public MyPipeline(HSBuffer <byte> inBuf)
{
Input = inBuf;
// For this lesson, we'll use a two-stage pipeline that sharpens
// and then applies a look-up-table (LUT).
// First we'll define the LUT. It will be a gamma curve.
Lut[I] = HS.Cast <byte>(HS.Clamp(HSMath.Pow(I / 255.0f, 1.2f) * 255.0f, 0, 255));
// Augment the input with a boundary condition.
Padded[X, Y, C] = Input[HS.Clamp(X, 0, Input.Width - 1),
HS.Clamp(Y, 0, Input.Height - 1), C];
// Cast it to 16-bit to do the math.
Padded16[X, Y, C] = HS.Cast <ushort>(Padded[X, Y, C]);
// Next we sharpen it with a five-tap filter.
Sharpen[X, Y, C] = (Padded16[X, Y, C] * 2 -
(Padded16[X - 1, Y, C] +
Padded16[X, Y - 1, C] +
Padded16[X + 1, Y, C] +
Padded16[X, Y + 1, C]) / 4);
// Then apply the LUT.
Curved[X, Y, C] = Lut[Sharpen[X, Y, C]];
}
public Color GetColor(LiveMonster lm, int mouseX, int mouseY)
{
if (Type == RegionType.None || Type == RegionType.Grid)
{
return(Color.White);
}
if (color == Color.Red && !lm.GoLeft)
{
return(Color.White);
}
if (color == Color.Green && lm.GoLeft)
{
return(Color.White);
}
if (Type == RegionType.Circle)
{
if (HSMath.GetDistance(mouseX, mouseY, lm.Position.X + 50, lm.Position.Y * 100 + 50) > length * 10)
{
return(Color.White);
}
}
else if (Type == RegionType.Rect)
{
if (mouseX < lm.Position.X + 50 - length * 10 || mouseX > lm.Position.X + 50 + length * 10)
{
return(Color.White);
}
if (mouseY < lm.Position.Y * 100 + 50 - length * 10 || mouseY > lm.Position.Y * 100 + 50 + length * 10)
{
return(Color.White);
}
}
else if (Type == RegionType.Row)
{
if (mouseY / 100 != lm.Position.Y)
{
return(Color.White);
}
}
else if (Type == RegionType.Column)
{
if (mouseX < lm.Position.X + 50 - length * 5 || mouseX > lm.Position.X + 50 + length * 5)
{
return(Color.White);
}
}
return(color);
}
public static int Main(string[] args)
{
// First we'll declare some Vars to use below.
var x = new HSVar("x");
var y = new HSVar("y");
var xo = new HSVar("xo");
var yo = new HSVar("yo");
var xi = new HSVar("xi");
var yi = new HSVar("yi");
// This lesson will be about "wrapping" a Func or an ImageParam using the
// Func::in and ImageParam::in directives
{
{
// Consider a simple two-stage pipeline:
var f = new HSFunc("f_local");
var g = new HSFunc("g_local");
f[x, y] = x + y;
g[x, y] = 2 * f[x, y] + 3;
f.ComputeRoot();
// This produces the following loop nests:
// for y:
// for x:
// f(x, y) = x + y
// for y:
// for x:
// g(x, y) = 2 * f(x, y) + 3
// Using Func::in, we can interpose a new Func in between f
// and g using the schedule alone:
HSFunc f_in_g = f.In(g);
f_in_g.ComputeRoot();
// Equivalently, we could also chain the schedules like so:
// f.in(g).ComputeRoot();
// This produces the following three loop nests:
// for y:
// for x:
// f(x, y) = x + y
// for y:
// for x:
// f_in_g(x, y) = f(x, y)
// for y:
// for x:
// g(x, y) = 2 * f_in_g(x, y) + 3
g.Realize <int>(5, 5);
// See figures/lesson_19_wrapper_local.mp4 for a visualization.
}
// The schedule directive f.in(g) replaces all calls to 'f'
// inside 'g' with a wrapper Func and then returns that
// wrapper. Essentially, it rewrites the original pipeline
// above into the following:
{
var f_in_g = new HSFunc("f_in_g");
var f = new HSFunc("f");
var g = new HSFunc("g");
f[x, y] = x + y;
f_in_g[x, y] = f[x, y];
g[x, y] = 2 * f_in_g[x, y] + 3;
f.ComputeRoot();
f_in_g.ComputeRoot();
g.ComputeRoot();
}
// In isolation, such a transformation seems pointless, but it
// can be used for a variety of scheduling tricks.
}
{
// In the schedule above, only the calls to 'f' made by 'g'
// are replaced. Other calls made to f would still call 'f'
// directly. If we wish to globally replace all calls to 'f'
// with a single wrapper, we simply say f.in().
// Consider a three stage pipeline, with two consumers of f:
var f = new HSFunc("f_global");
var g = new HSFunc("g_global");
var h = new HSFunc("h_global");
f[x, y] = x + y;
g[x, y] = 2 * f[x, y];
h[x, y] = 3 + g[x, y] - f[x, y];
f.ComputeRoot();
g.ComputeRoot();
h.ComputeRoot();
// We will replace all calls to 'f' inside both 'g' and 'h'
// with calls to a single wrapper:
f.In().ComputeRoot();
// The equivalent loop nests are:
// for y:
// for x:
// f(x, y) = x + y
// for y:
// for x:
// f_in(x, y) = f(x, y)
// for y:
// for x:
// g(x, y) = 2 * f_in(x, y)
// for y:
// for x:
// h(x, y) = 3 + g(x, y) - f_in(x, y)
h.Realize <int>(5, 5);
// See figures/lesson_19_wrapper_global.mp4 and for a
// visualization of what this did.
