[v1.05][X86] Fix for Meteor Lake (#255 )

[v1.05][X86] Experimental new implementation of abbreviate_intel_cpu_name
[v1.05][X86] Add preeliminary support for Meteor Lake (#255 )
2026-03-25 16:00:39 +01:00 · 2024-07-30 08:52:22 +01:00 · 2024-07-29 08:53:01 +01:00 · 2024-07-28 22:53:17 +01:00 · 2024-07-25 08:29:05 +01:00 · 2024-07-25 08:23:56 +01:00
37 changed files with 1865 additions and 578 deletions
--- a/17
+++ b/17
@@ -13,12 +13,18 @@ COMMON_HDR = $(SRC_COMMON)ascii.h $(SRC_COMMON)cpu.h $(SRC_COMMON)udev.h $(SRC_C
 ifneq ($(OS),Windows_NT)
 	GIT_VERSION := "$(shell git describe --abbrev=4 --dirty --always --tags)"
 	arch := $(shell uname -m)
 	os := $(shell uname -s)
 	ifeq ($(os), Linux)
 		COMMON_SRC += $(SRC_COMMON)freq.c
 		COMMON_HDR += $(SRC_COMMON)freq.h
 	endif
 	ifeq ($(arch), $(filter $(arch), x86_64 amd64 i386 i486 i586 i686))
 		SRC_DIR=src/x86/
 		SOURCE += $(COMMON_SRC) $(SRC_DIR)cpuid.c $(SRC_DIR)apic.c $(SRC_DIR)cpuid_asm.c $(SRC_DIR)uarch.c
 		HEADERS += $(COMMON_HDR) $(SRC_DIR)cpuid.h $(SRC_DIR)apic.h $(SRC_DIR)cpuid_asm.h $(SRC_DIR)uarch.h $(SRC_DIR)freq/freq.h
                os := $(shell uname -s)
 		ifeq ($(os), Linux)
 			SOURCE += $(SRC_DIR)freq/freq.c freq_nov.o freq_avx.o freq_avx512.o
 			HEADERS += $(SRC_DIR)freq/freq.h
@@ -32,14 +38,13 @@ ifneq ($(OS),Windows_NT)
 		CFLAGS += -DARCH_PPC -std=gnu99 -fstack-protector-all -Wno-language-extension-token
 	else ifeq ($(arch), $(filter $(arch), arm aarch64_be aarch64 arm64 armv8b armv8l armv7l armv6l))
 		SRC_DIR=src/arm/
-		SOURCE += $(COMMON_SRC) $(SRC_DIR)midr.c $(SRC_DIR)uarch.c $(SRC_COMMON)soc.c $(SRC_DIR)soc.c $(SRC_DIR)udev.c
+		SOURCE += $(COMMON_SRC) $(SRC_DIR)midr.c $(SRC_DIR)uarch.c $(SRC_COMMON)soc.c $(SRC_DIR)soc.c $(SRC_COMMON)pci.c $(SRC_DIR)udev.c
-		HEADERS += $(COMMON_HDR) $(SRC_DIR)midr.h $(SRC_DIR)uarch.h  $(SRC_COMMON)soc.h $(SRC_DIR)soc.h $(SRC_DIR)udev.c $(SRC_DIR)socs.h
+		HEADERS += $(COMMON_HDR) $(SRC_DIR)midr.h $(SRC_DIR)uarch.h  $(SRC_COMMON)soc.h $(SRC_DIR)soc.h $(SRC_COMMON)pci.h $(SRC_DIR)udev.c $(SRC_DIR)socs.h
 		CFLAGS += -DARCH_ARM -Wno-unused-parameter -std=c99 -fstack-protector-all
 		os := $(shell uname -s)
 		ifeq ($(os), Darwin)
-			SOURCE += $(SRC_DIR)sysctl.c
+			SOURCE += $(SRC_COMMON)sysctl.c
-			HEADERS += $(SRC_DIR)sysctl.h
+			HEADERS += $(SRC_COMMON)sysctl.h
 		endif
 	else ifeq ($(arch), $(filter $(arch), riscv64 riscv32))
 		SRC_DIR=src/riscv/
--- a/README.md
+++ b/README.md
@@ -50,6 +50,8 @@ cpufetch is a command-line tool written in C that displays the CPU information i
  - [4.2 Specifying the colors in RGB format](#42-specifying-the-colors-in-rgb-format)
 - [5. Implementation](#5-implementation)
 - [6. Bugs or improvements](#6-bugs-or-improvements)
  - [6.1 Unknown microarchitecture error](#61-unknown-microarchitecture-error)
  - [6.2 Other situations](#62-other-situations)
 - [7. Acknowledgements](#7-acknowledgements)
 - [8. cpufetch for GPUs (gpufetch)](#8-cpufetch-for-gpus-gpufetch)
@@ -147,6 +149,21 @@ By default, `cpufetch` will print the CPU logo with the system colorscheme. Howe
 See [cpufetch programming documentation](https://github.com/Dr-Noob/cpufetch/tree/master/doc).
 ## 6. Bugs or improvements
 ### 6.1 Unknown microarchitecture error
 If you get the `Unknown microarchitecture detected` error when running cpufetch, it might be caused by two possible reasons:
 1. You are running an old release of cpufetch (most likely)
 2. Your microarchitecture is not yet supported
 Download and compile the latest version (see https://github.com/Dr-Noob/cpufetch#22-building-from-source for instructions)
 and verify if the error persists.
 * __If the error dissapears__: It means that this is the first situation. In this case, just use the
 latest version of cpufetch which already has support for your hardware.
 * __If the error does not dissapear__: It means that this is the
 second situation. In this case, please create a new issue with the error message and the output of 'cpufetch --debug' on https://github.com/Dr-Noob/cpufetch/issues
 ### 6.2 Other situations
 See [cpufetch contributing guidelines](https://github.com/Dr-Noob/cpufetch/blob/master/CONTRIBUTING.md).
 ## 7. Acknowledgements
@@ -157,6 +174,8 @@ Thanks to the fellow contributors and interested people in the project. Special
 - [bbonev](https://github.com/bbonev) and [stephan-cr](https://github.com/stephan-cr): Reviewed the source code.
 - [mdoksa76](https://github.com/mdoksa76) and [exkc](https://github.com/exkc): Excellent ideas and feedback for supporting Allwinner SoCs.
 - [Sakura286](https://github.com/Sakura286), [exkc](https://github.com/exkc) and [Patola](https://github.com/Patola): Helped with RISC-V port with ssh access, ideas, testing, etc.
 - [ThomasKaiser](https://github.com/ThomasKaiser): Very valuable feedback on improving ARM SoC detection (Apple, Allwinner, Rockchip).
 - [zerkerX](https://github.com/zerkerX): Helped with feedback for supporting old (e.g., Pentium III) Intel CPUs.
 ## 8. cpufetch for GPUs (gpufetch)
 See [gpufetch](https://github.com/Dr-Noob/gpufetch) project!
--- a/src/arm/midr.c
+++ b/src/arm/midr.c
@@ -8,12 +8,14 @@
 #ifdef __linux__
  #include <sys/auxv.h>
  #include <asm/hwcap.h>
  #include "../common/freq.h"
 #elif defined __APPLE__ || __MACH__
-  #include "sysctl.h"
+  #include "../common/sysctl.h"
 #endif
 #include "../common/global.h"
 #include "../common/soc.h"
 #include "../common/args.h"
 #include "udev.h"
 #include "midr.h"
 #include "uarch.h"
@@ -39,8 +41,17 @@ struct cache* get_cache_info(struct cpuInfo* cpu) {
 struct frequency* get_frequency_info(uint32_t core) {
  struct frequency* freq = emalloc(sizeof(struct frequency));
  freq->measured = false;
  freq->base = UNKNOWN_DATA;
  freq->max = get_max_freq_from_file(core);
  #ifdef __linux__
    if (freq->max == UNKNOWN_DATA || measure_max_frequency_flag()) {
      if (freq->max == UNKNOWN_DATA)
        printWarn("Unable to find max frequency from udev, measuring CPU frequency");
      freq->max = measure_max_frequency(core);
      freq->measured = true;
    }
  #endif
  return freq;
 }
@@ -237,7 +248,7 @@ struct cpuInfo* get_cpu_info_linux(struct cpuInfo* cpu) {
  cpu->num_cpus = sockets;
  cpu->hv = emalloc(sizeof(struct hypervisor));
  cpu->hv->present = false;
-  cpu->soc = get_soc();
+  cpu->soc = get_soc(cpu);
  cpu->peak_performance = get_peak_performance(cpu);
  return cpu;
@@ -289,7 +300,7 @@ void fill_cpu_info_avalanche_blizzard(struct cpuInfo* cpu, uint32_t pcores, uint
  bli->feat = get_features_info();
  bli->topo = malloc(sizeof(struct topology));
  bli->topo->cach = bli->cach;
-  bli->topo->total_cores = pcores;
+  bli->topo->total_cores = ecores;
  bli->freq = malloc(sizeof(struct frequency));
  bli->freq->base = UNKNOWN_DATA;
  bli->freq->max = 2800;
@@ -305,7 +316,7 @@ void fill_cpu_info_avalanche_blizzard(struct cpuInfo* cpu, uint32_t pcores, uint
  ava->feat = get_features_info();
  ava->topo = malloc(sizeof(struct topology));
  ava->topo->cach = ava->cach;
-  ava->topo->total_cores = ecores;
+  ava->topo->total_cores = pcores;
  ava->freq = malloc(sizeof(struct frequency));
  ava->freq->base = UNKNOWN_DATA;
  ava->freq->max = 3500;
@@ -314,75 +325,83 @@ void fill_cpu_info_avalanche_blizzard(struct cpuInfo* cpu, uint32_t pcores, uint
  ava->next_cpu = NULL;
 }
-struct cpuInfo* get_cpu_info_mach(struct cpuInfo* cpu) {
+void fill_cpu_info_everest_sawtooth(struct cpuInfo* cpu, uint32_t pcores, uint32_t ecores) {
-  uint32_t cpu_family = get_sys_info_by_name("hw.cpufamily");
+  // 1. Fill SAWTOOTH
  struct cpuInfo* saw = cpu;
  saw->midr = MIDR_APPLE_M3_SAWTOOTH;
  saw->arch = get_uarch_from_midr(saw->midr, saw);
  saw->cach = get_cache_info(saw);
  saw->feat = get_features_info();
  saw->topo = malloc(sizeof(struct topology));
  saw->topo->cach = saw->cach;
  saw->topo->total_cores = ecores;
  saw->freq = malloc(sizeof(struct frequency));
  saw->freq->base = UNKNOWN_DATA;
  saw->freq->max = 2750;
  saw->hv = malloc(sizeof(struct hypervisor));
  saw->hv->present = false;
  saw->next_cpu = malloc(sizeof(struct cpuInfo));
  // 2. Fill EVEREST
  struct cpuInfo* eve = saw->next_cpu;
  eve->midr = MIDR_APPLE_M3_EVEREST;
  eve->arch = get_uarch_from_midr(eve->midr, eve);
  eve->cach = get_cache_info(eve);
  eve->feat = get_features_info();
  eve->topo = malloc(sizeof(struct topology));
  eve->topo->cach = eve->cach;
  eve->topo->total_cores = pcores;
  eve->freq = malloc(sizeof(struct frequency));
  eve->freq->base = UNKNOWN_DATA;
  eve->freq->max = 4050;
  eve->hv = malloc(sizeof(struct hypervisor));
  eve->hv->present = false;
  eve->next_cpu = NULL;
 }
 struct cpuInfo* get_cpu_info_mach(struct cpuInfo* cpu) {
  // https://developer.apple.com/documentation/kernel/1387446-sysctlbyname/determining_system_capabilities
  uint32_t nperflevels = get_sys_info_by_name("hw.nperflevels");
  if((cpu->num_cpus = nperflevels) != 2) {
    printBug("Expected to find SoC with 2 perf levels, found: %d", cpu->num_cpus);
    return NULL;
  }
  uint32_t pcores = get_sys_info_by_name("hw.perflevel0.physicalcpu");
  uint32_t ecores = get_sys_info_by_name("hw.perflevel1.physicalcpu");
  if(ecores <= 0) {
    printBug("Expected to find a numer of ecores > 0, found: %d", ecores);
    return NULL;
  }
  if(pcores <= 0) {
    printBug("Expected to find a numer of pcores > 0, found: %d", pcores);
    return NULL;
  }
  uint32_t cpu_family = get_sys_info_by_name("hw.cpufamily");
  // Manually fill the cpuInfo assuming that
-  // the CPU is an Apple M1/M2
+  // the CPU is an Apple SoC
  if(cpu_family == CPUFAMILY_ARM_FIRESTORM_ICESTORM) {
-    cpu->num_cpus = 2;
+    fill_cpu_info_firestorm_icestorm(cpu, pcores, ecores);
-    // Now detect the M1 version
+    cpu->soc = get_soc(cpu);
    uint32_t cpu_subfamily = get_sys_info_by_name("hw.cpusubfamily");
    if(cpu_subfamily == CPUSUBFAMILY_ARM_HG) {
      // Apple M1
      fill_cpu_info_firestorm_icestorm(cpu, 4, 4);
    }
    else if(cpu_subfamily == CPUSUBFAMILY_ARM_HS || cpu_subfamily == CPUSUBFAMILY_ARM_HC_HD) {
      // Apple M1 Pro/Max/Ultra. Detect number of cores
      uint32_t physicalcpu = get_sys_info_by_name("hw.physicalcpu");
      if(physicalcpu == 20) {
        // M1 Ultra
        fill_cpu_info_firestorm_icestorm(cpu, 16, 4);
      }
      else if(physicalcpu == 8 || physicalcpu == 10) {
        // M1 Pro/Max
        fill_cpu_info_firestorm_icestorm(cpu, physicalcpu-2, 2);
      }
      else {
        printBug("Found invalid physical cpu number: %d", physicalcpu);
        return NULL;
      }
    }
    else {
      printBug("Found invalid cpu_subfamily: 0x%.8X", cpu_subfamily);
      return NULL;
    }
    cpu->soc = get_soc();
    cpu->peak_performance = get_peak_performance(cpu);
  }
  else if(cpu_family == CPUFAMILY_ARM_AVALANCHE_BLIZZARD) {
-    cpu->num_cpus = 2;
+    fill_cpu_info_avalanche_blizzard(cpu, pcores, ecores);
-    // Now detect the M2 version
+    cpu->soc = get_soc(cpu);
-    uint32_t cpu_subfamily = get_sys_info_by_name("hw.cpusubfamily");
+    cpu->peak_performance = get_peak_performance(cpu);
    if(cpu_subfamily == CPUSUBFAMILY_ARM_HG) {
      // Apple M2
      fill_cpu_info_avalanche_blizzard(cpu, 4, 4);
  }
-    else if(cpu_subfamily == CPUSUBFAMILY_ARM_HS) {
+  else if(cpu_family == CPUFAMILY_ARM_EVEREST_SAWTOOTH ||
-      // Apple M2 Pro/Max/Ultra. Detect number of cores
+          cpu_family == CPUFAMILY_ARM_EVEREST_SAWTOOTH_PRO ||
-      uint32_t physicalcpu = get_sys_info_by_name("hw.physicalcpu");
+          cpu_family == CPUFAMILY_ARM_EVEREST_SAWTOOTH_MAX) {
-      if(physicalcpu == 24) {
+    fill_cpu_info_everest_sawtooth(cpu, pcores, ecores);
-        // M2 Ultra
+    cpu->soc = get_soc(cpu);
        fill_cpu_info_avalanche_blizzard(cpu, 16, 8);
      }
      else if(physicalcpu == 10 || physicalcpu == 12) {
        // M2 Pro/Max
        fill_cpu_info_avalanche_blizzard(cpu, physicalcpu-4, 4);
      }
      else {
        printBug("Found invalid physical cpu number: %d", physicalcpu);
        return NULL;
      }
    }
    else {
      printBug("Found invalid cpu_subfamily: 0x%.8X", cpu_subfamily);
      return NULL;
    }
    cpu->soc = get_soc();
    cpu->peak_performance = get_peak_performance(cpu);
  }
  else {
-    printBug("Found invalid cpu_family: 0x%.8X", cpu_family);
+    printBugCheckRelease("Found invalid cpu_family: 0x%.8X", cpu_family);
    return NULL;
  }
@@ -467,6 +486,15 @@ void print_debug(struct cpuInfo* cpu) {
      printf("%ld MHz\n", freq);
    }
  }
  #if defined(__APPLE__) || defined(__MACH__)
    printf("hw.cpufamily: 0x%.8X\n", get_sys_info_by_name("hw.cpufamily"));
    printf("hw.cpusubfamily: 0x%.8X\n", get_sys_info_by_name("hw.cpusubfamily"));
    printf("hw.nperflevels: %d\n", get_sys_info_by_name("hw.nperflevels"));
    printf("hw.physicalcpu: %d\n", get_sys_info_by_name("hw.physicalcpu"));
    printf("hw.perflevel0.physicalcpu: %d\n", get_sys_info_by_name("hw.perflevel0.physicalcpu"));
    printf("hw.perflevel1.physicalcpu: %d\n", get_sys_info_by_name("hw.perflevel1.physicalcpu"));
  #endif
 }
 void free_topo_struct(struct topology* topo) {
--- a/src/arm/soc.c
+++ b/src/arm/soc.c
@@ -6,12 +6,15 @@
 #include "soc.h"
 #include "socs.h"
 #include "udev.h"
 #include "uarch.h"
 #include "../common/global.h"
 #include "../common/pci.h"
 #if defined(__APPLE__) || defined(__MACH__)
-  #include "sysctl.h"
+  #include "../common/sysctl.h"
 #endif
 #define NA -1
 #define min(a,b) (((a)<(b))?(a):(b))
 #define ARRAY_SIZE(arr)     (sizeof(arr) / sizeof((arr)[0]))
@@ -49,6 +52,8 @@ uint32_t get_sid_from_nvmem(char* buf) {
 // SIDs list:
 // - https://linux-sunxi.org/SID_Register_Guide#Currently_known_SID.27s
 // - https://github.com/Dr-Noob/cpufetch/issues/173
 // - https://github.com/ThomasKaiser/sbc-bench/blob/master/sbc-bench.sh
 // - https://linux-sunxi.org/*CHIP_NAME*
 bool get_sunxisoc_from_sid(struct system_on_chip* soc, char* raw_name, uint32_t sid) {
  typedef struct {
    uint32_t sid;
@@ -57,21 +62,39 @@ bool get_sunxisoc_from_sid(struct system_on_chip* soc, char* raw_name, uint32_t
  sidToSoC socFromSid[] = {
    // --- sun8i Family ---
    // A33
    {0x0461872a, {SOC_ALLWINNER_A33,    SOC_VENDOR_ALLWINNER, 40, "A33",  raw_name} },
    // A83T
    {0x32c00401, {SOC_ALLWINNER_A83T,   SOC_VENDOR_ALLWINNER, 28, "A83T", raw_name} },
    {0x32c00403, {SOC_ALLWINNER_A83T,   SOC_VENDOR_ALLWINNER, 28, "A83T", raw_name} },
    // S3
    {0x12c00001, {SOC_ALLWINNER_S3,     SOC_VENDOR_ALLWINNER, 40, "S3",   raw_name} },
    // H2+
    {0x02c00042, {SOC_ALLWINNER_H2PLUS, SOC_VENDOR_ALLWINNER, 40, "H2+",  raw_name} },
    {0x02c00142, {SOC_ALLWINNER_H2PLUS, SOC_VENDOR_ALLWINNER, 40, "H2+",  raw_name} },
    {0x02c00242, {SOC_ALLWINNER_H2PLUS, SOC_VENDOR_ALLWINNER, 40, "H2+",  raw_name} },
    // H3
    {0x02c00181, {SOC_ALLWINNER_H3,     SOC_VENDOR_ALLWINNER, 40, "H3",   raw_name} },
    {0x02c00081, {SOC_ALLWINNER_H3,     SOC_VENDOR_ALLWINNER, 40, "H3",   raw_name} },
-    // Others
+    // R40
    {0x12c00017, {SOC_ALLWINNER_R40,    SOC_VENDOR_ALLWINNER, 40, "R40",  raw_name} },
    // V3S
    {0x12c00000, {SOC_ALLWINNER_V3S,    SOC_VENDOR_ALLWINNER, 40, "V3s",  raw_name} }, // 40nm is only my guess, no source
    // --- sun50i Family ---
    // H5
    {0x82800001, {SOC_ALLWINNER_H5,     SOC_VENDOR_ALLWINNER, 40, "H5",   raw_name} },
    // H6
    {0x82c00001, {SOC_ALLWINNER_H6,     SOC_VENDOR_ALLWINNER, 28, "H6",   raw_name} },
    {0x82c00007, {SOC_ALLWINNER_H6,     SOC_VENDOR_ALLWINNER, 28, "H6",   raw_name} },
-    {0x92c000bb, {SOC_ALLWINNER_H64,    SOC_VENDOR_ALLWINNER, 40, "H64",  raw_name} }, // Same as A64
+    // H64
    {0x92c000bb, {SOC_ALLWINNER_H64,    SOC_VENDOR_ALLWINNER, 40, "H64",  raw_name} }, // Same manufacturing process as A64
    // H616
    {0x32c05000, {SOC_ALLWINNER_H616,   SOC_VENDOR_ALLWINNER, 28, "H616", raw_name} },
    // H618
    {0x33802000, {SOC_ALLWINNER_H618,   SOC_VENDOR_ALLWINNER, 28, "H618", raw_name} },
    // A64
    {0x92c000ba, {SOC_ALLWINNER_A64,    SOC_VENDOR_ALLWINNER, 40, "A64",  raw_name} },
    {0x92c001ba, {SOC_ALLWINNER_A64,    SOC_VENDOR_ALLWINNER, 40, "A64",  raw_name} },
    // Unknown
    {0x00000000, {UNKNOWN,              SOC_VENDOR_UNKNOWN,   -1, "",     raw_name} }
  };
@@ -126,6 +149,22 @@ bool match_broadcom(char* soc_name, struct system_on_chip* soc) {
  SOC_END
 }
 // https://en.wikipedia.org/wiki/Google_Tensor
 bool match_google(char* soc_name, struct system_on_chip* soc) {
  char* tmp;
  if((tmp = strstr(soc_name, "gs")) == NULL)
    return false;
  soc->soc_vendor = SOC_VENDOR_GOOGLE;
  SOC_START
  SOC_EQ(tmp, "gs101", "Tensor",    SOC_GOOGLE_TENSOR,    soc, 5)
  SOC_EQ(tmp, "gs201", "Tensor G2", SOC_GOOGLE_TENSOR_G2, soc, 5)
  SOC_EQ(tmp, "gs301", "Tensor G3", SOC_GOOGLE_TENSOR_G3, soc, 4)
  SOC_END
 }
 // https://www.techinsights.com/
 // https://datasheetspdf.com/pdf-file/1316605/HiSilicon/Hi3660/1
 bool match_hisilicon(char* soc_name, struct system_on_chip* soc) {
@@ -224,6 +263,10 @@ bool match_exynos(char* soc_name, struct system_on_chip* soc) {
  SOC_END
 }
 // https://www.phonemore.com/processors/mediatek/
 // https://phonedb.net/
 // https://en.wikipedia.org/wiki/List_of_MediaTek_systems_on_chips
 // https://wikimovel.com/index.php/MediaTek
 bool match_mediatek(char* soc_name, struct system_on_chip* soc) {
  char* tmp;
  char* soc_name_upper = toupperstr(soc_name);
@@ -235,25 +278,38 @@ bool match_mediatek(char* soc_name, struct system_on_chip* soc) {
  SOC_START
  // Dimensity //
  SOC_EQ(tmp, "MT6893Z",  "Dimensity 1300",  SOC_MTK_MT6893Z,  soc, 6)
  SOC_EQ(tmp, "MT6893",   "Dimensity 1200",  SOC_MTK_MT6893,   soc, 6)
  SOC_EQ(tmp, "MT6891",   "Dimensity 1100",  SOC_MTK_MT6891,   soc, 6)
  //SOC_EQ(tmp, "MT6877V",  "Dimensity 1080",  SOC_MTK_MT6877V   soc, 7) // There is a clash between this and another chip
  SOC_EQ(tmp, "MT6879",   "Dimensity 1050",  SOC_MTK_MT6879,   soc, 6)
  SOC_EQ(tmp, "MT6889",   "Dimensity 1000",  SOC_MTK_MT6889,   soc, 7)
  SOC_EQ(tmp, "MT6885Z",  "Dimensity 1000L", SOC_MTK_MT6885Z,  soc, 7)
-  //SOC_EQ(tmp, "?",      "Dimensity 700",   SOC_MTK_,         soc, 7)
+  SOC_EQ(tmp, "MT6889Z",  "Dimensity 1000+", SOC_MTK_MT6889Z,  soc, 7)
  SOC_EQ(tmp, "MT6883Z",  "Dimensity 1000C", SOC_MTK_MT6883Z,  soc, 7)
  SOC_EQ(tmp, "MT6833",   "Dimensity 700",   SOC_MTK_MT6833,   soc, 7)
  SOC_EQ(tmp, "MT6853",   "Dimensity 720",   SOC_MTK_MT6853,   soc, 7)
  SOC_EQ(tmp, "MT6873",   "Dimensity 800",   SOC_MTK_MT6873,   soc, 7)
  SOC_EQ(tmp, "MT6853V",  "Dimensity 800U",  SOC_MTK_MT6853V,  soc, 7)
  SOC_EQ(tmp, "MT6833",   "Dimensity 810",   SOC_MTK_MT6833,   soc, 6)
  SOC_EQ(tmp, "MT6875",   "Dimensity 820",   SOC_MTK_MT6875,   soc, 7)
  // Helio //
  SOC_EQ(tmp, "MT6761D",  "Helio A20",       SOC_MTK_MT6761D,  soc, 12)
  SOC_EQ(tmp, "MT6761",   "Helio A22",       SOC_MTK_MT6761,   soc, 12)
  SOC_EQ(tmp, "MT6762D",  "Helio A25",       SOC_MTK_MT6762D,  soc, 12)
-  //SOC_EQ(tmp, "?",      "Helio G25",       SOC_MTK_,         soc, 12)
+  SOC_EQ(tmp, "MT6762G",  "Helio G25",       SOC_MTK_MT6762G,  soc, 12)
-  //SOC_EQ(tmp, "?",      "Helio G35",       SOC_MTK_,         soc, 12)
+  SOC_EQ(tmp, "MT6765G",  "Helio G35",       SOC_MTK_MT6765G,  soc, 12)
-  //SOC_EQ(tmp, "?",      "Helio G70",       SOC_MTK_,         soc, 12)
+  //SOC_EQ(tmp, "???",    "Helio G36",       SOC_MTK_MT6765G,  soc,  ?)
