1 | #! perl |
1 | #! perl |
2 | |
2 | |
3 | #:META:X_RESOURCE:%.expr:string:background expression |
3 | #:META:X_RESOURCE:%.expr:string:background expression |
4 | #:META:X_RESOURCE:%.enable:boolean:some boolean |
4 | #:META:X_RESOURCE:%.border:boolean:respect the terminal border |
5 | #:META:X_RESOURCE:%.extra.:value:extra config |
5 | #:META:X_RESOURCE:%.interval:seconds:minimum time between updates |
6 | |
6 | |
7 | our $EXPR = 'move X, Y, load "MagnoliaAlpha.png"'; |
7 | =head1 NAME |
8 | #$EXPR = ' |
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9 | # rotate W, H, 50, 50, counter 1/59.95, repeat_mirror, |
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10 | # clip X, Y, W, H, repeat_mirror, |
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11 | # load "/root/pix/das_fette_schwein.jpg" |
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12 | #'; |
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13 | #$EXPR = 'solid "red"'; |
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14 | #$EXPR = 'blur root, 10, 10' |
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15 | #$EXPR = 'blur move (root, -x, -y), 5, 5' |
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16 | #resize load "/root/pix/das_fette_schwein.jpg", w, h |
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17 | |
8 | |
18 | use Safe; |
9 | background - manage terminal background |
19 | |
10 | |
20 | our ($bgdsl_self, $old, $new); |
11 | =head1 SYNOPSIS |
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12 | |
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13 | urxvt --background-expr 'background expression' |
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14 | --background-border |
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15 | --background-interval seconds |
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16 | |
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17 | =head1 DESCRIPTION |
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18 | |
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19 | This extension manages the terminal background by creating a picture that |
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20 | is behind the text, replacing the normal background colour. |
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21 | |
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22 | It does so by evaluating a Perl expression that I<calculates> the image on |
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23 | the fly, for example, by grabbing the root background or loading a file. |
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24 | |
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25 | While the full power of Perl is available, the operators have been design |
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26 | to be as simple as possible. |
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27 | |
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28 | For example, to load an image and scale it to the window size, you would |
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29 | use: |
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30 | |
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31 | urxvt --background-expr 'scale keep { load "/path/to/mybg.png" }' |
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32 | |
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33 | Or specified as a X resource: |
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34 | |
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35 | URxvt.background-expr: scale keep { load "/path/to/mybg.png" } |
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36 | |
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37 | =head1 THEORY OF OPERATION |
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38 | |
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39 | At startup, just before the window is mapped for the first time, the |
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40 | expression is evaluated and must yield an image. The image is then |
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41 | extended as necessary to cover the whole terminal window, and is set as a |
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42 | background pixmap. |
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43 | |
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44 | If the image contains an alpha channel, then it will be used as-is in |
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45 | visuals that support alpha channels (for example, for a compositing |
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46 | manager). In other visuals, the terminal background colour will be used to |
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47 | replace any transparency. |
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48 | |
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49 | When the expression relies, directly or indirectly, on the window size, |
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50 | position, the root pixmap, or a timer, then it will be remembered. If not, |
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51 | then it will be removed. |
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52 | |
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53 | If any of the parameters that the expression relies on changes (when the |
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54 | window is moved or resized, its position or size changes; when the root |
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55 | pixmap is replaced by another one the root background changes; or when the |
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56 | timer elapses), then the expression will be evaluated again. |
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57 | |
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58 | For example, an expression such as C<scale keep { load "$HOME/mybg.png" |
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59 | }> scales the image to the window size, so it relies on the window size |
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60 | and will be reevaluated each time it is changed, but not when it moves for |
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61 | example. That ensures that the picture always fills the terminal, even |
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62 | after its size changes. |
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63 | |
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64 | =head2 EXPRESSIONS |
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65 | |
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66 | Expressions are normal Perl expressions, in fact, they are Perl blocks - |
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67 | which means you could use multiple lines and statements: |
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68 | |
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69 | scale keep { |
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70 | again 3600; |
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71 | if (localtime now)[6]) { |
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72 | return load "$HOME/weekday.png"; |
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73 | } else { |
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74 | return load "$HOME/sunday.png"; |
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75 | } |
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76 | } |
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77 | |
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78 | This expression is evaluated once per hour. It will set F<sunday.png> as |
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79 | background on Sundays, and F<weekday.png> on all other days. |
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80 | |
