{-# LANGUAGE Safe #-} {- Copyright (c) 2006-2011 John Goerzen <jgoerzen@complete.org> All rights reserved. For license and copyright information, see the file LICENSE -} {- | Module : Data.Progress.Tracker Copyright : Copyright (C) 2006-2011 John Goerzen SPDX-License-Identifier: BSD-3-Clause Stability : provisional Portability: portable Tools for tracking the status of a long operation. Written by John Goerzen, jgoerzen\@complete.org See also "Data.Progress.Meter" -} module Data.Progress.Tracker ( -- * Introduction -- $introduction -- ** Examples -- $examples -- * Creation and Options newProgress, newProgress', addCallback, addParent, -- * Updating incrP, incrP', setP, setP', incrTotal, setTotal, finishP, -- * Reading and Processing getSpeed, withStatus, getETR, getETA, -- * Types ProgressStatus(..), Progress, ProgressTimeSource, ProgressCallback, ProgressStatuses, -- * Utilities defaultTimeSource ) where import Control.Concurrent.MVar import System.Time import System.Time.Utils import Data.Ratio {- $introduction ProgressTracker is a module for tracking the progress on long-running operations. It can be thought of as the back end engine behind a status bar. ProgressTracker can do things such as track how far along a task is, provide an estimated time of completion, estimated time remaining, current speed, etc. It is designed to be as generic as possible; it can even base its speed calculations on something other than the system clock. ProgressTracker also supports a notion of a parent tracker. This is used when a large task is composed of several individual tasks which may also be long-running. Downloading many large files over the Internet is a common example of this. Any given ProgressTracker can be told about one or more parent trackers. When the child tracker's status is updated, the parent tracker's status is also updated in the same manner. Therefore, the progress on each individual component, as well as the overall progress, can all be kept in sync automatically. Finally, you can register callbacks. Callbacks are functions that are called whenever the status of a tracker changes. They'll be passed the old and new status and are intended to do things like update on-screen status displays. The cousin module 'Data.Progress.Meter' can be used to nicely render these trackers on a console. -} {- $examples Here is an example use: >do prog <- newProgress "mytracker" 1024 > incrP prog 10 > getETR prog >>= print -- prints number of seconds remaining > incrP prog 500 > finishP prog -} ---------------------------------------------------------------------- -- TYPES ---------------------------------------------------------------------- {- | A function that, when called, yields the current time. The default is 'defaultTimeSource'. -} type ProgressTimeSource = IO Integer {- | The type for a callback function for the progress tracker. When given at creation time to 'newProgress\'' or when added via 'addCallback', these functions get called every time the status of the tracker changes. This function is passed two 'ProgressStatus' records: the first reflects the status prior to the update, and the second reflects the status after the update. Please note that the owning 'Progress' object will be locked while the callback is running, so the callback will not be able to make changes to it. -} type ProgressCallback = ProgressStatus -> ProgressStatus -> IO () {- | The main progress status record. -} data ProgressStatus = ProgressStatus {completedUnits :: Integer, totalUnits :: Integer, startTime :: Integer, trackerName :: String, -- ^ An identifying string timeSource :: ProgressTimeSource } data ProgressRecord = ProgressRecord {parents :: [Progress], callbacks :: [ProgressCallback], status :: ProgressStatus} {- | The main Progress object. -} newtype Progress = Progress (MVar ProgressRecord) class ProgressStatuses a b where {- | Lets you examine the 'ProgressStatus' that is contained within a 'Progress' object. You can simply pass a 'Progress' object and a function to 'withStatus', and 'withStatus' will lock the 'Progress' object (blocking any modifications while you are reading it), then pass the object to your function. If you happen to already have a 'ProgressStatus' object, withStatus will also accept it and simply pass it unmodified to the function. -} withStatus :: a -> (ProgressStatus -> b) -> b class ProgressRecords a b where withRecord :: a -> (ProgressRecord -> b) -> b {- instance ProgressStatuses ProgressRecord b where withStatus x func = func (status x) instance ProgressRecords ProgressRecord b where withRecord