jit-lora / src /ane_mil_lora.py

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	"""
	ane_mil_lora.py — MIL code generators for LoRA forward and backward passes on ANE.

	Generates Apple Machine Learning Intermediate Language (MIL) programs that
	compile and run on the Neural Engine via libane_bridge.dylib.

	Based on the dynamic matmul pattern from maderix/ANE: weights are packed
	into the spatial dimension of the input IOSurface, enabling weight updates
	without recompilation. Each kernel is compiled ONCE and reused across all
	layers by writing different weights to the IOSurface.

	ANE matmul constraint: all dimensions (channels, spatial, matmul operands)
	must be multiples of 16 with minimum of 16. This means:
	- LoRA rank must be a multiple of 16 (recommend 16 or 32)
	- Sequence length must be a multiple of 16 (pad if needed)
	- Model hidden dimension is typically large enough (e.g. 3584)

	Kernels produced:
	1. lora_down — x @ A^T → h [dim → rank]
	2. lora_up — h @ B^T → out * scale [rank → dim]
	3. grad_b — grad_out @ h^T → dB [gradient for B]
	4. grad_a — (B^T @ grad_out) @ x^T → dA [gradient for A]
	5. rmsnorm — RMSNorm with baked weights
	"""

	import numpy as np

	# Standard MIL header required by ANE's modelWithMILText API
	MIL_HEADER = (
	'program(1.3)\n'
	'[buildInfo = dict<string, string>({{"coremlc-component-MIL", "3510.2.1"}, '
	'{"coremlc-version", "3505.4.1"}, '
	'{"coremltools-component-milinternal", ""}, '
	'{"coremltools-version", "9.0"}})]\n'
	'{\n'
	)


	def _dynamic_matmul_block(prefix: str, ic: int, oc: int, seq: int,
	act_sp_off: int, w_sp_off: int,
	input_var: str) -> str:
	"""Generate MIL statements for a dynamic matmul within a function.

	Slices activation [1,ic,1,seq] and weight [1,ic,1,oc] from the input
	spatial dimension, reshapes for matmul, and produces output [1,oc,1,seq].

	This is the core building block from maderix's training_dynamic approach.
	"""
	lines = []

	# Slice activations: [1, ic, 1, seq] from spatial offset
	lines.append(f' tensor<int32, [4]> {prefix}_ba = const()[name = string("{prefix}_ba"), val = tensor<int32, [4]>([0, 0, 0, {act_sp_off}])];')
	lines.append(f' tensor<int32, [4]> {prefix}_sa = const()[name = string("{prefix}_sa"), val = tensor<int32, [4]>([1, {ic}, 1, {seq}])];')
	lines.append(f' tensor<fp16, [1, {ic}, 1, {seq}]> {prefix}_act = slice_by_size(x = {input_var}, begin = {prefix}_ba, size = {prefix}_sa)[name = string("{prefix}_act")];')

	# Slice weight: [1, ic, 1, oc] from spatial offset
	lines.append(f' tensor<int32, [4]> {prefix}_bw = const()[name = string("{prefix}_bw"), val = tensor<int32, [4]>([0, 0, 0, {w_sp_off}])];')
	lines.append(f' tensor<int32, [4]> {prefix}_sw = const()[name = string("{prefix}_sw"), val = tensor<int32, [4]>([1, {ic}, 1, {oc}])];')
	lines.append(f' tensor<fp16, [1, {ic}, 1, {oc}]> {prefix}_wt = slice_by_size(x = {input_var}, begin = {prefix}_bw, size = {prefix}_sw)[name = string("{prefix}_wt")];')

	# Reshape activation: [1,ic,1,seq] → [1,1,ic,seq]
	lines.append(f' tensor<int32, [4]> {prefix}_ra = const()[name = string("{prefix}_ra"), val = tensor<int32, [4]>([1, 1, {ic}, {seq}])];')
	lines.append(f' tensor<fp16, [1, 1, {ic}, {seq}]> {prefix}_a2 = reshape(shape = {prefix}_ra, x = {prefix}_act)[name = string("{prefix}_a2")];')

	# Transpose: [1,1,ic,seq] → [1,1,seq,ic]
	lines.append(f' tensor<int32, [4]> {prefix}_pm = const()[name = string("{prefix}_pm"), val = tensor<int32, [4]>([0, 1, 3, 2])];')
	lines.append(f' tensor<fp16, [1, 1, {seq}, {ic}]> {prefix}_a3 = transpose(perm = {prefix}_pm, x = {prefix}_a2)[name = string("{prefix}_a3")];')

