Log10 Loadshare May 2026

# Alert when log10 loadshare is > (median + 0.477) # Because log10(3) ≈ 0.477 ( log10(sum by (instance) (rate(http_requests_total[1m])) + 1) ) > ( quantile(0.5, log10(sum by (instance) (rate(http_requests_total[1m])) + 1)) + 0.477 ) Here is a reusable function to compute loadshare imbalance scores:

This article explores what log10 loadshare means, how to calculate it, why it beats linear metrics in distributed environments, and how to implement it in real-world monitoring stacks like Prometheus, Grafana, and custom Python load testers. Before we apply the logarithm, we must define the base unit: loadshare .

In distributed systems, loadshare represents the proportionate amount of traffic, computational work, or connection handles assigned to a specific node (server, container, or thread) relative to the total system capacity or total incoming requests. | Context | Definition of Loadshare | | :--- | :--- | | Load Balancer | The number of active connections or requests per second (RPS) routed to a single backend server. | | Message Queue | The number of unacknowledged messages a specific consumer is processing. | | Database Shard | The query throughput or data volume stored on a specific shard replica. | | CDN Edge Node | The bandwidth or request count handled by a particular Point of Presence (PoP). | log10 loadshare

But log10 loadshare scales universally. Both clusters will show values between 1.7 (50 RPS) and 3.7 (5,000 RPS). You can now create a for all clusters. 3. Autoscaling Algorithms Reactive autoscaling (e.g., KEDA, HPA) often uses thresholds like "scale if CPU > 80%". But CPU is a noisy metric. Request-based scaling using raw RPS is better, but it suffers from the "elephant vs. mouse" problem: a 10x spike in RPS on a small service looks identical to a 10% spike on a large service.

log10_loadshare = log10( current_loadshare + 1 ) Why add 1? To handle zero values. log10(0) is undefined (negative infinity). By adding 1, an idle server with 0 RPS yields log10(1) = 0 . A server with 9 RPS yields log10(10) = 1 . This creates a clean, zero-bound metric. | Raw Loadshare (RPS) | log10(RPS + 1) | Interpretation | | :--- | :--- | :--- | | 0 | 0.00 | Idle | | 9 | 1.00 | Minimal load | | 99 | 2.00 | Low load | | 999 | 3.00 | Moderate load | | 9,999 | 4.00 | High load | | 99,999 | 5.00 | Extreme load | # Alert when log10 loadshare is > (median + 0

# Extract RPS per backend from HAProxy logs (simplified) awk 'print $NF' /var/log/haproxy.log | sort | uniq -c | \ awk 'print "log10_loadshare=" log($1+1)/log(10) " raw=" $1' Raw loadshare tells you how much traffic a node handles, but not how well it handles it. A powerful composite metric is the Log-Load Latency Ratio (L3R) :

# Instantaneous loadshare per instance log10( sum by (instance) ( rate(http_requests_total[1m]) ) + 1 ) For a (threshold: any instance exceeds 3x the median): | Context | Definition of Loadshare | |

Notice how each order of magnitude increase in raw loadshare adds only to the log10 loadshare . This makes dashboards readable across a wide range. Practical Use Cases 1. Detecting "Hot Spots" in Load Balancer Pools Imagine you have an NGINX load balancer distributing traffic to 20 Node.js backends. The raw metrics show one server at 8,500 RPS and another at 1,200 RPS. The linear graph shows a tall spike and a flat line.