1 <?xml version="1.0" encoding="iso-8859-1"?>
2 <chapter id="using-ghc">
3 <title>Using GHC</title>
5 <indexterm><primary>GHC, using</primary></indexterm>
6 <indexterm><primary>using GHC</primary></indexterm>
9 <title>Options overview</title>
11 <para>GHC's behaviour is controlled by
12 <firstterm>options</firstterm>, which for historical reasons are
13 also sometimes referred to as command-line flags or arguments.
14 Options can be specified in three ways:</para>
17 <title>Command-line arguments</title>
19 <indexterm><primary>structure, command-line</primary></indexterm>
20 <indexterm><primary>command-line</primary><secondary>arguments</secondary></indexterm>
21 <indexterm><primary>arguments</primary><secondary>command-line</secondary></indexterm>
23 <para>An invocation of GHC takes the following form:</para>
29 <para>Command-line arguments are either options or file names.</para>
31 <para>Command-line options begin with <literal>-</literal>.
32 They may <emphasis>not</emphasis> be grouped:
33 <option>-vO</option> is different from <option>-v -O</option>.
34 Options need not precede filenames: e.g., <literal>ghc *.o -o
35 foo</literal>. All options are processed and then applied to
36 all files; you cannot, for example, invoke <literal>ghc -c -O1
37 Foo.hs -O2 Bar.hs</literal> to apply different optimisation
38 levels to the files <filename>Foo.hs</filename> and
39 <filename>Bar.hs</filename>.</para>
42 <sect2 id="source-file-options">
43 <title>Command line options in source files</title>
45 <indexterm><primary>source-file options</primary></indexterm>
47 <para>Sometimes it is useful to make the connection between a
48 source file and the command-line options it requires quite
49 tight. For instance, if a Haskell source file deliberately
50 uses name shadowing, it should be compiled with the
51 <option>-fno-warn-name-shadowing</option> option. Rather than maintaining
52 the list of per-file options in a <filename>Makefile</filename>,
53 it is possible to do this directly in the source file using the
54 <literal>OPTIONS_GHC</literal> pragma <indexterm><primary>OPTIONS_GHC
55 pragma</primary></indexterm>:</para>
58 {-# OPTIONS_GHC -fno-warn-name-shadowing #-}
63 <para><literal>OPTIONS_GHC</literal> is a <emphasis>file-header pragma</emphasis>
64 (see <xref linkend="pragmas"/>).</para>
66 <para>Only <emphasis>dynamic</emphasis> flags can be used in an <literal>OPTIONS_GHC</literal> pragma
67 (see <xref linkend="static-dynamic-flags"/>).</para>
69 <para>Note that your command shell does not
70 get to the source file options, they are just included literally
71 in the array of command-line arguments the compiler
72 maintains internally, so you'll be desperately disappointed if
73 you try to glob etc. inside <literal>OPTIONS_GHC</literal>.</para>
75 <para>NOTE: the contents of OPTIONS_GHC are appended to the
76 command-line options, so options given in the source file
77 override those given on the command-line.</para>
79 <para>It is not recommended to move all the contents of your
80 Makefiles into your source files, but in some circumstances, the
81 <literal>OPTIONS_GHC</literal> pragma is the Right Thing. (If you
82 use <option>-keep-hc-file</option> and have OPTION flags in
83 your module, the OPTIONS_GHC will get put into the generated .hc
88 <title>Setting options in GHCi</title>
90 <para>Options may also be modified from within GHCi, using the
91 <literal>:set</literal> command. See <xref linkend="ghci-set"/>
92 for more details.</para>
96 <sect1 id="static-dynamic-flags">
97 <title>Static, Dynamic, and Mode options</title>
98 <indexterm><primary>static</primary><secondary>options</secondary>
100 <indexterm><primary>dynamic</primary><secondary>options</secondary>
102 <indexterm><primary>mode</primary><secondary>options</secondary>
105 <para>Each of GHC's command line options is classified as
106 <firstterm>static</firstterm>, <firstterm>dynamic</firstterm> or
107 <firstterm>mode</firstterm>:</para>
111 <term>Mode flags</term>
113 <para>For example, <option>--make</option> or <option>-E</option>.
114 There may only be a single mode flag on the command line. The
115 available modes are listed in <xref linkend="modes"/>.</para>
119 <term>Dynamic Flags</term>
121 <para>Most non-mode flags fall into this category. A dynamic flag
122 may be used on the command line, in a
123 <literal>OPTIONS_GHC</literal> pragma in a source file, or set
124 using <literal>:set</literal> in GHCi.</para>
128 <term>Static Flags</term>
130 <para>A few flags are "static", which means they can only be used on
131 the command-line, and remain in force over the entire GHC/GHCi
137 <para>The flag reference tables (<xref
138 linkend="flag-reference"/>) lists the status of each flag.</para>
140 <para>There are a few flags that are static except that they can
141 also be used with GHCi's <literal>:set</literal> command; these
142 are listed as “static/<literal>:set</literal>” in the
146 <sect1 id="file-suffixes">
147 <title>Meaningful file suffixes</title>
149 <indexterm><primary>suffixes, file</primary></indexterm>
150 <indexterm><primary>file suffixes for GHC</primary></indexterm>
152 <para>File names with “meaningful” suffixes (e.g.,
153 <filename>.lhs</filename> or <filename>.o</filename>) cause the
154 “right thing” to happen to those files.</para>
159 <term><filename>.hs</filename></term>
161 <para>A Haskell module.</para>
167 <filename>.lhs</filename>
168 <indexterm><primary><literal>lhs</literal> suffix</primary></indexterm>
171 <para>A “literate Haskell” module.</para>
176 <term><filename>.hi</filename></term>
178 <para>A Haskell interface file, probably
179 compiler-generated.</para>
184 <term><filename>.hc</filename></term>
186 <para>Intermediate C file produced by the Haskell
192 <term><filename>.c</filename></term>
194 <para>A C file not produced by the Haskell
200 <term><filename>.s</filename></term>
202 <para>An assembly-language source file, usually produced by
208 <term><filename>.o</filename></term>
210 <para>An object file, produced by an assembler.</para>
215 <para>Files with other suffixes (or without suffixes) are passed
216 straight to the linker.</para>
221 <title>Modes of operation</title>
223 <para>GHC's behaviour is firstly controlled by a mode flag. Only
224 one of these flags may be given, but it does not necessarily need
225 to be the first option on the command-line. The available modes
231 <cmdsynopsis><command>ghc --interactive</command>
233 <indexterm><primary>interactive mode</primary></indexterm>
234 <indexterm><primary>ghci</primary></indexterm>
237 <para>Interactive mode, which is also available as
238 <command>ghci</command>. Interactive mode is described in
239 more detail in <xref linkend="ghci"/>.</para>
245 <cmdsynopsis><command>ghc --make</command>
247 <indexterm><primary>make mode</primary></indexterm>
248 <indexterm><primary><option>––make</option></primary></indexterm>
251 <para>In this mode, GHC will build a multi-module Haskell
252 program automatically, figuring out dependencies for itself.
