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34 changed files with 5115 additions and 1615 deletions

2
.gitignore vendored
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@ -1,5 +1,3 @@
zig-cache/
zig-out/
*.mp3
*.wav
build_runner.zig

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@ -20,9 +20,6 @@ glitch art "framework", ???????? language??? something?
will likely be there by default)
- the SWH plugins ( https://github.com/swh/lv2 )
- the Invada Studio plugins ( https://launchpad.net/invada-studio/ )
- abGate plugin
- MDA plugins
- Calf plugins
```bash
# build and install
@ -51,17 +48,10 @@ $your_image_viewer blah_g1.bmp
using repl works via `scritcher repl scri_file.scri input_image.bmp`
you type commands as you'd write the specific scritcher commands
(`doc/README.md`), with four repl-specific ones (semicolons do not apply):
(`doc/README.md`), with three repl-specific ones:
- `push`, to push the last written command to the queue
- `save`, to write the queue to the given `scri_file.scri` file
- `list`, to print the current contents of the queue
- `quit`, to exit
After a non-REPL command, such as an effect, the program pointed by
`SCRITCHER_RUNNER` will run as argument to the `runqs` command. By default,
the program run will be `ristretto` (as it is my preffered image viewer,
considering it was able to handle when some images went broke)
this allows for quicker iteration of commands, as you can type a command, see
the image changes as fast as possible, tweak its arguments,
and when satisfied, `push` it, and work on the next command, etc.
this allows for quicker iteration of commands, as you can type a command, tweak
its arguments, and when satisfied, `push` it, and work on the next one, etc.

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@ -1,6 +1,7 @@
const std = @import("std");
const builds = @import("std").build;
const Builder = @import("std").build.Builder;
fn setupLinks(step: *std.Build.Step.Compile) void {
fn setupLinks(step: *builds.LibExeObjStep) void {
step.linkSystemLibrary("c");
step.linkSystemLibrary("lilv-0");
@ -10,64 +11,27 @@ fn setupLinks(step: *std.Build.Step.Compile) void {
step.linkSystemLibrary("GraphicsMagickWand");
step.linkSystemLibrary("GraphicsMagick");
step.addIncludePath(.{ .path = "/usr/include/GraphicsMagick" });
step.addIncludePath(.{ .path = "/usr/include" });
const possible_lilv_include_dirs = [_][]const u8{
"/usr/include/lilv-0/lilv",
"/usr/include/lilv-0",
};
var found_any_lilv = false;
for (possible_lilv_include_dirs) |possible_lilv_dir| {
var possible_dir = std.fs.cwd().openDir(possible_lilv_dir, .{}) catch |err| {
std.debug.print("possible lilv {s} fail: {s}\n", .{ possible_lilv_dir, @errorName(err) });
continue;
};
possible_dir.close();
found_any_lilv = true;
std.debug.print("found lilv at '{s}'\n", .{possible_lilv_dir});
step.addIncludePath(.{ .path = possible_lilv_dir });
step.addIncludeDir("/usr/include/lilv-0");
step.addIncludeDir("/usr/include/GraphicsMagick");
}
if (!found_any_lilv) {
std.debug.print("No LILV library was found :(\n", .{});
@panic("no lilv found");
}
}
pub fn build(b: *Builder) void {
const mode = b.standardReleaseOptions();
const exe = b.addExecutable("scritcher", "src/main.zig");
exe.setBuildMode(mode);
exe.install();
pub fn build(b: *std.Build) void {
const target = b.standardTargetOptions(.{});
const optimize = b.standardOptimizeOption(.{});
const exe = b.addExecutable(.{
.name = "scritcher",
.root_source_file = b.path("src/main.zig"),
.target = target,
.optimize = optimize,
});
setupLinks(exe);
b.installArtifact(exe);
const run_cmd = b.addRunArtifact(exe);
const test_obj_step = b.addTest("src/main.zig");
setupLinks(test_obj_step);
if (b.args) |args| {
run_cmd.addArgs(args);
}
const run_cmd = exe.run();
run_cmd.step.dependOn(b.getInstallStep());
const run_step = b.step("run", "Run the app");
run_step.dependOn(&run_cmd.step);
const test_step = b.addTest(.{
.root_source_file = b.path("src/main.zig"),
.target = target,
.optimize = optimize,
});
setupLinks(test_step);
const run_unit_tests = b.addRunArtifact(test_step);
const test_cmd = b.step("test", "run unit tests");
test_cmd.dependOn(&run_unit_tests.step);
const test_step = b.step("test", "Run tests");
test_step.dependOn(&test_obj_step.step);
}

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@ -23,8 +23,7 @@ where in the file you want the plugin to be ran.
so, if you did `plugin 3 1...`, it would split the file in 3, then get the
part that is of index 1 (starting at 0).
**Keep in mind parts can start from either top or bottom of the image,
it depends of the file format**
**Keep in mind parts start from the bottom of the file.**
## `load path_or_arg`
@ -167,11 +166,6 @@ Rotate the image by `deg` degrees, filling the resulting triangles with `bgfill`
`bgfill` is a hex string, e.g `#000000`.
## `embed split index path_to_file`
embed an audio file in the given image. the file is opened with libsndfile,
which means some formats, like mp3, will not be opened.
## `quicksave`
Save the file on the same directory of the file specified by `load`, but
@ -179,201 +173,3 @@ with a suffix on the filename (before extension).
Doing consecutive `quicksave`s will not overwrite any files, the suffixes will
just be different.
## `gate split index switch threshold attack hold decay gaterange`
**TODO:** find good parameters
- switch (bool): 0..1, default 0
- threshold (dB): -70..12, default -70
- attack (ms): 0.1..500, default 30
- hold (ms): 5..3000, default 500
- decay (ms): 5..4000, default 1000
- gaterange (dB): -90..-20, default -90
## `detune split index detune mix output latency`
> A low-quality stereo pitch shifter for the sort of chorus and detune effects found on multi-effects hardware.
- detune (cents, left channel is lowered in pitch, right channel is raised): 0..1, default 0.2
- mix (wet/dry mix): 0..1, default 0.9
- output (level trim): 0..1, default 0.5
- latency (trade-off between latency and low-freq response): 0..1, default 0.5
other presets:
- stereo detune: 0.2 0.9 0.5 0.5
- out of tune: 0.8 0.7 0.5 0.5
## `overdrive split index drive muffle output`
> Possible uses include adding body to drum loops, fuzz guitar, and that 'standing outside a nightclub' sound. This plug does not simulate valve distortion, and any attempt to process organ sounds through it will be extremely unrewarding!
- drive (amount of distortion): 0..1, default 0
- muffle (gentle low-pass filter): 0..1, default 0
- output (level trim): 0..1, default 0.5
## `degrade split index headroom quant rate post_filt non_lin output`
> Sample quality reduction
**NOTE:** finding the right parameters is HARD for this plugin.
- headroom (peak clipping threshold): 0..1, default 0.8
- quant (bit depth, typically 8 or below for "telephone" quality): 0..1, default 0.5
- rate (sample rate): 0..1, default 0.65
- post_filt (low-pass filter to muffle the distortion): 0..1, default 0.9
- non_lin (additional harmonic distortion "thickening"): 0..1, default 0.58
- output: 0..1, default 0.5
## `repsycho split index tune fine decay thresh hold mix quality`
**NOTE:** HARD to find good parameters
- tune (coarse tune, semitones): 0..1, default 1
- fine (fine tune, cents): 0..1, default 1
- decay (adjust envelope of each trunk, a fast decay can be useful while setting up): 0..1, default 0.5
- thresh (trigger level to divide the input into chunks): 0..1, default 0.6
- hold (minimum chunk length): 0..1, default 0.45
- mix (mix original signal with output): 0..1, default 1
- quality (quality, bool. the high=1 setting uses smoother pitch-shifting and allows stereo): 0..1, default 0
## `talkbox split index wet dry carrier quality`
> High resolution vocoder
- wet: 0..1, default 0.5
- dry: 0..1, default 0
- carrier: 0..1, default 0
- quality: 0..1, default 1
## `dyncomp split index enable hold inputgain threshold ratio attack release gain_min gain_max rms`
- enable (bool): 0..1, default 1
- hold (bool): 0..1, default 0
- inputgain (dB): -10..30, default 0
- threshold (dB): -50..-10, default -30
- ratio (???): 0..1, default 0
- attack (seconds): 0.001..0.1, default 0.01
- release (seconds): 0.03..3.0, default 0.3
- gain\_min (dB): -20..40
- gain\_max (dB): -20..40
- rms (signal level, dB): -80..10
## `thruzero split index rate mix feedback depth_mod`
> Tape flanger and ADT
> This plug simulates tape-flanging, where two copies of a signal cancel out completely as the tapes pass each other. It can also be used for other "modulated delay" effects such as phasing and simple chorusing.
- rate (modulation rate, set to minimum for static comb filtering): 0..1, default 0.3
- mix (wet/dry mix, set to 50% for complete cancelling): 0..1, default 0.47
- feedback (add positive or negative feedback for harsher or "ringing" sound): 0..1, default 0.3
- depth_mod (modulation depth, set to less than 100% to limit build up of low frequencies with feedback): 0..1, default 1
## `foverdrive split index drive`
Fast Overdrive from SWH plugins.
- drive: 1..3, default 1
## `gverb split index roomsize revtime damping drylevel earlylevel taillevel`
GVerb algorithm from SWH plugins.
- roomsize (meters): 1..300, default 75.75
- revtime (reverb time, seconds): 0.1..30, default 7.575
- damping: 0..1, default 0.5
- inputbandwidth: 0..1, default 0.75
- drylevel (dB): -70..0, default 0
- earlylevel (dB): -70..0, default 0
- taillevel (dB): -70..0, default -17.5
## `invert split index`
> A utility plugin that inverts the signal, also (wrongly) known as a 180 degree phase shift.
## `tapedelay split index speed da_db t1d t1a_db...`
**TODO:** gives 0 output
> Correctly models the tape motion and some of the smear effect, there is no simulation fo the head saturation yet, as I don't have a good model of it. When I get one I will add it.
> The way the tape accelerates and decelerates gives a nicer delay effect for many purposes.
- speed (inches/sec, 1=normal): 0..10, default 1
- da\_db (dry level, dB): -90..0, default -90
- t1d (tap 1 distance, inches): 0..4, default 0
- t1a\_db (tap 1 level, dB): -90..0, default 0
- t2d (tap 2 distance, inches): 0..4, default 1
- t2a\_db (tap 2 level, dB): -90..0, default -90
- t3d (tap 3 distance, inches): 0..4, default 2
- t3a\_db (tap 3 level, dB): -90..0, default -90
- t4d (tap 4 distance, inches): 0..4, default 3
- t4a\_db (tap 4 level, dB): -90..0, default -90
## `moddelay split index base`
> A delay whose tap can be modulated at audio rate.
