src/arm/mach/init.c - platform/external/cpuinfo - Git at Google

 #include <stdio.h>
 #include <stdint.h>
 #include <stdlib.h>
 #include <string.h>
 #include <alloca.h>

 #include <errno.h>
 #include <sys/types.h>
 #include <sys/sysctl.h>
 #include <mach/machine.h>

 #include <cpuinfo.h>
 #include <mach/api.h>
 #include <cpuinfo/internal-api.h>
 #include <cpuinfo/log.h>


 struct cpuinfo_arm_isa cpuinfo_isa = {
 #if CPUINFO_ARCH_ARM
 	.thumb = true,
 	.thumb2 = true,
 	.thumbee = false,
 	.jazelle = false,
 	.armv5e = true,
 	.armv6 = true,
 	.armv6k = true,
 	.armv7 = true,
 	.vfpv2 = false,
 	.vfpv3 = true,
 	.d32 = true,
 	.wmmx = false,
 	.wmmx2 = false,
 	.neon = true,
 #endif
 #if CPUINFO_ARCH_ARM64
 	.aes = true,
 	.sha1 = true,
 	.sha2 = true,
 	.pmull = true,
 	.crc32 = true,
 #endif
 };

 static uint32_t get_sys_info(int type_specifier, const char* name) {
 	size_t size = 0;
 	uint32_t result = 0;
 	int mib[2] = { CTL_HW, type_specifier };
 	if (sysctl(mib, 2, NULL, &size, NULL, 0) != 0) {
 		cpuinfo_log_info("sysctl(\"%s\") failed: %s", name, strerror(errno));
 	} else if (size == sizeof(uint32_t)) {
 		sysctl(mib, 2, &result, &size, NULL, 0);
 		cpuinfo_log_debug("%s: %"PRIu32 ", size = %lu", name, result, size);
 	} else {
 		cpuinfo_log_info("sysctl does not support non-integer lookup for (\"%s\")", name);
 	}
 	return result;
 }

 static uint32_t get_sys_info_by_name(const char* type_specifier) {
 	size_t size = 0;
 	uint32_t result = 0;
 	if (sysctlbyname(type_specifier, NULL, &size, NULL, 0) != 0) {
 		cpuinfo_log_info("sysctlbyname(\"%s\") failed: %s", type_specifier, strerror(errno));
 	} else if (size == sizeof(uint32_t)) {
 		sysctlbyname(type_specifier, &result, &size, NULL, 0);
 		cpuinfo_log_debug("%s: %"PRIu32 ", size = %lu", type_specifier, result, size);
 	} else {
 		cpuinfo_log_info("sysctl does not support non-integer lookup for (\"%s\")", type_specifier);
 	}
 	return result;
 }

 static enum cpuinfo_uarch decode_uarch(uint32_t cpu_family, uint32_t cpu_subtype, uint32_t core_index, uint32_t core_count) {
 	switch (cpu_family) {
 		case CPUFAMILY_ARM_SWIFT:
 			return cpuinfo_uarch_swift;
 		case CPUFAMILY_ARM_CYCLONE:
 			return cpuinfo_uarch_cyclone;
 		case CPUFAMILY_ARM_TYPHOON:
 			return cpuinfo_uarch_typhoon;
 		case CPUFAMILY_ARM_TWISTER:
 			return cpuinfo_uarch_twister;
 		case CPUFAMILY_ARM_HURRICANE:
 			return cpuinfo_uarch_hurricane;
 #ifdef CPUFAMILY_ARM_MONSOON_MISTRAL
 		case CPUFAMILY_ARM_MONSOON_MISTRAL:
 #else
 		case 0xe81e7ef6:
 			/* Hard-coded value for older SDKs which do not define CPUFAMILY_ARM_MONSOON_MISTRAL */
 #endif
 			/* 2x Monsoon + 4x Mistral cores */
 			return core_index < 2 ? cpuinfo_uarch_monsoon : cpuinfo_uarch_mistral;
 #ifdef CPUFAMILY_ARM_VORTEX_TEMPEST
 		case CPUFAMILY_ARM_VORTEX_TEMPEST:
 #else
 		case 0x07d34b9f:
 			/* Hard-coded value for older SDKs which do not define CPUFAMILY_ARM_VORTEX_TEMPEST */
 #endif
 			/* Hexa-core: 2x Vortex + 4x Tempest; Octa-core: 4x Cortex + 4x Tempest */
 			return core_index + 4 < core_count ? cpuinfo_uarch_vortex : cpuinfo_uarch_tempest;
 		default:
 			/* Use hw.cpusubtype for detection */
 			break;
 	}

 	switch (cpu_subtype) {
 		case CPU_SUBTYPE_ARM_V7:
 			return cpuinfo_uarch_cortex_a8;
 		case CPU_SUBTYPE_ARM_V7F:
 			return cpuinfo_uarch_cortex_a9;
 		case CPU_SUBTYPE_ARM_V7K:
 			return cpuinfo_uarch_cortex_a7;
 		default:
 			return cpuinfo_uarch_unknown;
 	}
 }

 static void decode_package_name(char* package_name) {
 	size_t size;
 	if (sysctlbyname("hw.machine", NULL, &size, NULL, 0) != 0) {
 		cpuinfo_log_warning("sysctlbyname(\"hw.machine\") failed: %s", strerror(errno));
 		return;
 	}

 	char *machine_name = alloca(size);
 	if (sysctlbyname("hw.machine", machine_name, &size, NULL, 0) != 0) {
 		cpuinfo_log_warning("sysctlbyname(\"hw.machine\") failed: %s", strerror(errno));
 		return;
 	}
 	cpuinfo_log_debug("hw.machine: %s", machine_name);

 	char name[10];
 	uint32_t major = 0, minor = 0;
 	if (sscanf(machine_name, "%9[^,0123456789]%"SCNu32",%"SCNu32, name, &major, &minor) != 3) {
 		cpuinfo_log_warning("parsing \"hw.machine\" failed: %s", strerror(errno));
 		return;
 	}