	# Reshape weight: [1,ic,1,oc] → [1,1,ic,oc]
	lines.append(f' tensor<int32, [4]> {prefix}_rw = const()[name = string("{prefix}_rw"), val = tensor<int32, [4]>([1, 1, {ic}, {oc}])];')
	lines.append(f' tensor<fp16, [1, 1, {ic}, {oc}]> {prefix}_W = reshape(shape = {prefix}_rw, x = {prefix}_wt)[name = string("{prefix}_W")];')

	# Core matmul: [1,1,seq,ic] @ [1,1,ic,oc] → [1,1,seq,oc]
	lines.append(f' bool {prefix}_bF = const()[name = string("{prefix}_bF"), val = bool(false)];')
	lines.append(f' tensor<fp16, [1, 1, {seq}, {oc}]> {prefix}_yh = matmul(transpose_x = {prefix}_bF, transpose_y = {prefix}_bF, x = {prefix}_a3, y = {prefix}_W)[name = string("{prefix}_yh")];')

	# Transpose back: [1,1,seq,oc] → [1,1,oc,seq]
	lines.append(f' tensor<fp16, [1, 1, {oc}, {seq}]> {prefix}_yt = transpose(perm = {prefix}_pm, x = {prefix}_yh)[name = string("{prefix}_yt")];')

	# Reshape to standard: [1,1,oc,seq] → [1,oc,1,seq]
	lines.append(f' tensor<int32, [4]> {prefix}_ro = const()[name = string("{prefix}_ro"), val = tensor<int32, [4]>([1, {oc}, 1, {seq}])];')
	lines.append(f' tensor<fp16, [1, {oc}, 1, {seq}]> {prefix}_y = reshape(shape = {prefix}_ro, x = {prefix}_yt)[name = string("{prefix}_y")];')

	return '\n'.join(lines) + '\n'


	def gen_lora_down_mil(dim: int, rank: int, seq: int) -> tuple[str, int, int]:
	"""Generate MIL for LoRA down-projection: h = x @ A^T.

	Uses dynamic weight packing:
	Input: [1, dim, 1, seq + rank] (fp32)
	- spatial[0:seq] = x (activation)
	- spatial[seq:seq+rank] = A^T (transposed LoRA A matrix)
	Output: [1, rank, 1, seq] (fp32)

	Returns:
	(mil_text, input_bytes, output_bytes)
	"""
	sp_in = seq + rank
	mil = MIL_HEADER
	mil += f' func main<ios18>(tensor<fp32, [1, {dim}, 1, {sp_in}]> x) {{\n'

	# Cast fp32 → fp16
	mil += f' string to16 = const()[name = string("to16"), val = string("fp16")];\n'
	mil += f' tensor<fp16, [1, {dim}, 1, {sp_in}]> xh = cast(dtype = to16, x = x)[name = string("cin")];\n'

	# Dynamic matmul: [seq, dim] @ [dim, rank] → [seq, rank]
	mil += _dynamic_matmul_block("ld", dim, rank, seq, 0, seq, "xh")

	# Cast fp16 → fp32
	mil += f' string to32 = const()[name = string("to32"), val = string("fp32")];\n'
	mil += f' tensor<fp32, [1, {rank}, 1, {seq}]> y = cast(dtype = to32, x = ld_y)[name = string("cout")];\n'
	mil += ' } -> (y);\n}\n'

	input_bytes = dim * sp_in * 4 # fp32
	output_bytes = rank * seq * 4 # fp32
	return mil, input_bytes, output_bytes


	def gen_lora_up_mil(rank: int, dim: int, seq: int,
	scaling: float = 1.0) -> tuple[str, int, int]:
	"""Generate MIL for LoRA up-projection: out = (h @ B^T) * scale.

	Uses dynamic weight packing:
	Input: [1, rank, 1, seq + dim] (fp32)
	- spatial[0:seq] = h (from lora_down)
	- spatial[seq:seq+dim] = B^T (transposed LoRA B matrix)
	Output: [1, dim, 1, seq] (fp32)

	Returns:
	(mil_text, input_bytes, output_bytes)
	"""
	sp_in = seq + dim
	mil = MIL_HEADER
	mil += f' func main<ios18>(tensor<fp32, [1, {rank}, 1, {sp_in}]> x) {{\n'

	# Cast fp32 → fp16
	mil += f' string to16 = const()[name = string("to16"), val = string("fp16")];\n'
	mil += f' tensor<fp16, [1, {rank}, 1, {sp_in}]> xh = cast(dtype = to16, x = x)[name = string("cin")];\n'

	# Dynamic matmul: [seq, rank] @ [rank, dim] → [seq, dim]
	mil += _dynamic_matmul_block("lu", rank, dim, seq, 0, seq, "xh")