}
{
// We could also give g and h their own unique wrappers of
// f. This time we'll schedule them each inside the loop nests
// of the consumer, which is not something we could do with a
// single global wrapper.
var f = new HSFunc("f_unique");
var g = new HSFunc("g_unique");
var h = new HSFunc("h_unique");
f[x, y] = x + y;
g[x, y] = 2 * f[x, y];
h[x, y] = 3 + g[x, y] - f[x, y];
f.ComputeRoot();
g.ComputeRoot();
h.ComputeRoot();
f.In(g).ComputeAt(g, y);
f.In(h).ComputeAt(h, y);
// This creates the loop nests:
// for y:
// for x:
// f(x, y) = x + y
// for y:
// for x:
// f_in_g(x, y) = f(x, y)
// for x:
// g(x, y) = 2 * f_in_g(x, y)
// for y:
// for x:
// f_in_h(x, y) = f(x, y)
// for x:
// h(x, y) = 3 + g(x, y) - f_in_h(x, y)
h.Realize <int>(5, 5);
// See figures/lesson_19_wrapper_unique.mp4 for a visualization.
}
{
// So far this may seem like a lot of pointless copying of
// memory. Func::in can be combined with other scheduling
// directives for a variety of purposes. The first we will
// examine is creating distinct realizations of a Func for
// several consumers and scheduling each differently.
// We'll start with nearly the same pipeline.
var f = new HSFunc("f_sched");
var g = new HSFunc("g_sched");
var h = new HSFunc("h_sched");
f[x, y] = x + y;
g[x, y] = 2 * f[x, y];
// h will use a far-away region of f
h[x, y] = 3 + g[x, y] - f[x + 93, y - 87];
// This time we'll inline f.
// f.ComputeRoot();
g.ComputeRoot();
h.ComputeRoot();
f.In(g).ComputeAt(g, y);
f.In(h).ComputeAt(h, y);
// g and h now call f via distinct wrappers. The wrappers are
// scheduled, but f is not, which means that f is inlined into
// its two wrappers. They will each independently compute the
// region of f required by their consumer. If we had scheduled
// f ComputeRoot, we'd be computing the bounding box of the
// region required by g and the region required by h, which
// would mostly be unused data.
// We can also schedule each of these wrappers
// differently. For scheduling purposes, wrappers inherit the
// pure vars of the Func they wrap, so we use the same x and y
// that we used when defining f:
f.In(g).Vectorize(x, 4);
f.In(h).Split(x, xo, xi, 2).Reorder(xo, xi);
// Note that calling f.in(g) a second time returns the wrapper
// already created by the first call, it doesn't make a new one.
h.Realize <int>(8, 8);
// See figures/lesson_19_wrapper_vary_schedule.mp4 for a
// visualization.
// Note that because f is inlined into its two wrappers, it is
// the wrappers that do the work of computing f, rather than
// just loading from an existing computed realization.
}
{
// Func::in is useful to stage loads from a Func via some
// smaller intermediate buffer, perhaps on the stack or in
// shared GPU memory.
// Consider a pipeline that transposes some ComputeRoot'd Func:
var f = new HSFunc("f_transpose");
var g = new HSFunc("g_transpose");
f[x, y] = HSMath.Sin(((x + y) * HSMath.Sqrt(y)) / 10);
f.ComputeRoot();
g[x, y] = f[y, x];
// The execution strategy we want is to load an 4x4 tile of f
// into registers, transpose it in-register, and then write it
// out as an 4x4 tile of g. We will use Func::in to express this:
HSFunc f_tile = f.In(g);
// We now have a three stage pipeline:
// f -> f_tile -> g
// f_tile will load vectors of f, and store them transposed
// into registers. g will then write this data back to main
// memory.
g.Tile(x, y, xo, yo, xi, yi, 4, 4)
.Vectorize(xi)
.Unroll(yi);
// We will compute f_transpose at tiles of g, and use
// Func::reorder_storage to state that f_transpose should be
// stored column-major, so that the loads to it done by g can
// be dense vector loads.
f_tile.ComputeAt(g, xo)
.ReorderStorage(y, x)
.Vectorize(x)
.Unroll(y);
// We take care to make sure f_transpose is only ever accessed
// at constant indicies. The full unrolling/vectorization of
// all loops that exist inside its compute_at level has this
// effect. Allocations that are only ever accessed at constant
// indices can be promoted into registers.
g.Realize <float>(16, 16);
// See figures/lesson_19_transpose.mp4 for a visualization
}
{
// ImageParam::in behaves the same way as Func::in, and you
// can use it to stage loads in similar ways. Instead of
// transposing again, we'll use ImageParam::in to stage tiles
// of an input image into GPU shared memory, effectively using
// shared/local memory as an explicitly-managed cache.
var img = new HSImageParam <int>(2);
// We will compute a small blur of the input.
var blur = new HSFunc("blur");
blur[x, y] = (img[x - 1, y - 1] + img[x, y - 1] + img[x + 1, y - 1] +
img[x - 1, y] + img[x, y] + img[x + 1, y] +
img[x - 1, y + 1] + img[x, y + 1] + img[x + 1, y + 1]);
blur.ComputeRoot().GpuTile(x, y, xo, yo, xi, yi, 8, 8);
// The wrapper Func created by ImageParam::in has pure vars
// named _0, _1, etc. Schedule it per tile of "blur", and map
// _0 and _1 to gpu threads.
img.In(blur).ComputeAt(blur, xo).GpuThreads(HS._0, HS._1);
// Without Func::in, computing an 8x8 tile of blur would do
// 8*8*9 loads to global memory. With Func::in, the wrapper
// does 10*10 loads to global memory up front, and then blur
// does 8*8*9 loads to shared/local memory.
