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mlx_native/
kernel_registry.rs

1//! [`KernelRegistry`] — lazy compilation and caching of Metal compute pipelines.
2//!
3//! MSL shader source is embedded at compile time via `include_str!`.  On first
4//! access, the source is compiled into a Metal library, the named function is
5//! extracted, and a `ComputePipelineState` is created and cached.  Subsequent
6//! calls return the cached pipeline.
7//!
8//! ## Precompiled `.metallib` fast path
9//!
10//! `build.rs` runs `xcrun metal -O3` on every `.metal` file under
11//! `src/shaders/` and links the results into a single `default.metallib`
12//! placed in `OUT_DIR`.  We embed the bytes via `include_bytes!`.
13//!
14//! When `MLX_PRECOMPILED_METALLIB=1` is set, `get_pipeline` and
15//! `get_pipeline_with_constants` first try to resolve the kernel function
16//! against this precompiled library; if found, build the pipeline from it
17//! (saves Apple's runtime source-compile pass).  On any failure (function
18//! missing, empty embedded blob, load error) the code transparently falls
19//! back to the original source-compile path — byte-identical behavior.
20//!
21//! Default-ON; precompiled gives ~+6% on gemma4 Q-sliding decode (M5 Max).
22
23use std::collections::HashMap;
24use std::sync::OnceLock;
25
26use metal::{ComputePipelineDescriptor, ComputePipelineState, FunctionConstantValues, MTLDataType};
27
28use crate::error::{MlxError, Result};
29
30/// Bytes of the precompiled `default.metallib` produced by `build.rs` from
31/// every `src/shaders/*.metal` file.  Empty when `MLX_NATIVE_SKIP_METALLIB`
32/// was set at build time or xcrun was unavailable.
33const EMBEDDED_METALLIB: &[u8] = include_bytes!(concat!(env!("OUT_DIR"), "/default.metallib"));
34
35/// Returns `true` when the precompiled `.metallib` fast path is enabled
36/// (default-ON).  Set `MLX_PRECOMPILED_METALLIB=0` (or `false`, `off`)
37/// to opt out — useful for diagnosing kernel-compile regressions or
38/// A/B benching.
39fn precompiled_enabled() -> bool {
40    static FLAG: OnceLock<bool> = OnceLock::new();
41    *FLAG.get_or_init(|| {
42        match std::env::var("MLX_PRECOMPILED_METALLIB").as_deref() {
43            Ok("0") | Ok("false") | Ok("off") => false,
44            _ => true,
45        }
46    })
47}
48
49/// Returns `true` when the precompiled `.metallib` is consulted for
50/// `get_pipeline_with_constants` (FCV-specialized) kernels.  Inherits
51/// the master gate [`precompiled_enabled`]; both must be ON for the
52/// FCV path to use precompiled.  Default-ON.
53fn precompiled_fcv_enabled() -> bool {
54    static FLAG: OnceLock<bool> = OnceLock::new();
55    *FLAG.get_or_init(|| {
56        match std::env::var("MLX_PRECOMPILED_METALLIB_FCV").as_deref() {
57            Ok("0") | Ok("false") | Ok("off") => false,
58            _ => true,
59        }
60    })
61}
62
63// MTLDataType numeric values (from metal-rs argument.rs, confirmed in Apple Metal spec):
64//   Int  = 29
65//   Bool = 53
66// These are used when calling set_constant_value_at_index so the Metal runtime
67// knows how wide each constant value is.
68
69/// Registry that lazily compiles and caches Metal compute pipelines from
70/// embedded MSL source.
71///
72/// # Usage
73///
74/// ```ignore
75/// let mut registry = KernelRegistry::new();
76/// let pipeline = registry.get_pipeline("elementwise_add", device.metal_device())?;
77/// encoder.encode(&pipeline, &buffers, grid, tg);
78/// ```
79///
80/// # Thread Safety
81///
82/// `KernelRegistry` is **not** `Sync` by default (it uses `&mut self` for
83/// `get_pipeline` to allow mutable cache insertion).  If you need concurrent
84/// access, wrap it in a `Mutex` or use one registry per thread.
85pub struct KernelRegistry {
86    /// Cached pipelines keyed by kernel function name.
87    cache: HashMap<String, ComputePipelineState>,
88    /// MSL source text keyed by kernel function name.
89    ///
90    /// Populated at construction time with all embedded shader sources.
91    sources: HashMap<String, &'static str>,
92    /// Precompiled `default.metallib` (lazy).
93    ///
94    /// `None` initially.  On first `get_pipeline*` call under
95    /// `MLX_PRECOMPILED_METALLIB=1`, populated via
96    /// `device.new_library_with_data(EMBEDDED_METALLIB)` — or set to a
97    /// sentinel "load-failed" marker (still `None`) so we don't retry.
98    /// Set to `Some(library)` on success.
99    ///
100    /// Lazily filled because we need a `&metal::DeviceRef` to load it
101    /// and `KernelRegistry::new()` does not have one.
102    precompiled_lib: Option<metal::Library>,
103    /// Whether we've already attempted to load the precompiled library.
104    /// Prevents repeated load attempts on failure.
105    precompiled_load_attempted: bool,
106}
107
108impl KernelRegistry {
109    /// Create a new registry with all embedded shader sources pre-registered.
110    ///
111    /// No compilation happens here — shaders are compiled lazily on first use.
112    pub fn new() -> Self {
113        let mut sources = HashMap::new();
114
115        // Register embedded shader sources.
116        sources.insert(
117            "placeholder".into(),
118            include_str!("shaders/placeholder.metal"),
119        );
120        sources.insert(
121            "quantized_matmul".into(),
122            include_str!("shaders/quantized_matmul.metal"),
123        );
124        sources.insert(
125            "quantized_matmul_simd".into(),
126            include_str!("shaders/quantized_matmul.metal"),
127        );
128        sources.insert(
129            "quantized_matmul_simd_bf16".into(),
130            include_str!("shaders/quantized_matmul.metal"),
131        );
132        sources.insert(
133            "quantized_matmul_simd_bf16_expert".into(),
134            include_str!("shaders/quantized_matmul.metal"),
135        );
136
137        // GGML block-format quantized mat-vec kernels (ADR-006 Phase 3)
138        let ggml_src: &'static str =
139            include_str!("shaders/quantized_matmul_ggml.metal");
140        sources.insert("kernel_mul_mv_q4_0_f32".into(), ggml_src);
141        sources.insert("kernel_mul_mv_q8_0_f32".into(), ggml_src);
142        // ADR-028 iter-368: peer-style NSG=4 NR=2 variant (128 threads/TG).
143        sources.insert("kernel_mul_mv_q8_0_f32_nr2".into(), ggml_src);
144        sources.insert("kernel_mul_mv_q6_K_f32".into(), ggml_src);
145        // ADR-028 iter-309 — q6_K mat-vec with nr0=2 + cached yl[16]
146        // (peer-pattern port of llama.cpp's `kernel_mul_mv_q6_K_f32_impl`
147        // with N_R0_Q6_K=2; 4 rows/TG vs baseline's 2).  Env-gated via
148        // `HF2Q_Q6K_MV_NR2=1` in the dispatcher.
149        sources.insert("kernel_mul_mv_q6_K_f32_nr2".into(), ggml_src);
150        // ADR-022 Phase 1 — Q5_1 / IQ4_NL dense mat-vec.
151        sources.insert("kernel_mul_mv_q5_1_f32".into(), ggml_src);
152        sources.insert("kernel_mul_mv_iq4_nl_f32".into(), ggml_src);
153        // ADR-013 P7 — Q4_K dense decode mat-vec (port of llama.cpp's
154        // kernel_mul_mv_q4_K_f32 at ggml-metal.metal:7715-7821).
155        sources.insert("kernel_mul_mv_q4_K_f32".into(), ggml_src);
156        // ADR-022 Phase 2 — Q5_K dense mv kernel.
157        sources.insert("kernel_mul_mv_q5_K_f32".into(), ggml_src);
158
159        // GGML block-format quantized matrix-matrix kernels
160        // (ADR-011 Phase 3 Wave P3a: port of llama.cpp's kernel_mul_mm_<q>_f32).
161        // Used at prefill m > 8 to reuse each weight tile across a 32-row
162        // block via threadgroup-staged simdgroup MMA, instead of re-reading
163        // every block per prompt-token as the mv kernel does.
164        let ggml_mm_src: &'static str =
165            include_str!("shaders/quantized_matmul_mm.metal");
166        sources.insert("kernel_mul_mm_q4_0_f32".into(), ggml_mm_src);
167        sources.insert("kernel_mul_mm_q8_0_f32".into(), ggml_mm_src);
168        sources.insert("kernel_mul_mm_q6_K_f32".into(), ggml_mm_src);
169        // ADR-022 Phase 1 — dense Q5_1 / IQ4_NL mm.
170        sources.insert("kernel_mul_mm_q5_1_f32".into(), ggml_mm_src);
171        sources.insert("kernel_mul_mm_iq4_nl_f32".into(), ggml_mm_src);
172        // ADR-022 Phase 2 — dense Q5_K mm.
173        sources.insert("kernel_mul_mm_q5_K_f32".into(), ggml_mm_src);
174        // ADR-022 Phase 3 — dense Q4_K mm.
175        sources.insert("kernel_mul_mm_q4_K_f32".into(), ggml_mm_src);
176
177        // GGML block-format quantized matrix-matrix kernels — tensor API
178        // variant (ADR-011 Phase 3 Wave P3b-tensor: port of llama.cpp's
179        // kernel_mul_mm_impl `#ifdef GGML_METAL_HAS_TENSOR` branch).
180        // Uses Apple's MetalPerformancePrimitives `tensor_ops::matmul2d`
181        // primitive which on M3+ dispatches to hardware tensor cores for
182        // 2-3x the effective FLOP throughput vs the simdgroup MMA path.
183        // Only compiled on devices where the tensor API is available; the
184        // kernel_registry's runtime-probe (see MlxDevice::has_tensor) gates
185        // compilation so non-tensor devices transparently fall back to the
186        // non-tensor `kernel_mul_mm_<q>_f32` kernels.
187        let ggml_mm_tensor_src: &'static str =
188            include_str!("shaders/quantized_matmul_mm_tensor.metal");
189        sources.insert("kernel_mul_mm_q4_0_tensor_f32".into(), ggml_mm_tensor_src);
190        sources.insert("kernel_mul_mm_q4_0_tensor_bf16_perm021".into(), ggml_mm_tensor_src);
191        sources.insert("kernel_mul_mm_q6_K_tensor_bf16_perm021".into(), ggml_mm_tensor_src);
192        sources.insert("kernel_mul_mm_q8_0_tensor_f32".into(), ggml_mm_tensor_src);
193        sources.insert("kernel_mul_mm_q6_K_tensor_f32".into(), ggml_mm_tensor_src);
194        // ADR-022 Phase 1 — Q5_1 / IQ4_NL tensor mm.
195        sources.insert("kernel_mul_mm_q5_1_tensor_f32".into(), ggml_mm_tensor_src);
196        sources.insert("kernel_mul_mm_iq4_nl_tensor_f32".into(), ggml_mm_tensor_src);
197        // ADR-022 Phase 2 — Q5_K tensor mm.
198        sources.insert("kernel_mul_mm_q5_K_tensor_f32".into(), ggml_mm_tensor_src);
199        // ADR-022 Phase 3 — Q4_K tensor mm + Q8_0 perm021.
200        sources.insert("kernel_mul_mm_q4_K_tensor_f32".into(), ggml_mm_tensor_src);
201        sources.insert("kernel_mul_mm_q8_0_tensor_bf16_perm021".into(), ggml_mm_tensor_src);
202        // ADR-029 iter-30 H29-speed — F16-weight V2 large-tile mm.
203        // Same source file as the V2 quantized variants; reads F16 weight
204        // directly from device memory (no per-call dequant).  Used when
205        // MlxQWeight.f16_shadow is populated and m > MM_ROUTING_THRESHOLD.
206        sources.insert("hf2q_mul_mm_tensor_v2_f16".into(), ggml_mm_tensor_src);
207        // ADR-029 iter-36 H28-D — F16-weight perm021 mm for O-projection.
208        // Same source file; reads F16 weight from MlxQWeight.f16_shadow when
209        // populated, bypassing the per-call quantized dequant.  B-stage
210        // (bfloat permuted [n_heads, seq_len, head_dim] input) is byte-
211        // identical to the quantized variant.
212        sources.insert("kernel_mul_mm_f16_tensor_bf16_perm021".into(), ggml_mm_tensor_src);
213        // ADR-029 iter-23 H28-A — V2 large-tile tensor mm (NRA=64 M, NRB=128 N).
214        // Same source file as V1 tensor mm; distinct kernel host names so the
215        // dispatcher can pick V1 vs V2 at runtime via HF2Q_LARGE_TILE_MM.
216        sources.insert("kernel_mul_mm_q4_0_tensor_v2_f32".into(), ggml_mm_tensor_src);
217        sources.insert("kernel_mul_mm_q8_0_tensor_v2_f32".into(), ggml_mm_tensor_src);
218        sources.insert("kernel_mul_mm_q6_K_tensor_v2_f32".into(), ggml_mm_tensor_src);
219        sources.insert("kernel_mul_mm_q5_1_tensor_v2_f32".into(), ggml_mm_tensor_src);
220        sources.insert("kernel_mul_mm_iq4_nl_tensor_v2_f32".into(), ggml_mm_tensor_src);
221        sources.insert("kernel_mul_mm_q5_K_tensor_v2_f32".into(), ggml_mm_tensor_src);
222        sources.insert("kernel_mul_mm_q4_K_tensor_v2_f32".into(), ggml_mm_tensor_src);
223        // ADR-029 iter-28 H29 — whole-tensor dequant from block_q → F16.