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81 | Fortunately, we expect that most expressions will be much simpler, with |
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82 | little Perl knowledge needed. |
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83 | |
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84 | Basically, you always start with a function that "generates" an image |
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85 | object, such as C<load>, which loads an image from disk, or C<root>, which |
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86 | returns the root window background image: |
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87 | |
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88 | load "$HOME/mypic.png" |
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89 | |
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90 | The path is usually specified as a quoted string (the exact rules can be |
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91 | found in the L<perlop> manpage). The F<$HOME> at the beginning of the |
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92 | string is expanded to the home directory. |
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93 | |
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94 | Then you prepend one or more modifiers or filtering expressions, such as |
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95 | C<scale>: |
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96 | |
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97 | scale load "$HOME/mypic.png" |
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98 | |
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99 | Just like a mathematical expression with functions, you should read these |
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100 | expressions from right to left, as the C<load> is evaluated first, and |
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101 | its result becomes the argument to the C<scale> function. |
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102 | |
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103 | Many operators also allow some parameters preceding the input image |
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104 | that modify its behaviour. For example, C<scale> without any additional |
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105 | arguments scales the image to size of the terminal window. If you specify |
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106 | an additional argument, it uses it as a scale factor (multiply by 100 to |
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107 | get a percentage): |
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108 | |
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109 | scale 2, load "$HOME/mypic.png" |
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110 | |
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111 | This enlarges the image by a factor of 2 (200%). As you can see, C<scale> |
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112 | has now two arguments, the C<200> and the C<load> expression, while |
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113 | C<load> only has one argument. Arguments are separated from each other by |
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114 | commas. |
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115 | |
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116 | Scale also accepts two arguments, which are then separate factors for both |
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117 | horizontal and vertical dimensions. For example, this halves the image |
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118 | width and doubles the image height: |
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119 | |
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120 | scale 0.5, 2, load "$HOME/mypic.png" |
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121 | |
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122 | IF you try out these expressions, you might suffer from sluggishness, |
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123 | because each time the terminal is resized, it again loads the PNG image |
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124 | and scales it. Scaling is usually fast, but loading the image can be quite |
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125 | time consuming. This is where C<keep> comes in handy: |
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126 | |
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127 | scale 0.5, 2, keep { load "$HOME/mypic.png" } |
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128 | |
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129 | The C<keep> operator executes all the statements inside the braces only |
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130 | once, or when it thinks the outcome might change. In other cases it |
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131 | returns the last value computed by the brace block. |
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132 | |
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133 | This means that the C<load> is only executed once, which makes it much |
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134 | faster, but also means that more memory is being used, because the loaded |
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135 | image must be kept in memory at all times. In this expression, the |
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136 | trade-off is likely worth it. |
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137 | |
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138 | But back to effects: Other effects than scaling are also readily |
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139 | available, for example, you can tile the image to fill the whole window, |
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140 | instead of resizing it: |
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141 | |
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142 | tile keep { load "$HOME/mypic.png" } |
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143 | |
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144 | In fact, images returned by C<load> are in C<tile> mode by default, so the |
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145 | C<tile> operator is kind of superfluous. |
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146 | |
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147 | Another common effect is to mirror the image, so that the same edges |
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148 | touch: |
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149 | |
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150 | mirror keep { load "$HOME/mypic.png" } |
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151 | |
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152 | Another common background expression is: |
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153 | |
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154 | rootalign root |
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155 | |
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156 | This one first takes a snapshot of the screen background image, and then |
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157 | moves it to the upper left corner of the screen (as opposed to the upper |
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158 | left corner of the terminal window)- the result is pseudo-transparency: |
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159 | the image seems to be static while the window is moved around. |
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160 | |
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161 | =head2 CACHING AND SENSITIVITY |