253 If you have a straightforward Haskell program, this is
254 likely to be much easier, and faster, than using
255 <command>make</command>. Make mode is described in <xref
256 linkend="make-mode"/>.</para>
262 <cmdsynopsis><command>ghc -e</command>
263 <arg choice='plain'><replaceable>expr</replaceable></arg>
265 <indexterm><primary>eval mode</primary></indexterm>
268 <para>Expression-evaluation mode. This is very similar to
269 interactive mode, except that there is a single expression
270 to evaluate (<replaceable>expr</replaceable>) which is given
271 on the command line. See <xref linkend="eval-mode"/> for
279 <command>ghc -E</command>
280 <command>ghc -c</command>
281 <command>ghc -S</command>
282 <command>ghc -c</command>
284 <indexterm><primary><option>-E</option></primary></indexterm>
285 <indexterm><primary><option>-C</option></primary></indexterm>
286 <indexterm><primary><option>-S</option></primary></indexterm>
287 <indexterm><primary><option>-c</option></primary></indexterm>
290 <para>This is the traditional batch-compiler mode, in which
291 GHC can compile source files one at a time, or link objects
292 together into an executable. This mode also applies if
293 there is no other mode flag specified on the command line,
294 in which case it means that the specified files should be
295 compiled and then linked to form a program. See <xref
296 linkend="options-order"/>.</para>
303 <command>ghc -M</command>
305 <indexterm><primary>dependency-generation mode</primary></indexterm>
308 <para>Dependency-generation mode. In this mode, GHC can be
309 used to generate dependency information suitable for use in
310 a <literal>Makefile</literal>. See <xref
311 linkend="makefile-dependencies"/>.</para>
318 <command>ghc --mk-dll</command>
320 <indexterm><primary>DLL-creation mode</primary></indexterm>
323 <para>DLL-creation mode (Windows only). See <xref
324 linkend="win32-dlls-create"/>.</para>
331 <command>ghc --help</command> <command>ghc -?</command>
333 <indexterm><primary><option>––help</option></primary></indexterm>
336 <para>Cause GHC to spew a long usage message to standard
337 output and then exit.</para>
344 <command>ghc --show-iface <replaceable>file</replaceable></command>
346 <indexterm><primary><option>––--show-iface</option></primary></indexterm>
349 <para>Read the interface in
350 <replaceable>file</replaceable> and dump it as text to
351 <literal>stdout</literal>. For example <literal>ghc --show-iface M.hi</literal>.</para>
358 <command>ghc --supported-languages</command>
360 <indexterm><primary><option>––supported-languages</option></primary></indexterm>
363 <para>Print the supported language extensions.</para>
370 <command>ghc --info</command>
372 <indexterm><primary><option>––info</option></primary></indexterm>
375 <para>Print information about the compiler.</para>
382 <command>ghc --version</command>
383 <command>ghc -V</command>
385 <indexterm><primary><option>-V</option></primary></indexterm>
386 <indexterm><primary><option>––version</option></primary></indexterm>
389 <para>Print a one-line string including GHC's version number.</para>
396 <command>ghc --numeric-version</command>
398 <indexterm><primary><option>––numeric-version</option></primary></indexterm>
401 <para>Print GHC's numeric version number only.</para>
408 <command>ghc --print-libdir</command>
410 <indexterm><primary><option>––print-libdir</option></primary></indexterm>
413 <para>Print the path to GHC's library directory. This is
414 the top of the directory tree containing GHC's libraries,
415 interfaces, and include files (usually something like
416 <literal>/usr/local/lib/ghc-5.04</literal> on Unix). This
418 <literal>$libdir</literal><indexterm><primary><literal>libdir</literal></primary></indexterm>
419 in the package configuration file
420 (see <xref linkend="packages"/>).</para>
426 <sect2 id="make-mode">
427 <title>Using <command>ghc</command> <option>––make</option></title>
428 <indexterm><primary><option>––make</option></primary></indexterm>
429 <indexterm><primary>separate compilation</primary></indexterm>
431 <para>When given the <option>––make</option> option,
432 GHC will build a multi-module Haskell program by following
433 dependencies from one or more root modules (usually just
434 <literal>Main</literal>). For example, if your
435 <literal>Main</literal> module is in a file called
436 <filename>Main.hs</filename>, you could compile and link the
437 program like this:</para>
440 ghc ––make Main.hs
443 <para>The command line may contain any number of source file
444 names or module names; GHC will figure out all the modules in
445 the program by following the imports from these initial modules.
446 It will then attempt to compile each module which is out of
447 date, and finally, if there is a <literal>Main</literal> module,
448 the program will also be linked into an executable.</para>
450 <para>The main advantages to using <literal>ghc
451 ––make</literal> over traditional
452 <literal>Makefile</literal>s are:</para>
456 <para>GHC doesn't have to be restarted for each compilation,
457 which means it can cache information between compilations.
458 Compiling a multi-module program with <literal>ghc
459 ––make</literal> can be up to twice as fast as
460 running <literal>ghc</literal> individually on each source
464 <para>You don't have to write a <literal>Makefile</literal>.</para>
465 <indexterm><primary><literal>Makefile</literal>s</primary><secondary>avoiding</secondary></indexterm>
468 <para>GHC re-calculates the dependencies each time it is
469 invoked, so the dependencies never get out of sync with the
474 <para>Any of the command-line options described in the rest of
475 this chapter can be used with
476 <option>––make</option>, but note that any options
477 you give on the command line will apply to all the source files
478 compiled, so if you want any options to apply to a single source
479 file only, you'll need to use an <literal>OPTIONS_GHC</literal>
480 pragma (see <xref linkend="source-file-options"/>).</para>
482 <para>If the program needs to be linked with additional objects
483 (say, some auxiliary C code), then the object files can be
484 given on the command line and GHC will include them when linking
485 the executable.</para>
487 <para>Note that GHC can only follow dependencies if it has the
488 source file available, so if your program includes a module for
489 which there is no source file, even if you have an object and an
490 interface file for the module, then GHC will complain. The
491 exception to this rule is for package modules, which may or may
492 not have source files.</para>
494 <para>The source files for the program don't all need to be in
495 the same directory; the <option>-i</option> option can be used
496 to add directories to the search path (see <xref
497 linkend="search-path"/>).</para>
500 <sect2 id="eval-mode">
501 <title>Expression evaluation mode</title>
503 <para>This mode is very similar to interactive mode, except that
504 there is a single expression to evaluate which is specified on
505 the command line as an argument to the <option>-e</option>
509 ghc -e <replaceable>expr</replaceable>
512 <para>Haskell source files may be named on the command line, and
513 they will be loaded exactly as in interactive mode. The
514 expression is evaluated in the context of the loaded
517 <para>For example, to load and run a Haskell program containing
518 a module <literal>Main</literal>, we might say</para>
521 ghc -e Main.main Main.hs
524 <para>or we can just use this mode to evaluate expressions in
525 the context of the <literal>Prelude</literal>:</para>
528 $ ghc -e "interact (unlines.map reverse.lines)"
534 <sect2 id="options-order">
535 <title>Batch compiler mode</title>
537 <para>In <emphasis>batch mode</emphasis>, GHC will compile one or more source files
538 given on the command line.</para>
540 <para>The first phase to run is determined by each input-file
541 suffix, and the last phase is determined by a flag. If no
542 relevant flag is present, then go all the way through to linking.