224        // Used at model load to materialize an F16 shadow of attn/dense MLP
225        // weights so the runtime dispatch can use kernel_mul_mm_f16_f32_*
226        // (peer's gemma4 pattern).  Trades ~1 GB resident memory for 2-3×
227        // faster per-call dense matmul at prefill.
228        let dequant_to_f16_src: &'static str =
229            include_str!("shaders/dequant_to_f16.metal");
230        sources.insert("hf2q_dequant_q4_0_to_f16".into(), dequant_to_f16_src);
231        sources.insert("hf2q_dequant_q8_0_to_f16".into(), dequant_to_f16_src);
232        sources.insert("hf2q_dequant_q5_1_to_f16".into(), dequant_to_f16_src);
233        sources.insert("hf2q_dequant_iq4_nl_to_f16".into(), dequant_to_f16_src);
234        sources.insert("hf2q_dequant_q4_K_to_f16".into(), dequant_to_f16_src);
235        sources.insert("hf2q_dequant_q5_K_to_f16".into(), dequant_to_f16_src);
236        sources.insert("hf2q_dequant_q6_K_to_f16".into(), dequant_to_f16_src);
237
238        // ADR-022 Phase 1 P1.7 — Q5_1 / IQ4_NL mul_mv_ext r1 family.
239        // Eight instantiations (2 types × 4 r1ptg widths). Each PSO is
240        // additionally specialized at PSO-compile time with FC_mul_mv_nsg
241        // (function_constant 600) and FC_mul_mv_nxpsg (function_constant 601).
242        let mul_mv_ext_src: &'static str = include_str!("shaders/mul_mv_ext.metal");
243        sources.insert("kernel_mul_mv_ext_q5_1_f32_r1_2".into(), mul_mv_ext_src);
244        sources.insert("kernel_mul_mv_ext_q5_1_f32_r1_3".into(), mul_mv_ext_src);
245        sources.insert("kernel_mul_mv_ext_q5_1_f32_r1_4".into(), mul_mv_ext_src);
246        sources.insert("kernel_mul_mv_ext_q5_1_f32_r1_5".into(), mul_mv_ext_src);
247        sources.insert("kernel_mul_mv_ext_iq4_nl_f32_r1_2".into(), mul_mv_ext_src);
248        sources.insert("kernel_mul_mv_ext_iq4_nl_f32_r1_3".into(), mul_mv_ext_src);
249        sources.insert("kernel_mul_mv_ext_iq4_nl_f32_r1_4".into(), mul_mv_ext_src);
250        sources.insert("kernel_mul_mv_ext_iq4_nl_f32_r1_5".into(), mul_mv_ext_src);
251        // ADR-022 Phase 4 — Q4_0 / Q8_0 / Q4_K / Q5_K / Q6_K mv_ext.
252        // 5 types × 4 r1ptg widths = 20 instantiations.
253        for r1 in [2, 3, 4, 5].iter() {
254            for ty in ["q4_0", "q8_0", "q4_K", "q5_K", "q6_K"].iter() {
255                let name = format!("kernel_mul_mv_ext_{ty}_f32_r1_{r1}");
256                sources.insert(name, mul_mv_ext_src);
257            }
258        }
259
260        // Dense bf16×f32 → f32 tensor-API matmul (non-flash-attention
261        // prefill Q@K^T and scores@V, modeled on llama.cpp's
262        // kernel_mul_mm_bf16_f32 with the GGML_METAL_HAS_TENSOR branch
263        // active).  Tile geometry and write-back identical to the
264        // quantized tensor kernel; only the A-stage copy (bfloat →
265        // bfloat, no dequantize) differs.
266        let dense_mm_bf16_tensor_src: &'static str =
267            include_str!("shaders/dense_mm_bf16_tensor.metal");
268        sources.insert("hf2q_dense_mm_bf16_f32_tensor".into(), dense_mm_bf16_tensor_src);
269        // ADR-029 iter-80 H60: V2 large-tile variant (NRA=64, NRB=128).
270        // Same source file (`dense_mm_bf16_tensor.metal`) — second host_name
271        // entry resolves to the V2 kernel appended at the bottom of that
272        // file. Picked at dispatch time when HF2Q_LARGE_TILE_MM=1.
273        sources.insert("hf2q_dense_mm_bf16_f32_tensor_v2".into(), dense_mm_bf16_tensor_src);
274
275        // Dense f32×f32 → f32 tensor-API matmul (F32-everywhere
276        // sibling of dense_mm_bf16_tensor).  Used by hf2q's ADR-005
277        // iter-118 BF16-vs-F32 ViT attention A/B diagnostic to remove
278        // the BF16 K-stage cast as a confounding variable.  Port of
279        // llama.cpp's kernel_mul_mm_f32_f32 specialization
280        // (ggml-metal.metal:10098) on the GGML_METAL_HAS_TENSOR
281        // branch.  Same tile geometry (NR0=64 NR1=32 NK=32) but
282        // float-everywhere shmem staging.
283        let dense_mm_f32_f32_tensor_src: &'static str =
284            include_str!("shaders/dense_mm_f32_f32.metal");
285        sources.insert("hf2q_dense_mm_f32_f32_tensor".into(), dense_mm_f32_f32_tensor_src);
286
287        // Dense f16×f32 → f32 tensor-API matmul (F16-staging sibling
288        // of dense_mm_bf16_tensor).  Used by hf2q's ADR-005 Phase 2c
289        // iter-128 gemma4v ViT precision-parity path: every mmproj
290        // weight is stored as F16 in GGUF, peer's `kernel_mul_mm_f16_f32`
291        // (`ggml-metal.metal:10099`) stages BOTH A and B as `half` in
292        // shmem and computes on `simdgroup_half8x8`.  Matches peer
293        // per-element rounding budget exactly (10-bit mantissa vs
294        // BF16's 7-bit), closing the 1.16x/block cascade compound that
295        // iter-127 numerically bisected to BF16 staging.  Same tile
296        // geometry as the BF16 sibling (NR0=64 NR1=32 NK=32, 8 KB
297        // shmem) — half and bfloat share 16-bit storage.
298        let dense_mm_f16_tensor_src: &'static str =
299            include_str!("shaders/dense_mm_f16_tensor.metal");
300        sources.insert("hf2q_dense_mm_f16_f32_tensor".into(), dense_mm_f16_tensor_src);
301
302        // Dense bf16×f32 → f32 GEMV (matrix-vector multiply) — optimized
303        // for M=1 single-token decode.  Port of llama.cpp's
304        // kernel_mul_mv_bf16_f32_4 (bfloat4-vectorized GEMV kernel).
305        // Used in apply_linear_projection_f32 when seq_len=1 and the
306        // weight matrix is BF16, replacing the MM kernel (~2× faster for
307        // M=1 due to better memory bandwidth utilization per thread).
308        let dense_gemv_bf16_src: &'static str =
309            include_str!("shaders/dense_gemv_bf16.metal");
310        sources.insert("hf2q_dense_gemv_bf16_f32_4".into(), dense_gemv_bf16_src);
311
312        // Fused scale-mask-softmax for the non-flash-attention prefill
313        // path.  One row-local threadgroup per (head, query) pair
314        // replaces three separate dispatches (scale, mask-add, softmax);
315        // reads a bf16 mask (-INF at masked positions, matching
316        // flash_attn_prefill_mask.metal) that is shared across heads.
317        let scale_mask_softmax_src: &'static str =
318            include_str!("shaders/scale_mask_softmax.metal");
319        sources.insert("scale_mask_softmax_f32".into(), scale_mask_softmax_src);
320        // ADR-029 iter-93 H71: float4-vectorized variant for peer parity
321        // with kernel_soft_max_f32_4. Same source file; v4 host_name resolves
322        // to the second kernel appended at the bottom of scale_mask_softmax.metal.
323        sources.insert("scale_mask_softmax_f32_v4".into(), scale_mask_softmax_src);
324
325        // Expert-routed (MoE) quantized matmul kernel (Story 2.1)
326        sources.insert(
327            "quantized_matmul_id".into(),
328            include_str!("shaders/quantized_matmul_id.metal"),
329        );
330
331        // Expert-routed (MoE) GGML block-format quantized matmul kernels
332        let ggml_id_src: &'static str =
333            include_str!("shaders/quantized_matmul_id_ggml.metal");
334        sources.insert("kernel_mul_mv_id_q4_0_f32".into(), ggml_id_src);
335        sources.insert("kernel_mul_mv_id_q8_0_f32".into(), ggml_id_src);
336        // ADR-013 P7 — Q4_K MoE expert-routed mat-vec (port of
337        // llama.cpp's kernel_mul_mv_id_q4_K_f32 at ggml-metal.metal:10349).
338        sources.insert("kernel_mul_mv_id_q4_K_f32".into(), ggml_id_src);
339        sources.insert("kernel_mul_mv_id_q5_K_f32".into(), ggml_id_src);
340        sources.insert("kernel_mul_mv_id_q6_K_f32".into(), ggml_id_src);
341        // ADR-028 iter-321 — q6_K _id with nr0=2 + cached yl[16]
342        // (peer-pattern port mirroring iter-309's non-_id variant).
343        // Env-gated via HF2Q_Q6K_ID_MV_NR2=1 in dispatch_id_mv.
344        sources.insert("kernel_mul_mv_id_q6_K_f32_nr2".into(), ggml_id_src);
345        // ADR-029 iter-6 — q8_0 _id with nr0=2 + nsg=4 cross-SG reduce
346        // (peer-pattern port; peer N_R0_Q8_0=2 + N_SG_Q8_0=4 in
347        //  /opt/llama.cpp/ggml/src/ggml-metal/ggml-metal-impl.h:27,40).
348        // Env-gated via HF2Q_Q8_0_ID_MV_NR2=1 in dispatch_id_mv.
349        sources.insert("kernel_mul_mv_id_q8_0_f32_nr2".into(), ggml_id_src);
350        // ADR-022 Phase 1 — Q5_1 / IQ4_NL MoE expert-routed mat-vec.
351        sources.insert("kernel_mul_mv_id_q5_1_f32".into(), ggml_id_src);
352        sources.insert("kernel_mul_mv_id_iq4_nl_f32".into(), ggml_id_src);
353        // Fused-SwiGLU mv_id variants (ADR-012 §Optimize / Task #15):
354        // computes y[r][n] = sum_k(dequant(W[expert][n][k]) * silu(gate[r][k]) * up[r][k])
355        // in one dispatch — replaces silu_mul + expert_down sequence.
356        sources.insert("kernel_mul_mv_id_q4_0_f32_swiglu".into(), ggml_id_src);
357
358        // Expert-routed (MoE) GGML block-format QUANTIZED MATRIX-MATRIX kernels
359        // (ADR-011 Phase 3 Wave P3a: port of llama.cpp's
360        // `kernel_mul_mm_id_map0_ne20_N` + `kernel_mul_mm_id_<q>_f32`).
361        // Two-stage dispatch: map0 regroups the token-to-expert table into
362        // per-expert routed-token lists, then mm_id stages a 64x32 expert
363        // weight tile into threadgroup shmem and reuses it across a 32-row
364        // block of that expert's routed tokens.
365        let ggml_id_mm_src: &'static str =
366            include_str!("shaders/quantized_matmul_id_mm.metal");
367        sources.insert("kernel_mul_mm_id_map0_ne20_1".into(), ggml_id_mm_src);
368        sources.insert("kernel_mul_mm_id_map0_ne20_8".into(), ggml_id_mm_src);
369        sources.insert("kernel_mul_mm_id_q4_0_f32".into(), ggml_id_mm_src);
370        sources.insert("kernel_mul_mm_id_q8_0_f32".into(), ggml_id_mm_src);
371        sources.insert("kernel_mul_mm_id_q6_K_f32".into(), ggml_id_mm_src);
372        // ADR-013 P16 — Q4_K mm_id (port of llama.cpp ggml-metal.metal:10169).
373        sources.insert("kernel_mul_mm_id_q4_K_f32".into(), ggml_id_mm_src);
374        // ADR-022 Phase 1 P1.6 — Q5_1 / IQ4_NL mm_id template instantiations.
375        sources.insert("kernel_mul_mm_id_q5_1_f32".into(), ggml_id_mm_src);
376        sources.insert("kernel_mul_mm_id_iq4_nl_f32".into(), ggml_id_mm_src);
377        // ADR-022 Phase 2 — Q5_K mm_id template instantiation.
378        sources.insert("kernel_mul_mm_id_q5_K_f32".into(), ggml_id_mm_src);
379
380        // ADR-033 §Pi Task #20 / ADR-034 §93 — fused MoE gate+up+silu_mul
381        // mm_id kernel for Q6_K. Replaces 3 dispatches (gate_mm_id, up_mm_id,
382        // silu_mul_id) with 1 fused dispatch per MoE FFN per layer. Closes
383        // hf2q-vs-llama.cpp prefill gap at production Qwen MoE shapes.
384        let fused_q6_k_mm_id_src: &'static str =
385            include_str!("shaders/fused_gate_up_silu_mm_id_q6_K.metal");
386        sources.insert("kernel_fused_gate_up_silu_mm_id_q6_K_f32".into(), fused_q6_k_mm_id_src);
387
388        // MoE-routed quantized matrix-matrix kernels — tensor API variant
389        // (ADR-011 Phase 3 Wave P3b-tensor).  Uses the MPP tensor_ops
390        // matmul2d primitive for hardware-tensor-core MMA on M3+.  Only
391        // the mm_id kernel is ported — map0 is a short pre-pass (not
392        // matmul) and continues to use the simdgroup version.
