Files
glint/internal/graph/render_test.go
T
k3nny 7a4d55ec9a
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feat(graph): intra-stage DAG sub-columns and connectors behind chips
When jobs within the same declared GitLab stage have needs: relationships
between each other, the pipeline graph now splits that stage into
topological sub-columns: jobs with no same-stage deps are in sub-column 0,
jobs that depend on them shift one column right. A new computeColumns()
function handles the topo-sort; a narrower subStageGap (20 px vs 50 px
stageGap) separates sub-columns; stage headers span all sub-columns.

SVG connector lines (Bézier curves in DAG mode, bus-bar stubs in classic
mode) are now emitted before job chip rectangles so connectors visually
pass behind chips rather than on top of them.

100% statement coverage maintained (99 tests in graph package).

Co-Authored-By: Claude Sonnet 4.6 <noreply@anthropic.com>
2026-06-25 23:06:49 +02:00

666 lines
23 KiB
Go

package graph
import (
"os"
"strings"
"testing"
"git.k3nny.fr/glint/internal/cicontext"
"git.k3nny.fr/glint/internal/model"
)
// ── svgEsc ────────────────────────────────────────────────────────────────────
func TestSvgEsc(t *testing.T) {
cases := []struct{ in, want string }{
{"hello", "hello"},
{"a&b", "a&amp;b"},
{"<tag>", "&lt;tag&gt;"},
{"a&b<c>d", "a&amp;b&lt;c&gt;d"},
}
for _, tc := range cases {
if got := svgEsc(tc.in); got != tc.want {
t.Errorf("svgEsc(%q)=%q want %q", tc.in, got, tc.want)
}
}
}
// ── svgTrunc ──────────────────────────────────────────────────────────────────
func TestSvgTrunc(t *testing.T) {
cases := []struct {
s string
maxLen int
want string
}{
{"short", 20, "short"},
{"exactly20charslong!", 20, "exactly20charslong!"},
{"this-is-a-very-long-job-name", 20, "this-is-a-very-long…"},
{"αβγδεζηθικλμνξο", 5, "αβγδ…"},
}
for _, tc := range cases {
got := svgTrunc(tc.s, tc.maxLen)
if got != tc.want {
t.Errorf("svgTrunc(%q, %d)=%q want %q", tc.s, tc.maxLen, got, tc.want)
}
}
}
// ── svgEmpty ──────────────────────────────────────────────────────────────────
func TestSvgEmpty(t *testing.T) {
out := svgEmpty()
if !strings.Contains(out, "<svg") { t.Error("expected <svg") }
if !strings.Contains(out, "no jobs defined") { t.Error("expected 'no jobs defined'") }
}
// ── chipColor ─────────────────────────────────────────────────────────────────
func TestChipColor(t *testing.T) {
if chipColor(model.Job{Trigger: "x"}) != "#6b4fbb" { t.Error("trigger color") }
if chipColor(model.Job{When: "manual"}) != "#fc6d26" { t.Error("manual color") }
if chipColor(model.Job{When: "delayed"}) != "#fca326" { t.Error("delayed color") }
if chipColor(model.Job{When: "on_failure"}) != "#d9534f" { t.Error("on_failure color") }
if chipColor(model.Job{}) != "#1f75cb" { t.Error("regular color") }
}
// ── imageString ───────────────────────────────────────────────────────────────
func TestImageString(t *testing.T) {
if imageString("alpine") != "alpine" { t.Error("string form") }
if imageString(map[string]any{"name": "golang:1.21"}) != "golang:1.21" { t.Error("map form") }
if imageString(map[string]any{"other": "x"}) != "" { t.Error("map without name key") }
if imageString(nil) != "" { t.Error("nil") }
if imageString(42) != "" { t.Error("unexpected type") }
}
// ── drawChipIcon ──────────────────────────────────────────────────────────────
func TestDrawChipIcon(t *testing.T) {
cases := []struct {
job model.Job
wantTag string
}{
{model.Job{Trigger: "x"}, "<polyline"},
{model.Job{When: "manual"}, "<polygon"},
{model.Job{When: "delayed"}, "<circle"},
{model.Job{When: "on_failure"}, "<line"},
{model.Job{}, "<polyline"},
}
for _, tc := range cases {
var sb strings.Builder
drawChipIcon(&sb, tc.job, 10, 10)