 	uint32_t chip_model = 0;
 	char suffix = '\0';
 	if (strcmp(name, "iPhone") == 0) {
 		/*
 		 * iPhone 4 and up are supported:
 		 *  - iPhone 4       [A4]:  iPhone3,1, iPhone3,2, iPhone3,3
 		 *  - iPhone 4S      [A5]:  iPhone4,1
 		 *  - iPhone 5       [A6]:  iPhone5,1, iPhone5,2
 		 *  - iPhone 5c      [A6]:  iPhone5,3, iPhone5,4
 		 *  - iPhone 5s      [A7]:  iPhone6,1, iPhone6,2
 		 *  - iPhone 6       [A8]:  iPhone7,2
 		 *  - iPhone 6 Plus  [A8]:  iPhone7,1
 		 *  - iPhone 6s      [A9]:  iPhone8,1
 		 *  - iPhone 6s Plus [A9]:  iPhone8,2
 		 *  - iPhone SE      [A9]:  iPhone8,4
 		 *  - iPhone 7       [A10]: iPhone9,1, iPhone9,3
 		 *  - iPhone 7 Plus  [A10]: iPhone9,2, iPhone9,4
 		 *  - iPhone 8       [A11]: iPhone10,1, iPhone10,4
 		 *  - iPhone 8 Plus  [A11]: iPhone10,2, iPhone10,5
 		 *  - iPhone X       [A11]: iPhone10,3, iPhone10,6
 		 *  - iPhone XS      [A12]: iPhone11,2,
 		 *  - iPhone XS Max  [A12]: iPhone11,4, iPhone11,6
 		 *  - iPhone XR      [A12]: iPhone11,8
 		 */
 		chip_model = major + 1;
 	} else if (strcmp(name, "iPad") == 0) {
 		switch (major) {
 			/* iPad 2 and up are supported */
 			case 2:
 				/*
 				 * iPad 2    [A5]: iPad2,1, iPad2,2, iPad2,3, iPad2,4
 				 * iPad mini [A5]: iPad2,5, iPad2,6, iPad2,7
 				 */
 				chip_model = major + 3;
 				break;
 			case 3:
 				/*
 				 * iPad 3rd Gen [A5X]: iPad3,1, iPad3,2, iPad3,3
 				 * iPad 4th Gen [A6X]: iPad3,4, iPad3,5, iPad3,6
 				 */
 				chip_model = (minor <= 3) ? 5 : 6;
 				suffix = 'X';
 				break;
 			case 4:
 				/*
 				 * iPad Air         [A7]: iPad4,1, iPad4,2, iPad4,3
 				 * iPad mini Retina [A7]: iPad4,4, iPad4,5, iPad4,6
 				 * iPad mini 3      [A7]: iPad4,7, iPad4,8, iPad4,9
 				 */
 				chip_model = major + 3;
 				break;
 			case 5:
 				/*
 				 * iPad mini 4 [A8]:  iPad5,1, iPad5,2
 				 * iPad Air 2  [A8X]: iPad5,3, iPad5,4
 				 */
 				chip_model = major + 3;
 				suffix = (minor <= 2) ? '\0' : 'X';
 				break;
 			case 6:
 				/*
 				 * iPad Pro 9.7" [A9X]: iPad6,3, iPad6,4
 				 * iPad Pro      [A9X]: iPad6,7, iPad6,8
 				 * iPad 5th Gen  [A9]:  iPad6,11, iPad6,12
 				 */
 				chip_model = major + 3;
 				suffix = minor <= 8 ? 'X' : '\0';
 				break;
 			case 7:
 				/*
 				 * iPad Pro 12.9" [A10X]: iPad7,1, iPad7,2
 				 * iPad Pro 10.5" [A10X]: iPad7,3, iPad7,4
 				 * iPad 6th Gen   [A10]:  iPad7,5, iPad7,6
 				 */
 				chip_model = major + 3;
 				suffix = minor <= 4 ? 'X' : '\0';
 				break;
 			default:
 				cpuinfo_log_info("unknown iPad: %s", machine_name);
 				break;
 		}
 	} else if (strcmp(name, "iPod") == 0) {
 		switch (major) {
 			case 5:
 				chip_model = 5;
 				break;
 				/* iPod touch (5th Gen) [A5]: iPod5,1 */
 			case 7:
 				/* iPod touch (6th Gen, 2015) [A8]: iPod7,1 */
 				chip_model = 8;
 				break;
 			default:
 				cpuinfo_log_info("unknown iPod: %s", machine_name);
 				break;
 		}
 	} else {
 		cpuinfo_log_info("unknown device: %s", machine_name);
 	}
 	if (chip_model != 0) {
 		snprintf(package_name, CPUINFO_PACKAGE_NAME_MAX, "Apple A%"PRIu32"%c", chip_model, suffix);
 	}
 }

 void cpuinfo_arm_mach_init(void) {
 	struct cpuinfo_processor* processors = NULL;
 	struct cpuinfo_core* cores = NULL;
 	struct cpuinfo_cluster* clusters = NULL;
 	struct cpuinfo_package* packages = NULL;
 	struct cpuinfo_cache* l1i = NULL;
 	struct cpuinfo_cache* l1d = NULL;
 	struct cpuinfo_cache* l2 = NULL;
 	struct cpuinfo_cache* l3 = NULL;

 	struct cpuinfo_mach_topology mach_topology = cpuinfo_mach_detect_topology();
 	processors = calloc(mach_topology.threads, sizeof(struct cpuinfo_processor));
 	if (processors == NULL) {
 		cpuinfo_log_error("failed to allocate %zu bytes for descriptions of %"PRIu32" logical processors",
 			mach_topology.threads * sizeof(struct cpuinfo_processor), mach_topology.threads);
 		goto cleanup;
 	}
 	cores = calloc(mach_topology.cores, sizeof(struct cpuinfo_core));
 	if (cores == NULL) {
 		cpuinfo_log_error("failed to allocate %zu bytes for descriptions of %"PRIu32" cores",
 			mach_topology.cores * sizeof(struct cpuinfo_core), mach_topology.cores);
 		goto cleanup;
 	}
 	packages = calloc(mach_topology.packages, sizeof(struct cpuinfo_package));
 	if (packages == NULL) {
 		cpuinfo_log_error("failed to allocate %zu bytes for descriptions of %"PRIu32" packages",
 			mach_topology.packages * sizeof(struct cpuinfo_package), mach_topology.packages);
 		goto cleanup;
 	}

 	const uint32_t threads_per_core = mach_topology.threads / mach_topology.cores;
 	const uint32_t threads_per_package = mach_topology.threads / mach_topology.packages;
 	const uint32_t cores_per_package = mach_topology.cores / mach_topology.packages;