	# Scale by lora_alpha/rank
	if abs(scaling - 1.0) > 1e-6:
	mil += f' fp16 sc = const()[name = string("sc"), val = fp16({scaling})];\n'
	mil += f' tensor<fp16, [1, {dim}, 1, {seq}]> lu_s = mul(x = lu_y, y = sc)[name = string("scaled")];\n'
	out_var = "lu_s"
	else:
	out_var = "lu_y"

	# Cast fp16 → fp32
	mil += f' string to32 = const()[name = string("to32"), val = string("fp32")];\n'
	mil += f' tensor<fp32, [1, {dim}, 1, {seq}]> y = cast(dtype = to32, x = {out_var})[name = string("cout")];\n'
	mil += ' } -> (y);\n}\n'

	input_bytes = rank * sp_in * 4
	output_bytes = dim * seq * 4
	return mil, input_bytes, output_bytes


	def gen_lora_grad_b_mil(dim: int, rank: int, seq: int,
	scaling: float = 1.0) -> tuple[str, int, int]:
	"""Generate MIL for LoRA B gradient: dB = grad_out @ h^T * scale.

	Input: [1, dim, 1, seq + seq] (fp32)
	- spatial[0:seq] = grad_out [dim, seq]
	- spatial[seq:2*seq] = h [dim ??? no, h is [rank, seq]]

	Actually, grad_out is [dim, seq] and h is [rank, seq].
	We need matmul(grad_out, h^T) = [dim, seq] @ [seq, rank] = [dim, rank].

	But grad_out has dim channels and h has rank channels — they can't share
	the same IC dimension. Solution: use two separate inputs.

	Input 0: [1, dim, 1, seq] — grad_out (fp32)
	Input 1: [1, rank, 1, seq] — h (fp32)
	Output: [1, dim, 1, rank] — dB (fp32)

	We use matmul(transpose_x=False, transpose_y=True):
	[1,1,dim,seq] @ [1,1,rank,seq]^T = [1,1,dim,rank]

	Returns:
	(mil_text, input0_bytes, input1_bytes, output_bytes)
	"""
	mil = MIL_HEADER
	mil += f' func main<ios18>(tensor<fp32, [1, {dim}, 1, {seq}]> go, tensor<fp32, [1, {rank}, 1, {seq}]> h) {{\n'

	# Cast both to fp16
	mil += f' string to16 = const()[name = string("to16"), val = string("fp16")];\n'
	mil += f' tensor<fp16, [1, {dim}, 1, {seq}]> go16 = cast(dtype = to16, x = go)[name = string("cgo")];\n'
	mil += f' tensor<fp16, [1, {rank}, 1, {seq}]> h16 = cast(dtype = to16, x = h)[name = string("ch")];\n'

	# Reshape grad_out: [1,dim,1,seq] → [1,1,dim,seq]
	mil += f' tensor<int32, [4]> rgo = const()[name = string("rgo"), val = tensor<int32, [4]>([1, 1, {dim}, {seq}])];\n'
	mil += f' tensor<fp16, [1, 1, {dim}, {seq}]> go4 = reshape(shape = rgo, x = go16)[name = string("rgo4")];\n'

	# Reshape h: [1,rank,1,seq] → [1,1,rank,seq]
	mil += f' tensor<int32, [4]> rh = const()[name = string("rh"), val = tensor<int32, [4]>([1, 1, {rank}, {seq}])];\n'
	mil += f' tensor<fp16, [1, 1, {rank}, {seq}]> h4 = reshape(shape = rh, x = h16)[name = string("rh4")];\n'

	# matmul(grad_out, h^T): [1,1,dim,seq] @ [1,1,seq,rank] → [1,1,dim,rank]
	mil += f' bool bF = const()[name = string("bF"), val = bool(false)];\n'
	mil += f' bool bT = const()[name = string("bT"), val = bool(true)];\n'
	mil += f' tensor<fp16, [1, 1, {dim}, {rank}]> db4 = matmul(transpose_x = bF, transpose_y = bT, x = go4, y = h4)[name = string("mm")];\n'

	# Scale
	if abs(scaling - 1.0) > 1e-6:
	mil += f' fp16 sc = const()[name = string("sc"), val = fp16({scaling})];\n'
	mil += f' tensor<fp16, [1, 1, {dim}, {rank}]> db_s = mul(x = db4, y = sc)[name = string("scaled")];\n'
	mm_var = "db_s"
	else:
	mm_var = "db4"

	# Reshape: [1,1,dim,rank] → [1,dim,1,rank]
	mil += f' tensor<int32, [4]> ro = const()[name = string("ro"), val = tensor<int32, [4]>([1, {dim}, 1, {rank}])];\n'
	mil += f' tensor<fp16, [1, {dim}, 1, {rank}]> db16 = reshape(shape = ro, x = {mm_var})[name = string("rdb")];\n'

