Copyright | (c) 2018 Yclept Nemo |
---|---|
License | BSD-style (see LICENSE) |
Maintainer | Stability : unstable |
Portability | unportable |
Safe Haskell | None |
Language | Haskell98 |
Module for tracking master window history per workspace, and associated functions for manipulating the stack using such history.
Synopsis
- newtype MasterHistory = MasterHistory {}
- getMasterHistoryMap :: X (Map WorkspaceId [Window])
- getMasterHistoryFromTag :: WorkspaceId -> X [Window]
- getMasterHistoryCurrent :: X [Window]
- getMasterHistoryFromWindow :: Window -> X [Window]
- modifyMasterHistoryFromTag :: WorkspaceId -> ([Window] -> [Window]) -> X ()
- modifyMasterHistoryCurrent :: ([Window] -> [Window]) -> X ()
- masterHistoryHook :: X ()
- masterHistoryHook' :: Bool -> ([Window] -> [Window] -> [Window]) -> X ()
- updateMasterHistory :: [Window] -> [Window] -> [Window]
- swapPromote :: Bool -> X Bool
- swapPromote' :: Bool -> X ()
- swapIn :: Bool -> X Bool
- swapIn' :: Bool -> X ()
- swapHybrid :: Bool -> X Bool
- swapHybrid' :: Bool -> X ()
- swapApply :: Bool -> (Maybe Window -> Stack Window -> (Bool, Stack Window)) -> X Bool
- swapPromoteStack :: Maybe Window -> Stack Window -> (Bool, Stack Window)
- swapInStack :: Maybe Window -> Stack Window -> (Bool, Stack Window)
- swapHybridStack :: Maybe Window -> Stack Window -> (Bool, Stack Window)
- cycleN :: Int -> [a] -> [a]
- split :: (Num a, Enum a) => (b -> Bool) -> [b] -> ([(a, b)], [b])
- split' :: (Num a, Enum a) => (b -> Bool) -> a -> [b] -> (a, [(a, b)], [b])
- merge :: (Ord a, Num a) => [(a, b)] -> [b] -> [b]
- merge' :: (Ord a, Num a) => a -> [(a, b)] -> [b] -> (a, [(a, b)], [b])
- stackSplit :: (Num a, Enum a, Ord b) => Stack b -> Set b -> ([(a, b)], Stack b)
- stackMerge :: (Ord a, Num a) => Stack b -> [(a, b)] -> Stack b
Usage
Given your configuration file, import this module:
import XMonad.Actions.SwapPromote
First add masterHistoryHook
to your logHook
to track master windows per
workspace:
myLogHook = otherHook >> masterHistoryHook
Then replace xmonad's default promote keybinding with swapPromote'
:
, ((mod1Mask, xK_Return), swapPromote' False)
Depending on your xmonad configuration or window actions the master history may be empty. If this is the case you can still chain another promotion function:
import XMonad.Actions.DwmPromote , ((mod1Mask, xK_Return), whenX (swapPromote False) dwmpromote)
To be clear, this is only called when the lack of master history hindered the swap and not other conditions, such as having a only a single window.
While swapPromote
preserves window focus, swapIn
preserves the focus
position - effectively "swapping" new windows into focus without moving the
zipper. A mix of both, swapHybrid
promotes focused non-master windows
while swapping windows into the focused master. This works well on layouts
with large masters. Both come with chainable variants, see swapIn'
and
swapHybrid'
.
So far floating windows have been treated no differently than tiled windows
even though their positions are independent of the stack. Often, yanking
floating windows in and out of the workspace will obliterate the stack
history - particularly frustrating with Scratchpad
since it is
toggled so frequenty and always replaces the master window. That's why the
swap functions accept a boolean argument; when True
non-focused floating
windows will be ignored.
All together:
, ((mod1Mask, xK_Return), whenX (swapHybrid True) dwmpromote)
newtype MasterHistory Source #
Mapping from workspace tag to master history list. The current master is the head of the list, the previous master the second element, and so on. Without history, the list is empty.
Instances
Read MasterHistory Source # | |
Defined in XMonad.Actions.SwapPromote readsPrec :: Int -> ReadS MasterHistory # readList :: ReadS [MasterHistory] # | |
Show MasterHistory Source # | |
Defined in XMonad.Actions.SwapPromote showsPrec :: Int -> MasterHistory -> ShowS # show :: MasterHistory -> String # showList :: [MasterHistory] -> ShowS # | |
ExtensionClass MasterHistory Source # | |
Defined in XMonad.Actions.SwapPromote |
State Accessors
getMasterHistoryMap :: X (Map WorkspaceId [Window]) Source #
Return the master history map from the state.
getMasterHistoryFromTag :: WorkspaceId -> X [Window] Source #
Return the master history list of a given tag. The master history list may be empty. An invalid tag will also result in an empty list.
getMasterHistoryCurrent :: X [Window] Source #
Return the master history list of the current workspace.
getMasterHistoryFromWindow :: Window -> X [Window] Source #
Return the master history list of the workspace containing the given window. Return an empty list if the window is not in the stackset.
modifyMasterHistoryFromTag :: WorkspaceId -> ([Window] -> [Window]) -> X () Source #
Modify the master history list of a given workspace, or the empty list of no such workspace is mapped. The result is then re-inserted into the master history map.
modifyMasterHistoryCurrent :: ([Window] -> [Window]) -> X () Source #
Modify the master history list of the current workspace. While the current
workspace is guaranteed to exist; its master history may not. For more
information see modifyMasterHistoryFromTag
.