 	for (uint32_t i = 0; i < mach_topology.packages; i++) {
 		packages[i] = (struct cpuinfo_package) {
 			.processor_start = i * threads_per_package,
 			.processor_count = threads_per_package,
 			.core_start = i * cores_per_package,
 			.core_count = cores_per_package,
 		};
 		decode_package_name(packages[i].name);
 	}


 	const uint32_t cpu_family = get_sys_info_by_name("hw.cpufamily");
 	const uint32_t cpu_type = get_sys_info_by_name("hw.cputype");
 	const uint32_t cpu_subtype = get_sys_info_by_name("hw.cpusubtype");
 	switch (cpu_type) {
 		case CPU_TYPE_ARM64:
 			cpuinfo_isa.aes = true;
 			cpuinfo_isa.sha1 = true;
 			cpuinfo_isa.sha2 = true;
 			cpuinfo_isa.pmull = true;
 			cpuinfo_isa.crc32 = true;
 			break;
 #if CPUINFO_ARCH_ARM
 		case CPU_TYPE_ARM:
 			switch (cpu_subtype) {
 				case CPU_SUBTYPE_ARM_V8:
 					cpuinfo_isa.aes = true;
 					cpuinfo_isa.sha1 = true;
 					cpuinfo_isa.sha2 = true;
 					cpuinfo_isa.pmull = true;
 					cpuinfo_isa.crc32 = true;
 					/* Fall-through to add ARMv7S features */
 				case CPU_SUBTYPE_ARM_V7S:
 				case CPU_SUBTYPE_ARM_V7K:
 					cpuinfo_isa.fma = true;
 					/* Fall-through to add ARMv7F features */
 				case CPU_SUBTYPE_ARM_V7F:
 					cpuinfo_isa.armv7mp = true;
 					cpuinfo_isa.fp16 = true;
 					/* Fall-through to add ARMv7 features */
 				case CPU_SUBTYPE_ARM_V7:
 					break;
 				default:
 					break;
 			}
 			break;
 #endif
 	}
 	/*
 	 * Support for ARMv8.1 Atomics & FP16 arithmetic instructions is supposed to be detected via
 	 * sysctlbyname calls with "hw.optional.armv8_1_atomics" and "hw.optional.neon_fp16" arguments
 	 * (see https://devstreaming-cdn.apple.com/videos/wwdc/2018/409t8zw7rumablsh/409/409_whats_new_in_llvm.pdf),
 	 * but on new iOS versions these calls just fail with EPERM.
 	 *
 	 * Thus, we whitelist CPUs known to support these instructions.
 	 */
 	switch (cpu_family) {
 #ifdef CPUFAMILY_ARM_MONSOON_MISTRAL
 		case CPUFAMILY_ARM_MONSOON_MISTRAL:
 #else
 		case 0xe81e7ef6:
 			/* Hard-coded value for older SDKs which do not define CPUFAMILY_ARM_MONSOON_MISTRAL */
 #endif
 #ifdef CPUFAMILY_ARM_VORTEX_TEMPEST
 		case CPUFAMILY_ARM_VORTEX_TEMPEST:
 #else
 		case 0x07d34b9f:
 			/* Hard-coded value for older SDKs which do not define CPUFAMILY_ARM_VORTEX_TEMPEST */
 #endif
 #if CPUINFO_ARCH_ARM64
 			cpuinfo_isa.atomics = true;
 #endif
 			cpuinfo_isa.fp16arith = true;
 	}

 	uint32_t num_clusters = 1;
 	for (uint32_t i = 0; i < mach_topology.cores; i++) {
 		cores[i] = (struct cpuinfo_core) {
 			.processor_start = i * threads_per_core,
 			.processor_count = threads_per_core,
 			.core_id = i % cores_per_package,
 			.package = packages + i / cores_per_package,
 			.vendor = cpuinfo_vendor_apple,
 			.uarch = decode_uarch(cpu_family, cpu_subtype, i, mach_topology.cores),
 		};
 		if (i != 0 && cores[i].uarch != cores[i - 1].uarch) {
 			num_clusters++;
 		}
 	}
 	for (uint32_t i = 0; i < mach_topology.threads; i++) {
 		const uint32_t smt_id = i % threads_per_core;
 		const uint32_t core_id = i / threads_per_core;
 		const uint32_t package_id = i / threads_per_package;

 		processors[i].smt_id = smt_id;
 		processors[i].core = &cores[core_id];
 		processors[i].package = &packages[package_id];
 	}

 	clusters = calloc(num_clusters, sizeof(struct cpuinfo_cluster));
 	if (clusters == NULL) {
 		cpuinfo_log_error(
 			"failed to allocate %zu bytes for descriptions of %"PRIu32" clusters",
 			num_clusters * sizeof(struct cpuinfo_cluster), num_clusters);
 		goto cleanup;
 	}
 	uint32_t cluster_idx = UINT32_MAX;
 	for (uint32_t i = 0; i < mach_topology.cores; i++) {
 		if (i == 0 || cores[i].uarch != cores[i - 1].uarch) {
 			cluster_idx++;
 			clusters[cluster_idx] = (struct cpuinfo_cluster) {
 				.processor_start = i * threads_per_core,
 				.processor_count = 1,
 				.core_start = i,
 				.core_count = 1,
 				.cluster_id = cluster_idx,
 				.package = cores[i].package,
 				.vendor = cores[i].vendor,
 				.uarch = cores[i].uarch,
 			};
 		} else {
 			clusters[cluster_idx].processor_count++;
 			clusters[cluster_idx].core_count++;
 		}
 		cores[i].cluster = &clusters[cluster_idx];
 	}

 	for (uint32_t i = 0; i < mach_topology.threads; i++) {
 		const uint32_t core_id = i / threads_per_core;
 		processors[i].cluster = cores[core_id].cluster;
 	}

 	for (uint32_t i = 0; i < mach_topology.packages; i++) {
 		packages[i].cluster_start = 0;
 		packages[i].cluster_count = num_clusters;
 	}

 	const uint32_t cacheline_size = get_sys_info(HW_CACHELINE, "HW_CACHELINE");
 	const uint32_t l1d_cache_size = get_sys_info(HW_L1DCACHESIZE, "HW_L1DCACHESIZE");
 	const uint32_t l1i_cache_size = get_sys_info(HW_L1ICACHESIZE, "HW_L1ICACHESIZE");
 	const uint32_t l2_cache_size = get_sys_info(HW_L2CACHESIZE, "HW_L2CACHESIZE");
 	const uint32_t l3_cache_size = get_sys_info(HW_L3CACHESIZE, "HW_L3CACHESIZE");
 	const uint32_t l1_cache_associativity = 4;
 	const uint32_t l2_cache_associativity = 8;
 	const uint32_t l3_cache_associativity = 16;
 	const uint32_t cache_partitions = 1;
 	const uint32_t cache_flags = 0;