- base (base delay, seconds): 0..1, default 1
## `multichorus split index min_delay mod_depth mod_rate stereo voices vphase amount dry freq freq2 q overlap level_in level_out lfo`
Calf Multi Chorus
- `min_delay` (ms): 0.1..10, default 5
- `mod_depth` (ms): 0.1..10, default 6
- `mod_rate` (hz): 0.1..20, default 0.1
- `stereo` (degrees): 0..360, default 180
- `voices`: 1..8, default 4
- `vphase` (inter-voice phase, degrees): 0..360, default 64
- `amount`: 0..4, default 0.5
- `dry`: 0..4, default 0.5
- `freq` (center frq 1, hz): 10..20000, default 100
- `freq2` (center frq 2, hz): 10..20000, default 5000
- `q` (???): 0.125..8, default 0.125
- `overlap`: 0..1, default 0.75
- `level_in` (Input Gain): 0.0156250..64, default 1
- `level_out` (Output Gain): 0.0156250..64, default 1
- `lfo` (toggle): 0..1, default 1
## `saturator split index bypass level_in level_out mix drive blend lp_pre_freq hp_pre_fre lp_post_freq hp_post_freq p_freq p_level p_q pre post`
- `bypass` (toggle): 0..1, default 0
- `level_in` (Input Gain): 0.0156250..64, default 1
- `level_out` (Output Gain): 0.0156250..64, default 1
- `mix`: 0..1, default 1
- `drive` (saturation, coef): 0.1..10, default 5
- `blend` (coef): -10..10, default 10
- `lp_pre_freq` (lowpass, hz): 10..20000, default 20000
- `hp_pre_freq` (highpass, hz): 10..20000, default 10
- `lp_post_freq` (lowpass, hz): 10..20000, default 20000
- `hp_post_freq` (highpass, hz): 10..20000, default 10
- `p_freq` (Tone, hz): 80..8000, default 2000
- `p_level` (Amount): 0.0625..16, default 1
- `p_q` (???, coef): 0.1..10, default 1
- `pre` (Activate Pre, toggle): 0..1, default 0
- `post` (Activate Post, toggle): 0..1, default 0
## `vintagedelay split index ...`
- `level_in` (Input Gain): 0.0156250..64, default 1
- `level_out` (Output Gain): 0.0156250..64, default 1
- `subdiv` (int): 1..16, default 4
- `time_l` (int): 1..16, default 3
- `time_r` (int): 1..16, default 5
- `feedback`: 0..1, default 0.5
- `amount` (Wet): 0..4, default 0.25
- `mix_mode` (enum): Stereo=0, Ping-Pong=1, L then R=2, R then L=3, default 1
- `medium` (enum): Plain=0, Tape=1, Old Tape=2, default 1
- `dry` (dry): 0..4, default 1
- `width` (stereo width, strict): -1..1, default 1
- `fragmentation` (enum): Repeating=0, Pattern=1, default 0
- `pbeats` (Pattern Beats, int): 1..8, default 4
- `pfrag` (Pattern Fragmentation, int): 1..8, default 4
- `timing` (enum): BPM=0, ms=1, Hz=2, Sync=3, default 0
- `bpm`: 30..300, default 120
- `ms` (int): 10..2000, default 500
- `hz`: 0.01..100, default 2
- `bpm_host` (strict): 1..300, default 120

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@ -1,8 +0,0 @@
load :0;
degrade 8 1 0.8 0.5 0.65 0.9 0.58 0.5;
degrade 8 2 0.1 1 0.65 0.5 0.5 0.4;
degrade 8 3 0.1 1 0.65 0.9 0.58 0.5;
degrade 8 4 0 1 1 0 0 1;
degrade 8 5 0 1 1 0 0 0;
degrade 8 6 0 0 0 0 0 0;
quicksave;

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@ -1,3 +0,0 @@
load :0;
detune 3 1 0.2 0.9 0.5 0.5;
quicksave;

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@ -1,3 +0,0 @@
load :0;
dyncomp 3 1 1 0 0 -30 0 0.01 0.3 0 0 0;
quicksave;

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@ -1,3 +0,0 @@
load :0;
foverdrive 3 1 100;
quicksave;

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@ -1,3 +0,0 @@
load :0;
gate 3 1 0 -70 30 500 1000 -90;
quicksave;

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@ -1,3 +0,0 @@
load :0;
gverb 3 1 75.75 7.575 0.5 0.75 0 0 -17.5;
quicksave;

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@ -1,3 +0,0 @@
load :0;
invert 3 1;
quicksave;

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@ -1,3 +1,3 @@
load :0;
mbeq 3 1 0 0 0 0.3 0 0 7 0 0 0 0 0 0.1 0 0;
mbeq 3 1 1 4 0.2 2.1;
quicksave;

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@ -1,3 +0,0 @@
load :0;
moddelay 3 1 1;
quicksave;

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@ -1,3 +0,0 @@
load :0;
multichorus 3 1 5 6 0.1 180 4 64 0.5 0.5 100 5000 0.125 0.75 1 1 1;
quicksave;

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@ -1,5 +0,0 @@
load :0;
overdrive 5 1 0.5 0 0.4;
overdrive 5 2 0.6 0.2 0.3;
overdrive 5 3 0.7 0.3 0.2;
quicksave;

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@ -1,8 +0,0 @@
load :0;
repsycho 8 1 1 1 0.5 0.6 0.45 1 0;
repsycho 8 2 1 1 1 0.6 0.45 1 0;
repsycho 8 3 1 1 0.5 0.8 0.45 1 0;
repsycho 8 4 1 1 0.5 0.6 0.1 1 0;
repsycho 8 5 1 1 0.5 0.6 0.45 0.5 0;
repsycho 8 6 1 1 0.5 0.6 0.45 1 1;
quicksave;

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@ -1,3 +0,0 @@
load :0;
rflanger 3 1 2.5 1;
quicksave;

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@ -1,3 +0,0 @@
load :0;
saturator 3 1 0 1 1 1 5 10 20000 10 20000 10 2000 1 1 0 0;
quicksave;

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@ -1,3 +0,0 @@
load :0;
talkbox 3 1 0.5 0 0 1;
quicksave;

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@ -1,3 +0,0 @@
load :0;
tapedelay 3 1 1 -90 0 0 1 -90 2 -90 3 -90;
quicksave;

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@ -1,3 +0,0 @@
load :0;
thruzero 3 1 0.3 0.47 0.3 1;
quicksave;

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@ -1,3 +0,0 @@
load :0;
vintagedelay 3 1 1 1 4 3 5 0.5 0.25 1 1 1 1 0 4 4 0 120 500 2 120;
quicksave;

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@ -1,10 +1,11 @@
const std = @import("std");
const log = std.log.scoped(.scritcher_bmp);
pub const BMPValidError = error{InvalidMagic};
const VALID_MAGICS = [_][]const u8{
"BM",
"BA",
"CI",
"CP",
"IC",
@ -19,7 +20,7 @@ pub fn magicValid(magic: []const u8) !void {
}
if (!valid) {
log.debug("\tINVALID HEADER: '{s}'", .{magic});
std.debug.warn("\tINVALID HEADER: '{}'\n", magic);
return BMPValidError.InvalidMagic;
}
}

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@ -4,7 +4,6 @@ const lv2 = @import("lv2_helpers.zig");
const plugins = @import("plugin.zig");
const image = @import("image.zig");
const log = std.log.scoped(.scritcher_custom);
const c = lv2.c;
const RunBuffers = plugins.RunBuffers;
@ -12,20 +11,23 @@ const RunBuffers = plugins.RunBuffers;
pub const RandomNoise = struct {
r: std.rand.DefaultPrng,
rand_buf: ?[]f32 = null,
allocator: ?std.mem.Allocator = null,
allocator: ?*std.mem.Allocator = null,
cnt: usize = 0,
pub fn init(
allocator: std.mem.Allocator,
params: anytype,
allocator: *std.mem.Allocator,
params: *plugins.ParamMap,
) ?RandomNoise {
var r = std.rand.DefaultPrng.init(params.seed);
const seed = @floatToInt(u64, params.get("seed").?.value);
const fillbytes = @floatToInt(usize, params.get("fill_bytes").?.value);
if (params.fill_bytes > 0) {
var rand_buf = allocator.alloc(f32, params.fill_bytes) catch return null;
var r = std.rand.DefaultPrng.init(seed);
for (rand_buf, 0..) |_, idx| {
rand_buf[idx] = r.random().float(f32);
if (fillbytes > 0) {
var rand_buf = allocator.alloc(f32, fillbytes) catch return null;
for (rand_buf) |_, idx| {
rand_buf[idx] = r.random.float(f32);
}
return RandomNoise{
@ -52,7 +54,7 @@ pub const RandomNoise = struct {
bufs.out[0] = rand_buf[self.cnt];
self.cnt += 1;
} else {
bufs.out[0] = self.r.random().float(f32);
bufs.out[0] = self.r.random.float(f32);
}
}
};
@ -60,20 +62,23 @@ pub const RandomNoise = struct {
pub const WildNoise = struct {
r: std.rand.DefaultPrng,
rand_buf: ?[]f32 = null,
allocator: ?std.mem.Allocator = null,
allocator: ?*std.mem.Allocator = null,
cnt: usize = 0,
pub fn init(
allocator: std.mem.Allocator,
params: anytype,
allocator: *std.mem.Allocator,
params: *plugins.ParamMap,
) ?WildNoise {
var r = std.rand.DefaultPrng.init(params.seed);
const seed = @floatToInt(u64, params.get("seed").?.value);
const fillbytes = @floatToInt(usize, params.get("fill_bytes").?.value);
if (params.fill_bytes > 0) {
var rand_buf = allocator.alloc(f32, params.fill_bytes) catch return null;
var r = std.rand.DefaultPrng.init(seed);
for (rand_buf, 0..) |_, idx| {
rand_buf[idx] = @as(f32, @floatFromInt(r.random().int(u1)));
if (fillbytes > 0) {
var rand_buf = allocator.alloc(f32, fillbytes) catch return null;
for (rand_buf) |_, idx| {
rand_buf[idx] = @intToFloat(f32, r.random.int(u1));
}
return WildNoise{
@ -99,7 +104,7 @@ pub const WildNoise = struct {
bufs.out[0] = rand_buf[self.cnt];
self.cnt += 1;
} else {
bufs.out[0] = @as(f32, @floatFromInt(self.r.random().int(u1)));
bufs.out[0] = @intToFloat(f32, self.r.random.int(u1));
}
}
};
@ -112,18 +117,16 @@ pub const Write = struct {
data: f32,
pub fn init(
allocator: std.mem.Allocator,
params: anytype,
allocator: *std.mem.Allocator,
params: *plugins.ParamMap,
) Write {
_ = allocator;
const data = params.get("data").?;
return Write{
.data = params.data,
.data = data.value,
};
}
pub fn deinit(self: *Write) void {
_ = self;
}
pub fn deinit(self: *Write) void {}
pub fn run(self: *Write, bufs: *RunBuffers) void {
bufs.out[0] = self.data;
@ -131,27 +134,27 @@ pub const Write = struct {
};
pub const Embed = struct {
allocator: std.mem.Allocator,
allocator: *std.mem.Allocator,
filepath: []const u8,
sndfile: *c.SNDFILE = undefined,
buf: []f32 = undefined,
pub fn init(allocator: std.mem.Allocator, params: anytype) @This() {
pub fn init(allocator: *std.mem.Allocator, filepath: []const u8) @This() {
return Embed{
.allocator = allocator,
.filepath = params.path,
.filepath = filepath,
};
}
pub fn setup(self: *@This()) !void {
var in_fmt = c.SF_INFO{
.frames = @as(c_int, 0),
.samplerate = @as(c_int, 0),
.channels = @as(c_int, 0),
.format = @as(c_int, 0),
.sections = @as(c_int, 0),
.seekable = @as(c_int, 0),
.frames = c_int(0),
.samplerate = c_int(0),
.channels = c_int(0),
.format = c_int(0),
.sections = c_int(0),
.seekable = c_int(0),
};
self.sndfile = try image.sopen(
@ -163,12 +166,10 @@ pub const Embed = struct {
image.sseek(self.sndfile, 0);
self.buf = try self.allocator.alloc(f32, @as(usize, @intCast(in_fmt.channels)));
self.buf = try self.allocator.alloc(f32, @intCast(usize, in_fmt.channels));
}
pub fn deinit(self: *@This()) void {
_ = self;
}
pub fn deinit(self: *@This()) void {}
pub fn run(self: *@This(), bufs: *RunBuffers) void {
const read_bytes = c.sf_readf_float(self.sndfile, self.buf.ptr, 1);
@ -180,10 +181,11 @@ pub const Embed = struct {
if (read_bytes < 0) {
const st: i32 = c.sf_error(self.sndfile);
log.debug("Failed to read {s} ({s})", .{
std.debug.warn(
"Failed to read {} ({})\n",
self.filepath,
c.sf_error_number(st),
});
);
return;
}

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@ -3,9 +3,11 @@ const lv2 = @import("lv2_helpers.zig");
const c = lv2.c;
const bmp = @import("bmp_valid.zig");
const log = std.log.scoped(.scritcher_image);
const plugins = @import("plugin.zig");
/// Approximate size of the BMP header, in bytes.
