# What is P99 latency?

• Organize all your data points from lowest to highest, from left to right. Gather the lowest (leftmost) 99% of the data points, and discard the remaining 1% to the right. The highest value in this gathered group (the right-most value in this left group) is the P99 value. May 22 at 19:00

It's 99th percentile. It means that 99% of the requests should be faster than given latency. In other words only 1% of the requests are allowed to be slower.

• Only 1% of requests are expected to be slower. Oct 8, 2021 at 20:34
• Besides, it is a straightforward answer and has links to the definition, I prefer the @kanagavelu-sugumar answer, which gives an example and also explains why the P99 will be better than p95 in a context. Just remember to consider the context. Jul 13, 2022 at 14:04

Imagine that you are collecting performance data of your service and the below table is the collection of results (the latency values are fictional to illustrate the idea).

``````Latency    Number of requests
1s         5
2s         5
3s         10
4s         40
5s         20
6s         15
7s         4
8s         1
``````

• Found this as more practical example :) Feb 21, 2022 at 13:10
• I like this example! It's easier to understand. Mar 11, 2022 at 12:14
• How/why did we select 7 here ? Mar 13, 2022 at 18:30
• @ShahbazZaidi You take all your requests and discard 99% of the bottom ones. In this example above, we discard all requests with latency from 1s to 7s. Mar 28, 2022 at 15:56
• @ShahbazZaidi If I understand ThePavolC's explanation correctly, it's close but not quite right: If we discard the bottom 99% (including `7s`), then we'd be left with `8s` but that is NOT the 99th percentile! Instead, I would explain it the other way around: Sort the requests in ascending order and discard the top/largest 1%. The largest remaining value is the 99th percentile. Here, there are 100 requests so the "top 1%" corresponds to the 1 largest request (the one that took `8s`). When we get rid of that, the max remaining value is `7s`, which is the correct 99th percentile.
– Seth
Aug 15 at 22:20

We can explain it through an analogy, if 100 students are running a race then 99 students should complete the race in "latency" time.

• `Should` not `will`. Mar 8, 2018 at 23:37
• Also, <= 'latency time' Apr 27, 2018 at 0:31
• It's the time that the student who came in 99th crossed the line. Aug 28, 2018 at 14:44
• I love this analogy.
– luii
Oct 21, 2019 at 16:43
• @Tyler Lui Then half a student should complete the race in "latency" time Mar 15, 2022 at 4:43

Lets take an example from here

``````Request latency:
min: 0.1
max: 7.2
median: 0.2
p95: 0.5
p99: 1.3
``````

So we can say, 99 percent of web requests, the average latency found was 1.3ms (milli seconds/microseconds depends on your system latency measures configured). Like @tranmq said, if we decrease the P99 latency of the service, we can increase its performance.

And it is also worth noting the p95, since may be few requests makes p99 to be more costlier than p95 e.g.) initial requests that builds cache, class objects warm up, threads init, etc. So p95 may be cutting out those 5% worst case scenarios. Still out of that 5%, we dont know percentile of real noise cases Vs worst case inputs.

Finally; we can have roughly 1% noise in our measurements (like network congestions, outages, service degradations), so the p99 latency is a good representative of practically the worst case. And, almost always, our goal is to reduce the p99 latency.

Explaining P99 it through an analogy: `If 100 horses are running in a race, 99 horses should complete the race in less than or equal to "latency" time. Only 1 horse is allowed to finish the race in time higher than "latency" time.`

That means if P99 is 10ms, 99 percentile requests should have latency less than or equal to 10ms.

If p99 value is 1ms, it means, 99 out of 100 requests take less than 1ms, and 1 request take about 1 or more than 1ms.

To put it simply, imagine you have an API with a contract stating that it must respond within 10 milliseconds (ms) to callers. Over the course of an hour, you've received various requests from different consumers:

Consumer A made 10 requests at 10:00 am with responses taking 5ms each. Consumer B sent 2 requests at 10:05 am, each with a 5ms response. At 10:07 am, Consumer B submitted 20 requests, each taking 7ms to respond. Again at 10:07 am, Consumer B had 20 more requests with 7ms responses. At 10:20 am, Consumer B requested 20 times, with responses taking 11ms. Consumer B made 30 requests at 10:15 am, with responses at 12ms. At 10:30 am, Consumer B submitted 20 requests, and each took 10ms. Finally, at 10:43 am, Consumer B had 40 requests, with 9ms responses. If we sort these response times in ascending order, the second-highest response time is 11ms, which exceeds the agreed 10ms. This value, known as P99, indicates that 99% of responses were below or equal to 11ms. Since P99 is above the agreed response time, we should also check P95, which examines if 95% of all requests breach the agreed response time. If they do, we must also look into P90. By continuously monitoring these metrics (P90, P95, and P99), the Operations team can swiftly identify issues in the service or infrastructure and take corrective action.