-  //SOC_EQ(tmp, "?",      "Helio G80",       SOC_MTK_,         soc, 12)
+  SOC_EQ(tmp, "MT6765H",  "Helio G37",       SOC_MTK_MT6765H,  soc, 12)
-  //SOC_EQ(tmp, "?",      "Helio G90",       SOC_MTK_,         soc, 12)
+  SOC_EQ(tmp, "MT6769V",  "Helio G70",       SOC_MTK_MT6769V,  soc, 12)
-  //SOC_EQ(tmp, "?",      "Helio G90T",      SOC_MTK_,         soc, 12)
+  SOC_EQ(tmp, "MT6769T",  "Helio G80",       SOC_MTK_MT6769T,  soc, 12)
-  //SOC_EQ(tmp, "?",      "Helio G95",       SOC_MTK_,         soc, 12)
+  SOC_EQ(tmp, "MT6769Z",  "Helio G85",       SOC_MTK_MT6769Z,  soc, 12)
  SOC_EQ(tmp, "MT6769H",  "Helio G88",       SOC_MTK_MT6769H,  soc, 12)
  //SOC_EQ(tmp, "MT6785V/CD", "Helio G90",   SOC_MTK_MT6785V_CD, soc, 12) // How to distingish between this and G95?
  SOC_EQ(tmp, "MT6785V/CC", "Helio G90T",    SOC_MTK_MT6785V_CC, soc, 12)
  SOC_EQ(tmp, "MT6785V/CD", "Helio G95",     SOC_MTK_MT6785V_CD, soc, 12)
  SOC_EQ(tmp, "MT6789",   "Helio G99",       SOC_MTK_MT6789,   soc,  6)
  SOC_EQ(tmp, "MT8781V",  "Helio G99",       SOC_MTK_MT8781V,  soc,  6) // Same as MT6789
  SOC_EQ(tmp, "MT6755",   "Helio P10",       SOC_MTK_MT6755M,  soc, 28)
  SOC_EQ(tmp, "MT6755M",  "Helio P10 M",     SOC_MTK_MT6755M,  soc, 28)
  SOC_EQ(tmp, "MT6755T",  "Helio P15",       SOC_MTK_MT6755T,  soc, 28)
@@ -268,8 +324,8 @@ bool match_mediatek(char* soc_name, struct system_on_chip* soc) {
  SOC_EQ(tmp, "MT6768",   "Helio P65",       SOC_MTK_MT6768,   soc, 12)
  SOC_EQ(tmp, "MT6771T",  "Helio P70",       SOC_MTK_MT6771,   soc, 12)
  SOC_EQ(tmp, "MT6771V",  "Helio P70",       SOC_MTK_MT6771,   soc, 12)
-  SOC_EQ(tmp, "MT6779",   "Helio P90",       SOC_MTK_MT6779,   soc, 12)
+  SOC_EQ(tmp, "MT6779V/CU", "Helio P90",     SOC_MTK_MT6779V_CU, soc, 12)
-  //SOC_EQ(tmp, "?",      "Helio P95",       SOC_MTK_,         soc, 12)
+  SOC_EQ(tmp, "MT6779V/CV", "Helio P95",     SOC_MTK_MT6779V_CV, soc, 12)
  SOC_EQ(tmp, "MT6795",   "Helio X10",       SOC_MTK_MT6795,   soc, 28)
  SOC_EQ(tmp, "MT6795T",  "Helio X10 T",     SOC_MTK_MT6795,   soc, 28)
  SOC_EQ(tmp, "MT6797",   "Helio X20",       SOC_MTK_MT6797,   soc, 20)
@@ -278,7 +334,31 @@ bool match_mediatek(char* soc_name, struct system_on_chip* soc) {
  SOC_EQ(tmp, "MT6797T",  "Helio X25",       SOC_MTK_MT6797T,  soc, 20)
  SOC_EQ(tmp, "MT6797X",  "Helio X27",       SOC_MTK_MT6797X,  soc, 20)
  SOC_EQ(tmp, "MT6799",   "Helio X30",       SOC_MTK_MT6799,   soc, 10)
  // Pentonic
  SOC_EQ(tmp, "MT9618",   "Pentonic  700",   SOC_MTK_MT9618,   soc,  7)
  SOC_EQ(tmp, "MT9653",   "Pentonic  700",   SOC_MTK_MT9653,   soc,  7)
  SOC_EQ(tmp, "MT9689",   "Pentonic  700",   SOC_MTK_MT9689,   soc,  7) // !! Assumption only, needs confirmation
  SOC_EQ(tmp, "MT9972",   "Pentonic 1000",   SOC_MTK_MT9972,   soc,  7) // !! Assumption only, needs confirmation
  SOC_EQ(tmp, "MT9902",   "Pentonic 2000",   SOC_MTK_MT9902,   soc,  7)
  SOC_EQ(tmp, "MT9982",   "Pentonic 2000",   SOC_MTK_MT9982,   soc,  7)
  // MT XXXX //
  SOC_EQ(tmp, "MT5327",   "MT5327",          SOC_MTK_MT5327,   soc, NA)
  SOC_EQ(tmp, "MT5329",   "MT5329",          SOC_MTK_MT5329,   soc, NA)
  SOC_EQ(tmp, "MT5366",   "MT5366",          SOC_MTK_MT5366,   soc, NA)
  SOC_EQ(tmp, "MT5389",   "MT5389",          SOC_MTK_MT5389,   soc, NA)
  SOC_EQ(tmp, "MT5395",   "MT5395",          SOC_MTK_MT5395,   soc, NA)
  SOC_EQ(tmp, "MT5396",   "MT5396",          SOC_MTK_MT5396,   soc, NA)
  SOC_EQ(tmp, "MT5398",   "MT5398",          SOC_MTK_MT5398,   soc, NA)
  SOC_EQ(tmp, "MT5505",   "MT5505",          SOC_MTK_MT5505,   soc, NA)
  SOC_EQ(tmp, "MT5561",   "MT5561",          SOC_MTK_MT5561,   soc, NA)
  SOC_EQ(tmp, "MT5580",   "MT5580",          SOC_MTK_MT5580,   soc, NA)
  SOC_EQ(tmp, "MT5582",   "MT5582",          SOC_MTK_MT5582,   soc, NA)
  SOC_EQ(tmp, "MT5592",   "MT5592",          SOC_MTK_MT5592,   soc, NA)
  SOC_EQ(tmp, "MT5595",   "MT5595",          SOC_MTK_MT5595,   soc, NA)
  SOC_EQ(tmp, "MT5596",   "MT5596",          SOC_MTK_MT5596,   soc, 28) // !! Assumption only, needs confirmation
  SOC_EQ(tmp, "MT5597",   "MT5597",          SOC_MTK_MT5597,   soc, 28) // !! Assumption only, needs confirmation
  SOC_EQ(tmp, "MT5895",   "MT5895",          SOC_MTK_MT5895,   soc, 28) // Same as MT9950*
  SOC_EQ(tmp, "MT5889",   "MT5889",          SOC_MTK_MT5889,   soc, 28) // Same as MT9615 (https://www.displayspecifications.com/en/model/97272c1f)
  SOC_EQ(tmp, "MT6515",   "MT6515",          SOC_MTK_MT6515,   soc, 40)
  SOC_EQ(tmp, "MT6516",   "MT6516",          SOC_MTK_MT6516,   soc, 65)
  SOC_EQ(tmp, "MT6517",   "MT6517",          SOC_MTK_MT6517,   soc, 40)
@@ -324,6 +404,19 @@ bool match_mediatek(char* soc_name, struct system_on_chip* soc) {
  SOC_EQ(tmp, "MT8735",   "MT8735",          SOC_MTK_MT8735,   soc, 28)
  SOC_EQ(tmp, "MT8765B",  "MT8765B",         SOC_MTK_MT8765B,  soc, 28)
  SOC_EQ(tmp, "MT8783",   "MT8783",          SOC_MTK_MT8783,   soc, 28)
  SOC_EQ(tmp, "MT9602",   "MT9602",          SOC_MTK_MT9602,   soc, 28) // Same as MT9675*
  SOC_EQ(tmp, "MT9612",   "MT9612",          SOC_MTK_MT9612,   soc, 28) // Same as MT9685*
  SOC_EQ(tmp, "MT9613",   "MT9613",          SOC_MTK_MT9613,   soc, 28) // !! Assumption only, needs confirmation
  SOC_EQ(tmp, "MT9615",   "MT9615",          SOC_MTK_MT9615,   soc, 28) // https://gadgetversus.com/processor/mediatek-mt9615-specs/
  SOC_EQ(tmp, "MT9632",   "MT9632",          SOC_MTK_MT9632,   soc, 28) // Same as MT9675*
  SOC_EQ(tmp, "MT9638",   "MT9638",          SOC_MTK_MT9638,   soc, 28) // !! Assumption only, needs confirmation
  SOC_EQ(tmp, "MT9652",   "MT9652",          SOC_MTK_MT9652,   soc, 28) // Same as MT9613*
  SOC_EQ(tmp, "MT9675",   "MT9675",          SOC_MTK_MT9675,   soc, 28) // !! Assumption only, needs confirmation
  SOC_EQ(tmp, "MT9685",   "MT9685",          SOC_MTK_MT9685,   soc, 28) // https://gadgetversus.com/processor/mediatek-mt9685-specs/
  SOC_EQ(tmp, "MT9950",   "MT9950",          SOC_MTK_MT9950,   soc, 28) // https://gadgetversus.com/processor/mediatek-mt9950-specs/
  SOC_EQ(tmp, "MT9686",   "MT9686",          SOC_MTK_MT9686,   soc, 28) // Same as MT9613*
  // (*) Many SoCs are reported with different names but they are the same chip.
  // Source: https://en.wikipedia.org/wiki/List_of_MediaTek_systems_on_chips#Digital_television_SoCs
  SOC_END
 }
@@ -485,6 +578,14 @@ bool match_qualcomm(char* soc_name, struct system_on_chip* soc) {
  SOC_EQ(tmp, "SM8250-AB",      "865+",      SOC_SNAPD_SM8250_AB,      soc,  7)
  SOC_EQ(tmp, "SM8350",         "888",       SOC_SNAPD_SM8350,         soc,  5)
  SOC_EQ(tmp, "SM8350-AC",      "888+",      SOC_SNAPD_SM8350,         soc,  5)
  // Snapdragon Gen //
  SOC_EQ(tmp, "SM4450",         "4 Gen 2",   SOC_SNAPD_SM4450,         soc,  4)
  SOC_EQ(tmp, "SM6450",         "6 Gen 1",   SOC_SNAPD_SM6450,         soc,  4)
  SOC_EQ(tmp, "SM7435-AB",      "7s Gen 2",  SOC_SNAPD_SM7435_AB,      soc,  4)
  SOC_EQ(tmp, "SM7450",         "7 Gen 1",   SOC_SNAPD_SM7450,         soc,  4)
  SOC_EQ(tmp, "SM7475",         "7+ Gen 2",  SOC_SNAPD_SM7475,         soc,  4)
  SOC_EQ(tmp, "SM8450",         "8 Gen 1",   SOC_SNAPD_SM8450,         soc,  4)
  SOC_EQ(tmp, "SM8475",         "8+ Gen 1",  SOC_SNAPD_SM8475,         soc,  4)
  SOC_END
 }
@@ -531,12 +632,52 @@ bool match_special(char* soc_name, struct system_on_chip* soc) {
    return true;
  }
-  // Snapdragon 8 Gen 1 reported as "taro"
+  // New Snapdragon SoCs codenames
  // https://github.com/sm8450-mainline/fdt?tab=readme-ov-file#chipsets
  // https://github.com/Dr-Noob/cpufetch/issues/253
  if (strcmp(soc_name, "cape") == 0) {
    fill_soc(soc, "8+ Gen 1", SOC_SNAPD_SM8475, 4);
    return true;
  }
  if(strcmp(soc_name, "taro") == 0) {
    fill_soc(soc, "8 Gen 1", SOC_SNAPD_SM8450, 4);
    return true;
  }
  if(strcmp(soc_name, "ukee") == 0) {
    fill_soc(soc, "7+ Gen 2", SOC_SNAPD_SM7475, 4);
    return true;
  }
  if(strcmp(soc_name, "diwali") == 0) {
    fill_soc(soc, "7 Gen 1", SOC_SNAPD_SM7450, 4);
    return true;
  }
  // parrot can be either SM7435 or SM6450, we need more data
  // to distingish between those two
  if(strcmp(soc_name, "ravelin") == 0) {
    fill_soc(soc, "4 Gen 2", SOC_SNAPD_SM4450, 4);
    return true;
  }
  // Google Pixel 6
  // https://github.com/Dr-Noob/cpufetch/issues/134
  if(strcmp(soc_name, "oriole") == 0) {
    fill_soc(soc, "Tensor", SOC_GOOGLE_TENSOR, 5);
    return true;
  }
  // Google Pixel 8
  // https://github.com/Dr-Noob/cpufetch/issues/198
  if(strcmp(soc_name, "husky") == 0 ||
     strcmp(soc_name, "zuma") == 0) {
    fill_soc(soc, "Tensor G3", SOC_GOOGLE_TENSOR_G3, 4);
    return true;
  }
  return false;
 }
@@ -561,6 +702,9 @@ struct system_on_chip* parse_soc_from_string(struct system_on_chip* soc) {
  if(match_allwinner(raw_name, soc))
    return soc;
  if(match_google(raw_name, soc))
    return soc;
  match_broadcom(raw_name, soc);
  return soc;
 }
@@ -591,6 +735,16 @@ struct system_on_chip* guess_soc_from_android(struct system_on_chip* soc) {
    else return soc;
  }
  // https://github.com/Dr-Noob/cpufetch/issues/253
  // ro.soc.model might be more reliable than ro.product.board or
  // ro.board.platform, so try with it first
  property_len = android_property_get("ro.soc.model", (char *) &tmp);
  if(property_len > 0) {
    try_parse_soc_from_string(soc, property_len, tmp);
    if(soc->soc_vendor == SOC_VENDOR_UNKNOWN) printWarn("SoC detection failed using Android property ro.soc.model: %s", tmp);
    else return soc;
  }
  property_len = android_property_get("ro.product.board", (char *) &tmp);
  if(property_len > 0) {
    try_parse_soc_from_string(soc, property_len, tmp);
@@ -645,6 +799,7 @@ bool get_rk_soc_from_efuse(struct system_on_chip* soc, char* efuse) {
  rkToSoC socFromRK[] = {
    // TODO: Add RK2XXX
    // RK3XXX
    // Reverse order
    {0x2388, {SOC_ROCKCHIP_3288,  SOC_VENDOR_ROCKCHIP, 28, "RK3288",  NULL} },
    {0x2392, {SOC_ROCKCHIP_3229,  SOC_VENDOR_ROCKCHIP, 28, "RK3229",  NULL} }, // https://gadgetversus.com/processor/rockchip-rk3229-vs-rockchip-rk3128/
    {0x3380, {SOC_ROCKCHIP_3308,  SOC_VENDOR_ROCKCHIP, 28, "RK3308",  NULL} }, // https://en.t-firefly.com/product/rocrk3308cc?theme=pc
@@ -653,10 +808,12 @@ bool get_rk_soc_from_efuse(struct system_on_chip* soc, char* efuse) {
    {0x3382, {SOC_ROCKCHIP_3328,  SOC_VENDOR_ROCKCHIP, 28, "RK3328",  NULL} },
    {0x3386, {SOC_ROCKCHIP_3368,  SOC_VENDOR_ROCKCHIP, 28, "RK3368",  NULL} },
    {0x3399, {SOC_ROCKCHIP_3399,  SOC_VENDOR_ROCKCHIP, 28, "RK3399",  NULL} },
-    {0x5366, {SOC_ROCKCHIP_3566,  SOC_VENDOR_ROCKCHIP, 22, "RK3566",  NULL} },
+    // Normal Order (https://github.com/Dr-Noob/cpufetch/issues/209)
-    {0x5386, {SOC_ROCKCHIP_3568,  SOC_VENDOR_ROCKCHIP, 22, "RK3568",  NULL} },
+    {0x3528, {SOC_ROCKCHIP_3528,  SOC_VENDOR_ROCKCHIP, 28, "RK3528",  NULL} },
-    {0x5388, {SOC_ROCKCHIP_3588,  SOC_VENDOR_ROCKCHIP,  8, "RK3588",  NULL} },
+    {0x3562, {SOC_ROCKCHIP_3562,  SOC_VENDOR_ROCKCHIP, 22, "RK3562",  NULL} },
-    {0x3588, {SOC_ROCKCHIP_3588S, SOC_VENDOR_ROCKCHIP,  8, "RK3588S", NULL} }, // https://github.com/Dr-Noob/cpufetch/issues/188
+    {0x3566, {SOC_ROCKCHIP_3566,  SOC_VENDOR_ROCKCHIP, 22, "RK3566",  NULL} },
    {0x3568, {SOC_ROCKCHIP_3568,  SOC_VENDOR_ROCKCHIP, 22, "RK3568",  NULL} },
    {0x3588, {SOC_ROCKCHIP_3588,  SOC_VENDOR_ROCKCHIP,  8, "RK3588",  NULL} }, // No known way to distingish between S version: https://github.com/Dr-Noob/cpufetch/issues/188,209
    // Unknown
    {0x0000, {UNKNOWN,            SOC_VENDOR_UNKNOWN,   -1,       "", NULL} }
  };
@@ -689,6 +846,75 @@ struct system_on_chip* guess_soc_from_nvmem(struct system_on_chip* soc) {
  return soc;
 }
 struct system_on_chip* guess_soc_from_uarch(struct system_on_chip* soc, struct cpuInfo* cpu) {
  // Currently we only support CPUs with only one uarch (in other words, one socket)
  struct uarch* arch = cpu->arch;
  if (arch == NULL) {
    printWarn("guess_soc_from_uarch: uarch is NULL");
    return soc;
  }
  typedef struct {
    MICROARCH u;
    struct system_on_chip soc;
  } uarchToSoC;
  uarchToSoC socFromUarch[] = {
    {UARCH_TAISHAN_V110, {SOC_KUNPENG_920,  SOC_VENDOR_KUNPENG,  7, "920", NULL} },
    {UARCH_TAISHAN_V200, {SOC_KUNPENG_930,  SOC_VENDOR_KUNPENG,  7, "930", NULL} }, // manufacturing process is not well-known
    {UARCH_UNKNOWN,      {UNKNOWN,          SOC_VENDOR_UNKNOWN, -1,    "", NULL} }
  };
  int index = 0;
  while(socFromUarch[index].u != UARCH_UNKNOWN) {
    if(socFromUarch[index].u == get_uarch(arch)) {
      fill_soc(soc, socFromUarch[index].soc.soc_name, socFromUarch[index].soc.soc_model, socFromUarch[index].soc.process);
      return soc;
    }
    index++;
  }
  printWarn("guess_soc_from_uarch: No uarch matched the list");
  return soc;
 }
 struct system_on_chip* guess_soc_from_pci(struct system_on_chip* soc, struct cpuInfo* cpu) {
  struct pci_devices * pci = get_pci_devices();
  if (pci == NULL) {
    printWarn("guess_soc_from_pci: Unable to find suitable PCI devices");
    return soc;
  }
  typedef struct {
    uint16_t vendor_id;
    uint16_t device_id;
    struct system_on_chip soc;
  } pciToSoC;
  pciToSoC socFromPCI[] = {
    {PCI_VENDOR_NVIDIA, PCI_DEVICE_TEGRA_X1, {SOC_TEGRA_X1, SOC_VENDOR_NVIDIA,  20, "Tegra X1", NULL} },
    // {PCI_VENDOR_NVIDIA, PCI_DEVICE_GH_200,{SOC_GH_200,   SOC_VENDOR_NVIDIA,  ?, "Grace Hopper", NULL} },
    {0x0000,            0x0000,              {UNKNOWN,      SOC_VENDOR_UNKNOWN, -1,          "", NULL} }
  };
  int index = 0;
  while (socFromPCI[index].vendor_id != 0x0) {
    for (int i=0; i < pci->num_devices; i++) {
      struct pci_device * dev = pci->devices[i];
      if (socFromPCI[index].vendor_id == dev->vendor_id &&
          socFromPCI[index].device_id == dev->device_id) {
        fill_soc(soc, socFromPCI[index].soc.soc_name, socFromPCI[index].soc.soc_model, socFromPCI[index].soc.process);
        return soc;
      }
    }
    index++;
  }
  printWarn("guess_soc_from_pci: No PCI device matched the list");
  return soc;
 }
 int hex2int(char c) {
  if (c >= '0' && c <= '9')
    return c - '0';
@@ -766,7 +992,7 @@ struct system_on_chip* guess_soc_apple(struct system_on_chip* soc) {
      }
    }
    else {
-      printBug("Found invalid cpu_subfamily: 0x%.8X", cpu_subfamily);
+      printBugCheckRelease("Found invalid cpu_subfamily: 0x%.8X", cpu_subfamily);
      soc->soc_vendor = SOC_VENDOR_UNKNOWN;
    }
  }
@@ -793,19 +1019,37 @@ struct system_on_chip* guess_soc_apple(struct system_on_chip* soc) {
      }
    }
    else {
-      printBug("Found invalid cpu_subfamily: 0x%.8X", cpu_subfamily);
+      printBugCheckRelease("Found invalid cpu_subfamily: 0x%.8X", cpu_subfamily);
      soc->soc_vendor = SOC_VENDOR_UNKNOWN;
    }
  }
  else if(cpu_family == CPUFAMILY_ARM_EVEREST_SAWTOOTH ||
          cpu_family == CPUFAMILY_ARM_EVEREST_SAWTOOTH_PRO ||
          cpu_family == CPUFAMILY_ARM_EVEREST_SAWTOOTH_MAX) {
    // Check M3 version
    if(cpu_family == CPUFAMILY_ARM_EVEREST_SAWTOOTH) {
      fill_soc(soc, "M3", SOC_APPLE_M3, 3);
    }
    else if(cpu_family == CPUFAMILY_ARM_EVEREST_SAWTOOTH_PRO) {
      fill_soc(soc, "M3 Pro", SOC_APPLE_M3_PRO, 3);
    }
    else if(cpu_family == CPUFAMILY_ARM_EVEREST_SAWTOOTH_MAX) {
      fill_soc(soc, "M3 Max", SOC_APPLE_M3_MAX, 3);
    }
    else {
      printBugCheckRelease("Found invalid cpu_family: 0x%.8X", cpu_family);
      soc->soc_vendor = SOC_VENDOR_UNKNOWN;
    }
  }
  else {
-    printBug("Found invalid cpu_family: 0x%.8X", cpu_family);
+    printBugCheckRelease("Found invalid cpu_family: 0x%.8X", cpu_family);
    soc->soc_vendor = SOC_VENDOR_UNKNOWN;
  }
  return soc;
 }
 #endif
-struct system_on_chip* get_soc(void) {
+struct system_on_chip* get_soc(struct cpuInfo* cpu) {
  struct system_on_chip* soc = emalloc(sizeof(struct system_on_chip));
  soc->raw_name = NULL;
  soc->soc_vendor = SOC_VENDOR_UNKNOWN;
@@ -841,10 +1085,18 @@ struct system_on_chip* get_soc(void) {
      printWarn("SoC detection failed using Android: Found '%s' string", soc->raw_name);
    }
 #endif // ifdef __ANDROID__
-    // If cpufinfo/Android (if available) detection fails, try with nvmem
+    // If previous steps failed, try with nvmem
    if(soc->soc_vendor == SOC_VENDOR_UNKNOWN) {
      soc = guess_soc_from_nvmem(soc);
    }
    // If previous steps failed, try infering it from the microarchitecture
    if(soc->soc_vendor == SOC_VENDOR_UNKNOWN) {
      soc = guess_soc_from_uarch(soc, cpu);
    }
    // If previous steps failed, try infering it from the pci device id
    if(soc->soc_vendor == SOC_VENDOR_UNKNOWN) {
      soc = guess_soc_from_pci(soc, cpu);
    }
  }
 #elif defined __APPLE__ || __MACH__
  soc = guess_soc_apple(soc);
--- a/src/arm/soc.h
+++ b/src/arm/soc.h
@@ -5,6 +5,6 @@
 #include "../common/soc.h"
 #include <stdint.h>
-struct system_on_chip* get_soc(void);