pub const BMPHeaderSize: usize = 82000;
/// Buffer size for main image copying.
pub const BufferSize: usize = 300000;
@ -21,34 +23,35 @@ pub const ImageError = error{
/// Low level integration function with libsndfile.
pub fn sopen(
allocator: std.mem.Allocator,
allocator: *std.mem.Allocator,
path: []const u8,
mode: i32,
fmt: *c.SF_INFO,
) !*c.SNDFILE {
const cstr_path = try allocator.dupeZ(u8, path);
var cstr_path = try std.cstr.addNullByte(allocator, path);
defer allocator.free(cstr_path);
const file = c.sf_open(cstr_path.ptr, mode, fmt);
var file = c.sf_open(cstr_path.ptr, mode, fmt);
const st: i32 = c.sf_error(file);
if (st != 0) {
log.debug("Failed to open {s} ({s})", .{
std.debug.warn(
"Failed to open {} ({})\n",
path,
c.sf_error_number(st),
});
);
return ImageError.OpenFail;
}
const frames_on_end = c.sf_seek(file, 0, c.SEEK_END);
_ = c.sf_seek(file, 0, c.SEEK_SET);
try std.testing.expectEqual(fmt.frames, frames_on_end);
std.testing.expectEqual(fmt.frames, frames_on_end);
const frames_on_end_by_end = c.sf_seek(file, frames_on_end, c.SEEK_SET);
try std.testing.expectEqual(frames_on_end, frames_on_end_by_end);
std.testing.expectEqual(frames_on_end, frames_on_end_by_end);
log.debug("frames on end: {}, frame on end (2): {}", .{ frames_on_end, frames_on_end_by_end });
std.debug.warn("frames on end: {}, frame on end (2): {}\n", frames_on_end, frames_on_end_by_end);
return file.?;
}
@ -57,54 +60,49 @@ pub fn swrite(file: *c.SNDFILE, buf: [*]f32, frames: i64) !void {
const count = c.sf_writef_float(file, buf, frames);
if (count != frames) {
log.debug("Wanted to write {}, got {}", .{ frames, count });
std.debug.warn("Wanted to write {}, got {}\n", frames, count);
return ImageError.WriteFail;
}
}
pub fn sseek(file: *c.SNDFILE, offset: usize) void {
const offset_i64 = @as(i64, @intCast(offset));
const offset_i64 = @intCast(i64, offset);
const frames = c.sf_seek(file, offset_i64, c.SEEK_SET);
const frames_current = c.sf_seek(file, 0, c.SEEK_CUR);
std.debug.assert(frames == frames_current);
std.testing.expectEqual(frames, frames_current);
if (frames != offset_i64) {
log.debug("failed to seek to {} (seeked {} frames, offset_i64={})", .{ offset, frames, offset_i64 });
std.debug.warn("failed to seek to {} (seeked {} frames, offset_i64={})\n", offset, frames, offset_i64);
}
}
/// Caller owns the returned memory.
pub fn temporaryName(allocator: std.mem.Allocator) ![]u8 {
pub fn temporaryName(allocator: *std.mem.Allocator) ![]u8 {
const template_start = "/temp/temp_";
const template = "/tmp/temp_XXXXXXXXXXXXXXXXXXXXX";
const template = "/tmp/temp_XXXXXXXXXXX";
var nam = try allocator.alloc(u8, template.len);
std.mem.copyForwards(u8, nam, template);
std.mem.copy(u8, nam, template);
const seed = @as(u64, @truncate(@as(u128, @bitCast(std.time.nanoTimestamp()))));
var r = std.rand.DefaultPrng.init(seed);
var r = std.rand.DefaultPrng.init(std.time.timestamp());
var fill = nam[template_start.len..nam.len];
var i: usize = 0;
while (i < 100) : (i += 1) {
// generate a random uppercase letter, that is, 65 + random number.
for (fill, 0..) |_, f_idx| {
const idx = @as(u8, @intCast(r.random().uintLessThan(u5, 24)));
const letter = @as(u8, 65) + idx;
for (fill) |_, f_idx| {
var idx = @intCast(u8, r.random.uintLessThan(u5, 24));
var letter = u8(65) + idx;
fill[f_idx] = letter;
}
// if we fail to access it, we assume it doesn't exist and return it.
var tmp_file: std.fs.File = std.fs.cwd().openFile(
nam,
.{ .mode = .read_only },
) catch |err| {
if (err == error.FileNotFound) return nam else continue;
std.fs.File.access(nam) catch |err| {
if (err == error.FileNotFound) {
return nam;
}
};
// if we actually found someone, close the handle so that we don't
// get EMFILE later on.
tmp_file.close();
}
return error.TempGenFail;
@ -112,17 +110,17 @@ pub fn temporaryName(allocator: std.mem.Allocator) ![]u8 {
pub fn mkSfInfo() c.SF_INFO {
return c.SF_INFO{
.frames = @as(c_int, 0),
.samplerate = @as(c_int, 44100),
.channels = @as(c_int, 1),
.frames = c_int(0),
.samplerate = c_int(44100),
.channels = c_int(1),
.format = c.SF_FORMAT_ULAW | c.SF_FORMAT_RAW | c.SF_ENDIAN_BIG,
.sections = @as(c_int, 0),
.seekable = @as(c_int, 0),
.sections = c_int(0),
.seekable = c_int(0),
};
}
pub const Image = struct {
allocator: std.mem.Allocator,
allocator: *std.mem.Allocator,
/// Pointer to the underlying libsndfile's SNDFILE struct.
sndfile: *c.SNDFILE,
@ -137,21 +135,21 @@ pub const Image = struct {
curpath: []const u8,
/// Open a BMP image for later.
pub fn open(allocator: std.mem.Allocator, path: []const u8) !*Image {
pub fn open(allocator: *std.mem.Allocator, path: []const u8) !*Image {
var in_fmt = mkSfInfo();
const sndfile = try sopen(allocator, path, c.SFM_READ, &in_fmt);
var sndfile = try sopen(allocator, path, c.SFM_READ, &in_fmt);
const image = try allocator.create(Image);
var image = try allocator.create(Image);
std.debug.assert(in_fmt.frames > @as(i64, 0));
std.debug.assert(in_fmt.seekable == @as(i32, 1));
std.debug.assert(in_fmt.frames > i64(0));
std.debug.assert(in_fmt.seekable == i32(1));
image.* = Image{
.allocator = allocator,
.sndfile = sndfile,
.path = path,
.curpath = path,
.frames = @as(usize, @intCast(in_fmt.frames)),
.frames = @intCast(usize, in_fmt.frames),
};
return image;
@ -160,50 +158,49 @@ pub const Image = struct {
pub fn clone(self: *Image) !*Image {
var in_fmt = mkSfInfo();
// clone sndfile
const sndfile = try sopen(self.allocator, self.curpath, c.SFM_READ, &in_fmt);
std.debug.assert(self.frames == @as(usize, @intCast(in_fmt.frames)));
var sndfile = try sopen(self.allocator, self.curpath, c.SFM_READ, &in_fmt);
std.testing.expectEqual(self.frames, @intCast(usize, in_fmt.frames));
const image = try self.allocator.create(Image);
var image = try self.allocator.create(Image);
std.debug.assert(in_fmt.frames > @as(i64, 0));
std.debug.assert(in_fmt.seekable == @as(i32, 1));
std.debug.assert(in_fmt.frames > i64(0));
std.debug.assert(in_fmt.seekable == i32(1));
image.* = Image{
.allocator = self.allocator,
.sndfile = sndfile,
.path = self.path,
.curpath = self.curpath,
.frames = @as(usize, @intCast(in_fmt.frames)),
.frames = @intCast(usize, in_fmt.frames),
};
return image;
}
pub fn close(self: *Image) void {
const st: i32 = c.sf_close(self.sndfile);
//self.allocator.free(self.path);
//self.allocator.free(self.curpath);
var st: i32 = c.sf_close(self.sndfile);
if (st != 0) {
log.debug("Failed to close {s} ({s})", .{
std.debug.warn(
"Failed to close {} ({})\n",
self.path,
c.sf_error_number(st),
});
);
}
self.allocator.free(self.path);
self.allocator.free(self.curpath);
var allocator = self.allocator;
self.* = undefined;
allocator.destroy(self);
}
pub fn read(self: *Image, file_chans: c_int, buf: []f32) bool {
const n_read: c.sf_count_t = c.sf_readf_float(self.sndfile, buf.ptr, 1);
const buf_chans = @as(c_int, @intCast(buf.len));
var file = file_opt.?;
const n_read: c.sf_count_t = c.sf_readf_float(file, buf.ptr, 1);
const buf_chans = @intCast(c_int, buf.len);
var i = file_chans - 1;
while (i < buf_chans) : (i += 1) {
//buf[@intCast(usize, i)] = buf[i % file_chans];
buf[@as(usize, @intCast(i))] = buf[@as(usize, @intCast(@mod(i, file_chans)))];
buf[@intCast(usize, i)] = buf[@intCast(usize, @mod(i, file_chans))];
}
return n_read == 1;
@ -227,7 +224,7 @@ pub const Image = struct {
sseek(out_file, start);
while (i <= end) : (i += buf.len) {
log.debug("\t\ti={d}, buf.len={d}, end={d}", .{ i, buf.len, end });
std.debug.warn("\t\ti={}, buf.len={}, end={}\n", i, buf.len, end);
sseek(self.sndfile, i);
sseek(out_file, i);
@ -237,13 +234,13 @@ pub const Image = struct {
var view: []f32 = buf[0..buf.len];
if (bytes_until_end < buf.len) {
read_bytes = c.sf_readf_float(self.sndfile, buf.ptr, @as(i64, @intCast(bytes_until_end)));
read_bytes = c.sf_readf_float(self.sndfile, buf.ptr, @intCast(i64, bytes_until_end));
view = buf[0..bytes_until_end];
} else {
read_bytes = c.sf_readf_float(self.sndfile, buf.ptr, @as(i64, @intCast(buf.len)));
read_bytes = c.sf_readf_float(self.sndfile, buf.ptr, @intCast(i64, buf.len));
}
try swrite(out_file, view.ptr, @as(i64, @intCast(view.len)));
try swrite(out_file, view.ptr, @intCast(i64, view.len));
}
sseek(self.sndfile, end);
@ -252,8 +249,8 @@ pub const Image = struct {
fn getSeekPos(self: *Image, position: plugins.Position) plugins.SeekPos {
const file_end = self.frames;
const seek_pos = position.seekPos(file_end);
log.debug("\tstart {d} end {d}", .{ seek_pos.start, seek_pos.end });
var seek_pos = position.seekPos(file_end);
std.debug.warn("\tstart {} end {}\n", seek_pos.start, seek_pos.end);
return seek_pos;
}
@ -261,20 +258,21 @@ pub const Image = struct {
var in_fmt = mkSfInfo();
self.sndfile = try sopen(self.allocator, path, c.SFM_READ, &in_fmt);
// std.testing.expectEqual(self.frames, @intCast(usize, in_fmt.frames));
std.testing.expectEqual(self.frames, @intCast(usize, in_fmt.frames));
self.curpath = path;
self.frames = @as(usize, @intCast(in_fmt.frames));
self.frames = @intCast(usize, in_fmt.frames);
log.debug("\timage: reopened on '{s}' (frames={d}, fmt.frames={d})", .{
std.debug.warn(
"\timage: reopened on '{}' (frames={}, fmt.frames={})\n",
self.curpath,
self.frames,
in_fmt.frames,
});
);
}
pub fn checkValid(self: *Image) !void {
var file = try std.fs.cwd().openFile(self.path, .{ .mode = .read_only });
var file = try std.fs.File.openRead(self.path);
defer file.close();
// main bmp header:
@ -286,7 +284,6 @@ pub const Image = struct {
var magic = [2]u8{ 0, 0 };
_ = try file.read(&magic);
if (std.mem.endsWith(u8, self.path, ".bmp"))
try bmp.magicValid(&magic);
}
@ -306,48 +303,50 @@ pub const Image = struct {
defer ctx.deinit();
var ports = try lv2.setupPorts(&ctx);
defer ctx.allocator.free(ports);
if (ctx.n_audio_in > 2) {
log.debug("plugin <{s}> has more than two inputs.", .{plugin_uri});
std.debug.warn("plugin <{}> has more than two inputs.\n", plugin_uri);
return ImageError.InvalidPlugin;
}
if (ctx.n_audio_out > 2) {
log.debug("plugin <{s}> has more than two outputs.", .{plugin_uri});
std.debug.warn("plugin <{}> has more than two outputs.\n", plugin_uri);
return ImageError.InvalidPlugin;
}
// now, for each param for the plugin, we find its port, and set
// the value for the port there.
