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|
\input texinfo @c -*-texinfo-*-
@c %**start of header
@setfilename blueshift.info
@settitle blueshift
@afourpaper
@documentencoding UTF-8
@documentlanguage en
@finalout
@c %**end of header
@c --- start of do not touch ---
@set DOCDIR /usr/share/doc
@set PKGNAME blueshift
@c --- end of do not touch ---
@dircategory Ergonomy
@direntry
@c * blueshift: (blueshift). Automatically adjust the colour temperature
* blueshift: (blueshift). The grand unified dynamic colour adjustment framework
@end direntry
@copying
Copyright @copyright{} 2014 Mattias Andrée
@quotation
Permission is granted to copy, distribute and/or modify this document
under the terms of the GNU Free Documentation License, Version 1.3 or
any later version published by the Free Software Foundation; with no
Invariant Sections, with no Front-Cover Texts, and with no Back-Cover
Texts. A copy of the license is included in the section entitled
``GNU Free Documentation License''.
@end quotation
@end copying
@ifnottex
@node Top
@c @top blueshift -- Automatically adjust the colour temperature
@top blueshift -- The grand unified dynamic colour adjustment framework
@insertcopying
@end ifnottex
@titlepage
@title blueshift
@c @subtitle Automatically adjust the colour temperature
@subtitle The grand unified dynamic colour adjustment framework
@author by Mattias Andrée (maandree)
@page
@center `The possibilities are... like endless.' -- Scootaloo
@vskip 0pt plus 1filll
@insertcopying
@end titlepage
@contents
@menu
* Overview:: Brief overview of @command{blueshift}.
* Invoking:: Invocation of @command{blueshift}.
* Signals:: Signals handled by @command{blueshift}.
* Configuration API:: How to write configuration files.
* Configuration examples:: Example configuration files.
* Related software:: Software related to @command{blueshift}.
* Terminology:: Related terminology.
* GNU Free Documentation License:: Copying and sharing this manual.
@end menu
@node Overview
@chapter Overview
Inspired by Redshift, Blueshift adjusts the colour
temperature of your monitor according to brightness
outside to reduce eye strain and make it easier to
fall asleep when going to bed. It can also be used
to increase the colour temperature and make the
monitor bluer, this helps you focus on your work.
Blueshift is not user friendly and it is not
meant to be. Blueshift does offer limited
use of command line options to apply settings,
but it is really meant for you to have configuration
files (written in Python 3) where all the policies
are implemented, Blueshift is only meant to provide
the mechanism for modifying the colour curves.
Blueshift neither provides any means of automatically
getting your geographical position; the intention is
that you should implement that in the policy yourself
using library which can do that. Additionally
Blueshift provides not safe guards from making your
screen unreadable or otherwise miscoloured; and
Blueshift will never, officially, add support
specifically for any proprietary operating system.
Blueshift is fully extensible so it is possible to
make extensions that make it usable under unsupported
systems, the base code is written in Python 3 without
calls to any system dependent functions.
If Blueshift does not work for you for any of these
reasons, you should take a look at Redshift.
@node Invoking
@chapter Invoking
Blueshift uses argparser to read options from the
commnad line. It inherits a few properaties from this:
abbreviations are supported, you only need to type the
beginning of the long options so that the rest can
be filled in unambiguously by the program; @option{--}
can be used, as usual, to make all following options
being parsed as just arguments; and @option{++} works
like @option{--}, except it only allied to the next
option. Any argument that is not parsed as an option
for Blueshift is passed onto the configuration script.
Blueshift recognises the following options:
@table @option
@item -c
@itemx --configurations FILE
Select configuration script. This defaults to the
first file of the following the exists:
@itemize @bullet
@item @file{$XDG_CONFIG_HOME/blueshift/blueshiftrc}
@item @file{$HOME/.config/blueshift/blueshiftrc}
@item @file{$HOME/.blueshiftrc}
@item @file{/etc/blueshiftrc}
@end itemize
Blueshift does not check the user home, rather it
checks @env{HOME} which should be the user home, unless
you change it yourself.
You update the configuration file you can send a
SIGUSR1 signal to reload it.
@item -p @c the long name of option is inspired from openntpd
@itemx --panic-gate
@itemx --panicgate
Applies the settings directly instead of transitioning
into the initial settings. There is not option for doing
this when the program exists. But you press @kbd{Control+c}
twice, or send SIGTERM twice, to skip transition into
default settings.
@item -h
@itemx -?
@itemx --help
Prints help information.
@item -C
@itemx --copying
@itemx --copyright
Prints copyright information.
@item -W
@itemx --warranty
Prints non-warranty information,
included in the copyright information.
@item -v
@itemx --version
Prints the name of the program and the
installed version of the program
@end table
Blueshift also supports a few options
for ad-hoc settings. These are ignored
(unless fetched by the configuration file)
if @option{-c} (@option{--configurations})
is used.
@table @option
@item -g
@itemx --gamma RGB
Apply gamma correction to the colour curves.
All values in the three colour curves are raised
to the power of 1 divided by @code{RGB}. Assuming
no values in the curves are larger than 1 (100 %)
the curves are bent upwards if @code{RGB} is larger
than 1.
@item -g
@itemx --gamma R:G:B
This works as @option{--gamma RGB}, except the
gamma is applied separately for the three colour
curves. If we want to apply the 0,9 gamma to the
red colour component, and 1,1 and 1,2 for the
green and blue colour components, respectively use
@option{-g 0.9:1.1:1.2} or @option{-gamma 0.9:1.1:1.2}.
@item -b
@itemx --brightness RGB
This multiplies all values in the colour curves
with @env{RGB}, effectively making the display
@env{RGB} times as bright. Values larger than 1,
will be clipped to 1. This is indented to be used
to make the screen slightly darker during the night.
@item -b
@itemx --brightness R:G:B
This option is to @option{--brightness RGB} as
@option{--gamma R:G:B} is to @option{--gamma RGB}.
@item +b
@itemx ++brightness Y
This option works as @option{--brightness RGB},
except the CIE xyY colour spaces is used instead
of sRGB and will probably make the colour curves
look better.
@item -t
@itemx --temperature TEMP
Changes the colour tempurature to @code{TEMP}
Kelvin. The standard colour tempurature is
6500 K@footnote{Or actually 6504 K using revised
constants in Planck's law}. If not specified,
the colour temperature will be 3700 K during
high night and 6500 K during the high day.
@item -l
@itemx --location LAT:LON
Specify your geographical coordinates. This
is used to determine how dark it is outside.
@env{LAT} is the latitude, floating point
measured in degrees celestial northwards from
the equator. It is negative if you are on the
southern hemisphere. @env{LON} is the
longitude, floating point measured in degrees
eastwards from Greenwich. Negative if you
are on the west side of the Earth.
@item -r
@itemx --reset
Transition from the specified settings to
normal, clean, settings.
@item -o
@itemx --output
@itemx --crtc CRTC
Select CRTC to apply changes to. This is
comma separated list, and multiple options
may be used. It is best to start one
instance per monitor with colour calibration.
Be aware than under X — using the Resize and
Rotate (RandR) extension@footnote{Don't be
fooled by the name, it can actually do anything
that has to do with monitor control.} — the
primary monitor is reported to have the zeroth
CRTC. But under TTY — using DRM — this is no
concept of primary monitors, and thus the CRTC
indices can slightly different.
@end table
@option{-g}, @option{-b}, @option{+b}, and
@option{-t} can be use twice, each, to use
different settings during the night and during
the day. While this is possible for gamma,
it is not recommended. The purpose of gamma
is to adjust the same error that are present
in minors and make all colours look correct
in relation to each other.
@node Signals
@chapter Signals
@command{blueshift}, by default in continuous
mode, implements special support for three
signals:
@table @asis
@item SIGTERM
Fades out the settings and exits the first
time SIGTERM is received. If SIGTERM is
received again, Blueshift immediately
resets effects and exits.
@kbd{Control+c} is treated as SIGTERM.
@item SIGTSTP
@itemx SIGCONT
Blueshift does implement special handling
of the termporary stop signal (SIGTSTP),
or continue signal (SIGCONT). So if you send
SIGTSTP to Blueshift it pause until you send
SIGCONT.
With usual TTY settings, the terminal sends
SIGTSTP when @kbd{Control+z} is processed.
