#ifdef TORCH_ENABLE_LLVM #include #include #include #include #include #include #include #include #include #include #include #include #include namespace torch { namespace jit { using namespace torch::jit::tensorexpr; using LLVMExprEval = ExprEval; // Typed tests, can't use gtest params here due to the way we instantiate tests. #define TEST_LLVM_SCALAR_TYPES(_) \ _(uint8_t, Byte, 24) \ _(int8_t, Char, -20) \ _(int16_t, Short, 3332) \ _(int, Int, 123456) \ _(int64_t, Long, 2631563121321) \ _(float, Float, 0.122) \ _(double, Double, 0.21312) \ _(at::Half, Half, 0.128f) #define IMM_TEST(Type, Name, Val) \ TEST(LLVM, Name##ImmTest) { \ KernelScope kernel_scope; \ auto a = Name##Imm::make(Val); \ LLVMExprEval cg(a); \ if (std::is_floating_point()) { \ ASSERT_NEAR(cg.value(), Val, 0.1); \ } else { \ ASSERT_EQ(cg.value(), Val); \ } \ } TEST_LLVM_SCALAR_TYPES(IMM_TEST) #undef IMM_TEST #define ADD_TEST(Type, Name, Val) \ TEST(LLVM, Name##AddTest) { \ KernelScope kernel_scope; \ auto a = Name##Imm::make(Val); \ auto b = Name##Imm::make(Val * 2); \ auto c = Add::make(a, b); \ LLVMExprEval cg(c); \ if (std::is_floating_point()) { \ ASSERT_NEAR(cg.value(), Val * 3, 0.1); \ } else { \ ASSERT_EQ(cg.value(), Val * 3); \ } \ } TEST_LLVM_SCALAR_TYPES(ADD_TEST) #undef ADD_TEST #define SUB_TEST(Type, Name, Val) \ TEST(LLVM, Name##SubTest) { \ KernelScope kernel_scope; \ auto a = Name##Imm::make(Val * 2); \ auto b = Name##Imm::make(Val); \ auto c = Sub::make(a, b); \ LLVMExprEval cg(c); \ if (std::is_floating_point()) { \ ASSERT_NEAR(cg.value(), Val, 0.1); \ } else { \ ASSERT_EQ(cg.value(), Val); \ } \ } TEST_LLVM_SCALAR_TYPES(SUB_TEST) #undef SUB_TEST #define MUL_TEST(Type, Name, Val) \ TEST(LLVM, Name##MulTest) { \ KernelScope kernel_scope; \ auto a = Name##Imm::make(Val); \ auto b = Name##Imm::make((Type)4); \ auto c = Mul::make(a, b); \ LLVMExprEval cg(c); \ if (std::is_floating_point()) { \ ASSERT_NEAR(cg.value(), Val * 4, 0.1); \ } else { \ ASSERT_EQ(cg.value(), Val * 4); \ } \ } TEST_LLVM_SCALAR_TYPES(MUL_TEST) #undef MUL_TEST #define DIV_TEST(Type, Name, Val) \ TEST(LLVM, Name##DivTest) { \ KernelScope kernel_scope; \ auto a = Name##Imm::make((Type)6); \ auto b = Name##Imm::make((Type)3); \ auto c = Div::make(a, b); \ LLVMExprEval cg(c); \ if (std::is_floating_point()) { \ ASSERT_NEAR(cg.value(), 2, 0.1); \ } else { \ ASSERT_EQ(cg.value(), 2); \ } \ } TEST_LLVM_SCALAR_TYPES(DIV_TEST) #undef DIV_TEST TEST(LLVM, IntToFloatCastTest) { KernelScope kernel_scope; auto a = IntImm::make(2); auto b = Cast::make(kFloat, a); LLVMExprEval cg(b, {}); ASSERT_EQ(cg.value(), 2.0); } TEST(LLVM, FloatToIntCastTest) { KernelScope kernel_scope; auto a = FloatImm::make(2.0); auto b = Cast::make(kInt, a); LLVMExprEval cg(b); ASSERT_EQ(cg.value(), 2); } TEST(LLVM, IntToLongCastTest) { KernelScope kernel_scope; auto a = IntImm::make(12345); auto b = Cast::make(kLong, a); LLVMExprEval cg(b); ASSERT_EQ(cg.value(), 12345); } TEST(LLVM, ByteToCharCastTest) { KernelScope kernel_scope; auto a = ByteImm::make(250); auto b = Cast::make(kChar, a); LLVMExprEval cg(b); ASSERT_EQ(cg.value(), (int8_t)250); } TEST(LLVM, HalfToLongCastTest) { KernelScope kernel_scope; auto a = HalfImm::make(2.0); auto b = Cast::make(kLong, a); LLVMExprEval cg(b); ASSERT_EQ(cg.value(), 2); } TEST(LLVM, ByteToDoubleCastTest) { KernelScope kernel_scope; auto a = ByteImm::make(2); auto b = Cast::make(kDouble, a); LLVMExprEval cg(b); ASSERT_EQ(cg.value(), 2); } TEST(LLVM, BitCast) { constexpr int16_t ref16 = 1337; constexpr int32_t ref32 = 1337; constexpr int64_t ref64 = 1337; at::Half reff16 = 1337.0f; constexpr float reff32 = 1337.0f; constexpr double reff64 = 1337.0f; // this is broken /*{ KernelScope kernel_scope; at::Half k_; at::Half* k = &k_; *reinterpret_cast(k) = ref16; auto a = HalfImm::make(k); auto b = BitCast::make(kShort, a); LLVMExprEval cg(b); ASSERT_EQ(cg.value(), ref16); }*/ { KernelScope kernel_scope; float k = raw_bitcast(ref32); auto a = FloatImm::make(k); auto b = BitCast::make(kInt, a); LLVMExprEval cg(b); ASSERT_EQ(cg.value(), ref32); } { KernelScope kernel_scope; double k = raw_bitcast(ref64); auto a = DoubleImm::make(k); auto b = BitCast::make(kLong, a); LLVMExprEval cg(b); ASSERT_EQ(cg.value(), ref64); } { KernelScope kernel_scope; int64_t k = raw_bitcast(reff64); auto a = LongImm::make(k); auto b = BitCast::make(kDouble, a); LLVMExprEval cg(b); ASSERT_EQ(cg.value(), reff64); } { KernelScope kernel_scope; int32_t k = raw_bitcast(reff32); auto a = IntImm::make(k); auto b = BitCast::make(kFloat, a); LLVMExprEval cg(b); ASSERT_EQ(cg.value(), reff32); } } TEST(LLVM, fastLogFloat) { KernelScope kernel_scope; const int kTotalSize = 128 * 128; Placeholder a_buf(BufHandle("A", {ExprHandle(kTotalSize)}, kFloat)); Placeholder b_buf(BufHandle("B", {ExprHandle(kTotalSize)}, kFloat)); VarHandle index = VarHandle("index", kInt); ExprHandle load_a = a_buf.load(index); Stmt* store_b = b_buf.store({index}, fast_log(load_a)); Stmt* stmt = For::make(index, 0, kTotalSize, store_b); PaddedBuffer a_v(kTotalSize); PaddedBuffer b_v(kTotalSize); for (int i = 0; i < kTotalSize; ++i) { a_v(i) = at::randn({1}).item().to(); } LLVMCodeGen ir_eval(stmt, {a_buf, b_buf}); ir_eval.call({a_v, b_v}); for (int i = 0; i < kTotalSize; ++i) { auto test = b_v(i); auto ref = std::log(a_v(i)); if (std::isnan(ref)) { ASSERT_EQ(std::isnan(test), true); } else { ASSERT_FLOAT_EQ(test, ref); } } } TEST(LLVM, LetTest01) { KernelScope kernel_scope; Placeholder a(BufHandle("A", {1}, kFloat)); std::vector v = {1, 0}; std::vector args({v.data()}); VarHandle x("x", kFloat); auto block = Block::make({ Let::make(x, 3.f), a.store({0}, ExprHandle(2.f) + (x * ExprHandle(3.f) + ExprHandle(4.f))), }); LLVMCodeGen cg(block, {a}); ASSERT_EQ(cg.value(args), 0); ASSERT_EQ(v[0], 2.f + 3.f * 3.f + 4.f); } TEST(LLVM, LetTest02) { KernelScope kernel_scope; Placeholder a(BufHandle("A", {1}, kFloat)); std::vector v = {1, 0}; std::vector args({v.data()}); VarHandle x("x", kFloat); VarHandle y("y", kFloat); auto block = Block::make( {Let::make(x, 3.f), Let::make(y, 6.f), a.store( {IntImm::make(0)}, ExprHandle(2.f) + (x * ExprHandle(3.f) + y * ExprHandle(4.f)))}); LLVMCodeGen cg(block, {a}); ASSERT_EQ(cg.value(args), 0); ASSERT_EQ(v[0], 2.f + 3.f * 3.f + 6.f * 4.f); } TEST(LLVM, LetTestMultitype) { KernelScope kernel_scope; Placeholder a(BufHandle("A", {1}, kDouble)); std::vector v = {1, 0}; std::vector args({v.data()}); VarHandle x("x", kByte); VarHandle y("y", kHalf); auto block = Block::make( {Let::make(x, 3), Let::make(y, 6.f), a.store( {0}, Cast::make( kDouble, ExprHandle(2.f) + (x * ExprHandle(3.f) + y * ExprHandle(4.f))))}); LLVMCodeGen cg(block, {a}); ASSERT_EQ(cg.value(args), 0); ASSERT_EQ(v[0], 2.f + 3 * 3.f + 6.f * 4.f); } TEST(LLVM, BufferTest) { KernelScope kernel_scope; Placeholder a(BufHandle("A", {32}, kFloat)); std::vector v(5); std::vector args({v.data()}); auto rv = IntImm::make(0); LLVMExprEval cg(rv, {a}); ASSERT_EQ(cg.value(args), 0); } TEST(LLVM, BlockTest) { KernelScope kernel_scope; Placeholder a(BufHandle("A", {32}, kInt)); std::vector v = {1, 2}; std::vector args({v.data()}); auto block = Block::make({ a.store({0}, 3), a.store({1}, 4), a.store({0}, 4), }); LLVMCodeGen cg(block, {a}); ASSERT_EQ(cg.value(args), 0); ASSERT_EQ(v[0], 4); ASSERT_EQ(v[1], 4); } TEST(LLVM, LoadStoreTest) { KernelScope kernel_scope; Placeholder a(BufHandle("A", {1}, kInt)); Placeholder b(BufHandle("B", {1}, kInt)); std::vector a_buffer = {42}; std::vector b_buffer = {-11}; auto store = b.store({0}, a.load(0)); LLVMCodeGen cg(store, {a, b}); std::vector args({a_buffer.data(), b_buffer.data()}); ASSERT_EQ(cg.value(args), 0); ASSERT_EQ(a_buffer[0], 42); ASSERT_EQ(b_buffer[0], 42); } TEST(LLVM, IfThenElseTest) { KernelScope kernel_scope; Placeholder a(BufHandle("A", {1}, kInt)); Placeholder b(BufHandle("B", {1}, kInt)); Placeholder c(BufHandle("C", {1}, kInt)); std::vector a_buffer = {42}; std::vector b_buffer = {-11}; std::vector c_buffer = {1}; auto store = b.store({0}, IfThenElse::make(c.load(0), a.load(0), 0)); LLVMCodeGen cg(store, {a, b, c}); std::vector args({a_buffer.data(), b_buffer.data(), c_buffer.data()}); ASSERT_EQ(cg.value(args), 0); ASSERT_EQ(a_buffer[0], 42); ASSERT_EQ(b_buffer[0], 42); } // if (x < 10) x = x + 1 TEST(LLVM, CondNoFalseBlockTest) { KernelScope kernel_scope; Placeholder x(BufHandle("X", {1}, kInt)); auto cmp = CompareSelect::make(x.load(0), 10, CompareSelectOperation::kLT); auto cond = Cond::make(cmp, x.store({0}, x.load(0) + 1), nullptr); for (int32_t x_value : {0, 10, 20}) { std::vector x_buffer = {x_value}; std::vector args({x_buffer.data()}); LLVMCodeGen cg(cond, {x}); ASSERT_EQ(cg.value(args), 0); if (x_value < 10) { ASSERT_EQ(x_buffer[0], x_value + 1); } else { ASSERT_EQ(x_buffer[0], x_value); } } } // if (x < 10) { // x = x + 1; // } else { // x = x - 1; // } TEST(LLVM, CondTest) { KernelScope kernel_scope; Placeholder x(BufHandle("X", {1}, kInt)); auto cmp = CompareSelect::make(x.load(0), 10, CompareSelectOperation::kLT); auto cond = Cond::make(cmp, x.store({0}, x.load(0) + 1), x.store({0}, x.load(0) - 1)); auto block = Block::make({ cond, x.store({0}, x.load(0) * 2), }); for (int32_t x_value : {0, 10, 20}) { std::vector x_buffer = {x_value}; std::vector args({x_buffer.data()}); LLVMCodeGen cg(block, {x}); ASSERT_EQ(cg.value(args), 0); if (x_value < 10) { ASSERT_EQ(x_buffer[0], (x_value + 1) * 2); } else { ASSERT_EQ(x_buffer[0], (x_value - 1) * 2); } } } // if (x < 10) { // if (x > 5) { // x = x + 1; // } else { // x = x - 1; // } // } else { // if (x <= 15) { // x = x + 2; // } else { // x = x - 2; // } // } TEST(LLVM, CondNestedTest) { KernelScope kernel_scope; Placeholder x(BufHandle("X", {1}, kInt)); auto true_cmp = CompareSelect::make(x.load(0), 5, CompareSelectOperation::kGT); auto true_cond = Cond::make( true_cmp, x.store({0}, x.load(0) + 1), x.store({0}, x.load(0) - 1)); auto false_cmp = CompareSelect::make(x.load(0), 15, CompareSelectOperation::kLE); auto false_cond = Cond::make( false_cmp, x.store({0}, x.load(0) + 2), x.store({0}, x.load(0) - 2)); auto cmp = CompareSelect::make(x.load(0), 10, CompareSelectOperation::kLT); auto cond = Cond::make(cmp, true_cond, false_cond); for (int32_t x_value : {0, 8, 15, 20}) { std::vector x_buffer = {x_value}; std::vector args({x_buffer.data()}); LLVMCodeGen cg(cond, {x}); ASSERT_EQ(cg.value(args), 0); if (x_value < 10) { if (x_value > 5) { ASSERT_EQ(x_buffer[0], x_value + 1); } else { ASSERT_EQ(x_buffer[0], x_value - 1); } } else { if (x_value <= 15) { ASSERT_EQ(x_buffer[0], x_value + 2); } else { ASSERT_EQ(x_buffer[0], x_value - 2); } } } } TEST(LLVM, VecLoadStoreTest) { KernelScope kernel_scope; Placeholder a(BufHandle("A", {1}, kInt)); Placeholder b(BufHandle("B", {1}, kInt)); std::vector a_buffer = {1, 1, 1, 1}; std::vector b_buffer = {2, 2, 2, 2}; auto store = b.storeWithMask( {Ramp::make(0, 1, 4)}, a.loadWithMask( {Ramp::make(0, 1, 4)}, Broadcast::make(IntImm::make(1), 4)), Broadcast::make(IntImm::make(1), 4)); LLVMCodeGen cg(store, {a, b}); std::vector args({a_buffer.data(), b_buffer.data()}); ASSERT_EQ(cg.value(args), 0); ASSERT_EQ(a_buffer[0], 1); ASSERT_EQ(a_buffer[1], 1); ASSERT_EQ(a_buffer[2], 1); ASSERT_EQ(a_buffer[3], 1); ASSERT_EQ(b_buffer[0], 1); ASSERT_EQ(b_buffer[1], 1); ASSERT_EQ(b_buffer[2], 1); ASSERT_EQ(b_buffer[3], 1); } #define FLOAT_INTRINSICS_TEST(Name, Lanes) \ TEST(LLVM, VecFloat_##Name##Lane##Lanes##Test) { \ KernelScope kernel_scope; \ Placeholder a(BufHandle("A", {1}, kFloat)); \ Placeholder b(BufHandle("B", {1}, kFloat)); \ float val = 0.5f; \ std::vector a_buffer(Lanes, val); \ std::vector b_buffer(Lanes, val); \ auto store = b.storeWithMask( \ {Ramp::make(0, 1, Lanes)}, \ Name(a.loadWithMask( \ {Ramp::make(0, 1, Lanes)}, \ Broadcast::make(IntImm::make(1), Lanes))), \ Broadcast::make(IntImm::make(1), Lanes)); \ LLVMCodeGen cg(store, {a, b}); \ std::vector args({a_buffer.data(), b_buffer.data()}); \ ASSERT_EQ(cg.value(args), 0); \ for (int i = 0; i < Lanes; i++) { \ ASSERT_FLOAT_EQ(a_buffer[i], val); \ } \ } // namespace jit FLOAT_INTRINSICS_TEST(erf, 4) FLOAT_INTRINSICS_TEST(erfc, 4) FLOAT_INTRINSICS_TEST(acos, 4) FLOAT_INTRINSICS_TEST(asin, 4) FLOAT_INTRINSICS_TEST(atan, 4) FLOAT_INTRINSICS_TEST(cosh, 4) FLOAT_INTRINSICS_TEST(sinh, 4) FLOAT_INTRINSICS_TEST(tanh, 4) FLOAT_INTRINSICS_TEST(expm1, 4) FLOAT_INTRINSICS_TEST(lgamma, 4) FLOAT_INTRINSICS_TEST(erf, 8) FLOAT_INTRINSICS_TEST(erfc, 8) FLOAT_INTRINSICS_TEST(acos, 8) FLOAT_INTRINSICS_TEST(asin, 8) FLOAT_INTRINSICS_TEST(atan, 8) FLOAT_INTRINSICS_TEST(cosh, 8) FLOAT_INTRINSICS_TEST(sinh, 8) FLOAT_INTRINSICS_TEST(tanh, 8) FLOAT_INTRINSICS_TEST(expm1, 8) FLOAT_INTRINSICS_TEST(lgamma, 8) #undef FLOAT_INTRINSICS_TEST #define DOUBLE_INTRINSICS_TEST(Name, Lanes) \ TEST(LLVM, VecDouble_##Name##Lane##Lanes##Test) { \ KernelScope kernel_scope; \ Placeholder a(BufHandle("A", {1}, kDouble)); \ Placeholder b(BufHandle("B", {1}, kDouble)); \ float val = 0.5f; \ std::vector a_buffer(Lanes, val); \ std::vector b_buffer(Lanes, val); \ auto store = b.storeWithMask( \ {Ramp::make(0, 1, Lanes)}, \ Name(a.loadWithMask( \ {Ramp::make(0, 1, Lanes)}, \ Broadcast::make(IntImm::make(1), Lanes))), \ Broadcast::make(IntImm::make(1), Lanes)); \ LLVMCodeGen cg(store, {a, b}); \ std::vector args({a_buffer.data(), b_buffer.data()}); \ ASSERT_EQ(cg.value(args), 0); \ for (int i = 0; i < Lanes; i++) { \ ASSERT_FLOAT_EQ(a_buffer[i], val); \ } \ } // namespace jit DOUBLE_INTRINSICS_TEST(erf, 2) DOUBLE_INTRINSICS_TEST(erfc, 2) DOUBLE_INTRINSICS_TEST(acos, 2) DOUBLE_INTRINSICS_TEST(asin, 2) DOUBLE_INTRINSICS_TEST(atan, 2) DOUBLE_INTRINSICS_TEST(cosh, 2) DOUBLE_INTRINSICS_TEST(sinh, 2) DOUBLE_INTRINSICS_TEST(tanh, 2) DOUBLE_INTRINSICS_TEST(expm1, 2) DOUBLE_INTRINSICS_TEST(lgamma, 2) DOUBLE_INTRINSICS_TEST(erf, 4) DOUBLE_INTRINSICS_TEST(erfc, 4) DOUBLE_INTRINSICS_TEST(acos, 4) DOUBLE_INTRINSICS_TEST(asin, 4) DOUBLE_INTRINSICS_TEST(atan, 4) DOUBLE_INTRINSICS_TEST(cosh, 4) DOUBLE_INTRINSICS_TEST(sinh, 4) DOUBLE_INTRINSICS_TEST(tanh, 4) DOUBLE_INTRINSICS_TEST(expm1, 4) DOUBLE_INTRINSICS_TEST(lgamma, 4) #undef DOUBLE_INTRINSICS_TEST TEST(LLVM, VectorizerLoadStoreTest) { KernelScope kernel_scope; Placeholder a(BufHandle("A", {1}, kInt)); Tensor* c = Compute("c", {{4, "i"}}, [&](const VarHandle& i) { return a.load(i); }); Placeholder c_buf(BufHandle(c->buf())); LoopNest l({c}); Stmt* s = l.root_stmt(); l.vectorize(dynamic_cast(dynamic_cast(s)->front())); ASSERT_TRUE(dynamic_cast(dynamic_cast(s)->front()) == nullptr); LLVMCodeGen cg(s, {a, c_buf}); std::vector a_vec(4, 21); std::vector c_vec(4, 0); std::vector args({a_vec.data(), c_vec.data()}); ASSERT_EQ(cg.value(args), 0); assertAllEqual(c_vec, 21); } TEST(LLVM, VectorizeBitCast) { KernelScope kernel_scope; Placeholder a(BufHandle("A", {128}, kInt)); Tensor* c = Compute("c", {{128, "i"}}, [&](const VarHandle& i) { return