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This reverts commit 4f08f3dc6f
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@ -130,9 +130,6 @@ Optimizations
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* GITHUB#14032: Speed up PostingsEnum when positions are requested.
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(Adrien Grand)
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* GITHUB#14031: Ensure Panama float vector distance impls inlinable.
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(Robert Muir, Chris Hegarty)
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Bug Fixes
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---------------------
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* GITHUB#13832: Fixed an issue where the DefaultPassageFormatter.format method did not format passages as intended
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@ -75,9 +75,6 @@ final class PanamaVectorUtilSupport implements VectorUtilSupport {
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}
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}
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// cached vector sizes for smaller method bodies
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private static final int FLOAT_SPECIES_LENGTH = FLOAT_SPECIES.length();
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// the way FMA should work! if available use it, otherwise fall back to mul/add
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private static FloatVector fma(FloatVector a, FloatVector b, FloatVector c) {
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if (Constants.HAS_FAST_VECTOR_FMA) {
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@ -102,7 +99,7 @@ final class PanamaVectorUtilSupport implements VectorUtilSupport {
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float res = 0;
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// if the array size is large (> 2x platform vector size), its worth the overhead to vectorize
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if (a.length > 2 * FLOAT_SPECIES_LENGTH) {
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if (a.length > 2 * FLOAT_SPECIES.length()) {
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i += FLOAT_SPECIES.loopBound(a.length);
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res += dotProductBody(a, b, i);
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}
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@ -123,33 +120,30 @@ final class PanamaVectorUtilSupport implements VectorUtilSupport {
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FloatVector acc2 = FloatVector.zero(FLOAT_SPECIES);
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FloatVector acc3 = FloatVector.zero(FLOAT_SPECIES);
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FloatVector acc4 = FloatVector.zero(FLOAT_SPECIES);
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final int unrolledLimit = limit - 3 * FLOAT_SPECIES_LENGTH;
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for (; i < unrolledLimit; i += 4 * FLOAT_SPECIES_LENGTH) {
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int unrolledLimit = limit - 3 * FLOAT_SPECIES.length();
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for (; i < unrolledLimit; i += 4 * FLOAT_SPECIES.length()) {
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// one
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FloatVector va = FloatVector.fromArray(FLOAT_SPECIES, a, i);
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FloatVector vb = FloatVector.fromArray(FLOAT_SPECIES, b, i);
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acc1 = fma(va, vb, acc1);
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// two
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final int i2 = i + FLOAT_SPECIES_LENGTH;
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FloatVector vc = FloatVector.fromArray(FLOAT_SPECIES, a, i2);
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FloatVector vd = FloatVector.fromArray(FLOAT_SPECIES, b, i2);
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FloatVector vc = FloatVector.fromArray(FLOAT_SPECIES, a, i + FLOAT_SPECIES.length());
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FloatVector vd = FloatVector.fromArray(FLOAT_SPECIES, b, i + FLOAT_SPECIES.length());
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acc2 = fma(vc, vd, acc2);
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// three
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final int i3 = i2 + FLOAT_SPECIES_LENGTH;
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FloatVector ve = FloatVector.fromArray(FLOAT_SPECIES, a, i3);
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FloatVector vf = FloatVector.fromArray(FLOAT_SPECIES, b, i3);
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FloatVector ve = FloatVector.fromArray(FLOAT_SPECIES, a, i + 2 * FLOAT_SPECIES.length());
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FloatVector vf = FloatVector.fromArray(FLOAT_SPECIES, b, i + 2 * FLOAT_SPECIES.length());
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acc3 = fma(ve, vf, acc3);
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// four
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final int i4 = i3 + FLOAT_SPECIES_LENGTH;
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FloatVector vg = FloatVector.fromArray(FLOAT_SPECIES, a, i4);
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FloatVector vh = FloatVector.fromArray(FLOAT_SPECIES, b, i4);
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FloatVector vg = FloatVector.fromArray(FLOAT_SPECIES, a, i + 3 * FLOAT_SPECIES.length());
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FloatVector vh = FloatVector.fromArray(FLOAT_SPECIES, b, i + 3 * FLOAT_SPECIES.length());
