tests/regres/cov/coverage_test.go - SwiftShader - Git at Google

 // Copyright 2020 The SwiftShader Authors. All Rights Reserved.
 //
 // Licensed under the Apache License, Version 2.0 (the "License");
 // you may not use this file except in compliance with the License.
 // You may obtain a copy of the License at
 //
 //    http://www.apache.org/licenses/LICENSE-2.0
 //
 // Unless required by applicable law or agreed to in writing, software
 // distributed under the License is distributed on an "AS IS" BASIS,
 // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 // See the License for the specific language governing permissions and
 // limitations under the License.

 package cov_test

 import (
 	"reflect"
 	"strings"
 	"testing"

 	cov "."
 )

 var (
 	fileA = "coverage/file/a"
 	fileB = "coverage/file/b"
 	fileC = "coverage/file/c"
 	fileD = "coverage/file/c"

 	span0 = cov.Span{cov.Location{3, 2}, cov.Location{3, 9}}
 	span1 = cov.Span{cov.Location{4, 1}, cov.Location{5, 1}}
 	span2 = cov.Span{cov.Location{5, 5}, cov.Location{5, 7}}
 	span3 = cov.Span{cov.Location{7, 2}, cov.Location{7, 7}}
 )

 //                a
 //        ╭───────┴───────╮
 //        b               c
 //    ╭───┴───╮       ╭───┴───╮
 //    d       e       f       g
 //  ╭─┴─╮   ╭─┴─╮   ╭─┴─╮   ╭─┴─╮
 //  h   i   j   k   l   m   n   o
 //     ╭┴╮ ╭┴╮ ╭┴╮ ╭┴╮ ╭┴╮ ╭╯
 //     p q r s t u v w x y z
 //

 func TestTree(t *testing.T) {
 	tree := &cov.Tree{}

 	t.Log("Add 'b' with the coverage [0,1]")
 	tree.Add(cov.Path{"a", "b"}, coverage(fileA, span0, span1))

 	//           [0,1]
 	//            (a)
 	//       ╭─────╯
 	//       b

 	checkSpans(t, tree.Spans(), span0, span1)
 	checkTests(t, tree, `{a:{b}}`)
 	checkCoverage(t, tree, fileA, `a:{[0,1]}`)

 	t.Log("Add 'i' with the coverage [0,1]")
 	tree.Add(cov.Path{"a", "b", "d", "i"}, coverage(fileA, span0, span1))

 	//           [0,1]
 	//            (a)
 	//       ╭─────╯
 	//       b
 	//    ╭──╯
 	//    d
 	//    ╰─╮
 	//      i
 	checkSpans(t, tree.Spans(), span0, span1)
 	checkTests(t, tree, `{a:{b:{d:{i}}}}`)
 	checkCoverage(t, tree, fileA, `a:{[0,1]}`)

 	t.Log("Add 'e' with the coverage [0,1,2]")
 	tree.Add(cov.Path{"a", "b", "e"}, coverage(fileA, span0, span1, span2))

 	//           [0,1]
 	//            (a)
 	//       ┏━━━━━┛
 	//      (b)
 	//    ╭──┺━━┓
 	//    d    (e)[2]
 	//    ╰─╮
 	//      i
 	checkSpans(t, tree.Spans(), span0, span1, span2)
 	checkTests(t, tree, `{a:{b:{d:{i} e}}}`)
 	checkCoverage(t, tree, fileA, `a:{[0,1] b:{e:{[2]}}}`)

 	t.Log("Add 'n' with the coverage [0,3]")
 	tree.Add(cov.Path{"a", "c", "g", "n"}, coverage(fileA, span0, span3))

 	//            [0]
 	//            (a)
 	//       ┏━━━━━┻━━━━━┓
 	//   [1](b)         (c)[3]
 	//    ╭──┺━━┓        ╰──╮
 	//    d    (e)[2]       g
 	//    ╰─╮             ╭─╯
 	//      i             n
 	checkSpans(t, tree.Spans(), span0, span1, span2, span3)
 	checkTests(t, tree, `{a:{b:{d:{i}e}c:{g:{n}}}}`)
 	checkCoverage(t, tree, fileA, `a:{[0] b:{[1] e:{[2]}} c:{[3]}}`)

 	t.Log("Add 'o' with the coverage [0, 3]")
 	tree.Add(cov.Path{"a", "c", "g", "o"}, coverage(fileA, span0, span3))

 	//              [0]
 	//              (a)
 	//       ┏━━━━━━━┻━━━━━━━┓
 	//   [1](b)             (c)[3]
 	//    ╭──┺━━┓            ╰──╮
 	//    d    (e)[2]           g
 	//    ╰─╮                 ╭─┴─╮
 	//      i                 n   o
 	checkSpans(t, tree.Spans(), span0, span1, span2, span3)
 	checkTests(t, tree, `{a:{b:{d:{i}e}c:{g:{n o}}}}`)
 	checkCoverage(t, tree, fileA, `a:{[0] b:{[1] e:{[2]}} c:{[3]}}`)

 	t.Log("Add 'f' with the coverage [1]")
 	tree.Add(cov.Path{"a", "c", "f"}, coverage(fileA, span1))

