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/*
* Copyright © 2017 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_fs_bank_conflicts.cpp
*
* This file contains a GRF bank conflict mitigation pass. The pass is
* intended to be run after register allocation and works by rearranging the
* layout of the GRF space (without altering the semantics of the program) in
* a way that minimizes the number of GRF bank conflicts incurred by ternary
* instructions.
*
* Unfortunately there is close to no information about bank conflicts in the
* hardware spec, but experimentally on Gen7-Gen9 ternary instructions seem to
* incur an average bank conflict penalty of one cycle per SIMD8 op whenever
* the second and third source are stored in the same GRF bank (\sa bank_of()
* for the exact bank layout) which cannot be fetched during the same cycle by
* the EU, unless the EU logic manages to optimize out the read cycle of a
* duplicate source register (\sa is_conflict_optimized_out()).
*
* The asymptotic run-time of the algorithm is dominated by the
* shader_conflict_weight_matrix() computation below, which is O(n) on the
* number of instructions in the program, however for small and medium-sized
* programs the run-time is likely to be dominated by
* optimize_reg_permutation() which is O(m^3) on the number of GRF atoms of
* the program (\sa partitioning), which is bounded (since the program uses a
* bounded number of registers post-regalloc) and of the order of 100. For
* that reason optimize_reg_permutation() is vectorized in order to keep the
* cubic term within reasonable bounds for m close to its theoretical maximum.
*/
#include "brw_fs.h"
#include "brw_cfg.h"
#include "util/os_memory.h"
#ifdef __SSE2__
#include <emmintrin.h>
/**
* Thin layer around vector intrinsics so they can be easily replaced with
* e.g. the fall-back scalar path, an implementation with different vector
* width or using different SIMD architectures (AVX-512?!).
*
* This implementation operates on pairs of independent SSE2 integer vectors à
* la SIMD16 for somewhat improved throughput. SSE2 is supported by virtually
* all platforms that care about bank conflicts, so this path should almost
* always be available in practice.
*/
namespace {
/**
* SIMD integer vector data type.
*/
struct vector_type {
__m128i v[2];
};
/**
* Scalar data type matching the representation of a single component of \p
* vector_type.
*/
typedef int16_t scalar_type;
/**
* Maximum integer value representable as a \p scalar_type.
*/
const scalar_type max_scalar = INT16_MAX;
/**
* Number of components of a \p vector_type.
*/
const unsigned vector_width = 2 * sizeof(__m128i) / sizeof(scalar_type);
/**
* Set the i-th component of vector \p v to \p x.
*/
void
set(vector_type &v, unsigned i, scalar_type x)
{
assert(i < vector_width);
memcpy((char *)v.v + i * sizeof(x), &x, sizeof(x));
}
/**
* Get the i-th component of vector \p v.
*/
scalar_type
get(const vector_type &v, unsigned i)
{
assert(i < vector_width);
scalar_type x;
memcpy(&x, (char *)v.v + i * sizeof(x), sizeof(x));
return x;
}
/**
* Add two vectors with saturation.
*/
vector_type
adds(const vector_type &v, const vector_type &w)
{
const vector_type u = {{
_mm_adds_epi16(v.v[0], w.v[0]),
_mm_adds_epi16(v.v[1], w.v[1])
}};
return u;
}
/**
* Subtract two vectors with saturation.
*/
vector_type
subs(const vector_type &v, const vector_type &w)
{
const vector_type u = {{
_mm_subs_epi16(v.v[0], w.v[0]),
_mm_subs_epi16(v.v[1], w.v[1])
}};
return u;
}
/**
* Compute the bitwise conjunction of two vectors.
*/
vector_type
mask(const vector_type &v, const vector_type &w)
{
const vector_type u = {{
_mm_and_si128(v.v[0], w.v[0]),
_mm_and_si128(v.v[1], w.v[1])
}};
return u;
}
/**
* Reduce the components of a vector using saturating addition.
*/
scalar_type
sums(const vector_type &v)
{
const __m128i v8 = _mm_adds_epi16(v.v[0], v.v[1]);
const __m128i v4 = _mm_adds_epi16(v8, _mm_shuffle_epi32(v8, 0x4e));
const __m128i v2 = _mm_adds_epi16(v4, _mm_shuffle_epi32(v4, 0xb1));
const __m128i v1 = _mm_adds_epi16(v2, _mm_shufflelo_epi16(v2, 0xb1));
return _mm_extract_epi16(v1, 0);
}
}
#else
/**
* Thin layer around vector intrinsics so they can be easily replaced with
* e.g. the fall-back scalar path, an implementation with different vector
* width or using different SIMD architectures (AVX-512?!).
