MLIR 22.0.0git
AMDGPUToROCDL.cpp
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1//===- AMDGPUToROCDL.cpp - AMDGPU to ROCDL dialect conversion -------===//
2//
3// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
4// See https://llvm.org/LICENSE.txt for license information.
5// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
6//
7//===----------------------------------------------------------------------===//
8
9#include "mlir/Conversion/AMDGPUToROCDL/AMDGPUToROCDL.h"
10
11#include "mlir/Conversion/GPUCommon/GPUCommonPass.h"
12#include "mlir/Conversion/LLVMCommon/ConversionTarget.h"
13#include "mlir/Conversion/LLVMCommon/Pattern.h"
14#include "mlir/Conversion/LLVMCommon/TypeConverter.h"
15#include "mlir/Dialect/AMDGPU/IR/AMDGPUDialect.h"
16#include "mlir/Dialect/AMDGPU/Utils/Chipset.h"
17#include "mlir/Dialect/LLVMIR/LLVMDialect.h"
18#include "mlir/Dialect/LLVMIR/LLVMTypes.h"
19#include "mlir/Dialect/LLVMIR/ROCDLDialect.h"
20#include "mlir/IR/Attributes.h"
21#include "mlir/IR/BuiltinAttributes.h"
22#include "mlir/IR/BuiltinTypes.h"
23#include "mlir/IR/Matchers.h"
24#include "mlir/IR/TypeUtilities.h"
25#include "mlir/Pass/Pass.h"
26
27#include "../LLVMCommon/MemRefDescriptor.h"
28
29#include "llvm/ADT/STLExtras.h"
30#include "llvm/ADT/TypeSwitch.h"
31#include "llvm/Support/Casting.h"
32#include "llvm/Support/ErrorHandling.h"
33#include <optional>
34
35namespace mlir {
36#define GEN_PASS_DEF_CONVERTAMDGPUTOROCDLPASS
37#include "mlir/Conversion/Passes.h.inc"
38} // namespace mlir
39
40using namespace mlir;
41using namespace mlir::amdgpu;
42
43// Define commonly used chipsets versions for convenience.
44constexpr Chipset kGfx908 = Chipset(9, 0, 8);
45constexpr Chipset kGfx90a = Chipset(9, 0, 0xa);
46constexpr Chipset kGfx942 = Chipset(9, 4, 2);
47constexpr Chipset kGfx950 = Chipset(9, 5, 0);
48constexpr Chipset kGfx1250 = Chipset(12, 5, 0);
49
50/// Convert an unsigned number `val` to i32.
51static Value convertUnsignedToI32(ConversionPatternRewriter &rewriter,
52 Location loc, Value val) {
53 IntegerType i32 = rewriter.getI32Type();
54 // Force check that `val` is of int type.
55 auto valTy = cast<IntegerType>(val.getType());
56 if (i32 == valTy)
57 return val;
58 return valTy.getWidth() > 32
59 ? Value(LLVM::TruncOp::create(rewriter, loc, i32, val))
60 : Value(LLVM::ZExtOp::create(rewriter, loc, i32, val));
61}
62
63static Value createI32Constant(ConversionPatternRewriter &rewriter,
64 Location loc, int32_t value) {
65 return LLVM::ConstantOp::create(rewriter, loc, rewriter.getI32Type(), value);
66}
67
68/// Convert an unsigned number `val` to i64.
69static Value convertUnsignedToI64(ConversionPatternRewriter &rewriter,
70 Location loc, Value val) {
71 IntegerType i64 = rewriter.getI64Type();
72 // Force check that `val` is of int type.
73 auto valTy = cast<IntegerType>(val.getType());
74 if (i64 == valTy)
75 return val;
76 return valTy.getWidth() > 64
77 ? Value(LLVM::TruncOp::create(rewriter, loc, i64, val))
78 : Value(LLVM::ZExtOp::create(rewriter, loc, i64, val));
79}
80
81static Value createI64Constant(ConversionPatternRewriter &rewriter,
82 Location loc, int64_t value) {
83 return LLVM::ConstantOp::create(rewriter, loc, rewriter.getI64Type(), value);
84}
85
86/// Returns the linear index used to access an element in the memref.
87static Value getLinearIndexI32(ConversionPatternRewriter &rewriter,
88 Location loc, MemRefDescriptor &memRefDescriptor,
89 ValueRange indices, ArrayRef<int64_t> strides) {
90 IntegerType i32 = rewriter.getI32Type();
91 Value index;
92 for (auto [i, increment, stride] : llvm::enumerate(indices, strides)) {
93 if (stride != 1) { // Skip if stride is 1.
94 Value strideValue =
95 ShapedType::isDynamic(stride)
96 ? convertUnsignedToI32(rewriter, loc,
97 memRefDescriptor.stride(rewriter, loc, i))
98 : LLVM::ConstantOp::create(rewriter, loc, i32, stride);
99 increment = LLVM::MulOp::create(rewriter, loc, increment, strideValue);
100 }
101 index = index ? LLVM::AddOp::create(rewriter, loc, index, increment)
102 : increment;
103 }
104 return index ? index : createI32Constant(rewriter, loc, 0);
105}
106
107/// Compute the contents of the `num_records` field for a given memref
108/// descriptor - that is, the number of bytes that's one element past the
109/// greatest possible valid index into the memref.
110static Value getNumRecords(ConversionPatternRewriter &rewriter, Location loc,
111 MemRefType memrefType,
112 MemRefDescriptor &memrefDescriptor,
113 ArrayRef<int64_t> strides,
114 int64_t elementByteWidth) {
115 if (memrefType.hasStaticShape() &&
116 !llvm::any_of(strides, ShapedType::isDynamic)) {
117 int64_t size = memrefType.getRank() == 0 ? 1 : 0;
118 ArrayRef<int64_t> shape = memrefType.getShape();
119 for (uint32_t i = 0, e = memrefType.getRank(); i < e; ++i)
120 size = std::max(shape[i] * strides[i], size);
121 size = size * elementByteWidth;
122 return createI64Constant(rewriter, loc, size);
123 }
124 Value maxIndex;
125 for (uint32_t i = 0, e = memrefType.getRank(); i < e; ++i) {
126 Value size = memrefDescriptor.size(rewriter, loc, i);
127 Value stride = memrefDescriptor.stride(rewriter, loc, i);
128 Value maxThisDim = LLVM::MulOp::create(rewriter, loc, size, stride);
129 maxIndex = maxIndex
130 ? LLVM::UMaxOp::create(rewriter, loc, maxIndex, maxThisDim)
131 : maxThisDim;
132 }
133 Value maxIndexI64 = convertUnsignedToI64(rewriter, loc, maxIndex);
134 Value byteWidthConst = createI64Constant(rewriter, loc, elementByteWidth);
135 return LLVM::MulOp::create(rewriter, loc, maxIndexI64, byteWidthConst);
136}
137
138static Value makeBufferRsrc(ConversionPatternRewriter &rewriter, Location loc,
139 Value basePointer, Value numRecords,
140 bool boundsCheck, amdgpu::Chipset chipset,
141 Value cacheSwizzleStride = nullptr,
142 unsigned addressSpace = 8) {
143 // The stride value is generally 0. However, on MI-300 and onward, you can
144 // enable a cache swizzling mode by setting bit 14 of the stride field
145 // and setting that stride to a cache stride.
146 Type i16 = rewriter.getI16Type();
147 Value stride;
148 if (chipset.majorVersion == 9 && chipset >= kGfx942 && cacheSwizzleStride) {
149 Value cacheStrideZext =
150 LLVM::ZExtOp::create(rewriter, loc, i16, cacheSwizzleStride);
151 Value swizzleBit = LLVM::ConstantOp::create(
152 rewriter, loc, i16, rewriter.getI16IntegerAttr(1 << 14));
153 stride = LLVM::OrOp::create(rewriter, loc, cacheStrideZext, swizzleBit,
154 /*isDisjoint=*/true);
155 } else {
156 stride = LLVM::ConstantOp::create(rewriter, loc, i16,
157 rewriter.getI16IntegerAttr(0));
158 }
159 // Get the number of elements.
160 // Flag word:
161 // bits 0-11: dst sel, ignored by these intrinsics
162 // bits 12-14: data format (ignored, must be nonzero, 7=float)
163 // bits 15-18: data format (ignored, must be nonzero, 4=32bit)
164 // bit 19: In nested heap (0 here)
165 // bit 20: Behavior on unmap (0 means "return 0 / ignore")
166 // bits 21-22: Index stride for swizzles (N/A)
167 // bit 23: Add thread ID (0)
168 // bit 24: Reserved to 1 (RDNA) or 0 (CDNA)
169 // bits 25-26: Reserved (0)
170 // bit 27: Buffer is non-volatile (CDNA only)
171 // bits 28-29: Out of bounds select (0 = structured, 1 = check index, 2 =
172 // none, 3 = either swizzles or testing against offset field) RDNA only
173 // bits 30-31: Type (must be 0)
174 uint32_t flags = (7 << 12) | (4 << 15);
175 if (chipset.majorVersion >= 10) {
176 flags |= (1 << 24);
177 uint32_t oob = boundsCheck ? 3 : 2;
178 flags |= (oob << 28);
179 }
180 Value flagsConst = createI32Constant(rewriter, loc, flags);
181 Type rsrcType =
182 LLVM::LLVMPointerType::get(rewriter.getContext(), addressSpace);
183 Value resource = rewriter.createOrFold<ROCDL::MakeBufferRsrcOp>(
184 loc, rsrcType, basePointer, stride, numRecords, flagsConst);
185 return resource;
186}
187
188namespace {
189struct FatRawBufferCastLowering
190 : public ConvertOpToLLVMPattern<FatRawBufferCastOp> {
191 FatRawBufferCastLowering(const LLVMTypeConverter &converter, Chipset chipset)
192 : ConvertOpToLLVMPattern<FatRawBufferCastOp>(converter),
193 chipset(chipset) {}
194
195 Chipset chipset;
196
197 LogicalResult
198 matchAndRewrite(FatRawBufferCastOp op, FatRawBufferCastOpAdaptor adaptor,
199 ConversionPatternRewriter &rewriter) const override {
200 Location loc = op.getLoc();
201 Value memRef = adaptor.getSource();
202 Value unconvertedMemref = op.getSource();
203 MemRefType memrefType = cast<MemRefType>(unconvertedMemref.getType());
204 MemRefDescriptor descriptor(memRef);
205
206 DataLayout dataLayout = DataLayout::closest(op);
207 int64_t elementByteWidth =
208 dataLayout.getTypeSizeInBits(memrefType.getElementType()) / 8;
209
210 int64_t unusedOffset = 0;
211 SmallVector<int64_t, 5> strideVals;
212 if (failed(memrefType.getStridesAndOffset(strideVals, unusedOffset)))
213 return op.emitOpError("Can't lower non-stride-offset memrefs");
214
215 Value numRecords = adaptor.getValidBytes();
216 if (!numRecords)
217 numRecords = getNumRecords(rewriter, loc, memrefType, descriptor,
218 strideVals, elementByteWidth);
219
220 Value basePointer =
221 adaptor.getResetOffset()
222 ? descriptor.bufferPtr(rewriter, loc, *getTypeConverter(),
223 memrefType)
224 : descriptor.alignedPtr(rewriter, loc);
225
226 Value offset = adaptor.getResetOffset()
227 ? LLVM::ConstantOp::create(rewriter, loc, getIndexType(),
228 rewriter.getIndexAttr(0))
229 : descriptor.offset(rewriter, loc);
230
231 bool hasSizes = memrefType.getRank() > 0;
232 // No need to unpack() and pack() all the individual sizes and strides,
233 // so we'll just extract the arrays.
234 Value sizes = hasSizes
235 ? LLVM::ExtractValueOp::create(rewriter, loc, descriptor,
236 kSizePosInMemRefDescriptor)
237 : Value{};
238 Value strides =
239 hasSizes ? LLVM::ExtractValueOp::create(rewriter, loc, descriptor,
240 kStridePosInMemRefDescriptor)
241 : Value{};
242
243 Value fatPtr = makeBufferRsrc(
244 rewriter, loc, basePointer, numRecords, adaptor.getBoundsCheck(),
245 chipset, adaptor.getCacheSwizzleStride(), /*addressSpace=*/7);
246
247 Value result = MemRefDescriptor::poison(
248 rewriter, loc,
249 getTypeConverter()->convertType(op.getResult().getType()));
250 SmallVector<int64_t> pos{kAllocatedPtrPosInMemRefDescriptor};
251 result = LLVM::InsertValueOp::create(rewriter, loc, result, fatPtr, pos);
252 result = LLVM::InsertValueOp::create(rewriter, loc, result, fatPtr,
253 kAlignedPtrPosInMemRefDescriptor);
254 result = LLVM::InsertValueOp::create(rewriter, loc, result, offset,
255 kOffsetPosInMemRefDescriptor);
256 if (hasSizes) {
257 result = LLVM::InsertValueOp::create(rewriter, loc, result, sizes,
258 kSizePosInMemRefDescriptor);
259 result = LLVM::InsertValueOp::create(rewriter, loc, result, strides,
260 kStridePosInMemRefDescriptor);
261 }
262 rewriter.replaceOp(op, result);
263 return success();
264 }
265};
266
267/// Define lowering patterns for raw buffer ops
268template <typename GpuOp, typename Intrinsic>
269struct RawBufferOpLowering : public ConvertOpToLLVMPattern<GpuOp> {
270 RawBufferOpLowering(const LLVMTypeConverter &converter, Chipset chipset)
271 : ConvertOpToLLVMPattern<GpuOp>(converter), chipset(chipset) {}
272
273 Chipset chipset;
274 static constexpr uint32_t maxVectorOpWidth = 128;
275
276 LogicalResult
277 matchAndRewrite(GpuOp gpuOp, typename GpuOp::Adaptor adaptor,
278 ConversionPatternRewriter &rewriter) const override {
279 Location loc = gpuOp.getLoc();
280 Value memref = adaptor.getMemref();
281 Value unconvertedMemref = gpuOp.getMemref();
282 MemRefType memrefType = cast<MemRefType>(unconvertedMemref.getType());
283
284 if (chipset.majorVersion < 9)
285 return gpuOp.emitOpError("raw buffer ops require GCN or higher");
286
287 Value storeData = adaptor.getODSOperands(0)[0];
288 if (storeData == memref) // no write component to this op
289 storeData = Value();
290 Type wantedDataType;
291 if (storeData)
292 wantedDataType = storeData.getType();
293 else
294 wantedDataType = gpuOp.getODSResults(0)[0].getType();
295
296 Value atomicCmpData = Value();
297 // Operand index 1 of a load is the indices, trying to read them can crash.
298 if (storeData) {
299 Value maybeCmpData = adaptor.getODSOperands(1)[0];
300 if (maybeCmpData != memref)
301 atomicCmpData = maybeCmpData;
302 }
303
304 Type llvmWantedDataType = this->typeConverter->convertType(wantedDataType);
305
306 Type i32 = rewriter.getI32Type();
307
308 // Get the type size in bytes.
309 DataLayout dataLayout = DataLayout::closest(gpuOp);
310 int64_t elementByteWidth =
311 dataLayout.getTypeSizeInBits(memrefType.getElementType()) / 8;
312 Value byteWidthConst = createI32Constant(rewriter, loc, elementByteWidth);
313
314 // If we want to load a vector<NxT> with total size <= 32
315 // bits, use a scalar load and bitcast it. Similarly, if bitsize(T) < 32
316 // and the total load size is >= 32, use a vector load of N / (bitsize(T) /
317 // 32) x i32 and bitcast. Also, the CAS intrinsic requires integer operands,
318 // so bitcast any floats to integers.
319 Type llvmBufferValType = llvmWantedDataType;
320 if (atomicCmpData) {
321 if (auto floatType = dyn_cast<FloatType>(wantedDataType))
322 llvmBufferValType = this->getTypeConverter()->convertType(
323 rewriter.getIntegerType(floatType.getWidth()));
324 }
325 if (auto dataVector = dyn_cast<VectorType>(wantedDataType)) {
326 uint32_t vecLen = dataVector.getNumElements();
327 uint32_t elemBits =
328 dataLayout.getTypeSizeInBits(dataVector.getElementType());
329 uint32_t totalBits = elemBits * vecLen;
330 bool usePackedFp16 =
331 isa_and_present<RawBufferAtomicFaddOp>(*gpuOp) && vecLen == 2;
332 if (totalBits > maxVectorOpWidth)
333 return gpuOp.emitOpError(
334 "Total width of loads or stores must be no more than " +
335 Twine(maxVectorOpWidth) + " bits, but we call for " +
336 Twine(totalBits) +
337 " bits. This should've been caught in validation");
338 if (!usePackedFp16 && elemBits < 32) {
339 if (totalBits > 32) {
340 if (totalBits % 32 != 0)
341 return gpuOp.emitOpError("Load or store of more than 32-bits that "
342 "doesn't fit into words. Can't happen\n");
343 llvmBufferValType = this->typeConverter->convertType(
344 VectorType::get(totalBits / 32, i32));
345 } else {
346 llvmBufferValType = this->typeConverter->convertType(
347 rewriter.getIntegerType(totalBits));
348 }
349 }
350 }
351 if (auto vecType = dyn_cast<VectorType>(llvmBufferValType)) {
352 // Buffer intrinsics doesn't support 1-element vectors, cast them to
353 // scalars.
354 if (vecType.getNumElements() == 1)
355 llvmBufferValType = vecType.getElementType();
356 }
357
358 SmallVector<Value, 6> args;
359 if (storeData) {
360 if (llvmBufferValType != llvmWantedDataType) {
361 Value castForStore = LLVM::BitcastOp::create(
362 rewriter, loc, llvmBufferValType, storeData);
363 args.push_back(castForStore);
364 } else {
365 args.push_back(storeData);
366 }
367 }
368
369 if (atomicCmpData) {
370 if (llvmBufferValType != llvmWantedDataType) {
371 Value castForCmp = LLVM::BitcastOp::create(
372 rewriter, loc, llvmBufferValType, atomicCmpData);
373 args.push_back(castForCmp);
374 } else {
375 args.push_back(atomicCmpData);
376 }
377 }
378
379 // Construct buffer descriptor from memref, attributes
380 int64_t offset = 0;
381 SmallVector<int64_t, 5> strides;
382 if (failed(memrefType.getStridesAndOffset(strides, offset)))
383 return gpuOp.emitOpError("Can't lower non-stride-offset memrefs");
384
385 MemRefDescriptor memrefDescriptor(memref);
386
387 Value ptr = memrefDescriptor.bufferPtr(
388 rewriter, loc, *this->getTypeConverter(), memrefType);
389 Value numRecords = getNumRecords(
390 rewriter, loc, memrefType, memrefDescriptor, strides, elementByteWidth);
391 Value resource = makeBufferRsrc(rewriter, loc, ptr, numRecords,
392 adaptor.getBoundsCheck(), chipset);
393 args.push_back(resource);
394
395 // Indexing (voffset)
396 Value voffset = getLinearIndexI32(rewriter, loc, memrefDescriptor,
397 adaptor.getIndices(), strides);
398 if (std::optional<int32_t> indexOffset = adaptor.getIndexOffset();
399 indexOffset && *indexOffset > 0) {
400 Value extraOffsetConst = createI32Constant(rewriter, loc, *indexOffset);
401 voffset = voffset ? LLVM::AddOp::create(rewriter, loc, voffset,
402 extraOffsetConst)
403 : extraOffsetConst;
404 }
405 voffset = LLVM::MulOp::create(rewriter, loc, voffset, byteWidthConst);
406 args.push_back(voffset);
407
408 // SGPR offset.
409 Value sgprOffset = adaptor.getSgprOffset();
410 if (!sgprOffset)
411 sgprOffset = createI32Constant(rewriter, loc, 0);
412 sgprOffset = LLVM::MulOp::create(rewriter, loc, sgprOffset, byteWidthConst);
413 args.push_back(sgprOffset);
414
415 // bit 0: GLC = 0 (atomics drop value, less coherency)
416 // bits 1-2: SLC, DLC = 0 (similarly)
417 // bit 3: swizzled (0 for raw)
418 args.push_back(createI32Constant(rewriter, loc, 0));
419
420 llvm::SmallVector<Type, 1> resultTypes(gpuOp->getNumResults(),
421 llvmBufferValType);
422 Operation *lowered = Intrinsic::create(rewriter, loc, resultTypes, args,
423 ArrayRef<NamedAttribute>());
424 if (lowered->getNumResults() == 1) {
425 Value replacement = lowered->getResult(0);
426 if (llvmBufferValType != llvmWantedDataType) {
427 replacement = LLVM::BitcastOp::create(rewriter, loc, llvmWantedDataType,
428 replacement);
429 }
430 rewriter.replaceOp(gpuOp, replacement);
431 } else {
432 rewriter.eraseOp(gpuOp);
433 }
434 return success();
435 }
436};
437
438// TODO: AMDGPU backend already have all this bitpacking logic, we should move
439// it to some common place.
440/// Vmcnt, Expcnt and Lgkmcnt are decoded as follows:
441/// Vmcnt = Waitcnt[3:0] (pre-gfx9)
442/// Vmcnt = Waitcnt[15:14,3:0] (gfx9,10)
443/// Vmcnt = Waitcnt[15:10] (gfx11)
444/// Expcnt = Waitcnt[6:4] (pre-gfx11)
445/// Expcnt = Waitcnt[2:0] (gfx11)
446/// Lgkmcnt = Waitcnt[11:8] (pre-gfx10)
447/// Lgkmcnt = Waitcnt[13:8] (gfx10)
448/// Lgkmcnt = Waitcnt[9:4] (gfx11)
449static FailureOr<unsigned> encodeWaitcnt(Chipset chipset, unsigned vmcnt,
450 unsigned expcnt, unsigned lgkmcnt) {
451 if (chipset.majorVersion < 9) {
452 vmcnt = std::min(15u, vmcnt);
453 expcnt = std::min(7u, expcnt);
454 lgkmcnt = std::min(15u, lgkmcnt);
455 return vmcnt | (expcnt << 4) | (lgkmcnt << 8);
456 }
457 if (chipset.majorVersion == 9) {
458 vmcnt = std::min(63u, vmcnt);
459 expcnt = std::min(7u, expcnt);
460 lgkmcnt = std::min(15u, lgkmcnt);
461 unsigned lowBits = vmcnt & 0xF;
462 unsigned highBits = (vmcnt >> 4) << 14;
463 unsigned otherCnts = (expcnt << 4) | (lgkmcnt << 8);
464 return lowBits | highBits | otherCnts;
465 }
466 if (chipset.majorVersion == 10) {
467 vmcnt = std::min(63u, vmcnt);
468 expcnt = std::min(7u, expcnt);
469 lgkmcnt = std::min(63u, lgkmcnt);
470 unsigned lowBits = vmcnt & 0xF;
471 unsigned highBits = (vmcnt >> 4) << 14;
472 unsigned otherCnts = (expcnt << 4) | (lgkmcnt << 8);
473 return lowBits | highBits | otherCnts;
474 }
475 if (chipset.majorVersion == 11) {
476 vmcnt = std::min(63u, vmcnt);
477 expcnt = std::min(7u, expcnt);
478 lgkmcnt = std::min(63u, lgkmcnt);
479 return (vmcnt << 10) | expcnt | (lgkmcnt << 4);
480 }
481 return failure();
482}
483
484struct MemoryCounterWaitOpLowering
485 : public ConvertOpToLLVMPattern<MemoryCounterWaitOp> {
486 MemoryCounterWaitOpLowering(const LLVMTypeConverter &converter,
487 Chipset chipset)
488 : ConvertOpToLLVMPattern<MemoryCounterWaitOp>(converter),
489 chipset(chipset) {}
490
491 Chipset chipset;
492
493 LogicalResult
494 matchAndRewrite(MemoryCounterWaitOp op, OpAdaptor adaptor,
495 ConversionPatternRewriter &rewriter) const override {
496 if (chipset.majorVersion >= 12) {
497 Location loc = op.getLoc();
498 if (std::optional<int> ds = adaptor.getDs())
499 ROCDL::WaitDscntOp::create(rewriter, loc, *ds);
500
501 if (std::optional<int> load = adaptor.getLoad())
502 ROCDL::WaitLoadcntOp::create(rewriter, loc, *load);
503
504 if (std::optional<int> store = adaptor.getStore())
505 ROCDL::WaitStorecntOp::create(rewriter, loc, *store);
506
507 if (std::optional<int> exp = adaptor.getExp())
508 ROCDL::WaitExpcntOp::create(rewriter, loc, *exp);
509
510 if (std::optional<int> tensor = adaptor.getTensor())
511 ROCDL::WaitTensorcntOp::create(rewriter, loc, *tensor);
512
513 rewriter.eraseOp(op);
514 return success();
515 }
516
517 if (adaptor.getTensor())
518 return op.emitOpError("unsupported chipset");
519
520 auto getVal = [](Attribute attr) -> unsigned {
521 if (attr)
522 return cast<IntegerAttr>(attr).getInt();
523
524 // This value will be clamped to the maximum value for the chipset.