+struct system_on_chip* get_soc(struct cpuInfo* cpu);
 #endif
--- a/src/arm/socs.h
+++ b/src/arm/socs.h
@@ -29,6 +29,9 @@ enum {
  SOC_HISILICON_3670,
  SOC_HISILICON_3680,
  SOC_HISILICON_3690,
  // Kunpeng //
  SOC_KUNPENG_920,
  SOC_KUNPENG_930,
  // Exynos //
  SOC_EXYNOS_3475,
  SOC_EXYNOS_4210,
@@ -64,39 +67,23 @@ enum {
  SOC_EXYNOS_980,
  SOC_EXYNOS_880,
  // Mediatek //
-  SOC_MTK_MT6893,
+  SOC_MTK_MT5327,
-  SOC_MTK_MT6891,
+  SOC_MTK_MT5329,
-  SOC_MTK_MT6889,
+  SOC_MTK_MT5366,
-  SOC_MTK_MT6885Z,
+  SOC_MTK_MT5389,
-  SOC_MTK_MT6853,
+  SOC_MTK_MT5395,
-  SOC_MTK_MT6873,
+  SOC_MTK_MT5396,
-  SOC_MTK_MT6875,
+  SOC_MTK_MT5398,
-  SOC_MTK_MT6761D,
+  SOC_MTK_MT5505,
-  SOC_MTK_MT6761,
+  SOC_MTK_MT5561,
-  SOC_MTK_MT6762D,
+  SOC_MTK_MT5580,
-  SOC_MTK_MT6755,
+  SOC_MTK_MT5582,
-  SOC_MTK_MT6755M,
+  SOC_MTK_MT5592,
-  SOC_MTK_MT6755T,
+  SOC_MTK_MT5595,
-  SOC_MTK_MT6757,
+  SOC_MTK_MT5596,
-  SOC_MTK_MT6762,
+  SOC_MTK_MT5597,
-  SOC_MTK_MT6763V,
+  SOC_MTK_MT5889,
-  SOC_MTK_MT6763T,
+  SOC_MTK_MT5895,
  SOC_MTK_MT6757CD,
  SOC_MTK_MT6758,
  SOC_MTK_MT6765,
  SOC_MTK_MT6771,
  SOC_MTK_MT6768,
  SOC_MTK_MT6771T,
  SOC_MTK_MT6771V,
  SOC_MTK_MT6779,
  SOC_MTK_MT6795,
  SOC_MTK_MT6795T,
  SOC_MTK_MT6797,
  SOC_MTK_MT6797M,
  SOC_MTK_MT6797D,
  SOC_MTK_MT6797T,
  SOC_MTK_MT6797X,
  SOC_MTK_MT6799,
  SOC_MTK_MT6515,
  SOC_MTK_MT6516,
  SOC_MTK_MT6517,
@@ -126,7 +113,51 @@ enum {
  SOC_MTK_MT6750T,
  SOC_MTK_MT6752,
  SOC_MTK_MT6753,
  SOC_MTK_MT6755M,
  SOC_MTK_MT6755T,
  SOC_MTK_MT6757,
  SOC_MTK_MT6757CD,
  SOC_MTK_MT6758,
  SOC_MTK_MT6761,
  SOC_MTK_MT6761D,
  SOC_MTK_MT6762,
  SOC_MTK_MT6762D,
  SOC_MTK_MT6762G,
  SOC_MTK_MT6763T,
  SOC_MTK_MT6763V,
  SOC_MTK_MT6765,
  SOC_MTK_MT6765G,
  SOC_MTK_MT6765H,
  SOC_MTK_MT6768,
  SOC_MTK_MT6769H,
  SOC_MTK_MT6769T,
  SOC_MTK_MT6769V,
  SOC_MTK_MT6769Z,
  SOC_MTK_MT6771,
  SOC_MTK_MT6779V_CU,
  SOC_MTK_MT6779V_CV,
  SOC_MTK_MT6785V_CC,
  SOC_MTK_MT6785V_CD,
  SOC_MTK_MT6789,
  SOC_MTK_MT6795,
  SOC_MTK_MT6797,
  SOC_MTK_MT6797T,
  SOC_MTK_MT6797X,
  SOC_MTK_MT6799,
  SOC_MTK_MT6833,
  SOC_MTK_MT6850,
  SOC_MTK_MT6853,
  SOC_MTK_MT6853V,
  SOC_MTK_MT6873,
  SOC_MTK_MT6875,
  SOC_MTK_MT6879,
  SOC_MTK_MT6883Z,
  SOC_MTK_MT6885Z,
  SOC_MTK_MT6889,
  SOC_MTK_MT6889Z,
  SOC_MTK_MT6891,
  SOC_MTK_MT6893,
  SOC_MTK_MT6893Z,
  SOC_MTK_MT8121,
  SOC_MTK_MT8125,
  SOC_MTK_MT8127,
@@ -141,7 +172,25 @@ enum {
  SOC_MTK_MT8581,
  SOC_MTK_MT8735,
  SOC_MTK_MT8765B,
  SOC_MTK_MT8781V,
  SOC_MTK_MT8783,
  SOC_MTK_MT9602,
  SOC_MTK_MT9612,
  SOC_MTK_MT9613,
  SOC_MTK_MT9615,
  SOC_MTK_MT9618,
  SOC_MTK_MT9632,
  SOC_MTK_MT9638,
  SOC_MTK_MT9652,
  SOC_MTK_MT9653,
  SOC_MTK_MT9675,
  SOC_MTK_MT9685,
  SOC_MTK_MT9686,
  SOC_MTK_MT9689,
  SOC_MTK_MT9902,
  SOC_MTK_MT9950,
  SOC_MTK_MT9972,
  SOC_MTK_MT9982,
  // Snapdragon //
  SOC_SNAPD_QSD8650,
  SOC_SNAPD_QSD8250,
@@ -221,11 +270,13 @@ enum {
  SOC_SNAPD_SDM660,
  SOC_SNAPD_SM6115,
  SOC_SNAPD_SM6125,
  SOC_SNAPD_SM6450,
  SOC_SNAPD_SDM670,
  SOC_SNAPD_SM6150,
  SOC_SNAPD_SM6350,
  SOC_SNAPD_SDM710,
  SOC_SNAPD_SDM712,
  SOC_SNAPD_SM4450,
  SOC_SNAPD_SM7125,
  SOC_SNAPD_SM7150_AA,
  SOC_SNAPD_SM7150_AB,
@@ -234,6 +285,9 @@ enum {
  SOC_SNAPD_SM7250_AA,
  SOC_SNAPD_SM7250_AB,
  SOC_SNAPD_SM7250_AC,
  SOC_SNAPD_SM7435_AB,
  SOC_SNAPD_SM7450,
  SOC_SNAPD_SM7475,
  SOC_SNAPD_MSM8974AA,
  SOC_SNAPD_MSM8974AB,
  SOC_SNAPD_MSM8974AC,
@@ -254,6 +308,7 @@ enum {
  SOC_SNAPD_SM8250_AB,
  SOC_SNAPD_SM8350,
  SOC_SNAPD_SM8450,
  SOC_SNAPD_SM8475,
  // APPLE
  SOC_APPLE_M1,
  SOC_APPLE_M1_PRO,
@@ -263,6 +318,9 @@ enum {
  SOC_APPLE_M2_PRO,
  SOC_APPLE_M2_MAX,
  SOC_APPLE_M2_ULTRA,
  SOC_APPLE_M3,
  SOC_APPLE_M3_PRO,
  SOC_APPLE_M3_MAX,
  // ALLWINNER
  SOC_ALLWINNER_A10,
  SOC_ALLWINNER_A13,
@@ -280,12 +338,14 @@ enum {
  SOC_ALLWINNER_V3S,
  SOC_ALLWINNER_HZP,
  SOC_ALLWINNER_H2PLUS,
  SOC_ALLWINNER_S3,
  SOC_ALLWINNER_H3,
  SOC_ALLWINNER_H8,
  SOC_ALLWINNER_H5,
  SOC_ALLWINNER_H6,
  SOC_ALLWINNER_H64,
  SOC_ALLWINNER_H616,
  SOC_ALLWINNER_H618,
  SOC_ALLWINNER_R8,
  SOC_ALLWINNER_R16,
  SOC_ALLWINNER_R40,
@@ -300,10 +360,17 @@ enum {
  SOC_ROCKCHIP_3328,
  SOC_ROCKCHIP_3368,
  SOC_ROCKCHIP_3399,
  SOC_ROCKCHIP_3528,
  SOC_ROCKCHIP_3562,
  SOC_ROCKCHIP_3566,
  SOC_ROCKCHIP_3568,
  SOC_ROCKCHIP_3588,
-  SOC_ROCKCHIP_3588S,
+  // GOOGLE
  SOC_GOOGLE_TENSOR,
  SOC_GOOGLE_TENSOR_G2,
  SOC_GOOGLE_TENSOR_G3,
  // NVIDIA,
  SOC_TEGRA_X1,
  // UNKNOWN
  SOC_MODEL_UNKNOWN
 };
@@ -311,12 +378,15 @@ enum {
 inline static VENDOR get_soc_vendor_from_soc(SOC soc) {
  if(soc >= SOC_BCM_2835 && soc <= SOC_BCM_2712) return SOC_VENDOR_BROADCOM;
  else if(soc >= SOC_HISILICON_3620 && soc <= SOC_HISILICON_3690) return SOC_VENDOR_KIRIN;
  else if(soc >= SOC_KUNPENG_920 && soc <= SOC_KUNPENG_930) return SOC_VENDOR_KUNPENG;
  else if(soc >= SOC_EXYNOS_3475 && soc <= SOC_EXYNOS_880) return SOC_VENDOR_EXYNOS;
  else if(soc >= SOC_MTK_MT6893 && soc <= SOC_MTK_MT8783) return SOC_VENDOR_MEDIATEK;
-  else if(soc >= SOC_SNAPD_QSD8650 && soc <= SOC_SNAPD_SM8450) return SOC_VENDOR_SNAPDRAGON;
+  else if(soc >= SOC_SNAPD_QSD8650 && soc <= SOC_SNAPD_SM8475) return SOC_VENDOR_SNAPDRAGON;
-  else if(soc >= SOC_APPLE_M1 && soc <= SOC_APPLE_M2_ULTRA) return SOC_VENDOR_APPLE;
+  else if(soc >= SOC_APPLE_M1 && soc <= SOC_APPLE_M3_MAX) return SOC_VENDOR_APPLE;
  else if(soc >= SOC_ALLWINNER_A10 && soc <= SOC_ALLWINNER_R328) return SOC_VENDOR_ALLWINNER;
-  else if(soc >= SOC_ROCKCHIP_3288 && soc <= SOC_ROCKCHIP_3588S) return SOC_VENDOR_ROCKCHIP;
+  else if(soc >= SOC_ROCKCHIP_3288 && soc <= SOC_ROCKCHIP_3588) return SOC_VENDOR_ROCKCHIP;
  else if(soc >= SOC_GOOGLE_TENSOR && soc <= SOC_GOOGLE_TENSOR_G3) return SOC_VENDOR_GOOGLE;
  else if(soc >= SOC_TEGRA_X1 && soc <= SOC_TEGRA_X1) return SOC_VENDOR_NVIDIA;
  return SOC_VENDOR_UNKNOWN;
 }
--- a/src/arm/uarch.c
+++ b/src/arm/uarch.c
@@ -10,7 +10,6 @@
 // Data not available
 #define NA                   -1
 typedef uint32_t MICROARCH;
 typedef uint32_t ISA;
 struct uarch {
@@ -37,85 +36,6 @@ enum {
  ISA_ARMv9_A
 };
 enum {
  UARCH_UNKNOWN,
  // ARM
  UARCH_ARM7,
  UARCH_ARM9,
  UARCH_ARM1136,
  UARCH_ARM1156,
  UARCH_ARM1176,
  UARCH_ARM11MPCORE,
  UARCH_CORTEX_A5,
  UARCH_CORTEX_A7,
  UARCH_CORTEX_A8,
  UARCH_CORTEX_A9,
  UARCH_CORTEX_A12,
  UARCH_CORTEX_A15,
  UARCH_CORTEX_A17,
  UARCH_CORTEX_A32,
  UARCH_CORTEX_A35,
  UARCH_CORTEX_A53,
  UARCH_CORTEX_A55r0, // ARM Cortex-A55 revision 0 (restricted dual-issue capabilities compared to revision 1+).
  UARCH_CORTEX_A55,
  UARCH_CORTEX_A57,
  UARCH_CORTEX_A65,
  UARCH_CORTEX_A72,
  UARCH_CORTEX_A73,
  UARCH_CORTEX_A75,
  UARCH_CORTEX_A76,
  UARCH_CORTEX_A77,
  UARCH_CORTEX_A78,
  UARCH_CORTEX_A510,
  UARCH_CORTEX_A710,
  UARCH_CORTEX_X1,
  UARCH_CORTEX_X2,
  UARCH_NEOVERSE_N1,
  UARCH_NEOVERSE_E1,
  UARCH_NEOVERSE_V1,
  UARCH_SCORPION,
  UARCH_KRAIT,
  UARCH_KYRO,
  UARCH_FALKOR,
  UARCH_SAPHIRA,
  UARCH_DENVER,
  UARCH_DENVER2,
  UARCH_CARMEL,
  // SAMSUNG
  UARCH_EXYNOS_M1,  // Samsung Exynos M1 (Exynos 8890 big cores)
  UARCH_EXYNOS_M2,  // Samsung Exynos M2 (Exynos 8895 big cores)
  UARCH_EXYNOS_M3,  // Samsung Exynos M3 (Exynos 9810 big cores)
  UARCH_EXYNOS_M4,  // Samsung Exynos M4 (Exynos 9820 big cores)
  UARCH_EXYNOS_M5,  // Samsung Exynos M5 (Exynos 9830 big cores)
  // APPLE
  UARCH_SWIFT,      // Apple A6 and A6X processors.
  UARCH_CYCLONE,    // Apple A7 processor.
  UARCH_TYPHOON,    // Apple A8 and A8X processor
  UARCH_TWISTER,    // Apple A9 and A9X processor.
  UARCH_HURRICANE,  // Apple A10 and A10X processor.
  UARCH_MONSOON,    // Apple A11 processor (big cores).
  UARCH_MISTRAL,    // Apple A11 processor (little cores).
  UARCH_VORTEX,     // Apple A12 processor (big cores).
  UARCH_TEMPEST,    // Apple A12 processor (big cores).
  UARCH_LIGHTNING,  // Apple A13 processor (big cores).
  UARCH_THUNDER,    // Apple A13 processor (little cores).
  UARCH_ICESTORM,   // Apple M1 processor (little cores).
  UARCH_FIRESTORM,  // Apple M1 processor (big cores).
  UARCH_BLIZZARD,   // Apple M2 processor (little cores).
  UARCH_AVALANCHE,  // Apple M2 processor (big cores).
  // CAVIUM
  UARCH_THUNDERX,   // Cavium ThunderX
  UARCH_THUNDERX2,  // Cavium ThunderX2 (originally Broadcom Vulkan).
  // MARVELL
  UARCH_PJ4,
  UARCH_BRAHMA_B15,
  UARCH_BRAHMA_B53,
  UARCH_XGENE,        // Applied Micro X-Gene.
  UARCH_TAISHAN_V110, // HiSilicon TaiShan v110 (Huawei Kunpeng 920 series processors).
  // PHYTIUM
  UARCH_XIAOMI,       // Not to be confused with Xiaomi Inc
 };
 static const ISA isas_uarch[] = {
  [UARCH_ARM1136]      = ISA_ARMv6,
  [UARCH_ARM1156]      = ISA_ARMv6_T2,
@@ -143,8 +63,10 @@ static const ISA isas_uarch[] = {
  [UARCH_CORTEX_A78]   = ISA_ARMv8_2_A,
  [UARCH_CORTEX_A510]   = ISA_ARMv9_A,
  [UARCH_CORTEX_A710]   = ISA_ARMv9_A,
  [UARCH_CORTEX_A715]  = ISA_ARMv9_A,
  [UARCH_CORTEX_X1]    = ISA_ARMv8_2_A,
  [UARCH_CORTEX_X2]    = ISA_ARMv9_A,
  [UARCH_CORTEX_X3]    = ISA_ARMv9_A,
  [UARCH_NEOVERSE_N1]  = ISA_ARMv8_2_A,
  [UARCH_NEOVERSE_E1]  = ISA_ARMv8_2_A,
  [UARCH_NEOVERSE_V1]  = ISA_ARMv8_4_A,
@@ -153,6 +75,7 @@ static const ISA isas_uarch[] = {
  [UARCH_THUNDERX]     = ISA_ARMv8_A,
  [UARCH_THUNDERX2]    = ISA_ARMv8_1_A,
  [UARCH_TAISHAN_V110] = ISA_ARMv8_2_A,
  [UARCH_TAISHAN_V200] = ISA_ARMv8_2_A, // Not confirmed
  [UARCH_DENVER]       = ISA_ARMv8_A,
  [UARCH_DENVER2]      = ISA_ARMv8_A,
  [UARCH_CARMEL]       = ISA_ARMv8_A,
@@ -194,7 +117,8 @@ static char* isas_string[] = {
 #define UARCH_START if (false) {}
 #define CHECK_UARCH(arch, cpu, im_, p_, v_, r_, str, uarch, vendor) \
   else if (im_ == im && p_ == p && (v_ == NA || v_ == v) && (r_ == NA || r_ == r)) fill_uarch(arch, cpu, str, uarch, vendor);
-#define UARCH_END else { printBug("Unknown microarchitecture detected: IM=0x%.8X P=0x%.8X V=0x%.8X R=0x%.8X", im, p, v, r); fill_uarch(arch, cpu, "Unknown", UARCH_UNKNOWN, CPU_VENDOR_UNKNOWN); }
+#define UARCH_END else { printBugCheckRelease("Unknown microarchitecture detected: IM=0x%X P=0x%X V=0x%X R=0x%X", im, p, v, r); \
 fill_uarch(arch, cpu, "Unknown", UARCH_UNKNOWN, CPU_VENDOR_UNKNOWN); }
 void fill_uarch(struct uarch* arch, struct cpuInfo* cpu, char* str, MICROARCH u, VENDOR vendor) {
  arch->uarch = u;
@@ -210,10 +134,11 @@ void fill_uarch(struct uarch* arch, struct cpuInfo* cpu, char* str, MICROARCH u,
 /*
 * Codes are based on pytorch/cpuinfo, more precisely:
- * - https://github.com/pytorch/cpuinfo/blob/master/src/arm/uarch.c
+ * - https://github.com/pytorch/cpuinfo/blob/main/src/arm/uarch.c
 * Other sources:
 * - https://elixir.bootlin.com/linux/latest/source/arch/arm64/include/asm/cputype.h
 * - https://elixir.bootlin.com/linux/latest/source/arch/arm/include/asm/cputype.h
 * - https://github.com/AsahiLinux/m1n1/blob/main/src/chickens.c
 */
 struct uarch* get_uarch_from_midr(uint32_t midr, struct cpuInfo* cpu) {
  struct uarch* arch = emalloc(sizeof(struct uarch));
@@ -263,6 +188,8 @@ struct uarch* get_uarch_from_midr(uint32_t midr, struct cpuInfo* cpu) {
  CHECK_UARCH(arch, cpu, 'A', 0xD47, NA, NA, "Cortex‑A710",           UARCH_CORTEX_A710,  CPU_VENDOR_ARM)
  CHECK_UARCH(arch, cpu, 'A', 0xD48, NA, NA, "Cortex-X2",             UARCH_CORTEX_X2,    CPU_VENDOR_ARM)
  CHECK_UARCH(arch, cpu, 'A', 0xD4A, NA, NA, "Neoverse E1",           UARCH_NEOVERSE_E1,  CPU_VENDOR_ARM)
  CHECK_UARCH(arch, cpu, 'A', 0xD4D, NA, NA, "Cortex-A715",           UARCH_CORTEX_A715,  CPU_VENDOR_ARM)
  CHECK_UARCH(arch, cpu, 'A', 0xD4E, NA, NA, "Cortex-X3",             UARCH_CORTEX_X3,    CPU_VENDOR_ARM)
  CHECK_UARCH(arch, cpu, 'B', 0x00F, NA, NA, "Brahma B15",            UARCH_BRAHMA_B15,   CPU_VENDOR_BROADCOM)
  CHECK_UARCH(arch, cpu, 'B', 0x100, NA, NA, "Brahma B53",            UARCH_BRAHMA_B53,   CPU_VENDOR_BROADCOM)
@@ -274,7 +201,8 @@ struct uarch* get_uarch_from_midr(uint32_t midr, struct cpuInfo* cpu) {
  CHECK_UARCH(arch, cpu, 'C', 0x0A3, NA, NA, "ThunderX 81XX",         UARCH_THUNDERX,     CPU_VENDOR_CAVIUM)
  CHECK_UARCH(arch, cpu, 'C', 0x0AF, NA, NA, "ThunderX2 99XX",        UARCH_THUNDERX2,    CPU_VENDOR_CAVIUM)
-  CHECK_UARCH(arch, cpu, 'H', 0xD01, NA, NA, "TaiShan v110",          UARCH_TAISHAN_V110, CPU_VENDOR_HUAWUEI) // Kunpeng 920 series
+  CHECK_UARCH(arch, cpu, 'H', 0xD01, NA, NA, "TaiShan v110",          UARCH_TAISHAN_V110, CPU_VENDOR_HUAWEI) // Kunpeng 920 series
  CHECK_UARCH(arch, cpu, 'H', 0xD02, NA, NA, "TaiShan v200",          UARCH_TAISHAN_V200, CPU_VENDOR_HUAWEI) // Kunpeng 930 series (found in openeuler: https://mailweb.openeuler.org/hyperkitty/list/kernel@openeuler.org/message/XQCV7NX2UKRIUWUFKRF4PO3QENCOUFR3)
  CHECK_UARCH(arch, cpu, 'H', 0xD40, NA, NA, "Cortex-A76",            UARCH_CORTEX_A76,   CPU_VENDOR_ARM)    // Kirin 980 Big/Medium cores -> Cortex-A76
  CHECK_UARCH(arch, cpu, 'N', 0x000, NA, NA, "Denver",                UARCH_DENVER,       CPU_VENDOR_NVIDIA)
@@ -319,6 +247,8 @@ struct uarch* get_uarch_from_midr(uint32_t midr, struct cpuInfo* cpu) {
  CHECK_UARCH(arch, cpu, 'a', 0x023, NA, NA, "Firestorm",             UARCH_FIRESTORM,    CPU_VENDOR_APPLE)
  CHECK_UARCH(arch, cpu, 'a', 0x030, NA, NA, "Blizzard",              UARCH_BLIZZARD,     CPU_VENDOR_APPLE)
  CHECK_UARCH(arch, cpu, 'a', 0x031, NA, NA, "Avalanche",             UARCH_AVALANCHE,    CPU_VENDOR_APPLE)
  CHECK_UARCH(arch, cpu, 'a', 0x048, NA, NA, "Sawtooth",              UARCH_SAWTOOTH,     CPU_VENDOR_APPLE)
  CHECK_UARCH(arch, cpu, 'a', 0x049, NA, NA, "Everest",               UARCH_EVEREST,      CPU_VENDOR_APPLE)
  CHECK_UARCH(arch, cpu, 'V', 0x581, NA, NA, "PJ4",                   UARCH_PJ4,          CPU_VENDOR_MARVELL)
  CHECK_UARCH(arch, cpu, 'V', 0x584, NA, NA, "PJ4B-MP",               UARCH_PJ4,          CPU_VENDOR_MARVELL)
@@ -379,18 +309,23 @@ int get_number_of_vpus(struct cpuInfo* cpu) {
  MICROARCH ua = cpu->arch->uarch;
  switch(ua) {
    case UARCH_EVEREST:     // Just a guess, needs confirmation.
    case UARCH_FIRESTORM:   // [https://dougallj.github.io/applecpu/firestorm-simd.html]
    case UARCH_AVALANCHE:   // [https://en.wikipedia.org/wiki/Comparison_of_ARM_processors]
    case UARCH_CORTEX_X1:   // [https://www.anandtech.com/show/15813/arm-cortex-a78-cortex-x1-cpu-ip-diverging/3]
    case UARCH_CORTEX_X2:   // [https://www.anandtech.com/show/16693/arm-announces-mobile-armv9-cpu-microarchitectures-cortexx2-cortexa710-cortexa510/2]
    case UARCH_CORTEX_X3:   // [https://www.hwcooling.net/en/cortex-x3-the-new-fastest-arm-core-architecture-analysis: "The FPU and SIMD unit of the core still has four pipelines"]
    case UARCH_NEOVERSE_V1: // [https://en.wikichip.org/wiki/arm_holdings/microarchitectures/neoverse_v1]
      return 4;
    case UARCH_SAWTOOTH:    // Needs confirmation, rn this is the best we know: https://mastodon.social/@dougall/111118317031041336
    case UARCH_EXYNOS_M3:   // [https://www.anandtech.com/show/12361/samsung-exynos-m3-architecture]
    case UARCH_EXYNOS_M4:   // [https://en.wikichip.org/wiki/samsung/microarchitectures/m4#Block_Diagram]
    case UARCH_EXYNOS_M5:   // [https://en.wikichip.org/wiki/samsung/microarchitectures/m5]
      return 3;
    case UARCH_ICESTORM:    // [https://dougallj.github.io/applecpu/icestorm-simd.html]
    case UARCH_BLIZZARD:    // [https://en.wikipedia.org/wiki/Comparison_of_ARM_processors]
    case UARCH_TAISHAN_V110:// [https://www-file.huawei.com/-/media/corp2020/pdf/publications/huawei-research/2022/huawei-research-issue1-en.pdf]: "128-bit x 2 for single precision"
    case UARCH_TAISHAN_V200:// Not confirmed, asssuming same as v110
    case UARCH_CORTEX_A57:  // [https://www.anandtech.com/show/8718/the-samsung-galaxy-note-4-exynos-review/5]
    case UARCH_CORTEX_A72:  // [https://www.anandtech.com/show/10347/arm-cortex-a73-artemis-unveiled/2]
    case UARCH_CORTEX_A73:  // [https://www.anandtech.com/show/10347/arm-cortex-a73-artemis-unveiled/2]
@@ -401,13 +336,13 @@ int get_number_of_vpus(struct cpuInfo* cpu) {
    case UARCH_EXYNOS_M1:   // [https://www.anandtech.com/show/12361/samsung-exynos-m3-architecture]
    case UARCH_EXYNOS_M2:   // [https://www.anandtech.com/show/12361/samsung-exynos-m3-architecture]
    case UARCH_NEOVERSE_N1: // [https://en.wikichip.org/wiki/arm_holdings/microarchitectures/neoverse_n1#Individual_Core]
    case UARCH_CORTEX_A710: // [https://chipsandcheese.com/2023/08/11/arms-cortex-a710-winning-by-default/]: Fig in Core Overview. Table in Instruction Scheduling and Execution
    case UARCH_CORTEX_A715: // [https://www.hwcooling.net/en/arm-introduces-new-cortex-a715-core-architecture-analysis/]: "the numbers of ALU and FPU execution units themselves >
      return 2;
    case UARCH_NEOVERSE_E1: // [https://www.anandtech.com/show/13959/arm-announces-neoverse-n1-platform/5]
    // A510 is integrated as part of a Complex. Normally, each complex would incorporate two Cortex-A510 cores.
