opencv/venv/lib/python3.12/site-packages/jax/experimental/mosaic/gpu/mma.py

# Copyright 2025 The JAX Authors. All Rights Reserved.
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
#     http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
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# ==============================================================================

import itertools
from jax.experimental.mosaic.gpu import fragmented_array as fa
from jaxlib.mlir import ir
from jaxlib.mlir.dialects import llvm
from jaxlib.mlir.dialects import vector
import numpy as np
from . import utils


SUPPORTED_F8_TYPES = (ir.Float8E4M3FNType, ir.Float8E5M2Type)


class MMALayouts:
  """Container for MMA layouts, providing a convenient way to create
  layouts for MMA operands based on warp configuration.
  """

  def __init__(self, element_type: ir.Type):
    elems_per_reg = 32 // utils.bitwidth(element_type)
    k = 8 * elems_per_reg
    sub_k = 4 * elems_per_reg
    self.lhs = fa.TiledLayout(
        fa.Tiling(((64, k), (16, sub_k), (8, sub_k), (elems_per_reg,))),
        warp_dims=(-7,),
        lane_dims=(-3, -2),
        vector_dim=-1,
    )
    self.rhs = fa.TiledLayout(
        fa.Tiling(((8, k), (8, sub_k), (elems_per_reg,))),
        warp_dims=(fa.Replicated(4),),
        lane_dims=(-3, -2),
        vector_dim=-1,
    )
    self.acc = fa.TiledLayout(
        fa.Tiling(((64, 8), (16, 8), (8, 8), (2,))),
        warp_dims=(-7,),
        lane_dims=(-3, -2),
        vector_dim=-1,
    )


def _ptx_dtype_str(dtype: ir.Type, *, is_signed: bool | None = None) -> str:
  if isinstance(dtype, ir.Float8E4M3FNType):
    return "e4m3"
  elif isinstance(dtype, ir.Float8E5M2Type):
    return "e5m2"
  elif isinstance(dtype, ir.IntegerType):
    if is_signed is None:
      raise ValueError("is_signed must be specified for integer types")
    prefix = "s" if is_signed else "u"
    return f"{prefix}{dtype.width}"
  return str(dtype)


def _mma_single_tile(
    acc: fa.FragmentedArray, a: fa.FragmentedArray, b: fa.FragmentedArray
) -> fa.FragmentedArray:
  """Performs `acc + a @ b.T` using warp level MMA instructions."""
  i32 = ir.IntegerType.get_signless(32)

  k_tile = 256 // utils.bitwidth(a.mlir_dtype)
  assert a.shape == (64, k_tile)
  assert b.shape == (8, k_tile)
  assert acc.shape == (64, 8)
  assert a.mlir_dtype == b.mlir_dtype
  is_integer = isinstance(a.mlir_dtype, ir.IntegerType)
  assert acc.mlir_dtype == i32 if is_integer else ir.F32Type.get()
  assert acc.is_signed in {None, True}
  assert (
      isinstance(acc.layout, fa.TiledLayout)
      and isinstance(a.layout, fa.TiledLayout)
      and isinstance(b.layout, fa.TiledLayout)
  )
  num_acc_regs, num_a_regs, num_b_regs = 4, 4, 2

  acc_regs = [
      vector.extract(
          reg,
          dynamic_position=[],
          static_position=ir.DenseI64ArrayAttr.get([pos]),
      )
      for reg in acc.registers.flatten()
      for pos in range(acc.layout.vector_length)
  ]
  a_regs = [utils.bitcast(r, i32) for r in a.registers.flatten()]
  b_regs = [utils.bitcast(r, i32) for r in b.registers.flatten()]

  # Make sure we have the right number of registers for the instruction.
  assert len(a_regs) == 4
  assert len(acc_regs) == 4
  assert len(b_regs) == 2

  a_ptx_dtype = _ptx_dtype_str(a.mlir_dtype, is_signed=a.is_signed)
  b_ptx_dtype = _ptx_dtype_str(b.mlir_dtype, is_signed=b.is_signed)
  acc_ptx_dtype = "s32" if is_integer else "f32"
  acc_constraint = "r" if is_integer else "f"
  instr = f"mma.sync.aligned.m16n8k{k_tile}.row.col.{acc_ptx_dtype}.{a_ptx_dtype}.{b_ptx_dtype}.{acc_ptx_dtype}"
  counter = itertools.count()
  n_regs_str = lambda n: (
      "{" + ",".join([f"${next(counter)}" for _ in range(n)]) + "}"
  )
  out_regs_str = n_regs_str(num_acc_regs)
  a_regs_str = n_regs_str(num_a_regs)
  b_regs_str = n_regs_str(num_b_regs)
  c_regs_str = n_regs_str(num_acc_regs)
  ptx = f"{instr} {out_regs_str}, {a_regs_str}, {b_regs_str}, {c_regs_str};"
  # See: https://llvm.org/docs/LangRef.html#inline-assembler-expressions
  constraints = (
      f"{','.join([f'={acc_constraint}']*num_acc_regs)},"
      f"{','.join(['r']*num_a_regs)},"
      f"{','.join(['r']*num_b_regs)},"
      f"{','.join([acc_constraint]*num_acc_regs)}"
  )

