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# https://github.com/jheinen/GR.jl
# significant contributions by @jheinen
import GR
export GR
# --------------------------------------------------------------------------------------
const gr_linetype = KW(
:auto => 1,
:solid => 1,
:dash => 2,
:dot => 3,
:dashdot => 4,
:dashdotdot => -1
)
const gr_markertype = KW(
:auto => 1,
:none => -1,
:circle => -1,
:rect => -7,
:diamond => -13,
:utriangle => -3,
:dtriangle => -5,
:ltriangle => -18,
:rtriangle => -17,
:pentagon => -21,
:hexagon => -22,
:heptagon => -23,
:octagon => -24,
:cross => 2,
:xcross => 5,
:+ => 2,
:x => 5,
:star4 => -25,
:star5 => -26,
:star6 => -27,
:star7 => -28,
:star8 => -29,
:vline => -30,
:hline => -31
)
const gr_halign = KW(
:left => 1,
:hcenter => 2,
:right => 3
)
const gr_valign = KW(
:top => 1,
:vcenter => 3,
:bottom => 5
)
const gr_font_family = Dict(
"times" => 1,
"helvetica" => 5,
"courier" => 9,
"bookman" => 14,
"newcenturyschlbk" => 18,
"avantgarde" => 22,
"palatino" => 26
)
# --------------------------------------------------------------------------------------
gr_color(c) = gr_color(c, color_type(c))
gr_color(c, ::Type{<:AbstractRGB}) = UInt32( round(UInt, clamp(alpha(c) * 255, 0, 255)) << 24 +
round(UInt, clamp(blue(c) * 255, 0, 255)) << 16 +
round(UInt, clamp(green(c) * 255, 0, 255)) << 8 +
round(UInt, clamp(red(c) * 255, 0, 255)) )
function gr_color(c, ::Type{<:AbstractGray})
g = round(UInt, clamp(gray(c) * 255, 0, 255))
α = round(UInt, clamp(alpha(c) * 255, 0, 255))
rgba = UInt32( α<<24 + g<<16 + g<<8 + g )
end
gr_color(c, ::Type) = gr_color(RGBA(c), RGB)
function gr_getcolorind(c)
gr_set_transparency(float(alpha(c)))
convert(Int, GR.inqcolorfromrgb(red(c), green(c), blue(c)))
end
gr_set_linecolor(c) = GR.setlinecolorind(gr_getcolorind(_cycle(c,1)))
gr_set_fillcolor(c) = GR.setfillcolorind(gr_getcolorind(_cycle(c,1)))
gr_set_markercolor(c) = GR.setmarkercolorind(gr_getcolorind(_cycle(c,1)))
gr_set_textcolor(c) = GR.settextcolorind(gr_getcolorind(_cycle(c,1)))
gr_set_transparency(α::Real) = GR.settransparency(clamp(α, 0, 1))
gr_set_transparency(::Nothing) = GR.settransparency(1)
gr_set_transparency(c, α) = gr_set_transparency(α)
gr_set_transparency(c::Colorant, ::Nothing) = gr_set_transparency(c)
gr_set_transparency(c::Colorant) = GR.settransparency(alpha(c))
const _gr_arrow_map = Dict(
:simple => 1,
:hollow => 3,
:filled => 4,
:triangle => 5,
:filledtriangle => 6,
:closed => 6,
:open => 5,
)
gr_set_arrowstyle(s::Symbol) = GR.setarrowstyle(get(_gr_arrow_map, s, 1))
# --------------------------------------------------------------------------------------
# draw line segments, splitting x/y into contiguous/finite segments
# note: this can be used for shapes by passing func `GR.fillarea`
function gr_polyline(x, y, func = GR.polyline; arrowside = :none, arrowstyle = :simple)
iend = 0
n = length(x)
while iend < n-1
# set istart to the first index that is finite
istart = -1
for j = iend+1:n
if isfinite(x[j]) && isfinite(y[j])
istart = j
break
end
end
if istart > 0
# iend is the last finite index
iend = -1
for j = istart+1:n
if isfinite(x[j]) && isfinite(y[j])
iend = j
else
break
end
end
end
# if we found a start and end, draw the line segment, otherwise we're done
if istart > 0 && iend > 0
func(x[istart:iend], y[istart:iend])
if arrowside in (:head,:both)
gr_set_arrowstyle(arrowstyle)
GR.drawarrow(x[iend-1], y[iend-1], x[iend], y[iend])
end
if arrowside in (:tail,:both)
gr_set_arrowstyle(arrowstyle)
GR.drawarrow(x[istart+1], y[istart+1], x[istart], y[istart])
end
else
break
end
end
end
gr_inqtext(x, y, s::Symbol) = gr_inqtext(x, y, string(s))
function gr_inqtext(x, y, s)
if length(s) >= 2 && s[1] == '$' && s[end] == '$'
GR.inqmathtex(x, y, s[2:end-1])
elseif findfirst(isequal('\\'), s) !== nothing || occursin("10^{", s)
GR.inqtextext(x, y, s)
else
GR.inqtext(x, y, s)
end
end
gr_text(x, y, s::Symbol) = gr_text(x, y, string(s))
function gr_text(x, y, s)
if length(s) >= 2 && s[1] == '$' && s[end] == '$'
GR.mathtex(x, y, s[2:end-1])
elseif findfirst(isequal('\\'), s) !== nothing || occursin("10^{", s)
GR.textext(x, y, s)
else
GR.text(x, y, s)
end
end
function gr_polaraxes(rmin::Real, rmax::Real, sp::Subplot)
GR.savestate()
xaxis = sp[:xaxis]
yaxis = sp[:yaxis]
α = 0:45:315
a = α .+ 90
sinf = sind.(a)
cosf = cosd.(a)
rtick_values, rtick_labels = get_ticks(sp, yaxis)
if yaxis[:formatter] in (:scientific, :auto) && yaxis[:ticks] in (:auto, :native)
rtick_labels = convert_sci_unicode.(rtick_labels)
end
#draw angular grid
if xaxis[:grid]
gr_set_line(xaxis[:gridlinewidth], xaxis[:gridstyle], xaxis[:foreground_color_grid])
gr_set_transparency(xaxis[:foreground_color_grid], xaxis[:gridalpha])
for i in 1:length(α)
GR.polyline([sinf[i], 0], [cosf[i], 0])
end
end
#draw radial grid
if yaxis[:grid]
gr_set_line(yaxis[:gridlinewidth], yaxis[:gridstyle], yaxis[:foreground_color_grid])
gr_set_transparency(yaxis[:foreground_color_grid], yaxis[:gridalpha])
for i in 1:length(rtick_values)
r = (rtick_values[i] - rmin) / (rmax - rmin)
if r <= 1.0 && r >= 0.0
GR.drawarc(-r, r, -r, r, 0, 359)
end
end
GR.drawarc(-1, 1, -1, 1, 0, 359)
end
#prepare to draw ticks
gr_set_transparency(1)
GR.setlinecolorind(90)
GR.settextalign(GR.TEXT_HALIGN_CENTER, GR.TEXT_VALIGN_HALF)
#draw angular ticks
if xaxis[:showaxis]
GR.drawarc(-1, 1, -1, 1, 0, 359)
for i in 1:length(α)
x, y = GR.wctondc(1.1 * sinf[i], 1.1 * cosf[i])
GR.textext(x, y, string((360-α[i])%360, "^o"))
end
end
#draw radial ticks
if yaxis[:showaxis]
for i in 1:length(rtick_values)
r = (rtick_values[i] - rmin) / (rmax - rmin)
if r <= 1.0 && r >= 0.0
x, y = GR.wctondc(0.05, r)
gr_text(x, y, _cycle(rtick_labels, i))
end
end
end
GR.restorestate()
end
# using the axis extrema and limit overrides, return the min/max value for this axis
gr_x_axislims(sp::Subplot) = axis_limits(sp, :x)
gr_y_axislims(sp::Subplot) = axis_limits(sp, :y)
gr_z_axislims(sp::Subplot) = axis_limits(sp, :z)
gr_xy_axislims(sp::Subplot) = gr_x_axislims(sp)..., gr_y_axislims(sp)...
function gr_lims(sp::Subplot, axis::Axis, adjust::Bool, expand = nothing)
if expand !== nothing
expand_extrema!(axis, expand)
end
lims = axis_limits(sp, axis[:letter])
if adjust
GR.adjustrange(lims...)
else
lims
end
end
function gr_fill_viewport(vp::AVec{Float64}, c)
GR.savestate()
GR.selntran(0)
GR.setscale(0)
GR.setfillintstyle(GR.INTSTYLE_SOLID)
gr_set_fillcolor(c)
GR.fillrect(vp...)
