo, dst, src);
return;
}
#define uncompact(field) \
brw_inst_set_##field(devinfo, dst, brw_compact_inst_##field(devinfo, src))
uncompact(opcode);
uncompact(debug_control);
set_uncompacted_control(devinfo, dst, src);
set_uncompacted_datatype(devinfo, dst, src);
/* src0/1 register file fields are in the datatype table. */
bool is_immediate = brw_inst_src0_reg_file(devinfo, dst) == BRW_IMMEDIATE_VALUE ||
brw_inst_src1_reg_file(devinfo, dst) == BRW_IMMEDIATE_VALUE;
set_uncompacted_subreg(devinfo, dst, src);
if (devinfo->gen >= 6) {
uncompact(acc_wr_control);
} else {
uncompact(mask_control_ex);
}
uncompact(cond_modifier);
if (devinfo->gen <= 6)
uncompact(flag_subreg_nr);
set_uncompacted_src0(devinfo, dst, src);
set_uncompacted_src1(devinfo, dst, src, is_immediate);
brw_inst_set_dst_da_reg_nr(devinfo, dst,
brw_compact_inst_dst_reg_nr(devinfo, src));
brw_inst_set_src0_da_reg_nr(devinfo, dst,
brw_compact_inst_src0_reg_nr(devinfo, src));
if (is_immediate) {
brw_inst_set_imm_ud(devinfo, dst,
brw_inst_imm_ud(devinfo, dst) |
brw_compact_inst_src1_reg_nr(devinfo, src));
} else {
brw_inst_set_src1_da_reg_nr(devinfo, dst,
brw_compact_inst_src1_reg_nr(devinfo, src));
}
#undef uncompact
}
void brw_debug_compact_uncompact(const struct gen_device_info *devinfo,
brw_inst *orig,
brw_inst *uncompacted)
{
fprintf(stderr, "Instruction compact/uncompact changed (gen%d):\n",
devinfo->gen);
fprintf(stderr, " before: ");
brw_disassemble_inst(stderr, devinfo, orig, true);
fprintf(stderr, " after: ");
brw_disassemble_inst(stderr, devinfo, uncompacted, false);
uint32_t *before_bits = (uint32_t *)orig;
uint32_t *after_bits = (uint32_t *)uncompacted;
fprintf(stderr, " changed bits:\n");
for (int i = 0; i < 128; i++) {
uint32_t before = before_bits[i / 32] & (1 << (i & 31));
uint32_t after = after_bits[i / 32] & (1 << (i & 31));
if (before != after) {
fprintf(stderr, " bit %d, %s to %s\n", i,
before ? "set" : "unset",
after ? "set" : "unset");
}
}
}
static int
compacted_between(int old_ip, int old_target_ip, int *compacted_counts)
{
int this_compacted_count = compacted_counts[old_ip];
int target_compacted_count = compacted_counts[old_target_ip];
return target_compacted_count - this_compacted_count;
}
static void
update_uip_jip(const struct gen_device_info *devinfo, brw_inst *insn,
int this_old_ip, int *compacted_counts)
{
/* JIP and UIP are in units of:
* - bytes on Gen8+; and
* - compacted instructions on Gen6+.
*/
int shift = devinfo->gen >= 8 ? 3 : 0;
int32_t jip_compacted = brw_inst_jip(devinfo, insn) >> shift;
jip_compacted -= compacted_between(this_old_ip,
this_old_ip + (jip_compacted / 2),
compacted_counts);
brw_inst_set_jip(devinfo, insn, jip_compacted << shift);
if (brw_inst_opcode(devinfo, insn) == BRW_OPCODE_ENDIF ||
brw_inst_opcode(devinfo, insn) == BRW_OPCODE_WHILE ||
(brw_inst_opcode(devinfo, insn) == BRW_OPCODE_ELSE && devinfo->gen <= 7))
return;
int32_t uip_compacted = brw_inst_uip(devinfo, insn) >> shift;
uip_compacted -= compacted_between(this_old_ip,
this_old_ip + (uip_compacted / 2),
compacted_counts);
brw_inst_set_uip(devinfo, insn, uip_compacted << shift);
}
static void
update_gen4_jump_count(const struct gen_device_info *devinfo, brw_inst *insn,
int this_old_ip, int *compacted_counts)
{
assert(devinfo->gen == 5 || devinfo->is_g4x);
/* Jump Count is in units of:
* - uncompacted instructions on G45; and
* - compacted instructions on Gen5.
