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authorMattias Andrée <maandree@operamail.com>2014-03-19 05:46:06 +0100
committerMattias Andrée <maandree@operamail.com>2014-03-19 05:46:06 +0100
commit1f289a0b90529346ea88169840a1cf11c7da3842 (patch)
tree91fcf2d5c1fcc3d3aed441521f56a80ed5cf2117 /examples
parentupdate todo (diff)
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Signed-off-by: Mattias Andrée <maandree@operamail.com>
Diffstat (limited to 'examples')
-rw-r--r--examples/comprehensive25
-rw-r--r--examples/logarithmic16
-rw-r--r--examples/textconf5
3 files changed, 27 insertions, 19 deletions
diff --git a/examples/comprehensive b/examples/comprehensive
index ec0a42e..29070d4 100644
--- a/examples/comprehensive
+++ b/examples/comprehensive
@@ -1,13 +1,11 @@
# -*- python -*-
-# This example is complete with exceptions for less normal colour
-# curve modifiers: nothing else than CIE 1964 10 degree CMF for
-# colour temperature, nor use of temporarly linear RGB curves,
-# sigmoid correction, or free function modifier, work on individual
-# subpixels in CIE xyY colour space. Neither does it # support multiple
-# screens, this is normally not an issue because Xinerama is normally
-# used to put all monitors on the same screen; # nor does it parse
-# options other than -r from ad-hoc settigns, or use monitor identifiation.
+# This example covers most of what Blueshift offers. For a complete
+# coverage of Blueshift complement this example with:
+# backlight, crtc-detection, crtc-searching, logarithmic,
+# stored-settings, modes, textconf
+# However the are features that are only covered by the info manual:
+# Methods for calculating correlated colour temperature
# This file is dual-licensed under GNU General Public License
@@ -188,10 +186,13 @@ if not panicgate:
# colour resolution. `red_x_resolution` is the number of colours
# colours there are one encoding axis of the red curve.
# `red_y_resolution` is how many colours there are on the
-# output axis of the red curve.
-red_x_resolution, red_y_resolution = [i_size], [o_size]
-green_x_resolution, green_y_resolution = [i_size], [o_size]
-blue_x_resolution, blue_y_resolution = [i_size], [o_size]
+# output axis of the red curve. `None` means that the default
+# resolution should be used, which are `i_size` for *_x_resolution
+# and `o_size` for *_y_resolution. `...` means that the value
+# above should be used.
+red_x_resolution, red_y_resolution = [None], [None]
+green_x_resolution, green_y_resolution = [...], [...]
+blue_x_resolution, blue_y_resolution = [...], [...]
# Negative image settings. `None` means that negative image
diff --git a/examples/logarithmic b/examples/logarithmic
index 731b27d..62271d9 100644
--- a/examples/logarithmic
+++ b/examples/logarithmic
@@ -20,14 +20,22 @@ import math
linearise()
# Make the curves logarithmic. The function applies
-# to all colour curves, but you can change them
-# individually by specifing three functions: red,
-# green and blue.
-manipulate(lambda x : math.log(x + 1, 2))
+# to the red (first argument) and green (second
+# argument) colour curves. `...` is used to use the
+# same value as the argument before it. `None`,
+# which is used for the blue colour curve, means
+# that no adjustment is made, which is the same
+# thing as using `lambda x : x`.
+manipulate(lambda x : math.log(x + 1, 2), ..., None)
# Switch back to sRGB.
standardise()
+# Alternatively you can use `cie_manipulate` instead
+# of `manipulate`. To to the logaritmisation in the
+# CIE xyY colour space. If doing so, do not use
+# `linearise`–`standardise`.
+
# Apply settings, using vidmode.
(drm if ttymode else vidmode)()
#(drm if ttymode else randr)()
diff --git a/examples/textconf b/examples/textconf
index 1e00c6b..acddc79 100644
--- a/examples/textconf
+++ b/examples/textconf
@@ -469,10 +469,9 @@ def periodically(year, month, day, hour, minute, second, weekday, fade):
for adjustment in adjustments:
adjustment(timepoint, alpha)
- r, g, b = r_curve[:], g_curve[:], b_curve[:]
-
+ stored = store()
for crtcs, screens, output_adjustments in monitors:
- r_curve[:], g_curve[:], b_curve[:] = r, g, b
+ restore(stored)
for adjustment in output_adjustments:
adjustment(timepoint, alpha)