	# Cast to fp32
	mil += f' string to32 = const()[name = string("to32"), val = string("fp32")];\n'
	mil += f' tensor<fp32, [1, {dim}, 1, {rank}]> dB = cast(dtype = to32, x = db16)[name = string("cout")];\n'
	mil += ' } -> (dB);\n}\n'

	in0_bytes = dim * seq * 4
	in1_bytes = rank * seq * 4
	out_bytes = dim * rank * 4
	return mil, in0_bytes, in1_bytes, out_bytes


	def gen_lora_grad_a_mil(dim: int, rank: int, seq: int,
	scaling: float = 1.0) -> tuple[str, int, int]:
	"""Generate MIL for LoRA A gradient: dA = B^T @ grad_out @ x^T * scale.

	This is two chained matmuls:
	1. tmp = B^T @ grad_out: [rank,dim] @ [dim,seq] → [rank,seq]
	2. dA = tmp @ x^T: [rank,seq] @ [seq,dim] → [rank,dim]

	Input 0: [1, dim, 1, seq + rank] (fp32) — grad_out + B^T packed
	- spatial[0:seq] = grad_out [dim, seq]
	- spatial[seq:seq+rank] = B^T [dim, rank]
	Input 1: [1, dim, 1, seq] (fp32) — x (activation)
	Output: [1, rank, 1, dim] (fp32) — dA

	Returns:
	(mil_text, input0_bytes, input1_bytes, output_bytes)
	"""
	sp0 = seq + rank
	mil = MIL_HEADER
	mil += f' func main<ios18>(tensor<fp32, [1, {dim}, 1, {sp0}]> packed, tensor<fp32, [1, {dim}, 1, {seq}]> xin) {{\n'

	# Cast to fp16
	mil += f' string to16 = const()[name = string("to16"), val = string("fp16")];\n'
	mil += f' tensor<fp16, [1, {dim}, 1, {sp0}]> ph = cast(dtype = to16, x = packed)[name = string("cp")];\n'
	mil += f' tensor<fp16, [1, {dim}, 1, {seq}]> xh = cast(dtype = to16, x = xin)[name = string("cx")];\n'

	# Step 1: B^T @ grad_out using dynamic matmul helper
	# Slices grad_out[dim, seq] and B^T[dim, rank] from packed input
	# matmul: [seq, dim] @ [dim, rank] → [seq, rank]
	# Result: tmp_y [1, rank, 1, seq]
	mil += _dynamic_matmul_block("tmp", dim, rank, seq, 0, seq, "ph")

	# Step 2: tmp @ x^T
	# tmp is [1, rank, 1, seq], need to matmul with x [1, dim, 1, seq]
	# Want: [rank, seq] @ [seq, dim] → [rank, dim]
	# Use matmul(tmp_reshaped, x_reshaped, transpose_y=True... no)
	# Actually: reshape tmp [1,rank,1,seq] → [1,1,rank,seq]
	# reshape x [1,dim,1,seq] → [1,1,dim,seq]
	# matmul(transpose_y=True): [1,1,rank,seq] @ [1,1,seq,dim] → [1,1,rank,dim]
	# But transpose_y=True on [1,1,dim,seq] gives [1,1,seq,dim]
	# So matmul(x=tmp4, transpose_y=True, y=x4): [1,1,rank,seq]@[1,1,seq,dim] = [1,1,rank,dim]

	mil += f' tensor<int32, [4]> rt = const()[name = string("rt"), val = tensor<int32, [4]>([1, 1, {rank}, {seq}])];\n'
	mil += f' tensor<fp16, [1, 1, {rank}, {seq}]> tmp4 = reshape(shape = rt, x = tmp_y)[name = string("rt4")];\n'

	mil += f' tensor<int32, [4]> rx = const()[name = string("rx"), val = tensor<int32, [4]>([1, 1, {dim}, {seq}])];\n'
	mil += f' tensor<fp16, [1, 1, {dim}, {seq}]> x4 = reshape(shape = rx, x = xh)[name = string("rx4")];\n'

	mil += f' bool bF = const()[name = string("bF"), val = bool(false)];\n'
	mil += f' bool bT = const()[name = string("bT"), val = bool(true)];\n'
	mil += f' tensor<fp16, [1, 1, {rank}, {dim}]> da4 = matmul(transpose_x = bF, transpose_y = bT, x = tmp4, y = x4)[name = string("mm2")];\n'

	# Scale
	if abs(scaling - 1.0) > 1e-6:
	mil += f' fp16 sc = const()[name = string("sc"), val = fp16({scaling})];\n'
	mil += f' tensor<fp16, [1, 1, {rank}, {dim}]> da_s = mul(x = da4, y = sc)[name = string("scaled")];\n'
	mm_var = "da_s"
	else:
	mm_var = "da4"

