1 #pragma once
2 #include <stdint.h>
3
4
5 #define CPUINFO_ARM_MIDR_IMPLEMENTER_MASK UINT32_C(0xFF000000)
6 #define CPUINFO_ARM_MIDR_VARIANT_MASK UINT32_C(0x00F00000)
7 #define CPUINFO_ARM_MIDR_ARCHITECTURE_MASK UINT32_C(0x000F0000)
8 #define CPUINFO_ARM_MIDR_PART_MASK UINT32_C(0x0000FFF0)
9 #define CPUINFO_ARM_MIDR_REVISION_MASK UINT32_C(0x0000000F)
10
11 #define CPUINFO_ARM_MIDR_IMPLEMENTER_OFFSET 24
12 #define CPUINFO_ARM_MIDR_VARIANT_OFFSET 20
13 #define CPUINFO_ARM_MIDR_ARCHITECTURE_OFFSET 16
14 #define CPUINFO_ARM_MIDR_PART_OFFSET 4
15 #define CPUINFO_ARM_MIDR_REVISION_OFFSET 0
16
17 #define CPUINFO_ARM_MIDR_ARM1156 UINT32_C(0x410FB560)
18 #define CPUINFO_ARM_MIDR_CORTEX_A7 UINT32_C(0x410FC070)
19 #define CPUINFO_ARM_MIDR_CORTEX_A9 UINT32_C(0x410FC090)
20 #define CPUINFO_ARM_MIDR_CORTEX_A15 UINT32_C(0x410FC0F0)
21 #define CPUINFO_ARM_MIDR_CORTEX_A17 UINT32_C(0x410FC0E0)
22 #define CPUINFO_ARM_MIDR_CORTEX_A35 UINT32_C(0x410FD040)
23 #define CPUINFO_ARM_MIDR_CORTEX_A53 UINT32_C(0x410FD030)
24 #define CPUINFO_ARM_MIDR_CORTEX_A55 UINT32_C(0x410FD050)
25 #define CPUINFO_ARM_MIDR_CORTEX_A57 UINT32_C(0x410FD070)
26 #define CPUINFO_ARM_MIDR_CORTEX_A72 UINT32_C(0x410FD080)
27 #define CPUINFO_ARM_MIDR_CORTEX_A73 UINT32_C(0x410FD090)
28 #define CPUINFO_ARM_MIDR_CORTEX_A75 UINT32_C(0x410FD0A0)
29 #define CPUINFO_ARM_MIDR_KRYO280_GOLD UINT32_C(0x51AF8001)
30 #define CPUINFO_ARM_MIDR_KRYO280_SILVER UINT32_C(0x51AF8014)
31 #define CPUINFO_ARM_MIDR_KRYO385_GOLD UINT32_C(0x518F802D)
32 #define CPUINFO_ARM_MIDR_KRYO385_SILVER UINT32_C(0x518F803C)
33 #define CPUINFO_ARM_MIDR_KRYO_SILVER_821 UINT32_C(0x510F2010)
34 #define CPUINFO_ARM_MIDR_KRYO_GOLD UINT32_C(0x510F2050)
35 #define CPUINFO_ARM_MIDR_KRYO_SILVER_820 UINT32_C(0x510F2110)
36 #define CPUINFO_ARM_MIDR_EXYNOS_M1_M2 UINT32_C(0x530F0010)
37 #define CPUINFO_ARM_MIDR_DENVER2 UINT32_C(0x4E0F0030)
38
midr_set_implementer(uint32_t midr,uint32_t implementer)39 inline static uint32_t midr_set_implementer(uint32_t midr, uint32_t implementer) {
40 return (midr & ~CPUINFO_ARM_MIDR_IMPLEMENTER_MASK) |
41 ((implementer << CPUINFO_ARM_MIDR_IMPLEMENTER_OFFSET) & CPUINFO_ARM_MIDR_IMPLEMENTER_MASK);
42 }
43
midr_set_variant(uint32_t midr,uint32_t variant)44 inline static uint32_t midr_set_variant(uint32_t midr, uint32_t variant) {
45 return (midr & ~CPUINFO_ARM_MIDR_VARIANT_MASK) |
46 ((variant << CPUINFO_ARM_MIDR_VARIANT_OFFSET) & CPUINFO_ARM_MIDR_VARIANT_MASK);
47 }
48
midr_set_architecture(uint32_t midr,uint32_t architecture)49 inline static uint32_t midr_set_architecture(uint32_t midr, uint32_t architecture) {
50 return (midr & ~CPUINFO_ARM_MIDR_ARCHITECTURE_MASK) |
51 ((architecture << CPUINFO_ARM_MIDR_ARCHITECTURE_OFFSET) & CPUINFO_ARM_MIDR_ARCHITECTURE_MASK);
52 }
53
midr_set_part(uint32_t midr,uint32_t part)54 inline static uint32_t midr_set_part(uint32_t midr, uint32_t part) {
55 return (midr & ~CPUINFO_ARM_MIDR_PART_MASK) |
56 ((part << CPUINFO_ARM_MIDR_PART_OFFSET) & CPUINFO_ARM_MIDR_PART_MASK);
57 }
58
midr_set_revision(uint32_t midr,uint32_t revision)59 inline static uint32_t midr_set_revision(uint32_t midr, uint32_t revision) {