if !strings.Contains(sb.String(), tc.wantTag) {
t.Errorf("drawChipIcon(%q): want %s, got:\n%s", tc.job.When, tc.wantTag, sb.String())
}
}
}
// ── pipelineSVG ───────────────────────────────────────────────────────────────
func TestPipelineSVG_Empty(t *testing.T) {
svg := pipelineSVG(&model.Pipeline{}, nil)
if !strings.Contains(svg, "no jobs defined") {
t.Errorf("expected 'no jobs defined', got:\n%s", svg)
}
}
func TestPipelineSVG_ClassicMode(t *testing.T) {
p := &model.Pipeline{
Stages: []string{"build", "test"},
Jobs: map[string]model.Job{
"build-job": {Name: "build-job", Stage: "build"},
"test-job": {Name: "test-job", Stage: "test"},
},
}
svg := pipelineSVG(p, nil)
if !strings.Contains(svg, "<svg") { t.Error("expected <svg") }
if !strings.Contains(svg, "build-job") { t.Error("expected build-job") }
if !strings.Contains(svg, "test-job") { t.Error("expected test-job") }
// Classic mode bus-bar draws <line> elements for connectors
if !strings.Contains(svg, "<line") {
t.Error("expected <line> connector in classic mode")
}
}
func TestPipelineSVG_ClassicMode_MultiJob(t *testing.T) {
// Two source jobs, two destination jobs → bus-bar with vertical segment
p := &model.Pipeline{
Stages: []string{"build", "test"},
Jobs: map[string]model.Job{
"build-a": {Name: "build-a", Stage: "build"},
"build-b": {Name: "build-b", Stage: "build"},
"test-a": {Name: "test-a", Stage: "test"},
"test-b": {Name: "test-b", Stage: "test"},
},
}
svg := pipelineSVG(p, nil)
// Bus bar: horizontal stubs from each src + dst, plus a vertical bus line
// and an arrowhead polygon for each dst job.
if !strings.Contains(svg, "<polygon") {
t.Error("expected arrowhead <polygon> in multi-job classic mode")
}
}
func TestPipelineSVG_DAGMode(t *testing.T) {
p := &model.Pipeline{
Stages: []string{"build", "test"},
Jobs: map[string]model.Job{
"build-job": {Name: "build-job", Stage: "build"},
"test-job": {Name: "test-job", Stage: "test", Needs: []any{"build-job"}},
},
}
svg := pipelineSVG(p, nil)
// DAG mode draws <path> bezier curves
if !strings.Contains(svg, "<path") {
t.Error("expected <path> connector in DAG mode")
}
}
func TestPipelineSVG_DAGMode_StraightConnector(t *testing.T) {
// Two stages at same height → straight connector in classic mode
p := &model.Pipeline{
Stages: []string{"a", "b"},
Jobs: map[string]model.Job{
"j1": {Name: "j1", Stage: "a"},
"j2": {Name: "j2", Stage: "b"},
},
}
svg := pipelineSVG(p, nil)
if !strings.Contains(svg, "<svg") { t.Error("expected <svg") }
}
func TestPipelineSVG_AllJobTypes(t *testing.T) {
p := &model.Pipeline{
Stages: []string{"deploy"},
Jobs: map[string]model.Job{
"manual-job": {Name: "manual-job", Stage: "deploy", When: "manual"},
"delayed-job": {Name: "delayed-job", Stage: "deploy", When: "delayed"},
"trigger-job": {Name: "trigger-job", Stage: "deploy", Trigger: "other/project"},
"onfailure-job": {Name: "onfailure-job", Stage: "deploy", When: "on_failure"},
},
}
svg := pipelineSVG(p, nil)
if !strings.Contains(svg, "#fc6d26") { t.Error("expected manual color") }
if !strings.Contains(svg, "#fca326") { t.Error("expected delayed color") }
if !strings.Contains(svg, "#6b4fbb") { t.Error("expected trigger color") }
if !strings.Contains(svg, "#d9534f") { t.Error("expected on_failure color") }
// on_failure chips have a dashed border
if !strings.Contains(svg, `stroke-dasharray="4,3"`) {
t.Error("expected dashed border on on_failure chip")
}
}
func TestPipelineSVG_JobNoStage(t *testing.T) {
p := &model.Pipeline{
Jobs: map[string]model.Job{
"myjob": {Name: "myjob"},
},
}
svg := pipelineSVG(p, nil)
if !strings.Contains(svg, "myjob") { t.Error("expected myjob") }
}
func TestPipelineSVG_CrossPipelineNeed(t *testing.T) {
p := &model.Pipeline{
Stages: []string{"build"},
Jobs: map[string]model.Job{