    // Each complex incorporates a single VPU with 2 ports, so for each A510 there is theoretically 1 port.
    case UARCH_CORTEX_A510: // [https://en.wikichip.org/wiki/arm_holdings/microarchitectures/cortex-a510#Vector_Processing_Unit_.28VPU.29]
    // Not sure about this one since there is no explicit information saying it has one, but they never state it has more either.
    case UARCH_CORTEX_A710: // [Arm Cortex‑A710 Core Technical Reference Manual]
      return 1;
    default:
      // ARMv6
@@ -422,6 +357,10 @@ char* get_str_uarch(struct cpuInfo* cpu) {
  return cpu->arch->uarch_str;
 }
 MICROARCH get_uarch(struct uarch* arch) {
  return arch->uarch;
 }
 void free_uarch_struct(struct uarch* arch) {
  free(arch->uarch_str);
  free(arch);
--- a/src/arm/uarch.h
+++ b/src/arm/uarch.h
@@ -5,11 +5,98 @@
 #include "midr.h"
 enum {
  UARCH_UNKNOWN,
  // ARM
  UARCH_ARM7,
  UARCH_ARM9,
  UARCH_ARM1136,
  UARCH_ARM1156,
  UARCH_ARM1176,
  UARCH_ARM11MPCORE,
  UARCH_CORTEX_A5,
  UARCH_CORTEX_A7,
  UARCH_CORTEX_A8,
  UARCH_CORTEX_A9,
  UARCH_CORTEX_A12,
  UARCH_CORTEX_A15,
  UARCH_CORTEX_A17,
  UARCH_CORTEX_A32,
  UARCH_CORTEX_A35,
  UARCH_CORTEX_A53,
  UARCH_CORTEX_A55r0, // ARM Cortex-A55 revision 0 (restricted dual-issue capabilities compared to revision 1+).
  UARCH_CORTEX_A55,
  UARCH_CORTEX_A57,
  UARCH_CORTEX_A65,
  UARCH_CORTEX_A72,
  UARCH_CORTEX_A73,
  UARCH_CORTEX_A75,
  UARCH_CORTEX_A76,
  UARCH_CORTEX_A77,
  UARCH_CORTEX_A78,
  UARCH_CORTEX_A510,
  UARCH_CORTEX_A710,
  UARCH_CORTEX_A715,
  UARCH_CORTEX_X1,
  UARCH_CORTEX_X2,
  UARCH_CORTEX_X3,
  UARCH_NEOVERSE_N1,
  UARCH_NEOVERSE_E1,
  UARCH_NEOVERSE_V1,
  UARCH_SCORPION,
  UARCH_KRAIT,
  UARCH_KYRO,
  UARCH_FALKOR,
  UARCH_SAPHIRA,
  UARCH_DENVER,
  UARCH_DENVER2,
  UARCH_CARMEL,
  // SAMSUNG
  UARCH_EXYNOS_M1,  // Samsung Exynos M1 (Exynos 8890 big cores)
  UARCH_EXYNOS_M2,  // Samsung Exynos M2 (Exynos 8895 big cores)
  UARCH_EXYNOS_M3,  // Samsung Exynos M3 (Exynos 9810 big cores)
  UARCH_EXYNOS_M4,  // Samsung Exynos M4 (Exynos 9820 big cores)
  UARCH_EXYNOS_M5,  // Samsung Exynos M5 (Exynos 9830 big cores)
  // APPLE
  UARCH_SWIFT,      // Apple A6 and A6X processors.
  UARCH_CYCLONE,    // Apple A7 processor.
  UARCH_TYPHOON,    // Apple A8 and A8X processor
  UARCH_TWISTER,    // Apple A9 and A9X processor.
  UARCH_HURRICANE,  // Apple A10 and A10X processor.
  UARCH_MONSOON,    // Apple A11 processor (big cores).
  UARCH_MISTRAL,    // Apple A11 processor (little cores).
  UARCH_VORTEX,     // Apple A12 processor (big cores).
  UARCH_TEMPEST,    // Apple A12 processor (big cores).
  UARCH_LIGHTNING,  // Apple A13 processor (big cores).
  UARCH_THUNDER,    // Apple A13 processor (little cores).
  UARCH_ICESTORM,   // Apple M1 processor (little cores).
  UARCH_FIRESTORM,  // Apple M1 processor (big cores).
  UARCH_BLIZZARD,   // Apple M2 processor (little cores).
  UARCH_AVALANCHE,  // Apple M2 processor (big cores).
  UARCH_SAWTOOTH,   // Apple M3 processor (little cores).
  UARCH_EVEREST,    // Apple M3 processor (big cores).
  // CAVIUM
  UARCH_THUNDERX,   // Cavium ThunderX
  UARCH_THUNDERX2,  // Cavium ThunderX2 (originally Broadcom Vulkan).
  // MARVELL
  UARCH_PJ4,
  UARCH_BRAHMA_B15,
  UARCH_BRAHMA_B53,
  UARCH_XGENE,        // Applied Micro X-Gene.
  UARCH_TAISHAN_V110, // HiSilicon TaiShan v110
  UARCH_TAISHAN_V200, // HiSilicon TaiShan v200
  // PHYTIUM
  UARCH_XIAOMI,       // Not to be confused with Xiaomi Inc
 };
 typedef uint32_t MICROARCH;
 struct uarch* get_uarch_from_midr(uint32_t midr, struct cpuInfo* cpu);
 int get_number_of_vpus(struct cpuInfo* cpu);
 int get_vpus_width(struct cpuInfo* cpu);
 bool has_fma_support(struct cpuInfo* cpu);
 char* get_str_uarch(struct cpuInfo* cpu);
 void free_uarch_struct(struct uarch* arch);
 MICROARCH get_uarch(struct uarch* arch);
 #endif
--- a/src/common/args.c
+++ b/src/common/args.c
@@ -28,6 +28,7 @@ struct args_struct {
  bool help_flag;
  bool raw_flag;
  bool accurate_pp;
  bool measure_max_frequency_flag;
  bool full_cpu_name_flag;
  bool logo_long;
  bool logo_short;
@@ -50,6 +51,7 @@ const char args_chr[] = {
  /* [ARG_LOGO_INTEL_NEW]   = */ 3,
  /* [ARG_LOGO_INTEL_OLD]   = */ 4,
  /* [ARG_ACCURATE_PP]      = */ 5,
  /* [ARG_MEASURE_MAX_FREQ] = */ 6,
  /* [ARG_DEBUG]            = */ 'd',
  /* [ARG_VERBOSE]          = */ 'v',
  /* [ARG_VERSION]          = */ 'V',
@@ -66,6 +68,7 @@ const char *args_str[] = {
  /* [ARG_LOGO_INTEL_NEW]   = */ "logo-intel-new",
  /* [ARG_LOGO_INTEL_OLD]   = */ "logo-intel-old",
  /* [ARG_ACCURATE_PP]      = */ "accurate-pp",
  /* [ARG_MEASURE_MAX_FREQ] = */ "measure-max-freq",
  /* [ARG_DEBUG]            = */ "debug",
  /* [ARG_VERBOSE]          = */ "verbose",
  /* [ARG_VERSION]          = */ "version",
@@ -101,6 +104,10 @@ bool accurate_pp(void) {
  return args.accurate_pp;
 }
 bool measure_max_frequency_flag(void) {
  return args.measure_max_frequency_flag;
 }
 bool show_full_cpu_name(void) {
  return args.full_cpu_name_flag;
 }
@@ -222,12 +229,20 @@ char* build_short_options(void) {
  memset(str, 0, sizeof(char) * (len*2 + 1));
 #ifdef ARCH_X86
-  sprintf(str, "%c:%c:%c%c%c%c%c%c%c%c%c%c%c",
+  sprintf(str, "%c:%c:%c%c%c%c%c%c%c%c%c%c%c%c",
  c[ARG_STYLE], c[ARG_COLOR], c[ARG_HELP],
  c[ARG_RAW], c[ARG_FULLCPUNAME],
  c[ARG_LOGO_SHORT], c[ARG_LOGO_LONG],
  c[ARG_LOGO_INTEL_NEW], c[ARG_LOGO_INTEL_OLD],
-  c[ARG_ACCURATE_PP], c[ARG_DEBUG], c[ARG_VERBOSE],
+  c[ARG_ACCURATE_PP], c[ARG_MEASURE_MAX_FREQ],
  c[ARG_DEBUG], c[ARG_VERBOSE],
  c[ARG_VERSION]);
 #elif ARCH_ARM
  sprintf(str, "%c:%c:%c%c%c%c%c%c%c",
  c[ARG_STYLE], c[ARG_COLOR], c[ARG_HELP],
  c[ARG_LOGO_SHORT], c[ARG_LOGO_LONG],
  c[ARG_MEASURE_MAX_FREQ],
  c[ARG_DEBUG], c[ARG_VERBOSE],
  c[ARG_VERSION]);
 #else
  sprintf(str, "%c:%c:%c%c%c%c%c%c",
@@ -270,8 +285,11 @@ bool parse_args(int argc, char* argv[]) {
    {args_str[ARG_LOGO_INTEL_NEW],   no_argument,       0, args_chr[ARG_LOGO_INTEL_NEW]   },
    {args_str[ARG_LOGO_INTEL_OLD],   no_argument,       0, args_chr[ARG_LOGO_INTEL_OLD]   },
    {args_str[ARG_ACCURATE_PP],      no_argument,       0, args_chr[ARG_ACCURATE_PP]      },
    {args_str[ARG_MEASURE_MAX_FREQ], no_argument,       0, args_chr[ARG_MEASURE_MAX_FREQ] },
    {args_str[ARG_FULLCPUNAME],      no_argument,       0, args_chr[ARG_FULLCPUNAME]      },
    {args_str[ARG_RAW],              no_argument,       0, args_chr[ARG_RAW]              },
 #elif ARCH_ARM
    {args_str[ARG_MEASURE_MAX_FREQ], no_argument,       0, args_chr[ARG_MEASURE_MAX_FREQ] },
 #endif
    {args_str[ARG_LOGO_SHORT],       no_argument,       0, args_chr[ARG_LOGO_SHORT]       },
    {args_str[ARG_LOGO_LONG],        no_argument,       0, args_chr[ARG_LOGO_LONG]        },
@@ -313,6 +331,9 @@ bool parse_args(int argc, char* argv[]) {
    else if(opt == args_chr[ARG_ACCURATE_PP]) {
       args.accurate_pp = true;
    }
    else if(opt == args_chr[ARG_MEASURE_MAX_FREQ]) {
       args.measure_max_frequency_flag = true;
    }
    else if(opt == args_chr[ARG_FULLCPUNAME]) {
       args.full_cpu_name_flag = true;
    }
--- a/src/common/args.h
+++ b/src/common/args.h
@@ -29,6 +29,7 @@ enum {
  ARG_LOGO_INTEL_NEW,
  ARG_LOGO_INTEL_OLD,
  ARG_ACCURATE_PP,
  ARG_MEASURE_MAX_FREQ,
  ARG_DEBUG,
  ARG_VERBOSE,
  ARG_VERSION
@@ -43,6 +44,7 @@ int max_arg_str_length(void);
 bool parse_args(int argc, char* argv[]);
 bool show_help(void);
 bool accurate_pp(void);
 bool measure_max_frequency_flag(void);
 bool show_full_cpu_name(void);
 bool show_logo_long(void);
 bool show_logo_short(void);
--- a/src/common/ascii.h
+++ b/src/common/ascii.h
@@ -33,7 +33,7 @@ struct ascii_logo {
  uint32_t width;
  uint32_t height;
  bool replace_blocks;
-  char color_ascii[3][100];
+  char color_ascii[4][100];
  char color_text[2][100];
 };
@@ -105,6 +105,19 @@ $C1  MMM  :MMM      NMM  dMMK   dMMX            MMN   \
 $C1  MMM  :MMM      NMM  dMMMoo  OMM0....:Nx.   MMN   \
 $C1  MMM  :WWW      XWW   lONMM   'xXMMMMNOc    MMN   "
 #define ASCII_HYGON \
 "$C1                                                   \
 $C1                                                   \
 $C1                                                   \
 $C1 ##    ##  ##    ##  ######     ######    ##    #  \
 $C1 ##....##   ##  ##  ##        ##      ##  ####  #  \
 $C1 ########     ##    ##    ##. ##      ##  #  ####  \
 $C1 ##    ##     ##    *######.    ######    #    ##  \
 $C1                                                   \
 $C1                                                   \
 $C1                                                   \
 $C1                                                   "
 #define ASCII_SNAPD \
 "              $C1@@$C2########               \
           $C1@@@@@$C2###########            \
@@ -145,6 +158,25 @@ $C2     Exynos           \
 $C2                      \
 $C2                      "
 #define ASCII_KUNPENG \
 "$C2                                             .  \
 $C2                                          ..    \
 $C2                                       .##      \
 $C1                                 .$CR  $C2.###.       \
 $C1                            ..$CR   $C2#####.         \
 $C1                       .#.$CR   $C2.#######.          \
 $C1                 .####.$CR   $C2.#######.             \
 $C1           ..######*$CR  $C2.#######.   .             \
 $C1      .#########*$CR  $C2.#######*   .                \
 $C1      ######*$CR  $C2.#######.   .#.                  \
 $C1*#######*$CR   $C2.#######.   *##.                    \
 $C1    ##*$CR $C2.#######.   #######                     \
 $C2          ###.$CR $C1#####$C2   *###                     \
 $C1              *##########                       \
 $C1                    *########                   \
 $C1                          #####.                \
 $C1                             *###.              "
 #define ASCII_KIRIN \
 "$C1                                #######              \
 $C1    #####             ####################           \
@@ -218,6 +250,23 @@ $C1    kMMMMMMMMMMMMMMMMMMMMMMd    \
 $C1     'KMMMMMMMWXXWMMMMMMMk.     \
 $C1       \"cooc\"*    \"*coo'\"       "
 #define ASCII_GOOGLE \
 "$C1            aaaaaaaa               \
 $C1        .MMMMMMMMMMMMMMMM.         \
 $C1     .MMMMMMMMMMMMMMMMMMMMM*       \
 $C1   .MMMMMMMM**        *MM*         \
 $C2  MM$C1MMMMM.                         \
 $C2 *MMM$C1MM.                           \
 $C2*MMMMMM          $C4lMMMMMMMMMMMMMMM* \
 $C2MMMMMMM          $C4lMMMMMMMMMMMMMMMM \
 $C2*MMMMMM          $C4lMMMMMMMMMMMMMMMd \
 $C2 MMMM$C3MMM.                  $C4*MMMMM. \
 $C2  MM$C3MMMMMM.              $C4.MMMMMM.  \
 $C3   *MMMMMMMMM*.......MMM$C4MMMMMM*    \
 $C3     *MMMMMMMMMMMMMMMMMMMM$C4MM*      \
 $C3         *MMMMMMMMMMMMMM*          \
 $C3              ******               "
 #define ASCII_ALLWINNER \
 "$C1                                               \
 $C1                #################              \
@@ -306,6 +355,45 @@ $C1    ########   ########          \
 $C1         #########               \
 $C1             #                   "
 #define ASCII_SIPEED \
 "$C1  ####################################   \
 $C1######@@################################ \
 $C1####@@##@@####@@@@@@@@@@@@@@@@########## \
 $C1######@@####@@@@@@@@@@@@@@@@@@########## \
 $C1#########@@@@########################### \
 $C1#######@@@@@@########################### \
 $C1#########@@@@########################### \
 $C1###########@@@@@@@@@@@@@@@############## \
 $C1##############@@@@@@@@@@@@@@@########### \
 $C1###########################@@@@@######## \
 $C1###########################@@@@@@####### \
 $C1###########################@@@@@######## \
 $C1##########@@@@@@@@@@@@@@@@@@@########### \
 $C1##########@@@@@@@@@@@@@@@@############## \
 $C1######################################## \
 $C1  ####################################   "
 #define ASCII_NVIDIA \
 "$C1               'cccccccccccccccccccccccccc   \
 $C1               ;oooooooooooooooooooooooool   \
 $C1           .:::.     .oooooooooooooooooool   \
 $C1      .:cll;   ,c:::.     cooooooooooooool   \
 $C1   ,clo'      ;.   oolc:     ooooooooooool   \
 $C1.cloo    ;cclo .      .olc.    coooooooool   \
 $C1oooo   :lo,    ;ll;    looc    :oooooooool   \
 $C1 oooc   ool.   ;oooc;clol    :looooooooool   \
 $C1  :ooc   ,ol;  ;oooooo.   .cloo;     loool   \
 $C1    ool;   .olc.       ,:lool        .lool   \
 $C1      ool:.    ,::::ccloo.        :clooool   \
 $C1         oolc::.            ':cclooooooool   \
 $C1               ;oooooooooooooooooooooooool   \
 $C1                                             \
 $C1                                             \
 $C2######.  ##   ##  ##  ######   ##    ###     \
 $C2##   ##  ##   ##  ##  ##   ##  ##   #: :#    \
 $C2##   ##   ## ##   ##  ##   ##  ##  #######   \
 $C2##   ##    ###    ##  ######   ## ##     ##  "
 // --------------------- LONG LOGOS ------------------------- //
 #define ASCII_AMD_L \
 "$C1                                                              \
@@ -438,29 +526,51 @@ $C1        ###########. ############                 \
 $C1            ################                      \
 $C1                 #######                          "
 #define ASCII_NVIDIA_L \
 "$C1                  MMMMMMMMMMMMMMMMMMMMMMMMMMMMMM  \
 $C1                  MMMMMMMMMMMMMMMMMMMMMMMMMMMMMM  \
 $C1                .::   'MMMMMMMMMMMMMMMMMMMMMMMMM  \
 $C1           ccllooo;:;.       ;MMMMMMMMMMMMMMMMMM  \
 $C1       cloc       :ooollcc:     :MMMMMMMMMMMMMMM  \
 $C1    cloc      :ccl;      lolc,     ;MMMMMMMMMMMM  \
 $C1.cloo:    :clo    ;c:      .ool;     MMMMMMMMMMM  \
 $C1  ooo:    ooo     :ool,  .cloo.    ;lMMMMMMMMMMM  \
 $C1   ooo:    ooc    :ooooccooo.    :MMMM  lMMMMMMM  \
 $C1     ooc.   ool:  :oooooo'    ,cloo.        MMMM  \
 $C1      ool:.    olc:       .:cloo.          :MMMM  \
 $C1         olc,     ;:::cccloo.          :MMMMMMMM  \
 $C1            olcc::;              ,:ccloMMMMMMMMM  \
 $C1                  :......oMMMMMMMMMMMMMMMMMMMMMM  \
 $C1                  :lllMMMMMMMMMMMMMMMMMMMMMMMMMM  "
 typedef struct ascii_logo asciiL;
-//                        +-----------------------------------------------------------------------------------------------------+
+//                        +-----------------------------------------------------------------------------------------------------------------+
 //                        | LOGO             | W | H | REPLACE | COLORS LOGO (>0 && <10)                      | COLORS TEXT (=2)            |
-//                        +-----------------------------------------------------------------------------------------------------+
+//                        +-----------------------------------------------------------------------------------------------------------------+
 asciiL logo_amd         = { ASCII_AMD,         39, 15, false, {C_FG_WHITE, C_FG_GREEN},                       {C_FG_WHITE,   C_FG_GREEN}   };
 asciiL logo_intel       = { ASCII_INTEL,       48, 14, false, {C_FG_CYAN},                                    {C_FG_CYAN,    C_FG_WHITE}   };
 asciiL logo_intel_new   = { ASCII_INTEL_NEW,   51,  9, false, {C_FG_CYAN},                                    {C_FG_CYAN,    C_FG_WHITE}   };
 asciiL logo_hygon       = { ASCII_HYGON,       51, 11, false, {C_FG_RED},                                     {C_FG_RED,     C_FG_WHITE}   };
 asciiL logo_snapd       = { ASCII_SNAPD,       39, 16, false, {C_FG_RED, C_FG_WHITE},                         {C_FG_RED,     C_FG_WHITE}   };
 asciiL logo_mtk         = { ASCII_MTK,         59,  5, false, {C_FG_BLUE, C_FG_YELLOW},                       {C_FG_BLUE,    C_FG_YELLOW}  };
 asciiL logo_exynos      = { ASCII_EXYNOS,      22, 13, true,  {C_BG_BLUE, C_FG_WHITE},                        {C_FG_BLUE,    C_FG_WHITE}   };
 asciiL logo_kirin       = { ASCII_KIRIN,       53, 12, false, {C_FG_RED},                                     {C_FG_WHITE,   C_FG_RED}     };
 asciiL logo_kunpeng     = { ASCII_KUNPENG,     48, 17, false, {C_FG_RED, C_FG_WHITE},                         {C_FG_WHITE,   C_FG_RED}     };
 asciiL logo_broadcom    = { ASCII_BROADCOM,    44, 19, false, {C_FG_WHITE, C_FG_RED},                         {C_FG_WHITE,   C_FG_RED}     };
 asciiL logo_arm         = { ASCII_ARM,         42,  5, false, {C_FG_CYAN},                                    {C_FG_WHITE,   C_FG_CYAN}    };
 asciiL logo_ibm         = { ASCII_IBM,         42,  9, false, {C_FG_CYAN, C_FG_WHITE},                        {C_FG_CYAN,    C_FG_WHITE}   };
 asciiL logo_apple       = { ASCII_APPLE,       32, 17, false, {C_FG_WHITE},                                   {C_FG_CYAN,    C_FG_B_WHITE} };
 asciiL logo_google      = { ASCII_GOOGLE,      35, 15, false, {C_FG_RED, C_FG_YELLOW, C_FG_GREEN, C_FG_BLUE}, {C_FG_BLUE,    C_FG_B_WHITE} };
 asciiL logo_allwinner   = { ASCII_ALLWINNER,   47, 16, false, {C_FG_CYAN},                                    {C_FG_B_BLACK, C_FG_B_CYAN } };
 asciiL logo_rockchip    = { ASCII_ROCKCHIP,    58,  8, false, {C_FG_CYAN, C_FG_YELLOW},                       {C_FG_CYAN,    C_FG_YELLOW}  };
 asciiL logo_riscv       = { ASCII_RISCV,       63, 18, false, {C_FG_CYAN, C_FG_YELLOW},                       {C_FG_CYAN,    C_FG_YELLOW}  };
 asciiL logo_sifive      = { ASCII_SIFIVE,      48, 19, true,  {C_BG_WHITE, C_BG_BLACK},                       {C_FG_WHITE,   C_FG_BLUE}    };
 asciiL logo_starfive    = { ASCII_STARFIVE,    33, 17, false, {C_FG_WHITE},                                   {C_FG_WHITE,   C_FG_BLUE}    };
 asciiL logo_sipeed      = { ASCII_SIPEED,      41, 16, true,  {C_BG_RED, C_BG_WHITE},                         {C_FG_RED,     C_FG_WHITE}   };
 asciiL logo_nvidia      = { ASCII_NVIDIA,      45, 19, false, {C_FG_GREEN, C_FG_WHITE},                       {C_FG_WHITE,   C_FG_GREEN}   };
-// Long variants          | ----------------------------------------------------------------------------------------------------|
+// Long variants          | ----------------------------------------------------------------------------------------------------------------|
 asciiL logo_amd_l       = { ASCII_AMD_L,       62, 19, true,  {C_BG_WHITE, C_BG_GREEN},                       {C_FG_WHITE, C_FG_GREEN}     };
 asciiL logo_intel_l     = { ASCII_INTEL_L,     62, 19, true,  {C_BG_CYAN, C_BG_WHITE},                        {C_FG_CYAN,  C_FG_WHITE}     };
 asciiL logo_intel_l_new = { ASCII_INTEL_L_NEW, 57, 14, true,  {C_BG_CYAN, C_BG_WHITE, C_BG_BLUE},             {C_FG_CYAN,  C_FG_WHITE}     };
@@ -468,6 +578,7 @@ asciiL logo_arm_l       = { ASCII_ARM_L,       60,  8, true,  {C_BG_CYAN},
 asciiL logo_ibm_l       = { ASCII_IBM_L,       62, 13, true,  {C_BG_CYAN, C_FG_WHITE},                        {C_FG_CYAN,  C_FG_WHITE}     };
 asciiL logo_starfive_l  = { ASCII_STARFIVE_L,  50, 22, false, {C_FG_WHITE},                                   {C_FG_WHITE, C_FG_BLUE}      };
 asciiL logo_sifive_l    = { ASCII_SIFIVE_L,    53, 21, true,  {C_BG_WHITE, C_BG_BLACK},                       {C_FG_WHITE, C_FG_CYAN}      };
 asciiL logo_nvidia_l    = { ASCII_NVIDIA_L,    50, 15, false, {C_FG_GREEN, C_FG_WHITE},                       {C_FG_WHITE, C_FG_GREEN}     };
 asciiL logo_unknown     = { NULL,               0,  0, false, {COLOR_NONE},                                   {COLOR_NONE, COLOR_NONE}     };
 #endif
--- a/src/common/cpu.c
+++ b/src/common/cpu.c
@@ -145,17 +145,25 @@ char* get_str_l3(struct cache* cach) {
 char* get_str_freq(struct frequency* freq) {
  //Max 3 digits and 3 for '(M/G)Hz' plus 1 for '\0'
-  uint32_t size = (5+1+3+1);
+  uint32_t size = (1+5+1+3+1);
