Files
sglang/test
leavelet 9368c33b23 L2 prereqs for CP8DP2 + L3: scope HiCache consensus to the CP group + reset pooled allocator on flush
Two latent CP shared-KV L2 correctness fixes, landed BEFORE L3 (not in an L3
commit). Surfaced by a per-CP8-instance (CP8DP2EP16) scoping review.

PREREQ-1 (CP-group scoping). The B1 commit/evict consensus collectives
(writing_check ReduceOp.MIN, placement_digest MIN/MAX + its tp_world_size<=1
entry guard, drain_storage_control_queues, the evict/prefetch MINs, the flush
barrier) AND cache_controller.prefetch_tp_group all derive from
self.tp_group/self.tp_world_size, which was params.tp_cache_group. tp_cache_group
equals the CP group ONLY at dp_size=1 (enable_dp_attention False -> tp_cpu_group,
and attn_cp_size==tp_size -> _ATTN_CP==_TP) -- the sole reason B1 works today.
Under CP8DP2 (DP attention, attn_tp_size=1) tp_cache_group is the size-1 attn-TP
group, so every `tp_world_size>1` collective silently no-ops per rank and the
placement assert self-disables -> divergent placement -> shared-slab corruption.
Fix: for CP hicache (cp_size>1) scope self.tp_group to the CP cpu group
(get_attention_cp_group().cpu_group -- already used for the slab-handle
broadcast) + self.tp_world_size to its size. A no-op handle change at dp_size=1
(same group object); the intended fix at CP8DP2. The single init-point change
propagates to every consensus collective + un-gates prefetch_tp_group + re-enables
the placement assert.

PREREQ-2 (flush reset). HiRadixCache.reset() cleared the radix tree + host pool
but never reset CpSharedL2PageAllocator -> stale free list/ranges/committed after
flush_cache (leak; the shared pool was never reclaimed). Added
CpSharedL2PageAllocator.reset() (rebuild the per-slab free list all-free, drop
ranges + committed, restore the freshly-built placement_digest) called from
cache_controller.reset() after the ack queues are cleared. Safe: flush_cache is
idle-gated (no in-flight backup/reserve). This is also L3's clear hookpoint.

Validation: new test_reset_restores_freshly_constructed_all_free_state + 89/89
pool suite (torch-2.11 container) + import smoke. PREREQ-1 is a no-op at dp_size=1
(live no-regression confirmed on the next prefill restart); CP8DP2 correctness is
by construction (CP-group membership verified) pending a 2-machine run.

Co-Authored-By: Claude Opus 4.8 (1M context) <noreply@anthropic.com>
2026-06-20 21:25:34 +00:00
..

Run Unit Tests

SGLang uses the built-in library unittest as the testing framework.

Test Backend Runtime

cd sglang/test/srt

# Run a single file
python3 test_srt_endpoint.py

# Run a single test
python3 test_srt_endpoint.py TestSRTEndpoint.test_simple_decode

# Run a suite with multiple files
python3 run_suite.py --suite per-commit

Test Frontend Language

cd sglang/test/lang

# Run a single file
python3 test_choices.py

Adding or Updating Tests in CI

  • Create new test files under test/srt or test/lang depending on the type of test.
  • For nightly tests, place them in test/srt/nightly/. Use the NightlyBenchmarkRunner helper class in nightly_utils.py for performance benchmarking tests.
  • Ensure they are referenced in the respective run_suite.py (e.g., test/srt/run_suite.py) so they are picked up in CI. For most small test cases, they can be added to the per-commit-1-gpu suite. Sort the test cases alphabetically by name.
  • Ensure you added unittest.main() for unittest and sys.exit(pytest.main([__file__])) for pytest in the scripts. The CI run them via python3 test_file.py.
  • The CI will run some suites such as per-commit-1-gpu, per-commit-2-gpu, and nightly-1-gpu automatically. If you need special setup or custom test groups, you may modify the workflows in .github/workflows/.

CI Registry System

Tests in test/registered/ use a registry-based CI system for flexible backend/schedule configuration.