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162 | |
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163 | Since some operations (such as C<load> and C<blur>) can take a long time, |
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164 | caching results can be very important for a smooth operation. Caching can |
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165 | also be useful to reduce memory usage, though, for example, when an image |
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166 | is cached by C<load>, it could be shared by multiple terminal windows |
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167 | running inside urxvtd. |
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168 | |
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169 | =head3 C<keep { ... }> caching |
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170 | |
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171 | The most important way to cache expensive operations is to use C<keep { |
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172 | ... }>. The C<keep> operator takes a block of multiple statements enclosed |
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173 | by C<{}> and keeps the return value in memory. |
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174 | |
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175 | An expression can be "sensitive" to various external events, such as |
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176 | scaling or moving the window, root background changes and timers. Simply |
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177 | using an expression (such as C<scale> without parameters) that depend on |
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178 | certain changing values (called "variables"), or using those variables |
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179 | directly, will make an expression sensitive to these events - for example, |
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180 | using C<scale> or C<TW> will make the expression sensitive to the terminal |
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181 | size, and thus to resizing events. |
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182 | |
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183 | When such an event happens, C<keep> will automatically trigger a |
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184 | reevaluation of the whole expression with the new value of the expression. |
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185 | |
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186 | C<keep> is most useful for expensive operations, such as C<blur>: |
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187 | |
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188 | rootalign once { blur 20, root } |
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189 | |
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190 | This makes a blurred copy of the root background once, and on subsequent |
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191 | calls, just root-aligns it. Since C<blur> is usually quite slow and |
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192 | C<rootalign> is quite fast, this trades extra memory (for the cached |
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193 | blurred pixmap) with speed (blur only needs to be redone when root |
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194 | changes). |
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195 | |
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196 | =head3 C<load> caching |
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197 | |
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198 | The C<load> operator itself does not keep images in memory, but as long as |
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199 | the image is still in memory, C<load> will use the in-memory image instead |
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200 | of loading it freshly from disk. |
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201 | |
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202 | That means that this expression: |
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203 | |
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204 | keep { load "$HOME/path..." } |
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205 | |
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206 | Not only caches the image in memory, other terminal instances that try to |
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207 | C<load> it can reuse that in-memory copy. |
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208 | |
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209 | =head1 REFERENCE |
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210 | |
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211 | =head2 COMMAND LINE SWITCHES |
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212 | |
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213 | =over 4 |
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214 | |
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215 | =item --background-expr perl-expression |
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216 | |
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217 | Specifies the Perl expression to evaluate. |
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218 | |
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219 | =item --background-border |
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220 | |
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221 | By default, the expression creates an image that fills the full window, |
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222 | overwriting borders and any other areas, such as the scrollbar. |
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223 | |
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224 | Specifying this flag changes the behaviour, so that the image only |
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225 | replaces the background of the character area. |
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226 | |
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227 | =item --background-interval seconds |
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228 | |
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229 | Since some operations in the underlying XRender extension can effectively |
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230 | freeze your X-server for prolonged time, this extension enforces a minimum |
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231 | time between updates, which is normally about 0.1 seconds. |
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232 | |
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233 | If you want to do updates more often, you can decrease this safety |
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234 | interval with this switch. |
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235 | |
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236 | =back |
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237 | |
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238 | =cut |
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239 | |
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240 | our %_IMG_CACHE; |
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241 | our $HOME; |
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242 | our ($self, $frame); |
21 | our ($l, $t, $w, $h); |
243 | our ($x, $y, $w, $h); |
22 | |
244 | |
23 | # enforce at least this interval between updates |
245 | # enforce at least this interval between updates |
24 | our $MIN_INTERVAL = 1/100; |
246 | our $MIN_INTERVAL = 6/59.951; |
25 | |
247 | |
26 | { |
248 | { |
27 | package urxvt::bgdsl; # background language |
