Are there any major differences in performance between http and https? I seem to recall reading that HTTPS can be a fifth as fast as HTTP. Is this valid with the current generation webservers/browsers? If so, are there any whitepapers to support it?
问题:
回答1:
There\'s a very simple answer to this: Profile the performance of your web server to see what the performance penalty is for your particular situation. There are several tools out there to compare the performance of an HTTP vs HTTPS server (JMeter and Visual Studio come to mind) and they are quite easy to use.
No one can give you a meaningful answer without some information about the nature of your web site, hardware, software, and network configuration.
As others have said, there will be some level of overhead due to encryption, but it is highly dependent on:
- Hardware
- Server software
- Ratio of dynamic vs static content
- Client distance to server
- Typical session length
- Etc (my personal favorite)
- Caching behavior of clients
In my experience, servers that are heavy on dynamic content tend to be impacted less by HTTPS because the time spent encrypting (SSL-overhead) is insignificant compared to content generation time.
Servers that are heavy on serving a fairly small set of static pages that can easily be cached in memory suffer from a much higher overhead (in one case, throughput was havled on an \"intranet\").
Edit: One point that has been brought up by several others is that SSL handshaking is the major cost of HTTPS. That is correct, which is why \"typical session length\" and \"caching behavior of clients\" are important.
Many, very short sessions means that handshaking time will overwhelm any other performance factors. Longer sessions will mean the handshaking cost will be incurred at the start of the session, but subsequent requests will have relatively low overhead.
Client caching can be done at several steps, anywhere from a large-scale proxy server down to the individual browser cache. Generally HTTPS content will not be cached in a shared cache (though a few proxy servers can exploit a man-in-the-middle type behavior to achieve this). Many browsers cache HTTPS content for the current session and often times across sessions. The impact the not-caching or less caching means clients will retrieve the same content more frequently. This results in more requests and bandwidth to service the same number of users.
回答2:
HTTPS requires an initial handshake which can be very slow. The actual amount of data transferred as part of the handshake isn\'t huge (under 5 kB typically), but for very small requests, this can be quite a bit of overhead. However, once the handshake is done, a very fast form of symmetric encryption is used, so the overhead there is minimal. Bottom line: making lots of short requests over HTTPS will be quite a bit slower than HTTP, but if you transfer a lot of data in a single request, the difference will be insignificant.
However, keepalive is the default behaviour in HTTP/1.1, so you will do a single handshake and then lots of requests over the same connection. This makes a significant difference for HTTPS. You should probably profile your site (as others have suggested) to make sure, but I suspect that the performance difference will not be noticeable.
回答3:
To really understand how HTTPS will increase your latency, you have to understand how HTTPS connections are established. Here is a nice diagram. The key is that instead of the client getting the data after 2 \"legs\" (one round trip, you send a request, the server sends a response), the client won\'t get data until at least 4 legs (2 round trips). So, if it takes 100 ms for a packet to move between the client and the server, your first HTTPS request will take at least 500 ms.
Of course, this can be mitigated by re-using the HTTPS connection (which browsers should do), but it does explain part of that initial stall when loading up an HTTPS web site.
回答4:
The overhead is NOT due to the encryption. On a modern CPU, the encryption required by SSL is trivial.
The overhead is due to the SSL handshakes, which are lengthy and drastically increase the number of round-trips required for a HTTPS session over a HTTP one.
Measure (using a tool such as Firebug) the page load times while the server is on the end of a simulated high-latency link. Tools exist to simulate a high latency link - for Linux there is \"netem\". Compare HTTP with HTTPS on the same setup.
The latency can be mitigated to some extent by:
- Ensuring that your server is using HTTP keepalives - this allows the client to reuse SSL sessions, which avoids the need for another handshake
- Reducing the number of requests to as few as possible - by combining resources where possible (e.g. .js include files, CSS) and encouraging client-side caching
- Reduce the number of page loads, e.g. by loading data not required into the page (perhaps in a hidden HTML element) and then showing it using client-script.
回答5:
December 2014 Update
You can easily test the difference between HTTP and HTTPS performance in your own browser using the HTTP vs HTTPS Test website by AnthumChris: “This page measures its load time over unsecure HTTP and encrypted HTTPS connections. Both pages load 360 unique, non-cached images (2.04 MB total).”
