Resource Utilization

CPU, memory, disk I/O, and network throughput analysis for PQ Devnet clients.

This notebook examines container-level resource usage using cAdvisor metrics:

  • CPU usage (cores) per client
  • Memory working set and RSS per client
  • Disk read/write throughput
  • Disk usage over time
  • Network receive/transmit throughput
Show code
import json
from pathlib import Path

import pandas as pd
import plotly.express as px
import plotly.graph_objects as go
from plotly.subplots import make_subplots
from IPython.display import HTML, display

# Set default renderer for static HTML output
import plotly.io as pio
pio.renderers.default = "notebook"
Show code
# Resolve devnet_id
DATA_DIR = Path("../data")

if devnet_id is None:
    # Use latest devnet from manifest
    devnets_path = DATA_DIR / "devnets.json"
    if devnets_path.exists():
        with open(devnets_path) as f:
            devnets = json.load(f).get("devnets", [])
        if devnets:
            devnet_id = devnets[-1]["id"]  # Latest
            print(f"Using latest devnet: {devnet_id}")
    else:
        raise ValueError("No devnets.json found. Run 'just detect-devnets' first.")

DEVNET_DIR = DATA_DIR / devnet_id
print(f"Loading data from: {DEVNET_DIR}")
Loading data from: ../data/pqdevnet-20260701T1125Z
Show code
# Load devnet metadata
with open(DATA_DIR / "devnets.json") as f:
    devnets_data = json.load(f)
    devnet_info = next((d for d in devnets_data["devnets"] if d["id"] == devnet_id), None)

if devnet_info:
    print(f"Devnet: {devnet_info['id']}")
    print(f"Duration: {devnet_info['duration_hours']:.1f} hours")
    print(f"Time: {devnet_info['start_time']} to {devnet_info['end_time']}")
    print(f"Slots: {devnet_info['start_slot']} \u2192 {devnet_info['end_slot']}")
    print(f"Clients: {', '.join(devnet_info['clients'])}")
Devnet: pqdevnet-20260701T1125Z
Duration: 0.7 hours
Time: 2026-07-01T11:25:00+00:00 to 2026-07-01T12:09:21+00:00
Slots: 0 β†’ 16917
Clients: buildx_buildkit_multiarch0, ethlambda_0, ethlambda_1, ethlambda_10, ethlambda_2, ethlambda_3, ethlambda_4, ethlambda_5, ethlambda_6, ethlambda_7, ethlambda_8, ethlambda_9, gean_0, gean_1, gean_2, gean_3, grandine_0, grandine_1, grandine_2, grandine_3, grandine_4, grandine_5, grandine_6, lantern_0, lantern_1, lantern_2, lantern_3, ream_0, ream_1, ream_2, ream_3, ream_4, ream_5, ream_6, zeam_0, zeam_1, zeam_2, zeam_4, zeam_5, zeam_6
Show code
def format_bytes(val: float) -> str:
    """Format bytes to human-readable units."""
    for unit in ["B", "KB", "MB", "GB", "TB"]:
        if abs(val) < 1024:
            return f"{val:.1f} {unit}"
        val /= 1024
    return f"{val:.1f} PB"


def format_bytes_per_sec(val: float) -> str:
    """Format bytes/s to human-readable units."""
    return format_bytes(val) + "/s"

Load DataΒΆ

Show code
# Load container resource data
data_files = {
    "cpu": "container_cpu.parquet",
    "memory": "container_memory.parquet",
    "disk_io": "container_disk_io.parquet",
    "network": "container_network.parquet",
}

# Infrastructure containers irrelevant to devnet client analysis
EXCLUDED_CONTAINERS = {"unknown", "cadvisor", "prometheus", "promtail", "node-exporter", "node_exporter", "grafana"}

# Aggregation strategy per data type:
# - cpu/memory: max (gauge-like, take the active container's value)
# - disk_io/network: sum (per-device/interface rates should be summed)
AGG_STRATEGY = {"cpu": "max", "memory": "max", "disk_io": "sum", "network": "sum"}

