--------------------------------------------------------------------------- --- Module dedicated to gather common shape painters. -- -- It add the concept of "shape" to Awesome. A shape can be applied to a -- background, a margin, a mask or a drawable shape bounding. -- -- The functions exposed by this module always take a context as first -- parameter followed by the widget and height and additional parameters. -- -- The functions provided by this module only create a path in the content. -- to actually draw the content, use `cr:fill()`, `cr:mask()`, `cr:clip()` or -- `cr:stroke()` -- -- In many case, it is necessary to apply the shape using a transformation -- such as a rotation. The preferred way to do this is to wrap the function -- in another function calling `cr:rotate()` (or any other transformation -- matrix). -- -- To specialize a shape where the API doesn't allows extra arguments to be -- passed, it is possible to wrap the shape function like: -- -- local new_shape = function(cr, width, height) -- gears.shape.rounded_rect(cr, width, height, 2) -- end -- -- Many elements can be shaped. This include: -- -- * `client`s (see `gears.surface.apply_shape_bounding`) -- * `wibox`es (see `wibox.shape`) -- * All widgets (see `wibox.container.background`) -- * The progressbar (see `wibox.widget.progressbar.bar_shape`) -- * The graph (see `wibox.widget.graph.step_shape`) -- * The checkboxes (see `wibox.widget.checkbox.check_shape`) -- * Images (see `wibox.widget.imagebox.clip_shape`) -- * The taglist tags (see `awful.widget.taglist`) -- * The tasklist clients (see `awful.widget.tasklist`) -- * The tooltips (see `awful.tooltip`) -- -- @author Emmanuel Lepage Vallee -- @copyright 2011-2016 Emmanuel Lepage Vallee -- @themelib gears.shape --------------------------------------------------------------------------- local g_matrix = require( "gears.matrix" ) local unpack = unpack or table.unpack -- luacheck: globals unpack (compatibility with Lua 5.1) local atan2 = math.atan2 or math.atan -- lua 5.3 compat local module = {} --- Add a rounded rectangle to the current path. -- Note: If the radius is bigger than either half side, it will be reduced. -- -- @DOC_gears_shape_rounded_rect_EXAMPLE@ -- -- @param cr A cairo content -- @tparam number width The rectangle width -- @tparam number height The rectangle height -- @tparam number radius the corner radius -- @staticfct gears.shape.rounded_rect function module.rounded_rect(cr, width, height, radius) radius = radius or 10 if width / 2 < radius then radius = width / 2 end if height / 2 < radius then radius = height / 2 end cr:move_to(0, radius) cr:arc( radius , radius , radius, math.pi , 3*(math.pi/2) ) cr:arc( width-radius, radius , radius, 3*(math.pi/2), math.pi*2 ) cr:arc( width-radius, height-radius, radius, math.pi*2 , math.pi/2 ) cr:arc( radius , height-radius, radius, math.pi/2 , math.pi ) cr:close_path() end --- Add a rectangle delimited by 2 180 degree arcs to the path. -- -- @DOC_gears_shape_rounded_bar_EXAMPLE@ -- -- @param cr A cairo content -- @param width The rectangle width -- @param height The rectangle height. -- @staticfct gears.shape.rounded_bar function module.rounded_bar(cr, width, height) module.rounded_rect(cr, width, height, height / 2) end --- A rounded rect with only some of the corners rounded. -- -- @DOC_gears_shape_partially_rounded_rect_EXAMPLE@ -- -- @param cr A cairo context -- @tparam number width The shape width -- @tparam number height The shape height -- @tparam boolean tl If the top left corner is rounded -- @tparam boolean tr If the top right corner is rounded -- @tparam boolean br If the bottom right corner is rounded -- @tparam boolean bl If the bottom left corner is rounded -- @tparam number rad The corner radius -- @staticfct gears.shape.partially_rounded_rect function module.partially_rounded_rect(cr, width, height, tl, tr, br, bl, rad) rad = rad or 10 if width / 2 < rad then rad = width / 2 end if height / 2 < rad then