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acc4 = fma(vg, vh, acc4);
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}
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// vector tail: less scalar computations for unaligned sizes, esp with big vector sizes
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for (; i < limit; i += FLOAT_SPECIES_LENGTH) {
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for (; i < limit; i += FLOAT_SPECIES.length()) {
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FloatVector va = FloatVector.fromArray(FLOAT_SPECIES, a, i);
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FloatVector vb = FloatVector.fromArray(FLOAT_SPECIES, b, i);
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acc1 = fma(va, vb, acc1);
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@ -168,7 +162,7 @@ final class PanamaVectorUtilSupport implements VectorUtilSupport {
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float norm2 = 0;
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// if the array size is large (> 2x platform vector size), its worth the overhead to vectorize
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if (a.length > 2 * FLOAT_SPECIES_LENGTH) {
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if (a.length > 2 * FLOAT_SPECIES.length()) {
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i += FLOAT_SPECIES.loopBound(a.length);
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float[] ret = cosineBody(a, b, i);
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sum += ret[0];
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@ -196,8 +190,8 @@ final class PanamaVectorUtilSupport implements VectorUtilSupport {
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FloatVector norm1_2 = FloatVector.zero(FLOAT_SPECIES);
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FloatVector norm2_1 = FloatVector.zero(FLOAT_SPECIES);
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FloatVector norm2_2 = FloatVector.zero(FLOAT_SPECIES);
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final int unrolledLimit = limit - FLOAT_SPECIES_LENGTH;
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for (; i < unrolledLimit; i += 2 * FLOAT_SPECIES_LENGTH) {
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int unrolledLimit = limit - FLOAT_SPECIES.length();
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for (; i < unrolledLimit; i += 2 * FLOAT_SPECIES.length()) {
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// one
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FloatVector va = FloatVector.fromArray(FLOAT_SPECIES, a, i);
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FloatVector vb = FloatVector.fromArray(FLOAT_SPECIES, b, i);
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@ -206,15 +200,14 @@ final class PanamaVectorUtilSupport implements VectorUtilSupport {
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norm2_1 = fma(vb, vb, norm2_1);
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// two
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final int i2 = i + FLOAT_SPECIES_LENGTH;
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FloatVector vc = FloatVector.fromArray(FLOAT_SPECIES, a, i2);
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FloatVector vd = FloatVector.fromArray(FLOAT_SPECIES, b, i2);
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FloatVector vc = FloatVector.fromArray(FLOAT_SPECIES, a, i + FLOAT_SPECIES.length());
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FloatVector vd = FloatVector.fromArray(FLOAT_SPECIES, b, i + FLOAT_SPECIES.length());
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sum2 = fma(vc, vd, sum2);
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norm1_2 = fma(vc, vc, norm1_2);
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norm2_2 = fma(vd, vd, norm2_2);
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}
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// vector tail: less scalar computations for unaligned sizes, esp with big vector sizes
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for (; i < limit; i += FLOAT_SPECIES_LENGTH) {
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for (; i < limit; i += FLOAT_SPECIES.length()) {
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FloatVector va = FloatVector.fromArray(FLOAT_SPECIES, a, i);
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FloatVector vb = FloatVector.fromArray(FLOAT_SPECIES, b, i);
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sum1 = fma(va, vb, sum1);
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@ -234,7 +227,7 @@ final class PanamaVectorUtilSupport implements VectorUtilSupport {
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float res = 0;
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// if the array size is large (> 2x platform vector size), its worth the overhead to vectorize
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if (a.length > 2 * FLOAT_SPECIES_LENGTH) {
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if (a.length > 2 * FLOAT_SPECIES.length()) {
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i += FLOAT_SPECIES.loopBound(a.length);
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res += squareDistanceBody(a, b, i);
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}
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@ -247,12 +240,6 @@ final class PanamaVectorUtilSupport implements VectorUtilSupport {
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return res;
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}
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/** helper: returns fma(a.sub(b), a.sub(b), c) */
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private static FloatVector square(FloatVector a, FloatVector b, FloatVector c) {