// Select an appropriate GPU API, as we did in lesson 12
var target = HS.GetHostTarget();
if (target.OS == HSOperatingSystem.OSX)
{
target.SetFeature(HSFeature.Metal);
}
else
{
target.SetFeature(HSFeature.OpenCL);
}
// Create an interesting input image to use.
var input = new HSBuffer <int>(258, 258);
input.SetMin(-1, -1);
for (int yy = input.Top; yy <= input.Bottom; yy++)
{
for (int xx = input.Left; xx <= input.Right; xx++)
{
input[xx, yy] = xx * 17 + yy % 4;
}
}
img.Set(input);
blur.CompileJit(target);
var output = blur.Realize <int>(256, 256);
// Check the output is what we expected
for (int yy = output.Top; yy <= output.Bottom; yy++)
{
for (int xx = output.Left; xx <= output.Right; xx++)
{
int val = output[xx, yy];
int expected = (input[xx - 1, yy - 1] + input[xx, yy - 1] + input[xx + 1, yy - 1] +
input[xx - 1, yy] + input[xx, yy] + input[xx + 1, yy] +
input[xx - 1, yy + 1] + input[xx, yy + 1] + input[xx + 1, yy + 1]);
if (val != expected)
{
Console.WriteLine($"output({xx}, {yy}) = {val} instead of {expected}\n",
xx, yy, val, expected);
return(-1);
}
}
}
}
{
// Func::in can also be used to group multiple stages of a
// Func into the same loop nest. Consider the following
// pipeline, which computes a value per pixel, then sweeps
// from left to right and back across each scanline.
var f = new HSFunc("f_group");
var g = new HSFunc("g_group");
var h = new HSFunc("h_group");
// Initialize f
f[x, y] = HSMath.Sin(x - y);
var r = new HSRDom(1, 7);
// Sweep from left to right
f[r, y] = (f[r, y] + f[r - 1, y]) / 2;
// Sweep from right to left
f[7 - r, y] = (f[7 - r, y] + f[8 - r, y]) / 2;
// Then we do something with a complicated access pattern: A
// 45 degree rotation with wrap-around
g[x, y] = f[(x + y) % 8, (x - y) % 8];
// f should be scheduled ComputeRoot, because its consumer
// accesses it in a complicated way. But that means all stages
// of f are computed in separate loop nests:
// for y:
// for x:
// f(x, y) = sin(x - y)
// for y:
// for r:
// f(r, y) = (f(r, y) + f(r - 1, y)) / 2
// for y:
// for r:
// f(7 - r, y) = (f(7 - r, y) + f(8 - r, y)) / 2
// for y:
// for x:
// g(x, y) = f((x + y) % 8, (x - y) % 8);
// We can get better locality if we schedule the work done by
// f to share a common loop over y. We can do this by
// computing f at scanlines of a wrapper like so:
f.In(g).ComputeRoot();
f.ComputeAt(f.In(g), y);
// f has the default schedule for a Func with update stages,
// which is to be computed at the innermost loop of its
// consumer, which is now the wrapper f.in(g). This therefore
// generates the following loop nest, which has better
// locality:
// for y:
// for x:
// f(x, y) = sin(x - y)
// for r:
// f(r, y) = (f(r, y) + f(r - 1, y)) / 2
// for r:
// f(7 - r, y) = (f(7 - r, y) + f(8 - r, y)) / 2
// for x:
// f_in_g(x, y) = f(x, y)
// for y:
// for x:
// g(x, y) = f_in_g((x + y) % 8, (x - y) % 8);
// We'll additionally vectorize the initialization of, and
// then transfer of pixel values from f into its wrapper:
f.Vectorize(x, 4);
f.In(g).Vectorize(x, 4);
g.Realize <float>(8, 8);
// See figures/lesson_19_group_updates.mp4 for a visualization.
}
Console.WriteLine("Success!");
return(0);
}
public static int Main(string[] args)
{
// First we'll declare some Vars to use below.
var x = new HSVar("x");
var y = new HSVar("y");
// Let's examine various scheduling options for a simple two stage
// pipeline. We'll start with the default schedule:
{
var producer = new HSFunc("producer_default");
var consumer = new HSFunc("consumer_default");
// The first stage will be some simple pointwise math similar
// to our familiar gradient function. The value at position x,
// y is the sin of product of x and y.
producer[x, y] = HSMath.Sin(x * y);
// Now we'll add a second stage which averages together multiple
// points in the first stage.
consumer[x, y] = (producer[x, y] +
producer[x, y + 1] +
producer[x + 1, y] +
producer[x + 1, y + 1]) / 4;
// We'll turn on tracing for both functions.
consumer.TraceStores();
producer.TraceStores();
// And evaluate it over a 4x4 box.
Console.WriteLine("\nEvaluating producer-consumer pipeline with default schedule");
consumer.Realize <float>(4, 4);
// There were no messages about computing values of the
// producer. This is because the default schedule fully
// inlines 'producer' into 'consumer'. It is as if we had
// written the following code instead:
// consumer(x, y) = (sin(x * y) +
// sin(x * (y + 1)) +
// sin((x + 1) * y) +
// sin((x + 1) * (y + 1))/4);
// All calls to 'producer' have been replaced with the body of
// 'producer', with the arguments substituted in for the
// variables.
// The equivalent C code is:
var result = new float[4, 4];
for (int yy = 0; yy < 4; yy++)
{
for (int xx = 0; xx < 4; xx++)
{
result[yy, xx] = (float)((Math.Sin(xx * yy) +
Math.Sin(xx * (yy + 1)) +
Math.Sin((xx + 1) * yy) +
Math.Sin((xx + 1) * (yy + 1))) / 4);
}
}
Console.WriteLine();
// If we look at the loop nest, the producer doesn't appear
// at all. It has been inlined into the consumer.
Console.WriteLine("Pseudo-code for the schedule:");
consumer.PrintLoopNest();
Console.WriteLine();
}
// Next we'll examine the next simplest option - computing all
// values required in the producer before computing any of the
// consumer. We call this schedule "root".
{
// Start with the same function definitions:
var producer = new HSFunc("producer_root");
var consumer = new HSFunc("consumer_root");
producer[x, y] = HSMath.Sin(x * y);
consumer[x, y] = (producer[x, y] +
producer[x, y + 1] +
producer[x + 1, y] +
producer[x + 1, y + 1]) / 4;
// Tell Halide to evaluate all of producer before any of consumer.
producer.ComputeRoot();
// Turn on tracing.
consumer.TraceStores();
producer.TraceStores();
// Compile and run.
Console.WriteLine("\nEvaluating producer.compute_root()");
consumer.Realize <float>(4, 4);
// Reading the output we can see that:
// A) There were stores to producer.
// B) They all happened before any stores to consumer.
