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livetrax/scripts/hplp.lua

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ardour {
["type"] = "dsp",
2016-07-05 11:17:59 -04:00
name = "a-High/Low Pass Filter",
category = "Filter",
license = "MIT",
2016-07-05 11:17:59 -04:00
author = "Ardour Team",
description = [[Example Ardour Lua DSP Plugin]]
}
function dsp_ioconfig ()
return
{
-- allow any number of I/O as long as port-count matches
{ audio_in = -1, audio_out = -1},
}
end
function dsp_params ()
return
{
{ ["type"] = "input", name = "Type", min = 0, max = 1, default = 0, enum = true, scalepoints =
{
["High Pass"] = 0,
["Low Pass"] = 1,
}
},
{ ["type"] = "input", name = "Steepness", min = 1, max = 4, default = 1, enum = true, scalepoints =
{
["12dB/oct"] = 1,
["24dB/oct"] = 2,
["36dB/oct"] = 3,
["48dB/oct"] = 4,
}
},
{ ["type"] = "input", name = "Cut off frequency", min = 5, max = 20000, default = 1000, unit="Hz", logarithmic = true },
{ ["type"] = "input", name = "Resonance", min = 0.1, max = 8, default = .707, logarithmic = true },
}
end
-- translate type parameter to DSP enum
-- http://manual.ardour.org/lua-scripting/class_reference/#ARDOUR.DSP.Biquad.Type
function map_type (t)
if t == 1 then
return ARDOUR.DSP.BiquadType.LowPass
else
return ARDOUR.DSP.BiquadType.HighPass
end
end
-- these globals are *not* shared between DSP and UI
local filters = {} -- the biquad filter instances (DSP)
local filt -- the biquad filter instance (GUI, response)
local cur = {0, 0, 0, 0} -- current parameters
local lpf = 0.03 -- parameter low-pass filter time-constant
local chn = 0 -- channel/filter count
function dsp_init (rate)
self:shmem ():allocate (1) -- shared mem to tell the GUI the samplerate
local cfg = self:shmem ():to_int (0):array ()
cfg[1] = rate
lpf = 13000 / rate -- interpolation time constant
end
function dsp_configure (ins, outs)
assert (ins:n_audio () == outs:n_audio ())
local cfg = self:shmem ():to_int (0):array ()
local rate = cfg[1]
chn = ins:n_audio ()
for c = 1, chn do
filters[c] = {}
-- http://manual.ardour.org/lua-scripting/class_reference/#ARDOUR:DSP:Biquad
for k = 1,4 do
filters[c][k] = ARDOUR.DSP.Biquad (rate) -- initialize filters
end
end
cur = {0, 0, 0, 0}
end
-- helper functions for parameter interpolation
function param_changed (ctrl)
if math.floor(ctrl[1]) == math.floor(cur[1]) and math.floor(ctrl[2]) == math.floor(cur[2]) and ctrl[3] == cur[3] and ctrl[4] == cur[4] then
return false
end
return true
end
function low_pass_filter_param (old, new, limit)
if math.abs (old - new) < limit then
return new
else
return old + lpf * (new - old)
end
end
-- apply parameters, re-compute filter coefficients if needed
function apply_params (ctrl)
if not param_changed (ctrl) then
return
end
if cur[1] ~= ctrl[1] or cur[2] ~= ctrl[2] then
-- reset filter state when type or order changes
for c = 1, chn do
for k = 1,4 do
filters[c][k]:reset ()
end
end
for k = 1,4 do cur[k] = ctrl[k] end
else
-- low-pass filter ctrl parameter values, smooth transition
cur[3] = low_pass_filter_param (cur[3], ctrl[3], 1.0) -- freq/Hz
cur[4] = low_pass_filter_param (cur[4], ctrl[4], 0.01) -- quality
end
if cur[2] < 1 then cur[2] = 1 end
if cur[2] > 4 then cur[2] = 4 end
for c = 1, chn do
for k = 1,4 do
filters[c][k]:compute (map_type (cur[1]), cur[3], cur[4], 0)
end
end
end
-- the actual DSP callback
function dsp_run (ins, outs, n_samples)
local changed = false
local siz = n_samples
local off = 0
-- if a parameter was changed, process at most 64 samples at a time
-- and interpolate parameters until the current settings match
-- the target values
if param_changed (CtrlPorts:array ()) then
changed = true
siz = 64
end
local o = math.floor(cur[2])
while n_samples > 0 do