*/
int shift = devinfo->is_g4x ? 1 : 0;
int jump_count_compacted = brw_inst_gen4_jump_count(devinfo, insn) << shift;
int target_old_ip = this_old_ip + (jump_count_compacted / 2);
int this_compacted_count = compacted_counts[this_old_ip];
int target_compacted_count = compacted_counts[target_old_ip];
jump_count_compacted -= (target_compacted_count - this_compacted_count);
brw_inst_set_gen4_jump_count(devinfo, insn, jump_count_compacted >> shift);
}
void
brw_init_compaction_tables(const struct gen_device_info *devinfo)
{
assert(g45_control_index_table[ARRAY_SIZE(g45_control_index_table) - 1] != 0);
assert(g45_datatype_table[ARRAY_SIZE(g45_datatype_table) - 1] != 0);
assert(g45_subreg_table[ARRAY_SIZE(g45_subreg_table) - 1] != 0);
assert(g45_src_index_table[ARRAY_SIZE(g45_src_index_table) - 1] != 0);
assert(gen6_control_index_table[ARRAY_SIZE(gen6_control_index_table) - 1] != 0);
assert(gen6_datatype_table[ARRAY_SIZE(gen6_datatype_table) - 1] != 0);
assert(gen6_subreg_table[ARRAY_SIZE(gen6_subreg_table) - 1] != 0);
assert(gen6_src_index_table[ARRAY_SIZE(gen6_src_index_table) - 1] != 0);
assert(gen7_control_index_table[ARRAY_SIZE(gen7_control_index_table) - 1] != 0);
assert(gen7_datatype_table[ARRAY_SIZE(gen7_datatype_table) - 1] != 0);
assert(gen7_subreg_table[ARRAY_SIZE(gen7_subreg_table) - 1] != 0);
assert(gen7_src_index_table[ARRAY_SIZE(gen7_src_index_table) - 1] != 0);
assert(gen8_control_index_table[ARRAY_SIZE(gen8_control_index_table) - 1] != 0);
assert(gen8_datatype_table[ARRAY_SIZE(gen8_datatype_table) - 1] != 0);
assert(gen8_subreg_table[ARRAY_SIZE(gen8_subreg_table) - 1] != 0);
assert(gen8_src_index_table[ARRAY_SIZE(gen8_src_index_table) - 1] != 0);
switch (devinfo->gen) {
case 10:
case 9:
case 8:
control_index_table = gen8_control_index_table;
datatype_table = gen8_datatype_table;
subreg_table = gen8_subreg_table;
src_index_table = gen8_src_index_table;
break;
case 7:
control_index_table = gen7_control_index_table;
datatype_table = gen7_datatype_table;
subreg_table = gen7_subreg_table;
src_index_table = gen7_src_index_table;
break;
case 6:
control_index_table = gen6_control_index_table;
datatype_table = gen6_datatype_table;
subreg_table = gen6_subreg_table;
src_index_table = gen6_src_index_table;
break;
case 5:
case 4:
control_index_table = g45_control_index_table;
datatype_table = g45_datatype_table;
subreg_table = g45_subreg_table;
src_index_table = g45_src_index_table;
break;
default:
unreachable("unknown generation");
}
}
void
brw_compact_instructions(struct brw_codegen *p, int start_offset,
int num_annotations, struct annotation *annotation)
{
if (unlikely(INTEL_DEBUG & DEBUG_NO_COMPACTION))
return;
const struct gen_device_info *devinfo = p->devinfo;
void *store = p->store + start_offset / 16;
/* For an instruction at byte offset 16*i before compaction, this is the
* number of compacted instructions minus the number of padding NOP/NENOPs
* that preceded it.
*/
int compacted_counts[(p->next_insn_offset - start_offset) / sizeof(brw_inst)];
/* For an instruction at byte offset 8*i after compaction, this was its IP
* (in 16-byte units) before compaction.
*/
int old_ip[(p->next_insn_offset - start_offset) / sizeof(brw_compact_inst)];
if (devinfo->gen == 4 && !devinfo->is_g4x)
return;
int offset = 0;
int compacted_count = 0;
for (int src_offset = 0; src_offset < p->next_insn_offset - start_offset;
src_offset += sizeof(brw_inst)) {
brw_inst *src = store + src_offset;
void *dst = store + offset;
old_ip[offset / sizeof(brw_compact_inst)] = src_offset / sizeof(brw_inst);
compacted_counts[src_offset / sizeof(brw_inst)] = compacted_count;
brw_inst inst = precompact(devinfo, *src);
brw_inst saved = inst;
if (brw_try_compact_instruction(devinfo, dst, &inst)) {
compacted_count++;
if (INTEL_DEBUG) {
brw_inst uncompacted;
brw_uncompact_instruction(devinfo, &uncompacted, dst);
if (memcmp(&saved, &uncompacted, sizeof(uncompacted))) {
brw_debug_compact_uncompact(devinfo, &saved, &uncompacted);
}
}
offset += sizeof(brw_compact_inst);
} else {
/* All uncompacted instructions need to be aligned on G45. */
if ((offset & sizeof(brw_compact_inst)) != 0 && devinfo->is_g4x){
brw_compact_inst *align = store + offset;
memset(align, 0, sizeof(*align));
brw_compact_inst_set_opcode(devinfo, align, BRW_OPCODE_NENOP);
brw_compact_inst_set_cmpt_control(devinfo, align, true);
offset += sizeof(brw_compact_inst);
compacted_count--;
compacted_counts[src_offset / sizeof(brw_inst)] = compacted_count;
old_ip[offset / sizeof(brw_compact_inst)] = src_offset / sizeof(brw_inst);
dst = store + offset;
}
/* If we didn't compact this intruction, we need to move it down into
* place.