	# Reshape: [1,1,rank,dim] → [1,rank,1,dim]
	mil += f' tensor<int32, [4]> ro = const()[name = string("ro"), val = tensor<int32, [4]>([1, {rank}, 1, {dim}])];\n'
	mil += f' tensor<fp16, [1, {rank}, 1, {dim}]> da16 = reshape(shape = ro, x = {mm_var})[name = string("rda")];\n'

	# Cast to fp32
	mil += f' string to32 = const()[name = string("to32"), val = string("fp32")];\n'
	mil += f' tensor<fp32, [1, {rank}, 1, {dim}]> dA = cast(dtype = to32, x = da16)[name = string("cout")];\n'
	mil += ' } -> (dA);\n}\n'

	in0_bytes = dim * sp0 * 4
	in1_bytes = dim * seq * 4
	out_bytes = rank * dim * 4
	return mil, in0_bytes, in1_bytes, out_bytes


	def gen_rmsnorm_mil(dim: int, seq: int) -> tuple[str, int, int]:
	"""Generate MIL for RMSNorm: out = (x / sqrt(mean(x^2) + eps)) * weight.

	Uses baked weight constant from BLOBFILE.
	Input: [1, dim, 1, seq] (fp16)
	Output: [1, dim, 1, seq] (fp16)

	The weight file "@model_path/weights/rms_w.bin" must be provided as
	a weight blob when compiling.

	Returns:
	(mil_text, input_bytes, output_bytes)
	"""
	inv_dim = 1.0 / dim
	mil = MIL_HEADER
	mil += f' func main<ios18>(tensor<fp16, [1, {dim}, 1, {seq}]> x) {{\n'

	# x^2
	mil += f' tensor<fp16, [1, {dim}, 1, {seq}]> sq = mul(x = x, y = x)[name = string("sq")];\n'

	# reduce_sum over channels (axis 1), keep_dims
	mil += f' tensor<int32, [1]> rax = const()[name = string("rax"), val = tensor<int32, [1]>([1])];\n'
	mil += f' bool kd = const()[name = string("kd"), val = bool(true)];\n'
	mil += f' tensor<fp16, [1, 1, 1, {seq}]> ss = reduce_sum(x = sq, axes = rax, keep_dims = kd)[name = string("ss")];\n'

	# mean: sum / dim
	mil += f' fp16 invd = const()[name = string("invd"), val = fp16({inv_dim})];\n'
	mil += f' tensor<fp16, [1, 1, 1, {seq}]> ss2 = mul(x = ss, y = invd)[name = string("ss2")];\n'

	# + eps
	mil += f' fp16 eps = const()[name = string("eps"), val = fp16(0.00001)];\n'
	mil += f' tensor<fp16, [1, 1, 1, {seq}]> ss3 = add(x = ss2, y = eps)[name = string("ss3")];\n'

	# rsqrt: pow(x, -0.5)
	mil += f' fp16 nhalf = const()[name = string("nhalf"), val = fp16(-0.5)];\n'
	mil += f' tensor<fp16, [1, 1, 1, {seq}]> rrms = pow(x = ss3, y = nhalf)[name = string("rrms")];\n'

	# normalize
	mil += f' tensor<fp16, [1, {dim}, 1, {seq}]> xr = mul(x = x, y = rrms)[name = string("xr")];\n'

	# weight (baked)
	mil += f' tensor<fp16, [1, {dim}, 1, 1]> rw = const()[name = string("rw"), val = tensor<fp16, [1, {dim}, 1, 1]>(BLOBFILE(path = string("@model_path/weights/rms_w.bin"), offset = uint64(64)))];\n'
	mil += f' tensor<fp16, [1, {dim}, 1, {seq}]> out = mul(x = xr, y = rw)[name = string("out")];\n'
	mil += ' } -> (out);\n}\n'

	tensor_bytes = dim * seq * 2 # fp16
	return mil, tensor_bytes, tensor_bytes


	def gen_conv_matmul_mil(dim_in: int, dim_out: int, seq: int) -> tuple[str, int, int]:
	"""Generate MIL for a conv-based linear projection (baked weights).

	Used for classifier/embedding projections.
	Input: [1, dim_in, 1, seq] (fp32)
	Output: [1, dim_out, 1, seq] (fp32)

	Weight: BLOBFILE "embed.bin" [dim_out, dim_in, 1, 1] in fp16.

