xref: /linux/drivers/ras/amd/atl/dehash.c (revision a1ff5a7d78a036d6c2178ee5acd6ba4946243800)
1 // SPDX-License-Identifier: GPL-2.0-or-later
2 /*
3  * AMD Address Translation Library
4  *
5  * dehash.c : Functions to account for hashing bits
6  *
7  * Copyright (c) 2023, Advanced Micro Devices, Inc.
8  * All Rights Reserved.
9  *
10  * Author: Yazen Ghannam <Yazen.Ghannam@amd.com>
11  */
12 
13 #include "internal.h"
14 
df2_dehash_addr(struct addr_ctx * ctx)15 static int df2_dehash_addr(struct addr_ctx *ctx)
16 {
17 	u8 hashed_bit, intlv_bit, intlv_bit_pos;
18 
19 	intlv_bit_pos = ctx->map.intlv_bit_pos;
20 	intlv_bit = !!(BIT_ULL(intlv_bit_pos) & ctx->ret_addr);
21 
22 	hashed_bit = intlv_bit;
23 	hashed_bit ^= FIELD_GET(BIT_ULL(12), ctx->ret_addr);
24 	hashed_bit ^= FIELD_GET(BIT_ULL(18), ctx->ret_addr);
25 	hashed_bit ^= FIELD_GET(BIT_ULL(21), ctx->ret_addr);
26 	hashed_bit ^= FIELD_GET(BIT_ULL(30), ctx->ret_addr);
27 
28 	if (hashed_bit != intlv_bit)
29 		ctx->ret_addr ^= BIT_ULL(intlv_bit_pos);
30 
31 	return 0;
32 }
33 
df3_dehash_addr(struct addr_ctx * ctx)34 static int df3_dehash_addr(struct addr_ctx *ctx)
35 {
36 	bool hash_ctl_64k, hash_ctl_2M, hash_ctl_1G;
37 	u8 hashed_bit, intlv_bit, intlv_bit_pos;
38 
39 	hash_ctl_64k = FIELD_GET(DF3_HASH_CTL_64K, ctx->map.ctl);
40 	hash_ctl_2M  = FIELD_GET(DF3_HASH_CTL_2M, ctx->map.ctl);
41 	hash_ctl_1G  = FIELD_GET(DF3_HASH_CTL_1G, ctx->map.ctl);
42 
43 	intlv_bit_pos = ctx->map.intlv_bit_pos;
44 	intlv_bit = !!(BIT_ULL(intlv_bit_pos) & ctx->ret_addr);
45 
46 	hashed_bit = intlv_bit;
47 	hashed_bit ^= FIELD_GET(BIT_ULL(14), ctx->ret_addr);
48 	hashed_bit ^= FIELD_GET(BIT_ULL(18), ctx->ret_addr) & hash_ctl_64k;
49 	hashed_bit ^= FIELD_GET(BIT_ULL(23), ctx->ret_addr) & hash_ctl_2M;
50 	hashed_bit ^= FIELD_GET(BIT_ULL(32), ctx->ret_addr) & hash_ctl_1G;
51 
52 	if (hashed_bit != intlv_bit)
53 		ctx->ret_addr ^= BIT_ULL(intlv_bit_pos);
54 
55 	/* Calculation complete for 2 channels. Continue for 4 and 8 channels. */
56 	if (ctx->map.intlv_mode == DF3_COD4_2CHAN_HASH)
57 		return 0;
58 
59 	intlv_bit = FIELD_GET(BIT_ULL(12), ctx->ret_addr);
60 
61 	hashed_bit = intlv_bit;
62 	hashed_bit ^= FIELD_GET(BIT_ULL(16), ctx->ret_addr) & hash_ctl_64k;
63 	hashed_bit ^= FIELD_GET(BIT_ULL(21), ctx->ret_addr) & hash_ctl_2M;
64 	hashed_bit ^= FIELD_GET(BIT_ULL(30), ctx->ret_addr) & hash_ctl_1G;
65 
66 	if (hashed_bit != intlv_bit)
67 		ctx->ret_addr ^= BIT_ULL(12);
68 
69 	/* Calculation complete for 4 channels. Continue for 8 channels. */
70 	if (ctx->map.intlv_mode == DF3_COD2_4CHAN_HASH)
71 		return 0;
72 
73 	intlv_bit = FIELD_GET(BIT_ULL(13), ctx->ret_addr);
74 
75 	hashed_bit = intlv_bit;
76 	hashed_bit ^= FIELD_GET(BIT_ULL(17), ctx->ret_addr) & hash_ctl_64k;
77 	hashed_bit ^= FIELD_GET(BIT_ULL(22), ctx->ret_addr) & hash_ctl_2M;