// See figures/lesson_08_compute_root.gif for a visualization.
// The producer is on the left and the consumer is on the
// right. Stores are marked in orange and loads are marked in
// blue.
// Equivalent C:
var result = new float[4, 4];
// Allocate some temporary storage for the producer.
var producer_storage = new float[5, 5];
// Compute the producer.
for (int yy = 0; yy < 5; yy++)
{
for (int xx = 0; xx < 5; xx++)
{
producer_storage[yy, xx] = (float)Math.Sin(xx * yy);
}
}
// Compute the consumer. Skip the prints this time.
for (int yy = 0; yy < 4; yy++)
{
for (int xx = 0; xx < 4; xx++)
{
result[yy, xx] = (producer_storage[yy, xx] +
producer_storage[yy + 1, xx] +
producer_storage[yy, xx + 1] +
producer_storage[yy + 1, xx + 1]) / 4;
}
}
// Note that consumer was evaluated over a 4x4 box, so Halide
// automatically inferred that producer was needed over a 5x5
// box. This is the same 'bounds inference' logic we saw in
// the previous lesson, where it was used to detect and avoid
// out-of-bounds reads from an input image.
// If we print the loop nest, we'll see something very
// similar to the C above.
Console.WriteLine("Pseudo-code for the schedule:");
consumer.PrintLoopNest();
Console.WriteLine();
}
// Let's compare the two approaches above from a performance
// perspective.
// Full inlining (the default schedule):
// - Temporary memory allocated: 0
// - Loads: 0
// - Stores: 16
// - Calls to sin: 64
// producer.compute_root():
// - Temporary memory allocated: 25 floats
// - Loads: 64
// - Stores: 41
// - Calls to sin: 25
// There's a trade-off here. Full inlining used minimal temporary
// memory and memory bandwidth, but did a whole bunch of redundant
// expensive math (calling sin). It evaluated most points in
// 'producer' four times. The second schedule,
// producer.compute_root(), did the mimimum number of calls to
// sin, but used more temporary memory and more memory bandwidth.
// In any given situation the correct choice can be difficult to
// make. If you're memory-bandwidth limited, or don't have much
// memory (e.g. because you're running on an old cell-phone), then
// it can make sense to do redundant math. On the other hand, sin
// is expensive, so if you're compute-limited then fewer calls to
// sin will make your program faster. Adding vectorization or
// multi-core parallelism tilts the scales in favor of doing
// redundant work, because firing up multiple cpu cores increases
// the amount of math you can do per second, but doesn't increase
// your system memory bandwidth or capacity.
// We can make choices in between full inlining and
// compute_root. Next we'll alternate between computing the
// producer and consumer on a per-scanline basis:
{
// Start with the same function definitions:
var producer = new HSFunc("producer_y");
var consumer = new HSFunc("consumer_y");
producer[x, y] = HSMath.Sin(x * y);
consumer[x, y] = (producer[x, y] +
producer[x, y + 1] +
producer[x + 1, y] +
producer[x + 1, y + 1]) / 4;
// Tell Halide to evaluate producer as needed per y coordinate
// of the consumer:
producer.ComputeAt(consumer, y);
// This places the code that computes the producer just
// *inside* the consumer's for loop over y, as in the
// equivalent C below.
// Turn on tracing.
producer.TraceStores();
consumer.TraceStores();
// Compile and run.
Console.WriteLine("\nEvaluating producer.ComputeAt(consumer, y)");
consumer.Realize <float>(4, 4);
// See figures/lesson_08_compute_y.gif for a visualization.
// Reading the log or looking at the figure you should see
// that producer and consumer alternate on a per-scanline
// basis. Let's look at the equivalent C:
var result = new float[4, 4];
// There's an outer loop over scanlines of consumer:
for (int yy = 0; yy < 4; yy++)
{
// Allocate space and compute enough of the producer to
// satisfy this single scanline of the consumer. This
// means a 5x2 box of the producer.
var producer_storage = new float[2, 5];
for (int py = yy; py < yy + 2; py++)
{
for (int px = 0; px < 5; px++)
{
producer_storage[py - yy, px] = (float)Math.Sin(px * py);
}
}
// Compute a scanline of the consumer.
for (int xx = 0; xx < 4; xx++)
{
result[yy, xx] = (producer_storage[0, xx] +
producer_storage[1, xx] +
producer_storage[0, xx + 1] +
producer_storage[1, xx + 1]) / 4;
}
}
// Again, if we print the loop nest, we'll see something very
// similar to the C above.
Console.WriteLine("Pseudo-code for the schedule:");
consumer.PrintLoopNest();
Console.WriteLine();
// The performance characteristics of this strategy are in
// between inlining and compute root. We still allocate some
// temporary memory, but less that compute_root, and with
// better locality (we load from it soon after writing to it,
// so for larger images, values should still be in cache). We
// still do some redundant work, but less than full inlining:
// producer.ComputeAt(consumer, y):
// - Temporary memory allocated: 10 floats
// - Loads: 64
// - Stores: 56
// - Calls to sin: 40
}
// We could also say producer.ComputeAt(consumer, x), but this
// would be very similar to full inlining (the default
// schedule). Instead let's distinguish between the loop level at
// which we allocate storage for producer, and the loop level at
// which we actually compute it. This unlocks a few optimizations.
{
var producer = new HSFunc("producer_root_y");
var consumer = new HSFunc("consumer_root_y");
producer[x, y] = HSMath.Sin(x * y);
consumer[x, y] = (producer[x, y] +
producer[x, y + 1] +
producer[x + 1, y] +
producer[x + 1, y + 1]) / 4;
// Tell Halide to make a buffer to store all of producer at
// the outermost level:
producer.StoreRoot();
// ... but compute it as needed per y coordinate of the
// consumer.
producer.ComputeAt(consumer, y);
producer.TraceStores();
consumer.TraceStores();
Console.WriteLine("\nEvaluating producer.store_root().ComputeAt(consumer, y)");
consumer.Realize <float>(4, 4);
// See figures/lesson_08_store_root_compute_y.gif for a
// visualization.
