mlir/test/Target/Cpp/common-cpp.mlir - llvm-project - Git at Google

 // RUN: mlir-translate -mlir-to-cpp %s | FileCheck %s

 // CHECK: #include "myheader.h"
 emitc.include "myheader.h"
 // CHECK: #include <myheader.h>
 emitc.include <"myheader.h">

 // CHECK: void test_foo_print() {
 func @test_foo_print() {
   // CHECK: [[V1:[^ ]*]] = foo::constant({0, 1});
   %0 = emitc.call "foo::constant"() {args = [dense<[0, 1]> : tensor<2xi32>]} : () -> (i32)
   // CHECK: [[V2:[^ ]*]] = foo::op_and_attr({0, 1}, [[V1]]);
   %1 = emitc.call "foo::op_and_attr"(%0) {args = [dense<[0, 1]> : tensor<2xi32>, 0 : index]} : (i32) -> (i32)
   // CHECK: [[V3:[^ ]*]] = foo::op_and_attr([[V2]], {0, 1});
   %2 = emitc.call "foo::op_and_attr"(%1) {args = [0 : index, dense<[0, 1]> : tensor<2xi32>]} : (i32) -> (i32)
   // CHECK: foo::print([[V3]]);
   emitc.call "foo::print"(%2): (i32) -> ()
   return
 }

 // CHECK: int32_t test_single_return(int32_t [[V2:.*]])
 func @test_single_return(%arg0 : i32) -> i32 {
   // CHECK: return [[V2]]
   return %arg0 : i32
 }

 // CHECK: std::tuple<int32_t, int32_t> test_multiple_return()
 func @test_multiple_return() -> (i32, i32) {
   // CHECK: std::tie([[V3:.*]], [[V4:.*]]) = foo::blah();
   %0:2 = emitc.call "foo::blah"() : () -> (i32, i32)
   // CHECK: [[V5:[^ ]*]] = test_single_return([[V3]]);
   %1 = call @test_single_return(%0#0) : (i32) -> i32
   // CHECK: return std::make_tuple([[V5]], [[V4]]);
   return %1, %0#1 : i32, i32
 }

 // CHECK: test_float
 func @test_float() {
   // CHECK: foo::constant({(float)0.0e+00, (float)1.000000000e+00})
   %0 = emitc.call "foo::constant"() {args = [dense<[0.000000e+00, 1.000000e+00]> : tensor<2xf32>]} : () -> f32
   return
 }

 // CHECK: test_uint
 func @test_uint() {
   // CHECK: uint32_t
   %0 = emitc.call "foo::constant"() {args = [dense<[0, 1]> : tensor<2xui32>]} : () -> ui32
   // CHECK: uint64_t
   %1 = emitc.call "foo::constant"() {args = [dense<[0, 1]> : tensor<2xui64>]} : () -> ui64
   return
 }

 // CHECK: int64_t test_plus_int(int64_t [[V1]])
 func @test_plus_int(%arg0 : i64) -> i64 {
   // CHECK: mhlo::add([[V1]], [[V1]])
   %0 = emitc.call "mhlo::add"(%arg0, %arg0) {args = [0 : index, 1 : index]} : (i64, i64) -> i64
   return %0 : i64
 }

 // CHECK: Tensor<float, 2> mixed_types(Tensor<double, 2> [[V1]])
 func @mixed_types(%arg0: tensor<2xf64>) -> tensor<2xf32> {
   // CHECK: foo::mixed_types([[V1]]);
   %0 = emitc.call "foo::mixed_types"(%arg0) {args = [0 : index]} : (tensor<2xf64>) -> tensor<2xf32>
   return %0 : tensor<2xf32>
 }

 // CHECK: Tensor<uint64_t> mhlo_convert(Tensor<uint32_t> [[V1]])
 func @mhlo_convert(%arg0: tensor<ui32>) -> tensor<ui64> {
   // CHECK: mhlo::convert([[V1]]);
   %0 = emitc.call "mhlo::convert"(%arg0) {args = [0 : index]} : (tensor<ui32>) -> tensor<ui64>
   return %0 : tensor<ui64>
 }

 // CHECK: status_t opaque_types(bool [[V1:[^ ]*]], char [[V2:[^ ]*]]) {
 func @opaque_types(%arg0: !emitc.opaque<"bool">, %arg1: !emitc.opaque<"char">) -> !emitc.opaque<"status_t"> {
   // CHECK: int [[V3:[^ ]*]] = a([[V1]], [[V2]]);
   %0 = emitc.call "a"(%arg0, %arg1) : (!emitc.opaque<"bool">, !emitc.opaque<"char">) -> (!emitc.opaque<"int">)
   // CHECK: char [[V4:[^ ]*]] = b([[V3]]);
   %1 = emitc.call "b"(%0): (!emitc.opaque<"int">) -> (!emitc.opaque<"char">)
   // CHECK: status_t [[V5:[^ ]*]] = c([[V3]], [[V4]]);
   %2 = emitc.call "c"(%0, %1): (!emitc.opaque<"int">, !emitc.opaque<"char">) -> (!emitc.opaque<"status_t">)
   return %2 : !emitc.opaque<"status_t">
 }

 func @apply(%arg0: i32) -> !emitc.opaque<"int32_t*"> {
   // CHECK: int32_t* [[V2]] = &[[V1]];
   %0 = emitc.apply "&"(%arg0) : (i32) -> !emitc.opaque<"int32_t*">
   // CHECK: int32_t [[V3]] = *[[V2]];
   %1 = emitc.apply "*"(%0) : (!emitc.opaque<"int32_t*">) -> (i32)
   return %0 : !emitc.opaque<"int32_t*">
 }
	// RUN: mlir-translate -mlir-to-cpp %s \| FileCheck %s