78 	hashed_bit ^= FIELD_GET(BIT_ULL(31), ctx->ret_addr) & hash_ctl_1G;
79 
80 	if (hashed_bit != intlv_bit)
81 		ctx->ret_addr ^= BIT_ULL(13);
82 
83 	return 0;
84 }
85 
df3_6chan_dehash_addr(struct addr_ctx * ctx)86 static int df3_6chan_dehash_addr(struct addr_ctx *ctx)
87 {
88 	u8 intlv_bit_pos = ctx->map.intlv_bit_pos;
89 	u8 hashed_bit, intlv_bit, num_intlv_bits;
90 	bool hash_ctl_2M, hash_ctl_1G;
91 
92 	if (ctx->map.intlv_mode != DF3_6CHAN) {
93 		atl_debug_on_bad_intlv_mode(ctx);
94 		return -EINVAL;
95 	}
96 
97 	num_intlv_bits = ilog2(ctx->map.num_intlv_chan) + 1;
98 
99 	hash_ctl_2M = FIELD_GET(DF3_HASH_CTL_2M, ctx->map.ctl);
100 	hash_ctl_1G = FIELD_GET(DF3_HASH_CTL_1G, ctx->map.ctl);
101 
102 	intlv_bit = !!(BIT_ULL(intlv_bit_pos) & ctx->ret_addr);
103 
104 	hashed_bit = intlv_bit;
105 	hashed_bit ^= !!(BIT_ULL(intlv_bit_pos + num_intlv_bits) & ctx->ret_addr);
106 	hashed_bit ^= FIELD_GET(BIT_ULL(23), ctx->ret_addr) & hash_ctl_2M;
107 	hashed_bit ^= FIELD_GET(BIT_ULL(32), ctx->ret_addr) & hash_ctl_1G;
108 
109 	if (hashed_bit != intlv_bit)
110 		ctx->ret_addr ^= BIT_ULL(intlv_bit_pos);
111 
112 	intlv_bit_pos++;
113 	intlv_bit = !!(BIT_ULL(intlv_bit_pos) & ctx->ret_addr);
114 
115 	hashed_bit = intlv_bit;
116 	hashed_bit ^= FIELD_GET(BIT_ULL(21), ctx->ret_addr) & hash_ctl_2M;
117 	hashed_bit ^= FIELD_GET(BIT_ULL(30), ctx->ret_addr) & hash_ctl_1G;
118 
119 	if (hashed_bit != intlv_bit)
120 		ctx->ret_addr ^= BIT_ULL(intlv_bit_pos);
121 
122 	intlv_bit_pos++;
123 	intlv_bit = !!(BIT_ULL(intlv_bit_pos) & ctx->ret_addr);
124 
125 	hashed_bit = intlv_bit;
126 	hashed_bit ^= FIELD_GET(BIT_ULL(22), ctx->ret_addr) & hash_ctl_2M;
127 	hashed_bit ^= FIELD_GET(BIT_ULL(31), ctx->ret_addr) & hash_ctl_1G;
128 
129 	if (hashed_bit != intlv_bit)
130 		ctx->ret_addr ^= BIT_ULL(intlv_bit_pos);
131 
132 	return 0;
133 }
134 
df4_dehash_addr(struct addr_ctx * ctx)135 static int df4_dehash_addr(struct addr_ctx *ctx)
136 {
137 	bool hash_ctl_64k, hash_ctl_2M, hash_ctl_1G;
138 	u8 hashed_bit, intlv_bit;
139 
140 	hash_ctl_64k = FIELD_GET(DF4_HASH_CTL_64K, ctx->map.ctl);
141 	hash_ctl_2M  = FIELD_GET(DF4_HASH_CTL_2M, ctx->map.ctl);
142 	hash_ctl_1G  = FIELD_GET(DF4_HASH_CTL_1G, ctx->map.ctl);
143 
144 	intlv_bit = FIELD_GET(BIT_ULL(8), ctx->ret_addr);
145 
146 	hashed_bit = intlv_bit;
147 	hashed_bit ^= FIELD_GET(BIT_ULL(16), ctx->ret_addr) & hash_ctl_64k;
148 	hashed_bit ^= FIELD_GET(BIT_ULL(21), ctx->ret_addr) & hash_ctl_2M;
149 	hashed_bit ^= FIELD_GET(BIT_ULL(30), ctx->ret_addr) & hash_ctl_1G;
150 
151 	if (ctx->map.num_intlv_sockets == 1)
152 		hashed_bit ^= FIELD_GET(BIT_ULL(14), ctx->ret_addr);
153 
154 	if (hashed_bit != intlv_bit)
155 		ctx->ret_addr ^= BIT_ULL(8);
156 
157 	/*
158 	 * Hashing is possible with socket interleaving, so check the total number
159 	 * of channels in the system rather than DRAM map interleaving mode.