  assert(strlen(STRING_UNKNOWN)+1 <= size);
-  char* string = emalloc(sizeof(char)*size);
+  char* string = ecalloc(size, sizeof(char));
  memset(string, 0, sizeof(char)*size);
-  if(freq->max == UNKNOWN_DATA || freq->max < 0)
+  if(freq->max == UNKNOWN_DATA || freq->max < 0) {
    snprintf(string,strlen(STRING_UNKNOWN)+1,STRING_UNKNOWN);
-  else if(freq->max >= 1000)
+  }
  else if(freq->max >= 1000) {
    if (freq->measured)
      snprintf(string,size,"~%.3f "STRING_GIGAHERZ,(float)(freq->max)/1000);
    else
      snprintf(string,size,"%.3f "STRING_GIGAHERZ,(float)(freq->max)/1000);
  }
  else {
    if (freq->measured)
      snprintf(string,size,"~%d "STRING_MEGAHERZ,freq->max);
    else
      snprintf(string,size,"%d "STRING_MEGAHERZ,freq->max);
  }
  return string;
 }
@@ -194,7 +202,7 @@ void init_topology_struct(struct topology* topo, struct cache* cach) {
  topo->sockets = 0;
 #ifdef ARCH_X86
  topo->smt_available = 0;
-  topo->apic = emalloc(sizeof(struct apic));
+  topo->apic = ecalloc(1, sizeof(struct apic));
 #endif
 #endif
 }
--- a/src/common/cpu.h
+++ b/src/common/cpu.h
@@ -8,6 +8,7 @@ enum {
 // ARCH_X86
  CPU_VENDOR_INTEL,
  CPU_VENDOR_AMD,
  CPU_VENDOR_HYGON,
 // ARCH_ARM
  CPU_VENDOR_ARM,
  CPU_VENDOR_APPLE,
@@ -16,7 +17,7 @@ enum {
  CPU_VENDOR_NVIDIA,
  CPU_VENDOR_APM,
  CPU_VENDOR_QUALCOMM,
-  CPU_VENDOR_HUAWUEI,
+  CPU_VENDOR_HUAWEI,
  CPU_VENDOR_SAMSUNG,
  CPU_VENDOR_MARVELL,
  CPU_VENDOR_PHYTIUM,
@@ -32,18 +33,21 @@ enum {
 enum {
  HV_VENDOR_KVM,
  HV_VENDOR_QEMU,
  HV_VENDOR_VBOX,
  HV_VENDOR_HYPERV,
  HV_VENDOR_VMWARE,
  HV_VENDOR_XEN,
  HV_VENDOR_PARALLELS,
  HV_VENDOR_PHYP,
  HV_VENDOR_BHYVE,
  HV_VENDOR_APPLEVZ,
  HV_VENDOR_INVALID
 };
 enum {
  CORE_TYPE_EFFICIENCY,
  CORE_TYPE_PERFORMANCE,
  CORE_TYPE_EFFICIENCY,
  CORE_TYPE_LP_EFFICIENCY,
  CORE_TYPE_UNKNOWN
 };
@@ -55,6 +59,8 @@ typedef int32_t VENDOR;
 struct frequency {
  int32_t base;
  int32_t max;
  // Indicates if max frequency was measured
  bool measured;
 };
 struct hypervisor {
--- a/src/common/freq.c
+++ b/src/common/freq.c
@@ -0,0 +1,195 @@
 #ifdef __linux__
 #define _GNU_SOURCE
 #include <time.h>
 #include <stdio.h>
 #include <stdint.h>
 #include <string.h>
 #include <errno.h>
 #include <unistd.h>
 #include <asm/unistd.h>
 #include <sys/ioctl.h>
 #include <linux/perf_event.h>
 #include "global.h"
 #include "cpu.h"
 static long
 perf_event_open(struct perf_event_attr *hw_event, pid_t pid,
                int cpu, int group_fd, unsigned long flags) {
    int ret;
    ret = syscall(__NR_perf_event_open, hw_event, pid, cpu,
                    group_fd, flags);
    return ret;
 }
 #define INSERT_ASM_ONCE __asm volatile("nop");
 #define INSERT_ASM_10_TIMES \
    INSERT_ASM_ONCE         \
    INSERT_ASM_ONCE         \
    INSERT_ASM_ONCE         \
    INSERT_ASM_ONCE         \
    INSERT_ASM_ONCE         \
    INSERT_ASM_ONCE         \
    INSERT_ASM_ONCE         \
    INSERT_ASM_ONCE         \
    INSERT_ASM_ONCE         \
    INSERT_ASM_ONCE         \
 #define INSERT_ASM_100_TIMES \
    INSERT_ASM_10_TIMES      \
    INSERT_ASM_10_TIMES      \
    INSERT_ASM_10_TIMES      \
    INSERT_ASM_10_TIMES      \
    INSERT_ASM_10_TIMES      \
    INSERT_ASM_10_TIMES      \
    INSERT_ASM_10_TIMES      \
    INSERT_ASM_10_TIMES      \
    INSERT_ASM_10_TIMES      \
    INSERT_ASM_10_TIMES
 #define INSERT_ASM_1000_TIMES \
    INSERT_ASM_100_TIMES     \
    INSERT_ASM_100_TIMES     \
    INSERT_ASM_100_TIMES     \
    INSERT_ASM_100_TIMES     \
    INSERT_ASM_100_TIMES     \
    INSERT_ASM_100_TIMES     \
    INSERT_ASM_100_TIMES     \
    INSERT_ASM_100_TIMES     \
    INSERT_ASM_100_TIMES     \
    INSERT_ASM_100_TIMES     \
 void nop_function(uint64_t iters) {
  for (uint64_t i = 0; i < iters; i++) {
    INSERT_ASM_1000_TIMES
    INSERT_ASM_1000_TIMES
    INSERT_ASM_1000_TIMES
    INSERT_ASM_1000_TIMES
  }
 }
 // Run the nop_function with the number of iterations specified and
 // measure both the time and number of cycles
 int measure_freq_iters(uint64_t iters, uint32_t core, double* freq) {
  clockid_t clock = CLOCK_PROCESS_CPUTIME_ID;
  struct timespec start, end;
  struct perf_event_attr pe;
  uint64_t cycles;
  int fd;
  int pid = 0;
  memset(&pe, 0, sizeof(struct perf_event_attr));
  pe.type = PERF_TYPE_HARDWARE;
  pe.size = sizeof(struct perf_event_attr);
  pe.config = PERF_COUNT_HW_CPU_CYCLES;
  pe.disabled = 1;
  pe.exclude_kernel = 1;
  pe.exclude_hv = 1;
  fd = perf_event_open(&pe, pid, core, -1, 0);
  if (fd == -1) {
    perror("perf_event_open");
    if (errno == EPERM || errno == EACCES) {
      printErr("You may not have permission to collect stats.\n"\
      "Consider tweaking /proc/sys/kernel/perf_event_paranoid or running as root");
    }
    return -1;
  }
  if (clock_gettime(clock, &start) == -1) {
    perror("clock_gettime");
    return -1;
  }
  if(ioctl(fd, PERF_EVENT_IOC_RESET, 0) == -1) {
    perror("ioctl");
    return -1;
  }
  if(ioctl(fd, PERF_EVENT_IOC_ENABLE, 0) == -1) {
    perror("ioctl");
    return -1;
  }
  nop_function(iters);
  ssize_t ret = read(fd, &cycles, sizeof(uint64_t));
  if (ret == -1) {
    perror("read");
    return -1;
  }
  if (ret != sizeof(uint64_t)) {
    printErr("Read returned %d, expected %d", ret, sizeof(uint64_t));
    return -1;
  }
  if(ioctl(fd, PERF_EVENT_IOC_DISABLE, 0) == -1) {
    perror("ioctl");
    return -1;
  }
  if (clock_gettime(clock, &end) == -1) {
    perror("clock_gettime");
    return -1;
  }
  uint64_t nsecs = (end.tv_sec*1e9 + end.tv_nsec) - (start.tv_sec*1e9 + start.tv_nsec);
  uint64_t usecs = nsecs/1000;  
  *freq = cycles/((double)usecs);
  return 0;
 }
 // Return a good number of iterations to run the nop_function in
 // order to get a precise measurement of the frequency without taking
 // too much time.
 uint64_t get_num_iters_from_freq(double frequency) {
  // Truncate to reduce variability
  uint64_t freq_trunc = ((uint64_t) frequency / 100) * 100;
  uint64_t osp_per_iter = 4 * 1000;
  return freq_trunc * 1e7 * 1/osp_per_iter;
 }
 // Differences between x86 measure_frequency and this measure_max_frequency:
 // - measure_frequency employs all cores simultaneously whereas
 //   measure_max_frequency only employs 1.
 // - measure_frequency runs the computation and checks /proc/cpuinfo whereas
 //   measure_max_frequency does not rely on /proc/cpuinfo and simply
 //   counts cpu cycles to measure frequency.
 // - measure_frequency uses actual computation while measuring the frequency
 //   whereas measure_max_frequency uses nop instructions. This makes the former
 //   x86 dependant whereas the latter is architecture independant.
 int64_t measure_max_frequency(uint32_t core) {
  if (!bind_to_cpu(core)) {
    printErr("Failed binding the process to CPU %d", core);
    return UNKNOWN_DATA;
  }
  // First, get very rough estimation of clock cycle to
  // compute a reasonable value for the iterations
  double estimation_freq, frequency;
  uint64_t iters = 100000;
  if (measure_freq_iters(iters, core, &estimation_freq) == -1)
    return UNKNOWN_DATA;
  if (estimation_freq <= 0.0) {
    printErr("First frequency measurement yielded an invalid value: %f", estimation_freq);
    return UNKNOWN_DATA;
  }
  iters = get_num_iters_from_freq(estimation_freq);
  printWarn("Running frequency measurement with %ld iterations on core %d...", iters, core);
  // Now perform actual measurement
  const char* frequency_banner = "cpufetch is measuring the max frequency...";
  printf("%s", frequency_banner);
  fflush(stdout);
  if (measure_freq_iters(iters, core, &frequency) == -1)
    return UNKNOWN_DATA;
  // Clean screen once measurement is finished
  printf("\r%*c\r", (int) strlen(frequency_banner), ' ');
  // Discard last digit in the frequency, which should help providing
  // more reliable and predictable values.
  return (((int) frequency + 5)/10) * 10;
 }
 #endif // #ifdef __linux__
--- a/src/common/freq.h
+++ b/src/common/freq.h
@@ -0,0 +1,6 @@
 #ifndef __COMMON_FREQ__
 #define __COMMON_FREQ__
 int64_t measure_max_frequency(uint32_t core);
 #endif
--- a/src/common/global.c
+++ b/src/common/global.c
@@ -1,3 +1,14 @@
 #ifdef _WIN32
  #define NOMINMAX
  #include <windows.h>
 #elif defined __linux__
  #define _GNU_SOURCE
  #include <sched.h>
 #elif defined __FreeBSD__
  #include <sys/param.h>
  #include <sys/cpuset.h>
 #endif
 #include <stdarg.h>
 #include <stdio.h>
 #include <stdlib.h>
@@ -21,7 +32,7 @@
 #endif
 #ifdef ARCH_X86
-  static const char* ARCH_STR = "x86_64 build";
+  static const char* ARCH_STR = "x86 / x86_64 build";
  #include "../x86/cpuid.h"
 #elif ARCH_PPC
  static const char* ARCH_STR = "PowerPC build";
@@ -51,7 +62,7 @@
 #endif
 #ifndef GIT_FULL_VERSION
-  static const char* VERSION = "1.04";
+  static const char* VERSION = "1.05";
 #endif
 enum {
@@ -61,6 +72,14 @@ enum {
 int LOG_LEVEL;
 void printBugMessage(FILE *restrict stream) {
  #if defined(ARCH_X86) || defined(ARCH_PPC)
    fprintf(stream, "Please, create a new issue with this error message, the output of 'cpufetch' and 'cpufetch --debug' on https://github.com/Dr-Noob/cpufetch/issues\n");
  #elif ARCH_ARM
    fprintf(stream, "Please, create a new issue with this error message, your smartphone/computer model, the output of 'cpufetch --verbose' and 'cpufetch --debug' on https://github.com/Dr-Noob/cpufetch/issues\n");
  #endif
 }
 void printWarn(const char *fmt, ...) {
  if(LOG_LEVEL == LOG_LEVEL_VERBOSE) {
    int buffer_size = 4096;
@@ -95,10 +114,40 @@ void printBug(const char *fmt, ...) {
  fprintf(stderr,RED "[ERROR]: "RESET "%s\n",buffer);
  fprintf(stderr,"[VERSION]: ");
  print_version(stderr);
-#if defined(ARCH_X86) || defined(ARCH_PPC)
+  printBugMessage(stderr);
-  fprintf(stderr, "Please, create a new issue with this error message, the output of 'cpufetch' and 'cpufetch --debug' on https://github.com/Dr-Noob/cpufetch/issues\n");
+}
-#elif ARCH_ARM
+
-  fprintf(stderr, "Please, create a new issue with this error message, your smartphone/computer model, the output of 'cpufetch --verbose' and 'cpufetch --debug' on https://github.com/Dr-Noob/cpufetch/issues\n");
+bool isReleaseVersion(char *git_full_version) {
  return strstr(git_full_version, "-") == NULL;
 }
 /// The unknown uarch errors are by far the most common error a user will encounter.
 /// Rather than using the generic printBug function, which asks the user to report
 /// the problem on the issues webpage, this function will check if the program is
 /// the release version. In such case, support for this feature is most likely already
 /// in the last version, so just tell the user to compile that one and not report this
 /// in github.
 void printBugCheckRelease(const char *fmt, ...) {
  int buffer_size = 4096;
  char buffer[buffer_size];
  va_list args;
  va_start(args, fmt);
  vsnprintf(buffer,buffer_size, fmt, args);
  va_end(args);
  fprintf(stderr, RED "[ERROR]: "RESET "%s\n", buffer);
  fprintf(stderr, "[VERSION]: ");
  print_version(stderr);
 #ifdef GIT_FULL_VERSION
  if (isReleaseVersion(GIT_FULL_VERSION)) {
    fprintf(stderr, RED "[ERROR]: "RESET "You are using an outdated version of cpufetch. Please compile cpufetch from source (see https://github.com/Dr-Noob/cpufetch?tab=readme-ov-file#22-building-from-source)");
  }
  else {
    printBugMessage(stderr);
  }
 #else
  printBugMessage(stderr);
 #endif
 }
@@ -161,6 +210,34 @@ void* erealloc(void *ptr, size_t size) {
  return newptr;
 }
 #ifndef __APPLE__
 bool bind_to_cpu(int cpu_id) {
  #ifdef _WIN32
    HANDLE process = GetCurrentProcess();
    DWORD_PTR processAffinityMask = 1 << cpu_id;
    return SetProcessAffinityMask(process, processAffinityMask);
  #elif defined __linux__
    cpu_set_t currentCPU;
    CPU_ZERO(&currentCPU);
    CPU_SET(cpu_id, &currentCPU);
    if (sched_setaffinity (0, sizeof(currentCPU), &currentCPU) == -1) {
      printWarn("sched_setaffinity: %s", strerror(errno));
      return false;
    }
    return true;
  #elif defined __FreeBSD__
    cpuset_t currentCPU;
    CPU_ZERO(&currentCPU);
    CPU_SET(cpu_id, &currentCPU);
    if(cpuset_setaffinity(CPU_LEVEL_WHICH, CPU_WHICH_TID, -1, sizeof(cpuset_t), &currentCPU) == -1) {
      printWarn("cpuset_setaffinity: %s", strerror(errno));
      return false;
    }
    return true;
  #endif
 }
 #endif
 void print_version(FILE *restrict stream) {
 #ifdef GIT_FULL_VERSION
  fprintf(stream, "cpufetch %s (%s %s)\n", GIT_FULL_VERSION, OS_STR, ARCH_STR);
--- a/src/common/global.h
+++ b/src/common/global.h
@@ -12,12 +12,16 @@ void set_log_level(bool verbose);
 void printWarn(const char *fmt, ...);
 void printErr(const char *fmt, ...);
 void printBug(const char *fmt, ...);
 void printBugCheckRelease(const char *fmt, ...);
 int min(int a, int b);
 int max(int a, int b);
 char *strremove(char *str, const char *sub);
 void* emalloc(size_t size);
 void* ecalloc(size_t nmemb, size_t size);
 void* erealloc(void *ptr, size_t size);
 #ifndef __APPLE__
 bool bind_to_cpu(int cpu_id);
 #endif
 void print_version(FILE *restrict stream);
 #endif
--- a/src/common/main.c
+++ b/src/common/main.c
@@ -30,11 +30,17 @@ void print_help(char *argv[]) {
 #ifdef ARCH_X86
 #ifdef __linux__
  printf("      --%s %*s Compute the peak performance accurately (measure the CPU frequency instead of using the maximum)\n", t[ARG_ACCURATE_PP], (int) (max_len-strlen(t[ARG_ACCURATE_PP])), "");
-#endif
+  printf("      --%s %*s Measure the max CPU frequency instead of reading it\n", t[ARG_MEASURE_MAX_FREQ], (int) (max_len-strlen(t[ARG_MEASURE_MAX_FREQ])), "");
 #endif // __linux__
  printf("      --%s %*s Show the old Intel logo\n", t[ARG_LOGO_INTEL_OLD], (int) (max_len-strlen(t[ARG_LOGO_INTEL_OLD])), "");
  printf("      --%s %*s Show the new Intel logo\n", t[ARG_LOGO_INTEL_NEW], (int) (max_len-strlen(t[ARG_LOGO_INTEL_NEW])), "");
  printf("  -%c, --%s %*s Show the full CPU name (do not abbreviate it)\n", c[ARG_FULLCPUNAME], t[ARG_FULLCPUNAME], (int) (max_len-strlen(t[ARG_FULLCPUNAME])), "");
  printf("  -%c, --%s %*s Print raw cpuid data (debug purposes)\n", c[ARG_RAW], t[ARG_RAW], (int) (max_len-strlen(t[ARG_RAW])), "");
 #endif // ARCH_X86
 #ifdef ARCH_ARM
 #ifdef __linux__
  printf("      --%s %*s Measure the max CPU frequency instead of reading it\n", t[ARG_MEASURE_MAX_FREQ], (int) (max_len-strlen(t[ARG_MEASURE_MAX_FREQ])), "");
 #endif
 #endif
  printf("  -%c, --%s %*s Print this help and exit\n", c[ARG_HELP], t[ARG_HELP], (int) (max_len-strlen(t[ARG_HELP])), "");
  printf("  -%c, --%s %*s Print cpufetch version and exit\n", c[ARG_VERSION], t[ARG_VERSION], (int) (max_len-strlen(t[ARG_VERSION])), "");
@@ -45,7 +51,7 @@ void print_help(char *argv[]) {
  printf("  * \"amd\":       Use AMD color scheme \n");
  printf("  * \"ibm\",       Use IBM color scheme \n");
  printf("  * \"arm\":       Use ARM color scheme \n");
-  printf("  * \"rockchip\":  Use ARM color scheme \n");
+  printf("  * \"rockchip\":  Use Rockchip color scheme \n");
  printf("  * \"sifive\":    Use SiFive color scheme \n");
  printf("  * custom:      If the argument of --color does not match any of the previous strings, a custom scheme can be specified.\n");
  printf("                 5 colors must be given in RGB with the format: R,G,B:R,G,B:...\n");
@@ -80,6 +86,11 @@ void print_help(char *argv[]) {
  printf("    --accurate-pp option, which will measure the AVX frequency and show a more precise estimation\n");
  printf("    (this option is only available in x86 architectures).\n");
  printf("    To precisely measure peak performance, see: https://github.com/Dr-Noob/peakperf\n");
  printf("\n");
  printf("    Both --accurate-pp and --measure-max-freq measure the actual frequency of the CPU. However,\n");
  printf("    they differ slightly. The former measures the max frequency while running vectorized SSE/AVX\n");
  printf("    instructions and it is thus x86 only, whereas the latter simply measures the max clock cycle\n");
  printf("    and is architecture independent.\n");
 }
 int main(int argc, char* argv[]) {
--- a/src/common/pci.c
+++ b/src/common/pci.c
@@ -0,0 +1,178 @@
 #define _GNU_SOURCE
 #include <sys/stat.h>
 #include <dirent.h>
 #include "udev.h"
 #include "global.h"
 #include "pci.h"
 #ifndef PATH_MAX
  #define PATH_MAX 1024
 #endif
 #define PCI_PATH "/sys/bus/pci/devices/"
 #define MAX_LENGTH_PCI_DIR_NAME 1024
 /*
 * doc: https://wiki.osdev.org/PCI#Class_Codes
 *      https://pci-ids.ucw.cz/read/PC
 */
 #define PCI_VENDOR_ID_AMD    0x1002
 #define CLASS_VGA_CONTROLLER 0x0300
 #define CLASS_3D_CONTROLLER  0x0302
 // Return a list of PCI devices containing only
 // the sysfs path
 struct pci_devices * get_pci_paths(void) {
  DIR *dirp;
  if ((dirp = opendir(PCI_PATH)) == NULL) {
    perror("opendir");
    return NULL;
  }
  struct dirent *dp;
  int numDirs = 0;  
  errno = 0;
  while ((dp = readdir(dirp)) != NULL) {
    if (strcmp(dp->d_name, ".") != 0 && strcmp(dp->d_name, "..") != 0)
      numDirs++;
  }  
  if (errno != 0) {
    perror("readdir");
    return NULL;
  }
  rewinddir(dirp);
  struct pci_devices * pci = emalloc(sizeof(struct pci_devices));
  pci->num_devices = numDirs;
  pci->devices = emalloc(sizeof(struct pci_device) * pci->num_devices);
  char * full_path = emalloc(PATH_MAX * sizeof(char));
  struct stat stbuf;
  int i = 0;
  while ((dp = readdir(dirp)) != NULL) {
    if (strcmp(dp->d_name, ".") == 0 || strcmp(dp->d_name, "..") == 0)
      continue;
    if (strlen(dp->d_name) > MAX_LENGTH_PCI_DIR_NAME) {
      printErr("Directory name is too long: %s", dp->d_name);
      return NULL;
    }
    memset(full_path, 0, PATH_MAX * sizeof(char));
    snprintf(full_path, min(strlen(PCI_PATH) + strlen(dp->d_name) + 1, PATH_MAX), "%s%s", PCI_PATH, dp->d_name);    
    if (stat(full_path, &stbuf) == -1) {
      perror("stat");
      return NULL;
    }
    if ((stbuf.st_mode & S_IFMT) == S_IFDIR) {
      int strLen = min(MAX_LENGTH_PCI_DIR_NAME, strlen(dp->d_name)) + 1;
      pci->devices[i] = emalloc(sizeof(struct pci_device));
      pci->devices[i]->path = ecalloc(sizeof(char), strLen);
      strncpy(pci->devices[i]->path, dp->d_name, strLen);
      i++;
    }        
  }
  if (errno != 0) {
    perror("readdir");
    return NULL;
  }
  return pci;
 }
 // For each PCI device in the list pci, fetch its vendor and 
 // device id using sysfs (e.g., /sys/bus/pci/devices/XXX/{vendor/device})
 void populate_pci_devices(struct pci_devices * pci) {
  int filelen;
  char* buf;
  for (int i=0; i < pci->num_devices; i++) {
    struct pci_device* dev = pci->devices[i];
    int path_size = strlen(PCI_PATH) + strlen(dev->path) + 2;
    // Read vendor_id
    char *vendor_id_path = emalloc(sizeof(char) * (path_size + strlen("vendor")));
    sprintf(vendor_id_path, "%s/%s/%s", PCI_PATH, dev->path, "vendor");
    if ((buf = read_file(vendor_id_path, &filelen)) == NULL) {
      printWarn("read_file: %s: %s\n", vendor_id_path, strerror(errno));
      dev->vendor_id = 0;
    }
    else {
      dev->vendor_id = strtol(buf, NULL, 16);
    }
    // Read device_id
    char *device_id_path = emalloc(sizeof(char) * (path_size + strlen("device")));
    sprintf(device_id_path, "%s/%s/%s", PCI_PATH, dev->path, "device");
    if ((buf = read_file(device_id_path, &filelen)) == NULL) {
      printWarn("read_file: %s: %s\n", device_id_path, strerror(errno));
      dev->device_id = 0;
    }
    else {
      dev->device_id = strtol(buf, NULL, 16);
    }
    free(vendor_id_path);
    free(device_id_path);
  }
 }
 // Right now, we are interested in PCI devices which
 // vendor is NVIDIA (to be extended in the future).