	Returns:
	(mil_text, input_bytes, output_bytes)
	"""
	mil = MIL_HEADER
	mil += f' func main<ios18>(tensor<fp32, [1, {dim_in}, 1, {seq}]> x) {{\n'

	# Conv constants
	mil += ' string pt = const()[name = string("pt"), val = string("valid")];\n'
	mil += ' tensor<int32, [2]> st = const()[name = string("st"), val = tensor<int32, [2]>([1, 1])];\n'
	mil += ' tensor<int32, [4]> pd = const()[name = string("pd"), val = tensor<int32, [4]>([0, 0, 0, 0])];\n'
	mil += ' tensor<int32, [2]> dl = const()[name = string("dl"), val = tensor<int32, [2]>([1, 1])];\n'
	mil += ' int32 gr = const()[name = string("gr"), val = int32(1)];\n'

	# Cast to fp16
	mil += f' string to16 = const()[name = string("to16"), val = string("fp16")];\n'
	mil += f' tensor<fp16, [1, {dim_in}, 1, {seq}]> x16 = cast(dtype = to16, x = x)[name = string("cin")];\n'

	# Baked weight
	mil += f' tensor<fp16, [{dim_out}, {dim_in}, 1, 1]> W = const()[name = string("W"), val = tensor<fp16, [{dim_out}, {dim_in}, 1, 1]>(BLOBFILE(path = string("@model_path/weights/embed.bin"), offset = uint64(64)))];\n'

	# Conv (equivalent to matmul for 1x1 kernel)
	mil += f' tensor<fp16, [1, {dim_out}, 1, {seq}]> y16 = conv(dilations = dl, groups = gr, pad = pd, pad_type = pt, strides = st, weight = W, x = x16)[name = string("conv")];\n'

	# Cast to fp32
	mil += f' string to32 = const()[name = string("to32"), val = string("fp32")];\n'
	mil += f' tensor<fp32, [1, {dim_out}, 1, {seq}]> y = cast(dtype = to32, x = y16)[name = string("cout")];\n'
	mil += ' } -> (y);\n}\n'

	in_bytes = dim_in * seq * 4
	out_bytes = dim_out * seq * 4
	return mil, in_bytes, out_bytes


	class LoRAKernelSet:
	"""Pre-compiled set of LoRA kernels for a given model dimension.

	Compiles 4 kernels once, then reuses them across all layers by
	writing different weights to the IOSurfaces.
	"""

	def __init__(self, ane_bridge, dim: int, rank: int, seq: int,
	scaling: float = 1.0):
	"""Compile all LoRA kernels.

	Args:
	ane_bridge: ANEBridge instance
	dim: model hidden dimension
	rank: LoRA rank
	seq: sequence length
	scaling: LoRA scaling factor (alpha/rank)
	"""
	# ANE requires all matmul dims to be multiples of 16
	for name, val in [("dim", dim), ("rank", rank), ("seq", seq)]:
	if val < 16 or val % 16 != 0:
	raise ValueError(
	f"ANE requires {name}={val} to be a multiple of 16 (min 16)")

	self.ane = ane_bridge
	self.dim = dim
	self.rank = rank
	self.seq = seq
	self.scaling = scaling

	# Compile kernels
	self._compile_all()

	def _compile_all(self):
	"""Compile all 4 LoRA kernels."""
	# 1. LoRA down: x @ A^T → h
	mil, in_bytes, out_bytes = gen_lora_down_mil(self.dim, self.rank, self.seq)
	self.down_kernel = self.ane.compile_kernel(
	mil, input_sizes=[in_bytes], output_sizes=[out_bytes])
	self.down_in_bytes = in_bytes
	self.down_out_bytes = out_bytes

	# 2. LoRA up: h @ B^T → out * scale
	mil, in_bytes, out_bytes = gen_lora_up_mil(
	self.rank, self.dim, self.seq, self.scaling)
	self.up_kernel = self.ane.compile_kernel(
	mil, input_sizes=[in_bytes], output_sizes=[out_bytes])
	self.up_in_bytes = in_bytes
	self.up_out_bytes = out_bytes

	# 3. Gradient B: grad_out @ h^T → dB
	mil, in0, in1, out = gen_lora_grad_b_mil(
	self.dim, self.rank, self.seq, self.scaling)
	self.grad_b_kernel = self.ane.compile_kernel(
	mil, input_sizes=[in0, in1], output_sizes=[out])
	self.grad_b_in0 = in0
	self.grad_b_in1 = in1
	self.grad_b_out = out

	# 4. Gradient A: (B^T @ grad_out) @ x^T → dA
	mil, in0, in1, out = gen_lora_grad_a_mil(
	self.dim, self.rank, self.seq, self.scaling)
	self.grad_a_kernel = self.ane.compile_kernel(
	mil, input_sizes=[in0, in1], output_sizes=[out])
	self.grad_a_in0 = in0
	self.grad_a_in1 = in1
	self.grad_a_out = out

	def forward(self, x: np.ndarray, A: np.ndarray, B: np.ndarray) -> np.ndarray:
	"""Compute LoRA forward: out = (B @ A @ x) * scale.

