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21d776dfc031d63ca16e506986ce78356ed90290
clice/tests/unit/server/compile_graph_tests.cpp
ykiko 75b9ea05b8 refactor(server): split into service layer, add agentic protocol, adopt task_group (#437) 
## Summary

- **Restructure `src/server/` into subdirectories** (`service/`,
`compiler/`, `worker/`, `workspace/`, `protocol/`) to separate concerns:
transport/session management, compilation, worker orchestration, and
persistent workspace state.
- **Decouple MasterServer from transport**: MasterServer no longer holds
a `JsonPeer&` reference or registers handlers itself. New `LSPClient`
and `AgentClient` classes own their peer references and register
protocol handlers, accessing MasterServer internals via `friend class`.
- **Add agentic protocol**: A TCP-based side channel
(`agentic/compileCommand`) that lets external tools (AI agents, build
systems) query compile commands from a running clice server. Includes a
CLI client mode (`--mode agentic --port N --path FILE`), server-side
listener when `--port` is specified in pipe mode, and integration tests
for happy path, fallback, concurrency, and connection-refused.
- **Replace fire-and-forget `loop.schedule()` with `kota::task_group`**:
Compiler compile tasks, Indexer background indexing + resource monitor,
WorkerPool worker monitors, and socket accept loops now use structured
concurrency. This eliminates manual `alive_count_`/generation counters
and ensures all spawned tasks are joined on shutdown.
- **Fix flaky integration test**: `CliceClient.initialize()` now always
sets `cache_dir` to a workspace-local `.clice/` directory, preventing
stale PCH artifacts from the global `~/.cache/clice/` from polluting
test runs.

## Details

**Compiler peer lifetime**: `Compiler` and `Indexer` previously took
`JsonPeer&` in their constructors, coupling them to a single connection.
They now store a `JsonPeer*` set via `set_peer()`, with null checks
before sending diagnostics/progress. This supports the multi-connection
model where agentic clients don't need diagnostics.

**Socket mode single-LSP enforcement**: `accept_connections()` takes a
`register_lsp` flag; when true, only the first connection gets an
`LSPClient`. All connections get an `AgentClient`. This prevents
multiple LSP sessions from racing on shared server state.

**Structured shutdown**: `Compiler::stop()` cancels in-flight compile
tasks and joins them. `WorkerPool::stop()` signals workers and joins the
monitor task group. `Indexer` uses a `cancellation_source` to stop its
resource monitor when a background indexing run completes.

**Pin kotatsu**: Changed from `GIT_TAG main` + `GIT_SHALLOW TRUE` to an
exact commit hash for reproducible builds.

---------

Co-authored-by: Claude Opus 4.6 <noreply@anthropic.com>
2026-05-02 01:06:18 +08:00

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#include <optional>
#include "test/test.h"
#include "server/compiler/compile_graph.h"
namespace clice::testing {
namespace {
namespace ranges = std::ranges;
/// A resolve_fn that always returns no dependencies.
CompileGraph::resolve_fn no_deps() {
return [](std::uint32_t) -> llvm::SmallVector<std::uint32_t> {
return {};
};
}
/// A resolve_fn backed by a static adjacency map.
CompileGraph::resolve_fn
static_resolver(llvm::DenseMap<std::uint32_t, llvm::SmallVector<std::uint32_t>> adj) {
return [adj = std::move(adj)](std::uint32_t path_id) -> llvm::SmallVector<std::uint32_t> {
auto it = adj.find(path_id);
if(it != adj.end()) {
return it->second;
}
return {};
};
}
CompileGraph::dispatch_fn instant_dispatch() {
return [](std::uint32_t) -> kota::task<bool> {
co_return true;
};
}
CompileGraph::dispatch_fn tracking_dispatch(std::vector<std::uint32_t>& compiled) {
return [&compiled](std::uint32_t path_id) -> kota::task<bool> {
compiled.push_back(path_id);
co_return true;
};
}
CompileGraph::dispatch_fn failing_dispatch() {
return [](std::uint32_t) -> kota::task<bool> {
co_return false;
};
}
/// Dispatch that fails only for specific path_ids.
