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kernbench2/tests/test_data_executor.py
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ywkang 51004c311c Implement ADR-0020: 2-pass data execution with greenlet kernel runner 
Step 1 — Foundation:
- OpRecord/OpLogger: op log infrastructure with t_start stable ordering
- MemoryStore: numpy ndarray tensor-granular storage (reference semantics)
- data_op=True flag on DmaReadCmd, DmaWriteCmd, GemmCmd, MathCmd, CompositeCmd
- numpy/greenlet dependencies added to pyproject.toml

Step 2 — ComponentBase hooks:
- _on_process_start/end hooks in _forward_txn (fabric messages)
- _handle_with_hooks in PeEngineBase (PE-internal commands)
- op_logger optional — zero overhead when disabled

Step 3 — KernelRunner + greenlet:
- KernelRunner: greenlet ↔ SimPy bridge in triton_emu/kernel_runner.py
- TLContext: _emit() method routes to greenlet switch or command list
- tl.load() returns real numpy data in greenlet mode
- Dynamic control flow supported (memory-read based branching)

Step 4 — PE_CPU integration:
- Greenlet mode when ctx.memory_store is set, legacy fallback otherwise
- Refactored into _execute_greenlet/_execute_legacy/_send_response
- ComponentContext gains memory_store and op_logger fields

Step 5 — DataExecutor:
- Phase 2 numpy execution for GEMM/Math ops from op_log
- _compute_math: all unary/binary/reduction ops
- verify(): compare MemoryStore against expected with dtype tolerance

28 new tests, 366 total passing.

Co-Authored-By: Claude Opus 4.6 (1M context) <noreply@anthropic.com>
2026-04-08 00:22:44 -07:00