 	//               (a)
 	//       ┏━━━━━━━━┻━━━━━━━━┓
 	// [0,1](b)               (c)
 	//    ╭──┺━━┓           ┏━━┻━━┓
 	//    d    (e)[2]   [1](f)   (g)[0,3]
 	//    ╰─╮                   ╭─┴─╮
 	//      i                   n   o
 	checkSpans(t, tree.Spans(), span0, span1, span2, span3)
 	checkTests(t, tree, `{a:{b:{d:{i} e} c:{f g:{n o}}}}`)
 	checkCoverage(t, tree, fileA, `a:{b:{[0,1] e:{[2]}} c:{f:{[1]} g:{[0,3]}}}`)

 	t.Log("Add 'j' with the coverage [3]")
 	tree.Add(cov.Path{"a", "b", "e", "j"}, coverage(fileA, span3))

 	//                   (a)
 	//           ┏━━━━━━━━┻━━━━━━━━┓
 	//          (b)               (c)
 	//       ┏━━━┻━━━┓          ┏━━┻━━┓
 	// [0,1](d)     (e)[3]  [1](f)   (g)[0,3]
 	//       ╰─╮   ╭─╯              ╭─┴─╮
 	//         i   j                n   o
 	checkSpans(t, tree.Spans(), span0, span1, span2, span3)
 	checkTests(t, tree, `{a:{b:{d:{i} e:{j}} c:{f g:{n o}}}}`)
 	checkCoverage(t, tree, fileA, `a:{b:{d:{[0,1]} e:{[3]}} c:{f:{[1]} g:{[0,3]}}}`)

 	t.Log("Add 'k' with the coverage [3]")
 	tree.Add(cov.Path{"a", "b", "e", "k"}, coverage(fileA, span3))

 	//                   (a)
 	//           ┏━━━━━━━━┻━━━━━━━━┓
 	//          (b)               (c)
 	//       ┏━━━┻━━━┓          ┏━━┻━━┓
 	// [0,1](d)     (e)[3]  [1](f)   (g)[0,3]
 	//       ╰─╮   ╭─┴─╮            ╭─┴─╮
 	//         i   j   k            n   o
 	checkSpans(t, tree.Spans(), span0, span1, span2, span3)
 	checkTests(t, tree, `{a:{b:{d:{i} e:{j k}} c:{f g:{n o}}}}`)
 	checkCoverage(t, tree, fileA, `a:{b:{d:{[0,1]} e:{[3]}} c:{f:{[1]} g:{[0,3]}}}`)

 	t.Log("Add 'v' with the coverage [1,2]")
 	tree.Add(cov.Path{"a", "c", "f", "l", "v"}, coverage(fileA, span1, span2))

 	//                   (a)
 	//           ┏━━━━━━━━┻━━━━━━━━━━┓
 	//          (b)                 (c)
 	//       ┏━━━┻━━━┓            ┏━━┻━━┓
 	// [0,1](d)     (e)[3]  [1,2](f)   (g)[0,3]
 	//       ╰─╮   ╭─┴─╮        ╭─╯   ╭─┴─╮
 	//         i   j   k        l     n   o
 	//                         ╭╯
 	//                         v
 	checkSpans(t, tree.Spans(), span0, span1, span2, span3)
 	checkTests(t, tree, `{a:{b:{d:{i} e:{j k}} c:{f:{l:{v}} g:{n o}}}}`)
 	checkCoverage(t, tree, fileA, `a:{b:{d:{[0,1]} e:{[3]}} c:{f:{[1,2]} g:{[0,3]}}}`)

 	t.Log("Add 'x' with the coverage [1,2]")
 	tree.Add(cov.Path{"a", "c", "f", "l", "x"}, coverage(fileA, span1, span2))

 	//                   (a)
 	//           ┏━━━━━━━━┻━━━━━━━━━━┓
 	//          (b)                 (c)
 	//       ┏━━━┻━━━┓            ┏━━┻━━┓
 	// [0,1](d)     (e)[3]  [1,2](f)   (g)[0,3]
 	//       ╰─╮   ╭─┴─╮        ╭─╯   ╭─┴─╮
 	//         i   j   k        l     n   o
 	//                         ╭┴╮
 	//                         v x
 	checkSpans(t, tree.Spans(), span0, span1, span2, span3)
 	checkTests(t, tree, `{a:{b:{d:{i} e:{j k}} c:{f:{l:{v x}} g:{n o}}}}`)
 	checkCoverage(t, tree, fileA, `a:{b:{d:{[0,1]} e:{[3]}} c:{f:{[1,2]} g:{[0,3]}}}`)

 	t.Log("Add 'z' with the coverage [2]")
 	tree.Add(cov.Path{"a", "c", "g", "n", "z"}, coverage(fileA, span2))