GR.selntran(1)
GR.restorestate()
end
# ---------------------------------------------------------
# draw ONE Shape
function gr_draw_marker(xi, yi, msize, shape::Shape)
sx, sy = coords(shape)
# convert to ndc coords (percentages of window)
GR.selntran(0)
w, h = gr_plot_size
f = msize / (w + h)
xi, yi = GR.wctondc(xi, yi)
GR.fillarea(xi .+ sx .* f,
yi .+ sy .* f)
GR.selntran(1)
end
# draw ONE symbol marker
function gr_draw_marker(xi, yi, msize::Number, shape::Symbol)
GR.setmarkertype(gr_markertype[shape])
w, h = gr_plot_size
GR.setmarkersize(0.3msize / ((w + h) * 0.001))
GR.polymarker([xi], [yi])
end
# draw the markers, one at a time
function gr_draw_markers(series::Series, x, y, clims, msize = series[:markersize])
isempty(x) && return
GR.setfillintstyle(GR.INTSTYLE_SOLID)
shapes = series[:markershape]
if shapes != :none
for i=1:length(x)
msi = _cycle(msize, i)
shape = _cycle(shapes, i)
cfunc = isa(shape, Shape) ? gr_set_fillcolor : gr_set_markercolor
# draw a filled in shape, slightly bigger, to estimate a stroke
if series[:markerstrokewidth] > 0
c = get_markerstrokecolor(series, i)
cfunc(c)
gr_set_transparency(c, get_markerstrokealpha(series, i))
gr_draw_marker(x[i], y[i], msi + series[:markerstrokewidth], shape)
end
# draw the shape - don't draw filled area if marker shape is 1D
if !(shape in (:hline, :vline, :+, :x))
c = get_markercolor(series, clims, i)
cfunc(c)
gr_set_transparency(c, get_markeralpha(series, i))
gr_draw_marker(x[i], y[i], msi, shape)
end
end
end
end
# ---------------------------------------------------------
function gr_set_line(lw, style, c) #, a)
GR.setlinetype(gr_linetype[style])
w, h = gr_plot_size
GR.setlinewidth(_gr_thickness_scaling[1] * max(0, lw / ((w + h) * 0.001)))
gr_set_linecolor(c) #, a)
end
function gr_set_fill(c) #, a)
gr_set_fillcolor(c) #, a)
GR.setfillintstyle(GR.INTSTYLE_SOLID)
end
# this stores the conversion from a font pointsize to "percentage of window height" (which is what GR uses)
const _gr_point_mult = 0.0018 * ones(1)
const _gr_thickness_scaling = ones(1)
# set the font attributes... assumes _gr_point_mult has been populated already
function gr_set_font(f::Font; halign = f.halign, valign = f.valign,
color = f.color, rotation = f.rotation)
family = lowercase(f.family)
GR.setcharheight(_gr_point_mult[1] * f.pointsize)
GR.setcharup(sind(-rotation), cosd(-rotation))
if haskey(gr_font_family, family)
GR.settextfontprec(100 + gr_font_family[family], GR.TEXT_PRECISION_STRING)
end
gr_set_textcolor(color)
GR.settextalign(gr_halign[halign], gr_valign[valign])
end
function gr_nans_to_infs!(z)
for (i,zi) in enumerate(z)
if zi == NaN
z[i] = Inf
end
end
end
# --------------------------------------------------------------------------------------
# viewport plot area
# this stays constant for a given subplot while displaying that subplot.
# values are [xmin, xmax, ymin, ymax]. they range [0,1].
const viewport_plotarea = zeros(4)
# the size of the current plot in pixels
const gr_plot_size = [600.0, 400.0]
const gr_colorbar_ratio = 0.1
function gr_viewport_from_bbox(sp::Subplot{GRBackend}, bb::BoundingBox, w, h, viewport_canvas)
viewport = zeros(4)
viewport[1] = viewport_canvas[2] * (left(bb) / w)
viewport[2] = viewport_canvas[2] * (right(bb) / w)
viewport[3] = viewport_canvas[4] * (1.0 - bottom(bb) / h)
viewport[4] = viewport_canvas[4] * (1.0 - top(bb) / h)
if is3d(sp)
vp = viewport[:]
extent = min(vp[2] - vp[1], vp[4] - vp[3])
viewport[1] = 0.5 * (vp[1] + vp[2] - extent)
viewport[2] = 0.5 * (vp[1] + vp[2] + extent)
viewport[3] = 0.5 * (vp[3] + vp[4] - extent)
viewport[4] = 0.5 * (vp[3] + vp[4] + extent)
end
if hascolorbar(sp)
viewport[2] -= gr_colorbar_ratio
end
viewport
end
# change so we're focused on the viewport area
function gr_set_viewport_cmap(sp::Subplot)
GR.setviewport(
viewport_plotarea[2] + (is3d(sp) ? 0.07 : 0.02),
viewport_plotarea[2] + (is3d(sp) ? 0.10 : 0.05),
viewport_plotarea[3],
viewport_plotarea[4]
)
end
# reset the viewport to the plot area
function gr_set_viewport_plotarea()
GR.setviewport(
viewport_plotarea[1],
viewport_plotarea[2],
viewport_plotarea[3],
viewport_plotarea[4]
)
end
function gr_set_viewport_polar()
xmin, xmax, ymin, ymax = viewport_plotarea
ymax -= 0.05 * (xmax - xmin)
xcenter = 0.5 * (xmin + xmax)
ycenter = 0.5 * (ymin + ymax)
r = 0.5 * NaNMath.min(xmax - xmin, ymax - ymin)
GR.setviewport(xcenter -r, xcenter + r, ycenter - r, ycenter + r)
GR.setwindow(-1, 1, -1, 1)
r
end
struct GRColorbar
gradients
fills
lines
GRColorbar() = new([],[],[])
end
function gr_update_colorbar!(cbar::GRColorbar, series::Series)
style = colorbar_style(series)
style === nothing && return
list = style == cbar_gradient ? cbar.gradients :
style == cbar_fill ? cbar.fills :
style == cbar_lines ? cbar.lines :
error("Unknown colorbar style: $style.")
