588cec7f91
GrRenderTargetOpList maintains an array of op chains. When it receives a new op it tries to add it to an existing chain, working backwards from the end of the current array. If the op can be added to a chain it additionally tries to merge the new op with ops already in the chain before adding it to the tail of the chain. In forward combining it tries to concatenate chains. If chains can concatenate it also attempts to merge ops between the two chains. Now op chaining results reported by Op subclasses must be transitive. Moreover, if op A is able to merge with B then it must be the case that any op that can chain with A will either merge or chain with any op that can chain to B. Bug: skia:8491 Change-Id: Ib6a2a669acd4257134a37d271289b8b3f247cd3f Reviewed-on: https://skia-review.googlesource.com/c/170351 Commit-Queue: Brian Salomon <bsalomon@google.com> Reviewed-by: Brian Osman <brianosman@google.com>
239 lines
9.4 KiB
C++
239 lines
9.4 KiB
C++
/*
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* Copyright 2018 Google Inc.
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*
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* Use of this source code is governed by a BSD-style license that can be
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* found in the LICENSE file.
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*/
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#include "GrContext.h"
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#include "GrContextPriv.h"
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#include "GrMemoryPool.h"
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#include "GrOpFlushState.h"
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#include "GrRenderTargetOpList.h"
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#include "Test.h"
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#include "ops/GrOp.h"
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// We create Ops that write a value into a range of a buffer. We create ranges from
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// kNumOpPositions starting positions x kRanges canonical ranges. We repeat each range kNumRepeats
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// times (with a different value written by each of the repeats).
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namespace {
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struct Range {
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unsigned fOffset;
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unsigned fLength;
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};
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static constexpr int kNumOpPositions = 4;
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static constexpr Range kRanges[] = {{0, 4,}, {1, 2}};
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static constexpr int kNumRanges = (int)SK_ARRAY_COUNT(kRanges);
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static constexpr int kNumRepeats = 2;
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static constexpr int kNumOps = kNumRepeats * kNumOpPositions * kNumRanges;
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static constexpr uint64_t fact(int n) {
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assert(n > 0);
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return n > 1 ? n * fact(n - 1) : 1;
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}
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// How wide should our result buffer be to hold values written by the ranges of the ops.
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static constexpr unsigned result_width() {
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unsigned maxLength = 0;
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for (size_t i = 0; i < kNumRanges; ++i) {
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maxLength = maxLength > kRanges[i].fLength ? maxLength : kRanges[i].fLength;
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}
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return kNumOpPositions + maxLength - 1;
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}
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// Number of possible allowable binary chainings among the kNumOps ops.
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static constexpr int kNumCombinableValues = fact(kNumOps) / fact(kNumOps - 2);
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using Combinable = std::array<GrOp::CombineResult, kNumCombinableValues>;
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/**
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* The index in Combinable for the result for combining op 'b' into op 'a', i.e. the result of
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* op[a]->combineIfPossible(op[b]).
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*/
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int64_t combinable_index(int a, int b) {
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SkASSERT(b != a);
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// Each index gets kNumOps - 1 contiguous bools
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int64_t aOffset = a * (kNumOps - 1);
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// Within a's range we have one value each other op, but not one for a itself.
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int64_t bIdxInA = b < a ? b : b - 1;
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return aOffset + bIdxInA;
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}
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/**
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* Creates a legal set of combinability results for the ops. The likelihood that any two ops
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* in a group can merge is randomly chosen.
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*/
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static void init_combinable(int numGroups, Combinable* combinable, SkRandom* random) {
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SkScalar mergeProbability = random->nextUScalar1();
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std::fill_n(combinable->begin(), kNumCombinableValues, GrOp::CombineResult::kCannotCombine);
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SkTDArray<int> groups[kNumOps];
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for (int i = 0; i < kNumOps; ++i) {
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auto& group = groups[random->nextULessThan(numGroups)];
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for (int g = 0; g < group.count(); ++g) {
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int j = group[g];
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if (random->nextUScalar1() < mergeProbability) {
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(*combinable)[combinable_index(i, j)] = GrOp::CombineResult::kMerged;
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} else {
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(*combinable)[combinable_index(i, j)] = GrOp::CombineResult::kMayChain;
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}
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if (random->nextUScalar1() < mergeProbability) {
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(*combinable)[combinable_index(j, i)] = GrOp::CombineResult::kMerged;
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} else {
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(*combinable)[combinable_index(j, i)] = GrOp::CombineResult::kMayChain;
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}
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}
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group.push_back(i);
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}
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}
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/**
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* A simple test op. It has an integer position, p. When it executes it writes p into an array
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* of ints at index p and p+1. It takes a bitfield that indicates allowed pair-wise chainings.