bitcast(a.load(i)); }); Placeholder c_buf(BufHandle(c->buf())); LoopNest l({c}); Stmt* s = l.root_stmt(); l.vectorize(dynamic_cast(dynamic_cast(s)->front())); ASSERT_TRUE(dynamic_cast(dynamic_cast(s)->front()) == nullptr); LLVMCodeGen cg(s, {a, c_buf}); std::vector a_vec(128); std::vector c_vec(128); for (auto i = 0; i < 128; ++i) { a_vec[i] = raw_bitcast(1337.f); } std::vector args({a_vec.data(), c_vec.data()}); ASSERT_EQ(cg.value(args), 0); assertAllEqual(c_vec, 1337.f); } TEST(LLVM, MemcpyTest) { KernelScope kernel_scope; constexpr int N = 32; Placeholder a(BufHandle("A", {N}, kInt)); Placeholder b(BufHandle("B", {N}, kInt)); std::vector a_buffer(N, 42); std::vector b_buffer(N, 0); VarHandle i("i", kInt); auto expr = For::make(i, 0, N, b.store({i}, a.load(i))); LLVMCodeGen cg(expr, {a, b}); std::vector args({a_buffer.data(), b_buffer.data()}); ASSERT_EQ(cg.value(args), 0); ASSERT_EQ(a_buffer.size(), N); ASSERT_EQ(b_buffer.size(), N); assertAllEqual(a_buffer, 42); assertAllEqual(b_buffer, 42); } TEST(LLVM, BzeroTest) { KernelScope kernel_scope; constexpr int N = 32; Placeholder b(BufHandle("B", {N}, kInt)); std::vector b_buffer(N, 11); VarHandle i("i", kInt); auto expr = For::make(i, 0, N, b.store({i}, 0)); LLVMCodeGen cg(expr, {b}); std::vector args({b_buffer.data()}); ASSERT_EQ(cg.value(args), 0); ASSERT_EQ(b_buffer.size(), N); assertAllEqual(b_buffer, 0); } TEST(LLVM, ElemwiseAdd) { KernelScope kernel_scope; constexpr int N = 1024; Placeholder a(BufHandle("A", {N}, kInt)); Placeholder b(BufHandle("B", {N}, kInt)); Placeholder c(BufHandle("C", {N}, kInt)); std::vector a_buffer(N, 41); std::vector b_buffer(N, 1); std::vector c_buffer(N, 1); VarHandle i("i", kInt); auto expr = For::make(i, 0, N, c.store({i}, Add::make(a.load(i), b.load(i)))); LLVMCodeGen cg(expr, {a, b, c}); std::vector args({a_buffer.data(), b_buffer.data(), c_buffer.data()}); ASSERT_EQ(cg.value(args), 0); ASSERT_EQ(a_buffer.size(), N); ASSERT_EQ(b_buffer.size(), N); ASSERT_EQ(c_buffer.size(), N); assertAllEqual(a_buffer, 41); assertAllEqual(b_buffer, 1); assertAllEqual(c_buffer, 42); } TEST(LLVM, ElemwiseAddFloat) { KernelScope kernel_scope; constexpr int N = 1024; Placeholder a(BufHandle("A", {N}, kFloat)); Placeholder b(BufHandle("B", {N}, kFloat)); Placeholder c(BufHandle("C", {N}, kFloat)); std::vector a_buffer(N, 41); std::vector b_buffer(N, 1); std::vector c_buffer(N, 1); VarHandle i("i", kInt); auto expr = For::make(i, 0, N, c.store({i}, a.load(i) + b.load(i))); LLVMCodeGen cg(expr, {a, b, c}); std::vector args({a_buffer.data(), b_buffer.data(), c_buffer.data()}); ASSERT_EQ(cg.value(args), 0); ASSERT_EQ(a_buffer.size(), N); ASSERT_EQ(b_buffer.size(), N); ASSERT_EQ(c_buffer.size(), N); assertAllEqual(a_buffer, 41.0f); assertAllEqual(b_buffer, 1.0f); assertAllEqual(c_buffer, 42.0f); } TEST(LLVM, ElemwiseLog10Float) { KernelScope kernel_scope; constexpr int N = 1024; Placeholder a(BufHandle("A", {N}, kFloat)); Placeholder b(BufHandle("B", {N}, kFloat)); std::vector a_buffer(N, 10.0f); std::vector b_buffer(N, 2.0f); auto mask = Broadcast::make(IntImm::make(1), 4); VarHandle i("i", kInt); auto expr = For::make( i, 0, N / 4, b.storeWithMask( {Ramp::make(i * 4, 1, 4)}, log10(a.loadWithMask({Ramp::make(i * 4, 1, 4)}, mask)), mask)); LLVMCodeGen cg(expr, {a, b}); std::vector args({a_buffer.data(), b_buffer.data()}); ASSERT_EQ(cg.value(args), 0); ASSERT_EQ(a_buffer.size(), N); ASSERT_EQ(b_buffer.size(), N); assertAllEqual(a_buffer, 10.0f); assertAllEqual(b_buffer, 1.0f); } TEST(LLVM, ElemwiseLog1pFloat) { KernelScope kernel_scope; constexpr int N = 1024; Placeholder a(BufHandle("A", {N}, kFloat)); Placeholder b(BufHandle("B", {N}, kFloat)); std::vector a_buffer(N, expf(3.0f) - 1); std::vector b_buffer(N, 42.0f); auto mask = Broadcast::make(IntImm::make(1), 4); VarHandle i("i", kInt); auto expr = For::make( i, 0, N / 4, b.storeWithMask( {Ramp::make(i * 4, 1, 4)}, log1p(a.loadWithMask({Ramp::make(i * 4, 1, 4)}, mask)), mask)); LLVMCodeGen cg(expr, {a, b}); std::vector args({a_buffer.data(), b_buffer.data()}); ASSERT_EQ(cg.value(args), 0); ASSERT_EQ(a_buffer.size(), N); ASSERT_EQ(b_buffer.size(), N); assertAllEqual(a_buffer, expf(3.0f) - 1); ExpectAllNear(b_buffer, 3.0f, 1e-5f); } TEST(LLVM, ElemwiseMaxInt) { KernelScope kernel_scope; constexpr int N = 1024; Placeholder a(BufHandle("A", {N}, kInt)); Placeholder b(BufHandle("B", {N}, kInt)); Placeholder c(BufHandle("C", {N}, kInt)); std::vector a_buffer(N, 41); std::vector b_buffer(N, 1); std::vector c_buffer(N, 1); VarHandle i("i", kInt); auto expr = For::make(i, 0, N, c.store({i}, Max::make(a.load(i), b.load(i), false))); LLVMCodeGen cg(expr, {a, b, c}); std::vector args({a_buffer.data(), b_buffer.data(), c_buffer.data()}); ASSERT_EQ(cg.value(args), 0); ASSERT_EQ(a_buffer.size(), N); ASSERT_EQ(b_buffer.size(), N); ASSERT_EQ(c_buffer.size(), N); assertAllEqual(a_buffer, 41); assertAllEqual(b_buffer, 1); assertAllEqual(c_buffer, 