525 return 1024;
526 };
527 unsigned ds = getVal(adaptor.getDsAttr());
528 unsigned exp = getVal(adaptor.getExpAttr());
529
530 unsigned vmcnt = 1024;
531 Attribute load = adaptor.getLoadAttr();
532 Attribute store = adaptor.getStoreAttr();
533 if (load && store) {
534 vmcnt = getVal(load) + getVal(store);
535 } else if (load) {
536 vmcnt = getVal(load);
537 } else if (store) {
538 vmcnt = getVal(store);
539 }
540
541 FailureOr<unsigned> waitcnt = encodeWaitcnt(chipset, vmcnt, exp, ds);
542 if (failed(waitcnt))
543 return op.emitOpError("unsupported chipset");
544
545 rewriter.replaceOpWithNewOp<ROCDL::SWaitcntOp>(op, *waitcnt);
546 return success();
547 }
548};
549
550struct LDSBarrierOpLowering : public ConvertOpToLLVMPattern<LDSBarrierOp> {
551 LDSBarrierOpLowering(const LLVMTypeConverter &converter, Chipset chipset)
552 : ConvertOpToLLVMPattern<LDSBarrierOp>(converter), chipset(chipset) {}
553
554 Chipset chipset;
555
556 LogicalResult
557 matchAndRewrite(LDSBarrierOp op, LDSBarrierOp::Adaptor adaptor,
558 ConversionPatternRewriter &rewriter) const override {
559 Location loc = op.getLoc();
560 // This ensures that waits on global memory aren't introduced on
561 // chips that don't have the BackOffBarrier feature enabled in LLVM.
562 bool requiresInlineAsm = chipset < kGfx90a;
563
564 Attribute mmra =
565 rewriter.getAttr<LLVM::MMRATagAttr>("amdgpu-synchronize-as", "local");
566 // Note: while there *is* a workgroup-one-as scope, this, when combined with
567 // the MMRA, will lead to the fence having no effect. This is because the
568 // codepaths for an atomic load or store will observe that a
569 // one-address-space atomic to LDS requires no synchronization because
570 // operations on LDS are totally ordered with respect to each other, and so
571 // will not emit the correct waitcnt operations that these fences are
572 // intended to produce. Therefore, we use a broader type of fence and rely
573 // on the MMRA to relax it to the semantics we want.
574 StringRef scope = "workgroup";
575
576 auto relFence = LLVM::FenceOp::create(rewriter, loc,
577 LLVM::AtomicOrdering::release, scope);
578 relFence->setDiscardableAttr(LLVM::LLVMDialect::getMmraAttrName(), mmra);
579 if (requiresInlineAsm) {
580 auto asmDialectAttr = LLVM::AsmDialectAttr::get(rewriter.getContext(),
581 LLVM::AsmDialect::AD_ATT);
582 const char *asmStr = ";;;WARNING: BREAKS DEBUG WATCHES\ns_barrier";
583 const char *constraints = "";
584 LLVM::InlineAsmOp::create(
585 rewriter, loc,
586 /*resultTypes=*/TypeRange(), /*operands=*/ValueRange(),
587 /*asm_string=*/asmStr, constraints, /*has_side_effects=*/true,
588 /*is_align_stack=*/false, LLVM::TailCallKind::None,
589 /*asm_dialect=*/asmDialectAttr,
590 /*operand_attrs=*/ArrayAttr());
591 } else if (chipset.majorVersion < 12) {
592 ROCDL::SBarrierOp::create(rewriter, loc);
593 } else {
594 ROCDL::BarrierSignalOp::create(rewriter, loc, -1);
595 ROCDL::BarrierWaitOp::create(rewriter, loc, -1);
596 }
597
598 auto acqFence = LLVM::FenceOp::create(rewriter, loc,
599 LLVM::AtomicOrdering::acquire, scope);
600 acqFence->setDiscardableAttr(LLVM::LLVMDialect::getMmraAttrName(), mmra);
601 rewriter.replaceOp(op, acqFence);
602 return success();
603 }
604};
605
606struct SchedBarrierOpLowering : public ConvertOpToLLVMPattern<SchedBarrierOp> {
607 SchedBarrierOpLowering(const LLVMTypeConverter &converter, Chipset chipset)
608 : ConvertOpToLLVMPattern<SchedBarrierOp>(converter), chipset(chipset) {}
609
610 Chipset chipset;
611
612 LogicalResult
613 matchAndRewrite(SchedBarrierOp op, SchedBarrierOp::Adaptor adaptor,
614 ConversionPatternRewriter &rewriter) const override {
615 rewriter.replaceOpWithNewOp<ROCDL::SchedBarrier>(op,
616 (uint32_t)op.getOpts());
617 return success();
618 }
619};
620
621} // namespace
622
623/// Pack small float vector operands (fp4/fp6/fp8/bf16) into the format
624/// expected by scaled matrix multiply intrinsics (MFMA/WMMA).
625///
626/// Specifically:
627/// 1. If the element type is bfloat16, bitcast it to i16 unless rocdl intrinsic
628/// allows bf16. Newer MFMAs support bf16 types on operand, check
629/// IntrinsicsAMDGPU.td file for reference.
630/// 2. If instead we have a more than 64-bit quantity, use a <N / 4 x i32>
631/// instead, which is what the f8f6f4 intrinsics use.
632/// 3. If `input` is a vector of N <= 8 bytes, bitcast it to a (N * 8)-bit
633/// integer.
634///
635/// Note that the type of `input` has already been LLVM type converted:
636/// therefore 8-bit and smaller floats are represented as their corresponding
637/// `iN` integers.
638static Value packSmallFloatVectorOperand(ConversionPatternRewriter &rewriter,
639 Location loc, Value input,
640 bool allowBf16 = true) {
641 Type inputType = input.getType();
642 if (auto vectorType = dyn_cast<VectorType>(inputType)) {
643 if (vectorType.getElementType().isBF16() && !allowBf16)
644 return LLVM::BitcastOp::create(
645 rewriter, loc, vectorType.clone(rewriter.getI16Type()), input);
646 if (vectorType.getElementType().isInteger(8) &&
647 vectorType.getNumElements() <= 8)
648 return LLVM::BitcastOp::create(
649 rewriter, loc,
650 rewriter.getIntegerType(vectorType.getNumElements() * 8), input);
651 if (isa<IntegerType>(vectorType.getElementType()) &&
652 vectorType.getElementTypeBitWidth() <= 8) {
653 int64_t numWords = llvm::divideCeil(
654 vectorType.getNumElements() * vectorType.getElementTypeBitWidth(),
655 32);
656 return LLVM::BitcastOp::create(
657 rewriter, loc, VectorType::get(numWords, rewriter.getI32Type()),
658 input);
659 }
660 }
661 return input;
662}
663
664/// Converts sparse MFMA (smfmac) operands to the expected ROCDL types.
665static Value convertSparseMFMAVectorOperand(ConversionPatternRewriter &rewriter,
666 Location loc, Value input,
667 bool allowBf16 = true) {
668 Type inputType = input.getType();
669 auto vectorType = cast<VectorType>(inputType);
670 // bf16 -> i16 when not allowed (pre-gfx950).
671 if (vectorType.getElementType().isBF16() && !allowBf16)
672 return LLVM::BitcastOp::create(
673 rewriter, loc, vectorType.clone(rewriter.getI16Type()), input);
674 // i8/fp8 vectors -> vector<Nxi32>.
675 if (isa<IntegerType>(vectorType.getElementType()) &&
676 vectorType.getElementTypeBitWidth() <= 8) {
677 int64_t numWords = llvm::divideCeil(
678 vectorType.getNumElements() * vectorType.getElementTypeBitWidth(), 32);
679 return LLVM::BitcastOp::create(
680 rewriter, loc, VectorType::get(numWords, rewriter.getI32Type()), input);
681 }
682 return input;
683}
684
685/// Converts the scaled MFMA/WMMA operands, `scalesA` and `scalesB`, from MLIR
686/// AMDGPU dialect convention to ROCDL and LLVM AMDGPU intrinsics convention.
687///
688/// Specifically:
689/// 1. If `input` is a i8 value, zero extend it to i32
690/// 2. If `input` is a vector of length 4 or 8 and type i8, cast it to i32
691///
692/// Note that the type of `input` has already been LLVM type converted:
693/// therefore 8-bit and smaller floats are represented as their corresponding
694/// `iN` integers.
695static Value castScaleOperand(ConversionPatternRewriter &rewriter, Location loc,
696 Value input) {
697 return TypeSwitch<Type, Value>(input.getType())
698 .Case([&](IntegerType) {
699 // Handle scalar i8: zero extend to i32.
700 return LLVM::ZExtOp::create(rewriter, loc, rewriter.getI32Type(),
701 input);
702 })
703 .Case([&](VectorType vectorType) {
704 // Handle vector<4xi8> -> i32 or vector<8xi8> -> i64.
705 int64_t numElements = vectorType.getNumElements();
706 assert((numElements == 4 || numElements == 8) &&
707 "scale operand must be a vector of length 4 or 8");
708 IntegerType outputType =
709 (numElements == 4) ? rewriter.getI32Type() : rewriter.getI64Type();
710 return LLVM::BitcastOp::create(rewriter, loc, outputType, input);
711 })
712 .DefaultUnreachable("unexpected input type for scale operand");
713}
714
715/// Maps f8 scale element types to WMMA scale format codes.
716static std::optional<uint32_t> getWmmaScaleFormat(Type elemType) {
717 return TypeSwitch<Type, std::optional<uint32_t>>(elemType)
718 .Case([](Float8E8M0FNUType) { return 0; })
719 .Case([](Float8E4M3FNType) { return 2; })
720 .Default(std::nullopt);
721}
722
723/// Determines the ROCDL intrinsic name for scaled WMMA based on dimensions
724/// and scale block size (16 or 32).
725static std::optional<StringRef>
726getScaledWmmaIntrinsicName(int64_t m, int64_t n, int64_t k, bool isScale16) {
727 if (m == 16 && n == 16 && k == 128)
728 return isScale16
729 ? ROCDL::wmma_scale16_f32_16x16x128_f8f6f4::getOperationName()
730 : ROCDL::wmma_scale_f32_16x16x128_f8f6f4::getOperationName();
731
732 if (m == 32 && n == 16 && k == 128)
733 return isScale16 ? ROCDL::wmma_scale16_f32_32x16x128_f4::getOperationName()
734 : ROCDL::wmma_scale_f32_32x16x128_f4::getOperationName();
735
736 return std::nullopt;
737}
738
739/// Push an input operand. If it is a float type, nothing to do. If it is
740/// an integer type, then we need to also push its signdness (1 for signed, 0
741/// for unsigned) and we need to pack the input 16xi8 vector into a 4xi32
742/// vector (or the 8xi8 vector into a 2xi32 one for gfx12+).
743/// We also need to convert bfloat inputs to i16 to account for the bfloat
744/// intrinsics having been defined before the AMD backend supported bfloat. We
745/// similarly need to pack 8-bit float types into integers as if they were i8
746/// (which they are for the backend's purposes).
747static void wmmaPushInputOperand(
748 ConversionPatternRewriter &rewriter, Location loc,
749 const TypeConverter *typeConverter, bool isUnsigned, Value llvmInput,
750 Value mlirInput, SmallVectorImpl<Value> &operands,
751 SmallVectorImpl<NamedAttribute> &attrs, StringRef attrName) {
752 Type inputType = llvmInput.getType();
753 auto vectorType = dyn_cast<VectorType>(inputType);
754 if (!vectorType) {
755 operands.push_back(llvmInput);
756 return;
757 }
758 Type elemType = vectorType.getElementType();
759 if (elemType.getIntOrFloatBitWidth() > 8) {
760 operands.push_back(llvmInput);
761 return;
762 }
763
764 // We need to check the type of the input before conversion to properly test
765 // for int8. This is because, in LLVM, fp8 type is converted to int8, so the
766 // fp8/int8 information is lost during the conversion process.
767 auto mlirInputType = cast<VectorType>(mlirInput.getType());
768 bool isInputInteger = mlirInputType.getElementType().isInteger();
769 if (isInputInteger) {
770 // if element type is 8-bit signed or unsigned, ignore the isUnsigned flag
771 bool localIsUnsigned = isUnsigned;
772 if (elemType.isUnsignedInteger()) {
773 localIsUnsigned = true;
774 } else if (elemType.isSignedInteger()) {
775 localIsUnsigned = false;
776 }
777 attrs.push_back(
778 NamedAttribute(attrName, rewriter.getBoolAttr(!localIsUnsigned)));
779 }
780
781 int64_t numBits =
782 vectorType.getNumElements() * elemType.getIntOrFloatBitWidth();
783 Type i32 = rewriter.getI32Type();
784 Type intrinsicInType = numBits <= 32
785 ? (Type)rewriter.getIntegerType(numBits)
786 : (Type)VectorType::get(numBits / 32, i32);
787 auto llvmIntrinsicInType = typeConverter->convertType(intrinsicInType);
788 Value castInput = rewriter.createOrFold<LLVM::BitcastOp>(
789 loc, llvmIntrinsicInType, llvmInput);
790 // The wave64-mode 16x16x16 intrinsics that take 4-bit integers only need
791 // (256 / 64) * 4 = 16 bits of input (on gfx12+) but take i32 arguments.
792 // Add in the zeros here.
793 if (numBits < 32)
794 castInput = LLVM::ZExtOp::create(rewriter, loc, i32, castInput);
795 operands.push_back(castInput);
796}
797
798/// Push the output operand. For many cases this is only pushing the output in
799/// the operand list. But when we have f16 -> f16 or bf16 -> bf16 intrinsics,
800/// since the same numbers of VGPRs is used, we need to decide if to store the
801/// result in the upper 16 bits of the VGPRs or in the lower part. To store the
802/// result in the lower 16 bits, set subwordOffset to 1, otherwise result will
803/// be stored it in the upper part. The subwordOffset must not be set for gfx12,
804/// as the instructions have been changed to return fewer registers instead.
805static void wmmaPushOutputOperand(ConversionPatternRewriter &rewriter,
806 Location loc,
807 const TypeConverter *typeConverter,
808 Value output, int32_t subwordOffset,
809 bool clamp, SmallVectorImpl<Value> &operands,
810 SmallVectorImpl<NamedAttribute> &attrs) {
811 Type inputType = output.getType();
812 auto vectorType = dyn_cast<VectorType>(inputType);
813 Type elemType = vectorType.getElementType();
814 operands.push_back(output);
815 if (elemType.isF16() || elemType.isBF16() || elemType.isInteger(16)) {
816 attrs.push_back(
817 NamedAttribute("opsel", rewriter.getBoolAttr(subwordOffset)));
818 } else if (elemType.isInteger(32)) {
819 attrs.push_back(NamedAttribute("clamp", rewriter.getBoolAttr(clamp)));
820 }
821}
822
823/// Return true if `type` is the E5M2 variant of an 8-bit float that is
824/// supported by the `_bf8` instructions on the given `chipset`.
825static bool typeIsExpectedBf8ForChipset(Chipset chipset, Type type) {
826 return (chipset == kGfx942 && isa<Float8E5M2FNUZType>(type)) ||
827 (hasOcpFp8(chipset) && isa<Float8E5M2Type>(type));
828}
829
830/// Return true if `type` is the E4M3FN variant of an 8-bit float that is
831/// supported by the `_fp8` instructions on the given `chipset`.
832static bool typeIsExpectedFp8ForChipset(Chipset chipset, Type type) {
833 return (chipset == kGfx942 && isa<Float8E4M3FNUZType>(type)) ||
834 (hasOcpFp8(chipset) && isa<Float8E4M3FNType>(type));
835}
836
837/// Return the `rocdl` intrinsic corresponding to a MFMA operation `mfma`
838/// if one exists. This includes checking to ensure the intrinsic is supported
839/// on the architecture you are compiling for.
840static std::optional<StringRef> mfmaOpToIntrinsic(MFMAOp mfma,
841 Chipset chipset) {
842 uint32_t m = mfma.getM(), n = mfma.getN(), k = mfma.getK(),
843 b = mfma.getBlocks();
844 Type sourceElem = getElementTypeOrSelf(mfma.getSourceA().getType());
845 Type destElem = getElementTypeOrSelf(mfma.getDestC().getType());
846
847 if (sourceElem.isF32() && destElem.isF32()) {
848 if (mfma.getReducePrecision() && chipset >= kGfx942) {
849 if (m == 32 && n == 32 && k == 4 && b == 1)
850 return ROCDL::mfma_f32_32x32x4_xf32::getOperationName();
851 if (m == 16 && n == 16 && k == 8 && b == 1)
852 return ROCDL::mfma_f32_16x16x8_xf32::getOperationName();
853 }
854 if (m == 32 && n == 32 && k == 1 && b == 2)
855 return ROCDL::mfma_f32_32x32x1f32::getOperationName();
856 if (m == 16 && n == 16 && k == 1 && b == 4)
857 return ROCDL::mfma_f32_16x16x1f32::getOperationName();
858 if (m == 4 && n == 4 && k == 1 && b == 16)
859 return ROCDL::mfma_f32_4x4x1f32::getOperationName();
860 if (m == 32 && n == 32 && k == 2 && b == 1)
861 return ROCDL::mfma_f32_32x32x2f32::getOperationName();
862 if (m == 16 && n == 16 && k == 4 && b == 1)
863 return ROCDL::mfma_f32_16x16x4f32::getOperationName();
864 }
865
866 if (sourceElem.isF16() && destElem.isF32()) {
867 if (chipset >= kGfx950) {
868 if (m == 32 && n == 32 && k == 16 && b == 1)
869 return ROCDL::mfma_f32_32x32x16_f16::getOperationName();
870 if (m == 16 && n == 16 && k == 32 && b == 1)
871 return ROCDL::mfma_f32_16x16x32_f16::getOperationName();
872 }
873 if (m == 32 && n == 32 && k == 4 && b == 2)
874 return ROCDL::mfma_f32_32x32x4f16::getOperationName();
875 if (m == 16 && n == 16 && k == 4 && b == 4)
876 return ROCDL::mfma_f32_16x16x4f16::getOperationName();
877 if (m == 4 && n == 4 && k == 4 && b == 16)
878 return ROCDL::mfma_f32_4x4x4f16::getOperationName();
879 if (m == 32 && n == 32 && k == 8 && b == 1)
880 return ROCDL::mfma_f32_32x32x8f16::getOperationName();
881 if (m == 16 && n == 16 && k == 16 && b == 1)
882 return ROCDL::mfma_f32_16x16x16f16::getOperationName();
883 }
884
885 if (sourceElem.isBF16() && destElem.isF32()) {
886 if (chipset >= kGfx950) {
887 if (m == 32 && n == 32 && k == 16 && b == 1)
888 return ROCDL::mfma_f32_32x32x16_bf16::getOperationName();
889 if (m == 16 && n == 16 && k == 32 && b == 1)
890 return ROCDL::mfma_f32_16x16x32_bf16::getOperationName();
891 }
892 if (chipset >= kGfx90a) {
893 if (m == 32 && n == 32 && k == 4 && b == 2)
894 return ROCDL::mfma_f32_32x32x4bf16_1k::getOperationName();
895 if (m == 16 && n == 16 && k == 4 && b == 4)
896 return ROCDL::mfma_f32_16x16x4bf16_1k::getOperationName();
897 if (m == 4 && n == 4 && k == 4 && b == 16)
898 return ROCDL::mfma_f32_4x4x4bf16_1k::getOperationName();
899 if (m == 32 && n == 32 && k == 8 && b == 1)
900 return ROCDL::mfma_f32_32x32x8bf16_1k::getOperationName();
901 if (m == 16 && n == 16 && k == 16 && b == 1)
902 return ROCDL::mfma_f32_16x16x16bf16_1k::getOperationName();
903 }
904 if (m == 32 && n == 32 && k == 2 && b == 2)
905 return ROCDL::mfma_f32_32x32x2bf16::getOperationName();
906 if (m == 16 && n == 16 && k == 2 && b == 4)
907 return ROCDL::mfma_f32_16x16x2bf16::getOperationName();
908 if (m == 4 && n == 4 && k == 2 && b == 16)
909 return ROCDL::mfma_f32_4x4x2bf16::getOperationName();
910 if (m == 32 && n == 32 && k == 4 && b == 1)
911 return ROCDL::mfma_f32_32x32x4bf16::getOperationName();
912 if (m == 16 && n == 16 && k == 8 && b == 1)
913 return ROCDL::mfma_f32_16x16x8bf16::getOperationName();
914 }
915
916 if (sourceElem.isInteger(8) && destElem.isInteger(32)) {
917 if (chipset >= kGfx950) {
918 if (m == 32 && n == 32 && k == 32 && b == 1)
919 return ROCDL::mfma_i32_32x32x32_i8::getOperationName();
920 if (m == 16 && n == 16 && k == 64 && b == 1)
921 return ROCDL::mfma_i32_16x16x64_i8::getOperationName();
922 }
923 if (m == 32 && n == 32 && k == 4 && b == 2)
924 return ROCDL::mfma_i32_32x32x4i8::getOperationName();
925 if (m == 16 && n == 16 && k == 4 && b == 4)
926 return ROCDL::mfma_i32_16x16x4i8::getOperationName();
927 if (m == 4 && n == 4 && k == 4 && b == 16)
928 return ROCDL::mfma_i32_4x4x4i8::getOperationName();
929 if (m == 32 && n == 32 && k == 8 && b == 1)
930 return ROCDL::mfma_i32_32x32x8i8::getOperationName();
931 if (m == 16 && n == 16 && k == 16 && b == 1)
932 return ROCDL::mfma_i32_16x16x16i8::getOperationName();
933 if (m == 32 && n == 32 && k == 16 && b == 1 && chipset >= kGfx942)
934 return ROCDL::mfma_i32_32x32x16_i8::getOperationName();
935 if (m == 16 && n == 16 && k == 32 && b == 1 && chipset >= kGfx942)
936 return ROCDL::mfma_i32_16x16x32_i8::getOperationName();
937 }
938
939 if (sourceElem.isF64() && destElem.isF64() && chipset >= kGfx90a) {
940 if (m == 16 && n == 16 && k == 4 && b == 1)
941 return ROCDL::mfma_f64_16x16x4f64::getOperationName();
942 if (m == 4 && n == 4 && k == 4 && b == 4)
943 return ROCDL::mfma_f64_4x4x4f64::getOperationName();
944 }
945
946 if (destElem.isF32() && typeIsExpectedBf8ForChipset(chipset, sourceElem)) {
947 // Known to be correct because there are no scalar f8 instructions and
948 // because a length mismatch will have been caught by the verifier.
949 Type sourceBElem =
950 cast<VectorType>(mfma.getSourceB().getType()).getElementType();
951 if (m == 16 && n == 16 && k == 32 && b == 1) {
952 if (typeIsExpectedBf8ForChipset(chipset, sourceBElem))
953 return ROCDL::mfma_f32_16x16x32_bf8_bf8::getOperationName();
954 if (typeIsExpectedFp8ForChipset(chipset, sourceBElem))
955 return ROCDL::mfma_f32_16x16x32_bf8_fp8::getOperationName();
956 }
957 if (m == 32 && n == 32 && k == 16 && b == 1) {
958 if (typeIsExpectedBf8ForChipset(chipset, sourceBElem))
959 return ROCDL::mfma_f32_32x32x16_bf8_bf8::getOperationName();
960 if (typeIsExpectedFp8ForChipset(chipset, sourceBElem))
961 return ROCDL::mfma_f32_32x32x16_bf8_fp8::getOperationName();
962 }
963 }
964
965 if (destElem.isF32() && typeIsExpectedFp8ForChipset(chipset, sourceElem)) {
966 Type sourceBElem =
967 cast<VectorType>(mfma.getSourceB().getType()).getElementType();
968 if (m == 16 && n == 16 && k == 32 && b == 1) {
969 if (typeIsExpectedBf8ForChipset(chipset, sourceBElem))
970 return ROCDL::mfma_f32_16x16x32_fp8_bf8::getOperationName();
971 if (typeIsExpectedFp8ForChipset(chipset, sourceBElem))
972 return ROCDL::mfma_f32_16x16x32_fp8_fp8::getOperationName();
973 }
974 if (m == 32 && n == 32 && k == 16 && b == 1) {
975 if (typeIsExpectedBf8ForChipset(chipset, sourceBElem))
976 return ROCDL::mfma_f32_32x32x16_fp8_bf8::getOperationName();
977 if (typeIsExpectedFp8ForChipset(chipset, sourceBElem))
978 return ROCDL::mfma_f32_32x32x16_fp8_fp8::getOperationName();
979 }
980 }
981
982 return std::nullopt;
983}
984
985static std::optional<uint32_t> smallFloatTypeToFormatCode(Type mlirElemType) {
986 return llvm::TypeSwitch<Type, std::optional<uint32_t>>(mlirElemType)
987 .Case([](Float8E4M3FNType) { return 0u; })
988 .Case([](Float8E5M2Type) { return 1u; })
989 .Case([](Float6E2M3FNType) { return 2u; })
990 .Case([](Float6E3M2FNType) { return 3u; })
991 .Case([](Float4E2M1FNType) { return 4u; })
992 .Default(std::nullopt);
993}
994
995/// If there is a scaled MFMA instruction for the input element types `aType`
996/// and `bType`, output type `destType`, problem size M, N, K, and B (number of
997/// blocks) on the given `chipset`, return a tuple consisting of the
998/// OperationName of the intrinsic and the type codes that need to be passed to
999/// that intrinsic. Note that this is also used to implement some un-scaled
1000/// MFMAs, since the compiler represents the ordinary instruction as a "scaled"
1001/// MFMA with a scale of 0.