543 This table summarises:</para>
547 <colspec align="left"/>
548 <colspec align="left"/>
549 <colspec align="left"/>
550 <colspec align="left"/>
554 <entry>Phase of the compilation system</entry>
555 <entry>Suffix saying “start here”</entry>
556 <entry>Flag saying “stop after”</entry>
557 <entry>(suffix of) output file</entry>
562 <entry>literate pre-processor</entry>
563 <entry><literal>.lhs</literal></entry>
565 <entry><literal>.hs</literal></entry>
569 <entry>C pre-processor (opt.) </entry>
570 <entry><literal>.hs</literal> (with
571 <option>-cpp</option>)</entry>
572 <entry><option>-E</option></entry>
573 <entry><literal>.hspp</literal></entry>
577 <entry>Haskell compiler</entry>
578 <entry><literal>.hs</literal></entry>
579 <entry><option>-C</option>, <option>-S</option></entry>
580 <entry><literal>.hc</literal>, <literal>.s</literal></entry>
584 <entry>C compiler (opt.)</entry>
585 <entry><literal>.hc</literal> or <literal>.c</literal></entry>
586 <entry><option>-S</option></entry>
587 <entry><literal>.s</literal></entry>
591 <entry>assembler</entry>
592 <entry><literal>.s</literal></entry>
593 <entry><option>-c</option></entry>
594 <entry><literal>.o</literal></entry>
598 <entry>linker</entry>
599 <entry><replaceable>other</replaceable></entry>
601 <entry><filename>a.out</filename></entry>
607 <indexterm><primary><option>-C</option></primary></indexterm>
608 <indexterm><primary><option>-E</option></primary></indexterm>
609 <indexterm><primary><option>-S</option></primary></indexterm>
610 <indexterm><primary><option>-c</option></primary></indexterm>
612 <para>Thus, a common invocation would be: </para>
615 ghc -c Foo.hs</screen>
617 <para>to compile the Haskell source file
618 <filename>Foo.hs</filename> to an object file
619 <filename>Foo.o</filename>.</para>
621 <para>Note: What the Haskell compiler proper produces depends on
622 whether a native-code generator<indexterm><primary>native-code
623 generator</primary></indexterm> is used (producing assembly
624 language) or not (producing C). See <xref
625 linkend="options-codegen"/> for more details.</para>
627 <para>Note: C pre-processing is optional, the
628 <option>-cpp</option><indexterm><primary><option>-cpp</option></primary></indexterm>
629 flag turns it on. See <xref linkend="c-pre-processor"/> for more
632 <para>Note: The option <option>-E</option><indexterm><primary>-E
633 option</primary></indexterm> runs just the pre-processing passes
634 of the compiler, dumping the result in a file.</para>
636 <sect3 id="overriding-suffixes">
637 <title>Overriding the default behaviour for a file</title>
639 <para>As described above, the way in which a file is processed by GHC
640 depends on its suffix. This behaviour can be overridden using the
641 <option>-x</option> option:</para>
645 <term><option>-x</option> <replaceable>suffix</replaceable>
646 <indexterm><primary><option>-x</option></primary>
649 <para>Causes all files following this option on the command
650 line to be processed as if they had the suffix
651 <replaceable>suffix</replaceable>. For example, to compile a
652 Haskell module in the file <literal>M.my-hs</literal>,
653 use <literal>ghc -c -x hs M.my-hs</literal>.</para>
662 <sect1 id="options-help">
663 <title>Help and verbosity options</title>
665 <indexterm><primary>help options</primary></indexterm>
666 <indexterm><primary>verbosity options</primary></indexterm>
668 <para>See also the <option>--help</option>, <option>--version</option>, <option>--numeric-version</option>,
669 and <option>--print-libdir</option> modes in <xref linkend="modes"/>.</para>
674 <indexterm><primary><option>-n</option></primary></indexterm>
677 <para>Does a dry-run, i.e. GHC goes through all the motions
678 of compiling as normal, but does not actually run any
679 external commands.</para>
686 <indexterm><primary><option>-v</option></primary></indexterm>
689 <para>The <option>-v</option> option makes GHC
690 <emphasis>verbose</emphasis>: it reports its version number
691 and shows (on stderr) exactly how it invokes each phase of
692 the compilation system. Moreover, it passes the
693 <option>-v</option> flag to most phases; each reports its
694 version number (and possibly some other information).</para>
696 <para>Please, oh please, use the <option>-v</option> option
697 when reporting bugs! Knowing that you ran the right bits in
698 the right order is always the first thing we want to
705 <option>-v</option><replaceable>n</replaceable>
706 <indexterm><primary><option>-v</option></primary></indexterm>
709 <para>To provide more control over the compiler's verbosity,
710 the <option>-v</option> flag takes an optional numeric
711 argument. Specifying <option>-v</option> on its own is
712 equivalent to <option>-v3</option>, and the other levels
713 have the following meanings:</para>
717 <term><option>-v0</option></term>
719 <para>Disable all non-essential messages (this is the
725 <term><option>-v1</option></term>
727 <para>Minimal verbosity: print one line per
728 compilation (this is the default when
729 <option>––make</option> or
730 <option>––interactive</option> is on).</para>
735 <term><option>-v2</option></term>
737 <para>Print the name of each compilation phase as it
738 is executed. (equivalent to
739 <option>-dshow-passes</option>).</para>
744 <term><option>-v3</option></term>
746 <para>The same as <option>-v2</option>, except that in
747 addition the full command line (if appropriate) for
748 each compilation phase is also printed.</para>
753 <term><option>-v4</option></term>
755 <para>The same as <option>-v3</option> except that the
756 intermediate program representation after each
757 compilation phase is also printed (excluding
758 preprocessed and C/assembly files).</para>
766 <term><option>-ferror-spans</option>
767 <indexterm><primary><option>-ferror-spans</option></primary>
771 <para>Causes GHC to emit the full source span of the
772 syntactic entity relating to an error message. Normally, GHC
773 emits the source location of the start of the syntactic
776 <para>For example:</para>
778 <screen>test.hs:3:6: parse error on input `where'</screen>
780 <para>becomes:</para>
782 <screen>test296.hs:3:6-10: parse error on input `where'</screen>
784 <para>And multi-line spans are possible too:</para>
786 <screen>test.hs:(5,4)-(6,7):
787 Conflicting definitions for `a'
788 Bound at: test.hs:5:4
790 In the binding group for: a, b, a</screen>
792 <para>Note that line numbers start counting at one, but
793 column numbers start at zero. This choice was made to
794 follow existing convention (i.e. this is how Emacs does
800 <term><option>-H</option><replaceable>size</replaceable>
801 <indexterm><primary><option>-H</option></primary></indexterm>
804 <para>Set the minimum size of the heap to
805 <replaceable>size</replaceable>.
806 This option is equivalent to
807 <literal>+RTS -H<replaceable>size</replaceable></literal>,
808 see <xref linkend="rts-options-gc" />.
814 <term><option>-Rghc-timing</option>
815 <indexterm><primary><option>-Rghc-timing</option></primary></indexterm>
818 <para>Prints a one-line summary of timing statistics for the
819 GHC run. This option is equivalent to
820 <literal>+RTS -tstderr</literal>, see <xref
821 linkend="rts-options-gc" />.
830 <sect1 id="options-sanity">
831 <title>Warnings and sanity-checking</title>
833 <indexterm><primary>sanity-checking options</primary></indexterm>
834 <indexterm><primary>warnings</primary></indexterm>
837 <para>GHC has a number of options that select which types of
838 non-fatal error messages, otherwise known as warnings, can be
839 generated during compilation. By default, you get a standard set
840 of warnings which are generally likely to indicate bugs in your
842 <option>-fwarn-overlapping-patterns</option>,
843 <option>-fwarn-warnings-deprecations</option>,
844 <option>-fwarn-deprecated-flags</option>,
845 <option>-fwarn-duplicate-exports</option>,
846 <option>-fwarn-missing-fields</option>,
847 <option>-fwarn-missing-methods</option>,
848 <option>-fwarn-lazy-unlifted-bindings</option>,
849 <option>-fwarn-wrong-do-bind</option>, and
850 <option>-fwarn-dodgy-foreign-imports</option>. The following
852 simple ways to select standard “packages” of warnings:
858 <term><option>-W</option>:</term>
860 <indexterm><primary>-W option</primary></indexterm>
861 <para>Provides the standard warnings plus
862 <option>-fwarn-incomplete-patterns</option>,
863 <option>-fwarn-dodgy-exports</option>,
864 <option>-fwarn-dodgy-imports</option>,
865 <option>-fwarn-unused-matches</option>,
866 <option>-fwarn-unused-imports</option>, and
867 <option>-fwarn-unused-binds</option>.</para>
872 <term><option>-Wall</option>:</term>
874 <indexterm><primary><option>-Wall</option></primary></indexterm>
875 <para>Turns on all warning options that indicate potentially
876 suspicious code. The warnings that are
877 <emphasis>not</emphasis> enabled by <option>-Wall</option>
879 <option>-fwarn-simple-patterns</option>,
880 <option>-fwarn-tabs</option>,
881 <option>-fwarn-incomplete-record-updates</option>,
882 <option>-fwarn-monomorphism-restriction</option>,
883 <option>-fwarn-unused-do-bind</option>, and
884 <option>-fwarn-implicit-prelude</option>.</para>
889 <term><option>-w</option>:</term>