60 return (midr & ~CPUINFO_ARM_MIDR_REVISION_MASK) |
61 ((revision << CPUINFO_ARM_MIDR_REVISION_OFFSET) & CPUINFO_ARM_MIDR_REVISION_MASK);
62 }
63
midr_get_variant(uint32_t midr)64 inline static uint32_t midr_get_variant(uint32_t midr) {
65 return (midr & CPUINFO_ARM_MIDR_VARIANT_MASK) >> CPUINFO_ARM_MIDR_VARIANT_OFFSET;
66 }
67
midr_get_implementer(uint32_t midr)68 inline static uint32_t midr_get_implementer(uint32_t midr) {
69 return (midr & CPUINFO_ARM_MIDR_IMPLEMENTER_MASK) >> CPUINFO_ARM_MIDR_IMPLEMENTER_OFFSET;
70 }
71
midr_get_part(uint32_t midr)72 inline static uint32_t midr_get_part(uint32_t midr) {
73 return (midr & CPUINFO_ARM_MIDR_PART_MASK) >> CPUINFO_ARM_MIDR_PART_OFFSET;
74 }
75
midr_get_revision(uint32_t midr)76 inline static uint32_t midr_get_revision(uint32_t midr) {
77 return (midr & CPUINFO_ARM_MIDR_REVISION_MASK) >> CPUINFO_ARM_MIDR_REVISION_OFFSET;
78 }
79
midr_copy_implementer(uint32_t midr,uint32_t other_midr)80 inline static uint32_t midr_copy_implementer(uint32_t midr, uint32_t other_midr) {
81 return (midr & ~CPUINFO_ARM_MIDR_IMPLEMENTER_MASK) | (other_midr & CPUINFO_ARM_MIDR_IMPLEMENTER_MASK);
82 }
83
midr_copy_variant(uint32_t midr,uint32_t other_midr)84 inline static uint32_t midr_copy_variant(uint32_t midr, uint32_t other_midr) {
85 return (midr & ~CPUINFO_ARM_MIDR_VARIANT_MASK) | (other_midr & CPUINFO_ARM_MIDR_VARIANT_MASK);
86 }
87
midr_copy_architecture(uint32_t midr,uint32_t other_midr)88 inline static uint32_t midr_copy_architecture(uint32_t midr, uint32_t other_midr) {
89 return (midr & ~CPUINFO_ARM_MIDR_ARCHITECTURE_MASK) | (other_midr & CPUINFO_ARM_MIDR_ARCHITECTURE_MASK);
90 }
91
midr_copy_part(uint32_t midr,uint32_t other_midr)92 inline static uint32_t midr_copy_part(uint32_t midr, uint32_t other_midr) {
93 return (midr & ~CPUINFO_ARM_MIDR_PART_MASK) | (other_midr & CPUINFO_ARM_MIDR_PART_MASK);
94 }
95
midr_copy_revision(uint32_t midr,uint32_t other_midr)96 inline static uint32_t midr_copy_revision(uint32_t midr, uint32_t other_midr) {
97 return (midr & ~CPUINFO_ARM_MIDR_REVISION_MASK) | (other_midr & CPUINFO_ARM_MIDR_REVISION_MASK);
98 }
99
midr_is_arm1156(uint32_t midr)100 inline static bool midr_is_arm1156(uint32_t midr) {
101 const uint32_t uarch_mask = CPUINFO_ARM_MIDR_IMPLEMENTER_MASK | CPUINFO_ARM_MIDR_PART_MASK;
102 return (midr & uarch_mask) == (CPUINFO_ARM_MIDR_ARM1156 & uarch_mask);
103 }
104
midr_is_arm11(uint32_t midr)105 inline static bool midr_is_arm11(uint32_t midr) {
106 return (midr & (CPUINFO_ARM_MIDR_IMPLEMENTER_MASK | 0x0000F000)) == UINT32_C(0x4100B000);
107 }
108
midr_is_cortex_a9(uint32_t midr)109 inline static bool midr_is_cortex_a9(uint32_t midr) {
110 const uint32_t uarch_mask = CPUINFO_ARM_MIDR_IMPLEMENTER_MASK | CPUINFO_ARM_MIDR_PART_MASK;
111 return (midr & uarch_mask) == (CPUINFO_ARM_MIDR_CORTEX_A9 & uarch_mask);
112 }
113
midr_is_scorpion(uint32_t midr)114 inline static bool midr_is_scorpion(uint32_t midr) {
115 switch (midr & (CPUINFO_ARM_MIDR_IMPLEMENTER_MASK | CPUINFO_ARM_MIDR_PART_MASK)) {