393        let ggml_id_mm_tensor_src: &'static str =
394            include_str!("shaders/quantized_matmul_id_mm_tensor.metal");
395        sources.insert("kernel_mul_mm_id_q4_0_tensor_f32".into(), ggml_id_mm_tensor_src);
396        sources.insert("kernel_mul_mm_id_q8_0_tensor_f32".into(), ggml_id_mm_tensor_src);
397        sources.insert("kernel_mul_mm_id_q6_K_tensor_f32".into(), ggml_id_mm_tensor_src);
398        // ADR-013 P16 — Q4_K tensor-API mm_id.
399        sources.insert("kernel_mul_mm_id_q4_K_tensor_f32".into(), ggml_id_mm_tensor_src);
400        // ADR-022 Phase 1 P1.6 — Q5_1 / IQ4_NL tensor-API mm_id.
401        sources.insert("kernel_mul_mm_id_q5_1_tensor_f32".into(), ggml_id_mm_tensor_src);
402        sources.insert("kernel_mul_mm_id_iq4_nl_tensor_f32".into(), ggml_id_mm_tensor_src);
403        // ADR-022 Phase 2 — Q5_K tensor-API mm_id.
404        sources.insert("kernel_mul_mm_id_q5_K_tensor_f32".into(), ggml_id_mm_tensor_src);
405
406        // Embedding kernels (Story 1.5)
407        let embedding_src: &'static str = include_str!("shaders/embedding.metal");
408        sources.insert("embedding_gather_4bit".into(), embedding_src);
409        sources.insert("embedding_gather_6bit".into(), embedding_src);
410
411        // MoE gate kernel (Story 1.5)
412        let moe_gate_src: &'static str = include_str!("shaders/moe_gate.metal");
413        sources.insert("moe_gate".into(), moe_gate_src);
414
415        // MoE dispatch kernels (Story 1.5)
416        let moe_dispatch_src: &'static str = include_str!("shaders/moe_dispatch.metal");
417        sources.insert("fused_gelu_mul".into(), moe_dispatch_src);
418        sources.insert("moe_swiglu_fused".into(), moe_dispatch_src);
419        sources.insert("moe_swiglu_batch".into(), moe_dispatch_src);
420        sources.insert("moe_swiglu_seq".into(), moe_dispatch_src);
421        sources.insert("moe_accumulate".into(), moe_dispatch_src);
422        sources.insert("moe_weighted_sum".into(), moe_dispatch_src);
423        sources.insert("moe_weighted_sum_seq".into(), moe_dispatch_src);
424        sources.insert("zero_buffer".into(), moe_dispatch_src);
425        sources.insert("naive_matvec_f32".into(), moe_dispatch_src);
426        sources.insert("moe_gather_topk_weights".into(), moe_dispatch_src);
427        // bf16 variants (Phase 2 bf16 activation path)
428        sources.insert("fused_gelu_mul_bf16".into(), moe_dispatch_src);
429        sources.insert("moe_swiglu_seq_bf16".into(), moe_dispatch_src);
430        sources.insert("moe_weighted_sum_seq_bf16_input".into(), moe_dispatch_src);
431
432        // ADR-033 §Pi next-iter arc — two-pass MoE mm_id (iter A: map0).
433        // Pre-pass that sorts tokens by expert assignment before the main
434        // mm_id kernel. Ported from llama.cpp's kernel_mul_mm_id_map0; one
435        // template specialization per supported ne20 (n_expert_used).
436        let moe_mm_id_map0_src: &'static str =
437            include_str!("shaders/moe_mm_id_map0.metal");
438        sources.insert("moe_mm_id_map0_ne20_1".into(),  moe_mm_id_map0_src);
439        sources.insert("moe_mm_id_map0_ne20_2".into(),  moe_mm_id_map0_src);
440        sources.insert("moe_mm_id_map0_ne20_4".into(),  moe_mm_id_map0_src);
441        sources.insert("moe_mm_id_map0_ne20_5".into(),  moe_mm_id_map0_src);
442        sources.insert("moe_mm_id_map0_ne20_6".into(),  moe_mm_id_map0_src);
443        sources.insert("moe_mm_id_map0_ne20_8".into(),  moe_mm_id_map0_src);
444        sources.insert("moe_mm_id_map0_ne20_10".into(), moe_mm_id_map0_src);
445        sources.insert("moe_mm_id_map0_ne20_16".into(), moe_mm_id_map0_src);
446        sources.insert("moe_mm_id_map0_ne20_22".into(), moe_mm_id_map0_src);
447
448        // ADR-033 §Pi iter B-1 — main mm_id kernel skeleton (Q4_0). Body
449        // pending iter B-2 (simdgroup matmul + Q4_0 dequant chain). NOT
450        // registered: the shader currently writes zeros for routed tiles, so
451        // registering it would expose a known-wrong pipeline (and prewarm_all
452        // would compile it). The shader file is retained for iter B-2; re-add
453        // the source insert once the real matmul body lands.
454        //   let moe_mm_id_q4_0_src = include_str!("shaders/moe_mm_id_q4_0.metal");
455        //   sources.insert("moe_mm_id_q4_0_f32_skeleton".into(), moe_mm_id_q4_0_src);
456        // ADR-020 iter-11h-e3a: backward kernels for moe_weighted_sum_seq.
457        sources.insert(
458            "moe_weighted_sum_seq_backward_outputs_f32".into(),
459            moe_dispatch_src,
460        );
461        sources.insert(
462            "moe_weighted_sum_seq_backward_weights_f32".into(),
463            moe_dispatch_src,
464        );
465        // ADR-020 iter-11h-e3b: fused backward kernel for moe_swiglu_seq.
466        sources.insert(
467            "moe_swiglu_seq_backward_f32".into(),
468            moe_dispatch_src,
469        );
470
471        // Batched KV cache copy kernels
472        let kv_cache_src: &'static str = include_str!("shaders/kv_cache_copy.metal");
473        sources.insert("kv_cache_copy_batch_f32".into(), kv_cache_src);
474        sources.insert("kv_cache_copy_batch_f32_to_f16".into(), kv_cache_src);
475        sources.insert("kv_cache_copy_seq_f32".into(), kv_cache_src);
476        sources.insert("kv_cache_copy_seq_f32_to_f16".into(), kv_cache_src);
477        // Wave P4.11 — fused K+V copy variants
478        sources.insert("kv_cache_copy_seq_f32_kv_dual".into(), kv_cache_src);
479        sources.insert("kv_cache_copy_seq_f32_to_f16_kv_dual".into(), kv_cache_src);
480        // ADR-028 iter-145 — fused single-position K+V copy variants (decode shape)
481        sources.insert("kv_cache_copy_batch_f32_kv_dual".into(), kv_cache_src);
482        sources.insert("kv_cache_copy_batch_f32_to_f16_kv_dual".into(), kv_cache_src);
483        // bf16-source KV cache copy (Phase 2 bf16 activation path)
484        sources.insert("kv_cache_copy_seq_bf16".into(), kv_cache_src);
485        // ADR-030 iter-95 — bit-exact BF16→BF16 head-major cache copy for
486        // Option A xlen verify (avoids F16 round-trip precision drift).
487        sources.insert("kv_cache_copy_seq_bf16_to_bf16_head_major".into(), kv_cache_src);
488
489        // Elementwise and transpose kernels (Story 1.5)
490        let elementwise_src: &'static str = include_str!("shaders/elementwise.metal");
491        sources.insert("elementwise_add_f32".into(), elementwise_src);
492        sources.insert("elementwise_add_f16".into(), elementwise_src);
493        sources.insert("elementwise_mul_f32".into(), elementwise_src);
494        sources.insert("elementwise_mul_f16".into(), elementwise_src);
495        sources.insert("elementwise_add_bf16".into(), elementwise_src);
496        sources.insert("elementwise_mul_bf16".into(), elementwise_src);
497        sources.insert("cast_f16_to_f32".into(), elementwise_src);
498        sources.insert("cast_f32_to_f16".into(), elementwise_src);
499        sources.insert("cast_bf16_to_f32".into(), elementwise_src);
500        sources.insert("cast_f32_to_bf16".into(), elementwise_src);
501        sources.insert("cast_bf16_to_f16".into(), elementwise_src);
502        sources.insert("cast_f16_to_bf16".into(), elementwise_src);
503        sources.insert("scalar_mul_bf16".into(), elementwise_src);
504        sources.insert("scalar_mul_f32".into(), elementwise_src);
505        sources.insert("embedding_gather_scale_f32".into(), elementwise_src);
506        sources.insert("embedding_gather_scale_batch_f32".into(), elementwise_src);
507        sources.insert("permute_021_bf16".into(), elementwise_src);
508        sources.insert("transpose_last2_bf16".into(), elementwise_src);
509        sources.insert("transpose_last2_f16".into(), elementwise_src);
510        sources.insert("permute_021_f32".into(), elementwise_src);
511        sources.insert("permute_021_bf16_to_f32".into(), elementwise_src);
512        sources.insert("permute_021_f32_to_f16".into(), elementwise_src);
513        sources.insert("transpose_2d_f32".into(), elementwise_src);
514        sources.insert("transpose_2d_f16".into(), elementwise_src);
515
516        // Attention kernels (Story 1.3)
517        let sdpa_src: &'static str = include_str!("shaders/sdpa.metal");
518        sources.insert("sdpa".into(), sdpa_src);
519        sources.insert("sdpa_bf16".into(), sdpa_src);
520        let sdpa_sliding_src: &'static str = include_str!("shaders/sdpa_sliding.metal");
521        sources.insert("sdpa_sliding".into(), sdpa_sliding_src);
522        sources.insert("sdpa_sliding_bf16".into(), sdpa_sliding_src);
523
524        // Flash-attention tiled prefill kernel (ADR-011 Phase 1).
525        // Ten entry points; all backed by the same shader source.
526        // Pipelines are compiled with function constants via
527        // `get_pipeline_with_bool_constants` — not `get_pipeline`.
528        let flash_attn_prefill_src: &'static str =
529            include_str!("shaders/flash_attn_prefill.metal");
530        // D=256 variants (BQ=32, BK=16, WM=4, WN=1 — 128 threads/threadgroup)
531        sources.insert(
532            "steel_attention_float32_bq32_bk16_bd256_wm4_wn1_maskfloat32".into(),
533            flash_attn_prefill_src,
534        );
535        sources.insert(
536            "steel_attention_float32_bq32_bk16_bd256_wm4_wn1_maskbool_".into(),
537            flash_attn_prefill_src,
538        );
539        sources.insert(
540            "steel_attention_bfloat16_bq32_bk16_bd256_wm4_wn1_maskbfloat16".into(),
541            flash_attn_prefill_src,
542        );
543        sources.insert(
544            "steel_attention_bfloat16_bq32_bk16_bd256_wm4_wn1_maskbool_".into(),
545            flash_attn_prefill_src,
546        );
547        sources.insert(
548            "steel_attention_float16_bq32_bk16_bd256_wm4_wn1_maskfloat16".into(),
549            flash_attn_prefill_src,
550        );
551        sources.insert(
552            "steel_attention_float16_bq32_bk16_bd256_wm4_wn1_maskbool_".into(),
553            flash_attn_prefill_src,
554        );
555        // D=512 variants (BQ=8, BK=8, WM=1, WN=1 — 32 threads/threadgroup)
556        // NOTE: f32 at D=512 is NOT instantiated — threadgroup memory exceeds
557        // the 32 KB Metal limit (candle sdpa.rs:86-94).
558        sources.insert(
559            "steel_attention_bfloat16_bq8_bk8_bd512_wm1_wn1_maskbfloat16".into(),
560            flash_attn_prefill_src,
561        );
562        sources.insert(
563            "steel_attention_bfloat16_bq8_bk8_bd512_wm1_wn1_maskbool_".into(),
564            flash_attn_prefill_src,
565        );
566        sources.insert(
567            "steel_attention_float16_bq8_bk8_bd512_wm1_wn1_maskfloat16".into(),
568            flash_attn_prefill_src,
569        );
570        sources.insert(
571            "steel_attention_float16_bq8_bk8_bd512_wm1_wn1_maskbool_".into(),
572            flash_attn_prefill_src,
573        );
574
575        // Flash attention vector kernels — SIMD-vectorized decode-path SDPA
576        // (ported from llama.cpp flash_attn_ext_vec)
577        let flash_attn_vec_src: &'static str =
578            include_str!("shaders/flash_attn_vec.metal");
579        sources.insert("flash_attn_vec_dk256".into(), flash_attn_vec_src);
580        sources.insert("flash_attn_vec_dk512".into(), flash_attn_vec_src);
581        sources.insert("flash_attn_vec_reduce_dk128".into(), flash_attn_vec_src);
582        sources.insert("flash_attn_vec_reduce_dk256".into(), flash_attn_vec_src);
583        sources.insert("flash_attn_vec_reduce_dk512".into(), flash_attn_vec_src);
584        // F16 KV variants (Phase 4a)
585        sources.insert("flash_attn_vec_f16kv_dk256".into(), flash_attn_vec_src);
586        sources.insert("flash_attn_vec_f16kv_dk512".into(), flash_attn_vec_src);
587
588        // ADR-037 Phase E1.1 (2026-05-22) — tree-attention kernel for
589        // EAGLE-3 + dynamic tree speculative decoding. Variant of
590        // flash_attn_vec consuming an explicit per-(query, kv_pos) mask
591        // buffer instead of implicit causal. Reduce pass reuses
592        // flash_attn_vec_reduce_* (identical output layout).