	Args:
	x: [1, dim, 1, seq] fp32 activation
	A: [rank, dim] fp32 LoRA A matrix
	B: [dim, rank] fp32 LoRA B matrix

	Returns:
	[1, dim, 1, seq] fp32 LoRA output
	"""
	# Step 1: h = x @ A^T
	# Pack x and A^T into spatial dimension
	A_T = A.T # [dim, rank]
	packed_down = np.zeros((1, self.dim, 1, self.seq + self.rank), dtype=np.float32)
	packed_down[:, :, :, :self.seq] = x
	packed_down[:, :, :, self.seq:] = A_T.reshape(1, self.dim, 1, self.rank)

	self.ane.write_input(self.down_kernel, 0, packed_down)
	self.ane.eval(self.down_kernel)
	h = self.ane.read_output(self.down_kernel, 0,
	(1, self.rank, 1, self.seq), dtype=np.float32)

	# Step 2: out = h @ B^T * scale
	B_T = B.T # [rank, dim]
	packed_up = np.zeros((1, self.rank, 1, self.seq + self.dim), dtype=np.float32)
	packed_up[:, :, :, :self.seq] = h
	packed_up[:, :, :, self.seq:] = B_T.reshape(1, self.rank, 1, self.dim)

	self.ane.write_input(self.up_kernel, 0, packed_up)
	self.ane.eval(self.up_kernel)
	out = self.ane.read_output(self.up_kernel, 0,
	(1, self.dim, 1, self.seq), dtype=np.float32)

	return out

	def backward(self, grad_out: np.ndarray, x: np.ndarray,
	A: np.ndarray, B: np.ndarray) -> tuple[np.ndarray, np.ndarray]:
	"""Compute LoRA gradients: dA, dB.

	Args:
	grad_out: [1, dim, 1, seq] fp32 upstream gradient
	x: [1, dim, 1, seq] fp32 saved activation
	A: [rank, dim] fp32 LoRA A matrix
	B: [dim, rank] fp32 LoRA B matrix

	Returns:
	(dA [rank, dim], dB [dim, rank]) fp32 gradients
	"""
	# Compute h = A @ x (needed for dB)
	A_T = A.T
	packed_down = np.zeros((1, self.dim, 1, self.seq + self.rank), dtype=np.float32)
	packed_down[:, :, :, :self.seq] = x
	packed_down[:, :, :, self.seq:] = A_T.reshape(1, self.dim, 1, self.rank)
	self.ane.write_input(self.down_kernel, 0, packed_down)
	self.ane.eval(self.down_kernel)
	h = self.ane.read_output(self.down_kernel, 0,
	(1, self.rank, 1, self.seq), dtype=np.float32)

	# Gradient B: dB = grad_out @ h^T * scale → [dim, rank]
	self.ane.write_input(self.grad_b_kernel, 0,
	np.ascontiguousarray(grad_out))
	self.ane.write_input(self.grad_b_kernel, 1,
	np.ascontiguousarray(h))
	self.ane.eval(self.grad_b_kernel)
	dB_raw = self.ane.read_output(self.grad_b_kernel, 0,
	(1, self.dim, 1, self.rank), dtype=np.float32)
	dB = dB_raw.reshape(self.dim, self.rank)

	# Gradient A: dA = (B^T @ grad_out) @ x^T * scale → [rank, dim]
	B_T = B.T # [rank, dim] — wait, B is [dim, rank], B^T is [rank, dim]
	# Pack grad_out + B^T into input 0: [1, dim, 1, seq + rank]
	# B^T is [rank, dim], but we need to pack as [dim, rank] in channel dim...
	# Actually, for the grad_a kernel: packed = [1, dim, 1, seq+rank]
	# where spatial[0:seq] = grad_out, spatial[seq:seq+rank] = B (which is [dim, rank])
	# The dynamic matmul does: [seq, dim] @ [dim, rank] → [seq, rank]
	# This gives us B^T @ grad_out transposed = (grad_out^T @ B)^T hmm...
	# Actually the dynamic matmul convention:
	# act = grad_out [1, dim, 1, seq] → matmul as [seq, dim]
	# W = B [1, dim, 1, rank] → matmul as [dim, rank]
	# result = [seq, dim] @ [dim, rank] = [seq, rank]
	# which is (B^T @ grad_out)^T in row-major
	# This is exactly what we want for step 1 of dA computation.
	packed_a0 = np.zeros((1, self.dim, 1, self.seq + self.rank), dtype=np.float32)
	packed_a0[:, :, :, :self.seq] = grad_out
	packed_a0[:, :, :, self.seq:] = B.reshape(1, self.dim, 1, self.rank)