249 | package urxvt::bgdsl; # background language |
28 | |
250 | |
29 | *repeat_empty = \&urxvt::RepeatNone; |
251 | sub FR_PARENT() { 0 } # parent frame, if any - must be #0 |
30 | *repeat_tile = \&urxvt::RepeatNormal; |
252 | sub FR_CACHE () { 1 } # cached values |
31 | *repeat_pad = \&urxvt::RepeatPad; |
253 | sub FR_AGAIN () { 2 } # what this expr is sensitive to |
32 | *repeat_mirror = \&urxvt::RepeatReflect; |
254 | sub FR_STATE () { 3 } # watchers etc. |
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255 | |
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256 | use List::Util qw(min max sum shuffle); |
33 | |
257 | |
34 | =head2 PROVIDERS/GENERATORS |
258 | =head2 PROVIDERS/GENERATORS |
35 | |
259 | |
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260 | These functions provide an image, by loading it from disk, grabbing it |
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261 | from the root screen or by simply generating it. They are used as starting |
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262 | points to get an image you can play with. |
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263 | |
36 | =over 4 |
264 | =over 4 |
37 | |
265 | |
38 | =item load $path |
266 | =item load $path |
39 | |
267 | |
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268 | Loads the image at the given C<$path>. The image is set to plane tiling |
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269 | mode. |
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270 | |
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271 | If the image is already in memory (e.g. because another terminal instance |
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272 | uses it), then the in-memory copy us returned instead. |
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273 | |
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274 | =item load_uc $path |
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275 | |
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276 | Load uncached - same as load, but does not cache the image, which means it |
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277 | is I<always> loaded from the filesystem again. |
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278 | |
40 | =cut |
279 | =cut |
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280 | |
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281 | sub load_uc($) { |
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282 | $self->new_img_from_file ($path) |
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283 | } |
41 | |
284 | |
42 | sub load($) { |
285 | sub load($) { |
43 | my ($path) = @_; |
286 | my ($path) = @_; |
44 | |
287 | |
45 | $new->{load}{$path} = $old->{load}{$path} || $bgdsl_self->new_img_from_file ($path); |
288 | $_IMG_CACHE{$path} || do { |
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289 | my $img = load_uc $path; |
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290 | Scalar::Util::weaken ($_IMG_CACHE{$path} = $img); |
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291 | $img |
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292 | } |
46 | } |
293 | } |
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294 | |
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295 | =item root |
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296 | |
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297 | Returns the root window pixmap, that is, hopefully, the background image |
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298 | of your screen. |
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299 | |
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300 | This function makes your expression root sensitive, that means it will be |
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301 | reevaluated when the bg image changes. |
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302 | |
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303 | =cut |
47 | |
304 | |
48 | sub root() { |
305 | sub root() { |
49 | $new->{rootpmap_sensitive} = 1; |
306 | $frame->[FR_AGAIN]{rootpmap} = 1; |
50 | die "root op not supported, exg, we need you"; |
307 | $self->new_img_from_root |
51 | } |
308 | } |
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309 | |
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310 | =item solid $colour |
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311 | |
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312 | =item solid $width, $height, $colour |
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313 | |
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314 | Creates a new image and completely fills it with the given colour. The |
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315 | image is set to tiling mode. |
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316 | |
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317 | If C<$width> and C<$height> are omitted, it creates a 1x1 image, which is |
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318 | useful for solid backgrounds or for use in filtering effects. |
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319 | |
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320 | =cut |
52 | |
321 | |
53 | sub solid($;$$) { |
322 | sub solid($;$$) { |
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323 | my $colour = pop; |
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324 | |
54 | my $img = $bgdsl_self->new_img (urxvt::PictStandardARGB32, $_[1] || 1, $_[2] || 1); |
325 | my $img = $self->new_img (urxvt::PictStandardARGB32, 0, 0, $_[0] || 1, $_[1] || 1); |
55 | $img->fill ($_[0]); |
326 | $img->fill ($colour); |
56 | $img |
327 | $img |
57 | } |
328 | } |
58 | |
329 | |
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330 | =item clone $img |
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331 | |
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332 | Returns an exact copy of the image. This is useful if you want to have |
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333 | multiple copies of the same image to apply different effects to. |
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334 | |
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335 | =cut |
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336 | |
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337 | sub clone($) { |
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338 | $_[0]->clone |
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339 | } |
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340 | |
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341 | =item merge $img ... |
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342 | |
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343 | Takes any number of images and merges them together, creating a single |
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344 | image containing them all. The tiling mode of the first image is used as |
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345 | the tiling mode of the resulting image. |
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346 | |
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347 | This function is called automatically when an expression returns multiple |
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348 | images. |
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349 | |
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350 | =cut |
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351 | |
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352 | sub merge(@) { |
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353 | return $_[0] unless $#_; |
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354 | |
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355 | # rather annoyingly clumsy, but optimisation is for another time |
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356 | |