 	//                   (a)
 	//           ┏━━━━━━━━┻━━━━━━━━━━━━┓
 	//          (b)                   (c)
 	//       ┏━━━┻━━━┓            ┏━━━━┻━━━━┓
 	// [0,1](d)     (e)[3]  [1,2](f)       (g)
 	//       ╰─╮   ╭─┴─╮        ╭─╯       ┏━┻━┓
 	//         i   j   k        l    [2](n) (o)[0,3]
 	//                         ╭┴╮      ╭╯
 	//                         v x      z
 	checkSpans(t, tree.Spans(), span0, span1, span2, span3)
 	checkTests(t, tree, `{a:{b:{d:{i} e:{j k}} c:{f:{l:{v x}} g:{n: {z} o}}}}`)
 	checkCoverage(t, tree, fileA, `a:{b:{d:{[0,1]} e:{[3]}} c:{f:{[1,2]} g:{n:{[2]} o:{[0,3]}}}}`)

 	tree.Optimize()

 	//                   (a)
 	//           ┏━━━━━━━━┻━━━━━━━━━━━━┓
 	//          (b)                   (c)
 	//       ┏━━━┻━━━┓            ┏━━━━┻━━━━┓
 	//   <0>(d)     (e)[3]    <2>(f)       (g)
 	//       ╰─╮   ╭─┴─╮        ╭─╯       ┏━┻━┓
 	//         i   j   k        l    [2](n) (o)<1>
 	//                         ╭┴╮      ╭╯
 	//                         v x      z
 	checkSpans(t, tree.Spans(), span0, span1, span2, span3)
 	checkGroups(t, tree.FileSpanGroups(fileA), map[cov.SpanGroupID]cov.SpanGroup{
 		0: cov.SpanGroup{Spans: spans(0, 1)},
 		1: cov.SpanGroup{Spans: spans(0, 3)},
 		2: cov.SpanGroup{Spans: spans(1, 2)},
 	})
 	checkTests(t, tree, `{a:{b:{d:{i} e:{j k}} c:{f:{l:{v x}} g:{n: {z} o}}}}`)
 	checkCoverage(t, tree, fileA, `a:{b:{d:{<0>} e:{[3]}} c:{f:{<2>} g:{n:{[2]} o:{<1>}}}}`)
 }

 func TestTreeOptInvertForCommon(t *testing.T) {
 	tree := &cov.Tree{}

 	tree.Add(cov.Path{"a", "b"}, coverage(fileA, span0))
 	tree.Add(cov.Path{"a", "c"}, coverage(fileA, span0))
 	tree.Add(cov.Path{"a", "d"}, coverage(fileA, span0))
 	tree.Add(cov.Path{"a", "e"}, coverage(fileA, span1))
 	tree.Add(cov.Path{"a", "f"}, coverage(fileA, span1))
 	tree.Add(cov.Path{"a", "g"}, coverage(fileA, span0))
 	tree.Add(cov.Path{"a", "h"}, coverage(fileA, span0))
 	tree.Add(cov.Path{"a", "i"}, coverage(fileA, span0))

 	//               (a)
 	//  ┏━━━┳━━━┳━━━┳━┻━┳━━━┳━━━┳━━━┓
 	// (b) (c) (d) (e) (f) (g) (h) (i)
 	// [0] [0] [0] [1] [1] [0] [0] [0]
 	checkSpans(t, tree.Spans(), span0, span1)
 	checkTests(t, tree, `{a:{b c d e f g h i}}`)
 	checkCoverage(t, tree, fileA, `a:{b:{[0]} c:{[0]} d:{[0]} e:{[1]} f:{[1]} g:{[0]} h:{[0]} i:{[0]}}`)

 	tree.Optimize()

 	//               [0]
 	//               (a)
 	//  ╭───┬───┬───┲━┻━┱───┬───┬───╮
 	//  b   c   d  ┏┛   ┗┓  g   h   i
 	//            (e)   (f)
 	//            <0>   <0>
 	checkSpans(t, tree.Spans(), span0, span1)
 	checkGroups(t, tree.FileSpanGroups(fileA), map[cov.SpanGroupID]cov.SpanGroup{
 		0: cov.SpanGroup{Spans: spans(0, 1)},
 	})
 	checkTests(t, tree, `{a:{b c d e f g h i}}`)
 	checkCoverage(t, tree, fileA, `a:{[0] e:{<0>} f:{<0>}}`)
 }

 func TestTreeOptDontInvertForCommon(t *testing.T) {
 	tree := &cov.Tree{}

 	tree.Add(cov.Path{"a", "b"}, coverage(fileA, span0))
 	tree.Add(cov.Path{"a", "c"}, coverage(fileA, span0))
 	tree.Add(cov.Path{"a", "d"}, coverage(fileA, span0))
 	tree.Add(cov.Path{"a", "e"}, coverage(fileA, span1))
 	tree.Add(cov.Path{"a", "f"}, coverage(fileA, span1))
 	tree.Add(cov.Path{"a", "g"}, coverage(fileA, span2))
 	tree.Add(cov.Path{"a", "h"}, coverage(fileA, span2))
 	tree.Add(cov.Path{"a", "i"}, coverage(fileA, span2))