593        let tree_attention_src: &'static str =
594            include_str!("shaders/tree_attention.metal");
595        sources.insert("tree_attention_dk128".into(), tree_attention_src);
596        sources.insert("tree_attention_dk256".into(), tree_attention_src);
597        sources.insert("tree_attention_dk512".into(), tree_attention_src);
598        sources.insert("tree_attention_f16kv_dk128".into(), tree_attention_src);
599        sources.insert("tree_attention_f16kv_dk256".into(), tree_attention_src);
600        sources.insert("tree_attention_f16kv_dk512".into(), tree_attention_src);
601
602        // RoPE, normalization, activation kernels (Story 1.4)
603        let rope_src: &'static str = include_str!("shaders/rope.metal");
604        sources.insert("rope_f32".into(), rope_src);
605        sources.insert("rope_f16".into(), rope_src);
606        sources.insert("rope_bf16".into(), rope_src);
607        sources.insert("rope_neox_bf16".into(), rope_src);
608        sources.insert("rope_neox_f32".into(), rope_src);
609        let rms_norm_src: &'static str = include_str!("shaders/rms_norm.metal");
610        sources.insert("rms_norm_f32".into(), rms_norm_src);
611        // ADR-028 iter-310 — float4 + simd_sum variants (peer-pattern,
612        // ported from llama.cpp kernel_rms_norm_fuse_impl<float4, 1>).
613        // Env-gated via HF2Q_RMS_NORM_V2=1 in the dispatchers.
614        sources.insert("rms_norm_f32_v2".into(), rms_norm_src);
615        sources.insert("rms_norm_no_scale_f32_v2".into(), rms_norm_src);
616        sources.insert("rms_norm_f16".into(), rms_norm_src);
617        sources.insert("rms_norm_bf16".into(), rms_norm_src);
618        sources.insert("rms_norm_no_scale_bf16".into(), rms_norm_src);
619        sources.insert("rms_norm_no_scale_f32".into(), rms_norm_src);
620        sources.insert("rms_norm_no_scale_f32_dual".into(), rms_norm_src);
621        sources.insert("rms_norm_f32_triple".into(), rms_norm_src);
622        sources.insert("fused_post_attn_triple_norm_f32".into(), rms_norm_src);
623        // ADR-028 iter-370: V2 (float4 + simd_sum) variant of triple_norm.
624        sources.insert("fused_post_attn_triple_norm_f32_v2".into(), rms_norm_src);
625        // ADR-028 iter-217: fused post-FF norm 2 + end-of-layer FINAL
626        // (combines 2 sequential fused_norm_add dispatches into 1 kernel).
627        sources.insert("fused_post_ff_norm2_endlayer_f32".into(), rms_norm_src);
628        // ADR-028 iter-362: V2 (float4 + simd_sum) variant of the above.
629        // Same math, 75% fewer barriers per dispatch (4 vs 16 at tg=256).
630        sources.insert("fused_post_ff_norm2_endlayer_f32_v2".into(), rms_norm_src);
631        // ADR-028 iter-367: V2 fusion of moe_weighted_sum INTO Path A end-of-layer.
632        // Eliminates 1 dispatch + moe_accum round-trip from gemma4 decode default.
633        sources.insert("fused_moe_wsum_post_ff_norm2_endlayer_f32_v2".into(), rms_norm_src);
634        sources.insert("rms_norm_no_scale_f32_dual_perm".into(), rms_norm_src);
635        // Fused RMS norm + elementwise multiply kernels (Phase 4e.2)
636        sources.insert("rms_norm_mul_f32".into(), rms_norm_src);
637        sources.insert("rms_norm_mul_f16".into(), rms_norm_src);
638        sources.insert("rms_norm_mul_bf16".into(), rms_norm_src);
639        // L2 norm kernels (ADR-013 Decision 3 — Gated DeltaNet Q/K norm)
640        let l2_norm_src: &'static str = include_str!("shaders/l2_norm.metal");
641        sources.insert("l2_norm_f32".into(), l2_norm_src);
642        sources.insert("l2_norm_f16".into(), l2_norm_src);
643        sources.insert("l2_norm_bf16".into(), l2_norm_src);
644        // ADR-015 iter59a — fused L2 norm + scalar multiply (DN q-path).
645        sources.insert("l2_norm_scale_f32".into(), l2_norm_src);
646        // Cumulative-sum kernels (ADR-013 Decision 4 — DeltaNet decay-mask base)
647        let cumsum_src: &'static str = include_str!("shaders/cumsum.metal");
648        sources.insert("cumsum_f32".into(), cumsum_src);
649        sources.insert("cumsum_bf16".into(), cumsum_src);
650        // SSM conv kernels (ADR-013 Decision 7 — DeltaNet 1D causal conv + SiLU)
651        let ssm_conv_src: &'static str = include_str!("shaders/ssm_conv.metal");
652        sources.insert("ssm_conv_forward_f32".into(), ssm_conv_src);
653        sources.insert("ssm_conv_forward_bf16".into(), ssm_conv_src);
654        sources.insert("ssm_conv_state_update_f32".into(), ssm_conv_src);
655        sources.insert("ssm_conv_state_update_bf16".into(), ssm_conv_src);
656        // Tri-solve kernels (ADR-013 Decision 5 — chunked DeltaNet debug path)
657        let tri_solve_src: &'static str = include_str!("shaders/tri_solve.metal");
658        sources.insert("tri_solve_lower_unit_f32".into(), tri_solve_src);
659        sources.insert("tri_solve_lower_unit_bf16".into(), tri_solve_src);
660        // Rope-multi kernels (ADR-013 Decision 10 — IMROPE for Qwen3.5)
661        let rope_multi_src: &'static str = include_str!("shaders/rope_multi.metal");
662        sources.insert("rope_multi_f32".into(), rope_multi_src);
663        sources.insert("rope_multi_bf16".into(), rope_multi_src);
664        // Gated DeltaNet fused kernel (ADR-013 Decision 6 — centerpiece)
665        let gdn_src: &'static str = include_str!("shaders/gated_delta_net.metal");
666        sources.insert("gated_delta_net_f32".into(), gdn_src);
667        // ADR-015 iter56 — decode-only `simd_sum` variant. Three NSG-templated
668        // host names share the same source; selection is by D_k via
669        // `dispatch_gated_delta_net_decode`. Drop-in for the fused kernel
670        // above when n_tokens=1.
671        let gdn_decode_src: &'static str =
672            include_str!("shaders/gated_delta_net_decode.metal");
673        sources.insert("gated_delta_net_decode_f32_1".into(), gdn_decode_src);
674        sources.insert("gated_delta_net_decode_f32_2".into(), gdn_decode_src);
675        sources.insert("gated_delta_net_decode_f32_4".into(), gdn_decode_src);
676        // Wave 5b — chunk-parallel inter-chunk state-recurrence kernel
677        // (the one new kernel in the chunk-parallel pipeline; spec source:
678        // arXiv 2412.06464 §4 + FLA chunk_delta_h.py:43-298).
679        let gdn_chunk_src: &'static str =
680            include_str!("shaders/gated_delta_net_chunk.metal");
681        sources.insert(
682            "gated_delta_net_chunk_inter_state_bf16".into(),
683            gdn_chunk_src,
684        );
685        // ADR-033 §Pi Task #25 iter 19 — K=256 native variant. Same algorithm
686        // as gated_delta_net_chunk_inter_state_bf16 but with compile-time
687        // 32-tile MMA loops (vs 16 for K=128). Required for Qwen3.6's
688        // head_dim=256 chunk-scan path support. Per the K=128 kernel's
689        // documented constraint at gated_delta_net_chunk.metal:441, runtime-K
690        // bounds defeat MMA scheduling — this separate kernel keeps K=256
691        // compile-time-known, avoiding the 3.15× regression.
692        let gdn_chunk_k256_src: &'static str =
693            include_str!("shaders/gated_delta_net_chunk_k256.metal");
694        sources.insert(
695            "gated_delta_net_chunk_inter_state_bf16_k256".into(),
696            gdn_chunk_k256_src,
697        );
698        // ADR-033 §Pi Task #25 iter 20 — K=256 native chunk_o variant.
699        // Sister kernel to iter 19's inter_state_k256. Bumped from K=128's
700        // num_k_tiles=16 to num_k_tiles=32; bo_acc/bA_acc accumulators are
701        // V/BT-indexed (not K-indexed) so they keep their original sizes.
702        let gdn_chunk_o_k256_src: &'static str =
703            include_str!("shaders/gated_delta_net_chunk_o_k256.metal");
704        sources.insert(
705            "gated_delta_net_chunk_o_bf16_k256".into(),
706            gdn_chunk_o_k256_src,
707        );
708        // Wave 5b.1 iter 2 — chunk_scaled_dot_kkt kernel (input-side of
709        // the chunk pipeline; spec source: FLA chunk_scaled_dot_kkt.py:36-99).
710        let gdn_kkt_src: &'static str =
711            include_str!("shaders/gated_delta_net_kkt.metal");
712        sources.insert("gated_delta_net_kkt_bf16".into(), gdn_kkt_src);
713        // Wave 5b.1 iter 2 — recompute_w_u_fwd kernel (applies post-solve A
714        // to (β·v) and (β·k·exp(g)) to produce w and u; spec source: FLA
715        // wy_fast.py:29-117).
716        let gdn_recompute_wu_src: &'static str =
717            include_str!("shaders/gated_delta_net_recompute_wu.metal");
718        sources.insert(
719            "gated_delta_net_recompute_wu_bf16".into(),
720            gdn_recompute_wu_src,
721        );
722        // Wave 5b.1 iter 3 — chunk_fwd_o kernel (per-chunk output: closes
723        // the chunk pipeline; spec source: FLA chunk_o.py:42-138).
724        let gdn_chunk_o_src: &'static str =
725            include_str!("shaders/gated_delta_net_chunk_o.metal");
726        sources.insert("gated_delta_net_chunk_o_bf16".into(), gdn_chunk_o_src);
727        // Wave 5b.1 iter 4 — orchestrator helper kernels:
728        //   chunk_local_cumsum_g_f32      — per-chunk prefix sum on g [B, T, H]
729        //   chunk_tri_solve_invert_f32    — per-chunk-block (I + A_strict)^-1
730        //                                   on FLA's [B, T, H, BT] layout.
731        let chunk_local_cumsum_g_src: &'static str =
732            include_str!("shaders/chunk_local_cumsum_g.metal");
733        sources.insert(
734            "chunk_local_cumsum_g_f32".into(),
735            chunk_local_cumsum_g_src,
736        );
737        let chunk_tri_solve_invert_src: &'static str =
738            include_str!("shaders/chunk_gated_delta_rule_tri_solve_invert.metal");
739        sources.insert(
740            "chunk_tri_solve_invert_f32".into(),
741            chunk_tri_solve_invert_src,
742        );
743        // Sigmoid-gated elementwise multiply (ADR-013 Decision 9 — full-attn output gate)
744        let sigmoid_mul_src: &'static str = include_str!("shaders/sigmoid_mul.metal");
745        sources.insert("sigmoid_mul_f32".into(), sigmoid_mul_src);
746        sources.insert("sigmoid_mul_bf16".into(), sigmoid_mul_src);
747        let silu_mul_src: &'static str = include_str!("shaders/silu_mul.metal");
748        sources.insert("silu_mul_f32".into(), silu_mul_src);
749        // ADR-033 §Pi Task #25 iter 16 — K-bank slice copy for K=256 → 2×K=128
750        // bank-split chunk-scan path (Qwen3.6 head_dim=256 support).
751        let bank_slice_bf16_src: &'static str =
752            include_str!("shaders/bank_slice_bf16.metal");
753        sources.insert("bank_slice_bf16".into(), bank_slice_bf16_src);
754        // ADR-033 §Pi Task #25 iter 17 — F32 variants (for h0 input and
755        // final_state output) + concat (inverse of slice, for assembling
756        // the K=256 final_state from per-bank K=128 outputs). Same source
757        // file — multiple kernels share the BankSliceParams struct.
758        sources.insert("bank_slice_f32".into(), bank_slice_bf16_src);
759        sources.insert("bank_concat_f32".into(), bank_slice_bf16_src);
760        // ADR-034 task #93 — fused gate_proj + up_proj + silu_mul Q8_0.
761        let fused_gate_up_silu_q8_0_src: &'static str =
762            include_str!("shaders/fused_gate_up_silu_q8_0.metal");
763        sources.insert(
764            "kernel_fused_gate_up_silu_q8_0_f32".into(),
765            fused_gate_up_silu_q8_0_src,
766        );
767        // ADR-034 task #94 — fused dual Q4_0 projection (FA Q/K/V/gate fuse).
768        let fused_dual_proj_q4_0_src: &'static str =
769            include_str!("shaders/fused_dual_proj_q4_0.metal");
770        sources.insert(
771            "kernel_fused_dual_proj_q4_0_f32".into(),
772            fused_dual_proj_q4_0_src,
773        );
774        // ADR-034 task #93 cont. 24 — fused gate+up+silu_mul Q4_K (broader quant coverage).
775        #[allow(non_snake_case)]
776        let fused_gate_up_silu_q4_K_src: &'static str =
777            include_str!("shaders/fused_gate_up_silu_q4_K.metal");
778        sources.insert(
779            "kernel_fused_gate_up_silu_q4_K_f32".into(),
780            fused_gate_up_silu_q4_K_src,
781        );
782        // ADR-034 task #93 cont. 26 — fused gate+up+silu_mul IQ4_NL.
783        let fused_gate_up_silu_iq4_nl_src: &'static str =
784            include_str!("shaders/fused_gate_up_silu_iq4_nl.metal");
785        sources.insert(
786            "kernel_fused_gate_up_silu_iq4_nl_f32".into(),
787            fused_gate_up_silu_iq4_nl_src,
788        );
789        // ADR-034 task #93 cont. 27 — fused gate+up+silu_mul Q5_K.
790        #[allow(non_snake_case)]
791        let fused_gate_up_silu_q5_K_src: &'static str =
792            include_str!("shaders/fused_gate_up_silu_q5_K.metal");
793        sources.insert(
794            "kernel_fused_gate_up_silu_q5_K_f32".into(),
795            fused_gate_up_silu_q5_K_src,
796        );
797        // ADR-034 task #93 cont. 28 — fused gate+up+silu_mul Q6_K.