1002static std::optional<std::tuple<StringRef, uint32_t, uint32_t>>
1003mfmaOpToScaledIntrinsic(Type aType, Type bType, Type destType, uint32_t m,
1004 uint32_t n, uint32_t k, uint32_t b, Chipset chipset) {
1005 aType = getElementTypeOrSelf(aType);
1006 bType = getElementTypeOrSelf(bType);
1007 destType = getElementTypeOrSelf(destType);
1008
1009 if (chipset < kGfx950)
1010 return std::nullopt;
1011 if (!isa<Float32Type>(destType))
1012 return std::nullopt;
1013
1014 std::optional<uint32_t> aTypeCode = smallFloatTypeToFormatCode(aType);
1015 std::optional<uint32_t> bTypeCode = smallFloatTypeToFormatCode(bType);
1016 if (!aTypeCode || !bTypeCode)
1017 return std::nullopt;
1018
1019 if (m == 32 && n == 32 && k == 64 && b == 1)
1020 return std::tuple{ROCDL::mfma_scale_f32_32x32x64_f8f6f4::getOperationName(),
1021 *aTypeCode, *bTypeCode};
1022 if (m == 16 && n == 16 && k == 128 && b == 1)
1023 return std::tuple{
1024 ROCDL::mfma_scale_f32_16x16x128_f8f6f4::getOperationName(), *aTypeCode,
1025 *bTypeCode};
1026
1027 return std::nullopt;
1028}
1029
1030static std::optional<std::tuple<StringRef, uint32_t, uint32_t>>
1031mfmaOpToScaledIntrinsic(MFMAOp mfma, Chipset chipset) {
1032 return mfmaOpToScaledIntrinsic(
1033 mfma.getSourceA().getType(), mfma.getSourceB().getType(),
1034 mfma.getDestC().getType(), mfma.getM(), mfma.getN(), mfma.getK(),
1035 mfma.getBlocks(), chipset);
1036}
1037
1038static std::optional<std::tuple<StringRef, uint32_t, uint32_t>>
1039mfmaOpToScaledIntrinsic(ScaledMFMAOp smfma, Chipset chipset) {
1040 return mfmaOpToScaledIntrinsic(smfma.getSourceA().getType(),
1041 smfma.getSourceB().getType(),
1042 smfma.getDestC().getType(), smfma.getM(),
1043 smfma.getN(), smfma.getK(), 1u, chipset);
1044}
1045
1046/// Returns the `rocdl` intrinsic corresponding to a WMMA operation `wmma`
1047/// for RDNA3/4 architectures.
1048static std::optional<StringRef>
1049wmmaOpToIntrinsicRDNA(Type elemSourceType, Type elemBSourceType,
1050 Type elemDestType, uint32_t k, bool isRDNA3) {
1051 using fp8 = Float8E4M3FNType;
1052 using bf8 = Float8E5M2Type;
1053
1054 // Handle k == 16 for RDNA3/4.
1055 if (k == 16) {
1056 // Common patterns for RDNA3 and RDNA4.
1057 if (elemSourceType.isF16() && elemDestType.isF32())
1058 return ROCDL::wmma_f32_16x16x16_f16::getOperationName();
1059 if (elemSourceType.isBF16() && elemDestType.isF32())
1060 return ROCDL::wmma_f32_16x16x16_bf16::getOperationName();
1061 if (elemSourceType.isF16() && elemDestType.isF16())
1062 return ROCDL::wmma_f16_16x16x16_f16::getOperationName();
1063 if (elemSourceType.isBF16() && elemDestType.isBF16())
1064 return ROCDL::wmma_bf16_16x16x16_bf16::getOperationName();
1065 if (elemSourceType.isInteger(8) && elemDestType.isInteger(32))
1066 return ROCDL::wmma_i32_16x16x16_iu8::getOperationName();
1067
1068 // RDNA3 specific patterns.
1069 if (isRDNA3) {
1070 if (elemSourceType.isInteger(4) && elemDestType.isInteger(32))
1071 return ROCDL::wmma_i32_16x16x16_iu4::getOperationName();
1072 return std::nullopt;
1073 }
1074
1075 // RDNA4 specific patterns (fp8/bf8).
1076 if (isa<fp8>(elemSourceType) && isa<fp8>(elemBSourceType) &&
1077 elemDestType.isF32())
1078 return ROCDL::wmma_f32_16x16x16_fp8_fp8::getOperationName();
1079 if (isa<fp8>(elemSourceType) && isa<bf8>(elemBSourceType) &&
1080 elemDestType.isF32())
1081 return ROCDL::wmma_f32_16x16x16_fp8_bf8::getOperationName();
1082 if (isa<bf8>(elemSourceType) && isa<bf8>(elemBSourceType) &&
1083 elemDestType.isF32())
1084 return ROCDL::wmma_f32_16x16x16_bf8_bf8::getOperationName();
1085 if (isa<bf8>(elemSourceType) && isa<fp8>(elemBSourceType) &&
1086 elemDestType.isF32())
1087 return ROCDL::wmma_f32_16x16x16_bf8_fp8::getOperationName();
1088 if (elemSourceType.isInteger(4) && elemDestType.isInteger(32))
1089 return ROCDL::wmma_i32_16x16x16_iu4::getOperationName();
1090
1091 return std::nullopt;
1092 }
1093
1094 // Handle k == 32 for RDNA4.
1095 if (k == 32 && !isRDNA3) {
1096 if (elemSourceType.isInteger(4) && elemDestType.isInteger(32))
1097 return ROCDL::wmma_i32_16x16x32_iu4::getOperationName();
1098 }
1099
1100 return std::nullopt;
1101}
1102
1103/// Return the `rocdl` intrinsic corresponding to a WMMA operation `wmma`
1104/// for the gfx1250 architecture.
1105static std::optional<StringRef> wmmaOpToIntrinsicGfx1250(Type elemSourceType,
1106 Type elemBSourceType,
1107 Type elemDestType,
1108 uint32_t k) {
1109 using fp8 = Float8E4M3FNType;
1110 using bf8 = Float8E5M2Type;
1111
1112 if (k == 4) {
1113 if (elemSourceType.isF32() && elemDestType.isF32())
1114 return ROCDL::wmma_f32_16x16x4_f32::getOperationName();
1115
1116 return std::nullopt;
1117 }
1118
1119 if (k == 32) {
1120 if (elemSourceType.isF16() && elemDestType.isF32())
1121 return ROCDL::wmma_f32_16x16x32_f16::getOperationName();
1122 if (elemSourceType.isBF16() && elemDestType.isF32())
1123 return ROCDL::wmma_f32_16x16x32_bf16::getOperationName();
1124 if (elemSourceType.isF16() && elemDestType.isF16())
1125 return ROCDL::wmma_f16_16x16x32_f16::getOperationName();
1126 if (elemSourceType.isBF16() && elemDestType.isBF16())
1127 return ROCDL::wmma_bf16_16x16x32_bf16::getOperationName();
1128
1129 return std::nullopt;
1130 }
1131
1132 if (k == 64) {
1133 if (isa<fp8>(elemSourceType) && isa<fp8>(elemBSourceType)) {
1134 if (elemDestType.isF32())
1135 return ROCDL::wmma_f32_16x16x64_fp8_fp8::getOperationName();
1136 if (elemDestType.isF16())
1137 return ROCDL::wmma_f16_16x16x64_fp8_fp8::getOperationName();
1138 }
1139 if (isa<fp8>(elemSourceType) && isa<bf8>(elemBSourceType)) {
1140 if (elemDestType.isF32())
1141 return ROCDL::wmma_f32_16x16x64_fp8_bf8::getOperationName();
1142 if (elemDestType.isF16())
1143 return ROCDL::wmma_f16_16x16x64_fp8_bf8::getOperationName();
1144 }
1145 if (isa<bf8>(elemSourceType) && isa<bf8>(elemBSourceType)) {
1146 if (elemDestType.isF32())
1147 return ROCDL::wmma_f32_16x16x64_bf8_bf8::getOperationName();
1148 if (elemDestType.isF16())
1149 return ROCDL::wmma_f16_16x16x64_bf8_bf8::getOperationName();
1150 }
1151 if (isa<bf8>(elemSourceType) && isa<fp8>(elemBSourceType)) {
1152 if (elemDestType.isF32())
1153 return ROCDL::wmma_f32_16x16x64_bf8_fp8::getOperationName();
1154 if (elemDestType.isF16())
1155 return ROCDL::wmma_f16_16x16x64_bf8_fp8::getOperationName();
1156 }
1157 if (elemSourceType.isInteger(8) && elemDestType.isInteger(32))
1158 return ROCDL::wmma_i32_16x16x64_iu8::getOperationName();
1159
1160 return std::nullopt;
1161 }
1162
1163 if (k == 128) {
1164 if (isa<fp8>(elemSourceType) && isa<fp8>(elemBSourceType)) {
1165 if (elemDestType.isF32())
1166 return ROCDL::wmma_f32_16x16x128_fp8_fp8::getOperationName();
1167 if (elemDestType.isF16())
1168 return ROCDL::wmma_f16_16x16x128_fp8_fp8::getOperationName();
1169 }
1170 if (isa<fp8>(elemSourceType) && isa<bf8>(elemBSourceType)) {
1171 if (elemDestType.isF32())
1172 return ROCDL::wmma_f32_16x16x128_fp8_bf8::getOperationName();
1173 if (elemDestType.isF16())
1174 return ROCDL::wmma_f16_16x16x128_fp8_bf8::getOperationName();
1175 }
1176 if (isa<bf8>(elemSourceType) && isa<bf8>(elemBSourceType)) {
1177 if (elemDestType.isF32())
1178 return ROCDL::wmma_f32_16x16x128_bf8_bf8::getOperationName();
1179 if (elemDestType.isF16())
1180 return ROCDL::wmma_f16_16x16x128_bf8_bf8::getOperationName();
1181 }
1182 if (isa<bf8>(elemSourceType) && isa<fp8>(elemBSourceType)) {
1183 if (elemDestType.isF32())
1184 return ROCDL::wmma_f32_16x16x128_bf8_fp8::getOperationName();
1185 if (elemDestType.isF16())
1186 return ROCDL::wmma_f16_16x16x128_bf8_fp8::getOperationName();
1187 }
1188
1189 return std::nullopt;
1190 }
1191
1192 return std::nullopt;
1193}
1194
1195/// Returns the `rocdl` intrinsic corresponding to a SparseMFMA (smfmac)
1196/// operation if one exists. This includes checking to ensure the intrinsic is
1197/// supported on the architecture you are compiling for.
1198static std::optional<StringRef> smfmacOpToIntrinsic(SparseMFMAOp op,
1199 Chipset chipset) {
1200 bool isGfx950 = chipset >= kGfx950;
1201 auto isFp8 = [&](Type t) { return typeIsExpectedFp8ForChipset(chipset, t); };
1202 auto isBf8 = [&](Type t) { return typeIsExpectedBf8ForChipset(chipset, t); };
1203
1204 uint32_t m = op.getM(), n = op.getN(), k = op.getK();
1205 Type sourceAElem = getElementTypeOrSelf(op.getSourceA().getType());
1206 Type sourceBElem = getElementTypeOrSelf(op.getSourceB().getType());
1207 Type destElem = getElementTypeOrSelf(op.getDestC().getType());
1208
1209 if (m == 16 && n == 16 && k == 32) {
1210 if (sourceAElem.isF16() && sourceBElem.isF16() && destElem.isF32())
1211 return ROCDL::smfmac_f32_16x16x32_f16::getOperationName();
1212 if (sourceAElem.isBF16() && sourceBElem.isBF16() && destElem.isF32())
1213 return ROCDL::smfmac_f32_16x16x32_bf16::getOperationName();
1214 }
1215
1216 if (m == 16 && n == 16 && k == 64) {
1217 if (isGfx950) {
1218 if (sourceAElem.isF16() && sourceBElem.isF16() && destElem.isF32())
1219 return ROCDL::smfmac_f32_16x16x64_f16::getOperationName();
1220 if (sourceAElem.isBF16() && sourceBElem.isBF16() && destElem.isF32())
1221 return ROCDL::smfmac_f32_16x16x64_bf16::getOperationName();
1222 }
1223 if (sourceAElem.isInteger(8) && sourceBElem.isInteger(8) &&
1224 destElem.isInteger(32))
1225 return ROCDL::smfmac_i32_16x16x64_i8::getOperationName();
1226 if (isFp8(sourceAElem) && isFp8(sourceBElem) && destElem.isF32())
1227 return ROCDL::smfmac_f32_16x16x64_fp8_fp8::getOperationName();
1228 if (isFp8(sourceAElem) && isBf8(sourceBElem) && destElem.isF32())
1229 return ROCDL::smfmac_f32_16x16x64_fp8_bf8::getOperationName();
1230 if (isBf8(sourceAElem) && isFp8(sourceBElem) && destElem.isF32())
1231 return ROCDL::smfmac_f32_16x16x64_bf8_fp8::getOperationName();
1232 if (isBf8(sourceAElem) && isBf8(sourceBElem) && destElem.isF32())
1233 return ROCDL::smfmac_f32_16x16x64_bf8_bf8::getOperationName();
1234 }
1235
1236 if (m == 16 && n == 16 && k == 128 && isGfx950) {
1237 if (sourceAElem.isInteger(8) && sourceBElem.isInteger(8) &&
1238 destElem.isInteger(32))
1239 return ROCDL::smfmac_i32_16x16x128_i8::getOperationName();
1240 if (isFp8(sourceAElem) && isFp8(sourceBElem) && destElem.isF32())
1241 return ROCDL::smfmac_f32_16x16x128_fp8_fp8::getOperationName();
1242 if (isFp8(sourceAElem) && isBf8(sourceBElem) && destElem.isF32())
1243 return ROCDL::smfmac_f32_16x16x128_fp8_bf8::getOperationName();
1244 if (isBf8(sourceAElem) && isFp8(sourceBElem) && destElem.isF32())
1245 return ROCDL::smfmac_f32_16x16x128_bf8_fp8::getOperationName();
1246 if (isBf8(sourceAElem) && isBf8(sourceBElem) && destElem.isF32())
1247 return ROCDL::smfmac_f32_16x16x128_bf8_bf8::getOperationName();
1248 }
1249
1250 if (m == 32 && n == 32 && k == 16) {
1251 if (sourceAElem.isF16() && sourceBElem.isF16() && destElem.isF32())
1252 return ROCDL::smfmac_f32_32x32x16_f16::getOperationName();
1253 if (sourceAElem.isBF16() && sourceBElem.isBF16() && destElem.isF32())
1254 return ROCDL::smfmac_f32_32x32x16_bf16::getOperationName();
1255 }
1256
1257 if (m == 32 && n == 32 && k == 32) {
1258 if (isGfx950) {
1259 if (sourceAElem.isF16() && sourceBElem.isF16() && destElem.isF32())
1260 return ROCDL::smfmac_f32_32x32x32_f16::getOperationName();
1261 if (sourceAElem.isBF16() && sourceBElem.isBF16() && destElem.isF32())
1262 return ROCDL::smfmac_f32_32x32x32_bf16::getOperationName();
1263 }
1264 if (sourceAElem.isInteger(8) && sourceBElem.isInteger(8) &&
1265 destElem.isInteger(32))
1266 return ROCDL::smfmac_i32_32x32x32_i8::getOperationName();
1267 if (isFp8(sourceAElem) && isFp8(sourceBElem) && destElem.isF32())
1268 return ROCDL::smfmac_f32_32x32x32_fp8_fp8::getOperationName();
1269 if (isFp8(sourceAElem) && isBf8(sourceBElem) && destElem.isF32())
1270 return ROCDL::smfmac_f32_32x32x32_fp8_bf8::getOperationName();
1271 if (isBf8(sourceAElem) && isFp8(sourceBElem) && destElem.isF32())
1272 return ROCDL::smfmac_f32_32x32x32_bf8_fp8::getOperationName();
1273 if (isBf8(sourceAElem) && isBf8(sourceBElem) && destElem.isF32())
1274 return ROCDL::smfmac_f32_32x32x32_bf8_bf8::getOperationName();
1275 }
1276
1277 if (m == 32 && n == 32 && k == 64 && isGfx950) {
1278 if (sourceAElem.isInteger(8) && sourceBElem.isInteger(8) &&
1279 destElem.isInteger(32))
1280 return ROCDL::smfmac_i32_32x32x64_i8::getOperationName();
1281 if (isFp8(sourceAElem) && isFp8(sourceBElem) && destElem.isF32())
1282 return ROCDL::smfmac_f32_32x32x64_fp8_fp8::getOperationName();
1283 if (isFp8(sourceAElem) && isBf8(sourceBElem) && destElem.isF32())
1284 return ROCDL::smfmac_f32_32x32x64_fp8_bf8::getOperationName();
1285 if (isBf8(sourceAElem) && isFp8(sourceBElem) && destElem.isF32())
1286 return ROCDL::smfmac_f32_32x32x64_bf8_fp8::getOperationName();
1287 if (isBf8(sourceAElem) && isBf8(sourceBElem) && destElem.isF32())
1288 return ROCDL::smfmac_f32_32x32x64_bf8_bf8::getOperationName();
1289 }
1290
1291 return std::nullopt;
1292}
1293
1294/// Returns the `rocdl` intrinsic corresponding to a WMMA operation `wmma`
1295/// if one exists. This includes checking to ensure the intrinsic is supported
1296/// on the architecture you are compiling for.
1297static std::optional<StringRef> wmmaOpToIntrinsic(WMMAOp wmma,
1298 Chipset chipset) {
1299 auto sourceVectorType = cast<VectorType>(wmma.getSourceA().getType());
1300 auto sourceBVectorType = cast<VectorType>(wmma.getSourceB().getType());
1301 auto destVectorType = cast<VectorType>(wmma.getDestC().getType());
1302 Type elemSourceType = sourceVectorType.getElementType();
1303 Type elemBSourceType = sourceBVectorType.getElementType();
1304 Type elemDestType = destVectorType.getElementType();
1305
1306 const uint32_t k = wmma.getK();
1307 const bool isRDNA3 = chipset.majorVersion == 11;
1308 const bool isRDNA4 = chipset.majorVersion == 12 && chipset.minorVersion == 0;
1309
1310 // Handle RDNA3 and RDNA4.
1311 if (isRDNA3 || isRDNA4)
1312 return wmmaOpToIntrinsicRDNA(elemSourceType, elemBSourceType, elemDestType,
1313 k, isRDNA3);
1314
1315 // Handle gfx1250.
1316 if (chipset == kGfx1250)
1317 return wmmaOpToIntrinsicGfx1250(elemSourceType, elemBSourceType,
1318 elemDestType, k);
1319
1320 return std::nullopt;
1321}
1322
1323namespace {
1324struct MFMAOpLowering : public ConvertOpToLLVMPattern<MFMAOp> {
1325 MFMAOpLowering(const LLVMTypeConverter &converter, Chipset chipset)
1326 : ConvertOpToLLVMPattern<MFMAOp>(converter), chipset(chipset) {}
1327
1328 Chipset chipset;
1329
1330 LogicalResult
1331 matchAndRewrite(MFMAOp op, MFMAOpAdaptor adaptor,
1332 ConversionPatternRewriter &rewriter) const override {
1333 Location loc = op.getLoc();
1334 Type outType = typeConverter->convertType(op.getDestD().getType());
1335 Type intrinsicOutType = outType;
1336 if (auto outVecType = dyn_cast<VectorType>(outType))
1337 if (outVecType.getElementType().isBF16())
1338 intrinsicOutType = outVecType.clone(rewriter.getI16Type());
1339
1340 if (chipset.majorVersion != 9 || chipset < kGfx908)
1341 return op->emitOpError("MFMA only supported on gfx908+");
1342 uint32_t getBlgpField = static_cast<uint32_t>(op.getBlgp());
1343 if (op.getNegateA() || op.getNegateB() || op.getNegateC()) {
1344 if (chipset < kGfx942)
1345 return op.emitOpError("negation unsupported on older than gfx942");
1346 getBlgpField |=
1347 op.getNegateA() | (op.getNegateB() << 1) | (op.getNegateC() << 2);
1348 }
1349 std::optional<StringRef> maybeIntrinsic = mfmaOpToIntrinsic(op, chipset);
1350 std::optional<std::tuple<StringRef, uint32_t, uint32_t>>
1351 maybeScaledIntrinsic = mfmaOpToScaledIntrinsic(op, chipset);
1352 if (!maybeIntrinsic.has_value() && !maybeScaledIntrinsic.has_value())
1353 return op.emitOpError("no intrinsic matching MFMA size on given chipset");
1354
1355 bool isScaled =
1356 !maybeIntrinsic.has_value() && maybeScaledIntrinsic.has_value();
1357 if (isScaled &&
1358 (adaptor.getAbid() > 0 || getBlgpField > 0 || op.getCbsz() > 0)) {
1359 return op.emitOpError(
1360 "non-default abid, blgp, and cbsz aren't supported on MFMAs that can "
1361 "be scaled as those fields are used for type information");
1362 }
1363
1364 StringRef intrinsicName =
1365 isScaled ? std::get<0>(*maybeScaledIntrinsic) : *maybeIntrinsic;
1366 // Determine if we can use bf16 in the intrinsic. Newer MFMAs in gfx950+
1367 // allows bf16 as the input. For reference check IntrinsicsAMDGPU.td file.
1368 bool allowBf16 = [&]() {
1369 if (chipset < kGfx950)
1370 return false;
1371 if (isScaled)
1372 return true;
1373 return intrinsicName.contains("16x16x32.bf16") ||
1374 intrinsicName.contains("32x32x16.bf16");
1375 }();
1376 OperationState loweredOp(loc, intrinsicName);
1377 loweredOp.addTypes(intrinsicOutType);
1378 loweredOp.addOperands({packSmallFloatVectorOperand(
1379 rewriter, loc, adaptor.getSourceA(), allowBf16),
1380 packSmallFloatVectorOperand(
1381 rewriter, loc, adaptor.getSourceB(), allowBf16),
1382 adaptor.getDestC()});
1383 if (isScaled) {
1384 Value zero = createI32Constant(rewriter, loc, 0);
1385 auto [_scaledName, aTypeCode, bTypeCode] = *maybeScaledIntrinsic;
1386 loweredOp.addOperands({createI32Constant(rewriter, loc, aTypeCode),
1387 createI32Constant(rewriter, loc, bTypeCode),
1388 /*scale A byte=*/zero, /*scale A=*/zero,
1389 /*scale B byte=*/zero, /*scale B=*/zero});
1390 } else {
1391 loweredOp.addOperands({createI32Constant(rewriter, loc, op.getCbsz()),
1392 createI32Constant(rewriter, loc, op.getAbid()),
1393 createI32Constant(rewriter, loc, getBlgpField)});
1394 };
1395 Value lowered = rewriter.create(loweredOp)->getResult(0);
1396 if (outType != intrinsicOutType)
1397 lowered = LLVM::BitcastOp::create(rewriter, loc, outType, lowered);
1398 rewriter.replaceOp(op, lowered);
1399 return success();
1400 }
1401};
1402
1403struct ScaledMFMAOpLowering : public ConvertOpToLLVMPattern<ScaledMFMAOp> {
1404 ScaledMFMAOpLowering(const LLVMTypeConverter &converter, Chipset chipset)
1405 : ConvertOpToLLVMPattern(converter), chipset(chipset) {}
1406
1407 Chipset chipset;
1408
1409 LogicalResult
1410 matchAndRewrite(ScaledMFMAOp op, ScaledMFMAOpAdaptor adaptor,
1411 ConversionPatternRewriter &rewriter) const override {
1412 Location loc = op.getLoc();
1413 Type intrinsicOutType = typeConverter->convertType(op.getDestD().getType());
1414
1415 if (chipset.majorVersion != 9 || chipset < kGfx950)
1416 return op->emitOpError("scaled MFMA only supported on gfx908+");
1417 std::optional<std::tuple<StringRef, uint32_t, uint32_t>>
1418 maybeScaledIntrinsic = mfmaOpToScaledIntrinsic(op, chipset);
1419 if (!maybeScaledIntrinsic.has_value())
1420 return op.emitOpError(
1421 "no intrinsic matching scaled MFMA size on given chipset");
1422
1423 auto [intrinsicName, aTypeCode, bTypeCode] = *maybeScaledIntrinsic;
1424 OperationState loweredOp(loc, intrinsicName);
1425 loweredOp.addTypes(intrinsicOutType);
1426 loweredOp.addOperands(
1427 {packSmallFloatVectorOperand(rewriter, loc, adaptor.getSourceA()),
1428 packSmallFloatVectorOperand(rewriter, loc, adaptor.getSourceB()),
1429 adaptor.getDestC()});
1430 Value scalesIdxA =
1431 createI32Constant(rewriter, loc, adaptor.getScalesIdxA());
1432 Value scalesIdxB =
1433 createI32Constant(rewriter, loc, adaptor.getScalesIdxB());
1434 loweredOp.addOperands(
1435 {createI32Constant(rewriter, loc, aTypeCode),
1436 createI32Constant(rewriter, loc, bTypeCode),
1437 /*scales idx A=*/scalesIdxA,
1438 /*scales A*/
1439 castScaleOperand(rewriter, loc, adaptor.getScalesA()),
1440 /*scales idx B=*/scalesIdxB,
1441 /*scales B*/
1442 castScaleOperand(rewriter, loc, adaptor.getScalesB())});
1443 Value lowered = rewriter.create(loweredOp)->getResult(0);
1444 rewriter.replaceOp(op, lowered);
1445 return success();
1446 }
1447};
1448
1449struct SparseMFMAOpLowering : public ConvertOpToLLVMPattern<SparseMFMAOp> {
1450 SparseMFMAOpLowering(const LLVMTypeConverter &converter, Chipset chipset)
1451 : ConvertOpToLLVMPattern<SparseMFMAOp>(converter), chipset(chipset) {}
1452
1453 Chipset chipset;
1454
1455 LogicalResult
1456 matchAndRewrite(SparseMFMAOp op, SparseMFMAOpAdaptor adaptor,
1457 ConversionPatternRewriter &rewriter) const override {
1458 Location loc = op.getLoc();
1459 auto outType =
1460 typeConverter->convertType<VectorType>(op.getDestC().getType());
1461 if (!outType)
1462 return rewriter.notifyMatchFailure(op, "type conversion failed");
1463
1464 // smfmac is supported on gfx942 and gfx950.
