At present there are only three XSLT 2.0 processors known and from them Saxon 9.x is probably the most efficient (at least according to my experience) both in speed and in memory utilisation. Saxon-SA (the schema-aware version of Saxon, not free as the B (basic) version) has special extensions for streamed processing.
From the various existing *XSLT 1.0* processors, .NET XslCompiledTransform (C#-based, not Java!) seems to be the champion.
In the Java-based world of XSLT 1.0 processors *Saxon 6.x* again is pretty good.
Now, more than 3 years from the date this question was originally answered, there isn't any evidence that the efficiency difference between of the XSLT processors mentioned has changed.
As for streaming:
- An XML document with "millions of nodes" may well be processed even without any streaming. I conducted an experiment in which Saxom 9.1.07 processed an XML document that contains around one million 3-rd level elements with integer values. The transformation simply calculates their sum. The total time for the transformation on my computer is less than 1.5 seconds. The used memory was 500MB -- something that PCs could have even 10 years ago,
Here are Saxon's informational messages that show details about the transformation:
Saxon 184.108.40.206J from Saxonica
Java version 1.6.0_17
Stylesheet compilation time: 190 milliseconds
Building tree for file:/C:\temp\delete\MRowst.xml using class net.sf.saxon.tinytree.TinyBuilder
Tree built in 1053 milliseconds
Tree size: 3075004 nodes, 1800000 characters, 0 attributes
Execution time: 1448 milliseconds
Memory used: 506661648
NamePool contents: 14 entries in 14 chains. 6 prefixes, 6 URIs
.2. Saxon 9.4 has a saxon:stream() extension function that can be used for processing huge XML documents.
Here is an excerpt from the documentation:
There are basically two ways of doing streaming in Saxon:
Burst-mode streaming: with this approach, the transformation of a
large file is broken up into a sequence of transformations of small
pieces of the file. Each piece in turn is read from the input, turned
into a small tree in memory, transformed, and written to the output
This approach works well for files that are fairly flat in structure,
for example a log file holding millions of log records, where the
processing of each log record is independent of the ones that went
A variant of this technique uses the new XSLT 3.0 xsl:iterate
instruction to iterate over the records, in place of xsl:for-each.
This allows working data to be maintained as the records are
processed: this makes it possible, for example, to output totals or
averages at the end of the run, or to make the processing of one
record dependent on what came before it in the file. The xsl:iterate
instruction also allows early exit from the loop, which makes it
possible for a transformation to process data from the beginning of a
large file without actually reading the whole file.
Burst-mode streaming is available in both XSLT and XQuery, but there
is no equivalent in XQuery to the xsl:iterate construct.
Streaming templates: this approach follows the traditional XSLT
processing pattern of performing a recursive descent of the input XML
hierarchy by matching template rules to the nodes at each level, but
does so one element at a time, without building the tree in memory.
Every template belongs to a mode (perhaps the default, unnamed mode),
and streaming is a property of the mode that can be specified using
the new xsl:mode declaration. If the mode is declared to be
streamable, then every template rule within that mode must obey the
rules for streamable processing.
The rules for what is allowed in streamed processing are quite
complicated, but the essential principle is that the template rule for
a given node can only read the descendants of that node once, in
order. There are further rules imposed by limitations in the current
Saxon implementation: for example, although grouping using
is theoretically consistent
with a streamed implementation, it is not currently implemented in
.3. XSLT 3.0 would have standard streaming feature. However, the W3C document is still with a "working draft" status and the streaming specification is likely to change in subsequent draft versions. Due to this, no implementations of the current draft (streaming) specification exist.
.4. Warning: Not every transformation can be performed in streaming mode -- regardless of the XSLT processor. One example of a transformation that isn't possible to perform in a streaming mode (with a limited amount of RAM) for huge documents is sorting their elements (say by a common attribute).