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Upgrade v0.3.X to v0.5.X
The ArrayView
and VariableView
structures have been adapted to the C# 'ref' features.
This renders explicit Load
and Store
methods obsolete.
In addition, all methods that accept VariableView<X>
parameter types have been adapted to the parameter types ref X
.
This applies, for example, to all methods of the class Atomic
.
class ...
{
static void ...(...)
{
// Old way (obsolete and no longer supported)
ArrayView<int> someView = ...
var variableView = someView.GetVariableView(X);
Atomic.Add(variableView);
...
variableView.Store(42);
// New way
ArrayView<int> someView = ...
Atomic.Add(ref someView[X]);
...
someView[X] = 42;
// or
ref var variable = ref someView[X];
variable = 42;
// or
var variableView = someView.GetVariableView(X);
variableView.Value = 42;
}
}
The general concept of shared memory has been redesigned.
The previous model required SharedMemoryAttribute
attributes on specific parameters that should be allocated in shared memory.
The new model uses the static class SharedMemory
to allocate this kind of memory procedurally in the scope of kernels.
This simplifies programming, kernel-delegate creation and enables non-kernel methods to allocate their own pool of shared memory.
Note that array lengths must be constants in this ILGPU version. Hence, a dynamic allocation of shared memory is currently not supported.
The kernel loader methods LoadSharedMemoryKernelX
and LoadSharedMemoryStreamKernelX
have been removed.
They are no longer required, since a kernel does not have to declare its shared memory allocations in the form of additional parameters.
class ...
{
static void SharedMemoryKernel(GroupedIndex index, ...)
{
// Allocate an array of 32 integers
ArrayView<int> sharedMemoryArray = SharedMemory.Allocate<int>(32);
// Allocate a single variable of type long in shared memory
ref long sharedMemoryVariable = ref SharedMemory.Allocate<long>();
...
}
}
Starting a kernel in debug mode is a common task that developers go through many times a day.
Although ILGPU has been optimized for performance, you may not wait a few milliseconds every time you start your program to debug a kernel on the CPU.
For this reason, the context flag ContextFlags.SkipCPUCodeGeneration
has been added.
It suppresses IR code generation for CPU kernels and uses the .Net runtime directly.
Warning: This avoids general kernel analysis/verification checks. It should only be used by experienced users.
The old LLVM-based concept of CompileUnit
objects is obsolete and has been replaced by a completely new IR.
The new IR leverages IRContext
objects to manage IR objects that are derived from the class ILGPU.IR.Node
.
Unlike previous versions, an IRContext
is not tied to a specific Backend
instance and can be reused accross different hardware architectures.
The global optimization process can be controlled with the enumeration OptimizationLevel
.
This level can be specified by passing the desired level to the ILGPU.Context
constructor.
If the optimization level is not explicitly specified, the level is determined by the current build mode (either Debug
or Release
).