 	//               (a)
 	//  ┏━━━┳━━━┳━━━┳━┻━┳━━━┳━━━┳━━━┓
 	// (b) (c) (d) (e) (f) (g) (h) (i)
 	// [0] [0] [0] [1] [1] [2] [2] [2]
 	checkSpans(t, tree.Spans(), span0, span1, span2)
 	checkTests(t, tree, `{a:{b c d e f g h i}}`)
 	checkCoverage(t, tree, fileA, `a:{b:{[0]} c:{[0]} d:{[0]} e:{[1]} f:{[1]} g:{[2]} h:{[2]} i:{[2]}}`)

 	tree.Optimize()

 	//               (a)
 	//  ┏━━━┳━━━┳━━━┳━┻━┳━━━┳━━━┳━━━┓
 	// (b) (c) (d) (e) (f) (g) (h) (i)
 	// [0] [0] [0] [1] [1] [2] [2] [2]
 	checkSpans(t, tree.Spans(), span0, span1, span2)
 	checkTests(t, tree, `{a:{b c d e f g h i}}`)
 	checkCoverage(t, tree, fileA, `a:{b:{[0]} c:{[0]} d:{[0]} e:{[1]} f:{[1]} g:{[2]} h:{[2]} i:{[2]}}`)
 }

 func checkSpans(t *testing.T, got []cov.Span, expect ...cov.Span) {
 	if !reflect.DeepEqual(got, expect) {
 		t.Errorf("Spans not as expected.\nGot:    %+v\nExpect: %+v", got, expect)
 	}
 }

 func checkGroups(t *testing.T, got, expect map[cov.SpanGroupID]cov.SpanGroup) {
 	if !reflect.DeepEqual(got, expect) {
 		t.Errorf("SpanGroupss not as expected.\nGot:    %+v\nExpect: %+v", got, expect)
 	}
 }

 func checkTests(t *testing.T, tree *cov.Tree, expect string) {
 	g, e := tree.Tests().String(tree.Strings()), expect
 	if tg, te := trimWS(g), trimWS(e); tg != te {
 		t.Errorf("Tests not as expected.\nGot:\n%v\nExpect:\n%v\n------\nGot:    %v\nExpect: %v", g, e, tg, te)
 	}
 }

 func checkCoverage(t *testing.T, tree *cov.Tree, file string, expect string) {
 	g, e := tree.FileCoverage(file).String(tree.Tests(), tree.Strings()), expect
 	if tg, te := trimWS(g), trimWS(e); tg != te {
 		t.Errorf("Coverage not as expected.\nGot:\n%v\nExpect:\n%v\n------\nGot:    %v\nExpect: %v", g, e, tg, te)
 	}
 }

 func trimWS(s string) string {
 	s = strings.ReplaceAll(s, " ", "")
 	s = strings.ReplaceAll(s, "\n", "")
 	return s
 }

 func coverage(file string, spans ...cov.Span) *cov.Coverage {
 	return &cov.Coverage{
 		[]cov.File{
 			cov.File{
 				Path:    file,
 				Covered: spans,
 			},
 		},
 	}
 }

 func spans(ids ...cov.SpanID) cov.SpanSet {
 	out := make(cov.SpanSet, len(ids))
 	for _, id := range ids {
 		out[id] = struct{}{}
 	}
 	return out
 }

 func TestTreeEncodeDecode(t *testing.T) {
 	orig := &cov.Tree{}
 	orig.Add(cov.Path{"a", "b"}, coverage(fileA, span0, span1))
 	orig.Add(cov.Path{"a", "b", "d", "i"}, coverage(fileA, span0, span1))
 	orig.Add(cov.Path{"a", "b", "e"}, coverage(fileA, span0, span1, span2))
 	orig.Add(cov.Path{"a", "c", "g", "n"}, coverage(fileB, span0, span3))
 	orig.Add(cov.Path{"a", "c", "g", "o"}, coverage(fileB, span0, span3))
 	orig.Add(cov.Path{"a", "c", "f"}, coverage(fileA, span1))
 	orig.Add(cov.Path{"a", "b", "e", "j"}, coverage(fileC, span3))
 	orig.Add(cov.Path{"a", "b", "e", "k"}, coverage(fileA, span3))
 	orig.Add(cov.Path{"a", "c", "f", "l", "v"}, coverage(fileA, span1, span2))
 	orig.Add(cov.Path{"a", "c", "f", "l", "x"}, coverage(fileA, span1, span2))
 	orig.Add(cov.Path{"a", "c", "g", "n", "z"}, coverage(fileC, span2))
 	orig.Add(cov.Path{"a", "b"}, coverage(fileA, span0, span1))
 	orig.Add(cov.Path{"a", "b"}, coverage(fileA, span0, span1))