for (params.items) |param| {
const sym_cstr = try self.allocator.dupeZ(u8, param.sym);
var it = params.iterator();
while (it.next()) |param| {
var sym_cstr = try std.cstr.addNullByte(self.allocator, param.sym);
defer self.allocator.free(sym_cstr);
const sym = c.lilv_new_string(ctx.world, sym_cstr.ptr);
const port = c.lilv_plugin_get_port_by_symbol(ctx.plugin, sym) orelse {
log.debug("assert fail: symbol {s} not found on port", .{param.sym});
var sym = c.lilv_new_string(ctx.world, sym_cstr.ptr);
const port = c.lilv_plugin_get_port_by_symbol(ctx.plugin, sym) orelse blk: {
std.debug.warn("assert fail: symbol {} not found on port\n", param.sym);
return ImageError.InvalidSymbol;
};
c.lilv_node_free(sym);
const idx = c.lilv_port_get_index(ctx.plugin, port);
log.debug("\tset sym={s}, idx={d} to val={}", .{
var idx = c.lilv_port_get_index(ctx.plugin, port);
std.debug.warn(
"\tset sym={}, idx={} to val={}\n",
param.sym,
idx,
param.value,
});
);
(&ports[idx]).value = param.value;
}
// now we need to generate a temporary file and put the output of
// running the plugin on that file
const tmpnam = try temporaryName(self.allocator);
log.debug("\trunning plugin from '{s}' to '{s}'", .{ self.curpath, tmpnam });
var tmpnam = try temporaryName(self.allocator);
std.debug.warn("\trunning plugin from '{}' to '{}'\n", self.curpath, tmpnam);
var out_fmt = mkSfInfo();
const out_file = try sopen(self.allocator, tmpnam, c.SFM_WRITE, &out_fmt);
var out_file = try sopen(self.allocator, tmpnam, c.SFM_WRITE, &out_fmt);
var rctx = try plugins.RunContext.init(self.allocator, ctx.plugin);
defer rctx.deinit();
@ -370,34 +369,27 @@ pub const Image = struct {
// pre-plugin copy, merged with bmp header copy
try self.copyBytes(
out_file,
@as(usize, 0),
usize(0),
seek_pos.start,
);
sseek(self.sndfile, seek_pos.start);
var i: usize = seek_pos.start;
log.debug("\tseek pos start: {d} end: {d}", .{ seek_pos.start, seek_pos.end });
std.debug.warn("\tseek pos start: {} end: {}\n", seek_pos.start, seek_pos.end);
var inbuf = &rctx.buffers.in;
const outbuf = &rctx.buffers.out;
var inbuf = rctx.buffers.in;
var outbuf = rctx.buffers.out;
while (i <= seek_pos.end) : (i += 1) {
inbuf[0] = 0;
inbuf[1] = 0;
const read_bytes = c.sf_readf_float(self.sndfile, inbuf, 1);
const read_bytes = c.sf_readf_float(self.sndfile, inbuf.ptr, 1);
if (read_bytes == 0) {
log.debug("WARN! reached EOF at idx={d}", .{i});
std.debug.warn("WARN! reached EOF at idx={}\n", i);
break;
}
// trick plugins into having correct stereo signal from
// my mono input
inbuf[1] = inbuf[0];
lv2.lilv_instance_run(rctx.instance, 1);
try swrite(out_file, outbuf, 1);
try swrite(out_file, outbuf.ptr, 1);
}
sseek(self.sndfile, seek_pos.end);
@ -416,22 +408,23 @@ pub const Image = struct {
try self.reopen(tmpnam);
try self.checkValid();
const time_taken = timer.read();
log.debug("\ttook {d:.2}ms running plugin", .{time_taken / std.time.us_per_ms});
var time_taken = timer.read();
std.debug.warn("\ttook {d:.2}ms running plugin\n", time_taken / std.time.millisecond);
}
pub fn saveTo(self: *Image, out_path: []const u8) !void {
log.debug("\timg: copy from '{s}' to '{s}'", .{ self.curpath, out_path });
try std.fs.copyFileAbsolute(self.curpath, out_path, .{});
std.debug.warn("\timg: copy from '{}' to '{}'\n", self.curpath, out_path);
try std.fs.copyFile(self.curpath, out_path);
}
pub fn runCustomPlugin(
self: *Image,
comptime Plugin: type,
position: plugins.Position,
extra: anytype,
comptime ExtraType: type,
extra: ExtraType,
) !void {
const plugin_opt: ?Plugin = Plugin.init(self.allocator, extra);
var plugin_opt: ?Plugin = Plugin.init(self.allocator, extra);
if (plugin_opt == null) {
return ImageError.PluginLoadFail;
}
@ -448,13 +441,15 @@ pub const Image = struct {
// the code here is a copypaste of runPlugin() without the specific
// lilv things.
const tmpnam = try temporaryName(self.allocator);
log.debug("\trunning CUSTOM plugin from '{s}' to '{s}'", .{ self.curpath, tmpnam });
var tmpnam = try temporaryName(self.allocator);
std.debug.warn("\trunning CUSTOM plugin from '{}' to '{}'\n", self.curpath, tmpnam);
var out_fmt = mkSfInfo();
const out_file = try sopen(self.allocator, tmpnam, c.SFM_WRITE, &out_fmt);
var out_file = try sopen(self.allocator, tmpnam, c.SFM_WRITE, &out_fmt);
var bufs = try plugins.RunBuffers.init(self.allocator);
defer bufs.deinit();
var bufs = plugins.RunBuffers{};
const seek_pos = self.getSeekPos(position);
// make sure we start from 0
@ -469,27 +464,27 @@ pub const Image = struct {
// pre-plugin copy, merged with bmp header copy
try self.copyBytes(
out_file,
@as(usize, 0),
usize(0),
seek_pos.start,
);
sseek(self.sndfile, seek_pos.start);
var i: usize = seek_pos.start;
log.debug("\tseek pos start: {d} end: {d}", .{ seek_pos.start, seek_pos.end });
std.debug.warn("\tseek pos start: {} end: {}\n", seek_pos.start, seek_pos.end);
const inbuf = &bufs.in;
const outbuf = &bufs.out;
var inbuf = bufs.in;
var outbuf = bufs.out;
while (i <= seek_pos.end) : (i += 1) {
const read_bytes = c.sf_readf_float(self.sndfile, inbuf, 1);
const read_bytes = c.sf_readf_float(self.sndfile, bufs.in.ptr, 1);
if (read_bytes == 0) {
log.debug("WARN! reached EOF at idx={d}", .{i});
std.debug.warn("WARN! reached EOF at idx={}\n", i);
break;
}
plugin.run(&bufs);
try swrite(out_file, outbuf, 1);
try swrite(out_file, bufs.out.ptr, 1);
}
sseek(self.sndfile, seek_pos.end);

File diff suppressed because it is too large Load diff

View file

@ -1,12 +1,10 @@
const std = @import("std");
const plugin = @import("plugin.zig");
const log = std.log.scoped(.scritcher_lv2);
pub const c = @cImport({
@cInclude("sndfile.h");
@cInclude("lilv/lilv.h");
@cInclude("lv2.h");
@cInclude("lv2/core/lv2.h");
});
pub fn Lv2Core(comptime ns: []const u8) []const u8 {
@ -23,7 +21,7 @@ const LV2_CORE__connectionOptional = Lv2Core("#connectionOptional");
pub fn lilv_instance_connect_port(
instance: [*c]c.LilvInstance,
port_index: u32,
data_location: ?*anyopaque,
data_location: ?*c_void,
) void {
instance.?.*.lv2_descriptor.?.*.connect_port.?(instance.?.*.lv2_handle, port_index, data_location);
}
@ -61,44 +59,42 @@ pub const Port = struct {
/// Setup ports for a given plugin. Gives an array to pointers of Port structs.
/// This setup is required so we link the plugin to the ports later on, and
/// also link our buffers, and control values.
///
/// Caller owns returned memory.
