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-<sect1 id="concurrent-and-parallel">
-<title>Concurrent and Parallel Haskell</title>
-
-<para>
-<indexterm><primary>Concurrent Haskell</primary></indexterm>
-<indexterm><primary>Parallel Haskell</primary></indexterm>
-Concurrent and Parallel Haskell are Glasgow extensions to Haskell
-which let you structure your program as a group of independent
-`threads'.
-</para>
-
-<para>
-Concurrent and Parallel Haskell have very different purposes.
-</para>
-
-<para>
-Concurrent Haskell is for applications which have an inherent
-structure of interacting, concurrent tasks (i.e. `threads'). Threads
-in such programs may be <emphasis>required</emphasis>. For example, if a concurrent thread has been spawned to handle a mouse click, it isn't
-optional—the user wants something done!
-</para>
-
-<para>
-A Concurrent Haskell program implies multiple `threads' running within
-a single Unix process on a single processor.
-</para>
-
-<para>
-You will find at least one paper about Concurrent Haskell hanging off
-of <ulink url="http://research.microsoft.com/~simonpj/">Simon Peyton
-Jones's Web page</ulink>.
-</para>
-
-<para>
-Parallel Haskell is about <emphasis>speed</emphasis>—spawning
-threads onto multiple processors so that your program will run faster.
-The `threads' are always <emphasis>advisory</emphasis>—if the
-runtime system thinks it can get the job done more quickly by
-sequential execution, then fine.
-</para>
-
-<para>
-A Parallel Haskell program implies multiple processes running on
-multiple processors, under a PVM (Parallel Virtual Machine) framework.
-An MPI interface is under development but not fully functional, yet.
-</para>
-
-<para>
-Parallel Haskell is still relatively new; it is more about “research
-fun” than about “speed.” That will change.
-</para>
-
-<para>
-Check the <ulink url="http://www.cee.hw.ac.uk/~dsg/gph/">GPH Page</ulink>
-for more information on “GPH” (Haskell98 with extensions for
-parallel execution), the latest version of “GUM” (the runtime
-system to enable parallel executions) and papers on research issues. A
-list of publications about GPH and about GUM is also available from Simon's
-Web Page.
-</para>
-
-<para>
-Some details about Parallel Haskell follow. For more information
-about concurrent Haskell, see the module
-<literal>Control.Concurrent</literal> in the library documentation.
-</para>
-
-<sect2>
-<title>Features specific to Parallel Haskell
-<indexterm><primary>Parallel Haskell—features</primary></indexterm></title>
-
-<sect3>
-<title>The <literal>Parallel</literal> interface (recommended)
-<indexterm><primary>Parallel interface</primary></indexterm></title>
-
-<para>
-GHC provides two functions for controlling parallel execution, through
-the <literal>Parallel</literal> interface:
-</para>
-
-<para>
+<sect1 id="lang-parallel">
+ <title>Parallel Haskell</title>
+ <indexterm><primary>parallelism</primary>
+ </indexterm>
+
+ <para>There are two implementations of Parallel Haskell: SMP paralellism
+ <indexterm><primary>SMP</primary></indexterm>
+ which is built-in to GHC (see <xref linkend="sec-using-smp" />) and
+ supports running Parallel Haskell programs on a single multiprocessor
+ machine, and
+ Glasgow Parallel Haskell<indexterm><primary>Glasgow Parallel Haskell</primary></indexterm>
+ (GPH) which supports running Parallel Haskell
+ programs on both clusters of machines or single multiprocessors. GPH is
+ developed and distributed
+ separately from GHC (see <ulink url="http://www.cee.hw.ac.uk/~dsg/gph/">The
+ GPH Page</ulink>).</para>
+
+ <para>Ordinary single-threaded Haskell programs will not benefit from
+ enabling SMP parallelism alone. You must expose parallelism to the
+ compiler in one of the following two ways.</para>
+
+ <sect2>
+ <title>Running Concurrent Haskell programs in parallel</title>
+
+ <para>The first possibility is to use concurrent threads to structure your
+ program, and make sure
+ that you spread computation amongst the threads. The runtime will
+ schedule the running Haskell threads among the available OS
+ threads, running as many in parallel as you specified with the
+ <option>-N</option> RTS option.</para>
+ </sect2>
+
+ <sect2>
+ <title>Annotating pure code for parallelism</title>
+
+ <para>The simplest mechanism for extracting parallelism from pure code is
+ to use the <literal>par</literal> combinator, which is closely related to (and often used
+ with) <literal>seq</literal>. Both of these are available from <ulink
+ url="../libraries/base/Control-Parallel.html"><literal>Control.Parallel</literal></ulink>:</para>
<programlisting>
-interface Parallel where
infixr 0 `par`
infixr 1 `seq`
par :: a -> b -> b
-seq :: a -> b -> b
-</programlisting>
-
-</para>
+seq :: a -> b -> b</programlisting>
-<para>
-The expression <literal>(x `par` y)</literal> <emphasis>sparks</emphasis> the evaluation of <literal>x</literal>
-(to weak head normal form) and returns <literal>y</literal>. Sparks are queued for
-execution in FIFO order, but are not executed immediately. At the
-next heap allocation, the currently executing thread will yield
-control to the scheduler, and the scheduler will start a new thread
-(until reaching the active thread limit) for each spark which has not
-already been evaluated to WHNF.