// Reading the log or looking at the figure you should see
// that producer and consumer again alternate on a
// per-scanline basis. It computes a 5x2 box of the producer
// to satisfy the first scanline of the consumer, but after
// that it only computes a 5x1 box of the output for each new
// scanline of the consumer!
//
// Halide has detected that for all scanlines except for the
// first, it can reuse the values already sitting in the
// buffer we've allocated for producer. Let's look at the
// equivalent C:
var result = new float[4, 4];
{
// producer.store_root() implies that storage goes here:
var producer_storage = new float[5, 5];
// There's an outer loop over scanlines of consumer:
for (int yy = 0; yy < 4; yy++)
{
// Compute enough of the producer to satisfy this scanline
// of the consumer.
for (int py = yy; py < yy + 2; py++)
{
// Skip over rows of producer that we've already
// computed in a previous iteration.
if (yy > 0 && py == yy)
{
continue;
}
for (int px = 0; px < 5; px++)
{
producer_storage[py, px] = (float)Math.Sin(px * py);
}
}
// Compute a scanline of the consumer.
for (int xx = 0; xx < 4; xx++)
{
result[yy, xx] = (producer_storage[yy, xx] +
producer_storage[yy + 1, xx] +
producer_storage[yy, xx + 1] +
producer_storage[yy + 1, xx + 1]) / 4;
}
}
}
Console.WriteLine("Pseudo-code for the schedule:");
consumer.PrintLoopNest();
Console.WriteLine();
// The performance characteristics of this strategy are pretty
// good! The numbers are similar compute_root, except locality
// is better. We're doing the minimum number of sin calls,
// and we load values soon after they are stored, so we're
// probably making good use of the cache:
// producer.store_root().ComputeAt(consumer, y):
// - Temporary memory allocated: 10 floats
// - Loads: 64
// - Stores: 39
// - Calls to sin: 25
// Note that my claimed amount of memory allocated doesn't
// match the reference C code. Halide is performing one more
// optimization under the hood. It folds the storage for the
// producer down into a circular buffer of two
// scanlines. Equivalent C would actually look like this:
{
// Actually store 2 scanlines instead of 5
var producer_storage = new float[2, 5];
for (int yy = 0; yy < 4; yy++)
{
for (int py = yy; py < yy + 2; py++)
{
if (yy > 0 && py == yy)
{
continue;
}
for (int px = 0; px < 5; px++)
{
// Stores to producer_storage have their y coordinate bit-masked.
producer_storage[py & 1, px] = (float)Math.Sin(px * py);
}
}
// Compute a scanline of the consumer.
for (int xx = 0; xx < 4; xx++)
{
// Loads from producer_storage have their y coordinate bit-masked.
result[yy, xx] = (producer_storage[yy & 1, xx] +
producer_storage[(yy + 1) & 1, xx] +
producer_storage[yy & 1, xx + 1] +
producer_storage[(yy + 1) & 1, xx + 1]) / 4;
}
}
}
}
// We can do even better, by leaving the storage outermost, but
// moving the computation into the innermost loop:
{
var producer = new HSFunc("producer_root_x");
var consumer = new HSFunc("consumer_root_x");
producer[x, y] = HSMath.Sin(x * y);
consumer[x, y] = (producer[x, y] +
producer[x, y + 1] +
producer[x + 1, y] +
producer[x + 1, y + 1]) / 4;
// Store outermost, compute innermost.
producer.StoreRoot().ComputeAt(consumer, x);
producer.TraceStores();
consumer.TraceStores();
Console.WriteLine("\nEvaluating producer.store_root().ComputeAt(consumer, x)");
consumer.Realize <float>(4, 4);
// See figures/lesson_08_store_root_compute_x.gif for a
// visualization.
// You should see that producer and consumer now alternate on
// a per-pixel basis. Here's the equivalent C:
var result = new float[4, 4];
// producer.store_root() implies that storage goes here, but
// we can fold it down into a circular buffer of two
// scanlines:
var producer_storage = new float[2, 5];
// For every pixel of the consumer:
for (int yy = 0; yy < 4; yy++)
{
for (int xx = 0; xx < 4; xx++)
{
// Compute enough of the producer to satisfy this
// pixel of the consumer, but skip values that we've
// already computed:
if (yy == 0 && xx == 0)
{
producer_storage[yy & 1, xx] = (float)Math.Sin(xx * yy);
}
if (yy == 0)
{
producer_storage[yy & 1, xx + 1] = (float)Math.Sin((xx + 1) * yy);
}
if (xx == 0)
{
producer_storage[(yy + 1) & 1, xx] = (float)Math.Sin(xx * (yy + 1));
}
producer_storage[(yy + 1) & 1, xx + 1] = (float)Math.Sin((xx + 1) * (yy + 1));
result[yy, xx] = (producer_storage[yy & 1, xx] +
producer_storage[(yy + 1) & 1, xx] +
producer_storage[yy & 1, xx + 1] +
producer_storage[(yy + 1) & 1, xx + 1]) / 4;
}
}
Console.WriteLine("Pseudo-code for the schedule:");
consumer.PrintLoopNest();
Console.WriteLine();
// The performance characteristics of this strategy are the
// best so far. One of the four values of the producer we need
// is probably still sitting in a register, so I won't count
// it as a load:
// producer.store_root().ComputeAt(consumer, x):
// - Temporary memory allocated: 10 floats
// - Loads: 48
// - Stores: 56
// - Calls to sin: 40
}
// So what's the catch? Why not always do
// producer.store_root().ComputeAt(consumer, x) for this type of
// code?
//
// The answer is parallelism. In both of the previous two
// strategies we've assumed that values computed on previous
// iterations are lying around for us to reuse. This assumes that
// previous values of x or y happened earlier in time and have
// finished. This is not true if you parallelize or vectorize
// either loop. Darn. If you parallelize, Halide won't inject the
// optimizations that skip work already done if there's a parallel
// loop in between the store_at level and the ComputeAt level,
// and won't fold the storage down into a circular buffer either,
// which makes our store_root pointless.