*
* This implementation operates on scalar values and doesn't rely on
* any vector extensions. This is mainly intended for debugging and
* to keep this file building on exotic platforms.
*/
namespace {
/**
* SIMD integer vector data type.
*/
typedef int16_t vector_type;
/**
* Scalar data type matching the representation of a single component of \p
* vector_type.
*/
typedef int16_t scalar_type;
/**
* Maximum integer value representable as a \p scalar_type.
*/
const scalar_type max_scalar = INT16_MAX;
/**
* Number of components of a \p vector_type.
*/
const unsigned vector_width = 1;
/**
* Set the i-th component of vector \p v to \p x.
*/
void
set(vector_type &v, unsigned i, scalar_type x)
{
assert(i < vector_width);
v = x;
}
/**
* Get the i-th component of vector \p v.
*/
scalar_type
get(const vector_type &v, unsigned i)
{
assert(i < vector_width);
return v;
}
/**
* Add two vectors with saturation.
*/
vector_type
adds(vector_type v, vector_type w)
{
return MAX2(INT16_MIN, MIN2(INT16_MAX, int(v) + w));
}
/**
* Substract two vectors with saturation.
*/
vector_type
subs(vector_type v, vector_type w)
{
return MAX2(INT16_MIN, MIN2(INT16_MAX, int(v) - w));
}
/**
* Compute the bitwise conjunction of two vectors.
*/
vector_type
mask(vector_type v, vector_type w)
{
return v & w;
}
/**
* Reduce the components of a vector using saturating addition.
*/
scalar_type
sums(vector_type v)
{
return v;
}
}
#endif
/**
* Swap \p x and \p y.
*/
#define SWAP(x, y) do { \
__typeof(y) _swap_tmp = y; \
y = x; \
x = _swap_tmp; \
} while (0)
namespace {
/**
* Variable-length vector type intended to represent cycle-count costs for
* arbitrary atom-to-bank assignments. It's indexed by a pair of integers
* (i, p), where i is an atom index and p in {0, 1} indicates the parity of
* the conflict (respectively, whether the cost is incurred whenever the
* atoms are assigned the same bank b or opposite-parity banks b and b^1).
* \sa shader_conflict_weight_matrix()
*/
struct weight_vector_type {
weight_vector_type() : v(NULL), size(0) {}
weight_vector_type(unsigned n) : v(alloc(n)), size(n) {}
weight_vector_type(const weight_vector_type &u) :
v(alloc(u.size)), size(u.size)
{
memcpy(v, u.v,
DIV_ROUND_UP(u.size, vector_width) * sizeof(vector_type));
}
~weight_vector_type()
{
os_free_aligned(v);
}
weight_vector_type &
operator=(weight_vector_type u)
{
SWAP(v, u.v);
SWAP(size, u.size);
return *this;
}
vector_type *v;
unsigned size;
private:
static vector_type *
alloc(unsigned n)
{
const unsigned align = MAX2(sizeof(void *), __alignof__(vector_type));
const unsigned size = DIV_ROUND_UP(n, vector_width) * sizeof(vector_type);
void *p = os_malloc_aligned(size, align);
if (!p)
return NULL;
memset(p, 0, size);
return reinterpret_cast<vector_type *>(p);
}
};
/**
* Set the (i, p)-th component of weight vector \p v to \p x.
*/
void
set(weight_vector_type &v, unsigned i, unsigned p, scalar_type x)
{
set(v.v[(2 * i + p) / vector_width], (2 * i + p) % vector_width, x);
}
/**
* Get the (i, p)-th component of weight vector \p v.
*/
scalar_type
get(const weight_vector_type &v, unsigned i, unsigned p)
{
return get(v.v[(2 * i + p) / vector_width], (2 * i + p) % vector_width);
}
/**
* Swap the (i, p)-th and (j, q)-th components of weight vector \p v.
*/
void
swap(weight_vector_type &v,
unsigned i, unsigned p,
unsigned j, unsigned q)
{
const scalar_type tmp = get(v, i, p);
set(v, i, p, get(v, j, q));
set(v, j, q, tmp);
}
}
namespace {
/**
* Object that represents the partitioning of an arbitrary register space
* into indivisible units (referred to as atoms below) that can potentially
* be rearranged independently from other registers. The partitioning is
* inferred from a number of contiguity requirements specified using
* require_contiguous(). This allows efficient look-up of the atom index a
* given register address belongs to, or conversely the range of register
* addresses that belong to a given atom.