"j": {Name: "j", Stage: "build",
Needs: []any{map[string]any{"pipeline": "other", "job": "x"}}},
},
}
svg := pipelineSVG(p, nil)
if !strings.Contains(svg, "<svg") { t.Error("expected <svg") }
}
func TestPipelineSVG_Tooltip(t *testing.T) {
p := &model.Pipeline{
Stages: []string{"build"},
Jobs: map[string]model.Job{
"build-job": {
Name: "build-job",
Stage: "build",
When: "on_success",
Image: "golang:1.21",
Needs: []any{"prep-job"},
},
},
}
svg := pipelineSVG(p, nil)
// Tooltip <title> and <desc> should appear inside the <g data-job> wrapper
if !strings.Contains(svg, `<title>build-job</title>`) {
t.Error("expected <title>build-job</title>")
}
if !strings.Contains(svg, `<desc>`) {
t.Error("expected <desc> element")
}
if !strings.Contains(svg, "image: golang:1.21") {
t.Error("expected image in desc")
}
if !strings.Contains(svg, "needs: prep-job") {
t.Error("expected needs in desc")
}
if !strings.Contains(svg, `data-job="build-job"`) {
t.Error("expected data-job attribute")
}
}
func TestPipelineSVG_SkippedJob(t *testing.T) {
// A job with rules that never match in the given context should be greyed out.
p := &model.Pipeline{
Stages: []string{"deploy"},
Jobs: map[string]model.Job{
"deploy-job": {
Name: "deploy-job",
Stage: "deploy",
Script: []any{"deploy.sh"},
Rules: []model.Rule{
{If: `$CI_COMMIT_TAG != ""`, When: "on_success"},
},
},
},
}
// Branch context: CI_COMMIT_TAG is empty → rule doesn't match → job skipped
ctx := cicontext.New("main", "", "push", nil)
svg := pipelineSVG(p, ctx)
// Skipped jobs use grey (#868686) instead of the regular blue
if !strings.Contains(svg, `fill="#868686"`) {
t.Error("expected grey fill for skipped job circle")
}
// Skipped state should appear in the tooltip desc
if !strings.Contains(svg, "state: skipped") {
t.Error("expected 'state: skipped' in tooltip desc")
}
}
func TestPipelineSVG_ContextNil(t *testing.T) {
// nil context → no skipped jobs, regular colors
p := &model.Pipeline{
Stages: []string{"build"},
Jobs: map[string]model.Job{
"j": {Name: "j", Stage: "build"},
},
}
svg := pipelineSVG(p, nil)
if !strings.Contains(svg, `fill="#1f75cb"`) {
t.Error("expected regular blue fill with nil context")
}
}
// ── RenderPipeline ────────────────────────────────────────────────────────────
func TestRenderPipeline(t *testing.T) {
p := &model.Pipeline{
Stages: []string{"build"},
Jobs: map[string]model.Job{
"build-job": {Name: "build-job", Stage: "build"},
},
}
dir := t.TempDir()
path, err := RenderPipeline(p, dir, nil)
if err != nil {
t.Fatalf("RenderPipeline: %v", err)
}
if _, statErr := os.Stat(path); statErr != nil {
t.Errorf("output file not found: %v", statErr)
}
}
func TestRenderPipeline_InvalidDir(t *testing.T) {
// Writing to a path under a file (not a dir) should error.
dir := t.TempDir()
filePath := dir + "/notadir"
if err := os.WriteFile(filePath, []byte("x"), 0o644); err != nil {
t.Fatal(err)
}
_, err := RenderPipeline(&model.Pipeline{}, filePath+"/nested", nil)
if err == nil {
t.Error("expected error writing to path under a file")
}
}
func TestRenderPipeline_WriteFileFails(t *testing.T) {
if os.Getuid() == 0 {
t.Skip("skipping as root — file permissions don't apply")
}
dir := t.TempDir()
if err := os.Chmod(dir, 0o555); err != nil {
t.Fatal(err)
}
t.Cleanup(func() { os.Chmod(dir, 0o755) })
p := &model.Pipeline{
Stages: []string{"build"},
Jobs: map[string]model.Job{"j": {Name: "j", Stage: "build"}},
}
_, err := RenderPipeline(p, dir, nil)
if err == nil {
t.Error("expected error when writing SVG to read-only directory")
}
}
// ── convertToPNG ─────────────────────────────────────────────────────────────
func TestRenderPipeline_SVGFallback(t *testing.T) {
// With no converters on PATH, RenderPipeline returns the SVG path (line 53).