891 <indexterm><primary><option>-w</option></primary></indexterm>
892 <para>Turns off all warnings, including the standard ones and
893 those that <literal>-Wall</literal> doesn't enable.</para>
898 <term><option>-Werror</option>:</term>
900 <indexterm><primary><option>-Werror</option></primary></indexterm>
901 <para>Makes any warning into a fatal error. Useful so that you don't
902 miss warnings when doing batch compilation. </para>
907 <term><option>-Wwarn</option>:</term>
909 <indexterm><primary><option>-Wwarn</option></primary></indexterm>
910 <para>Warnings are treated only as warnings, not as errors. This is
911 the default, but can be useful to negate a
912 <option>-Werror</option> flag.</para>
918 <para>The full set of warning options is described below. To turn
919 off any warning, simply give the corresponding
920 <option>-fno-warn-...</option> option on the command line.</para>
925 <term><option>-fwarn-unrecognised-pragmas</option>:</term>
927 <indexterm><primary><option>-fwarn-unrecognised-pragmas</option></primary>
929 <indexterm><primary>warnings</primary></indexterm>
930 <indexterm><primary>pragmas</primary></indexterm>
931 <para>Causes a warning to be emitted when a
932 pragma that GHC doesn't recognise is used. As well as pragmas
933 that GHC itself uses, GHC also recognises pragmas known to be used
934 by other tools, e.g. <literal>OPTIONS_HUGS</literal> and
935 <literal>DERIVE</literal>.</para>
937 <para>This option is on by default.</para>
942 <term><option>-fwarn-warnings-deprecations</option>:</term>
944 <indexterm><primary><option>-fwarn-warnings-deprecations</option></primary>
946 <indexterm><primary>warnings</primary></indexterm>
947 <indexterm><primary>deprecations</primary></indexterm>
948 <para>Causes a warning to be emitted when a
949 module, function or type with a WARNING or DEPRECATED pragma
950 is used. See <xref linkend="warning-deprecated-pragma"/> for more
951 details on the pragmas.</para>
953 <para>This option is on by default.</para>
958 <term><option>-fwarn-deprecated-flags</option>:</term>
960 <indexterm><primary><option>-fwarn-deprecated-flags</option></primary>
962 <indexterm><primary>deprecated-flags</primary></indexterm>
963 <para>Causes a warning to be emitted when a deprecated
964 commandline flag is used.</para>
966 <para>This option is on by default.</para>
971 <term><option>-fwarn-dodgy-foreign-imports</option>:</term>
973 <indexterm><primary><option>-fwarn-dodgy-foreign-imports</option></primary>
975 <para>Causes a warning to be emitted for foreign imports of
976 the following form:</para>
978 foreign import "f" f :: FunPtr t
980 <para>on the grounds that it probably should be</para>
982 foreign import "&f" f :: FunPtr t
984 <para>The first form declares that `f` is a (pure) C
985 function that takes no arguments and returns a pointer to a
986 C function with type `t`, whereas the second form declares
987 that `f` itself is a C function with type `t`. The first
988 declaration is usually a mistake, and one that is hard to
989 debug because it results in a crash, hence this
995 <term><option>-fwarn-dodgy-exports</option>:</term>
997 <indexterm><primary><option>-fwarn-dodgy-exports</option></primary>
999 <para>Causes a warning to be emitted when a datatype
1000 <literal>T</literal> is exported
1001 with all constructors, i.e. <literal>T(..)</literal>, but is it
1002 just a type synonym.</para>
1003 <para>Also causes a warning to be emitted when a module is
1004 re-exported, but that module exports nothing.</para>
1009 <term><option>-fwarn-dodgy-imports</option>:</term>
1011 <indexterm><primary><option>-fwarn-dodgy-imports</option></primary>
1013 <para>Causes a warning to be emitted when a datatype
1014 <literal>T</literal> is imported
1015 with all constructors, i.e. <literal>T(..)</literal>, but has been
1016 exported abstractly, i.e. <literal>T</literal>.</para>
1021 <term><option>-fwarn-lazy-unlifted-bindings</option>:</term>
1023 <indexterm><primary><option>-fwarn-lazy-unlifted-bindings</option></primary>
1025 <para>Causes a warning to be emitted when an unlifted type
1026 is bound in a way that looks lazy, e.g.
1027 <literal>where (I# x) = ...</literal>. Use
1028 <literal>where !(I# x) = ...</literal> instead. This will be an
1029 error, rather than a warning, in GHC 6.14.
1035 <term><option>-fwarn-duplicate-exports</option>:</term>
1037 <indexterm><primary><option>-fwarn-duplicate-exports</option></primary></indexterm>
1038 <indexterm><primary>duplicate exports, warning</primary></indexterm>
1039 <indexterm><primary>export lists, duplicates</primary></indexterm>
1041 <para>Have the compiler warn about duplicate entries in
1042 export lists. This is useful information if you maintain
1043 large export lists, and want to avoid the continued export
1044 of a definition after you've deleted (one) mention of it in
1045 the export list.</para>
1047 <para>This option is on by default.</para>
1052 <term><option>-fwarn-hi-shadowing</option>:</term>
1054 <indexterm><primary><option>-fwarn-hi-shadowing</option></primary></indexterm>
1055 <indexterm><primary>shadowing</primary>
1056 <secondary>interface files</secondary></indexterm>
1058 <para>Causes the compiler to emit a warning when a module or
1059 interface file in the current directory is shadowing one
1060 with the same module name in a library or other
1066 <term><option>-fwarn-implicit-prelude</option>:</term>
1068 <indexterm><primary><option>-fwarn-implicit-prelude</option></primary></indexterm>
1069 <indexterm><primary>implicit prelude, warning</primary></indexterm>
1070 <para>Have the compiler warn if the Prelude is implicitly
1071 imported. This happens unless either the Prelude module is
1072 explicitly imported with an <literal>import ... Prelude ...</literal>
1073 line, or this implicit import is disabled (either by
1074 <option>-XNoImplicitPrelude</option> or a
1075 <literal>LANGUAGE NoImplicitPrelude</literal> pragma).</para>
1077 <para>Note that no warning is given for syntax that implicitly
1078 refers to the Prelude, even if <option>-XNoImplicitPrelude</option>
1079 would change whether it refers to the Prelude.
1080 For example, no warning is given when
1081 <literal>368</literal> means
1082 <literal>Prelude.fromInteger (368::Prelude.Integer)</literal>
1083 (where <literal>Prelude</literal> refers to the actual Prelude module,
1084 regardless of the imports of the module being compiled).</para>
1086 <para>This warning is off by default.</para>
1091 <term><option>-fwarn-incomplete-patterns</option>:</term>
1093 <indexterm><primary><option>-fwarn-incomplete-patterns</option></primary></indexterm>
1094 <indexterm><primary>incomplete patterns, warning</primary></indexterm>
1095 <indexterm><primary>patterns, incomplete</primary></indexterm>
1097 <para>Similarly for incomplete patterns, the function
1098 <function>g</function> below will fail when applied to
1099 non-empty lists, so the compiler will emit a warning about
1100 this when <option>-fwarn-incomplete-patterns</option> is
1107 <para>This option isn't enabled by default because it can be
1108 a bit noisy, and it doesn't always indicate a bug in the
1109 program. However, it's generally considered good practice
1110 to cover all the cases in your functions.</para>
1115 <term><option>-fwarn-incomplete-record-updates</option>:</term>
1117 <indexterm><primary><option>-fwarn-incomplete-record-updates</option></primary></indexterm>
1118 <indexterm><primary>incomplete record updates, warning</primary></indexterm>
1119 <indexterm><primary>record updates, incomplete</primary></indexterm>
1122 <function>f</function> below will fail when applied to
1123 <literal>Bar</literal>, so the compiler will emit a warning about
1124 this when <option>-fwarn-incomplete-record-updates</option> is
1128 data Foo = Foo { x :: Int }
1132 f foo = foo { x = 6 }
1135 <para>This option isn't enabled by default because it can be
1136 very noisy, and it often doesn't indicate a bug in the
1143 <option>-fwarn-missing-fields</option>:
1144 <indexterm><primary><option>-fwarn-missing-fields</option></primary></indexterm>
1145 <indexterm><primary>missing fields, warning</primary></indexterm>
1146 <indexterm><primary>fields, missing</primary></indexterm>
1150 <para>This option is on by default, and warns you whenever
1151 the construction of a labelled field constructor isn't
1152 complete, missing initializers for one or more fields. While
1153 not an error (the missing fields are initialised with
1154 bottoms), it is often an indication of a programmer error.</para>
1159 <term><option>-fwarn-missing-methods</option>:</term>
1161 <indexterm><primary><option>-fwarn-missing-methods</option></primary></indexterm>
1162 <indexterm><primary>missing methods, warning</primary></indexterm>
1163 <indexterm><primary>methods, missing</primary></indexterm>
1165 <para>This option is on by default, and warns you whenever
1166 an instance declaration is missing one or more methods, and
1167 the corresponding class declaration has no default
1168 declaration for them.</para>
1169 <para>The warning is suppressed if the method name
1170 begins with an underscore. Here's an example where this is useful:
1173 _simpleFn :: a -> String
1174 complexFn :: a -> a -> String
1175 complexFn x y = ... _simpleFn ...