Log Hook
masterHistoryHook :: X () Source #
A logHook
to update the master history mapping. Non-existent workspaces
are removed, and the master history list for the current workspaces is
updated. See masterHistoryHook'
.
Log Hook Building Blocks
:: Bool | If |
-> ([Window] -> [Window] -> [Window]) | Function used to update the master history list of
the current workspace. First argument is the master
history, second is the integrated stack. See
|
-> X () |
Backend for masterHistoryHook
.
Given the current master history list and an integrated stack, return the new master history list. The current master is either moved (if it exists within the history) or added to the head of the list, and all missing (i.e. closed) windows are removed.
Actions
swapPromote :: Bool -> X Bool Source #
Wrap swapPromoteStack
; see also swapApply
.
swapPromote' :: Bool -> X () Source #
Like swapPromote'
but discard the result.
swapHybrid :: Bool -> X Bool Source #
Wrap swapHybridStack
; see also swapApply
.
swapHybrid' :: Bool -> X () Source #
Like swapHybrid'
but discard the result.
Action Building Blocks
swapApply :: Bool -> (Maybe Window -> Stack Window -> (Bool, Stack Window)) -> X Bool Source #
Apply the given master history stack modifier to the current stack. If
given True
, all non-focused floating windows will be ignored. Return
True
if insufficient history; if so use whenX
to sequence a backup
promotion function.
swapPromoteStack :: Maybe Window -> Stack Window -> (Bool, Stack Window) Source #
If the focused window is the master window and there is no previous master, do nothing. Otherwise swap the master with the previous master. If the focused window is not the master window, swap it with the master window. In either case focus follows the original window, i.e. the focused window does not change, only its position.
The first argument is the previous master (which may not exist), the second
a window stack. Return True
if the master history hindered the swap; the
history is either empty or out-of-sync. Though the latter shouldn't happen
this function never changes the stack under such circumstances.
swapInStack :: Maybe Window -> Stack Window -> (Bool, Stack Window) Source #
Perform the same swap as swapPromoteStack
. However the new window
receives the focus; it appears to "swap into" the position of the original
window. Under this model focus follows stack position and the zipper does
not move.
See swapPromoteStack
for more details regarding the parameters.
swapHybridStack :: Maybe Window -> Stack Window -> (Bool, Stack Window) Source #
If the focused window is the master window, use swapInStack
. Otherwise use
swapPromoteStack
.
See swapPromoteStack
for more details regarding the parameters.
List Utilities
cycleN :: Int -> [a] -> [a] Source #
Cycle a list by the given count. If positive, cycle to the left. If negative, cycle to the right:
>>>
cycleN 2 [1,2,3,4,5]
[3,4,5,1,2]>>>
cycleN (-2) [1,2,3,4,5]
[4,5,1,2,3]
split :: (Num a, Enum a) => (b -> Bool) -> [b] -> ([(a, b)], [b]) Source #
Wrap split'
with an initial index of 0
, discarding the list's length.
split' :: (Num a, Enum a) => (b -> Bool) -> a -> [b] -> (a, [(a, b)], [b]) Source #
Given a predicate, an initial index and a list, return a tuple containing:
- List length.
- Indexed list of elements which satisfy the predicate. An indexed element is a tuple containing the element index (offset by the initial index) and the element.
- List of elements which do not satisfy the predicate.
The initial index and length of the list simplify chaining calls to this function, such as for zippers of lists.
merge :: (Ord a, Num a) => [(a, b)] -> [b] -> [b] Source #
Wrap merge'
with an initial virtual index of 0
. Return only the
unindexed list with elements from the leftover indexed list appended.
merge' :: (Ord a, Num a) => a -> [(a, b)] -> [b] -> (a, [(a, b)], [b]) Source #
Inverse of split
. Merge an indexed list with an unindexed list (see
split'
). Given a virtual index, an indexed list and an unindexed list,
return a tuple containing:
- Virtual index after the unindexed list
- Remainder of the indexed list
- Merged unindexed list
If the indexed list is empty, this functions consumes the entire unindexed
list. If the unindexed list is empty, this function consumes only adjacent
indexed elements. For example, [(10,"ten"),(12,"twelve")]
implies missing
unindexed elements and so once (10,"ten")
is consumed this function
concludes.
The indexed list is assumed to have been created by split'
and not checked
for correctness. Indices are assumed to be ascending, i.e.
> [(1,"one"),(2,"two"),(4,"four")]
The initial and final virtual indices simplify chaining calls to the this function, as as for zippers of lists. Positive values shift the unindexed list towards the tail, as if preceded by that many elements.
Stack Utilities
stackSplit :: (Num a, Enum a, Ord b) => Stack b -> Set b -> ([(a, b)], Stack b) Source #
Remove all elements of the set from the stack. Skip the currently focused
member. Return an indexed list of excluded elements and the modified stack.
Use stackMerge
to re-insert the elements using this list.
stackMerge :: (Ord a, Num a) => Stack b -> [(a, b)] -> Stack b Source #
Inverse of stackSplit
. Given a list of elements and their original
indices, re-insert the elements into these same positions within the stack.
Skip the currently focused member. Works best if the stack's length hasn't
changed, though if shorter any leftover elements will be tacked on.