Working-set figure: right panel = W(t) time series

Replace the (redundant) nodes-vs-T cost curve with the working-set
W(t) over wall-clock time for T=2/30/300s. Shows footprint is steady
(peak ~ median) after a short warm-up, so peak-based sizing is sound;
the 300s curve hugs the 14-node ceiling throughout.

Co-Authored-By: Claude Opus 4.7 <noreply@anthropic.com>
This commit is contained in:
2026-05-28 16:31:26 +08:00
parent c94b2e237a
commit 2247d1de08
2 changed files with 30 additions and 24 deletions

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@@ -105,8 +105,10 @@ def _series(starts, ends, grid):
return np.searchsorted(s, grid, side="right") - np.searchsorted(e, grid, side="right")
def compute_working_set(ids, ts, taus):
"""Return dict with appearance stats + per-tau Denning peaks + oracle/all."""
def compute_working_set(ids, ts, taus, series_taus=()):
"""Return dict with appearance stats + per-tau Denning peaks + oracle/all.
For each T in series_taus, also return the full W(t) time series on `grid`."""
A = len(ids)
order = np.lexsort((ts, ids))
ids_s, ts_s = ids[order], ts[order]
@@ -127,6 +129,7 @@ def compute_working_set(ids, ts, taus):
oracle_peak = _sweep_peak(first[seen], last[seen])
rows = []
series = {}
for T in taus:
enter = ts_s[prev_gap > T]
exit_ = ts_s[next_gap > T] + T
@@ -138,11 +141,15 @@ def compute_working_set(ids, ts, taus):
"p50_blocks": float(np.percentile(ser, 50)),
"apc": float((prev_gap <= T).sum() / A),
})
if T in series_taus:
series[T] = ser
return {
"A": A, "n_unique": n_unique, "n_reuse": A - n_unique,
"apc_ceiling": (A - n_unique) / A,
"oracle_peak_blocks": oracle_peak,
"span": float(ts.max() - ts.min()),
"grid_s": grid - grid.min(),
"series": series,
"taus": rows,
}
@@ -200,28 +207,26 @@ def plot(ws, hw, block_bytes, label, out_path):
ax1.set_title("Benefit vs cost: APC per cluster size", fontweight="bold")
ax1.grid(alpha=.3); ax1.grid(alpha=.15, which="minor"); ax1.legend(loc="center right")
# ===== panel 2: cost -- nodes needed to retain T seconds of reuse =====
ax2.plot(tau, nodes, "s-", color="#1f77b4", lw=2, ms=7, zorder=4)
ax2.axhline(1, ls="--", color="#2ca02c", lw=1.8, label="1 node (your budget)")
ax2.axhline(oracle_nodes, ls=":", color="#d62728", lw=1.8,
label=f"full ceiling = {oracle_nodes:.0f} nodes")
# where the curve crosses the 1-node budget
tau_at_1 = float(np.interp(1.0, nodes, tau))
ax2.scatter([tau_at_1], [1], s=90, facecolors="none", edgecolors="#ff7f0e", lw=2, zorder=6)
ax2.annotate(f"1 node only retains\n~{tau_at_1:.0f}s of reuse", (tau_at_1, 1),
textcoords="offset points", xytext=(8, 14), fontsize=9, color="#ff7f0e")
for r, x, y in zip(rows, tau, nodes):
if y >= 1.5:
ax2.annotate(f"{r['tau']:g}s", (x, y), textcoords="offset points",
xytext=(4, 5), fontsize=8.5)
ax2.set_xscale("log")
ax2.set_xticks([1, 2, 5, 10, 30, 60, 300])
ax2.set_xticklabels(["1s", "2s", "5s", "10s", "30s", "60s", "300s"])
# ===== panel 2: working set W(t) over time (steady -> peak ~ median) =====
apc_of = {r["tau"]: r["apc"] * 100 for r in ws["taus"]}
t_min = ws["grid_s"] / 60.0 # minutes
colors = {2: "#2ca02c", 30: "#ff7f0e", 300: "#1f77b4"}
for T, ser in sorted(ws["series"].items()):
y = ser * bgb / pool
c = colors.get(T, "#777")
ax2.plot(t_min, y, lw=1.8, color=c, label=f"keep {T:g}s reuse (APC {apc_of[T]:.0f}%)")
ax2.axhline(float(np.median(y)), ls=":", color=c, alpha=.6, lw=1)
ax2.axhline(1, ls="--", color="#2ca02c", lw=1.6, alpha=.8)
ax2.text(t_min.max(), 1, " 1-node budget", color="#2ca02c", fontsize=8.5, va="center")
ax2.axhline(oracle_nodes, ls="--", color="#d62728", lw=1.6, alpha=.8)
ax2.text(t_min.max(), oracle_nodes, " ceiling: 14 nodes", color="#d62728",
fontsize=8.5, va="center")
ax2.set_ylim(0, XMAX); ax2.set_yticks(range(0, XMAX + 1, 2))
ax2.set_xlabel("retention window T (how long-idle a session's KV we keep)")
ax2.set_ylabel("# nodes of GPU HBM needed")
ax2.set_title("Cost: nodes needed to retain T-seconds of reuse", fontweight="bold")
ax2.grid(alpha=.3, which="both"); ax2.legend(loc="upper left", fontsize=9)
ax2.set_xlim(0, t_min.max())
ax2.set_xlabel("wall-clock time into the trace (min)")
ax2.set_ylabel("# nodes of GPU HBM resident (W(t))")
ax2.set_title("Working set over time (flat -> peak ~ median)", fontweight="bold")
ax2.grid(alpha=.3); ax2.legend(loc="center right", fontsize=9)
fig.suptitle(label, fontsize=13, fontweight="bold")
fig.tight_layout(rect=[0, 0, 1, 0.97])
@@ -258,8 +263,9 @@ def main():
hw = {"gpus_per_replica": gpus_per_replica, "kv_pool_gb": kv_pool_gb, "gpu": a.gpu}
taus = [1, 2, 5, 10, 30, 60, 300, 600, 1800]
series_taus = [2, 30, 300] # W(t) lines drawn in panel 2
n, ids, ts = load_trace(a.trace, a.min_ts, a.max_ts)
ws = compute_working_set(ids, ts, taus)
ws = compute_working_set(ids, ts, taus, series_taus)
label = a.label or f"{model['name']} {a.gpu} TP{a.tp}" + (f" EP{a.ep}" if a.ep else "")
print("=" * 84)