1177 The idea is that: (a) users of the class will only call <literal>complexFn</literal>;
1178 never <literal>_simpleFn</literal>; and (b)
1179 instance declarations can define either <literal>complexFn</literal> or <literal>_simpleFn</literal>.
1185 <term><option>-fwarn-missing-signatures</option>:</term>
1187 <indexterm><primary><option>-fwarn-missing-signatures</option></primary></indexterm>
1188 <indexterm><primary>type signatures, missing</primary></indexterm>
1190 <para>If you would like GHC to check that every top-level
1191 function/value has a type signature, use the
1192 <option>-fwarn-missing-signatures</option> option. As part of
1193 the warning GHC also reports the inferred type. The
1194 option is off by default.</para>
1199 <term><option>-fwarn-name-shadowing</option>:</term>
1201 <indexterm><primary><option>-fwarn-name-shadowing</option></primary></indexterm>
1202 <indexterm><primary>shadowing, warning</primary></indexterm>
1204 <para>This option causes a warning to be emitted whenever an
1205 inner-scope value has the same name as an outer-scope value,
1206 i.e. the inner value shadows the outer one. This can catch
1207 typographical errors that turn into hard-to-find bugs, e.g.,
1208 in the inadvertent capture of what would be a recursive call in
1209 <literal>f = ... let f = id in ... f ...</literal>.</para>
1210 <para>The warning is suppressed for names beginning with an underscore. For example
1212 f x = do { _ignore <- this; _ignore <- that; return (the other) }
1219 <term><option>-fwarn-orphans</option>:</term>
1221 <indexterm><primary><option>-fwarn-orphans</option></primary></indexterm>
1222 <indexterm><primary>orphan instances, warning</primary></indexterm>
1223 <indexterm><primary>orphan rules, warning</primary></indexterm>
1225 <para>This option causes a warning to be emitted whenever the
1226 module contains an "orphan" instance declaration or rewrite rule.
1227 An instance declaration is an orphan if it appears in a module in
1228 which neither the class nor the type being instanced are declared
1229 in the same module. A rule is an orphan if it is a rule for a
1230 function declared in another module. A module containing any
1231 orphans is called an orphan module.</para>
1232 <para>The trouble with orphans is that GHC must pro-actively read the interface
1233 files for all orphan modules, just in case their instances or rules
1234 play a role, whether or not the module's interface would otherwise
1235 be of any use. See <xref linkend="orphan-modules"/> for details.
1242 <option>-fwarn-overlapping-patterns</option>:
1243 <indexterm><primary><option>-fwarn-overlapping-patterns</option></primary></indexterm>
1244 <indexterm><primary>overlapping patterns, warning</primary></indexterm>
1245 <indexterm><primary>patterns, overlapping</primary></indexterm>
1248 <para>By default, the compiler will warn you if a set of
1249 patterns are overlapping, e.g.,</para>
1252 f :: String -> Int
1258 <para>where the last pattern match in <function>f</function>
1259 won't ever be reached, as the second pattern overlaps
1260 it. More often than not, redundant patterns is a programmer
1261 mistake/error, so this option is enabled by default.</para>
1266 <term><option>-fwarn-simple-patterns</option>:</term>
1268 <indexterm><primary><option>-fwarn-simple-patterns</option></primary>
1270 <para>Causes the compiler to warn about lambda-bound
1271 patterns that can fail, eg. <literal>\(x:xs)->...</literal>.
1272 Normally, these aren't treated as incomplete patterns by
1273 <option>-fwarn-incomplete-patterns</option>.</para>
1274 <para>“Lambda-bound patterns” includes all places where there is a single pattern,
1275 including list comprehensions and do-notation. In these cases, a pattern-match
1276 failure is quite legitimate, and triggers filtering (list comprehensions) or
1277 the monad <literal>fail</literal> operation (monads). For example:
1279 f :: [Maybe a] -> [a]
1280 f xs = [y | Just y <- xs]
1282 Switching on <option>-fwarn-simple-patterns</option> will elicit warnings about
1283 these probably-innocent cases, which is why the flag is off by default. </para>
1288 <term><option>-fwarn-tabs</option>:</term>
1290 <indexterm><primary><option>-fwarn-tabs</option></primary></indexterm>
1291 <indexterm><primary>tabs, warning</primary></indexterm>
1292 <para>Have the compiler warn if there are tabs in your source
1295 <para>This warning is off by default.</para>
1300 <term><option>-fwarn-type-defaults</option>:</term>
1302 <indexterm><primary><option>-fwarn-type-defaults</option></primary></indexterm>
1303 <indexterm><primary>defaulting mechanism, warning</primary></indexterm>
1304 <para>Have the compiler warn/inform you where in your source
1305 the Haskell defaulting mechanism for numeric types kicks
1306 in. This is useful information when converting code from a
1307 context that assumed one default into one with another,
1308 e.g., the ‘default default’ for Haskell 1.4 caused the
1309 otherwise unconstrained value <constant>1</constant> to be
1310 given the type <literal>Int</literal>, whereas Haskell 98
1311 defaults it to <literal>Integer</literal>. This may lead to
1312 differences in performance and behaviour, hence the
1313 usefulness of being non-silent about this.</para>
1315 <para>This warning is off by default.</para>
1320 <term><option>-fwarn-monomorphism-restriction</option>:</term>
1322 <indexterm><primary><option>-fwarn-monomorphism-restriction</option></primary></indexterm>
1323 <indexterm><primary>monomorphism restriction, warning</primary></indexterm>
1324 <para>Have the compiler warn/inform you where in your source
1325 the Haskell Monomorphism Restriction is applied. If applied silently
1326 the MR can give rise to unexpected behaviour, so it can be helpful
1327 to have an explicit warning that it is being applied.</para>
1329 <para>This warning is off by default.</para>
1334 <term><option>-fwarn-unused-binds</option>:</term>
1336 <indexterm><primary><option>-fwarn-unused-binds</option></primary></indexterm>
1337 <indexterm><primary>unused binds, warning</primary></indexterm>
1338 <indexterm><primary>binds, unused</primary></indexterm>
1339 <para>Report any function definitions (and local bindings)
1340 which are unused. For top-level functions, the warning is
1341 only given if the binding is not exported.</para>
1342 <para>A definition is regarded as "used" if (a) it is exported, or (b) it is
1343 mentioned in the right hand side of another definition that is used, or (c) the
1344 function it defines begins with an underscore. The last case provides a
1345 way to suppress unused-binding warnings selectively. </para>
1346 <para> Notice that a variable
1347 is reported as unused even if it appears in the right-hand side of another
1348 unused binding. </para>
1353 <term><option>-fwarn-unused-imports</option>:</term>
1355 <indexterm><primary><option>-fwarn-unused-imports</option></primary></indexterm>
1356 <indexterm><primary>unused imports, warning</primary></indexterm>
1357 <indexterm><primary>imports, unused</primary></indexterm>
1359 <para>Report any modules that are explicitly imported but
1360 never used. However, the form <literal>import M()</literal> is
1361 never reported as an unused import, because it is a useful idiom
1362 for importing instance declarations, which are anonymous in Haskell.</para>
1367 <term><option>-fwarn-unused-matches</option>:</term>
1369 <indexterm><primary><option>-fwarn-unused-matches</option></primary></indexterm>
1370 <indexterm><primary>unused matches, warning</primary></indexterm>
1371 <indexterm><primary>matches, unused</primary></indexterm>
1373 <para>Report all unused variables which arise from pattern
1374 matches, including patterns consisting of a single variable.
1375 For instance <literal>f x y = []</literal> would report
1376 <varname>x</varname> and <varname>y</varname> as unused. The
1377 warning is suppressed if the variable name begins with an underscore, thus:
1386 <term><option>-fwarn-unused-do-bind</option>:</term>
1388 <indexterm><primary><option>-fwarn-unused-do-bind</option></primary></indexterm>
1389 <indexterm><primary>unused do binding, warning</primary></indexterm>
1390 <indexterm><primary>do binding, unused</primary></indexterm>
1392 <para>Report expressions occuring in <literal>do</literal> and <literal>mdo</literal> blocks
1393 that appear to silently throw information away.