 // Should we also restrict to VGA controllers only?
 bool pci_device_is_useful(struct pci_device* dev) {
  return dev->vendor_id == PCI_VENDOR_NVIDIA;
 }
 // Filter the input list in order to get only those PCI devices which 
 // we are interested in (decided by pci_device_is_useful)
 // and return the filtered result.
 struct pci_devices * filter_pci_devices(struct pci_devices * pci) {
  int * devices_to_get = emalloc(sizeof(int) * pci->num_devices);
  int dev_ptr = 0;
  for (int i=0; i < pci->num_devices; i++) {
    if (pci_device_is_useful(pci->devices[i])) {
      devices_to_get[dev_ptr] = i;
      dev_ptr++;
    }
  }
  struct pci_devices * pci_filtered = emalloc(sizeof(struct pci_devices));
  pci_filtered->num_devices = dev_ptr;
  if (pci_filtered->num_devices == 0) {
    pci_filtered->devices = NULL;
  }
  else {
    pci_filtered->devices = emalloc(sizeof(struct pci_device) * pci_filtered->num_devices);  
    for (int i=0; i < pci_filtered->num_devices; i++)
      pci_filtered->devices[i] = pci->devices[devices_to_get[i]];
  }
  return pci_filtered;
 }
 // Return a list of PCI devices that could be used to infer the SoC.
 // The criteria to determine which devices are suitable for this task
 // is decided in filter_pci_devices.
 struct pci_devices * get_pci_devices(void) {
  struct pci_devices * pci = get_pci_paths();
  if (pci == NULL)
    return NULL;
  populate_pci_devices(pci);  
  return filter_pci_devices(pci);
 }
--- a/src/common/pci.h
+++ b/src/common/pci.h
@@ -0,0 +1,20 @@
 #ifndef __PCI__
 #define __PCI__
 #define PCI_VENDOR_NVIDIA 0x10de
 #define PCI_DEVICE_TEGRA_X1 0x0faf
 struct pci_device {
  char * path;
  uint16_t vendor_id;
  uint16_t device_id;
 };
 struct pci_devices {
  struct pci_device ** devices;
  int num_devices;
 };
 struct pci_devices * get_pci_devices(void);
 #endif
--- a/src/common/printer.c
+++ b/src/common/printer.c
@@ -61,6 +61,7 @@ enum {
  ATTRIBUTE_NCORES,
  ATTRIBUTE_NCORES_DUAL,
 #ifdef ARCH_X86
  ATTRIBUTE_SSE,
  ATTRIBUTE_AVX,
  ATTRIBUTE_FMA,
 #elif ARCH_PPC
@@ -96,6 +97,7 @@ static const char* ATTRIBUTE_FIELDS [] = {
  "Cores:",
  "Cores (Total):",
 #ifdef ARCH_X86
  "SSE:",
  "AVX:",
  "FMA:",
 #elif ARCH_PPC
@@ -131,6 +133,7 @@ static const char* ATTRIBUTE_FIELDS_SHORT [] = {
  "Cores:",
  "Cores (Total):",
 #ifdef ARCH_X86
  "SSE:",
  "AVX:",
  "FMA:",
 #elif ARCH_PPC
@@ -336,6 +339,13 @@ struct ascii_logo* choose_ascii_art_aux(struct ascii_logo* logo_long, struct asc
  }
 }
 // https://no-color.org/
 bool is_color_enabled(void) {
  const char *var_name = "NO_COLOR";
  char *no_color = getenv(var_name);
  return no_color == NULL || no_color[0] == '\0';
 }
 void choose_ascii_art(struct ascii* art, struct color** cs, struct terminal* term, int lf) {
  // 1. Choose logo
 #ifdef ARCH_X86
@@ -350,6 +360,9 @@ void choose_ascii_art(struct ascii* art, struct color** cs, struct terminal* ter
  else if(art->vendor == CPU_VENDOR_AMD) {
    art->art = choose_ascii_art_aux(&logo_amd_l, &logo_amd, term, lf);
  }
  else if(art->vendor == CPU_VENDOR_HYGON) {
    art->art = &logo_hygon;
  }
  else {
    art->art = &logo_unknown;
  }
@@ -364,14 +377,20 @@ void choose_ascii_art(struct ascii* art, struct color** cs, struct terminal* ter
    art->art = &logo_exynos;
  else if(art->vendor == SOC_VENDOR_KIRIN)
    art->art = &logo_kirin;
  else if(art->vendor == SOC_VENDOR_KUNPENG)
    art->art = &logo_kunpeng;
  else if(art->vendor == SOC_VENDOR_BROADCOM)
    art->art = &logo_broadcom;
  else if(art->vendor == SOC_VENDOR_APPLE)
    art->art = &logo_apple;
  else if(art->vendor == SOC_VENDOR_GOOGLE)
    art->art = &logo_google;
  else if(art->vendor == SOC_VENDOR_ALLWINNER)
    art->art = &logo_allwinner;
  else if(art->vendor == SOC_VENDOR_ROCKCHIP)
    art->art = &logo_rockchip;
  else if(art->vendor == SOC_VENDOR_NVIDIA)
    art->art = choose_ascii_art_aux(&logo_nvidia_l, &logo_nvidia, term, lf);
  else {
    art->art = choose_ascii_art_aux(&logo_arm_l, &logo_arm, term, lf);
  }
@@ -382,12 +401,17 @@ void choose_ascii_art(struct ascii* art, struct color** cs, struct terminal* ter
    art->art = choose_ascii_art_aux(&logo_starfive_l, &logo_starfive, term, lf);
  else if(art->vendor == SOC_VENDOR_ALLWINNER)
    art->art = &logo_allwinner;
  else if(art->vendor == SOC_VENDOR_SIPEED)
    art->art = &logo_sipeed;
  else
    art->art = &logo_riscv;
 #endif
  // 2. Choose colors
  struct ascii_logo* logo = art->art;
  bool color = is_color_enabled();
  if (!color)
    art->style = STYLE_LEGACY;
  switch(art->style) {
    case STYLE_LEGACY:
@@ -573,6 +597,7 @@ bool print_cpufetch_x86(struct cpuInfo* cpu, STYLE s, struct color** cs, struct
  for(int i = 0; i < cpu->num_cpus; ptr = ptr->next_cpu, i++) {
    char* max_frequency = get_str_freq(ptr->freq);
    char* avx = get_str_avx(ptr);
    char* sse = get_str_sse(ptr);
    char* fma = get_str_fma(ptr);
    char* cpu_num = emalloc(sizeof(char) * 9);
@@ -589,8 +614,9 @@ bool print_cpufetch_x86(struct cpuInfo* cpu, STYLE s, struct color** cs, struct
    }
    if(hybrid_architecture) {
-      if(ptr->core_type == CORE_TYPE_EFFICIENCY) sprintf(cpu_num, "E-cores:");
+      if (ptr->core_type == CORE_TYPE_PERFORMANCE) sprintf(cpu_num, "P-cores:");
-      else if(ptr->core_type == CORE_TYPE_PERFORMANCE) sprintf(cpu_num, "P-cores:");
+      else if (ptr->core_type == CORE_TYPE_EFFICIENCY) sprintf(cpu_num, "E-cores:");
      else if (ptr->core_type == CORE_TYPE_LP_EFFICIENCY) sprintf(cpu_num, "LP-E-cores:");
      else printBug("Found invalid core type!\n");
      setAttribute(art, ATTRIBUTE_CPU_NUM, cpu_num);
@@ -607,8 +633,17 @@ bool print_cpufetch_x86(struct cpuInfo* cpu, STYLE s, struct color** cs, struct
        setAttribute(art, ATTRIBUTE_NCORES, n_cores);
      }
    }
    // Show the most modern vector instructions.
    // If AVX is supported show it, otherwise show SSE
    if (strcmp(avx, "No") == 0) {
      setAttribute(art, ATTRIBUTE_SSE, sse);
    }
    else {
      setAttribute(art, ATTRIBUTE_AVX, avx);
      setAttribute(art, ATTRIBUTE_FMA, fma);
    }
    if(l1i != NULL) setAttribute(art, ATTRIBUTE_L1i, l1i);
    if(l1d != NULL) setAttribute(art, ATTRIBUTE_L1d, l1d);
    if(l2 != NULL) setAttribute(art, ATTRIBUTE_L2, l2);
--- a/src/common/soc.c
+++ b/src/common/soc.c
@@ -15,12 +15,16 @@ static char* soc_trademark_string[] = {
  [SOC_VENDOR_MEDIATEK]   = "MediaTek ",
  [SOC_VENDOR_EXYNOS]     = "Exynos ",
  [SOC_VENDOR_KIRIN]      = "Kirin ",
  [SOC_VENDOR_KUNPENG]    = "Kunpeng ",
  [SOC_VENDOR_BROADCOM]   = "Broadcom BCM",
  [SOC_VENDOR_APPLE]      = "Apple ",
  [SOC_VENDOR_ROCKCHIP]   = "Rockchip ",
  [SOC_VENDOR_GOOGLE]     = "Google ",
  [SOC_VENDOR_NVIDIA]     = "NVIDIA ",
  // RISC-V
  [SOC_VENDOR_SIFIVE]     = "SiFive ",
  [SOC_VENDOR_STARFIVE]   = "StarFive ",
  [SOC_VENDOR_SIPEED]     = "Sipeed ",
  // ARM & RISC-V
  [SOC_VENDOR_ALLWINNER]  = "Allwinner "
 };
--- a/src/common/soc.h
+++ b/src/common/soc.h
@@ -19,12 +19,16 @@ enum {
  SOC_VENDOR_MEDIATEK,
  SOC_VENDOR_EXYNOS,
  SOC_VENDOR_KIRIN,
  SOC_VENDOR_KUNPENG,
  SOC_VENDOR_BROADCOM,
  SOC_VENDOR_APPLE,
  SOC_VENDOR_ROCKCHIP,
  SOC_VENDOR_GOOGLE,
  SOC_VENDOR_NVIDIA,
  // RISC-V
  SOC_VENDOR_SIFIVE,
  SOC_VENDOR_STARFIVE,
  SOC_VENDOR_SIPEED,
  // ARM & RISC-V
  SOC_VENDOR_ALLWINNER
 };
@@ -37,7 +41,7 @@ struct system_on_chip {
  char* raw_name;
 };
-struct system_on_chip* get_soc(void);
+struct system_on_chip* get_soc(struct cpuInfo* cpu);
 char* get_soc_name(struct system_on_chip* soc);
 VENDOR get_soc_vendor(struct system_on_chip* soc);
 bool match_soc(struct system_on_chip* soc, char* raw_name, char* expected_name, char* soc_name, SOC soc_model, int32_t process);
--- a/src/common/sysctl.c
+++ b/src/common/sysctl.c
@@ -4,8 +4,8 @@
 #include <string.h>
 #include <errno.h>
-#include "../common/global.h"
+#include "global.h"
-#include "../common/cpu.h"
+#include "cpu.h"
 uint32_t get_sys_info_by_name(char* name) {
  size_t size = 0;
--- a/src/common/sysctl.h
+++ b/src/common/sysctl.h
@@ -8,6 +8,9 @@
 // APPLE_CPU_PART_M2_BLIZZARD=0x30,M2_AVALANCHE=0x31
 #define MIDR_APPLE_M2_BLIZZARD  0x610F0300
 #define MIDR_APPLE_M2_AVALANCHE 0x610F0310
 // https://github.com/AsahiLinux/m1n1/blob/main/src/chickens.c
 #define MIDR_APPLE_M3_SAWTOOTH  0x610F0480
 #define MIDR_APPLE_M3_EVEREST   0x610F0490
 // M1 / A14
 #ifndef CPUFAMILY_ARM_FIRESTORM_ICESTORM
@@ -17,6 +20,12 @@
 #ifndef CPUFAMILY_ARM_AVALANCHE_BLIZZARD
  #define CPUFAMILY_ARM_AVALANCHE_BLIZZARD 0xDA33D83D
 #endif
 // M3 / A16 / A17
 // https://ratfactor.com/zig/stdlib-browseable2/c/darwin.zig.html
 // https://github.com/Dr-Noob/cpufetch/issues/210
 #define CPUFAMILY_ARM_EVEREST_SAWTOOTH     0x8765EDEA
 #define CPUFAMILY_ARM_EVEREST_SAWTOOTH_PRO 0x5F4DEA93
 #define CPUFAMILY_ARM_EVEREST_SAWTOOTH_MAX 0x72015832
 // For detecting different M1 types
 // NOTE: Could also be achieved detecting different
--- a/src/ppc/ppc.c
+++ b/src/ppc/ppc.c
@@ -14,12 +14,14 @@
 static char *hv_vendors_name[] = {
  [HV_VENDOR_KVM]       = "KVM",
  [HV_VENDOR_QEMU]      = "QEMU",
  [HV_VENDOR_VBOX]      = "VirtualBox",
  [HV_VENDOR_HYPERV]    = "Microsoft Hyper-V",
  [HV_VENDOR_VMWARE]    = "VMware",
  [HV_VENDOR_XEN]       = "Xen",
  [HV_VENDOR_PARALLELS] = "Parallels",
  [HV_VENDOR_PHYP]      = "pHyp",
  [HV_VENDOR_BHYVE]     = "bhyve",
  [HV_VENDOR_APPLEVZ]   = "Apple VZ",
  [HV_VENDOR_INVALID]   = STRING_UNKNOWN
 };
@@ -144,6 +146,7 @@ struct uarch* get_cpu_uarch(struct cpuInfo* cpu) {
 struct frequency* get_frequency_info(void) {
  struct frequency* freq = emalloc(sizeof(struct frequency));
  freq->measured = false;
  freq->max = get_max_freq_from_file(0);
  freq->base = get_min_freq_from_file(0);
--- a/src/ppc/uarch.c
+++ b/src/ppc/uarch.c
@@ -280,9 +280,6 @@ char* get_str_process(struct cpuInfo* cpu) {
  if(process == UNK) {
    snprintf(str, strlen(STRING_UNKNOWN)+1, STRING_UNKNOWN);
  }
  else if(process > 100) {
    sprintf(str, "%.2fum", (double)process/100);
  }
  else if(process > 0){
    sprintf(str, "%dnm", process);
  }
--- a/src/riscv/riscv.c
+++ b/src/riscv/riscv.c
@@ -19,6 +19,7 @@
 struct frequency* get_frequency_info(uint32_t core) {
  struct frequency* freq = emalloc(sizeof(struct frequency));
  freq->measured = false;
  freq->base = UNKNOWN_DATA;
  freq->max = get_max_freq_from_file(core);
@@ -78,6 +79,18 @@ int parse_multi_letter_extension(struct extensions* ext, char* e) {
  return multi_letter_extension_len;
 }
 bool valid_extension(char ext) {
  bool found = false;
  uint64_t idx = 0;
  while(idx < sizeof(extension_list)/sizeof(extension_list[0]) && !found) {
    found = (extension_list[idx].id == (ext - 'a'));
    if(!found) idx++;
  }
  return found;
 }
 struct extensions* get_extensions_from_str(char* str) {
  struct extensions* ext = emalloc(sizeof(struct extensions));
  ext->mask = 0;
@@ -114,9 +127,23 @@ struct extensions* get_extensions_from_str(char* str) {
      e += multi_letter_extension_len;
    }
    else {
      // Single-letter extensions 's' and 'u' are invalid
      // according to Linux kernel (arch/riscv/kernel/cpufeature.c:
      // riscv_fill_hwcap). Optionally, we could opt for using
      // hwcap instead of cpuinfo to avoid this
      if (*e == 's' || *e == 'u') {
        continue;
      }
      // Make sure that the extension is valid before
      // adding it to the mask
      if(valid_extension(*e)) {
        int n = *e - 'a';
        ext->mask |= 1UL << n;
      }
      else {
        printBug("get_extensions_from_str: Invalid extension: '%c'", *e);
      }
    }
  }
  return ext;
@@ -137,7 +164,7 @@ struct cpuInfo* get_cpu_info(void) {
  cpu->ext = get_extensions_from_str(ext_str);
  if(cpu->ext->str != NULL && cpu->ext->mask == 0) return NULL;
  cpu->arch = get_uarch_from_cpuinfo_str(cpuinfo_str, cpu);
-  cpu->soc = get_soc();
+  cpu->soc = get_soc(cpu);
  cpu->freq = get_frequency_info(0);
  cpu->peak_performance = get_peak_performance(cpu);
--- a/src/riscv/riscv.h
+++ b/src/riscv/riscv.h
@@ -54,7 +54,6 @@ static const struct extension extension_list[] = {
  { 'v' - 'a', "(V) Vector Operations" },
  { 'n' - 'a', "(N) User-Level Interrupts" },
  { 'h' - 'a', "(H) Hypervisor" },
  { 's' - 'a', "(S) Supervisor-level Instructions" },
  // multi-letter extensions
  { RISCV_ISA_EXT_SSCOFPMF,    "(Sscofpmf) Count OverFlow and Privilege Mode Filtering" },
  { RISCV_ISA_EXT_SSTC,        "(Sstc) S and VS level Time Compare" },
--- a/src/riscv/soc.c
+++ b/src/riscv/soc.c
@@ -32,6 +32,12 @@ bool match_allwinner(char* soc_name, struct system_on_chip* soc) {
  SOC_END
 }
 bool match_sipeed(char* soc_name, struct system_on_chip* soc) {
  SOC_START
  SOC_EQ(soc_name, "light", "Lichee Pi 4A", SOC_SIPEED_LICHEEPI4A, soc, 12) // https://github.com/Dr-Noob/cpufetch/issues/200, https://sipeed.com/licheepi4a
  SOC_END
 }
 struct system_on_chip* parse_soc_from_string(struct system_on_chip* soc) {
  char* raw_name = soc->raw_name;
@@ -41,7 +47,10 @@ struct system_on_chip* parse_soc_from_string(struct system_on_chip* soc) {
  if(match_allwinner(raw_name, soc))
    return soc;
-  match_sifive(raw_name, soc);
+  if(match_sifive(raw_name, soc))
    return soc;
  match_sipeed(raw_name, soc);
  return soc;
 }
@@ -56,7 +65,7 @@ struct system_on_chip* guess_soc_from_devtree(struct system_on_chip* soc) {
  return soc;
 }
-struct system_on_chip* get_soc(void) {
+struct system_on_chip* get_soc(struct cpuInfo* cpu) {
  struct system_on_chip* soc = emalloc(sizeof(struct system_on_chip));
  soc->raw_name = NULL;
  soc->soc_vendor = SOC_VENDOR_UNKNOWN;
--- a/src/riscv/soc.h
+++ b/src/riscv/soc.h
@@ -5,6 +5,6 @@
 #include "../common/cpu.h"
 #include <stdint.h>
-struct system_on_chip* get_soc(void);
+struct system_on_chip* get_soc(struct cpuInfo* cpu);
 #endif
--- a/src/riscv/socs.h
+++ b/src/riscv/socs.h
@@ -11,6 +11,8 @@ enum {
  SOC_STARFIVE_VF2,
  // ALLWINNER
  SOC_ALLWINNER_D1H,
  // SIPEED
  SOC_SIPEED_LICHEEPI4A,
  // UNKNOWN
  SOC_MODEL_UNKNOWN
 };
@@ -19,6 +21,7 @@ inline static VENDOR get_soc_vendor_from_soc(SOC soc) {
  if(soc >= SOC_SIFIVE_U740 && soc <= SOC_SIFIVE_U740) return SOC_VENDOR_SIFIVE;
  if(soc >= SOC_STARFIVE_VF2 && soc <= SOC_STARFIVE_VF2) return SOC_VENDOR_STARFIVE;
  if(soc >= SOC_ALLWINNER_D1H && soc <= SOC_ALLWINNER_D1H) return SOC_VENDOR_ALLWINNER;
  if(soc >= SOC_SIPEED_LICHEEPI4A && soc <= SOC_SIPEED_LICHEEPI4A) return SOC_VENDOR_SIPEED;
  return SOC_VENDOR_UNKNOWN;
 }
--- a/src/x86/apic.c
+++ b/src/x86/apic.c
@@ -72,34 +72,6 @@ uint32_t get_apic_id(bool x2apic_id) {
  }
 }
 #ifndef __APPLE__
 bool bind_to_cpu(int cpu_id) {
  #ifdef _WIN32
    HANDLE process = GetCurrentProcess();
    DWORD_PTR processAffinityMask = 1 << cpu_id;
    return SetProcessAffinityMask(process, processAffinityMask);
  #elif defined __linux__
    cpu_set_t currentCPU;
    CPU_ZERO(&currentCPU);
    CPU_SET(cpu_id, &currentCPU);
    if (sched_setaffinity (0, sizeof(currentCPU), &currentCPU) == -1) {
      printWarn("sched_setaffinity: %s", strerror(errno));
      return false;
    }
    return true;
  #elif defined __FreeBSD__
    cpuset_t currentCPU;
    CPU_ZERO(&currentCPU);
    CPU_SET(cpu_id, &currentCPU);
    if(cpuset_setaffinity(CPU_LEVEL_WHICH, CPU_WHICH_TID, -1, sizeof(cpuset_t), &currentCPU) == -1) {
      printWarn("cpuset_setaffinity: %s", strerror(errno));
      return false;
    }
    return true;
  #endif
 }
 #endif
 #ifdef __linux__
 int get_total_cores_module(int total_cores, int module) {
  int total_modules = 2;
@@ -119,6 +91,7 @@ int get_total_cores_module(int total_cores, int module) {
  while(!end) {
    if(!bind_to_cpu(i)) {
      printBug("get_total_cores_module: Cannot bind to core %d", i);
      return -1;
    }
    uint32_t eax = 0x0000001A;
@@ -127,6 +100,17 @@ int get_total_cores_module(int total_cores, int module) {
    uint32_t edx = 0;
    cpuid(&eax, &ebx, &ecx, &edx);
    int32_t core_type = eax >> 24 & 0xFF;
    // Here we artificially create a new core type for
    // LP-E cores. In case the core has no L3 (on a hybrid)
    // architecture, then we now it's an LP-E core.
