This document describes the XLA aliasing API, which lets you specify the aliasing between the input and output buffers when building an XLA program.
Defining aliasing at compile-time
For example, consider a trivial HLO module which simply adds 1 to its input:
HloModule increment
ENTRY entry {
%p = f32[] parameter(0)
%c = f32[] constant(1)
ROOT %out = f32[] add(%p, %c)
}
This module will allocate two 4-byte buffers: one for the input %p, and one
for the output %out.
However, it is often desirable to perform the update in-place (for example, if
in the frontend generating the expression the input variable is no longer alive
after the computation, as in the increment p++).
To perform such an update efficiently, you can specify the input aliasing:
HloModule increment, input_output_alias={ {}: 0 }
ENTRY entry {
%p = f32[] parameter(0)
%c = f32[] constant(1)
ROOT %out = f32[] add(%p, %c)
}
The format specifies that the entire output (marked by {}) is aliased to the
input parameter 0.
To specify the aliasing programmatically, see the
XlaBuilder::SetUpAlias
API.
Defining aliasing at runtime
The aliasing defined in the previous step is specified during compilation.
During execution, you can use the
LocalClient::RunAsync
API to choose whether to donate the buffer.
Input buffers to the program are wrapped in
ExecutionInputs,
which in turn contain a tree of MaybeOwningDeviceMemory. If memory is
specified as owning (ownership of the buffer is passed to the XLA runtime),
the buffer is actually donated, and the update is executed in place, as
requested by the compile-time aliasing API.
If, however, the buffer that is aliased at compile time is not donated at
runtime, copy-protection kicks in: an extra output buffer O is allocated,
and the contents of the input buffer P that was meant to be aliased are copied
into O (so effectively the program can execute as if the buffer O was
donated at runtime).