160 	 *
161 	 * Calculation complete for 2 channels. Continue for 4, 8, and 16 channels.
162 	 */
163 	if (ctx->map.total_intlv_chan <= 2)
164 		return 0;
165 
166 	intlv_bit = FIELD_GET(BIT_ULL(12), ctx->ret_addr);
167 
168 	hashed_bit = intlv_bit;
169 	hashed_bit ^= FIELD_GET(BIT_ULL(17), ctx->ret_addr) & hash_ctl_64k;
170 	hashed_bit ^= FIELD_GET(BIT_ULL(22), ctx->ret_addr) & hash_ctl_2M;
171 	hashed_bit ^= FIELD_GET(BIT_ULL(31), ctx->ret_addr) & hash_ctl_1G;
172 
173 	if (hashed_bit != intlv_bit)
174 		ctx->ret_addr ^= BIT_ULL(12);
175 
176 	/* Calculation complete for 4 channels. Continue for 8 and 16 channels. */
177 	if (ctx->map.total_intlv_chan <= 4)
178 		return 0;
179 
180 	intlv_bit = FIELD_GET(BIT_ULL(13), ctx->ret_addr);
181 
182 	hashed_bit = intlv_bit;
183 	hashed_bit ^= FIELD_GET(BIT_ULL(18), ctx->ret_addr) & hash_ctl_64k;
184 	hashed_bit ^= FIELD_GET(BIT_ULL(23), ctx->ret_addr) & hash_ctl_2M;
185 	hashed_bit ^= FIELD_GET(BIT_ULL(32), ctx->ret_addr) & hash_ctl_1G;
186 
187 	if (hashed_bit != intlv_bit)
188 		ctx->ret_addr ^= BIT_ULL(13);
189 
190 	/* Calculation complete for 8 channels. Continue for 16 channels. */
191 	if (ctx->map.total_intlv_chan <= 8)
192 		return 0;
193 
194 	intlv_bit = FIELD_GET(BIT_ULL(14), ctx->ret_addr);
195 
196 	hashed_bit = intlv_bit;
197 	hashed_bit ^= FIELD_GET(BIT_ULL(19), ctx->ret_addr) & hash_ctl_64k;
198 	hashed_bit ^= FIELD_GET(BIT_ULL(24), ctx->ret_addr) & hash_ctl_2M;
199 	hashed_bit ^= FIELD_GET(BIT_ULL(33), ctx->ret_addr) & hash_ctl_1G;
200 
201 	if (hashed_bit != intlv_bit)
202 		ctx->ret_addr ^= BIT_ULL(14);
203 
204 	return 0;
205 }
206 
df4p5_dehash_addr(struct addr_ctx * ctx)207 static int df4p5_dehash_addr(struct addr_ctx *ctx)
208 {
209 	bool hash_ctl_64k, hash_ctl_2M, hash_ctl_1G, hash_ctl_1T;
210 	u8 hashed_bit, intlv_bit;
211 	u64 rehash_vector;
212 
213 	hash_ctl_64k = FIELD_GET(DF4_HASH_CTL_64K, ctx->map.ctl);
214 	hash_ctl_2M  = FIELD_GET(DF4_HASH_CTL_2M, ctx->map.ctl);
215 	hash_ctl_1G  = FIELD_GET(DF4_HASH_CTL_1G, ctx->map.ctl);
216 	hash_ctl_1T  = FIELD_GET(DF4p5_HASH_CTL_1T, ctx->map.ctl);
217 
218 	/*
219 	 * Generate a unique address to determine which bits
220 	 * need to be dehashed.
221 	 *
222 	 * Start with a contiguous bitmask for the total
223 	 * number of channels starting at bit 8.
224 	 *
225 	 * Then make a gap in the proper place based on
226 	 * interleave mode.