 	origJSON := orig.JSON("revision goes here")
 	read, revision, err := cov.ReadJSON(strings.NewReader(origJSON))
 	if err != nil {
 		t.Fatalf("cov.ReadJSON() failed with: %v", err)
 	}
 	readJSON := read.JSON(revision)
 	if origJSON != readJSON {
 		t.Fatalf("Encode -> Decode -> Encode produced different results:\nOriginal:\n\n%v\n\nRead:\n\n%v", origJSON, readJSON)
 	}
 }
	// Copyright 2020 The SwiftShader Authors. All Rights Reserved.
	//
	// Licensed under the Apache License, Version 2.0 (the "License");
	// you may not use this file except in compliance with the License.
	// You may obtain a copy of the License at
	//
	// http://www.apache.org/licenses/LICENSE-2.0
	//
	// Unless required by applicable law or agreed to in writing, software
	// distributed under the License is distributed on an "AS IS" BASIS,
	// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	// See the License for the specific language governing permissions and
	// limitations under the License.

	package cov_test

	import (
	"reflect"
	"strings"
	"testing"

	cov "."
	)

	var (
	fileA = "coverage/file/a"
	fileB = "coverage/file/b"
	fileC = "coverage/file/c"
	fileD = "coverage/file/c"

	span0 = cov.Span{cov.Location{3, 2}, cov.Location{3, 9}}
	span1 = cov.Span{cov.Location{4, 1}, cov.Location{5, 1}}
	span2 = cov.Span{cov.Location{5, 5}, cov.Location{5, 7}}
	span3 = cov.Span{cov.Location{7, 2}, cov.Location{7, 7}}
	)

	// a
	// ╭───────┴───────╮
	// b c
	// ╭───┴───╮ ╭───┴───╮
	// d e f g
	// ╭─┴─╮ ╭─┴─╮ ╭─┴─╮ ╭─┴─╮
	// h i j k l m n o
	// ╭┴╮ ╭┴╮ ╭┴╮ ╭┴╮ ╭┴╮ ╭╯
	// p q r s t u v w x y z
	//

	func TestTree(t *testing.T) {
	tree := &cov.Tree{}

	t.Log("Add 'b' with the coverage [0,1]")
	tree.Add(cov.Path{"a", "b"}, coverage(fileA, span0, span1))

	// [0,1]
	// (a)
	// ╭─────╯
	// b

	checkSpans(t, tree.Spans(), span0, span1)
	checkTests(t, tree, `{a:{b}}`)
	checkCoverage(t, tree, fileA, `a:{[0,1]}`)

	t.Log("Add 'i' with the coverage [0,1]")
	tree.Add(cov.Path{"a", "b", "d", "i"}, coverage(fileA, span0, span1))

	// [0,1]
	// (a)
	// ╭─────╯
	// b
	// ╭──╯
	// d
	// ╰─╮
	// i
	checkSpans(t, tree.Spans(), span0, span1)
	checkTests(t, tree, `{a:{b:{d:{i}}}}`)
	checkCoverage(t, tree, fileA, `a:{[0,1]}`)

	t.Log("Add 'e' with the coverage [0,1,2]")
	tree.Add(cov.Path{"a", "b", "e"}, coverage(fileA, span0, span1, span2))

	// [0,1]
	// (a)
	// ┏━━━━━┛
	// (b)
	// ╭──┺━━┓
	// d (e)[2]
	// ╰─╮
	// i
	checkSpans(t, tree.Spans(), span0, span1, span2)
	checkTests(t, tree, `{a:{b:{d:{i} e}}}`)
	checkCoverage(t, tree, fileA, `a:{[0,1] b:{e:{[2]}}}`)

	t.Log("Add 'n' with the coverage [0,3]")
	tree.Add(cov.Path{"a", "c", "g", "n"}, coverage(fileA, span0, span3))

	// [0]
	// (a)
	// ┏━━━━━┻━━━━━┓
	// [1](b) (c)[3]
	// ╭──┺━━┓ ╰──╮
	// d (e)[2] g
	// ╰─╮ ╭─╯
	// i n
	checkSpans(t, tree.Spans(), span0, span1, span2, span3)
	checkTests(t, tree, `{a:{b:{d:{i}e}c:{g:{n}}}}`)
	checkCoverage(t, tree, fileA, `a:{[0] b:{[1] e:{[2]}} c:{[3]}}`)

	t.Log("Add 'o' with the coverage [0, 3]")
	tree.Add(cov.Path{"a", "c", "g", "o"}, coverage(fileA, span0, span3))

