#include #include #include #include #include #ifdef __ANDROID__ #include #endif #include #include static inline bool is_ascii_whitespace(char c) { switch (c) { case ' ': case '\t': case '\r': case '\n': return true; default: return false; } } static inline bool is_ascii_alphabetic(char c) { const char lower_c = c | '\x20'; return (uint8_t) (lower_c - 'a') <= (uint8_t) ('z' - 'a'); } static inline bool is_ascii_alphabetic_uppercase(char c) { return (uint8_t) (c - 'A') <= (uint8_t) ('Z' - 'A'); } static inline bool is_ascii_numeric(char c) { return (uint8_t) (c - '0') < 10; } static inline uint16_t load_u16le(const void* ptr) { #if defined(__ARM_ARCH_7A__) || defined(__aarch64__) return *((const uint16_t*) ptr); #else const uint8_t* byte_ptr = (const uint8_t*) ptr; return ((uint16_t) byte_ptr[1] << 8) | (uint16_t) byte_ptr[0]; #endif } static inline uint32_t load_u24le(const void* ptr) { #if defined(__ARM_ARCH_7A__) || defined(__aarch64__) return ((uint32_t) ((const uint8_t*) ptr)[2] << 16) | ((uint32_t) *((const uint16_t*) ptr)); #else const uint8_t* byte_ptr = (const uint8_t*) ptr; return ((uint32_t) byte_ptr[2] << 16) | ((uint32_t) byte_ptr[1] << 8) | (uint32_t) byte_ptr[0]; #endif } static inline uint32_t load_u32le(const void* ptr) { #if defined(__ARM_ARCH_7A__) || defined(__aarch64__) return *((const uint32_t*) ptr); #else return ((uint32_t) ((const uint8_t*) ptr)[3] << 24) | load_u24le(ptr); #endif } /* * Map from ARM chipset series ID to ARM chipset vendor ID. * This map is used to avoid storing vendor IDs in tables. */ static enum cpuinfo_arm_chipset_vendor chipset_series_vendor[cpuinfo_arm_chipset_series_max] = { [cpuinfo_arm_chipset_series_unknown] = cpuinfo_arm_chipset_vendor_unknown, [cpuinfo_arm_chipset_series_qualcomm_qsd] = cpuinfo_arm_chipset_vendor_qualcomm, [cpuinfo_arm_chipset_series_qualcomm_msm] = cpuinfo_arm_chipset_vendor_qualcomm, [cpuinfo_arm_chipset_series_qualcomm_apq] = cpuinfo_arm_chipset_vendor_qualcomm, [cpuinfo_arm_chipset_series_qualcomm_snapdragon] = cpuinfo_arm_chipset_vendor_qualcomm, [cpuinfo_arm_chipset_series_mediatek_mt] = cpuinfo_arm_chipset_vendor_mediatek, [cpuinfo_arm_chipset_series_samsung_exynos] = cpuinfo_arm_chipset_vendor_samsung, [cpuinfo_arm_chipset_series_hisilicon_k3v] = cpuinfo_arm_chipset_vendor_hisilicon, [cpuinfo_arm_chipset_series_hisilicon_hi] = cpuinfo_arm_chipset_vendor_hisilicon, [cpuinfo_arm_chipset_series_hisilicon_kirin] = cpuinfo_arm_chipset_vendor_hisilicon, [cpuinfo_arm_chipset_series_actions_atm] = cpuinfo_arm_chipset_vendor_actions, [cpuinfo_arm_chipset_series_allwinner_a] = cpuinfo_arm_chipset_vendor_allwinner, [cpuinfo_arm_chipset_series_amlogic_aml] = cpuinfo_arm_chipset_vendor_amlogic, [cpuinfo_arm_chipset_series_amlogic_s] = cpuinfo_arm_chipset_vendor_amlogic, [cpuinfo_arm_chipset_series_broadcom_bcm] = cpuinfo_arm_chipset_vendor_broadcom, [cpuinfo_arm_chipset_series_lg_nuclun] = cpuinfo_arm_chipset_vendor_lg, [cpuinfo_arm_chipset_series_leadcore_lc] = cpuinfo_arm_chipset_vendor_leadcore, [cpuinfo_arm_chipset_series_marvell_pxa] = cpuinfo_arm_chipset_vendor_marvell, [cpuinfo_arm_chipset_series_mstar_6a] = cpuinfo_arm_chipset_vendor_mstar, [cpuinfo_arm_chipset_series_novathor_u] = cpuinfo_arm_chipset_vendor_novathor, [cpuinfo_arm_chipset_series_nvidia_tegra_t] = cpuinfo_arm_chipset_vendor_nvidia, [cpuinfo_arm_chipset_series_nvidia_tegra_ap] = cpuinfo_arm_chipset_vendor_nvidia, [cpuinfo_arm_chipset_series_nvidia_tegra_sl] = cpuinfo_arm_chipset_vendor_nvidia, [cpuinfo_arm_chipset_series_pinecone_surge_s] = cpuinfo_arm_chipset_vendor_pinecone, [cpuinfo_arm_chipset_series_renesas_mp] = cpuinfo_arm_chipset_vendor_renesas, [cpuinfo_arm_chipset_series_rockchip_rk] = cpuinfo_arm_chipset_vendor_rockchip, [cpuinfo_arm_chipset_series_spreadtrum_sc] = cpuinfo_arm_chipset_vendor_spreadtrum, [cpuinfo_arm_chipset_series_telechips_tcc] = cpuinfo_arm_chipset_vendor_telechips, [cpuinfo_arm_chipset_series_texas_instruments_omap] = cpuinfo_arm_chipset_vendor_texas_instruments, [cpuinfo_arm_chipset_series_wondermedia_wm] = cpuinfo_arm_chipset_vendor_wondermedia, }; /** * Tries to match /(MSM|APQ)\d{4}([A-Z\-]*)/ signature (case-insensitive) for Qualcomm MSM and APQ chipsets. * If match successful, extracts model information into \p chipset argument. * * @param start - start of the platform identifier (/proc/cpuinfo Hardware string, ro.product.board, ro.board.platform * or ro.chipname) to match. * @param end - end of the platform identifier (/proc/cpuinfo Hardware string, ro.product.board, ro.board.platform or * ro.chipname) to match. * @param[out] chipset - location where chipset information will be stored upon a successful match. * * @returns true if signature matched, false otherwise. */ static bool match_msm_apq( const char* start, const char* end, struct cpuinfo_arm_chipset chipset[restrict static 1]) { /* Expect at least 7 symbols: 3 symbols "MSM" or "APQ" + 4 digits */ if (start + 7 > end) { return false; } /* Check that string starts with "MSM" or "APQ", case-insensitive. * The first three characters are loaded as 24-bit little endian word, binary ORed with 0x20 to convert to lower * case, and compared to "MSM" and "APQ" strings as integers. */ const uint32_t series_signature = UINT32_C(0x00202020) | load_u24le(start); enum cpuinfo_arm_chipset_series series; switch (series_signature) { case UINT32_C(0x6D736D): /* "msm" = reverse("msm") */ series = cpuinfo_arm_chipset_series_qualcomm_msm; break; case UINT32_C(0x717061): /* "qpa" = reverse("apq") */ series = cpuinfo_arm_chipset_series_qualcomm_apq; break; default: return false; } /* Sometimes there is a space ' ' following the MSM/APQ series */ const char* pos = start + 3; if (*pos == ' ') { pos++; /* Expect at least 4 more symbols (4-digit model number) */ if (pos + 4 > end) { return false; } } /* Validate and parse 4-digit model number */ uint32_t model = 0; for (uint32_t i = 0; i < 4; i++) { const uint32_t digit = (uint32_t) (uint8_t) (*pos++) - '0'; if (digit >= 10) { /* Not really a digit */ return false; } model = model * 10 + digit; } /* Suffix is optional, so if we got to this point, parsing is successful. Commit parsed chipset. */ *chipset = (struct cpuinfo_arm_chipset) { .vendor = cpuinfo_arm_chipset_vendor_qualcomm, .series = series, .model = model, }; /* Parse as many suffix characters as match the pattern [A-Za-z\-] */ for (uint32_t i = 0; i < CPUINFO_ARM_CHIPSET_SUFFIX_MAX; i++) { if (pos + i == end) { break; } const char c = pos[i]; if (is_ascii_alphabetic(c)) { /* Matched a letter [A-Za-z] */ chipset->suffix[i] = c & '\xDF'; } else if (c == '-') { /* Matched a dash '-' */ chipset->suffix[i] = c; } else { /* Neither of [A-Za-z\-] */ break; } } return true; } /** * Tries to match /SDM\d{3}$/ signature for Qualcomm Snapdragon chipsets. * If match successful, extracts model information into \p chipset argument. * * @param start - start of the /proc/cpuinfo Hardware string to match. * @param end - end of the /proc/cpuinfo Hardware string to match. * @param[out] chipset - location where chipset information will be stored upon a successful match. * * @returns true if signature matched, false otherwise. */ static bool match_sdm( const char* start, const char* end, struct cpuinfo_arm_chipset chipset[restrict static 1]) { /* Expect exactly 6 symbols: 3 symbols "SDM" + 3 digits */ if (start + 6 != end) { return false; } /* Check that string starts with "SDM". * The first three characters are loaded and compared as 24-bit little endian word. */ const uint32_t expected_sdm = load_u24le(start); if (expected_sdm != UINT32_C(0x004D4453) /* "MDS" = reverse("SDM") */) { return false; } /* Validate and parse 3-digit model number */ uint32_t model = 0; for (uint32_t i = 3; i < 6; i++) { const uint32_t digit = (uint32_t) (uint8_t) start[i] - '0'; if (digit >= 10) { /* Not really a digit */ return false; } model = model * 10 + digit; } /* Return parsed chipset. */ *chipset = (struct cpuinfo_arm_chipset) { .vendor = cpuinfo_arm_chipset_vendor_qualcomm, .series = cpuinfo_arm_chipset_series_qualcomm_snapdragon, .model = model, }; return true; } /** * Tries to match /SM\d{4}$/ signature for Qualcomm Snapdragon chipsets. * If match successful, extracts model information into \p chipset argument. * * @param start - start of the /proc/cpuinfo Hardware string to match. * @param end - end of the /proc/cpuinfo Hardware string to match. * @param[out] chipset - location where chipset information will be stored upon a successful match. * * @returns true if signature matched, false otherwise. */ static bool match_sm( const