227 	 */
228 	rehash_vector = ctx->map.total_intlv_chan - 1;
229 	rehash_vector <<= 8;
230 
231 	if (ctx->map.intlv_mode == DF4p5_NPS2_4CHAN_1K_HASH ||
232 	    ctx->map.intlv_mode == DF4p5_NPS1_8CHAN_1K_HASH ||
233 	    ctx->map.intlv_mode == DF4p5_NPS1_16CHAN_1K_HASH)
234 		rehash_vector = expand_bits(10, 2, rehash_vector);
235 	else
236 		rehash_vector = expand_bits(9, 3, rehash_vector);
237 
238 	if (rehash_vector & BIT_ULL(8)) {
239 		intlv_bit = FIELD_GET(BIT_ULL(8), ctx->ret_addr);
240 
241 		hashed_bit = intlv_bit;
242 		hashed_bit ^= FIELD_GET(BIT_ULL(16), ctx->ret_addr) & hash_ctl_64k;
243 		hashed_bit ^= FIELD_GET(BIT_ULL(21), ctx->ret_addr) & hash_ctl_2M;
244 		hashed_bit ^= FIELD_GET(BIT_ULL(30), ctx->ret_addr) & hash_ctl_1G;
245 		hashed_bit ^= FIELD_GET(BIT_ULL(40), ctx->ret_addr) & hash_ctl_1T;
246 
247 		if (hashed_bit != intlv_bit)
248 			ctx->ret_addr ^= BIT_ULL(8);
249 	}
250 
251 	if (rehash_vector & BIT_ULL(9)) {
252 		intlv_bit = FIELD_GET(BIT_ULL(9), ctx->ret_addr);
253 
254 		hashed_bit = intlv_bit;
255 		hashed_bit ^= FIELD_GET(BIT_ULL(17), ctx->ret_addr) & hash_ctl_64k;
256 		hashed_bit ^= FIELD_GET(BIT_ULL(22), ctx->ret_addr) & hash_ctl_2M;
257 		hashed_bit ^= FIELD_GET(BIT_ULL(31), ctx->ret_addr) & hash_ctl_1G;
258 		hashed_bit ^= FIELD_GET(BIT_ULL(41), ctx->ret_addr) & hash_ctl_1T;
259 
260 		if (hashed_bit != intlv_bit)
261 			ctx->ret_addr ^= BIT_ULL(9);
262 	}
263 
264 	if (rehash_vector & BIT_ULL(12)) {
265 		intlv_bit = FIELD_GET(BIT_ULL(12), ctx->ret_addr);
266 
267 		hashed_bit = intlv_bit;
268 		hashed_bit ^= FIELD_GET(BIT_ULL(18), ctx->ret_addr) & hash_ctl_64k;
269 		hashed_bit ^= FIELD_GET(BIT_ULL(23), ctx->ret_addr) & hash_ctl_2M;
270 		hashed_bit ^= FIELD_GET(BIT_ULL(32), ctx->ret_addr) & hash_ctl_1G;
271 		hashed_bit ^= FIELD_GET(BIT_ULL(42), ctx->ret_addr) & hash_ctl_1T;
272 
273 		if (hashed_bit != intlv_bit)
274 			ctx->ret_addr ^= BIT_ULL(12);
275 	}
276 
277 	if (rehash_vector & BIT_ULL(13)) {
278 		intlv_bit = FIELD_GET(BIT_ULL(13), ctx->ret_addr);
279 
280 		hashed_bit = intlv_bit;
281 		hashed_bit ^= FIELD_GET(BIT_ULL(19), ctx->ret_addr) & hash_ctl_64k;
282 		hashed_bit ^= FIELD_GET(BIT_ULL(24), ctx->ret_addr) & hash_ctl_2M;
283 		hashed_bit ^= FIELD_GET(BIT_ULL(33), ctx->ret_addr) & hash_ctl_1G;
284 		hashed_bit ^= FIELD_GET(BIT_ULL(43), ctx->ret_addr) & hash_ctl_1T;
285 
286 		if (hashed_bit != intlv_bit)
287 			ctx->ret_addr ^= BIT_ULL(13);
288 	}
289 
290 	if (rehash_vector & BIT_ULL(14)) {
291 		intlv_bit = FIELD_GET(BIT_ULL(14), ctx->ret_addr);
292 
293 		hashed_bit = intlv_bit;
294 		hashed_bit ^= FIELD_GET(BIT_ULL(20), ctx->ret_addr) & hash_ctl_64k;
