Difference between revisions of "Debugging"
m (→Dynamic breakpoints in GHCi: The :break command input options have changed, no 'add' option anymore) |
(replace deprecated flags) |
||
| (4 intermediate revisions by 2 users not shown) | |||
| Line 5: | Line 5: | ||
=== General usage === |
=== General usage === |
||
| − | Recent versions of GHC allow a dump of a stack trace (of all cost centres) when an exception is raised. In order to enable this, compile with <code>-prof</code>, and run with <code>+RTS -xc</code>. (Since only the cost centre stack will be printed, you may want to add <code>-auto |
+ | Recent versions of GHC allow a dump of a stack trace (of all cost centres) when an exception is raised. In order to enable this, compile with <code>-prof</code>, and run with <code>+RTS -xc</code>. (Since only the cost centre stack will be printed, you may want to add <code>-fprof-auto -fprof-cafs</code><ref name=depflags></ref> to the compilation step to include all definitions in the trace.) Since GHC version 7.8, the function [http://hackage.haskell.org/package/base/docs/GHC-Stack.html#v:errorWithStackTrace errorWithStackTrace] can be used to programmatically dump the stack trace, see [http://www.reddit.com/r/haskell/comments/2fwwx3/how_to_get_approx_stack_traces_with_profiled/ How to get (approx) stack traces with profiled builds]. |
A more detailed list of options can be found [http://www.haskell.org/ghc/docs/latest/html/users_guide/runtime-control.html#rts-options-debugging in the RTS section] of the GHC user's guide. |
A more detailed list of options can be found [http://www.haskell.org/ghc/docs/latest/html/users_guide/runtime-control.html#rts-options-debugging in the RTS section] of the GHC user's guide. |
||
| Line 20: | Line 20: | ||
| − | > ghc-7.6.3 test.hs -prof - |
+ | > ghc-7.6.3 test.hs -prof -fprof-auto -fprof-cafs && ./test +RTS -xc |
*** Exception (reporting due to +RTS -xc): (THUNK_2_0), stack trace: |
*** Exception (reporting due to +RTS -xc): (THUNK_2_0), stack trace: |
||
GHC.Err.CAF |
GHC.Err.CAF |
||
| Line 26: | Line 26: | ||
called from Main.CAF:crash_reH |
called from Main.CAF:crash_reH |
||
test: Prelude.undefined |
test: Prelude.undefined |
||
| + | |||
== Printf and friends == |
== Printf and friends == |
||
| Line 44: | Line 45: | ||
You must keep in mind that due to lazy evaluation your traces will only print if the value they wrap is ever demanded. |
You must keep in mind that due to lazy evaluation your traces will only print if the value they wrap is ever demanded. |
||
| − | The trace function is located in the base package. The package [http://hackage.haskell.org/package/htrace htrace] defines a trace function similar to the one in the base package, but with indentation for better visual effect (see the [http://www.haskell.org/pipermail/haskell-cafe/2012-January/098847.html mailing list thread] for examples). Other tools can be found at [http://hackage.haskell.org/packages/ |
+ | The trace function is located in the base package. The package [http://hackage.haskell.org/package/htrace htrace] defines a trace function similar to the one in the base package, but with indentation for better visual effect (see the [http://www.haskell.org/pipermail/haskell-cafe/2012-January/098847.html mailing list thread] for examples). Other tools can be found at [http://hackage.haskell.org/packages/#cat:Debug the debug category in Hackage]. |
A more powerful alternative for this approach is [http://hackage.haskell.org/package/hood Hood]. Even if it hasn't been |
A more powerful alternative for this approach is [http://hackage.haskell.org/package/hood Hood]. Even if it hasn't been |
||
| Line 86: | Line 87: | ||
== Offline analysis of traces == |
== Offline analysis of traces == |
||
| − | The most advanced debugging tools are based in offline analysis of traces |
+ | The most advanced debugging tools are based in offline analysis of traces. |
| + | === Haskell Tracer HAT === |
||
| ⚫ | |||
| + | [http://projects.haskell.org/hat/ Hat] is probably the most advanced tool for this, offering a comprehensive set of tools. [[User:NeilMitchell|Neil Mitchell]] has made available a Windows port of Hat at [http://projects.haskell.org/~ndm/hat/ his site]. |
||
| − | ''Some Hat user should complete this section'' |
||
| + | |||
| ⚫ | |||
| + | |||
| + | === Hoed - The Lightweight Haskell Tracer and Debugger === |
||
| + | |||
| + | [https://github.com/MaartenFaddegon/Hoed Hoed] is a tracer/debugger that offers most of HATs functionality, and works with untransformed libraries. Hoed can therefore be used to debug much more programs than traditional tracer/debuggers. |