Shells can send SIGCONT if you type either
of @code{%}, @code{fg}, @code{%blueshift} or
@code{fg blueshift}. @code{bg} or
@code{bg blueshift} can be used to continue
in the background instead of in the foreground.
@item SIGUSR1
Reloads the configuration script.
@item SIGUSR2
Disables or enables Blueshift.
@end table
@node Configuration API
@chapter Configuration API
@menu
* Configuration variables:: Configuration variables.
* Colour curve manipulators:: Configuration functions colour adjustments.
* Custom colour curve manipulators:: Creating custom colour adjustment functions.
* Preexisting adjustments:: Using preexisting adjustment, in use and ICC.
* Applying colour curves:: Appying colour adjustments to the video drivers.
* Hardware detection:: Detecting connected monitors.
* Backlight:: Adjusting monitor backlight.
* Continuous mode:: Creating continuous mode configurations.
* Solar time:: Solar functions, such as elevation calcuation.
* Weather:: Making weather dependent settings.
* Running without X:: Configuration options for running without X.
* Optimising:: Functions that can be used to optimise performance.
* Interpolation:: Interpolation functionised curves.
* Temperature constants:: Predefined colour temperature values.
@end menu
@node Configuration variables
@section Configuration variables
Blueshift has three colour curves:
@table @code
@item r_curve
The curve for the red colour component.
@item g_curve
The curve for the green colour component.
@item b_curve
The curve for the blue colour component.
@end table
These are @code{i_size} sized floating point
lists, where 0 is the darkest colour and 1
is the brightest colour. Values outside this
range are clipped unless @code{clip_result}
is set to @code{False}. By calling @code{clip}
this clipping is done independently of the value
of @code{clip_result}. @code{clip} optionally
takes one or three arguments, if one, nothing
will happen if it is @code{False}, if three,
nothing will happen for the red, green and
blue colour curves if the first, second and
third arguments, respectively, is @code{False}.
When applied these values are automatically
translated to appropriate integer values:
[0, @code{o_size} - 1].
Additionally if the variable @code{panicgate}
is @code{True}, there is no fading when the program
starts. And @code{conf_opts} is a list of command line
arguments passed onto the configuration script; and
@code{conf_storage} is a dictionary can be used to
store information is required to survive a
configuration reload, such as replaced functions.
If you want to use the settings intended for ad-hoc
mode, set @code{uses_adhoc_opts} to @code{True}. This
lets you use @code{parser}, which is an instance of
@code{ArgParser} (from the argparser library) which
@code{parser} and @code{support_alternatives} already
invoked, without a warning being printed. If you do
not do this, @code{parser} will be @code{None} at the
time @code{periodically} is first invoked by Blueshift.
@node Colour curve manipulators
@section Colour curve manipulators
Blueshift provides a set of functions to
manipulate these curves:
@table @code
@item rgb_contrast(rgb)
Adjusts the contrast to @code{rgb}. This
function assumes the black is 0, and white
is 1, so you should apply this before brightness.
Note: This does not correspond to the contrast
on monitors control panels used to calibrate
the white point.
@item rgb_contrast(r, g, b)
Adjusts the contrast to @code{r}, @code{g}
and @code{b} on the red, green and blue colour
curves, respectively. This function assumes the
black is 0, and white is 1, so you should apply
this before brightness.
Note: This does not correspond to the contrast
on monitors control panels used to calibrate
the white point.
@item cie_contrast(rgb)
Adjusts the contrast to @code{rgb}.
The function calculate the values by using
the CIE xyY colour space instead of the sRGB
colour space. This function assumes the black
is 0, and white is 1, so you should apply
this before brightness.
Note: This does not correspond to the contrast
on monitors control panels used to calibrate
the white point.
@item cie_contrast(r, g, b)
Adjusts the contrast to @code{r}, @code{g}
and @code{b} on the red, green and blue
colour curves, respectively.
The function calculate the values by using
the CIE xyY colour space instead of the sRGB
colour space. This function assumes the black
is 0, and white is 1, so you should apply
this before brightness.
Note: This does not correspond to the contrast
on monitors control panels used to calibrate
the white point.
@item rgb_brightness(rgb)
Adjusts the brightness to @code{rgb}.
Note: This does not correspond to the contrast
on monitors control panels used to calibrate
the white point.
Note: This does not correspond to the brightness
on monitors control panels used to calibrate
the black point point, rather it corresponds
to the contrast on monitors control panels
used to calibrate white point.
@item rgb_brightness(r, g, b)
Adjusts the brightness to @code{r}, @code{g}
and @code{b} on the red, green and blue colour
curves, respectively.
Note: This does not correspond to the brightness
on monitors control panels used to calibrate
the black point point, rather it corresponds
to the contrast on monitors control panels
used to calibrate white point.
@item cie_brightness(rgb)
Adjusts the brightness to @code{rgb}.
The function calculate the values by using
the CIE xyY colour space instead of the sRGB
colour space.
Note: This does not correspond to the brightness
on monitors control panels used to calibrate
the black point point, rather it corresponds
to the contrast on monitors control panels
used to calibrate white point.
@item cie_brightness(r, g, b)
Adjusts the brightness to @code{r}, @code{g}
and @code{b} on the red, green and blue
colour curves, respectively.
The function calculate the values by using
the CIE xyY colour space instead of the sRGB
colour space.
Note: This does not correspond to the brightness
on monitors control panels used to calibrate
the black point point, rather it corresponds
to the contrast on monitors control panels
used to calibrate white point.
@item linearise()
Converts the colour curves from sRGB to
linear RGB. sRGB is the default colour space.
@item linearise(rgb)
Converts the colour curves from sRGB to
linear RGB if @code{rgb} is @code{True}.
sRGB is the default colour space.
@item linearise(r, g, b)
Converts the colour curves from sRGB to
linear RGB, but only for the red, green
and blue colour curves if @code{red},
@code{green}, @code{blue} is @code{True},
respectively. sRGB is the default colour
space.
@item standardise()
Converts the colour curves from linear RGB to
sRGB, the default colour space.
@item standardise(rgb)
Converts the colour curves from linear RGB to
sRGB, the default colour space, if @code{rgb}
is @code{True}.
@item standardise(r, g, b)
Converts the colour curves from linear RGB to
sRGB, the default colour space, but only for
the red, green and blue colour curves if
@code{red}, @code{green}, @code{blue} is
@code{True}, respectively.
@item gamma(rgb)
Adjusts the gamma to @code{rgb}.
@item gamma(r, g, b)
Adjusts the gamma to @code{r}, @code{g} and
@code{b} on the red, green and blue colour
curves, respectively.
@item negative()
Reverse the colour curves on the encoding axis.
This creates a negative image with preserved gamma.
@item negative(rgb)
Reverse the colour curves on the encoding axis
if @code{rgb} is @code{True}.
@item negative(r, g, b)
Reverse the red, green and blue colour curves
on the encoding axis if @code{r}, @code{g} and
@code{b} are @code{True}, respectively.
@item rgb_invert()
Inverts the all values on the colour curves.
This creates a negative image with inverted gamma.
@item rgb_invert(rgb)
Inverts the all values on the colour curves
if @code{rgb} is @code{True}.
@item rgb_invert(r, g, b)
Inverts the all values on the red, green and
blue colour curves if @code{r}, @code{g} and
@code{b} are @code{True}, respectively.
@item cie_invert()
Inverts the all values on the colour curves
using the CIE xyY colour space instead of sRGB.
@item cie_invert(rgb)
Inverts the all values on the colour curves
using the CIE xyY colour space instead of sRGB,
if @code{rgb} is @code{true}.
@item cie_invert(r, g, b)
Inverts the all values on the red, green and
blue colour curves using the CIE xyY colour
space instead of sRGB if @code{r}, @code{g} and
@code{b} are @code{True}, respectively.
@item sigmoid(rgb)
An inverted sigmoid curve function is applied
to the values of in colour curves if @code{rgb}
is not @code{None}, @code{rgb} is the sigmoid
curve multiplier.
@item sigmoid(r, g, b)
An inverted sigmoid curve function is applied
to the values of in the red, green and blue
colour curves if @code{r}, @code{g} and @code{b}
are not @code{None}, respectively. @code{r},
@code{g} and @code{b} are the sigmoid curve
multipliers for the red, green and blue colour
curves, respectively.