*/
struct partitioning {
/**
* Create a (for the moment unrestricted) partitioning of a register
* file of size \p n. The units are arbitrary.
*/
partitioning(unsigned n) :
max_reg(n),
offsets(new unsigned[n + num_terminator_atoms]),
atoms(new unsigned[n + num_terminator_atoms])
{
for (unsigned i = 0; i < n + num_terminator_atoms; i++) {
offsets[i] = i;
atoms[i] = i;
}
}
partitioning(const partitioning &p) :
max_reg(p.max_reg),
offsets(new unsigned[p.num_atoms() + num_terminator_atoms]),
atoms(new unsigned[p.max_reg + num_terminator_atoms])
{
memcpy(offsets, p.offsets,
sizeof(unsigned) * (p.num_atoms() + num_terminator_atoms));
memcpy(atoms, p.atoms,
sizeof(unsigned) * (p.max_reg + num_terminator_atoms));
}
~partitioning()
{
delete[] offsets;
delete[] atoms;
}
partitioning &
operator=(partitioning p)
{
SWAP(max_reg, p.max_reg);
SWAP(offsets, p.offsets);
SWAP(atoms, p.atoms);
return *this;
}
/**
* Require register range [reg, reg + n[ to be considered part of the
* same atom.
*/
void
require_contiguous(unsigned reg, unsigned n)
{
unsigned r = atoms[reg];
/* Renumber atoms[reg...] = { r... } and their offsets[r...] for the
* case that the specified contiguity requirement leads to the fusion
* (yay) of one or more existing atoms.
*/
for (unsigned reg1 = reg + 1; reg1 <= max_reg; reg1++) {
if (offsets[atoms[reg1]] < reg + n) {
atoms[reg1] = r;
} else {
if (offsets[atoms[reg1 - 1]] != offsets[atoms[reg1]])
r++;
offsets[r] = offsets[atoms[reg1]];
atoms[reg1] = r;
}
}
}
/**
* Get the atom index register address \p reg belongs to.
*/
unsigned
atom_of_reg(unsigned reg) const
{
return atoms[reg];
}
/**
* Get the base register address that belongs to atom \p r.
*/
unsigned
reg_of_atom(unsigned r) const
{
return offsets[r];
}
/**
* Get the size of atom \p r in register address units.
*/
unsigned
size_of_atom(unsigned r) const
{
assert(r < num_atoms());
return reg_of_atom(r + 1) - reg_of_atom(r);
}
/**
* Get the number of atoms the whole register space is partitioned into.
*/
unsigned
num_atoms() const
{
return atoms[max_reg];
}
private:
/**
* Number of trailing atoms inserted for convenience so among other
* things we don't need to special-case the last element in
* size_of_atom().
*/
static const unsigned num_terminator_atoms = 1;
unsigned max_reg;
unsigned *offsets;
unsigned *atoms;
};
/**
* Only GRF sources (whether they have been register-allocated or not) can
* possibly incur bank conflicts.
*/
bool
is_grf(const fs_reg &r)
{
return r.file == VGRF || r.file == FIXED_GRF;
}
/**
* Register offset of \p r in GRF units. Useful because the representation
* of GRFs post-register allocation is somewhat inconsistent and depends on
* whether the register already had a fixed GRF offset prior to register
* allocation or whether it was part of a VGRF allocation.
*/
unsigned
reg_of(const fs_reg &r)
{
assert(is_grf(r));
if (r.file == VGRF)
return r.nr + r.offset / REG_SIZE;
else
return reg_offset(r) / REG_SIZE;
}
/**
* Calculate the finest partitioning of the GRF space compatible with the
* register contiguity requirements derived from all instructions part of
* the program.
*/
partitioning
shader_reg_partitioning(const fs_visitor *v)
{
partitioning p(BRW_MAX_GRF);
foreach_block_and_inst(block, fs_inst, inst, v->cfg) {
if (is_grf(inst->dst))
p.require_contiguous(reg_of(inst->dst), regs_written(inst));
for (int i = 0; i < inst->sources; i++) {
if (is_grf(inst->src[i]))
p.require_contiguous(reg_of(inst->src[i]), regs_read(inst, i));
}
}
return p;
}
/**
* Return the set of GRF atoms that should be left untouched at their
* original location to avoid violating hardware or software assumptions.