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357 | my $x0 = +1e9; |
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358 | my $y0 = +1e9; |
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359 | my $x1 = -1e9; |
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360 | my $y1 = -1e9; |
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361 | |
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362 | for (@_) { |
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363 | my ($x, $y, $w, $h) = $_->geometry; |
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364 | |
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365 | $x0 = $x if $x0 > $x; |
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366 | $y0 = $y if $y0 > $y; |
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367 | |
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368 | $x += $w; |
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369 | $y += $h; |
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370 | |
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371 | $x1 = $x if $x1 < $x; |
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372 | $y1 = $y if $y1 < $y; |
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373 | } |
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374 | |
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375 | my $base = $self->new_img (urxvt::PictStandardARGB32, $x0, $y0, $x1 - $x0, $y1 - $y0); |
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376 | $base->repeat_mode ($_[0]->repeat_mode); |
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377 | $base->fill ([0, 0, 0, 0]); |
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378 | |
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379 | $base->draw ($_) |
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380 | for @_; |
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381 | |
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382 | $base |
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383 | } |
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384 | |
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385 | =head2 TILING MODES |
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386 | |
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387 | The following operators modify the tiling mode of an image, that is, the |
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388 | way that pixels outside the image area are painted when the image is used. |
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389 | |
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390 | =over 4 |
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391 | |
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392 | =item tile $img |
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393 | |
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394 | Tiles the whole plane with the image and returns this new image - or in |
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395 | other words, it returns a copy of the image in plane tiling mode. |
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396 | |
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397 | Example: load an image and tile it over the background, without |
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398 | resizing. The C<tile> call is superfluous because C<load> already defaults |
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399 | to tiling mode. |
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400 | |
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401 | tile load "mybg.png" |
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402 | |
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403 | =item mirror $img |
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404 | |
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405 | Similar to tile, but reflects the image each time it uses a new copy, so |
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406 | that top edges always touch top edges, right edges always touch right |
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407 | edges and so on (with normal tiling, left edges always touch right edges |
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408 | and top always touch bottom edges). |
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409 | |
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410 | Example: load an image and mirror it over the background, avoiding sharp |
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411 | edges at the image borders at the expense of mirroring the image itself |
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412 | |
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413 | mirror load "mybg.png" |
|
|
414 | |
|
|
415 | =item pad $img |
|
|
416 | |
|
|
417 | Takes an image and modifies it so that all pixels outside the image area |
|
|
418 | become transparent. This mode is most useful when you want to place an |
|
|
419 | image over another image or the background colour while leaving all |
|
|
420 | background pixels outside the image unchanged. |
|
|
421 | |
|
|
422 | Example: load an image and display it in the upper left corner. The rest |
|
|
423 | of the space is left "empty" (transparent or whatever your compositor does |
|
|
424 | in alpha mode, else background colour). |
|
|
425 | |
|
|
426 | pad load "mybg.png" |
|
|
427 | |
|
|
428 | =item extend $img |
|
|
429 | |
|
|
430 | Extends the image over the whole plane, using the closest pixel in the |
|
|
431 | area outside the image. This mode is mostly useful when you use more complex |
|
|
432 | filtering operations and want the pixels outside the image to have the |
|
|
433 | same values as the pixels near the edge. |
|
|
434 | |
|
|
435 | Example: just for curiosity, how does this pixel extension stuff work? |
|
|
436 | |
|
|
437 | extend move 50, 50, load "mybg.png" |
|
|
438 | |
|
|
439 | =cut |
|
|
440 | |
|
|
441 | sub pad($) { |
|
|
442 | my $img = $_[0]->clone; |
|
|
443 | $img->repeat_mode (urxvt::RepeatNone); |
|
|
444 | $img |
|
|
445 | } |
|
|
446 | |
|
|
447 | sub tile($) { |
|
|
448 | my $img = $_[0]->clone; |
|
|
449 | $img->repeat_mode (urxvt::RepeatNormal); |
|
|
450 | $img |
|
|
451 | } |
|
|
452 | |
|
|
453 | sub mirror($) { |
|
|
454 | my $img = $_[0]->clone; |
|
|
455 | $img->repeat_mode (urxvt::RepeatReflect); |
|
|
456 | $img |
|
|
457 | } |
|
|
458 | |
|
|
459 | sub extend($) { |
|
|
460 | my $img = $_[0]->clone; |
|
|
461 | $img->repeat_mode (urxvt::RepeatPad); |
|
|
462 | $img |
|
|
463 | } |
|
|
464 | |
59 | =back |
465 | =back |
60 | |
466 | |
61 | =head2 OPERATORS |
467 | =head2 VARIABLE VALUES |
|
|
468 | |
|
|
469 | The following functions provide variable data such as the terminal window |
|
|
470 | dimensions. They are not (Perl-) variables, they just return stuff that |
|
|
471 | varies. Most of them make your expression sensitive to some events, for |
|
|
472 | example using C<TW> (terminal width) means your expression is evaluated |
|
|
473 | again when the terminal is resized. |
62 | |
474 | |
63 | =over 4 |
475 | =over 4 |
64 | |
476 | |
65 | =cut |
477 | =item TX |
66 | |
478 | |
67 | # sub clone($) { |
479 | =item TY |
68 | # $_[0]->clone |
480 | |
|
|
481 | Return the X and Y coordinates of the terminal window (the terminal |
|
|
482 | window is the full window by default, and the character area only when in |
|
|
483 | border-respect mode). |
|
|
484 | |
|
|
485 | Using these functions make your expression sensitive to window moves. |
|
|
486 | |
|
|
487 | These functions are mainly useful to align images to the root window. |
|
|
488 | |
|
|
489 | Example: load an image and align it so it looks as if anchored to the |
|
|
490 | background (that's exactly what C<rootalign> does btw.): |
|
|
491 | |
|
|
492 | move -TX, -TY, keep { load "mybg.png" } |
|
|
493 | |
|
|
494 | =item TW |
|
|
495 | |
|
|
496 | Return the width (C<TW>) and height (C<TH>) of the terminal window (the |