CompileGraph::dispatch_fn selective_dispatch(llvm::DenseSet<std::uint32_t> fail_ids) {
return [fail_ids = std::move(fail_ids)](std::uint32_t path_id) -> kota::task<bool> {
co_return !fail_ids.contains(path_id);
};
}
TEST_SUITE(CompileGraph) {
std::vector<std::uint32_t> compiled;
std::optional<CompileGraph> graph;
template <typename F>
void execute(F&& fn) {
kota::event_loop loop;
auto t = fn();
loop.schedule(t);
loop.run();
}
TEST_CASE(CompileNoDeps) {
graph.emplace(tracking_dispatch(compiled), no_deps());
execute([&]() -> kota::task<> {
auto result = co_await graph->compile(1).catch_cancel();
EXPECT_TRUE(result.has_value());
EXPECT_TRUE(*result);
EXPECT_EQ(compiled.size(), 1u);
EXPECT_EQ(compiled[0], 1u);
EXPECT_FALSE(graph->is_dirty(1));
});
}
TEST_CASE(CompileWithDependency) {
// Unit 1 depends on unit 2.
graph.emplace(tracking_dispatch(compiled),
static_resolver({
{1, {2}}
}));
execute([&]() -> kota::task<> {
auto result = co_await graph->compile(1).catch_cancel();
EXPECT_TRUE(result.has_value());
EXPECT_TRUE(*result);
// Both 2 (dep) and 1 (self) should be compiled, in that order.
EXPECT_EQ(compiled.size(), 2u);
auto pos2 = ranges::find(compiled, 2u);
auto pos1 = ranges::find(compiled, 1u);
EXPECT_TRUE(pos2 < pos1);
EXPECT_FALSE(graph->is_dirty(1));
EXPECT_FALSE(graph->is_dirty(2));
});
}
TEST_CASE(CompileChain) {
// Chain: 1 -> 2 -> 3.
graph.emplace(tracking_dispatch(compiled),
static_resolver({
{1, {2}},
{2, {3}}
}));
execute([&]() -> kota::task<> {
auto result = co_await graph->compile(1).catch_cancel();
EXPECT_TRUE(result.has_value());
EXPECT_TRUE(*result);
EXPECT_EQ(compiled.size(), 3u);
// 3 before 2 before 1.
auto pos3 = ranges::find(compiled, 3u);
auto pos2 = ranges::find(compiled, 2u);
auto pos1 = ranges::find(compiled, 1u);
EXPECT_TRUE(pos3 < pos2);
EXPECT_TRUE(pos2 < pos1);
});
}
TEST_CASE(DiamondDependency) {
// Diamond: 1 -> {2, 3}, 2 -> 4, 3 -> 4.
graph.emplace(tracking_dispatch(compiled),
static_resolver({
{1, {2, 3}},
{2, {4} },
{3, {4} }
}));
execute([&]() -> kota::task<> {
auto result = co_await graph->compile(1).catch_cancel();
EXPECT_TRUE(result.has_value());
EXPECT_TRUE(*result);
// Unit 4 should be compiled exactly once (dedup).
auto count4 = ranges::count(compiled, 4u);
EXPECT_EQ(count4, 1);
EXPECT_FALSE(graph->is_dirty(2));
EXPECT_FALSE(graph->is_dirty(3));
EXPECT_FALSE(graph->is_dirty(4));
});
}
TEST_CASE(UpdateInvalidates) {
// 1 -> 2.
graph.emplace(instant_dispatch(),
static_resolver({
{1, {2}}
}));
execute([&]() -> kota::task<> {
co_await graph->compile(1).catch_cancel();
EXPECT_FALSE(graph->is_dirty(2));
EXPECT_FALSE(graph->is_dirty(1));
graph->update(2);
EXPECT_TRUE(graph->is_dirty(2));
// Cascade: 1 depends on 2, so 1 should also be dirty.