41); } TEST(LLVM, ElemwiseMinInt) { KernelScope kernel_scope; constexpr int N = 1024; Placeholder a(BufHandle("A", {N}, kInt)); Placeholder b(BufHandle("B", {N}, kInt)); Placeholder c(BufHandle("C", {N}, kInt)); std::vector a_buffer(N, 41); std::vector b_buffer(N, 1); std::vector c_buffer(N, 1); VarHandle i("i", kInt); auto expr = For::make(i, 0, N, c.store({i}, Min::make(a.load(i), b.load(i), false))); LLVMCodeGen cg(expr, {a, b, c}); std::vector args({a_buffer.data(), b_buffer.data(), c_buffer.data()}); ASSERT_EQ(cg.value(args), 0); ASSERT_EQ(a_buffer.size(), N); ASSERT_EQ(b_buffer.size(), N); ASSERT_EQ(c_buffer.size(), N); assertAllEqual(a_buffer, 41); assertAllEqual(b_buffer, 1); assertAllEqual(c_buffer, 1); } TEST(LLVM, ElemwiseMaxFloat) { KernelScope kernel_scope; constexpr int N = 1024; Placeholder a(BufHandle("A", {N}, kFloat)); Placeholder b(BufHandle("B", {N}, kFloat)); Placeholder c(BufHandle("C", {N}, kFloat)); std::vector a_buffer(N, 41); std::vector b_buffer(N, 1); std::vector c_buffer(N, 1); VarHandle i("i", kInt); auto expr = For::make(i, 0, N, c.store({i}, Max::make(a.load(i), b.load(i), false))); LLVMCodeGen cg(expr, {a, b, c}); std::vector args({a_buffer.data(), b_buffer.data(), c_buffer.data()}); ASSERT_EQ(cg.value(args), 0); ASSERT_EQ(a_buffer.size(), N); ASSERT_EQ(b_buffer.size(), N); ASSERT_EQ(c_buffer.size(), N); assertAllEqual(a_buffer, 41.0f); assertAllEqual(b_buffer, 1.0f); assertAllEqual(c_buffer, 41.0f); } TEST(LLVM, ElemwiseMaxNaNFloat) { KernelScope kernel_scope; constexpr int N = 1024; Placeholder a(BufHandle("A", {N}, kFloat)); Placeholder b(BufHandle("B", {N}, kFloat)); Placeholder c(BufHandle("C", {N}, kFloat)); std::vector a_buffer(N, NAN); std::vector b_buffer(N, 1); std::vector c_buffer(N, 1); VarHandle i("i", kInt); auto expr = For::make(i, 0, N, c.store({i}, Max::make(a.load(i), b.load(i), false))); LLVMCodeGen cg(expr, {a, b, c}); std::vector args({a_buffer.data(), b_buffer.data(), c_buffer.data()}); ASSERT_EQ(cg.value(args), 0); ASSERT_EQ(a_buffer.size(), N); ASSERT_EQ(b_buffer.size(), N); ASSERT_EQ(c_buffer.size(), N); assertAllEqual(b_buffer, 1.0f); for (auto const& elt : c_buffer) { ASSERT_TRUE(std::isnan(elt)); } } TEST(LLVM, ElemwiseMinFloat) { KernelScope kernel_scope; constexpr int N = 1024; Placeholder a(BufHandle("A", {N}, kFloat)); Placeholder b(BufHandle("B", {N}, kFloat)); Placeholder c(BufHandle("C", {N}, kFloat)); std::vector a_buffer(N, 41); std::vector b_buffer(N, 1); std::vector c_buffer(N, 1); VarHandle i("i", kInt); auto expr = For::make(i, 0, N, c.store({i}, Min::make(a.load(i), b.load(i), false))); LLVMCodeGen cg(expr, {a, b, c}); std::vector args({a_buffer.data(), b_buffer.data(), c_buffer.data()}); ASSERT_EQ(cg.value(args), 0); ASSERT_EQ(a_buffer.size(), N); ASSERT_EQ(b_buffer.size(), N); ASSERT_EQ(c_buffer.size(), N); assertAllEqual(a_buffer, 41.0f); assertAllEqual(b_buffer, 1.0f); assertAllEqual(c_buffer, 1.0f); } TEST(LLVM, ElemwiseMinNaNFloat) { KernelScope kernel_scope; constexpr int N = 1024; Placeholder a(BufHandle("A", {N}, kFloat)); Placeholder b(BufHandle("B", {N}, kFloat)); Placeholder c(BufHandle("C", {N}, kFloat)); std::vector a_buffer(N, NAN); std::vector b_buffer(N, 1); std::vector c_buffer(N, 1); VarHandle i("i", kInt); auto expr = For::make(i, 0, N, c.store({i}, Min::make(a.load(i), b.load(i), false))); LLVMCodeGen cg(expr, {a, b, c}); std::vector args({a_buffer.data(), b_buffer.data(), c_buffer.data()}); ASSERT_EQ(cg.value(args), 0); ASSERT_EQ(a_buffer.size(), N); ASSERT_EQ(b_buffer.size(), N); ASSERT_EQ(c_buffer.size(), N); assertAllEqual(b_buffer, 1.0f); for (auto const& elt : c_buffer) { ASSERT_TRUE(std::isnan(elt)); } } TEST(LLVM, ElemwiseMod) { KernelScope kernel_scope; constexpr int N = 1024; Placeholder a(BufHandle("A", {N}, kInt)); Placeholder b(BufHandle("B", {N}, kInt)); Placeholder c(BufHandle("C", {N}, kInt)); std::vector a_buffer(N, 41); std::vector b_buffer(N, 23); std::vector c_buffer(N, 18); VarHandle i("i", kInt); auto expr = For::make(i, 0, N, c.store({i}, Mod::make(a.load(i), b.load(i)))); LLVMCodeGen cg(expr, {a, b, c}); std::vector args({a_buffer.data(), b_buffer.data(), c_buffer.data()}); ASSERT_EQ(cg.value(args), 0); ASSERT_EQ(a_buffer.size(), N); ASSERT_EQ(b_buffer.size(), N); ASSERT_EQ(c_buffer.size(), N); assertAllEqual(a_buffer, 41); assertAllEqual(b_buffer, 23); assertAllEqual(c_buffer, 18); } TEST(LLVM, CompareSelectIntEQ) { KernelScope kernel_scope; constexpr int N = 1024; Placeholder a(BufHandle("A", {N}, kInt)); Placeholder b(BufHandle("B", {N}, kInt)); Placeholder c(BufHandle("C", {N}, kInt)); std::vector a_buffer(N, 1); std::vector b_buffer(N, 1); std::vector c_buffer(N, 0); std::vector c_ref(N, 1); for (int i = 0; i < N / 2; i++) { b_buffer[i] = 0; c_ref[i] = 0; } VarHandle i("i", kInt); auto expr = For::make( i, 0, N, c.store( {i}, CompareSelect::make( a.load(i), b.load(i), CompareSelectOperation::kEQ))); LLVMCodeGen cg(expr, {a, b, c}); std::vector