	// [0]
	// (a)
	// ┏━━━━━━━┻━━━━━━━┓
	// [1](b) (c)[3]
	// ╭──┺━━┓ ╰──╮
	// d (e)[2] g
	// ╰─╮ ╭─┴─╮
	// i n o
	checkSpans(t, tree.Spans(), span0, span1, span2, span3)
	checkTests(t, tree, `{a:{b:{d:{i}e}c:{g:{n o}}}}`)
	checkCoverage(t, tree, fileA, `a:{[0] b:{[1] e:{[2]}} c:{[3]}}`)

	t.Log("Add 'f' with the coverage [1]")
	tree.Add(cov.Path{"a", "c", "f"}, coverage(fileA, span1))

	// (a)
	// ┏━━━━━━━━┻━━━━━━━━┓
	// [0,1](b) (c)
	// ╭──┺━━┓ ┏━━┻━━┓
	// d (e)[2] [1](f) (g)[0,3]
	// ╰─╮ ╭─┴─╮
	// i n o
	checkSpans(t, tree.Spans(), span0, span1, span2, span3)
	checkTests(t, tree, `{a:{b:{d:{i} e} c:{f g:{n o}}}}`)
	checkCoverage(t, tree, fileA, `a:{b:{[0,1] e:{[2]}} c:{f:{[1]} g:{[0,3]}}}`)

	t.Log("Add 'j' with the coverage [3]")
	tree.Add(cov.Path{"a", "b", "e", "j"}, coverage(fileA, span3))

	// (a)
	// ┏━━━━━━━━┻━━━━━━━━┓
	// (b) (c)
	// ┏━━━┻━━━┓ ┏━━┻━━┓
	// [0,1](d) (e)[3] [1](f) (g)[0,3]
	// ╰─╮ ╭─╯ ╭─┴─╮
	// i j n o
	checkSpans(t, tree.Spans(), span0, span1, span2, span3)
	checkTests(t, tree, `{a:{b:{d:{i} e:{j}} c:{f g:{n o}}}}`)
	checkCoverage(t, tree, fileA, `a:{b:{d:{[0,1]} e:{[3]}} c:{f:{[1]} g:{[0,3]}}}`)

	t.Log("Add 'k' with the coverage [3]")
	tree.Add(cov.Path{"a", "b", "e", "k"}, coverage(fileA, span3))

	// (a)
	// ┏━━━━━━━━┻━━━━━━━━┓
	// (b) (c)
	// ┏━━━┻━━━┓ ┏━━┻━━┓
	// [0,1](d) (e)[3] [1](f) (g)[0,3]
	// ╰─╮ ╭─┴─╮ ╭─┴─╮
	// i j k n o
	checkSpans(t, tree.Spans(), span0, span1, span2, span3)
	checkTests(t, tree, `{a:{b:{d:{i} e:{j k}} c:{f g:{n o}}}}`)
	checkCoverage(t, tree, fileA, `a:{b:{d:{[0,1]} e:{[3]}} c:{f:{[1]} g:{[0,3]}}}`)

	t.Log("Add 'v' with the coverage [1,2]")
	tree.Add(cov.Path{"a", "c", "f", "l", "v"}, coverage(fileA, span1, span2))

	// (a)
	// ┏━━━━━━━━┻━━━━━━━━━━┓
	// (b) (c)
	// ┏━━━┻━━━┓ ┏━━┻━━┓
	// [0,1](d) (e)[3] [1,2](f) (g)[0,3]
	// ╰─╮ ╭─┴─╮ ╭─╯ ╭─┴─╮
	// i j k l n o
	// ╭╯
	// v
	checkSpans(t, tree.Spans(), span0, span1, span2, span3)
	checkTests(t, tree, `{a:{b:{d:{i} e:{j k}} c:{f:{l:{v}} g:{n o}}}}`)
	checkCoverage(t, tree, fileA, `a:{b:{d:{[0,1]} e:{[3]}} c:{f:{[1,2]} g:{[0,3]}}}`)

	t.Log("Add 'x' with the coverage [1,2]")
	tree.Add(cov.Path{"a", "c", "f", "l", "x"}, coverage(fileA, span1, span2))

	// (a)
	// ┏━━━━━━━━┻━━━━━━━━━━┓
	// (b) (c)
	// ┏━━━┻━━━┓ ┏━━┻━━┓
	// [0,1](d) (e)[3] [1,2](f) (g)[0,3]
	// ╰─╮ ╭─┴─╮ ╭─╯ ╭─┴─╮
	// i j k l n o
	// ╭┴╮
	// v x
	checkSpans(t, tree.Spans(), span0, span1, span2, span3)
	checkTests(t, tree, `{a:{b:{d:{i} e:{j k}} c:{f:{l:{v x}} g:{n o}}}}`)
	checkCoverage(t, tree, fileA, `a:{b:{d:{[0,1]} e:{[3]}} c:{f:{[1,2]} g:{[0,3]}}}`)

	t.Log("Add 'z' with the coverage [2]")
	tree.Add(cov.Path{"a", "c", "g", "n", "z"}, coverage(fileA, span2))