pub fn setupPorts(ctx: *plugin.Context) ![]Port {
const world = ctx.world;
var world = ctx.world;
const n_ports: u32 = c.lilv_plugin_get_num_ports(ctx.plugin);
var ports = try ctx.allocator.alloc(Port, n_ports);
for (ports, 0..) |_, idx| {
const port: *Port = &ports[idx];
for (ports) |_, idx| {
var port: *Port = &ports[idx];
port.* = Port{
.lilv_port = null,
.ptype = .Control,
.index = @as(f32, 0),
.value = @as(f32, 0),
.index = f32(0),
.value = f32(0),
.is_input = false,
.optional = false,
};
}
const values: []f32 = try ctx.allocator.alloc(f32, n_ports);
var values: []f32 = try ctx.allocator.alloc(f32, n_ports);
defer ctx.allocator.free(values);
c.lilv_plugin_get_port_ranges_float(ctx.plugin, null, null, values.ptr);
const lv2_InputPort = c.lilv_new_uri(world, LV2_CORE__InputPort.ptr).?;
//defer std.heap.c_allocator.destroy(lv2_InputPort);
var lv2_InputPort = c.lilv_new_uri(world, LV2_CORE__InputPort.ptr);
defer std.heap.c_allocator.destroy(lv2_InputPort);
const lv2_OutputPort = c.lilv_new_uri(world, LV2_CORE__OutputPort.ptr).?;
//defer std.heap.c_allocator.destroy(lv2_OutputPort);
var lv2_OutputPort = c.lilv_new_uri(world, LV2_CORE__OutputPort.ptr);
defer std.heap.c_allocator.destroy(lv2_OutputPort);
const lv2_AudioPort = c.lilv_new_uri(world, LV2_CORE__AudioPort.ptr).?;
//defer std.heap.c_allocator.destroy(lv2_AudioPort);
var lv2_AudioPort = c.lilv_new_uri(world, LV2_CORE__AudioPort.ptr);
defer std.heap.c_allocator.destroy(lv2_AudioPort);
const lv2_ControlPort = c.lilv_new_uri(world, LV2_CORE__ControlPort.ptr).?;
//defer std.heap.c_allocator.destroy(lv2_ControlPort);
var lv2_ControlPort = c.lilv_new_uri(world, LV2_CORE__ControlPort.ptr);
defer std.heap.c_allocator.destroy(lv2_ControlPort);
const lv2_connection_string = c.lilv_new_uri(world, LV2_CORE__connectionOptional.ptr).?;
//defer std.heap.c_allocator.destroy(lv2_connection_string);
var lv2_connectionOptional = c.lilv_new_uri(world, LV2_CORE__connectionOptional.ptr);
defer std.heap.c_allocator.destroy(lv2_connectionOptional);
var i: u32 = 0;
while (i < n_ports) : (i += 1) {
@ -110,17 +106,17 @@ pub fn setupPorts(ctx: *plugin.Context) ![]Port {
port.index = i;
if (std.math.isNan(values[i])) {
port.value = @as(f32, 0);
port.value = f32(0);
} else {
port.value = values[i];
}
port.optional = c.lilv_port_has_property(ctx.plugin, lport, lv2_connection_string);
port.optional = c.lilv_port_has_property(ctx.plugin, lport, lv2_connectionOptional);
if (c.lilv_port_is_a(ctx.plugin, lport, lv2_InputPort)) {
port.is_input = true;
} else if (!c.lilv_port_is_a(ctx.plugin, lport, lv2_OutputPort) and !port.optional) {
log.debug("Port {d} is neither input or output", .{i});
std.debug.warn("Port {} is neither input or output\n", i);
return error.UnassignedIOPort;
}
@ -136,7 +132,7 @@ pub fn setupPorts(ctx: *plugin.Context) ![]Port {
ctx.n_audio_out += 1;
}
} else if (!port.optional) {
log.debug("Port {d} has unsupported type", .{i});
std.debug.warn("Port {} has unsupported type\n", i);
return error.UnsupportedPortType;
}
}

View file

@ -2,12 +2,9 @@
const std = @import("std");
const images = @import("image.zig");
const log = std.log.scoped(.scritcher_magick);
const Image = images.Image;
const mc = @cImport({
@cInclude("wand/magick_wand.h");
});
const mc = @import("magick_wand.zig");
pub const MagickContext = struct {
wand: *mc.MagickWand,
@ -15,7 +12,7 @@ pub const MagickContext = struct {
pub fn init() !MagickContext {
mc.InitializeMagick(null);
const wand = mc.NewMagickWand();
var wand = mc.NewMagickWand();
if (wand == null) return error.WandCreateFail;
return MagickContext{
@ -29,7 +26,6 @@ pub const MagickContext = struct {
}
pub fn doErr(self: *MagickContext) !void {
_ = self;
return error.WandError;
}
};
@ -38,10 +34,10 @@ fn magickLoad(image: *Image) !MagickContext {
var mctx = try MagickContext.init();
errdefer mctx.deinit();
const curpath = try image.allocator.dupeZ(u8, image.curpath);
var curpath = try std.cstr.addNullByte(image.allocator, image.curpath);
defer image.allocator.free(curpath);
log.debug("loading '{s}'", .{curpath});
std.debug.warn("loading '{}'\n", curpath);
if (mc.MagickReadImage(mctx.wand, curpath.ptr) != 1)
return error.MagickReadFail;
@ -52,16 +48,16 @@ fn magickLoad(image: *Image) !MagickContext {
fn magickSave(image: *Image, wand: *mc.MagickWand) !void {
const allocator = image.allocator;
const tmpnam = try images.temporaryName(allocator);
const c_tmpnam = try allocator.dupeZ(u8, tmpnam);
var tmpnam = try images.temporaryName(allocator);
var c_tmpnam = try std.cstr.addNullByte(allocator, tmpnam);
defer allocator.free(c_tmpnam);
log.debug("\tmagick: saving to '{s}'..", .{c_tmpnam});
std.debug.warn("\tmagick: saving to '{}'..", c_tmpnam);
if (mc.MagickWriteImage(wand, c_tmpnam.ptr) != 1)
return error.MagickWriteFail;
log.debug("OK", .{});
std.debug.warn("OK\n");
try image.reopen(tmpnam);
}
@ -72,7 +68,7 @@ pub fn runRotate(image: *Image, deg: f32, bgfill: []const u8) !void {
var mctx = try magickLoad(image);
defer mctx.deinit();
const bg = mc.NewPixelWand();
var bg = mc.NewPixelWand();
defer mc.DestroyPixelWand(bg);
if (mc.PixelSetColor(bg, bgfill.ptr) != 1)

4124
src/magick_wand.zig Normal file

File diff suppressed because it is too large Load diff

View file

@ -3,8 +3,6 @@ const langs = @import("lang.zig");
const runners = @import("runner.zig");
const printer = @import("printer.zig");
const log = std.log.scoped(.scritcher);
test "scritcher" {
_ = @import("lang.zig");
_ = @import("runner.zig");
@ -18,32 +16,18 @@ const readline = @cImport({
@cInclude("readline/history.h");
});
fn wrapInCmdList(allocator: std.mem.Allocator, cmd: *langs.Command) !langs.CommandList {
fn wrapInCmdList(allocator: *std.mem.Allocator, cmd: langs.Command) !langs.CommandList {
var cmds = langs.CommandList.init(allocator);
try cmds.append(cmd);
return cmds;
}
fn copyCommandToHeap(allocator: std.mem.Allocator, command: langs.Command, comptime tag: langs.Command.Tag) !*langs.Command {
const CommandStruct = langs.Command.tagToType(tag);
const casted = command.cast(CommandStruct).?;
var heap_cmd = try allocator.create(CommandStruct);
pub fn doRepl(allocator: *std.mem.Allocator, args_it: var) !void {
var stdout_file = try std.io.getStdOut();
const stdout = &stdout_file.outStream().stream;
const scri_path = try (args_it.next(allocator) orelse @panic("expected scri path"));
heap_cmd.* = casted.*;
log.debug("casted: {}", .{casted});
log.debug("heap_cmd: {}", .{heap_cmd});
return &heap_cmd.base;
}
pub fn doRepl(allocator: std.mem.Allocator, args_it: anytype) !void {
var stdout_file = std.io.getStdOut();
const stdout = &stdout_file.writer();
const scri_path = (args_it.next() orelse @panic("expected scri path"));
errdefer allocator.free(scri_path);
defer allocator.free(scri_path);
var file_read_opt: ?std.fs.File = std.fs.cwd().openFile(scri_path, .{}) catch |err| blk: {
var file_read_opt: ?std.fs.File = std.fs.File.openRead(scri_path) catch |err| blk: {
if (err == error.FileNotFound) break :blk null;
return err;
};
@ -56,47 +40,42 @@ pub fn doRepl(allocator: std.mem.Allocator, args_it: anytype) !void {
defer lang.deinit();
if (total_bytes > 0) {
const scri_existing = try allocator.alloc(u8, total_bytes);
// this MUST BE long lived (a reference to it is kept inside
// existing_cmds, and then passed along to cmds),
// we can't defer them here
var scri_existing = try allocator.alloc(u8, total_bytes);
_ = try file_read_opt.?.read(scri_existing);
defer allocator.free(scri_existing);
// we can't defer this directly because we copy the
// Command pointers to the cmds list. running deinit() directly
// would cause those pointers to be freed.
// we can defer this because we copy the Command structs back to cmds
var existing_cmds = try lang.parse(scri_existing);
defer existing_cmds.list.deinit();
defer existing_cmds.deinit();
// copy the existing command list into the repl's command list
for (existing_cmds.list.items) |existing_cmd| {
var it = existing_cmds.iterator();
while (it.next()) |existing_cmd| {
try cmds.append(existing_cmd);
}
} else {
// if there isn't any commands on the file, we load our default
// 'load :0' command
var loadargs = langs.ArgList.init(allocator);
try loadargs.append(":0");
// TODO: deliberate memleak here. we only allocate this
// command once, for the start of the file, so.
var load_cmd = try allocator.create(langs.Command.Load);
load_cmd.path = ":0";
load_cmd.base.tag = langs.Command.Tag.load;
// taking address is fine, because load_cmd lives in the lifetime
// of the allocator.
try cmds.append(&load_cmd.base);
try cmds.append(langs.Command{
.command = .Load,
.args = loadargs,
});
}
if (file_read_opt) |file_read| {
file_read.close();
}
var file = try std.fs.cwd().createFile(scri_path, .{
.read = false,
.truncate = true,
});
var file = try std.fs.File.openWrite(scri_path);
defer file.close();
var out = file.writer();
const stream = &out;
var out = file.outStream();
var stream = &out.stream;
// since we opened the file for writing, it becomes empty, so, to ensure
// we don't fuck up later on, we print cmds before starting the repl
@ -120,72 +99,31 @@ pub fn doRepl(allocator: std.mem.Allocator, args_it: anytype) !void {
// run the load command
try runner.runCommands(cmds, true);
const wanted_runner: []const u8 = std.posix.getenv("SCRITCHER_RUNNER") orelse "ristretto";
var runqs_args = langs.ArgList.init(allocator);
defer runqs_args.deinit();
var runqs_cmd = langs.Command.RunQS{
.base = langs.Command{ .tag = langs.Command.Tag.runqs },
.program = wanted_runner,
};
// TODO change the runqs command to something given in an env var
try runqs_args.append("ristretto");
while (true) {
lang.reset();
var rd_line = readline.readline("> ");
var rd_line = readline.readline(c"> ");
if (rd_line == null) {
log.debug("leaving from eof", .{});
std.debug.warn("leaving from eof\n");
break;
}
readline.add_history(rd_line);
//defer std.heap.c_allocator.destroy(rd_line);
const line = rd_line[0..std.mem.len(rd_line)];
var line = rd_line[0..std.mem.len(u8, rd_line)];
if (std.mem.eql(u8, line, "push")) {
const heap_cmd = switch (current.tag) {
.noop => try copyCommandToHeap(allocator, current, .noop),
.load => try copyCommandToHeap(allocator, current, .load),
.quicksave => try copyCommandToHeap(allocator, current, .quicksave),
.runqs => try copyCommandToHeap(allocator, current, .runqs),
.amp => try copyCommandToHeap(allocator, current, .amp),
.rflanger => try copyCommandToHeap(allocator, current, .rflanger),
.eq => try copyCommandToHeap(allocator, current, .eq),
.phaser => try copyCommandToHeap(allocator, current, .phaser),
.mbeq => try copyCommandToHeap(allocator, current, .mbeq),
.chorus => try copyCommandToHeap(allocator, current, .chorus),
.pitchscaler => try copyCommandToHeap(allocator, current, .pitchscaler),
.reverb => try copyCommandToHeap(allocator, current, .reverb),
.highpass => try copyCommandToHeap(allocator, current, .highpass),
.delay => try copyCommandToHeap(allocator, current, .delay),
.vinyl => try copyCommandToHeap(allocator, current, .vinyl),
.revdelay => try copyCommandToHeap(allocator, current, .revdelay),
.gate => try copyCommandToHeap(allocator, current, .gate),
.detune => try copyCommandToHeap(allocator, current, .detune),
.overdrive => try copyCommandToHeap(allocator, current, .overdrive),
.degrade => try copyCommandToHeap(allocator, current, .degrade),
.repsycho => try copyCommandToHeap(allocator, current, .repsycho),
.talkbox => try copyCommandToHeap(allocator, current, .talkbox),
.dyncomp => try copyCommandToHeap(allocator, current, .dyncomp),
.thruzero => try copyCommandToHeap(allocator, current, .thruzero),
.foverdrive => try copyCommandToHeap(allocator, current, .foverdrive),
.gverb => try copyCommandToHeap(allocator, current, .gverb),
.invert => try copyCommandToHeap(allocator, current, .invert),
.tapedelay => try copyCommandToHeap(allocator, current, .tapedelay),
.moddelay => try copyCommandToHeap(allocator, current, .moddelay),
.multichorus => try copyCommandToHeap(allocator, current, .multichorus),
.saturator => try copyCommandToHeap(allocator, current, .saturator),
.vintagedelay => try copyCommandToHeap(allocator, current, .vintagedelay),
.noise => try copyCommandToHeap(allocator, current, .noise),
.wildnoise => try copyCommandToHeap(allocator, current, .wildnoise),
.write => try copyCommandToHeap(allocator, current, .write),
.embed => try copyCommandToHeap(allocator, current, .embed),
.rotate => try copyCommandToHeap(allocator, current, .rotate),
};
try cmds.append(heap_cmd);
try cmds.append(current);
// run the current added command to main cmds list
// with the main parent runner
var cmds_wrapped = try wrapInCmdList(allocator, heap_cmd);
var cmds_wrapped = try wrapInCmdList(allocator, current);
defer cmds_wrapped.deinit();
try runner.runCommands(cmds_wrapped, true);
@ -200,20 +138,17 @@ pub fn doRepl(allocator: std.mem.Allocator, args_it: anytype) !void {
try printer.printList(cmds, stream);
continue;
} else if (std.mem.eql(u8, line, "quit") or std.mem.eql(u8, line, "q")) {
log.debug("leaving", .{});
std.debug.warn("leaving\n");
break;
} else if (std.mem.startsWith(u8, line, "#")) {
continue;
}
var cmds_parsed = lang.parse(line) catch |err| {
log.debug("repl: error while parsing: {}", .{err});
std.debug.warn("repl: error while parsing: {}\n", err);
continue;
};
// no command? ignore!