    eax = 0x4;
    ebx = 0;
    ecx = 0x3;
    edx = 0;
    cpuid(&eax, &ebx, &ecx, &edx);
    core_type += eax == 0;
    bool found = false;
    for(int j=0; j < total_modules && !found; j++) {
@@ -397,6 +381,11 @@ bool fill_apic_ids(uint32_t* apic_ids, int first_core, int n, bool x2apic_id) {
 }
 bool get_topology_from_apic(struct cpuInfo* cpu, struct topology* topo) {
  if (topo->cach == NULL) {
    printWarn("get_topology_from_apic: cach is NULL");
    return false;
  }
  uint32_t apic_id;
  uint32_t* apic_ids = emalloc(sizeof(uint32_t) * topo->total_cores_module);
  uint32_t* apic_pkg = emalloc(sizeof(uint32_t) * topo->total_cores_module);
--- a/src/x86/apic.h
+++ b/src/x86/apic.h
@@ -17,10 +17,6 @@ struct apic {
 bool get_topology_from_apic(struct cpuInfo* cpu, struct topology* topo);
 uint32_t is_smt_enabled_amd(struct topology* topo);
 #ifndef __APPLE__
 bool bind_to_cpu(int cpu_id);
 #endif
 #ifdef __linux__
 int get_total_cores_module(int total_cores, int module);
 #endif
--- a/src/x86/cpuid.c
+++ b/src/x86/cpuid.c
@@ -6,6 +6,10 @@
  #include <unistd.h>
 #endif
 #ifdef __linux__
  #include "../common/freq.h"
 #endif
 #include <stdio.h>
 #include <stdlib.h>
 #include <string.h>
@@ -22,27 +26,32 @@
 #define CPU_VENDOR_INTEL_STRING "GenuineIntel"
 #define CPU_VENDOR_AMD_STRING   "AuthenticAMD"
 #define CPU_VENDOR_HYGON_STRING "HygonGenuine"
 static const char *hv_vendors_string[] = {
  [HV_VENDOR_KVM]       = "KVMKVMKVM",
  [HV_VENDOR_QEMU]      = "TCGTCGTCGTCG",
  [HV_VENDOR_VBOX]      = "VBoxVBoxVBox",
  [HV_VENDOR_HYPERV]    = "Microsoft Hv",
  [HV_VENDOR_VMWARE]    = "VMwareVMware",
  [HV_VENDOR_XEN]       = "XenVMMXenVMM",
  [HV_VENDOR_PARALLELS] = "lrpepyh vr",
  [HV_VENDOR_PHYP]      = NULL,
  [HV_VENDOR_BHYVE]     = "bhyve bhyve ",
-  [HV_VENDOR_PHYP]      = NULL
+  [HV_VENDOR_APPLEVZ]   = "Apple VZ"
 };
 static char *hv_vendors_name[] = {
  [HV_VENDOR_KVM]       = "KVM",
  [HV_VENDOR_QEMU]      = "QEMU",
  [HV_VENDOR_VBOX]      = "VirtualBox",
  [HV_VENDOR_HYPERV]    = "Microsoft Hyper-V",
  [HV_VENDOR_VMWARE]    = "VMware",
  [HV_VENDOR_XEN]       = "Xen",
  [HV_VENDOR_PARALLELS] = "Parallels",
  [HV_VENDOR_PHYP]      = "pHyp",
  [HV_VENDOR_BHYVE]     = "bhyve",
  [HV_VENDOR_APPLEVZ]   = "Apple VZ",
  [HV_VENDOR_INVALID]   = STRING_UNKNOWN
 };
@@ -128,39 +137,31 @@ bool abbreviate_intel_cpu_name(char** name) {
  char* new_name_ptr = new_name;
  char* aux_ptr = NULL;
-  // 1. Remove "(R)"
+  // 1. Find "Intel(R)"
  old_name_ptr = strstr(old_name_ptr, "Intel(R)");
  if(old_name_ptr == NULL) return false;
  strcpy(new_name_ptr, "Intel");
  new_name_ptr += strlen("Intel");
  old_name_ptr += strlen("Intel(R)");
-  // 2. Remove "(R)" or "(TM)"
+  // 2. Search for "@"
  aux_ptr = strstr(old_name_ptr, "(");
  if(aux_ptr == NULL) return false;
  strncpy(new_name_ptr, old_name_ptr, aux_ptr-old_name_ptr);
  new_name_ptr += aux_ptr-old_name_ptr;
  strcpy(new_name_ptr, " ");
  new_name_ptr++;
  old_name_ptr = strstr(aux_ptr, ")");
  if(old_name_ptr == NULL) return false;
  old_name_ptr++;
  while(*old_name_ptr == ' ') old_name_ptr++;
  // 3. Copy the CPU name
  aux_ptr = strstr(old_name_ptr, "@");
-  if(aux_ptr == NULL) return false;
+  if(aux_ptr == NULL) {
    // New CPUs, copy end ptr is end of string
    aux_ptr = old_name + strlen(old_name);
    strncpy(new_name_ptr, old_name_ptr, (aux_ptr)-old_name_ptr);
  }
  else {
    // Copy end ptr is "@"
    strncpy(new_name_ptr, old_name_ptr, (aux_ptr-1)-old_name_ptr);
  }
-  // 4. Remove dummy strings in Intel CPU names
+  // 3. Remove dummy strings in Intel CPU names
  strremove(new_name, "(R)");
  strremove(new_name, "(TM)");
  strremove(new_name, " CPU");
  strremove(new_name, " Dual");
  strremove(new_name, " 0");
  free(old_name);
  *name = new_name;
  return true;
 }
@@ -214,7 +215,7 @@ int64_t get_peak_performance(struct cpuInfo* cpu, bool accurate_pp) {
  #endif
    //First, check we have consistent data
-    if(freq == UNKNOWN_DATA || topo->logical_cores == UNKNOWN_DATA) {
+    if(freq == UNKNOWN_DATA || topo == NULL || topo->logical_cores == UNKNOWN_DATA) {
      return -1;
    }
@@ -284,7 +285,7 @@ struct hypervisor* get_hp_info(bool hv_present) {
    if(!found) {
      hv->hv_vendor = HV_VENDOR_INVALID;
-      printBug("Unknown hypervisor vendor: %s", name);
+      printBug("Unknown hypervisor vendor: '%s'", name);
    }
  }
@@ -388,6 +389,17 @@ bool set_cpu_module(int m, int total_modules, int32_t* first_core) {
      uint32_t edx = 0;
      cpuid(&eax, &ebx, &ecx, &edx);
      int32_t core_type = eax >> 24 & 0xFF;
      // Here we artificially create a new core type for
      // LP-E cores. In case the core has no L3 (on a hybrid)
      // architecture, then we now it's an LP-E core.
      eax = 0x4;
      ebx = 0;
      ecx = 0x3;
      edx = 0;
      cpuid(&eax, &ebx, &ecx, &edx);
      core_type += eax == 0;
      bool found = false;
      for(int j=0; j < total_modules && !found; j++) {
@@ -414,13 +426,19 @@ bool set_cpu_module(int m, int total_modules, int32_t* first_core) {
    #endif
  }
  else {
-    // This is a normal architecture
+    // This is a non-hybrid architecture
    *first_core = 0;
  }
  return true;
 }
 // Difference between E and LP-E cores:
 // According to Intel Core Ultra Processor Datasheet Volume 1 of 2
 // (https://www.intel.com/content/www/us/en/content-details/792044/intel-core-ultra-processor-datasheet-volume-1-of-2.html),
 // LP-E cores do not have L3 cache. This seems to be the only way of differentiating them.
 // - https://community.intel.com/t5/Processors/Detecting-LP-E-Cores-on-Meteor-Lake-in-software/m-p/1584555/highlight/true#M70732
 // - https://x.com/InstLatX64/status/1741416428538941718
 int32_t get_core_type(void) {
  uint32_t eax = 0x0000001A;
  uint32_t ebx = 0;
@@ -431,8 +449,26 @@ int32_t get_core_type(void) {
  cpuid(&eax, &ebx, &ecx, &edx);
  int32_t type = eax >> 24 & 0xFF;
-  if(type == 0x20) return CORE_TYPE_EFFICIENCY;
+  if (type == 0x40) return CORE_TYPE_PERFORMANCE;
-  else if(type == 0x40) return CORE_TYPE_PERFORMANCE;
+  else if (type == 0x20) {
    // get_core_type is only called iff hybrid_flag is true, which can only
    // happen if CPUID maxLevel >= 0x7 so we can assume the CPU supports
    // CPUID leaf 0x4
    eax = 0x4;
    ebx = 0;
    ecx = 0x3;
    edx = 0;
    cpuid(&eax, &ebx, &ecx, &edx);
    if (eax == 0) {
      // No L3 access, this is LP-E
      return CORE_TYPE_LP_EFFICIENCY;
    }
    else {
      return CORE_TYPE_EFFICIENCY;
    }
  }
  else {
    printErr("Found invalid core type: 0x%.8X\n", type);
    return CORE_TYPE_UNKNOWN;
@@ -447,7 +483,6 @@ struct cpuInfo* get_cpu_info(void) {
  cpu->cach = NULL;
  cpu->feat = NULL;
  uint32_t modules = 1;
  uint32_t eax = 0;
  uint32_t ebx = 0;
  uint32_t ecx = 0;
@@ -466,6 +501,8 @@ struct cpuInfo* get_cpu_info(void) {
    cpu->cpu_vendor = CPU_VENDOR_INTEL;
  else if (strcmp(CPU_VENDOR_AMD_STRING,name) == 0)
    cpu->cpu_vendor = CPU_VENDOR_AMD;
  else if (strcmp(CPU_VENDOR_HYGON_STRING,name) == 0)
    cpu->cpu_vendor = CPU_VENDOR_HYGON;
  else {
    cpu->cpu_vendor = CPU_VENDOR_INVALID;
    printErr("Unknown CPU vendor: %s", name);
@@ -484,9 +521,8 @@ struct cpuInfo* get_cpu_info(void) {
    cpu->cpu_name = get_str_cpu_name_internal();
  }
  else {
-    cpu->cpu_name = emalloc(sizeof(char) * (strlen(STRING_UNKNOWN) + 1));
+    cpu->cpu_name = NULL;
-    strcpy(cpu->cpu_name, STRING_UNKNOWN);
+    printWarn("Can't read CPU name from cpuid (needed extended level is 0x%.8X, max is 0x%.8X)", 0x80000004, cpu->maxExtendedLevels);
    printWarn("Can't read cpu name from cpuid (needed extended level is 0x%.8X, max is 0x%.8X)", 0x80000004, cpu->maxExtendedLevels);
  }
  cpu->topology_extensions = false;
@@ -504,12 +540,18 @@ struct cpuInfo* get_cpu_info(void) {
    cpu->hybrid_flag = (edx >> 15) & 0x1;
  }
-  if(cpu->hybrid_flag) modules = 2;
+  if(cpu->hybrid_flag) {
    struct uarch* tmp = get_cpu_uarch(cpu);
    cpu->num_cpus = get_hybrid_num_cpus(tmp);
  }
  else {
    cpu->num_cpus = 1;
  }
  struct cpuInfo* ptr = cpu;
-  for(uint32_t i=0; i < modules; i++) {
+  for(uint32_t i=0; i < cpu->num_cpus; i++) {
    int32_t first_core;
-    set_cpu_module(i, modules, &first_core);
+    set_cpu_module(i, cpu->num_cpus, &first_core);
    if(i > 0) {
      ptr->next_cpu = emalloc(sizeof(struct cpuInfo));
@@ -519,8 +561,9 @@ struct cpuInfo* get_cpu_info(void) {
      ptr->topo = NULL;
      ptr->cach = NULL;
      ptr->feat = NULL;
-      // We assume that this cores have the
+      // We assume that this core has the
-      // same cpuid capabilities
+      // same cpuid capabilities as the core in the
      // first module
      ptr->cpu_vendor = cpu->cpu_vendor;
      ptr->maxLevels = cpu->maxLevels;
      ptr->maxExtendedLevels = cpu->maxExtendedLevels;
@@ -536,14 +579,15 @@ struct cpuInfo* get_cpu_info(void) {
    ptr->first_core_id = first_core;
    ptr->feat = get_features_info(ptr);
    // If any field of the struct is NULL,
    // return inmideately, as further functions
    // require valid fields (cach, topo, etc)
    ptr->arch = get_cpu_uarch(ptr);
    ptr->freq = get_frequency_info(ptr);
    if (cpu->cpu_name == NULL && ptr == cpu) {
      // If we couldnt read CPU name from cpuid, infer it now
      cpu->cpu_name = infer_cpu_name_from_uarch(cpu->arch);
    }
    ptr->cach = get_cache_info(ptr);
    if(ptr->cach == NULL) return cpu;
    if(cpu->hybrid_flag) {
      ptr->topo = get_topology_info(ptr, ptr->cach, i);
@@ -551,16 +595,23 @@ struct cpuInfo* get_cpu_info(void) {
    else {
      ptr->topo = get_topology_info(ptr, ptr->cach, -1);
    }
-    if(cpu->topo == NULL) return cpu;
+
    // If topo is NULL, return early, as get_peak_performance
    // requries non-NULL topology.
    if(ptr->topo == NULL) return cpu;
  }
  cpu->num_cpus = modules;
  cpu->peak_performance = get_peak_performance(cpu, accurate_pp());
  return cpu;
 }
 bool get_cache_topology_amd(struct cpuInfo* cpu, struct topology* topo) {
  if (topo->cach == NULL) {
    printWarn("get_cache_topology_amd: cach is NULL");
    return false;
  }
  if(cpu->maxExtendedLevels >= 0x8000001D && cpu->topology_extensions) {
    uint32_t i, eax, ebx, ecx, edx, num_sharing_cache, cache_type, cache_level;
@@ -636,10 +687,17 @@ bool get_cache_topology_amd(struct cpuInfo* cpu, struct topology* topo) {
 #ifdef __linux__
 void get_topology_from_udev(struct topology* topo) {
  // TODO: To be improved in the future
  topo->total_cores = get_ncores_from_cpuinfo();
  // TODO: To be improved in the future
  if (topo->total_cores == 1) {
    // We can assume it's a single core CPU
    topo->logical_cores = topo->total_cores;
    topo->physical_cores = topo->total_cores;
  }
  else {
    topo->logical_cores = UNKNOWN_DATA;
    topo->physical_cores = UNKNOWN_DATA;
  }
  topo->smt_available = 1;
  topo->smt_supported = 1;
  topo->sockets = 1;
@@ -675,6 +733,8 @@ struct topology* get_topology_info(struct cpuInfo* cpu, struct cache* cach, int
  if(cpu->hybrid_flag) {
    #ifdef __linux__
      topo->total_cores_module = get_total_cores_module(topo->total_cores, module);
      printBug("get_total_cores_module: Failed to get number of cores in module");
      return NULL;
    #else
      UNUSED(module);
      topo->total_cores_module = topo->total_cores;
@@ -686,30 +746,29 @@ struct topology* get_topology_info(struct cpuInfo* cpu, struct cache* cach, int
  switch(cpu->cpu_vendor) {
    case CPU_VENDOR_INTEL:
      bool toporet = false;
      if (cpu->maxLevels >= 0x00000004) {
-        bool toporet = get_topology_from_apic(cpu, topo);
+        toporet = get_topology_from_apic(cpu, topo);
      }
      else {
        printWarn("Can't read topology information from cpuid (needed level is 0x%.8X, max is 0x%.8X)", 0x00000004, cpu->maxLevels);
      }
      if(!toporet) {
        #ifdef __linux__
-            printWarn("Failed to retrieve topology from APIC, using udev...\n");
+          printWarn("Failed to retrieve topology from APIC, using udev...");
          get_topology_from_udev(topo);
        #else
-            printErr("Failed to retrieve topology from APIC, assumming default values...\n");
+          if (cpu->maxLevels >= 0x00000004)
            printErr("Failed to retrieve topology from APIC, assumming default values...");
          topo->logical_cores = UNKNOWN_DATA;
          topo->physical_cores = UNKNOWN_DATA;
          topo->smt_available = 1;
          topo->smt_supported = 1;
        #endif
      }
      }
      else {
        printWarn("Can't read topology information from cpuid (needed level is 0x%.8X, max is 0x%.8X)", 0x00000001, cpu->maxLevels);
        topo->physical_cores = 1;
        topo->logical_cores = 1;
        topo->smt_available = 1;
        topo->smt_supported = 1;
      }
      break;
    case CPU_VENDOR_AMD:
    case CPU_VENDOR_HYGON:
      if (cpu->maxExtendedLevels >= 0x80000008) {
        eax = 0x80000008;
        cpuid(&eax, &ebx, &ecx, &edx);
@@ -906,6 +965,7 @@ struct cache* get_cache_info(struct cpuInfo* cpu) {
 struct frequency* get_frequency_info(struct cpuInfo* cpu) {
  struct frequency* freq = emalloc(sizeof(struct frequency));
  freq->measured = false;
  if(cpu->maxLevels < 0x00000016) {
    #if defined (_WIN32) || defined (__APPLE__)
@@ -915,7 +975,7 @@ struct frequency* get_frequency_info(struct cpuInfo* cpu) {
    #else
      printWarn("Can't read frequency information from cpuid (needed level is 0x%.8X, max is 0x%.8X). Using udev", 0x00000016, cpu->maxLevels);
      freq->base = UNKNOWN_DATA;
-      freq->max = get_max_freq_from_file(0);
+      freq->max = get_max_freq_from_file(cpu->first_core_id);
      if(freq->max == 0) {
        printWarn("Read max CPU frequency from udev and got 0 MHz");
@@ -942,7 +1002,7 @@ struct frequency* get_frequency_info(struct cpuInfo* cpu) {
      printWarn("Read max CPU frequency from CPUID and got 0 MHz");
      #ifdef __linux__
        printWarn("Using udev to detect frequency");
-        freq->max = get_max_freq_from_file(0);
+        freq->max = get_max_freq_from_file(cpu->first_core_id);
        if(freq->max == 0) {
          printWarn("Read max CPU frequency from udev and got 0 MHz");
@@ -954,6 +1014,15 @@ struct frequency* get_frequency_info(struct cpuInfo* cpu) {
    }
  }
  #ifdef __linux__
    if (freq->max == UNKNOWN_DATA || measure_max_frequency_flag()) {
      if (freq->max == UNKNOWN_DATA)
        printWarn("All previous methods failed, measuring CPU frequency");
      freq->max = measure_max_frequency(cpu->first_core_id);
      freq->measured = true;
    }
  #endif
  return freq;
 }
@@ -975,24 +1044,33 @@ char* get_str_topology(struct cpuInfo* cpu, struct topology* topo, bool dual_soc
    string = emalloc(sizeof(char) * (strlen(STRING_UNKNOWN) + 1));
    strcpy(string, STRING_UNKNOWN);
  }
-  else if(topo->smt_supported > 1) {
+  else {
    char cores_str[6];
    memset(cores_str, 0, sizeof(char) * 6);
    if (topo->physical_cores * topo_sockets > 1)
      strcpy(cores_str, "cores");
    else
      strcpy(cores_str, "core");
    if(topo->smt_supported > 1) {
      // 4 for digits, 21 for ' cores (SMT disabled)' which is the longest possible output
      uint32_t max_size = 4+21+1;
      string = emalloc(sizeof(char) * max_size);
      if(topo->smt_available > 1)
-      snprintf(string, max_size, "%d cores (%d threads)", topo->physical_cores * topo_sockets, topo->logical_cores * topo_sockets);
+        snprintf(string, max_size, "%d %s (%d threads)", topo->physical_cores * topo_sockets, cores_str, topo->logical_cores * topo_sockets);
      else {
        if(cpu->cpu_vendor == CPU_VENDOR_AMD)
-        snprintf(string, max_size, "%d cores (SMT disabled)", topo->physical_cores * topo_sockets);
+          snprintf(string, max_size, "%d %s (SMT disabled)", topo->physical_cores * topo_sockets, cores_str);
        else
-        snprintf(string, max_size, "%d cores (HT disabled)", topo->physical_cores * topo_sockets);
+          snprintf(string, max_size, "%d %s (HT disabled)", topo->physical_cores * topo_sockets, cores_str);
      }
    }
    else {
      uint32_t max_size = 4+7+1;
      string = emalloc(sizeof(char) * max_size);
-    snprintf(string, max_size, "%d cores",topo->physical_cores * topo_sockets);
+      snprintf(string, max_size, "%d %s",topo->physical_cores * topo_sockets, cores_str);
    }
  }
  return string;
--- a/src/x86/uarch.c
+++ b/src/x86/uarch.c
@@ -48,7 +48,9 @@ enum {
  UARCH_UNKNOWN,
  // INTEL //
  UARCH_P5,
-  UARCH_P6,
+  UARCH_P5_MMX,
  UARCH_P6_PENTIUM_II,
  UARCH_P6_PENTIUM_III,
  UARCH_DOTHAN,
  UARCH_YONAH,
  UARCH_MEROM,
@@ -92,6 +94,7 @@ enum {
  UARCH_TIGER_LAKE,
  UARCH_ALDER_LAKE,
  UARCH_RAPTOR_LAKE,
  UARCH_METEOR_LAKE,
  // AMD //
  UARCH_AM486,
  UARCH_AM5X86,
@@ -112,7 +115,8 @@ enum {
  UARCH_ZEN2,
  UARCH_ZEN3,
  UARCH_ZEN3_PLUS,
-  UARCH_ZEN4
+  UARCH_ZEN4,
  UARCH_ZEN4C
 };
 struct uarch {
@@ -124,7 +128,8 @@ struct uarch {
 #define UARCH_START if (false) {}
 #define CHECK_UARCH(arch, ef_, f_, em_, m_, s_, str, uarch, process) \
   else if (ef_ == ef && f_ == f && (em_ == NA || em_ == em) && (m_ == NA || m_ == m) && (s_ == NA || s_ == s)) fill_uarch(arch, str, uarch, process);
-#define UARCH_END else { printBug("Unknown microarchitecture detected: M=0x%.8X EM=0x%.8X F=0x%.8X EF=0x%.8X S=0x%.8X", m, em, f, ef, s); fill_uarch(arch, STRING_UNKNOWN, UARCH_UNKNOWN, 0); }
+#define UARCH_END else { printBugCheckRelease("Unknown microarchitecture detected: M=0x%X EM=0x%X F=0x%X EF=0x%X S=0x%X", m, em, f, ef, s); \
 fill_uarch(arch, STRING_UNKNOWN, UARCH_UNKNOWN, UNK); }
 void fill_uarch(struct uarch* arch, char* str, MICROARCH u, uint32_t process) {
  arch->uarch_str = emalloc(sizeof(char) * (strlen(str)+1));
@@ -142,31 +147,31 @@ struct uarch* get_uarch_from_cpuid_intel(uint32_t ef, uint32_t f, uint32_t em, u
  // EM: Extended Model                                                              //
  // M: Model                                                                        //
  // S: Stepping                                                                     //
-  // ----------------------------------------------------------------------------- //
+  // ------------------------------------------------------------------------------- //
  //                EF  F  EM   M   S                                                //
  UARCH_START
  CHECK_UARCH(arch, 0,  5,  0,  0, NA, "P5",                UARCH_P5,              800)
  CHECK_UARCH(arch, 0,  5,  0,  1, NA, "P5",                UARCH_P5,              800)
  CHECK_UARCH(arch, 0,  5,  0,  2, NA, "P5",                UARCH_P5,              UNK)
  CHECK_UARCH(arch, 0,  5,  0,  3, NA, "P5",                UARCH_P5,              600)
-  CHECK_UARCH(arch, 0,  5,  0,  4, NA, "P5 MMX",          UARCH_P5,              UNK)
+  CHECK_UARCH(arch, 0,  5,  0,  4, NA, "P5 (MMX)",          UARCH_P5_MMX,          UNK)
-  CHECK_UARCH(arch, 0,  5,  0,  7, NA, "P5 MMX",          UARCH_P5,              UNK)
+  CHECK_UARCH(arch, 0,  5,  0,  7, NA, "P5 (MMX)",          UARCH_P5_MMX,          UNK)
-  CHECK_UARCH(arch, 0,  5,  0,  8, NA, "P5 MMX",          UARCH_P5,              250)
+  CHECK_UARCH(arch, 0,  5,  0,  8, NA, "P5 (MMX)",          UARCH_P5_MMX,          250)
  CHECK_UARCH(arch, 0,  5,  0,  9,  0, "Lakemont",          UARCH_LAKEMONT,         32)
-  CHECK_UARCH(arch, 0,  5,  0,  9, NA, "P5 MMX",          UARCH_P5,              UNK)
+  CHECK_UARCH(arch, 0,  5,  0,  9, NA, "P5 (MMX)",          UARCH_P5_MMX,          UNK)
  CHECK_UARCH(arch, 0,  5,  0, 10,  0, "Lakemont",          UARCH_LAKEMONT,         32)
-  CHECK_UARCH(arch, 0,  6,  0,  0, NA, "P6 Pentium II",   UARCH_P6,              UNK)
+  CHECK_UARCH(arch, 0,  6,  0,  0, NA, "P6 (Pentium II)",   UARCH_P6_PENTIUM_II,   UNK)
-  CHECK_UARCH(arch, 0,  6,  0,  1, NA, "P6 Pentium II",   UARCH_P6,              UNK) // process depends on core
+  CHECK_UARCH(arch, 0,  6,  0,  1, NA, "P6 (Pentium II)",   UARCH_P6_PENTIUM_II,   UNK) // process depends on core
-  CHECK_UARCH(arch, 0,  6,  0,  2, NA, "P6 Pentium II",   UARCH_P6,              UNK)
+  CHECK_UARCH(arch, 0,  6,  0,  2, NA, "P6 (Pentium II)",   UARCH_P6_PENTIUM_II,   UNK)
-  CHECK_UARCH(arch, 0,  6,  0,  3, NA, "P6 Pentium II",   UARCH_P6,              350)
+  CHECK_UARCH(arch, 0,  6,  0,  3, NA, "P6 (Klamath)",      UARCH_P6_PENTIUM_II,   350) // http://instlatx64.atw.hu.
-  CHECK_UARCH(arch, 0,  6,  0,  4, NA, "P6 Pentium II",   UARCH_P6,              UNK)
+  CHECK_UARCH(arch, 0,  6,  0,  4, NA, "P6 (Pentium II)",   UARCH_P6_PENTIUM_II,   UNK)
-  CHECK_UARCH(arch, 0,  6,  0,  5, NA, "P6 Pentium II",   UARCH_P6,              250)
+  CHECK_UARCH(arch, 0,  6,  0,  5, NA, "P6 (Deschutes)",    UARCH_P6_PENTIUM_II,   250) // http://instlatx64.atw.hu.