1394 For instance <literal>do { mapM popInt xs ; return 10 }</literal> would report
1395 the first statement in the <literal>do</literal> block as suspicious,
1396 as it has the type <literal>StackM [Int]</literal> and not <literal>StackM ()</literal>, but that
1397 <literal>[Int]</literal> value is not bound to anything. The warning is suppressed by
1398 explicitly mentioning in the source code that your program is throwing something away:
1400 do { _ <- mapM popInt xs ; return 10 }
1402 Of course, in this particular situation you can do even better:
1404 do { mapM_ popInt xs ; return 10 }
1411 <term><option>-fwarn-wrong-do-bind</option>:</term>
1413 <indexterm><primary><option>-fwarn-wrong-do-bind</option></primary></indexterm>
1414 <indexterm><primary>apparently erroneous do binding, warning</primary></indexterm>
1415 <indexterm><primary>do binding, apparently erroneous</primary></indexterm>
1417 <para>Report expressions occuring in <literal>do</literal> and <literal>mdo</literal> blocks
1418 that appear to lack a binding.
1419 For instance <literal>do { return (popInt 10) ; return 10 }</literal> would report
1420 the first statement in the <literal>do</literal> block as suspicious,
1421 as it has the type <literal>StackM (StackM Int)</literal> (which consists of two nested applications
1422 of the same monad constructor), but which is not then "unpacked" by binding the result.
1423 The warning is suppressed by explicitly mentioning in the source code that your program is throwing something away:
1425 do { _ <- return (popInt 10) ; return 10 }
1427 For almost all sensible programs this will indicate a bug, and you probably intended to write:
1429 do { popInt 10 ; return 10 }
1437 <para>If you're feeling really paranoid, the
1438 <option>-dcore-lint</option>
1439 option<indexterm><primary><option>-dcore-lint</option></primary></indexterm>
1440 is a good choice. It turns on heavyweight intra-pass
1441 sanity-checking within GHC. (It checks GHC's sanity, not
1448 <sect1 id="options-optimise">
1449 <title>Optimisation (code improvement)</title>
1451 <indexterm><primary>optimisation</primary></indexterm>
1452 <indexterm><primary>improvement, code</primary></indexterm>
1454 <para>The <option>-O*</option> options specify convenient
1455 “packages” of optimisation flags; the
1456 <option>-f*</option> options described later on specify
1457 <emphasis>individual</emphasis> optimisations to be turned on/off;
1458 the <option>-m*</option> options specify
1459 <emphasis>machine-specific</emphasis> optimisations to be turned
1462 <sect2 id="optimise-pkgs">
1463 <title><option>-O*</option>: convenient “packages” of optimisation flags.</title>
1465 <para>There are <emphasis>many</emphasis> options that affect
1466 the quality of code produced by GHC. Most people only have a
1467 general goal, something like “Compile quickly” or
1468 “Make my program run like greased lightning.” The
1469 following “packages” of optimisations (or lack
1470 thereof) should suffice.</para>
1472 <para>Note that higher optimisation levels cause more
1473 cross-module optimisation to be performed, which can have an
1474 impact on how much of your program needs to be recompiled when
1475 you change something. This is one reason to stick to
1476 no-optimisation when developing code.</para>
1482 No <option>-O*</option>-type option specified:
1483 <indexterm><primary>-O* not specified</primary></indexterm>
1486 <para>This is taken to mean: “Please compile
1487 quickly; I'm not over-bothered about compiled-code
1488 quality.” So, for example: <command>ghc -c
1489 Foo.hs</command></para>
1495 <option>-O0</option>:
1496 <indexterm><primary><option>-O0</option></primary></indexterm>
1499 <para>Means “turn off all optimisation”,
1500 reverting to the same settings as if no
1501 <option>-O</option> options had been specified. Saying
1502 <option>-O0</option> can be useful if
1503 eg. <command>make</command> has inserted a
1504 <option>-O</option> on the command line already.</para>
1510 <option>-O</option> or <option>-O1</option>:
1511 <indexterm><primary>-O option</primary></indexterm>
1512 <indexterm><primary>-O1 option</primary></indexterm>
1513 <indexterm><primary>optimise</primary><secondary>normally</secondary></indexterm>
1516 <para>Means: “Generate good-quality code without
1517 taking too long about it.” Thus, for example:
1518 <command>ghc -c -O Main.lhs</command></para>
1524 <option>-O2</option>:
1525 <indexterm><primary>-O2 option</primary></indexterm>
1526 <indexterm><primary>optimise</primary><secondary>aggressively</secondary></indexterm>
1529 <para>Means: “Apply every non-dangerous
1530 optimisation, even if it means significantly longer
1531 compile times.”</para>
1533 <para>The avoided “dangerous” optimisations
1534 are those that can make runtime or space
1535 <emphasis>worse</emphasis> if you're unlucky. They are
1536 normally turned on or off individually.</para>
1538 <para>At the moment, <option>-O2</option> is
1539 <emphasis>unlikely</emphasis> to produce better code than
1540 <option>-O</option>.</para>
1546 <option>-Ofile <file></option>:
1547 <indexterm><primary>-Ofile <file> option</primary></indexterm>
1548 <indexterm><primary>optimising, customised</primary></indexterm>
1551 <para>(NOTE: not supported since GHC 4.x. Please ask if
1552 you're interested in this.)</para>
1554 <para>For those who need <emphasis>absolute</emphasis>
1555 control over <emphasis>exactly</emphasis> what options are
1556 used (e.g., compiler writers, sometimes :-), a list of
1557 options can be put in a file and then slurped in with
1558 <option>-Ofile</option>.</para>
1560 <para>In that file, comments are of the
1561 <literal>#</literal>-to-end-of-line variety; blank
1562 lines and most whitespace is ignored.</para>
1564 <para>Please ask if you are baffled and would like an
1565 example of <option>-Ofile</option>!</para>
1570 <para>We don't use a <option>-O*</option> flag for day-to-day
1571 work. We use <option>-O</option> to get respectable speed;
1572 e.g., when we want to measure something. When we want to go for
1573 broke, we tend to use <option>-O2 -fvia-C</option> (and we go for
1574 lots of coffee breaks).</para>
1576 <para>The easiest way to see what <option>-O</option> (etc.)
1577 “really mean” is to run with <option>-v</option>,
1578 then stand back in amazement.</para>
1581 <sect2 id="options-f">
1582 <title><option>-f*</option>: platform-independent flags</title>
1584 <indexterm><primary>-f* options (GHC)</primary></indexterm>
1585 <indexterm><primary>-fno-* options (GHC)</primary></indexterm>
1587 <para>These flags turn on and off individual optimisations.
1588 They are normally set via the <option>-O</option> options
1589 described above, and as such, you shouldn't need to set any of
1590 them explicitly (indeed, doing so could lead to unexpected
1591 results). However, there are one or two that may be of
1596 <term><option>-fexcess-precision</option>:</term>
1598 <indexterm><primary><option>-fexcess-precision</option></primary></indexterm>
1599 <para>When this option is given, intermediate floating
1600 point values can have a <emphasis>greater</emphasis>
1601 precision/range than the final type. Generally this is a
1602 good thing, but some programs may rely on the exact
1604 <literal>Float</literal>/<literal>Double</literal> values
1605 and should not use this option for their compilation.</para>
1610 <term><option>-fignore-asserts</option>:</term>
1612 <indexterm><primary><option>-fignore-asserts</option></primary></indexterm>
1613 <para>Causes GHC to ignore uses of the function
1614 <literal>Exception.assert</literal> in source code (in
1615 other words, rewriting <literal>Exception.assert p
1616 e</literal> to <literal>e</literal> (see <xref
1617 linkend="assertions"/>). This flag is turned on by
1618 <option>-O</option>.
1625 <option>-fno-cse</option>
1626 <indexterm><primary><option>-fno-cse</option></primary></indexterm>
1629 <para>Turns off the common-sub-expression elimination optimisation.
1630 Can be useful if you have some <literal>unsafePerformIO</literal>
1631 expressions that you don't want commoned-up.</para>
1637 <option>-fno-strictness</option>
1638 <indexterm><primary><option>-fno-strictness</option></primary></indexterm>
1641 <para>Turns off the strictness analyser; sometimes it eats
1642 too many cycles.</para>
1648 <option>-fno-full-laziness</option>
1649 <indexterm><primary><option>-fno-full-laziness</option></primary></indexterm>
1652 <para>Turns off the full laziness optimisation (also known as
1653 let-floating). Full laziness increases sharing, which can lead
1654 to increased memory residency.</para>
1656 <para>NOTE: GHC doesn't implement complete full-laziness.