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*/
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class TestOp : public GrOp {
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public:
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DEFINE_OP_CLASS_ID
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static std::unique_ptr<TestOp> Make(GrContext* context, int value, const Range& range,
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int result[], const Combinable* combinable) {
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GrOpMemoryPool* pool = context->contextPriv().opMemoryPool();
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return pool->allocate<TestOp>(value, range, result, combinable);
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}
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const char* name() const override { return "TestOp"; }
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void writeResult(int result[]) const {
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for (const auto& op : ChainRange<TestOp>(this)) {
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for (const auto& vr : op.fValueRanges) {
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for (unsigned i = 0; i < vr.fRange.fLength; ++i) {
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result[vr.fRange.fOffset + i] = vr.fValue;
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}
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}
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}
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}
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private:
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friend class ::GrOpMemoryPool; // for ctor
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TestOp(int value, const Range& range, int result[], const Combinable* combinable)
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: INHERITED(ClassID()), fResult(result), fCombinable(combinable) {
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fValueRanges.push_back({value, range});
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this->setBounds(SkRect::MakeXYWH(range.fOffset, 0, range.fOffset + range.fLength, 1),
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HasAABloat::kNo, IsZeroArea::kNo);
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}
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void onPrepare(GrOpFlushState*) override {}
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void onExecute(GrOpFlushState*, const SkRect& chainBounds) override {
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for (auto& op : ChainRange<TestOp>(this)) {
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op.writeResult(fResult);
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}
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}
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CombineResult onCombineIfPossible(GrOp* t, const GrCaps&) override {
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auto that = t->cast<TestOp>();
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int v0 = fValueRanges[0].fValue;
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int v1 = that->fValueRanges[0].fValue;
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auto result = (*fCombinable)[combinable_index(v0, v1)];
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if (result == GrOp::CombineResult::kMerged) {
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std::move(that->fValueRanges.begin(), that->fValueRanges.end(),
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std::back_inserter(fValueRanges));
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}
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return result;
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}
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struct ValueRange {
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int fValue;
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Range fRange;
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};
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std::vector<ValueRange> fValueRanges;
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int* fResult;
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const Combinable* fCombinable;
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typedef GrOp INHERITED;
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};
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} // namespace
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/**
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* Tests adding kNumOps to an op list with all possible allowed chaining configurations. Tests
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* adding the ops in all possible orders and verifies that the chained executions don't violate
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* painter's order.
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*/
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DEF_GPUTEST(OpChainTest, reporter, /*ctxInfo*/) {
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auto context = GrContext::MakeMock(nullptr);
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SkASSERT(context);
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GrSurfaceDesc desc;
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desc.fConfig = kRGBA_8888_GrPixelConfig;
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desc.fWidth = kNumOps + 1;
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desc.fHeight = 1;
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desc.fFlags = kRenderTarget_GrSurfaceFlag;
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auto proxy = context->contextPriv().proxyProvider()->createProxy(
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desc, kTopLeft_GrSurfaceOrigin, GrMipMapped::kNo, SkBackingFit::kExact, SkBudgeted::kNo,
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GrInternalSurfaceFlags::kNone);
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SkASSERT(proxy);
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proxy->instantiate(context->contextPriv().resourceProvider());
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int result[result_width()];
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int validResult[result_width()];
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int permutation[kNumOps];
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for (int i = 0; i < kNumOps; ++i) {
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permutation[i] = i;
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}
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// Op order permutations.
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static constexpr int kNumPermutations = 100;
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// For a given number of chainability groups, this is the number of random combinability reuslts
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// we will test.
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static constexpr int kNumCombinabilitiesPerGrouping = 20;
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SkRandom random;
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bool repeat = false;
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Combinable combinable;
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for (int p = 0; p < kNumPermutations; ++p) {
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for (int i = 0; i < kNumOps - 2 && !repeat; ++i) {
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// The current implementation of nextULessThan() is biased. :(
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unsigned j = i + random.nextULessThan(kNumOps - i);
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std::swap(permutation[i], permutation[j]);
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}
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// g is the number of chainable groups that we partition the ops into.
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for (int g = 1; g < kNumOps; ++g) {
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for (int c = 0; c < kNumCombinabilitiesPerGrouping; ++c) {
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init_combinable(g, &combinable, &random);
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GrTokenTracker tracker;
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GrOpFlushState flushState(context->contextPriv().getGpu(),
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context->contextPriv().resourceProvider(), &tracker,
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nullptr, nullptr);
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GrRenderTargetOpList opList(context->contextPriv().resourceProvider(),
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sk_ref_sp(context->contextPriv().opMemoryPool()),
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proxy->asRenderTargetProxy(),
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context->contextPriv().getAuditTrail());
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// This assumes the particular values of kRanges.
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std::fill_n(result, result_width(), -1);
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std::fill_n(validResult, result_width(), -1);
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for (int i = 0; i < kNumOps; ++i) {
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int value = permutation[i];
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// factor out the repeats and then use the canonical starting position and range
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// to determine an actual range.
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int j = value % (kNumRanges * kNumOpPositions);
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int pos = j % kNumOpPositions;
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Range range = kRanges[j / kNumOpPositions];
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range.fOffset += pos;
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auto op = TestOp::Make(context.get(), value, range, result, &combinable);
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op->writeResult(validResult);
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opList.addOp(std::move(op), *context->contextPriv().caps());
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}
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opList.makeClosed(*context->contextPriv().caps());
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opList.prepare(&flushState);
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opList.execute(&flushState);
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opList.endFlush();
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#if 0 // Useful to repeat a random configuration that fails the test while debugger attached.
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if (!std::equal(result, result + result_width(), validResult)) {
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repeat = true;
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}
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#endif
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(void)repeat;
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REPORTER_ASSERT(reporter, std::equal(result, result + result_width(), validResult));
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}
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}
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}
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}
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