if changed then apply_params (CtrlPorts:array ()) end
if siz > n_samples then siz = n_samples end
-- process all channels
for c = 1,#ins do
-- check if output and input buffers for this channel are identical
-- http://manual.ardour.org/lua-scripting/class_reference/#C:FloatArray
if not ins[c]:sameinstance (outs[c]) then
-- http://manual.ardour.org/lua-scripting/class_reference/#ARDOUR:DSP
ARDOUR.DSP.copy_vector (outs[c]:offset (off), ins[c]:offset (off), siz)
end
for k = 1,o do
filters[c][k]:run (outs[c]:offset (off), siz) -- in-place processing
end
end
n_samples = n_samples - siz
off = off + siz
end
if changed then
-- notify display
self:queue_draw ()
end
end
-------------------------------------------------------------------------------
--- inline display
function round (n)
return math.floor (n + .5)
end
function freq_at_x (x, w)
-- x-axis pixel for given freq, power-scale
return 20 * 1000 ^ (x / w)
end
function x_at_freq (f, w)
-- frequency at given x-axis pixel
return w * math.log (f / 20.0) / math.log (1000.0)
end
function db_to_y (db, h)
-- y-axis gain mapping
if db < -60 then db = -60 end
if db > 12 then db = 12 end
return -.5 + round (0.2 * h) - h * db / 60
end
function grid_db (ctx, w, h, db)
-- draw horizontal grid line
local y = -.5 + round (db_to_y (db, h))
ctx:move_to (0, y)
ctx:line_to (w, y)
ctx:stroke ()
end
function grid_freq (ctx, w, h, f)
-- draw vertical grid line
local x = -.5 + round (x_at_freq (f, w))
ctx:move_to (x, 0)
ctx:line_to (x, h)
ctx:stroke ()
end
function render_inline (ctx, w, max_h)
if not filt then
-- the GUI is separate from the DSP, but the GUI needs to know
-- the sample-rate that the DSP is using.
local shmem = self:shmem () -- get shared memory region
local cfg = shmem:to_int (0):array () -- "cast" into lua-table
-- instantiate filter (to calculate the transfer function's response)
filt = ARDOUR.DSP.Biquad (cfg[1])
end
-- set filter coefficients if they have changed
if param_changed (CtrlPorts:array ()) then
local ctrl = CtrlPorts:array ()
for k = 1,4 do cur[k] = ctrl[k] end
if cur[2] < 1 then cur[2] = 1 end
if cur[2] > 4 then cur[2] = 4 end
filt:compute (map_type (cur[1]), cur[3], cur[4], 0)
end
-- calc height of inline display
local h = math.ceil (w * 10 / 16) -- use 16:10 aspect
if (h > max_h) then h = max_h end -- but at most max-height
-- ctx is a http://cairographics.org/ context
-- http://manual.ardour.org/lua-scripting/class_reference/#Cairo:Context
-- clear background
ctx:rectangle (0, 0, w, h)
ctx:set_source_rgba (.2, .2, .2, 1.0)
ctx:fill ()
ctx:rectangle (0, 0, w, h)
ctx:clip ();
-- set line width: 1px
-- Note: a cairo pixel at [1,1] spans [0.5->1.5 , 0.5->1.5]
-- hence the offset -0.5 in various move_to(), line_to() calls
ctx:set_line_width (1.0)
-- draw grid
local dash3 = C.DoubleVector ()
local dash2 = C.DoubleVector ()
dash2:add ({1, 2})
dash3:add ({1, 3})
ctx:set_dash (dash2, 2) -- dotted line
ctx:set_source_rgba (.5, .5, .5, .8)
grid_db (ctx, w, h, 0)
ctx:set_dash (dash3, 2) -- dotted line
ctx:set_source_rgba (.5, .5, .5, .5)
grid_db (ctx, w, h, -12)
grid_db (ctx, w, h, -24)
grid_db (ctx, w, h, -36)
grid_freq (ctx, w, h, 100)
grid_freq (ctx, w, h, 1000)
grid_freq (ctx, w, h, 10000)
ctx:unset_dash ()
local o = math.floor(cur[2])
-- draw transfer function line
ctx:set_source_rgba (.8, .8, .8, 1.0)
ctx:move_to (-.5, db_to_y (o * filt:dB_at_freq (freq_at_x (0, w)), h))
for x = 1,w do
local db = o * filt:dB_at_freq (freq_at_x (x, w))
ctx:line_to (-.5 + x, db_to_y (db, h))
end
ctx:stroke_preserve ()
-- fill area to zero under the curve
ctx:line_to (w, -.5 + round (db_to_y (0, h)))
ctx:line_to (0, -.5 + round (db_to_y (0, h)))
ctx:close_path ()
ctx:set_source_rgba (.5, .5, .5, .5)
ctx:fill ()
return {w, h}
end