push!(list, series)
end
function gr_contour_levels(series::Series, clims)
levels = contour_levels(series, clims)
if isfilledcontour(series)
# GR implicitly uses the maximal z value as the highest level
levels = levels[1:end-1]
end
levels
end
function gr_colorbar_colors(series::Series, clims)
if iscontour(series)
levels = gr_contour_levels(series, clims)
if isfilledcontour(series)
# GR.contourf uses a color range according to supplied levels
zrange = ignorenan_extrema(levels)
else
# GR.contour uses a color range according to data range
zrange = clims
end
colors = 1000 .+ 255 .* (levels .- zrange[1]) ./ (zrange[2] - zrange[1])
else
colors = 1000:1255
end
round.(Int,colors)
end
function _cbar_unique(values, propname)
out = last(values)
if any(x != out for x in values)
@warn "Multiple series with different $propname share a colorbar. " *
"Colorbar may not reflect all series correctly."
end
out
end
# add the colorbar
function gr_draw_colorbar(cbar::GRColorbar, sp::Subplot, clims)
GR.savestate()
xmin, xmax = gr_xy_axislims(sp)[1:2]
zmin, zmax = clims[1:2]
gr_set_viewport_cmap(sp)
GR.setscale(0)
GR.setwindow(xmin, xmax, zmin, zmax)
if !isempty(cbar.gradients)
series = cbar.gradients
gr_set_gradient(_cbar_unique(gr_get_color.(series),"color"))
gr_set_transparency(_cbar_unique(get_fillalpha.(series), "fill alpha"))
GR.cellarray(xmin, xmax, zmax, zmin, 1, 256, 1000:1255)
end
if !isempty(cbar.fills)
series = cbar.fills
GR.setfillintstyle(GR.INTSTYLE_SOLID)
gr_set_gradient(_cbar_unique(gr_get_color.(series), "color"))
gr_set_transparency(_cbar_unique(get_fillalpha.(series), "fill alpha"))
levels = _cbar_unique(contour_levels.(series, Ref(clims)), "levels")
# GR implicitly uses the maximal z value as the highest level
if levels[end] < clims[2]
@warn("GR: highest contour level less than maximal z value is not supported.")
# replace levels, rather than assign to levels[end], to ensure type
# promotion in case levels is an integer array
levels = [levels[1:end-1]; clims[2]]
end
colors = gr_colorbar_colors(last(series), clims)
for (from, to, color) in zip(levels[1:end-1], levels[2:end], colors)
GR.setfillcolorind(color)
GR.fillrect( xmin, xmax, from, to )
end
end
if !isempty(cbar.lines)
series = cbar.lines
gr_set_gradient(_cbar_unique(gr_get_color.(series),"color"))
gr_set_line(_cbar_unique(get_linewidth.(series), "line width"),
_cbar_unique(get_linestyle.(series), "line style"),
_cbar_unique(get_linecolor.(series, Ref(clims)), "line color"))
gr_set_transparency(_cbar_unique(get_linealpha.(series), "line alpha"))
levels = _cbar_unique(contour_levels.(series, Ref(clims)), "levels")
colors = gr_colorbar_colors(last(series), clims)
for (line, color) in zip(levels, colors)
GR.setlinecolorind(color)
GR.polyline([xmin,xmax], [line,line] )
end
end
ztick = 0.5 * GR.tick(zmin, zmax)
gr_set_line(1, :solid, plot_color(:black))
GR.axes(0, ztick, xmax, zmin, 0, 1, 0.005)
gr_set_font(guidefont(sp[:yaxis]))
GR.settextalign(GR.TEXT_HALIGN_CENTER, GR.TEXT_VALIGN_TOP)
GR.setcharup(-1, 0)
gr_text(viewport_plotarea[2] + gr_colorbar_ratio,
gr_view_ycenter(), sp[:colorbar_title])
GR.restorestate()
end
gr_view_xcenter() = 0.5 * (viewport_plotarea[1] + viewport_plotarea[2])
gr_view_ycenter() = 0.5 * (viewport_plotarea[3] + viewport_plotarea[4])
function gr_legend_pos(sp::Subplot, w, h)
s = sp[:legend]
typeof(s) <: Symbol || return gr_legend_pos(s, w, h)
str = string(s)
if str == "best"
str = "topright"
end
if occursin("outer", str)
xaxis, yaxis = sp[:xaxis], sp[:yaxis]
xmirror = xaxis[:guide_position] == :top || (xaxis[:guide_position] == :auto && xaxis[:mirror] == true)
ymirror = yaxis[:guide_position] == :right || (yaxis[:guide_position] == :auto && yaxis[:mirror] == true)
end
if occursin("right", str)
if occursin("outer", str)
# As per https://github.com/jheinen/GR.jl/blob/master/src/jlgr.jl#L525
xpos = viewport_plotarea[2] + 0.11 + ymirror * gr_yaxis_width(sp)
else
xpos = viewport_plotarea[2] - 0.05 - w
end
elseif occursin("left", str)
if occursin("outer", str)
xpos = viewport_plotarea[1] - 0.05 - w - !ymirror * gr_yaxis_width(sp)
else
xpos = viewport_plotarea[1] + 0.11
end
else
xpos = (viewport_plotarea[2]-viewport_plotarea[1])/2 - w/2 +.04
end
if occursin("top", str)
if s == :outertop
ypos = viewport_plotarea[4] + 0.02 + h + xmirror * gr_xaxis_height(sp)
else
ypos = viewport_plotarea[4] - 0.06
end
elseif occursin("bottom", str)
if s == :outerbottom
ypos = viewport_plotarea[3] - 0.05 - !xmirror * gr_xaxis_height(sp)
else
ypos = viewport_plotarea[3] + h + 0.06
end
else
ypos = (viewport_plotarea[4]-viewport_plotarea[3])/2 + h/2
end
(xpos,ypos)
end
function gr_legend_pos(v::Tuple{S,T},w,h) where {S<:Real, T<:Real}
xpos = v[1] * (viewport_plotarea[2] - viewport_plotarea[1]) + viewport_plotarea[1]
ypos = v[2] * (viewport_plotarea[4] - viewport_plotarea[3]) + viewport_plotarea[3]
(xpos,ypos)
end
# --------------------------------------------------------------------------------------
const _gr_gradient_alpha = ones(256)
function gr_set_gradient(c)
grad = _as_gradient(c)
for (i,z) in enumerate(range(0, stop=1, length=256))
c = grad[z]
GR.setcolorrep(999+i, red(c), green(c), blue(c))
_gr_gradient_alpha[i] = alpha(c)
end
grad
end
function gr_set_gradient(series::Series)
color = gr_get_color(series)
color !== nothing && gr_set_gradient(color)
end
function gr_get_color(series::Series)
st = series[:seriestype]
if st in (:surface, :heatmap) || isfilledcontour(series)
series[:fillcolor]
elseif st in (:contour, :wireframe)
series[:linecolor]
elseif series[:marker_z] !== nothing
series[:markercolor]
elseif series[:line_z] !== nothing
series[:linecolor]
elseif series[:fill_z] !== nothing
series[:fillcolor]
end
end
# this is our new display func... set up the viewport_canvas, compute bounding boxes, and display each subplot
function gr_display(plt::Plot, fmt="")
GR.clearws()
_gr_thickness_scaling[1] = plt[:thickness_scaling]
dpi_factor = plt[:dpi] / Plots.DPI
if fmt == "svg"
dpi_factor *= 4
end
