HTTP Transformations¶
Transform plugins examine or transform HTTP message body content. For example, transform plugins can:
Append text to HTML documents
Compress images
Do virus checking (on client
POST
data or server response data)Do content-based filtering (filter out HTML documents that contain certain terms or expressions)
This chapter explains how to write transform plugins. The following examples are discussed in detail:
Writing Content Transform Plugins¶
Content transformation plugins transform HTTP response content (such as
images or HTML documents) and HTTP request content (such as client
POST
data). Because the data stream to be transformed is of variable
length, these plugins must use a mechanism that passes data from buffer
to buffer and checks to see if the end of the data stream is reached.
This mechanism is provided by virtual connections (VConnection
s)
and virtual IO descriptors (VIO
s).
A VConnection
is an abstraction for a data pipe that allows its
users to perform asynchronous reads and writes without knowing the
underlying implementation. A transformation is a specific type of
VConnection
. A transformation connects an input data source and
an output data sink; this feature enables it to view and modify all the
data passing through it.
Transformations can be chained together, one after the other, so that
multiple transformations can be performed on the same content. The
VConnection
type, TSVConn
, is actually a subclass of TSCont
,
which means that VConnection
s (and transformations) are
continuations. VConnection
s and transformations can thus exchange
events, informing one another that data is available for reading or
writing, or that the end of a data stream is reached.
A VIO
is a description of an IO operation that is in progress.
Every VConnection
has an associated input VIO and an associated
output VIO. When VConnection
s are transferring data to one
another, one VConnection
’s input VIO
is another
VConnection
’s output VIO
. A VConnection
’s input VIO
is
also called its write ``VIO`` because the input VIO
refers to a
write operation performed on the VConnection
itself. Similarly, the
output VIO
is also called the read ``VIO``. For transformations,
which are designed to pass data in one direction, you can picture the
relationship between the transformation VConnection
and its
VIO
s as follows:
Because the Traffic Server API places transformations directly in the
response or request data stream, the transformation VConnection
is
responsible only for reading the data from the input buffer,
transforming it, and then writing it to the output buffer. The upstream
VConnection
writes the incoming data to the transformation’s input
buffer. In the figure above, A Transformation and its VIOs, the input VIO
describes the
progress of the upstream VConnection
’s write operation on the
transformation, while the output VIO
describes the progress of the
transformation’s write operation on the output (downstream)
VConnection
. The nbytes value in the VIO
is the total number
of bytes to be written. The ndone value is the current progress, or
the number of bytes that have been written at a specific point in time.
When writing a transformation plugin, you must understand implementation
as well as the use of VConnection
s. The implementer’s side
refers to how to implement a VConnection
that others can use. At
minimum, a transform plugin creates a transformation that sits in the
data stream and must be able to handle the events that the upstream and
downstream VConnection
s send to it. The user’s side refers to
how to use a VConnection
to read or write data. At the very least,
transformations output (write) data.
Transformations¶
VIOs¶
A VIO
or virtual IO is a description of an in progress IO
operation. The VIO
data structure is used by VConnection
users
to determine how much progress has been made on a particular IO
operation, and to re-enable an IO operation when it stalls due to buffer
space. VConnection
implementers use VIO
s to determine the
buffer for an IO operation, how much work to do on the IO operation, and
which continuation to call back when progress on the IO operation is
made.
The TSVIO
data structure itself is opaque, but it might have been
defined as follows:
typedef struct {
TSCont continuation;
TSVConn vconnection;
TSIOBufferReader reader;
TSMutex mutex;
int nbytes;
int ndone;
} *TSVIO;
IO Buffers¶
The IO buffer data structure is the building block of the
VConnection
abstraction. An IO buffer is composed of a list of
buffer blocks which, in turn, point to buffer data. Both the buffer
block (TSIOBufferBlock
) and buffer data (TSIOBufferData
) data
structures are reference counted so they can reside in multiple buffers
at the same time. This makes it extremely efficient to copy data from
one IO buffer to another using TSIOBufferCopy
, since Traffic Server
only needs to copy pointers and adjust reference counts appropriately
(instead of actually copying any data).
The IO buffer abstraction provides for a single writer and multiple
readers. In order for the readers to have no knowledge of each other,
they manipulate IO buffers through theTSIOBufferReader
data
structure. Since only a single writer is allowed, there is no
corresponding TSIOBufferWriter
data structure. The writer simply
modifies the IO buffer directly.
Transaction Data Sink¶
The hook TS_HTTP_RESPONSE_CLIENT_HOOK is a hook that supports a special type of transformation, one with only input and no output. Although the transformation doesn’t provide data back to Traffic Server it can do anything else with the data, such as writing it to another output device or process. It must, however, consume all the data for the transaction. There are two primary use cases.
Tap in to the transaction to provide the data for external processing.
Maintain the transaction.
For the latter it is important to note that if all consumers of a transaction (primarily the user agent) shut down the transaction is also
terminated, including the connection to the origin server. A data sink transform, unlike a standard transform, is considered to be a consumer
and will keep the transaction and the origin server connection up. This is useful when the transaction is in some way expensive and should
run to completion even if the user agent disconnects. Examples would be a standard transform that is expensive to initiate, or expensive
origin server connections that should be shared
.
There is an example plugin that demonstrates this used as a pure data sink to keep the transaction up regardless of whether the user agent disconnects.