args({a_buffer.data(), b_buffer.data(), c_buffer.data()}); ASSERT_EQ(cg.value(args), 0); ASSERT_EQ(a_buffer.size(), N); ASSERT_EQ(b_buffer.size(), N); ASSERT_EQ(c_buffer.size(), N); assertAllEqual(a_buffer, 1); for (int i = 0; i < N; i++) { ASSERT_EQ(c_ref[i], c_buffer[i]); } } TEST(LLVM, CompareSelectFloatEQ) { KernelScope kernel_scope; constexpr int N = 1024; Placeholder a(BufHandle("A", {N}, kFloat)); Placeholder b(BufHandle("B", {N}, kFloat)); Placeholder c(BufHandle("C", {N}, kInt)); std::vector a_buffer(N, 1.0f); std::vector b_buffer(N, 1.0f); std::vector c_buffer(N, 0); VarHandle i("i", kInt); auto expr = For::make( i, 0, N, c.store( {i}, CompareSelect::make( a.load(i), b.load(i), CompareSelectOperation::kEQ))); LLVMCodeGen cg(expr, {a, b, c}); std::vector args({a_buffer.data(), b_buffer.data(), c_buffer.data()}); ASSERT_EQ(cg.value(args), 0); ASSERT_EQ(a_buffer.size(), N); ASSERT_EQ(b_buffer.size(), N); ASSERT_EQ(c_buffer.size(), N); assertAllEqual(a_buffer, 1.0f); assertAllEqual(b_buffer, 1.0f); assertAllEqual(c_buffer, 1); } TEST(LLVM, CompareSelectByteGT) { KernelScope kernel_scope; constexpr int N = 1024; Placeholder a(BufHandle("A", {N}, kByte)); Placeholder b(BufHandle("B", {N}, kByte)); Placeholder c(BufHandle("C", {N}, kInt)); std::vector a_buffer(N, 0); std::vector b_buffer(N, 0); std::vector c_buffer(N, 0); std::vector c_ref(N, 0); for (int i = 0; i < N / 2; i++) { a_buffer[i] = 128; c_ref[i] = 1; } VarHandle i("i", kInt); auto expr = For::make( i, 0, N, c.store( {i}, CompareSelect::make( a.load(i), b.load(i), CompareSelectOperation::kGT))); LLVMCodeGen cg(expr, {a, b, c}); std::vector args({a_buffer.data(), b_buffer.data(), c_buffer.data()}); ASSERT_EQ(cg.value(args), 0); ASSERT_EQ(a_buffer.size(), N); ASSERT_EQ(b_buffer.size(), N); ASSERT_EQ(c_buffer.size(), N); assertAllEqual(b_buffer, uint8_t(0)); for (int i = 0; i < N; i++) { ASSERT_EQ(c_ref[i], c_buffer[i]); } } TEST(LLVM, CompareSelectByteGE) { KernelScope kernel_scope; constexpr int N = 1024; Placeholder a(BufHandle("A", {N}, kByte)); Placeholder b(BufHandle("B", {N}, kByte)); Placeholder c(BufHandle("C", {N}, kInt)); std::vector a_buffer(N, 0); std::vector b_buffer(N, 0); std::vector c_buffer(N, 0); std::vector c_ref(N, 1); VarHandle i("i", kInt); auto expr = For::make( i, 0, N, c.store( {i}, CompareSelect::make( a.load(i), b.load(i), CompareSelectOperation::kGE))); LLVMCodeGen cg(expr, {a, b, c}); std::vector args({a_buffer.data(), b_buffer.data(), c_buffer.data()}); ASSERT_EQ(cg.value(args), 0); ASSERT_EQ(a_buffer.size(), N); ASSERT_EQ(b_buffer.size(), N); ASSERT_EQ(c_buffer.size(), N); assertAllEqual(b_buffer, uint8_t(0)); for (int i = 0; i < N; i++) { ASSERT_EQ(c_ref[i], c_buffer[i]); } } TEST(LLVM, CompareSelectByteLT) { KernelScope kernel_scope; constexpr int N = 1024; Placeholder a(BufHandle("A", {N}, kByte)); Placeholder b(BufHandle("B", {N}, kByte)); Placeholder c(BufHandle("C", {N}, kInt)); std::vector a_buffer(N, 0); std::vector b_buffer(N, 128); std::vector c_buffer(N, 0); std::vector c_ref(N, 1); for (int i = 0; i < N / 2; i++) { a_buffer[i] = 128; c_ref[i] = 0; } VarHandle i("i", kInt); auto expr = For::make( i, 0, N, c.store( {i}, CompareSelect::make( a.load(i), b.load(i), CompareSelectOperation::kLT))); LLVMCodeGen cg(expr, {a, b, c}); std::vector args({a_buffer.data(), b_buffer.data(), c_buffer.data()}); ASSERT_EQ(cg.value(args), 0); ASSERT_EQ(a_buffer.size(), N); ASSERT_EQ(b_buffer.size(), N); ASSERT_EQ(c_buffer.size(), N); assertAllEqual(b_buffer, uint8_t(128)); for (int i = 0; i < N; i++) { ASSERT_EQ(c_ref[i], c_buffer[i]); } } TEST(LLVM, CompareSelectByteLE) { KernelScope kernel_scope; constexpr int N = 1024; Placeholder a(BufHandle("A", {N}, kByte)); Placeholder b(BufHandle("B", {N}, kByte)); Placeholder c(BufHandle("C", {N}, kInt)); std::vector a_buffer(N, 0); std::vector b_buffer(N, 128); std::vector c_buffer(N, 0); std::vector c_ref(N, 1); VarHandle i("i", kInt); auto expr = For::make( i, 0, N, c.store( {i}, CompareSelect::make( a.load(i), b.load(i), CompareSelectOperation::kLE))); LLVMCodeGen cg(expr, {a, b, c}); std::vector args({a_buffer.data(), b_buffer.data(), c_buffer.data()}); ASSERT_EQ(cg.value(args), 0); ASSERT_EQ(a_buffer.size(), N); ASSERT_EQ(b_buffer.size(), N); ASSERT_EQ(c_buffer.size(), N); assertAllEqual(b_buffer, uint8_t(128)); for (int i = 0; i < N; i++) { ASSERT_EQ(c_ref[i], c_buffer[i]); } } TEST(LLVM, StoreFloat) { KernelScope kernel_scope; Placeholder result(BufHandle("result", {1}, kFloat)); std::vector result_buffer = {0.0f}; auto expr = result.store({0}, FloatImm::make(3.14f)); LLVMCodeGen cg(expr, {result}); std::vector args({result_buffer.data()}); ASSERT_EQ(cg.value(args), 0); ASSERT_EQ(result_buffer[0], 3.14f); } TEST(LLVM, SimpleMath01) { KernelScope kernel_scope; const int N = 1024; Tensor* tensor = Compute("f", {{N, "i"}}, [](const VarHandle& i) { return cast(i * i + 1); }); LoopNest l({tensor}); Stmt* stmt = l.root_stmt(); Placeholder