origPath := os.Getenv("PATH")
os.Setenv("PATH", "")
t.Cleanup(func() { os.Setenv("PATH", origPath) })
p := &model.Pipeline{
Stages: []string{"build"},
Jobs: map[string]model.Job{"j": {Name: "j", Stage: "build"}},
}
dir := t.TempDir()
path, err := RenderPipeline(p, dir, nil)
if err != nil {
t.Fatalf("RenderPipeline: %v", err)
}
if !strings.HasSuffix(path, ".svg") {
t.Errorf("expected .svg output when no converter available, got %q", path)
}
}
func TestConvertToPNG_NoConverter(t *testing.T) {
// In a test environment without rsvg-convert/inkscape/magick, returns false.
// We can't assert false because the CI machine might have one of them,
// but we can assert it doesn't panic.
dir := t.TempDir()
svgPath := dir + "/test.svg"
pngPath := dir + "/test.png"
_ = os.WriteFile(svgPath, []byte(`<svg xmlns="http://www.w3.org/2000/svg"/>`), 0o644)
// result is either true (converter found) or false (no converter) — just no panic
convertToPNG(svgPath, pngPath)
}
func TestConvertToPNG_FakeConverter(t *testing.T) {
// Install a fake rsvg-convert that just creates the output file and exits 0.
// This exercises the "return true" branch and os.Remove in RenderPipeline.
binDir := t.TempDir()
script := "#!/bin/sh\n# rsvg-convert --output <out> <in>\ncp \"$3\" \"$2\"\n"
fakeBin := binDir + "/rsvg-convert"
if err := os.WriteFile(fakeBin, []byte(script), 0o755); err != nil {
t.Fatal(err)
}
origPath := os.Getenv("PATH")
os.Setenv("PATH", binDir+":"+origPath)
t.Cleanup(func() { os.Setenv("PATH", origPath) })
svgDir := t.TempDir()
svgPath := svgDir + "/test.svg"
pngPath := svgDir + "/test.png"
if err := os.WriteFile(svgPath, []byte(`<svg xmlns="http://www.w3.org/2000/svg"/>`), 0o644); err != nil {
t.Fatal(err)
}
ok := convertToPNG(svgPath, pngPath)
if !ok {
t.Error("expected convertToPNG to return true with fake rsvg-convert")
}
}
func TestRenderPipeline_PNGConversion(t *testing.T) {
// Verify the PNG path is returned (and SVG removed) when converter succeeds.
binDir := t.TempDir()
script := "#!/bin/sh\ncp \"$3\" \"$2\"\n"
if err := os.WriteFile(binDir+"/rsvg-convert", []byte(script), 0o755); err != nil {
t.Fatal(err)
}
origPath := os.Getenv("PATH")
os.Setenv("PATH", binDir+":"+origPath)
t.Cleanup(func() { os.Setenv("PATH", origPath) })
p := &model.Pipeline{
Stages: []string{"build"},
Jobs: map[string]model.Job{"j": {Name: "j", Stage: "build"}},
}
dir := t.TempDir()
path, err := RenderPipeline(p, dir, nil)
if err != nil {
t.Fatalf("RenderPipeline: %v", err)
}
if !strings.HasSuffix(path, ".png") {
t.Errorf("expected .png output, got %q", path)
}
}
// ── pipelineSVG coverage gaps ─────────────────────────────────────────────────
func TestPipelineSVG_LShapedElbow(t *testing.T) {
// Classic mode with unequal stage sizes → vertical bus bar required
p := &model.Pipeline{
Stages: []string{"build", "test"},
Jobs: map[string]model.Job{
"j1": {Name: "j1", Stage: "build"},
"j2": {Name: "j2", Stage: "test"},
"j3": {Name: "j3", Stage: "test"},
},
}
svg := pipelineSVG(p, nil)
// The bus bar is a <line>; arrowheads are <polygon>
if !strings.Contains(svg, "<polygon") {
t.Error("expected <polygon> arrowhead in bus-bar connector")
}
}
func TestPipelineSVG_DAGNeedNotInPositionMap(t *testing.T) {
// DAG mode: job needs a template job (starts with .) → dep not in position maps → continue
p := &model.Pipeline{
Stages: []string{"build"},
Jobs: map[string]model.Job{
"j": {Name: "j", Stage: "build", Needs: []any{".hidden-template"}},
".hidden-template": {Name: ".hidden-template", Stage: "build"},
},
}
svg := pipelineSVG(p, nil)
// Should render without panic; .hidden-template is not visible so no connector drawn.