798        #[allow(non_snake_case)]
799        let fused_gate_up_silu_q6_K_src: &'static str =
800            include_str!("shaders/fused_gate_up_silu_q6_K.metal");
801        sources.insert(
802            "kernel_fused_gate_up_silu_q6_K_f32".into(),
803            fused_gate_up_silu_q6_K_src,
804        );
805        let compute_g_beta_src: &'static str = include_str!("shaders/compute_g_beta.metal");
806        sources.insert("compute_g_beta_f32".into(), compute_g_beta_src);
807        let ssm_norm_gate_src: &'static str = include_str!("shaders/ssm_norm_gate.metal");
808        sources.insert("ssm_norm_gate_f32".into(), ssm_norm_gate_src);
809        let gelu_src: &'static str = include_str!("shaders/gelu.metal");
810        sources.insert("gelu_f32".into(), gelu_src);
811        sources.insert("gelu_f16".into(), gelu_src);
812        sources.insert("gelu_bf16".into(), gelu_src);
813        let softmax_src: &'static str = include_str!("shaders/softmax.metal");
814        sources.insert("softmax_f32".into(), softmax_src);
815        sources.insert("softmax_f16".into(), softmax_src);
816        sources.insert("softmax_bf16".into(), softmax_src);
817        let softmax_backward_src: &'static str =
818            include_str!("shaders/softmax_backward.metal");
819        sources.insert("softmax_backward_f32".into(), softmax_backward_src);
820        let log_elementwise_src: &'static str =
821            include_str!("shaders/log_elementwise.metal");
822        sources.insert("log_f32".into(), log_elementwise_src);
823        sources.insert("log_backward_f32".into(), log_elementwise_src);
824        let row_sum_src: &'static str = include_str!("shaders/row_sum.metal");
825        sources.insert("row_sum_f32".into(), row_sum_src);
826        sources.insert("row_sum_backward_f32".into(), row_sum_src);
827        // ADR-020 iter-10a: GGUF-legacy quantize-dequantize round-trip kernels
828        // (Q4_0 + Q8_0).  Used by hf2q's dynamic_quant Track 1 to produce
829        // W_low / W_high for the gradient-Taylor sensitivity formula.
830        let qdq_legacy_src: &'static str = include_str!("shaders/qdq_legacy.metal");
831        sources.insert("qdq_q4_0_f32".into(), qdq_legacy_src);
832        sources.insert("qdq_q8_0_f32".into(), qdq_legacy_src);
833        // ADR-020 iter-10b: RMSNorm reverse-mode autograd kernels.
834        // r_inv helper is reused by both backward kernels; dx and dw cover
835        // the full backward identity for `y = x * rsqrt(mean(x²) + eps) * w`.
836        let rms_norm_backward_src: &'static str =
837            include_str!("shaders/rms_norm_backward.metal");
838        sources.insert(
839            "rms_norm_compute_rms_inv_f32".into(),
840            rms_norm_backward_src,
841        );
842        sources.insert("rms_norm_backward_dx_f32".into(), rms_norm_backward_src);
843        sources.insert("rms_norm_backward_dw_f32".into(), rms_norm_backward_src);
844        // ADR-020 iter-11a: 2-D row-major slice + concat-by-column kernels.
845        // Used by hf2q's multi-head SDPA on GpuTape (slice Q/K/V into
846        // per-head views, run per-head SDPA, concat per-head contexts
847        // back to full attention output).
848        let slice_concat_2d_src: &'static str =
849            include_str!("shaders/slice_concat_2d.metal");
850        sources.insert("slice_2d_cols_f32".into(), slice_concat_2d_src);
851        sources.insert("copy_2d_cols_into_f32".into(), slice_concat_2d_src);
852        // ADR-020 iter-11b: SiLU forward + backward kernels for GpuTape
853        // SwiGLU FFN composition.
854        let silu_backward_src: &'static str =
855            include_str!("shaders/silu_backward.metal");
856        sources.insert("silu_f32".into(), silu_backward_src);
857        sources.insert("silu_backward_f32".into(), silu_backward_src);
858        // ADR-020 iter-11d: FP32 embedding lookup + scatter-add backward.
859        let embedding_autograd_src: &'static str =
860            include_str!("shaders/embedding_autograd.metal");
861        sources.insert("embedding_lookup_f32".into(), embedding_autograd_src);
862        sources.insert(
863            "embedding_scatter_add_f32".into(),
864            embedding_autograd_src,
865        );
866        // ADR-020 iter-13a: Adam optimizer step kernel for Track 2
867        // DWQ-proper training loop.
868        let adam_update_src: &'static str =
869            include_str!("shaders/adam_update.metal");
870        sources.insert("adam_update_f32".into(), adam_update_src);
871        // ADR-020 iter-13b: differentiable affine qdq kernels for the
872        // DWQ-proper training loop.  Init + forward + backward (scales,
873        // biases) — q_int is FROZEN, scales+biases learnable.
874        let qdq_affine_src: &'static str =
875            include_str!("shaders/qdq_affine.metal");
876        sources.insert("qdq_affine_init_f32".into(), qdq_affine_src);
877        sources.insert("qdq_affine_forward_f32".into(), qdq_affine_src);
878        sources.insert(
879            "qdq_affine_backward_scales_f32".into(),
880            qdq_affine_src,
881        );
882        sources.insert(
883            "qdq_affine_backward_biases_f32".into(),
884            qdq_affine_src,
885        );
886        // ADR-020 iter-15: fused affine quantized matmul for DWQ inference.
887        // Per-element kernel; one thread per (m, n) output element.
888        // Tiled + simdgroup-MMA variant lands in iter-15b.
889        let qmm_affine_src: &'static str =
890            include_str!("shaders/qmm_affine.metal");
891        sources.insert("qmm_affine_t_f32".into(), qmm_affine_src);
892        // ADR-020 iter-15b: tiled variant — 16x16 thread block with
893        // cooperative-load X/W tiles in threadgroup-shared memory for
894        // 2-5x speedup over the per-element kernel.
895        let qmm_affine_tiled_src: &'static str =
896            include_str!("shaders/qmm_affine_tiled.metal");
897        sources.insert(
898            "qmm_affine_t_f32_tiled".into(),
899            qmm_affine_tiled_src,
900        );
901        // ADR-020 iter-15c: simdgroup-MMA variant — uses Apple GPU
902        // hardware `simdgroup_matrix<float, 8, 8>` MMA for the inner
903        // reduction.  Per-tile algorithmic 8× over scalar tiled, lands
904        // as ~3-4× wall after launch / load amortization.
905        let qmm_affine_simd_src: &'static str =
906            include_str!("shaders/qmm_affine_simd.metal");
907        sources.insert(
908            "qmm_affine_t_f32_simd".into(),
909            qmm_affine_simd_src,
910        );
911        // ADR-020 iter-15c-2: 4-simdgroup-per-TG variant — 32×32
912        // output tile, 4 simdgroups arranged as 2×2 grid each owning
913        // a 16×16 sub-tile = 4 simdgroup_matrix accumulators.  Same
914        // math as 15c-1, fuller warp-pool exploitation.
915        let qmm_affine_simd4_src: &'static str =
916            include_str!("shaders/qmm_affine_simd4.metal");
917        sources.insert(
918            "qmm_affine_t_f32_simd4".into(),
919            qmm_affine_simd4_src,
920        );
921        // ADR-020 iter-15c-2b: gs=64 variant (mlx-lm dynamic_quant
922        // canonical default).  Same 4-simdgroup geometry, BK=64
923        // instead of 32 (= 8 sub-K-tiles per K-step instead of 4).
924        let qmm_affine_simd4_gs64_src: &'static str =
925            include_str!("shaders/qmm_affine_simd4_gs64.metal");
926        sources.insert(
927            "qmm_affine_t_f32_simd4_gs64".into(),
928            qmm_affine_simd4_gs64_src,
929        );
930        // ADR-020 AC#5 Iter A: packed-U32 dense affine matmul (bits=4,
931        // gs=32) — production decode/prefill kernel for serving DWQ
932        // safetensors directly without a load-time unpack pass.
933        let qmm_affine_t_packed_simd4_b4_src: &'static str =
934            include_str!("shaders/qmm_affine_t_packed_simd4_b4.metal");
935        sources.insert(
936            "qmm_affine_t_packed_simd4_b4".into(),
937            qmm_affine_t_packed_simd4_b4_src,
938        );
939        // ADR-020 iter-11h-b: training-mode causal depthwise 1D
940        // convolution (forward + backward dx + backward dw).  Used by
941        // GpuTape autograd for differentiable Qwen3.5MoE forward
942        // (GatedDeltaNet's conv1d step).
943        let conv1d_dwc_src: &'static str =
944            include_str!("shaders/conv1d_depthwise_causal.metal");
945        sources.insert(
946            "conv1d_depthwise_causal_forward_f32".into(),
947            conv1d_dwc_src,
948        );
949        sources.insert(
950            "conv1d_depthwise_causal_backward_dx_f32".into(),
951            conv1d_dwc_src,
952        );
953        sources.insert(
954            "conv1d_depthwise_causal_backward_dw_f32".into(),
955            conv1d_dwc_src,
956        );
957        // ADR-020 iter-11h-c1: elementwise exp forward + backward.
958        // Building block for GatedDeltaNet's alpha = exp(-g) state-decay.
959        let exp_src: &'static str =
960            include_str!("shaders/exp_elementwise.metal");
961        sources.insert("exp_f32".into(), exp_src);
962        sources.insert("exp_backward_f32".into(), exp_src);
963        // ADR-020 iter-11h-c2: vector outer product (forward + dlhs +
964        // drhs).  Building block for gated_delta_update's
965        // outer(delta, k) state-update term.
966        let outer_src: &'static str =
967            include_str!("shaders/outer_product.metal");
968        sources.insert("outer_product_f32".into(), outer_src);
969        sources.insert("outer_product_backward_lhs_f32".into(), outer_src);
970        sources.insert("outer_product_backward_rhs_f32".into(), outer_src);
971        // ADR-020 iter-11h-e1: take_along_axis (gather) + scatter-backward.
972        // Building block for MoE router on GpuTape.
973        let taa_src: &'static str =
974            include_str!("shaders/take_along_axis.metal");
975        sources.insert("take_along_axis_f32".into(), taa_src);
976        sources.insert("take_along_axis_backward_f32".into(), taa_src);
977        // ADR-020 iter-11h-misc-1: elementwise divide forward + backward.
978        let div_src: &'static str =
979            include_str!("shaders/divide_elementwise.metal");
980        sources.insert("divide_f32".into(), div_src);
981        sources.insert("divide_backward_f32".into(), div_src);
982        // ADR-020 iter-11h-misc-3: elementwise sqrt forward + backward.
983        let sqrt_src: &'static str =
984            include_str!("shaders/sqrt_elementwise.metal");
985        sources.insert("sqrt_f32".into(), sqrt_src);
986        sources.insert("sqrt_backward_f32".into(), sqrt_src);
987        let softcap_src: &'static str = include_str!("shaders/softcap.metal");
988        sources.insert("softcap_f32".into(), softcap_src);
989        sources.insert("softcap_f16".into(), softcap_src);
990        sources.insert("softcap_bf16".into(), softcap_src);
991
992        // Fused norm-add kernels — Gemma4 post-attention / post-FFN ordering:
993        //   normed = rms_norm(input, weight, eps);  output = residual + normed
994        let fused_norm_add_src: &'static str =
995            include_str!("shaders/fused_norm_add_bf16.metal");
996        sources.insert("fused_norm_add_bf16".into(), fused_norm_add_src);
997        sources.insert("fused_norm_add_no_weight_bf16".into(), fused_norm_add_src);
998
999        // Fused head-norm + RoPE f32 kernel — replaces separate rms_norm + rope_neox_f32
1000        let fused_hnr_f32_src: &'static str =
1001            include_str!("shaders/fused_head_norm_rope_f32.metal");
1002        sources.insert("fused_head_norm_rope_f32".into(), fused_hnr_f32_src);
1003        // ADR-028 iter-337 — float4 + simd_sum Phase 1 variant.  Phases
1004        // 2-4 byte-identical to v1; race-fix barrier preserved.  Env-gated
1005        // via HF2Q_FUSED_HEAD_NORM_ROPE_V2 (default ON, opt-out via =0).
1006        sources.insert("fused_head_norm_rope_f32_v2".into(), fused_hnr_f32_src);
1007
1008        // Fused head-norm + RoPE bf16 kernels (single-token + batch prefill)
1009        // Both entry points live in the same .metal file.
1010        let fused_hnr_bf16_src: &'static str =
1011            include_str!("shaders/fused_head_norm_rope_bf16.metal");
1012        sources.insert("fused_head_norm_rope_bf16".into(), fused_hnr_bf16_src);
1013        sources.insert("fused_head_norm_rope_batch_bf16".into(), fused_hnr_bf16_src);
1014
1015        // Fused norm-add f32 kernels — post-attention / post-FFN / end-of-layer
1016        let fused_norm_add_f32_src: &'static str =
1017            include_str!("shaders/fused_norm_add_f32.metal");
1018        sources.insert("fused_norm_add_f32".into(), fused_norm_add_f32_src);
1019        // ADR-028 iter-331 — float4 + simd_sum variant (peer-pattern,
1020        // ported from llama.cpp kernel_rms_norm_fuse_impl<float4, 3>).
1021        // Env-gated via HF2Q_FUSED_NORM_ADD_V2=1 in the dispatcher
1022        // (default ON since iter-331; opt-out via =0/false/off).