# collect some monitor/display sizes in meters and pixels
display_width_meters, display_height_meters, display_width_px, display_height_px = GR.inqdspsize()
display_width_ratio = display_width_meters / display_width_px
display_height_ratio = display_height_meters / display_height_px
# compute the viewport_canvas, normalized to the larger dimension
viewport_canvas = Float64[0,1,0,1]
w, h = plt[:size]
gr_plot_size[:] = [w, h]
if w > h
ratio = float(h) / w
msize = display_width_ratio * w * dpi_factor
GR.setwsviewport(0, msize, 0, msize * ratio)
GR.setwswindow(0, 1, 0, ratio)
viewport_canvas[3] *= ratio
viewport_canvas[4] *= ratio
else
ratio = float(w) / h
msize = display_height_ratio * h * dpi_factor
GR.setwsviewport(0, msize * ratio, 0, msize)
GR.setwswindow(0, ratio, 0, 1)
viewport_canvas[1] *= ratio
viewport_canvas[2] *= ratio
end
# fill in the viewport_canvas background
gr_fill_viewport(viewport_canvas, plt[:background_color_outside])
# update point mult
px_per_pt = px / pt
_gr_point_mult[1] = 1.5 * _gr_thickness_scaling[1] * px_per_pt / max(h,w)
# subplots:
for sp in plt.subplots
gr_display(sp, w*px, h*px, viewport_canvas)
end
GR.updatews()
end
function gr_set_xticks_font(sp)
flip = sp[:yaxis][:flip]
mirror = sp[:xaxis][:mirror]
gr_set_font(tickfont(sp[:xaxis]),
halign = (:left, :hcenter, :right)[sign(sp[:xaxis][:rotation]) + 2],
valign = (mirror ? :bottom : :top),
rotation = sp[:xaxis][:rotation])
return flip, mirror
end
function gr_set_yticks_font(sp)
flip = sp[:xaxis][:flip]
mirror = sp[:yaxis][:mirror]
gr_set_font(tickfont(sp[:yaxis]),
halign = (mirror ? :left : :right),
valign = (:top, :vcenter, :bottom)[sign(sp[:yaxis][:rotation]) + 2],
rotation = sp[:yaxis][:rotation])
return flip, mirror
end
function gr_text_size(str)
GR.savestate()
GR.selntran(0)
xs, ys = gr_inqtext(0, 0, string(str))
l, r = extrema(xs)
b, t = extrema(ys)
w = r - l
h = t - b
GR.restorestate()
return w, h
end
function gr_text_size(str, rot)
GR.savestate()
GR.selntran(0)
xs, ys = gr_inqtext(0, 0, string(str))
l, r = extrema(xs)
b, t = extrema(ys)
w = text_box_width(r - l, t - b, rot)
h = text_box_height(r - l, t - b, rot)
GR.restorestate()
return w, h
end
text_box_width(w, h, rot) = abs(cosd(rot)) * w + abs(cosd(rot + 90)) * h
text_box_height(w, h, rot) = abs(sind(rot)) * w + abs(sind(rot + 90)) * h
function gr_get_ticks_size(ticks, rot)
w, h = 0.0, 0.0
for (cv, dv) in zip(ticks...)
wi, hi = gr_text_size(dv, rot)
w = max(w, wi)
h = max(h, hi)
end
return w, h
end
function gr_xaxis_height(sp)
xaxis = sp[:xaxis]
xticks, yticks = axis_drawing_info(sp)[1:2]
gr_set_font(tickfont(xaxis))
h = (xticks in (nothing, false, :none) ? 0 : last(gr_get_ticks_size(xticks, xaxis[:rotation])))
if xaxis[:guide] != ""
gr_set_font(guidefont(xaxis))
h += last(gr_text_size(xaxis[:guide]))
end
return h
end
function gr_yaxis_width(sp)
yaxis = sp[:yaxis]
xticks, yticks = axis_drawing_info(sp)[1:2]
gr_set_font(tickfont(yaxis))
w = (xticks in (nothing, false, :none) ? 0 : first(gr_get_ticks_size(yticks, yaxis[:rotation])))
if yaxis[:guide] != ""
gr_set_font(guidefont(yaxis))
w += last(gr_text_size(yaxis[:guide]))
end
return w
end
function _update_min_padding!(sp::Subplot{GRBackend})
dpi = sp.plt[:thickness_scaling]
if !haskey(ENV, "GKSwstype")
if isijulia()
ENV["GKSwstype"] = "svg"
end
end
# Add margin given by the user
leftpad = 2mm + sp[:left_margin]
toppad = 2mm + sp[:top_margin]
rightpad = 2mm + sp[:right_margin]
bottompad = 2mm + sp[:bottom_margin]
# Add margin for title
if sp[:title] != ""
gr_set_font(titlefont(sp))
l = last(last(gr_text_size(sp[:title])))
h = 1mm + gr_plot_size[2] * l * px
toppad += h
end
# Add margin for x and y ticks
xticks, yticks = axis_drawing_info(sp)[1:2]
if !(xticks in (nothing, false, :none))
flip, mirror = gr_set_xticks_font(sp)
l = 0.01 + last(gr_get_ticks_size(xticks, sp[:xaxis][:rotation]))
h = 1mm + gr_plot_size[2] * l * px
if mirror
toppad += h
else
bottompad += h
end
end
if !(yticks in (nothing, false, :none))
flip, mirror = gr_set_yticks_font(sp)
l = 0.01 + first(gr_get_ticks_size(yticks, sp[:yaxis][:rotation]))
w = 1mm + gr_plot_size[1] * l * px
if mirror
rightpad += w
else
leftpad += w
end
end
# Add margin for x label
if sp[:xaxis][:guide] != ""
gr_set_font(guidefont(sp[:xaxis]))
l = last(gr_text_size(sp[:xaxis][:guide]))
h = 1mm + gr_plot_size[2] * l * px
if sp[:xaxis][:guide_position] == :top || (sp[:xaxis][:guide_position] == :auto && sp[:xaxis][:mirror] == true)
toppad += h
else
bottompad += h
end
end
# Add margin for y label
if sp[:yaxis][:guide] != ""
gr_set_font(guidefont(sp[:yaxis]))
l = last(gr_text_size(sp[:yaxis][:guide]))
w = 1mm + gr_plot_size[2] * l * px
if sp[:yaxis][:guide_position] == :right || (sp[:yaxis][:guide_position] == :auto && sp[:yaxis][:mirror] == true)
rightpad += w
else
leftpad += w
end
end
if sp[:colorbar_title] != ""
rightpad += 4mm
end
sp.minpad = Tuple(dpi * [leftpad, toppad, rightpad, bottompad])
end
function gr_display(sp::Subplot{GRBackend}, w, h, viewport_canvas)
_update_min_padding!(sp)
# the viewports for this subplot
viewport_subplot = gr_viewport_from_bbox(sp, bbox(sp), w, h, viewport_canvas)
viewport_plotarea[:] = gr_viewport_from_bbox(sp, plotarea(sp), w, h, viewport_canvas)
# get data limits
data_lims = gr_xy_axislims(sp)
xy_lims = data_lims
ratio = sp[:aspect_ratio]
if ratio != :none
if ratio == :equal
ratio = 1
end
viewport_ratio = (viewport_plotarea[2] - viewport_plotarea[1]) / (viewport_plotarea[4] - viewport_plotarea[3])
window_ratio = (data_lims[2] - data_lims[1]) / (data_lims[4] - data_lims[3]) / ratio
if window_ratio < viewport_ratio
viewport_center = 0.5 * (viewport_plotarea[1] + viewport_plotarea[2])
viewport_size = (viewport_plotarea[2] - viewport_plotarea[1]) * window_ratio / viewport_ratio
viewport_plotarea[1] = viewport_center - 0.5 * viewport_size
viewport_plotarea[2] = viewport_center + 0.5 * viewport_size
elseif window_ratio > viewport_ratio
viewport_center = 0.5 * (viewport_plotarea[3] + viewport_plotarea[4])
viewport_size = (viewport_plotarea[4] - viewport_plotarea[3]) * viewport_ratio / window_ratio