EXPECT_TRUE(graph->is_dirty(1));
});
}
TEST_CASE(UpdateCascade) {
// Chain: 1 -> 2 -> 3.
graph.emplace(instant_dispatch(),
static_resolver({
{1, {2}},
{2, {3}}
}));
execute([&]() -> kota::task<> {
co_await graph->compile(1).catch_cancel();
EXPECT_FALSE(graph->is_dirty(2));
EXPECT_FALSE(graph->is_dirty(3));
// Update leaf (3) — should cascade to 2 and 1.
graph->update(3);
EXPECT_TRUE(graph->is_dirty(3));
EXPECT_TRUE(graph->is_dirty(2));
EXPECT_TRUE(graph->is_dirty(1));
});
}
TEST_CASE(CompileAfterUpdate) {
// 1 -> 2.
graph.emplace(tracking_dispatch(compiled),
static_resolver({
{1, {2}}
}));
execute([&]() -> kota::task<> {
co_await graph->compile(1).catch_cancel();
EXPECT_EQ(compiled.size(), 2u);
graph->update(2);
co_await graph->compile(1).catch_cancel();
// 2 and 1 should be recompiled.
EXPECT_EQ(compiled.size(), 4u);
});
}
TEST_CASE(DispatchFailure) {
// 1 -> 2. Dispatch always fails.
graph.emplace(failing_dispatch(),
static_resolver({
{1, {2}}
}));
execute([&]() -> kota::task<> {
auto result = co_await graph->compile(1).catch_cancel();
EXPECT_TRUE(result.has_value());
EXPECT_FALSE(*result);
// Dep 2 failed, so it stays dirty.
EXPECT_TRUE(graph->is_dirty(2));
});
}
TEST_CASE(CancelAll) {
graph.emplace(instant_dispatch(), no_deps());
// Just verify it doesn't crash.
graph->cancel_all();
}
TEST_CASE(SecondCompileSkips) {
graph.emplace(tracking_dispatch(compiled), no_deps());
execute([&]() -> kota::task<> {
co_await graph->compile(1).catch_cancel();
EXPECT_EQ(compiled.size(), 1u);
// Second compile should skip (already clean).
co_await graph->compile(1).catch_cancel();
EXPECT_EQ(compiled.size(), 1u);
});
}
TEST_CASE(CascadeThroughAlreadyDirty) {
// Chain: 1 -> 2 -> 3.
graph.emplace(instant_dispatch(),
static_resolver({
{1, {2}},
{2, {3}}
}));
execute([&]() -> kota::task<> {
co_await graph->compile(1).catch_cancel();
// Update node 2: marks 2 and 1 dirty.
graph->update(2);
EXPECT_TRUE(graph->is_dirty(1));
EXPECT_TRUE(graph->is_dirty(2));
EXPECT_FALSE(graph->is_dirty(3));
// Now update node 3: must cascade through already-dirty 2 to reach 1.
graph->update(3);
EXPECT_TRUE(graph->is_dirty(3));
EXPECT_TRUE(graph->is_dirty(2));
EXPECT_TRUE(graph->is_dirty(1));
});
}
TEST_CASE(CircularDependencyDetection) {
// Cycle: 1 -> 2 -> 1.
graph.emplace(instant_dispatch(),
static_resolver({
{1, {2}},
{2, {1}}
}));
execute([&]() -> kota::task<> {
auto result = co_await graph->compile(1).catch_cancel();
// Should return false (cycle detected), not deadlock.
EXPECT_TRUE(result.has_value());
EXPECT_FALSE(*result);
});
}
TEST_CASE(CrossBranchCycleDetection) {
// Cross-branch cycle: 1 -> {2, 3}, 2 -> 3, 3 -> 2.
