Adjust benchmarks.

benchmarks/src/jvmMain/kotlin/space/kscience/kmath/benchmarks/BigIntBenchmark.kt

@@ -11,7 +11,10 @@ import org.openjdk.jmh.annotations.Benchmark
 import org.openjdk.jmh.annotations.Scope
 import org.openjdk.jmh.annotations.State
 import space.kscience.kmath.misc.UnstableKMathAPI
-import space.kscience.kmath.operations.*
+import space.kscience.kmath.operations.BigIntField
+import space.kscience.kmath.operations.JBigIntegerField
+import space.kscience.kmath.operations.invoke
+import space.kscience.kmath.operations.parseBigInteger
 import java.math.BigInteger
 
 
@@ -19,12 +22,24 @@ import java.math.BigInteger
 @State(Scope.Benchmark)
 internal class BigIntBenchmark {
 
+    val kmSmallNumber = BigIntField.number(100)
+    val jvmSmallNumber = JBigIntegerField.number(100)
     val kmNumber = BigIntField.number(Int.MAX_VALUE)
     val jvmNumber = JBigIntegerField.number(Int.MAX_VALUE)
-    val largeKmNumber = BigIntField { number(11).pow(100_000U) }
-    val largeJvmNumber: BigInteger = JBigIntegerField { number(11).pow(100_000) }
+    val kmLargeNumber = BigIntField { number(11).pow(100_000U) }
+    val jvmLargeNumber: BigInteger = JBigIntegerField { number(11).pow(100_000) }
     val bigExponent = 50_000
 
+    @Benchmark
+    fun kmSmallAdd(blackhole: Blackhole) = BigIntField {
+        blackhole.consume(kmSmallNumber + kmSmallNumber + kmSmallNumber)
+    }
+
+    @Benchmark
+    fun jvmSmallAdd(blackhole: Blackhole) = JBigIntegerField {
+        blackhole.consume(jvmSmallNumber + jvmSmallNumber + jvmSmallNumber)
+    }
+
     @Benchmark
     fun kmAdd(blackhole: Blackhole) = BigIntField {
         blackhole.consume(kmNumber + kmNumber + kmNumber)
@@ -37,12 +52,12 @@ internal class BigIntBenchmark {
 
     @Benchmark
     fun kmAddLarge(blackhole: Blackhole) = BigIntField {
-        blackhole.consume(largeKmNumber + largeKmNumber + largeKmNumber)
+        blackhole.consume(kmLargeNumber + kmLargeNumber + kmLargeNumber)
     }
 
     @Benchmark
     fun jvmAddLarge(blackhole: Blackhole) = JBigIntegerField {
-        blackhole.consume(largeJvmNumber + largeJvmNumber + largeJvmNumber)
+        blackhole.consume(jvmLargeNumber + jvmLargeNumber + jvmLargeNumber)
     }
 
     @Benchmark
@@ -52,7 +67,7 @@ internal class BigIntBenchmark {
 
     @Benchmark
     fun kmMultiplyLarge(blackhole: Blackhole) = BigIntField {
-        blackhole.consume(largeKmNumber*largeKmNumber)
+        blackhole.consume(kmLargeNumber*kmLargeNumber)
     }
 
     @Benchmark
@@ -62,7 +77,7 @@ internal class BigIntBenchmark {
 
     @Benchmark
     fun jvmMultiplyLarge(blackhole: Blackhole) = JBigIntegerField {
-        blackhole.consume(largeJvmNumber*largeJvmNumber)
+        blackhole.consume(jvmLargeNumber*jvmLargeNumber)
     }
 
     @Benchmark

benchmarks/src/jvmMain/kotlin/space/kscience/kmath/benchmarks/DotBenchmark.kt

@@ -11,7 +11,6 @@ import kotlinx.benchmark.Scope
 import kotlinx.benchmark.State
 import space.kscience.kmath.commons.linear.CMLinearSpace
 import space.kscience.kmath.ejml.EjmlLinearSpaceDDRM
-import space.kscience.kmath.linear.LinearSpace
 import space.kscience.kmath.linear.invoke
 import space.kscience.kmath.linear.linearSpace
 import space.kscience.kmath.operations.DoubleField
@@ -26,8 +25,12 @@ internal class DotBenchmark {
         const val dim = 1000
 