1657 When optimisation in on, and
1658 <option>-fno-full-laziness</option> is not given, some
1659 transformations that increase sharing are performed, such
1660 as extracting repeated computations from a loop. These
1661 are the same transformations that a fully lazy
1662 implementation would do, the difference is that GHC
1663 doesn't consistently apply full-laziness, so don't rely on
1670 <option>-fno-float-in</option>
1671 <indexterm><primary><option>-fno-float-in</option></primary></indexterm>
1674 <para>Turns off the float-in transformation.</para>
1680 <option>-fno-specialise</option>
1681 <indexterm><primary><option>-fno-specialise</option></primary></indexterm>
1684 <para>Turns off the automatic specialisation of overloaded functions.</para>
1690 <option>-fspec-constr</option>
1691 <indexterm><primary><option>-fspec-constr</option></primary></indexterm>
1694 <para>Turn on call-pattern specialisation.</para>
1700 <option>-fliberate-case</option>
1701 <indexterm><primary><option>-fliberate-case</option></primary></indexterm>
1704 <para>Turn on the liberate-case transformation.</para>
1710 <option>-fstatic-argument-transformation</option>
1711 <indexterm><primary><option>-fstatic-argument-transformation</option></primary></indexterm>
1714 <para>Turn on the static argument transformation.</para>
1720 <option>-fno-state-hack</option>
1721 <indexterm><primary><option>-fno-state-hack</option></primary></indexterm>
1724 <para>Turn off the "state hack" whereby any lambda with a
1725 <literal>State#</literal> token as argument is considered to be
1726 single-entry, hence it is considered OK to inline things inside
1727 it. This can improve performance of IO and ST monad code, but it
1728 runs the risk of reducing sharing.</para>
1734 <option>-fomit-interface-pragmas</option>
1735 <indexterm><primary><option>-fomit-interface-pragmas</option></primary></indexterm>
1738 <para>Tells GHC to omit all inessential information from the interface file
1739 generated for the module being compiled (say M). This means that a module
1740 importing M will see only the <emphasis>types</emphasis> of the functions that M exports, but not
1741 their unfoldings, strictness info, etc. Hence, for example,
1742 no function exported by M will be inlined
1743 into an importing module. The benefit is that modules that import M will
1744 need to be recompiled less often (only when M's exports change their type,
1745 not when they change their implementation).
1752 <option>-fignore-interface-pragmas</option>
1753 <indexterm><primary><option>-fignore-interface-pragmas</option></primary></indexterm>
1756 <para>Tells GHC to ignore all inessential information when reading interface files.
1757 That is, even if <filename>M.hi</filename> contains unfolding or strictness information
1758 for a function, GHC will ignore that information.</para>
1764 <option>-funbox-strict-fields</option>:
1765 <indexterm><primary><option>-funbox-strict-fields</option></primary></indexterm>
1766 <indexterm><primary>strict constructor fields</primary></indexterm>
1767 <indexterm><primary>constructor fields, strict</primary></indexterm>
1770 <para>This option causes all constructor fields which are
1771 marked strict (i.e. “!”) to be unboxed or
1772 unpacked if possible. It is equivalent to adding an
1773 <literal>UNPACK</literal> pragma to every strict
1774 constructor field (see <xref
1775 linkend="unpack-pragma"/>).</para>
1777 <para>This option is a bit of a sledgehammer: it might
1778 sometimes make things worse. Selectively unboxing fields
1779 by using <literal>UNPACK</literal> pragmas might be
1786 <option>-funfolding-creation-threshold=<replaceable>n</replaceable></option>:
1787 <indexterm><primary><option>-funfolding-creation-threshold</option></primary></indexterm>
1788 <indexterm><primary>inlining, controlling</primary></indexterm>
1789 <indexterm><primary>unfolding, controlling</primary></indexterm>
1792 <para>(Default: 45) Governs the maximum size that GHC will
1793 allow a function unfolding to be. (An unfolding has a
1794 “size” that reflects the cost in terms of
1795 “code bloat” of expanding that unfolding at
1796 at a call site. A bigger function would be assigned a
1797 bigger cost.) </para>
1799 <para> Consequences: (a) nothing larger than this will be
1800 inlined (unless it has an INLINE pragma); (b) nothing
1801 larger than this will be spewed into an interface
1805 <para> Increasing this figure is more likely to result in longer
1806 compile times than faster code. The next option is more
1812 <term><option>-funfolding-use-threshold=<replaceable>n</replaceable></option></term>
1814 <indexterm><primary><option>-funfolding-use-threshold</option></primary></indexterm>
1815 <indexterm><primary>inlining, controlling</primary></indexterm>
1816 <indexterm><primary>unfolding, controlling</primary></indexterm>
1818 <para>(Default: 8) This is the magic cut-off figure for
1819 unfolding: below this size, a function definition will be
1820 unfolded at the call-site, any bigger and it won't. The
1821 size computed for a function depends on two things: the
1822 actual size of the expression minus any discounts that
1823 apply (see <option>-funfolding-con-discount</option>).</para>
1836 <sect1 id="using-concurrent">
1837 <title>Using Concurrent Haskell</title>
1838 <indexterm><primary>Concurrent Haskell</primary><secondary>using</secondary></indexterm>
1840 <para>GHC supports Concurrent Haskell by default, without requiring a
1841 special option or libraries compiled in a certain way. To get access to
1842 the support libraries for Concurrent Haskell, just import
1844 url="&libraryBaseLocation;/Control-Concurrent.html"><literal>Control.Concurrent</literal></ulink>. More information on Concurrent Haskell is provided in the documentation for that module.</para>
1846 <para>The following RTS option(s) affect the behaviour of Concurrent
1847 Haskell programs:<indexterm><primary>RTS options, concurrent</primary></indexterm></para>
1851 <term><option>-C<replaceable>s</replaceable></option></term>
1853 <para><indexterm><primary><option>-C<replaceable>s</replaceable></option></primary><secondary>RTS option</secondary></indexterm>
1854 Sets the context switch interval to <replaceable>s</replaceable>
1855 seconds. A context switch will occur at the next heap block
1856 allocation after the timer expires (a heap block allocation occurs
1857 every 4k of allocation). With <option>-C0</option> or
1858 <option>-C</option>, context switches will occur as often as
1859 possible (at every heap block allocation). By default, context
1860 switches occur every 20ms.</para>
1866 <sect1 id="using-smp">
1867 <title>Using SMP parallelism</title>
1868 <indexterm><primary>parallelism</primary>
1870 <indexterm><primary>SMP</primary>
1873 <para>GHC supports running Haskell programs in parallel on an SMP
1874 (symmetric multiprocessor).</para>
1876 <para>There's a fine distinction between
1877 <emphasis>concurrency</emphasis> and <emphasis>parallelism</emphasis>:
1878 parallelism is all about making your program run
1879 <emphasis>faster</emphasis> by making use of multiple processors
1880 simultaneously. Concurrency, on the other hand, is a means of
1881 abstraction: it is a convenient way to structure a program that must
1882 respond to multiple asynchronous events.</para>
1884 <para>However, the two terms are certainly related. By making use of
1885 multiple CPUs it is possible to run concurrent threads in parallel,
1886 and this is exactly what GHC's SMP parallelism support does. But it
1887 is also possible to obtain performance improvements with parallelism
1888 on programs that do not use concurrency. This section describes how to
1889 use GHC to compile and run parallel programs, in <xref
1890 linkend="lang-parallel" /> we describe the language features that affect
1893 <sect2 id="parallel-compile-options">
1894 <title>Compile-time options for SMP parallelism</title>
1896 <para>In order to make use of multiple CPUs, your program must be
1897 linked with the <option>-threaded</option> option (see <xref
1898 linkend="options-linker" />). Additionally, the following
1899 compiler options affect parallelism:</para>
1903 <term><option>-feager-blackholing</option></term>
1904 <indexterm><primary><option>-feager-blackholing</option></primary></indexterm>
1907 Blackholing is the act of marking a thunk (lazy
1908 computuation) as being under evaluation. It is useful for
1909 three reasons: firstly it lets us detect certain kinds of
1910 infinite loop (the <literal>NonTermination</literal>
1911 exception), secondly it avoids certain kinds of space
1912 leak, and thirdly it avoids repeating a computation in a
1913 parallel program, because we can tell when a computation
1914 is already in progress.</para>
1917 The option <option>-feager-blackholing</option> causes
1918 each thunk to be blackholed as soon as evaluation begins.