rad = height / 2 end -- Top left if tl then cr:arc( rad, rad, rad, math.pi, 3*(math.pi/2)) else cr:move_to(0,0) end -- Top right if tr then cr:arc( width-rad, rad, rad, 3*(math.pi/2), math.pi*2) else cr:line_to(width, 0) end -- Bottom right if br then cr:arc( width-rad, height-rad, rad, math.pi*2 , math.pi/2) else cr:line_to(width, height) end -- Bottom left if bl then cr:arc( rad, height-rad, rad, math.pi/2, math.pi) else cr:line_to(0, height) end cr:close_path() end --- A rounded rectangle with a triangle at the top. -- -- @DOC_gears_shape_infobubble_EXAMPLE@ -- -- @param cr A cairo context -- @tparam number width The shape width -- @tparam number height The shape height -- @tparam[opt=5] number corner_radius The corner radius -- @tparam[opt=10] number arrow_size The width and height of the arrow -- @tparam[opt=width/2 - arrow_size/2] number arrow_position The position of the arrow -- @staticfct gears.shape.infobubble function module.infobubble(cr, width, height, corner_radius, arrow_size, arrow_position) arrow_size = arrow_size or 10 corner_radius = math.min((height-arrow_size)/2, corner_radius or 5) arrow_position = arrow_position or width/2 - arrow_size/2 cr:move_to(0 ,corner_radius+arrow_size) -- Top left corner cr:arc(corner_radius, corner_radius+arrow_size, (corner_radius), math.pi, 3*(math.pi/2)) -- The arrow triangle (still at the top) cr:line_to(arrow_position , arrow_size ) cr:line_to(arrow_position + arrow_size , 0 ) cr:line_to(arrow_position + 2*arrow_size , arrow_size ) -- Complete the rounded rounded rectangle cr:arc(width-corner_radius, corner_radius+arrow_size , (corner_radius) , 3*(math.pi/2) , math.pi*2 ) cr:arc(width-corner_radius, height-(corner_radius) , (corner_radius) , math.pi*2 , math.pi/2 ) cr:arc(corner_radius , height-(corner_radius) , (corner_radius) , math.pi/2 , math.pi ) -- Close path cr:close_path() end --- A rectangle terminated by an arrow. -- -- @DOC_gears_shape_rectangular_tag_EXAMPLE@ -- -- @param cr A cairo context -- @tparam number width The shape width -- @tparam number height The shape height -- @tparam[opt=height/2] number arrow_length The length of the arrow part -- @staticfct gears.shape.rectangular_tag function module.rectangular_tag(cr, width, height, arrow_length) arrow_length = arrow_length or height/2 if arrow_length > 0 then cr:move_to(0 , height/2 ) cr:line_to(arrow_length , 0 ) cr:line_to(width , 0 ) cr:line_to(width , height ) cr:line_to(arrow_length , height ) else cr:move_to(0 , 0 ) cr:line_to(-arrow_length, height/2 ) cr:line_to(0 , height ) cr:line_to(width , height ) cr:line_to(width , 0 ) end cr:close_path() end --- A simple arrow shape. -- -- @DOC_gears_shape_arrow_EXAMPLE@ -- -- @param cr A cairo context -- @tparam number width The shape width -- @tparam number height The shape height -- @tparam[opt=head_width] number head_width The width of the head (/\) of the arrow -- @tparam[opt=width /2] number shaft_width The width of the shaft of the arrow -- @tparam[opt=height/2] number shaft_length The head_length of the shaft (the rest is the head) -- @staticfct gears.shape.arrow function module.arrow(cr, width, height, head_width, shaft_width, shaft_length) shaft_length = shaft_length or height / 2 shaft_width = shaft_width or width / 2 head_width = head_width or width local head_length = height - shaft_length cr:move_to ( width/2 , 0 ) cr:rel_line_to( head_width/2 , head_length ) cr:rel_line_to( -(head_width-shaft_width)/2 , 0 ) cr:rel_line_to( 0 , shaft_length ) cr:rel_line_to( -shaft_width , 0 ) cr:rel_line_to( 0 , -shaft_length ) cr:rel_line_to( -(head_width-shaft_width)/2 , 0 ) cr:close_path() end --- A squeezed hexagon filling the rectangle. -- -- @DOC_gears_shape_hexagon_EXAMPLE@ -- -- @param cr A cairo context -- @tparam number width The shape width -- @tparam number height The shape height -- @staticfct gears.shape.hexagon function