let { html = OptHTMLOutput `elem` flags;
latex = OptLaTeXOutput `elem` flags;
- ascii = OptASCIIOutput `elem` flags
+ ascii = OptASCIIOutput `elem` flags;
+ csv = [ table | OptCSV table <- flags ];
+ no_norm = OptNoNormalise `elem` flags;
}
when (ascii && html) $ die "Can't produce both ASCII and HTML"
(prog,res) <- Map.toList result_table ]
case () of
+ _ | not (null csv) ->
+ putStr (csvTable results (head csv) (not no_norm))
_ | html ->
putStr (renderHtml (htmlPage results column_headings))
_ | latex ->
(a -> Bool) -- Result within reasonable limits?
-- The various per-program aspects of execution that we can generate results for.
-size_spec, alloc_spec, runtime_spec, muttime_spec, gctime_spec,
- gcwork_spec, instrs_spec, mreads_spec, mwrite_spec, cmiss_spec
+size_spec, alloc_spec, runtime_spec, elapsedtime_spec, muttime_spec, mutetime_spec,
+ gctime_spec, gcelap_spec,
+ gcwork_spec, instrs_spec, mreads_spec, mwrite_spec, cmiss_spec,
+ gc0time_spec, gc0elap_spec, gc1time_spec, gc1elap_spec, balance_spec
:: PerProgTableSpec
size_spec = SpecP "Binary Sizes" "Size" "binary-sizes" binary_size compile_status always_ok
alloc_spec = SpecP "Allocations" "Allocs" "allocations" allocs run_status always_ok
runtime_spec = SpecP "Run Time" "Runtime" "run-times" (mean run_time) run_status time_ok
+elapsedtime_spec = SpecP "Elapsed Time" "Elapsed" "elapsed-times" (mean elapsed_time) run_status time_ok
muttime_spec = SpecP "Mutator Time" "MutTime" "mutator-time" (mean mut_time) run_status time_ok
+mutetime_spec = SpecP "Mutator Elapsed Time" "MutETime" "mutator-elapsed-time" (mean mut_elapsed_time) run_status time_ok
gctime_spec = SpecP "GC Time" "GCTime" "gc-time" (mean gc_time) run_status time_ok
+gcelap_spec = SpecP "GC Elapsed Time" "GCETime" "gc-elapsed-time" (mean gc_elapsed_time) run_status time_ok
+gc0time_spec = SpecP "GC(0) Time" "GC0Time" "gc0-time" (mean gc0_time) run_status time_ok
+gc0elap_spec = SpecP "GC(0) Elapsed Time" "GC0ETime" "gc0-elapsed-time" (mean gc0_elapsed_time) run_status time_ok
+gc1time_spec = SpecP "GC(1) Time" "GC1Time" "gc1-time" (mean gc1_time) run_status time_ok
+gc1elap_spec = SpecP "GC(1) Elapsed Time" "GC1ETime" "gc1-elapsed-time" (mean gc1_elapsed_time) run_status time_ok
+balance_spec = SpecP "GC work balance" "Balance" "balance" (mean balance) run_status time_ok
gcwork_spec = SpecP "GC Work" "GCWork" "gc-work" gc_work run_status always_ok
instrs_spec = SpecP "Instructions" "Instrs" "instrs" instrs run_status always_ok
mreads_spec = SpecP "Memory Reads" "Reads" "mem-reads" mem_reads run_status always_ok
size_spec,
alloc_spec,
runtime_spec,
+ elapsedtime_spec,
muttime_spec,
+ mutetime_spec,
gctime_spec,
+ gcelap_spec,
+ gc0time_spec,
+ gc0elap_spec,
+ gc1time_spec,
+ gc1elap_spec,
+ balance_spec,
gcwork_spec,
instrs_spec,
mreads_spec,
-- These are the per-prog tables we want to generate
per_prog_result_tab :: [PerProgTableSpec]
per_prog_result_tab =
- [ size_spec, alloc_spec, runtime_spec, muttime_spec, gctime_spec,
- gcwork_spec, instrs_spec, mreads_spec, mwrite_spec, cmiss_spec ]
+ [ size_spec, alloc_spec, runtime_spec, elapsedtime_spec, muttime_spec, mutetime_spec, gctime_spec,
+ gcelap_spec, gc0time_spec, gc0elap_spec, gc1time_spec, gc1elap_spec,
+ gcwork_spec, balance_spec, instrs_spec, mreads_spec, mwrite_spec, cmiss_spec]
-- A single summary table, giving comparison figures for a number of
-- aspects, each in its own column. Only works when comparing two runs.