@item rgb_limits(rgb_min, rgb_max)
Changes the black point to @code{rgb_min}, and
the white point to @code{rgb_max}.
@code{rgb_min} corresponds to the brightness
on monitor control panels used to calibrate the
black point. @code{rgb_max} corresponds to the
contrast on monitor control panels used to
calibrate the white point.
@item rgb_limits(r_min, r_max, g_min, g_max, b_min, b_max)
Changes the black point to (@code{r_min},
@code{g_min}, @code{b_min}), and the white
point to (@code{r_max}, @code{g_max}, @code{b_max}).
@item cie_limits(rgb_min, rgb_max)
Changes the black point to @code{rgb_min}, and
the white point to @code{rgb_max}, using the
CIE xyY colour space instead of sRGB.
@item cie_limits(r_min, r_max, g_min, g_max, b_min, b_max)
Changes the black point to (@code{r_min},
@code{g_min}, @code{b_min}), and the white
point to (@code{r_max}, @code{g_max},
@code{b_max}), using the CIE xyY colour space
instead of sRGB.
@item manipulate(rgb)
Applies the function @code{rgb} : float
@click{} float to the colour curves.
Nothing is done if @code{rgb} is @code{None}.
@item manipulate(r, g, b)
Applies the functions @code{r}, @code{g} and
@code{b} : float @click{} float to the red, green
and blue colour curves, respectively.
Nothing is done for the red, green and blue
colour curves if @code{red}, @code{green} and
@code{blue} are @code{None}, respectively.
@item cie_manipulate(rgb)
Applies the function @code{rgb} : float @click{}
float to Y component (illumination) of the colour
curves when converted to CIE xyY.
Nothing is done if @code{rgb} is @code{None}.
@item cie_manipulate(r, g, b)
Applies the function @code{r}, @code{g} and
@code{b} : float @click{} float to Y component
(illumination) of the red, green and blue colour
curves, respectively, when converted to CIE xyY.
Nothing is done for the red, green and blue
colour curves if @code{red}, @code{green} and
@code{blue} are @code{None}, respectively.
@item temperature(temperature, algorithm)
Applies the a blackbody colour temperature of
@code{temperature}@footnote{Actually multiplied
by 1,000556328, due to revisions of natural
constants.} Kelvin. Where the white point
for that temperature is calculates by
the function @code{algorithm} : @code{temperature}
@click{} (red, green, blue). When the white
point has been calculates, its components
are used as parameters in a componentwise
brightness adjustment.
There are a few algorithm for calculating the
white point included:
@table @code
@item series_d(temperature)
Can only calculate the white point correctly for
temperatures inside [4000, 25000]. The CIE illuminant
series D is used to calculate the white point.
@item simple_whitepoint(temperature)
Can only calculate the white point accurately for
temperatures inside [1000, 40000]. A mathematical
model of the @code{cmf_10deg} function is used.
@item cmf_2deg(temperature)
Uses a lookup table with linear interpolation to
calculate temperatures inside [1000, 40000].
CIE 1931 2 degree CMF is used.
@item cmf_10deg(temperature)
Uses a lookup table with linear interpolation to
calculate temperatures inside [1000, 40000].
CIE 1964 10 degree CMF is used. This is the
preferred algorithm.
@item redshift(temperature, old_version, linear_interpolation = False)
Uses the lookup table from Redshift with linear
interpolation. If @code{old_version} is @code{True}
the table Redshift<=1.8 is used, which is limited
to [1000, 10000], and is not that accurate. Otherwise
(the default) the table from Redshift>1.8 is used,
which is limited to [1000, 25100], and is accurate.
If @code{linear_interpolation} is @code{False}
(the default) the sRGB colour space is used for
interpolation, otherwise linear RGB is used.
@end table
Some of these algorithms (including @code{cmf_10deg})
are not very good by themself and should be wrapped
with @code{divide_by_maximum} or @code{clip_whitepoint}
((red, green, blue) @click{} (red, green, blue) functions.)
For example, instead of using @code{cmf_10deg}, you can use
@code{lambda t : clip_whitepoint(divide_by_maximum(cmf_10deg(t)))}.
@item rgb_temperature(temperature, algorithm)
This function is a synonym for @code{temperature}.
@item cie_temperature(temperature, algorithm)
This works the same way as @code{temperature},
except that subpixel brightness adjustment is
done in CIE xyY colour space rather than sRGB.
You probability do not want to use this variant
of @code{temperature}.
@item lower_resolution(x, y)
Emulate low resolution. @code{x} is the number of
colours to emulate that each subpixel can have.
@code{y} does the same thing as @code{x}, except
on the output axis rather than the encoding axis.
For arguments taht are set to @code{None}, the
default value will be used.
@item lower_resolution(rx, ry, gx, gy, bx, by)
This works the same way as @code{lower_resolution(x, y)},
except the subpixels are controlled individually.
@code{rx} and @code{ry} are @code{x} and @code{y}
for the red subpixel, and analogously for @code{gx}
and @code{gy} for green, and @code{bx} and @code{by}
for blue. For arguments taht are set to @code{None},
the default value will be used.
@end table
Keep in mind that the order your call the
function matters. For example, adjusting
the gamma before the brightness does not
yeild the same result as in the reverse
order, the latter is the correct way to
apply gamma correction.
Before performing adjusts you must (not required
the very first time) reset the curves by invoking
@code{start_over} (no parameters.) Otherwise the
adjustments will accumulate.
@node Custom colour curve manipulators
@section Custom colour curve manipulators
If you want to write your own functions
@code{curves(r, g, b)} returns a tuple
containing the tuples @code{(r_curve, r)},
@code{(g_curve, g)} and @code{(b_curve, b)}.
To make this easier Blueshift provies a set
of functions used to convert colour space:
@table @code
@item linear_to_standard(r, g, b)
Convert [0, 1] linear RGB to [0, 1] sRGB
@item standard_to_linear(r, g, b)
Convert [0, 1] sRGB to [0, 1] linear RGB
@item ciexyy_to_ciexyz(x, y, Y)
Convert CIE xyY to CIE XYZ
@item ciexyz_to_ciexyy(X, Y, Z)
Convert CIE XYZ to CIE xyY
@item ciexyz_to_linear(X, Y, Z)
Convert CIE XYZ to [0, 1] linear RGB
@item linear_to_ciexyz(r, g, b)
Convert [0, 1] linear RGB to CIE XYZ
@item srgb_to_ciexyy(r, g, b)
Convert [0, 1] sRGB to CIE xyY
@item ciexyy_to_srgb(x, y, Y)
Convert CIE xyY to [0, 1] sRGB
@item ciexyz_to_cielab(x, y, z)
Convert CIE XYZ to CIE L*a*b*
@item cielab_to_xiexyz(l, a, b)
Convert CIE L*a*b* to CIE XYZ
@end table
All these functions return lists with
the three colour components, not tuples.
Input and output is one colour instance.
If you want to calculated the distance (difference)
between two colours, you can use @code{delta_e}. It
has two parameters, each is red–green–blue-tuple of
an sRGB colour. The just notice difference is circa
2,3.
@node Preexisting adjustments
@section Preexisting adjustments
If you have an ICC profile for calibration (applied last)
or want to use one for as a video filter (applied first),
the function @code{load_icc} can be used to load an ICC
profile file. @code{load_icc} takes one argument, the
pathname of the ICC profile file; the function returns
a fuction that can be invoked to apply the profile.
Alternatively, you can use either of the functions:
@table @code
@item parse_icc(data)
Parse raw (series of bytes) ICC profile data into a function
that applies the profile when invoked.
@item get_current_icc_raw()
@itemx get_current_icc_raw(display)
Load the raw data for the currently applied ICC profiles,
stored on the X server. This function returns a list of
3-tuples, each tuple contains the index of a screen,
the index of a monitor and the raw data (series of bytes)
of the ICC profile for indicated monitor on the indicated
screen. Monitors without profiles are not listed.
Associated ICC profile is mapped as properties of the
root window of X screens. The ICC profile of a primary
monitor in a screen is saved as a property named
@var{_ICC_PROFILE}, the secondary monitor is stored as
@var{_ICC_PROFILE_1}, the tertiary monitor is stored as
@var{_ICC_PROFILE_2}, and so on.