// With when_all, sibling branches could deadlock on each other's
// completion.wait() without proper deadlock detection.
graph.emplace(instant_dispatch(),
static_resolver({
{1, {2, 3}},
{2, {3} },
{3, {2} }
}));
execute([&]() -> kota::task<> {
auto result = co_await graph->compile(1).catch_cancel();
// Should return false (cycle detected), not deadlock.
EXPECT_TRUE(result.has_value());
EXPECT_FALSE(*result);
});
}
TEST_CASE(UpdateResetsResolved) {
int resolve_count = 0;
// 1 depends on {2} initially; after update, depends on {3}.
bool updated = false;
auto resolver = [&](std::uint32_t path_id) -> llvm::SmallVector<std::uint32_t> {
if(path_id == 1) {
resolve_count++;
return updated ? llvm::SmallVector<std::uint32_t>{3}
: llvm::SmallVector<std::uint32_t>{2};
}
return {};
};
graph.emplace(tracking_dispatch(compiled), std::move(resolver));
execute([&]() -> kota::task<> {
// First compile: resolves 1 -> {2}.
co_await graph->compile(1).catch_cancel();
EXPECT_EQ(resolve_count, 1);
EXPECT_EQ(compiled.size(), 2u); // 2, then 1
// Update node 1: resets resolved, changes deps.
updated = true;
graph->update(1);
// Recompile: should re-resolve 1 -> {3}.
co_await graph->compile(1).catch_cancel();
EXPECT_EQ(resolve_count, 2);
// New dep 3 should be compiled, then 1 recompiled.
auto tail = compiled | std::views::drop(2);
EXPECT_TRUE(ranges::find(tail, 3u) != tail.end());
});
}
TEST_CASE(UpdateCleansBackEdges) {
bool updated = false;
auto resolver = [&](std::uint32_t path_id) -> llvm::SmallVector<std::uint32_t> {
if(path_id == 1) {
// Initially depends on 2; after update, no deps.
return updated ? llvm::SmallVector<std::uint32_t>{}
: llvm::SmallVector<std::uint32_t>{2};
}
return {};
};
graph.emplace(tracking_dispatch(compiled), std::move(resolver));
execute([&]() -> kota::task<> {
// First compile: 1 -> {2}.
co_await graph->compile(1).catch_cancel();
EXPECT_FALSE(graph->is_dirty(1));
// Update 1: resets resolved, removes dep on 2.
updated = true;
graph->update(1);
// Recompile: 1 has no deps now.
co_await graph->compile(1).catch_cancel();
EXPECT_FALSE(graph->is_dirty(1));
// Now update 2: should NOT cascade to 1 (back-edge was removed).
graph->update(2);
EXPECT_TRUE(graph->is_dirty(2));
EXPECT_FALSE(graph->is_dirty(1));
});
}
TEST_CASE(DiamondUpdateCascade) {
// Diamond: 1 -> {2, 3}, 2 -> 4, 3 -> 4.
graph.emplace(tracking_dispatch(compiled),
static_resolver({
{1, {2, 3}},
{2, {4} },
{3, {4} }
}));
execute([&]() -> kota::task<> {
co_await graph->compile(1).catch_cancel();
EXPECT_FALSE(graph->is_dirty(1));
EXPECT_FALSE(graph->is_dirty(4));
// Update leaf 4: should cascade to 2, 3, and 1.
graph->update(4);
EXPECT_TRUE(graph->is_dirty(4));
EXPECT_TRUE(graph->is_dirty(2));
EXPECT_TRUE(graph->is_dirty(3));
EXPECT_TRUE(graph->is_dirty(1));
compiled.clear();
auto result = co_await graph->compile(1).catch_cancel();
EXPECT_TRUE(result.has_value() && *result);
// Unit 4 should still be compiled exactly once (dedup on recompile).
auto count4 = ranges::count(compiled, 4u);
EXPECT_EQ(count4, 1);
});
}
TEST_CASE(UpdateReturnsAllDirtied) {
// Chain: 1 -> 2 -> 3.
graph.emplace(instant_dispatch(),
static_resolver({
{1, {2}},
{2, {3}}
}));
execute([&]() -> kota::task<> {
co_await graph->compile(1).catch_cancel();
auto dirtied = graph->update(3);
// Should return 3, 2, 1 (all dirtied nodes).