1023        sources.insert("fused_norm_add_f32_v2".into(), fused_norm_add_f32_src);
1024        sources.insert("fused_residual_norm_f32".into(), fused_norm_add_f32_src);
1025        sources.insert("fused_residual_norm_scalar_f32".into(), fused_norm_add_f32_src);
1026        sources.insert("fused_moe_routing_f32".into(), fused_norm_add_f32_src);
1027        // ADR-028 iter-363: V2 (simd_max + simd_sum) variant of MoE routing.
1028        sources.insert("fused_moe_routing_f32_v2".into(), fused_norm_add_f32_src);
1029        // ADR-029 iter-175 Step 1i: V3 = V2 + parallel SG-tournament top-K
1030        // (replaces V2's single-thread serial scan for k = 0..top_k).
1031        sources.insert("fused_moe_routing_f32_v3".into(), fused_norm_add_f32_src);
1032        sources.insert("fused_moe_routing_batch_f32".into(), fused_norm_add_f32_src);
1033        // ADR-029 iter-175 Step 1j: batched-prefill V3 (same parallel
1034        // SG-tournament top-K as fused_moe_routing_f32_v3, applied per-token
1035        // within each TG of the batched dispatch).
1036        sources.insert("fused_moe_routing_batch_f32_v3".into(), fused_norm_add_f32_src);
1037        sources.insert("fused_norm_add_scalar_f32".into(), fused_norm_add_f32_src);
1038        sources.insert("fused_moe_wsum_norm_add_f32".into(), fused_norm_add_f32_src);
1039        sources.insert("fused_moe_wsum_dnorm_add_f32".into(), fused_norm_add_f32_src);
1040
1041        // Argsort kernel (Story 2.3) — MoE top-K routing
1042        let argsort_src: &'static str = include_str!("shaders/argsort.metal");
1043        sources.insert("argsort_desc_f32".into(), argsort_src);
1044
1045        // Gather / index_select kernel (Story 2.4)
1046        let gather_src: &'static str = include_str!("shaders/gather.metal");
1047        sources.insert("gather_f32".into(), gather_src);
1048
1049        // F32 KV cache copy kernel (Session merge S1+S2)
1050        let kv_cache_copy_src: &'static str =
1051            include_str!("shaders/kv_cache_copy.metal");
1052        sources.insert("kv_cache_copy".into(), kv_cache_copy_src);
1053        sources.insert("kv_cache_copy_f32".into(), kv_cache_copy_src);
1054
1055        // Strided copy kernel (Story 2.5)
1056        let copy_src: &'static str = include_str!("shaders/copy.metal");
1057        sources.insert("strided_copy_f32".into(), copy_src);
1058        sources.insert("offset_copy_f32".into(), copy_src);
1059
1060        // Fused-QKV split kernel (ADR-005 W-5b.18 — replaces hf2q CPU
1061        // download → triple-loop split → 3× upload round-trip in
1062        // gpu_delta_net::layer_qkv_deinterleave).
1063        let qkv_split_src: &'static str = include_str!("shaders/qkv_split.metal");
1064        sources.insert("qkv_split_f32".into(), qkv_split_src);
1065
1066        // Tiled-GQA broadcast kernel (ADR-005 W-5b.19 — replaces hf2q CPU
1067        // tiled-replicate at gpu_delta_net::apply_gated_delta_net_chunk
1068        // GQA pre-expansion, ~497 ms / 10.4 ms-per-layer at PP4106).
1069        let repeat_tiled_src: &'static str =
1070            include_str!("shaders/repeat_tiled.metal");
1071        sources.insert("repeat_tiled_f32".into(), repeat_tiled_src);
1072
1073        // Dense F16 GEMM kernel (Story 2.6) — lm_head projection
1074        let dense_gemm_src: &'static str = include_str!("shaders/dense_gemm.metal");
1075        sources.insert("dense_gemm_f16".into(), dense_gemm_src);
1076        sources.insert("dense_matvec_f16".into(), dense_gemm_src);
1077        sources.insert("dense_matvec_f16w_f32io".into(), dense_gemm_src);
1078        // BF16-weight mat-vec: BF16 weights × F32 input → F32 output (decode lm_head)
1079        sources.insert("dense_matvec_bf16w_f32io".into(), dense_gemm_src);
1080        // Pure F32 mat-vec: F32 weights × F32 input → F32 output (decode lm_head)
1081        sources.insert("dense_matvec_f32".into(), dense_gemm_src);
1082
1083        // Standalone FWHT for TurboQuant pre/post-rotation (SIMD shuffle, zero barriers)
1084        let fwht_src: &'static str = include_str!("shaders/fwht_standalone.metal");
1085        sources.insert("fwht_standalone_f32_d256".into(), fwht_src);
1086        sources.insert("fwht_standalone_f32_d512".into(), fwht_src);
1087        // ADR-007 iter-14 D1 SRHT variants: sign pre-mult (for Q) + sign undo (for output)
1088        sources.insert("fwht_sign_premult_f32_d256".into(), fwht_src);
1089        sources.insert("fwht_sign_premult_f32_d512".into(), fwht_src);
1090        sources.insert("fwht_sign_undo_f32_d256".into(), fwht_src);
1091        sources.insert("fwht_sign_undo_f32_d512".into(), fwht_src);
1092
1093        // Fast Hadamard quantize (SIMD shuffle, zero barriers)
1094        let hq_fast_src: &'static str = include_str!("shaders/hadamard_quantize_kv_fast.metal");
1095        sources.insert("hadamard_quantize_kv_fast_d256".into(), hq_fast_src);
1096        sources.insert("hadamard_quantize_kv_fast_d512".into(), hq_fast_src);
1097        // ADR-028 iter-485 (Phase 7d / H4): fused K+V single-position 4-bit encoder.
1098        sources.insert("hadamard_quantize_kv_fast_dual_d256".into(), hq_fast_src);
1099        sources.insert("hadamard_quantize_kv_fast_dual_d512".into(), hq_fast_src);
1100        // Track B (iter-21): higher-bit (5/6-bit) quantize kernels (byte-packed)
1101        sources.insert("hadamard_quantize_kv_hb_d256".into(), hq_fast_src);
1102        sources.insert("hadamard_quantize_kv_hb_d512".into(), hq_fast_src);
1103        // ADR-028 iter-148: fused K+V single-position HB encoder
1104        sources.insert("hadamard_quantize_kv_hb_dual_d256".into(), hq_fast_src);
1105        sources.insert("hadamard_quantize_kv_hb_dual_d512".into(), hq_fast_src);
1106        // ADR-028 Phase 10e.5 (iter-351): no-FWHT V quantize for hybrid path.
1107        // Same byte-packed Lloyd-Max codebook output, but skips the Hadamard
1108        // rotation so dequant in SDPA recovers raw V (no FWHT-undo needed).
1109        sources.insert("kv_quantize_v_no_fwht_d256".into(), hq_fast_src);
1110        sources.insert("kv_quantize_v_no_fwht_d512".into(), hq_fast_src);
1111        // ADR-028 Phase 10c.5 (iter-354): fused F16-K-copy + V-no-FWHT-encode.
1112        // Saves 30 KV-write dispatches/decode-token at gemma4 30L by combining
1113        // the per-layer K-cast and V-encode into a single dispatch (Z-dim).
1114        sources.insert("kv_copy_kf16_quantize_v_no_fwht_d256".into(), hq_fast_src);
1115        sources.insert("kv_copy_kf16_quantize_v_no_fwht_d512".into(), hq_fast_src);
1116
1117        // iter-20 Leg F: TQ KV dequantize kernel (nibbles+norms → F32)
1118        let tq_dq_src: &'static str = include_str!("shaders/tq_dequantize_kv.metal");
1119        sources.insert("tq_dequantize_kv".into(), tq_dq_src);
1120        // Track B (iter-21): higher-bit dequantize kernel (byte-packed indices)
1121        sources.insert("tq_dequantize_hb_kv".into(), tq_dq_src);
1122        // ADR-027 Phase B iter-30 (hf2q sub-sub-iter 23c-β.1): sequence-batch
1123        // dequant variant. Same MSL source; new kernel entry point
1124        // `tq_dequantize_hb_kv_seq` reads positions [start_pos..start_pos+n_tokens)
1125        // in one dispatch (one threadgroup per (kv_head, position)). Unblocks
1126        // hf2q's TQ-aware prefill SDPA path (current per-position kernel
1127        // requires cur_len separate dispatches).
1128        sources.insert("tq_dequantize_hb_kv_seq".into(), tq_dq_src);
1129
1130        // iter-24: native higher-bit (5/6/8-bit) TQ SDPA kernel (byte-packed K/V)
1131        let tq_hb_src: &'static str = include_str!("shaders/flash_attn_vec_tq_hb.metal");
1132        sources.insert("flash_attn_vec_tq_hb_dk256".into(), tq_hb_src);
1133        sources.insert("flash_attn_vec_tq_hb_dk512".into(), tq_hb_src);
1134
1135        // ADR-028 §iter-485 (Phase 7d H3): fused TQ-HB reduce + FWHT-sign-undo.
1136        // Combines flash_attn_vec_reduce + fwht_sign_undo_f32 into a single
1137        // dispatch, saving 1 dispatch + 1 forced barrier per layer per decode
1138        // token. Gated by env flag `HF2Q_TQ_HB_OUT_FUSED=1` in forward_mlx.rs.
1139        let reduce_undo_src: &'static str = include_str!("shaders/flash_attn_vec_reduce_tq_hb_undo.metal");
1140        sources.insert("flash_attn_vec_reduce_tq_hb_undo_dk256".into(), reduce_undo_src);
1141        sources.insert("flash_attn_vec_reduce_tq_hb_undo_dk512".into(), reduce_undo_src);
1142
1143        // ADR-028 Phase 10d (iter-349): hybrid F16-K + TQ-HB-V SDPA kernel.
1144        // Same V-side codebook as flash_attn_vec_tq_hb (5/6/8-bit Lloyd-Max);
1145        // K-side reads F16 dense — peer-equivalent layout, no codebook lookup.
1146        let hybrid_src: &'static str = include_str!("shaders/flash_attn_vec_hybrid.metal");
1147        sources.insert("flash_attn_vec_hybrid_dk256".into(), hybrid_src);
1148        sources.insert("flash_attn_vec_hybrid_dk512".into(), hybrid_src);
1149        // ADR-040 M4 — batched multi-seq decode flash (same source file).
1150        sources.insert("flash_attn_vec_hybrid_batched_dk256".into(), hybrid_src);
1151        sources.insert("flash_attn_vec_hybrid_batched_dk512".into(), hybrid_src);
1152
1153        // ADR-029: verbatim llama.cpp peer port.
1154        // F16-K + F16-V, DK=DV=256, NWG=1, NSG=1, NE=1. No function constants — baked.
1155        let peer_port_src: &'static str = include_str!("shaders/flash_attn_vec_peer_port_f16.metal");
1156        sources.insert("flash_attn_vec_peer_port_f16_dk256_dv256".into(), peer_port_src);
1157
1158        // ADR-029 iter-134: peer reduce kernel (verbatim port of ggml-metal.metal 7235-7275).
1159        // Pairs with the NWG=32 vec kernel to match peer's actual runtime dispatch.
1160        let peer_port_reduce_src: &'static str =
1161            include_str!("shaders/flash_attn_vec_peer_port_f16_reduce.metal");
1162        sources.insert(
1163            "flash_attn_vec_peer_port_f16_reduce_dv256_nwg32".into(),
1164            peer_port_reduce_src,
1165        );
1166
1167        // ADR-029 iter-135: NWG=32 variant of the verbatim peer port. Same body as
1168        // flash_attn_vec_peer_port_f16.metal with NWG=1→32. Pairs with iter-134 reduce kernel.
1169        let peer_port_nwg32_src: &'static str =
1170            include_str!("shaders/flash_attn_vec_peer_port_f16_nwg32.metal");
1171        sources.insert(
1172            "flash_attn_vec_peer_port_f16_nwg32_dk256_dv256".into(),
1173            peer_port_nwg32_src,
1174        );
1175
1176        // GPU sampling kernels — eliminate logits readback (Phase 6)
1177        let argmax_src: &'static str = include_str!("shaders/argmax.metal");
1178        sources.insert("argmax_f32".into(), argmax_src);
1179        let softmax_sample_src: &'static str =
1180            include_str!("shaders/softmax_sample.metal");
1181        sources.insert("softmax_sample_f32".into(), softmax_sample_src);
1182        // Top-K kernel for Q8 rerank: avoids full-logits readback.
1183        let top_k_src: &'static str = include_str!("shaders/top_k.metal");
1184        sources.insert("top_k_f32".into(), top_k_src);
1185
1186        // MoE GPU routing + weighted reduce (ADR-013 P13.3 perf).
1187        // Replaces CPU softmax+topk round-trip and CPU weighted accumulate.
1188        let moe_stk_src: &'static str =
1189            include_str!("shaders/moe_softmax_topk.metal");
1190        sources.insert("moe_softmax_topk_f32".into(), moe_stk_src);
1191        let moe_wr_src: &'static str =
1192            include_str!("shaders/moe_weighted_reduce.metal");
1193        sources.insert("moe_weighted_reduce_f32".into(), moe_wr_src);
1194        let sdpa_decode_src: &'static str =
1195            include_str!("shaders/sdpa_decode.metal");
1196        sources.insert("sdpa_decode".into(), sdpa_decode_src);
1197
1198        Self {
1199            cache: HashMap::new(),
1200            sources,
1201            precompiled_lib: None,
1202            precompiled_load_attempted: false,
1203        }
1204    }
1205
1206    /// Try to obtain the precompiled `default.metallib` Library, loading it
1207    /// lazily on first call.  Returns `None` when:
1208    /// - `MLX_PRECOMPILED_METALLIB` is unset (default)
1209    /// - The embedded blob is empty (build.rs skipped metallib build)
1210    /// - `device.new_library_with_data` failed previously
1211    /// - The previous load attempt already failed (no retry)
1212    fn try_precompiled_lib(
1213        &mut self,
1214        device: &metal::DeviceRef,
1215    ) -> Option<&metal::LibraryRef> {
1216        if !precompiled_enabled() {
1217            return None;
1218        }
1219        if !self.precompiled_load_attempted {
1220            self.precompiled_load_attempted = true;
1221            if EMBEDDED_METALLIB.is_empty() {
1222                return None;
1223            }
1224            // Apple's `newLibraryWithData:` expects a dispatch_data_t.