*/
bool *
shader_reg_constraints(const fs_visitor *v, const partitioning &p)
{
bool *constrained = new bool[p.num_atoms()]();
/* These are read implicitly by some send-message instructions without
* any indication at the IR level. Assume they are unsafe to move
* around.
*/
for (unsigned reg = 0; reg < 2; reg++)
constrained[p.atom_of_reg(reg)] = true;
/* At Intel Broadwell PRM, vol 07, section "Instruction Set Reference",
* subsection "EUISA Instructions", Send Message (page 990):
*
* "r127 must not be used for return address when there is a src and
* dest overlap in send instruction."
*
* Register allocation ensures that, so don't move 127 around to avoid
* breaking that property.
*/
if (v->devinfo->gen >= 8)
constrained[p.atom_of_reg(127)] = true;
foreach_block_and_inst(block, fs_inst, inst, v->cfg) {
/* Assume that anything referenced via fixed GRFs is baked into the
* hardware's fixed-function logic and may be unsafe to move around.
* Also take into account the source GRF restrictions of EOT
* send-message instructions.
*/
if (inst->dst.file == FIXED_GRF)
constrained[p.atom_of_reg(reg_of(inst->dst))] = true;
for (int i = 0; i < inst->sources; i++) {
if (inst->src[i].file == FIXED_GRF ||
(is_grf(inst->src[i]) && inst->eot))
constrained[p.atom_of_reg(reg_of(inst->src[i]))] = true;
}
/* The location of the Gen7 MRF hack registers is hard-coded in the
* rest of the compiler back-end. Don't attempt to move them around.
*/
if (v->devinfo->gen >= 7) {
assert(inst->dst.file != MRF);
for (int i = 0; i < v->implied_mrf_writes(inst); i++) {
const unsigned reg = GEN7_MRF_HACK_START + inst->base_mrf + i;
constrained[p.atom_of_reg(reg)] = true;
}
}
}
return constrained;
}
/**
* Return whether the hardware will be able to prevent a bank conflict by
* optimizing out the read cycle of a source register. The formula was
* found experimentally.
*/
bool
is_conflict_optimized_out(const gen_device_info *devinfo, const fs_inst *inst)
{
return devinfo->gen >= 9 &&
((is_grf(inst->src[0]) && (reg_of(inst->src[0]) == reg_of(inst->src[1]) ||
reg_of(inst->src[0]) == reg_of(inst->src[2]))) ||
reg_of(inst->src[1]) == reg_of(inst->src[2]));
}
/**
* Return a matrix that allows reasonably efficient computation of the
* cycle-count cost of bank conflicts incurred throughout the whole program
* for any given atom-to-bank assignment.
*
* More precisely, if C_r_s_p is the result of this function, the total
* cost of all bank conflicts involving any given atom r can be readily
* recovered as follows:
*
* S(B) = Sum_s_p(d_(p^B_r)_(B_s) * C_r_s_p)
*
* where d_i_j is the Kronecker delta, and B_r indicates the bank
* assignment of r. \sa delta_conflicts() for a vectorized implementation
* of the expression above.
*
* FINISHME: Teach this about the Gen10+ bank conflict rules, which are
* somewhat more relaxed than on previous generations. In the
* meantime optimizing based on Gen9 weights is likely to be more
* helpful than not optimizing at all.
*/
weight_vector_type *
shader_conflict_weight_matrix(const fs_visitor *v, const partitioning &p)
{
weight_vector_type *conflicts = new weight_vector_type[p.num_atoms()];
for (unsigned r = 0; r < p.num_atoms(); r++)
conflicts[r] = weight_vector_type(2 * p.num_atoms());
/* Crude approximation of the number of times the current basic block
* will be executed at run-time.
*/
unsigned block_scale = 1;
foreach_block_and_inst(block, fs_inst, inst, v->cfg) {
if (inst->opcode == BRW_OPCODE_DO) {
block_scale *= 10;
} else if (inst->opcode == BRW_OPCODE_WHILE) {
block_scale /= 10;
} else if (inst->is_3src(v->devinfo) &&
is_grf(inst->src[1]) && is_grf(inst->src[2])) {
const unsigned r = p.atom_of_reg(reg_of(inst->src[1]));
const unsigned s = p.atom_of_reg(reg_of(inst->src[2]));
/* Estimate of the cycle-count cost of incurring a bank conflict
* for this instruction. This is only true on the average, for a
* sequence of back-to-back ternary instructions, since the EU
* front-end only seems to be able to issue a new instruction at
* an even cycle. The cost of a bank conflict incurred by an
* isolated ternary instruction may be higher.