116 case UINT32_C(0x510000F0):
117 case UINT32_C(0x510002D0):
118 return true;
119 default:
120 return false;
121 }
122 }
123
midr_is_krait(uint32_t midr)124 inline static bool midr_is_krait(uint32_t midr) {
125 switch (midr & (CPUINFO_ARM_MIDR_IMPLEMENTER_MASK | CPUINFO_ARM_MIDR_PART_MASK)) {
126 case UINT32_C(0x510004D0):
127 case UINT32_C(0x510006F0):
128 return true;
129 default:
130 return false;
131 }
132 }
133
midr_is_cortex_a53(uint32_t midr)134 inline static bool midr_is_cortex_a53(uint32_t midr) {
135 const uint32_t uarch_mask = CPUINFO_ARM_MIDR_IMPLEMENTER_MASK | CPUINFO_ARM_MIDR_PART_MASK;
136 return (midr & uarch_mask) == (CPUINFO_ARM_MIDR_CORTEX_A53 & uarch_mask);
137 }
138
midr_is_qualcomm_cortex_a53_silver(uint32_t midr)139 inline static bool midr_is_qualcomm_cortex_a53_silver(uint32_t midr) {
140 const uint32_t uarch_mask = CPUINFO_ARM_MIDR_IMPLEMENTER_MASK | CPUINFO_ARM_MIDR_PART_MASK;
141 return (midr & uarch_mask) == (CPUINFO_ARM_MIDR_KRYO280_SILVER & uarch_mask);
142 }
143
midr_is_qualcomm_cortex_a55_silver(uint32_t midr)144 inline static bool midr_is_qualcomm_cortex_a55_silver(uint32_t midr) {
145 const uint32_t uarch_mask = CPUINFO_ARM_MIDR_IMPLEMENTER_MASK | CPUINFO_ARM_MIDR_PART_MASK;
146 return (midr & uarch_mask) == (CPUINFO_ARM_MIDR_KRYO385_SILVER & uarch_mask);
147 }
148
midr_is_kryo280_gold(uint32_t midr)149 inline static bool midr_is_kryo280_gold(uint32_t midr) {
150 const uint32_t uarch_mask = CPUINFO_ARM_MIDR_IMPLEMENTER_MASK | CPUINFO_ARM_MIDR_PART_MASK;
151 return (midr & uarch_mask) == (CPUINFO_ARM_MIDR_KRYO280_GOLD & uarch_mask);
152 }
153
midr_is_kryo_silver(uint32_t midr)154 inline static bool midr_is_kryo_silver(uint32_t midr) {
155 const uint32_t uarch_mask =
156 CPUINFO_ARM_MIDR_IMPLEMENTER_MASK | CPUINFO_ARM_MIDR_ARCHITECTURE_MASK | CPUINFO_ARM_MIDR_PART_MASK;
157 switch (midr & uarch_mask) {
158 case CPUINFO_ARM_MIDR_KRYO_SILVER_820:
159 case CPUINFO_ARM_MIDR_KRYO_SILVER_821:
160 return true;
161 default:
162 return false;
163 }
164 }
165
midr_is_kryo_gold(uint32_t midr)166 inline static bool midr_is_kryo_gold(uint32_t midr) {
167 const uint32_t uarch_mask = CPUINFO_ARM_MIDR_IMPLEMENTER_MASK | CPUINFO_ARM_MIDR_PART_MASK;
168 return (midr & uarch_mask) == (CPUINFO_ARM_MIDR_KRYO_GOLD & uarch_mask);
169 }
170
midr_score_core(uint32_t midr)171 inline static uint32_t midr_score_core(uint32_t midr) {
172 const uint32_t core_mask = CPUINFO_ARM_MIDR_IMPLEMENTER_MASK | CPUINFO_ARM_MIDR_PART_MASK;
173 switch (midr & core_mask) {
174 case UINT32_C(0x53000030): /* Exynos M4 */
175 case UINT32_C(0x53000040): /* Exynos M5 */
176 case UINT32_C(0x4100D440): /* Cortex-X1 */
177 /* These cores are in big role w.r.t Cortex-A75/-A76/-A77/-A78 */
178 return 6;
179 case UINT32_C(0x4E000030): /* Denver 2 */
180 case UINT32_C(0x53000010): /* Exynos M1 and Exynos M2 */
181 case UINT32_C(0x53000020): /* Exynos M3 */
182 case UINT32_C(0x51008040): /* Kryo 485 Gold / Gold Prime */
183 case UINT32_C(0x51008020): /* Kryo 385 Gold */
184 case UINT32_C(0x51008000): /* Kryo 260 / 280 Gold */