1465 if (chipset.majorVersion != 9 || chipset < kGfx942)
1466 return op->emitOpError("sparse MFMA (smfmac) only supported on gfx942+");
1467 bool isGfx950 = chipset >= kGfx950;
1468
1469 Value a = convertSparseMFMAVectorOperand(rewriter, loc,
1470 adaptor.getSourceA(), isGfx950);
1471 Value b = convertSparseMFMAVectorOperand(rewriter, loc,
1472 adaptor.getSourceB(), isGfx950);
1473 Value c = adaptor.getDestC();
1474
1475 std::optional<StringRef> maybeIntrinsic = smfmacOpToIntrinsic(op, chipset);
1476 if (!maybeIntrinsic.has_value())
1477 return op.emitOpError(
1478 "no intrinsic matching sparse MFMA on the given chipset");
1479
1480 // Bitcast sparse indices from vector<4xi8> or vector<2xi16> to i32.
1481 Value sparseIdx = LLVM::BitcastOp::create(
1482 rewriter, loc, rewriter.getI32Type(), adaptor.getSparseIdx());
1483
1484 OperationState loweredOp(loc, maybeIntrinsic.value());
1485 loweredOp.addTypes(outType);
1486 loweredOp.addOperands({a, b, c, sparseIdx,
1487 createI32Constant(rewriter, loc, op.getCbsz()),
1488 createI32Constant(rewriter, loc, op.getAbid())});
1489 Value lowered = rewriter.create(loweredOp)->getResult(0);
1490 rewriter.replaceOp(op, lowered);
1491 return success();
1492 }
1493};
1494
1495struct WMMAOpLowering : public ConvertOpToLLVMPattern<WMMAOp> {
1496 WMMAOpLowering(const LLVMTypeConverter &converter, Chipset chipset)
1497 : ConvertOpToLLVMPattern<WMMAOp>(converter), chipset(chipset) {}
1498
1499 Chipset chipset;
1500
1501 LogicalResult
1502 matchAndRewrite(WMMAOp op, WMMAOpAdaptor adaptor,
1503 ConversionPatternRewriter &rewriter) const override {
1504 Location loc = op.getLoc();
1505 auto outType =
1506 typeConverter->convertType<VectorType>(op.getDestD().getType());
1507 if (!outType)
1508 return rewriter.notifyMatchFailure(op, "type conversion failed");
1509
1510 if (chipset.majorVersion != 11 && chipset.majorVersion != 12)
1511 return op->emitOpError("WMMA only supported on gfx11 and gfx12");
1512
1513 bool isGFX1250 = chipset >= kGfx1250;
1514
1515 // The WMMA operations represent vectors of bf16s as vectors of i16s
1516 // (except on gfx1250), so we need to bitcast bfloats to i16 and then
1517 // bitcast them back.
1518 auto aType = cast<VectorType>(adaptor.getSourceA().getType());
1519 auto bType = cast<VectorType>(adaptor.getSourceB().getType());
1520 auto destCType = cast<VectorType>(adaptor.getDestC().getType());
1521 bool castAToI16 = aType.getElementType().isBF16() && !isGFX1250;
1522 bool castBToI16 = bType.getElementType().isBF16() && !isGFX1250;
1523 bool castDestCToI16 = destCType.getElementType().isBF16() && !isGFX1250;
1524 bool castOutToI16 = outType.getElementType().isBF16() && !isGFX1250;
1525 VectorType rawOutType = outType;
1526 if (castOutToI16)
1527 rawOutType = outType.clone(rewriter.getI16Type());
1528 Value a = adaptor.getSourceA();
1529 if (castAToI16)
1530 a = LLVM::BitcastOp::create(rewriter, loc,
1531 aType.clone(rewriter.getI16Type()), a);
1532 Value b = adaptor.getSourceB();
1533 if (castBToI16)
1534 b = LLVM::BitcastOp::create(rewriter, loc,
1535 bType.clone(rewriter.getI16Type()), b);
1536 Value destC = adaptor.getDestC();
1537 if (castDestCToI16)
1538 destC = LLVM::BitcastOp::create(
1539 rewriter, loc, destCType.clone(rewriter.getI16Type()), destC);
1540
1541 std::optional<StringRef> maybeIntrinsic = wmmaOpToIntrinsic(op, chipset);
1542
1543 if (!maybeIntrinsic.has_value())
1544 return op.emitOpError("no intrinsic matching WMMA on the given chipset");
1545
1546 if (chipset.majorVersion >= 12 && op.getSubwordOffset() != 0)
1547 return op.emitOpError("subwordOffset not supported on gfx12+");
1548
1549 SmallVector<Value, 4> operands;
1550 SmallVector<NamedAttribute, 4> attrs;
1551 wmmaPushInputOperand(rewriter, loc, typeConverter, op.getUnsignedA(), a,
1552 op.getSourceA(), operands, attrs, "signA");
1553 wmmaPushInputOperand(rewriter, loc, typeConverter, op.getUnsignedB(), b,
1554 op.getSourceB(), operands, attrs, "signB");
1555 wmmaPushOutputOperand(rewriter, loc, typeConverter, destC,
1556 op.getSubwordOffset(), op.getClamp(), operands,
1557 attrs);
1558
1559 OperationState loweredOp(loc, *maybeIntrinsic);
1560 loweredOp.addTypes(rawOutType);
1561 loweredOp.addOperands(operands);
1562 loweredOp.addAttributes(attrs);
1563 Operation *lowered = rewriter.create(loweredOp);
1564
1565 Operation *maybeCastBack = lowered;
1566 if (rawOutType != outType)
1567 maybeCastBack = LLVM::BitcastOp::create(rewriter, loc, outType,
1568 lowered->getResult(0));
1569 rewriter.replaceOp(op, maybeCastBack->getResults());
1570
1571 return success();
1572 }
1573};
1574
1575struct ScaledWMMAOpLowering : public ConvertOpToLLVMPattern<ScaledWMMAOp> {
1576 ScaledWMMAOpLowering(const LLVMTypeConverter &converter, Chipset chipset)
1577 : ConvertOpToLLVMPattern<ScaledWMMAOp>(converter), chipset(chipset) {}
1578
1579 Chipset chipset;
1580
1581 LogicalResult
1582 matchAndRewrite(ScaledWMMAOp op, ScaledWMMAOpAdaptor adaptor,
1583 ConversionPatternRewriter &rewriter) const override {
1584 Location loc = op.getLoc();
1585 auto outType =
1586 typeConverter->convertType<VectorType>(op.getDestD().getType());
1587 if (!outType)
1588 return rewriter.notifyMatchFailure(op, "type conversion failed");
1589
1590 if (chipset < kGfx1250)
1591 return op->emitOpError("WMMA scale only supported on gfx1250+");
1592
1593 int64_t m = op.getM();
1594 int64_t n = op.getN();
1595 int64_t k = op.getK();
1596
1597 Type aElemType = getElementTypeOrSelf(op.getSourceA().getType());
1598 Type bElemType = getElementTypeOrSelf(op.getSourceB().getType());
1599
1600 std::optional<uint32_t> aFmtCode = smallFloatTypeToFormatCode(aElemType);
1601 std::optional<uint32_t> bFmtCode = smallFloatTypeToFormatCode(bElemType);
1602
1603 if (!aFmtCode || !bFmtCode)
1604 return op.emitOpError("unsupported element types for scaled_wmma");
1605
1606 // Get scale vector types and determine variant (scale vs scale16).
1607 auto scaleAVecType = cast<VectorType>(op.getScaleA().getType());
1608 auto scaleBVecType = cast<VectorType>(op.getScaleB().getType());
1609
1610 if (scaleAVecType.getNumElements() != scaleBVecType.getNumElements())
1611 return op.emitOpError("scaleA and scaleB must have equal vector length");
1612
1613 // Extract scale format from element types.
1614 Type scaleAElemType = scaleAVecType.getElementType();
1615 Type scaleBElemType = scaleBVecType.getElementType();
1616
1617 std::optional<uint32_t> scaleAFmt = getWmmaScaleFormat(scaleAElemType);
1618 std::optional<uint32_t> scaleBFmt = getWmmaScaleFormat(scaleBElemType);
1619
1620 if (!scaleAFmt || !scaleBFmt)
1621 return op.emitOpError("unsupported scale element types");
1622
1623 // Determine which intrinsic to use based on dimensions.
1624 bool isScale16 = (scaleAVecType.getNumElements() == 8);
1625 std::optional<StringRef> intrinsicName =
1626 getScaledWmmaIntrinsicName(m, n, k, isScale16);
1627 if (!intrinsicName)
1628 return op.emitOpError("unsupported scaled_wmma dimensions: ")
1629 << m << "x" << n << "x" << k;
1630
1631 SmallVector<NamedAttribute, 8> attrs;
1632
1633 // The f4 variant does not have fmtA and fmtB attributes.
1634 bool is32x16 = (m == 32 && n == 16 && k == 128);
1635 if (!is32x16) {
1636 attrs.emplace_back("fmtA", rewriter.getI32IntegerAttr(*aFmtCode));
1637 attrs.emplace_back("fmtB", rewriter.getI32IntegerAttr(*bFmtCode));
1638 }
1639
1640 // modC uses default value of 0.
1641 attrs.emplace_back("modC", rewriter.getI16IntegerAttr(0));
1642
1643 // Scale attributes. Convert user-facing firstScaleLane (0 or 16) to the
1644 // half of the wave that is being selected (0 or 1).
1645 attrs.emplace_back(
1646 "scaleAType", rewriter.getI32IntegerAttr(op.getAFirstScaleLane() / 16));
1647 attrs.emplace_back("fmtScaleA", rewriter.getI32IntegerAttr(*scaleAFmt));
1648 attrs.emplace_back(
1649 "scaleBType", rewriter.getI32IntegerAttr(op.getBFirstScaleLane() / 16));
1650 attrs.emplace_back("fmtScaleB", rewriter.getI32IntegerAttr(*scaleBFmt));
1651
1652 // Reuse flags use default value of false.
1653 attrs.emplace_back("reuseA", rewriter.getBoolAttr(false));
1654 attrs.emplace_back("reuseB", rewriter.getBoolAttr(false));
1655
1656 // Convert typed float vectors to packed format.
1657 Value sourceA =
1658 packSmallFloatVectorOperand(rewriter, loc, adaptor.getSourceA());
1659 Value sourceB =
1660 packSmallFloatVectorOperand(rewriter, loc, adaptor.getSourceB());
1661
1662 // Pack scale vectors into i32/i64.
1663 Value packedScaleA = castScaleOperand(rewriter, loc, adaptor.getScaleA());
1664 Value packedScaleB = castScaleOperand(rewriter, loc, adaptor.getScaleB());
1665
1666 // Create the intrinsic call.
1667 OperationState loweredOp(loc, *intrinsicName);
1668 loweredOp.addTypes(outType);
1669 loweredOp.addOperands(
1670 {sourceA, sourceB, adaptor.getDestC(), packedScaleA, packedScaleB});
1671 loweredOp.addAttributes(attrs);
1672
1673 Operation *lowered = rewriter.create(loweredOp);
1674 rewriter.replaceOp(op, lowered->getResults());
1675
1676 return success();
1677 }
1678};
1679
1680struct TransposeLoadOpLowering
1681 : public ConvertOpToLLVMPattern<TransposeLoadOp> {
1682 TransposeLoadOpLowering(const LLVMTypeConverter &converter, Chipset chipset)
1683 : ConvertOpToLLVMPattern<TransposeLoadOp>(converter), chipset(chipset) {}
1684
1685 Chipset chipset;
1686
1687 LogicalResult
1688 matchAndRewrite(TransposeLoadOp op, TransposeLoadOpAdaptor adaptor,
1689 ConversionPatternRewriter &rewriter) const override {
1690 if (chipset != kGfx950)
1691 return op.emitOpError("Non-gfx950 chipset not supported");
1692
1693 Location loc = op.getLoc();
1694 auto srcMemRefType = cast<MemRefType>(op.getSrc().getType());
1695
1696 // Elements in subbyte memrefs are stored non-contiguously,
1697 // reject if source is sub-byte memref. Use emulated memrefs instead.
1698 size_t srcElementSize =
1699 srcMemRefType.getElementType().getIntOrFloatBitWidth();
1700 if (srcElementSize < 8)
1701 return op.emitOpError("Expect source memref to have at least 8 bits "
1702 "element size, got ")
1703 << srcElementSize;
1704
1705 auto resultType = cast<VectorType>(op.getResult().getType());
1706 Value srcPtr =
1707 getStridedElementPtr(rewriter, loc, srcMemRefType, adaptor.getSrc(),
1708 (adaptor.getSrcIndices()));
1709
1710 size_t numElements = resultType.getNumElements();
1711 size_t elementTypeSize =
1712 resultType.getElementType().getIntOrFloatBitWidth();
1713
1714 // ROCDL transpose load intrinsics return vectors of 32-bit integers, if
1715 // the element size is smaller than 16 bits.
1716 Type rocdlResultType = VectorType::get((numElements * elementTypeSize) / 32,
1717 rewriter.getIntegerType(32));
1718 Type llvmResultType = typeConverter->convertType(resultType);
1719
1720 switch (elementTypeSize) {
1721 case 4: {
1722 assert(numElements == 16);
1723 auto rocdlOp = ROCDL::ds_read_tr4_b64::create(rewriter, loc,
1724 rocdlResultType, srcPtr);
1725 rewriter.replaceOpWithNewOp<LLVM::BitcastOp>(op, llvmResultType, rocdlOp);
1726 break;
1727 }
1728 case 6: {
1729 assert(numElements == 16);
1730 auto rocdlOp = ROCDL::ds_read_tr6_b96::create(rewriter, loc,
1731 rocdlResultType, srcPtr);
1732 rewriter.replaceOpWithNewOp<LLVM::BitcastOp>(op, llvmResultType, rocdlOp);
1733 break;
1734 }
1735 case 8: {
1736 assert(numElements == 8);
1737 auto rocdlOp = ROCDL::ds_read_tr8_b64::create(rewriter, loc,
1738 rocdlResultType, srcPtr);
1739 rewriter.replaceOpWithNewOp<LLVM::BitcastOp>(op, llvmResultType, rocdlOp);
1740 break;
1741 }
1742 case 16: {
1743 assert(numElements == 4);
1744 rewriter.replaceOpWithNewOp<ROCDL::ds_read_tr16_b64>(op, llvmResultType,
1745 srcPtr);
1746 break;
1747 }
1748 default:
1749 return op.emitOpError("Unsupported element size for transpose load");
1750 }
1751 return success();
1752 }
1753};
1754
1755struct GatherToLDSOpLowering : public ConvertOpToLLVMPattern<GatherToLDSOp> {
1756 GatherToLDSOpLowering(const LLVMTypeConverter &converter, Chipset chipset)
1757 : ConvertOpToLLVMPattern<GatherToLDSOp>(converter), chipset(chipset) {}
1758
1759 Chipset chipset;
1760
1761 LogicalResult
1762 matchAndRewrite(GatherToLDSOp op, GatherToLDSOpAdaptor adaptor,
1763 ConversionPatternRewriter &rewriter) const override {
1764 if (chipset.majorVersion < 9 || chipset.majorVersion > 10)
1765 return op.emitOpError("pre-gfx9 and post-gfx10 not supported");
1766
1767 Location loc = op.getLoc();
1768
1769 auto srcMemRefType = cast<MemRefType>(op.getSrc().getType());
1770 auto dstMemRefType = cast<MemRefType>(op.getDst().getType());
1771
1772 // TODO: instead of only transfering one element per thread, we could
1773 // augment it to transfer multiple elements per thread by issuing multiple
1774 // `global_load_lds` instructions.
1775 Type transferType = op.getTransferType();
1776 int loadWidth = [&]() -> int {
1777 if (auto transferVectorType = dyn_cast<VectorType>(transferType)) {
1778 return (transferVectorType.getNumElements() *
1779 transferVectorType.getElementTypeBitWidth()) /
1780 8;
1781 }
1782 return transferType.getIntOrFloatBitWidth() / 8;
1783 }();
1784
1785 // Currently only 1, 2, 4, 12 and 16 byte loads are supported.
1786 if (!llvm::is_contained({1, 2, 4, 12, 16}, loadWidth))
1787 return op.emitOpError("chipset unsupported element size");
1788
1789 if (chipset != kGfx950 && llvm::is_contained({12, 16}, loadWidth))
1790 return op.emitOpError("Gather to LDS instructions with 12-byte and "
1791 "16-byte load widths are only supported on gfx950");
1792
1793 Value srcPtr =
1794 getStridedElementPtr(rewriter, loc, srcMemRefType, adaptor.getSrc(),
1795 (adaptor.getSrcIndices()));
1796 Value dstPtr =
1797 getStridedElementPtr(rewriter, loc, dstMemRefType, adaptor.getDst(),
1798 (adaptor.getDstIndices()));
1799
1800 rewriter.replaceOpWithNewOp<ROCDL::LoadToLDSOp>(
1801 op, srcPtr, dstPtr, rewriter.getI32IntegerAttr(loadWidth),
1802 /*offset=*/rewriter.getI32IntegerAttr(0),
1803 /*aux=*/rewriter.getI32IntegerAttr(0), ArrayAttr{}, ArrayAttr{},
1804 ArrayAttr{});
1805
1806 return success();
1807 }
1808};
1809
1810namespace {
1811struct ExtPackedFp8OpLowering final
1812 : public ConvertOpToLLVMPattern<ExtPackedFp8Op> {
1813 ExtPackedFp8OpLowering(const LLVMTypeConverter &converter, Chipset chipset)
1814 : ConvertOpToLLVMPattern<amdgpu::ExtPackedFp8Op>(converter),
1815 chipset(chipset) {}
1816 Chipset chipset;
1817
1818 LogicalResult
1819 matchAndRewrite(ExtPackedFp8Op op, ExtPackedFp8OpAdaptor adaptor,
1820 ConversionPatternRewriter &rewriter) const override;
1821};
1822
1823struct ScaledExtPackedMatrixOpLowering final
1824 : public ConvertOpToLLVMPattern<ScaledExtPackedMatrixOp> {
1825 ScaledExtPackedMatrixOpLowering(const LLVMTypeConverter &converter,
1826 Chipset chipset)
1827 : ConvertOpToLLVMPattern<amdgpu::ScaledExtPackedMatrixOp>(converter),
1828 chipset(chipset) {}
1829 Chipset chipset;
1830
1831 LogicalResult
1832 matchAndRewrite(ScaledExtPackedMatrixOp op,
1833 ScaledExtPackedMatrixOpAdaptor adaptor,
1834 ConversionPatternRewriter &rewriter) const override;
1835};
1836
1837struct PackedTrunc2xFp8OpLowering final
1838 : public ConvertOpToLLVMPattern<PackedTrunc2xFp8Op> {
1839 PackedTrunc2xFp8OpLowering(const LLVMTypeConverter &converter,
1840 Chipset chipset)
1841 : ConvertOpToLLVMPattern<amdgpu::PackedTrunc2xFp8Op>(converter),
1842 chipset(chipset) {}
1843 Chipset chipset;
1844
1845 LogicalResult
1846 matchAndRewrite(PackedTrunc2xFp8Op op, PackedTrunc2xFp8OpAdaptor adaptor,
1847 ConversionPatternRewriter &rewriter) const override;
1848};
1849
1850struct PackedStochRoundFp8OpLowering final
1851 : public ConvertOpToLLVMPattern<PackedStochRoundFp8Op> {
1852 PackedStochRoundFp8OpLowering(const LLVMTypeConverter &converter,
1853 Chipset chipset)
1854 : ConvertOpToLLVMPattern<amdgpu::PackedStochRoundFp8Op>(converter),
1855 chipset(chipset) {}
1856 Chipset chipset;
1857
1858 LogicalResult
1859 matchAndRewrite(PackedStochRoundFp8Op op,
1860 PackedStochRoundFp8OpAdaptor adaptor,
1861 ConversionPatternRewriter &rewriter) const override;
1862};
1863
1864struct ScaledExtPackedOpLowering final
1865 : public ConvertOpToLLVMPattern<ScaledExtPackedOp> {
1866 ScaledExtPackedOpLowering(const LLVMTypeConverter &converter, Chipset chipset)
1867 : ConvertOpToLLVMPattern<amdgpu::ScaledExtPackedOp>(converter),
1868 chipset(chipset) {}
1869 Chipset chipset;
1870
1871 LogicalResult
1872 matchAndRewrite(ScaledExtPackedOp op, ScaledExtPackedOpAdaptor adaptor,
1873 ConversionPatternRewriter &rewriter) const override;
1874};
1875
1876struct PackedScaledTruncOpLowering final
1877 : public ConvertOpToLLVMPattern<PackedScaledTruncOp> {
1878 PackedScaledTruncOpLowering(const LLVMTypeConverter &converter,
1879 Chipset chipset)
1880 : ConvertOpToLLVMPattern<amdgpu::PackedScaledTruncOp>(converter),
1881 chipset(chipset) {}
1882 Chipset chipset;
1883
1884 LogicalResult
1885 matchAndRewrite(PackedScaledTruncOp op, PackedScaledTruncOpAdaptor adaptor,
1886 ConversionPatternRewriter &rewriter) const override;
1887};
1888
1889} // end namespace
1890
1891LogicalResult ExtPackedFp8OpLowering::matchAndRewrite(
1892 ExtPackedFp8Op op, ExtPackedFp8OpAdaptor adaptor,
1893 ConversionPatternRewriter &rewriter) const {
1894 Location loc = op.getLoc();
1895 if (!(chipset == kGfx942 || hasOcpFp8(chipset)))
1896 return rewriter.notifyMatchFailure(
1897 loc, "Fp8 conversion instructions are not available on target "
1898 "architecture and their emulation is not implemented");
1899 Type v4i8 =
1900 getTypeConverter()->convertType(VectorType::get(4, rewriter.getI8Type()));
1901 Type i32 = getTypeConverter()->convertType(rewriter.getI32Type());
1902 Type f32 = getTypeConverter()->convertType(op.getResult().getType());
1903
1904 Value source = adaptor.getSource();
1905 auto sourceVecType = dyn_cast<VectorType>(op.getSource().getType());
1906 auto resultVecType = dyn_cast<VectorType>(op.getResult().getType());
1907 Type sourceElemType = getElementTypeOrSelf(op.getSource());
1908 // Extend to a v4i8
1909 if (!sourceVecType || sourceVecType.getNumElements() < 4) {
1910 Value longVec = LLVM::UndefOp::create(rewriter, loc, v4i8);
1911 if (!sourceVecType) {
1912 longVec = LLVM::InsertElementOp::create(
1913 rewriter, loc, longVec, source, createI32Constant(rewriter, loc, 0));
1914 } else {
1915 for (int32_t i = 0, e = sourceVecType.getNumElements(); i < e; ++i) {
1916 Value idx = createI32Constant(rewriter, loc, i);
1917 Value elem = LLVM::ExtractElementOp::create(rewriter, loc, source, idx);
1918 longVec =
1919 LLVM::InsertElementOp::create(rewriter, loc, longVec, elem, idx);
1920 }
1921 }
1922 source = longVec;
1923 }
1924 Value i32Source = LLVM::BitcastOp::create(rewriter, loc, i32, source);
1925 if (resultVecType) {
1926 if (typeIsExpectedBf8ForChipset(chipset, sourceElemType)) {
1927 rewriter.replaceOpWithNewOp<ROCDL::CvtPkF32Bf8Op>(op, f32, i32Source,
1928 op.getIndex());
1929 } else if (typeIsExpectedFp8ForChipset(chipset, sourceElemType)) {
1930 rewriter.replaceOpWithNewOp<ROCDL::CvtPkF32Fp8Op>(op, f32, i32Source,
1931 op.getIndex());
1932 }
1933 } else {
1934 if (typeIsExpectedBf8ForChipset(chipset, sourceElemType)) {
1935 rewriter.replaceOpWithNewOp<ROCDL::CvtF32Bf8Op>(op, f32, i32Source,
1936 op.getIndex());
1937 } else if (typeIsExpectedFp8ForChipset(chipset, sourceElemType)) {
1938 rewriter.replaceOpWithNewOp<ROCDL::CvtF32Fp8Op>(op, f32, i32Source,
1939 op.getIndex());
1940 }
1941 }
1942 return success();
1943}
1944
1945int32_t getScaleSel(int32_t blockSize, unsigned bitWidth, int32_t scaleWaveHalf,
1946 int32_t firstScaleByte) {
1947 // When lowering amdgpu.scaled_ext_packed_matrix to rocdl.cvt.scale.pk*.f*.f*
1948 // operations, the attributes blockSize, sourceType, scaleWaveHalf, and
1949 // firstScaleByte are merged into a single attribute scaleSel. This is how
1950 // those values are merged together. (Note: scaleWaveHalf isn't a high-level
1951 // attribute but is derifed from firstScaleLane).
1952 assert(llvm::is_contained({16, 32}, blockSize));
1953 assert(llvm::is_contained({4u, 6u, 8u}, bitWidth));
1954
1955 const bool isFp8 = bitWidth == 8;
1956 const bool isBlock16 = blockSize == 16;
1957
1958 if (!isFp8) {
1959 int32_t bit0 = isBlock16;
1960 assert(llvm::is_contained({0, 1, 2}, firstScaleByte));
1961 int32_t bit1 = (firstScaleByte == 2) << 1;
1962 assert(llvm::is_contained({0, 1}, scaleWaveHalf));
1963 int32_t bit2 = scaleWaveHalf << 2;
1964 return bit2 | bit1 | bit0;
1965 }
1966
1967 int32_t bit0 = isBlock16;
1968 // firstScaleByte is guaranteed to be defined by two bits.