if !strings.Contains(svg, "<svg") {
t.Error("expected valid SVG output")
}
}
// ── RenderHTML ────────────────────────────────────────────────────────────────
func TestRenderHTML(t *testing.T) {
p := &model.Pipeline{
Stages: []string{"build"},
Jobs: map[string]model.Job{
"build-job": {Name: "build-job", Stage: "build"},
},
}
dir := t.TempDir()
path, err := RenderHTML(p, dir, nil)
if err != nil {
t.Fatalf("RenderHTML: %v", err)
}
if !strings.HasSuffix(path, ".html") {
t.Errorf("expected .html output, got %q", path)
}
data, err := os.ReadFile(path)
if err != nil {
t.Fatalf("reading output: %v", err)
}
html := string(data)
if !strings.Contains(html, "<!DOCTYPE html>") { t.Error("expected DOCTYPE") }
if !strings.Contains(html, "<svg") { t.Error("expected embedded <svg") }
if !strings.Contains(html, "build-job") { t.Error("expected job name in HTML") }
if !strings.Contains(html, "applyTransform") { t.Error("expected JS pan/zoom function") }
if !strings.Contains(html, "sidebar") { t.Error("expected sidebar element") }
}
func TestRenderHTML_InvalidDir(t *testing.T) {
dir := t.TempDir()
filePath := dir + "/notadir"
if err := os.WriteFile(filePath, []byte("x"), 0o644); err != nil {
t.Fatal(err)
}
_, err := RenderHTML(&model.Pipeline{}, filePath+"/nested", nil)
if err == nil {
t.Error("expected error writing to path under a file")
}
}
func TestRenderHTML_WriteFileFails(t *testing.T) {
if os.Getuid() == 0 {
t.Skip("skipping as root — file permissions don't apply")
}
dir := t.TempDir()
if err := os.Chmod(dir, 0o555); err != nil {
t.Fatal(err)
}
t.Cleanup(func() { os.Chmod(dir, 0o755) })
p := &model.Pipeline{
Stages: []string{"build"},
Jobs: map[string]model.Job{"j": {Name: "j", Stage: "build"}},
}
_, err := RenderHTML(p, dir, nil)
if err == nil {
t.Error("expected error when writing HTML to read-only directory")
}
}
// ── computeColumns ────────────────────────────────────────────────────────────
func TestComputeColumns_NoIntraNeeds(t *testing.T) {
// No intra-stage needs → one column per stage.
stages := []string{"build", "test"}
byStage := map[string][]string{
"build": {"build-a", "build-b"},
"test": {"test-a"},
}
jobs := map[string]model.Job{
"build-a": {Name: "build-a", Stage: "build"},
"build-b": {Name: "build-b", Stage: "build"},
"test-a": {Name: "test-a", Stage: "test"},
}
cols := computeColumns(stages, byStage, jobs)
if len(cols) != 2 {
t.Fatalf("expected 2 columns (one per stage), got %d", len(cols))
}
if cols[0].stage != "build" || len(cols[0].jobs) != 2 {
t.Errorf("col[0]: got stage=%q jobs=%v", cols[0].stage, cols[0].jobs)
}
if cols[1].stage != "test" || len(cols[1].jobs) != 1 {
t.Errorf("col[1]: got stage=%q jobs=%v", cols[1].stage, cols[1].jobs)
}
}
func TestComputeColumns_IntraNeeds(t *testing.T) {
// job-b depends on job-a in the same stage → split into 2 sub-columns.
stages := []string{"build"}
byStage := map[string][]string{
"build": {"job-a", "job-b"},
}
jobs := map[string]model.Job{
"job-a": {Name: "job-a", Stage: "build"},
"job-b": {Name: "job-b", Stage: "build", Needs: []any{"job-a"}},
}
cols := computeColumns(stages, byStage, jobs)
if len(cols) != 2 {
t.Fatalf("expected 2 sub-columns, got %d", len(cols))
}
// Both belong to the same stage.
