mirror of
https://github.com/RPCS3/llvm-mirror.git
synced 2024-11-24 03:33:20 +01:00
220 lines
9.2 KiB
ReStructuredText
220 lines
9.2 KiB
ReStructuredText
.. _gmir:
|
|
|
|
Generic Machine IR
|
|
==================
|
|
|
|
.. contents::
|
|
:local:
|
|
|
|
Generic MIR (gMIR) is an intermediate representation that shares the same data
|
|
structures as :doc:`MachineIR (MIR) <../MIRLangRef>` but has more relaxed
|
|
constraints. As the compilation pipeline proceeds, these constraints are
|
|
gradually tightened until gMIR has become MIR.
|
|
|
|
The rest of this document will assume that you are familiar with the concepts
|
|
in :doc:`MachineIR (MIR) <../MIRLangRef>` and will highlight the differences
|
|
between MIR and gMIR.
|
|
|
|
.. _gmir-instructions:
|
|
|
|
Generic Machine Instructions
|
|
----------------------------
|
|
|
|
.. note::
|
|
|
|
This section expands on :ref:`mir-instructions` from the MIR Language
|
|
Reference.
|
|
|
|
Whereas MIR deals largely in Target Instructions and only has a small set of
|
|
target independent opcodes such as ``COPY``, ``PHI``, and ``REG_SEQUENCE``,
|
|
gMIR defines a rich collection of ``Generic Opcodes`` which are target
|
|
independent and describe operations which are typically supported by targets.
|
|
One example is ``G_ADD`` which is the generic opcode for an integer addition.
|
|
More information on each of the generic opcodes can be found at
|
|
:doc:`GenericOpcode`.
|
|
|
|
The ``MachineIRBuilder`` class wraps the ``MachineInstrBuilder`` and provides
|
|
a convenient way to create these generic instructions.
|
|
|
|
.. _gmir-gvregs:
|
|
|
|
Generic Virtual Registers
|
|
-------------------------
|
|
|
|
.. note::
|
|
|
|
This section expands on :ref:`mir-registers` from the MIR Language
|
|
Reference.
|
|
|
|
Generic virtual registers are like virtual registers but they are not assigned a
|
|
Register Class constraint. Instead, generic virtual registers have less strict
|
|
constraints starting with a :ref:`gmir-llt` and then further constrained to a
|
|
:ref:`gmir-regbank`. Eventually they will be constrained to a register class
|
|
at which point they become normal virtual registers.
|
|
|
|
Generic virtual registers can be used with all the virtual register API's
|
|
provided by ``MachineRegisterInfo``. In particular, the def-use chain API's can
|
|
be used without needing to distinguish them from non-generic virtual registers.
|
|
|
|
For simplicity, most generic instructions only accept virtual registers (both
|
|
generic and non-generic). There are some exceptions to this but in general:
|
|
|
|
* instead of immediates, they use a generic virtual register defined by an
|
|
instruction that materializes the immediate value (see
|
|
:ref:`irtranslator-constants`). Typically this is a G_CONSTANT or a
|
|
G_FCONSTANT. One example of an exception to this rule is G_SEXT_INREG where
|
|
having an immediate is mandatory.
|
|
* instead of physical register, they use a generic virtual register that is
|
|
either defined by a ``COPY`` from the physical register or used by a ``COPY``
|
|
that defines the physical register.
|
|
|
|
.. admonition:: Historical Note
|
|
|
|
We started with an alternative representation, where MRI tracks a size for
|
|
each generic virtual register, and instructions have lists of types.
|
|
That had two flaws: the type and size are redundant, and there was no generic
|
|
way of getting a given operand's type (as there was no 1:1 mapping between
|
|
instruction types and operands).
|
|
We considered putting the type in some variant of MCInstrDesc instead:
|
|
See `PR26576 <https://llvm.org/PR26576>`_: [GlobalISel] Generic MachineInstrs
|
|
need a type but this increases the memory footprint of the related objects
|
|
|
|
.. _gmir-regbank:
|
|
|
|
Register Bank
|
|
-------------
|
|
|
|
A Register Bank is a set of register classes defined by the target. This
|
|
definition is rather loose so let's talk about what they can achieve.
|
|
|
|
Suppose we have a processor that has two register files, A and B. These are
|
|
equal in every way and support the same instructions for the same cost. They're
|
|
just physically stored apart and each instruction can only access registers from
|
|
A or B but never a mix of the two. If we want to perform an operation on data
|
|
that's in split between the two register files, we must first copy all the data
|
|
into a single register file.
|
|
|
|
Given a processor like this, we would benefit from clustering related data
|
|
together into one register file so that we minimize the cost of copying data
|
|
back and forth to satisfy the (possibly conflicting) requirements of all the
|
|
instructions. Register Banks are a means to constrain the register allocator to
|
|
use a particular register file for a virtual register.
|
|
|
|
In practice, register files A and B are rarely equal. They can typically store
|
|
the same data but there's usually some restrictions on what operations you can
|
|
do on each register file. A fairly common pattern is for one of them to be
|
|
accessible to integer operations and the other accessible to floating point
|
|
operations. To accommodate this, let's rename A and B to GPR (general purpose
|
|
registers) and FPR (floating point registers).