295 		hashed_bit ^= FIELD_GET(BIT_ULL(25), ctx->ret_addr) & hash_ctl_2M;
296 		hashed_bit ^= FIELD_GET(BIT_ULL(34), ctx->ret_addr) & hash_ctl_1G;
297 		hashed_bit ^= FIELD_GET(BIT_ULL(44), ctx->ret_addr) & hash_ctl_1T;
298 
299 		if (hashed_bit != intlv_bit)
300 			ctx->ret_addr ^= BIT_ULL(14);
301 	}
302 
303 	return 0;
304 }
305 
306 /*
307  * MI300 hash bits
308  *					  4K 64K  2M  1G  1T  1T
309  * COH_ST_Select[0]	= XOR of addr{8,  12, 15, 22, 29, 36, 43}
310  * COH_ST_Select[1]	= XOR of addr{9,  13, 16, 23, 30, 37, 44}
311  * COH_ST_Select[2]	= XOR of addr{10, 14, 17, 24, 31, 38, 45}
312  * COH_ST_Select[3]	= XOR of addr{11,     18, 25, 32, 39, 46}
313  * COH_ST_Select[4]	= XOR of addr{14,     19, 26, 33, 40, 47} aka Stack
314  * DieID[0]		= XOR of addr{12,     20, 27, 34, 41    }
315  * DieID[1]		= XOR of addr{13,     21, 28, 35, 42    }
316  */
mi300_dehash_addr(struct addr_ctx * ctx)317 static int mi300_dehash_addr(struct addr_ctx *ctx)
318 {
319 	bool hash_ctl_4k, hash_ctl_64k, hash_ctl_2M, hash_ctl_1G, hash_ctl_1T;
320 	bool hashed_bit, intlv_bit, test_bit;
321 	u8 num_intlv_bits, base_bit, i;
322 
323 	hash_ctl_4k  = FIELD_GET(DF4p5_HASH_CTL_4K, ctx->map.ctl);
324 	hash_ctl_64k = FIELD_GET(DF4_HASH_CTL_64K,  ctx->map.ctl);
325 	hash_ctl_2M  = FIELD_GET(DF4_HASH_CTL_2M,   ctx->map.ctl);
326 	hash_ctl_1G  = FIELD_GET(DF4_HASH_CTL_1G,   ctx->map.ctl);
327 	hash_ctl_1T  = FIELD_GET(DF4p5_HASH_CTL_1T, ctx->map.ctl);
328 
329 	/* Channel bits */
330 	num_intlv_bits = ilog2(ctx->map.num_intlv_chan);
331 
332 	for (i = 0; i < num_intlv_bits; i++) {
333 		base_bit = 8 + i;
334 
335 		/* COH_ST_Select[4] jumps to a base bit of 14. */
336 		if (i == 4)
337 			base_bit = 14;
338 
339 		intlv_bit = BIT_ULL(base_bit) & ctx->ret_addr;
340 
341 		hashed_bit = intlv_bit;
342 
343 		/* 4k hash bit only applies to the first 3 bits. */
344 		if (i <= 2) {
345 			test_bit    = BIT_ULL(12 + i) & ctx->ret_addr;
346 			hashed_bit ^= test_bit & hash_ctl_4k;
347 		}
348 
349 		/* Use temporary 'test_bit' value to avoid Sparse warnings. */
350 		test_bit    = BIT_ULL(15 + i) & ctx->ret_addr;
351 		hashed_bit ^= test_bit & hash_ctl_64k;
352 		test_bit    = BIT_ULL(22 + i) & ctx->ret_addr;
353 		hashed_bit ^= test_bit & hash_ctl_2M;
354 		test_bit    = BIT_ULL(29 + i) & ctx->ret_addr;
355 		hashed_bit ^= test_bit & hash_ctl_1G;
356 		test_bit    = BIT_ULL(36 + i) & ctx->ret_addr;
357 		hashed_bit ^= test_bit & hash_ctl_1T;
358 		test_bit    = BIT_ULL(43 + i) & ctx->ret_addr;
359 		hashed_bit ^= test_bit & hash_ctl_1T;
360 
361 		if (hashed_bit != intlv_bit)
362 			ctx->ret_addr ^= BIT_ULL(base_bit);
363 	}
364 
365 	/* Die bits */
366 	num_intlv_bits = ilog2(ctx->map.num_intlv_dies);