module.hexagon(cr, width, height) cr:move_to(height/2,0) cr:line_to(width-height/2,0) cr:line_to(width,height/2) cr:line_to(width-height/2,height) cr:line_to(height/2,height) cr:line_to(0,height/2) cr:line_to(height/2,0) cr:close_path() end --- Double arrow popularized by the vim-powerline module. -- -- @DOC_gears_shape_powerline_EXAMPLE@ -- -- @param cr A cairo context -- @tparam number width The shape width -- @tparam number height The shape height -- @tparam[opt=height/2] number arrow_depth The width of the arrow part of the shape -- @staticfct gears.shape.powerline function module.powerline(cr, width, height, arrow_depth) arrow_depth = arrow_depth or height/2 local offset = 0 -- Avoid going out of the (potential) clip area if arrow_depth < 0 then width = width + 2*arrow_depth offset = -arrow_depth end cr:move_to(offset , 0 ) cr:line_to(offset + width - arrow_depth , 0 ) cr:line_to(offset + width , height/2 ) cr:line_to(offset + width - arrow_depth , height ) cr:line_to(offset , height ) cr:line_to(offset + arrow_depth , height/2 ) cr:close_path() end --- An isosceles triangle. -- -- @DOC_gears_shape_isosceles_triangle_EXAMPLE@ -- -- @param cr A cairo context -- @tparam number width The shape width -- @tparam number height The shape height -- @staticfct gears.shape.isosceles_triangle function module.isosceles_triangle(cr, width, height) cr:move_to( width/2, 0 ) cr:line_to( width , height ) cr:line_to( 0 , height ) cr:close_path() end --- A cross (**+**) symbol. -- -- @DOC_gears_shape_cross_EXAMPLE@ -- -- @param cr A cairo context -- @tparam number width The shape width -- @tparam number height The shape height -- @tparam[opt=width/3] number thickness The cross section thickness -- @staticfct gears.shape.cross function module.cross(cr, width, height, thickness) thickness = thickness or width/3 local xpadding = (width - thickness) / 2 local ypadding = (height - thickness) / 2 cr:move_to(xpadding, 0) cr:line_to(width - xpadding, 0) cr:line_to(width - xpadding, ypadding) cr:line_to(width , ypadding) cr:line_to(width , height-ypadding) cr:line_to(width - xpadding, height-ypadding) cr:line_to(width - xpadding, height ) cr:line_to(xpadding , height ) cr:line_to(xpadding , height-ypadding) cr:line_to(0 , height-ypadding) cr:line_to(0 , ypadding ) cr:line_to(xpadding , ypadding ) cr:close_path() end --- A similar shape to the `rounded_rect`, but with sharp corners. -- -- @DOC_gears_shape_octogon_EXAMPLE@ -- -- @param cr A cairo context -- @tparam number width The shape width -- @tparam number height The shape height -- @tparam number corner_radius -- @staticfct gears.shape.octogon function module.octogon(cr, width, height, corner_radius) corner_radius = corner_radius or math.min(10, math.min(width, height)/4) local offset = math.sqrt( (corner_radius*corner_radius) / 2 ) cr:move_to(offset, 0) cr:line_to(width-offset, 0) cr:line_to(width, offset) cr:line_to(width, height-offset) cr:line_to(width-offset, height) cr:line_to(offset, height) cr:line_to(0, height-offset) cr:line_to(0, offset) cr:close_path() end --- A circle shape. -- -- @DOC_gears_shape_circle_EXAMPLE@ -- -- @param cr A cairo context -- @tparam number width The shape width -- @tparam number height The shape height -- @tparam[opt=math.min(width height) / 2)] number radius The radius -- @staticfct gears.shape.circle function module.circle(cr, width, height, radius) radius = radius or math.min(width, height) / 2 cr:move_to(width/2+radius, height/2) cr:arc(width / 2, height / 2, radius, 0, 2*math.pi) cr:close_path() end --- A simple rectangle. -- -- @DOC_gears_shape_rectangle_EXAMPLE@ -- -- @param cr A cairo context -- @tparam number width The shape width -- @tparam number height The shape height -- @staticfct gears.shape.rectangle function module.rectangle(cr, width, height) cr:rectangle(0, 0, width, height) end --- A diagonal parallelogram with the bottom left corner at x=0 and top right -- at x=width. -- -- @DOC_gears_shape_parallelogram_EXAMPLE@ -- -- @param cr A cairo context -- @tparam number width The shape width -- @tparam number height The