Data Structure Registers
Contents
Data Structure Registers¶
Data Structure Registers (DSRs) are physical registers that are used to
store DSD values. Each DSR belongs to one of three DSR files, namely
the dest
, src0
and src1
DSR files. All DSD operations will
actually operate on DSRs behind the scenes and therefore, all DSD operands
to DSD operations must be loaded to DSRs before executing the respective
DSD operation.
Certain operations on DSRs require Extended DSRs (XDSRs). In this case, the DSRs are augmented by the use of an XDSR, a physical register belonging to a separate file.
The allocation of DSRs and XDSRs, and the loading of DSDs to DSRs, is typically done automatically by the compiler.
However, it is also possible to create and use DSRs and XDSRs directly. This chapter describes how users can allocate DSRs and XDSRs and then load DSDs to DSRs explicitly without the compiler’s assistance.
DSR Types¶
There are 5 types of DSRs supported in CSL, each corresponding to one of the three DSR files. These are the following:
dsr_dest
represents a DSR value that can only be used to store a destination operand to a DSD operation.dsr_src0
represents a DSR value that can be used to store a source as well as a destination operand to a DSD operation.dsr_src1
represents a DSR value that can be only be used to store a source operand to a DSD operation.dsr_fifo_dest
represents adsr_dest
DSR that is expected to store a FIFO (See _language-fifo-dsrs).dsr_fifo_src1
represents adsr_src1
DSR that is expected to store a FIFO.
XDSR values are represented by the xdsr
type.
FIFO DSR types¶
The dsr_fifo_dest
and dsr_fifo_src1
types can be used instead of
dsr_dest
and dsr_src1
, respectively, to represent DSRs that are
known to store a FIFO if one does not have access to a FIFO object. Like
FIFO objects, non-asynchronous DSD operations on FIFO DSRs will terminate
and return false
when reading from an empty FIFO or writing to a full
FIFO. Otherwise, FIFO DSR-typed values have the same semantics as the
corresponding non-FIFO DSR types.
Behavior is undefined if a FIFO DSR-typed value is not initialized as part of a FIFO when it is used in a DSD operation.
If a non-asynchronous DSD operation has a DSR operand that does not have FIFO DSR type, but that DSR holds a FIFO, behavior is undefined if that FIFO experiences a FIFO full or FIFO empty event. It is the programmer’s responsibility to avoid such FIFO full or FIFO empty events.
DSR Builtins¶
@get_dsr¶
Create a unique DSR identifier value. This value will uniquely identify a physical DSR along with its DSR file.
Syntax¶
@get_dsr(dsr_type, dsr_id);
@get_dsr(fifo_dsr_type, non_fifo_dsr);
Where:
dsr_type
is an expression of typetype
and whose value must be one of the DSR types.dsr_id
is a comptime-known expression of integer type.fifo_dsr_type
is an expression of typetype
whose value is one of the FIFO DSR types (dsr_fifo_dest
ordsr_fifo_src1
).non_fifo_dsr
is a comptime-known expression of a non-FIFO DSR type.Returns a value of
dsr_type
.
Example¶
const dsr1 = @get_dsr(dsr_dest, 0);
const dsr2 = @get_dsr(dsr_src0, 1);
const dsr3 = @get_dsr(dsr_src1, 6);
const dsr4 = @get_dsr(dsr_fifo_dest, 4);
const dsr5 = @get_dsr(dsr_fifo_src1, dsr3);
Semantics¶
Creates a unique DSR identifier value of dsr_type
type using the specified
integer identifier. This builtin must be evaluated at comptime. If the provided
integer identifier has already been used for the given DSR type or it is
outside the valid range of values for the given target architecture, then
an error will be emitted.
The type of non_fifo_dsr
must correspond to fifo_dsr_type
. If
fifo_dsr_type
is dsr_fifo_dest
, then non_fifo_dsr
must have
type dsr_dest
, and if fifo_dsr_type
is dsr_fifo_src1
, then
non_fifo_dsr
must have type dsr_src1
.
@get_xdsr¶
Create a unique XDSR identifier value. This value will uniquely identify a physical XDSR.
Syntax¶
@get_xdsr(xdsr_id);
Where:
xdsr_id
is a comptime-known expression of integer type.Returns a value of type
xdsr
.
Example¶
const my_xdsr = @get_xdsr(4);
Semantics¶
Creates a unique XDSR identifier value using the specified integer identifier. This builtin must be evaluated at comptime. If the provided integer identifier has already been used or it exceeds the valid range of values for the given target architecture, then an error will be emitted.
@load_to_dsr¶
Load a DSD value into a DSR.
Syntax¶
@load_to_dsr(dsr_value, dsd_value);
@load_to_dsr(dsr_value, dsd_value, config_struct);
Where:
dsr_value
a comptime-known expression of a DSR type.dsd_value
an expression of DSD type.config_struct
optional anonymous struct consisting of either of the following:Asynchronous configuration setting fields as explained in Asynchronous DSD Operations. These are allowed only for fabric DSDs. The supported settings are: *
async
*activate
*unblock
*on_control
The
save_address
setting field. This is allowed only formem1d
andmem4d
DSDs. See save_address for more details.