*/
const unsigned exec_size = inst->dst.component_size(inst->exec_size);
const unsigned cycle_scale = block_scale * DIV_ROUND_UP(exec_size,
REG_SIZE);
/* Neglect same-atom conflicts (since they're either trivial or
* impossible to avoid without splitting the atom), and conflicts
* known to be optimized out by the hardware.
*/
if (r != s && !is_conflict_optimized_out(v->devinfo, inst)) {
/* Calculate the parity of the sources relative to the start of
* their respective atoms. If their parity is the same (and
* none of the atoms straddle the 2KB mark), the instruction
* will incur a conflict iff both atoms are assigned the same
* bank b. If their parity is opposite, the instruction will
* incur a conflict iff they are assigned opposite banks (b and
* b^1).
*/
const bool p_r = 1 & (reg_of(inst->src[1]) - p.reg_of_atom(r));
const bool p_s = 1 & (reg_of(inst->src[2]) - p.reg_of_atom(s));
const unsigned p = p_r ^ p_s;
/* Calculate the updated cost of a hypothetical conflict
* between atoms r and s. Note that the weight matrix is
* symmetric with respect to indices r and s by construction.
*/
const scalar_type w = MIN2(unsigned(max_scalar),
get(conflicts[r], s, p) + cycle_scale);
set(conflicts[r], s, p, w);
set(conflicts[s], r, p, w);
}
}
}
return conflicts;
}
/**
* Return the set of GRF atoms that could potentially lead to bank
* conflicts if laid out unfavorably in the GRF space according to
* the specified \p conflicts matrix (\sa
* shader_conflict_weight_matrix()).
*/
bool *
have_any_conflicts(const partitioning &p,
const weight_vector_type *conflicts)
{
bool *any_conflicts = new bool[p.num_atoms()]();
for (unsigned r = 0; r < p.num_atoms(); r++) {
const unsigned m = DIV_ROUND_UP(conflicts[r].size, vector_width);
for (unsigned s = 0; s < m; s++)
any_conflicts[r] |= sums(conflicts[r].v[s]);
}
return any_conflicts;
}
/**
* Calculate the difference between two S(B) cost estimates as defined
* above (\sa shader_conflict_weight_matrix()). This represents the
* (partial) cycle-count benefit from moving an atom r from bank p to n.
* The respective bank assignments Bp and Bn are encoded as the \p
* bank_mask_p and \p bank_mask_n bitmasks for efficient computation,
* according to the formula:
*
* bank_mask(B)_s_p = -d_(p^B_r)_(B_s)
*
* Notice the similarity with the delta function in the S(B) expression
* above, and how bank_mask(B) can be precomputed for every possible
* selection of r since bank_mask(B) only depends on it via B_r that may
* only assume one of four different values, so the caller can keep every
* possible bank_mask(B) vector in memory without much hassle (\sa
* bank_characteristics()).
*/
int
delta_conflicts(const weight_vector_type &bank_mask_p,
const weight_vector_type &bank_mask_n,
const weight_vector_type &conflicts)
{
const unsigned m = DIV_ROUND_UP(conflicts.size, vector_width);
vector_type s_p = {}, s_n = {};
for (unsigned r = 0; r < m; r++) {
s_p = adds(s_p, mask(bank_mask_p.v[r], conflicts.v[r]));
s_n = adds(s_n, mask(bank_mask_n.v[r], conflicts.v[r]));
}
return sums(subs(s_p, s_n));
}
/**
* Register atom permutation, represented as the start GRF offset each atom
* is mapped into.
*/
struct permutation {
permutation() : v(NULL), size(0) {}
permutation(unsigned n) :
v(new unsigned[n]()), size(n) {}
permutation(const permutation &p) :
v(new unsigned[p.size]), size(p.size)
{
memcpy(v, p.v, p.size * sizeof(unsigned));
}
~permutation()
{
delete[] v;
}
permutation &
operator=(permutation p)
{
SWAP(v, p.v);
SWAP(size, p.size);
return *this;
}
unsigned *v;
unsigned size;
};
/**
* Return an identity permutation of GRF atoms.
*/
permutation
identity_reg_permutation(const partitioning &p)
{
permutation map(p.num_atoms());
for (unsigned r = 0; r < map.size; r++)
map.v[r] = p.reg_of_atom(r);
return map;
}
/**
* Return the bank index of GRF address \p reg, numbered according to the
* table:
* Even Odd
* Lo 0 1
* Hi 2 3
*/
unsigned
bank_of(unsigned reg)
{
return (reg & 0x40) >> 5 | (reg & 1);
}
/**
* Return bitmasks suitable for use as bank mask arguments for the
* delta_conflicts() computation. Note that this is just the (negative)
* characteristic function of each bank, if you regard it as a set
* containing all atoms assigned to it according to the \p map array.