if (cmds_parsed.list.items.len == 0) continue;
current = cmds_parsed.list.items[0].*;
current = cmds_parsed.at(0);
// by cloning the parent runner, we can iteratively write
// whatever command we want and only commit the good results
@ -221,38 +156,43 @@ pub fn doRepl(allocator: std.mem.Allocator, args_it: anytype) !void {
var runner_clone = try runner.clone();
defer runner_clone.deinit();
// taking address is fine, because runqs_cmd lives in the lifetime
// of this function.
try cmds_parsed.append(&runqs_cmd.base);
try cmds_parsed.append(langs.Command{
.command = .RunQS,
.args = runqs_args,
});
try runner_clone.runCommands(cmds_parsed, true);
_ = try stdout.write("\n");
try stdout.write("\n");
}
}
fn doHelp() void {
log.debug("scritcher!", .{});
log.debug("usage: scritcher [run|help|repl]", .{});
log.debug("\tscritcher run path_to_script.scri path_to_input_file.bmp", .{});
log.debug("\tscritcher repl path_to_script.scri path_to_input_file.bmp", .{});
}
pub fn main() !void {
const allocator = std.heap.direct_allocator;
fn doRun(allocator: std.mem.Allocator, args_it: anytype) !void {
var lang = langs.Lang.init(allocator);
defer lang.deinit();
var runner = runners.Runner.init(allocator, false);
defer runner.deinit();
const scri_path = (args_it.next() orelse @panic("run: expected scri path"));
var args_it = std.process.args();
var file = try std.fs.cwd().openFile(scri_path, .{});
// TODO print help
_ = try (args_it.next(allocator) orelse @panic("expected exe name"));
const scri_path = try (args_it.next(allocator) orelse @panic("expected scri path"));
if (std.mem.eql(u8, scri_path, "repl")) {
return try doRepl(allocator, &args_it);
}
var file = try std.fs.File.openRead(scri_path);
defer file.close();
// sadly, we read it all into memory. such is life
const total_bytes = try file.getEndPos();
const data = try allocator.alloc(u8, total_bytes);
var data = try allocator.alloc(u8, total_bytes);
defer allocator.free(data);
_ = try file.read(data);
@ -261,33 +201,3 @@ fn doRun(allocator: std.mem.Allocator, args_it: anytype) !void {
try runner.runCommands(cmds, true);
}
pub fn main() !void {
var allocator_instance = std.heap.GeneralPurposeAllocator(.{}){};
defer {
_ = allocator_instance.deinit();
}
const allocator = allocator_instance.allocator();
var args_it = try std.process.argsWithAllocator(allocator);
defer args_it.deinit();
_ = args_it.skip();
const cli_command_opt = args_it.next();
if (cli_command_opt == null) {
return doHelp();
}
const cli_command = cli_command_opt.?;
if (std.mem.eql(u8, cli_command, "help")) {
return doHelp();
} else if (std.mem.eql(u8, cli_command, "repl")) {
return try doRepl(allocator, &args_it);
} else if (std.mem.eql(u8, cli_command, "run")) {
return try doRun(allocator, &args_it);
} else {
log.debug("unknown command: '{s}'", .{cli_command});
return error.UnknownCommand;
}
}

View file

@ -3,7 +3,6 @@ const std = @import("std");
const lv2 = @import("lv2_helpers.zig");
const c = lv2.c;
const log = std.log.scoped(.scritcher_plugin);
const ImageError = @import("image.zig").ImageError;
/// Control port
@ -36,7 +35,7 @@ pub const Position = struct {
pub fn seekPos(self: Position, total_size: usize) SeekPos {
std.debug.assert(self.index <= self.split);
const tot = total_size / self.split;
var tot = total_size / self.split;
return SeekPos{
.start = self.index * tot,
@ -47,7 +46,7 @@ pub const Position = struct {
/// Represents the starting context for a single plugin run.
pub const Context = struct {
allocator: std.mem.Allocator,
allocator: *std.mem.Allocator,
world: *c.LilvWorld,
plugin: *const c.LilvPlugin,
@ -62,11 +61,29 @@ pub const Context = struct {
/// Specific run context for non-plugins.
pub const RunBuffers = struct {
// we use [2]f32 to account for stereo plugins, however
// we only use in_buf[0] and out_buf[0], and don't use the
allocator: *std.mem.Allocator,
in: []f32,
out: []f32,
pub fn init(allocator: *std.mem.Allocator) !RunBuffers {
// we allocate []f32 with size 2 to account for stereo plugins, however
// we only use &in_buf[0] and &out_buf[0], and don't use the
// (supposedly) right side of neither input or output.
in: [2]f32 = [_]f32{0} ** 2,
out: [2]f32 = [_]f32{0} ** 2,
var in_buf = try allocator.alloc(f32, 2);
std.mem.secureZero(f32, in_buf);
return RunBuffers{
.allocator = allocator,
.in = in_buf,
.out = try allocator.alloc(f32, 2),
};
}
pub fn deinit(self: *RunBuffers) void {
self.allocator.free(self.in);
self.allocator.free(self.out);
}
};
/// Represents the specific run context of plugin instantation.
@ -75,12 +92,10 @@ pub const RunContext = struct {
instance: *c.LilvInstance,
pub fn init(
allocator: std.mem.Allocator,
allocator: *std.mem.Allocator,
plugin: *const c.LilvPlugin,
) !RunContext {
_ = allocator; // TODO batch RunBuffers?
const instance = c.lilv_plugin_instantiate(plugin, @as(f64, 44100), null);
var instance = c.lilv_plugin_instantiate(plugin, f64(44100), null);
errdefer c.lilv_instance_free(instance);
if (instance == null) {
@ -88,67 +103,63 @@ pub const RunContext = struct {
}
return RunContext{
.buffers = RunBuffers{},
.buffers = try RunBuffers.init(allocator),
.instance = instance.?,
};
}
pub fn deinit(self: *RunContext) void {
c.lilv_instance_free(self.instance);
self.buffers.deinit();
}
pub fn connectPorts(self: *RunContext, ports: []lv2.Port) void {
var i: usize = 0;
var o: usize = 0;
for (ports, 0..) |_, p_idx| {
const p = @as(u32, @intCast(p_idx));
var in_buf = self.buffers.in;
var out_buf = self.buffers.out;
for (ports) |_, p_idx| {
var p = @intCast(u32, p_idx);
var port: *lv2.Port = &ports[p_idx];
switch (port.ptype) {
.Control => lv2.lilv_instance_connect_port(self.instance, p, &port.value),
.Audio => {
.Audio => blk: {
if (port.is_input) {
lv2.lilv_instance_connect_port(
self.instance,
p,
&self.buffers.in[i],
);
lv2.lilv_instance_connect_port(self.instance, p, &in_buf[i]);
i += 1;
} else {
lv2.lilv_instance_connect_port(
self.instance,
p,
&self.buffers.out[o],
);
lv2.lilv_instance_connect_port(self.instance, p, &out_buf[o]);
o += 1;
}
},
// else => lv2.lilv_instance_connect_port(self.instance, p, null),
else => lv2.lilv_instance_connect_port(self.instance, p, null),
}
}
}
};
pub fn makeContext(allocator: std.mem.Allocator, plugin_uri: []const u8) !Context {
const cstr_plugin_uri = try allocator.dupeZ(u8, plugin_uri);
pub fn makeContext(allocator: *std.mem.Allocator, plugin_uri: []const u8) !Context {
const cstr_plugin_uri = try std.cstr.addNullByte(allocator, plugin_uri);
defer allocator.free(cstr_plugin_uri);
const world: *c.LilvWorld = c.lilv_world_new().?;
var world: *c.LilvWorld = c.lilv_world_new().?;
errdefer c.lilv_world_free(world);
c.lilv_world_load_all(world);
const uri: *c.LilvNode = c.lilv_new_uri(world, cstr_plugin_uri.ptr) orelse {
log.debug("Invalid plugin URI <{s}>", .{plugin_uri});
var uri: *c.LilvNode = c.lilv_new_uri(world, cstr_plugin_uri.ptr) orelse blk: {
std.debug.warn("Invalid plugin URI <{}>\n", plugin_uri);
return ImageError.InvalidPlugin;
};
defer c.lilv_node_free(uri);
const plugins: *const c.LilvPlugins = c.lilv_world_get_all_plugins(world).?;
const plugins: *const c.LilvPlugins = c.lilv_world_get_all_plugins(world);
const plugin: *const c.LilvPlugin = c.lilv_plugins_get_by_uri(plugins, uri) orelse {
log.debug("Plugin <{s}> not found", .{plugin_uri});
var plugin: *const c.LilvPlugin = c.lilv_plugins_get_by_uri(plugins, uri) orelse blk: {
std.debug.warn("Plugin <{}> not found\n", plugin_uri);
return ImageError.UnknownPlugin;
};

View file

@ -1,88 +1,40 @@
const std = @import("std");
const langs = @import("lang.zig");
const log = std.log.scoped(.scritcher_printer);
pub fn printList(list: langs.CommandList, stream: var) !void {
for (list.toSlice()) |cmd| {
var command = switch (cmd.command) {
.Noop => "noop",
.Load => "load",
.Quicksave => "quicksave",
.RunQS => "runqs",
fn printCommandWithParams(stream: anytype, command: anytype) !void {
const Parameters = @TypeOf(command.parameters);
try stream.print(" {d} {d}", .{ command.split, command.index });
inline for (@typeInfo(Parameters).Struct.fields) |field| {
if (field.type == f32 or field.type == f64) {
try stream.print(" {}", .{@field(command.parameters, field.name)});
} else if (field.type == usize or field.type == u64) {
try stream.print(" {d}", .{@field(command.parameters, field.name)});
} else {
try stream.print(" {s}", .{@field(command.parameters, field.name)});
}
}
.Amp => "amp",
.RFlanger => "rflanger",
.Eq => "eq",
.Phaser => "phaser",
.Mbeq => "mbeq",
.Chorus => "chorus",
.PitchScaler => "pitchscaler",
.Reverb => "reverb",
.Highpass => "highpass",
.Delay => "delay",
.Vinyl => "vinyl",
.RevDelay => "revdelay",
.Noise => "noise",
.WildNoise => "wildnoise",
.Write => "write",
.Embed => "embed",
.Rotate => "rotate",
};
try stream.print("{}", command);
for (cmd.args.toSlice()) |arg| {
try stream.print(" {}", arg);
}
fn printCommand(stream: anytype, cmd: *langs.Command, comptime tag: langs.Command.Tag) !void {
const CommandStruct = langs.Command.tagToType(tag);
const casted = cmd.cast(CommandStruct).?;
const ctype = CommandStruct.command_type;
switch (ctype) {
.lv2_command => try printCommandWithParams(stream, casted),
.custom_command => try printCommandWithParams(stream, casted),
}
}
pub fn printList(list: langs.CommandList, stream: anytype) !void {