1969 assert(llvm::is_contained({0, 1, 2, 3}, firstScaleByte));
1970 int32_t bits2and1 = firstScaleByte << 1;
1971 assert(llvm::is_contained({0, 1}, scaleWaveHalf));
1972 int32_t bit3 = scaleWaveHalf << 3;
1973 int32_t bits = bit3 | bits2and1 | bit0;
1974 // These are invalid cases.
1975 assert(!llvm::is_contained(
1976 {0b0011, 0b0101, 0b0111, 0b1000, 0b1001, 0b1011, 0b1111}, bits));
1977 return bits;
1978}
1979
1980static std::optional<StringRef>
1981scaledExtPacked816ToIntrinsic(Type srcElemType, Type destElemType) {
1982 using fp4 = Float4E2M1FNType;
1983 using fp8 = Float8E4M3FNType;
1984 using bf8 = Float8E5M2Type;
1985 using fp6 = Float6E2M3FNType;
1986 using bf6 = Float6E3M2FNType;
1987 if (isa<fp4>(srcElemType)) {
1988 if (destElemType.isF16())
1989 return ROCDL::CvtPkScalePk8F16Fp4Op::getOperationName();
1990 if (destElemType.isBF16())
1991 return ROCDL::CvtPkScalePk8Bf16Fp4Op::getOperationName();
1992 if (destElemType.isF32())
1993 return ROCDL::CvtPkScalePk8F32Fp4Op::getOperationName();
1994 return std::nullopt;
1995 }
1996 if (isa<fp8>(srcElemType)) {
1997 if (destElemType.isF16())
1998 return ROCDL::CvtPkScalePk8F16Fp8Op::getOperationName();
1999 if (destElemType.isBF16())
2000 return ROCDL::CvtPkScalePk8Bf16Fp8Op::getOperationName();
2001 if (destElemType.isF32())
2002 return ROCDL::CvtPkScalePk8F32Fp8Op::getOperationName();
2003 return std::nullopt;
2004 }
2005 if (isa<bf8>(srcElemType)) {
2006 if (destElemType.isF16())
2007 return ROCDL::CvtPkScalePk8F16Bf8Op::getOperationName();
2008 if (destElemType.isBF16())
2009 return ROCDL::CvtPkScalePk8Bf16Bf8Op::getOperationName();
2010 if (destElemType.isF32())
2011 return ROCDL::CvtPkScalePk8F32Bf8Op::getOperationName();
2012 return std::nullopt;
2013 }
2014 if (isa<fp6>(srcElemType)) {
2015 if (destElemType.isF16())
2016 return ROCDL::CvtPkScalePk16F16Fp6Op::getOperationName();
2017 if (destElemType.isBF16())
2018 return ROCDL::CvtPkScalePk16Bf16Fp6Op::getOperationName();
2019 if (destElemType.isF32())
2020 return ROCDL::CvtPkScalePk16F32Fp6Op::getOperationName();
2021 return std::nullopt;
2022 }
2023 if (isa<bf6>(srcElemType)) {
2024 if (destElemType.isF16())
2025 return ROCDL::CvtPkScalePk16F16Bf6Op::getOperationName();
2026 if (destElemType.isBF16())
2027 return ROCDL::CvtPkScalePk16Bf16Bf6Op::getOperationName();
2028 if (destElemType.isF32())
2029 return ROCDL::CvtPkScalePk16F32Bf6Op::getOperationName();
2030 return std::nullopt;
2031 }
2032 llvm_unreachable("invalid combination of element types for packed conversion "
2033 "instructions");
2034}
2035
2036LogicalResult ScaledExtPackedMatrixOpLowering::matchAndRewrite(
2037 ScaledExtPackedMatrixOp op, ScaledExtPackedMatrixOpAdaptor adaptor,
2038 ConversionPatternRewriter &rewriter) const {
2039 using fp4 = Float4E2M1FNType;
2040 using fp8 = Float8E4M3FNType;
2041 using bf8 = Float8E5M2Type;
2042 using fp6 = Float6E2M3FNType;
2043 using bf6 = Float6E3M2FNType;
2044 Location loc = op.getLoc();
2045 if (chipset != kGfx1250) {
2046 return rewriter.notifyMatchFailure(
2047 loc,
2048 "Scaled fp packed conversion instructions are not available on target "
2049 "architecture and their emulation is not implemented");
2050 }
2051 // Convert user-facing firstScaleLane (0 or 16) to the half of the wave that
2052 // is being selected.
2053 int32_t scaleWaveHalf = op.getFirstScaleLane() / 16;
2054 int32_t firstScaleByte = op.getFirstScaleByte();
2055 int32_t blockSize = op.getBlockSize();
2056 auto sourceType = cast<VectorType>(op.getSource().getType());
2057 auto srcElemType = cast<FloatType>(sourceType.getElementType());
2058 unsigned bitWidth = srcElemType.getWidth();
2059
2060 auto targetType = cast<VectorType>(op.getResult().getType());
2061 auto destElemType = cast<FloatType>(targetType.getElementType());
2062
2063 IntegerType i32 = rewriter.getI32Type();
2064 Value source = adaptor.getSource();
2065 Type llvmResultType = typeConverter->convertType(op.getResult().getType());
2066 Type packedType = nullptr;
2067 if (isa<fp4>(srcElemType)) {
2068 packedType = i32;
2069 packedType = getTypeConverter()->convertType(packedType);
2070 } else if (isa<fp8, bf8>(srcElemType)) {
2071 packedType = VectorType::get(2, i32);
2072 packedType = getTypeConverter()->convertType(packedType);
2073 } else if (isa<fp6, bf6>(srcElemType)) {
2074 packedType = VectorType::get(3, i32);
2075 packedType = getTypeConverter()->convertType(packedType);
2076 } else {
2077 llvm_unreachable("invalid element type for packed scaled ext");
2078 }
2079
2080 if (!packedType || !llvmResultType) {
2081 return rewriter.notifyMatchFailure(op, "type conversion failed");
2082 }
2083
2084 std::optional<StringRef> maybeIntrinsic =
2085 scaledExtPacked816ToIntrinsic(srcElemType, destElemType);
2086 if (!maybeIntrinsic.has_value())
2087 return op.emitOpError(
2088 "no intrinsic matching packed scaled conversion on the given chipset");
2089
2090 int32_t scaleSel =
2091 getScaleSel(blockSize, bitWidth, scaleWaveHalf, firstScaleByte);
2092 Value castedScale =
2093 LLVM::BitcastOp::create(rewriter, loc, i32, adaptor.getScale());
2094 Value castedSource =
2095 LLVM::BitcastOp::create(rewriter, loc, packedType, source);
2096
2097 OperationState loweredOp(loc, *maybeIntrinsic);
2098 loweredOp.addTypes({llvmResultType});
2099 loweredOp.addOperands({castedSource, castedScale});
2100
2101 SmallVector<NamedAttribute, 1> attrs;
2102 attrs.push_back(
2103 NamedAttribute("scaleSel", rewriter.getI32IntegerAttr(scaleSel)));
2104
2105 loweredOp.addAttributes(attrs);
2106 Operation *lowered = rewriter.create(loweredOp);
2107 rewriter.replaceOp(op, lowered);
2108
2109 return success();
2110}
2111
2112LogicalResult ScaledExtPackedOpLowering::matchAndRewrite(
2113 ScaledExtPackedOp op, ScaledExtPackedOpAdaptor adaptor,
2114 ConversionPatternRewriter &rewriter) const {
2115 Location loc = op.getLoc();
2116 if (chipset != kGfx950)
2117 return rewriter.notifyMatchFailure(
2118 loc, "Scaled fp conversion instructions are not available on target "
2119 "architecture and their emulation is not implemented");
2120 Type i32 = getTypeConverter()->convertType(rewriter.getI32Type());
2121
2122 Value source = adaptor.getSource();
2123 Value scale = adaptor.getScale();
2124
2125 VectorType sourceVecType = cast<VectorType>(op.getSource().getType());
2126 Type sourceElemType = sourceVecType.getElementType();
2127 VectorType destVecType = cast<VectorType>(op.getResult().getType());
2128 Type destElemType = destVecType.getElementType();
2129
2130 VectorType packedVecType;
2131 if (isa<Float8E5M2Type, Float8E4M3FNType>(sourceElemType)) {
2132 VectorType v4i8 = VectorType::get(4, rewriter.getI8Type());
2133 packedVecType = cast<VectorType>(getTypeConverter()->convertType(v4i8));
2134 } else if (isa<Float4E2M1FNType>(sourceElemType)) {
2135 VectorType v8i4 = VectorType::get(8, rewriter.getI4Type());
2136 packedVecType = cast<VectorType>(getTypeConverter()->convertType(v8i4));
2137 } else {
2138 llvm_unreachable("invalid element type for scaled ext");
2139 }
2140
2141 // Extend to a packedVectorType
2142 if (sourceVecType.getNumElements() < packedVecType.getNumElements()) {
2143 Value longVec = LLVM::ZeroOp::create(rewriter, loc, packedVecType);
2144 if (!sourceVecType) {
2145 longVec = LLVM::InsertElementOp::create(
2146 rewriter, loc, longVec, source, createI32Constant(rewriter, loc, 0));
2147 } else {
2148 for (int32_t i = 0, e = sourceVecType.getNumElements(); i < e; ++i) {
2149 Value idx = createI32Constant(rewriter, loc, i);
2150 Value elem = LLVM::ExtractElementOp::create(rewriter, loc, source, idx);
2151 longVec =
2152 LLVM::InsertElementOp::create(rewriter, loc, longVec, elem, idx);
2153 }
2154 }
2155 source = longVec;
2156 }
2157 Value i32Source = LLVM::BitcastOp::create(rewriter, loc, i32, source);
2158
2159 if (isa<Float8E5M2Type>(sourceElemType) && destElemType.isF32())
2160 rewriter.replaceOpWithNewOp<ROCDL::CvtScaleF32PkF32Bf8Op>(
2161 op, destVecType, i32Source, scale, op.getIndex());
2162 else if (isa<Float8E5M2Type>(sourceElemType) && destElemType.isF16())
2163 rewriter.replaceOpWithNewOp<ROCDL::CvtScaleF32PkF16Bf8Op>(
2164 op, destVecType, i32Source, scale, op.getIndex());
2165 else if (isa<Float8E5M2Type>(sourceElemType) && destElemType.isBF16())
2166 rewriter.replaceOpWithNewOp<ROCDL::CvtScaleF32PkBf16Bf8Op>(
2167 op, destVecType, i32Source, scale, op.getIndex());
2168 else if (isa<Float8E4M3FNType>(sourceElemType) && destElemType.isF32())
2169 rewriter.replaceOpWithNewOp<ROCDL::CvtScaleF32PkF32Fp8Op>(
2170 op, destVecType, i32Source, scale, op.getIndex());
2171 else if (isa<Float8E4M3FNType>(sourceElemType) && destElemType.isF16())
2172 rewriter.replaceOpWithNewOp<ROCDL::CvtScaleF32PkF16Fp8Op>(
2173 op, destVecType, i32Source, scale, op.getIndex());
2174 else if (isa<Float8E4M3FNType>(sourceElemType) && destElemType.isBF16())
2175 rewriter.replaceOpWithNewOp<ROCDL::CvtScaleF32PkBf16Fp8Op>(
2176 op, destVecType, i32Source, scale, op.getIndex());
2177 else if (isa<Float4E2M1FNType>(sourceElemType) && destElemType.isF32())
2178 rewriter.replaceOpWithNewOp<ROCDL::CvtScaleF32PkF32Fp4Op>(
2179 op, destVecType, i32Source, scale, op.getIndex());
2180 else if (isa<Float4E2M1FNType>(sourceElemType) && destElemType.isF16())
2181 rewriter.replaceOpWithNewOp<ROCDL::CvtScaleF32PkF16Fp4Op>(
2182 op, destVecType, i32Source, scale, op.getIndex());
2183 else if (isa<Float4E2M1FNType>(sourceElemType) && destElemType.isBF16())
2184 rewriter.replaceOpWithNewOp<ROCDL::CvtScaleF32PkBf16Fp4Op>(
2185 op, destVecType, i32Source, scale, op.getIndex());
2186 else
2187 return failure();
2188
2189 return success();
2190}
2191
2192LogicalResult PackedScaledTruncOpLowering::matchAndRewrite(
2193 PackedScaledTruncOp op, PackedScaledTruncOpAdaptor adaptor,
2194 ConversionPatternRewriter &rewriter) const {
2195 Location loc = op.getLoc();
2196 if (chipset != kGfx950)
2197 return rewriter.notifyMatchFailure(
2198 loc, "Scaled fp conversion instructions are not available on target "
2199 "architecture and their emulation is not implemented");
2200 Type v2i16 = getTypeConverter()->convertType(
2201 VectorType::get(2, rewriter.getI16Type()));
2202 Type i32 = getTypeConverter()->convertType(rewriter.getI32Type());
2203
2204 Type resultType = op.getResult().getType();
2205 Type resultElemType = getElementTypeOrSelf(resultType);
2206 VectorType sourceVecType = cast<VectorType>(op.getSource().getType());
2207 Type sourceElemType = sourceVecType.getElementType();
2208
2209 Type intResultType = isa<Float4E2M1FNType>(resultElemType) ? i32 : v2i16;
2210
2211 Value source = adaptor.getSource();
2212 Value scale = adaptor.getScale();
2213 Value existing = adaptor.getExisting();
2214 if (existing)
2215 existing = LLVM::BitcastOp::create(rewriter, loc, intResultType, existing);
2216 else
2217 existing = LLVM::ZeroOp::create(rewriter, loc, intResultType);
2218
2219 if (sourceVecType.getNumElements() < 2) {
2220 Value c0 = createI32Constant(rewriter, loc, 0);
2221 Value elem0 = LLVM::ExtractElementOp::create(rewriter, loc, source, c0);
2222 VectorType v2 = VectorType::get(2, sourceElemType);
2223 source = LLVM::ZeroOp::create(rewriter, loc, v2);
2224 source = LLVM::InsertElementOp::create(rewriter, loc, source, elem0, c0);
2225 }
2226
2227 Value sourceA, sourceB;
2228 if (sourceElemType.isF32()) {
2229 Value c0 = createI32Constant(rewriter, loc, 0);
2230 Value c1 = createI32Constant(rewriter, loc, 1);
2231 sourceA = LLVM::ExtractElementOp::create(rewriter, loc, source, c0);
2232 sourceB = LLVM::ExtractElementOp::create(rewriter, loc, source, c1);
2233 }
2234
2235 Value result;
2236 if (sourceElemType.isF32() && isa<Float8E5M2Type>(resultElemType))
2237 result = ROCDL::CvtScaleF32PkBf8F32Op::create(rewriter, loc, intResultType,
2238 existing, sourceA, sourceB,
2239 scale, op.getIndex());
2240 else if (sourceElemType.isF16() && isa<Float8E5M2Type>(resultElemType))
2241 result = ROCDL::CvtScaleF32PkBf8F16Op::create(
2242 rewriter, loc, intResultType, existing, source, scale, op.getIndex());
2243 else if (sourceElemType.isBF16() && isa<Float8E5M2Type>(resultElemType))
2244 result = ROCDL::CvtScaleF32PkBf8Bf16Op::create(
2245 rewriter, loc, intResultType, existing, source, scale, op.getIndex());
2246 else if (sourceElemType.isF32() && isa<Float8E4M3FNType>(resultElemType))
2247 result = ROCDL::CvtScaleF32PkFp8F32Op::create(rewriter, loc, intResultType,
2248 existing, sourceA, sourceB,
2249 scale, op.getIndex());
2250 else if (sourceElemType.isF16() && isa<Float8E4M3FNType>(resultElemType))
2251 result = ROCDL::CvtScaleF32PkFp8F16Op::create(
2252 rewriter, loc, intResultType, existing, source, scale, op.getIndex());
2253 else if (sourceElemType.isBF16() && isa<Float8E4M3FNType>(resultElemType))
2254 result = ROCDL::CvtScaleF32PkFp8Bf16Op::create(
2255 rewriter, loc, intResultType, existing, source, scale, op.getIndex());
2256 else if (sourceElemType.isF32() && isa<Float4E2M1FNType>(resultElemType))
2257 result = ROCDL::CvtScaleF32PkFp4F32Op::create(rewriter, loc, intResultType,
2258 existing, sourceA, sourceB,
2259 scale, op.getIndex());
2260 else if (sourceElemType.isF16() && isa<Float4E2M1FNType>(resultElemType))
2261 result = ROCDL::CvtScaleF32PkFp4F16Op::create(
2262 rewriter, loc, intResultType, existing, source, scale, op.getIndex());
2263 else if (sourceElemType.isBF16() && isa<Float4E2M1FNType>(resultElemType))
2264 result = ROCDL::CvtScaleF32PkFp4Bf16Op::create(
2265 rewriter, loc, intResultType, existing, source, scale, op.getIndex());
2266 else
2267 return failure();
2268
2269 result = rewriter.replaceOpWithNewOp<LLVM::BitcastOp>(
2270 op, getTypeConverter()->convertType(resultType), result);
2271 return success();
2272}
2273
2274LogicalResult PackedTrunc2xFp8OpLowering::matchAndRewrite(
2275 PackedTrunc2xFp8Op op, PackedTrunc2xFp8OpAdaptor adaptor,
2276 ConversionPatternRewriter &rewriter) const {
2277 Location loc = op.getLoc();
2278 if (!(chipset == kGfx942 || hasOcpFp8(chipset)))
2279 return rewriter.notifyMatchFailure(
2280 loc, "Fp8 conversion instructions are not available on target "
2281 "architecture and their emulation is not implemented");
2282 Type i32 = getTypeConverter()->convertType(rewriter.getI32Type());
2283
2284 Type resultType = op.getResult().getType();
2285 Type resultElemType = getElementTypeOrSelf(resultType);
2286
2287 Value sourceA = adaptor.getSourceA();
2288 Value sourceB = adaptor.getSourceB();
2289 if (!sourceB)
2290 sourceB = LLVM::UndefOp::create(rewriter, loc, sourceA.getType());
2291 Value existing = adaptor.getExisting();
2292 if (existing)
2293 existing = LLVM::BitcastOp::create(rewriter, loc, i32, existing);
2294 else
2295 existing = LLVM::UndefOp::create(rewriter, loc, i32);
2296
2297 Value result;
2298 if (typeIsExpectedBf8ForChipset(chipset, resultElemType))
2299 result = ROCDL::CvtPkBf8F32Op::create(rewriter, loc, i32, sourceA, sourceB,
2300 existing, op.getWordIndex());
2301 else if (typeIsExpectedFp8ForChipset(chipset, resultElemType))
2302 result = ROCDL::CvtPkFp8F32Op::create(rewriter, loc, i32, sourceA, sourceB,
2303 existing, op.getWordIndex());
2304
2305 result = rewriter.replaceOpWithNewOp<LLVM::BitcastOp>(
2306 op, getTypeConverter()->convertType(resultType), result);
2307 return success();
2308}
2309
2310LogicalResult PackedStochRoundFp8OpLowering::matchAndRewrite(
2311 PackedStochRoundFp8Op op, PackedStochRoundFp8OpAdaptor adaptor,
2312 ConversionPatternRewriter &rewriter) const {
2313 Location loc = op.getLoc();
2314 if (!(chipset == kGfx942 || hasOcpFp8(chipset)))
2315 return rewriter.notifyMatchFailure(
2316 loc, "Fp8 conversion instructions are not available on target "
2317 "architecture and their emulation is not implemented");
2318 Type i32 = getTypeConverter()->convertType(rewriter.getI32Type());
2319
2320 Type resultType = op.getResult().getType();
2321 Type resultElemType = getElementTypeOrSelf(resultType);
2322
2323 Value source = adaptor.getSource();
2324 Value stoch = adaptor.getStochiasticParam();
2325 Value existing = adaptor.getExisting();
2326 if (existing)
2327 existing = LLVM::BitcastOp::create(rewriter, loc, i32, existing);
2328 else
2329 existing = LLVM::UndefOp::create(rewriter, loc, i32);
2330
2331 Value result;
2332 if (typeIsExpectedBf8ForChipset(chipset, resultElemType))
2333 result = ROCDL::CvtSrBf8F32Op::create(rewriter, loc, i32, source, stoch,
2334 existing, op.getStoreIndex());
2335 else if (typeIsExpectedFp8ForChipset(chipset, resultElemType))
2336 result = ROCDL::CvtSrFp8F32Op::create(rewriter, loc, i32, source, stoch,
2337 existing, op.getStoreIndex());
2338
2339 result = rewriter.replaceOpWithNewOp<LLVM::BitcastOp>(
2340 op, getTypeConverter()->convertType(resultType), result);
2341 return success();
2342}
2343
2344// Implement the AMDGPU_DPPLowering class that will convert the amdgpu.dpp
2345// operation into the corresponding ROCDL instructions.
2346struct AMDGPUDPPLowering : public ConvertOpToLLVMPattern<DPPOp> {
2347 AMDGPUDPPLowering(const LLVMTypeConverter &converter, Chipset chipset)
2348 : ConvertOpToLLVMPattern<DPPOp>(converter), chipset(chipset) {}
2349 Chipset chipset;
2350
2351 LogicalResult
2352 matchAndRewrite(DPPOp DppOp, DPPOp::Adaptor adaptor,
2353 ConversionPatternRewriter &rewriter) const override {
2354
2355 // Convert the source operand to the corresponding LLVM type
2356 Location loc = DppOp.getLoc();
2357 Value src = adaptor.getSrc();
2358 Value old = adaptor.getOld();
2359 Type srcType = src.getType();
2360 Type oldType = old.getType();
2361 Type llvmType = nullptr;
2362 if (srcType.getIntOrFloatBitWidth() < 32) {
2363 llvmType = rewriter.getI32Type();
2364 } else if (isa<FloatType>(srcType)) {
2365 llvmType = (srcType.getIntOrFloatBitWidth() == 32)
2366 ? rewriter.getF32Type()
2367 : rewriter.getF64Type();
2368 } else if (isa<IntegerType>(srcType)) {
2369 llvmType = (srcType.getIntOrFloatBitWidth() == 32)
2370 ? rewriter.getI32Type()
2371 : rewriter.getI64Type();
2372 }
2373 auto llvmSrcIntType = typeConverter->convertType(
2374 rewriter.getIntegerType(srcType.getIntOrFloatBitWidth()));
2375
2376 // If the source type is less of 32, use bitcast to convert it to i32.
2377 auto convertOperand = [&](Value operand, Type operandType) {
2378 if (operandType.getIntOrFloatBitWidth() <= 16) {
2379 if (llvm::isa<FloatType>(operandType)) {
2380 operand =
2381 LLVM::BitcastOp::create(rewriter, loc, llvmSrcIntType, operand);
2382 }
2383 auto llvmVecType = typeConverter->convertType(mlir::VectorType::get(
2384 32 / operandType.getIntOrFloatBitWidth(), llvmSrcIntType));
2385 Value undefVec = LLVM::UndefOp::create(rewriter, loc, llvmVecType);
2386 operand =
2387 LLVM::InsertElementOp::create(rewriter, loc, undefVec, operand,
2388 createI32Constant(rewriter, loc, 0));
2389 operand = LLVM::BitcastOp::create(rewriter, loc, llvmType, operand);
2390 }
2391 return operand;
2392 };
2393
2394 src = convertOperand(src, srcType);
2395 old = convertOperand(old, oldType);
2396
2397 // This is taken from the following file llvm/lib/Target/AMDGPU/SIDefines.h
2398 enum DppCtrl : unsigned {
2399 ROW_SHL0 = 0x100,
2400 ROW_SHR0 = 0x110,
2401 ROW_ROR0 = 0x120,
2402 WAVE_SHL1 = 0x130,
2403 WAVE_ROL1 = 0x134,
2404 WAVE_SHR1 = 0x138,
2405 WAVE_ROR1 = 0x13C,
2406 ROW_MIRROR = 0x140,
2407 ROW_HALF_MIRROR = 0x141,
2408 BCAST15 = 0x142,
2409 BCAST31 = 0x143,
2410 };
2411
2412 auto kind = DppOp.getKind();
2413 auto permArgument = DppOp.getPermArgument();
2414 uint32_t DppCtrl = 0;
2415
2416 switch (kind) {
2417
2418 case DPPPerm::quad_perm: {
2419 auto quadPermAttr = cast<ArrayAttr>(*permArgument);
2420 int32_t i = 0;
2421 for (auto elem : quadPermAttr.getAsRange<IntegerAttr>()) {
2422 uint32_t num = elem.getInt();
2423 DppCtrl |= num << (i * 2);
2424 i++;
2425 }
2426 break;
2427 }
2428 case DPPPerm::row_shl: {
2429 auto intAttr = cast<IntegerAttr>(*permArgument);
2430 DppCtrl = intAttr.getInt() + DppCtrl::ROW_SHL0;
2431 break;
2432 }
2433 case DPPPerm::row_shr: {
2434 auto intAttr = cast<IntegerAttr>(*permArgument);
2435 DppCtrl = intAttr.getInt() + DppCtrl::ROW_SHR0;
2436 break;
2437 }
2438 case DPPPerm::row_ror: {
2439 auto intAttr = cast<IntegerAttr>(*permArgument);
2440 DppCtrl = intAttr.getInt() + DppCtrl::ROW_ROR0;
2441 break;
2442 }
2443 case DPPPerm::wave_shl:
2444 DppCtrl = DppCtrl::WAVE_SHL1;
2445 break;
2446 case DPPPerm::wave_shr:
2447 DppCtrl = DppCtrl::WAVE_SHR1;
2448 break;
2449 case DPPPerm::wave_rol:
2450 DppCtrl = DppCtrl::WAVE_ROL1;
2451 break;
2452 case DPPPerm::wave_ror:
2453 DppCtrl = DppCtrl::WAVE_ROR1;
2454 break;
2455 case DPPPerm::row_mirror:
2456 DppCtrl = DppCtrl::ROW_MIRROR;
2457 break;
2458 case DPPPerm::row_half_mirror:
2459 DppCtrl = DppCtrl::ROW_HALF_MIRROR;
2460 break;
2461 case DPPPerm::row_bcast_15:
2462 DppCtrl = DppCtrl::BCAST15;
2463 break;
2464 case DPPPerm::row_bcast_31:
2465 DppCtrl = DppCtrl::BCAST31;
2466 break;
2467 }
2468
2469 // Check for row_mask, bank_mask, bound_ctrl if they exist and create
2470 // constants
2471 auto rowMask = DppOp->getAttrOfType<IntegerAttr>("row_mask").getInt();
2472 auto bankMask = DppOp->getAttrOfType<IntegerAttr>("bank_mask").getInt();
2473 bool boundCtrl = DppOp->getAttrOfType<BoolAttr>("bound_ctrl").getValue();
2474
2475 // create a ROCDL_DPPMovOp instruction with the appropriate attributes
2476 auto dppMovOp =
2477 ROCDL::DPPUpdateOp::create(rewriter, loc, llvmType, old, src, DppCtrl,
2478 rowMask, bankMask, boundCtrl);
2479
2480 Value result = dppMovOp.getRes();
2481 if (srcType.getIntOrFloatBitWidth() < 32) {
2482 result = LLVM::TruncOp::create(rewriter, loc, llvmSrcIntType, result);
2483 if (!llvm::isa<IntegerType>(srcType)) {
2484 result = LLVM::BitcastOp::create(rewriter, loc, srcType, result);
2485 }
2486 }
2487
2488 // We are replacing the AMDGPU_DPPOp instruction with the new
2489 // ROCDL_DPPMovOp instruction
2490 rewriter.replaceOp(DppOp, ValueRange(result));
2491 return success();
2492 }
2493};
2494
2495struct AMDGPUSwizzleBitModeLowering
2496 : public ConvertOpToLLVMPattern<SwizzleBitModeOp> {
2497 using ConvertOpToLLVMPattern::ConvertOpToLLVMPattern;
2498
2499 LogicalResult
2500 matchAndRewrite(SwizzleBitModeOp op, OpAdaptor adaptor,
2501 ConversionPatternRewriter &rewriter) const override {
2502 Location loc = op.getLoc();
2503 Type i32 = rewriter.getI32Type();
2504 Value src = adaptor.getSrc();
2505 SmallVector<Value> decomposed =
2506 LLVM::decomposeValue(rewriter, loc, src, i32);
2507 unsigned andMask = op.getAndMask();
2508 unsigned orMask = op.getOrMask();
2509 unsigned xorMask = op.getXorMask();
2510
2511 // bit 15 is 0 for the BitMode swizzle.