# Group-by columns per data type (all have container+timestamp, some have metric)
GROUP_COLS = {
    "cpu": ["container", "timestamp"],
    "memory": ["container", "metric", "timestamp"],
    "disk_io": ["container", "metric", "timestamp"],
    "network": ["container", "metric", "timestamp"],
}

dfs = {}
for key, filename in data_files.items():
    path = DEVNET_DIR / filename
    if path.exists():
        df = pd.read_parquet(path)
        df = df[~df["container"].isin(EXCLUDED_CONTAINERS)]
        # Deduplicate: multiple Prometheus series (interfaces, devices, container
        # IDs after restarts) can produce duplicate rows per container+timestamp.
        df = df.groupby(GROUP_COLS[key], as_index=False)["value"].agg(AGG_STRATEGY[key])
        dfs[key] = df
        print(f"{key}: {len(df)} records, containers: {df['container'].nunique()}")
    else:
        dfs[key] = pd.DataFrame()
        print(f"{key}: no data (file not found)")

# Unified container list: use devnet_info["clients"] which already contains
# full names with instance suffixes (e.g., "ream_0", "ream_1").
all_containers = sorted(devnet_info["clients"])
n_cols = min(len(all_containers), 2)
n_rows = -(-len(all_containers) // n_cols)
print(f"\nAll containers ({len(all_containers)}): {all_containers}")
cpu: 297 records, containers: 40
memory: 2926 records, containers: 40
disk_io: 482 records, containers: 33
network: 594 records, containers: 40

All containers (40): ['buildx_buildkit_multiarch0', 'ethlambda_0', 'ethlambda_1', 'ethlambda_10', 'ethlambda_2', 'ethlambda_3', 'ethlambda_4', 'ethlambda_5', 'ethlambda_6', 'ethlambda_7', 'ethlambda_8', 'ethlambda_9', 'gean_0', 'gean_1', 'gean_2', 'gean_3', 'grandine_0', 'grandine_1', 'grandine_2', 'grandine_3', 'grandine_4', 'grandine_5', 'grandine_6', 'lantern_0', 'lantern_1', 'lantern_2', 'lantern_3', 'ream_0', 'ream_1', 'ream_2', 'ream_3', 'ream_4', 'ream_5', 'ream_6', 'zeam_0', 'zeam_1', 'zeam_2', 'zeam_4', 'zeam_5', 'zeam_6']

CPU UsageΒΆ

CPU cores used per container over time, derived from rate(container_cpu_usage_seconds_total[5m]).

Show code
cpu_df = dfs["cpu"]

if cpu_df.empty:
    print("No CPU data available")
else:
    fig = make_subplots(
        rows=n_rows, cols=n_cols,
        subplot_titles=all_containers,
        vertical_spacing=0.12 / max(n_rows - 1, 1) * 2,
        horizontal_spacing=0.08,
    )

    for i, container in enumerate(all_containers):
        row = i // n_cols + 1
        col = i % n_cols + 1
        cdf = cpu_df[cpu_df["container"] == container].sort_values("timestamp")
        if not cdf.empty:
            fig.add_trace(
                go.Scatter(
                    x=cdf["timestamp"], y=cdf["value"],
                    name=container, showlegend=False,
                    line=dict(color="#636EFA"),
                ),
                row=row, col=col,
            )
        else:
            fig.add_trace(
                go.Scatter(x=[None], y=[None], showlegend=False, hoverinfo='skip'),
                row=row, col=col,
            )
            _n = (row - 1) * n_cols + col
            _s = "" if _n == 1 else str(_n)
            fig.add_annotation(
                text="No data available",
                xref=f"x{_s} domain", yref=f"y{_s} domain",
                x=0.5, y=0.5,
                showarrow=False,
                font=dict(size=12, color="#999"),
            )
        fig.update_yaxes(title_text="CPU (cores)", row=row, col=col)