char* start, const char* end, struct cpuinfo_arm_chipset chipset[restrict static 1]) { /* Expect exactly 6 symbols: 2 symbols "SM" + 4 digits */ if (start + 6 != end) { return false; } /* Check that string starts with "SM". * The first three characters are loaded and compared as 16-bit little endian word. */ const uint32_t expected_sm = load_u16le(start); if (expected_sm != UINT16_C(0x4D53) /* "MS" = reverse("SM") */) { return false; } /* Validate and parse 4-digit model number */ uint32_t model = 0; for (uint32_t i = 2; i < 6; i++) { const uint32_t digit = (uint32_t) (uint8_t) start[i] - '0'; if (digit >= 10) { /* Not really a digit */ return false; } model = model * 10 + digit; } /* Return parsed chipset. */ *chipset = (struct cpuinfo_arm_chipset) { .vendor = cpuinfo_arm_chipset_vendor_qualcomm, .series = cpuinfo_arm_chipset_series_qualcomm_snapdragon, .model = model, }; return true; } /** * Tries to match /Samsung Exynos\d{4}$/ signature (case-insensitive) for Samsung Exynos chipsets. * If match successful, extracts model information into \p chipset argument. * * @param start - start of the /proc/cpuinfo Hardware string to match. * @param end - end of the /proc/cpuinfo Hardware string to match. * @param[out] chipset - location where chipset information will be stored upon a successful match. * * @returns true if signature matched, false otherwise. */ static bool match_samsung_exynos( const char* start, const char* end, struct cpuinfo_arm_chipset chipset[restrict static 1]) { /* * Expect at 18-19 symbols: * - "Samsung" (7 symbols) + space + "Exynos" (6 symbols) + optional space 4-digit model number */ const size_t length = end - start; switch (length) { case 18: case 19: break; default: return false; } /* * Check that the string starts with "samsung exynos", case-insensitive. * Blocks of 4 characters are loaded and compared as little-endian 32-bit word. * Case-insensitive characters are binary ORed with 0x20 to convert them to lowercase. */ const uint32_t expected_sams = UINT32_C(0x20202000) | load_u32le(start); if (expected_sams != UINT32_C(0x736D6153) /* "smaS" = reverse("Sams") */) { return false; } const uint32_t expected_ung = UINT32_C(0x00202020) | load_u32le(start + 4); if (expected_ung != UINT32_C(0x20676E75) /* " ung" = reverse("ung ") */) { return false; } const uint32_t expected_exyn = UINT32_C(0x20202000) | load_u32le(start + 8); if (expected_exyn != UINT32_C(0x6E797845) /* "nyxE" = reverse("Exyn") */) { return false; } const uint16_t expected_os = UINT16_C(0x2020) | load_u16le(start + 12); if (expected_os != UINT16_C(0x736F) /* "so" = reverse("os") */) { return false; } const char* pos = start + 14; /* There can be a space ' ' following the "Exynos" string */ if (*pos == ' ') { pos++; /* If optional space if present, we expect exactly 19 characters */ if (length != 19) { return false; } } /* Validate and parse 4-digit model number */ uint32_t model = 0; for (uint32_t i = 0; i < 4; i++) { const uint32_t digit = (uint32_t) (uint8_t) (*pos++) - '0'; if (digit >= 10) { /* Not really a digit */ return false; } model = model * 10 + digit; } /* Return parsed chipset */ *chipset = (struct cpuinfo_arm_chipset) { .vendor = cpuinfo_arm_chipset_vendor_samsung, .series = cpuinfo_arm_chipset_series_samsung_exynos, .model = model, }; return true; } /** * Tries to match /exynos\d{4}$/ signature for Samsung Exynos chipsets. * If match successful, extracts model information into \p chipset argument. * * @param start - start of the platform identifier (ro.board.platform or ro.chipname) to match. * @param end - end of the platform identifier (ro.board.platform or ro.chipname) to match. * @param[out] chipset - location where chipset information will be stored upon a successful match. * * @returns true if signature matched, false otherwise. */ static bool match_exynos( const char* start, const char* end, struct cpuinfo_arm_chipset chipset[restrict static 1]) { /* Expect exactly 10 symbols: "exynos" (6 symbols) + 4-digit model number */ if (start + 10 != end) { return false; } /* Load first 4 bytes as little endian 32-bit word */ const uint32_t expected_exyn = load_u32le(start); if (expected_exyn != UINT32_C(0x6E797865) /* "nyxe" = reverse("exyn") */ ) { return false; } /* Load next 2 bytes as little endian 16-bit word */ const uint16_t expected_os = load_u16le(start + 4); if (expected_os != UINT16_C(0x736F) /* "so" = reverse("os") */ ) { return false; } /* Check and parse 4-digit model number */ uint32_t model = 0; for (uint32_t i = 6; i < 10; i++) { const uint32_t digit = (uint32_t) (uint8_t) start[i] - '0'; if (digit >= 10) { /* Not really a digit */ return false; } model = model * 10 + digit; } /* Return parsed chipset. */ *chipset = (struct cpuinfo_arm_chipset) { .vendor = cpuinfo_arm_chipset_vendor_samsung, .series = cpuinfo_arm_chipset_series_samsung_exynos, .model = model, }; return true; } /** * Tries to match /universal\d{4}$/ signature for Samsung Exynos chipsets. * If match successful, extracts model information into \p chipset argument. * * @param start - start of the platform identifier (/proc/cpuinfo Hardware string, ro.product.board or ro.chipname) * to match. * @param end - end of the platform identifier (/proc/cpuinfo Hardware string, ro.product.board or ro.chipname) * to match. * @param[out] chipset - location where chipset information will be stored upon a successful match. * * @returns true if signature matched, false otherwise. */ static bool match_universal( const char* start, const char* end, struct cpuinfo_arm_chipset chipset[restrict static 1]) { /* Expect exactly 13 symbols: "universal" (9 symbols) + 4-digit model number */ if (start + 13 != end) { return false; } /* * Check that the string starts with "universal". * Blocks of 4 characters are loaded and compared as little-endian 32-bit word. * Case-insensitive characters are binary ORed with 0x20 to convert them to lowercase. */ const uint8_t expected_u = UINT8_C(0x20) | (uint8_t) start[0]; if (expected_u != UINT8_C(0x75) /* "u" */) { return false; } const uint32_t expected_nive = UINT32_C(0x20202020) | load_u32le(start + 1); if (expected_nive != UINT32_C(0x6576696E) /* "evin" = reverse("nive") */ ) { return false; } const uint32_t expected_ersa = UINT32_C(0x20202020) | load_u32le(start + 5); if (expected_ersa != UINT32_C(0x6C617372) /* "lasr" = reverse("rsal") */) { return false; } /* Validate and parse 4-digit model number */ uint32_t model = 0; for (uint32_t i = 9; i < 13; i++) { const uint32_t digit = (uint32_t) (uint8_t) start[i] - '0'; if (digit >= 10) { /* Not really a digit */ return false; } model = model * 10 + digit; } /* Return parsed chipset. */ *chipset = (struct cpuinfo_arm_chipset) { .vendor = cpuinfo_arm_chipset_vendor_samsung, .series = cpuinfo_arm_chipset_series_samsung_exynos, .model = model, }; return true; } /** * Compares, case insensitively, a string to known values "SMDK4210" and "SMDK4x12" for Samsung Exynos chipsets. * If platform identifier matches one of the SMDK* values, extracts model information into \p chipset argument. * For "SMDK4x12" match, decodes the chipset name using number of cores. * * @param start - start of the platform identifier (/proc/cpuinfo Hardware string or ro.product.board) to match. * @param end - end of the platform identifier (/proc/cpuinfo Hardware string or ro.product.board) to match. * @param cores - number of cores in the chipset. * @param[out] chipset - location where chipset information will be stored upon a successful match. * * @returns true if signature matched, false otherwise. */ static bool match_and_parse_smdk( const char* start, const char* end, uint32_t cores, struct cpuinfo_arm_chipset chipset[restrict static 1]) { /* Expect exactly 8 symbols: "SMDK" (4 symbols) + 4-digit model number */ if (start + 8 != end) { return false; } /* * Check that string starts with "MT" (case-insensitive). * The first four characters are loaded as a 32-bit little endian word and converted to lowercase. */ const uint32_t expected_smdk = UINT32_C(0x20202020) | load_u32le(start); if (expected_smdk != UINT32_C(0x6B646D73) /* "kdms" = reverse("smdk") */) { return false; } /* * Check that string ends with "4210" or "4x12". * The last four characters are loaded and compared as a 32-bit little endian word. */ uint32_t model = 0; const uint32_t expected_model = load_u32le(start + 4); switch (expected_model) { case UINT32_C(0x30313234): /* "0124" = reverse("4210") */ model = 4210; break; case UINT32_C(0x32317834): /* "21x4" = reverse("4x12") */ switch (cores) { case 2: model = 4212; break; case 4: model = 4412; break; default: cpuinfo_log_warning("system reported invalid %"PRIu32"-core Exynos 4x12 chipset", cores); } } if (model == 0) { return false; } *chipset = (struct cpuinfo_arm_chipset) { .vendor = cpuinfo_arm_chipset_vendor_samsung, .series = cpuinfo_arm_chipset_series_samsung_exynos, .model = model, }; return true; } /** * Tries to match /MTK?