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"""Tests for DataExecutor Phase 2 execution (ADR-0020 D6)."""
import numpy as np
from kernbench.sim_engine.data_executor import DataExecutor
from kernbench.sim_engine.memory_store import MemoryStore
from kernbench.sim_engine.op_log import OpRecord
def test_gemm_execution():
"""Phase 2 GEMM: out = a @ b with f32 accumulation."""
store = MemoryStore()
a = np.ones((4, 8), dtype=np.float16)
b = np.ones((8, 4), dtype=np.float16) * 2.0
store.write("tcm", 0x0, a)
store.write("tcm", 0x100, b)
op = OpRecord(
t_start=0.0, t_end=100.0,
component_id="pe_gemm",
op_kind="gemm", op_name="gemm_f16",
params={
"src_a_addr": 0x0, "src_b_addr": 0x100, "dst_addr": 0x200,
"shape_a": (4, 8), "shape_b": (8, 4), "shape_out": (4, 4),
"dtype_in": "f16", "dtype_acc": "f32", "dtype_out": "f16",
"addr_space": "tcm",
},
)
executor = DataExecutor([op], store)
executor.run()
result = store.read("tcm", 0x200)
expected = (a.astype(np.float32) @ b.astype(np.float32)).astype(np.float16)
assert np.allclose(result, expected)
def test_math_exp():
store = MemoryStore()
x = np.array([0.0, 1.0, 2.0], dtype=np.float32)
store.write("tcm", 0x0, x)
op = OpRecord(
t_start=0.0, t_end=10.0,
component_id="pe_math",
op_kind="math", op_name="exp",
params={
"op": "exp",
"input_addrs": [0x0], "input_shapes": [(3,)],
"dst_addr": 0x100, "shape_out": (3,),
"dtype": "f32", "axis": None, "addr_space": "tcm",
},
)
executor = DataExecutor([op], store)
executor.run()
result = store.read("tcm", 0x100)
assert np.allclose(result, np.exp(x))
def test_math_add():
store = MemoryStore()
a = np.array([1.0, 2.0], dtype=np.float32)
b = np.array([3.0, 4.0], dtype=np.float32)
store.write("tcm", 0x0, a)
store.write("tcm", 0x100, b)
op = OpRecord(
t_start=0.0, t_end=5.0,
component_id="pe_math",
op_kind="math", op_name="add",
params={
"op": "add",
"input_addrs": [0x0, 0x100], "input_shapes": [(2,), (2,)],
"dst_addr": 0x200, "shape_out": (2,),
"dtype": "f32", "axis": None, "addr_space": "tcm",
},
)
executor = DataExecutor([op], store)
executor.run()
result = store.read("tcm", 0x200)
assert np.array_equal(result, np.array([4.0, 6.0], dtype=np.float32))
def test_math_sum_reduction():
store = MemoryStore()
x = np.array([[1.0, 2.0], [3.0, 4.0]], dtype=np.float32)
store.write("tcm", 0x0, x)
op = OpRecord(
t_start=0.0, t_end=5.0,
component_id="pe_math",
op_kind="math", op_name="sum",
params={
"op": "sum",
"input_addrs": [0x0], "input_shapes": [(2, 2)],
"dst_addr": 0x100, "shape_out": (1, 2),
"dtype": "f32", "axis": 0, "addr_space": "tcm",
},
)
executor = DataExecutor([op], store)
executor.run()
result = store.read("tcm", 0x100)
assert np.array_equal(result, np.array([[4.0, 6.0]], dtype=np.float32))
def test_verify_pass():
store = MemoryStore()
store.write("hbm", 0x0, np.array([1.0, 2.0], dtype=np.float32))
executor = DataExecutor([], store)
results = executor.verify({
("hbm", 0x0): np.array([1.0, 2.0], dtype=np.float32),
})
assert results["hbm:0x0"] is True
def test_verify_fail():
store = MemoryStore()
store.write("hbm", 0x0, np.array([1.0, 2.0], dtype=np.float32))
executor = DataExecutor([], store)
results = executor.verify({
("hbm", 0x0): np.array([9.0, 9.0], dtype=np.float32),
})
assert results["hbm:0x0"] is False
def test_memory_ops_skipped():
"""Memory ops in op_log should be skipped (handled in Phase 1)."""
store = MemoryStore()
op = OpRecord(
t_start=0.0, t_end=5.0,
component_id="pe_dma",
op_kind="memory", op_name="dma_read",
params={"src_addr": 0x0, "nbytes": 64, "handle_id": "t0"},
)
# Should not raise
executor = DataExecutor([op], store)
executor.run()
def test_sequential_gemm_then_math():
"""GEMM output feeds into math op."""
store = MemoryStore()
a = np.eye(2, dtype=np.float16)
b = np.ones((2, 2), dtype=np.float16)
store.write("tcm", 0x0, a)
store.write("tcm", 0x100, b)
ops = [
OpRecord(
t_start=0.0, t_end=50.0,
component_id="pe_gemm",
op_kind="gemm", op_name="gemm_f16",
params={
"src_a_addr": 0x0, "src_b_addr": 0x100, "dst_addr": 0x200,
"shape_a": (2, 2), "shape_b": (2, 2), "shape_out": (2, 2),
"dtype_in": "f16", "dtype_acc": "f32", "dtype_out": "f32",
"addr_space": "tcm",
},
),
OpRecord(
t_start=50.0, t_end=55.0,
component_id="pe_math",
op_kind="math", op_name="exp",
params={
"op": "exp",
"input_addrs": [0x200], "input_shapes": [(2, 2)],
"dst_addr": 0x300, "shape_out": (2, 2),
"dtype": "f32", "axis": None, "addr_space": "tcm",
},
),
]
executor = DataExecutor(ops, store)
executor.run()
gemm_result = store.read("tcm", 0x200)
expected_gemm = (a.astype(np.float32) @ b.astype(np.float32)).astype(np.float32)
assert np.allclose(gemm_result, expected_gemm)
exp_result = store.read("tcm", 0x300)
assert np.allclose(exp_result, np.exp(expected_gemm))
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