viewport_plotarea[3] = viewport_center - 0.5 * viewport_size
viewport_plotarea[4] = viewport_center + 0.5 * viewport_size
end
end
# calculate legend size
# has to be done now due to a potential adjustment to the plotarea given an outer legend.
legendn = 0
legendw = 0
if sp[:legend] != :none
GR.savestate()
GR.selntran(0)
GR.setscale(0)
if sp[:legendtitle] !== nothing
gr_set_font(legendtitlefont(sp))
tbx, tby = gr_inqtext(0, 0, string(sp[:legendtitle]))
legendw = tbx[3] - tbx[1]
legendn += 1
end
gr_set_font(legendfont(sp))
for series in series_list(sp)
should_add_to_legend(series) || continue
legendn += 1
lab = series[:label]
tbx, tby = gr_inqtext(0, 0, string(lab))
legendw = max(legendw, tbx[3] - tbx[1])
end
GR.setscale(1)
GR.selntran(1)
GR.restorestate()
end
dy = _gr_point_mult[1] * sp[:legendfontsize] * 1.75
legendh = dy * legendn
leg_str = string(sp[:legend])
if occursin("outer", leg_str)
if occursin("right", leg_str)
viewport_plotarea[2] -= legendw + 0.11
elseif occursin("left", leg_str)
viewport_plotarea[1] += legendw + 0.11
elseif occursin("top", leg_str)
viewport_plotarea[4] -= legendh + 0.03
elseif occursin("bottom", leg_str)
viewport_plotarea[3] += legendh + 0.04
end
end
# fill in the plot area background
bg = plot_color(sp[:background_color_inside])
gr_fill_viewport(viewport_plotarea, bg)
# reduced from before... set some flags based on the series in this subplot
# TODO: can these be generic flags?
outside_ticks = false
cbar = GRColorbar()
draw_axes = sp[:framestyle] != :none
# axes_2d = true
for series in series_list(sp)
st = series[:seriestype]
if st == :pie
draw_axes = false
end
if st == :heatmap
outside_ticks = true
for ax in (sp[:xaxis], sp[:yaxis])
v = series[ax[:letter]]
end
x, y = heatmap_edges(series[:x], sp[:xaxis][:scale], series[:y], sp[:yaxis][:scale], size(series[:z]))
xy_lims = x[1], x[end], y[1], y[end]
expand_extrema!(sp[:xaxis], x)
expand_extrema!(sp[:yaxis], y)
data_lims = gr_xy_axislims(sp)
end
gr_update_colorbar!(cbar,series)
end
# set our plot area view
gr_set_viewport_plotarea()
# these are the Axis objects, which hold scale, lims, etc
xaxis = sp[:xaxis]
yaxis = sp[:yaxis]
zaxis = sp[:zaxis]
# set the scale flags and window
xmin, xmax, ymin, ymax = data_lims
scaleop = 0
xtick, ytick = 1, 1
if xmax > xmin && ymax > ymin
# NOTE: for log axes, the major_x and major_y - if non-zero (omit labels) - control the minor grid lines (1 = draw 9 minor grid lines, 2 = no minor grid lines)
# NOTE: for log axes, the x_tick and y_tick - if non-zero (omit axes) - only affect the output appearance (1 = nomal, 2 = scientiic notation)
xaxis[:scale] == :log10 && (scaleop |= GR.OPTION_X_LOG)
yaxis[:scale] == :log10 && (scaleop |= GR.OPTION_Y_LOG)
xaxis[:flip] && (scaleop |= GR.OPTION_FLIP_X)
yaxis[:flip] && (scaleop |= GR.OPTION_FLIP_Y)
if scaleop & GR.OPTION_X_LOG == 0
majorx = 1 #5
xtick = GR.tick(xmin, xmax) / majorx
else
# log axis
xtick = 2 # scientific notation
majorx = 2 # no minor grid lines
end
if scaleop & GR.OPTION_Y_LOG == 0
majory = 1 #5
ytick = GR.tick(ymin, ymax) / majory
else
# log axis
ytick = 2 # scientific notation
majory = 2 # no minor grid lines
end
# NOTE: setwindow sets the "data coordinate" limits of the current "viewport"
GR.setwindow(xmin, xmax, ymin, ymax)
GR.setscale(scaleop)
end
# draw the axes
gr_set_font(tickfont(xaxis))
GR.setlinewidth(sp.plt[:thickness_scaling])
if is3d(sp)
# TODO do we really need a different clims computation here from the one
# computed above using get_clims(sp)?
zmin, zmax = gr_lims(sp, zaxis, true)
clims3d = sp[:clims]
if is_2tuple(clims3d)
isfinite(clims3d[1]) && (zmin = clims3d[1])
isfinite(clims3d[2]) && (zmax = clims3d[2])
end
GR.setspace(zmin, zmax, round.(Int, sp[:camera])...)
xtick = GR.tick(xmin, xmax) / 2
ytick = GR.tick(ymin, ymax) / 2
ztick = GR.tick(zmin, zmax) / 2
ticksize = 0.01 * (viewport_plotarea[2] - viewport_plotarea[1])
if xaxis[:grid]
gr_set_line(xaxis[:gridlinewidth], xaxis[:gridstyle], xaxis[:foreground_color_grid])
gr_set_transparency(xaxis[:foreground_color_grid], xaxis[:gridalpha])
GR.grid3d(xtick, 0, 0, xmin, ymax, zmin, 2, 0, 0)
end
if yaxis[:grid]
gr_set_line(yaxis[:gridlinewidth], yaxis[:gridstyle], yaxis[:foreground_color_grid])
gr_set_transparency(yaxis[:foreground_color_grid], yaxis[:gridalpha])
GR.grid3d(0, ytick, 0, xmin, ymax, zmin, 0, 2, 0)
end
if zaxis[:grid]
gr_set_line(zaxis[:gridlinewidth], zaxis[:gridstyle], zaxis[:foreground_color_grid])
gr_set_transparency(zaxis[:foreground_color_grid], zaxis[:gridalpha])
GR.grid3d(0, 0, ztick, xmin, ymax, zmin, 0, 0, 2)
end
gr_set_line(1, :solid, xaxis[:foreground_color_axis])
gr_set_transparency(xaxis[:foreground_color_axis])
GR.axes3d(xtick, 0, ztick, xmin, ymin, zmin, 2, 0, 2, -ticksize)
GR.axes3d(0, ytick, 0, xmax, ymin, zmin, 0, 2, 0, ticksize)
elseif ispolar(sp)
r = gr_set_viewport_polar()
#rmin, rmax = GR.adjustrange(ignorenan_minimum(r), ignorenan_maximum(r))
rmin, rmax = axis_limits(sp, :y)
gr_polaraxes(rmin, rmax, sp)
elseif draw_axes
if xmax > xmin && ymax > ymin
GR.setwindow(xmin, xmax, ymin, ymax)
end
xticks, yticks, xspine_segs, yspine_segs, xtick_segs, ytick_segs, xgrid_segs, ygrid_segs, xminorgrid_segs, yminorgrid_segs, xborder_segs, yborder_segs = axis_drawing_info(sp)
# @show xticks yticks #spine_segs grid_segs
# draw the grid lines
if xaxis[:grid]
# gr_set_linecolor(sp[:foreground_color_grid])
# GR.grid(xtick, ytick, 0, 0, majorx, majory)
gr_set_line(xaxis[:gridlinewidth], xaxis[:gridstyle], xaxis[:foreground_color_grid])
gr_set_transparency(xaxis[:foreground_color_grid], xaxis[:gridalpha])
gr_polyline(coords(xgrid_segs)...)