2512 // https://gpuopen.com/learn/amd-gcn-assembly-cross-lane-operations/
2513 unsigned mask = andMask | (orMask << 5) | (xorMask << 10);
2514 Value maskValue = createI32Constant(rewriter, loc, mask);
2515 SmallVector<Value> swizzled;
2516 for (Value v : decomposed) {
2517 Value res =
2518 ROCDL::DsSwizzleOp::create(rewriter, loc, v.getType(), v, maskValue);
2519 swizzled.emplace_back(res);
2520 }
2521
2522 Value result = LLVM::composeValue(rewriter, loc, swizzled, src.getType());
2523 rewriter.replaceOp(op, result);
2524 return success();
2525 }
2526};
2527
2528struct AMDGPUPermlaneLowering : public ConvertOpToLLVMPattern<PermlaneSwapOp> {
2529 using ConvertOpToLLVMPattern::ConvertOpToLLVMPattern;
2530
2531 AMDGPUPermlaneLowering(const LLVMTypeConverter &converter, Chipset chipset)
2532 : ConvertOpToLLVMPattern<PermlaneSwapOp>(converter), chipset(chipset) {}
2533 Chipset chipset;
2534
2535 LogicalResult
2536 matchAndRewrite(PermlaneSwapOp op, OpAdaptor adaptor,
2537 ConversionPatternRewriter &rewriter) const override {
2538 if (chipset < kGfx950)
2539 return op->emitOpError("permlane_swap is only supported on gfx950+");
2540
2541 Location loc = op.getLoc();
2542 Type i32 = rewriter.getI32Type();
2543 Value src = adaptor.getSrc();
2544 unsigned rowLength = op.getRowLength();
2545 bool fi = op.getFetchInactive();
2546 bool boundctrl = op.getBoundCtrl();
2547
2548 SmallVector<Value> decomposed =
2549 LLVM::decomposeValue(rewriter, loc, src, i32);
2550
2551 SmallVector<Value> permuted;
2552 for (Value v : decomposed) {
2553 Value res;
2554 Type i32pair = LLVM::LLVMStructType::getLiteral(
2555 rewriter.getContext(), {v.getType(), v.getType()});
2556
2557 if (rowLength == 16)
2558 res = ROCDL::Permlane16SwapOp::create(rewriter, loc, i32pair, v, v, fi,
2559 boundctrl);
2560 else if (rowLength == 32)
2561 res = ROCDL::Permlane32SwapOp::create(rewriter, loc, i32pair, v, v, fi,
2562 boundctrl);
2563 else
2564 llvm_unreachable("unsupported row length");
2565
2566 Value vdst0 = LLVM::ExtractValueOp::create(rewriter, loc, res, {0});
2567 Value vdst1 = LLVM::ExtractValueOp::create(rewriter, loc, res, {1});
2568
2569 Value isEqual = LLVM::ICmpOp::create(rewriter, loc,
2570 LLVM::ICmpPredicate::eq, vdst0, v);
2571
2572 // Per `permlane(16|32)` semantics: if the first extracted element equals
2573 // 'v', the result is the second element; otherwise it is the first.
2574 Value vdstNew =
2575 LLVM::SelectOp::create(rewriter, loc, isEqual, vdst1, vdst0);
2576 permuted.emplace_back(vdstNew);
2577 }
2578
2579 Value result = LLVM::composeValue(rewriter, loc, permuted, src.getType());
2580 rewriter.replaceOp(op, result);
2581 return success();
2582 }
2583};
2584
2585static Value setValueAtOffset(ConversionPatternRewriter &rewriter, Location loc,
2586 Value accumulator, Value value, int64_t shift) {
2587 shift = shift % 32;
2588 Value shiftAmount;
2589 if (shift != 0) {
2590 shiftAmount = createI32Constant(rewriter, loc, shift % 32);
2591 value = LLVM::ShlOp::create(rewriter, loc, value, shiftAmount);
2592 }
2593
2594 if (matchPattern(accumulator, mlir::m_Zero()))
2595 return value;
2596
2597 constexpr bool isDisjoint = true;
2598 return LLVM::OrOp::create(rewriter, loc, accumulator, value, isDisjoint);
2599}
2600
2601template <typename BaseOp>
2602struct AMDGPUMakeDmaBaseLowering : public ConvertOpToLLVMPattern<BaseOp> {
2603 using ConvertOpToLLVMPattern<BaseOp>::ConvertOpToLLVMPattern;
2604 using Adaptor = typename ConvertOpToLLVMPattern<BaseOp>::OpAdaptor;
2605
2606 AMDGPUMakeDmaBaseLowering(const LLVMTypeConverter &converter, Chipset chipset)
2607 : ConvertOpToLLVMPattern<BaseOp>(converter), chipset(chipset) {}
2608 Chipset chipset;
2609
2610 LogicalResult
2611 matchAndRewrite(BaseOp op, Adaptor adaptor,
2612 ConversionPatternRewriter &rewriter) const override {
2613 if (chipset < kGfx1250)
2614 return op->emitOpError("make_dma_base is only supported on gfx1250");
2615
2616 Location loc = op.getLoc();
2617
2618 constexpr int32_t constlen = 4;
2619 Value consts[constlen];
2620 for (int64_t i = 0; i < constlen; ++i)
2621 consts[i] = createI32Constant(rewriter, loc, i);
2622
2623 constexpr int32_t sgprslen = constlen;
2624 Value sgprs[sgprslen];
2625 for (int64_t i = 0; i < sgprslen; ++i) {
2626 sgprs[i] = consts[0];
2627 }
2628
2629 sgprs[0] = consts[1];
2630
2631 if constexpr (BaseOp::isGather()) {
2632 sgprs[0] = setValueAtOffset(rewriter, loc, sgprs[0], consts[1], 30);
2633
2634 auto type = cast<TDMGatherBaseType>(op.getResult().getType());
2635 Type indexType = type.getIndexType();
2636 unsigned indexSize = indexType.getIntOrFloatBitWidth();
2637 assert(llvm::is_contained({16u, 32u}, indexSize) &&
2638 "expected index_size to be 16 or 32");
2639 unsigned idx = (indexSize / 16) - 1;
2640
2641 if (idx)
2642 sgprs[0] = setValueAtOffset(rewriter, loc, sgprs[0], consts[1], 31);
2643 }
2644
2645 ValueRange ldsIndices = adaptor.getLdsIndices();
2646 Value lds = adaptor.getLds();
2647 auto ldsMemRefType = cast<MemRefType>(op.getLds().getType());
2648
2649 Value ldsPtr = ConvertToLLVMPattern::getStridedElementPtr(
2650 rewriter, loc, ldsMemRefType, lds, ldsIndices);
2651
2652 ValueRange globalIndices = adaptor.getGlobalIndices();
2653 Value global = adaptor.getGlobal();
2654 auto globalMemRefType = cast<MemRefType>(op.getGlobal().getType());
2655
2656 Value globalPtr = ConvertToLLVMPattern::getStridedElementPtr(
2657 rewriter, loc, globalMemRefType, global, globalIndices);
2658
2659 Type i32 = rewriter.getI32Type();
2660 Type i64 = rewriter.getI64Type();
2661
2662 sgprs[1] = LLVM::PtrToIntOp::create(rewriter, loc, i32, ldsPtr);
2663 Value castForGlobalAddr =
2664 LLVM::PtrToIntOp::create(rewriter, loc, i64, globalPtr);
2665
2666 sgprs[2] = LLVM::TruncOp::create(rewriter, loc, i32, castForGlobalAddr);
2667
2668 Value shift = LLVM::LShrOp::create(rewriter, loc, castForGlobalAddr,
2669 createI64Constant(rewriter, loc, 32));
2670
2671 Value highHalf = LLVM::TruncOp::create(rewriter, loc, i32, shift);
2672
2673 Value mask = createI32Constant(rewriter, loc, (1ull << 25) - 1);
2674 highHalf = LLVM::AndOp::create(rewriter, loc, highHalf, mask);
2675
2676 sgprs[3] = setValueAtOffset(rewriter, loc, highHalf, consts[2], 30);
2677
2678 Type v4i32 = this->typeConverter->convertType(VectorType::get(4, i32));
2679 assert(v4i32 && "expected type conversion to succeed");
2680 Value result = LLVM::PoisonOp::create(rewriter, loc, v4i32);
2681
2682 for (auto [sgpr, constant] : llvm::zip_equal(sgprs, consts))
2683 result =
2684 LLVM::InsertElementOp::create(rewriter, loc, result, sgpr, constant);
2685
2686 rewriter.replaceOp(op, result);
2687 return success();
2688 }
2689};
2690
2691template <typename DescriptorOp>
2692struct AMDGPULowerDescriptor : public ConvertOpToLLVMPattern<DescriptorOp> {
2693 using ConvertOpToLLVMPattern<DescriptorOp>::ConvertOpToLLVMPattern;
2694 using OpAdaptor = typename ConvertOpToLLVMPattern<DescriptorOp>::OpAdaptor;
2695
2696 AMDGPULowerDescriptor(const LLVMTypeConverter &converter, Chipset chipset)
2697 : ConvertOpToLLVMPattern<DescriptorOp>(converter), chipset(chipset) {}
2698 Chipset chipset;
2699
2700 Value getDGroup0(OpAdaptor adaptor) const { return adaptor.getBase(); }
2701
2702 Value setWorkgroupMask(DescriptorOp op, OpAdaptor adaptor,
2703 ConversionPatternRewriter &rewriter, Location loc,
2704 Value sgpr0) const {
2705 Value mask = op.getWorkgroupMask();
2706 if (!mask)
2707 return sgpr0;
2708
2709 Type i16 = rewriter.getI16Type();
2710 mask = LLVM::BitcastOp::create(rewriter, loc, i16, mask);
2711 Type i32 = rewriter.getI32Type();
2712 Value extendedMask = LLVM::ZExtOp::create(rewriter, loc, i32, mask);
2713 return setValueAtOffset(rewriter, loc, sgpr0, extendedMask, 0);
2714 }
2715
2716 Value setDataSize(DescriptorOp op, OpAdaptor adaptor,
2717 ConversionPatternRewriter &rewriter, Location loc,
2718 Value sgpr0, ArrayRef<Value> consts) const {
2719 unsigned elementTypeWidthInBits = op.getElementTypeWidth();
2720 assert(llvm::is_contained({8u, 16u, 32u, 64u}, elementTypeWidthInBits) &&
2721 "expected type width to be 8, 16, 32, or 64.");
2722 int64_t idx = llvm::Log2_32(elementTypeWidthInBits / 8);
2723 Value size = consts[idx];
2724 return setValueAtOffset(rewriter, loc, sgpr0, size, 16);
2725 }
2726
2727 Value setAtomicBarrier(DescriptorOp op, OpAdaptor adaptor,
2728 ConversionPatternRewriter &rewriter, Location loc,
2729 Value sgpr0, ArrayRef<Value> consts) const {
2730 if (!adaptor.getAtomicBarrierAddress())
2731 return sgpr0;
2732
2733 return setValueAtOffset(rewriter, loc, sgpr0, consts[1], 18);
2734 }
2735
2736 Value setIterateEnable(DescriptorOp op, OpAdaptor adaptor,
2737 ConversionPatternRewriter &rewriter, Location loc,
2738 Value sgpr0, ArrayRef<Value> consts) const {
2739 if (!adaptor.getGlobalIncrement())
2740 return sgpr0;
2741
2742 // Value is ignored when in gather mode.
2743 // TODO: emit error earlier?
2744 return setValueAtOffset(rewriter, loc, sgpr0, consts[1], 19);
2745 }
2746
2747 Value setPadEnable(DescriptorOp op, OpAdaptor adaptor,
2748 ConversionPatternRewriter &rewriter, Location loc,
2749 Value sgpr0, ArrayRef<Value> consts) const {
2750 if (!op.getPadAmount())
2751 return sgpr0;
2752
2753 return setValueAtOffset(rewriter, loc, sgpr0, consts[1], 20);
2754 }
2755
2756 Value setEarlyTimeout(DescriptorOp op, OpAdaptor adaptor,
2757 ConversionPatternRewriter &rewriter, Location loc,
2758 Value sgpr0, ArrayRef<Value> consts) const {
2759 if (!op.getWorkgroupMask())
2760 return sgpr0;
2761
2762 return setValueAtOffset(rewriter, loc, sgpr0, consts[1], 21);
2763 }
2764
2765 Value setPadInterval(DescriptorOp op, OpAdaptor adaptor,
2766 ConversionPatternRewriter &rewriter, Location loc,
2767 Value sgpr0, ArrayRef<Value> consts) const {
2768 if (!op.getPadAmount())
2769 return sgpr0;
2770
2771 // pre-condition: padInterval can be a power of two between 2 and 256.
2772 // TODO: Validation if the value breaks the pre-condition.
2773 // If the pre-condition fails, there is a possibility of
2774 // affecting the higher bits. In a following PR implement
2775 // RuntimeVerifiableOpInterface that instruments conditions that need to be
2776 // checked at runtime.
2777 IntegerType i32 = rewriter.getI32Type();
2778 Value padInterval = adaptor.getPadInterval();
2779 padInterval = LLVM::CountTrailingZerosOp::create(rewriter, loc, i32,
2780 padInterval, false);
2781 padInterval = LLVM::SubOp::create(rewriter, loc, padInterval, consts[1]);
2782 // post-condition: padInterval can be a value between 0 and 7.
2783 return setValueAtOffset(rewriter, loc, sgpr0, padInterval, 22);
2784 }
2785
2786 Value setPadAmount(DescriptorOp op, OpAdaptor adaptor,
2787 ConversionPatternRewriter &rewriter, Location loc,
2788 Value sgpr0, ArrayRef<Value> consts) const {
2789 if (!op.getPadAmount())
2790 return sgpr0;
2791
2792 // pre-condition: padAmount is a value between 1-128.
2793 // TODO: Validation if the value breaks the pre-condition.
2794 // If the pre-condition fails, there is a possibility of
2795 // affecting the higher bits. In a following PR implement
2796 // RuntimeVerifiableOpInterface that instruments conditions that need to be
2797 // checked at runtime.
2798 Value padAmount = adaptor.getPadAmount();
2799 padAmount = LLVM::SubOp::create(rewriter, loc, padAmount, consts[1]);
2800 // post-condition: padAmount is a value between 0-127.
2801 return setValueAtOffset(rewriter, loc, sgpr0, padAmount, 25);
2802 }
2803
2804 Value setAtomicBarrierAddress(DescriptorOp op, OpAdaptor adaptor,
2805 ConversionPatternRewriter &rewriter,
2806 Location loc, Value sgpr1,
2807 ArrayRef<Value> consts) const {
2808 if (!adaptor.getAtomicBarrierAddress())
2809 return sgpr1;
2810
2811 Value atomicBarrierAddress = adaptor.getAtomicBarrierAddress();
2812 auto barrierAddressTy =
2813 cast<MemRefType>(op.getAtomicBarrierAddress().getType());
2814 ValueRange atomicBarrierIndices = adaptor.getAtomicBarrierIndices();
2815 atomicBarrierAddress = ConvertToLLVMPattern::getStridedElementPtr(
2816 rewriter, loc, barrierAddressTy, atomicBarrierAddress,
2817 atomicBarrierIndices);
2818 IntegerType i32 = rewriter.getI32Type();
2819 // pre-condition: atomicBarrierAddress is aligned to 8 bytes which implies
2820 // that the 3 LSBs are zero.
2821 // TODO: Validation if the value breaks the pre-condition.
2822 // In a following PR implement RuntimeVerifiableOpInterface
2823 // that instruments conditions that need to be checked at runtime.
2824 atomicBarrierAddress =
2825 LLVM::PtrToIntOp::create(rewriter, loc, i32, atomicBarrierAddress);
2826 atomicBarrierAddress =
2827 LLVM::LShrOp::create(rewriter, loc, atomicBarrierAddress, consts[3]);
2828 Value mask = createI32Constant(rewriter, loc, 0xFFFF);
2829 atomicBarrierAddress =
2830 LLVM::AndOp::create(rewriter, loc, atomicBarrierAddress, mask);
2831 return setValueAtOffset(rewriter, loc, sgpr1, atomicBarrierAddress, 32);
2832 }
2833
2834 std::pair<Value, Value> setTensorDimX(DescriptorOp op, OpAdaptor adaptor,
2835 ConversionPatternRewriter &rewriter,
2836 Location loc, Value sgpr1, Value sgpr2,
2837 ArrayRef<Value> consts, uint64_t dimX,
2838 uint32_t offset) const {
2839 ArrayRef<int64_t> globalStaticSizes = adaptor.getGlobalStaticSizes();
2840 ValueRange globalDynamicSizes = adaptor.getGlobalDynamicSizes();
2841 SmallVector<OpFoldResult> mixedGlobalSizes =
2842 getMixedValues(globalStaticSizes, globalDynamicSizes, rewriter);
2843 if (mixedGlobalSizes.size() <= dimX)
2844 return {sgpr1, sgpr2};
2845
2846 OpFoldResult tensorDimXOpFoldResult = *(mixedGlobalSizes.rbegin() + dimX);
2847 // pre-condition: tensorDimX is less than 2^32-1
2848 // TODO: Validation if the value breaks the pre-condition.
2849 // In a following PR implement RuntimeVerifiableOpInterface that instruments
2850 // conditions that need to be checked at runtime. This could also be fixed
2851 // by saying that mixedGlobalSizes is a DynamicI32List.
2852 Value tensorDimX;
2853 if (auto attr = dyn_cast<Attribute>(tensorDimXOpFoldResult)) {
2854 tensorDimX =
2855 createI32Constant(rewriter, loc, cast<IntegerAttr>(attr).getInt());
2856 } else {
2857 IntegerType i32 = rewriter.getI32Type();
2858 tensorDimX = cast<Value>(tensorDimXOpFoldResult);
2859 tensorDimX = LLVM::TruncOp::create(rewriter, loc, i32, tensorDimX);
2860 }
2861
2862 sgpr1 = setValueAtOffset(rewriter, loc, sgpr1, tensorDimX, offset);
2863
2864 Value c16 = createI32Constant(rewriter, loc, 16);
2865 Value tensorDimXHigh = LLVM::LShrOp::create(rewriter, loc, tensorDimX, c16);
2866 sgpr2 = setValueAtOffset(rewriter, loc, sgpr2, tensorDimXHigh, offset + 16);
2867 return {sgpr1, sgpr2};
2868 }
2869
2870 std::pair<Value, Value> setTensorDim0(DescriptorOp op, OpAdaptor adaptor,
2871 ConversionPatternRewriter &rewriter,
2872 Location loc, Value sgpr1, Value sgpr2,
2873 ArrayRef<Value> consts) const {
2874 return setTensorDimX(op, adaptor, rewriter, loc, sgpr1, sgpr2, consts, 0,
2875 48);
2876 }
2877
2878 std::pair<Value, Value> setTensorDim1(DescriptorOp op, OpAdaptor adaptor,
2879 ConversionPatternRewriter &rewriter,
2880 Location loc, Value sgpr2, Value sgpr3,
2881 ArrayRef<Value> consts) const {
2882 return setTensorDimX(op, adaptor, rewriter, loc, sgpr2, sgpr3, consts, 1,
2883 80);
2884 }
2885
2886 Value setTileDimX(DescriptorOp op, OpAdaptor adaptor,
2887 ConversionPatternRewriter &rewriter, Location loc,
2888 Value sgpr, ArrayRef<Value> consts, size_t dimX,
2889 int64_t offset) const {
2890 ArrayRef<int64_t> sharedStaticSizes = adaptor.getSharedStaticSizes();
2891 ValueRange sharedDynamicSizes = adaptor.getSharedDynamicSizes();
2892 SmallVector<OpFoldResult> mixedSharedSizes =
2893 getMixedValues(sharedStaticSizes, sharedDynamicSizes, rewriter);
2894 if (mixedSharedSizes.size() <= dimX)
2895 return sgpr;
2896
2897 OpFoldResult tileDimXOpFoldResult = *(mixedSharedSizes.rbegin() + dimX);
2898 // pre-condition: tileDimX is less than 2^16-1
2899 // TODO: Validation if the value breaks the pre-condition.
2900 // If the pre-condition fails, there is a possibility of
2901 // affecting the higher bits. In a following PR implement
2902 // RuntimeVerifiableOpInterface that instruments conditions that need to be
2903 // checked at runtime. This could also be fixed by saying that
2904 // mixedSharedSizes is a DynamicI16List.
2905 Value tileDimX;
2906 if (auto attr = dyn_cast<Attribute>(tileDimXOpFoldResult)) {
2907 tileDimX =
2908 createI32Constant(rewriter, loc, cast<IntegerAttr>(attr).getInt());
2909 } else {
2910 IntegerType i32 = rewriter.getI32Type();
2911 tileDimX = cast<Value>(tileDimXOpFoldResult);
2912 tileDimX = LLVM::TruncOp::create(rewriter, loc, i32, tileDimX);
2913 }
2914
2915 return setValueAtOffset(rewriter, loc, sgpr, tileDimX, offset);
2916 }
2917
2918 Value setTileDim0(DescriptorOp op, OpAdaptor adaptor,
2919 ConversionPatternRewriter &rewriter, Location loc,
2920 Value sgpr3, ArrayRef<Value> consts) const {
2921 return setTileDimX(op, adaptor, rewriter, loc, sgpr3, consts, 0, 112);
2922 }
2923
2924 Value setTileDim1(DescriptorOp op, OpAdaptor adaptor,
2925 ConversionPatternRewriter &rewriter, Location loc,
2926 Value sgpr4, ArrayRef<Value> consts) const {
2927 return setTileDimX(op, adaptor, rewriter, loc, sgpr4, consts, 1, 128);
2928 }
2929
2930 Value setValidIndices(DescriptorOp op, OpAdaptor adaptor,
2931 ConversionPatternRewriter &rewriter, Location loc,
2932 Value sgpr4, ArrayRef<Value> consts) const {
2933 auto type = cast<VectorType>(op.getIndices().getType());
2934 ArrayRef<int64_t> shape = type.getShape();
2935 assert(shape.size() == 1 && "expected shape to be of rank 1.");
2936 unsigned length = shape.back();
2937 assert(0 < length && length <= 16 && "expected length to be at most 16.");
2938 Value value = createI32Constant(rewriter, loc, length);
2939 return setValueAtOffset(rewriter, loc, sgpr4, value, 128);
2940 }
2941
2942 Value setTileDim1OrValidIndices(DescriptorOp op, OpAdaptor adaptor,
2943 ConversionPatternRewriter &rewriter,
2944 Location loc, Value sgpr4,
2945 ArrayRef<Value> consts) const {
2946 if constexpr (DescriptorOp::isGather())
2947 return setValidIndices(op, adaptor, rewriter, loc, sgpr4, consts);
2948 return setTileDim1(op, adaptor, rewriter, loc, sgpr4, consts);
2949 }
2950
2951 Value setTileDim2(DescriptorOp op, OpAdaptor adaptor,
2952 ConversionPatternRewriter &rewriter, Location loc,
2953 Value sgpr4, ArrayRef<Value> consts) const {
2954 // Value is ignored when in gather mode.