x func = func x -} instance ProgressStatuses Progress (IO b) where withStatus (Progress x) func = withMVar x (\y -> func (status y)) instance ProgressRecords Progress (IO b) where withRecord (Progress x) func = withMVar x func instance ProgressStatuses ProgressStatus b where withStatus x func = func x ---------------------------------------------------------------------- -- Creation ---------------------------------------------------------------------- {- | Create a new 'Progress' object with the given name and number of total units initialized as given. The start time will be initialized with the current time at the present moment according to the system clock. The units completed will be set to 0, the time source will be set to the system clock, and the parents and callbacks will be empty. If you need more control, see 'newProgress\''. Example: > prog <- newProgress "mytracker" 1024 -} newProgress :: String -- ^ Name of this tracker -> Integer -- ^ Total units expected -> IO Progress newProgress name total = do t <- defaultTimeSource newProgress' (ProgressStatus {completedUnits = 0, totalUnits = total, startTime = t, trackerName = name, timeSource = defaultTimeSource}) [] {- | Create a new 'Progress' object initialized with the given status and callbacks. No adjustment to the 'startTime' will be made. If you want to use the system clock, you can initialize 'startTime' with the return value of 'defaultTimeSource' and also pass 'defaultTimeSource' as the timing source. -} newProgress' :: ProgressStatus -> [ProgressCallback] -> IO Progress newProgress' news newcb = do r <- newMVar $ ProgressRecord {parents = [], callbacks = newcb, status = news} return (Progress r) {- | Adds an new callback to an existing 'Progress'. The callback will be called whenever the object's status is updated, except by the call to finishP. Please note that the Progress object will be locked while the callback is running, so the callback will not be able to make any modifications to it. -} addCallback :: Progress -> ProgressCallback -> IO () addCallback (Progress mpo) cb = modifyMVar_ mpo $ \po -> return $ po {callbacks = cb : callbacks po} {- | Adds a new parent to an existing 'Progress'. The parent will automatically have its completed and total counters incremented by the value of those counters in the existing 'Progress'. -} addParent :: Progress -- ^ The child object -> Progress -- ^ The parent to add to this child -> IO () addParent (Progress mcpo) ppo = modifyMVar_ mcpo $ \cpo -> do incrP' ppo (completedUnits . status $ cpo) incrTotal ppo (totalUnits . status $ cpo) return $ cpo {parents = ppo : parents cpo} {- | Call this when you are finished with the object. It is especially important to do this when parent objects are involved. This will simply set the totalUnits to the current completedUnits count, but will not call the callbacks. It will additionally propogate any adjustment in totalUnits to the parents, whose callbacks /will/ be called. This ensures that the total expected counts on the parent are always correct. Without doing this, if, say, a transfer ended earlier than expected, ETA values on the parent would be off since it would be expecting more data than actually arrived. -} finishP :: Progress -> IO () finishP (Progress mp) = modifyMVar_ mp modfunc where modfunc :: ProgressRecord -> IO ProgressRecord modfunc oldpr = do let adjustment = (completedUnits . status $ oldpr) - (totalUnits . status $ oldpr) callParents oldpr (\x -> incrTotal x adjustment) return $ oldpr {status = (status oldpr) {totalUnits = completedUnits . status $ oldpr}} ---------------------------------------------------------------------- -- Updating ---------------------------------------------------------------------- {- | Increment the completed unit count in the 'Progress' object by the amount given. If the value as given exceeds the total, then the total will also be raised to match this value so that the completed count never exceeds the total. You can decrease the completed unit count by supplying a negative number here. -} incrP :: Progress -> Integer -> IO () incrP po count = modStatus po statusfunc where statusfunc s = s {completedUnits = newcu s, totalUnits = if newcu s > totalUnits s then newcu s else totalUnits s} newcu s = completedUnits s + count {- | Like 'incrP', but never modify the total. -} incrP' :: Progress -> Integer -> IO () incrP' po count = modStatus po (\s -> s {completedUnits = completedUnits s + count}) {- | Set the completed unit count in the 'Progress' object to the specified value. Unlike 'incrP', this function sets