end
if yaxis[:grid]
gr_set_line(yaxis[:gridlinewidth], yaxis[:gridstyle], yaxis[:foreground_color_grid])
gr_set_transparency(yaxis[:foreground_color_grid], yaxis[:gridalpha])
gr_polyline(coords(ygrid_segs)...)
end
if xaxis[:minorgrid]
# gr_set_linecolor(sp[:foreground_color_grid])
# GR.grid(xtick, ytick, 0, 0, majorx, majory)
gr_set_line(xaxis[:minorgridlinewidth], xaxis[:minorgridstyle], xaxis[:foreground_color_minor_grid])
gr_set_transparency(xaxis[:foreground_color_minor_grid], xaxis[:minorgridalpha])
gr_polyline(coords(xminorgrid_segs)...)
end
if yaxis[:minorgrid]
gr_set_line(yaxis[:minorgridlinewidth], yaxis[:minorgridstyle], yaxis[:foreground_color_minor_grid])
gr_set_transparency(yaxis[:foreground_color_minor_grid], yaxis[:minorgridalpha])
gr_polyline(coords(yminorgrid_segs)...)
end
gr_set_transparency(1.0)
# axis lines
if xaxis[:showaxis]
gr_set_line(1, :solid, xaxis[:foreground_color_border])
GR.setclip(0)
gr_polyline(coords(xspine_segs)...)
end
if yaxis[:showaxis]
gr_set_line(1, :solid, yaxis[:foreground_color_border])
GR.setclip(0)
gr_polyline(coords(yspine_segs)...)
end
GR.setclip(1)
# axis ticks
if xaxis[:showaxis]
if sp[:framestyle] in (:zerolines, :grid)
gr_set_line(1, :solid, xaxis[:foreground_color_grid])
gr_set_transparency(xaxis[:foreground_color_grid], xaxis[:tick_direction] == :out ? xaxis[:gridalpha] : 0)
else
gr_set_line(1, :solid, xaxis[:foreground_color_axis])
end
GR.setclip(0)
gr_polyline(coords(xtick_segs)...)
end
if yaxis[:showaxis]
if sp[:framestyle] in (:zerolines, :grid)
gr_set_line(1, :solid, yaxis[:foreground_color_grid])
gr_set_transparency(yaxis[:foreground_color_grid], yaxis[:tick_direction] == :out ? yaxis[:gridalpha] : 0)
else
gr_set_line(1, :solid, yaxis[:foreground_color_axis])
end
GR.setclip(0)
gr_polyline(coords(ytick_segs)...)
end
GR.setclip(1)
# tick marks
if !(xticks in (:none, nothing, false)) && xaxis[:showaxis]
# x labels
flip, mirror = gr_set_xticks_font(sp)
for (cv, dv) in zip(xticks...)
# use xor ($) to get the right y coords
xi, yi = GR.wctondc(cv, sp[:framestyle] == :origin ? 0 : xor(flip, mirror) ? ymax : ymin)
# @show cv dv ymin xi yi flip mirror (flip $ mirror)
if xaxis[:ticks] in (:auto, :native)
# ensure correct dispatch in gr_text for automatic log ticks
if xaxis[:scale] in _logScales
dv = string(dv, "\\ ")
elseif xaxis[:formatter] in (:scientific, :auto)
dv = convert_sci_unicode(dv)
end
end
gr_text(xi, yi + (mirror ? 1 : -1) * 5e-3 * (xaxis[:tick_direction] == :out ? 1.5 : 1.0), string(dv))
end
end
if !(yticks in (:none, nothing, false)) && yaxis[:showaxis]
# y labels
flip, mirror = gr_set_yticks_font(sp)
for (cv, dv) in zip(yticks...)
# use xor ($) to get the right y coords
xi, yi = GR.wctondc(sp[:framestyle] == :origin ? 0 : xor(flip, mirror) ? xmax : xmin, cv)
# @show cv dv xmin xi yi
if yaxis[:ticks] in (:auto, :native)
# ensure correct dispatch in gr_text for automatic log ticks
if yaxis[:scale] in _logScales
dv = string(dv, "\\ ")
elseif yaxis[:formatter] in (:scientific, :auto)
dv = convert_sci_unicode(dv)
end
end
gr_text(xi + (mirror ? 1 : -1) * 1e-2 * (yaxis[:tick_direction] == :out ? 1.5 : 1.0), yi, string(dv))
end
end
# border
intensity = sp[:framestyle] == :semi ? 0.5 : 1.0
if sp[:framestyle] in (:box, :semi)
gr_set_line(intensity, :solid, xaxis[:foreground_color_border])
gr_set_transparency(xaxis[:foreground_color_border], intensity)
gr_polyline(coords(xborder_segs)...)
gr_set_line(intensity, :solid, yaxis[:foreground_color_border])
gr_set_transparency(yaxis[:foreground_color_border], intensity)
gr_polyline(coords(yborder_segs)...)
end
end
# end
# add the guides
GR.savestate()
if sp[:title] != ""
gr_set_font(titlefont(sp))
loc = sp[:title_location]
if loc == :left
xpos = viewport_plotarea[1]
halign = GR.TEXT_HALIGN_LEFT
elseif loc == :right
xpos = viewport_plotarea[2]
halign = GR.TEXT_HALIGN_RIGHT
else
xpos = gr_view_xcenter()
halign = GR.TEXT_HALIGN_CENTER
end
GR.settextalign(halign, GR.TEXT_VALIGN_TOP)
gr_text(xpos, viewport_subplot[4], sp[:title])
end
if is3d(sp)
gr_set_font(guidefont(xaxis))
GR.titles3d(xaxis[:guide], yaxis[:guide], zaxis[:guide])
else
xticks, yticks = axis_drawing_info(sp)[1:2]
if xaxis[:guide] != ""
h = 0.01 + gr_xaxis_height(sp)
gr_set_font(guidefont(xaxis))
if xaxis[:guide_position] == :top || (xaxis[:guide_position] == :auto && xaxis[:mirror] == true)
GR.settextalign(GR.TEXT_HALIGN_CENTER, GR.TEXT_VALIGN_TOP)
gr_text(gr_view_xcenter(), viewport_plotarea[4] + h, xaxis[:guide])
else
GR.settextalign(GR.TEXT_HALIGN_CENTER, GR.TEXT_VALIGN_BOTTOM)
gr_text(gr_view_xcenter(), viewport_plotarea[3] - h, xaxis[:guide])
end
end
if yaxis[:guide] != ""
w = 0.02 + gr_yaxis_width(sp)
gr_set_font(guidefont(yaxis))
GR.setcharup(-1, 0)
if yaxis[:guide_position] == :right || (yaxis[:guide_position] == :auto && yaxis[:mirror] == true)
GR.settextalign(GR.TEXT_HALIGN_CENTER, GR.TEXT_VALIGN_BOTTOM)
gr_text(viewport_plotarea[2] + w, gr_view_ycenter(), yaxis[:guide])
else
GR.settextalign(GR.TEXT_HALIGN_CENTER, GR.TEXT_VALIGN_TOP)
gr_text(viewport_plotarea[1] - w, gr_view_ycenter(), yaxis[:guide])
end
end
end
GR.restorestate()
gr_set_font(tickfont(xaxis))
# this needs to be here to point the colormap to the right indices
GR.setcolormap(1000 + GR.COLORMAP_COOLWARM)
for (idx, series) in enumerate(series_list(sp))
st = series[:seriestype]
# update the current stored gradient
gr_set_gradient(series)
GR.savestate()
# update the bounding window
if ispolar(sp)
gr_set_viewport_polar()
else
xmin, xmax, ymin, ymax = data_lims
if xmax > xmin && ymax > ymin
GR.setwindow(xmin, xmax, ymin, ymax)
end
end
x, y, z = series[:x], series[:y], series[:z]
frng = series[:fillrange]
clims = get_clims(sp, series)
