Note: If you haven’t read Shape Average Vs Shape Peak – Part 1 already, I suggest you read it first and then return to this entry.
Three Types of Shaping
There are three types of shaping, and they are called:
- Shape Average
- Shape Peak
- Shaping with no Excess
Using the following details, I will explain how each shaping type answers the following question – What if after an interval (10 milliseconds) only 3,00 bits are sent – what happens to the remaining 2,000 tokens in the Token Bucket?
- CIR = 500kbps (500,000 bps)
- Bc = 5,000 bps
- Tc = 10ms (0.001 seconds)
- Be = 5,000 bps for Shape Average and Shape Peak, 0 bps for Shaping with no Excess
Before reading on, please keep the following information in mind:
- When using the above details, there are 100 intervals in 1 second
- The Token Bucket size = Bc – Therefore in this case the Token Bucket can hold no more than 5,000 tokens
- Each Tc, the router will add 5,000 tokens to its bucket – the way in which the router handles unused tokens is dependent on which shaping method is used
- When using Shape Average and Shape Peak, if you do not specify the Be, it will automatically be the same size as the Bc. Therefore in this examples below, the Be will be 5,000 for Shape Average and Shape Peak.
As per the question above, we want to know how Shape Average handles the 2,000 unused tokens at the end of the Tc.
Instead of discarding those left over tokens, Shape Average will put them in to the Be bucket. By doing this, future Tc intervals will be able to utilise these tokens, and therefore you will still be able to meet your CIR.
For example, when the next Tc comes the Bc bucket will be filled with 5,000 new tokens as it is every other Tc. However, the router will also have access to the additional 2,000 tokens which were put in to the Be bucket – therefore the router is able to send 7,000 bits this Tc as opposed to 5,000 bits as is the regular amount. So you see, even though the router did not fully utilise its previous Bc, it is able to make up for it in a subsequent Tc and therefore it will still be able to fully utilise its CIR.
The way in which Shape Peak uses the Be is completely different to the way Shape Average does. In the above explanation we saw that Shape Average uses Be to keep unused Bc tokens for later use so that the CIR can be met. Shape Peak on the other hand fills both the Bc and Be buckets with tokens every Tc. This means that instead of the router being able to use 5,000 tokens per interval, it can now use 10,000 tokens per interval. This equates to 10,000 bits per interval which equates to 1mb per second.
In regards to the question, what happens to the 2,000 unused tokens – the answer is, they’re discarded and replaced with 10,000 new tokens.
Why the Extra Tokens?
You might be wondering why Shape Peak fills both the Bc and Be buckets with tokens every interval. The reason is because ISPs can allow customers to send extra bursts of traffic over and above what has been agreed to in their traffic contract (also known as the CIR). However, this extra allowance is not guaranteed and is therefore susceptible to being dropped when the ISP’s network is congested.
The reason why ISPs offer this solution is because it works out more cost effective for them and their customers. This is because it would be too expensive for them to offer all of their customers a guaranteed 1mb connection as they know that most of the customers won’t be using the full bandwidth consistently. Therefore to save on costs they will instead give each customer a guaranteed 500kb connection (Bc) and will also give them an additional, non-guaranteed 500kb (Be), resulting in a 1mb/sec connection when there is no congestion on the network.
In short, by using the Be users can send more data than is specified by their CIR, but they must be prepared to see packet loss during times of congestion on their ISPs network.
Shaping with no Excess
As mentioned in my previous post, Shaping with no Excess does not use Be. Because of this, unused tokens are not able to be set aside and used in a later Tc as is the case with Shape Average and are therefore discarded. This means that if tokens are unused during a Tc, you will not be able to meet the CIR for that one second as all subsequent intervals will still only be able to use 5,000 tokens each.
On most platforms, you cannot directly change the Tc value. Further to this, Cisco recommends that you do not change the Bc and Be values manually and instead let the router choose them for you. However, rules were made to be broken! Engineers may find that they need to change their Tc value to ensure time sensitive packets are sent in a timely manner. They may also want to change the Be to a value other than one which is equal to Bc (which is the default). Both of these scenarios will be covered in a future post.
As always, if you have any questions or have a topic that you would like me to discuss, please feel free to post a comment at the bottom of this blog entry, e-mail at email@example.com, or drop me a message on Twitter (@OzNetNerd).
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