1919 The default is "lazy blackholing", whereby thunks are only
1920 marked as being under evaluation when a thread is paused
1921 for some reason. Lazy blackholing is typically more
1922 efficient (by 1-2% or so), because most thunks don't
1923 need to be blackholed. However, eager blackholing can
1924 avoid more repeated computation in a parallel program, and
1925 this often turns out to be important for parallelism.
1929 We recommend compiling any code that is intended to be run
1930 in parallel with the <option>-feager-blackholing</option>
1938 <sect2 id="parallel-options">
1939 <title>RTS options for SMP parallelism</title>
1941 <para>To run a program on multiple CPUs, use the
1942 RTS <option>-N</option> option:</para>
1946 <term><option>-N<optional><replaceable>x</replaceable></optional></option></term>
1948 <para><indexterm><primary><option>-N<replaceable>x</replaceable></option></primary><secondary>RTS option</secondary></indexterm>
1949 Use <replaceable>x</replaceable> simultaneous threads when
1950 running the program. Normally <replaceable>x</replaceable>
1951 should be chosen to match the number of CPU cores on the
1952 machine<footnote><para>Whether hyperthreading cores should be counted or not is an
1953 open question; please feel free to experiment and let us know what
1954 results you find.</para></footnote>. For example,
1955 on a dual-core machine we would probably use
1956 <literal>+RTS -N2 -RTS</literal>.</para>
1958 <para>Omitting <replaceable>x</replaceable>,
1959 i.e. <literal>+RTS -N -RTS</literal>, lets the runtime
1960 choose the value of <replaceable>x</replaceable> itself
1961 based on how many processors are in your machine.</para>
1963 <para>Be careful when using all the processors in your
1964 machine: if some of your processors are in use by other
1965 programs, this can actually harm performance rather than
1968 <para>Setting <option>-N</option> also has the effect of
1969 enabling the parallel garbage collector (see
1970 <xref linkend="rts-options-gc" />).</para>
1972 <para>There is no means (currently) by which this value
1973 may vary after the program has started.</para>
1975 <para>The current value of the <option>-N</option> option
1976 is available to the Haskell program
1977 via <literal>GHC.Conc.numCapabilities</literal>.</para>
1982 <para>The following options affect the way the runtime schedules
1983 threads on CPUs:</para>
1987 <term><option>-qa</option></term>
1988 <indexterm><primary><option>-qa</option></primary><secondary>RTS
1989 option</secondary></indexterm>
1991 <para>Use the OS's affinity facilities to try to pin OS
1992 threads to CPU cores. This is an experimental feature,
1993 and may or may not be useful. Please let us know
1994 whether it helps for you!</para>
1998 <term><option>-qm</option></term>
1999 <indexterm><primary><option>-qm</option></primary><secondary>RTS
2000 option</secondary></indexterm>
2002 <para>Disable automatic migration for load balancing.
2003 Normally the runtime will automatically try to schedule
2004 threads across the available CPUs to make use of idle
2005 CPUs; this option disables that behaviour. Note that
2006 migration only applies to threads; sparks created
2007 by <literal>par</literal> are load-balanced separately
2008 by work-stealing.</para>
2011 This option is probably only of use for concurrent
2012 programs that explicitly schedule threads onto CPUs
2013 with <literal>GHC.Conc.forkOnIO</literal>.
2018 <term><option>-qw</option></term>
2019 <indexterm><primary><option>-qw</option></primary><secondary>RTS
2020 option</secondary></indexterm>
2022 <para>Migrate a thread to the current CPU when it is woken
2023 up. Normally when a thread is woken up after being
2024 blocked it will be scheduled on the CPU it was running on
2025 last; this option allows the thread to immediately migrate
2026 to the CPU that unblocked it.</para>
2028 <para>The rationale for allowing this eager migration is
2029 that it tends to move threads that are communicating with
2030 each other onto the same CPU; however there are
2031 pathalogical situations where it turns out to be a poor
2032 strategy. Depending on the communication pattern in your
2033 program, it may or may not be a good idea.</para>
2040 <title>Hints for using SMP parallelism</title>
2042 <para>Add the <literal>-s</literal> RTS option when
2043 running the program to see timing stats, which will help to tell you
2044 whether your program got faster by using more CPUs or not. If the user
2045 time is greater than
2046 the elapsed time, then the program used more than one CPU. You should
2047 also run the program without <literal>-N</literal> for
2050 <para>The output of <literal>+RTS -s</literal> tells you how
2051 many “sparks” were created and executed during the
2052 run of the program (see <xref linkend="rts-options-gc" />), which
2053 will give you an idea how well your <literal>par</literal>
2054 annotations are working.</para>
2056 <para>GHC's parallelism support has improved in 6.12.1 as a
2057 result of much experimentation and tuning in the runtime
2058 system. We'd still be interested to hear how well it works
2059 for you, and we're also interested in collecting parallel
2060 programs to add to our benchmarking suite.</para>
2064 <sect1 id="options-platform">
2065 <title>Platform-specific Flags</title>
2067 <indexterm><primary>-m* options</primary></indexterm>
2068 <indexterm><primary>platform-specific options</primary></indexterm>
2069 <indexterm><primary>machine-specific options</primary></indexterm>
2071 <para>Some flags only make sense for particular target
2077 <term><option>-msse2</option>:</term>
2080 (x86 only, added in GHC 6.14.1) Use the SSE2 registers and
2081 instruction set to implement floating point operations
2082 when using the native code generator. This gives a
2083 substantial performance improvement for floating point,
2084 but the resulting compiled code will only run on
2085 processors that support SSE2 (Intel Pentium 4 and later,
2086 or AMD Athlon 64 and later).
2089 SSE2 is unconditionally used on x86-64 platforms.
2095 <term><option>-monly-[32]-regs</option>:</term>
2097 <para>(x86 only)<indexterm><primary>-monly-N-regs
2098 option (iX86 only)</primary></indexterm> GHC tries to
2099 “steal” four registers from GCC, for performance
2100 reasons; it almost always works. However, when GCC is
2101 compiling some modules with four stolen registers, it will
2102 crash, probably saying:
2105 Foo.hc:533: fixed or forbidden register was spilled.
2106 This may be due to a compiler bug or to impossible asm
2107 statements or clauses.
2110 Just give some registers back with
2111 <option>-monly-N-regs</option>. Try `3' first, then `2'.
2112 If `2' doesn't work, please report the bug to us.</para>
2121 <sect1 id="ext-core">
2122 <title>Generating and compiling External Core Files</title>
2124 <indexterm><primary>intermediate code generation</primary></indexterm>
2126 <para>GHC can dump its optimized intermediate code (said to be in “Core” format)
2127 to a file as a side-effect of compilation. Non-GHC back-end tools can read and process Core files; these files have the suffix
2128 <filename>.hcr</filename>. The Core format is described in <ulink url="../../core.pdf">
2129 <citetitle>An External Representation for the GHC Core Language</citetitle></ulink>,
2131 for manipulating Core files (in Haskell) are in the GHC source distribution
2132 directory under <literal>utils/ext-core</literal>.
2133 Note that the format of <literal>.hcr</literal>
2134 files is <emphasis>different</emphasis> from the Core output format that GHC generates
2135 for debugging purposes (<xref linkend="options-debugging"/>), though the two formats appear somewhat similar.</para>
2137 <para>The Core format natively supports notes which you can add to
2138 your source code using the <literal>CORE</literal> pragma (see <xref
2139 linkend="pragmas"/>).</para>
2145 <option>-fext-core</option>
2146 <indexterm><primary><option>-fext-core</option></primary></indexterm>
2149 <para>Generate <literal>.hcr</literal> files.</para>
2155 <para>Currently (as of version 6.8.2), GHC does not have the ability to read in External Core files as source. If you would like GHC to have this ability, please <ulink url="http://hackage.haskell.org/trac/ghc/wiki/MailingListsAndIRC">make your wishes known to the GHC Team</ulink>.</para>
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