// We're running out of options. We can make new ones by
// splitting. We can store_at or ComputeAt at the natural
// variables of the consumer (x and y), or we can split x or y
// into new inner and outer sub-variables and then schedule with
// respect to those. We'll use this to express fusion in tiles:
{
var producer = new HSFunc("producer_tile");
var consumer = new HSFunc("consumer_tile");
producer[x, y] = HSMath.Sin(x * y);
consumer[x, y] = (producer[x, y] +
producer[x, y + 1] +
producer[x + 1, y] +
producer[x + 1, y + 1]) / 4;
// We'll compute 8x8 of the consumer, in 4x4 tiles.
var x_outer = new HSVar("x_outer");
var y_outer = new HSVar("y_outer");
var x_inner = new HSVar("x_inner");
var y_inner = new HSVar("y_inner");
consumer.Tile(x, y, x_outer, y_outer, x_inner, y_inner, 4, 4);
// Compute the producer per tile of the consumer
producer.ComputeAt(consumer, x_outer);
// Notice that I wrote my schedule starting from the end of
// the pipeline (the consumer). This is because the schedule
// for the producer refers to x_outer, which we introduced
// when we tiled the consumer. You can write it in the other
// order, but it tends to be harder to read.
// Turn on tracing.
producer.TraceStores();
consumer.TraceStores();
Console.WriteLine("\nEvaluating:");
Console.WriteLine("consumer.tile(x, y, x_outer, y_outer, x_inner, y_inner, 4, 4);");
Console.WriteLine("producer.ComputeAt(consumer, x_outer);");
consumer.Realize <float>(8, 8);
// See figures/lesson_08_tile.gif for a visualization.
// The producer and consumer now alternate on a per-tile
// basis. Here's the equivalent C:
var result = new float[8, 8];
// For every tile of the consumer:
for (int yy_outer = 0; yy_outer < 2; yy_outer++)
{
for (int xx_outer = 0; xx_outer < 2; xx_outer++)
{
// Compute the x and y coords of the start of this tile.
int x_base = xx_outer * 4;
int y_base = yy_outer * 4;
// Compute enough of producer to satisfy this tile. A
// 4x4 tile of the consumer requires a 5x5 tile of the
// producer.
var producer_storage = new float[5, 5];
for (int py = y_base; py < y_base + 5; py++)
{
for (int px = x_base; px < x_base + 5; px++)
{
producer_storage[py - y_base, px - x_base] = (float)Math.Sin(px * py);
}
}
// Compute this tile of the consumer
for (int yy_inner = 0; yy_inner < 4; yy_inner++)
{
for (int xx_inner = 0; xx_inner < 4; xx_inner++)
{
int xx = x_base + xx_inner;
int yy = y_base + yy_inner;
result[yy, xx] =
(producer_storage[yy - y_base, xx - x_base] +
producer_storage[yy - y_base + 1, xx - x_base] +
producer_storage[yy - y_base, xx - x_base + 1] +
producer_storage[yy - y_base + 1, xx - x_base + 1]) / 4;
}
}
}
}
Console.WriteLine("Pseudo-code for the schedule:");
consumer.PrintLoopNest();
Console.WriteLine();
// Tiling can make sense for problems like this one with
// stencils that reach outwards in x and y. Each tile can be
// computed independently in parallel, and the redundant work
// done by each tile isn't so bad once the tiles get large
// enough.
}
// Let's try a mixed strategy that combines what we have done with
// splitting, parallelizing, and vectorizing. This is one that
// often works well in practice for large images. If you
// understand this schedule, then you understand 95% of scheduling
// in Halide.
{
var producer = new HSFunc("producer_mixed");
var consumer = new HSFunc("consumer_mixed");
producer[x, y] = HSMath.Sin(x * y);
consumer[x, y] = (producer[x, y] +
producer[x, y + 1] +
producer[x + 1, y] +
producer[x + 1, y + 1]) / 4;
// Split the y coordinate of the consumer into strips of 16 scanlines:
var yo = new HSVar("yo");
var yi = new HSVar("yi");
consumer.Split(y, yo, yi, 16);
// Compute the strips using a thread pool and a task queue.
consumer.Parallel(yo);
// Vectorize across x by a factor of four.
consumer.Vectorize(x, 4);
// Now store the producer per-strip. This will be 17 scanlines
// of the producer (16+1), but hopefully it will fold down
// into a circular buffer of two scanlines:
producer.StoreAt(consumer, yo);
// Within each strip, compute the producer per scanline of the
// consumer, skipping work done on previous scanlines.
producer.ComputeAt(consumer, yi);
// Also vectorize the producer (because sin is vectorizable on x86 using SSE).
producer.Vectorize(x, 4);
// Let's leave tracing off this time, because we're going to
// evaluate over a larger image.
// consumer.TraceStores();
// producer.TraceStores();
var halide_result = consumer.Realize <float>(160, 160);
// See figures/lesson_08_mixed.mp4 for a visualization.
// Here's the equivalent (serial) C:
var c_result = new float[160, 160];
// For every strip of 16 scanlines (this loop is parallel in
// the Halide version)
for (int yyo = 0; yyo < 160 / 16 + 1; yyo++)
{
// 16 doesn't divide 160, so push the last slice upwards
// to fit within [0, 159] (see lesson 05).
int y_base = yyo * 16;
if (y_base > 160 - 16)
{
y_base = 160 - 16;
}
// Allocate a two-scanline circular buffer for the producer
var producer_storage = new float[2, 161];
// For every scanline in the strip of 16:
for (int yyi = 0; yyi < 16; yyi++)
{
int yy = y_base + yyi;
for (int py = yy; py < yy + 2; py++)
{
// Skip scanlines already computed *within this task*
if (yyi > 0 && py == yy)
{
continue;
}
// Compute this scanline of the producer in 4-wide vectors
for (int x_vec = 0; x_vec < 160 / 4 + 1; x_vec++)
{
int x_base = x_vec * 4;
// 4 doesn't divide 161, so push the last vector left
// (see lesson 05).