Example¶
const dsr1 = @get_dsr(dsr_dest, 0);
const dsr2 = @get_dsr(dsr_src0, 1);
fn foo(mem_dsd: mem1d_dsd, fab_dsd: fabin_dsd) void {
// Loads a memory DSD to a DSR.
@load_to_dsr(dsr1, mem_dsd);
// Loads a fabric DSD to a DSR while specifying that the
// input DSD is asynchronous with activation and on_control settings.
@load_to_dsr(dsr2, fab_dsd, .{.async = true,
.activate = callback,
.on_control = .{.terminate = true}});
}
const A = @zeros([10]f16);
const mem_dsd = @get_dsd(mem1d_dsd, .{.tensor_access = |i|{10} -> A[i]});
const fab_dsd = @get_dsd(fabin_dsd, .{.extent = 10,
.fabric_color = @get_color(0),
.input_queue = @get_input_queue(0)});
comptime {
// The DSD will be loaded to the DSR at comptime, i.e., before the
// program begins its execution.
@load_to_dsr(dsr1, mem_dsd);
// A fabric DSD with asynchronous properties will be loaded at comptime.
@load_to_dsr(dsr2, fab_dsd, .{.async = true,
.activate = callback,
.on_control = .{.terminate = true}});
}
Semantics¶
The @load_to_dsr
builtin can be called at comptime or runtime.
If it is called at runtime it will load the input DSD to the specified DSR at runtime.
If it is called at comptime, the specified DSD will be loaded to the DSR before the program begins executing.
A DSD of type fabin_dsd
cannot be loaded to a dsr_dest
DSR.
A DSD of type fabout_dsd
cannot be loaded to a dsr_src0
or
dsr_src1
DSRs.
FIFO DSRs are not permitted in @load_to_dsr
.
save_address¶
The save_address
option may be supplied to @load_to_dsr
if the DSD is
of the type mem1d_dsd
or mem4d_dsd
. This causes subsequent DSD
operations on the DSR to update the DSR’s base address for the outermost
(slowest-varying) dimension after termination to point one position past the
end of the range covered by the DSD operation. The next operation on the DSR
will effectively pick up where the previous one ended.
Example¶
const CHUNK_LENGTH = 4;
const N_CHUNKS = 3;
var chunks_in =
[CHUNK_LENGTH * N_CHUNKS]i16 {
0, 1, 2, 3,
4, 5, 6, 7,
8, 9, 10, 11
};
var chunks_out = @zeros(
[CHUNK_LENGTH * N_CHUNKS]i16
);
const chunks_in_dsd = @get_dsd(
mem1d_dsd,
.{ .tensor_access = |i|{CHUNK_LENGTH} -> chunks_in[i] }
);
const chunks_out_dsd = @get_dsd(
mem1d_dsd,
.{ .tensor_access = |i|{CHUNK_LENGTH} -> chunks_out[i] }
);
comptime {
@load_to_dsr(chunks_out_dsr, chunks_out_dsd, .{ .save_address = true });
@load_to_dsr(chunks_in_dsr, chunks_in_dsd, .{ .save_address = true });
}
task main() void {
//
// Each call to @mov16 will copy a chunk of size CHUNK_LENGTH, as
// specified in the .tensor_access expression. The base address for both
// the source and target operations will be incremented by CHUNK_LENGTH
// each time.
//
// Thus the following loop is semantically equivalent to:
//
// for (@range(i16, N_CHUNKS)) |i| {
// @mov16(chunks_out_dsr, chunks_in_dsr);
// @set_dsr_base_addr(chunks_out_dsr,
// &chunks_out[CHUNK_LENGTH * (i+1)]);
// @set_dsr_base_addr(chunks_in_dsr,
// &chunks_in[CHUNK_LENGTH * (i+1)]);
// }
//
for (@range(i16, N_CHUNKS)) |i| {
@mov16(chunks_out_dsr, chunks_in_dsr);
}
}
@allocate_fifo with DSRs¶
By default, the DSRs and XDSR used by @allocate_fifo
(see
FIFOs) are allocated by the compiler. However, it
supports the use of user-specified DSRs and XDSR as well, using the
following syntax:
@allocate_fifo(fifo_buffer, config_struct);
Where, in order to allocate a FIFO with user-specified DSRs and XDSR,
config_struct
must contain the fields:
* dest
: a comptime-known expression of dsr_dest
type.
* src
: a comptime-known expression of dsr_src1
type.
* xdsr
: a comptime-known expression of xdsr
type.
The fields dest
, src
, and xdsr
must all be specified together,
or all absent, otherwise an error will be emitted. The integer identifiers
of dest
and src
must match. If the provided DSR and XDSR
identifiers have already been used for their respective types or exceed
the valid range of values for the given target architecture, then an error
will be emitted.
Other fields of config_struct
described in
Task Activation on Pop and Push retain their same semantics
when the DSRs and XDSR are specified.
Example¶
var buf = @zeros([240]u16);
const my_fifo = @allocate_fifo(buf, .{
.dest = @get_dsr(dsr_dest, 4),
.src = @get_dsr(dsr_src1, 4),
.xdsr = @get_xdsr(1)});