	// (a)
	// ┏━━━━━━━━┻━━━━━━━━━━━━┓
	// (b) (c)
	// ┏━━━┻━━━┓ ┏━━━━┻━━━━┓
	// [0,1](d) (e)[3] [1,2](f) (g)
	// ╰─╮ ╭─┴─╮ ╭─╯ ┏━┻━┓
	// i j k l [2](n) (o)[0,3]
	// ╭┴╮ ╭╯
	// v x z
	checkSpans(t, tree.Spans(), span0, span1, span2, span3)
	checkTests(t, tree, `{a:{b:{d:{i} e:{j k}} c:{f:{l:{v x}} g:{n: {z} o}}}}`)
	checkCoverage(t, tree, fileA, `a:{b:{d:{[0,1]} e:{[3]}} c:{f:{[1,2]} g:{n:{[2]} o:{[0,3]}}}}`)

	tree.Optimize()

	// (a)
	// ┏━━━━━━━━┻━━━━━━━━━━━━┓
	// (b) (c)
	// ┏━━━┻━━━┓ ┏━━━━┻━━━━┓
	// <0>(d) (e)[3] <2>(f) (g)
	// ╰─╮ ╭─┴─╮ ╭─╯ ┏━┻━┓
	// i j k l [2](n) (o)<1>
	// ╭┴╮ ╭╯
	// v x z
	checkSpans(t, tree.Spans(), span0, span1, span2, span3)
	checkGroups(t, tree.FileSpanGroups(fileA), map[cov.SpanGroupID]cov.SpanGroup{
	0: cov.SpanGroup{Spans: spans(0, 1)},
	1: cov.SpanGroup{Spans: spans(0, 3)},
	2: cov.SpanGroup{Spans: spans(1, 2)},
	})
	checkTests(t, tree, `{a:{b:{d:{i} e:{j k}} c:{f:{l:{v x}} g:{n: {z} o}}}}`)
	checkCoverage(t, tree, fileA, `a:{b:{d:{<0>} e:{[3]}} c:{f:{<2>} g:{n:{[2]} o:{<1>}}}}`)
	}

	func TestTreeOptInvertForCommon(t *testing.T) {
	tree := &cov.Tree{}

	tree.Add(cov.Path{"a", "b"}, coverage(fileA, span0))
	tree.Add(cov.Path{"a", "c"}, coverage(fileA, span0))
	tree.Add(cov.Path{"a", "d"}, coverage(fileA, span0))
	tree.Add(cov.Path{"a", "e"}, coverage(fileA, span1))
	tree.Add(cov.Path{"a", "f"}, coverage(fileA, span1))
	tree.Add(cov.Path{"a", "g"}, coverage(fileA, span0))
	tree.Add(cov.Path{"a", "h"}, coverage(fileA, span0))
	tree.Add(cov.Path{"a", "i"}, coverage(fileA, span0))

	// (a)
	// ┏━━━┳━━━┳━━━┳━┻━┳━━━┳━━━┳━━━┓
	// (b) (c) (d) (e) (f) (g) (h) (i)
	// [0] [0] [0] [1] [1] [0] [0] [0]
	checkSpans(t, tree.Spans(), span0, span1)
	checkTests(t, tree, `{a:{b c d e f g h i}}`)
	checkCoverage(t, tree, fileA, `a:{b:{[0]} c:{[0]} d:{[0]} e:{[1]} f:{[1]} g:{[0]} h:{[0]} i:{[0]}}`)

	tree.Optimize()

	// [0]
	// (a)
	// ╭───┬───┬───┲━┻━┱───┬───┬───╮
	// b c d ┏┛ ┗┓ g h i
	// (e) (f)
	// <0> <0>
	checkSpans(t, tree.Spans(), span0, span1)
	checkGroups(t, tree.FileSpanGroups(fileA), map[cov.SpanGroupID]cov.SpanGroup{
	0: cov.SpanGroup{Spans: spans(0, 1)},
	})
	checkTests(t, tree, `{a:{b c d e f g h i}}`)
	checkCoverage(t, tree, fileA, `a:{[0] e:{<0>} f:{<0>}}`)
	}

	func TestTreeOptDontInvertForCommon(t *testing.T) {
	tree := &cov.Tree{}

	tree.Add(cov.Path{"a", "b"}, coverage(fileA, span0))
	tree.Add(cov.Path{"a", "c"}, coverage(fileA, span0))
	tree.Add(cov.Path{"a", "d"}, coverage(fileA, span0))
	tree.Add(cov.Path{"a", "e"}, coverage(fileA, span1))
	tree.Add(cov.Path{"a", "f"}, coverage(fileA, span1))
	tree.Add(cov.Path{"a", "g"}, coverage(fileA, span2))
	tree.Add(cov.Path{"a", "h"}, coverage(fileA, span2))
	tree.Add(cov.Path{"a", "i"}, coverage(fileA, span2))