if (x_base > 161 - 4)
{
x_base = 161 - 4;
}
// If you're on x86, Halide generates SSE code for this part:
int[] xx = { x_base, x_base + 1, x_base + 2, x_base + 3 };
float[] vec = { (float)Math.Sin(xx[0] * py), (float)Math.Sin(xx[1] * py),
(float)Math.Sin(xx[2] * py), (float)Math.Sin(xx[3] * py) };
producer_storage[py & 1, xx[0]] = vec[0];
producer_storage[py & 1, xx[1]] = vec[1];
producer_storage[py & 1, xx[2]] = vec[2];
producer_storage[py & 1, xx[3]] = vec[3];
}
}
// Now compute consumer for this scanline:
for (int x_vec = 0; x_vec < 160 / 4; x_vec++)
{
int x_base = x_vec * 4;
// Again, Halide's equivalent here uses SSE.
int[] xx = { x_base, x_base + 1, x_base + 2, x_base + 3 };
float[] vec =
{
(producer_storage[yy & 1, xx[0]] +
producer_storage[(yy + 1) & 1, xx[0]] +
producer_storage[yy & 1, xx[0] + 1] +
producer_storage[(yy + 1) & 1, xx[0] + 1]) / 4,
(producer_storage[yy & 1, xx[1]] +
producer_storage[(yy + 1) & 1, xx[1]] +
producer_storage[yy & 1, xx[1] + 1] +
producer_storage[(yy + 1) & 1, xx[1] + 1]) / 4,
(producer_storage[yy & 1, xx[2]] +
producer_storage[(yy + 1) & 1, xx[2]] +
producer_storage[yy & 1, xx[2] + 1] +
producer_storage[(yy + 1) & 1, xx[2] + 1]) / 4,
(producer_storage[yy & 1, xx[3]] +
producer_storage[(yy + 1) & 1, xx[3]] +
producer_storage[yy & 1, xx[3] + 1] +
producer_storage[(yy + 1) & 1, xx[3] + 1]) / 4
};
c_result[yy, xx[0]] = vec[0];
c_result[yy, xx[1]] = vec[1];
c_result[yy, xx[2]] = vec[2];
c_result[yy, xx[3]] = vec[3];
}
}
}
Console.WriteLine("Pseudo-code for the schedule:");
consumer.PrintLoopNest();
Console.WriteLine();
// Look on my code, ye mighty, and despair!
// Let's check the C result against the Halide result. Doing
// this I found several bugs in my C implementation, which
// should tell you something.
for (int yy = 0; yy < 160; yy++)
{
for (int xx = 0; xx < 160; xx++)
{
float error = halide_result[xx, yy] - c_result[yy, xx];
// It's floating-point math, so we'll allow some slop:
if (error < -0.001f || error > 0.001f)
{
Console.WriteLine("halide_result(%d, %d) = %f instead of %f",
xx, yy, halide_result[xx, yy], c_result[yy, xx]);
return(-1);
}
}
}
}
// This stuff is hard. We ended up in a three-way trade-off
// between memory bandwidth, redundant work, and
// parallelism. Halide can't make the correct choice for you
// automatically (sorry). Instead it tries to make it easier for
// you to explore various options, without messing up your
// program. In fact, Halide promises that scheduling calls like
// compute_root won't change the meaning of your algorithm -- you
// should get the same bits back no matter how you schedule
// things.
// So be empirical! Experiment with various schedules and keep a
// log of performance. Form hypotheses and then try to prove
// yourself wrong. Don't assume that you just need to vectorize
// your code by a factor of four and run it on eight cores and
// you'll get 32x faster. This almost never works. Modern systems
// are complex enough that you can't predict performance reliably
// without running your code.
// We suggest you start by scheduling all of your non-trivial
// stages compute_root, and then work from the end of the pipeline
// upwards, inlining, parallelizing, and vectorizing each stage in
// turn until you reach the top.
// Halide is not just about vectorizing and parallelizing your
// code. That's not enough to get you very far. Halide is about
// giving you tools that help you quickly explore different
// trade-offs between locality, redundant work, and parallelism,
// without messing up the actual result you're trying to compute.
Console.WriteLine("Success!");
return(0);
}
public static int Main(string[] args)
{
// This program defines a single-stage imaging pipeline that
// brightens an image.
// First we'll load the input image we wish to brighten.
var input = HSBuffer <byte> .LoadImage("rgb.png");
// See figures/lesson_02_input.jpg for a smaller version.
// Next we define our Func object that represents our one pipeline
// stage.
var brighter = new HSFunc("brighter");
// Our Func will have three arguments, representing the position
// in the image and the color channel. Halide treats color
// channels as an extra dimension of the image.
var x = new HSVar("x");
var y = new HSVar("y");
var c = new HSVar("c");
// Normally we'd probably write the whole function definition on
// one line. Here we'll break it apart so we can explain what
// we're doing at every step.
// For each pixel of the input image.
var value = input[x, y, c];
// Cast it to a floating point value.
value = HS.Cast <float>(value);
// Multiply it by 1.5 to brighten it. Halide represents real
// numbers as floats, not doubles, so we stick an 'f' on the end
// of our constant.
value = value * 1.5f;
// Clamp it to be less than 255, so we don't get overflow when we
// cast it back to an 8-bit unsigned int.
value = HSMath.Min(value, 255.0f);
// Cast it back to an 8-bit unsigned integer.
value = HS.Cast <byte>(value);
// Define the function.
brighter[x, y, c] = value;
// The equivalent one-liner to all of the above is:
//
// brighter(x, y, c) = Halide::cast<uint8_t>(min(input(x, y, c) * 1.5f, 255));
//
// In the shorter version:
// - I skipped the cast to float, because multiplying by 1.5f does
// that automatically.
// - I also used an integer constant as the second argument in the
// call to min, because it gets cast to float to be compatible
// with the first argument.
// - I left the Halide:: off the call to min. It's unnecessary due
// to Koenig lookup.
// Remember, all we've done so far is build a representation of a
// Halide program in memory. We haven't actually processed any
// pixels yet. We haven't even compiled that Halide program yet.