    fig.update_layout(
        title="CPU Usage per Container",
        height=270 * n_rows,
    )
    fig.show()
Show code
# CPU summary statistics
if not cpu_df.empty:
    cpu_summary = cpu_df.groupby("container")["value"].agg(
        ["mean", "max", "min", "std"]
    ).round(3)
    cpu_summary.columns = ["Mean (cores)", "Max (cores)", "Min (cores)", "Std Dev"]
    cpu_summary = cpu_summary.sort_index()
    display(cpu_summary)
Mean (cores) Max (cores) Min (cores) Std Dev
container
buildx_buildkit_multiarch0 0.001 0.003 0.000 0.002
ethlambda_0 2.614 4.253 0.006 1.511
ethlambda_1 1.143 1.913 0.374 1.088
ethlambda_10 0.300 0.442 0.006 0.140
ethlambda_2 0.243 0.355 0.009 0.105
ethlambda_3 0.333 0.562 0.103 0.324
ethlambda_4 0.253 0.417 0.006 0.128
ethlambda_5 0.531 1.020 0.042 0.692
ethlambda_6 0.645 1.231 0.060 0.828
ethlambda_7 0.258 0.425 0.009 0.131
ethlambda_8 0.258 0.420 0.006 0.121
ethlambda_9 0.371 0.616 0.127 0.346
gean_0 3.466 4.650 0.022 1.537
gean_1 0.599 1.024 0.033 0.312
gean_2 0.351 0.671 0.004 0.196
gean_3 0.436 0.609 0.005 0.208
grandine_0 4.752 7.628 0.385 2.506
grandine_1 0.369 0.636 0.102 0.378
grandine_2 4.347 6.913 0.375 2.355
grandine_3 3.104 5.497 0.096 2.059
grandine_4 3.038 5.591 0.252 1.977
grandine_5 1.769 2.738 0.341 0.969
grandine_6 1.561 2.592 0.132 0.952
lantern_0 0.449 0.816 0.035 0.319
lantern_1 0.622 1.085 0.040 0.339
lantern_2 0.149 0.312 0.013 0.086
lantern_3 0.134 0.250 0.018 0.068
ream_0 2.884 6.634 0.011 2.249
ream_1 0.895 1.163 0.035 0.448
ream_2 0.849 1.181 0.010 0.454
ream_3 0.828 1.128 0.009 0.431
ream_4 0.862 1.180 0.012 0.453
ream_5 1.379 2.417 0.341 1.468
ream_6 0.839 1.142 0.007 0.438
zeam_0 2.192 2.823 0.426 0.856
zeam_1 2.022 2.640 0.362 0.785
zeam_2 2.681 3.527 0.476 0.991
zeam_4 1.615 2.057 0.375 0.546
zeam_5 1.543 1.850 0.343 0.493
zeam_6 1.576 1.884 0.355 0.494

Memory UsageΒΆ

Memory consumption per container, including working set (total usage minus inactive file cache) and RSS (Resident Set Size -- anonymous memory only, excluding file-backed pages). The gap between the two shows active file cache usage.

Show code
mem_df = dfs["memory"]

if mem_df.empty:
    print("No memory data available")
else:
    # Combine working_set and rss for per-container comparison
    mem_plot_df = mem_df[mem_df["metric"].isin(["working_set", "rss"])].copy()
    if not mem_plot_df.empty:
        mem_plot_df["value_mb"] = mem_plot_df["value"] / (1024 * 1024)

        fig = make_subplots(
            rows=n_rows, cols=n_cols,
            subplot_titles=all_containers,
            vertical_spacing=0.12 / max(n_rows - 1, 1) * 2,
            horizontal_spacing=0.08,
        )

        colors = {"working_set": "#636EFA", "rss": "#EF553B"}
        legend_added = set()

        for i, container in enumerate(all_containers):
            row = i // n_cols + 1
            col = i % n_cols + 1
            cdf = mem_plot_df[mem_plot_df["container"] == container]
            if not cdf.empty:
                for metric in ["working_set", "rss"]:
                    mdf = cdf[cdf["metric"] == metric].sort_values("timestamp")
                    if mdf.empty:
                        continue
                    show_legend = metric not in legend_added
                    legend_added.add(metric)
                    fig.add_trace(
                        go.Scatter(
                            x=mdf["timestamp"], y=mdf["value_mb"],
                            name=metric, legendgroup=metric,
                            showlegend=show_legend,
                            line=dict(color=colors[metric]),
                        ),
                        row=row, col=col,
                    )
            else:
                fig.add_trace(
                    go.Scatter(x=[None], y=[None], showlegend=False, hoverinfo='skip'),
                    row=row, col=col,
                )
                _n = (row - 1) * n_cols + col
                _s = "" if _n == 1 else str(_n)
                fig.add_annotation(
                    text="No data available",
                    xref=f"x{_s} domain", yref=f"y{_s} domain",
                    x=0.5, y=0.5,
                    showarrow=False,
                    font=dict(size=12, color="#999"),
                )
            fig.update_yaxes(title_text="MB", row=row, col=col)

