HACKER TERRITORY. HACKER TERRITORY. (You were warned.)
-ddump-
pass
Make a debugging dump after pass
<pass>
(may be common enough to need
a short form…). You can get all of these at once
(lots of output) by using
-v5
, or most of them with
-v4
. Some of the most useful ones
are:
-ddump-parsed
:
parser output
-ddump-rn
:
renamer output
-ddump-tc
:
typechecker output
-ddump-splices
:
Dump Template Haskell expressions that we splice in, and what Haskell code the expression evaluates to.
-ddump-types
:
Dump a type signature for each value defined at
the top level of the module. The list is sorted
alphabetically. Using -dppr-debug
dumps a type signature for all the imported and
system-defined things as well; useful for debugging the
compiler.
-ddump-deriv
:
derived instances
-ddump-ds
:
desugarer output
-ddump-spec
:
output of specialisation pass
-ddump-rules
:
dumps all rewrite rules (including those generated by the specialisation pass)
-ddump-simpl
:
simplifier output (Core-to-Core passes)
-ddump-inlinings
:
inlining info from the simplifier
-ddump-cpranal
:
CPR analyser output
-ddump-stranal
:
strictness analyser output
-ddump-cse
:
CSE pass output
-ddump-workwrap
:
worker/wrapper split output
-ddump-occur-anal
:
`occurrence analysis' output
-ddump-prep
:
output of core preparation pass
-ddump-stg
:
output of STG-to-STG passes
-ddump-flatC
:
flattened Abstract C
-ddump-cmm
:
Print the C-- code out.
-ddump-opt-cmm
:
Dump the results of C-- to C-- optimising passes.
-ddump-asm
:
assembly language from the native-code generator
-ddump-bcos
:
byte code compiler output
-ddump-foreign
:
dump foreign export stubs
-ddump-simpl-iterations
:
Show the output of each iteration
of the simplifier (each run of the simplifier has a maximum
number of iterations, normally 4). Used when even
-dverbose-simpl
doesn't cut it.
-ddump-simpl-stats
Dump statistics about how many of each kind of
transformation too place. If you add
-dppr-debug
you get more detailed
information.
-ddump-if-trace
Make the interface loader be *real* chatty about what it is upto.
-ddump-tc-trace
Make the type checker be *real* chatty about what it is upto.
-ddump-rn-trace
Make the renamer be *real* chatty about what it is upto.
-ddump-rn-stats
Print out summary of what kind of information the renamer had to bring in.
-dverbose-core2core
,
-dverbose-stg2stg
Show the output of the intermediate Core-to-Core and STG-to-STG passes, respectively. (Lots of output!) So: when we're really desperate:
% ghc -noC -O -ddump-simpl -dverbose-simpl -dcore-lint Foo.hs
-dshow-passes
Print out each pass name as it happens.
-dfaststring-stats
Show statistics for the usage of fast strings by the compiler.
-dppr-debug
Debugging output is in one of several “styles.” Take the printing of types, for example. In the “user” style (the default), the compiler's internal ideas about types are presented in Haskell source-level syntax, insofar as possible. In the “debug” style (which is the default for debugging output), the types are printed in with explicit foralls, and variables have their unique-id attached (so you can check for things that look the same but aren't). This flag makes debugging output appear in the more verbose debug style.
-dppr-user-length
In error messages, expressions are printed to a certain “depth”, with subexpressions beyond the depth replaced by ellipses. This flag sets the depth. Its default value is 5.
-dshow-unused-imports
Have the renamer report what imports does not contribute.
Let's do this by commenting an example. It's from doing
-ddump-ds
on this code:
skip2 m = m : skip2 (m+2)
Before we jump in, a word about names of things. Within GHC,
variables, type constructors, etc., are identified by their
“Uniques.” These are of the form `letter' plus
`number' (both loosely interpreted). The `letter' gives some idea
of where the Unique came from; e.g., _
means “built-in type variable”; t
means “from the typechecker”; s
means “from the simplifier”; and so on. The `number'
is printed fairly compactly in a `base-62' format, which everyone
hates except me (WDP).
Remember, everything has a “Unique” and it is usually printed out when debugging, in some form or another. So here we go…
Desugared: Main.skip2{-r1L6-} :: _forall_ a$_4 =>{{Num a$_4}} -> a$_4 -> [a$_4] --# `r1L6' is the Unique for Main.skip2; --# `_4' is the Unique for the type-variable (template) `a' --# `{{Num a$_4}}' is a dictionary argument _NI_ --# `_NI_' means "no (pragmatic) information" yet; it will later --# evolve into the GHC_PRAGMA info that goes into interface files. Main.skip2{-r1L6-} = /\ _4 -> \ d.Num.t4Gt -> let { {- CoRec -} +.t4Hg :: _4 -> _4 -> _4 _NI_ +.t4Hg = (+{-r3JH-} _4) d.Num.t4Gt fromInt.t4GS :: Int{-2i-} -> _4 _NI_ fromInt.t4GS = (fromInt{-r3JX-} _4) d.Num.t4Gt --# The `+' class method (Unique: r3JH) selects the addition code --# from a `Num' dictionary (now an explicit lambda'd argument). --# Because Core is 2nd-order lambda-calculus, type applications --# and lambdas (/\) are explicit. So `+' is first applied to a --# type (`_4'), then to a dictionary, yielding the actual addition --# function that we will use subsequently... --# We play the exact same game with the (non-standard) class method --# `fromInt'. Unsurprisingly, the type `Int' is wired into the --# compiler. lit.t4Hb :: _4 _NI_ lit.t4Hb = let { ds.d4Qz :: Int{-2i-} _NI_ ds.d4Qz = I#! 2# } in fromInt.t4GS ds.d4Qz --# `I# 2#' is just the literal Int `2'; it reflects the fact that --# GHC defines `data Int = I# Int#', where Int# is the primitive --# unboxed type. (see relevant info about unboxed types elsewhere...) --# The `!' after `I#' indicates that this is a *saturated* --# application of the `I#' data constructor (i.e., not partially --# applied). skip2.t3Ja :: _4 -> [_4] _NI_ skip2.t3Ja = \ m.r1H4 -> let { ds.d4QQ :: [_4] _NI_ ds.d4QQ = let { ds.d4QY :: _4 _NI_ ds.d4QY = +.t4Hg m.r1H4 lit.t4Hb } in skip2.t3Ja ds.d4QY } in :! _4 m.r1H4 ds.d4QQ {- end CoRec -} } in skip2.t3Ja
(“It's just a simple functional language” is an unregisterised trademark of Peyton Jones Enterprises, plc.)
The term "unregisterised" really means "compile via vanilla C", disabling some of the platform-specific tricks that GHC normally uses to make programs go faster. When compiling unregisterised, GHC simply generates a C file which is compiled via gcc.
Unregisterised compilation can be useful when porting GHC to a new machine, since it reduces the prerequisite tools to gcc, as, and ld and nothing more, and furthermore the amount of platform-specific code that needs to be written in order to get unregisterised compilation going is usually fairly small.