If @code{display} is not specified or is @code{None},
the current X display will be used. Otherwise, the
display indicated by @code{display} will be used.
@item get_current_icc()
@itemx get_current_icc(display)
This function works like @code{get_current_icc_raw}, except
rather than returning raw profile data it returns functions
that apply the profiles when invoked.
If @code{display} is not specified or is @code{None},
the current X display will be used. Otherwise, the
display indicated by @code{display} will be used.
@end table
If you have multiple profiles you want to interpolate
or want to, possible with an interpolation, apply a
profile partially, that is, interpolate between it an
an identity profile, you can use the function
@code{make_icc_interpolation}. It takes your profiles
as one argument, as a list, and outputs a function
that applies an interpolation of the profiles,
it takes to arguments: the timepoint and the filter
alpha. The timepoint is normally a [0, 1] floating point
of the dayness level, this means that you only have two
ICC profiles, but you have multiple profiles, in such
case profile the floor of the timepoint value is takes
as the index of the first profile to use in the
interpolation as well as the following profile (first
profile if the last profile was select). They are
interpolated linearly. The filter alpha is a [0, 1]
floating point of the degree to which the profile should
be applied.
If you want to apply your adjustments on top of the
current colour adjustments, you can use the functions
@code{randr_get} or @code{vidmode_get}. @code{randr_get}
and @code{vidmode_get} have three optional parameters:
@code{crtc}, @code{screen} and @code{display}, which are
the CRTC of the monitor to read from, the screen to which
the monitor belongs and the X display to use, respectively.
The functions return a parameterless function that applies
adjustsments that were applied at the time of invocation
of @code{randr_get} or @code{vidmode_get} to the current
working curves. If not specified, the zeroth (primary) CRTC,
the zeroth screen and the current X display is used, for
@code{crtc}, @code{screen} and @code{display} respectively.
The current X display is also used if @code{display} is
@code{None}.
@node Applying colour curves
@section Applying colour curves
To apply a colour curve to the display
server, invoke the @code{randr} function, or
@code{vidmode}@footnote{@code{vidmode} has
the same API as @code{randr}, but it only
supports using the zeroth CRTC.};
@code{print_curves} can be used to print
the curves to stdout instead (for debugging).
These functions apply the curves to all
monitors in the default screen (screen 0),
but you can also use select monitors by
specifying each monitor in as separate
arguments. The monitors are indexed from
zero. The screen by can be selected by
adding the argument @code{screen = X},
where @code{X} is the index of the screen,
also indexed from zero. Additionally,
you can add the argument @code{display = X},
where @code{X} is the X display to use,
or @code{None} (default) for the current
X display. @code{print_curves} has a fourth
optional parameter: @code{compact}, if it
is set to @code{True}, the curves will be
printed with run-length encoding.
If you want to write your own curve flushing
fucntion @code{translate_to_integers} can be
used, it returned the colour curves converted
from floating point lists to integer lists in
a tuple of three (red, green and blue.) Replace
the parameterless function @code{close_c_bindings}
to make it free all used resource, this is
invoked when Blueshift exits.
When Blueshift exists, it invoked the
parameterless function @code{reset} which
you should replace. By default it resets
the colour curves and flushes it to all
monitors. To restrict which monitors it
applies the changes to replace
@code{monitor_controller} with a parameterless
function that sends the colour curves to
the desired monitors to the display server.
This is only done if Blueshift runs in
continuous mode.
@node Hardware detection
@section Hardware detection
To support multiple monitors in a dynamic way,
the function @code{list_screens} can be used.
@code{list_screens} has two optional parameters
and returns the an instance of the class
@code{Screens}. Instances of @code{Screens} have
one variable: @code{screens}, a list of instances
of the class @code{Screen}. The index of each
screens is their index in @code{screens}.
@code{list_screens}'s first parameter,
@code{method}, selects the method and defaults
to `randr', it also supports the method `drm'.
Its second parameters, @code{display}, is no
effect if `drm' is used for @code{method}, but
otherwise selects the X display to use. If
@code{display} is @code{None}, or is not
specified, the current X display will be used.
Instances of the class @code{Screen} have two
variables: @code{crtc_count}, the number of CRT
controllers used within the screen, and
@code{outputs}, a list of all output ports as
instances of the class @code{Output}. Instances
of @code{Output} have six variables:
@table @code
@item name
The name of the output port.
@item connected
Whether the output is known to be connected
to a monitor.
@item widthmm
The physical width of the monitor, measured
in millimetres. @code{None} if unknown, not
defined or if not connected.
@item heightmm
The physical height of the monitor, measured
in millimetres. @code{None} if unknown, not
defined or if not connected.
@item crtc
The CRT controller index. @code{None} if not
connected.
@item screen
The screen index. @code{None} if not used.
@item edid
The extended display identification data of
the monitor in lower case hexadecimal representations.
@code{None} if not used or not found. If the monitor
is used it is probably found because it is needed
for plug and play support of the monitor.
@end table
The width and height are unknown if the monitor
does not specify them in the EDID if using DRM.
They are not defined the output is a projector.
If using RandR this values are probably not
correct, but the EDID can be parsed, which is
want is done by DRM. The EDID can only specify
whole centrimeters up to 255 cm.
@code{Screens} and @code{Screen} provide a set
of functions for finding the output, and traversal
the CRTC and screen, a monitor is connected to:
@table @code
@item find_by_crtc(index)
Matches outputs by CRTC index. If @code{index}
is @code{None}, it will find unused outputs.
@item find_by_name(name)
Matches outputs by output name.
@item find_by_size(widthmm, heightmm)
Matches outputs by physical size of the monitor.
@code{widthmm} and @code{heightmm} are the
monitor's physical width and heigth, respectively,
measured in millimetres. IF @code{widthmm} and
@code{heightmm} are @code{None} it will find
unused outputs and outputs whether the monitor's
size is unknown.
@item find_by_connected(status)
Matches outputs that are known to be in used
(if @code{status} is @code{True}) or outputs
that are either unused or not known whether
they are used or not (if @code{status} is
@code{False}.)
@item find_by_edid(name)
Matches outputs by monitor extended display
identification data.
@end table
These functions returns a list of matching
@code{Output}:s. The list is empty if non are
found.
Using the class @code{EDID} it is possible to
parse the extended display identification data
of an output. @code{EDID} as a constructor that
takes one argument: the EDID as stored by
@code{Output} in its variable @code{edid}.
This class can only parse EDID structure revision
1.3, which is way all monitors produced 2000 or
later should use. If the supplied EDID does
not meet this requirement an exception will be
raised by the constructor.
An instance of @code{EDID} currently have
the following variables:
@table @code
@item widthmm
The physical width of the monitor, measured
in millimetres. @code{None} if not, e.g. a
projector. This value is between 10 mm and 2550
mm inclusively and is always zero modulo 10 mm.
@item heightmm
The physical height of the monitor, measured
in millimetres. @code{None} if not, e.g. a
projector. This value is @code{None} exactly
when the value of @code{widthmm} is @code{None}.
This value is between 10 mm and 2550 mm
inclusively and is always zero modulo 10 mm.
@item gamma
The monitor's estimated gamma characteristics,
@code{None} if not specified. The range of this
value is 1,00 to 3,55 inclusively, with a
precision of 0,01.
@item gamma_correction
The value correlates exactly with @code{gamma},
and is @code{None} if and only if @code{gamma}
is @code{None}. More precisely, it is the value
of @code{gamma} divided by the gamma calibrated
monitors should have: 2,2. This value can be
used for gamma correction if you do not have
more exact values to use.
@end table
@node Backlight
@section Backlight
@command{blueshift} offers support for adjusting
the backlight on monitors through Linux's sysfs.
When available this preferable to adjusting the
brightness. It does however have two drawbacks:
it interferes with manual adjustments and depending
on the backlight controller you may have very
few backlight levels available.
To list the available backlight controllers, run the
function @code{list_backlights}, it has no parameters
and returns a list of controller names.