||
| + | |||
| + | To locate a defect with Hoed you annotate suspected functions and compile as usual. Then you run your program, information about the annotated functions is collected. Finally you connect to a debugging session using a webbrowser. |
||
== Dynamic breakpoints in GHCi == |
== Dynamic breakpoints in GHCi == |
||
| Line 118: | Line 127: | ||
Once a breakpoint is hit, you can explore the bindings in scope, as well as to evaluate any Haskell expression, as you would do in a normal GHCi prompt. The <code>:print</code> command can be very useful to explore the laziness of your code. |
Once a breakpoint is hit, you can explore the bindings in scope, as well as to evaluate any Haskell expression, as you would do in a normal GHCi prompt. The <code>:print</code> command can be very useful to explore the laziness of your code. |
||
| + | |||
== Source-located errors == |
== Source-located errors == |
||
| Line 229: | Line 239: | ||
=== Infinite loops === |
=== Infinite loops === |
||
| + | |||
On glasgow-haskell-users on 21 Nov 2007, pepe made the following suggestion for detecting the cause infinite loops in GHCi. Assuming the offending function is named `loop`, and takes one argument: |
On glasgow-haskell-users on 21 Nov 2007, pepe made the following suggestion for detecting the cause infinite loops in GHCi. Assuming the offending function is named `loop`, and takes one argument: |
||
| Line 237: | Line 248: | ||
''(For which versions? ghci >= 6.8?)'' |
''(For which versions? ghci >= 6.8?)'' |
||
| + | |||
| + | <references> |
||
| + | <ref name=depflags>was <code>-auto-all -caf-all</code> in previous ghc versions (now deprecated)</ref> |
||
| + | </references> |
||
| + | |||
[[Category:Tools]] |
[[Category:Tools]] |
||
Revision as of 18:06, 11 January 2016
Stack trace
General usage
Recent versions of GHC allow a dump of a stack trace (of all cost centres) when an exception is raised. In order to enable this, compile with -prof, and run with +RTS -xc. (Since only the cost centre stack will be printed, you may want to add -fprof-auto -fprof-cafs[1] to the compilation step to include all definitions in the trace.) Since GHC version 7.8, the function errorWithStackTrace can be used to programmatically dump the stack trace, see How to get (approx) stack traces with profiled builds.
A more detailed list of options can be found in the RTS section of the GHC user's guide.
Example
-- test.hs
crash = sum [1,2,3,undefined,5,6,7,8]
main = print crash
> ghc-7.6.3 test.hs -prof -fprof-auto -fprof-cafs && ./test +RTS -xc *** Exception (reporting due to +RTS -xc): (THUNK_2_0), stack trace: GHC.Err.CAF --> evaluated by: Main.crash, called from Main.CAF:crash_reH test: Prelude.undefined
Printf and friends
The simplest approach is to use Debug.Trace.trace:
trace :: String -> a -> a
- "When called, trace outputs the string in its first argument, before returning the second argument as its result.'"
A common idiom to trace a function is:
myfun a b | trace ("myfun " ++ show a ++ " " ++ show b) False = undefined
myfun a b = ...
The advantage is that disabling and enabling the trace takes only one line comment.
You must keep in mind that due to lazy evaluation your traces will only print if the value they wrap is ever demanded.
The trace function is located in the base package. The package htrace defines a trace function similar to the one in the base package, but with indentation for better visual effect (see the mailing list thread for examples). Other tools can be found at the debug category in Hackage.
A more powerful alternative for this approach is Hood. Even if it hasn't been updated in some time, Hood works perfectly with the current ghc distribution. Even more, Hugs has it already integrated, see the manual page. Add an import Observe and start inserting observations in your code. For instance:
import Hugs.Observe f' = observe "Informative name for f" f f x = if odd x then x*2 else 0
And then in hugs:
Main> map f' [1..5]
[2,0,6,0,10]
>>>>>>> Observations <<<<<<
Informative name for f
{ \ 5 -> 10
, \ 4 -> 0
, \ 3 -> 6
, \ 2 -> 0
, \ 1 -> 2
}
outputs a report of all the invocations of f and their result.
I have a handy bogus Hugs.Observe module with no-ops for the observations so that I don't need to remove them manually, expecting that the compiler will optimize them away.
The GHood package adds a graphical back-end to Hood. See also the GHood homepage.