The results may surprise you.
It\'s important to have an up to date knowledge about the HTTPS performance because the Let’s Encrypt Certificate Authority will start issuing free, automated, and open SSL certificates in Summer 2015, thanks to Mozilla, Akamai, Cisco, Electronic Frontier Foundation and IdenTrust.
June 2015 Update
Updates on Let’s Encrypt - Arriving September 2015:
- Let\'s Encrypt Launch Schedule (Jun 16, 2015)
- Let\'s Encrypt Root and Intermediate Certificates (Jun 4, 2015)
- Draft Let\'s Encrypt Subscriber Agreement (May 21, 2015)
More info on Twitter: @letsencrypt
For more info on HTTPS and SSL/TLS performance see:
- Is TLS Fast Yet?
- High Performance Browser Networking, Chapter 4: Transport Layer Security
- Overclocking SSL
- Anatomy and Performance of SSL Processing
For more info on the importance of using HTTPS see:
- Why HTTPS for Everything? (The HTTPS-Only Standard)
- Let’s Encrypt (Internet Security Research Group)
- HTTPS Everywhere (Electronic Frontier Foundation)
To sum it up, let me quote Ilya Grigorik: \"TLS has exactly one performance problem: it is not used widely enough. Everything else can be optimized.\"
Thanks to Chris - author of the HTTP vs HTTPS Test benchmark - for his comments below.
回答6:
The current top answer is not fully correct.
As others have pointed out here, https requires handshaking and therefore does more TCP/IP roundtrips.
In a WAN environment typically then the latency becomes the limiting factor and not the increased CPU usage on the server.
Just keep in mind that the latency from Europe to the US can be around 200 ms (torundtrip time).
You can easily measure this (for the single user case) with HTTPWatch.
回答7:
In addition to everything mentioned so far, please keep in mind that some (all?) web browsers do not store cached content obtained over HTTPS on the local hard-drive for security reasons. This means that from the user\'s perspective pages with plenty of static content will appear to load slower after the browser is restarted, and from your server\'s perspective the volume of requests for static content over HTTPS will be higher than would have been over HTTP.
回答8:
There isn\'t a single answer for this.
Encryption will always consume more CPU. This can be offloaded to dedicated hardware in many cases, and the cost will vary by algorithm selected. 3des is more expensive than AES, for example. Some algorithms are more expensive for the encrypter than the decryptor. Some have the opposite cost.
More expensive than the bulk crypto is handshake cost. New connections will consume much more CPU. This can be reduced with session resumption, at the cost of keeping old session secrets around until they expire. This means that small requests from a client that doesn\'t come back for more are the most expensive.
For cross internet traffic you may not notice this cost in your data rate, because the bandwidth available is too low. But you will certainly notice it in CPU usage on a busy server.
回答9:
I can tell you (as a dialup user) that the same page over SSL is several times slower than via regular HTTP...
回答10:
In a number of cases the performance impact of SSL handshakes will be mitigated by the fact that the SSL session can be cached on both ends (desktop and server). On Windows machines for example the SSL session can be cached for up to 10 hours. See http://support.microsoft.com/kb/247658/EN-US . Some SSL accelerators will also have parameters allowing you to tune the time the session is cached.
Another impact to consider is that static content served over HTTPS will not be cached by proxies, and this may reduce performance across multiple users accessing the site over the same proxy. This can be mitigated by the fact that static content will be cached at desktops as well, Internet Explorer versions 6 and 7 cache cacheable HTTPS static content unless instructed to do otherwise (Tools Menu/Internet Options/Advanced/Security/Do not save encrypted pages to disk).
回答11:
I made a small experiment and got 16% time difference for the same image from flickr (233 kb):
http://farm8.staticflickr.com/7405/13368635263_d792fc1189_b.jpg
https://farm8.staticflickr.com/7405/13368635263_d792fc1189_b.jpg
Of course these numbers depends on many factors, such as computer performance, connection speed, server load, QoS on path (the particular network path taken from browser to the server) but it shows the general idea: HTTPS is slowser then HTTP, since it requesres more operations to complete (SSL handshaking and encoding/decoding data).