To use a backlight controller, invoke the contructor
of the class @code{Backlight}. It takes one manditory
argument, the backlight controller either by name or
path, and two optional arguments: @code{adjbacklight}
and @code{minimum}. @code{adjbacklight} is booleanic,
if @code{True} the command @command{adjbacklight} from
the package with the same name will be used to set the
backlight, rather than @command{blueshift} setting it
by itself; this lets you adjust the backlight without
root permissions and without the administrator justing
the permission of @file{/sys/class/backlight/*/brightness}
files. @code{minimum} is an integer and is zero by default,
which is the lowest logical value to have. @code{minimum}
raises the minimum value from zero to avaoid the backlight
from getting stuck at zero when reached, as happens on
some controllers.
Instances of the class @code{Backlight} have one
variable: @code{maximum}. @code{maximum} is an integer
and is the highest inclusive brightness level. Instances
also have two properties: @code{actual} and
@code{brightness}. @code{actual} is read-only and gets
the current actual backlight level. @code{brightness}
can both be read and write and gets or sets the current
backlight level. Both are integer properties.
@node Continuous mode
@section Continuous mode
In continuous mode, there are some interesting
variables you can adjust at any time:
@table @code
@item wait_period
The number of seconds to wait before updating
the colour curves again. This is a floating
point variable.
@item fadein_time
he number of seconds used to fade in on start,
@code{None} for no fading. This is a floating
point variable.
@item fadeout_time
The number of seconds used to fade out on exit,
@code{None} for no fading. This is a floating
point variable.
@item fadein_steps
The number of steps in the fade in phase, if any.
@item fadeout_steps
The number of steps in the fade out phase, if any.
@item running
Set to @code{False} to exit the program. This is
normally done when @kbd{Control+c} is pressed or
a SIGTERM signal has been received.
@item panic
This variable only have effect if @code{running}
is @code{False}. If this variable is set to
@code{True}, the program will immediately
run @code{reset} and exit. This is normally done
the second time @kbd{Control+c} is pressed or
the second time a SIGTERM signal has been received.
(Or if both has happend.)
@item reset_on_error
The default value of this variable is @code{True},
but it can be set to @code{False}. If it is set to
false @code{False}, Blueshift will not attempt to
reset the colour curves if the configuration script
crashes.
@end table
The parameterless function @code{continuous_run},
may replace if you want to do something very special,
is invoked to run the continuous mode, it the program
shall run in continuous mode. Which is determined by
whether the function @code{periodically} is defined.
Updates to @code{continuous_run} are ignored when
SIGUSR1 signals are received.
You can also replace the function @code{signal_SIGTERM}.
@code{continuous_run} sets up the program to run it
when the program receive a SIGTERM signal.
@code{continuous_run} also invokes it when @kbd{Control+c}
is pressed. @code{signal_SIGTERM} has two parameters,
the second can be ignored as it is normally @code{None};
the first parameter is the signal that is received
(an integer), and zero if @kbd{Control+c} has been
pressed.
Similarly @code{signal_SIGUSR1} and @code{signal_SIGUSR2}
are invoked when the programs received a SIGUSR1 signal or
a SIGUSR2 signal, respectively. SIGUSR1 reloads the
configurations and SIGUSR2 enables or disables Blueshift.
To run in continuous mode, you must implement the
function @code{periodically}. It takes 8 positional
arguments:
@table @code
@item year
The year.
@item month
The month, 1 = January, 12 = December.
@item day
The day, minimum value is 1, probable maximum value is 31.
Theoretically, but most probably not, a change in the
calender system could happen and the month's could length
could be increased. This has happend once, giving us
1712-(02)Feb-30.
@item hour
The hour, minimum value is 0, maximum value is 23.
@item minute
The minute, minimum value is 0, maximum value is 59.
@item second
The second, minimum value is 0, probable maximum value is 60.
We can get 60, or even higher (but that has never happend yet)
due to leapseconds. A minutes length could also be shortend,
but that has never happend yet either.
@item weekday
The weekday, 1 = Monday, 7 = Sunday.
@item fade
Normally, @code{periodically} is invoked with @code{fade}
set to @code{None}. This is note the case when the program
starts or exits. When @code{fade} is not @code{None},
@code{wait_period} is not honoured.
Blueshift can use @code{periodically} to fade into a state
when it start or exits. @code{fade} can either be negative,
zero or positive or @code{None}, but the magnitude of value
cannot exceed 1. When Blueshift starts, the function will
be invoked multiple with the time parameters of the time it
is invoked and each time @code{fade} will increase towards
1, starting at 0, when the value is 1, the settings should
be applied to 100 %. After this this function will be invoked
once again with @code{fade} being @code{None}. When Blueshift
exits the same behaviour is used except, @code{fade} decrease
towards @math{-1} but start slightly below 0, when @math{-1}
is reached all settings should be normal. Then Blueshift will
@emph{not} invoke this function with @code{fade} being
@code{None}, instead it will by itself revert all settings,
by calling @code{reset} and quit.
@end table
Python does not specify that the exceptions can
happen, but do not could on them not. Python's
documentation could be work, or the API could
change.
If you want higher time precision --- the time
parameters are integers --- you are welcome to
use Python's time API. @code{periodically} will
never be invoked with fake time. Just do not mix
as you could theoretically get on two different
seconds, minutes, hours, or even days, months or
years, the delay between Blueshift's timestamp
and yours could overlap an increase in the second.
@node Solar time
@section Solar time
Blueshift includes a simple way to get the Sun's
position. The function @code{sun(latitude, longitude)}
returns the visibility of the Sun as an [0, 1] floating
point. It has three optional, additional, parameters:
@table @code
@item t = None
The time in Julian Centuries.
@item low = -6.0
The Sun's elevation at the limit to high night, that
is, the highest possible position (measured in degrees)
of the Sun before it becomes visible.
@item high = 3.0
The Sun's elevation at the limit to high day, that is,
the lowest possible position (measured in degrees) of
the before it starts becoming less visible (twilight.)
@end table
To convert a time to Julian Centuries, you can use
the function @code{epoch_to_julian_centuries}. It takes
one argument, the POSIX time, that is, the number of
seconds that have elapsed since 1970-(01)Jan-01 00:00:00
UTC, not counting leap seconds.
Blueshift provides a set of functions, used to calculate
solar data, and solar data constants, by importing the
library @command{solar-python}. Refer to its documentation
for more details.
Blueshift also defines the function
@table @code
@item ptime(t : float)
Prints a time, input in the Julian Centuries format,
as a human-readable local time.
@end table
Blueshift provides a constant, via @command{solar-python},
for the apparent size of the Sun: @code{SOLAR_APPARENT_RADIUS}.
This constant can for example be used to get a more
accurate time when the night begins: rather than simply
saying that the night begins when the Sun's apparent
elevation is zero, you can say that it begins when the
Sun is no longer visible at all, which is when the Sun's
apparent elevation is minus @code{SOLAR_APPARENT_RADIUS}.
This value is approximate.
@node Weather
@section Weather
Blueshift includes the function @code{whether}
which gives a brief weather report. @code{whether}
takes one manditory argument: the International
Civil Aviation Organization (ICAO) code of your
closest airport. It also takes one optional argument,
@code{downloader}: an function that takes an URL
to download as its only parameter and returns a
command, as a list of arguments, that downloads
the file at the given URL to standard output.
The default @code{downloader} is
@code{lambda url : ['wget', url, '-O', '-']}. If
Blueshift is unable to download the latest METAR
(Meteorological Aerodrome Report) @code{whether}
will return @code{None}. If successful it will
return the sky conditions (assumed clear if not
included in the report,) the visiblity range and
the weather. These components are returned as a
3-tuple with the components in the same order as
mentioned.
The sky condition is returned as a string. And
can be either of: `clear', `mostly clear',
`partly cloudy', `mostly cloudy', `overcast'
and `obscured'.
If the visibility range is not included in the
report it will be @code{None}; if it is included
in the report it will be an int–float-tuple. The
first element in the tuple will be either
@code{-1}, @code{0} or @code{1}, and the second
element will be an approximate visibility range
measured in kilometers. If the first element is
@code{-1} this measurement is an upper bound, if
it it @code{1} the measurement is an lower bound,
and if it is @code{0} the measurement is
approximate.
The weather is reported as an string list, that
can and often is empty.
Airports should publish METAR (Meteorological
Aerodrome Report) reports at XX:20 and XX:50,
it can presumable take some time before the
collection server we use (weather.noaa.gov) have
received it. Additionally some airports do not
update while closed, and updates while closed
are less accurate.