        fig.update_layout(
            title="Memory Usage per Container (Working Set vs RSS)",
            height=270 * n_rows,
        )
        fig.show()
Show code
# Memory summary
if not mem_df.empty:
    ws_df = mem_df[mem_df["metric"] == "working_set"]
    if not ws_df.empty:
        mem_summary = ws_df.groupby("container")["value"].agg(["mean", "max"]).reset_index()
        mem_summary["Mean"] = mem_summary["mean"].apply(format_bytes)
        mem_summary["Peak"] = mem_summary["max"].apply(format_bytes)
        mem_summary = mem_summary.rename(columns={"container": "Container"})[["Container", "Mean", "Peak"]]
        mem_summary = mem_summary.sort_values("Container")
        display(mem_summary.set_index("Container"))
Mean Peak
Container
buildx_buildkit_multiarch0 646.8 MB 646.8 MB
ethlambda_0 1.1 GB 2.2 GB
ethlambda_1 1.4 GB 1.5 GB
ethlambda_10 1.1 GB 2.1 GB
ethlambda_2 1.1 GB 2.2 GB
ethlambda_3 1.2 GB 1.4 GB
ethlambda_4 1.8 GB 3.9 GB
ethlambda_5 782.9 MB 1.1 GB
ethlambda_6 854.9 MB 1.1 GB
ethlambda_7 1.0 GB 2.1 GB
ethlambda_8 1.1 GB 2.1 GB
ethlambda_9 1.1 GB 1.1 GB
gean_0 6.4 GB 9.0 GB
gean_1 2.4 GB 4.4 GB
gean_2 2.2 GB 5.0 GB
gean_3 4.5 GB 8.4 GB
grandine_0 1.8 GB 3.9 GB
grandine_1 2.2 GB 2.2 GB
grandine_2 1.7 GB 3.9 GB
grandine_3 1.1 GB 1.8 GB
grandine_4 1.2 GB 3.7 GB
grandine_5 1.2 GB 3.6 GB
grandine_6 1.1 GB 1.9 GB
lantern_0 735.2 MB 2.0 GB
lantern_1 820.5 MB 3.6 GB
lantern_2 560.1 MB 652.7 MB
lantern_3 505.0 MB 551.2 MB
ream_0 8.1 GB 14.9 GB
ream_1 4.8 GB 9.4 GB
ream_2 4.0 GB 7.7 GB
ream_3 4.2 GB 7.6 GB
ream_4 3.8 GB 7.1 GB
ream_5 4.2 GB 4.2 GB
ream_6 3.7 GB 7.4 GB
zeam_0 4.4 GB 8.1 GB
zeam_1 2.8 GB 4.5 GB
zeam_2 4.1 GB 9.2 GB
zeam_4 3.9 GB 6.9 GB
zeam_5 3.2 GB 5.6 GB
zeam_6 3.0 GB 6.1 GB

Disk I/OΒΆ

Disk read/write throughput per container.

Show code
disk_df = dfs["disk_io"]

if disk_df.empty:
    print("No disk I/O data available")
else:
    # Read/write throughput per container
    throughput_df = disk_df[disk_df["metric"].isin(["read_throughput", "write_throughput"])].copy()
    if not throughput_df.empty:
        throughput_df["value_mb"] = throughput_df["value"] / (1024 * 1024)

        fig = make_subplots(
            rows=n_rows, cols=n_cols,
            subplot_titles=all_containers,
            vertical_spacing=0.12 / max(n_rows - 1, 1) * 2,
            horizontal_spacing=0.08,
        )

        colors = {"read_throughput": "#636EFA", "write_throughput": "#EF553B"}
        legend_added = set()