 	uint32_t threads_per_l1 = 0, l1_count = 0;
 	if (l1i_cache_size != 0 || l1d_cache_size != 0) {
 		/* Assume L1 caches are private to each core */
 		threads_per_l1 = 1;
 		l1_count = mach_topology.threads / threads_per_l1;
 		cpuinfo_log_debug("detected %"PRIu32" L1 caches", l1_count);
 	}

 	uint32_t threads_per_l2 = 0, l2_count = 0;
 	if (l2_cache_size != 0) {
 		/* Assume L2 cache is shared between all cores */
 		threads_per_l2 = mach_topology.cores;
 		l2_count = 1;
 		cpuinfo_log_debug("detected %"PRIu32" L2 caches", l2_count);
 	}

 	uint32_t threads_per_l3 = 0, l3_count = 0;
 	if (l3_cache_size != 0) {
 		/* Assume L3 cache is shared between all cores */
 		threads_per_l3 = mach_topology.cores;
 		l3_count = 1;
 		cpuinfo_log_debug("detected %"PRIu32" L3 caches", l3_count);
 	}

 	if (l1i_cache_size != 0) {
 		l1i = calloc(l1_count, sizeof(struct cpuinfo_cache));
 		if (l1i == NULL) {
 			cpuinfo_log_error("failed to allocate %zu bytes for descriptions of %"PRIu32" L1I caches",
 				l1_count * sizeof(struct cpuinfo_cache), l1_count);
 			goto cleanup;
 		}
 		for (uint32_t c = 0; c < l1_count; c++) {
 			l1i[c] = (struct cpuinfo_cache) {
 				.size            = l1i_cache_size,
 				.associativity   = l1_cache_associativity,
 				.sets            = l1i_cache_size / (l1_cache_associativity * cacheline_size),
 				.partitions      = cache_partitions,
 				.line_size       = cacheline_size,
 				.flags           = cache_flags,
 				.processor_start = c * threads_per_l1,
 				.processor_count = threads_per_l1,
 			};
 		}
 		for (uint32_t t = 0; t < mach_topology.threads; t++) {
 			processors[t].cache.l1i = &l1i[t / threads_per_l1];
 		}
 	}

 	if (l1d_cache_size != 0) {
 		l1d = calloc(l1_count, sizeof(struct cpuinfo_cache));
 		if (l1d == NULL) {
 			cpuinfo_log_error("failed to allocate %zu bytes for descriptions of %"PRIu32" L1D caches",
 				l1_count * sizeof(struct cpuinfo_cache), l1_count);
 			goto cleanup;
 		}
 		for (uint32_t c = 0; c < l1_count; c++) {
 			l1d[c] = (struct cpuinfo_cache) {
 				.size            = l1d_cache_size,
 				.associativity   = l1_cache_associativity,
 				.sets            = l1d_cache_size / (l1_cache_associativity * cacheline_size),
 				.partitions      = cache_partitions,
 				.line_size       = cacheline_size,
 				.flags           = cache_flags,
 				.processor_start = c * threads_per_l1,
 				.processor_count = threads_per_l1,
 			};
 		}
 		for (uint32_t t = 0; t < mach_topology.threads; t++) {
 			processors[t].cache.l1d = &l1d[t / threads_per_l1];
 		}
 	}

 	if (l2_count != 0) {
 		l2 = calloc(l2_count, sizeof(struct cpuinfo_cache));
 		if (l2 == NULL) {
 			cpuinfo_log_error("failed to allocate %zu bytes for descriptions of %"PRIu32" L2 caches",
 				l2_count * sizeof(struct cpuinfo_cache), l2_count);
 			goto cleanup;
 		}
 		for (uint32_t c = 0; c < l2_count; c++) {
 			l2[c] = (struct cpuinfo_cache) {
 				.size            = l2_cache_size,
 				.associativity   = l2_cache_associativity,
 				.sets            = l2_cache_size / (l2_cache_associativity * cacheline_size),
 				.partitions      = cache_partitions,
 				.line_size       = cacheline_size,
 				.flags           = cache_flags,
 				.processor_start = c * threads_per_l2,
 				.processor_count = threads_per_l2,
 			};
 		}
 		for (uint32_t t = 0; t < mach_topology.threads; t++) {
 			processors[t].cache.l2 = &l2[0];
 		}
 	}

 	if (l3_count != 0) {
 		l3 = calloc(l3_count, sizeof(struct cpuinfo_cache));
 		if (l3 == NULL) {
 			cpuinfo_log_error("failed to allocate %zu bytes for descriptions of %"PRIu32" L3 caches",
 												l3_count * sizeof(struct cpuinfo_cache), l3_count);
 			goto cleanup;
 		}
 		for (uint32_t c = 0; c < l3_count; c++) {
 			l3[c] = (struct cpuinfo_cache) {
 				.size            = l3_cache_size,
 				.associativity   = l3_cache_associativity,
 				.sets            = l3_cache_size / (l3_cache_associativity * cacheline_size),
 				.partitions      = cache_partitions,
 				.line_size       = cacheline_size,
 				.flags           = cache_flags,
 				.processor_start = c * threads_per_l3,
 				.processor_count = threads_per_l3,
 			};
 		}
 		for (uint32_t t = 0; t < mach_topology.threads; t++) {
 			processors[t].cache.l3 = &l3[0];
 		}
 	}

 	/* Commit changes */
 	cpuinfo_cache[cpuinfo_cache_level_1i] = l1i;
 	cpuinfo_cache[cpuinfo_cache_level_1d] = l1d;
 	cpuinfo_cache[cpuinfo_cache_level_2]  = l2;
 	cpuinfo_cache[cpuinfo_cache_level_3]  = l3;

 	cpuinfo_processors = processors;
 	cpuinfo_cores = cores;
 	cpuinfo_clusters = clusters;
 	cpuinfo_packages = packages;

 	cpuinfo_cache_count[cpuinfo_cache_level_1i] = l1_count;
 	cpuinfo_cache_count[cpuinfo_cache_level_1d] = l1_count;
 	cpuinfo_cache_count[cpuinfo_cache_level_2]  = l2_count;
 	cpuinfo_cache_count[cpuinfo_cache_level_3]  = l3_count;

 	cpuinfo_processors_count = mach_topology.threads;
 	cpuinfo_cores_count = mach_topology.cores;
 	cpuinfo_clusters_count = num_clusters;
 	cpuinfo_packages_count = mach_topology.packages;

 	cpuinfo_max_cache_size = cpuinfo_compute_max_cache_size(&processors[0]);