@node Running without X
@section Running without X
Blueshift has the capability of operating,
in fullness, without a display server like X.
Using Direct Rendering Manager (DRM), in Linux,
Blueshift is able to get monitor information
and get and set the colour curves for each
monitor, just as it is under X using RandR;
except this only works if the active VT does
not have a display server.
There are however a few differences:
@itemize @bullet{}
@item
DRM returns more exact physical monitor
dimensions. For example, my CRT:s have a
visible area of slightly (off by a millimeter
or two) larger than 400 mm by 300 mm, but
RandR returns 364 mm by 291 mm which is an
aspect ratio of 5:4 rather than 4:3.
@item
DRM does not have the concept of primary
monitors, which RandR has. RandR changes
the indices of the CRTC:s so that the
primary monitors have zero as their indices.
@item
DRM does not have a concept of screens,
but it does have the concept of graphic
cards which is missing from RandR. In
practice, these are however equivalent,
and therefore the DRM methods which have
a RandR version caps the parameters for
graphic cards for @code{screen} rather
than @code{card} to maintain API
compatibility with the RandR versions.
@end itemize
Unless your system administator have change
the requires permissions of devices in
@file{/dev/dri}, you need to be a member of
the group @code{video}.
Blueshift checks for you whether you are
running in a TTY by checking the @var{DISPLAY}
environment variable, and sets the variable
@code{ttymode}. That is Blueshift will set
the variable @code{ttymode} to @code{True}
if it thinks that it is not connected to a
display server, and @code{False} otherwise.
Not that it is still possible to use the DRM
functions when connected to a display server:
nothing will happen because, all requests to
change the colour curves will be rejected.
However if you switch VT to a TTY, the requests
will be accepted and the requests to the
display server will be ignored until you
reenter the VT with that display.
The DRM equivalent to the RandR functions
@code{randr} (applying colour curves) and
@code{randr_get} (reading current colour
curves) are @code{drm} and @code{drm_get},
respectively. The parameters are exactly the
same for the DRM functions as they are for
the RandR functions: @code{screen} is still
named @code{screen} instead of @code{card},
and @code{display} is still present but has
not effect.
The function @code{list_screens}, which
lists all screens, CRTC:s and outputs,
runs @code{list_screens_randr} by default.
By invoking @code{list_screens} with the
argument `drm' it will instead run
@code{list_screens_drm}. It will return
equivalent data, except with it calls
screens are actually graphics cards,
and as mentioned, the CRTC:s may have
different indices and the monitors may
have different physical sizes. But the
names of the outputs (which are called
connectors in DRM contected, but for this
function it will still be called outputs
for API compatibility with the RandR
version) by be different.
Blueshift also have support for running
under Windows, using Windows Graphics
Device Interface (Windows GDI) and Mac
OS X, using Quartz via Core Graphics.
However, this has only been tested on
GNU/Linux under X with compatibility
layers written, for Blueshift and
Redshift, from documentation; and are
not support beyond this documentation.
@footnote{The reason for this is simple:
the are proprietary operating systems
that would never touch because of the
fact that they are proprietary and that
they are GUI orientated, as well as
I would not like to pay for those
shortcomings.}
Windows GDI is used similarly to RandR.
To apply the adjustments invoke the
function @code{w32gdi}, optionally with
the indices of the CRTC:s to perform the
adjustment on. If no CRTC is selected,
the adjustment will be applied on all
CRTC:s. To create a function that applies
the adjustments that are applied currently
[when the function is created] on top of
the current adjustments [when the create
function is invoked] use the function
@code{w32gdi_get}, optionally with the
index of the CRTC to read from. If not
CRTC is selected CRTC 0 will be used.
For compatibility with the other methods,
@code{w32gdi} and @code{w32gdi_get} have
two dummy parameters: @code{screen} and
@code{display}.
Quartz is used in the same way as Windows
GDI, except the functions are named
@code{quartz} and @code{quartz_get},
respectively.
Quartz also have support for resetting the
adjustment on each and every monitor on the
system to this on ColorSync. To perform
this action run the function
@code{quartz_restore}. It takes no arguments
and does not return any value.
@node Optimising
@section Optimising
If you have adjustments that reused, perhaps
between adjustments or shared between monitors.
You can reduce the amount of calculates your
script needs to do my reusing made adjustments.
To snapshot the current state of the working
colour curves (those that are not applied yet)
you can use the function @code{store}. It is
parameterless and returns a 3-tuple of the
colour curves. To reset the to curves stored
by @code{store} you can use the function
@code{restore}:
@example
stored = store()
# To stuff ...
restore(stored)
@end example
You can also make a function of the stored
settings. A function like this will apply the
adjustments on top of current adjustments.
To do this input the output of @code{store}
into the function @code{functionise}:
@example
brightness(0.75)
stored = functionise(store())
stored()
stored()
# Now the brightness is 0,75 to the power of 3 = 0,421875.
@end example
Note that the @code{functionise(stored)()}
might be heavier than applying the adjustments
by invoking them.
@node Interpolation
@section Interpolation
ICC profiles and curves that have beens turned
into functions with @code{functionise}, or curves
read from the current adjustments, have lower
input resolution that the input they receive;
to compensate for this, nearest-neighbour
interpolation is used. If you want to better
interpolation there are a few functions that
can be used to scale up the lookup table using
interpolation. These functions have three
arguments: the red, the green and the blue
colour curves to scale up. The functions
return a tuple of these scaled up.
@table @code
@item linearly_interpolate_ramp
Scale up using linear interpolation.
@item cubicly_interpolate_ramp
Scale up using cubic Hermite interpolation.
This function have one additional, optional,
parameter: @code{tension}, those default value
is 0. It is a floating point value that should
be between 0 and 1.
@item monotonicly_cubicly_interpolate_ramp
Scale up using monotone cubic Hermite
interpolation, and the Fritsch–Carlson method.
Does not overshoot, but regular cubic
interpolation with uses linear replacement
for overshot areas is better.
This function have one additional, optional,
parameter: @code{tension}, those default value
is 0. It is a floating point value that should
be between 0 and 1.
@end table
All functions are will using linear
interpolation if an interpolation segment
is non-monotonic. This is done, automatically
by the functions, by using the function
@code{eliminate_halos} that takes six
arguments and does not return anything.
@code{eliminate_halos}'s arguments are
the original three colour curves, followed
by the scaled up colour curves. The latter
argument trio will be modified by the
function. It does not matter which order
there curves are in as long as the order
is the same for the original curves and the
scaled up curves. It is recommended to
use the order: red, green and blue.
However, often these lookup tables are
oftern turned in to functions. To interpolate
a function, you can use the function
@code{interpolate_function}, it takes
two arguments: the function that applies
adjustments from a lookup table, and
a function that interpolates a lookup
table trio. It returns a function that
applies the interpolated lookup table.
If the second argument is @code{None},
then the first argument will be returned:
no interpolation is done.
@node Temperature constants
@section Temperature constants
There is a collection of predefined colour
temperatures that are accessable in form
of constants. None of these (except those
from the D series) colour temperatures are
exact or guaranteed to even be approximate
values. A few of them are from Wikipedia,
others are from @emph{very} questionable
sources. Some values are, as indicated by
their name, those used in f.lux.
Warning: f.lux is nasty software that is
extremely negative in the freedom dimension.
Values are not verified, they are only
acquired from f.lux's ``Frequently asked
questions''.
The predefined colour temperatures, in
order of warmness, are:
@table @code
@item K_F_LUX_W32_EMBER = 1200 K
The colour temperature in the Windows port of f.lux named `ember'.
@item K_MATCH_FLAME = 1700 K
Approximate colour temperature of the flame of a match stick.
@c https://en.wikipedia.org/wiki/Colour_temperature
@item K_CANDLE_FLAME = 1850 K
@itemx K_CANDLELIGHT
Approximate colour temperature of the flame of a candle.
@c https://en.wikipedia.org/wiki/Colour_temperature
@item K_SUNSET = 1850 K
Approximate colour temperature of the sunset.
@c https://en.wikipedia.org/wiki/Colour_temperature
@item K_SUNRISE = 1850 K
Approximate colour temperature of the sunrise.