        for i, container in enumerate(all_containers):
            row = i // n_cols + 1
            col = i % n_cols + 1
            cdf = throughput_df[throughput_df["container"] == container]
            if not cdf.empty:
                for metric in ["read_throughput", "write_throughput"]:
                    mdf = cdf[cdf["metric"] == metric].sort_values("timestamp")
                    if mdf.empty:
                        continue
                    label = metric.replace("_throughput", "")
                    show_legend = metric not in legend_added
                    legend_added.add(metric)
                    fig.add_trace(
                        go.Scatter(
                            x=mdf["timestamp"], y=mdf["value_mb"],
                            name=label, legendgroup=metric,
                            showlegend=show_legend,
                            line=dict(color=colors[metric]),
                        ),
                        row=row, col=col,
                    )
            else:
                fig.add_trace(
                    go.Scatter(x=[None], y=[None], showlegend=False, hoverinfo='skip'),
                    row=row, col=col,
                )
                _n = (row - 1) * n_cols + col
                _s = "" if _n == 1 else str(_n)
                fig.add_annotation(
                    text="No data available",
                    xref=f"x{_s} domain", yref=f"y{_s} domain",
                    x=0.5, y=0.5,
                    showarrow=False,
                    font=dict(size=12, color="#999"),
                )
            fig.update_yaxes(title_text="MB/s", row=row, col=col)

        fig.update_layout(
            title="Disk I/O Throughput per Container (Read vs Write)",
            height=270 * n_rows,
        )
        fig.show()

Disk UsageΒΆ

Total disk space used per container over time.

Show code
# Disk usage uses the 'client' column (container is 'unknown' for this metric)
disk_io_path = DEVNET_DIR / "container_disk_io.parquet"
if disk_io_path.exists():
    raw_disk = pd.read_parquet(disk_io_path)
    usage_df = raw_disk[raw_disk["metric"] == "disk_usage"].copy()
    usage_df = usage_df.groupby(["client", "timestamp"], as_index=False)["value"].max()
else:
    usage_df = pd.DataFrame()

if usage_df.empty:
    print("No disk usage data available")
else:
    usage_df["value_gb"] = usage_df["value"] / (1024 * 1024 * 1024)

    # Use client names from devnet metadata
    all_clients_sorted = sorted(devnet_info["clients"])
    n_cols_du = min(len(all_clients_sorted), 2)
    n_rows_du = -(-len(all_clients_sorted) // n_cols_du)

    fig = make_subplots(
        rows=n_rows_du, cols=n_cols_du,
        subplot_titles=all_clients_sorted,
        vertical_spacing=0.12 / max(n_rows_du - 1, 1) * 2,
        horizontal_spacing=0.08,
    )

    for i, client in enumerate(all_clients_sorted):
        row = i // n_cols_du + 1
        col = i % n_cols_du + 1
        cdf = usage_df[usage_df["client"] == client].sort_values("timestamp")
        if not cdf.empty and cdf["value"].max() > 0:
            fig.add_trace(
                go.Scatter(
                    x=cdf["timestamp"], y=cdf["value_gb"],
                    name=client, showlegend=False,
                    line=dict(color="#636EFA"),
                ),
                row=row, col=col,
            )
        else:
            fig.add_trace(
                go.Scatter(x=[None], y=[None], showlegend=False, hoverinfo='skip'),
                row=row, col=col,
            )
            _n = (row - 1) * n_cols_du + col
            _s = "" if _n == 1 else str(_n)
            fig.add_annotation(
                text="No data available",
                xref=f"x{_s} domain", yref=f"y{_s} domain",
                x=0.5, y=0.5,
                showarrow=False,
                font=dict(size=12, color="#999"),
            )
        fig.update_yaxes(title_text="GB", row=row, col=col)

    fig.update_layout(
        title="Disk Usage per Client",
        height=270 * n_rows_du,
    )
    fig.show()

Network ThroughputΒΆ

Network receive (rx) and transmit (tx) throughput per container.