2955 if constexpr (DescriptorOp::isGather())
2956 return sgpr4;
2957 return setTileDimX(op, adaptor, rewriter, loc, sgpr4, consts, 2, 144);
2958 }
2959
2960 std::pair<Value, Value>
2961 setTensorDimXStride(DescriptorOp op, OpAdaptor adaptor,
2962 ConversionPatternRewriter &rewriter, Location loc,
2963 Value sgprY, Value sgprZ, ArrayRef<Value> consts,
2964 size_t dimX, int64_t offset) const {
2965 ArrayRef<int64_t> globalStaticStrides = adaptor.getGlobalStaticStrides();
2966 ValueRange globalDynamicStrides = adaptor.getGlobalDynamicStrides();
2967 SmallVector<OpFoldResult> mixedGlobalStrides =
2968 getMixedValues(globalStaticStrides, globalDynamicStrides, rewriter);
2969
2970 if (mixedGlobalStrides.size() <= dimX)
2971 return {sgprY, sgprZ};
2972
2973 OpFoldResult tensorDimXStrideOpFoldResult =
2974 *(mixedGlobalStrides.rbegin() + dimX);
2975 // pre-condition: tensorDimXStride is less than 2^48-1
2976 // TODO: Validation if the value breaks the pre-condition.
2977 // In a following PR implement RuntimeVerifiableOpInterface that instruments
2978 // conditions that need to be checked at runtime.
2979 Value tensorDimXStride;
2980 if (auto attr = dyn_cast<Attribute>(tensorDimXStrideOpFoldResult))
2981 tensorDimXStride =
2982 createI64Constant(rewriter, loc, cast<IntegerAttr>(attr).getInt());
2983 else
2984 tensorDimXStride = cast<Value>(tensorDimXStrideOpFoldResult);
2985
2986 constexpr int64_t first48bits = (1ll << 48) - 1;
2987 Value mask = createI64Constant(rewriter, loc, first48bits);
2988 tensorDimXStride =
2989 LLVM::AndOp::create(rewriter, loc, mask, tensorDimXStride);
2990 IntegerType i32 = rewriter.getI32Type();
2991 Value tensorDimXStrideLow =
2992 LLVM::TruncOp::create(rewriter, loc, i32, tensorDimXStride);
2993 sgprY = setValueAtOffset(rewriter, loc, sgprY, tensorDimXStrideLow, offset);
2994
2995 int64_t shift = (offset % 32) == 0 ? 32 : offset % 32;
2996 Value shiftVal = createI64Constant(rewriter, loc, shift);
2997 Value tensorDimXStrideHigh =
2998 LLVM::LShrOp::create(rewriter, loc, tensorDimXStride, shiftVal);
2999 tensorDimXStrideHigh =
3000 LLVM::TruncOp::create(rewriter, loc, i32, tensorDimXStrideHigh);
3001 sgprZ = setValueAtOffset(rewriter, loc, sgprZ, tensorDimXStrideHigh,
3002 offset + shift);
3003 return {sgprY, sgprZ};
3004 }
3005
3006 std::pair<Value, Value>
3007 setTensorDim0Stride(DescriptorOp op, OpAdaptor adaptor,
3008 ConversionPatternRewriter &rewriter, Location loc,
3009 Value sgpr5, Value sgpr6, ArrayRef<Value> consts) const {
3010 return setTensorDimXStride(op, adaptor, rewriter, loc, sgpr5, sgpr6, consts,
3011 0, 160);
3012 }
3013
3014 std::pair<Value, Value>
3015 setTensorDim1Stride(DescriptorOp op, OpAdaptor adaptor,
3016 ConversionPatternRewriter &rewriter, Location loc,
3017 Value sgpr5, Value sgpr6, ArrayRef<Value> consts) const {
3018 // Value is ignored when in gather mode.
3019 if constexpr (DescriptorOp::isGather())
3020 return {sgpr5, sgpr6};
3021 return setTensorDimXStride(op, adaptor, rewriter, loc, sgpr5, sgpr6, consts,
3022 1, 208);
3023 }
3024
3025 Value getDGroup1(DescriptorOp op, OpAdaptor adaptor,
3026 ConversionPatternRewriter &rewriter, Location loc,
3027 ArrayRef<Value> consts) const {
3028 Value sgprs[8];
3029 for (int64_t i = 0; i < 8; ++i) {
3030 sgprs[i] = consts[0];
3031 }
3032
3033 sgprs[0] = setWorkgroupMask(op, adaptor, rewriter, loc, sgprs[0]);
3034 sgprs[0] = setDataSize(op, adaptor, rewriter, loc, sgprs[0], consts);
3035 sgprs[0] = setAtomicBarrier(op, adaptor, rewriter, loc, sgprs[0], consts);
3036 sgprs[0] = setIterateEnable(op, adaptor, rewriter, loc, sgprs[0], consts);
3037 sgprs[0] = setPadEnable(op, adaptor, rewriter, loc, sgprs[0], consts);
3038 sgprs[0] = setEarlyTimeout(op, adaptor, rewriter, loc, sgprs[0], consts);
3039 sgprs[0] = setPadInterval(op, adaptor, rewriter, loc, sgprs[0], consts);
3040 sgprs[0] = setPadAmount(op, adaptor, rewriter, loc, sgprs[0], consts);
3041
3042 sgprs[1] =
3043 setAtomicBarrierAddress(op, adaptor, rewriter, loc, sgprs[1], consts);
3044 std::tie(sgprs[1], sgprs[2]) =
3045 setTensorDim0(op, adaptor, rewriter, loc, sgprs[1], sgprs[2], consts);
3046 std::tie(sgprs[2], sgprs[3]) =
3047 setTensorDim1(op, adaptor, rewriter, loc, sgprs[2], sgprs[3], consts);
3048
3049 sgprs[3] = setTileDim0(op, adaptor, rewriter, loc, sgprs[3], consts);
3050 sgprs[4] =
3051 setTileDim1OrValidIndices(op, adaptor, rewriter, loc, sgprs[4], consts);
3052 sgprs[4] = setTileDim2(op, adaptor, rewriter, loc, sgprs[4], consts);
3053 std::tie(sgprs[5], sgprs[6]) = setTensorDim0Stride(
3054 op, adaptor, rewriter, loc, sgprs[5], sgprs[6], consts);
3055 std::tie(sgprs[6], sgprs[7]) = setTensorDim1Stride(
3056 op, adaptor, rewriter, loc, sgprs[6], sgprs[7], consts);
3057
3058 IntegerType i32 = rewriter.getI32Type();
3059 Type v8i32 = this->typeConverter->convertType(VectorType::get(8, i32));
3060 assert(v8i32 && "expected type conversion to succeed");
3061 Value dgroup1 = LLVM::PoisonOp::create(rewriter, loc, v8i32);
3062
3063 for (auto [sgpr, constant] : llvm::zip_equal(sgprs, consts)) {
3064 dgroup1 =
3065 LLVM::InsertElementOp::create(rewriter, loc, dgroup1, sgpr, constant);
3066 }
3067
3068 return dgroup1;
3069 }
3070
3071 Value setTensorDimX(DescriptorOp op, OpAdaptor adaptor,
3072 ConversionPatternRewriter &rewriter, Location loc,
3073 Value sgpr0, ArrayRef<Value> consts, int64_t dimX,
3074 int64_t offset) const {
3075 ArrayRef<int64_t> globalStaticSizes = adaptor.getGlobalStaticSizes();
3076 ValueRange globalDynamicSizes = adaptor.getGlobalDynamicSizes();
3077 SmallVector<OpFoldResult> mixedGlobalSizes =
3078 getMixedValues(globalStaticSizes, globalDynamicSizes, rewriter);
3079 if (mixedGlobalSizes.size() <= static_cast<unsigned long>(dimX))
3080 return sgpr0;
3081
3082 OpFoldResult tensorDimXOpFoldResult = *(mixedGlobalSizes.rbegin() + dimX);
3083 Value tensorDimX;
3084 if (auto attr = dyn_cast<Attribute>(tensorDimXOpFoldResult)) {
3085 tensorDimX =
3086 createI32Constant(rewriter, loc, cast<IntegerAttr>(attr).getInt());
3087 } else {
3088 IntegerType i32 = rewriter.getI32Type();
3089 tensorDimX = cast<Value>(tensorDimXOpFoldResult);
3090 tensorDimX = LLVM::TruncOp::create(rewriter, loc, i32, tensorDimX);
3091 }
3092
3093 return setValueAtOffset(rewriter, loc, sgpr0, tensorDimX, offset);
3094 }
3095
3096 Value setTensorDim2(DescriptorOp op, OpAdaptor adaptor,
3097 ConversionPatternRewriter &rewriter, Location loc,
3098 Value sgpr0, ArrayRef<Value> consts) const {
3099 return setTensorDimX(op, adaptor, rewriter, loc, sgpr0, consts, 2, 0);
3100 }
3101
3102 Value truncateAndSetValueAtOffset(ConversionPatternRewriter &rewriter,
3103 Location loc, Value accumulator,
3104 Value value, int64_t shift) const {
3105
3106 IntegerType i32 = rewriter.getI32Type();
3107 value = LLVM::TruncOp::create(rewriter, loc, i32, value);
3108 return setValueAtOffset(rewriter, loc, accumulator, value, shift);
3109 }
3110
3111 Value setLDSAddrIncrement(DescriptorOp op, OpAdaptor adaptor,
3112 ConversionPatternRewriter &rewriter, Location loc,
3113 Value sgpr1, ArrayRef<Value> consts,
3114 int64_t offset) const {
3115 Value ldsAddrIncrement = adaptor.getLdsIncrement();
3116 return setValueAtOffset(rewriter, loc, sgpr1, ldsAddrIncrement, offset);
3117 }
3118
3119 std::pair<Value, Value>
3120 setGlobalAddrIncrement(DescriptorOp op, OpAdaptor adaptor,
3121 ConversionPatternRewriter &rewriter, Location loc,
3122 Value sgpr2, Value sgpr3, ArrayRef<Value> consts,
3123 int64_t offset) const {
3124 Value globalAddrIncrement = adaptor.getGlobalIncrement();
3125 sgpr2 = truncateAndSetValueAtOffset(rewriter, loc, sgpr2,
3126 globalAddrIncrement, offset);
3127 Value shift = createI64Constant(rewriter, loc, 32);
3128 globalAddrIncrement =
3129 LLVM::LShrOp::create(rewriter, loc, globalAddrIncrement, shift);
3130 constexpr int64_t first16BitsHigh = (1ll << 16) - 1;
3131 sgpr3 = truncateAndSetValueAtOffset(rewriter, loc, sgpr3,
3132 globalAddrIncrement, offset + 32);
3133 Value mask = createI32Constant(rewriter, loc, first16BitsHigh);
3134 sgpr3 = LLVM::AndOp::create(rewriter, loc, sgpr3, mask);
3135 return {sgpr2, sgpr3};
3136 }
3137
3138 Value setTensorDim3OrLDSAddrIncrement(DescriptorOp op, OpAdaptor adaptor,
3139 ConversionPatternRewriter &rewriter,
3140 Location loc, Value sgpr1,
3141 ArrayRef<Value> consts) const {
3142 Value ldsIncrement = op.getLdsIncrement();
3143 constexpr int64_t dim = 3;
3144 constexpr int64_t offset = 32;
3145 if (!ldsIncrement)
3146 return setTensorDimX(op, adaptor, rewriter, loc, sgpr1, consts, dim,
3147 offset);
3148 return setLDSAddrIncrement(op, adaptor, rewriter, loc, sgpr1, consts,
3149 offset);
3150 }
3151
3152 std::pair<Value, Value> setTensorDim2StrideOrGlobalAddrIncrement(
3153 DescriptorOp op, OpAdaptor adaptor, ConversionPatternRewriter &rewriter,
3154 Location loc, Value sgpr2, Value sgpr3, ArrayRef<Value> consts) const {
3155 Value globalIncrement = op.getGlobalIncrement();
3156 constexpr int32_t dim = 2;
3157 constexpr int32_t offset = 64;
3158 if (!globalIncrement)
3159 return setTensorDimXStride(op, adaptor, rewriter, loc, sgpr2, sgpr3,
3160 consts, dim, offset);
3161 return setGlobalAddrIncrement(op, adaptor, rewriter, loc, sgpr2, sgpr3,
3162 consts, offset);
3163 }
3164
3165 Value setIterateCount(DescriptorOp op, OpAdaptor adaptor,
3166 ConversionPatternRewriter &rewriter, Location loc,
3167 Value sgpr3, ArrayRef<Value> consts,
3168 int32_t offset) const {
3169 Value iterationCount = adaptor.getIterationCount();
3170 IntegerType i32 = rewriter.getI32Type();
3171 // pre-condition: iterationCount is in the inclusive interval [1, 256].
3172 // TODO: validation if the value breaks the pre-condition.
3173 // If the pre-condition fails, there is a possibility of
3174 // affecting the higher bits. In a following PR implement
3175 // RuntimeVerifiableOpInterface that instruments conditions that need to be
3176 // checked at runtime.
3177 iterationCount = LLVM::TruncOp::create(rewriter, loc, i32, iterationCount);
3178 iterationCount =
3179 LLVM::SubOp::create(rewriter, loc, iterationCount, consts[1]);
3180 return setValueAtOffset(rewriter, loc, sgpr3, iterationCount, offset);
3181 }
3182
3183 Value setTileDim3OrIterateCount(DescriptorOp op, OpAdaptor adaptor,
3184 ConversionPatternRewriter &rewriter,
3185 Location loc, Value sgpr3,
3186 ArrayRef<Value> consts) const {
3187 Value iterateCount = op.getIterationCount();
3188 constexpr int32_t dim = 2;
3189 constexpr int32_t offset = 112;
3190 if (!iterateCount)
3191 return setTileDimX(op, adaptor, rewriter, loc, sgpr3, consts, dim,
3192 offset);
3193
3194 return setIterateCount(op, adaptor, rewriter, loc, sgpr3, consts, offset);
3195 }
3196
3197 Value getDGroup2(DescriptorOp op, OpAdaptor adaptor,
3198 ConversionPatternRewriter &rewriter, Location loc,
3199 ArrayRef<Value> consts) const {
3200 if constexpr (DescriptorOp::isGather())
3201 return getDGroup2Gather(op, adaptor, rewriter, loc, consts);
3202 return getDGroup2NonGather(op, adaptor, rewriter, loc, consts);
3203 }
3204
3205 Value getDGroup2NonGather(DescriptorOp op, OpAdaptor adaptor,
3206 ConversionPatternRewriter &rewriter, Location loc,
3207 ArrayRef<Value> consts) const {
3208 IntegerType i32 = rewriter.getI32Type();
3209 Type v4i32 = this->typeConverter->convertType(VectorType::get(4, i32));
3210 assert(v4i32 && "expected type conversion to succeed.");
3211
3212 bool onlyNeedsTwoDescriptors = !op.getLdsIncrement() && op.getRank() <= 2;
3213 if (onlyNeedsTwoDescriptors)
3214 return LLVM::ZeroOp::create(rewriter, loc, v4i32);
3215
3216 constexpr int64_t sgprlen = 4;
3217 Value sgprs[sgprlen];
3218 for (int i = 0; i < sgprlen; ++i)
3219 sgprs[i] = consts[0];
3220
3221 sgprs[0] = setTensorDim2(op, adaptor, rewriter, loc, sgprs[0], consts);
3222 sgprs[1] = setTensorDim3OrLDSAddrIncrement(op, adaptor, rewriter, loc,
3223 sgprs[1], consts);
3224 std::tie(sgprs[2], sgprs[3]) = setTensorDim2StrideOrGlobalAddrIncrement(
3225 op, adaptor, rewriter, loc, sgprs[2], sgprs[3], consts);
3226 sgprs[3] =
3227 setTileDim3OrIterateCount(op, adaptor, rewriter, loc, sgprs[3], consts);
3228
3229 Value dgroup2 = LLVM::PoisonOp::create(rewriter, loc, v4i32);
3230 for (auto [sgpr, constant] : llvm::zip(sgprs, consts))
3231 dgroup2 =
3232 LLVM::InsertElementOp::create(rewriter, loc, dgroup2, sgpr, constant);
3233
3234 return dgroup2;
3235 }
3236
3237 Value getGatherIndices(DescriptorOp op, OpAdaptor adaptor,
3238 ConversionPatternRewriter &rewriter, Location loc,
3239 ArrayRef<Value> consts, bool firstHalf) const {
3240 IntegerType i32 = rewriter.getI32Type();
3241 Type v4i32 = this->typeConverter->convertType(VectorType::get(4, i32));
3242 assert(v4i32 && "expected type conversion to succeed.");
3243
3244 Value indices = adaptor.getIndices();
3245 auto vectorType = cast<VectorType>(indices.getType());
3246 unsigned length = vectorType.getShape().back();
3247 Type elementType = vectorType.getElementType();
3248 unsigned maxLength = elementType == i32 ? 4 : 8;
3249 int32_t offset = firstHalf ? 0 : maxLength;
3250 unsigned discountedLength =
3251 std::max(static_cast<int32_t>(length - offset), 0);
3252
3253 unsigned targetSize = std::min(maxLength, discountedLength);
3254
3255 SmallVector<Value> indicesVector;
3256 for (unsigned i = offset; i < targetSize + offset; ++i) {
3257 Value idx;
3258 if (i < consts.size())
3259 idx = consts[i];
3260 else
3261 idx = createI32Constant(rewriter, loc, i);
3262 Value elem = LLVM::ExtractElementOp::create(rewriter, loc, indices, idx);
3263 indicesVector.push_back(elem);
3264 }
3265
3266 SmallVector<Value> indicesI32Vector;
3267 if (elementType == i32) {
3268 indicesI32Vector = indicesVector;
3269 } else {
3270 for (unsigned i = 0; i < targetSize; ++i) {
3271 Value index = indicesVector[i];
3272 indicesI32Vector.push_back(
3273 LLVM::ZExtOp::create(rewriter, loc, i32, index));
3274 }
3275 if ((targetSize % 2) != 0)
3276 // Add padding when not divisible by two.
3277 indicesI32Vector.push_back(consts[0]);
3278 }
3279
3280 SmallVector<Value> indicesToInsert;
3281 if (elementType == i32) {
3282 indicesToInsert = indicesI32Vector;
3283 } else {
3284 unsigned size = indicesI32Vector.size() / 2;
3285 for (unsigned i = 0; i < size; ++i) {
3286 Value first = indicesI32Vector[2 * i];
3287 Value second = indicesI32Vector[2 * i + 1];
3288 Value joined = setValueAtOffset(rewriter, loc, first, second, 16);
3289 indicesToInsert.push_back(joined);
3290 }
3291 }
3292
3293 Value dgroup = LLVM::PoisonOp::create(rewriter, loc, v4i32);
3294 for (auto [sgpr, constant] : llvm::zip_first(indicesToInsert, consts))
3295 dgroup =
3296 LLVM::InsertElementOp::create(rewriter, loc, dgroup, sgpr, constant);
3297
3298 return dgroup;
3299 }
3300
3301 Value getDGroup2Gather(DescriptorOp op, OpAdaptor adaptor,
3302 ConversionPatternRewriter &rewriter, Location loc,
3303 ArrayRef<Value> consts) const {
3304 return getGatherIndices(op, adaptor, rewriter, loc, consts, true);
3305 }
3306
3307 std::pair<Value, Value>
3308 setTensorDim3Stride(DescriptorOp op, OpAdaptor adaptor,
3309 ConversionPatternRewriter &rewriter, Location loc,
3310 Value sgpr0, Value sgpr1, ArrayRef<Value> consts) const {
3311 constexpr int32_t dim = 3;
3312 constexpr int32_t offset = 0;
3313 return setTensorDimXStride(op, adaptor, rewriter, loc, sgpr0, sgpr1, consts,
3314 dim, offset);
3315 }
3316
3317 std::pair<Value, Value> setTensorDim4(DescriptorOp op, OpAdaptor adaptor,
3318 ConversionPatternRewriter &rewriter,
3319 Location loc, Value sgpr1, Value sgpr2,
3320 ArrayRef<Value> consts) const {
3321 constexpr int32_t dim = 4;
3322 constexpr int32_t offset = 48;
3323 return setTensorDimX(op, adaptor, rewriter, loc, sgpr1, sgpr2, consts, dim,
3324 offset);
3325 }
3326
3327 Value setTileDim4(DescriptorOp op, OpAdaptor adaptor,
3328 ConversionPatternRewriter &rewriter, Location loc,
3329 Value sgpr2, ArrayRef<Value> consts) const {
3330 constexpr int32_t dim = 4;
3331 constexpr int32_t offset = 80;
3332 return setTileDimX(op, adaptor, rewriter, loc, sgpr2, consts, dim, offset);
3333 }
3334
3335 Value getDGroup3(DescriptorOp op, OpAdaptor adaptor,
3336 ConversionPatternRewriter &rewriter, Location loc,
3337 ArrayRef<Value> consts) const {
3338 if constexpr (DescriptorOp::isGather())
3339 return getDGroup3Gather(op, adaptor, rewriter, loc, consts);
3340 return getDGroup3NonGather(op, adaptor, rewriter, loc, consts);
3341 }
3342
3343 Value getDGroup3NonGather(DescriptorOp op, OpAdaptor adaptor,
3344 ConversionPatternRewriter &rewriter, Location loc,
3345 ArrayRef<Value> consts) const {
3346 IntegerType i32 = rewriter.getI32Type();
3347 Type v4i32 = this->typeConverter->convertType(VectorType::get(4, i32));
3348 assert(v4i32 && "expected type conversion to succeed.");
3349 bool onlyNeedsTwoDescriptors = !op.getLdsIncrement() && op.getRank() <= 2;
3350 if (onlyNeedsTwoDescriptors)
3351 return LLVM::ZeroOp::create(rewriter, loc, v4i32);
3352
3353 constexpr int32_t sgprlen = 4;
3354 Value sgprs[sgprlen];
3355 for (int i = 0; i < sgprlen; ++i)
3356 sgprs[i] = consts[0];
3357
3358 std::tie(sgprs[0], sgprs[1]) = setTensorDim3Stride(
3359 op, adaptor, rewriter, loc, sgprs[0], sgprs[1], consts);
3360 std::tie(sgprs[1], sgprs[2]) =
3361 setTensorDim4(op, adaptor, rewriter, loc, sgprs[1], sgprs[2], consts);
3362 sgprs[2] = setTileDim4(op, adaptor, rewriter, loc, sgprs[2], consts);
3363
3364 Value dgroup3 = LLVM::PoisonOp::create(rewriter, loc, v4i32);
3365 for (auto [sgpr, constant] : llvm::zip(sgprs, consts))
3366 dgroup3 =
3367 LLVM::InsertElementOp::create(rewriter, loc, dgroup3, sgpr, constant);
3368
3369 return dgroup3;
3370 }
3371
3372 Value getDGroup3Gather(DescriptorOp op, OpAdaptor adaptor,
3373 ConversionPatternRewriter &rewriter, Location loc,
3374 ArrayRef<Value> consts) const {
3375 return getGatherIndices(op, adaptor, rewriter, loc, consts, false);
3376 }
3377
3378 LogicalResult
3379 matchAndRewrite(DescriptorOp op, OpAdaptor adaptor,
3380 ConversionPatternRewriter &rewriter) const override {
3381 if (chipset < kGfx1250)
3382 return op->emitOpError(
3383 "make_dma_descriptor is only supported on gfx1250");
3384
3385 Location loc = op.getLoc();
3386
3387 SmallVector<Value> consts;
3388 for (int64_t i = 0; i < 8; ++i)
3389 consts.push_back(createI32Constant(rewriter, loc, i));
3390
3391 Value dgroup0 = this->getDGroup0(adaptor);
3392 Value dgroup1 = this->getDGroup1(op, adaptor, rewriter, loc, consts);
3393 Value dgroup2 = this->getDGroup2(op, adaptor, rewriter, loc, consts);
3394 Value dgroup3 = this->getDGroup3(op, adaptor, rewriter, loc, consts);
3395 SmallVector<Value> results = {dgroup0, dgroup1, dgroup2, dgroup3};
3396 rewriter.replaceOpWithMultiple(op, {results});
3397 return success();
3398 }
3399};
3400
3401template <typename SourceOp, typename TargetOp>
3402struct AMDGPUTensorLoadStoreOpLowering
3403 : public ConvertOpToLLVMPattern<SourceOp> {
3404 using ConvertOpToLLVMPattern<SourceOp>::ConvertOpToLLVMPattern;
3405 using Adaptor = typename ConvertOpToLLVMPattern<SourceOp>::OneToNOpAdaptor;
3406 AMDGPUTensorLoadStoreOpLowering(const LLVMTypeConverter &converter,
3407 Chipset chipset)
3408 : ConvertOpToLLVMPattern<SourceOp>(converter), chipset(chipset) {}
3409 Chipset chipset;
3410
3411 LogicalResult
3412 matchAndRewrite(SourceOp op, Adaptor adaptor,
3413 ConversionPatternRewriter &rewriter) const override {
3414 if (chipset < kGfx1250)
3415 return op->emitOpError("is only supported on gfx1250");
3416
3417 ValueRange desc = adaptor.getDesc();
3418 rewriter.replaceOpWithNewOp<TargetOp>(op, desc[0], desc[1], desc[2],
3419 desc[3], /*cachePolicy=*/0,
3420 /*alias_scopes=*/nullptr,
3421 /*noalias_scopes=*/nullptr,
3422 /*tbaa=*/nullptr);
3423 return success();
3424 }
3425};
3426
3427struct ConvertAMDGPUToROCDLPass
3428 : public impl::ConvertAMDGPUToROCDLPassBase<ConvertAMDGPUToROCDLPass> {
3429 using Base::Base;
3430
3431 void runOnOperation() override {
3432 MLIRContext *ctx = &getContext();
3433 FailureOr<Chipset> maybeChipset = Chipset::parse(chipset);
3434 if (failed(maybeChipset)) {
3435 emitError(UnknownLoc::get(ctx), "Invalid chipset name: " + chipset);
3436 return signalPassFailure();
3437 }
3438
3439 RewritePatternSet patterns(ctx);
3440 LLVMTypeConverter converter(ctx);
3441
3442 populateAMDGPUToROCDLConversionPatterns(converter, patterns, *maybeChipset);
3443 amdgpu::populateCommonGPUTypeAndAttributeConversions(converter);
3444 LLVMConversionTarget target(getContext());
3445 target.addIllegalDialect<::mlir::amdgpu::AMDGPUDialect>();
3446 target.addLegalDialect<::mlir::LLVM::LLVMDialect>();
3447 target.addLegalDialect<::mlir::ROCDL::ROCDLDialect>();
3448 if (failed(applyPartialConversion(getOperation(), target,
3449 std::move(patterns))))
3450 signalPassFailure();
3451 }
3452};
3453} // namespace
3454
3455void mlir::amdgpu::populateCommonGPUTypeAndAttributeConversions(
3456 TypeConverter &typeConverter) {
3457 populateGpuMemorySpaceAttributeConversions(
3458 typeConverter, [](gpu::AddressSpace space) {
3459 switch (space) {
3460 case gpu::AddressSpace::Global:
3461 return ROCDL::ROCDLDialect::kGlobalMemoryAddressSpace;
3462 case gpu::AddressSpace::Workgroup:
3463 return ROCDL::ROCDLDialect::kSharedMemoryAddressSpace;
3464 case gpu::AddressSpace::Private:
3465 return ROCDL::ROCDLDialect::kPrivateMemoryAddressSpace;
3466 }
3467 llvm_unreachable("unknown address space enum value");
3468 });
3469}
3470
3471void mlir::populateAMDGPUTypeAndAttributeConversions(
3472 TypeConverter &typeConverter) {
3473 typeConverter.addTypeAttributeConversion(
3474 [](BaseMemRefType type, amdgpu::AddressSpaceAttr as)
3475 -> TypeConverter::AttributeConversionResult {
3476 MLIRContext *ctx = as.getContext();
3477 Type i64 = IntegerType::get(ctx, 64);
3478 switch (as.getValue()) {
3479 case amdgpu::AddressSpace::FatRawBuffer:
3480 return IntegerAttr::get(i64, 7);
3481 case amdgpu::AddressSpace::BufferRsrc:
3482 return IntegerAttr::get(i64, 8);
3483 case amdgpu::AddressSpace::FatStructuredBuffer:
3484 return IntegerAttr::get(i64, 9);
3485 }
3486 return TypeConverter::AttributeConversionResult::abort();
3487 });
3488 typeConverter.addConversion([&](TDMBaseType type) -> Type {
3489 Type i32 = IntegerType::get(type.getContext(), 32);
3490 return typeConverter.convertType(VectorType::get(4, i32));
3491 });
3492 typeConverter.addConversion([&](TDMGatherBaseType type) -> Type {
3493 Type i32 = IntegerType::get(type.getContext(), 32);
3494 return typeConverter.convertType(VectorType::get(4, i32));
3495 });
3496 typeConverter.addConversion(
3497 [&](TDMDescriptorType type,
3498 SmallVectorImpl<Type> &result) -> std::optional<LogicalResult> {
3499 Type i32 = IntegerType::get(type.getContext(), 32);
3500 Type v4i32 = typeConverter.convertType(VectorType::get(4, i32));
3501 Type v8i32 = typeConverter.convertType(VectorType::get(8, i32));
3502 llvm::append_values(result, v4i32, v8i32, v4i32, v4i32);
3503 return success();
3504 });
3505
3506 auto addUnrealizedCast = [](OpBuilder &builder, TypeRange types,
3507 ValueRange inputs,
3508 Location loc) -> SmallVector<Value> {
3509 // Only create unrealized_conversion_cast for TDMDescriptorType.