EXPECT_EQ(dirtied.size(), 3u);
EXPECT_TRUE(llvm::find(dirtied, 1u) != dirtied.end());
EXPECT_TRUE(llvm::find(dirtied, 2u) != dirtied.end());
EXPECT_TRUE(llvm::find(dirtied, 3u) != dirtied.end());
});
}
TEST_CASE(HasUnitAndIsCompiling) {
graph.emplace(instant_dispatch(), no_deps());
execute([&]() -> kota::task<> {
EXPECT_FALSE(graph->has_unit(1));
EXPECT_FALSE(graph->is_compiling(1));
co_await graph->compile(1).catch_cancel();
EXPECT_TRUE(graph->has_unit(1));
EXPECT_FALSE(graph->is_compiling(1));
});
}
TEST_CASE(FailureLeavesDepsDirty) {
// 1 -> 2. Dispatch always fails.
graph.emplace(failing_dispatch(),
static_resolver({
{1, {2}}
}));
execute([&]() -> kota::task<> {
auto result = co_await graph->compile(1).catch_cancel();
EXPECT_TRUE(result.has_value());
EXPECT_FALSE(*result);
// Both dep and self should stay dirty.
EXPECT_TRUE(graph->is_dirty(2));
EXPECT_TRUE(graph->is_dirty(1));
});
}
TEST_CASE(SelfLoop) {
// Unit 1 depends on itself.
graph.emplace(instant_dispatch(),
static_resolver({
{1, {1}}
}));
execute([&]() -> kota::task<> {
auto result = co_await graph->compile(1).catch_cancel();
// Should detect cycle and return false, not deadlock.
EXPECT_TRUE(result.has_value());
EXPECT_FALSE(*result);
});
}
TEST_CASE(CancelAllAndRecompile) {
graph.emplace(tracking_dispatch(compiled),
static_resolver({
{1, {2}}
}));
execute([&]() -> kota::task<> {
co_await graph->compile(1).catch_cancel();
EXPECT_EQ(compiled.size(), 2u);
EXPECT_FALSE(graph->is_dirty(1));
EXPECT_FALSE(graph->is_dirty(2));
// cancel_all + update to mark dirty again.
graph->cancel_all();
graph->update(2);
EXPECT_TRUE(graph->is_dirty(2));
EXPECT_TRUE(graph->is_dirty(1));
// Recompile should succeed normally.
auto result = co_await graph->compile(1).catch_cancel();
EXPECT_TRUE(result.has_value());
EXPECT_TRUE(*result);
EXPECT_EQ(compiled.size(), 4u);
EXPECT_FALSE(graph->is_dirty(1));
EXPECT_FALSE(graph->is_dirty(2));
});
}
TEST_CASE(UpdateDuringCompile) {
kota::event_loop loop;
kota::event gate;
auto gated_dispatch = [&gate](std::uint32_t) -> kota::task<bool> {
co_await gate.wait();
co_return true;
};
graph.emplace(std::move(gated_dispatch), no_deps());
bool compile_done = false;
bool was_cancelled = false;
// Coroutine 1: compile(1), will suspend inside dispatch waiting on gate.
auto compiler = [&]() -> kota::task<> {
auto result = co_await graph->compile(1).catch_cancel();
compile_done = true;
was_cancelled = !result.has_value();
};
// Coroutine 2: update(1) while dispatch is in flight, then unblock gate.
auto updater = [&]() -> kota::task<> {
graph->update(1);
gate.set();
co_return;
};
auto t1 = compiler();
auto t2 = updater();
loop.schedule(t1);
loop.schedule(t2);
loop.run();
// update() cancelled the source, so compile should have been cancelled.