|
|
497 | terminal window is the full window by default, and the character area only |
|
|
498 | when in border-respect mode). |
|
|
499 | |
|
|
500 | Using these functions make your expression sensitive to window resizes. |
|
|
501 | |
|
|
502 | These functions are mainly useful to scale images, or to clip images to |
|
|
503 | the window size to conserve memory. |
|
|
504 | |
|
|
505 | Example: take the screen background, clip it to the window size, blur it a |
|
|
506 | bit, align it to the window position and use it as background. |
|
|
507 | |
|
|
508 | clip move -TX, -TY, keep { blur 5, root } |
|
|
509 | |
|
|
510 | =cut |
|
|
511 | |
|
|
512 | sub TX() { $frame->[FR_AGAIN]{position} = 1; $x } |
|
|
513 | sub TY() { $frame->[FR_AGAIN]{position} = 1; $y } |
|
|
514 | sub TW() { $frame->[FR_AGAIN]{size} = 1; $w } |
|
|
515 | sub TH() { $frame->[FR_AGAIN]{size} = 1; $h } |
|
|
516 | |
|
|
517 | =item now |
|
|
518 | |
|
|
519 | Returns the current time as (fractional) seconds since the epoch. |
|
|
520 | |
|
|
521 | Using this expression does I<not> make your expression sensitive to time, |
|
|
522 | but the next two functions do. |
|
|
523 | |
|
|
524 | =item again $seconds |
|
|
525 | |
|
|
526 | When this function is used the expression will be reevaluated again in |
|
|
527 | C<$seconds> seconds. |
|
|
528 | |
|
|
529 | Example: load some image and rotate it according to the time of day (as if it were |
|
|
530 | the hour pointer of a clock). Update this image every minute. |
|
|
531 | |
|
|
532 | again 60; |
|
|
533 | rotate 50, 50, (now % 86400) * -72 / 8640, scale keep { load "myclock.png" } |
|
|
534 | |
|
|
535 | =item counter $seconds |
|
|
536 | |
|
|
537 | Like C<again>, but also returns an increasing counter value, starting at |
|
|
538 | 0, which might be useful for some simple animation effects. |
|
|
539 | |
|
|
540 | =cut |
|
|
541 | |
|
|
542 | sub now() { urxvt::NOW } |
|
|
543 | |
|
|
544 | sub again($) { |
|
|
545 | $frame->[FR_AGAIN]{time} = $_[0]; |
69 | # } |
546 | } |
70 | |
547 | |
|
|
548 | sub counter($) { |
|
|
549 | $frame->[FR_AGAIN]{time} = $_[0]; |
|
|
550 | $frame->[FR_STATE]{counter} + 0 |
|
|
551 | } |
|
|
552 | |
|
|
553 | =back |
|
|
554 | |
|
|
555 | =head2 SHAPE CHANGING OPERATORS |
|
|
556 | |
|
|
557 | The following operators modify the shape, size or position of the image. |
|
|
558 | |
|
|
559 | =over 4 |
|
|
560 | |
|
|
561 | =item clip $img |
|
|
562 | |
|
|
563 | =item clip $width, $height, $img |
|
|
564 | |
|
|
565 | =item clip $x, $y, $width, $height, $img |
|
|
566 | |
|
|
567 | Clips an image to the given rectangle. If the rectangle is outside the |
|
|
568 | image area (e.g. when C<$x> or C<$y> are negative) or the rectangle is |
|
|
569 | larger than the image, then the tiling mode defines how the extra pixels |
|
|
570 | will be filled. |
|
|
571 | |
|
|
572 | If C<$x> an C<$y> are missing, then C<0> is assumed for both. |
|
|
573 | |
|
|
574 | If C<$width> and C<$height> are missing, then the window size will be |
|
|
575 | assumed. |
|
|
576 | |
|
|
577 | Example: load an image, blur it, and clip it to the window size to save |
|
|
578 | memory. |
|
|
579 | |
|
|
580 | clip keep { blur 10, load "mybg.png" } |
|
|
581 | |
|
|
582 | =cut |
|
|
583 | |
71 | sub clip($$$$$;$) { |
584 | sub clip($;$$;$$) { |
72 | my $img = pop; |
585 | my $img = pop; |
|
|
586 | my $h = pop || TH; |
|
|
587 | my $w = pop || TW; |
73 | $img->sub_rect ($_[0], $_[1], $_[2], $_[3], $_[4]) |
588 | $img->sub_rect ($_[0], $_[1], $w, $h) |
|
|
589 | } |
|
|
590 | |
|
|
591 | =item scale $img |
|
|
592 | |
|
|
593 | =item scale $size_factor, $img |
|
|
594 | |
|
|
595 | =item scale $width_factor, $height_factor, $img |
|
|
596 | |
|
|
597 | Scales the image by the given factors in horizontal |
|
|
598 | (C<$width>) and vertical (C<$height>) direction. |
|
|
599 | |
|
|
600 | If only one factor is give, it is used for both directions. |
|
|
601 | |
|
|
602 | If no factors are given, scales the image to the window size without |
|
|
603 | keeping aspect. |
|
|
604 | |
|
|
605 | =item resize $width, $height, $img |
|
|
606 | |
|
|
607 | Resizes the image to exactly C<$width> times C<$height> pixels. |
|
|
608 | |
|
|
609 | =item fit $img |
|
|
610 | |
|
|
611 | =item fit $width, $height, $img |
|
|
612 | |
|
|
613 | Fits the image into the given C<$width> and C<$height> without changing |
|
|
614 | aspect, or the terminal size. That means it will be shrunk or grown until |
|
|
615 | the whole image fits into the given area, possibly leaving borders. |
|
|
616 | |
|
|
617 | =item cover $img |
|
|
618 | |
|
|
619 | =item cover $width, $height, $img |
|
|
620 | |
|
|
621 | Similar to C<fit>, but shrinks or grows until all of the area is covered |
|
|
622 | by the image, so instead of potentially leaving borders, it will cut off |
|
|
623 | image data that doesn't fit. |
|
|
624 | |
|
|
625 | =cut |
|
|
626 | |
|
|
627 | sub scale($;$;$) { |
|
|
628 | my $img = pop; |
|
|
629 | |
|
|
630 | @_ == 2 ? $img->scale ($_[0] * $img->w, $_[1] * $img->h) |
|
|
631 | : @_ ? $img->scale ($_[0] * $img->w, $_[0] * $img->h) |
|
|
632 | : $img->scale (TW, TH) |
74 | } |
633 | } |
75 | |
634 | |
76 | sub resize($$$) { |
635 | sub resize($$$) { |
77 | my $img = pop; |
636 | my $img = pop; |
78 | $img->scale ($_[0], $_[1]) |
637 | $img->scale ($_[0], $_[1]) |
79 | } |
638 | } |
80 | |
639 | |
81 | # TODO: ugly |
640 | sub fit($;$$) { |
|
|
641 | my $img = pop; |
|
|
642 | my $w = ($_[0] || TW) / $img->w; |
|
|
643 | my $h = ($_[1] || TH) / $img->h; |
|
|
644 | scale +(min $w, $h), $img |
|
|
645 | } |
|
|
646 | |
|
|
647 | sub cover($;$$) { |
|
|
648 | my $img = pop; |
|
|
649 | my $w = ($_[0] || TW) / $img->w; |
|
|
650 | my $h = ($_[1] || TH) / $img->h; |
|
|
651 | scale +(max $w, $h), $img |
|
|
652 | } |
|
|
653 | |
|
|
654 | =item move $dx, $dy, $img |
|
|
655 | |
|
|
656 | Moves the image by C<$dx> pixels in the horizontal, and C<$dy> pixels in |
|
|
657 | the vertical. |
|
|
658 | |
|
|
659 | Example: move the image right by 20 pixels and down by 30. |
|
|
660 | |
|
|
661 | move 20, 30, ... |
|
|
662 | |
|
|
663 | =item align $xalign, $yalign, $img |
|
|
664 | |
|
|
665 | Aligns the image according to a factor - C<0> means the image is moved to |
|
|
666 | the left or top edge (for C<$xalign> or C<$yalign>), C<0.5> means it is |
|
|
667 | exactly centered and C<1> means it touches the right or bottom edge. |
|
|
668 | |
|
|
669 | Example: remove any visible border around an image, center it vertically but move |
|
|
670 | it to the right hand side. |
|
|
671 | |
|
|
672 | align 1, 0.5, pad $img |
|
|
673 | |
|
|
674 | =item center $img |
|
|
675 | |
|
|
676 | =item center $width, $height, $img |
|
|
677 | |
|
|
678 | Centers the image, i.e. the center of the image is moved to the center of |
|
|
679 | the terminal window (or the box specified by C<$width> and C<$height> if |
|
|
680 | given). |
|
|
681 | |
|
|
682 | Example: load an image and center it. |
|
|
683 | |
|
|
684 | center keep { pad load "mybg.png" } |
|
|
685 | |
|
|
686 | =item rootalign $img |
|
|
687 | |
|
|
688 | Moves the image so that it appears glued to the screen as opposed to the |
|
|
689 | window. This gives the illusion of a larger area behind the window. It is |
|
|
690 | exactly equivalent to C<move -TX, -TY>, that is, it moves the image to the |
|
|
691 | top left of the screen. |
|
|
692 | |
|
|
693 | Example: load a background image, put it in mirror mode and root align it. |
|
|
694 | |
|
|
695 | rootalign keep { mirror load "mybg.png" } |
|
|
696 | |
|
|
697 | Example: take the screen background and align it, giving the illusion of |
|
|
698 | transparency as long as the window isn't in front of other windows. |
|
|
699 | |
|
|
700 | rootalign root |
|
|
701 | |
|
|
702 | =cut |
|
|
703 | |
82 | sub move($$;$) { |
704 | sub move($$;$) { |
|
|
705 | my $img = pop->clone; |
|
|
706 | $img->move ($_[0], $_[1]); |
|
|
707 | $img |
|
|
708 | } |
|
|
709 | |
|
|
710 | sub align($;$$) { |