	// (a)
	// ┏━━━┳━━━┳━━━┳━┻━┳━━━┳━━━┳━━━┓
	// (b) (c) (d) (e) (f) (g) (h) (i)
	// [0] [0] [0] [1] [1] [2] [2] [2]
	checkSpans(t, tree.Spans(), span0, span1, span2)
	checkTests(t, tree, `{a:{b c d e f g h i}}`)
	checkCoverage(t, tree, fileA, `a:{b:{[0]} c:{[0]} d:{[0]} e:{[1]} f:{[1]} g:{[2]} h:{[2]} i:{[2]}}`)

	tree.Optimize()

	// (a)
	// ┏━━━┳━━━┳━━━┳━┻━┳━━━┳━━━┳━━━┓
	// (b) (c) (d) (e) (f) (g) (h) (i)
	// [0] [0] [0] [1] [1] [2] [2] [2]
	checkSpans(t, tree.Spans(), span0, span1, span2)
	checkTests(t, tree, `{a:{b c d e f g h i}}`)
	checkCoverage(t, tree, fileA, `a:{b:{[0]} c:{[0]} d:{[0]} e:{[1]} f:{[1]} g:{[2]} h:{[2]} i:{[2]}}`)
	}

	func checkSpans(t *testing.T, got []cov.Span, expect ...cov.Span) {
	if !reflect.DeepEqual(got, expect) {
	t.Errorf("Spans not as expected.\nGot: %+v\nExpect: %+v", got, expect)
	}
	}

	func checkGroups(t *testing.T, got, expect map[cov.SpanGroupID]cov.SpanGroup) {
	if !reflect.DeepEqual(got, expect) {
	t.Errorf("SpanGroupss not as expected.\nGot: %+v\nExpect: %+v", got, expect)
	}
	}

	func checkTests(t testing.T, tree cov.Tree, expect string) {
	g, e := tree.Tests().String(tree.Strings()), expect
	if tg, te := trimWS(g), trimWS(e); tg != te {
	t.Errorf("Tests not as expected.\nGot:\n%v\nExpect:\n%v\n------\nGot: %v\nExpect: %v", g, e, tg, te)
	}
	}

	func checkCoverage(t testing.T, tree cov.Tree, file string, expect string) {
	g, e := tree.FileCoverage(file).String(tree.Tests(), tree.Strings()), expect
	if tg, te := trimWS(g), trimWS(e); tg != te {
	t.Errorf("Coverage not as expected.\nGot:\n%v\nExpect:\n%v\n------\nGot: %v\nExpect: %v", g, e, tg, te)
	}
	}

	func trimWS(s string) string {
	s = strings.ReplaceAll(s, " ", "")
	s = strings.ReplaceAll(s, "\n", "")
	return s
	}

	func coverage(file string, spans ...cov.Span) *cov.Coverage {
	return &cov.Coverage{
	[]cov.File{
	cov.File{
	Path: file,
	Covered: spans,
	},
	},
	}
	}

	func spans(ids ...cov.SpanID) cov.SpanSet {
	out := make(cov.SpanSet, len(ids))
	for _, id := range ids {
	out[id] = struct{}{}
	}
	return out
	}

	func TestTreeEncodeDecode(t *testing.T) {
	orig := &cov.Tree{}
	orig.Add(cov.Path{"a", "b"}, coverage(fileA, span0, span1))
	orig.Add(cov.Path{"a", "b", "d", "i"}, coverage(fileA, span0, span1))
	orig.Add(cov.Path{"a", "b", "e"}, coverage(fileA, span0, span1, span2))
	orig.Add(cov.Path{"a", "c", "g", "n"}, coverage(fileB, span0, span3))
	orig.Add(cov.Path{"a", "c", "g", "o"}, coverage(fileB, span0, span3))
	orig.Add(cov.Path{"a", "c", "f"}, coverage(fileA, span1))
	orig.Add(cov.Path{"a", "b", "e", "j"}, coverage(fileC, span3))
	orig.Add(cov.Path{"a", "b", "e", "k"}, coverage(fileA, span3))
	orig.Add(cov.Path{"a", "c", "f", "l", "v"}, coverage(fileA, span1, span2))
	orig.Add(cov.Path{"a", "c", "f", "l", "x"}, coverage(fileA, span1, span2))
	orig.Add(cov.Path{"a", "c", "g", "n", "z"}, coverage(fileC, span2))
	orig.Add(cov.Path{"a", "b"}, coverage(fileA, span0, span1))
	orig.Add(cov.Path{"a", "b"}, coverage(fileA, span0, span1))

	origJSON := orig.JSON("revision goes here")
	read, revision, err := cov.ReadJSON(strings.NewReader(origJSON))
	if err != nil {
	t.Fatalf("cov.ReadJSON() failed with: %v", err)
	}
	readJSON := read.JSON(revision)
	if origJSON != readJSON {
	t.Fatalf("Encode -> Decode -> Encode produced different results:\nOriginal:\n\n%v\n\nRead:\n\n%v", origJSON, readJSON)
	}
	}