*/
weight_vector_type *
bank_characteristics(const permutation &map)
{
weight_vector_type *banks = new weight_vector_type[4];
for (unsigned b = 0; b < 4; b++) {
banks[b] = weight_vector_type(2 * map.size);
for (unsigned j = 0; j < map.size; j++) {
for (unsigned p = 0; p < 2; p++)
set(banks[b], j, p,
(b ^ p) == bank_of(map.v[j]) ? -1 : 0);
}
}
return banks;
}
/**
* Return an improved permutation of GRF atoms based on \p map attempting
* to reduce the total cycle-count cost of bank conflicts greedily.
*
* Note that this doesn't attempt to merge multiple atoms into one, which
* may allow it to do a better job in some cases -- It simply reorders
* existing atoms in the GRF space without affecting their identity.
*/
permutation
optimize_reg_permutation(const partitioning &p,
const bool *constrained,
const weight_vector_type *conflicts,
permutation map)
{
const bool *any_conflicts = have_any_conflicts(p, conflicts);
weight_vector_type *banks = bank_characteristics(map);
for (unsigned r = 0; r < map.size; r++) {
const unsigned bank_r = bank_of(map.v[r]);
if (!constrained[r]) {
unsigned best_s = r;
int best_benefit = 0;
for (unsigned s = 0; s < map.size; s++) {
const unsigned bank_s = bank_of(map.v[s]);
if (bank_r != bank_s && !constrained[s] &&
p.size_of_atom(r) == p.size_of_atom(s) &&
(any_conflicts[r] || any_conflicts[s])) {
const int benefit =
delta_conflicts(banks[bank_r], banks[bank_s], conflicts[r]) +
delta_conflicts(banks[bank_s], banks[bank_r], conflicts[s]);
if (benefit > best_benefit) {
best_s = s;
best_benefit = benefit;
}
}
}
if (best_s != r) {
for (unsigned b = 0; b < 4; b++) {
for (unsigned p = 0; p < 2; p++)
swap(banks[b], r, p, best_s, p);
}
SWAP(map.v[r], map.v[best_s]);
}
}
}
delete[] banks;
delete[] any_conflicts;
return map;
}
/**
* Apply the GRF atom permutation given by \p map to register \p r and
* return the result.
*/
fs_reg
transform(const partitioning &p, const permutation &map, fs_reg r)
{
if (r.file == VGRF) {
const unsigned reg = reg_of(r);
const unsigned s = p.atom_of_reg(reg);
r.nr = map.v[s] + reg - p.reg_of_atom(s);
r.offset = r.offset % REG_SIZE;
}
return r;
}
}
bool
fs_visitor::opt_bank_conflicts()
{
assert(grf_used || !"Must be called after register allocation");
/* No ternary instructions -- No bank conflicts. */
if (devinfo->gen < 6)
return false;
const partitioning p = shader_reg_partitioning(this);
const bool *constrained = shader_reg_constraints(this, p);
const weight_vector_type *conflicts =
shader_conflict_weight_matrix(this, p);
const permutation map =
optimize_reg_permutation(p, constrained, conflicts,
identity_reg_permutation(p));
foreach_block_and_inst(block, fs_inst, inst, cfg) {
inst->dst = transform(p, map, inst->dst);
for (int i = 0; i < inst->sources; i++)
inst->src[i] = transform(p, map, inst->src[i]);
}
delete[] conflicts;
delete[] constrained;
return true;
}
/**
* Estimate the number of GRF bank conflict cycles incurred by an instruction.
*
* Note that this neglects conflict cycles prior to register allocation
* because we don't know which bank each VGRF is going to end up aligned to.
*/
unsigned
fs_visitor::bank_conflict_cycles(const fs_inst *inst) const
{
if (grf_used && inst->is_3src(devinfo) &&
is_grf(inst->src[1]) && is_grf(inst->src[2]) &&
bank_of(reg_of(inst->src[1])) == bank_of(reg_of(inst->src[2])) &&
!is_conflict_optimized_out(devinfo, inst)) {
return DIV_ROUND_UP(inst->dst.component_size(inst->exec_size), REG_SIZE);
} else {
return 0;
}
}