-</para>
+ <para>The expression <literal>(x `par` y)</literal>
+ <emphasis>sparks</emphasis> the evaluation of <literal>x</literal>
+ (to weak head normal form) and returns <literal>y</literal>. Sparks are
+ queued for execution in FIFO order, but are not executed immediately. If
+ the runtime detects that there is an idle CPU, then it may convert a
+ spark into a real thread, and run the new thread on the idle CPU. In
+ this way the available parallelism is spread amongst the real
+ CPUs.</para>
-<para>
-The expression <literal>(x `seq` y)</literal> evaluates <literal>x</literal> to weak head normal
-form and then returns <literal>y</literal>. The <function>seq</function> primitive can be used to
-force evaluation of an expression beyond WHNF, or to impose a desired
-execution sequence for the evaluation of an expression.
-</para>
-
-<para>
-For example, consider the following parallel version of our old
-nemesis, <function>nfib</function>:
-</para>
-
-<para>
+ <para>For example, consider the following parallel version of our old
+ nemesis, <function>nfib</function>:</para>
<programlisting>
-import Parallel
+import Control.Parallel
nfib :: Int -> Int
nfib n | n <= 1 = 1
| otherwise = par n1 (seq n2 (n1 + n2 + 1))
where n1 = nfib (n-1)
- n2 = nfib (n-2)
-</programlisting>
-
-</para>
-
-<para>
-For values of <varname>n</varname> greater than 1, we use <function>par</function> to spark a thread
-to evaluate <literal>nfib (n-1)</literal>, and then we use <function>seq</function> to force the
-parent thread to evaluate <literal>nfib (n-2)</literal> before going on to add
-together these two subexpressions. In this divide-and-conquer
-approach, we only spark a new thread for one branch of the computation
-(leaving the parent to evaluate the other branch). Also, we must use
-<function>seq</function> to ensure that the parent will evaluate <varname>n2</varname> <emphasis>before</emphasis>
-<varname>n1</varname> in the expression <literal>(n1 + n2 + 1)</literal>. It is not sufficient to
-reorder the expression as <literal>(n2 + n1 + 1)</literal>, because the compiler may
-not generate code to evaluate the addends from left to right.
-</para>
-
-</sect3>
-
-<sect3>
-<title>Underlying functions and primitives
-<indexterm><primary>parallelism primitives</primary></indexterm>
-<indexterm><primary>primitives for parallelism</primary></indexterm></title>
-
-<para>
-The functions <function>par</function> and <function>seq</function> are wired into GHC, and unfold
-into uses of the <function>par#</function> and <function>seq#</function> primitives, respectively. If
-you'd like to see this with your very own eyes, just run GHC with the
-<option>-ddump-simpl</option> option. (Anything for a good time…)
-</para>
-
-</sect3>
-
-<sect3>
-<title>Scheduling policy for concurrent threads
-<indexterm><primary>Scheduling—concurrent</primary></indexterm>
-<indexterm><primary>Concurrent scheduling</primary></indexterm></title>
-
-<para>
-Runnable threads are scheduled in round-robin fashion. Context
-switches are signalled by the generation of new sparks or by the
-expiry of a virtual timer (the timer interval is configurable with the
-<option>-C[<num>]</option><indexterm><primary>-C<num> RTS option (concurrent,
-parallel)</primary></indexterm> RTS option). However, a context switch doesn't
-really happen until the current heap block is full. You can't get any
-faster context switching than this.
-</para>
-
-<para>
-When a context switch occurs, pending sparks which have not already
-been reduced to weak head normal form are turned into new threads.
-However, there is a limit to the number of active threads (runnable or
-blocked) which are allowed at any given time. This limit can be
-adjusted with the <option>-t<num></option><indexterm><primary>-t <num> RTS option (concurrent, parallel)</primary></indexterm>
-RTS option (the default is 32). Once the
-thread limit is reached, any remaining sparks are deferred until some
-of the currently active threads are completed.
-</para>
-
-</sect3>
-
-<sect3>
-<title>Scheduling policy for parallel threads
-<indexterm><primary>Scheduling—parallel</primary></indexterm>
-<indexterm><primary>Parallel scheduling</primary></indexterm></title>
-
-<para>
-In GUM we use an unfair scheduler, which means that a thread continues to
-perform graph reduction until it blocks on a closure under evaluation, on a
-remote closure or until the thread finishes.
-</para>
-
-</sect3>
-
-</sect2>
+ n2 = nfib (n-2)</programlisting>
+
+ <para>For values of <varname>n</varname> greater than 1, we use
+ <function>par</function> to spark a thread to evaluate <literal>nfib (n-1)</literal>,
+ and then we use <function>seq</function> to force the
+ parent thread to evaluate <literal>nfib (n-2)</literal> before going on
+ to add together these two subexpressions. In this divide-and-conquer
+ approach, we only spark a new thread for one branch of the computation
+ (leaving the parent to evaluate the other branch). Also, we must use
+ <function>seq</function> to ensure that the parent will evaluate
+ <varname>n2</varname> <emphasis>before</emphasis> <varname>n1</varname>
+ in the expression <literal>(n1 + n2 + 1)</literal>. It is not sufficient
+ to reorder the expression as <literal>(n2 + n1 + 1)</literal>, because
+ the compiler may not generate code to evaluate the addends from left to
+ right.</para>
+
+ <para>When using <literal>par</literal>, the general rule of thumb is that
+ the sparked computation should be required at a later time, but not too
+ soon. Also, the sparked computation should not be too small, otherwise
+ the cost of forking it in parallel will be too large relative to the
+ amount of parallelism gained. Getting these factors right is tricky in
+ practice.</para>
+
+ <para>More sophisticated combinators for expressing parallelism are
+ available from the <ulink
+ url="../libraries/base/Control-Parallel-Strategies.html"><literal>Control.Parallel.Strategies</literal></ulink> module.
+ This module builds functionality around <literal>par</literal>,
+ expressing more elaborate patterns of parallel computation, such as
+ parallel <literal>map</literal>.</para>
+ </sect2>
</sect1>