	// CHECK: #include "myheader.h"
	emitc.include "myheader.h"
	// CHECK: #include <myheader.h>
	emitc.include <"myheader.h">

	// CHECK: void test_foo_print() {
	func @test_foo_print() {
	// CHECK: [[V1:[^ ]*]] = foo::constant({0, 1});
	%0 = emitc.call "foo::constant"() {args = [dense<[0, 1]> : tensor<2xi32>]} : () -> (i32)
	// CHECK: [[V2:[^ ]*]] = foo::op_and_attr({0, 1}, [[V1]]);
	%1 = emitc.call "foo::op_and_attr"(%0) {args = [dense<[0, 1]> : tensor<2xi32>, 0 : index]} : (i32) -> (i32)
	// CHECK: [[V3:[^ ]*]] = foo::op_and_attr([[V2]], {0, 1});
	%2 = emitc.call "foo::op_and_attr"(%1) {args = [0 : index, dense<[0, 1]> : tensor<2xi32>]} : (i32) -> (i32)
	// CHECK: foo::print([[V3]]);
	emitc.call "foo::print"(%2): (i32) -> ()
	return
	}

	// CHECK: int32_t test_single_return(int32_t [[V2:.*]])
	func @test_single_return(%arg0 : i32) -> i32 {
	// CHECK: return [[V2]]
	return %arg0 : i32
	}

	// CHECK: std::tuple<int32_t, int32_t> test_multiple_return()
	func @test_multiple_return() -> (i32, i32) {
	// CHECK: std::tie([[V3:.]], [[V4:.]]) = foo::blah();
	%0:2 = emitc.call "foo::blah"() : () -> (i32, i32)
	// CHECK: [[V5:[^ ]*]] = test_single_return([[V3]]);
	%1 = call @test_single_return(%0#0) : (i32) -> i32
	// CHECK: return std::make_tuple([[V5]], [[V4]]);
	return %1, %0#1 : i32, i32
	}

	// CHECK: test_float
	func @test_float() {
	// CHECK: foo::constant({(float)0.0e+00, (float)1.000000000e+00})
	%0 = emitc.call "foo::constant"() {args = [dense<[0.000000e+00, 1.000000e+00]> : tensor<2xf32>]} : () -> f32
	return
	}

	// CHECK: test_uint
	func @test_uint() {
	// CHECK: uint32_t
	%0 = emitc.call "foo::constant"() {args = [dense<[0, 1]> : tensor<2xui32>]} : () -> ui32
	// CHECK: uint64_t
	%1 = emitc.call "foo::constant"() {args = [dense<[0, 1]> : tensor<2xui64>]} : () -> ui64
	return
	}

	// CHECK: int64_t test_plus_int(int64_t [[V1]])
	func @test_plus_int(%arg0 : i64) -> i64 {
	// CHECK: mhlo::add([[V1]], [[V1]])
	%0 = emitc.call "mhlo::add"(%arg0, %arg0) {args = [0 : index, 1 : index]} : (i64, i64) -> i64
	return %0 : i64
	}

	// CHECK: Tensor<float, 2> mixed_types(Tensor<double, 2> [[V1]])
	func @mixed_types(%arg0: tensor<2xf64>) -> tensor<2xf32> {
	// CHECK: foo::mixed_types([[V1]]);
	%0 = emitc.call "foo::mixed_types"(%arg0) {args = [0 : index]} : (tensor<2xf64>) -> tensor<2xf32>
	return %0 : tensor<2xf32>
	}

	// CHECK: Tensor<uint64_t> mhlo_convert(Tensor<uint32_t> [[V1]])
	func @mhlo_convert(%arg0: tensor<ui32>) -> tensor<ui64> {
	// CHECK: mhlo::convert([[V1]]);
	%0 = emitc.call "mhlo::convert"(%arg0) {args = [0 : index]} : (tensor<ui32>) -> tensor<ui64>
	return %0 : tensor<ui64>
	}

	// CHECK: status_t opaque_types(bool [[V1:[^ ]]], char [[V2:[^ ]]]) {
	func @opaque_types(%arg0: !emitc.opaque<"bool">, %arg1: !emitc.opaque<"char">) -> !emitc.opaque<"status_t"> {
	// CHECK: int [[V3:[^ ]*]] = a([[V1]], [[V2]]);
	%0 = emitc.call "a"(%arg0, %arg1) : (!emitc.opaque<"bool">, !emitc.opaque<"char">) -> (!emitc.opaque<"int">)
	// CHECK: char [[V4:[^ ]*]] = b([[V3]]);
	%1 = emitc.call "b"(%0): (!emitc.opaque<"int">) -> (!emitc.opaque<"char">)
	// CHECK: status_t [[V5:[^ ]*]] = c([[V3]], [[V4]]);
	%2 = emitc.call "c"(%0, %1): (!emitc.opaque<"int">, !emitc.opaque<"char">) -> (!emitc.opaque<"status_t">)
	return %2 : !emitc.opaque<"status_t">
	}

	func @apply(%arg0: i32) -> !emitc.opaque<"int32_t*"> {
	// CHECK: int32_t* [[V2]] = &[[V1]];
	%0 = emitc.apply "&"(%arg0) : (i32) -> !emitc.opaque<"int32_t*">
	// CHECK: int32_t [[V3]] = *[[V2]];
	%1 = emitc.apply ""(%0) : (!emitc.opaque<"int32_t">) -> (i32)
	return %0 : !emitc.opaque<"int32_t*">
	}