@c https://en.wikipedia.org/wiki/Colour_temperature
@item K_F_LUX_W32_CANDLE = 1900 K
The colour temperature in the Windows port of f.lux named `candle'.
@item K_HIGH_PRESSURE_SODIUM = 2100 K
Approximate colour temperature of high pressure sodium
@item K_F_LUX_MAC_CANDLE = 2300 K
The colour temperature in the Mac OS X and iOS port of f.lux named `candle'.
@item K_F_LUX_W32_WARM_INCANDESCENT = 2300 K
The colour temperature in the Windows port of f.lux named `warm incandescent'.
@item K_STANDARD_INCANDESCENT = 2500 K
@itemx K_INCANDESCENT
Approximate colour of standard incandescent.
@item K_F_LUX_MAC_TUNGSTEN = 2700 K
The colour temperature in the Mac OS X and iOS port of f.lux named `tungsten'.
@item K_F_LUX_W32_INCANDESCENT = 2700 K
The colour temperature in the Windows port of f.lux named `incandescent'.
@item K_EXTRA_SOFT = 2700 K
@c @itemx K_PIANO_PIANO_LUX
@c @itemx K_PIANO_PIANO
A very soft colour temperature.
@item K_INCANDESCENT_LAMP = average of 2700 K and 3300 K
Approximate average colour temperature of incandescent lamps.
@c https://en.wikipedia.org/wiki/Colour_temperature
@item K_EARLY_SUNRISE = average of 2800 K and 3200 K
Approximate average colour temperature the the sunrise at its early stage.
@item K_LATE_SUNSET = average of 2800 K and 3200 K
Approximate average colour temperature the the sunsun at its late stage.
@item K_WARM_WHITE = 3000 K
Approximate colour temperature of ``warm white''.
@item K_SOFT_WHITE_COMPACT_FLOURESCENT_LAMP = 3000 K
@itemx K_WARM_WHITE_COMPACT_FLOURESCENT_LAMP
Approximate colour temperature of soft/warm white compact flourescent lamps.
@c https://en.wikipedia.org/wiki/Colour_temperature
@item K_HALOGEN_LIGHT = 3000 K
Approximate colour temperature of halogen light.
@item K_TUNGSTEN_LIGHT = 3200 K
Approximate colour temperature of tungsten light.
@c (not to be confused with scheelite)
@item K_HOUSEHOLD_LIGHT_BULB = 3200 K
@itemx K_LIGHT_BULB
Approximate colour temperature regular household light bulbs.
@item K_STUDIO_LAMP = 3200 K
Approximate colour temperature studio lamps.
@c https://en.wikipedia.org/wiki/Colour_temperature
@item K_PHOTOFLOOD = 3200 K
Approximate colour temperature photoflood.
@c https://en.wikipedia.org/wiki/Colour_temperature
@item K_STUDIO_CP_LIGHT = 3350 K
Approximate colour temperature studio `CP' light.
@c https://en.wikipedia.org/wiki/Colour_temperature
@item K_F_LUX_MAC_HALOGEN = 3400 K
The colour temperature in the Mac OS X and iOS port of f.lux named `halogen'.
@item K_F_LUX_W32_HALOGEN = 3400 K
The colour temperature in the Windows port of f.lux named `halogen'.
@item K_SOFT = 3700 K
@c @itemx K_PIANO_LUX
@c @itemx K_PIANO
A soft colour temperature.
@item K_MOONLIGHT = average of 4100 K and 4150 K
Approximate average colour temperature of moonlight.
@c https://en.wikipedia.org/wiki/Colour_temperature
@item K_COOL_WHITE = 4200 K
Approximate colour temperature of ``cool white''.
@item K_F_LUX_MAC_FLOURESCENT = 4200 K
The colour temperature in the Mac OS X and iOS port of f.lux named `flourescent'.
@item K_F_LUX_W32_FLOURESCENT = 4200 K
The colour temperature in the Windows port of f.lux named `flourescent'.
@item K_ELECTRONIC_FLASH_BULB = 4500 K
@itemx K_FLASH_BULB
Approximate colour temperature of electronic flash bulbs.
@item K_D50 = 5000 K
The standard illuminant D50 of the CIE standard illuminant series D.
@item K_NOON_DAYLIGHT = 5000 K
Approximate colour temperature of noon daylight.
@item K_DIRECT_SUN = 5000 K
Approximate colour temperature of direct sunlight.
@item K_METAL_HALIDE = 5000 K
Approximate colour temperature of metal halide.
@item K_HORIZON_DAYLIGHT = 5000 K
Approximate colour temperature of horizon daylight.
@c https://en.wikipedia.org/wiki/Colour_temperature
@item K_TUBULAR_FLUORESCENT_LAMP = 5000 K
Approximate colour temperature of tubular fluorescent lamps.
@c https://en.wikipedia.org/wiki/Colour_temperature
@item K_COOL_WHITE_COMPACT_FLUORESCENT_LAMPS = 5000 K
@itemx K_DAYLIGHT_WHITE_COMPACT_FLUORESCENT_LAMPS
Approximate colour temperature of cool white/daylight compact fluorescent lamps.
@c https://en.wikipedia.org/wiki/Colour_temperature
@item K_F_LUX_MAC_DAYLIGHT = 5000 K
The colour temperature in the Mac OS X and iOS port of f.lux named `daylight'.
@item K_D55 = 5500 K
The standard illuminant D55 of the CIE standard illuminant series D.
@item K_F_LUX_W32_DAYLIGHT = 5500 K
The colour temperature in the Windows port of f.lux named `daylight'.
@item K_MODERATELY_SOFT = 5500
@c @itemx K_MEZZO_PIANO_LUX
@c @itemx K_MEZZO_PIANO
A moderately soft colour temperature.
@c @item K_CRYSTAL_VERTICAL = 5600 K
@c The colour temperature of the standard lighting of
@c "Kristall, vertikal accent i glas och stål"
@c (Crystal, vertical accent in glass and steal)
@c @c http://ljusdesign.com/meriter/juryn.htm
@item K_CLEAR_MID_DAY = 5600 K
Approximate colour temperature of a clear mid-day.
@item K_VERTICAL_DAYLIGHT = average of 5500 K and 6000 K
Approximate average colour temperature of vertical daylight.
@c https://en.wikipedia.org/wiki/Colour_temperature
@item K_ELECTRONIC_FLASH = average of 5500 K and 6000 K
Approximate average colour temperature of electronic flash.
@c https://en.wikipedia.org/wiki/Colour_temperature
@item K_XENON_SHORT_ARC_LAMP = 6200 K
Approximate colour temperature of xenon short-arc lamp.
@c https://en.wikipedia.org/wiki/Colour_temperature
@item K_DAYLIGHT = 6500 K
Approximate colour temperature of daylight.
@c https://en.wikipedia.org/wiki/Colour_temperature
@item K_OVERCAST_DAY = 6500 K
Approximate colour temperature of daylight during an overcast day.
@c https://en.wikipedia.org/wiki/Colour_temperature
@item K_D65 = 6500 K
@itemx K_NEUTRAL
@itemx K_WHITE
@c @itemx K_MEZZO_LUX
@c @itemx K_MEZZO
The standard illuminant D65 of the CIE standard illuminant series D,
the standard colour temperature.
@item K_SHARP = 7000 K
@c @itemx K_FORTE_LUX
@c @itemx K_FORTE
A sharp colour temperature.
@item K_D75 = 7500 K
The standard illuminant D75 of the CIE standard illuminant series D.
@item K_BLUE_FILTER = 8000 K
Approximate colour temperature of a standard blue filter.
@item K_NORTH_LIGHT = 10000 K
@itemx K_BLUE_SKY
Approximate colour temperature of north light.
@item K_EXTRA_SHARP = 10000 K
@c @itemx K_FORTE_FORTE_LUX
@c @itemx K_FORTE_FORTE
A very sharp colour temperature.
@item K_SKYLIGHT = average of 9000 K and 15000 K
Approximate average colour temperature of the skylight.
@item K_OUTDOOR_SHADE = average of 9000 K and 15000 K
Approximate average colour temperature of an outdoor shade.
@item K_CLEAR_BLUE_POLEWARD_SKY = average of 15000 K and 27000 K
Approximate average colour temperature of a clear blue poleward sky.