-  CHECK_UARCH(arch, 0,  6,  0,  6, NA, "P6 Pentium II",   UARCH_P6,              UNK)
+  CHECK_UARCH(arch, 0,  6,  0,  6, NA, "P6 (Dixon)",        UARCH_P6_PENTIUM_II,   UNK) // http://instlatx64.atw.hu.
-  CHECK_UARCH(arch, 0,  6,  0,  7, NA, "P6 Pentium III",  UARCH_P6,              250)
+  CHECK_UARCH(arch, 0,  6,  0,  7, NA, "P6 (Katmai)",       UARCH_P6_PENTIUM_III,  250) // Core names from: https://en.wikichip.org/wiki/intel/cpuid. NOTE: Xeon core names are different! https://www.techpowerup.com/cpu-specs/?generation=Intel+Pentium+III+Xeon
-  CHECK_UARCH(arch, 0,  6,  0,  8, NA, "P6 Pentium III",  UARCH_P6,              180)
+  CHECK_UARCH(arch, 0,  6,  0,  8, NA, "P6 (Coppermine)",   UARCH_P6_PENTIUM_III,  180) // Also: https://en.wikipedia.org/wiki/Pentium_III
-  CHECK_UARCH(arch, 0,  6,  0,  9, NA, "P6 Pentium M",    UARCH_P6,              130)
+  CHECK_UARCH(arch, 0,  6,  0,  9, NA, "P6 (Pentium M)",    UARCH_P6_PENTIUM_III,  130)
-  CHECK_UARCH(arch, 0,  6,  0, 10, NA, "P6 Pentium III",  UARCH_P6,              180)
+  CHECK_UARCH(arch, 0,  6,  0, 10, NA, "P6 (Coppermine T)", UARCH_P6_PENTIUM_III,  180)
-  CHECK_UARCH(arch, 0,  6,  0, 11, NA, "P6 Pentium III",  UARCH_P6,              130)
+  CHECK_UARCH(arch, 0,  6,  0, 11, NA, "P6 (Tualatin)",     UARCH_P6_PENTIUM_III,  130)
  CHECK_UARCH(arch, 0,  6,  0, 13, NA, "Dothan",            UARCH_DOTHAN,          UNK)  // process depends on core
  CHECK_UARCH(arch, 0,  6,  0, 14, NA, "Yonah",             UARCH_YONAH,            65)
  CHECK_UARCH(arch, 0,  6,  0, 15, NA, "Merom",             UARCH_MEROM,            65)
@@ -244,6 +249,7 @@ struct uarch* get_uarch_from_cpuid_intel(uint32_t ef, uint32_t f, uint32_t em, u
  CHECK_UARCH(arch, 0,  6, 10,  5, NA, "Comet Lake",        UARCH_COMET_LAKE,       14) // wikichip
  CHECK_UARCH(arch, 0,  6, 10,  6, NA, "Comet Lake",        UARCH_COMET_LAKE,       14) // instlatx64.atw.hu (i7-10710U)
  CHECK_UARCH(arch, 0,  6, 10,  7, NA, "Rocket Lake",       UARCH_ROCKET_LAKE,      14) // instlatx64.atw.hu (i7-11700K)
  CHECK_UARCH(arch, 0,  6, 10, 10, NA, "Meteor Lake",       UARCH_METEOR_LAKE,       7) // instlatx64.atw.hu (Ultra 7 155H)
  CHECK_UARCH(arch, 0,  6, 11,  7, NA, "Raptor Lake",       UARCH_RAPTOR_LAKE,      10) // instlatx64.atw.hu (i5-13600K)
  CHECK_UARCH(arch, 0,  6, 11, 10, NA, "Raptor Lake",       UARCH_RAPTOR_LAKE,      10) // instlatx64.atw.hu (i7-1370P)
  CHECK_UARCH(arch, 0,  6, 11, 14, NA, "Alder Lake",        UARCH_ALDER_LAKE,       10) // instlatx64.atw.hu (Alder Lake-N)
@@ -350,6 +356,7 @@ struct uarch* get_uarch_from_cpuid_amd(uint32_t ef, uint32_t f, uint32_t em, uin
  CHECK_UARCH(arch,  6, 15,  6,  5, NA, "Excavator",   UARCH_EXCAVATOR,   28) // undocumented, but sample from Alexandros Couloumbis
  CHECK_UARCH(arch,  6, 15,  7,  0, NA, "Excavator",   UARCH_EXCAVATOR,   28)
  CHECK_UARCH(arch,  7, 15,  0,  0, NA, "Jaguar",      UARCH_JAGUAR,      28)
  CHECK_UARCH(arch,  7, 15,  1, NA, NA, "Jaguar",      UARCH_JAGUAR,      14) // instlatx64 (PS4) Normal PS4 is 28nm, Slim and Pro are 16nm
  CHECK_UARCH(arch,  7, 15,  2,  6, NA, "Jaguar",      UARCH_JAGUAR,      28) // AMD Cato (Xbox One?)
  CHECK_UARCH(arch,  7, 15,  3,  0, NA, "Puma 2014",   UARCH_PUMA_2014,   28)
  CHECK_UARCH(arch,  8, 15,  0,  0, NA, "Zen",         UARCH_ZEN,         14) // instlatx64 engr sample
@@ -364,14 +371,43 @@ struct uarch* get_uarch_from_cpuid_amd(uint32_t ef, uint32_t f, uint32_t em, uin
  CHECK_UARCH(arch,  8, 15,  6,  0, NA, "Zen 2",       UARCH_ZEN2,         7) // undocumented, geekbench.com example
  CHECK_UARCH(arch,  8, 15,  6,  8, NA, "Zen 2",       UARCH_ZEN2,         7) // found on instlatx64
  CHECK_UARCH(arch,  8, 15,  7,  1, NA, "Zen 2",       UARCH_ZEN2,         7) // samples from Steven Noonan and instlatx64
  CHECK_UARCH(arch,  8, 15,  8,  4, NA, "Zen 2",       UARCH_ZEN2,         7) // instlatx64 (Xbox Series X?)
  CHECK_UARCH(arch,  8, 15,  9,  0,  2, "Zen 2",       UARCH_ZEN2,         7) // Steam Deck (instlatx64)
  CHECK_UARCH(arch,  8, 15,  10, 0, NA, "Zen 2",       UARCH_ZEN2,         6) // instlatx64
  CHECK_UARCH(arch, 10, 15,  0,  1, NA, "Zen 3",       UARCH_ZEN3,         7) // instlatx64
  CHECK_UARCH(arch, 10, 15,  0,  8, NA, "Zen 3",       UARCH_ZEN3,         7) // instlatx64
  CHECK_UARCH(arch, 10, 15,  1,  1, NA, "Zen 4",       UARCH_ZEN4,         5) // instlatx64
  CHECK_UARCH(arch, 10, 15,  1,  8, NA, "Zen 4",       UARCH_ZEN4,         5) // instlatx64
  CHECK_UARCH(arch, 10, 15,  2,  1, NA, "Zen 3",       UARCH_ZEN3,         7) // instlatx64
  CHECK_UARCH(arch, 10, 15,  3, NA, NA, "Zen 3",       UARCH_ZEN3,         7) // instlatx64
  CHECK_UARCH(arch, 10, 15,  4,  4, NA, "Zen 3+",      UARCH_ZEN3_PLUS,    6) // instlatx64 (they say it is Zen3...)
  CHECK_UARCH(arch, 10, 15,  5,  0, NA, "Zen 3",       UARCH_ZEN3,         7) // instlatx64
  CHECK_UARCH(arch, 10, 15,  1,  1, NA, "Zen 4",       UARCH_ZEN4,         5) // instlatx64
  CHECK_UARCH(arch, 10, 15,  6,  1,  2, "Zen 4",       UARCH_ZEN4,         5) // instlatx64
  CHECK_UARCH(arch, 10, 15,  7,  4,  1, "Zen 4",       UARCH_ZEN4,         4) // instlatx64
  CHECK_UARCH(arch, 10, 15,  7,  5,  2, "Zen 4",       UARCH_ZEN4,         4) // instlatx64
  CHECK_UARCH(arch, 10, 15,  7,  8,  0, "Zen 4",       UARCH_ZEN4,         4) // instlatx64
  CHECK_UARCH(arch, 10, 15,  8, NA, NA, "Zen 4",       UARCH_ZEN4,         5) // instlatx64 (AMD MI300C)
  CHECK_UARCH(arch, 10, 15,  9, NA, NA, "Zen 4",       UARCH_ZEN4,         5) // instlatx64 (AMD MI300A)
  CHECK_UARCH(arch, 10, 15, 10, NA, NA, "Zen 4c",      UARCH_ZEN4C,        5) // instlatx64
  UARCH_END
  return arch;
 }
 struct uarch* get_uarch_from_cpuid_hygon(uint32_t ef, uint32_t f, uint32_t em, uint32_t m, int s) {
  struct uarch* arch = emalloc(sizeof(struct uarch));
  // EF: Extended Family                                                           //
  // F:  Family                                                                    //
  // EM: Extended Model                                                            //
  // M: Model                                                                      //
  // S: Stepping                                                                   //
  // ----------------------------------------------------------------------------- //
  //                 EF  F  EM   M   S                                             //
  UARCH_START
  // https://www.phoronix.com/news/Hygon-Dhyana-AMD-China-CPUs
  CHECK_UARCH(arch,  9,  15,  0,  1, NA, "Zen",       UARCH_ZEN,      UNK) // https://github.com/Dr-Noob/cpufetch/issues/244
  // CHECK_UARCH(arch,  9,  15,  0,  2, NA, "???",       ?????????,      UNK) // http://instlatx64.atw.hu/
  UARCH_END
  return arch;
@@ -379,11 +415,16 @@ struct uarch* get_uarch_from_cpuid_amd(uint32_t ef, uint32_t f, uint32_t em, uin
 struct uarch* get_uarch_from_cpuid(struct cpuInfo* cpu, uint32_t dump, uint32_t ef, uint32_t f, uint32_t em, uint32_t m, int s) {
  if(cpu->cpu_vendor == CPU_VENDOR_INTEL) {
    struct uarch* arch = emalloc(sizeof(struct uarch));
    if(dump == 0x000806E9) {
      if (cpu->cpu_name == NULL) {
        printErr("Unable to find uarch without CPU name");
        fill_uarch(arch, STRING_UNKNOWN, UARCH_UNKNOWN, UNK);
        return arch;
      }
      // It is not possible to determine uarch only from CPUID dump (can be Kaby Lake or Amber Lake)
      // See issue https://github.com/Dr-Noob/cpufetch/issues/122
      struct uarch* arch = emalloc(sizeof(struct uarch));
      if(strstr(cpu->cpu_name, "Y") != NULL) {
        fill_uarch(arch, "Amber Lake", UARCH_AMBER_LAKE, 14);
      }
@@ -394,10 +435,14 @@ struct uarch* get_uarch_from_cpuid(struct cpuInfo* cpu, uint32_t dump, uint32_t
      return arch;
    }
    else if (dump == 0x000806EA) {
      if (cpu->cpu_name == NULL) {
        printErr("Unable to find uarch without CPU name");
        fill_uarch(arch, STRING_UNKNOWN, UARCH_UNKNOWN, UNK);
        return arch;
      }
      // It is not possible to determine uarch only from CPUID dump (can be Kaby Lake R or Coffee Lake U)
      // See issue https://github.com/Dr-Noob/cpufetch/issues/149
      struct uarch* arch = emalloc(sizeof(struct uarch));
      if(strstr(cpu->cpu_name, "i5-8250U") != NULL ||
         strstr(cpu->cpu_name, "i5-8350U") != NULL ||
         strstr(cpu->cpu_name, "i7-8550U") != NULL ||
@@ -412,14 +457,58 @@ struct uarch* get_uarch_from_cpuid(struct cpuInfo* cpu, uint32_t dump, uint32_t
    }
    return get_uarch_from_cpuid_intel(ef, f, em, m, s);
  }
-  else
+  else if(cpu->cpu_vendor == CPU_VENDOR_AMD) {
    return get_uarch_from_cpuid_amd(ef, f, em, m, s);
  }
  else if(cpu->cpu_vendor == CPU_VENDOR_HYGON) {
    return get_uarch_from_cpuid_hygon(ef, f, em, m, s);
  }
  else {
    printBug("Invalid CPU vendor: %d", cpu->cpu_vendor);
    return NULL;
  }
 }
 // If we cannot get the CPU name from CPUID, try to infer it from uarch
 char* infer_cpu_name_from_uarch(struct uarch* arch) {
  char* cpu_name = NULL;
  if (arch == NULL) {
    printErr("infer_cpu_name_from_uarch: Unable to find CPU name");
    cpu_name = ecalloc(strlen(STRING_UNKNOWN) + 1, sizeof(char));
    strcpy(cpu_name, STRING_UNKNOWN);
    return cpu_name;
  }
  char *str = NULL;
  if (arch->uarch == UARCH_P5)
    str = "Intel Pentium";
  else if (arch->uarch == UARCH_P5_MMX)
    str = "Intel Pentium MMX";
  else if (arch->uarch == UARCH_P6_PENTIUM_II)
    str = "Intel Pentium II";
  else if (arch->uarch == UARCH_P6_PENTIUM_III)
    str = "Intel Pentium III";
  else
    printErr("Unable to find name from uarch: %d", arch->uarch);
  if (str == NULL) {
    cpu_name = ecalloc(strlen(STRING_UNKNOWN) + 1, sizeof(char));
    strcpy(cpu_name, STRING_UNKNOWN);
  }
  else {
    cpu_name = ecalloc(strlen(str) + 1, sizeof(char));
    strcpy(cpu_name, str);
  }
  return cpu_name;
 }
 bool vpus_are_AVX512(struct cpuInfo* cpu) {
  return cpu->arch->uarch != UARCH_ICE_LAKE &&
         cpu->arch->uarch != UARCH_TIGER_LAKE &&
-         cpu->arch->uarch != UARCH_ZEN4;
+         cpu->arch->uarch != UARCH_ZEN4 &&
         cpu->arch->uarch != UARCH_ZEN4C;
 }
 bool is_knights_landing(struct cpuInfo* cpu) {
@@ -449,18 +538,25 @@ int get_number_of_vpus(struct cpuInfo* cpu) {
      case UARCH_TIGER_LAKE:
      case UARCH_ALDER_LAKE:
      case UARCH_RAPTOR_LAKE:
      case UARCH_METEOR_LAKE:
      // AMD
      case UARCH_ZEN2:
      case UARCH_ZEN3:
      case UARCH_ZEN3_PLUS:
      case UARCH_ZEN4:
      case UARCH_ZEN4C:
        return 2;
      default:
        return 1;
  }
 }
 uint32_t get_hybrid_num_cpus(struct uarch* arch) {
  if (arch->uarch == UARCH_METEOR_LAKE) return 3;
  else return 2;
 }
 bool choose_new_intel_logo_uarch(struct cpuInfo* cpu) {
  switch(cpu->arch->uarch) {
    case UARCH_ALDER_LAKE:
@@ -484,9 +580,6 @@ char* get_str_process(struct cpuInfo* cpu) {
  if(process == UNK) {
    snprintf(str, strlen(STRING_UNKNOWN)+1, STRING_UNKNOWN);
  }
  else if(process > 100) {
    sprintf(str, "%.2fum", (double)process/100);
  }
  else if(process > 0){
    sprintf(str, "%dnm", process);
  }
--- a/src/x86/uarch.h
+++ b/src/x86/uarch.h
@@ -8,9 +8,11 @@
 struct uarch;
 struct uarch* get_uarch_from_cpuid(struct cpuInfo* cpu, uint32_t dump, uint32_t ef, uint32_t f, uint32_t em, uint32_t m, int s);
 char* infer_cpu_name_from_uarch(struct uarch* arch);
 bool vpus_are_AVX512(struct cpuInfo* cpu);
 bool is_knights_landing(struct cpuInfo* cpu);
 int get_number_of_vpus(struct cpuInfo* cpu);
 uint32_t get_hybrid_num_cpus(struct uarch* arch);
 bool choose_new_intel_logo_uarch(struct cpuInfo* cpu);
 char* get_str_uarch(struct cpuInfo* cpu);
 char* get_str_process(struct cpuInfo* cpu);
Author	SHA1	Message	Date
Dr-Noob	64ef0d889c	[v1.05][X86] Fix for Meteor Lake (#255 )	2024-07-30 08:52:22 +01:00
Dr-Noob	d297878a51	[v1.05][X86] Experimental new implementation of abbreviate_intel_cpu_name	2024-07-29 08:53:01 +01:00
Dr-Noob	ac308204c7	[v1.05][X86] Add preeliminary support for Meteor Lake (#255 )	2024-07-28 22:53:17 +01:00
Dr-Noob	260f9ec3b8	[v1.05] Add new contributor to acknowledgements	2024-07-25 08:29:05 +01:00
Dr-Noob	79013d0ec9	[v1.05][X86] Improve robustness in case of old CPUs (verified by #220 ) - Use udev to get topo when apic failed or is not available. - Assume single core in udev when total cores is 1. - Print core/cores accordingly to the number of cores.	2024-07-25 08:23:56 +01:00
Dr-Noob	e4227388b9	[v1.05][ARM] Add new SnapD SoCs and use ro.soc.mode in Android to improve SoC detection (#253 )	2024-07-19 08:21:11 +01:00
Dr-Noob	8fca4cb250	[v1.05][X86] Fix frequency fetching from udev and measurement in hybrid architectures	2024-07-11 22:27:42 +01:00
Dr-Noob	7c947bdf64	[v1.05] Use UNKNOWN_DATA instead of -1 in frequency measurement	2024-07-11 22:10:00 +01:00
Dr-Noob	1ed3a0f2bf	[v1.05] Adapt frequency measurement iterations depending on CPU speed This is achieved by running a first measurement which gets a taste of CPU speed, then estimate a reasonable value for the iterations of the real measurement and then running the actual measurement. This is very helpful to reduce the runtime of the measurement, especially for slow CPUs	2024-07-11 21:55:01 +01:00
Dr-Noob	0fe6fc3f4d	[v1.05][ARM] Fix mistake in Makefile	2024-07-11 08:17:26 +01:00
Dr-Noob	96c784026b	[v1.05] Fix formatting issues in Makefile	2024-07-09 08:47:34 +01:00
Dr-Noob	59cd2dd128	[v1.05][X86] Add support for Hygon CPUs (#244 )	2024-07-09 08:34:44 +01:00
Dr-Noob	da1981b97c	[v1.05] Check read return value in frequency measurement	2024-07-09 08:32:24 +01:00
Dr-Noob	8506c91e00	[v1.05] Add --measure-max-freq (available on x86 and ARM)	2024-07-08 09:07:57 +01:00
Dr-Noob	ece28cbdee	[v1.05] Small fix in help message	2024-07-08 08:31:00 +01:00
Dr-Noob	7b46c78249	[v1.05] Replace printf with proper printErr	2024-07-08 08:28:48 +01:00
Dr-Noob	e0095c303d	[v1.05] Print a tilde in case the freq was measured (indicating that this value is an approximation)	2024-07-08 08:23:56 +01:00
Dr-Noob	65378aaed9	[v1.05] Move sysctl from ARM-specific to common (#251 )	2024-07-07 12:43:03 +01:00
Dr-Noob	946729dd06	[v1.05] Compile measure freq only in Linux (avoids compiler warning in non-linux builds)	2024-07-06 11:28:46 +01:00
Dr-Noob	9212f19de1	[v1.05] Add support for frequency measurement (both x86 and ARM) (branch measure-freq #220 )	2024-07-05 08:44:34 +01:00
Dr-Noob	b019256515	[v1.05] Continue merging measure-freq #220 - [v1.05][X86] Show SSE if AVX/FMA is not supported - [v1.05][X86] Do not stop if cach is NULL and check for non-NULL cache in get_topology_info functions - [v1.05][X86] Fix bug where the number of cpus were not set if NULL was returned inside the loop. Ensure topo is not NULL in get_peak_performance. Fallback to UNKNOWN_DATA when we have no information about topology	2024-07-05 08:37:54 +01:00
Dr-Noob	d4cadbd807	[v1.05] Move bind_to_cpu from x86-specific to global (merging measure-freq #220 )	2024-07-05 08:32:11 +01:00
Dr-Noob	4f081ef1a2	[v1.05] Add newline to fix dummy warning with clang	2024-07-03 09:09:37 +02:00
Dr-Noob	1b746bc67d	[v1.05][ARM] Add support to detect SoC from PCI (#245 ) with initial support for NVIDIA Tegra	2024-07-03 08:01:53 +01:00
Dr-Noob	dfa2b773d1	[v1.05][X86] Add new Zen4 uarch (#237 )	2024-05-18 22:36:23 +01:00
Dr-Noob	59efbf4e08	[v1.05] Add VirtualBox hypervisor (noted in #235 )	2024-05-18 22:27:17 +01:00
Dr-Noob	29768e841d	[v1.05][ARM] Update TaiShan vector units	2024-02-20 09:35:30 +01:00
Dr-Noob	cc16bc56ef	[v1.05][X86] Improve support for old x86 CPUs (#220 ) by improving Pentium uarch detection and adding support to infer the CPU name from uarch when the corresponding CPUID level is not available	2024-02-13 21:29:08 +00:00
Dr-Noob	1504c5d0ef	[v1.05][X86] Report x86 / x86_64 in ARCH_X86 builds	2024-02-13 21:26:24 +00:00
Dr-Noob	08919916dc	[v1.05] Always print manufacturing process in nanometers (this indirectly fixes a bug of processes in micrometers being incorrectly reported by 10x	2024-02-13 21:24:16 +00:00
Dr-Noob	4a8a7567f0	[v1.05] Add support for NO_COLOR (#227 )	2024-02-13 08:41:54 +00:00
Dr-Noob	c01f60fa6c	[v1.05] Implement new approach to infer SoC from the uarch. Add support for Kunpeng SoCs	2024-02-08 09:04:51 +00:00
Dr-Noob	b610dc8c7d	[v1.05] Bump version	2024-02-05 18:33:15 +00:00
Dr-Noob	0967e3597b	[v1.04] Fix error in previous commit	2024-02-05 09:48:46 +01:00
Dr-Noob	14df701707	[v1.04] Check release when printing error also in Apple chip failures	2024-02-05 08:46:17 +00:00
Dr-Noob	cbcce9c2ed	[v1.04] Improve error reporting in the case of unkown microarchitectures. As pointed out in #224 this was already solved, but this commit tries to be an improvement over the previous implementation	2024-02-05 08:37:59 +00:00
Dr-Noob	b072e5c331	[v1.04] Update acknowledgements	2024-02-01 22:40:58 +00:00
Dr-Noob	4b42d2c89d	[v1.04][ARM] Extend Allwinner SoC list (#207 )	2024-02-01 23:26:23 +01:00
Dr-Noob	d221f578b7	[v1.04][ARM] Use sysctl to fetch topology in Apple SoCs	2024-01-25 09:33:22 +01:00
Dr-Noob	7b4b94bb93	[v1.04] Fix typo in Rockchip SoC detection	2024-01-22 07:18:15 +00:00
Dr-Noob	5e00d554aa	[v1.04][ARM] Fix number of cores per cluster in M2 and M3 SoCs (#183 )	2024-01-17 08:48:58 +00:00
Dr-Noob	5ffac60622	[v1.04][ARM] Support for reverse ordering in Rockchip SoCs	2024-01-17 09:37:15 +01:00
Dr-Noob	6566ac3ccf	[v1.04] Add Apple VZ hypervisor (#218 )	2024-01-15 08:43:28 +00:00
Dr-Noob	0a048717bf	[v1.04][X86] Fix bug in AMD CPUs (#212 )	2023-12-24 23:03:20 +00:00
Dr-Noob	ce6e6f9cd8	[v1.04][ARM] Preeliminary M3 support	2023-12-24 22:42:01 +00:00
Dr-Noob	2feee25659	[v1.04] Clarify how the unknown microarchitectures should be reported	2023-12-03 20:23:15 +00:00
Dr-Noob	8335bd004d	[v1.04][X86] Add AMD uarchs	2023-12-02 18:18:43 +00:00
Dr-Noob	a172b4b281	[v1.04][ARM] Add more Mediatek SoCs	2023-11-18 20:25:57 +01:00
Dr-Noob	d88a6bf763	[v1.04][X86] Fixed bhyve matcher (#193 )	2023-11-11 09:36:12 +00:00
Dr-Noob	8870a0ca0c	[v1.04][RISCV] Add Sipeed ASCII logo	2023-11-01 20:50:05 +00:00
Dr-Noob	a43b700540	[v1.04][RISCV] Add Lichee PI 4a SoC (#200 )	2023-11-01 20:48:25 +00:00
Dr-Noob	9a578d3670	[v1.04][RISCV] Make single-letter extension detection more robust. s and u are invalid but might appear (#200 ), so just skip them	2023-10-29 17:14:47 +00:00
Dr-Noob	bf890965a3	[v1.04] Add colors to Google logo	2023-10-17 09:19:05 +02:00
Dr-Noob	530207aee0	[v1.04] Added Google ascii logo	2023-10-17 08:56:20 +02:00
Dr-Noob	f64ff0d4cf	[v1.04] Added Google Tensor SoCs	2023-10-17 08:55:38 +02:00
Dr-Noob	4b7600d49e	[v1.04][ARM] Add Cortex-A715/X3 uarchs	2023-10-16 09:04:59 +02:00