\d{4}[A-Z/]*$/ signature for MediaTek MT chipsets. * If match successful, extracts model information into \p chipset argument. * * @param start - start of the platform identifier (/proc/cpuinfo Hardware string, ro.product.board, ro.board.platform, * ro.mediatek.platform, or ro.chipname) to match. * @param end - end of the platform identifier (/proc/cpuinfo Hardware string, ro.product.board, ro.board.platform, * ro.mediatek.platform, or ro.chipname) to match. * @param match_end - indicates if the function should attempt to match through the end of the string and fail if there * are unparsed characters in the end, or match only MTK signature, model number, and some of the * suffix characters (the ones that pass validation). * @param[out] chipset - location where chipset information will be stored upon a successful match. * * @returns true if signature matched, false otherwise. */ static bool match_mt( const char* start, const char* end, bool match_end, struct cpuinfo_arm_chipset chipset[restrict static 1]) { /* Expect at least 6 symbols: "MT" (2 symbols) + 4-digit model number */ if (start + 6 > end) { return false; } /* * Check that string starts with "MT" (case-insensitive). * The first two characters are loaded as 16-bit little endian word and converted to lowercase. */ const uint16_t mt = UINT16_C(0x2020) | load_u16le(start); if (mt != UINT16_C(0x746D) /* "tm" */) { return false; } /* Some images report "MTK" rather than "MT" */ const char* pos = start + 2; if (((uint8_t) *pos | UINT8_C(0x20)) == (uint8_t) 'k') { pos++; /* Expect 4 more symbols after "MTK" (4-digit model number) */ if (pos + 4 > end) { return false; } } /* Validate and parse 4-digit model number */ uint32_t model = 0; for (uint32_t i = 0; i < 4; i++) { const uint32_t digit = (uint32_t) (uint8_t) (*pos++) - '0'; if (digit >= 10) { /* Not really a digit */ return false; } model = model * 10 + digit; } /* Record parsed chipset. This implicitly zeroes-out suffix, which will be parsed later. */ *chipset = (struct cpuinfo_arm_chipset) { .vendor = cpuinfo_arm_chipset_vendor_mediatek, .series = cpuinfo_arm_chipset_series_mediatek_mt, .model = model, }; if (match_end) { /* Check that the potential suffix does not exceed maximum length */ const size_t suffix_length = end - pos; if (suffix_length > CPUINFO_ARM_CHIPSET_SUFFIX_MAX) { return false; } /* Validate suffix characters and copy them to chipset structure */ for (size_t i = 0; i < suffix_length; i++) { const char c = (*pos++); if (is_ascii_alphabetic(c)) { /* Matched a letter [A-Za-z], convert to uppercase */ chipset->suffix[i] = c & '\xDF'; } else if (c == '/') { /* Matched a slash '/' */ chipset->suffix[i] = c; } else { /* Invalid suffix character (neither of [A-Za-z/]) */ return false; } } } else { /* Validate and parse as many suffix characters as we can */ for (size_t i = 0; i < CPUINFO_ARM_CHIPSET_SUFFIX_MAX; i++) { if (pos + i == end) { break; } const char c = pos[i]; if (is_ascii_alphabetic(c)) { /* Matched a letter [A-Za-z], convert to uppercase */ chipset->suffix[i] = c & '\xDF'; } else if (c == '/') { /* Matched a slash '/' */ chipset->suffix[i] = c; } else { /* Invalid suffix character (neither of [A-Za-z/]). This marks the end of the suffix. */ break; } } } /* All suffix characters successfully validated and copied to chipset data */ return true; } /** * Tries to match /[Kk]irin\s?\d{3}$/ signature for HiSilicon Kirin chipsets. * If match successful, extracts model information into \p chipset argument. * * @param start - start of the /proc/cpuinfo Hardware string to match. * @param end - end of the /proc/cpuinfo Hardware string to match. * @param[out] chipset - location where chipset information will be stored upon a successful match. * * @returns true if signature matched, false otherwise. */ static bool match_kirin( const char* start, const char* end, struct cpuinfo_arm_chipset chipset[restrict static 1]) { /* Expect 8-9 symbols: "Kirin" (5 symbols) + optional whitespace (1 symbol) + 3-digit model number */ const size_t length = end - start; switch (length) { case 8: case 9: break; default: return false; } /* Check that the string starts with "Kirin" or "kirin". */ if (((uint8_t) start[0] | UINT8_C(0x20)) != (uint8_t) 'k') { return false; } /* Symbols 1-5 are loaded and compared as little-endian 32-bit word. */ const uint32_t irin = load_u32le(start + 1); if (irin != UINT32_C(0x6E697269) /* "niri" = reverse("irin") */) { return false; } /* Check for optional whitespace after "Kirin" */ if (is_ascii_whitespace(start[5])) { /* When whitespace is present after "Kirin", expect 9 symbols total */ if (length != 9) { return false; } } /* Validate and parse 3-digit model number */ uint32_t model = 0; for (int32_t i = 0; i < 3; i++) { const uint32_t digit = (uint32_t) (uint8_t) end[i - 3] - '0'; if (digit >= 10) { /* Not really a digit */ return false; } model = model * 10 + digit; } /* * Thats it, return parsed chipset. * Technically, Kirin 910T has a suffix, but it never appears in the form of "910T" string. * Instead, Kirin 910T devices report "hi6620oem" string (handled outside of this function). */ *chipset = (struct cpuinfo_arm_chipset) { .vendor = cpuinfo_arm_chipset_vendor_hisilicon, .series = cpuinfo_arm_chipset_series_hisilicon_kirin, .model = model, }; return true; } /** * Tries to match /rk\d{4}[a-z]?$/ signature for Rockchip RK chipsets. * If match successful, extracts model information into \p chipset argument. * * @param start - start of the platform identifier (/proc/cpuinfo Hardware string or ro.board.platform) to match. * @param end - end of the platform identifier (/proc/cpuinfo Hardware string or ro.board.platform) to match. * @param[out] chipset - location where chipset information will be stored upon a successful match. * * @returns true if signature matched, false otherwise. */ static bool match_rk( const char* start, const char* end, struct cpuinfo_arm_chipset chipset[restrict static 1]) { /* Expect 6-7 symbols: "RK" (2 symbols) + 4-digit model number + optional 1-letter suffix */ const size_t length = end - start; switch (length) { case 6: case 7: break; default: return false; } /* * Check that string starts with "RK" (case-insensitive). * The first two characters are loaded as 16-bit little endian word and converted to lowercase. */ const uint16_t expected_rk = UINT16_C(0x2020) | load_u16le(start); if (expected_rk != UINT16_C(0x6B72) /* "kr" = reverse("rk") */) { return false; } /* Validate and parse 4-digit model number */ uint32_t model = 0; for (uint32_t i = 2; i < 6; i++) { const uint32_t digit = (uint32_t) (uint8_t) start[i] - '0'; if (digit >= 10) { /* Not really a digit */ return false; } model = model * 10 + digit; } /* Parse optional suffix */ char suffix = 0; if (length == 7) { /* Parse the suffix letter */ const char c = start[6]; if (is_ascii_alphabetic(c)) { /* Convert to upper case */ suffix = c & '\xDF'; } else { /* Invalid suffix character */ return false; } } /* Return parsed chipset */ *chipset = (struct cpuinfo_arm_chipset) { .vendor = cpuinfo_arm_chipset_vendor_rockchip, .series = cpuinfo_arm_chipset_series_rockchip_rk, .model = model, .suffix = { [0] = suffix, }, }; return true; } /** * Tries to match, case-insentitively, /s[cp]\d{4}[a-z]*|scx15$/ signature for Spreadtrum SC chipsets. * If match successful, extracts model information into \p chipset argument. * * @param start - start of the platform identifier (/proc/cpuinfo Hardware string, ro.product.board, * ro.board.platform, or ro.chipname) to match. * @param end - end of the platform identifier (/proc/cpuinfo Hardware string, ro.product.board, * ro.board.platform, or ro.chipname) to match. * @param[out] chipset - location where chipset information will be stored upon a successful match. * * @returns true if signature matched, false otherwise. */ static bool match_sc( const char* start, const char* end, struct cpuinfo_arm_chipset chipset[restrict static 1]) { /* Expect at least 5 symbols: "scx15" */ if (start + 5 > end) { return false; } /* * Check that string starts with "S[CP]" (case-insensitive). * The first two characters are loaded as 16-bit little endian word and converted to lowercase. */ const uint16_t expected_sc_or_sp = UINT16_C(0x2020) | load_u16le(start); switch (expected_sc_or_sp) { case UINT16_C(0x6373): /* "cs" = reverse("sc") */ case UINT16_C(0x7073): /* "ps" = reverse("sp") */ break; default: return false; } /* Special case: "scx" prefix (SC7715 reported as "scx15") */ if ((start[2] | '\x20') == 'x') { /* Expect exactly 5 characters: "scx15" */ if (start + 5 != end) { return false; } /* Check that string ends with "15" */ const uint16_t expected_15 = load_u16le(start + 3); if (expected_15 != UINT16_C(0x3531) /* "51" = reverse("15") */ ) { return false; } *chipset = (struct cpuinfo_arm_chipset) { .vendor = cpuinfo_arm_chipset_vendor_spreadtrum, .series = cpuinfo_arm_chipset_series_spreadtrum_sc, .model = 7715, }; return true; } /* Expect at least 6 symbols: "S[CP]" (2 symbols) + 4-digit model number */ if (start + 6 > end) { return false; } /* Validate and parse 4-digit model number */ uint32_t model = 0; for (uint32_t i = 2; i < 6; i++) { const uint32_t digit = (uint32_t) (uint8_t) start[i] - '0'; if (digit >= 10) { /* Not really a digit */ return false; } model = model * 10 + digit; } /* Write parsed chipset */ *chipset = (struct cpuinfo_arm_chipset) { .vendor = cpuinfo_arm_chipset_vendor_spreadtrum, .series = cpuinfo_arm_chipset_series_spreadtrum_sc, .model = model, }; /* Validate and copy suffix letters. If suffix is too long, truncate at CPUINFO_ARM_CHIPSET_SUFFIX_MAX letters. */ const char* suffix = start + 6; for (size_t i = 0; i < CPUINFO_ARM_CHIPSET_SUFFIX_MAX; i++) { if (suffix + i == end) { break; } const char c = suffix[i]; if (!is_ascii_alphabetic(c)) { /* Invalid suffix character */ return false; } /* Convert suffix letter to uppercase */ chipset->suffix[i] = c & '\xDF'; } return true; } /** * Tries to match /lc\d{4}[a-z]?$/ signature for Leadcore LC chipsets. * If match successful, extracts model information into \p chipset argument. * * @param start - start of the platform identifier (ro.product.board or ro.board.platform) to match. * @param end - end of the platform identifier (ro.product.board or ro.board.platform) to match. * @param[out] chipset - location where chipset information will be stored upon a successful match. * * @returns true if signature matched, false otherwise. */ static bool match_lc( const char* start, const char* end, struct cpuinfo_arm_chipset chipset[restrict static 1]) { /* Expect at 6-7 symbols: "lc" (2 symbols) + 4-digit model number + optional 1-letter suffix */ const size_t length = end - start; switch (length) { case 6: case 7: break; default: return false; } /* Check that string starts with "lc". The first two characters are loaded as 16-bit little endian word */ const uint16_t expected_lc = load_u16le(start); if (expected_lc != UINT16_C(0x636C) /* "cl" = reverse("lc") */) { return false; } /* Validate and parse 4-digit model number */ uint32_t model = 0; for (uint32_t i = 2; i < 6; i++) { const uint32_t digit = (uint32_t) (uint8_t) start[i] - '0'; if (digit >= 10) { /* Not really a digit */ return false; } model = model * 10 + digit; } /* Parse optional suffix letter */ char suffix = 0; if (length == 7) { const char c = start[6]; if (is_ascii_alphabetic(c)) { /* Convert to uppercase */ chipset->suffix[0] = c & '\xDF'; } else { /* Invalid suffix character */ return false; } } /* Return parsed chipset */ *chipset = (struct cpuinfo_arm_chipset) { .vendor = cpuinfo_arm_chipset_vendor_leadcore, .series = cpuinfo_arm_chipset_series_leadcore_lc, .model = model, .suffix = { [0] = suffix, }, }; return true; } /** * Tries to match /PXA(\d{3,4}|1L88)$/ signature for Marvell PXA chipsets. * If match successful, extracts model information into \p chipset argument. * * @param start - start of the platform identifier (/proc/cpuinfo Hardware string, ro.product.board or ro.chipname) * to match. * @param end - end of the platform identifier (/proc/cpuinfo Hardaware string, ro.product.board or ro.chipname) to * match. * @param[out] chipset - location where chipset information will be stored upon a successful match. * * @returns true if signature matched, false otherwise. */ static bool match_pxa( const char* start, const char* end, struct cpuinfo_arm_chipset chipset[restrict static 1]) { /* Expect 6-7 symbols: "PXA" (3 symbols) + 3-4 digit model number */ const size_t length = end - start; switch (length) { case 6: case 7: break; default: return false; } /* Check that the string starts with "PXA". Symbols 1-3 are loaded and compared as little-endian 16-bit word. */ if (start[0] != 'P') { return false; } const uint16_t expected_xa = load_u16le(start + 1); if (expected_xa != UINT16_C(0x4158) /* "AX" = reverse("XA") */) { return false; } uint32_t model = 0; /* Check for a very common typo: "PXA1L88" for "PXA1088" */ if (length == 7) { /* Load 4 model "number" symbols as a little endian 32-bit word and compare to "1L88" */ const uint32_t expected_1L88 = load_u32le(start + 3); if (expected_1L88 == UINT32_C(0x38384C31) /* "88L1" = reverse("1L88") */) { model = 1088; goto write_chipset; } } /* Check and parse 3-4 digit model number */ for (uint32_t i = 3; i < length; i++) { const uint32_t digit = (uint32_t) (uint8_t) start[i] - '0'; if (digit >= 10) { /* Not really a digit */ return false; } model = model * 10 + digit; } /* Return parsed chipset. */ write_chipset: *chipset = (struct cpuinfo_arm_chipset) { .vendor = cpuinfo_arm_chipset_vendor_marvell, .series = cpuinfo_arm_chipset_series_marvell_pxa, .model = model, }; return true; } /** * Tries to match /BCM\d{4}$/ signature for Broadcom BCM chipsets. * If match successful, extracts model information into \p chipset argument. * * @param start - start of the /proc/cpuinfo Hardware string to match. * @param end - end of the /proc/cpuinfo Hardware string to match. * @param[out] chipset - location where chipset information will be stored upon a successful match. * * @returns true if signature matched, false otherwise. */ static bool match_bcm( const char* start, const char* end, struct cpuinfo_arm_chipset chipset[restrict static 1]) { /* Expect exactly 7 symbols: "BCM" (3 symbols) + 4-digit model number */ if (start + 7 != end) { return false; } /* Check that the string starts with "BCM". * The first three characters are loaded and compared as a 24-bit little endian word. */ const uint32_t expected_bcm = load_u24le(start); if (expected_bcm != UINT32_C(0x004D4342) /* "MCB" = reverse("BCM") */) { return false; } /* Validate and parse 4-digit model number */ uint32_t model = 0; for (uint32_t i = 3; i < 7; i++) { const uint32_t digit = (uint32_t) (uint8_t) start[i] - '0'; if (digit >= 10) { /* Not really a digit */ return false; } model = model * 10 + digit; } /* Return parsed chipset. */ *chipset = (struct cpuinfo_arm_chipset) { .vendor = cpuinfo_arm_chipset_vendor_broadcom, .series = cpuinfo_arm_chipset_series_broadcom_bcm, .model = model, }; return true; } /** * Tries to match /OMAP\d{4}$/ signature for Texas Instruments OMAP chipsets. * If match successful, extracts model information into \p chipset argument. * * @param start - start of the /proc/cpuinfo Hardware string to match. * @param end - end of the /proc/cpuinfo Hardware string to match. * @param[out] chipset - location where chipset information will be stored upon a successful match. * * @returns true if signature matched, false otherwise. */ static bool match_omap( const char* start, const char* end, struct cpuinfo_arm_chipset chipset[restrict static 1]) { /* Expect exactly 8 symbols: "OMAP" (4 symbols) + 4-digit model number */ if (start + 8 != end) { return false; } /* Check that the string starts with "OMAP". Symbols 0-4 are loaded and compared as little-endian 32-bit word. */ const uint32_t expected_omap = load_u32le(start); if (expected_omap != UINT32_C(0x50414D4F) /* "PAMO" = reverse("OMAP") */) { return false; } /* Validate and parse 4-digit model number */ uint32_t model = 0; for (uint32_t i = 4; i < 8; i++) { const uint32_t digit = (uint32_t) (uint8_t) start[i] - '0'; if (digit >= 10) { /* Not really a digit */ return false; } model = model * 10 + digit; } /* Return parsed chipset. */ *chipset = (struct cpuinfo_arm_chipset) { .vendor = cpuinfo_arm_chipset_vendor_texas_instruments, .series = cpuinfo_arm_chipset_series_texas_instruments_omap, .model = model, }; return true; } /** * Compares platform identifier string to known values for Broadcom chipsets. * If the string matches one of the known values, the function decodes Broadcom chipset from frequency and number of * cores into \p chipset argument. * * @param start - start of the platform identifier (ro.product.board or