 	__sync_synchronize();

 	cpuinfo_is_initialized = true;

 	processors = NULL;
 	cores = NULL;
 	clusters = NULL;
 	packages = NULL;
 	l1i = l1d = l2 = l3 = NULL;

 cleanup:
 	free(processors);
 	free(cores);
 	free(clusters);
 	free(packages);
 	free(l1i);
 	free(l1d);
 	free(l2);
 	free(l3);
 }
	#include <stdio.h>
	#include <stdint.h>
	#include <stdlib.h>
	#include <string.h>
	#include <alloca.h>

	#include <errno.h>
	#include <sys/types.h>
	#include <sys/sysctl.h>
	#include <mach/machine.h>

	#include <cpuinfo.h>
	#include <mach/api.h>
	#include <cpuinfo/internal-api.h>
	#include <cpuinfo/log.h>


	struct cpuinfo_arm_isa cpuinfo_isa = {
	#if CPUINFO_ARCH_ARM
	.thumb = true,
	.thumb2 = true,
	.thumbee = false,
	.jazelle = false,
	.armv5e = true,
	.armv6 = true,
	.armv6k = true,
	.armv7 = true,
	.vfpv2 = false,
	.vfpv3 = true,
	.d32 = true,
	.wmmx = false,
	.wmmx2 = false,
	.neon = true,
	#endif
	#if CPUINFO_ARCH_ARM64
	.aes = true,
	.sha1 = true,
	.sha2 = true,
	.pmull = true,
	.crc32 = true,
	#endif
	};

	static uint32_t get_sys_info(int type_specifier, const char* name) {
	size_t size = 0;
	uint32_t result = 0;
	int mib[2] = { CTL_HW, type_specifier };
	if (sysctl(mib, 2, NULL, &size, NULL, 0) != 0) {
	cpuinfo_log_info("sysctl(\"%s\") failed: %s", name, strerror(errno));
	} else if (size == sizeof(uint32_t)) {
	sysctl(mib, 2, &result, &size, NULL, 0);
	cpuinfo_log_debug("%s: %"PRIu32 ", size = %lu", name, result, size);
	} else {
	cpuinfo_log_info("sysctl does not support non-integer lookup for (\"%s\")", name);
	}
	return result;
	}

	static uint32_t get_sys_info_by_name(const char* type_specifier) {
	size_t size = 0;
	uint32_t result = 0;
	if (sysctlbyname(type_specifier, NULL, &size, NULL, 0) != 0) {
	cpuinfo_log_info("sysctlbyname(\"%s\") failed: %s", type_specifier, strerror(errno));
	} else if (size == sizeof(uint32_t)) {
	sysctlbyname(type_specifier, &result, &size, NULL, 0);
	cpuinfo_log_debug("%s: %"PRIu32 ", size = %lu", type_specifier, result, size);
	} else {
	cpuinfo_log_info("sysctl does not support non-integer lookup for (\"%s\")", type_specifier);
	}
	return result;
	}

	static enum cpuinfo_uarch decode_uarch(uint32_t cpu_family, uint32_t cpu_subtype, uint32_t core_index, uint32_t core_count) {
	switch (cpu_family) {
	case CPUFAMILY_ARM_SWIFT:
	return cpuinfo_uarch_swift;
	case CPUFAMILY_ARM_CYCLONE:
	return cpuinfo_uarch_cyclone;
	case CPUFAMILY_ARM_TYPHOON:
	return cpuinfo_uarch_typhoon;
	case CPUFAMILY_ARM_TWISTER:
	return cpuinfo_uarch_twister;
	case CPUFAMILY_ARM_HURRICANE:
	return cpuinfo_uarch_hurricane;
	#ifdef CPUFAMILY_ARM_MONSOON_MISTRAL
	case CPUFAMILY_ARM_MONSOON_MISTRAL:
	#else
	case 0xe81e7ef6:
	/* Hard-coded value for older SDKs which do not define CPUFAMILY_ARM_MONSOON_MISTRAL */
	#endif
	/* 2x Monsoon + 4x Mistral cores */
	return core_index < 2 ? cpuinfo_uarch_monsoon : cpuinfo_uarch_mistral;
	#ifdef CPUFAMILY_ARM_VORTEX_TEMPEST
	case CPUFAMILY_ARM_VORTEX_TEMPEST:
	#else
	case 0x07d34b9f:
	/* Hard-coded value for older SDKs which do not define CPUFAMILY_ARM_VORTEX_TEMPEST */
	#endif
	/* Hexa-core: 2x Vortex + 4x Tempest; Octa-core: 4x Cortex + 4x Tempest */
	return core_index + 4 < core_count ? cpuinfo_uarch_vortex : cpuinfo_uarch_tempest;
	default:
	/* Use hw.cpusubtype for detection */
	break;
	}

	switch (cpu_subtype) {
	case CPU_SUBTYPE_ARM_V7:
	return cpuinfo_uarch_cortex_a8;
	case CPU_SUBTYPE_ARM_V7F:
	return cpuinfo_uarch_cortex_a9;
	case CPU_SUBTYPE_ARM_V7K:
	return cpuinfo_uarch_cortex_a7;
	default:
	return cpuinfo_uarch_unknown;
	}
	}

	static void decode_package_name(char* package_name) {
	size_t size;
	if (sysctlbyname("hw.machine", NULL, &size, NULL, 0) != 0) {
	cpuinfo_log_warning("sysctlbyname(\"hw.machine\") failed: %s", strerror(errno));
	return;
	}

	char *machine_name = alloca(size);
	if (sysctlbyname("hw.machine", machine_name, &size, NULL, 0) != 0) {
	cpuinfo_log_warning("sysctlbyname(\"hw.machine\") failed: %s", strerror(errno));
	return;
	}
	cpuinfo_log_debug("hw.machine: %s", machine_name);

	char name[10];
	uint32_t major = 0, minor = 0;
	if (sscanf(machine_name, "%9[^,0123456789]%"SCNu32",%"SCNu32, name, &major, &minor) != 3) {
	cpuinfo_log_warning("parsing \"hw.machine\" failed: %s", strerror(errno));
	return;
	}