83 | my $img = pop; |
711 | my $img = pop; |
84 | $img->sub_rect ( |
|
|
85 | $_[0], $_[1], |
|
|
86 | $img->w, $img->h, |
|
|
87 | $_[2], |
|
|
88 | ) |
|
|
89 | } |
|
|
90 | |
712 | |
|
|
713 | move $_[0] * (TW - $img->w), |
|
|
714 | $_[1] * (TH - $img->h), |
|
|
715 | $img |
|
|
716 | } |
|
|
717 | |
|
|
718 | sub center($;$$) { |
|
|
719 | my $img = pop; |
|
|
720 | my $w = $_[0] || TW; |
|
|
721 | my $h = $_[1] || TH; |
|
|
722 | |
|
|
723 | move 0.5 * ($w - $img->w), 0.5 * ($h - $img->h), $img |
|
|
724 | } |
|
|
725 | |
|
|
726 | sub rootalign($) { |
|
|
727 | move -TX, -TY, $_[0] |
|
|
728 | } |
|
|
729 | |
|
|
730 | =item rotate $center_x, $center_y, $degrees, $img |
|
|
731 | |
|
|
732 | Rotates the image clockwise by C<$degrees> degrees, around the point at |
|
|
733 | C<$center_x> and C<$center_y> (specified as factor of image width/height). |
|
|
734 | |
|
|
735 | Example: rotate the image by 90 degrees around it's center. |
|
|
736 | |
|
|
737 | rotate 0.5, 0.5, 90, keep { load "$HOME/mybg.png" } |
|
|
738 | |
|
|
739 | =cut |
|
|
740 | |
91 | sub rotate($$$$$$;$) { |
741 | sub rotate($$$$) { |
92 | my $img = pop; |
742 | my $img = pop; |
93 | $img->rotate ( |
743 | $img->rotate ( |
94 | $_[0], |
744 | $_[0] * ($img->w + $img->x), |
95 | $_[1], |
745 | $_[1] * ($img->h + $img->y), |
96 | $_[2] * $img->w * .01, |
|
|
97 | $_[3] * $img->h * .01, |
|
|
98 | $_[4] * (3.14159265 / 180), |
746 | $_[2] * (3.14159265 / 180), |
99 | $_[5], |
|
|
100 | ) |
747 | ) |
101 | } |
748 | } |
102 | |
749 | |
103 | sub blur($$$) { |
750 | =back |
104 | my ($rh, $rv, $img) = @_; |
|
|
105 | |
751 | |
106 | $img->blur ($rh, $rv); |
752 | =head2 COLOUR MODIFICATIONS |
107 | } |
753 | |
|
|
754 | The following operators change the pixels of the image. |
|
|
755 | |
|
|
756 | =over 4 |
|
|
757 | |
|
|
758 | =item contrast $factor, $img |
|
|
759 | |
|
|
760 | =item contrast $r, $g, $b, $img |
|
|
761 | |
|
|
762 | =item contrast $r, $g, $b, $a, $img |
|
|
763 | |
|
|
764 | Adjusts the I<contrast> of an image. |
|
|
765 | |
|
|
766 | The first form applies a single C<$factor> to red, green and blue, the |
|
|
767 | second form applies separate factors to each colour channel, and the last |
|
|
768 | form includes the alpha channel. |
|
|
769 | |
|
|
770 | Values from 0 to 1 lower the contrast, values higher than 1 increase the |
|
|
771 | contrast. |
|
|
772 | |
|
|
773 | Due to limitations in the underlying XRender extension, lowering contrast |
|
|
774 | also reduces brightness, while increasing contrast currently also |
|
|
775 | increases brightness. |
|
|
776 | |
|
|
777 | =item brightness $bias, $img |
|
|
778 | |
|
|
779 | =item brightness $r, $g, $b, $img |
|
|
780 | |
|
|
781 | =item brightness $r, $g, $b, $a, $img |
|
|
782 | |
|
|
783 | Adjusts the brightness of an image. |
|
|
784 | |
|
|
785 | The first form applies a single C<$bias> to red, green and blue, the |
|
|
786 | second form applies separate biases to each colour channel, and the last |
|
|
787 | form includes the alpha channel. |
|
|
788 | |
|
|
789 | Values less than 0 reduce brightness, while values larger than 0 increase |
|
|
790 | it. Useful range is from -1 to 1 - the former results in a black, the |
|
|
791 | latter in a white picture. |
|
|
792 | |
|
|
793 | Due to idiosyncrasies in the underlying XRender extension, biases less |
|
|
794 | than zero can be I<very> slow. |
|
|
795 | |
|
|
796 | =cut |
108 | |
797 | |
109 | sub contrast($$;$$;$) { |
798 | sub contrast($$;$$;$) { |
110 | my $img = pop; |
799 | my $img = pop; |
111 | my ($r, $g, $b, $a) = @_; |
800 | my ($r, $g, $b, $a) = @_; |
112 | |
801 | |
113 | ($g, $b) = ($r, $r) if @_ < 4; |
802 | ($g, $b) = ($r, $r) if @_ < 3; |
114 | $a = 1 if @_ < 5; |
803 | $a = 1 if @_ < 4; |
115 | |
804 | |
116 | $img = $img->clone; |
805 | $img = $img->clone; |
117 | $img->contrast ($r, $g, $b, $a); |
806 | $img->contrast ($r, $g, $b, $a); |
118 | $img |
807 | $img |
119 | } |
808 | } |
120 | |
809 | |
121 | sub brightness($$;$$;$) { |
810 | sub brightness($$;$$;$) { |
122 | my $img = pop; |
811 | my $img = pop; |
123 | my ($r, $g, $b, $a) = @_; |
812 | my ($r, $g, $b, $a) = @_; |
124 | |
813 | |
125 | ($g, $b) = ($r, $r) if @_ < 4; |
814 | ($g, $b) = ($r, $r) if @_ < 3; |
126 | $a = 1 if @_ < 5; |
815 | $a = 1 if @_ < 4; |
127 | |
816 | |
128 | $img = $img->clone; |
817 | $img = $img->clone; |
129 | $img->brightness ($r, $g, $b, $a); |
818 | $img->brightness ($r, $g, $b, $a); |
130 | $img |
819 | $img |
131 | } |
820 | } |
132 | |
821 | |
133 | sub X() { $new->{position_sensitive} = 1; $l } |
822 | =item blur $radius, $img |
134 | sub Y() { $new->{position_sensitive} = 1; $t } |
|
|
135 | sub W() { $new->{size_sensitive} = 1; $w } |
|
|
136 | sub H() { $new->{size_sensitive} = 1; $h } |
|
|
137 | |
823 | |
138 | sub now() { urxvt::NOW } |
824 | =item blur $radius_horz, $radius_vert, $img |
139 | |
825 | |
140 | sub again($) { |
826 | Gaussian-blurs the image with (roughly) C<$radius> pixel radius. The radii |
141 | $new->{again} = $_[0]; |
827 | can also be specified separately. |
142 | } |
|
|
143 | |
828 | |
144 | sub counter($) { |
829 | Blurring is often I<very> slow, at least compared or other |
145 | $new->{again} = $_[0]; |
830 | operators. Larger blur radii are slower than smaller ones, too, so if you |
146 | $bgdsl_self->{counter} + 0 |
831 | don't want to freeze your screen for long times, start experimenting with |
|
|
832 | low values for radius (<5). |
|
|
833 | |
|
|
834 | =cut |
|
|
835 | |
|
|
836 | sub blur($$;$) { |
|
|
837 | my $img = pop; |
|
|
838 | $img->blur ($_[0], @_ >= 2 ? $_[1] : $_[0]) |
147 | } |
839 | } |
148 | |
840 | |
149 | =back |
841 | =back |
150 | |
842 | |
|
|
843 | =head2 OTHER STUFF |
|
|
844 | |
|
|
845 | Anything that didn't fit any of the other categories, even after applying |
|
|
846 | force and closing our eyes. |
|
|
847 | |
|
|
848 | =over 4 |
|
|
849 | |
|
|
850 | =item once { ... } |
|
|
851 | |
|
|
852 | This function takes a code block as argument, that is, one or more |
|
|
853 | statements enclosed by braces. |
|
|
854 | |
|
|
855 | The trick is that this code block is only evaluated once - future calls |
|
|
856 | will simply return the original image (yes, it should only be used with |
|
|
857 | images). |
|
|
858 | |
|
|
859 | This can be extremely useful to avoid redoing the same slow operations |
|
|
860 | again and again- for example, if your background expression takes the root |
|
|
861 | background, blurs it and then root-aligns it it would have to blur the |
|
|
862 | root background on every window move or resize. |
|
|
863 | |
|
|
864 | In fact, urxvt itself encloses the whole expression in some kind of |
|
|
865 | C<once> block so it only is reevaluated as required. |
|
|
866 | |
|
|
867 | Putting the blur into a C<once> block will make sure the blur is only done |
|
|
868 | once: |
|
|
869 | |
|
|
870 | rootlign once { blur 10, root } |
|
|
871 | |
|
|
872 | This leaves the question of how to force reevaluation of the block, |
|
|
873 | in case the root background changes: If expression inside the block |
|
|
874 | is sensitive to some event (root background changes, window geometry |
|
|
875 | changes), then it will be reevaluated automatically as needed. |
|
|
876 | |
|
|
877 | =item once_again |
|
|
878 | |
|
|
879 | Resets all C<once> block as if they had never been called, i.e. on the |
|
|
880 | next call they will be reevaluated again. |
|
|
881 | |
|
|
882 | =cut |
|
|
883 | |
|
|
884 | sub once(&) { |
|
|
885 | my $id = $_[0]+0; |
|
|
886 | |
|
|
887 | local $frame = $self->{frame_cache}{$id} ||= [$frame]; |
|
|
888 | |
|
|
889 | unless ($frame->[FR_CACHE]) { |
|
|
890 | $frame->[FR_CACHE] = [ $_[0]() ]; |
|
|
891 | |
|
|
892 | my $self = $self; |
|
|
893 | my $frame = $frame; |
|
|
894 | Scalar::Util::weaken $frame; |
|
|
895 | $self->compile_frame ($frame, sub { |
|
|
896 | # clear this frame cache, also for all parents |
|
|
897 | for (my $frame = $frame; $frame; $frame = $frame->[0]) { |
|
|