ro.board.platform) to match. * @param end - end of the platform identifier (ro.product.board or ro.board.platform) to match. * @param cores - number of cores in the chipset. * @param max_cpu_freq_max - maximum of /sys/devices/system/cpu/cpu/cpofreq/cpu_freq_max values. * @param[out] chipset - location where chipset information will be stored upon a successful match and decoding. * * @returns true if signature matched (even if exact model can't be decoded), false otherwise. */ static bool match_and_parse_broadcom( const char* start, const char* end, uint32_t cores, uint32_t max_cpu_freq_max, struct cpuinfo_arm_chipset chipset[restrict static 1]) { /* Expect 4-6 symbols: "java" (4 symbols), "rhea" (4 symbols), "capri" (5 symbols), or "hawaii" (6 symbols) */ const size_t length = end - start; switch (length) { case 4: case 5: case 6: break; default: return false; } /* * Compare the platform identifier to known values for Broadcom chipsets: * - "rhea" * - "java" * - "capri" * - "hawaii" * Upon a successful match, decode chipset name from frequency and number of cores. */ uint32_t model = 0; char suffix = 0; const uint32_t expected_platform = load_u32le(start); switch (expected_platform) { case UINT32_C(0x61656872): /* "aehr" = reverse("rhea") */ if (length == 4) { /* * Detected "rhea" platform: * - 1 core @ 849999 KHz -> BCM21654 * - 1 core @ 999999 KHz -> BCM21654G */ if (cores == 1) { model = 21654; if (max_cpu_freq_max >= 999999) { suffix = 'G'; } } } break; case UINT32_C(0x6176616A): /* "avaj" = reverse("java") */ if (length == 4) { /* * Detected "java" platform: * - 4 cores -> BCM23550 */ if (cores == 4) { model = 23550; } } break; case UINT32_C(0x61776168): /* "awah" = reverse("hawa") */ if (length == 6) { /* Check that string equals "hawaii" */ const uint16_t expected_ii = load_u16le(start + 4); if (expected_ii == UINT16_C(0x6969) /* "ii" */ ) { /* * Detected "hawaii" platform: * - 1 core -> BCM21663 * - 2 cores @ 999999 KHz -> BCM21664 * - 2 cores @ 1200000 KHz -> BCM21664T */ switch (cores) { case 1: model = 21663; break; case 2: model = 21664; if (max_cpu_freq_max >= 1200000) { suffix = 'T'; } break; } } } break; case UINT32_C(0x72706163): /* "rpac" = reverse("capr") */ if (length == 5) { /* Check that string equals "capri" */ if (start[4] == 'i') { /* * Detected "capri" platform: * - 2 cores -> BCM28155 */ if (cores == 2) { model = 28155; } } } break; } if (model != 0) { /* Chipset was successfully decoded */ *chipset = (struct cpuinfo_arm_chipset) { .vendor = cpuinfo_arm_chipset_vendor_broadcom, .series = cpuinfo_arm_chipset_series_broadcom_bcm, .model = model, .suffix = { [0] = suffix, }, }; } return model != 0; } struct sunxi_map_entry { uint8_t sunxi; uint8_t cores; uint8_t model; char suffix; }; static const struct sunxi_map_entry sunxi_map_entries[] = { #if CPUINFO_ARCH_ARM { /* ("sun4i", 1) -> "A10" */ .sunxi = 4, .cores = 1, .model = 10, }, { /* ("sun5i", 1) -> "A13" */ .sunxi = 5, .cores = 1, .model = 13, }, { /* ("sun6i", 4) -> "A31" */ .sunxi = 6, .cores = 4, .model = 31, }, { /* ("sun7i", 2) -> "A20" */ .sunxi = 7, .cores = 2, .model = 20, }, { /* ("sun8i", 2) -> "A23" */ .sunxi = 8, .cores = 2, .model = 23, }, { /* ("sun8i", 4) -> "A33" */ .sunxi = 8, .cores = 4, .model = 33, }, { /* ("sun8i", 8) -> "A83T" */ .sunxi = 8, .cores = 8, .model = 83, .suffix = 'T', }, { /* ("sun9i", 8) -> "A80" */ .sunxi = 9, .cores = 8, .model = 80, }, #endif /* CPUINFO_ARCH_ARM */ { /* ("sun50i", 4) -> "A64" */ .sunxi = 50, .cores = 4, .model = 64, }, }; /** * Tries to match /proc/cpuinfo Hardware string to Allwinner /sun\d+i/ signature. * If the string matches signature, the function decodes Allwinner chipset from the number in the signature and the * number of cores, and stores it in \p chipset argument. * * @param start - start of the /proc/cpuinfo Hardware string to match. * @param end - end of the /proc/cpuinfo Hardware string to match. * @param cores - number of cores in the chipset. * @param[out] chipset - location where chipset information will be stored upon a successful match and decoding. * * @returns true if signature matched (even if exact model can't be decoded), false otherwise. */ static bool match_and_parse_sunxi( const char* start, const char* end, uint32_t cores, struct cpuinfo_arm_chipset chipset[restrict static 1]) { /* Expect at least 5 symbols: "sun" (3 symbols) + platform id (1-2 digits) + "i" (1 symbol) */ if (start + 5 > end) { return false; } /* Compare the first 3 characters to "sun" */ if (start[0] != 's') { return false; } const uint16_t expected_un = load_u16le(start + 1); if (expected_un != UINT16_C(0x6E75) /* "nu" = reverse("un") */) { return false; } /* Check and parse the first (required) digit of the sunXi platform id */ uint32_t sunxi_platform = 0; { const uint32_t digit = (uint32_t) (uint8_t) start[3] - '0'; if (digit >= 10) { /* Not really a digit */ return false; } sunxi_platform = digit; } /* Parse optional second digit of the sunXi platform id */ const char* pos = start + 4; { const uint32_t digit = (uint32_t) (uint8_t) (*pos) - '0'; if (digit < 10) { sunxi_platform = sunxi_platform * 10 + digit; if (++pos == end) { /* Expected one more character, final 'i' letter */ return false; } } } /* Validate the final 'i' letter */ if (*pos != 'i') { return false; } /* Compare sunXi platform id and number of cores to tabluted values to decode chipset name */ uint32_t model = 0; char suffix = 0; for (size_t i = 0; i < CPUINFO_COUNT_OF(sunxi_map_entries); i++) { if (sunxi_platform == sunxi_map_entries[i].sunxi && cores == sunxi_map_entries[i].cores) { model = sunxi_map_entries[i].model; suffix = sunxi_map_entries[i].suffix; break; } } if (model == 0) { cpuinfo_log_info("unrecognized %"PRIu32"-core Allwinner sun%"PRIu32" platform", cores, sunxi_platform); } /* Create chipset name from decoded data */ *chipset = (struct cpuinfo_arm_chipset) { .vendor = cpuinfo_arm_chipset_vendor_allwinner, .series = cpuinfo_arm_chipset_series_allwinner_a, .model = model, .suffix = { [0] = suffix, }, }; return true; } /** * Compares /proc/cpuinfo Hardware string to "WMT" signature. * If the string matches signature, the function decodes WonderMedia chipset from frequency and number of cores into * \p chipset argument. * * @param start - start of the /proc/cpuinfo Hardware string to match. * @param end - end of the /proc/cpuinfo Hardware string to match. * @param cores - number of cores in the chipset. * @param max_cpu_freq_max - maximum of /sys/devices/system/cpu/cpu/cpofreq/cpu_freq_max values. * @param[out] chipset - location where chipset information will be stored upon a successful match and decoding. * * @returns true if signature matched (even if exact model can't be decoded), false otherwise. */ static bool match_and_parse_wmt( const char* start, const char* end, uint32_t cores, uint32_t max_cpu_freq_max, struct cpuinfo_arm_chipset chipset[restrict static 1]) { /* Expected 3 symbols: "WMT" */ if (start + 3 != end) { return false; } /* Compare string to "WMT" */ if (start[0] != 'W') { return false; } const uint16_t expected_mt = load_u16le(start + 1); if (expected_mt != UINT16_C(0x544D) /* "TM" = reverse("MT") */) { return false; } /* Decode chipset name from frequency and number of cores */ uint32_t model = 0; switch (cores) { case 1: switch (max_cpu_freq_max) { case 1008000: /* 1 core @ 1008000 KHz -> WM8950 */ model = 8950; break; case 1200000: /* 1 core @ 1200000 KHz -> WM8850 */ model = 8850; break; } break; case 2: if (max_cpu_freq_max == 1500000) { /* 2 cores @ 1500000 KHz -> WM8880 */ model = 8880; } break; } if (model == 0) { cpuinfo_log_info("unrecognized WonderMedia platform with %"PRIu32" cores at %"PRIu32" KHz", cores, max_cpu_freq_max); } *chipset = (struct cpuinfo_arm_chipset) { .vendor = cpuinfo_arm_chipset_vendor_wondermedia, .series = cpuinfo_arm_chipset_series_wondermedia_wm, .model = model, }; return true; } struct huawei_map_entry { uint32_t platform; uint32_t model; }; static const struct huawei_map_entry huawei_platform_map[] = { { /* "ALP" -> Kirin 970 */ .platform = UINT32_C(0x00504C41), /* "\0PLA" = reverse("ALP\0") */ .model = 970, }, { /* "BAC" -> Kirin 659 */ .platform = UINT32_C(0x00434142), /* "\0CAB" = reverse("BAC\0") */ .model = 659, }, { /* "BLA" -> Kirin 970 */ .platform = UINT32_C(0x00414C42), /* "\0ALB" = reverse("BLA\0") */ .model = 970, }, { /* "BKL" -> Kirin 970 */ .platform = UINT32_C(0x004C4B42), /* "\0LKB" = reverse("BKL\0") */ .model = 970, }, { /* "CLT" -> Kirin 970 */ .platform = UINT32_C(0x00544C43), /* "\0TLC" = reverse("CLT\0") */ .model = 