	uint32_t chip_model = 0;
	char suffix = '\0';
	if (strcmp(name, "iPhone") == 0) {
	/*
	* iPhone 4 and up are supported:
	* - iPhone 4 [A4]: iPhone3,1, iPhone3,2, iPhone3,3
	* - iPhone 4S [A5]: iPhone4,1
	* - iPhone 5 [A6]: iPhone5,1, iPhone5,2
	* - iPhone 5c [A6]: iPhone5,3, iPhone5,4
	* - iPhone 5s [A7]: iPhone6,1, iPhone6,2
	* - iPhone 6 [A8]: iPhone7,2
	* - iPhone 6 Plus [A8]: iPhone7,1
	* - iPhone 6s [A9]: iPhone8,1
	* - iPhone 6s Plus [A9]: iPhone8,2
	* - iPhone SE [A9]: iPhone8,4
	* - iPhone 7 [A10]: iPhone9,1, iPhone9,3
	* - iPhone 7 Plus [A10]: iPhone9,2, iPhone9,4
	* - iPhone 8 [A11]: iPhone10,1, iPhone10,4
	* - iPhone 8 Plus [A11]: iPhone10,2, iPhone10,5
	* - iPhone X [A11]: iPhone10,3, iPhone10,6
	* - iPhone XS [A12]: iPhone11,2,
	* - iPhone XS Max [A12]: iPhone11,4, iPhone11,6
	* - iPhone XR [A12]: iPhone11,8
	*/
	chip_model = major + 1;
	} else if (strcmp(name, "iPad") == 0) {
	switch (major) {
	/* iPad 2 and up are supported */
	case 2:
	/*
	* iPad 2 [A5]: iPad2,1, iPad2,2, iPad2,3, iPad2,4
	* iPad mini [A5]: iPad2,5, iPad2,6, iPad2,7
	*/
	chip_model = major + 3;
	break;
	case 3:
	/*
	* iPad 3rd Gen [A5X]: iPad3,1, iPad3,2, iPad3,3
	* iPad 4th Gen [A6X]: iPad3,4, iPad3,5, iPad3,6
	*/
	chip_model = (minor <= 3) ? 5 : 6;
	suffix = 'X';
	break;
	case 4:
	/*
	* iPad Air [A7]: iPad4,1, iPad4,2, iPad4,3
	* iPad mini Retina [A7]: iPad4,4, iPad4,5, iPad4,6
	* iPad mini 3 [A7]: iPad4,7, iPad4,8, iPad4,9
	*/
	chip_model = major + 3;
	break;
	case 5:
	/*
	* iPad mini 4 [A8]: iPad5,1, iPad5,2
	* iPad Air 2 [A8X]: iPad5,3, iPad5,4
	*/
	chip_model = major + 3;
	suffix = (minor <= 2) ? '\0' : 'X';
	break;
	case 6:
	/*
	* iPad Pro 9.7" [A9X]: iPad6,3, iPad6,4
	* iPad Pro [A9X]: iPad6,7, iPad6,8
	* iPad 5th Gen [A9]: iPad6,11, iPad6,12
	*/
	chip_model = major + 3;
	suffix = minor <= 8 ? 'X' : '\0';
	break;
	case 7:
	/*
	* iPad Pro 12.9" [A10X]: iPad7,1, iPad7,2
	* iPad Pro 10.5" [A10X]: iPad7,3, iPad7,4
	* iPad 6th Gen [A10]: iPad7,5, iPad7,6
	*/
	chip_model = major + 3;
	suffix = minor <= 4 ? 'X' : '\0';
	break;
	default:
	cpuinfo_log_info("unknown iPad: %s", machine_name);
	break;
	}
	} else if (strcmp(name, "iPod") == 0) {
	switch (major) {
	case 5:
	chip_model = 5;
	break;
	/* iPod touch (5th Gen) [A5]: iPod5,1 */
	case 7:
	/* iPod touch (6th Gen, 2015) [A8]: iPod7,1 */
	chip_model = 8;
	break;
	default:
	cpuinfo_log_info("unknown iPod: %s", machine_name);
	break;
	}
	} else {
	cpuinfo_log_info("unknown device: %s", machine_name);
	}
	if (chip_model != 0) {
	snprintf(package_name, CPUINFO_PACKAGE_NAME_MAX, "Apple A%"PRIu32"%c", chip_model, suffix);
	}
	}

	void cpuinfo_arm_mach_init(void) {
	struct cpuinfo_processor* processors = NULL;
	struct cpuinfo_core* cores = NULL;
	struct cpuinfo_cluster* clusters = NULL;
	struct cpuinfo_package* packages = NULL;
	struct cpuinfo_cache* l1i = NULL;
	struct cpuinfo_cache* l1d = NULL;
	struct cpuinfo_cache* l2 = NULL;
	struct cpuinfo_cache* l3 = NULL;

	struct cpuinfo_mach_topology mach_topology = cpuinfo_mach_detect_topology();
	processors = calloc(mach_topology.threads, sizeof(struct cpuinfo_processor));
	if (processors == NULL) {
	cpuinfo_log_error("failed to allocate %zu bytes for descriptions of %"PRIu32" logical processors",
	mach_topology.threads * sizeof(struct cpuinfo_processor), mach_topology.threads);
	goto cleanup;
	}
	cores = calloc(mach_topology.cores, sizeof(struct cpuinfo_core));
	if (cores == NULL) {
	cpuinfo_log_error("failed to allocate %zu bytes for descriptions of %"PRIu32" cores",
	mach_topology.cores * sizeof(struct cpuinfo_core), mach_topology.cores);
	goto cleanup;
	}
	packages = calloc(mach_topology.packages, sizeof(struct cpuinfo_package));
	if (packages == NULL) {
	cpuinfo_log_error("failed to allocate %zu bytes for descriptions of %"PRIu32" packages",
	mach_topology.packages * sizeof(struct cpuinfo_package), mach_topology.packages);
	goto cleanup;
	}

	const uint32_t threads_per_core = mach_topology.threads / mach_topology.cores;
	const uint32_t threads_per_package = mach_topology.threads / mach_topology.packages;
	const uint32_t cores_per_package = mach_topology.cores / mach_topology.packages;

	for (uint32_t i = 0; i < mach_topology.packages; i++) {
	packages[i] = (struct cpuinfo_package) {
	.processor_start = i * threads_per_package,
	.processor_count = threads_per_package,
	.core_start = i * cores_per_package,
	.core_count = cores_per_package,
	};
	decode_package_name(packages[i].name);
	}