# add custom frame shapes to markershape?
series_annotations_shapes!(series)
# -------------------------------------------------------
# recompute data
if typeof(z) <: Surface
z = vec(transpose_z(series, z.surf, false))
elseif ispolar(sp)
if frng !== nothing
_, frng = convert_to_polar(x, frng, (rmin, rmax))
end
x, y = convert_to_polar(x, y, (rmin, rmax))
end
if st == :straightline
x, y = straightline_data(series)
end
if st in (:path, :scatter, :straightline)
if x !== nothing && length(x) > 1
lz = series[:line_z]
segments = iter_segments(series)
# do area fill
if frng !== nothing
GR.setfillintstyle(GR.INTSTYLE_SOLID)
fr_from, fr_to = (is_2tuple(frng) ? frng : (y, frng))
for (i, rng) in enumerate(segments)
fc = get_fillcolor(series, clims, i)
gr_set_fillcolor(fc)
fx = _cycle(x, vcat(rng, reverse(rng)))
fy = vcat(_cycle(fr_from,rng), _cycle(fr_to,reverse(rng)))
gr_set_transparency(fc, get_fillalpha(series, i))
GR.fillarea(fx, fy)
end
end
# draw the line(s)
if st in (:path, :straightline)
for (i, rng) in enumerate(segments)
lc = get_linecolor(series, clims, i)
gr_set_line(get_linewidth(series, i), get_linestyle(series, i), lc) #, series[:linealpha])
arrowside = isa(series[:arrow], Arrow) ? series[:arrow].side : :none
arrowstyle = isa(series[:arrow], Arrow) ? series[:arrow].style : :simple
gr_set_fillcolor(lc)
gr_set_transparency(lc, get_linealpha(series, i))
gr_polyline(x[rng], y[rng]; arrowside = arrowside, arrowstyle = arrowstyle)
end
end
end
if series[:markershape] != :none
gr_draw_markers(series, x, y, clims)
end
elseif st == :contour
GR.setspace(clims[1], clims[2], 0, 90)
GR.setlinetype(gr_linetype[get_linestyle(series)])
GR.setlinewidth(max(0, get_linewidth(series) / (sum(gr_plot_size) * 0.001)))
is_lc_black = let black=plot_color(:black)
plot_color(series[:linecolor]) in (black,[black])
end
h = gr_contour_levels(series, clims)
if series[:fillrange] !== nothing
if series[:fillcolor] != series[:linecolor] && !is_lc_black
@warn("GR: filled contour only supported with black contour lines")
end
GR.contourf(x, y, h, z, series[:contour_labels] == true ? 1 : 0)
else
coff = is_lc_black ? 0 : 1000
GR.contour(x, y, h, z, coff + (series[:contour_labels] == true ? 1 : 0))
end
elseif st in [:surface, :wireframe]
if st == :surface
if length(x) == length(y) == length(z)
GR.trisurface(x, y, z)
else
try
GR.gr3.surface(x, y, z, GR.OPTION_COLORED_MESH)
catch
GR.surface(x, y, z, GR.OPTION_COLORED_MESH)
end
end
else
GR.setfillcolorind(0)
GR.surface(x, y, z, GR.OPTION_FILLED_MESH)
end
elseif st == :volume
sp[:legend] = :none
GR.gr3.clear()
dmin, dmax = GR.gr3.volume(y.v, 0)
elseif st == :heatmap
zmin, zmax = clims
if !ispolar(sp)
GR.setspace(zmin, zmax, 0, 90)
x, y = heatmap_edges(series[:x], sp[:xaxis][:scale], series[:y], sp[:yaxis][:scale], size(series[:z]))
w, h = length(x) - 1, length(y) - 1
z_normalized = map(x -> GR.jlgr.normalize_color(x, zmin, zmax), z)
if is_uniformly_spaced(x) && is_uniformly_spaced(y)
# For uniformly spaced data use GR.drawimage, which can be
# much faster than GR.nonuniformcellarray, especially for
# pdf output, and also supports alpha values.
# Note that drawimage draws uniformly spaced data correctly
# even on log scales, where it is visually non-uniform.
colors = plot_color.(series[:fillcolor][z_normalized], series[:fillalpha])
colors[isnan.(z_normalized)] .= RGBA(0,0,0,0)
rgba = gr_color.(colors)
GR.drawimage(first(x), last(x), last(y), first(y), w, h, rgba)
else
(something(series[:fillalpha],1) < 1 || any(_gr_gradient_alpha .< 1)) && @warn(
"GR: transparency not supported in non-uniform heatmaps. Alpha values ignored.")
z_normalized = map(x -> isnan(x) ? 256/255 : x, z_normalized) # results in color index = 1256 -> transparent
colors = Int32[round(Int32, 1000 + _i * 255) for _i in z_normalized]
GR.nonuniformcellarray(x, y, w, h, colors)
end
else
phimin, phimax = 0.0, 360.0 # nonuniform polar array is not yet supported in GR.jl
nx, ny = length(series[:x]), length(series[:y])
z_normalized = map(x -> GR.jlgr.normalize_color(x, zmin, zmax), z)
colors = Int32[round(Int32, 1000 + _i * 255) for _i in z_normalized]
xmin, xmax, ymin, ymax = xy_lims
rmax = data_lims[4]
GR.setwindow(-rmax, rmax, -rmax, rmax)
if ymin > 0
@warn "'ymin[1] > 0' (rmin) is not yet supported."
end
if series[:y][end] != ny
@warn "Right now only the maximum value of y (r) is taken into account."
end
# GR.polarcellarray(0, 0, phimin, phimax, ymin, ymax, nx, ny, colors)
GR.polarcellarray(0, 0, phimin, phimax, 0, ymax, nx, ny, colors)