|
|
|
|
We now have some additional constraints that limit us. An operation like G_FMUL
|
|
has to happen in FPR and G_ADD has to happen in GPR. However, even though this
|
|
prescribes a lot of the assignments we still have some freedom. A G_LOAD can
|
|
happen in both GPR and FPR, and which we want depends on who is going to consume
|
|
the loaded data. Similarly, G_FNEG can happen in both GPR and FPR. If we assign
|
|
it to FPR, then we'll use floating point negation. However, if we assign it to
|
|
GPR then we can equivalently G_XOR the sign bit with 1 to invert it.
|
|
|
|
In summary, Register Banks are a means of disambiguating between seemingly
|
|
equivalent choices based on some analysis of the differences when each choice
|
|
is applied in a given context.
|
|
|
|
To give some concrete examples:
|
|
|
|
AArch64
|
|
|
|
AArch64 has three main banks. GPR for integer operations, FPR for floating
|
|
point and also for the NEON vector instruction set. The third is CCR and
|
|
describes the condition code register used for predication.
|
|
|
|
MIPS
|
|
|
|
MIPS has five main banks of which many programs only really use one or two.
|
|
GPR is the general purpose bank for integer operations. FGR or CP1 is for
|
|
the floating point operations as well as the MSA vector instructions and a
|
|
few other application specific extensions. CP0 is for system registers and
|
|
few programs will use it. CP2 and CP3 are for any application specific
|
|
coprocessors that may be present in the chip. Arguably, there is also a sixth
|
|
for the LO and HI registers but these are only used for the result of a few
|
|
operations and it's of questionable value to model distinctly from GPR.
|
|
|
|
X86
|
|
|
|
X86 can be seen as having 3 main banks: general-purpose, x87, and
|
|
vector (which could be further split into a bank per domain for single vs
|
|
double precision instructions). It also looks like there's arguably a few
|
|
more potential banks such as one for the AVX512 Mask Registers.
|
|
|
|
Register banks are described by a target-provided API,
|
|
:ref:`RegisterBankInfo <api-registerbankinfo>`.
|
|
|
|
.. _gmir-llt:
|
|
|
|
Low Level Type
|
|
--------------
|
|
|
|
Additionally, every generic virtual register has a type, represented by an
|
|
instance of the ``LLT`` class.
|
|
|
|
Like ``EVT``/``MVT``/``Type``, it has no distinction between unsigned and signed
|
|
integer types. Furthermore, it also has no distinction between integer and
|
|
floating-point types: it mainly conveys absolutely necessary information, such
|
|
as size and number of vector lanes:
|
|
|
|
* ``sN`` for scalars
|
|
* ``pN`` for pointers
|
|
* ``<N x sM>`` for vectors
|
|
|
|
``LLT`` is intended to replace the usage of ``EVT`` in SelectionDAG.
|
|
|
|
Here are some LLT examples and their ``EVT`` and ``Type`` equivalents:
|
|
|
|
============= ========= ======================================
|
|
LLT EVT IR Type
|
|
============= ========= ======================================
|
|
``s1`` ``i1`` ``i1``
|
|
``s8`` ``i8`` ``i8``
|
|
``s32`` ``i32`` ``i32``
|
|
``s32`` ``f32`` ``float``
|
|
``s17`` ``i17`` ``i17``
|
|
``s16`` N/A ``{i8, i8}`` [#abi-dependent]_
|
|
``s32`` N/A ``[4 x i8]`` [#abi-dependent]_
|
|
``p0`` ``iPTR`` ``i8*``, ``i32*``, ``%opaque*``
|
|
``p2`` ``iPTR`` ``i8 addrspace(2)*``
|
|
``<4 x s32>`` ``v4f32`` ``<4 x float>``
|
|
``s64`` ``v1f64`` ``<1 x double>``
|
|
``<3 x s32>`` ``v3i32`` ``<3 x i32>``
|
|
============= ========= ======================================
|
|
|
|
|
|
Rationale: instructions already encode a specific interpretation of types
|
|
(e.g., ``add`` vs. ``fadd``, or ``sdiv`` vs. ``udiv``). Also encoding that
|
|
information in the type system requires introducing bitcast with no real
|
|
advantage for the selector.
|
|
|
|
Pointer types are distinguished by address space. This matches IR, as opposed
|
|
to SelectionDAG where address space is an attribute on operations.
|
|
This representation better supports pointers having different sizes depending
|
|
on their addressspace.
|
|
|
|
.. note::
|
|
|
|
.. caution::
|
|
|
|
Is this still true? I thought we'd removed the 1-element vector concept.
|
|
Hypothetically, it could be distinct from a scalar but I think we failed to
|
|
find a real occurrence.
|
|
|
|
Currently, LLT requires at least 2 elements in vectors, but some targets have
|
|
the concept of a '1-element vector'. Representing them as their underlying
|
|
scalar type is a nice simplification.
|
|
|
|
.. rubric:: Footnotes
|
|
|
|
.. [#abi-dependent] This mapping is ABI dependent. Here we've assumed no additional padding is required.
|
|
|
|
Generic Opcode Reference
|
|
------------------------
|
|
|
|
The Generic Opcodes that are available are described at :doc:`GenericOpcode`.
|