@c https://en.wikipedia.org/wiki/Colour_temperature
@end table
The functions @code{temperature} (@code{rgb_temperature})
and @code{cie_temperature} allow you to, instead of specifing
a colour temperature using literals or these constants,
use the proper name of this constants. For example,
if you use the string `@code{xenon short-arc lamp}'
as the first argument (the temperature value) for the
function @code{temperature}, @code{K_XENON_SHORT_ARC_LAMP}
(6200 kelvins) will be used. These functions utilise
the function @code{kelvins} that does this resolution.
@code{kelvins} kelvins takes either a numerical value
an returns it or takes a string and resolves it.
Predefined recognised punctuation (dot and hyphen)
and regular blank space is converted into underscores,
than the string it converted to upper case and prefixed
with `@code{K_}'. The string is then evaluated without
any sanity-checks, it should match one of the constants.
@node Configuration examples
@chapter Configuration examples
The Blueshift packages comes with a set of example
configuration scripts. These are installed to
@file{@value{DOCDIR}/@value{PKGNAME}/examples}.
These examples include:
@table @file
@item backlight
This example demonstrates how to use adjust backlight
without interfering to much with manual adjustments.
The example with oscillate the backlight between 50 %
and 100 % but include any manual adjustments.
@item battery
This is a small example that inverts the colours when
the battery's capacity is low. It includes very little
from the configuration API but uses Linux's sysfs to
determine the battery's capacity an charging status.
@item bedtime
This example adjusts the the colours to make it easier
to go to bed around a scheduled time, for each weekday.
@item comprehensive
This example includes most of Blueshift's features and
lets you use them very generically. It does include all
basic features of Blueshift.
@item crtc-detection
This is a small example that identifies which monitors
you have plugged in to the computer, and applied their
proper calibration.
@item crtc-searching
This example uses option parsing and CRTC searching.
@command{Screens.find_by_crtc} and
@command{Screen.find_by_crtc}, are not used, those are
not useful for anything. They can be used for seaching
the number of connected monitors, but
@command{Screen.crtc_count} is much more effective.
@item current-settings
This is a small example demonstrates how the currents
settings can be read and transitioned from.
@item darkroom
This is a samll example inverts the colours and then
makes the monitors red and dim. It is exited by running
again with Blueshift's @option{-r} (@option{--reset})
option.
@item icc-profile-atoms
This is a tiny example that demonstrates how to read
and use the @var{_ICC_PROFILE(_n)} atoms for X screens.
@c @item lisp-esque
@c @itemx lisp-esque.conf
@item logarithmic
A very small example that uses free function modifier
and temporary curve linearisation to make the colour
curves logarithmic.
@item modes
This example can be used to name a mode you want to use,
without having to use Blueshift's @option{-c} option and
give a pathname. You will only need to give a filename.
In this example, those modes are installed in the directory
@file{$@var{XDG_CONFIG_HOME}/blueshift-modes}, and the
default mode is named @file{default}.
@item sleepmode
This example graciously fades out the screen on start and
in on exit. It is a nice alternative to turning off the
monitor, just press @kbd{Control+c} when you wake up.
@item stored-settings
This example demonstrates how settings can be stored
and be transition from later.
@item textconf
@itemx textconf.conf
This example uses a text based configuration file to make
it easier for non-programmers to use Blueshift. It will
read a file with the same pathname just with @file{.conf}
appended (@file{textconf.conf} in this case.) However, if
the filename of this file ends with with @file{rc}, that
part will be removed, for example, if you rename this
script to @file{~/.blueshiftrc} it will read
@file{~/.blueshift.conf} rather than
@file{~/.blueshiftrc.conf}.
@item threaded
This is an example demonstrates how you can make a
multithreaded configurations script.
@item weather
This is a samll example demonstrates how to include
weather conditions in your configuration scripts.
@item x-window-focus
This example can be used (hopefully@footnote{It has
been tested on xmonad and twm, and the feature is
window manager dependent}) any X window manager.
It identifies what window is in focus, by class
@footnote{Class is almost the same thing as application.}
or title, and applies appropriate adjustments.
@item xmobar
This example can be used in @command{xmobar} to display
the Sun's elevation and to what degree it is day time.
@item xmonad
This configuration scripts read the @command{xmonad}
log to detect which workspace you are viewing. It can
also disable adjustments when you are in selected
programs such as The GIMP and Inkscape.
@item xpybar
This example can be used in @command{xpybar} to display
the Sun's elevation and to what degree it is day time.
@end table
@node Related software
@chapter Related software
@command{blueshift} by itself have a wide range of
feature, but it can be extended further by additional
software:
@table @command
@item blueshift-tray
A wrapper for Blueshift that makes it easy to
temporarily activate and deactivate Blueshift
by placing it in the X system tray.
@item blueshift-curse
(Under development)@*
@command{blueshift-curse} is an extension for
Blueshift that can be used by configuration scripts
to make it possible for other applications, included
an ncurses interface that comes with it, to do
modifications to the configurations.
@command{blueshift-curse} uses domain sockets for
interprocess communication.
@item blueshift-vt-cues
(Development planned)@*
@command{blueshift-vt-cues} is an extension for
Blueshift that, with the support of a daemon, can
listen for virtual terminal (VT) switching events.
@command{blueshift-vt-cues} uses domain sockets for
interprocess communication between the daemons and
users. It provides information about the currently
active VT such as VT number, wich user has ownership
of the VT and either it is a text (or framebuffer)
session or a graphical session (such as X, Wayland
and Mir.)
@command{blueshift-vt-cues} also provides the
capability of informing the Blueshift configuration
scripts whether or not they should reset the the
adjustments to make sure that one user's adjustments
does not interfere with another user's adjustments.
@end table
If you want to extend the capabilities of Blueshift
for your configuration scripts there are some library
packages that can be of particular interest:
@table @command
@item python3-xlib
X library for Python based on the Xlib library.
@item xpyb
(Not ported to Python 3)@*
X library for Python based on the XCB library.
@item xpybutil
(Not ported to Python 3)@*
A Python rendition of xcb-util including EWMH, ICCCM, key binding, Xinerama, &c.
@item ooxcb
(Not ported to Python 3)@*
An object-oriented X library for Python based on xpyb.
@item pygtk
(Not ported to Python 3)@*
GTK+ 2 bindings for Python.
@item python-gobject
GTK+ 3 bindings for Python.
@item python2-geoclue
(Not ported to Python 3)@*
GeoClue library for Python, can be used to get your geographical position.
GeoClue uses D-Bus, and can use multiple position providers:
@itemize @bullet{}
@item GPS:
Position information from a Global Positioning System receiver via @command{gpsd} and @command{gypsy}.
@item GSM:
Position information from cellular network connection.
@item Plazes:
Position information from the Plazes Wi-Fi location service.
@item Hostip:
Position information based on IP address.
@item Manual:
User-provided position information.
@end itemize
@item python-dbus
Python bindings for D-Bus.
@item python-networkmanager
Python interface to NetworkManager.
@item locateme
(Under development)@*
A command to get your geographical position.
@end table
@node Terminology
@chapter Terminology
Terminology related to Blueshift:
@table @asis
@item Ad-hoc mode
@itemx One time mode
Running Blueshift without a configuration script.
@item Configuration mode
Running Blueshift with a configuration script.
@item Configuration script
Blueshift provides a mechanism for adjusting
colours on the monitors. Configuration scripts,
invoked by Blueshift, implements the policy
for doing so.
@item Continuous mode
Running Blueshift such at it applies adjustments
but than continues to run and applies now
(time dependent) adjustments every now and then
until the user terminates Blueshift.
@item One shot mode
Running Blueshift such at it applies adjustments
and than exits.
@item Panicgate
Applying adjustments immediately without
transitioning. This terminology is borrowed
from OpenNTPD.
@item High day
@itemx Day
@itemx Daytime
The time during the day when the Sun elevated to
be 100 % visible. The time between sunrise and
sunset; when it is full daylight.
@item High night
@itemx Night
@itemx Nighttime
The time during the day when the Sun elevated to
be 0 % visible. The time between dusk and dawn;
when it is complete darkness.
@end table
@node GNU Free Documentation License
@appendix GNU Free Documentation License
@include fdl.texinfo
@bye
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