EXPECT_TRUE(compile_done);
EXPECT_TRUE(was_cancelled);
EXPECT_TRUE(graph->is_dirty(1));
}
TEST_CASE(WhenAllPartialFailure) {
// 1 -> {2, 3}. Only unit 3 fails.
graph.emplace(selective_dispatch({
3
}),
static_resolver({{1, {2, 3}}}));
execute([&]() -> kota::task<> {
auto result = co_await graph->compile(1).catch_cancel();
EXPECT_TRUE(result.has_value());
EXPECT_FALSE(*result);
// Unit 2 succeeded — should be clean.
EXPECT_FALSE(graph->is_dirty(2));
// Unit 3 failed — stays dirty.
EXPECT_TRUE(graph->is_dirty(3));
// Unit 1 was not dispatched — stays dirty.
EXPECT_TRUE(graph->is_dirty(1));
});
}
TEST_CASE(UpdateUnknownPathId) {
graph.emplace(instant_dispatch(), no_deps());
// update on a path_id that was never compiled should not crash.
auto dirtied = graph->update(999);
EXPECT_EQ(dirtied.size(), 0u);
EXPECT_FALSE(graph->has_unit(999));
}
TEST_CASE(EmptyGraphNoCompile) {
// Construct and destroy without any compile calls.
graph.emplace(instant_dispatch(), no_deps());
EXPECT_FALSE(graph->has_unit(1));
graph->cancel_all(); // Should not crash on empty graph.
}
TEST_CASE(CompileDepsNoDeps) {
graph.emplace(tracking_dispatch(compiled), no_deps());
execute([&]() -> kota::task<> {
auto result = co_await graph->compile_deps(1).catch_cancel();
EXPECT_TRUE(result.has_value());
EXPECT_TRUE(*result);
// No dependencies, so nothing should be dispatched.
EXPECT_EQ(compiled.size(), 0u);
});
}
TEST_CASE(CompileDepsWithDependency) {
// Unit 1 depends on unit 2.
graph.emplace(tracking_dispatch(compiled),
static_resolver({
{1, {2}}
}));
execute([&]() -> kota::task<> {
auto result = co_await graph->compile_deps(1).catch_cancel();
EXPECT_TRUE(result.has_value());
EXPECT_TRUE(*result);
// Only dep 2 should be compiled, NOT unit 1 itself.
EXPECT_EQ(compiled.size(), 1u);
EXPECT_EQ(compiled[0], 2u);
auto pos1 = ranges::find(compiled, 1u);
EXPECT_TRUE(pos1 == compiled.end());
});
}
TEST_CASE(CompileDepsChain) {
// Chain: 1 -> 2 -> 3.
graph.emplace(tracking_dispatch(compiled),
static_resolver({
{1, {2}},
{2, {3}}
}));
execute([&]() -> kota::task<> {
auto result = co_await graph->compile_deps(1).catch_cancel();
EXPECT_TRUE(result.has_value());
EXPECT_TRUE(*result);
// Deps 2 and 3 should be compiled, but NOT unit 1.
EXPECT_EQ(compiled.size(), 2u);
EXPECT_TRUE(ranges::find(compiled, 3u) != compiled.end());
EXPECT_TRUE(ranges::find(compiled, 2u) != compiled.end());
EXPECT_TRUE(ranges::find(compiled, 1u) == compiled.end());
});
}
TEST_CASE(CompileDepsDiamond) {
// Diamond: 1 -> {2, 3}, 2 -> 4, 3 -> 4.
graph.emplace(tracking_dispatch(compiled),
static_resolver({
{1, {2, 3}},
{2, {4} },
{3, {4} }
}));
execute([&]() -> kota::task<> {
auto result = co_await graph->compile_deps(1).catch_cancel();
EXPECT_TRUE(result.has_value());
EXPECT_TRUE(*result);
// Deps 2, 3, 4 should be compiled, but NOT unit 1.