	self.ane.write_input(self.grad_a_kernel, 0, packed_a0)
	self.ane.write_input(self.grad_a_kernel, 1,
	np.ascontiguousarray(x))
	self.ane.eval(self.grad_a_kernel)
	dA_raw = self.ane.read_output(self.grad_a_kernel, 0,
	(1, self.rank, 1, self.dim), dtype=np.float32)
	dA = dA_raw.reshape(self.rank, self.dim)

	return dA, dB

	def free(self):
	"""Free all compiled kernels."""
	for k in [self.down_kernel, self.up_kernel,
	self.grad_b_kernel, self.grad_a_kernel]:
	if k:
	self.ane.free_kernel(k)


	def self_test():
	"""Test MIL generators with ANE hardware."""
	from ane_bridge_py import ANEBridge

	print("LoRA MIL Generator Self-Test")
	print("=" * 50)

	ane = ANEBridge()
	# ANE requires all matmul dimensions to be multiples of 16 (minimum 16)
	dim, rank, seq = 64, 16, 16
	scaling = 2.0

	# Test 1: Compile all kernels
	print(f"\nCompiling LoRA kernels (dim={dim}, rank={rank}, seq={seq})...")
	try:
	kernels = LoRAKernelSet(ane, dim, rank, seq, scaling)
	print(f"[OK] All 4 kernels compiled (compile count: {ane.compile_count})")
	except Exception as e:
	print(f"[FAIL] Kernel compilation: {e}")
	return False

	# Test 2: Forward pass
	print("\nTesting forward pass...")
	x = np.random.randn(1, dim, 1, seq).astype(np.float32) * 0.1
	A = np.random.randn(rank, dim).astype(np.float32) * 0.01
	B = np.zeros((dim, rank), dtype=np.float32) # Standard LoRA init

	try:
	out = kernels.forward(x, A, B)
	print(f"[OK] Forward: input {x.shape} → output {out.shape}")
	print(f" Output max: {np.abs(out).max():.6f} (should be ~0 with B=0)")

	# With non-zero B
	B = np.random.randn(dim, rank).astype(np.float32) * 0.01
	out = kernels.forward(x, A, B)
	print(f" Output max (B≠0): {np.abs(out).max():.6f}")

	# Verify against numpy
	x_2d = x.reshape(dim, seq)
	expected = (B @ A @ x_2d * scaling).reshape(1, dim, 1, seq)
	err = np.abs(out - expected).max()
	print(f" Max error vs numpy: {err:.6f}")
	if err > 0.5:
	print(f"[WARN] High error — fp16 rounding may be significant")
	except Exception as e:
	print(f"[FAIL] Forward: {e}")
	kernels.free()
	return False

	# Test 3: Backward pass
	print("\nTesting backward pass...")
	grad_out = np.random.randn(1, dim, 1, seq).astype(np.float32) * 0.1

	try:
	dA, dB = kernels.backward(grad_out, x, A, B)
	print(f"[OK] Backward: dA {dA.shape}, dB {dB.shape}")
	print(f" dA max: {np.abs(dA).max():.6f}")
	print(f" dB max: {np.abs(dB).max():.6f}")

	# Verify shapes
	assert dA.shape == (rank, dim), f"dA shape {dA.shape} != ({rank}, {dim})"
	assert dB.shape == (dim, rank), f"dB shape {dB.shape} != ({dim}, {rank})"

	# Verify non-zero gradients
	assert np.abs(dA).max() > 0, "dA is all zeros"
	assert np.abs(dB).max() > 0, "dB is all zeros"

	# Verify against numpy
	x_2d = x.reshape(dim, seq)
	go_2d = grad_out.reshape(dim, seq)
	h = A @ x_2d # [rank, seq]
	expected_dB = go_2d @ h.T * scaling
	expected_dA = (B.T @ go_2d) @ x_2d.T * scaling

	err_dB = np.abs(dB - expected_dB).max()
	err_dA = np.abs(dA - expected_dA).max()
	print(f" dB error vs numpy: {err_dB:.6f}")
	print(f" dA error vs numpy: {err_dA:.6f}")
	except Exception as e:
	print(f"[FAIL] Backward: {e}")
	import traceback
	traceback.print_exc()
	kernels.free()
	return False

	kernels.free()
	print(f"\n[PASS] All LoRA MIL tests passed")
	print(f" Final compile count: {ane.compile_count}")
	return True


	if __name__ == "__main__":
	success = self_test()
	exit(0 if success else 1)