*/
if (offset != src_offset) {
memmove(dst, src, sizeof(brw_inst));
}
offset += sizeof(brw_inst);
}
}
/* Fix up control flow offsets. */
p->next_insn_offset = start_offset + offset;
for (offset = 0; offset < p->next_insn_offset - start_offset;
offset = next_offset(devinfo, store, offset)) {
brw_inst *insn = store + offset;
int this_old_ip = old_ip[offset / sizeof(brw_compact_inst)];
int this_compacted_count = compacted_counts[this_old_ip];
switch (brw_inst_opcode(devinfo, insn)) {
case BRW_OPCODE_BREAK:
case BRW_OPCODE_CONTINUE:
case BRW_OPCODE_HALT:
if (devinfo->gen >= 6) {
update_uip_jip(devinfo, insn, this_old_ip, compacted_counts);
} else {
update_gen4_jump_count(devinfo, insn, this_old_ip,
compacted_counts);
}
break;
case BRW_OPCODE_IF:
case BRW_OPCODE_IFF:
case BRW_OPCODE_ELSE:
case BRW_OPCODE_ENDIF:
case BRW_OPCODE_WHILE:
if (devinfo->gen >= 7) {
if (brw_inst_cmpt_control(devinfo, insn)) {
brw_inst uncompacted;
brw_uncompact_instruction(devinfo, &uncompacted,
(brw_compact_inst *)insn);
update_uip_jip(devinfo, &uncompacted, this_old_ip,
compacted_counts);
bool ret = brw_try_compact_instruction(devinfo,
(brw_compact_inst *)insn,
&uncompacted);
assert(ret); (void)ret;
} else {
update_uip_jip(devinfo, insn, this_old_ip, compacted_counts);
}
} else if (devinfo->gen == 6) {
assert(!brw_inst_cmpt_control(devinfo, insn));
/* Jump Count is in units of compacted instructions on Gen6. */
int jump_count_compacted = brw_inst_gen6_jump_count(devinfo, insn);
int target_old_ip = this_old_ip + (jump_count_compacted / 2);
int target_compacted_count = compacted_counts[target_old_ip];
jump_count_compacted -= (target_compacted_count - this_compacted_count);
brw_inst_set_gen6_jump_count(devinfo, insn, jump_count_compacted);
} else {
update_gen4_jump_count(devinfo, insn, this_old_ip,
compacted_counts);
}
break;
case BRW_OPCODE_ADD:
/* Add instructions modifying the IP register use an immediate src1,
* and Gens that use this cannot compact instructions with immediate
* operands.
*/
if (brw_inst_cmpt_control(devinfo, insn))
break;
if (brw_inst_dst_reg_file(devinfo, insn) == BRW_ARCHITECTURE_REGISTER_FILE &&
brw_inst_dst_da_reg_nr(devinfo, insn) == BRW_ARF_IP) {
assert(brw_inst_src1_reg_file(devinfo, insn) == BRW_IMMEDIATE_VALUE);
int shift = 3;
int jump_compacted = brw_inst_imm_d(devinfo, insn) >> shift;
int target_old_ip = this_old_ip + (jump_compacted / 2);
int target_compacted_count = compacted_counts[target_old_ip];
jump_compacted -= (target_compacted_count - this_compacted_count);
brw_inst_set_imm_ud(devinfo, insn, jump_compacted << shift);
}
break;
}
}
/* p->nr_insn is counting the number of uncompacted instructions still, so
* divide. We do want to be sure there's a valid instruction in any
* alignment padding, so that the next compression pass (for the FS 8/16
* compile passes) parses correctly.
*/
if (p->next_insn_offset & sizeof(brw_compact_inst)) {
brw_compact_inst *align = store + offset;
memset(align, 0, sizeof(*align));
brw_compact_inst_set_opcode(devinfo, align, BRW_OPCODE_NOP);
brw_compact_inst_set_cmpt_control(devinfo, align, true);
p->next_insn_offset += sizeof(brw_compact_inst);
}
p->nr_insn = p->next_insn_offset / sizeof(brw_inst);
/* Update the instruction offsets for each annotation. */
if (annotation) {
for (int offset = 0, i = 0; i < num_annotations; i++) {
while (start_offset + old_ip[offset / sizeof(brw_compact_inst)] *
sizeof(brw_inst) != annotation[i].offset) {
assert(start_offset + old_ip[offset / sizeof(brw_compact_inst)] *
sizeof(brw_inst) < annotation[i].offset);
offset = next_offset(devinfo, store, offset);
}
annotation[i].offset = start_offset + offset;
offset = next_offset(devinfo, store, offset);
}
annotation[num_annotations].offset = p->next_insn_offset;
}
}
|