EXPECT_TRUE(ranges::find(compiled, 1u) == compiled.end());
EXPECT_TRUE(ranges::find(compiled, 2u) != compiled.end());
EXPECT_TRUE(ranges::find(compiled, 3u) != compiled.end());
EXPECT_TRUE(ranges::find(compiled, 4u) != compiled.end());
// Unit 4 should be compiled exactly once (dedup).
auto count4 = ranges::count(compiled, 4u);
EXPECT_EQ(count4, 1);
});
}
TEST_CASE(CompileDepsFailure) {
// 1 -> 2. Dispatch fails for unit 2.
auto fail_and_track = [&](std::uint32_t path_id) -> kota::task<bool> {
compiled.push_back(path_id);
co_return false;
};
graph.emplace(std::move(fail_and_track),
static_resolver({
{1, {2}}
}));
execute([&]() -> kota::task<> {
auto result = co_await graph->compile_deps(1).catch_cancel();
EXPECT_TRUE(result.has_value());
EXPECT_FALSE(*result);
// Unit 1 should NOT be dispatched at all.
EXPECT_TRUE(ranges::find(compiled, 1u) == compiled.end());
});
}
TEST_CASE(CompileDepsPlainCpp) {
// Simulates a plain .cpp file (unit 10) that imports a module (unit 20).
graph.emplace(tracking_dispatch(compiled),
static_resolver({
{10, {20}}
}));
execute([&]() -> kota::task<> {
auto result = co_await graph->compile_deps(10).catch_cancel();
EXPECT_TRUE(result.has_value());
EXPECT_TRUE(*result);
// Only dep 20 should be compiled, NOT the .cpp file itself.
EXPECT_EQ(compiled.size(), 1u);
EXPECT_EQ(compiled[0], 20u);
EXPECT_TRUE(ranges::find(compiled, 10u) == compiled.end());
});
}
TEST_CASE(CompileDepsConcurrentDedup) {
// Two concurrent compile_deps calls with overlapping dependencies.
// Each dep should be dispatched exactly once (no duplicate compilation).
// Unit 1 depends on {3, 4}, unit 2 depends on {3, 5}.
// Dep 3 is shared — must be compiled only once.
graph.emplace(tracking_dispatch(compiled),
static_resolver({
{1, {3, 4}},
{2, {3, 5}},
}));
execute([&]() -> kota::task<> {
// Launch both compile_deps concurrently.
auto t1 = graph->compile_deps(1);
auto t2 = graph->compile_deps(2);
auto results = co_await kota::when_all(std::move(t1), std::move(t2));
auto [r1, r2] = results;
EXPECT_TRUE(r1);
EXPECT_TRUE(r2);
// Deps 3, 4, 5 should each be compiled exactly once.
// Unit 1 and 2 should NOT be compiled.
ranges::sort(compiled);
EXPECT_EQ(compiled.size(), 3u);
EXPECT_EQ(compiled[0], 3u);
EXPECT_EQ(compiled[1], 4u);
EXPECT_EQ(compiled[2], 5u);
});
}
TEST_CASE(CompileDepsResolveOnce) {
// Verify that resolve_fn is called at most once per unit,
// even when multiple compile_deps requests touch the same dependency.
int resolve_count = 0;
auto resolve = [&resolve_count](std::uint32_t path_id) -> llvm::SmallVector<std::uint32_t> {
resolve_count++;
if(path_id == 1 || path_id == 2)
return {3};
return {};
};
graph.emplace(tracking_dispatch(compiled), std::move(resolve));
execute([&]() -> kota::task<> {
auto t1 = graph->compile_deps(1);
auto t2 = graph->compile_deps(2);
auto results = co_await kota::when_all(std::move(t1), std::move(t2));
auto [r1, r2] = results;
EXPECT_TRUE(r1);
EXPECT_TRUE(r2);
// Dep 3 compiled exactly once.
EXPECT_EQ(compiled.size(), 1u);
EXPECT_EQ(compiled[0], 3u);
// resolve_fn called for units 1, 2, 3 — each at most once (3 total).
EXPECT_EQ(resolve_count, 3);
});
}
}; // TEST_SUITE(CompileGraph)
} // namespace
} // namespace clice::testing
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