         //creating invertible matrix
-        val matrix1 = LinearSpace.double.buildMatrix(dim, dim) { i, j -> if (i <= j) random.nextDouble() else 0.0 }
-        val matrix2 = LinearSpace.double.buildMatrix(dim, dim) { i, j -> if (i <= j) random.nextDouble() else 0.0 }
+        val matrix1 = Double.algebra.linearSpace.buildMatrix(dim, dim) { i, j ->
+            if (i <= j) random.nextDouble() else 0.0
+        }
+        val matrix2 = Double.algebra.linearSpace.buildMatrix(dim, dim) { i, j ->
+            if (i <= j) random.nextDouble() else 0.0
+        }
 
         val cmMatrix1 = CMLinearSpace { matrix1.toCM() }
         val cmMatrix2 = CMLinearSpace { matrix2.toCM() }
@@ -37,37 +40,32 @@ internal class DotBenchmark {
     }
 
     @Benchmark
-    fun cmDot(blackhole: Blackhole) {
-        CMLinearSpace {
-            blackhole.consume(cmMatrix1 dot cmMatrix2)
-        }
+    fun cmDotWithConversion(blackhole: Blackhole) = CMLinearSpace {
+        blackhole.consume(matrix1 dot matrix2)
     }
 
     @Benchmark
-    fun ejmlDot(blackhole: Blackhole) {
-        EjmlLinearSpaceDDRM {
-            blackhole.consume(ejmlMatrix1 dot ejmlMatrix2)
-        }
+    fun cmDot(blackhole: Blackhole) = CMLinearSpace {
+        blackhole.consume(cmMatrix1 dot cmMatrix2)
     }
 
     @Benchmark
-    fun ejmlDotWithConversion(blackhole: Blackhole) {
-        EjmlLinearSpaceDDRM {
-            blackhole.consume(matrix1 dot matrix2)
-        }
+    fun ejmlDot(blackhole: Blackhole) = EjmlLinearSpaceDDRM {
+        blackhole.consume(ejmlMatrix1 dot ejmlMatrix2)
     }
 
     @Benchmark
-    fun bufferedDot(blackhole: Blackhole) {
-        with(DoubleField.linearSpace(Buffer.Companion::auto)) {
-            blackhole.consume(matrix1 dot matrix2)
-        }
+    fun ejmlDotWithConversion(blackhole: Blackhole) = EjmlLinearSpaceDDRM {
+        blackhole.consume(matrix1 dot matrix2)
     }
 
     @Benchmark
-    fun doubleDot(blackhole: Blackhole) {
-        with(Double.algebra.linearSpace) {
-            blackhole.consume(matrix1 dot matrix2)
-        }
+    fun bufferedDot(blackhole: Blackhole) = with(DoubleField.linearSpace(Buffer.Companion::auto)) {
+        blackhole.consume(matrix1 dot matrix2)
+    }
+
+    @Benchmark
+    fun doubleDot(blackhole: Blackhole) = with(Double.algebra.linearSpace) {
+        blackhole.consume(matrix1 dot matrix2)
     }
 }

examples/src/main/kotlin/space/kscience/kmath/linear/dotPerformance.kt

@@ -0,0 +1,34 @@
+/*
+ * Copyright 2018-2021 KMath contributors.
+ * Use of this source code is governed by the Apache 2.0 license that can be found in the LICENSE file.
+ */
+
+package space.kscience.kmath.linear
+
+import space.kscience.kmath.operations.algebra
+import kotlin.random.Random
+import kotlin.system.measureTimeMillis
+
+fun main() {
+    val random = Random(12224)
+    val dim = 1000
+
+    //creating invertible matrix
+    val matrix1 = Double.algebra.linearSpace.buildMatrix(dim, dim) { i, j ->
+        if (i <= j) random.nextDouble() else 0.0
+    }
+    val matrix2 = Double.algebra.linearSpace.buildMatrix(dim, dim) { i, j ->
+        if (i <= j) random.nextDouble() else 0.0
+    }
+
+    val time = measureTimeMillis {
+        with(Double.algebra.linearSpace) {
+            repeat(10) {
+                val res = matrix1 dot matrix2
+            }
+        }
+    }
+
+    println(time)
+
+}