if cols[0].stage != "build" || cols[1].stage != "build" {
t.Error("both sub-columns should be in stage 'build'")
}
// job-a has no same-stage deps → depth 0 → first sub-column.
if len(cols[0].jobs) != 1 || cols[0].jobs[0] != "job-a" {
t.Errorf("col[0] should contain job-a, got %v", cols[0].jobs)
}
// job-b depends on job-a → depth 1 → second sub-column.
if len(cols[1].jobs) != 1 || cols[1].jobs[0] != "job-b" {
t.Errorf("col[1] should contain job-b, got %v", cols[1].jobs)
}
}
func TestComputeColumns_EmptyStageSkipped(t *testing.T) {
// Stages with no jobs are silently skipped.
stages := []string{"build", "empty", "test"}
byStage := map[string][]string{
"build": {"j1"},
"test": {"j2"},
}
jobs := map[string]model.Job{
"j1": {Name: "j1", Stage: "build"},
"j2": {Name: "j2", Stage: "test"},
}
cols := computeColumns(stages, byStage, jobs)
if len(cols) != 2 {
t.Fatalf("expected 2 columns (empty stage skipped), got %d", len(cols))
}
}
func TestComputeColumns_CrossStageNeedIgnored(t *testing.T) {
// job-b has needs: for both job-a (same stage) and prev-job (different stage).
// The cross-stage need must be ignored when computing topological depth.
stages := []string{"build"}
byStage := map[string][]string{
"build": {"job-a", "job-b"},
}
jobs := map[string]model.Job{
"job-a": {Name: "job-a", Stage: "build"},
"job-b": {Name: "job-b", Stage: "build", Needs: []any{"job-a", "prev-job"}},
"prev-job": {Name: "prev-job", Stage: "prepare"},
}
cols := computeColumns(stages, byStage, jobs)
// Still split into 2 sub-columns; the cross-stage need is ignored.
if len(cols) != 2 {
t.Fatalf("expected 2 sub-columns, got %d", len(cols))
}
if cols[0].jobs[0] != "job-a" {
t.Errorf("expected job-a in first sub-column, got %v", cols[0].jobs)
}
if cols[1].jobs[0] != "job-b" {
t.Errorf("expected job-b in second sub-column, got %v", cols[1].jobs)
}
}
func TestComputeColumns_CycleGuard(t *testing.T) {
// Intra-stage cycle must not hang (cycle guard returns depth 0).
stages := []string{"build"}
byStage := map[string][]string{
"build": {"a", "b"},
}
jobs := map[string]model.Job{
"a": {Name: "a", Stage: "build", Needs: []any{"b"}},
"b": {Name: "b", Stage: "build", Needs: []any{"a"}},
}
cols := computeColumns(stages, byStage, jobs)
// Should return without hanging; exact column count is implementation-defined.
if len(cols) == 0 {
t.Error("expected at least one column")
}
}
func TestPipelineSVG_IntraStageDAG(t *testing.T) {
// job-b depends on job-a in the same stage → SVG should render both,
// placed as sub-columns (sub-stage gap between them).
p := &model.Pipeline{
Stages: []string{"build"},
Jobs: map[string]model.Job{
"job-a": {Name: "job-a", Stage: "build"},
"job-b": {Name: "job-b", Stage: "build", Needs: []any{"job-a"}},
},
}
svg := pipelineSVG(p, nil)
if !strings.Contains(svg, "job-a") { t.Error("expected job-a in SVG") }
if !strings.Contains(svg, "job-b") { t.Error("expected job-b in SVG") }
// DAG mode: bezier connectors between the two jobs.
if !strings.Contains(svg, "<path") {
t.Error("expected bezier <path> connector between intra-stage jobs")
}
}
// ── htmlPage ──────────────────────────────────────────────────────────────────
func TestHtmlPage(t *testing.T) {
svgContent := `<svg xmlns="http://www.w3.org/2000/svg" width="100" height="50"><rect/></svg>`
html := htmlPage(svgContent)
if !strings.Contains(html, "<!DOCTYPE html>") { t.Error("expected DOCTYPE") }
if !strings.Contains(html, svgContent) { t.Error("expected SVG embedded in HTML") }
if !strings.Contains(html, "id=\"viewport\"") { t.Error("expected viewport element") }
if !strings.Contains(html, "id=\"sidebar\"") { t.Error("expected sidebar element") }
if !strings.Contains(html, "applyTransform") { t.Error("expected JS transform function") }
}