898 | undef $frame->[FR_CACHE]; |
|
|
899 | } |
|
|
900 | |
|
|
901 | $self->recalculate; |
|
|
902 | }); |
|
|
903 | }; |
|
|
904 | |
|
|
905 | # in scalar context we always return the first original result, which |
|
|
906 | # is not quite how perl works. |
|
|
907 | wantarray |
|
|
908 | ? @{ $frame->[FR_CACHE] } |
|
|
909 | : $frame->[FR_CACHE][0] |
|
|
910 | } |
|
|
911 | |
|
|
912 | sub once_again() { |
|
|
913 | delete $self->{frame_cache}; |
|
|
914 | } |
|
|
915 | |
|
|
916 | =back |
|
|
917 | |
151 | =cut |
918 | =cut |
152 | |
919 | |
153 | } |
920 | } |
154 | |
921 | |
155 | sub parse_expr { |
922 | sub parse_expr { |
156 | my $expr = eval "sub {\npackage urxvt::bgdsl;\n#line 0 'background expression'\n$_[0]\n}"; |
923 | my $expr = eval |
|
|
924 | "sub {\n" |
|
|
925 | . "package urxvt::bgdsl;\n" |
|
|
926 | . "#line 0 'background expression'\n" |
|
|
927 | . "$_[0]\n" |
|
|
928 | . "}"; |
157 | die if $@; |
929 | die if $@; |
158 | $expr |
930 | $expr |
159 | } |
931 | } |
160 | |
932 | |
161 | # compiles a parsed expression |
933 | # compiles a parsed expression |
162 | sub set_expr { |
934 | sub set_expr { |
163 | my ($self, $expr) = @_; |
935 | my ($self, $expr) = @_; |
164 | |
936 | |
|
|
937 | $self->{root} = []; |
165 | $self->{expr} = $expr; |
938 | $self->{expr} = $expr; |
166 | $self->recalculate; |
939 | $self->recalculate; |
167 | } |
940 | } |
168 | |
941 | |
|
|
942 | # takes a hash of sensitivity indicators and installs watchers |
|
|
943 | sub compile_frame { |
|
|
944 | my ($self, $frame, $cb) = @_; |
|
|
945 | |
|
|
946 | my $state = $frame->[urxvt::bgdsl::FR_STATE] ||= {}; |
|
|
947 | my $again = $frame->[urxvt::bgdsl::FR_AGAIN]; |
|
|
948 | |
|
|
949 | # don't keep stuff alive |
|
|
950 | Scalar::Util::weaken $state; |
|
|
951 | |
|
|
952 | if ($again->{nested}) { |
|
|
953 | $state->{nested} = 1; |
|
|
954 | } else { |
|
|
955 | delete $state->{nested}; |
|
|
956 | } |
|
|
957 | |
|
|
958 | if (my $interval = $again->{time}) { |
|
|
959 | $state->{time} = [$interval, urxvt::timer->new->after ($interval)->interval ($interval)] |
|
|
960 | if $state->{time}[0] != $interval; |
|
|
961 | |
|
|
962 | # callback *might* have changed, although we could just rule that out |
|
|
963 | $state->{time}[1]->cb (sub { |
|
|
964 | ++$state->{counter}; |
|
|
965 | $cb->(); |
|
|
966 | }); |
|
|
967 | } else { |
|
|
968 | delete $state->{time}; |
|
|
969 | } |
|
|
970 | |
|
|
971 | if ($again->{position}) { |
|
|
972 | $state->{position} = $self->on (position_change => $cb); |
|
|
973 | } else { |
|
|
974 | delete $state->{position}; |
|
|
975 | } |
|
|
976 | |
|
|
977 | if ($again->{size}) { |
|
|
978 | $state->{size} = $self->on (size_change => $cb); |
|
|
979 | } else { |
|
|
980 | delete $state->{size}; |
|
|
981 | } |
|
|
982 | |
|
|
983 | if ($again->{rootpmap}) { |
|
|
984 | $state->{rootpmap} = $self->on (rootpmap_change => $cb); |
|
|
985 | } else { |
|
|
986 | delete $state->{rootpmap}; |
|
|
987 | } |
|
|
988 | } |
|
|
989 | |
169 | # evaluate the current bg expression |
990 | # evaluate the current bg expression |
170 | sub recalculate { |
991 | sub recalculate { |
171 | my ($self) = @_; |
992 | my ($arg_self) = @_; |
172 | |
993 | |
173 | # rate limit evaluation |
994 | # rate limit evaluation |
174 | |
995 | |
175 | if ($self->{next_refresh} > urxvt::NOW) { |
996 | if ($arg_self->{next_refresh} > urxvt::NOW) { |
176 | $self->{next_refresh_timer} = urxvt::timer->new->after ($self->{next_refresh} - urxvt::NOW)->cb (sub { |
997 | $arg_self->{next_refresh_timer} = urxvt::timer->new->after ($arg_self->{next_refresh} - urxvt::NOW)->cb (sub { |
177 | $self->recalculate; |
998 | $arg_self->recalculate; |
178 | }); |
999 | }); |
179 | return; |
1000 | return; |
180 | } |
1001 | } |
181 | |
1002 | |
182 | $self->{next_refresh} = urxvt::NOW + $MIN_INTERVAL; |
1003 | $arg_self->{next_refresh} = urxvt::NOW + $MIN_INTERVAL; |
183 | |
1004 | |
184 | # set environment to evaluate user expression |
1005 | # set environment to evaluate user expression |
185 | |
1006 | |
186 | local $bgdsl_self = $self; |
1007 | local $self = $arg_self; |
|
|
1008 | local $HOME = $ENV{HOME}; |
|
|
1009 | local $frame = []; |
187 | |
1010 | |
188 | local $old = $self->{state}; |
1011 | ($x, $y, $w, $h) = $self->background_geometry ($self->{border}); |
189 | local $new = my $state = $self->{state} = {}; |
|
|
190 | |
|
|
191 | ($l, $t, $w, $h) = |
|
|
192 | $self->get_geometry; |
|
|
193 | |
1012 | |
194 | # evaluate user expression |
1013 | # evaluate user expression |
195 | |
1014 | |
196 | my $img = eval { $self->{expr}->() }; |
1015 | my @img = eval { $self->{expr}->() }; |
197 | warn $@ if $@;#d# |
1016 | die $@ if $@; |
|
|
1017 | die "background-expr did not return anything.\n" unless @img; |
|
|
1018 | die "background-expr: expected image(s), got something else.\n" |
198 | die if !UNIVERSAL::isa $img, "urxvt::img"; |
1019 | if grep { !UNIVERSAL::isa $_, "urxvt::img" } @img; |
|
|
1020 | |
|
|
1021 | my $img = urxvt::bgdsl::merge @img; |
|
|
1022 | |
|
|
1023 | $frame->[FR_AGAIN]{size} = 1 |
|
|
1024 | if $img->repeat_mode != urxvt::RepeatNormal; |
199 | |
1025 | |
200 | # if the expression is sensitive to external events, prepare reevaluation then |
1026 | # if the expression is sensitive to external events, prepare reevaluation then |
201 | |
1027 | $self->compile_frame ($frame, sub { $arg_self->recalculate }); |
202 | my $repeat; |
|
|
203 | |
|
|
204 | if (my $again = $state->{again}) { |
|
|
205 | $repeat = 1; |
|
|
206 | $state->{timer} = $again == $old->{again} |
|
|
207 | ? $old->{timer} |
|
|
208 | : urxvt::timer->new->after ($again)->interval ($again)->cb (sub { |
|
|
209 | ++$self->{counter}; |
|
|
210 | $self->recalculate |
|
|
211 | }); |
|
|
212 | } |
|
|
213 | |
|
|
214 | if (delete $state->{position_sensitive}) { |
|
|
215 | $repeat = 1; |
|
|
216 | $self->enable (position_change => sub { $_[0]->recalculate }); |
|
|
217 | } else { |
|
|
218 | $self->disable ("position_change"); |
|
|
219 | } |
|
|
220 | |
|
|
221 | if (delete $state->{size_sensitive}) { |
|
|
222 | $repeat = 1; |
|
|
223 | $self->enable (size_change => sub { $_[0]->recalculate }); |
|
|
224 | } else { |
|
|
225 | $self->disable ("size_change"); |
|
|
226 | } |
|
|
227 | |
|
|
228 | if (delete $state->{rootpmap_sensitive}) { |
|
|
229 | $repeat = 1; |
|
|
230 | $self->enable (rootpmap_change => sub { $_[0]->recalculate }); |
|
|
231 | } else { |
|
|
232 | $self->disable ("rootpmap_change"); |
|
|
233 | } |
|
|
234 | |
1028 | |
235 | # clear stuff we no longer need |
1029 | # clear stuff we no longer need |
236 | |
1030 | |
237 | %$old = (); |
1031 | # unless (%{ $frame->[FR_STATE] }) { |
238 | |
|
|
239 | unless ($repeat) { |
|
|
240 | delete $self->{state}; |
1032 | # delete $self->{state}; |
241 | delete $self->{expr}; |
1033 | # delete $self->{expr}; |
242 | } |
1034 | # } |
243 | |
1035 | |
244 | # prepare and set background pixmap |
1036 | # set background pixmap |
245 | |
1037 | |
246 | $img = $img->sub_rect (0, 0, $w, $h) |
|
|
247 | if $img->w != $w || $img->h != $h; |
|
|
248 | |
|
|
249 | $self->set_background ($img); |
1038 | $self->set_background ($img, $self->{border}); |
250 | $self->scr_recolour (0); |
1039 | $self->scr_recolour (0); |
251 | $self->want_refresh; |
1040 | $self->want_refresh; |
252 | } |
1041 | } |
253 | |
1042 | |
254 | sub on_start { |
1043 | sub on_start { |
255 | my ($self) = @_; |
1044 | my ($self) = @_; |
256 | |
1045 | |
|
|
1046 | my $expr = $self->x_resource ("%.expr") |
|
|
1047 | or return; |
|
|
1048 | |
|
|
1049 | $self->has_render |
|
|
1050 | or die "background extension needs RENDER extension 0.10 or higher, ignoring background-expr.\n"; |
|
|
1051 | |
257 | $self->set_expr (parse_expr $EXPR); |
1052 | $self->set_expr (parse_expr $expr); |
|
|
1053 | $self->{border} = $self->x_resource_boolean ("%.border"); |
|
|
1054 | |
|
|
1055 | $MIN_INTERVAL = $self->x_resource ("%.interval"); |
258 | |
1056 | |
259 | () |
1057 | () |
260 | } |
1058 | } |
261 | |
1059 | |