Show code
net_df = dfs["network"]

if net_df.empty:
    print("No network data available")
else:
    net_df["value_mb"] = net_df["value"] / (1024 * 1024)

    fig = make_subplots(
        rows=n_rows, cols=n_cols,
        subplot_titles=all_containers,
        vertical_spacing=0.12 / max(n_rows - 1, 1) * 2,
        horizontal_spacing=0.08,
    )

    colors = {"rx": "#636EFA", "tx": "#EF553B"}
    legend_added = set()

    for i, container in enumerate(all_containers):
        row = i // n_cols + 1
        col = i % n_cols + 1
        cdf = net_df[net_df["container"] == container]
        if not cdf.empty:
            for metric in ["rx", "tx"]:
                mdf = cdf[cdf["metric"] == metric].sort_values("timestamp")
                if mdf.empty:
                    continue
                show_legend = metric not in legend_added
                legend_added.add(metric)
                fig.add_trace(
                    go.Scatter(
                        x=mdf["timestamp"], y=mdf["value_mb"],
                        name=metric, legendgroup=metric,
                        showlegend=show_legend,
                        line=dict(color=colors[metric]),
                    ),
                    row=row, col=col,
                )
        else:
            fig.add_trace(
                go.Scatter(x=[None], y=[None], showlegend=False, hoverinfo='skip'),
                row=row, col=col,
            )
            _n = (row - 1) * n_cols + col
            _s = "" if _n == 1 else str(_n)
            fig.add_annotation(
                text="No data available",
                xref=f"x{_s} domain", yref=f"y{_s} domain",
                x=0.5, y=0.5,
                showarrow=False,
                font=dict(size=12, color="#999"),
            )
        fig.update_yaxes(title_text="MB/s", row=row, col=col)

    fig.update_layout(
        title="Network Throughput per Container (RX vs TX)",
        height=270 * n_rows,
    )
    fig.show()

SummaryΒΆ

Peak and average resource usage per container across the devnet.

Show code
# Build summary table across all resource types
summary_rows = []

# CPU
if not cpu_df.empty:
    for container, group in cpu_df.groupby("container"):
        summary_rows.append({
            "Container": container,
            "Avg CPU (cores)": f"{group['value'].mean():.3f}",
            "Peak CPU (cores)": f"{group['value'].max():.3f}",
        })

# Memory
if not mem_df.empty:
    ws_df = mem_df[mem_df["metric"] == "working_set"]
    for container, group in ws_df.groupby("container"):
        existing = next((r for r in summary_rows if r["Container"] == container), None)
        if existing is None:
            existing = {"Container": container}
            summary_rows.append(existing)
        existing["Avg Memory"] = format_bytes(group["value"].mean())
        existing["Peak Memory"] = format_bytes(group["value"].max())

# Network
if not net_df.empty:
    for container, group in net_df.groupby("container"):
        existing = next((r for r in summary_rows if r["Container"] == container), None)
        if existing is None:
            existing = {"Container": container}
            summary_rows.append(existing)
        rx = group[group["metric"] == "rx"]["value"]
        tx = group[group["metric"] == "tx"]["value"]
        if not rx.empty:
            existing["Avg RX"] = format_bytes_per_sec(rx.mean())
        if not tx.empty:
            existing["Avg TX"] = format_bytes_per_sec(tx.mean())