Registration Functions

from sglang.test.ci.ci_register import (
    register_cuda_ci,
    register_amd_ci,
    register_cpu_ci,
    register_npu_ci,
)

# Per-commit test (small 1-gpu, runs on 5090)
register_cuda_ci(est_time=80, suite="stage-b-test-1-gpu-small")

# Per-commit test (large 1-gpu, runs on H100)
register_cuda_ci(est_time=120, suite="stage-b-test-1-gpu-large")

# Per-commit test (2-gpu)
register_cuda_ci(est_time=200, suite="stage-b-test-2-gpu-large")

# Nightly-only test
register_cuda_ci(est_time=200, suite="nightly-1-gpu", nightly=True)

# Multi-backend test
register_cuda_ci(est_time=80, suite="stage-b-test-1-gpu-small")
register_amd_ci(est_time=120, suite="stage-a-test-1-gpu-small-amd")

# Temporarily disabled test
register_cuda_ci(est_time=80, suite="stage-b-test-1-gpu-small", disabled="flaky - see #12345")

Choosing Between 1-GPU Suites (5090 vs H100)

When adding 1-GPU tests, choose the appropriate suite based on hardware compatibility:

Suite Runner GPU When to Use
stage-a-test-1-gpu-small 1-gpu-5090 RTX 5090 (32GB, SM120) Stage A per-commit smoke on 5090 (CUDA)
stage-a-test-1-gpu-small-amd AMD CI runners ROCm Stage A per-commit smoke (AMD)
stage-b-test-1-gpu-small 1-gpu-5090 RTX 5090 (32GB, SM120) 5090-compatible tests (preferred)
stage-b-test-1-gpu-large 1-gpu-h100 H100 (80GB, SM90) Large models or 5090-incompatible tests

Use stage-b-test-1-gpu-small (5090) whenever possible - this is the preferred suite for most 1-GPU tests.

Use stage-b-test-1-gpu-large (H100) if ANY of these apply:

  1. Architecture incompatibility (SM120/Blackwell):

    • FA3 attention backend (requires SM≤90)
    • MLA with FA3 backend
    • FP8/MXFP4 quantization (not supported on SM120)
    • Certain Triton kernels (shared memory limits)
  2. Memory requirements:

    • Models >30B params or large MoE
    • Tests requiring >32GB VRAM
  3. Known 5090 failures:

    • Weight update/sync tests
    • Certain spec decoding tests

If a test cannot run on 5090 due to any of the above, use stage-b-test-1-gpu-large which runs on H100.

Available Suites

Per-Commit (CUDA):

  • Stage A: stage-a-test-1-gpu-small (5090), stage-a-test-2, stage-a-test-cpu
  • Stage B: stage-b-test-1-gpu-small (5090), stage-b-test-1-gpu-large (H100), stage-b-test-2-gpu-large
  • Stage C (4-GPU): stage-c-test-4-gpu-h100, stage-c-test-4-gpu-b200, stage-c-test-4-gpu-gb200, stage-c-test-deepep-4-gpu-h100
  • Stage C (8-GPU): stage-c-test-8-gpu-h20, stage-c-test-8-gpu-h200, stage-c-test-8-gpu-b200, stage-c-test-deepep-8-gpu-h200

Per-Commit (AMD):

  • stage-a-test-1-gpu-small-amd, stage-b-test-1-gpu-small-amd, stage-b-test-2-gpu-large-amd

Nightly:

  • nightly-1-gpu, nightly-2-gpu, nightly-4-gpu, nightly-8-gpu, etc.

Running Tests with run_suite.py

# Run per-commit tests
python test/run_suite.py --hw cuda --suite stage-b-test-1-gpu-small

# Run nightly tests
python test/run_suite.py --hw cuda --suite nightly-1-gpu --nightly

# With auto-partitioning (for parallel CI jobs)
python test/run_suite.py --hw cuda --suite stage-b-test-1-gpu-small \
    --auto-partition-id 0 --auto-partition-size 4

Writing Elegant Test Cases

  • Learn from existing examples in sglang/test/srt.
  • Reduce the test time by using smaller models and reusing the server for multiple test cases. Launching a server takes a lot of time.
  • Use as few GPUs as possible. Do not run long tests with 8-gpu runners.
  • If the test cases take too long, considering adding them to nightly tests instead of per-commit tests.
  • Keep each test function focused on a single scenario or piece of functionality.
  • Give tests descriptive names reflecting their purpose.
  • Use robust assertions (e.g., assert, unittest methods) to validate outcomes.
  • Clean up resources to avoid side effects and preserve test independence.
  • Reduce the test time by using smaller models and reusing the server for multiple test cases.

Adding New Models to Nightly CI

  • For text models: extend global model lists variables in test_utils.py, or add more model lists
  • For vlms: extend the MODEL_THRESHOLDS global dictionary in test/srt/nightly/test_vlms_mmmu_eval.py