3510 // All other types which are not expected, should be
3511 // materialized by other target materialization functions.
3512 if (inputs.size() != 1)
3513 return {};
3514
3515 if (!isa<TDMDescriptorType>(inputs[0].getType()))
3516 return {};
3517
3518 auto cast = UnrealizedConversionCastOp::create(builder, loc, types, inputs);
3519 return cast.getResults();
3520 };
3521
3522 typeConverter.addTargetMaterialization(addUnrealizedCast);
3523}
3524
3525void mlir::populateAMDGPUToROCDLConversionPatterns(LLVMTypeConverter &converter,
3526 RewritePatternSet &patterns,
3527 Chipset chipset) {
3528 populateAMDGPUTypeAndAttributeConversions(converter);
3529 patterns
3530 .add<FatRawBufferCastLowering,
3531 RawBufferOpLowering<RawBufferLoadOp, ROCDL::RawPtrBufferLoadOp>,
3532 RawBufferOpLowering<RawBufferStoreOp, ROCDL::RawPtrBufferStoreOp>,
3533 RawBufferOpLowering<RawBufferAtomicFaddOp,
3534 ROCDL::RawPtrBufferAtomicFaddOp>,
3535 RawBufferOpLowering<RawBufferAtomicFmaxOp,
3536 ROCDL::RawPtrBufferAtomicFmaxOp>,
3537 RawBufferOpLowering<RawBufferAtomicSmaxOp,
3538 ROCDL::RawPtrBufferAtomicSmaxOp>,
3539 RawBufferOpLowering<RawBufferAtomicUminOp,
3540 ROCDL::RawPtrBufferAtomicUminOp>,
3541 RawBufferOpLowering<RawBufferAtomicCmpswapOp,
3542 ROCDL::RawPtrBufferAtomicCmpSwap>,
3543 AMDGPUDPPLowering, MemoryCounterWaitOpLowering, LDSBarrierOpLowering,
3544 SchedBarrierOpLowering, MFMAOpLowering, ScaledMFMAOpLowering,
3545 SparseMFMAOpLowering, WMMAOpLowering, ScaledWMMAOpLowering,
3546 ExtPackedFp8OpLowering, ScaledExtPackedMatrixOpLowering,
3547 ScaledExtPackedOpLowering, PackedScaledTruncOpLowering,
3548 PackedTrunc2xFp8OpLowering, PackedStochRoundFp8OpLowering,
3549 GatherToLDSOpLowering, TransposeLoadOpLowering,
3550 AMDGPUPermlaneLowering, AMDGPUMakeDmaBaseLowering<MakeDmaBaseOp>,
3551 AMDGPUMakeDmaBaseLowering<MakeGatherDmaBaseOp>,
3552 AMDGPULowerDescriptor<MakeDmaDescriptorOp>,
3553 AMDGPULowerDescriptor<MakeGatherDmaDescriptorOp>,
3554 AMDGPUTensorLoadStoreOpLowering<TensorLoadToLDSOp,
3555 ROCDL::TensorLoadToLDSOp>,
3556 AMDGPUTensorLoadStoreOpLowering<TensorStoreFromLDSOp,
3557 ROCDL::TensorStoreFromLDSOp>>(
3558 converter, chipset);
3559 patterns.add<AMDGPUSwizzleBitModeLowering>(converter);
3560}
typeIsExpectedFp8ForChipset
static bool typeIsExpectedFp8ForChipset(Chipset chipset, Type type)
Return true if type is the E4M3FN variant of an 8-bit float that is supported by the _fp8 instruction...
Definition AMDGPUToROCDL.cpp:832
kGfx942
constexpr Chipset kGfx942
Definition AMDGPUToROCDL.cpp:46
wmmaOpToIntrinsicRDNA
static std::optional< StringRef > wmmaOpToIntrinsicRDNA(Type elemSourceType, Type elemBSourceType, Type elemDestType, uint32_t k, bool isRDNA3)
Returns the rocdl intrinsic corresponding to a WMMA operation wmma for RDNA3/4 architectures.
Definition AMDGPUToROCDL.cpp:1049
mfmaOpToScaledIntrinsic
static std::optional< std::tuple< StringRef, uint32_t, uint32_t > > mfmaOpToScaledIntrinsic(Type aType, Type bType, Type destType, uint32_t m, uint32_t n, uint32_t k, uint32_t b, Chipset chipset)
If there is a scaled MFMA instruction for the input element types aType and bType,...
Definition AMDGPUToROCDL.cpp:1003
mfmaOpToIntrinsic
static std::optional< StringRef > mfmaOpToIntrinsic(MFMAOp mfma, Chipset chipset)
Return the rocdl intrinsic corresponding to a MFMA operation mfma if one exists.
Definition AMDGPUToROCDL.cpp:840
kGfx908
constexpr Chipset kGfx908
Definition AMDGPUToROCDL.cpp:44
wmmaPushInputOperand
static void wmmaPushInputOperand(ConversionPatternRewriter &rewriter, Location loc, const TypeConverter *typeConverter, bool isUnsigned, Value llvmInput, Value mlirInput, SmallVectorImpl< Value > &operands, SmallVectorImpl< NamedAttribute > &attrs, StringRef attrName)
Push an input operand.
Definition AMDGPUToROCDL.cpp:747
kGfx1250
constexpr Chipset kGfx1250
Definition AMDGPUToROCDL.cpp:48
castScaleOperand
static Value castScaleOperand(ConversionPatternRewriter &rewriter, Location loc, Value input)
Converts the scaled MFMA/WMMA operands, scalesA and scalesB, from MLIR AMDGPU dialect convention to R...
Definition AMDGPUToROCDL.cpp:695
kGfx90a
constexpr Chipset kGfx90a
Definition AMDGPUToROCDL.cpp:45
getScaledWmmaIntrinsicName
static std::optional< StringRef > getScaledWmmaIntrinsicName(int64_t m, int64_t n, int64_t k, bool isScale16)
Determines the ROCDL intrinsic name for scaled WMMA based on dimensions and scale block size (16 or 3...
Definition AMDGPUToROCDL.cpp:726
wmmaPushOutputOperand
static void wmmaPushOutputOperand(ConversionPatternRewriter &rewriter, Location loc, const TypeConverter *typeConverter, Value output, int32_t subwordOffset, bool clamp, SmallVectorImpl< Value > &operands, SmallVectorImpl< NamedAttribute > &attrs)
Push the output operand.
Definition AMDGPUToROCDL.cpp:805
typeIsExpectedBf8ForChipset
static bool typeIsExpectedBf8ForChipset(Chipset chipset, Type type)
Return true if type is the E5M2 variant of an 8-bit float that is supported by the _bf8 instructions ...
Definition AMDGPUToROCDL.cpp:825
wmmaOpToIntrinsic
static std::optional< StringRef > wmmaOpToIntrinsic(WMMAOp wmma, Chipset chipset)
Returns the rocdl intrinsic corresponding to a WMMA operation wmma if one exists.
Definition AMDGPUToROCDL.cpp:1297
smfmacOpToIntrinsic
static std::optional< StringRef > smfmacOpToIntrinsic(SparseMFMAOp op, Chipset chipset)
Returns the rocdl intrinsic corresponding to a SparseMFMA (smfmac) operation if one exists.
Definition AMDGPUToROCDL.cpp:1198
makeBufferRsrc
static Value makeBufferRsrc(ConversionPatternRewriter &rewriter, Location loc, Value basePointer, Value numRecords, bool boundsCheck, amdgpu::Chipset chipset, Value cacheSwizzleStride=nullptr, unsigned addressSpace=8)
Definition AMDGPUToROCDL.cpp:138
createI64Constant
static Value createI64Constant(ConversionPatternRewriter &rewriter, Location loc, int64_t value)
Definition AMDGPUToROCDL.cpp:81
convertSparseMFMAVectorOperand
static Value convertSparseMFMAVectorOperand(ConversionPatternRewriter &rewriter, Location loc, Value input, bool allowBf16=true)
Converts sparse MFMA (smfmac) operands to the expected ROCDL types.
Definition AMDGPUToROCDL.cpp:665
wmmaOpToIntrinsicGfx1250
static std::optional< StringRef > wmmaOpToIntrinsicGfx1250(Type elemSourceType, Type elemBSourceType, Type elemDestType, uint32_t k)
Return the rocdl intrinsic corresponding to a WMMA operation wmma for the gfx1250 architecture.
Definition AMDGPUToROCDL.cpp:1105
packSmallFloatVectorOperand
static Value packSmallFloatVectorOperand(ConversionPatternRewriter &rewriter, Location loc, Value input, bool allowBf16=true)
Pack small float vector operands (fp4/fp6/fp8/bf16) into the format expected by scaled matrix multipl...
Definition AMDGPUToROCDL.cpp:638
getWmmaScaleFormat
static std::optional< uint32_t > getWmmaScaleFormat(Type elemType)
Maps f8 scale element types to WMMA scale format codes.
Definition AMDGPUToROCDL.cpp:716
getLinearIndexI32
static Value getLinearIndexI32(ConversionPatternRewriter &rewriter, Location loc, MemRefDescriptor &memRefDescriptor, ValueRange indices, ArrayRef< int64_t > strides)
Returns the linear index used to access an element in the memref.
Definition AMDGPUToROCDL.cpp:87
convertUnsignedToI32
static Value convertUnsignedToI32(ConversionPatternRewriter &rewriter, Location loc, Value val)
Convert an unsigned number val to i32.
Definition AMDGPUToROCDL.cpp:51
createI32Constant
static Value createI32Constant(ConversionPatternRewriter &rewriter, Location loc, int32_t value)
Definition AMDGPUToROCDL.cpp:63
smallFloatTypeToFormatCode
static std::optional< uint32_t > smallFloatTypeToFormatCode(Type mlirElemType)
Definition AMDGPUToROCDL.cpp:985
convertUnsignedToI64
static Value convertUnsignedToI64(ConversionPatternRewriter &rewriter, Location loc, Value val)
Convert an unsigned number val to i64.
Definition AMDGPUToROCDL.cpp:69
kGfx950
constexpr Chipset kGfx950
Definition AMDGPUToROCDL.cpp:47
getNumRecords
static Value getNumRecords(ConversionPatternRewriter &rewriter, Location loc, MemRefType memrefType, MemRefDescriptor &memrefDescriptor, ArrayRef< int64_t > strides, int64_t elementByteWidth)
Compute the contents of the num_records field for a given memref descriptor - that is,...
Definition AMDGPUToROCDL.cpp:110
success
return success()
b
b
Return true if permutation is a valid permutation of the outer_dims_perm (case OuterOrInnerPerm::Oute...
Definition LinalgTransformOps.cpp:2097
ArrayAttr
ArrayAttr()
getContext
b getContext())
load
auto load
Definition LoopUtils.cpp:1923
replacement
*if copies could not be generated due to yet unimplemented cases *copyInPlacementStart and copyOutPlacementStart in copyPlacementBlock *specify the insertion points where the incoming copies and outgoing should be the output argument nBegin is set to its * replacement(set to `begin` if no invalidation happens). Since outgoing *copies could have been inserted at `end`
kSizePosInMemRefDescriptor
static constexpr unsigned kSizePosInMemRefDescriptor
Definition MemRefDescriptor.h:19
kStridePosInMemRefDescriptor
static constexpr unsigned kStridePosInMemRefDescriptor
Definition MemRefDescriptor.h:20
kOffsetPosInMemRefDescriptor
static constexpr unsigned kOffsetPosInMemRefDescriptor
Definition MemRefDescriptor.h:18
kAllocatedPtrPosInMemRefDescriptor
static constexpr unsigned kAllocatedPtrPosInMemRefDescriptor
Definition MemRefDescriptor.h:16
kAlignedPtrPosInMemRefDescriptor
static constexpr unsigned kAlignedPtrPosInMemRefDescriptor
Definition MemRefDescriptor.h:17
clamp
static Value clamp(ImplicitLocOpBuilder &builder, Value value, Value lowerBound, Value upperBound)
Definition PolynomialApproximation.cpp:220
int64_t
mlir::Attribute
Attributes are known-constant values of operations.
Definition Attributes.h:25
mlir::BaseMemRefType
This class provides a shared interface for ranked and unranked memref types.
Definition BuiltinTypes.h:104
mlir::ConvertOpToLLVMPattern
Utility class for operation conversions targeting the LLVM dialect that match exactly one source oper...
Definition Pattern.h:216
mlir::ConvertOpToLLVMPattern::ConvertOpToLLVMPattern
ConvertOpToLLVMPattern(const LLVMTypeConverter &typeConverter, PatternBenefit benefit=1)
Definition Pattern.h:222
mlir::ConvertOpToLLVMPattern::OneToNOpAdaptor
typename SourceOp::template GenericAdaptor< ArrayRef< ValueRange > > OneToNOpAdaptor
Definition Pattern.h:219
mlir::ConvertOpToLLVMPattern::OpAdaptor
typename SourceOp::Adaptor OpAdaptor
Definition Pattern.h:218
mlir::ConvertToLLVMPattern::getStridedElementPtr
Value getStridedElementPtr(ConversionPatternRewriter &rewriter, Location loc, MemRefType type, Value memRefDesc, ValueRange indices, LLVM::GEPNoWrapFlags noWrapFlags=LLVM::GEPNoWrapFlags::none) const
Convenience wrapper for the corresponding helper utility.
Definition Pattern.cpp:64
mlir::DataLayout::getTypeSizeInBits
llvm::TypeSize getTypeSizeInBits(Type t) const
Returns the size in bits of the given type in the current scope.
Definition DataLayoutInterfaces.cpp:569
mlir::LLVMTypeConverter
Conversion from types to the LLVM IR dialect.
Definition TypeConverter.h:35
mlir::Location
This class defines the main interface for locations in MLIR and acts as a non-nullable wrapper around...
Definition Location.h:76
mlir::MLIRContext
MLIRContext is the top-level object for a collection of MLIR operations.
Definition MLIRContext.h:63
mlir::MemRefDescriptor
Helper class to produce LLVM dialect operations extracting or inserting elements of a MemRef descript...
Definition MemRefBuilder.h:33
mlir::MemRefDescriptor::stride
Value stride(OpBuilder &builder, Location loc, unsigned pos)
Builds IR extracting the pos-th size from the descriptor.
Definition MemRefBuilder.cpp:169
mlir::MemRefDescriptor::size
Value size(OpBuilder &builder, Location loc, unsigned pos)
Builds IR extracting the pos-th size from the descriptor.
Definition MemRefBuilder.cpp:127
mlir::NamedAttribute
NamedAttribute represents a combination of a name and an Attribute value.
Definition Attributes.h:164
mlir::OpBuilder
This class helps build Operations.
Definition Builders.h:207
mlir::Operation::getResult
OpResult getResult(unsigned idx)
Get the 'idx'th result of this operation.
Definition Operation.h:407
mlir::Operation::getResults
result_range getResults()
Definition Operation.h:415
mlir::Operation::getNumResults
unsigned getNumResults()
Return the number of results held by this operation.
Definition Operation.h:404
mlir::TypeRange
This class provides an abstraction over the various different ranges of value types.
Definition TypeRange.h:37
mlir::Type
Instances of the Type class are uniqued, have an immutable identifier and an optional mutable compone...
Definition Types.h:74
mlir::Type::isF64
bool isF64() const
Definition Types.cpp:41
mlir::Type::getContext
MLIRContext * getContext() const
Return the MLIRContext in which this type was uniqued.
Definition Types.cpp:35
mlir::Type::isSignedInteger
bool isSignedInteger() const
Return true if this is a signed integer type (with the specified width).
Definition Types.cpp:76
mlir::Type::isF32
bool isF32() const
Definition Types.cpp:40
mlir::Type::isUnsignedInteger
bool isUnsignedInteger() const
Return true if this is an unsigned integer type (with the specified width).
Definition Types.cpp:88
mlir::Type::isInteger
bool isInteger() const
Return true if this is an integer type (with the specified width).
Definition Types.cpp:56
mlir::Type::isF16
bool isF16() const
Definition Types.cpp:38
mlir::Type::getIntOrFloatBitWidth
unsigned getIntOrFloatBitWidth() const
Return the bit width of an integer or a float type, assert failure on other types.
Definition Types.cpp:122
mlir::Type::isBF16
bool isBF16() const
Definition Types.cpp:37
mlir::ValueRange
This class provides an abstraction over the different types of ranges over Values.
Definition ValueRange.h:387
mlir::Value
This class represents an instance of an SSA value in the MLIR system, representing a computable value...
Definition Value.h:96
mlir::Value::getType
Type getType() const
Return the type of this value.
Definition Value.h:105
mlir::impl::ConvertAMDGPUToROCDLPassBase::chipset
::mlir::Pass::Option< std::string > chipset
Definition AMDGPUToROCDL.cpp:514
mlir::LLVM::getStridedElementPtr
Value getStridedElementPtr(OpBuilder &builder, Location loc, const LLVMTypeConverter &converter, MemRefType type, Value memRefDesc, ValueRange indices, LLVM::GEPNoWrapFlags noWrapFlags=LLVM::GEPNoWrapFlags::none)
Performs the index computation to get to the element at indices of the memory pointed to by memRefDes...
Definition Pattern.cpp:471
mlir::LLVM::composeValue
Value composeValue(OpBuilder &builder, Location loc, ValueRange src, Type dstType)
Composes a set of src values into a single value of type dstType through series of bitcasts and vecto...
Definition Pattern.cpp:432
mlir::LLVM::decomposeValue
SmallVector< Value > decomposeValue(OpBuilder &builder, Location loc, Value src, Type dstType)
Decomposes a src value into a set of values of type dstType through series of bitcasts and vector ops...
Definition Pattern.cpp:393
mlir::amdgpu::hasOcpFp8
bool hasOcpFp8(const Chipset &chipset)
Definition Chipset.h:52
mlir::amdgpu::populateCommonGPUTypeAndAttributeConversions
void populateCommonGPUTypeAndAttributeConversions(TypeConverter &typeConverter)
Remap common GPU memory spaces (Workgroup, Private, etc) to LLVM address spaces.
Definition AMDGPUToROCDL.cpp:3455
mlir::remark::failed
detail::InFlightRemark failed(Location loc, RemarkOpts opts)
Report an optimization remark that failed.
Definition Remarks.h:573
mlir
Include the generated interface declarations.
Definition AliasAnalysis.h:19
mlir::matchPattern
bool matchPattern(Value value, const Pattern &pattern)
Entry point for matching a pattern over a Value.
Definition Matchers.h:490
mlir::getMixedValues
SmallVector< OpFoldResult > getMixedValues(ArrayRef< int64_t > staticValues, ValueRange dynamicValues, MLIRContext *context)
Return a vector of OpFoldResults with the same size a staticValues, but all elements for which Shaped...
Definition StaticValueUtils.cpp:198
mlir::getType
Type getType(OpFoldResult ofr)
Returns the int type of the integer in ofr.
Definition Utils.cpp:304
mlir::emitError
InFlightDiagnostic emitError(Location loc)
Utility method to emit an error message using this location.
Definition Diagnostics.cpp:332
mlir::m_Zero
detail::constant_int_predicate_matcher m_Zero()
Matches a constant scalar / vector splat / tensor splat integer zero.
Definition Matchers.h:442
mlir::getElementTypeOrSelf
Type getElementTypeOrSelf(Type type)
Return the element type or return the type itself.
Definition TypeUtilities.cpp:23
mlir::patterns
const FrozenRewritePatternSet & patterns
Definition GreedyPatternRewriteDriver.h:283
mlir::populateGpuMemorySpaceAttributeConversions
void populateGpuMemorySpaceAttributeConversions(TypeConverter &typeConverter, const MemorySpaceMapping &mapping)
Populates memory space attribute conversion rules for lowering gpu.address_space to integer values.
Definition GPUOpsLowering.cpp:818
mlir::populateAMDGPUToROCDLConversionPatterns
void populateAMDGPUToROCDLConversionPatterns(LLVMTypeConverter &converter, RewritePatternSet &patterns, amdgpu::Chipset chipset)
Note: This function will also add conversions for the AMDGPU-specific address spaces and types,...
Definition AMDGPUToROCDL.cpp:3525
mlir::TypeSwitch
llvm::TypeSwitch< T, ResultT > TypeSwitch
Definition LLVM.h:144
mlir::populateAMDGPUTypeAndAttributeConversions
void populateAMDGPUTypeAndAttributeConversions(TypeConverter &typeConverter)
Remap AMDGPU memory spaces to LLVM address spaces by mapping amdgpu::AddressSpace::fat_raw_buffer to ...
Definition AMDGPUToROCDL.cpp:3471
mlir::amdgpu::Chipset
Represents the amdgpu gfx chipset version, e.g., gfx90a, gfx942, gfx1103.
Definition Chipset.h:22
mlir::amdgpu::Chipset::majorVersion
unsigned majorVersion
Definition Chipset.h:23
mlir::amdgpu::Chipset::minorVersion
unsigned minorVersion
Definition Chipset.h:24
mlir::amdgpu::Chipset::parse
static FailureOr< Chipset > parse(StringRef name)
Parses the chipset version string and returns the chipset on success, and failure otherwise.
Definition Chipset.cpp:14
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