if summary_rows:
    summary_df = pd.DataFrame(summary_rows).set_index("Container").sort_index().fillna("-")
    display(summary_df)
else:
    print("No resource data available for summary.")
Avg CPU (cores) Peak CPU (cores) Avg Memory Peak Memory Avg RX Avg TX
Container
buildx_buildkit_multiarch0 0.001 0.003 646.8 MB 646.8 MB 0.0 B/s 0.0 B/s
ethlambda_0 2.614 4.253 1.1 GB 2.2 GB 1.5 MB/s 3.6 MB/s
ethlambda_1 1.143 1.913 1.4 GB 1.5 GB 834.8 KB/s 92.5 MB/s
ethlambda_10 0.300 0.442 1.1 GB 2.1 GB 2.2 MB/s 2.5 MB/s
ethlambda_2 0.243 0.355 1.1 GB 2.2 GB 861.8 KB/s 1.8 MB/s
ethlambda_3 0.333 0.562 1.2 GB 1.4 GB 609.1 KB/s 17.2 MB/s
ethlambda_4 0.253 0.417 1.8 GB 3.9 GB 1.9 MB/s 1.4 MB/s
ethlambda_5 0.531 1.020 782.9 MB 1.1 GB 754.3 KB/s 37.9 MB/s
ethlambda_6 0.645 1.231 854.9 MB 1.1 GB 723.4 KB/s 39.6 MB/s
ethlambda_7 0.258 0.425 1.0 GB 2.1 GB 1.9 MB/s 2.0 MB/s
ethlambda_8 0.258 0.420 1.1 GB 2.1 GB 2.0 MB/s 2.4 MB/s
ethlambda_9 0.371 0.616 1.1 GB 1.1 GB 823.8 KB/s 20.2 MB/s
gean_0 3.466 4.650 6.4 GB 9.0 GB 835.9 KB/s 2.5 MB/s
gean_1 0.599 1.024 2.4 GB 4.4 GB 1.2 MB/s 3.3 MB/s
gean_2 0.351 0.671 2.2 GB 5.0 GB 782.0 KB/s 2.0 MB/s
gean_3 0.436 0.609 4.5 GB 8.4 GB 730.3 KB/s 2.5 MB/s
grandine_0 4.752 7.628 1.8 GB 3.9 GB 10.8 MB/s 2.2 MB/s
grandine_1 0.369 0.636 2.2 GB 2.2 GB 855.7 KB/s 2.8 MB/s
grandine_2 4.347 6.913 1.7 GB 3.9 GB 18.0 MB/s 2.3 MB/s
grandine_3 3.104 5.497 1.1 GB 1.8 GB 6.3 MB/s 385.7 KB/s
grandine_4 3.038 5.591 1.2 GB 3.7 GB 7.0 MB/s 391.9 KB/s
grandine_5 1.769 2.738 1.2 GB 3.6 GB 15.6 MB/s 617.8 KB/s
grandine_6 1.561 2.592 1.1 GB 1.9 GB 6.4 MB/s 364.2 KB/s
lantern_0 0.449 0.816 735.2 MB 2.0 GB 155.7 KB/s 445.7 KB/s
lantern_1 0.622 1.085 820.5 MB 3.6 GB 288.5 KB/s 513.9 KB/s
lantern_2 0.149 0.312 560.1 MB 652.7 MB 156.1 KB/s 310.3 KB/s
lantern_3 0.134 0.250 505.0 MB 551.2 MB 169.3 KB/s 507.4 KB/s
ream_0 2.884 6.634 8.1 GB 14.9 GB 838.5 KB/s 1.2 MB/s
ream_1 0.895 1.163 4.8 GB 9.4 GB 1.1 MB/s 401.9 KB/s
ream_2 0.849 1.181 4.0 GB 7.7 GB 1.4 MB/s 958.6 KB/s
ream_3 0.828 1.128 4.2 GB 7.6 GB 1.1 MB/s 581.1 KB/s
ream_4 0.862 1.180 3.8 GB 7.1 GB 1.8 MB/s 50.1 KB/s
ream_5 1.379 2.417 4.2 GB 4.2 GB 844.8 KB/s 28.8 MB/s
ream_6 0.839 1.142 3.7 GB 7.4 GB 1.2 MB/s 75.8 KB/s
zeam_0 2.192 2.823 4.4 GB 8.1 GB 2.9 MB/s 2.9 MB/s
zeam_1 2.022 2.640 2.8 GB 4.5 GB 1.9 MB/s 2.3 MB/s
zeam_2 2.681 3.527 4.1 GB 9.2 GB 3.9 MB/s 2.8 MB/s
zeam_4 1.615 2.057 3.9 GB 6.9 GB 3.6 MB/s 3.0 MB/s
zeam_5 1.543 1.850 3.2 GB 5.6 GB 3.2 MB/s 2.3 MB/s
zeam_6 1.576 1.884 3.0 GB 6.1 GB 3.0 MB/s 2.5 MB/s
Show code
print(f"Devnet: {devnet_id}")
if devnet_info:
    print(f"Duration: {devnet_info['duration_hours']:.1f} hours")
print(f"Containers analyzed: {cpu_df['container'].nunique() if not cpu_df.empty else 0}")
Devnet: pqdevnet-20260701T1125Z
Duration: 0.7 hours
Containers analyzed: 40