shape height -- @tparam[opt=width/3] number base_width The parallelogram base width -- @staticfct gears.shape.parallelogram function module.parallelogram(cr, width, height, base_width) base_width = base_width or width/3 cr:move_to(width-base_width, 0 ) cr:line_to(width , 0 ) cr:line_to(base_width , height ) cr:line_to(0 , height ) cr:close_path() end --- A losange. -- -- @DOC_gears_shape_losange_EXAMPLE@ -- -- @param cr A cairo context -- @tparam number width The shape width -- @tparam number height The shape height -- @staticfct gears.shape.losange function module.losange(cr, width, height) cr:move_to(width/2 , 0 ) cr:line_to(width , height/2 ) cr:line_to(width/2 , height ) cr:line_to(0 , height/2 ) cr:close_path() end --- A pie. -- -- The pie center is the center of the area. -- -- @DOC_gears_shape_pie_EXAMPLE@ -- -- @param cr A cairo context -- @tparam number width The shape width -- @tparam number height The shape height -- @tparam[opt=0] number start_angle The start angle (in radian) -- @tparam[opt=math.pi/2] number end_angle The end angle (in radian) -- @tparam[opt=math.min(width height)/2] number radius The shape height -- @staticfct gears.shape.pie function module.pie(cr, width, height, start_angle, end_angle, radius) radius = radius or math.floor(math.min(width, height)/2) start_angle, end_angle = start_angle or 0, end_angle or math.pi/2 -- If the shape is a circle, then avoid the lines if math.abs(start_angle + end_angle - 2*math.pi) <= 0.01 then cr:arc(width/2, height/2, radius, 0, 2*math.pi) else cr:move_to(width/2, height/2) cr:line_to( width/2 + math.cos(start_angle)*radius, height/2 + math.sin(start_angle)*radius ) cr:arc(width/2, height/2, radius, start_angle, end_angle) end cr:close_path() end --- A rounded arc. -- -- The pie center is the center of the area. -- -- @DOC_gears_shape_arc_EXAMPLE@ -- -- @param cr A cairo context -- @tparam number width The shape width -- @tparam number height The shape height -- @tparam[opt=math.min(width height)/2] number thickness The arc thickness -- @tparam[opt=0] number start_angle The start angle (in radian) -- @tparam[opt=math.pi/2] number end_angle The end angle (in radian) -- @tparam[opt=false] boolean start_rounded if the arc start rounded -- @tparam[opt=false] boolean end_rounded if the arc end rounded -- @staticfct gears.shape.arc function module.arc(cr, width, height, thickness, start_angle, end_angle, start_rounded, end_rounded) start_angle = start_angle or 0 end_angle = end_angle or math.pi/2 -- This shape is a partial circle local radius = math.min(width, height)/2 thickness = thickness or radius/2 local inner_radius = radius - thickness -- As the edge of the small arc need to touch the [start_p1, start_p2] -- line, a small subset of the arc circumference has to be substracted -- that's (less or more) equal to the thickness/2 (a little longer given -- it is an arc and not a line, but it wont show) local arc_percent = math.abs(end_angle-start_angle)/(2*math.pi) local arc_length = ((radius-thickness/2)*2*math.pi)*arc_percent if start_rounded then arc_length = arc_length - thickness/2 -- And back to angles start_angle = end_angle - (arc_length/(radius - thickness/2)) end if end_rounded then arc_length = arc_length - thickness/2 -- And back to angles. Also make sure to avoid underflowing when the -- rounded edge radius is greater than the angle delta. end_angle = start_angle + math.max( 0, arc_length/(radius - thickness/2) ) end -- The path is a curcular arc joining 4 points -- Outer first corner local start_p1 = { width /2 + math.cos(start_angle)*radius, height/2 + math.sin(start_angle)*radius } if start_rounded then -- Inner first corner local start_p2 = { width /2 + math.cos(start_angle)*inner_radius, height/2 + math.sin(start_angle)*inner_radius } local median_angle = atan2( start_p2[1] - start_p1[1], -(start_p2[2] - start_p1[2]) ) local arc_center = { (start_p1[1] + start_p2[1])/2, (start_p1[2] + start_p2[2])/2, } cr:arc(arc_center[1], arc_center[2], thickness/2, median_angle-math.pi/2, median_angle+math.pi/2 ) else cr:move_to(unpack(start_p1)) end cr:arc(width/2, height/2, radius, start_angle, end_angle) if end_rounded then -- Outer second corner local end_p1 = { width /2 + math.cos(end_angle)*radius, height/2 + math.sin(end_angle)*radius } -- Inner first corner local end_p2 = { width /2 + math.cos(end_angle)*inner_radius, height/2 + math.sin(end_angle)*inner_radius } local median_angle = atan2( end_p2[1] - end_p1[1], -(end_p2[2] - end_p1[2]) ) - math.pi local arc_center = { (end_p1[1] + end_p2[1])/2, (end_p1[2] + end_p2[2])/2, } cr:arc(arc_center[1], arc_center[2], thickness/2, median_angle-math.pi/2, median_angle+math.pi/2 ) end cr:arc_negative(width/2, height/2, inner_radius, end_angle, start_angle) cr:close_path() end --- A partial rounded bar. How much of the rounded bar is visible depends on -- the given percentage value. -- -- Note that this shape is not closed and thus filling it doesn't make much -- sense. -- -- @DOC_gears_shape_radial_progress_EXAMPLE@ -- -- @param cr A cairo context -- @tparam number w The shape width -- @tparam number h The shape height -- @tparam number percent The progressbar percent -- @tparam boolean hide_left Do not draw the left side of the shape -- @staticfct gears.shape.radial_progress function module.radial_progress(cr, w, h, percent, hide_left) percent = percent or 1 local total_length = (2*(w-h))+2*((h/2)*math.pi) local bar_percent = (w-h)/total_length local arc_percent = ((h/2)*math.pi)/total_length -- Bottom line if percent > bar_percent then cr:move_to(h/2,h) cr:line_to((h/2) + (w-h),h) cr:stroke() elseif percent < bar_percent then cr:move_to(h/2,h) cr:line_to(h/2+(total_length*percent),h) cr:stroke() end -- Right arc if percent >= bar_percent+arc_percent then cr:arc(w-h/2 , h/2, h/2,3*(math.pi/2),math.pi/2) cr:stroke() elseif percent > bar_percent and percent < bar_percent+(arc_percent/2) then cr:arc(w-h/2 , h/2, h/2,(math.pi/2)-((math.pi/2)*((percent-bar_percent)/(arc_percent/2))),math.pi/2) cr:stroke() elseif percent >= bar_percent+arc_percent/2 and percent < bar_percent+arc_percent then cr:arc(w-h/2 , h/2, h/2,0,math.pi/2) cr:stroke() local add = (math.pi/2)*((percent-bar_percent-arc_percent/2)/(arc_percent/2)) cr:arc(w-h/2 , h/2, h/2,2*math.pi-add,0) cr:stroke() end -- Top line if percent > 2*bar_percent+arc_percent then cr:move_to((h/2) + (w-h),0) cr:line_to(h/2,0) cr:stroke() elseif percent > bar_percent+arc_percent and percent < 2*bar_percent+arc_percent then cr:move_to((h/2) + (w-h),0) cr:line_to(((h/2) + (w-h))-total_length*(percent-bar_percent-arc_percent),0) cr:stroke() end -- Left arc if not hide_left then if percent > 0.985 then cr:arc(h/2, h/2, h/2,math.pi/2,3*(math.pi/2)) cr:stroke() elseif percent > 2*bar_percent+arc_percent then local relpercent = (percent - 2*bar_percent - arc_percent)/arc_percent cr:arc(h/2, h/2, h/2,3*(math.pi/2)-(math.pi)*relpercent,3*(math.pi/2)) cr:stroke() end end end --- Adjust the shape using a transformation object -- -- Apply various transformations to the shape -- -- @usage gears.shape.transform(gears.shape.rounded_bar) -- : rotate(math.pi/2) -- : translate(10, 10) -- -- @param shape A shape function -- @return A transformation handle, also act as a shape function -- @staticfct gears.shape.transform function module.transform(shape) -- Apply the transformation matrix and apply the shape, then restore local function apply(self, cr, width, height, ...) cr:save() cr:transform(self.matrix:to_cairo_matrix()) shape(cr, width, height, ...) cr:restore() end -- Redirect function calls like :rotate() to the underlying matrix local function index(_, key) return function(self, ...) self.matrix = self.matrix[key](self.matrix, ...) return self end end local result = setmetatable({ matrix = g_matrix.identity }, { __call = apply, __index = index }) return result end return module -- vim: filetype=lua:expandtab:shiftwidth=4:tabstop=8:softtabstop=4:textwidth=80