The Safe Library
There is a safe library of functions from the Prelude that can crash, see the safe library. If you get an error message such as "pattern match failure, head []", you can then use headNote "extra information" to get a more detailed error message for that particular call to head. The safe library also has functions that return default values and wrap their computation in Maybe as required.
Offline analysis of traces
The most advanced debugging tools are based in offline analysis of traces.
Haskell Tracer HAT
Hat is probably the most advanced tool for this, offering a comprehensive set of tools. Neil Mitchell has made available a Windows port of Hat at his site.
The disadvantage of traditional Haskell tracers is that they either need to transform the whole program or require a specialized run-time system. Therefore they are not always compatible with the latest libraries, so you can put them to use only in some cases.
Hoed - The Lightweight Haskell Tracer and Debugger
Hoed is a tracer/debugger that offers most of HATs functionality, and works with untransformed libraries. Hoed can therefore be used to debug much more programs than traditional tracer/debuggers.
To locate a defect with Hoed you annotate suspected functions and compile as usual. Then you run your program, information about the annotated functions is collected. Finally you connect to a debugging session using a webbrowser.
Dynamic breakpoints in GHCi
Finally, the GHCi debugger enables dynamic breakpoints and intermediate values observation.
This tool allows to set breakpoints in your code, directly from the GHCi command prompt. An example session:
*main:Main> :break Main 2 Breakpoint set at (2,15) *main:Main> qsort [10,9..1] Local bindings in scope: x :: a, xs :: [a], left :: [a], right :: [a] qsort2.hs:2:15-46> :sprint x x = _ qsort2.hs:2:15-46> x
This is an untyped, unevaluated computation. You can use seq to force its evaluation and then :print to recover its type
qsort2.hs:2:15-46> seq x () () qsort2.hs:2:15-46> :p x x - 10
Once a breakpoint is hit, you can explore the bindings in scope, as well as to evaluate any Haskell expression, as you would do in a normal GHCi prompt. The :print command can be very useful to explore the laziness of your code.
Source-located errors
LocH provides wrappers over
assert for generating source-located exceptions and errors.
Consider the use of a located fromJust:
import Debug.Trace.Location
import qualified Data.Map as M
import Data.Maybe
main = do print f
f = let m = M.fromList
[(1,"1")
,(2,"2")
,(3,"3")]
s = M.lookup 4 m
in fromJustSafe assert s
fromJustSafe a s = check a (fromJust s)
This will result in:
$ ./a.out
a.out: A.hs:12:20-25: Maybe.fromJust: Nothing
This can be automated, using the 'loch' preprocessor, so a program failing with:
$ ghc A.hs --make -no-recomp
[1 of 1] Compiling Main ( A.hs, A.o )
Linking A ...
$ ./A
A: Maybe.fromJust: Nothing
Can be transformed to a src-located one by adding:
import Debug.Trace.Location
and then recompiling with the preprocessor on:
$ ghc A.hs --make -pgmF loch -F -no-recomp
[1 of 1] Compiling Main ( A.hs, A.o )
Linking A ...
$ ./A
A: A.hs:14:14-19: Maybe.fromJust: Nothing
Other tricks
- If you use GHC, you can get a stack trace in the console when your program fails with an error condition. See the description of relevant runtime options.
- Some tips how to use GHCi debugger are also in this message.
Locating a failure in a library function
The simplest way to provide locating in the source code a mismatch run-time error in the library functions:
head, tail, fromJust
and others is to avoid these functions and to use explicit matching instead.
For example, consider:
g x = h $ fromJust $ f x,
ghc-6.6 often loses the reference to g, f,
and h in its run-time error report, when f
returns Nothing.
But for the program:
g x = let Just y = f x in h y,
GHC reports:
Main: M1.hs:9:11-22:
Irrefutable pattern failed for pattern Data.Maybe.Just y
Indicating the source of the failure.
Mysterious parse errors
GHC provides `-ferror-spans`, which will give you the exactly position of the start and end of an offending statement.
Infinite loops
On glasgow-haskell-users on 21 Nov 2007, pepe made the following suggestion for detecting the cause infinite loops in GHCi. Assuming the offending function is named `loop`, and takes one argument:
- enable the flag -fbreak-on-error (`:set -fbreak-on-error` in GHCi)
- run your expression with :trace (`:trace loop 'a'`)
- hit Ctrl-C while your program is stuck in the loop to have the debugger break in the loop
- use :history and :back to find out where the loop is located and why.
(For which versions? ghci >= 6.8?)
- ↑ was
-auto-all -caf-allin previous ghc versions (now deprecated)