367 
368 	for (i = 0; i < num_intlv_bits; i++) {
369 		base_bit = 12 + i;
370 
371 		intlv_bit = BIT_ULL(base_bit) & ctx->ret_addr;
372 
373 		hashed_bit = intlv_bit;
374 
375 		test_bit    = BIT_ULL(20 + i) & ctx->ret_addr;
376 		hashed_bit ^= test_bit & hash_ctl_64k;
377 		test_bit    = BIT_ULL(27 + i) & ctx->ret_addr;
378 		hashed_bit ^= test_bit & hash_ctl_2M;
379 		test_bit    = BIT_ULL(34 + i) & ctx->ret_addr;
380 		hashed_bit ^= test_bit & hash_ctl_1G;
381 		test_bit    = BIT_ULL(41 + i) & ctx->ret_addr;
382 		hashed_bit ^= test_bit & hash_ctl_1T;
383 
384 		if (hashed_bit != intlv_bit)
385 			ctx->ret_addr ^= BIT_ULL(base_bit);
386 	}
387 
388 	return 0;
389 }
390 
dehash_address(struct addr_ctx * ctx)391 int dehash_address(struct addr_ctx *ctx)
392 {
393 	switch (ctx->map.intlv_mode) {
394 	/* No hashing cases. */
395 	case NONE:
396 	case NOHASH_2CHAN:
397 	case NOHASH_4CHAN:
398 	case NOHASH_8CHAN:
399 	case NOHASH_16CHAN:
400 	case NOHASH_32CHAN:
401 	/* Hashing bits handled earlier during CS ID calculation. */
402 	case DF4_NPS4_3CHAN_HASH:
403 	case DF4_NPS2_5CHAN_HASH:
404 	case DF4_NPS2_6CHAN_HASH:
405 	case DF4_NPS1_10CHAN_HASH:
406 	case DF4_NPS1_12CHAN_HASH:
407 	case DF4p5_NPS2_6CHAN_1K_HASH:
408 	case DF4p5_NPS2_6CHAN_2K_HASH:
409 	case DF4p5_NPS1_10CHAN_1K_HASH:
410 	case DF4p5_NPS1_10CHAN_2K_HASH:
411 	case DF4p5_NPS1_12CHAN_1K_HASH:
412 	case DF4p5_NPS1_12CHAN_2K_HASH:
413 	case DF4p5_NPS0_24CHAN_1K_HASH:
414 	case DF4p5_NPS0_24CHAN_2K_HASH:
415 	/* No hash physical address bits, so nothing to do. */
416 	case DF4p5_NPS4_3CHAN_1K_HASH:
417 	case DF4p5_NPS4_3CHAN_2K_HASH:
418 	case DF4p5_NPS2_5CHAN_1K_HASH:
419 	case DF4p5_NPS2_5CHAN_2K_HASH:
420 		return 0;
421 
422 	case DF2_2CHAN_HASH:
423 		return df2_dehash_addr(ctx);
424 
425 	case DF3_COD4_2CHAN_HASH:
426 	case DF3_COD2_4CHAN_HASH:
427 	case DF3_COD1_8CHAN_HASH:
428 		return df3_dehash_addr(ctx);
429 
430 	case DF3_6CHAN:
431 		return df3_6chan_dehash_addr(ctx);
432 
433 	case DF4_NPS4_2CHAN_HASH:
434 	case DF4_NPS2_4CHAN_HASH:
435 	case DF4_NPS1_8CHAN_HASH:
436 		return df4_dehash_addr(ctx);
437 
438 	case DF4p5_NPS4_2CHAN_1K_HASH:
439 	case DF4p5_NPS4_2CHAN_2K_HASH:
440 	case DF4p5_NPS2_4CHAN_2K_HASH:
441 	case DF4p5_NPS2_4CHAN_1K_HASH:
442 	case DF4p5_NPS1_8CHAN_1K_HASH:
443 	case DF4p5_NPS1_8CHAN_2K_HASH:
444 	case DF4p5_NPS1_16CHAN_1K_HASH:
445 	case DF4p5_NPS1_16CHAN_2K_HASH:
446 		return df4p5_dehash_addr(ctx);
447 
448 	case MI3_HASH_8CHAN:
449 	case MI3_HASH_16CHAN:
450 	case MI3_HASH_32CHAN:
451 		return mi300_dehash_addr(ctx);
452 
453 	default:
454 		atl_debug_on_bad_intlv_mode(ctx);
455 		return -EINVAL;
456 	}
457 }
458