185 case UINT32_C(0x51002050): /* Kryo Gold */
186 case UINT32_C(0x4800D400): /* Cortex-A76 (HiSilicon) */
187 case UINT32_C(0x4100D410): /* Cortex-A78 */
188 case UINT32_C(0x4100D0D0): /* Cortex-A77 */
189 case UINT32_C(0x4100D0E0): /* Cortex-A76AE */
190 case UINT32_C(0x4100D0B0): /* Cortex-A76 */
191 case UINT32_C(0x4100D0A0): /* Cortex-A75 */
192 case UINT32_C(0x4100D090): /* Cortex-A73 */
193 case UINT32_C(0x4100D080): /* Cortex-A72 */
194 #if CPUINFO_ARCH_ARM
195 case UINT32_C(0x4100C0F0): /* Cortex-A15 */
196 case UINT32_C(0x4100C0E0): /* Cortex-A17 */
197 case UINT32_C(0x4100C0D0): /* Rockchip RK3288 cores */
198 case UINT32_C(0x4100C0C0): /* Cortex-A12 */
199 #endif /* CPUINFO_ARCH_ARM */
200 /* These cores are always in big role */
201 return 5;
202 case UINT32_C(0x4100D070): /* Cortex-A57 */
203 /* Cortex-A57 can be in LITTLE role w.r.t. Denver 2, or in big role w.r.t. Cortex-A53 */
204 return 4;
205 #if CPUINFO_ARCH_ARM64
206 case UINT32_C(0x4100D060): /* Cortex-A65 */
207 #endif /* CPUINFO_ARCH_ARM64 */
208 case UINT32_C(0x4100D050): /* Cortex-A55 */
209 case UINT32_C(0x4100D030): /* Cortex-A53 */
210 /* Cortex-A53 is usually in LITTLE role, but can be in big role w.r.t. Cortex-A35 */
211 return 2;
212 case UINT32_C(0x4100D040): /* Cortex-A35 */
213 #if CPUINFO_ARCH_ARM
214 case UINT32_C(0x4100C070): /* Cortex-A7 */
215 #endif /* CPUINFO_ARCH_ARM */
216 case UINT32_C(0x51008050): /* Kryo 485 Silver */
217 case UINT32_C(0x51008030): /* Kryo 385 Silver */
218 case UINT32_C(0x51008010): /* Kryo 260 / 280 Silver */
219 case UINT32_C(0x51002110): /* Kryo Silver (Snapdragon 820) */
220 case UINT32_C(0x51002010): /* Kryo Silver (Snapdragon 821) */
221 /* These cores are always in LITTLE core */
222 return 1;
223 default:
224 /*
225 * Unknown cores, or cores which do not have big/LITTLE roles.
226 * To be future-proof w.r.t. cores not yet recognized in cpuinfo, assume position between
227 * Cortex-A57/A72/A73/A75 and Cortex-A53/A55. Then at least future cores paired with
228 * one of these known cores will be properly scored.
229 */
230 return 3;
231 }
232 }
233
midr_little_core_for_big(uint32_t midr)234 inline static uint32_t midr_little_core_for_big(uint32_t midr) {
235 const uint32_t core_mask =
236 CPUINFO_ARM_MIDR_IMPLEMENTER_MASK | CPUINFO_ARM_MIDR_ARCHITECTURE_MASK | CPUINFO_ARM_MIDR_PART_MASK;
237 switch (midr & core_mask) {
238 case CPUINFO_ARM_MIDR_CORTEX_A75:
239 return CPUINFO_ARM_MIDR_CORTEX_A55;
240 case CPUINFO_ARM_MIDR_CORTEX_A73:
241 case CPUINFO_ARM_MIDR_CORTEX_A72:
242 case CPUINFO_ARM_MIDR_CORTEX_A57:
243 case CPUINFO_ARM_MIDR_EXYNOS_M1_M2:
244 return CPUINFO_ARM_MIDR_CORTEX_A53;
245 case CPUINFO_ARM_MIDR_CORTEX_A17:
246 case CPUINFO_ARM_MIDR_CORTEX_A15:
247 return CPUINFO_ARM_MIDR_CORTEX_A7;
248 case CPUINFO_ARM_MIDR_KRYO280_GOLD:
249 return CPUINFO_ARM_MIDR_KRYO280_SILVER;
250 case CPUINFO_ARM_MIDR_KRYO_GOLD:
251 return CPUINFO_ARM_MIDR_KRYO_SILVER_820;
252 case CPUINFO_ARM_MIDR_DENVER2:
253 return CPUINFO_ARM_MIDR_CORTEX_A57;
254 default:
255 return midr;
256 }
257 }
258