// So now we'll realize the Func. The size of the output image
// should match the size of the input image. If we just wanted to
// brighten a portion of the input image we could request a
// smaller size. If we request a larger size Halide will throw an
// error at runtime telling us we're trying to read out of bounds
// on the input image.
var output =
brighter.Realize <byte>(input.Width, input.Height, input.Channels);
// Save the output for inspection. It should look like a bright parrot.
output.SaveImage("brighter.png");
// See figures/lesson_02_output.jpg for a small version of the output.
Console.WriteLine("Success!");
return(0);
}
public static int Main(string[] args)
{
var x = new HSVar("x");
var y = new HSVar("y");
// Printing out the value of Funcs as they are computed.
{
// We'll define our gradient function as before.
var gradient = new HSFunc("gradient");
gradient[x, y] = x + y;
// And tell Halide that we'd like to be notified of all
// evaluations.
gradient.TraceStores();
// Realize the function over an 8x8 region.
Console.WriteLine("Evaluating gradient");
var output = gradient.Realize <int>(8, 8);
// Click to show output ...
// This will print out all the times gradient(x, y) gets
// evaluated.
// Now that we can snoop on what Halide is doing, let's try our
// first scheduling primitive. We'll make a new version of
// gradient that processes each scanline in parallel.
var parallel_gradient = new HSFunc("parallel_gradient");
parallel_gradient[x, y] = x + y;
// We'll also trace this function.
parallel_gradient.TraceStores();
// Things are the same so far. We've defined the algorithm, but
// haven't said anything about how to schedule it. In general,
// exploring different scheduling decisions doesn't change the code
// that describes the algorithm.
// Now we tell Halide to use a parallel for loop over the y
// coordinate. On Linux we run this using a thread pool and a task
// queue. On OS X we call into grand central dispatch, which does
// the same thing for us.
parallel_gradient.Parallel(y);
// This time the printfs should come out of order, because each
// scanline is potentially being processed in a different
// thread. The number of threads should adapt to your system, but
// on linux you can control it manually using the environment
// variable HL_NUM_THREADS.
Console.WriteLine("\nEvaluating parallel_gradient");
parallel_gradient.Realize <int>(8, 8);
// Click to show output ...
}
// Printing individual Exprs.
{
// trace_stores() can only print the value of a
// Func. Sometimes you want to inspect the value of
// sub-expressions rather than the entire Func. The built-in
// function 'print' can be wrapped around any Expr to print
// the value of that Expr every time it is evaluated.
// For example, say we have some Func that is the sum of two terms:
var f = new HSFunc("f");
f[x, y] = HSMath.Sin(x) + HSMath.Cos(y);
// If we want to inspect just one of the terms, we can wrap
// 'print' around it like so:
var g = new HSFunc("g");
g[x, y] = HSMath.Sin(x) + HS.Print(HSMath.Cos(y));
Console.WriteLine("\nEvaluating sin(x) + cos(y), and just printing cos(y)");
g.Realize <float>(4, 4);
// Click to show output ...
}
// Printing additional context.
{
// print can take multiple arguments. It prints all of them
// and evaluates to the first one. The arguments can be Exprs
// or constant strings. This can be used to print additional
// context alongside the value:
var f = new HSFunc("f");
f[x, y] = HSMath.Sin(x) + HS.Print(HSMath.Cos(y), "<- this is cos(", y, ") when x =", x);
Console.WriteLine("\nEvaluating sin(x) + cos(y), and printing cos(y) with more context");
f.Realize <float>(4, 4);
// Click to show output ...
// It can be useful to split expressions like the one above
// across multiple lines to make it easier to turn on and off
// printing certain values while debugging.
HSExpr e = HSMath.Cos(y);
// Uncomment the following line to print the value of cos(y)
// e = print(e, "<- this is cos(", y, ") when x =", x);
var g = new HSFunc("g");
g[x, y] = HSMath.Sin(x) + e;
g.Realize <float>(4, 4);
}
// Conditional printing
{
// Both print and trace_stores can produce a lot of output. If
// you're looking for a rare event, or just want to see what
// happens at a single pixel, this amount of output can be
// difficult to dig through. Instead, the function print_when
// can be used to conditionally print an Expr. The first
// argument to print_when is a boolean Expr. If the Expr
// evaluates to true, it returns the second argument and
// prints all of the arguments. If the Expr evaluates to false
// it just returns the second argument and does not print.
var f = new HSFunc("f");
HSExpr e = HSMath.Cos(y);
e = HS.PrintWhen(x == 37 && y == 42, e, "<- this is cos(y) at x, y == (37, 42)");
f[x, y] = HSMath.Sin(x) + e;
Console.WriteLine("\nEvaluating sin(x) + cos(y), and printing cos(y) at a single pixel");
f.Realize <float>(640, 480);
// Click to show output ...
// print_when can also be used to check for values you're not expecting:
var g = new HSFunc("g");
e = HSMath.Cos(y);
e = HS.PrintWhen(e < 0, e, "cos(y) < 0 at y ==", y);
g[x, y] = HSMath.Sin(x) + e;
Console.WriteLine("\nEvaluating sin(x) + cos(y), and printing whenever cos(y) < 0");
g.Realize <float>(4, 4);
// Click to show output ...
}
// Printing expressions at compile-time.
{
// The code above builds up a Halide Expr across several lines
// of code. If you're programmatically constructing a complex
// expression, and you want to check the Expr you've created
// is what you think it is, you can also print out the
// expression itself using C++ streams:
var fizz = new HSVar("fizz");
var buzz = new HSVar("buzz");
var e = new HSExpr(1);
for (int i = 2; i < 100; i++)
{
if (i % 3 == 0 && i % 5 == 0)
{
e += fizz * buzz;
}
else if (i % 3 == 0)
{
e += fizz;
}
else if (i % 5 == 0)
{
e += buzz;
}
else
{
e += i;
}
}
Console.WriteLine($"Printing a complex Expr: {e}");
// Click to show output ...
}
Console.WriteLine("Success!");
return(0);
}