the count to a specific value, rather than adding to the existing value. If this value exceeds the total, then the total will also be raised to match this value so that the completed count never exceeds teh total. -} setP :: Progress -> Integer -> IO () setP po count = modStatus po statusfunc where statusfunc s = s {completedUnits = count, totalUnits = if count > totalUnits s then count else totalUnits s} {- | Like 'setP', but never modify the total. -} setP' :: Progress -> Integer -> IO () setP' po count = modStatus po (\s -> s {completedUnits = count}) {- | Increment the total unit count in the 'Progress' object by the amount given. This would rarely be needed, but could be needed in some special cases when the total number of units is not known in advance. -} incrTotal :: Progress -> Integer -> IO () incrTotal po count = modStatus po (\s -> s {totalUnits = totalUnits s + count}) {- | Set the total unit count in the 'Progress' object to the specified value. Like 'incrTotal', this would rarely be needed. -} setTotal :: Progress -> Integer -> IO () setTotal po count = modStatus po (\s -> s {totalUnits = count}) ---------------------------------------------------------------------- -- Reading and Processing ---------------------------------------------------------------------- {- | Returns the speed in units processed per time unit. (If you are using the default time source, this would be units processed per second). This obtains the current speed solely from analyzing the 'Progress' object. If no time has elapsed yet, returns 0. You can use this against either a 'Progress' object or a 'ProgressStatus' object. This is in the IO monad because the speed is based on the current time. Example: > getSpeed progressobj >>= print Don't let the type of this function confuse you. It is a fancy way of saying that it can take either a 'Progress' or a 'ProgressStatus' object, and returns a number that is valid as any Fractional type, such as a Double, Float, or Rational. -} getSpeed :: (ProgressStatuses a (IO b), Fractional b) => a -> IO b getSpeed po = withStatus po $ \status -> do t <- timeSource status let elapsed = t - (startTime status) return $ if elapsed == 0 then fromRational 0 else fromRational ((completedUnits status) % elapsed) {- | Returns the estimated time remaining, in standard time units. Returns 0 whenever 'getSpeed' would return 0. See the comments under 'getSpeed' for information about this function's type and result. -} getETR :: (ProgressStatuses a (IO Integer), ProgressStatuses a (IO Rational)) => a -> IO Integer getETR po = do speed <- ((getSpeed po)::IO Rational) if speed == 0 then return 0 else -- FIXME: potential for a race condition here, but it should -- be negligible withStatus po $ \status -> do let remaining = totalUnits status - completedUnits status return $ round $ (toRational remaining) / speed {- | Returns the estimated system clock time of completion, in standard time units. Returns the current time whenever 'getETR' would return 0. See the comments under 'getSpeed' for information about this function's type and result. -} getETA :: (ProgressStatuses a (IO Integer), ProgressStatuses a (IO Rational)) => a -> IO Integer getETA po = do etr <- getETR po -- FIXME: similar race potential here withStatus po $ \status -> do timenow <- timeSource status return $ timenow + etr ---------------------------------------------------------------------- -- Utilities ---------------------------------------------------------------------- {- | The default time source for the system. This is defined as: >getClockTime >>= (return . clockTimeToEpoch) -} defaultTimeSource :: ProgressTimeSource defaultTimeSource = getClockTime >>= (return . clockTimeToEpoch) now :: ProgressRecords a ProgressTimeSource => a -> ProgressTimeSource now x = withRecord x (timeSource . status) modStatus :: Progress -> (ProgressStatus -> ProgressStatus) -> IO () -- FIXME/TODO: handle parents modStatus (Progress mp) func = modifyMVar_ mp modfunc where modfunc :: ProgressRecord -> IO ProgressRecord modfunc oldpr = do let newpr = oldpr {status = func (status oldpr)} mapM_ (\x -> x (status oldpr) (status newpr)) (callbacks oldpr) -- Kick it up to the parents. case (completedUnits . status $ newpr) - (completedUnits . status $ oldpr) of 0 -> return () x -> callParents newpr (\y -> incrP' y x) case (totalUnits . status $ newpr) - (totalUnits . status $ oldpr) of 0 -> return () x -> callParents newpr (\y -> incrTotal y x) return newpr callParents :: ProgressRecord -> (Progress -> IO ()) -> IO () callParents pr func = mapM_ func (parents pr)