for (list.list.items) |cmd| {
const command = @tagName(cmd.tag);
try stream.print("{s}", .{command});
switch (cmd.tag) {
.load => {
const load = cmd.cast(langs.Command.Load).?;
try stream.print(" {s}", .{load.path});
},
.runqs => {
const runqs = cmd.cast(langs.Command.RunQS).?;
try stream.print(" {s}", .{runqs.program});
},
.noop, .quicksave => {},
.rotate => {
const rotate = cmd.cast(langs.Command.Rotate).?;
try stream.print(" {d} {s}", .{ rotate.deg, rotate.bgfill });
},
.amp => try printCommand(stream, cmd, .amp),
.rflanger => try printCommand(stream, cmd, .rflanger),
.eq => try printCommand(stream, cmd, .eq),
.phaser => try printCommand(stream, cmd, .phaser),
.mbeq => try printCommand(stream, cmd, .mbeq),
.chorus => try printCommand(stream, cmd, .chorus),
.pitchscaler => try printCommand(stream, cmd, .pitchscaler),
.reverb => try printCommand(stream, cmd, .reverb),
.highpass => try printCommand(stream, cmd, .highpass),
.delay => try printCommand(stream, cmd, .delay),
.vinyl => try printCommand(stream, cmd, .vinyl),
.revdelay => try printCommand(stream, cmd, .revdelay),
.gate => try printCommand(stream, cmd, .gate),
.detune => try printCommand(stream, cmd, .detune),
.overdrive => try printCommand(stream, cmd, .overdrive),
.degrade => try printCommand(stream, cmd, .degrade),
.repsycho => try printCommand(stream, cmd, .repsycho),
.talkbox => try printCommand(stream, cmd, .talkbox),
.dyncomp => try printCommand(stream, cmd, .dyncomp),
.thruzero => try printCommand(stream, cmd, .thruzero),
.foverdrive => try printCommand(stream, cmd, .foverdrive),
.gverb => try printCommand(stream, cmd, .gverb),
.invert => try printCommand(stream, cmd, .invert),
.tapedelay => try printCommand(stream, cmd, .tapedelay),
.moddelay => try printCommand(stream, cmd, .moddelay),
.multichorus => try printCommand(stream, cmd, .multichorus),
.saturator => try printCommand(stream, cmd, .saturator),
.vintagedelay => try printCommand(stream, cmd, .vintagedelay),
.noise => try printCommand(stream, cmd, .noise),
.wildnoise => try printCommand(stream, cmd, .wildnoise),
.write => try printCommand(stream, cmd, .write),
.embed => try printCommand(stream, cmd, .embed),
}
_ = try stream.write(";\n");
try stream.write(";\n");
}
}

View file

@ -5,8 +5,6 @@ const plugin = @import("plugin.zig");
const custom = @import("custom.zig");
const magick = @import("magick.zig");
const log = std.log.scoped(.scritcher_runner);
const Position = plugin.Position;
const ParamList = plugin.ParamList;
const ParamMap = plugin.ParamMap;
@ -20,21 +18,18 @@ pub const RunError = error{
};
pub const Runner = struct {
allocator: std.mem.Allocator,
allocator: *std.mem.Allocator,
/// The currently opened image in the runner
image: ?*Image = null,
/// If the runner is in REPL mode
repl: bool,
repl: bool = false,
args: []const [:0]u8,
pub fn init(allocator: std.mem.Allocator, repl: bool) Runner {
pub fn init(allocator: *std.mem.Allocator, repl: bool) Runner {
return Runner{
.allocator = allocator,
.repl = repl,
.args = std.process.argsAlloc(allocator) catch unreachable,
};
}
@ -42,59 +37,50 @@ pub const Runner = struct {
if (self.image) |image| {
image.close();
}
std.process.argsFree(self.allocator, self.args);
}
pub fn clone(self: *Runner) !Runner {
const cloned_image = if (self.image) |image| try image.clone() else null;
return Runner{
.allocator = self.allocator,
.image = cloned_image,
.repl = self.repl,
.args = self.args,
};
var cloned_image = if (self.image) |image| try image.clone() else null;
return Runner{ .allocator = self.allocator, .image = cloned_image };
}
fn resolveArg(self: *Runner, load_path: []const u8) ![]const u8 {
std.debug.assert(load_path.len > 0);
if (load_path[0] == ':') {
// parse the index from 1 to end
var index = try std.fmt.parseInt(usize, load_path[1..], 10);
// if it isn't in the repl, args look like this:
// 'scritcher ./script ./image'
// if it is, it looks like this
// 'scritcher repl ./script ./image'
// don't care about the 'repl' being prepended when we're in repl
if (self.repl) index += 1;
// ':0' should ALWAYS point to the image.
if (self.repl) index += 3 else index += 3;
var args_it = std.process.args();
_ = args_it.skip();
for (self.args, 0..) |arg, idx| {
log.debug("arg{d} = {s}", .{ idx, arg });
var i: usize = 0;
while (i <= index) : (i += 1) {
_ = args_it.skip();
}
log.debug("fetch arg idx={d}", .{index});
log.debug("fetch arg val={s}", .{self.args[index]});
return self.args[index];
const arg = try (args_it.next(self.allocator) orelse @panic("expected argument"));
return arg;
} else {
return load_path;
}
}
// Caller owns returned memory.
fn resolveArgPath(self: *Runner, path_or_argidx: []const u8) ![]const u8 {
const path = try self.resolveArg(path_or_argidx);
const resolved_path = try std.fs.path.resolve(
self.allocator,
&[_][]const u8{path},
[_][]const u8{path},
);
return resolved_path;
}
fn loadCmd(self: *Runner, path_or_argidx: []const u8) !void {
const load_path = try self.resolveArgPath(path_or_argidx);
log.debug("\tload path: {s}", .{load_path});
var load_path = try self.resolveArgPath(path_or_argidx);
std.debug.warn("\tload path: {}\n", load_path);
// we could use ImageMagick to convert from X to BMP
// but i can't find an easy way to do things in memory.
@ -103,15 +89,14 @@ pub const Runner = struct {
// before loading the file into scritcher. for example, you can start
// krita/gimp and make it export a bmp and while in the program you can
// apply filters, etc.
if (!std.mem.endsWith(u8, load_path, ".bmp") and !std.mem.endsWith(u8, load_path, ".ppm")) {
log.debug("Only BMP files are allowed to be loaded. Got path '{s}'", .{load_path});
if (!std.mem.endsWith(u8, load_path, ".bmp")) {
std.debug.warn("Only BMP files are allowed to be loaded.\n");
return RunError.NoBMP;
}
// we don't copy load_path into a temporary file because we're already
// loading it under the SFM_READ mode, which won't cause any destructive
// operations on the file.
if (self.image) |image| image.close();
self.image = try Image.open(self.allocator, load_path);
}
@ -119,21 +104,20 @@ pub const Runner = struct {
if (self.image) |image| {
return image;
} else {
log.debug("image is required!", .{});
std.debug.warn("image is required!\n");
return RunError.ImageRequired;
}
}
/// Caller owns returned memory.
fn makeGlitchedPath(self: *Runner) ![]const u8 {
// we want to transform basename, if it is "x.bmp" to "x_gN.bmp", where
// N is the maximum non-used integer.
const image = try self.getImage();
var image = try self.getImage();
const basename = std.fs.path.basename(image.path);
const dirname = std.fs.path.dirname(image.path).?;
var dir = try std.fs.cwd().openDir(dirname, .{ .iterate = true });
var dir = try std.fs.Dir.open(self.allocator, dirname);
defer dir.close();
const period_idx = std.mem.lastIndexOf(u8, basename, ".").?;
@ -141,18 +125,18 @@ pub const Runner = struct {
// starts_with would be "x_g", we want to find all files in the directory
// that start with that name.
const starts_with = try std.fmt.allocPrint(self.allocator, "{s}_g", .{
const starts_with = try std.fmt.allocPrint(
self.allocator,
"{}_g",
basename[0..period_idx],
});
);
defer self.allocator.free(starts_with);
var max: usize = 0;
var it = dir.iterate();
while (try it.next()) |entry| {
while (try dir.next()) |entry| {
switch (entry.kind) {
.file => blk: {
.File => blk: {
if (!std.mem.startsWith(u8, entry.name, starts_with)) break :blk {};
// we want to get the N in x_gN.ext
@ -166,8 +150,6 @@ pub const Runner = struct {
// if N isn't a number, we just ignore that file
const idx_str = entry.name[entry_gidx + 2 .. entry_pidx];
const idx = std.fmt.parseInt(usize, idx_str, 10) catch |err| {
log.debug("ignoring file {s}", .{@errorName(err)});
break :blk {};
};
@ -177,12 +159,14 @@ pub const Runner = struct {
}
}
const out_path = try std.fmt.allocPrint(self.allocator, "{s}/{s}{d}{s}", .{
const out_path = try std.fmt.allocPrint(
self.allocator,
"{}/{}{}{}",
dirname,
starts_with,
max + 1,
extension,
});
);
return out_path;
}
@ -190,155 +174,349 @@ pub const Runner = struct {
fn quicksaveCmd(self: *Runner) !void {
var image = try self.getImage();
const out_path = try self.makeGlitchedPath();
defer self.allocator.free(out_path);
try image.saveTo(out_path);
}
fn runQSCmd(self: *Runner, cmd: *lang.Command) !void {
const runqs = cmd.cast(lang.Command.RunQS).?;
fn runQSCmd(self: *Runner, program: []const u8) !void {
var image = try self.getImage();
const out_path = try self.makeGlitchedPath();
defer self.allocator.free(out_path);
try image.saveTo(out_path);
var proc = std.ChildProcess.init(
&[_][]const u8{ runqs.program, out_path },
var proc = try std.ChildProcess.init(
[_][]const u8{ program, out_path },
self.allocator,
);
//defer proc.deinit();
defer proc.deinit();
log.debug("running '{s} {s}'", .{ runqs.program, out_path });
std.debug.warn("running '{} {}'\n", program, out_path);
_ = try proc.spawnAndWait();
}
fn rotateCmd(self: *Runner, cmd: *lang.Command) !void {
const rotate_cmd = cmd.cast(lang.Command.Rotate).?;
const image = try self.getImage();
const c_bgfill = try self.allocator.dupeZ(u8, rotate_cmd.bgfill);
defer self.allocator.free(c_bgfill);
try magick.runRotate(image, rotate_cmd.deg, c_bgfill);
/// Run the http://lv2plug.in/plugins/eg-amp plugin over the file.