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FloatVector diff = a.sub(b);
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return fma(diff, diff, c);
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}
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/** vectorized square distance body */
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private float squareDistanceBody(float[] a, float[] b, int limit) {
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int i = 0;
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@ -262,36 +249,38 @@ final class PanamaVectorUtilSupport implements VectorUtilSupport {
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FloatVector acc2 = FloatVector.zero(FLOAT_SPECIES);
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FloatVector acc3 = FloatVector.zero(FLOAT_SPECIES);
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FloatVector acc4 = FloatVector.zero(FLOAT_SPECIES);
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final int unrolledLimit = limit - 3 * FLOAT_SPECIES_LENGTH;
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for (; i < unrolledLimit; i += 4 * FLOAT_SPECIES_LENGTH) {
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int unrolledLimit = limit - 3 * FLOAT_SPECIES.length();
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for (; i < unrolledLimit; i += 4 * FLOAT_SPECIES.length()) {
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// one
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FloatVector va = FloatVector.fromArray(FLOAT_SPECIES, a, i);
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FloatVector vb = FloatVector.fromArray(FLOAT_SPECIES, b, i);
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acc1 = square(va, vb, acc1);
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FloatVector diff1 = va.sub(vb);
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acc1 = fma(diff1, diff1, acc1);
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// two
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final int i2 = i + FLOAT_SPECIES_LENGTH;
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FloatVector vc = FloatVector.fromArray(FLOAT_SPECIES, a, i2);
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FloatVector vd = FloatVector.fromArray(FLOAT_SPECIES, b, i2);
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acc2 = square(vc, vd, acc2);
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FloatVector vc = FloatVector.fromArray(FLOAT_SPECIES, a, i + FLOAT_SPECIES.length());
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FloatVector vd = FloatVector.fromArray(FLOAT_SPECIES, b, i + FLOAT_SPECIES.length());
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FloatVector diff2 = vc.sub(vd);
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acc2 = fma(diff2, diff2, acc2);
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// three
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final int i3 = i2 + FLOAT_SPECIES_LENGTH;
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FloatVector ve = FloatVector.fromArray(FLOAT_SPECIES, a, i3);
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FloatVector vf = FloatVector.fromArray(FLOAT_SPECIES, b, i3);
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acc3 = square(ve, vf, acc3);
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FloatVector ve = FloatVector.fromArray(FLOAT_SPECIES, a, i + 2 * FLOAT_SPECIES.length());
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FloatVector vf = FloatVector.fromArray(FLOAT_SPECIES, b, i + 2 * FLOAT_SPECIES.length());
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FloatVector diff3 = ve.sub(vf);
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acc3 = fma(diff3, diff3, acc3);
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// four
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final int i4 = i3 + FLOAT_SPECIES_LENGTH;
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FloatVector vg = FloatVector.fromArray(FLOAT_SPECIES, a, i4);
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FloatVector vh = FloatVector.fromArray(FLOAT_SPECIES, b, i4);
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acc4 = square(vg, vh, acc4);
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FloatVector vg = FloatVector.fromArray(FLOAT_SPECIES, a, i + 3 * FLOAT_SPECIES.length());
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FloatVector vh = FloatVector.fromArray(FLOAT_SPECIES, b, i + 3 * FLOAT_SPECIES.length());
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FloatVector diff4 = vg.sub(vh);
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acc4 = fma(diff4, diff4, acc4);
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}
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// vector tail: less scalar computations for unaligned sizes, esp with big vector sizes
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for (; i < limit; i += FLOAT_SPECIES_LENGTH) {
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for (; i < limit; i += FLOAT_SPECIES.length()) {
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FloatVector va = FloatVector.fromArray(FLOAT_SPECIES, a, i);
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FloatVector vb = FloatVector.fromArray(FLOAT_SPECIES, b, i);
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acc1 = square(va, vb, acc1);
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FloatVector diff = va.sub(vb);
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acc1 = fma(diff, diff, acc1);
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}
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// reduce
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FloatVector res1 = acc1.add(acc2);
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