f_buf(BufHandle(tensor->buf())); LLVMCodeGen cg(stmt, {f_buf}); PaddedBuffer f_v(N, "f_v"); std::vector args({f_v.data()}); int value = cg.value(args); ASSERT_EQ(value, 0); PaddedBuffer f_ref(N, "f_ref"); for (int i = 0; i < N; i++) { f_ref(i) = i * i + 1; } ExpectAllNear(f_v, f_ref, 1e-5); } TEST(LLVM, ComputeMul) { KernelScope kernel_scope; const int N = 1024; Placeholder a(BufHandle("a", {N}, kFloat)); Placeholder b(BufHandle("b", {N}, kFloat)); Tensor* c = Compute("c", {{N, "i"}}, [&](const VarHandle& i) { return a.load(i) * b.load(i); }); Placeholder c_buf(BufHandle(c->buf())); LoopNest l({c}); Stmt* s = l.root_stmt(); LLVMCodeGen cg(s, {a, b, c_buf}); std::vector a_vec(N, 21.0f); std::vector b_vec(N, 2.0f); std::vector c_vec(N, 0.0f); std::vector args({a_vec.data(), b_vec.data(), c_vec.data()}); ASSERT_EQ(cg.value(args), 0); assertAllEqual(c_vec, 42.0f); } TEST(LLVM, BroadcastAdd) { KernelScope kernel_scope; const int M = 32; const int N = 1024; Placeholder a(BufHandle("a", {M, N}, kFloat)); Placeholder b(BufHandle("b", {N}, kFloat)); Tensor* c = Compute( "c", {{M, "i"}, {N, "j"}}, [&](const VarHandle& i, const VarHandle& j) { return a.load(i, j) + b.load(j); }); Placeholder c_buf(BufHandle(c->buf())); LoopNest l({c}); l.prepareForCodegen(); Stmt* s = l.root_stmt(); LLVMCodeGen cg(s, {a, b, c_buf}); std::vector av(M * N); std::iota(av.begin(), av.end(), 0); std::vector bv(N); std::iota(bv.begin(), bv.end(), 0); std::vector cv(M * N, 0); std::vector args({av.data(), bv.data(), cv.data()}); ASSERT_EQ(cg.value(args), 0); for (int i = 0; i < M; i++) { for (int j = 0; j < N; j++) { ASSERT_EQ(cv[i * N + j], av[i * N + j] + bv[j]); } } } TEST(LLVM, BitwiseOps) { KernelScope kernel_scope; auto a = IntImm::make(59); auto b = IntImm::make(11); auto c = IntImm::make(101); auto d = IntImm::make(2); ExprHandle f = (((a ^ (b << 1)) & c) >> 2) | d; LLVMExprEval cg(f); ASSERT_EQ(cg.value(), 11); } TEST(LLVM, DynamicShapeAdd) { KernelScope kernel_scope; auto testWithSize = [](int32_t size) { VarHandle n("n", kInt); Placeholder a(BufHandle("a", {n}, kFloat)); Placeholder b(BufHandle("b", {n}, kFloat)); Placeholder c(BufHandle("c", {n}, kFloat)); VarHandle i("i", kInt); Stmt* s = For::make(i, 0, n, c.store({i}, a.load(i) + b.load(i))); std::vector aData(size, 1.0f); std::vector bData(size, 2.0f); std::vector cData(size, 0.0f); LLVMCodeGen cg(s, {a, b, c, n}); std::vector args({aData.data(), bData.data(), cData.data(), &size}); cg.value(args); ExpectAllNear(cData, std::vector(size, 3.0f), 1e-7); }; testWithSize(1); testWithSize(16); testWithSize(37); } TEST(LLVM, BindDynamicShapeAdd) { KernelScope kernel_scope; auto testWithSize = [](int32_t size) { VarHandle n("n", kInt); Placeholder a(BufHandle("a", {n}, kFloat)); Placeholder b(BufHandle("b", {n}, kFloat)); Placeholder c(BufHandle("c", {n}, kFloat)); VarHandle i("i", kInt); Stmt* s = For::make(i, 0, n, c.store({i}, a.load(i) + b.load(i))); std::vector aData(size, 1.0f); std::vector bData(size, 2.0f); std::vector cData(size, 0.0f); LLVMCodeGen cg(s, {a, b, c, n}); cg.call({aData, bData, cData, size}); ExpectAllNear(cData, std::vector(size, 3.0f), 1e-7); }; testWithSize(1); testWithSize(16); testWithSize(37); } TEST(LLVM, TensorDynamicShapeAdd) { KernelScope kernel_scope; auto testWithSize = [](int32_t size) { VarHandle n("n", kInt); Placeholder a(BufHandle("a", {n}, kFloat)); Placeholder b(BufHandle("b", {n}, kFloat)); Tensor* c = Compute("c", {{n, "n"}}, [&](const VarHandle& i) { return a.load(i) + b.load(i); }); LoopNest l({c}); Stmt* s = l.root_stmt(); LLVMCodeGen cg(s, {a, b, c, n}); std::vector aData(size, 1.0f); std::vector bData(size, 2.0f); std::vector cData(size, 0.0f); cg.call({aData, bData, cData, size}); ExpectAllNear(cData, std::vector(size, 3.0f), 1e-7); }; testWithSize(1); testWithSize(16); testWithSize(37); } TEST(LLVM, DynamicShape2D) { KernelScope kernel_scope; auto testWithSize = [](int32_t M, int32_t N) { VarHandle m("m", kInt); VarHandle n("n", kInt); Placeholder a(BufHandle("a", {m, n}, kFloat)); Placeholder b(BufHandle("b", {m, n}, kFloat)); Tensor* c = Compute( "c", {{m, "m"}, {n, "n"}}, [&](const VarHandle& i, const VarHandle& j) { return a.load(i, j) + b.load(i, j); }); LoopNest l({c}); l.prepareForCodegen(); Stmt* s = l.root_stmt(); LLVMCodeGen cg(s, {a, b, c, m, n}); std::vector aData(M * N, 1.0f); std::vector bData(M * N, 2.0f); std::vector cData(M * N, 0.0f); cg.call({aData, bData, cData, M, N}); ExpectAllNear(cData, std::vector(M * N, 3.0f), 1e-7); }; testWithSize(1, 8); testWithSize(16, 32); testWithSize(37, 11); } TEST(LLVM, EmptyStmt) { KernelScope kernel_scope; Stmt* s = new Block({}); LLVMCodeGen cg(s, {}); cg.call({}); // Just don't crash. } TEST(LLVM, EliminatedStmt) { KernelScope kernel_scope; Placeholder a(BufHandle("a", {1}, kFloat)); Tensor* c = Compute("c", {{0, "m"}}, [&](const VarHandle& m) { return m; }); LoopNest l({c}); l.prepareForCodegen(); Stmt* s = l.root_stmt(); s = IRSimplifier::simplify(s); LLVMCodeGen cg(s, {a, c}); std::vector aData(1, 1.0f); std::vector cData(0, 0.0f); cg.call({aData, cData}); } TEST(LLVM, SimpleReduction) { KernelScope kernel_scope; int M = 128; int N = 64; const int kTotalSize = M * N; Placeholder a("a", kFloat, {1, M, N}); // TODO: why doesn't implicit vector work? std::vector axis = {DimArg(1)}; std::vector reduce_axis = {DimArg(M), DimArg(N)}; Tensor* b = Reduce("sum", axis, Sum(), a, reduce_axis); LoopNest loop({b}); loop.prepareForCodegen(); Stmt* s = loop.root_stmt(); s = IRSimplifier::simplify(s); LLVMCodeGen cg(s, {a, b}); PaddedBuffer a_v(1, M, N, "a_v"); PaddedBuffer b_v(1, "b_v"); PaddedBuffer b_ref(1, "b_ref"); b_ref(0) = 0; for (int i = 0; i < M; i++) { for (int j = 0; j < N; j++) { int v = i + j; a_v(0, i, j) = v; b_ref(0) += v; } } cg.call({a_v, b_v}); ExpectAllNear(b_v, b_ref, 1e-5); } TEST(LLVM, RFactorReduction) { KernelScope kernel_scope; int M = 128; int N = 64; const int kTotalSize = M * N; Placeholder a("a", kFloat, {1, M, N}); // TODO: why doesn't implicit vector work? std::vector axis = {DimArg(1)}; std::vector reduce_axis = {DimArg(M), DimArg(N)}; Tensor* b = Reduce("sum", axis, Sum(), a, reduce_axis); LoopNest loop({b}); std::vector loops = loop.getLoopStmtsFor(b); For* loop_m = loops.at(1); For* loop_n = loops.at(2); loop.reorderAxis(loop_m, loop_n); loops = loop.getLoopStmtsFor(b); loop_m = loops.at(2); loop_n = loops.at(1); auto b_body = NodeFinder::find(loop.root_stmt())[0]; loop.rfactor(b_body, loop_n->var(), loop_n->body()); loop.prepareForCodegen(); Stmt* s = loop.root_stmt(); s = IRSimplifier::simplify(s); LLVMCodeGen cg(s, {a, b}); PaddedBuffer a_v(1, M, N, "a_v"); PaddedBuffer b_v(1, "b_v"); PaddedBuffer b_ref(1, "b_ref"); b_ref(0) = 0; for (int i = 0; i < M; i++) { for (int j = 0; j < N; j++) { int v = i + j; a_v(0, i, j) = v; b_ref(0) += v; } } cg.call({a_v, b_v}); ExpectAllNear(b_v, b_ref, 1e-5); } TEST(LLVM, RFactorVectorizedReduction) { KernelScope kernel_scope; int M = 128; int N = 64; const int kTotalSize = M * N; Placeholder a("a", kFloat, {1, M, N}); Tensor* b = Reduce("sum", {{1, "K"}}, Sum(), a, {{M, "M"}, {N, "N"}}); LoopNest loopnest({b}); std::vector loops = loopnest.getLoopStmtsFor(b); For* loop_k = loops.at(0); For* loop_m = loops.at(1); For* loop_n = loops.at(2); auto b_body = NodeFinder::find(loopnest.root_stmt())[0]; loopnest.rfactor(b_body, loop_n->var()); loops = NodeFinder::find(loopnest.root_stmt()); loop_k = loops.at(0); // loop 1 is the initializer of tmp_buf loop_m = loops.at(2); loop_n = loops.at(3); loopnest.reorderAxis(loop_n, loop_m); // Case-III reductions loops = NodeFinder::find(loopnest.root_stmt()); // Vectorize initializer of tmp_buf loopnest.vectorize(loops[1]); // Vectorize producer of tmp_buf loopnest.vectorize(loops[2]); loopnest.prepareForCodegen(); Stmt* s = IRSimplifier::simplify(loopnest.root_stmt()); LLVMCodeGen cg(s, {a, b}); PaddedBuffer a_v(1, M, N, "a_v"); PaddedBuffer b_v(1, "b_v"); PaddedBuffer b_ref(1, "b_ref"); b_ref(0) = 0; for (int i = 0; i < M; i++) { for (int j = 0; j < N; j++) { int v = i + j; a_v(0, i, j) = v; b_ref(0) += v; } } cg.call({a_v, b_v}); ExpectAllNear(b_v, b_ref, 1e-5); } TEST(LLVM, VectorizedGEMM) { KernelScope ks; int M = 32; int N = 32; int K = 48; Placeholder AP(BufHandle("A", {M, K}, kFloat)); Placeholder BP(BufHandle("B", {K, N}, kFloat)); Tensor* CT = Reduce( "gemm", {{M, "M"}, {N, "N"}}, Sum(), [&](const ExprHandle& m, const ExprHandle& n, const ExprHandle& k) { return AP.load(m, k) * BP.load(k, n); }, {{K, "K"}}); LoopNest loop({CT}); { auto const& loops = loop.getLoopStmtsFor(CT); For* m = loops[0]; For* mo; For* mi; loop.splitWithMask(m, 16, &mo, &mi); } { auto const& loops = loop.getLoopStmtsFor(CT); For* n = loops[2]; For* no; For* ni; loop.splitWithMask(n, 16, &no, &ni); } // mo, mi, no, ni, k -> // mo, no, mi, ni, k { auto const& loops = loop.getLoopStmtsFor(CT); For* mi = loops[1]; For* no = loops[2]; loop.reorderAxis(mi, no); } // mo, no, mi, ni, k -> // mo, no, mi, k, ni { auto const& loops = loop.getLoopStmtsFor(CT); For* ni = loops[3]; For* k = loops[4]; loop.reorderAxis(ni, k); } // mo, no, mi, k, ni -> // mo, no, k, mi, ni { auto const& loops = loop.getLoopStmtsFor(CT); For* mi = loops[2]; For* k = loops[3]; loop.reorderAxis(mi, k); } { auto loops = NodeFinder::find(loop.root_stmt()); loop.vectorize(loops[3]); loop.vectorize(loops.back()); } loop.prepareForCodegen(); Stmt* s = loop.root_stmt(); s = IRSimplifier::simplify(s); LLVMCodeGen cg(s, {AP, BP, CT}); PaddedBuffer a_v(M, K, "a_v"); PaddedBuffer b_v(K, N, "b_v"); PaddedBuffer c_v(M, N, "c_v"); PaddedBuffer c_ref(M, N, "c_ref"); for (int m = 0; m < M; m++) { for (int n = 0; n < N; n++) { c_ref(m, n) = 0.f; for (int k = 0; k < K; k++) { c_ref(m, n) += a_v(m, k) * b_v(k, n); } } } cg.call({a_v, b_v, c_v}); ExpectAllNear(c_v, c_ref, 1e-5); } } // namespace jit } // namespace torch #endif // TORCH_ENABLE_LLVM