回答12:
Here\'s a great article (a little bit old, but still great) on SSL handshake latency. Helped me identifying SSL as the main cause of slowness for clients who were using my app through slow Internet connections:
http://www.semicomplete.com/blog/geekery/ssl-latency.html
回答13:
Since I am investigating same problem for my project, I found these slides. Older but interesting:
http://www.cs.nyu.edu/artg/research/comparison/comparison_slides/sld001.htm
回答14:
Is TLS fast yet? Yes.
- Watch: https://www.youtube.com/watch?v=0EB7zh_7UE4
- Read: https://istlsfastyet.com/
There are many projects out there that aim to blur the lines and to make HTTPS just as fast. Like SPDY and mod-spdy.
回答15:
HTTP VS HTTPS PERFORMANCE COMPARISON
I have always associated HTTPS with slower page load times when compared to plain old HTTP. As a web developer, web page performance is important to me and anything that will slow down the performance of my web pages is a no-no.
In order to understand the performance implications involved, the diagram below gives you a basic idea of what happens under the hood when you make a request for a resource using HTTPS.
As you can see from the diagram above, there are a few extra steps that need to take place when using HTTPS compared to using plain HTTP. When you make a request using HTTPS, a handshake needs to occur in order to verify the authenticity of the request. This handshake is an extra step when compared to an HTTP request and does unfortunately incur some overhead.
In order to understand the performance implications and see for myself whether or not the performance impact would be significant, I used this site as a testing platform. I headed over to webpagetest.org and used the visual comparison tool to compare this site loading using HTTPS vs HTTP.
As you can see from Here is Test video Result using HTTPS did have an impact on my page load times, however the difference is negligible and I only noticed a 300 millisecond difference. It\'s important to note that these times depend on many factors, such as computer performance, connection speed, server load, and distance from server.
Your site may be different, and it is important to test your site thoroughly and check the performance impact involved in switching to HTTPS.
CAN WE IMPROVE THE PERFORMANCE? visit here to get detailed information
回答16:
There seems to be a nasty edge case here: Ajax over congested wifi.
Ajax usually means that the KeepAlive has timed out after say 20 seconds. However, the wifi means that the (ideally fast) ajax connection has to make multiple round trips. Worse, the wifi often loses packets, and there are TCP retransmits. In this case, HTTPS performs really really badly!
回答17:
There is a way to measure this. The tool from apache called jmeter will measure throughput. If you set up a large sampling of your service with jmeter, in a controlled environment, with and without SSL, you should get an accurate comparison of the relative cost. I would be interested in your results.
回答18:
HTTPS has encryption/decryption overhead so it will always be slightly slower. SSL termination is very CPU intensive. If you have devices to offload SSL, the difference in latencies might be barely noticeable depending on the load your servers are under.
回答19:
A more important performance difference is that an HTTPS session is ketp open while the user is connected. An HTTP \'session\' lasts only for a single item request.
It you are running a site with a large number of concurrent users, expect to buy a lot of memory.
回答20:
This is almost certainly going to be true given that SSL requires an extra step of encryption that simply isn\'t required by non-SLL HTTP.
回答21:
Browsers can accept HTTP/1.1 protocol with either HTTP or HTTPS, yet browsers can only handle HTTP/2.0 protocol with HTTPS. The protocol differences from HTTP/1.1 to HTTP/2.0 make HTTP/2.0, on average, 4-5 times faster than HTTP/1.1. Also, of sites that implement HTTPS, most do so over the HTTP/2.0 protocol. Therefore, HTTPS is almost always going to be faster than HTTP simply due to the different protocol it generally uses. However, if HTTP over HTTP/1.1 is compared with HTTPS over HTTP/1.1, then HTTP is slightly faster, on average, than HTTPS.
Here are some comparisons I ran using Chrome (Ver. 64):
HTTPS over HTTP/1.1:
- 0.47 seconds average page load time
- 0.05 seconds slower than HTTP over HTTP/1.1
- 0.37 seconds slower than HTTPS over HTTP/2.0
HTTP over HTTP/1.1
- 0.42 seconds average page load time
- 0.05 seconds faster than HTTPS over HTTP/1.1
- 0.32 seconds slower than HTTPS over HTTP/2.0
HTTPS over HTTP/2.0
- 0.10 seconds average load time
- 0.32 seconds faster than HTTP over HTTP/1.1
- 0.37 seconds faster than HTTPS over HTTPS/1.1