normal_summary_specs :: [PerProgTableSpec]
normal_summary_specs =
- [ size_spec, alloc_spec, runtime_spec ]
+ [ size_spec, alloc_spec, runtime_spec, elapsedtime_spec ]
cachegrind_summary_specs :: [PerProgTableSpec]
cachegrind_summary_specs =
++ [tableRow (-1) ("Average", gms)])
where
-- results_per_prog :: [ (String,[BoxValue a]) ]
- results_per_prog = map (calc_result rs f stat result_ok) (Map.toList r)
+ results_per_prog = map (calc_result rs f stat result_ok convert_to_percentage) (Map.toList r)
results_per_run = transpose (map snd results_per_prog)
(lows,gms,highs) = unzip3 (map calc_gmsd results_per_run)
Just res -> f res
get_results_for_mod id_attr
- = calc_result fms Just (const Success) result_ok id_attr
+ = calc_result fms Just (const Success) result_ok convert_to_percentage id_attr
show_results_for_prog (prog,mrs) =
td <! [valign "top"] << bold << prog
. show_per_prog_results ("Average",gms)
where
-- results_per_prog :: [ (String,[BoxValue a]) ]
- results_per_prog = map (calc_result rs f stat result_ok) (Map.toList r)
+ results_per_prog = map (calc_result rs f stat result_ok convert_to_percentage) (Map.toList r)
results_per_run = transpose (map snd results_per_prog)
(lows,gms,highs) = unzip3 (map calc_gmsd results_per_run)
-- throw away the baseline result
= (heading, column, [column_min, column_max, column_mean])
where (_, boxes) = unzip (map calc_one_result baseline)
- calc_one_result = calc_result [r2] getr gets ok
+ calc_one_result = calc_result [r2] getr gets ok convert_to_percentage
column = map (\(_:b:_) -> b) boxes
(_, column_mean, _) = calc_gmsd column
(column_min, column_max) = calc_minmax column
Just res -> f res
get_results_for_mod id_attr
- = calc_result fms Just (const Success) result_ok id_attr
+ = calc_result fms Just (const Success) result_ok convert_to_percentage id_attr
show_results_for_prog (prog,mrs) =
str ("\n"++prog++"\n")
. str (space 5)
. foldr (.) id (map (str . rjustify w . showBox) results)
+-- -----------------------------------------------------------------------------
+-- CSV output
+
+csvTable :: [ResultTable] -> String -> Bool -> String
+csvTable results table_name norm
+ = let
+ table_spec = [ spec | spec@(SpecP _ n _ _ _ _) <- per_prog_result_tab,
+ n == table_name ]
+ in
+ case table_spec of
+ [] -> error ("can't find table named: " ++ table_name)
+ (spec:_) -> csvProgTable results spec norm "\n"
+
+csvProgTable :: [ResultTable] -> PerProgTableSpec -> Bool -> ShowS
+csvProgTable results (SpecP long_name _ _ get_result get_status result_ok) norm
+ = csv_show_results results get_result get_status result_ok norm
+
+csv_show_results
+ :: Result a
+ => [ResultTable]
+ -> (Results -> Maybe a)
+ -> (Results -> Status)
+ -> (a -> Bool)
+ -> Bool
+ -> ShowS
+
+csv_show_results [] _ _ _ _
+ = error "csv_show_results: Can't happen?"
+csv_show_results (r:rs) f stat result_ok norm
+ = interleave "\n" results_per_prog
+ where
+ -- results_per_prog :: [ (String,[BoxValue a]) ]
+ results_per_prog = map (result_line . calc) (Map.toList r)
+ calc = calc_result rs f stat (const True) do_norm
+
+ do_norm | norm = normalise_to_base
+ | otherwise = \base res -> toBox res
+
+ result_line (prog,boxes) = interleave "," (str prog : map (str.showBox) boxes)
+
-- ---------------------------------------------------------------------------
-- Generic stuff for results generation
=> [Map String b] -- accumulated results
-> (b -> Maybe a) -- get a result from the b
-> (b -> Status) -- get a status from the b
- -> (a -> Bool) -- is this result ok?
+ -> (a -> Bool) -- normalise against the baseline?
+ -> (a -> a -> BoxValue) -- how to normalise
-> (String,b) -- the baseline result
-> (String,[BoxValue])
-calc_result rts get_maybe_a get_stat result_ok (prog,base_r) =
+calc_result rts get_maybe_a get_stat base_ok normalise (prog,base_r) =
(prog, (just_result m_baseline base_stat :
let
in
(
case m_baseline of
- Just baseline
- | result_ok baseline
- -> map (\(r,s) -> percentage r s baseline) rts'
- _ -> map (\(r,s) -> just_result r s) rts'
+ Just baseline | base_ok baseline
+ -> map (\(r,s) -> do_norm r s baseline) rts'
+ _other
+ -> map (\(r,s) -> just_result r s) rts'
)))
where
m_baseline = get_maybe_a base_r
just_result Nothing s = RunFailed s
just_result (Just a) _ = toBox a
- percentage Nothing s _ = RunFailed s
- percentage (Just a) _ baseline
- = Percentage (convert_to_percentage baseline a)
+ do_norm Nothing s _ = RunFailed s
+ do_norm (Just a) _ baseline = normalise baseline a
+
-----------------------------------------------------------------------------
-- Calculating geometric means and standard deviations
-----------------------------------------------------------------------------
-- Show the Results
-class Num a => Result a where
+convert_to_percentage :: Result a => a -> a -> BoxValue
+convert_to_percentage 0 val = Percentage 100
+convert_to_percentage baseline val = Percentage ((realToFrac val / realToFrac baseline) * 100)
+
+normalise_to_base :: Result a => a -> a -> BoxValue
+normalise_to_base 0 val = BoxFloat 1
+normalise_to_base baseline val = BoxFloat (realToFrac baseline / realToFrac val)
+
+class Real a => Result a where
toBox :: a -> BoxValue
- convert_to_percentage :: a -> a -> Float
-- We assume an Int is a size, and print it in kilobytes.
instance Result Int where
- convert_to_percentage 0 _ = 100
- convert_to_percentage baseline val
- = (fromIntegral val / fromIntegral baseline) * 100
-
toBox = BoxInt
instance Result Integer where
- convert_to_percentage 0 _ = 100
- convert_to_percentage baseline val
- = (fromInteger val / fromInteger baseline) * 100
toBox = BoxInteger
instance Result Float where
- convert_to_percentage 0.0 _ = 100.0
- convert_to_percentage baseline val = val / baseline * 100
-
toBox = BoxFloat
-- -----------------------------------------------------------------------------