# Right now only the maximum value of y (r) is taken into account.
# This is certainly not perfect but nonuniform polar array is not yet supported in GR.jl
end
elseif st in (:path3d, :scatter3d)
# draw path
if st == :path3d
if length(x) > 1
lz = series[:line_z]
segments = iter_segments(series)
for (i, rng) in enumerate(segments)
lc = get_linecolor(series, clims, i)
gr_set_line(get_linewidth(series, i), get_linestyle(series, i), lc) #, series[:linealpha])
gr_set_transparency(lc, get_linealpha(series, i))
GR.polyline3d(x[rng], y[rng], z[rng])
end
end
end
# draw markers
if st == :scatter3d || series[:markershape] != :none
x2, y2 = unzip(map(GR.wc3towc, x, y, z))
gr_draw_markers(series, x2, y2, clims)
end
# TODO: replace with pie recipe
elseif st == :pie
GR.selntran(0)
GR.setfillintstyle(GR.INTSTYLE_SOLID)
xmin, xmax, ymin, ymax = viewport_plotarea
ymax -= 0.1 * (xmax - xmin)
xcenter = 0.5 * (xmin + xmax)
ycenter = 0.5 * (ymin + ymax)
if xmax - xmin > ymax - ymin
r = 0.5 * (ymax - ymin)
xmin, xmax = xcenter - r, xcenter + r
else
r = 0.5 * (xmax - xmin)
ymin, ymax = ycenter - r, ycenter + r
end
labels = pie_labels(sp, series)
slices = series[:y]
numslices = length(slices)
total = sum(slices)
a1 = 0
x = zeros(3)
y = zeros(3)
for i in 1:numslices
a2 = round(Int, a1 + (slices[i] / total) * 360.0)
GR.setfillcolorind(980 + (i-1) % 20)
GR.fillarc(xmin, xmax, ymin, ymax, a1, a2)
α = 0.5 * (a1 + a2)
cosf = r * cos(α * pi / 180)
sinf = r * sin(α * pi / 180)
x[1] = xcenter + cosf
y[1] = ycenter + sinf
x[2] = x[1] + 0.1 * cosf
y[2] = y[1] + 0.1 * sinf
y[3] = y[2]
if 90 <= α < 270
x[3] = x[2] - 0.05
GR.settextalign(GR.TEXT_HALIGN_RIGHT, GR.TEXT_VALIGN_HALF)
gr_text(x[3] - 0.01, y[3], string(labels[i]))
else
x[3] = x[2] + 0.05
GR.settextalign(GR.TEXT_HALIGN_LEFT, GR.TEXT_VALIGN_HALF)
gr_text(x[3] + 0.01, y[3], string(labels[i]))
end
gr_polyline(x, y)
a1 = a2
end
GR.selntran(1)
elseif st == :shape
x, y = shape_data(series)
for (i,rng) in enumerate(iter_segments(x, y))
if length(rng) > 1
# connect to the beginning
rng = vcat(rng, rng[1])
# get the segments
xseg, yseg = x[rng], y[rng]
# draw the interior
fc = get_fillcolor(series, clims, i)
gr_set_fill(fc)
gr_set_transparency(fc, get_fillalpha(series, i))
GR.fillarea(xseg, yseg)
# draw the shapes
lc = get_linecolor(series, clims, i)
gr_set_line(get_linewidth(series, i), get_linestyle(series, i), lc)
gr_set_transparency(lc, get_linealpha(series, i))
GR.polyline(xseg, yseg)
end
end
elseif st == :image
z = transpose_z(series, series[:z].surf, true)'
w, h = size(z)
xmin, xmax = ignorenan_extrema(series[:x]); ymin, ymax = ignorenan_extrema(series[:y])
rgba = gr_color.(z)
GR.drawimage(xmin, xmax, ymax, ymin, w, h, rgba)
end
# this is all we need to add the series_annotations text
anns = series[:series_annotations]
for (xi,yi,str,fnt) in EachAnn(anns, x, y)
gr_set_font(fnt)
gr_text(GR.wctondc(xi, yi)..., str)
end
GR.restorestate()
end
# draw the colorbar
hascolorbar(sp) && gr_draw_colorbar(cbar, sp, get_clims(sp))
# add the legend
if sp[:legend] != :none
GR.savestate()
GR.selntran(0)
GR.setscale(0)
gr_set_font(legendfont(sp))
w = legendw
n = legendn
if w > 0
dy = _gr_point_mult[1] * sp[:legendfontsize] * 1.75
h = dy*n
xpos, ypos = gr_legend_pos(sp, w, h)
GR.setfillintstyle(GR.INTSTYLE_SOLID)
gr_set_fillcolor(sp[:background_color_legend])
GR.fillrect(xpos - 0.08, xpos + w + 0.02, ypos + dy, ypos - dy * n)
gr_set_line(1, :solid, sp[:foreground_color_legend])
GR.drawrect(xpos - 0.08, xpos + w + 0.02, ypos + dy, ypos - dy * n)
i = 0
if sp[:legendtitle] !== nothing
GR.settextalign(GR.TEXT_HALIGN_CENTER, GR.TEXT_VALIGN_HALF)
gr_set_font(legendtitlefont(sp))
gr_text(xpos - 0.03 + 0.5*w, ypos, string(sp[:legendtitle]))
ypos -= dy
gr_set_font(legendfont(sp))
end
for series in series_list(sp)
clims = get_clims(sp, series)
should_add_to_legend(series) || continue
st = series[:seriestype]
lc = get_linecolor(series, clims)
gr_set_line(get_linewidth(series), get_linestyle(series), lc) #, series[:linealpha])
if (st == :shape || series[:fillrange] !== nothing) && series[:ribbon] === nothing
fc = get_fillcolor(series, clims)
gr_set_fill(fc) #, series[:fillalpha])
l, r = xpos-0.07, xpos-0.01
b, t = ypos-0.4dy, ypos+0.4dy
x = [l, r, r, l, l]
y = [b, b, t, t, b]
gr_set_transparency(fc, get_fillalpha(series))
gr_polyline(x, y, GR.fillarea)
lc = get_linecolor(series, clims)
gr_set_transparency(lc, get_linealpha(series))
gr_set_line(get_linewidth(series), get_linestyle(series), lc)
st == :shape && gr_polyline(x, y)
end
if st in (:path, :straightline)
gr_set_transparency(lc, get_linealpha(series))
if series[:fillrange] === nothing || series[:ribbon] !== nothing
GR.polyline([xpos - 0.07, xpos - 0.01], [ypos, ypos])
else
GR.polyline([xpos - 0.07, xpos - 0.01], [ypos+0.4dy, ypos+0.4dy])
end
end
if series[:markershape] != :none
gr_draw_markers(series, xpos - .035, ypos, clims, 6)
end
lab = series[:label]
GR.settextalign(GR.TEXT_HALIGN_LEFT, GR.TEXT_VALIGN_HALF)
gr_set_textcolor(plot_color(sp[:legendfontcolor]))
gr_text(xpos, ypos, string(lab))
ypos -= dy
end
end
GR.selntran(1)
GR.restorestate()
end
# add annotations
GR.savestate()
# update the bounding window
if ispolar(sp)
gr_set_viewport_polar()
else
xmin, xmax, ymin, ymax = data_lims
if xmax > xmin && ymax > ymin
GR.setwindow(xmin, xmax, ymin, ymax)
end
end
for ann in sp[:annotations]
x, y, val = locate_annotation(sp, ann...)
x, y = if is3d(sp)
# GR.wc3towc(x, y, z)
else
GR.wctondc(x, y)
end
gr_set_font(val.font)
gr_text(x, y, val.str)
end
GR.restorestate()
end
# ----------------------------------------------------------------
const _gr_mimeformats = Dict(
"application/pdf" => "pdf",
"image/png" => "png",
"application/postscript" => "ps",
"image/svg+xml" => "svg",
)
const _gr_wstype = Ref(get(ENV, "GKSwstype", ""))
gr_set_output(wstype::String) = (_gr_wstype[] = wstype)
for (mime, fmt) in _gr_mimeformats
@eval function _show(io::IO, ::MIME{Symbol($mime)}, plt::Plot{GRBackend})
GR.emergencyclosegks()
filepath = tempname() * "." * $fmt
env = get(ENV, "GKSwstype", "0")
ENV["GKSwstype"] = $fmt
ENV["GKS_FILEPATH"] = filepath
gr_display(plt, $fmt)
GR.emergencyclosegks()
write(io, read(filepath, String))
rm(filepath)
if env != "0"
ENV["GKSwstype"] = env
else
pop!(ENV,"GKSwstype")
end
end
end
function _display(plt::Plot{GRBackend})
if plt[:display_type] == :inline
GR.emergencyclosegks()
filepath = tempname() * ".pdf"
ENV["GKSwstype"] = "pdf"
ENV["GKS_FILEPATH"] = filepath
gr_display(plt)
GR.emergencyclosegks()
content = string("\033]1337;File=inline=1;preserveAspectRatio=0:", base64encode(open(read, filepath)), "\a")
println(content)
rm(filepath)
else
ENV["GKS_DOUBLE_BUF"] = true
if _gr_wstype[] != ""
ENV["GKSwstype"] = _gr_wstype[]
end
gr_display(plt)
end
end
closeall(::GRBackend) = GR.emergencyclosegks()
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