1225            // metal-rs wraps this via `new_library_with_data` which takes
1226            // a `&[u8]`.
1227            match device.new_library_with_data(EMBEDDED_METALLIB) {
1228                Ok(lib) => self.precompiled_lib = Some(lib),
1229                Err(_) => self.precompiled_lib = None,
1230            }
1231        }
1232        self.precompiled_lib.as_deref()
1233    }
1234
1235    /// Register a shader source at runtime (useful for testing and dynamic
1236    /// kernel generation).
1237    pub fn register_source(&mut self, name: impl Into<String>, source: &'static str) {
1238        let name = name.into();
1239        // Invalidate any cached pipeline for this name since the source changed.
1240        self.cache.remove(&name);
1241        self.sources.insert(name, source);
1242    }
1243
1244    /// ADR-033 §Pi Task #20 iter 11 (2026-05-23) — eagerly compile a list
1245    /// of kernel pipelines to move first-call JIT/PSO-creation cost out of
1246    /// the prefill hot path and into the model-load window.
1247    ///
1248    /// The profiler showed that on Qwen3.6 35B-A3B MoE prefill at seq=553,
1249    /// the FIRST FA layer + FIRST FFN layer take ~40ms each (vs ~14µs
1250    /// warm) — that's 80ms of the 221ms prefill, dominated by Metal
1251    /// pipeline state creation. Pre-creating these pipelines at load time
1252    /// (when 3.3s is already being spent on model parse + upload) is a
1253    /// strict perf win for measured prefill throughput.
1254    ///
1255    /// Best-effort: silently skips kernels that aren't registered (e.g.,
1256    /// list contains a kernel name for an arch this build doesn't use).
1257    /// Logs at debug level on failure to keep load-path quiet.
1258    ///
1259    /// Returns the count of pipelines successfully prewarmed.
1260    pub fn prewarm_pipelines(
1261        &mut self,
1262        device: &metal::DeviceRef,
1263        names: &[&str],
1264    ) -> usize {
1265        let mut warmed = 0_usize;
1266        for name in names {
1267            // Skip if already cached.
1268            if self.cache.contains_key(*name) {
1269                warmed += 1;
1270                continue;
1271            }
1272            // Skip if no source registered for this name.
1273            if !self.sources.contains_key(*name) {
1274                continue;
1275            }
1276            // Best-effort: ignore errors so one broken kernel doesn't
1277            // poison the whole prewarm pass.
1278            if self.get_pipeline(name, device).is_ok() {
1279                warmed += 1;
1280            }
1281        }
1282        warmed
1283    }
1284
1285    /// ADR-033 §Pi Task #20 iter 12 (2026-05-23) — prewarm pipelines that
1286    /// require `[[function_constant]]` specialization. Each entry is
1287    /// `(name, &[(constant_index, bool_value)])`. Mirrors
1288    /// `prewarm_pipelines` but routes through
1289    /// `get_pipeline_with_bool_constants` so kernels declaring
1290    /// `function_constant` decls without defaults can be safely
1291    /// prewarmed.
1292    ///
1293    /// Use case: hot-path kernels like `flash_attn_prefill_bf16_d256`
1294    /// (uses bool constants 200/201/300/301/303 for align/mask/causal/blk
1295    /// flags) cannot be safely prewarmed without specialization — Metal
1296    /// `validateWithDevice:` asserts and aborts the process. Provide
1297    /// the constants production uses and prewarming becomes safe.
1298    ///
1299    /// Returns count warmed.
1300    pub fn prewarm_pipelines_with_bool_constants(
1301        &mut self,
1302        device: &metal::DeviceRef,
1303        entries: &[(&str, &[(usize, bool)])],
1304    ) -> usize {
1305        let mut warmed = 0_usize;
1306        for (name, bool_constants) in entries {
1307            if !self.sources.contains_key(*name) {
1308                continue;
1309            }
1310            if self
1311                .get_pipeline_with_bool_constants(name, device, bool_constants)
1312                .is_ok()
1313            {
1314                warmed += 1;
1315            }
1316        }
1317        warmed
1318    }
1319
1320    /// ADR-033 §Pi Task #20 iter 11 (2026-05-23) — prewarm every registered
1321    /// kernel source. Useful when the exact set of needed kernels is hard
1322    /// to enumerate (e.g., serving paths that span multiple arches).
1323    /// Total cost is bounded by the number of registered kernels times
1324    /// the per-pipeline PSO creation cost (~5-15ms typical on M-series).
1325    ///
1326    /// Returns (warmed, skipped) counts.
1327    pub fn prewarm_all(&mut self, device: &metal::DeviceRef) -> (usize, usize) {
1328        let names: Vec<String> = self.sources.keys().cloned().collect();
1329        let mut warmed = 0_usize;
1330        let mut skipped = 0_usize;
1331        for name in &names {
1332            if self.cache.contains_key(name) {
1333                warmed += 1;
1334                continue;
1335            }
1336            if self.get_pipeline(name, device).is_ok() {
1337                warmed += 1;
1338            } else {
1339                skipped += 1;
1340            }
1341        }
1342        (warmed, skipped)
1343    }
1344
1345    /// Get a compiled compute pipeline for the named kernel function.
1346    ///
1347    /// On first call for a given name, this compiles the MSL source into a
1348    /// Metal library, extracts the named function, and creates a
1349    /// `ComputePipelineState`.  Subsequent calls return the cached pipeline.
1350    ///
1351    /// # Errors
1352    ///
1353    /// * `MlxError::KernelNotFound` — no source registered for this name.
1354    /// * `MlxError::ShaderCompilationError` — MSL compilation or pipeline
1355    ///   creation failed.
1356    pub fn get_pipeline(
1357        &mut self,
1358        name: &str,
1359        device: &metal::DeviceRef,
1360    ) -> Result<&ComputePipelineState> {
1361        if !self.cache.contains_key(name) {
1362            // ADR-029 iter-175 Step 1l: precompiled .metallib fast path.
1363            // When MLX_PRECOMPILED_METALLIB=1 AND the kernel exists in the
1364            // embedded library, use it.  Otherwise fall through to runtime
1365            // source compile.  Empirically ~+5.89% faster on q6_K matvec
1366            // (iter 1k bench).
1367            let precompiled_function = self
1368                .try_precompiled_lib(device)
1369                .and_then(|lib| lib.get_function(name, None).ok());
1370
1371            let function = match precompiled_function {
1372                Some(f) => f,
1373                None => {
1374                    // Slow path: compile the shader.
1375                    let source = self.sources.get(name).ok_or_else(|| {
1376                        MlxError::KernelNotFound(name.to_string())
1377                    })?;
1378
1379                    let compile_opts = metal::CompileOptions::new();
1380                    let library = device
1381                        .new_library_with_source(source, &compile_opts)
1382                        .map_err(|msg| MlxError::ShaderCompilationError {
1383                            name: name.to_string(),
1384                            message: msg,
1385                        })?;
1386
1387                    library
1388                        .get_function(name, None)
1389                        .map_err(|msg| MlxError::ShaderCompilationError {
1390                            name: name.to_string(),
1391                            message: msg,
1392                        })?
1393                }
1394            };
1395
1396            // Build the pipeline through a descriptor so we can attach a
1397            // human-readable label.  The label propagates into Instruments /
1398            // xctrace Metal System Trace as the per-pipeline identifier
1399            // (`metal-object-label` schema), giving us per-kernel attribution
1400            // instead of the generic "Compute Command 0" placeholder.
1401            //
1402            // `MTLComputePipelineState.label` is read-only after creation per
1403            // the Apple Metal spec; the only supported way to set it is via
1404            // the descriptor before pipeline creation.  ADR-015 iter9b.
1405            let descriptor = ComputePipelineDescriptor::new();
1406            descriptor.set_compute_function(Some(&function));
1407            descriptor.set_label(name);
1408            // ADR-028 iter-376: threadGroupSizeIsMultipleOfThreadExecutionWidth
1409            // hint allows the Metal compiler to skip bounds checks and use more
1410            // aggressive codegen.  Opt-in via HF2Q_PIPELINE_TG_MULT_HINT=1.
1411            // SAFETY: every dispatched threadgroup MUST be a multiple of 32 at
1412            // runtime — Apple specifies undefined behavior otherwise.  Our hot
1413            // kernels use tg_size ∈ {32, 64, 256, 1024} (all multiples of 32).
1414            if std::env::var("HF2Q_PIPELINE_TG_MULT_HINT").ok().as_deref() == Some("1") {
1415                descriptor.set_thread_group_size_is_multiple_of_thread_execution_width(true);
1416            }
1417
1418            let pipeline = device
1419                .new_compute_pipeline_state(&descriptor)
1420                .map_err(|msg| MlxError::ShaderCompilationError {
1421                    name: name.to_string(),
1422                    message: msg,
1423                })?;
1424
1425            self.cache.insert(name.to_string(), pipeline);
1426        }
1427
1428        // At this point the pipeline is guaranteed to be in the cache.
1429        // We use `ok_or_else` instead of `expect` to satisfy the no-panic policy.
1430        self.cache.get(name).ok_or_else(|| {
1431            MlxError::KernelNotFound(name.to_string())
1432        })
1433    }
1434
1435    /// Get a compiled compute pipeline for the named kernel, specialized with
1436    /// Metal function constants (both bool and i32 in one call).
1437    ///
1438    /// `bool_constants` contains `(index, value)` pairs mapping to
1439    /// `[[function_constant(index)]]` bool declarations in the MSL shader.
1440    /// `int_constants` contains `(index, value)` pairs mapping to
1441    /// `[[function_constant(index)]]` int (int32_t) declarations in the MSL
1442    /// shader.
1443    ///
1444    /// Pipelines are cached by a composite key:
1445    /// `"<name>|<index>:b<0|1>|...|<index>:i<value>|..."`.  The 'b' prefix
1446    /// marks bool entries and the 'i' prefix marks i32 entries, making the
1447    /// format unambiguous regardless of constant ordering.  Distinct
1448    /// `(name, constants)` combinations each compile to a separate pipeline;
1449    /// the slow compilation path runs at most once per unique combination.
1450    ///
1451    /// # Errors
1452    ///
1453    /// * `MlxError::KernelNotFound` — no source registered for this name.
1454    /// * `MlxError::ShaderCompilationError` — MSL compilation, function
1455    ///   specialisation, or pipeline creation failed.
1456    pub fn get_pipeline_with_constants(
1457        &mut self,
1458        name: &str,
1459        device: &metal::DeviceRef,
1460        bool_constants: &[(usize, bool)],
1461        int_constants: &[(usize, i32)],
1462    ) -> Result<&ComputePipelineState> {
1463        // Build a composite cache key so distinct constant combinations each
1464        // compile to their own pipeline.  Bool entries use the 'b' type marker
1465        // and i32 entries use 'i'; this prevents a collision between, e.g.,
1466        // bool index 5 value 1 and int index 5 value 1.
1467        let mut cache_key = name.to_string();
1468        for &(index, value) in bool_constants {
1469            cache_key.push('|');
1470            cache_key.push_str(&index.to_string());
1471            cache_key.push_str(if value { ":b1" } else { ":b0" });
1472        }
1473        for &(index, value) in int_constants {
1474            cache_key.push('|');
1475            cache_key.push_str(&index.to_string());
1476            cache_key.push(':');
1477            cache_key.push('i');
1478            cache_key.push_str(&value.to_string());
1479        }
1480
1481        if !self.cache.contains_key(&cache_key) {
1482            // Build the FunctionConstantValues object with all bool and i32
1483            // constants.  Metal's set_constant_value_at_index reads the value
1484            // through a raw pointer; the pointed-to bytes must match the size
1485            // declared in the MSL shader (1 byte for bool, 4 bytes for int).
1486            let fcv = FunctionConstantValues::new();
1487
1488            for &(index, value) in bool_constants {
1489                // MTLDataType::Bool = 53 (metal-rs argument.rs).
1490                // The Metal runtime reads it as an Objective-C BOOL (uint8_t).
1491                let v: u8 = if value { 1 } else { 0 };
1492                fcv.set_constant_value_at_index(
1493                    (&v as *const u8).cast::<std::ffi::c_void>(),
1494                    MTLDataType::Bool,
1495                    index as u64,
1496                );
1497            }
1498
1499            for &(index, value) in int_constants {
1500                // MTLDataType::Int = 29 (metal-rs argument.rs).
1501                // The Metal runtime reads 4 bytes as a signed 32-bit integer,
1502                // matching the Metal shader type `constant int`.
1503                fcv.set_constant_value_at_index(
1504                    (&value as *const i32).cast::<std::ffi::c_void>(),
1505                    MTLDataType::Int,
1506                    index as u64,
1507                );
1508            }
1509
1510            // ADR-029 iter-175 Step 1l: try precompiled .metallib first.
1511            // Step 1m: gated separately on MLX_PRECOMPILED_METALLIB_FCV=1
1512            // so we can isolate whether the integration regression at
1513            // Step 1l (tg50 95.4 → 62.1) lives in this FCV path vs the
1514            // no-FCV path in `get_pipeline`.
1515            //
1516            // get_function with FCV takes ownership of the FCV, so we
1517            // build a separate one for the precompiled probe.