	const uint32_t cpu_family = get_sys_info_by_name("hw.cpufamily");
	const uint32_t cpu_type = get_sys_info_by_name("hw.cputype");
	const uint32_t cpu_subtype = get_sys_info_by_name("hw.cpusubtype");
	switch (cpu_type) {
	case CPU_TYPE_ARM64:
	cpuinfo_isa.aes = true;
	cpuinfo_isa.sha1 = true;
	cpuinfo_isa.sha2 = true;
	cpuinfo_isa.pmull = true;
	cpuinfo_isa.crc32 = true;
	break;
	#if CPUINFO_ARCH_ARM
	case CPU_TYPE_ARM:
	switch (cpu_subtype) {
	case CPU_SUBTYPE_ARM_V8:
	cpuinfo_isa.aes = true;
	cpuinfo_isa.sha1 = true;
	cpuinfo_isa.sha2 = true;
	cpuinfo_isa.pmull = true;
	cpuinfo_isa.crc32 = true;
	/* Fall-through to add ARMv7S features */
	case CPU_SUBTYPE_ARM_V7S:
	case CPU_SUBTYPE_ARM_V7K:
	cpuinfo_isa.fma = true;
	/* Fall-through to add ARMv7F features */
	case CPU_SUBTYPE_ARM_V7F:
	cpuinfo_isa.armv7mp = true;
	cpuinfo_isa.fp16 = true;
	/* Fall-through to add ARMv7 features */
	case CPU_SUBTYPE_ARM_V7:
	break;
	default:
	break;
	}
	break;
	#endif
	}
	/*
	* Support for ARMv8.1 Atomics & FP16 arithmetic instructions is supposed to be detected via
	* sysctlbyname calls with "hw.optional.armv8_1_atomics" and "hw.optional.neon_fp16" arguments
	* (see https://devstreaming-cdn.apple.com/videos/wwdc/2018/409t8zw7rumablsh/409/409_whats_new_in_llvm.pdf),
	* but on new iOS versions these calls just fail with EPERM.
	*
	* Thus, we whitelist CPUs known to support these instructions.
	*/
	switch (cpu_family) {
	#ifdef CPUFAMILY_ARM_MONSOON_MISTRAL
	case CPUFAMILY_ARM_MONSOON_MISTRAL:
	#else
	case 0xe81e7ef6:
	/* Hard-coded value for older SDKs which do not define CPUFAMILY_ARM_MONSOON_MISTRAL */
	#endif
	#ifdef CPUFAMILY_ARM_VORTEX_TEMPEST
	case CPUFAMILY_ARM_VORTEX_TEMPEST:
	#else
	case 0x07d34b9f:
	/* Hard-coded value for older SDKs which do not define CPUFAMILY_ARM_VORTEX_TEMPEST */
	#endif
	#if CPUINFO_ARCH_ARM64
	cpuinfo_isa.atomics = true;
	#endif
	cpuinfo_isa.fp16arith = true;
	}

	uint32_t num_clusters = 1;
	for (uint32_t i = 0; i < mach_topology.cores; i++) {
	cores[i] = (struct cpuinfo_core) {
	.processor_start = i * threads_per_core,
	.processor_count = threads_per_core,
	.core_id = i % cores_per_package,
	.package = packages + i / cores_per_package,
	.vendor = cpuinfo_vendor_apple,
	.uarch = decode_uarch(cpu_family, cpu_subtype, i, mach_topology.cores),
	};
	if (i != 0 && cores[i].uarch != cores[i - 1].uarch) {
	num_clusters++;
	}
	}
	for (uint32_t i = 0; i < mach_topology.threads; i++) {
	const uint32_t smt_id = i % threads_per_core;
	const uint32_t core_id = i / threads_per_core;
	const uint32_t package_id = i / threads_per_package;

	processors[i].smt_id = smt_id;
	processors[i].core = &cores[core_id];
	processors[i].package = &packages[package_id];
	}

	clusters = calloc(num_clusters, sizeof(struct cpuinfo_cluster));
	if (clusters == NULL) {
	cpuinfo_log_error(
	"failed to allocate %zu bytes for descriptions of %"PRIu32" clusters",
	num_clusters * sizeof(struct cpuinfo_cluster), num_clusters);
	goto cleanup;
	}
	uint32_t cluster_idx = UINT32_MAX;
	for (uint32_t i = 0; i < mach_topology.cores; i++) {
	if (i == 0 \|\| cores[i].uarch != cores[i - 1].uarch) {
	cluster_idx++;
	clusters[cluster_idx] = (struct cpuinfo_cluster) {
	.processor_start = i * threads_per_core,
	.processor_count = 1,
	.core_start = i,
	.core_count = 1,
	.cluster_id = cluster_idx,
	.package = cores[i].package,
	.vendor = cores[i].vendor,
	.uarch = cores[i].uarch,
	};
	} else {
	clusters[cluster_idx].processor_count++;
	clusters[cluster_idx].core_count++;
	}
	cores[i].cluster = &clusters[cluster_idx];
	}

	for (uint32_t i = 0; i < mach_topology.threads; i++) {
	const uint32_t core_id = i / threads_per_core;
	processors[i].cluster = cores[core_id].cluster;
	}

	for (uint32_t i = 0; i < mach_topology.packages; i++) {
	packages[i].cluster_start = 0;
	packages[i].cluster_count = num_clusters;
	}

	const uint32_t cacheline_size = get_sys_info(HW_CACHELINE, "HW_CACHELINE");
	const uint32_t l1d_cache_size = get_sys_info(HW_L1DCACHESIZE, "HW_L1DCACHESIZE");
	const uint32_t l1i_cache_size = get_sys_info(HW_L1ICACHESIZE, "HW_L1ICACHESIZE");
	const uint32_t l2_cache_size = get_sys_info(HW_L2CACHESIZE, "HW_L2CACHESIZE");
	const uint32_t l3_cache_size = get_sys_info(HW_L3CACHESIZE, "HW_L3CACHESIZE");
	const uint32_t l1_cache_associativity = 4;
	const uint32_t l2_cache_associativity = 8;
	const uint32_t l3_cache_associativity = 16;
	const uint32_t cache_partitions = 1;
	const uint32_t cache_flags = 0;