fn ampCmd(self: *Runner, pos: Position, params: ParamList) !void {
var image = try self.getImage();
try image.runPlugin("http://lv2plug.in/plugins/eg-amp", pos, params);
}
fn executeLV2Command(self: *@This(), command: anytype) !void {
const pos = plugin.Position{
.split = command.split,
.index = command.index,
};
fn rFlangerCmd(self: *Runner, pos: Position, params: ParamList) !void {
var image = try self.getImage();
try image.runPlugin("http://plugin.org.uk/swh-plugins/retroFlange", pos, params);
}
fn eqCmd(self: *Runner, position: Position, params: ParamList) !void {
var image = try self.getImage();
try image.runPlugin("http://plugin.org.uk/swh-plugins/dj_eq_mono", position, params);
}
fn phaserCmd(self: *Runner, position: Position, params: ParamList) !void {
var image = try self.getImage();
try image.runPlugin("http://plugin.org.uk/swh-plugins/lfoPhaser", position, params);
}
fn mbeqCmd(self: *Runner, position: Position, bands: []const f32) !void {
var image = try self.getImage();
var params = ParamList.init(self.allocator);
defer params.deinit();
const typ = @TypeOf(command);
inline for (@typeInfo(@TypeOf(command.parameters)).Struct.fields) |cmd_field| {
for (bands) |band_value, idx| {
var sym = try std.fmt.allocPrint(self.allocator, "band_{}", idx + 1);
try params.append(plugin.Param{
.sym = cmd_field.name,
.value = @field(command.parameters, cmd_field.name),
.sym = sym,
.value = band_value,
});
}
var image = try self.getImage();
try image.runPlugin(typ.lv2_url, pos, params);
try image.runPlugin("http://plugin.org.uk/swh-plugins/mbeq", position, params);
}
fn executeCustomCommand(self: *@This(), command: anytype) !void {
const pos = plugin.Position{
.split = command.split,
.index = command.index,
};
fn chorusCmd(self: *Runner, pos: Position, params: ParamList) !void {
var image = try self.getImage();
try image.runCustomPlugin(@TypeOf(command).plugin_type, pos, command.parameters);
try image.runPlugin("http://plugin.org.uk/swh-plugins/multivoiceChorus", pos, params);
}
fn runSingleCommand(
self: *@This(),
cmd: *lang.Command,
comptime tag: lang.Command.Tag,
fn pitchScalerCmd(self: *Runner, pos: Position, params: ParamList) !void {
var image = try self.getImage();
try image.runPlugin("http://plugin.org.uk/swh-plugins/pitchScaleHQ", pos, params);
}
fn reverbCmd(self: *Runner, pos: Position, params: ParamList) !void {
var image = try self.getImage();
try image.runPlugin("http://invadarecords.com/plugins/lv2/erreverb/mono", pos, params);
}
fn highpassCmd(self: *Runner, pos: Position, params: ParamList) !void {
var image = try self.getImage();
try image.runPlugin("http://invadarecords.com/plugins/lv2/filter/hpf/mono", pos, params);
}
fn delayCmd(self: *Runner, pos: Position, params: ParamList) !void {
var image = try self.getImage();
try image.runPlugin("http://plugin.org.uk/swh-plugins/delayorama", pos, params);
}
fn vinylCmd(self: *Runner, pos: Position, params: ParamList) !void {
var image = try self.getImage();
try image.runPlugin("http://plugin.org.uk/swh-plugins/vynil", pos, params);
}
fn revDelayCmd(self: *Runner, pos: Position, params: ParamList) !void {
var image = try self.getImage();
try image.runPlugin("http://plugin.org.uk/swh-plugins/revdelay", pos, params);
}
fn noiseCmd(self: *Runner, pos: Position, map: *ParamMap) !void {
var image = try self.getImage();
try image.runCustomPlugin(custom.RandomNoise, pos, *ParamMap, map);
}
fn wildNoiseCmd(self: *Runner, pos: Position, map: *ParamMap) !void {
var image = try self.getImage();
try image.runCustomPlugin(custom.WildNoise, pos, *ParamMap, map);
}
fn writeCmd(self: *Runner, pos: Position, map: *ParamMap) !void {
var image = try self.getImage();
try image.runCustomPlugin(custom.Write, pos, *ParamMap, map);
}
fn embedCmd(self: *Runner, pos: Position, path: []const u8) !void {
var image = try self.getImage();
try image.runCustomPlugin(custom.Embed, pos, []const u8, path);
}
fn rotateCmd(
self: *Runner,
deg: f32,
bgfill: []const u8,
) !void {
const typ = lang.Command.tagToType(tag);
const command = cmd.cast(typ).?;
const ctype = typ.command_type;
switch (ctype) {
.lv2_command => try self.executeLV2Command(command.*),
.custom_command => try self.executeCustomCommand(command.*),
}
var image = try self.getImage();
var c_bgfill = try std.cstr.addNullByte(self.allocator, bgfill);
defer self.allocator.free(c_bgfill);
try magick.runRotate(image, deg, c_bgfill);
}
fn runCommand(self: *@This(), cmd: *lang.Command) !void {
switch (cmd.tag) {
.noop => {},
.load => {
const command = cmd.cast(lang.Command.Load).?;
try self.loadCmd(command.path);
fn runCommand(self: *Runner, cmd: *lang.Command) !void {
var params = ParamList.init(self.allocator);
defer params.deinit();
var map = ParamMap.init(self.allocator);
defer map.deinit();
return switch (cmd.command) {
.Noop => {},
.Load => blk: {
var path = cmd.args.at(0);
try self.loadCmd(path);
// TODO is this needed?
break :blk;
},
.quicksave => try self.quicksaveCmd(),
.rotate => try self.rotateCmd(cmd),
.runqs => try self.runQSCmd(cmd),
.Quicksave => try self.quicksaveCmd(),
.RunQS => try self.runQSCmd(cmd.args.at(0)),
.amp => try self.runSingleCommand(cmd, .amp),
.rflanger => try self.runSingleCommand(cmd, .rflanger),
.eq => try self.runSingleCommand(cmd, .eq),
.phaser => try self.runSingleCommand(cmd, .phaser),
.mbeq => try self.runSingleCommand(cmd, .mbeq),
.chorus => try self.runSingleCommand(cmd, .chorus),
.pitchscaler => try self.runSingleCommand(cmd, .pitchscaler),
.reverb => try self.runSingleCommand(cmd, .reverb),
.highpass => try self.runSingleCommand(cmd, .highpass),
.delay => try self.runSingleCommand(cmd, .delay),
.vinyl => try self.runSingleCommand(cmd, .vinyl),
.revdelay => try self.runSingleCommand(cmd, .revdelay),
.gate => try self.runSingleCommand(cmd, .gate),
.detune => try self.runSingleCommand(cmd, .detune),
.overdrive => try self.runSingleCommand(cmd, .overdrive),
.degrade => try self.runSingleCommand(cmd, .degrade),
.repsycho => try self.runSingleCommand(cmd, .repsycho),
.talkbox => try self.runSingleCommand(cmd, .talkbox),
.dyncomp => try self.runSingleCommand(cmd, .dyncomp),
.thruzero => try self.runSingleCommand(cmd, .thruzero),
.foverdrive => try self.runSingleCommand(cmd, .foverdrive),
.gverb => try self.runSingleCommand(cmd, .gverb),
.invert => try self.runSingleCommand(cmd, .invert),
.tapedelay => try self.runSingleCommand(cmd, .tapedelay),
.moddelay => try self.runSingleCommand(cmd, .moddelay),
.multichorus => try self.runSingleCommand(cmd, .multichorus),
.saturator => try self.runSingleCommand(cmd, .saturator),
.vintagedelay => try self.runSingleCommand(cmd, .vintagedelay),
.Amp => blk: {
const pos = try cmd.consumePosition();
try cmd.appendParam(&params, "gain");
try self.ampCmd(pos, params);
},
.noise => try self.runSingleCommand(cmd, .noise),
.wildnoise => try self.runSingleCommand(cmd, .wildnoise),
.write => try self.runSingleCommand(cmd, .write),
.embed => try self.runSingleCommand(cmd, .embed),
}
.RFlanger => blk: {
const pos = try cmd.consumePosition();
try cmd.appendParam(&params, "delay_depth_avg");
try cmd.appendParam(&params, "law_freq");
try self.rFlangerCmd(pos, params);
},
.Eq => blk: {
const pos = try cmd.consumePosition();
try cmd.appendParam(&params, "lo");
try cmd.appendParam(&params, "mid");
try cmd.appendParam(&params, "hi");
try self.eqCmd(pos, params);
},
.Phaser => blk: {
const pos = try cmd.consumePosition();
try cmd.appendParam(&params, "lfo_rate");
try cmd.appendParam(&params, "lfo_depth");
try cmd.appendParam(&params, "fb");
try cmd.appendParam(&params, "spread");
try self.phaserCmd(pos, params);
},
.Mbeq => blk: {
const pos = try cmd.consumePosition();
const bands = try cmd.floatArgMany(self.allocator, 2, 15, f32(0));
defer self.allocator.free(bands);
try self.mbeqCmd(pos, bands);
},
.Chorus => blk: {
const pos = try cmd.consumePosition();
try cmd.appendParam(&params, "voices");
try cmd.appendParam(&params, "delay_base");
try cmd.appendParam(&params, "voice_spread");
try cmd.appendParam(&params, "detune");
try cmd.appendParam(&params, "law_freq");
try cmd.appendParam(&params, "attendb");
try self.chorusCmd(pos, params);
},
.PitchScaler => blk: {
const pos = try cmd.consumePosition();
try cmd.appendParam(&params, "mult");
try self.pitchScalerCmd(pos, params);
},
.Reverb => blk: {
const pos = try cmd.consumePosition();
try cmd.appendParam(&params, "roomLength");
try cmd.appendParam(&params, "roomWidth");
try cmd.appendParam(&params, "roomHeight");
try cmd.appendParam(&params, "sourceLR");
try cmd.appendParam(&params, "sourceFB");
try cmd.appendParam(&params, "listLR");
try cmd.appendParam(&params, "listFB");
try cmd.appendParam(&params, "hpf");
try cmd.appendParam(&params, "warmth");
try cmd.appendParam(&params, "diffusion");
try self.reverbCmd(pos, params);
},
.Highpass => blk: {
const pos = try cmd.consumePosition();
try cmd.appendParam(&params, "freq");
try cmd.appendParam(&params, "gain");
try cmd.appendParam(&params, "noClip");
try self.highpassCmd(pos, params);
},
.Delay => blk: {
const pos = try cmd.consumePosition();
try cmd.appendParam(&params, "seed");
try cmd.appendParam(&params, "gain");
try cmd.appendParam(&params, "feedback_pc");
try cmd.appendParam(&params, "tap_count");
try cmd.appendParam(&params, "first_delay");
try cmd.appendParam(&params, "delay_range");
try cmd.appendParam(&params, "delay_scale");
try cmd.appendParam(&params, "delay_rand_pc");
try cmd.appendParam(&params, "gain_scale");
try cmd.appendParam(&params, "wet");
try self.delayCmd(pos, params);
},
.Vinyl => blk: {
const pos = try cmd.consumePosition();
try cmd.appendParam(&params, "year");
try cmd.appendParam(&params, "rpm");
try cmd.appendParam(&params, "warp");
try cmd.appendParam(&params, "click");
try cmd.appendParam(&params, "wear");
try self.vinylCmd(pos, params);
},
.RevDelay => blk: {
const pos = try cmd.consumePosition();
try cmd.appendParam(&params, "delay_time");
try cmd.appendParam(&params, "dry_level");
try cmd.appendParam(&params, "wet_level");
try cmd.appendParam(&params, "feedback");
try cmd.appendParam(&params, "xfade_samp");
try self.revDelayCmd(pos, params);
},
.Noise => blk: {
const pos = try cmd.consumePosition();
try cmd.appendParamMap(&map, "seed");
try cmd.appendParamMap(&map, "fill_bytes");
try self.noiseCmd(pos, &map);
},
.WildNoise => blk: {
const pos = try cmd.consumePosition();
try cmd.appendParamMap(&map, "seed");
try cmd.appendParamMap(&map, "fill_bytes");
try self.wildNoiseCmd(pos, &map);
},
.Write => blk: {
const pos = try cmd.consumePosition();
try cmd.appendParamMap(&map, "data");
try self.writeCmd(pos, &map);
},
.Embed => blk: {
const pos = try cmd.consumePosition();
const path = cmd.args.at(2);
try self.embedCmd(pos, path);
},
.Rotate => blk: {
const deg = try cmd.floatArgAt(0);
const bgfill = try cmd.argAt(1);
try self.rotateCmd(deg, bgfill);
},
else => blk: {
std.debug.warn("Unsupported command: {}\n", cmd.command);
break :blk RunError.UnknownCommand;
},
};
}
/// Run a list of commands.
pub fn runCommands(
self: *Runner,
cmds: lang.CommandList,
debug_flag: bool,
) !void {
_ = debug_flag;
for (cmds.list.items) |cmd| {
cmd.print();
for (cmds.toSlice()) |const_cmd| {
if (debug_flag) const_cmd.print();
// copy the command so we own its memory
var cmd = try const_cmd.copy(self.allocator);
defer self.allocator.destroy(cmd);
try self.runCommand(cmd);
}
}
};
test "running noop" {
const allocator = std.testing.allocator;
const allocator = std.heap.direct_allocator;
var cmds = lang.CommandList.init(allocator);
defer cmds.deinit();
const command = lang.Command{ .tag = .noop };
var cmd_ptr = try allocator.create(lang.Command);
cmd_ptr.* = lang.Command{
.command = .Noop,
.args = lang.ArgList.init(allocator),
};
try cmds.append(cmd_ptr);
var noop = try allocator.create(lang.Command.Noop);
noop.* = lang.Command.Noop{ .base = command };
try cmds.append(&noop.base);
var runner = Runner.init(allocator, false);
var runner = Runner.init(allocator);
defer runner.deinit();
try runner.runCommands(cmds, false);