1518            let precompiled_function = if precompiled_fcv_enabled() {
1519                let probe_fcv = FunctionConstantValues::new();
1520                for &(index, value) in bool_constants {
1521                    let v: u8 = if value { 1 } else { 0 };
1522                    probe_fcv.set_constant_value_at_index(
1523                        (&v as *const u8).cast::<std::ffi::c_void>(),
1524                        MTLDataType::Bool,
1525                        index as u64,
1526                    );
1527                }
1528                for &(index, value) in int_constants {
1529                    probe_fcv.set_constant_value_at_index(
1530                        (&value as *const i32).cast::<std::ffi::c_void>(),
1531                        MTLDataType::Int,
1532                        index as u64,
1533                    );
1534                }
1535                self.try_precompiled_lib(device)
1536                    .and_then(|lib| lib.get_function(name, Some(probe_fcv)).ok())
1537            } else {
1538                None
1539            };
1540
1541            let function = match precompiled_function {
1542                Some(f) => f,
1543                None => {
1544                    // Slow path: compile the shader with function constant specialisation.
1545                    let source = self.sources.get(name).ok_or_else(|| {
1546                        MlxError::KernelNotFound(name.to_string())
1547                    })?;
1548
1549                    let compile_opts = metal::CompileOptions::new();
1550                    let library = device
1551                        .new_library_with_source(source, &compile_opts)
1552                        .map_err(|msg| MlxError::ShaderCompilationError {
1553                            name: name.to_string(),
1554                            message: msg,
1555                        })?;
1556
1557                    library
1558                        .get_function(name, Some(fcv))
1559                        .map_err(|msg| MlxError::ShaderCompilationError {
1560                            name: name.to_string(),
1561                            message: msg,
1562                        })?
1563                }
1564            };
1565
1566            // Label this specialisation with the full composite cache key
1567            // (e.g. `kernel_mul_mv_q4_0_f32|0:b1|3:i32`) so xctrace Metal
1568            // System Trace shows each function-constant variant as a distinct
1569            // pipeline.  Without this, all specialisations share a generic
1570            // "Compute Command 0" identifier and we cannot attribute µs/token
1571            // to a specific (kernel, constants) combination.  ADR-015 iter9b.
1572            let descriptor = ComputePipelineDescriptor::new();
1573            descriptor.set_compute_function(Some(&function));
1574            descriptor.set_label(&cache_key);
1575            // ADR-028 iter-376: same hint as primary pipeline path.
1576            if std::env::var("HF2Q_PIPELINE_TG_MULT_HINT").ok().as_deref() == Some("1") {
1577                descriptor.set_thread_group_size_is_multiple_of_thread_execution_width(true);
1578            }
1579
1580            let pipeline = device
1581                .new_compute_pipeline_state(&descriptor)
1582                .map_err(|msg| MlxError::ShaderCompilationError {
1583                    name: name.to_string(),
1584                    message: msg,
1585                })?;
1586
1587            self.cache.insert(cache_key.clone(), pipeline);
1588        }
1589
1590        self.cache.get(&cache_key).ok_or_else(|| {
1591            MlxError::KernelNotFound(name.to_string())
1592        })
1593    }
1594
1595    /// Get a compiled compute pipeline for the named kernel, specialized with
1596    /// Metal bool function constants.
1597    ///
1598    /// The `bool_constants` slice contains `(index, value)` pairs.  Each pair
1599    /// maps to a `[[function_constant(index)]]` declaration in the MSL shader.
1600    ///
1601    /// This is a thin wrapper around [`get_pipeline_with_constants`] that
1602    /// passes an empty `int_constants` slice.  Existing callers continue to
1603    /// work without modification; the cache-key format for pure-bool pipelines
1604    /// is compatible (bool entries carry the 'b' type marker, which is the
1605    /// only format ever written by this wrapper).
1606    ///
1607    /// # Errors
1608    ///
1609    /// * `MlxError::KernelNotFound` — no source registered for this name.
1610    /// * `MlxError::ShaderCompilationError` — MSL compilation, function
1611    ///   specialisation, or pipeline creation failed.
1612    pub fn get_pipeline_with_bool_constants(
1613        &mut self,
1614        name: &str,
1615        device: &metal::DeviceRef,
1616        bool_constants: &[(usize, bool)],
1617    ) -> Result<&ComputePipelineState> {
1618        self.get_pipeline_with_constants(name, device, bool_constants, &[])
1619    }
1620
1621    /// Check if a pipeline for the given name is already compiled and cached.
1622    pub fn is_cached(&self, name: &str) -> bool {
1623        self.cache.contains_key(name)
1624    }
1625
1626    /// Number of compiled pipelines currently in the cache.
1627    pub fn cached_count(&self) -> usize {
1628        self.cache.len()
1629    }
1630
1631    /// Number of registered shader sources.
1632    pub fn source_count(&self) -> usize {
1633        self.sources.len()
1634    }
1635}
1636
1637impl Default for KernelRegistry {
1638    fn default() -> Self {
1639        Self::new()
1640    }
1641}
1642
1643#[cfg(test)]
1644mod tests {
1645    use super::*;
1646
1647    /// Minimal Metal shader that uses a single int function constant.
1648    ///
1649    /// The kernel writes the constant value N into the first element of the
1650    /// output buffer, allowing the test to verify that the Metal compiler
1651    /// actually sees distinct specialisations for N=4 and N=8.
1652    ///
1653    /// The shader is intentionally trivial — we only need it to *compile* with
1654    /// an int function constant; correctness of the kernel logic is not under
1655    /// test here.
1656    const INT_FC_TEST_SHADER: &str = r#"
1657#include <metal_stdlib>
1658using namespace metal;
1659
1660constant int test_N [[function_constant(100)]];
1661
1662kernel void int_fc_test_kernel(
1663    device int* out [[buffer(0)]],
1664    uint tid [[thread_position_in_grid]])
1665{
1666    if (tid == 0) {
1667        out[0] = test_N;
1668    }
1669}
1670"#;
1671
1672    /// Verify that `get_pipeline_with_constants` produces distinct cached
1673    /// pipelines for different i32 function-constant values, and that
1674    /// `get_pipeline_with_bool_constants` (the backward-compat wrapper) still
1675    /// works correctly with the new 'b'-prefixed cache-key format.
1676    ///
1677    /// This test requires a real Metal device and is therefore marked
1678    /// `#[ignore]` on non-Apple platforms, but runs unconditionally on macOS.
1679    #[test]
1680    fn test_int_fc_distinct_pipelines_and_bool_compat() {
1681        let device = metal::Device::system_default()
1682            .expect("no Metal device — run on Apple Silicon or x86 Mac with Metal support");
1683
1684        let mut registry = KernelRegistry::new();
1685
1686        // Register the inline test shader under a name that cannot collide with
1687        // any production kernel.
1688        registry.register_source("int_fc_test_kernel", INT_FC_TEST_SHADER);
1689
1690        // Compile with N=4.
1691        let p4_ptr = registry
1692            .get_pipeline_with_constants(
1693                "int_fc_test_kernel",
1694                &device,
1695                &[],                  // no bool constants
1696                &[(100, 4_i32)],      // int constant index 100 = 4
1697            )
1698            .expect("pipeline N=4 should compile") as *const _;
1699
1700        // Cache must now have exactly 1 entry for this kernel.
1701        // (Other production kernels may already be in cache from new(); here
1702        // we check that the N=4 key was inserted.)
1703        let count_after_n4 = registry.cached_count();
1704
1705        // Compile with N=8 — must produce a SEPARATE pipeline.
1706        let p8_ptr = registry
1707            .get_pipeline_with_constants(
1708                "int_fc_test_kernel",
1709                &device,
1710                &[],
1711                &[(100, 8_i32)],
1712            )
1713            .expect("pipeline N=8 should compile") as *const _;
1714
1715        // Cache must have grown by exactly 1.
1716        assert_eq!(
1717            registry.cached_count(),
1718            count_after_n4 + 1,
1719            "N=8 must produce a new cache entry"
1720        );
1721
1722        // The two pipelines must be distinct objects in the cache.
1723        assert_ne!(
1724            p4_ptr, p8_ptr,
1725            "N=4 and N=8 specialisations must be separate ComputePipelineState objects"
1726        );
1727
1728        // A second call with N=4 must return the SAME pipeline (cache hit, no
1729        // new compilation).
1730        let p4_again_ptr = registry
1731            .get_pipeline_with_constants(
1732                "int_fc_test_kernel",
1733                &device,
1734                &[],
1735                &[(100, 4_i32)],
1736            )
1737            .expect("pipeline N=4 cache hit should succeed") as *const _;
1738
1739        assert_eq!(
1740            registry.cached_count(),
1741            count_after_n4 + 1,
1742            "repeated N=4 call must be a cache hit, not a new entry"
1743        );
1744        assert_eq!(
1745            p4_ptr, p4_again_ptr,
1746            "repeated N=4 call must return the same pipeline pointer"
1747        );
1748
1749        // Verify backward compatibility: get_pipeline_with_bool_constants must
1750        // still route through get_pipeline_with_constants and produce a cached
1751        // pipeline without panicking.
1752        //
1753        // We register a separate bool-constant shader that does NOT use a bool
1754        // function constant (so the Metal compiler ignores missing FCs for
1755        // this trivial case) — but the call path and cache-key format are what
1756        // matter here.  We reuse the int_fc_test_kernel source; the bool FC is
1757        // simply unused by the shader (Metal allows unused FCs when the shader
1758        // declares them with `function_constant` but the value is never read).
1759        //
1760        // To avoid a Metal compiler error for an undeclared function constant,
1761        // we register a separate bare-kernel shader for the bool wrapper test.
1762        const BARE_SHADER: &str = r#"
1763#include <metal_stdlib>
1764using namespace metal;
1765kernel void bare_kernel(device int* out [[buffer(0)]], uint tid [[thread_position_in_grid]]) {
1766    if (tid == 0) { out[0] = 42; }
1767}
1768"#;
1769        registry.register_source("bare_kernel", BARE_SHADER);
1770
1771        let count_before_bool = registry.cached_count();
1772        let _bool_pipeline = registry
1773            .get_pipeline_with_bool_constants("bare_kernel", &device, &[])
1774            .expect("bool-constants wrapper with empty slice must succeed");
1775
1776        assert_eq!(
1777            registry.cached_count(),
1778            count_before_bool + 1,
1779            "bool-constants wrapper must insert one new cache entry"
1780        );
1781    }
1782
1783    /// Verify that the `MTLComputePipelineState.label` produced by
1784    /// `get_pipeline` and `get_pipeline_with_constants` actually propagates
1785    /// from the descriptor to the resulting pipeline state.
1786    ///
1787    /// This is the in-process smoke check for ADR-015 iter9b: we cannot
1788    /// reach into xctrace from Rust, but we can read back the same `label`
1789    /// property xctrace consumes via `ComputePipelineStateRef::label()`.
1790    /// If labels are missing or wrong here, the MST trace will also show
1791    /// generic identifiers — so this test gates the iter9 retry's
1792    /// per-Q4_0-kernel attribution.
1793    #[test]
1794    fn test_pipeline_labels_propagate_for_mst() {
1795        let device = metal::Device::system_default()
1796            .expect("no Metal device — run on Apple Silicon or x86 Mac with Metal support");
1797
1798        let mut registry = KernelRegistry::new();
1799
1800        // Reuse the same trivial shaders as the int-FC test.
1801        registry.register_source("int_fc_test_kernel", INT_FC_TEST_SHADER);
1802
1803        const BARE_SHADER_LABEL_TEST: &str = r#"
1804#include <metal_stdlib>
1805using namespace metal;
1806kernel void label_smoke_kernel(device int* out [[buffer(0)]], uint tid [[thread_position_in_grid]]) {
1807    if (tid == 0) { out[0] = 7; }
1808}
1809"#;
1810        registry.register_source("label_smoke_kernel", BARE_SHADER_LABEL_TEST);
1811
1812        // Plain get_pipeline path — label must equal the kernel name.
1813        // Capture as owned String so the cache borrow is released before
1814        // the next get_pipeline_with_constants call below.
1815        let plain_label = registry
1816            .get_pipeline("label_smoke_kernel", &device)
1817            .expect("plain pipeline must compile")
1818            .label()
1819            .to_string();
1820        assert_eq!(
1821            plain_label, "label_smoke_kernel",
1822            "get_pipeline must label the pipeline with the kernel name (xctrace MST attribution)"
1823        );
1824
1825        // Constants path — label must equal the composite cache key so each
1826        // function-constant variant is individually attributable in MST.
1827        // We capture the label as an owned String to release the borrow on
1828        // the cache before fetching the next specialisation.
1829        let label_v7 = registry
1830            .get_pipeline_with_constants(
1831                "int_fc_test_kernel",
1832                &device,
1833                &[],
1834                &[(100, 7_i32)],
1835            )
1836            .expect("specialised pipeline must compile")
1837            .label()
1838            .to_string();
1839        assert_eq!(
1840            label_v7, "int_fc_test_kernel|100:i7",
1841            "get_pipeline_with_constants must label with the cache_key so each \
1842             specialisation is distinct in xctrace MST"
1843        );
1844
1845        // A second specialisation must produce a different label.
1846        let label_v13 = registry
1847            .get_pipeline_with_constants(
1848                "int_fc_test_kernel",
1849                &device,
1850                &[],
1851                &[(100, 13_i32)],
1852            )
1853            .expect("second specialised pipeline must compile")
1854            .label()
1855            .to_string();
1856        assert_eq!(label_v13, "int_fc_test_kernel|100:i13");
1857        assert_ne!(
1858            label_v7, label_v13,
1859            "distinct constant values must yield distinct pipeline labels"
1860        );
1861    }
1862}