  in_operands = [*a_regs, *b_regs, *acc_regs]
  acc_struct_type = ir.Type.parse(
      f"!llvm.struct<({','.join(str(acc.mlir_dtype) for _ in acc_regs)})>"
  )
  out_regs_struct = llvm.inline_asm(
      acc_struct_type,
      in_operands,
      ptx,
      constraints,
      has_side_effects=False,
  )
  assert isinstance(out_regs_struct, ir.Value)
  out_regs = [
      llvm.extractvalue(acc.mlir_dtype, out_regs_struct, [i])
      for i in range(len(acc_regs))
  ]
  vec_regs = []
  vec_undef = llvm.mlir_undef(ir.VectorType.get((2,), acc.mlir_dtype))
  for first, second in zip(out_regs[::2], out_regs[1::2]):
    vec = llvm.insertelement(vec_undef, first, position=utils.c(0, i32))
    vec = llvm.insertelement(vec, second, position=utils.c(1, i32))
    vec_regs.append(vec)
  out_regs = np.asarray(vec_regs, dtype=object).reshape(acc.registers.shape)
  return fa.FragmentedArray(
      _registers=out_regs, _layout=acc.layout, _is_signed=acc.is_signed
  )


def mma(
    acc: fa.FragmentedArray,
    a: fa.FragmentedArray,
    b: fa.FragmentedArray,
) -> fa.FragmentedArray:
  """Computes `acc + a @ b.T` using synchronouse MMA instructions.

  All operands must have `TiledLayout`s. The layouts must be generated
  by the `MMALayouts` class, which ensures that the tiles are mapped
  to the warps correctly.

  Args:
    acc: A `FragmentedArray` with a `TiledLayout` generated from
      `MMALayouts.acc`.
    a: A `FragmentedArray` with a `TiledLayout`  generated from
      `MMALayouts.lhs`.
    b: A `FragmentedArray` with a `TiledLayout` generated from `MMALayouts.rhs`.

  Returns:
    A new `FragmentedArray` with the result of the computation with
      the same type as `acc`.
  """

  (m, k) = a.shape
  (n, k2) = b.shape
  (m2, n2) = acc.shape

  if m != m2:
    raise ValueError(f"M mismatch: {m} != {m2}")
  if n != n2:
    raise ValueError(f"N mismatch: {n} != {n2}")
  if k != k2:
    raise ValueError(f"K mismatch: {k} != {k2}")

  # todo(cperivol): A tile shape can have dimensions that are higher
  # multiples of the mma op size as long as those dimensions are not
  # sharded across warps.
  i4 = ir.IntegerType.get_signless(4)
  i8 = ir.IntegerType.get_signless(8)
  i32 = ir.IntegerType.get_signless(32)
  bf16 = ir.BF16Type.get()
  f16 = ir.F16Type.get()
  f8e4m3fn = ir.Float8E4M3FNType.get()
  f8e5m2 = ir.Float8E5M2Type.get()
  if (element_type := a.mlir_dtype) != b.mlir_dtype:
    raise ValueError(f"Dtype mismatch: {a.mlir_dtype} != {b.mlir_dtype}")
  if element_type not in (bf16, f16, f8e4m3fn, f8e5m2, i8, i4):
    raise NotImplementedError(f"Unsupported operand type: {element_type}")
  if isinstance(element_type, ir.IntegerType):
    if acc.mlir_dtype != i32:
      raise NotImplementedError("Only s32 accumulator supported for integer operands.")
    if not acc.is_signed:
      raise ValueError("Only signed accumulator supported for integer operands.")
  elif acc.mlir_dtype != ir.F32Type.get():
    raise NotImplementedError("Only f32 accumulator supported for floating operands.")

  layouts = MMALayouts(element_type)
  if layouts.lhs != a.layout:
    raise ValueError("Expected MMALayouts.lhs layout for A")
  if layouts.rhs != b.layout:
    raise ValueError("Expected MMALayouts.rhs layout for B")
  if layouts.acc != acc.layout:
    raise ValueError("Expected MMALayouts.acc layout for acc")

  assert isinstance(a.layout, fa.TiledLayout)
  assert isinstance(b.layout, fa.TiledLayout)
  assert isinstance(acc.layout, fa.TiledLayout)
  m_tile, k_tile = a.layout.base_tile_shape
  n_tile, k_tile2 = b.layout.base_tile_shape
  m_tile2, n_tile2 = acc.layout.base_tile_shape

  assert k_tile == k_tile2
  assert m_tile2 == m_tile
  assert n_tile2 == n_tile

  num_m_tiles, num_n_tiles, num_k_tiles = m // m_tile, n // n_tile, k // k_tile

  # Do not modify the accumualtor itself.
  acc = acc.copy()
  s = lambda idx, length: slice(idx * length, (idx + 1) * length)
  for k_idx in range(num_k_tiles):
    for m_idx in range(num_m_tiles):
      for n_idx in range(num_n_tiles):
        ms = s(m_idx, m_tile)
        ns = s(n_idx, n_tile)
        ks = s(k_idx, k_tile)
        acc[ms, ns] = _mma_single_tile(acc[ms, ns], a[ms, ks], b[ns, ks])

  return acc