	uint32_t threads_per_l1 = 0, l1_count = 0;
	if (l1i_cache_size != 0 \|\| l1d_cache_size != 0) {
	/* Assume L1 caches are private to each core */
	threads_per_l1 = 1;
	l1_count = mach_topology.threads / threads_per_l1;
	cpuinfo_log_debug("detected %"PRIu32" L1 caches", l1_count);
	}

	uint32_t threads_per_l2 = 0, l2_count = 0;
	if (l2_cache_size != 0) {
	/* Assume L2 cache is shared between all cores */
	threads_per_l2 = mach_topology.cores;
	l2_count = 1;
	cpuinfo_log_debug("detected %"PRIu32" L2 caches", l2_count);
	}

	uint32_t threads_per_l3 = 0, l3_count = 0;
	if (l3_cache_size != 0) {
	/* Assume L3 cache is shared between all cores */
	threads_per_l3 = mach_topology.cores;
	l3_count = 1;
	cpuinfo_log_debug("detected %"PRIu32" L3 caches", l3_count);
	}

	if (l1i_cache_size != 0) {
	l1i = calloc(l1_count, sizeof(struct cpuinfo_cache));
	if (l1i == NULL) {
	cpuinfo_log_error("failed to allocate %zu bytes for descriptions of %"PRIu32" L1I caches",
	l1_count * sizeof(struct cpuinfo_cache), l1_count);
	goto cleanup;
	}
	for (uint32_t c = 0; c < l1_count; c++) {
	l1i[c] = (struct cpuinfo_cache) {
	.size = l1i_cache_size,
	.associativity = l1_cache_associativity,
	.sets = l1i_cache_size / (l1_cache_associativity * cacheline_size),
	.partitions = cache_partitions,
	.line_size = cacheline_size,
	.flags = cache_flags,
	.processor_start = c * threads_per_l1,
	.processor_count = threads_per_l1,
	};
	}
	for (uint32_t t = 0; t < mach_topology.threads; t++) {
	processors[t].cache.l1i = &l1i[t / threads_per_l1];
	}
	}

	if (l1d_cache_size != 0) {
	l1d = calloc(l1_count, sizeof(struct cpuinfo_cache));
	if (l1d == NULL) {
	cpuinfo_log_error("failed to allocate %zu bytes for descriptions of %"PRIu32" L1D caches",
	l1_count * sizeof(struct cpuinfo_cache), l1_count);
	goto cleanup;
	}
	for (uint32_t c = 0; c < l1_count; c++) {
	l1d[c] = (struct cpuinfo_cache) {
	.size = l1d_cache_size,
	.associativity = l1_cache_associativity,
	.sets = l1d_cache_size / (l1_cache_associativity * cacheline_size),
	.partitions = cache_partitions,
	.line_size = cacheline_size,
	.flags = cache_flags,
	.processor_start = c * threads_per_l1,
	.processor_count = threads_per_l1,
	};
	}
	for (uint32_t t = 0; t < mach_topology.threads; t++) {
	processors[t].cache.l1d = &l1d[t / threads_per_l1];
	}
	}

	if (l2_count != 0) {
	l2 = calloc(l2_count, sizeof(struct cpuinfo_cache));
	if (l2 == NULL) {
	cpuinfo_log_error("failed to allocate %zu bytes for descriptions of %"PRIu32" L2 caches",
	l2_count * sizeof(struct cpuinfo_cache), l2_count);
	goto cleanup;
	}
	for (uint32_t c = 0; c < l2_count; c++) {
	l2[c] = (struct cpuinfo_cache) {
	.size = l2_cache_size,
	.associativity = l2_cache_associativity,
	.sets = l2_cache_size / (l2_cache_associativity * cacheline_size),
	.partitions = cache_partitions,
	.line_size = cacheline_size,
	.flags = cache_flags,
	.processor_start = c * threads_per_l2,
	.processor_count = threads_per_l2,
	};
	}
	for (uint32_t t = 0; t < mach_topology.threads; t++) {
	processors[t].cache.l2 = &l2[0];
	}
	}

	if (l3_count != 0) {
	l3 = calloc(l3_count, sizeof(struct cpuinfo_cache));
	if (l3 == NULL) {
	cpuinfo_log_error("failed to allocate %zu bytes for descriptions of %"PRIu32" L3 caches",
	l3_count * sizeof(struct cpuinfo_cache), l3_count);
	goto cleanup;
	}
	for (uint32_t c = 0; c < l3_count; c++) {
	l3[c] = (struct cpuinfo_cache) {
	.size = l3_cache_size,
	.associativity = l3_cache_associativity,
	.sets = l3_cache_size / (l3_cache_associativity * cacheline_size),
	.partitions = cache_partitions,
	.line_size = cacheline_size,
	.flags = cache_flags,
	.processor_start = c * threads_per_l3,
	.processor_count = threads_per_l3,
	};
	}
	for (uint32_t t = 0; t < mach_topology.threads; t++) {
	processors[t].cache.l3 = &l3[0];
	}
	}

	/* Commit changes */
	cpuinfo_cache[cpuinfo_cache_level_1i] = l1i;
	cpuinfo_cache[cpuinfo_cache_level_1d] = l1d;
	cpuinfo_cache[cpuinfo_cache_level_2] = l2;
	cpuinfo_cache[cpuinfo_cache_level_3] = l3;

	cpuinfo_processors = processors;
	cpuinfo_cores = cores;
	cpuinfo_clusters = clusters;
	cpuinfo_packages = packages;

	cpuinfo_cache_count[cpuinfo_cache_level_1i] = l1_count;
	cpuinfo_cache_count[cpuinfo_cache_level_1d] = l1_count;
	cpuinfo_cache_count[cpuinfo_cache_level_2] = l2_count;
	cpuinfo_cache_count[cpuinfo_cache_level_3] = l3_count;

	cpuinfo_processors_count = mach_topology.threads;
	cpuinfo_cores_count = mach_topology.cores;
	cpuinfo_clusters_count = num_clusters;
	cpuinfo_packages_count = mach_topology.packages;

	cpuinfo_max_cache_size = cpuinfo_compute_max_cache_size(&processors[0]);

	__sync_synchronize();

	cpuinfo_is_initialized = true;

	processors = NULL;
	cores = NULL;
	clusters = NULL;
	packages = NULL;
	l1i = l1d = l2 = l3 = NULL;

	cleanup:
	free(processors);
	free(cores);
	free(clusters);
	free(packages);
	free(l1i);
	free(l1d);
	free(l2);
	free(l3);
	}