970, }, { /* "COL" -> Kirin 970 */ .platform = UINT32_C(0x004C4F43), /* "\0LOC" = reverse("COL\0") */ .model = 970, }, { /* "COR" -> Kirin 970 */ .platform = UINT32_C(0x00524F43), /* "\0ROC" = reverse("COR\0") */ .model = 970, }, { /* "DUK" -> Kirin 960 */ .platform = UINT32_C(0x004B5544), /* "\0KUD" = reverse("DUK\0") */ .model = 960, }, { /* "EML" -> Kirin 970 */ .platform = UINT32_C(0x004C4D45), /* "\0LME" = reverse("EML\0") */ .model = 970, }, { /* "EVA" -> Kirin 955 */ .platform = UINT32_C(0x00415645), /* "\0AVE" = reverse("EVA\0") */ .model = 955, }, { /* "FRD" -> Kirin 950 */ .platform = UINT32_C(0x00445246), /* "\0DRF" = reverse("FRD\0") */ .model = 950, }, { /* "INE" -> Kirin 710 */ .platform = UINT32_C(0x00454E49), /* "\0ENI" = reverse("INE\0") */ .model = 710, }, { /* "KNT" -> Kirin 950 */ .platform = UINT32_C(0x00544E4B), /* "\0TNK" = reverse("KNT\0") */ .model = 950, }, { /* "LON" -> Kirin 960 */ .platform = UINT32_C(0x004E4F4C), /* "\0NOL" = reverse("LON\0") */ .model = 960, }, { /* "LYA" -> Kirin 980 */ .platform = UINT32_C(0x0041594C), /* "\0AYL" = reverse("LYA\0") */ .model = 980, }, { /* "MCN" -> Kirin 980 */ .platform = UINT32_C(0x004E434D), /* "\0NCM" = reverse("MCN\0") */ .model = 980, }, { /* "MHA" -> Kirin 960 */ .platform = UINT32_C(0x0041484D), /* "\0AHM" = reverse("MHA\0") */ .model = 960, }, { /* "NEO" -> Kirin 970 */ .platform = UINT32_C(0x004F454E), /* "\0OEN" = reverse("NEO\0") */ .model = 970, }, { /* "NXT" -> Kirin 950 */ .platform = UINT32_C(0x0054584E), /* "\0TXN" = reverse("NXT\0") */ .model = 950, }, { /* "PAN" -> Kirin 980 */ .platform = UINT32_C(0x004E4150), /* "\0NAP" = reverse("PAN\0") */ .model = 980, }, { /* "PAR" -> Kirin 970 */ .platform = UINT32_C(0x00524150), /* "\0RAP" = reverse("PAR\0") */ .model = 970, }, { /* "RVL" -> Kirin 970 */ .platform = UINT32_C(0x004C5652), /* "\0LVR" = reverse("RVL\0") */ .model = 970, }, { /* "STF" -> Kirin 960 */ .platform = UINT32_C(0x00465453), /* "\0FTS" = reverse("STF\0") */ .model = 960, }, { /* "SUE" -> Kirin 980 */ .platform = UINT32_C(0x00455553), /* "\0EUS" = reverse("SUE\0") */ .model = 980, }, { /* "VIE" -> Kirin 955 */ .platform = UINT32_C(0x00454956), /* "\0EIV" = reverse("VIE\0") */ .model = 955, }, { /* "VKY" -> Kirin 960 */ .platform = UINT32_C(0x00594B56), /* "\0YKV" = reverse("VKY\0") */ .model = 960, }, { /* "VTR" -> Kirin 960 */ .platform = UINT32_C(0x00525456), /* "\0RTV" = reverse("VTR\0") */ .model = 960, }, }; /** * Tries to match ro.product.board string to Huawei /([A-Z]{3})(\-[A-Z]?L\d{2})$/ signature where \1 is one of the * known values for Huawei devices, which do not report chipset name elsewhere. * If the string matches signature, the function decodes chipset (always HiSilicon Kirin for matched devices) from * the Huawei platform ID in the signature and stores it in \p chipset argument. * * @param start - start of the ro.product.board string to match. * @param end - end of the ro.product.board string to match. * @param[out] chipset - location where chipset information will be stored upon a successful match and decoding. * * @returns true if signature matched, false otherwise. */ static bool match_and_parse_huawei( const char* start, const char* end, struct cpuinfo_arm_chipset chipset[restrict static 1]) { /* * Expect length of either 3, 7 or 8, exactly: * - 3-letter platform identifier (see huawei_platform_map) * - 3-letter platform identifier + '-' + 'L' + two digits * - 3-letter platform identifier + '-' + capital letter + 'L' + two digits */ const size_t length = end - start; switch (length) { case 3: case 7: case 8: break; default: return false; } /* * Try to find the first three-letter substring in among the tabulated entries for Huawei devices. * The first three letters are loaded and compared as a little-endian 24-bit word. */ uint32_t model = 0; const uint32_t target_platform_id = load_u24le(start); for (uint32_t i = 0; i < CPUINFO_COUNT_OF(huawei_platform_map); i++) { if (huawei_platform_map[i].platform == target_platform_id) { model = huawei_platform_map[i].model; break; } } if (model == 0) { /* Platform does not match the tabulated Huawei entries */ return false; } if (length > 3) { /* * Check that: * - The symbol after platform id is a dash * - The symbol after it is an uppercase letter. For 7-symbol strings, the symbol is just 'L'. */ if (start[3] != '-' || !is_ascii_alphabetic_uppercase(start[4])) { return false; } /* Check that the last 3 entries are /L\d\d/ */ if (end[-3] != 'L' || !is_ascii_numeric(end[-2]) || !is_ascii_numeric(end[-1])) { return false; } } /* All checks succeeded, commit chipset name */ *chipset = (struct cpuinfo_arm_chipset) { .vendor = cpuinfo_arm_chipset_vendor_hisilicon, .series = cpuinfo_arm_chipset_series_hisilicon_kirin, .model = model, }; return true; } /** * Tries to match /tcc\d{3}x$/ signature for Telechips TCCXXXx chipsets. * If match successful, extracts model information into \p chipset argument. * * @param start - start of the /proc/cpuinfo Hardware string to match. * @param end - end of the /proc/cpuinfo Hardware string to match. * @param[out] chipset - location where chipset information will be stored upon a successful match. * * @returns true if signature matched, false otherwise. */ static bool match_tcc( const char* start, const char* end, struct cpuinfo_arm_chipset chipset[restrict static 1]) { /* Expect exactly 7 symbols: "tcc" (3 symbols) + 3-digit model number + fixed "x" suffix */ if (start + 7 != end) { return false; } /* Quick check for the first character */ if (start[0] != 't') { return false; } /* Load the next 2 bytes as little endian 16-bit word */ const uint16_t expected_cc = load_u16le(start + 1); if (expected_cc != UINT16_C(0x6363) /* "cc" */ ) { return false; } /* Check and parse 3-digit model number */ uint32_t model = 0; for (uint32_t i = 3; i < 6; i++) { const uint32_t digit = (uint32_t) (uint8_t) start[i] - '0'; if (digit >= 10) { /* Not really a digit */ return false; } model = model * 10 + digit; } /* Check the fixed 'x' suffix in the end */ if (start[6] != 'x') { return false; } /* Commit parsed chipset. */ *chipset = (struct cpuinfo_arm_chipset) { .vendor = cpuinfo_arm_chipset_vendor_telechips, .series = cpuinfo_arm_chipset_series_telechips_tcc, .model = model, .suffix = { [0] = 'X' }, }; return true; } /* * Compares ro.board.platform string to Nvidia Tegra signatures ("tegra" and "tegra3") * This check has effect on how /proc/cpuinfo Hardware string is interpreted. * * @param start - start of the ro.board.platform string to check. * @param end - end of the ro.board.platform string to check. * * @returns true if the string matches an Nvidia Tegra signature, and false otherwise */ static bool is_tegra(const char* start, const char* end) { /* Expect 5 ("tegra") or 6 ("tegra3") symbols */ const size_t length = end - start; switch (length) { case 5: case 6: break; default: return false; } /* Check that the first 5 characters match "tegra" */ if (start[0] != 't') { return false; } const uint32_t expected_egra = load_u32le(start + 1); if (expected_egra != UINT32_C(0x61726765) /* "arge" = reverse("egra") */) { return false; } /* Check if the string is either "tegra" (length = 5) or "tegra3" (length != 5) and last character is '3' */ return (length == 5 || start[5] == '3'); } struct special_map_entry { const char* platform; uint16_t model; uint8_t series; char suffix; }; static const struct special_map_entry special_hardware_map_entries[] = { #if CPUINFO_ARCH_ARM { /* "k3v2oem1" -> HiSilicon K3V2 */ .platform = "k3v2oem1", .series = cpuinfo_arm_chipset_series_hisilicon_k3v, .model = 2, }, { /* "hi6620oem" -> HiSilicon Kirin 910T */ .platform = "hi6620oem", .series = cpuinfo_arm_chipset_series_hisilicon_kirin, .model = 910, .suffix = 'T' }, #endif /* CPUINFO_ARCH_ARM */ { /* "hi6250" -> HiSilicon Kirin 650 */ .platform = "hi6250", .series = cpuinfo_arm_chipset_series_hisilicon_kirin, .model = 650, }, { /* "hi6210sft" -> HiSilicon Kirin 620 */ .platform = "hi6210sft", .series = cpuinfo_arm_chipset_series_hisilicon_kirin, .model = 620, }, { /* "hi3751" -> HiSilicon Hi3751 */ .platform = "hi3751", .series = cpuinfo_arm_chipset_series_hisilicon_hi, .model = 3751, }, #if CPUINFO_ARCH_ARM { /* "hi3630" -> HiSilicon Kirin 920 */ .platform = "hi3630", .series = cpuinfo_arm_chipset_series_hisilicon_kirin, .model = 920, }, #endif /* CPUINFO_ARCH_ARM */ { /* "hi3635" -> HiSilicon Kirin 930 */ .platform = "hi3635", .series = cpuinfo_arm_chipset_series_hisilicon_kirin, .model = 930, }, #if CPUINFO_ARCH_ARM { /* "gs702a" -> Actions ATM7029 (Cortex-A5 + GC1000) */ .platform = "gs702a", .series = cpuinfo_arm_chipset_series_actions_atm, .model = 7029, }, { /* "gs702c" -> Actions ATM7029B (Cortex-A5 + SGX540) */ .platform = "gs702c", .series = cpuinfo_arm_chipset_series_actions_atm, .model = 7029, .suffix = 'B', }, { /* "gs703d" -> Actions ATM7039S */ .platform = "gs703d", .series = cpuinfo_arm_chipset_series_actions_atm, .model = 7039, .suffix = 'S', }, { /* "gs705a" -> Actions ATM7059A */ .platform = "gs705a", .series = cpuinfo_arm_chipset_series_actions_atm, .model = 7059, .suffix = 'A', }, { /* "Amlogic Meson8" -> Amlogic S812 */ .platform = "Amlogic Meson8", .series = cpuinfo_arm_chipset_series_amlogic_s, .model = 812, }, { /* "Amlogic Meson8B" -> Amlogic S805 */ .platform = "Amlogic Meson8B", .series = cpuinfo_arm_chipset_series_amlogic_s, .model = 805, }, { /* "mapphone_CDMA" -> Texas Instruments OMAP4430 */ .platform = "mapphone_CDMA", .series = cpuinfo_arm_chipset_series_texas_instruments_omap, .model = 4430, }, { /* "Superior" -> Texas Instruments OMAP4470 */ .platform = "Superior", .series = cpuinfo_arm_chipset_series_texas_instruments_omap, .model = 4470, }, { /* "Tuna" (Samsung Galaxy Nexus) -> Texas Instruments OMAP4460 */ .platform = "Tuna", .series = cpuinfo_arm_chipset_series_texas_instruments_omap, .model = 4460, }, { /* "Manta" (Samsung Nexus 10) -> Samsung Exynos 5250 */ .platform = "Manta", .series = cpuinfo_arm_chipset_series_samsung_exynos, .model = 5250, }, { /* "Odin" -> LG Nuclun 7111 */ .platform = "Odin", .series = cpuinfo_arm_chipset_series_lg_nuclun, .model = 7111, }, { /* "Madison" -> MStar 6A338 */ .platform = "Madison", .series = cpuinfo_arm_chipset_series_mstar_6a, .model = 338, }, #endif /* CPUINFO_ARCH_ARM */ }; static const struct special_map_entry tegra_hardware_map_entries[] = { #if CPUINFO_ARCH_ARM { /* "cardhu" (Nvidia Cardhu developer tablet) -> Tegra T30 */ .platform = "cardhu", .series = cpuinfo_arm_chipset_series_nvidia_tegra_t, .model = 30, }, { /* "kai" -> Tegra T30L */ .platform = "kai", .series = cpuinfo_arm_chipset_series_nvidia_tegra_t, .model = 30, .suffix = 'L', }, { /* "p3" (Samsung Galaxy Tab 8.9) -> Tegra T20 */ .platform = "p3", .series = cpuinfo_arm_chipset_series_nvidia_tegra_t, .model = 20, }, { /* "n1" (Samsung Galaxy R / Samsung Captivate Glide) -> Tegra AP20H */ .platform = "n1", .series = cpuinfo_arm_chipset_series_nvidia_tegra_ap, .model = 20, .suffix = 'H', }, { /* "SHW-M380S" (Samsung Galaxy Tab 10.1) -> Tegra T20 */ .platform = "SHW-M380S", .series = cpuinfo_arm_chipset_series_nvidia_tegra_t, .model = 20, }, { /* "m470" (Hisense Sero 7 Pro) -> Tegra T30L */ .platform = "m470", .series = cpuinfo_arm_chipset_series_nvidia_tegra_t, .model = 30, .suffix = 'L', }, { /* "endeavoru" (HTC One X) -> Tegra AP33 */ .platform = "endeavoru", .series = cpuinfo_arm_chipset_series_nvidia_tegra_ap, .model = 33, }, { /* "evitareul" (HTC One X+) -> Tegra T33 */ .platform = "evitareul", .series = cpuinfo_arm_chipset_series_nvidia_tegra_t, .model = 33, }, { /* "enrc2b" (HTC One X+) -> Tegra T33 */ .platform = "enrc2b", .series = cpuinfo_arm_chipset_series_nvidia_tegra_t, .model = 33, }, { /* "mozart" (Asus Transformer Pad TF701T) -> Tegra T114 */ .platform = "mozart", .series = cpuinfo_arm_chipset_series_nvidia_tegra_t, .model = 114, }, { /* "tegratab" (Tegra Note 7) -> Tegra T114 */ .platform = "tegratab", .series = cpuinfo_arm_chipset_series_nvidia_tegra_t, .model = 114, }, { /* "tn8" (Nvidia Shield Tablet K1) -> Tegra T124 */ .platform = "tn8", .series = cpuinfo_arm_chipset_series_nvidia_tegra_t, .model = 124, }, { /* "roth" (Nvidia Shield Portable) -> Tegra T114 */ .platform = "roth", .series = cpuinfo_arm_chipset_series_nvidia_tegra_t, .model = 114, }, { /* "pisces" (Xiaomi Mi 3) -> Tegra T114 */ .platform = "pisces", .series = cpuinfo_arm_chipset_series_nvidia_tegra_t, .model = 114, }, { /* "mocha" (Xiaomi Mi Pad) -> Tegra T124 */ .platform = "mocha", .series = cpuinfo_arm_chipset_series_nvidia_tegra_t, .model = 124, }, { /* "stingray" (Motorola XOOM) -> Tegra AP20H */ .platform = "stingray", .series = cpuinfo_arm_chipset_series_nvidia_tegra_ap, .model = 20, .suffix = 'H', }, { /* "Ceres" (Wiko Highway 4G) -> Tegra SL460N */ .platform = "Ceres", .series = cpuinfo_arm_chipset_series_nvidia_tegra_sl, .model = 460, .suffix = 'N', }, { /* "MT799" (nabi 2 Tablet) -> Tegra T30 */ .platform = "MT799", .series = cpuinfo_arm_chipset_series_nvidia_tegra_t, .model = 30, }, { /* "t8400n" (nabi DreamTab HD8) -> Tegra T114 */ .platform = "t8400n", .series = cpuinfo_arm_chipset_series_nvidia_tegra_t, .model = 114, }, { /* "chagall" (Fujitsu Stylistic M532) -> Tegra T30 */ .platform = "chagall", .series = cpuinfo_arm_chipset_series_nvidia_tegra_t, .model = 30, }, { /* "ventana" (Asus Transformer TF101) -> Tegra T20 */ .platform = "ventana", .series = cpuinfo_arm_chipset_series_nvidia_tegra_t, .model = 20, }, { /* "bobsleigh" (Fujitsu Arrows Tab F-05E) -> Tegra T33 */ .platform = "bobsleigh", .series = cpuinfo_arm_chipset_series_nvidia_tegra_t, .model = 33, }, { /* "tegra_fjdev101" (Fujitsu Arrows X F-10D) -> Tegra AP33 */ .platform = "tegra_fjdev101", .series = cpuinfo_arm_chipset_series_nvidia_tegra_ap, .model = 33, }, { /* "tegra_fjdev103" (Fujitsu Arrows V F-04E) -> Tegra T33 */ .platform = "tegra_fjdev103", .series = cpuinfo_arm_chipset_series_nvidia_tegra_t, .model = 33, }, { /* "nbx03" (Sony Tablet S) -> Tegra T20 */ .platform = "nbx03", .series = cpuinfo_arm_chipset_series_nvidia_tegra_t, .model = 20, }, { /* "txs03" (Sony Xperia Tablet S) -> Tegra T30L */ .platform = "txs03", .series = cpuinfo_arm_chipset_series_nvidia_tegra_t, .model = 30, .suffix = 'L', }, { /* "x3" (LG Optimus 4X HD P880) -> Tegra AP33 */ .platform = "x3", .series = cpuinfo_arm_chipset_series_nvidia_tegra_ap, .model = 33, }, { /* "vu10" (LG Optimus Vu P895) -> Tegra AP33 */ .platform = "vu10", .series = cpuinfo_arm_chipset_series_nvidia_tegra_ap, .model = 33, }, { /* "BIRCH" (HP Slate 7 Plus) -> Tegra T30L */ .platform = "BIRCH", .series = cpuinfo_arm_chipset_series_nvidia_tegra_t, .model = 30, .suffix = 'L', }, { /* "macallan" (HP Slate 8 Pro) -> Tegra T114 */ .platform = "macallan", .series = cpuinfo_arm_chipset_series_nvidia_tegra_t, .model = 114, }, { /* "maya" (HP SlateBook 10 x2) -> Tegra T114 */ .platform = "maya", .series = cpuinfo_arm_chipset_series_nvidia_tegra_t, .model = 114, }, { /* "antares" (Toshiba AT100) -> Tegra T20 */ .platform = "antares", .series = cpuinfo_arm_chipset_series_nvidia_tegra_t, .model = 20, }, { /* "tostab12AL" (Toshiba AT300SE "Excite 10 SE") -> Tegra T30L */ .platform = "tostab12AL", .series = cpuinfo_arm_chipset_series_nvidia_tegra_t, .model = 30, .suffix = 'L', }, { /* "tostab12BL" (Toshiba AT10-A "Excite Pure") -> Tegra T30L */ .platform = "tostab12BL", .series = cpuinfo_arm_chipset_series_nvidia_tegra_t, .model = 30, .suffix = 'L', }, { /* "sphinx" (Toshiba AT270 "Excite 7.7") -> Tegra T30 */ .platform = "sphinx", .series = cpuinfo_arm_chipset_series_nvidia_tegra_t, .model = 30, }, { /* "tostab11BS" (Toshiba AT570 "Regza 7.7") -> Tegra T30 */ .platform = "tostab11BS", .series = cpuinfo_arm_chipset_series_nvidia_tegra_t, .model = 30, }, { /* "tostab12BA" (Toshiba AT10-LE-A "Excite Pro") -> Tegra T114 */ .platform = "tostab12BA", .series = cpuinfo_arm_chipset_series_nvidia_tegra_t, .model = 114, }, { /* "vangogh" (Acer Iconia Tab A100) -> Tegra T20 */ .platform = "vangogh", .series = cpuinfo_arm_chipset_series_nvidia_tegra_t, .model = 20, }, { /* "a110" (Acer Iconia Tab A110) -> Tegra T30L */ .platform = "a110", .series = cpuinfo_arm_chipset_series_nvidia_tegra_t, .model = 30, .suffix = 'L', }, { /* "picasso_e" (Acer Iconia Tab A200) -> Tegra AP20H */ .platform = "picasso_e", .series = cpuinfo_arm_chipset_series_nvidia_tegra_ap, .model = 20, .suffix = 'H', }, { /* "picasso_e2" (Acer Iconia Tab A210) -> Tegra T30L */ .platform = "picasso_e2", .series = cpuinfo_arm_chipset_series_nvidia_tegra_t, .model = 30, .suffix = 'L', }, { /* "picasso" (Acer Iconia Tab A500) -> Tegra AP20H */ .platform = "picasso", .series = cpuinfo_arm_chipset_series_nvidia_tegra_ap, .model = 20, .suffix = 'H', }, { /* "picasso_m" (Acer Iconia Tab A510) -> Tegra T30 */ .platform = "picasso_m", .series = cpuinfo_arm_chipset_series_nvidia_tegra_t, .model = 30, }, { /* "picasso_mf" (Acer Iconia Tab A700) -> Tegra T30 */ .platform = "picasso_mf", .series = cpuinfo_arm_chipset_series_nvidia_tegra_t, .model = 30, }, { /* "avalon" (Toshiba AT300 "Excite 10") -> Tegra T30L */ .platform = "avalon", .series = cpuinfo_arm_chipset_series_nvidia_tegra_t, .model = 30, .suffix = 'L', }, { /* "NS_14T004" (iRiver NS-14T004) -> Tegra T30L */ .platform = "NS_14T004", .series = cpuinfo_arm_chipset_series_nvidia_tegra_t, .model = 30, .suffix = 'L', }, { /* "WIKIPAD" (Wikipad) -> Tegra T30 */ .platform = "WIKIPAD", .series = cpuinfo_arm_chipset_series_nvidia_tegra_t, .model = 30, }, { /* "kb" (Pegatron Q00Q) -> Tegra T114 */ .platform = "kb", .series = cpuinfo_arm_chipset_series_nvidia_tegra_t, .model = 114, }, #endif /* CPUINFO_ARCH_ARM */ { /* "foster_e" (Nvidia Shield TV, Flash) -> Tegra T210 */ .platform = "foster_e", .series = cpuinfo_arm_chipset_series_nvidia_tegra_t, .model = 210, }, { /* "foster_e_hdd" (Nvidia Shield TV, HDD) -> Tegra T210 */ .platform = "foster_e_hdd", .series = cpuinfo_arm_chipset_series_nvidia_tegra_t, .model = 210, }, { /* "darcy" (Nvidia Shield TV 2017) -> Tegra T210 */ .platform = "darcy", .series = cpuinfo_arm_chipset_series_nvidia_tegra_t, .model = 210, }, }; /* * Decodes chipset name from /proc/cpuinfo Hardware string. * For some chipsets, the function relies frequency and on number of cores for chipset detection. * * @param[in] platform - /proc/cpuinfo Hardware string. * @param cores - number of cores in the chipset. * @param max_cpu_freq_max - maximum of /sys/devices/system/cpu/cpu/cpofreq/cpu_freq_max values. * * @returns Decoded chipset name. If chipset could not be decoded, the resulting structure would use `unknown` vendor * and series identifiers. */ struct cpuinfo_arm_chipset cpuinfo_arm_linux_decode_chipset_from_proc_cpuinfo_hardware( const char hardware[restrict static CPUINFO_HARDWARE_VALUE_MAX], uint32_t cores, uint32_t max_cpu_freq_max, bool is_tegra) { struct cpuinfo_arm_chipset chipset; const size_t hardware_length = strnlen(hardware, CPUINFO_HARDWARE_VALUE_MAX); const char* hardware_end = hardware + hardware_length; if (is_tegra) { /* * Nvidia Tegra-specific path: compare /proc/cpuinfo Hardware string to * tabulated Hardware values for popular chipsets/devices with Tegra chipsets. * This path is only used when ro.board.platform indicates a Tegra chipset * (albeit does not indicate which exactly Tegra chipset). */ for (size_t i = 0; i < CPUINFO_COUNT_OF(tegra_hardware_map_entries); i++) { if (strncmp(tegra_hardware_map_entries[i].platform, hardware, hardware_length) == 0 && tegra_hardware_map_entries[i].platform[hardware_length] == 0) { cpuinfo_log_debug( "found /proc/cpuinfo Hardware string \"%.*s\" in Nvidia Tegra chipset table", (int) hardware_length, hardware); /* Create chipset name from entry */ return (struct cpuinfo_arm_chipset) { .vendor = chipset_series_vendor[tegra_hardware_map_entries[i].series], .series = (enum cpuinfo_arm_chipset_series) tegra_hardware_map_entries[i].series, .model = tegra_hardware_map_entries[i].model, .suffix = { [0] = tegra_hardware_map_entries[i].suffix, }, }; } } } else { /* Generic path: consider all other vendors */ bool word_start = true; for (const char* pos = hardware; pos != hardware_end; pos++) { const char c = *pos; switch (c) { case ' ': case '\t': case ',': word_start = true; break; default: if (word_start && is_ascii_alphabetic(c)) { /* Check Qualcomm MSM/APQ signature */ if (match_msm_apq(pos, hardware_end, &chipset)) { cpuinfo_log_debug( "matched Qualcomm MSM/APQ signature in /proc/cpuinfo Hardware string \"%.*s\"", (int) hardware_length, hardware); return chipset; } /* Check SDMxxx (Qualcomm Snapdragon) signature */ if (match_sdm(pos, hardware_end, &chipset)) { cpuinfo_log_debug( "matched Qualcomm SDM signature in /proc/cpuinfo Hardware string \"%.*s\"", (int) hardware_length, hardware); return chipset; } /* Check SMxxxx (Qualcomm Snapdragon) signature */ if (match_sm(pos, hardware_end, &chipset)) { cpuinfo_log_debug( "matched Qualcomm SM signature in /proc/cpuinfo Hardware string \"%.*s\"", (int) hardware_length, hardware); return chipset; } /* Check MediaTek MT signature */ if (match_mt(pos, hardware_end, true, &chipset)) { cpuinfo_log_debug( "matched MediaTek MT signature in /proc/cpuinfo Hardware string \"%.*s\"", (int) hardware_length, hardware); return chipset; } /* Check HiSilicon Kirin signature */ if (match_kirin(pos, hardware_end, &chipset)) { cpuinfo_log_debug( "matched HiSilicon Kirin signature in /proc/cpuinfo Hardware string \"%.*s\"", (int) hardware_length, hardware); return chipset; } /* Check Rockchip RK signature */ if (match_rk(pos, hardware_end, &chipset)) { cpuinfo_log_debug( "matched Rockchip RK signature in /proc/cpuinfo Hardware string \"%.*s\"", (int) hardware_length, hardware); return chipset; } } word_start = false; break; } } /* Check Samsung Exynos signature */ if (match_samsung_exynos(hardware, hardware_end, &chipset)) { cpuinfo_log_debug( "matched Samsung Exynos signature in /proc/cpuinfo Hardware string \"%.*s\"", (int) hardware_length, hardware); return chipset; } /* Check universalXXXX (Samsung Exynos) signature */ if (match_universal(hardware, hardware_end, &chipset)) { cpuinfo_log_debug( "matched UNIVERSAL (Samsung Exynos) signature in /proc/cpuinfo Hardware string \"%.*s\"", (int) hardware_length, hardware); return chipset; } #if CPUINFO_ARCH_ARM /* Match /SMDK(4410|4x12)$/ */ if (match_and_parse_smdk(hardware, hardware_end, cores, &chipset)) { cpuinfo_log_debug( "matched SMDK (Samsung Exynos) signature in /proc/cpuinfo Hardware string \"%.*s\"", (int) hardware_length, hardware); return chipset; } #endif /* Check Spreadtrum SC signature */ if (match_sc(hardware, hardware_end, &chipset)) { cpuinfo_log_debug( "matched Spreadtrum SC signature in /proc/cpuinfo Hardware string \"%.*s\"", (int) hardware_length, hardware); return chipset; } #if CPUINFO_ARCH_ARM /* Check Marvell PXA signature */ if (match_pxa(hardware, hardware_end, &chipset)) { cpuinfo_log_debug( "matched Marvell PXA signature in /proc/cpuinfo Hardware string \"%.*s\"", (int) hardware_length, hardware); return chipset; } #endif /* Match /sun\d+i/ signature and map to Allwinner chipset name */ if (match_and_parse_sunxi(hardware, hardware_end, cores, &chipset)) { cpuinfo_log_debug( "matched sunxi (Allwinner Ax) signature in /proc/cpuinfo Hardware string \"%.*s\"", (int) hardware_length, hardware); return chipset; } /* Check Broadcom BCM signature */ if (match_bcm(hardware, hardware_end, &chipset)) { cpuinfo_log_debug( "matched Broadcom BCM signature in /proc/cpuinfo Hardware string \"%.*s\"", (int) hardware_length, hardware); return chipset; } #if CPUINFO_ARCH_ARM /* Check Texas Instruments OMAP signature */ if (match_omap(hardware, hardware_end, &chipset)) { cpuinfo_log_debug( "matched Texas Instruments OMAP signature in /proc/cpuinfo Hardware string \"%.*s\"", (int) hardware_length, hardware); return chipset; } /* Check WonderMedia WMT signature and decode chipset from frequency and number of cores */ if (match_and_parse_wmt(hardware, hardware_end, cores, max_cpu_freq_max, &chipset)) { cpuinfo_log_debug( "matched WonderMedia WMT signature in /proc/cpuinfo Hardware string \"%.*s\"", (int) hardware_length, hardware); return chipset; } #endif /* Check Telechips TCC signature */ if (match_tcc(hardware, hardware_end, &chipset)) { cpuinfo_log_debug( "matched Telechips TCC signature in /proc/cpuinfo Hardware string \"%.*s\"", (int) hardware_length, hardware); return chipset; } /* Compare to tabulated Hardware values for popular chipsets/devices which can't be otherwise detected */ for (size_t i = 0; i < CPUINFO_COUNT_OF(special_hardware_map_entries); i++) { if (strncmp(special_hardware_map_entries[i].platform, hardware, hardware_length) == 0 && special_hardware_map_entries[i].platform[hardware_length] == 0) { cpuinfo_log_debug( "found /proc/cpuinfo Hardware string \"%.*s\" in special chipset table", (int) hardware_length, hardware); /* Create chipset name from entry */ return (struct cpuinfo_arm_chipset) { .vendor = chipset_series_vendor[special_hardware_map_entries[i].series], .series = (enum cpuinfo_arm_chipset_series) special_hardware_map_entries[i].series, .model = special_hardware_map_entries[i].model, .suffix = { [0] = special_hardware_map_entries[i].suffix, }, }; } } } return (struct cpuinfo_arm_chipset) { .vendor = cpuinfo_arm_chipset_vendor_unknown, .series = cpuinfo_arm_chipset_series_unknown, }; } #ifdef __ANDROID__ static const struct special_map_entry special_board_map_entries[] = { { /* "hi6250" -> HiSilicon Kirin 650 */ .platform = "hi6250", .series = cpuinfo_arm_chipset_series_hisilicon_kirin, .model = 650, }, { /* "hi6210sft" -> HiSilicon Kirin 620 */ .platform = "hi6210sft", .series = cpuinfo_arm_chipset_series_hisilicon_kirin, .model = 620, }, #if CPUINFO_ARCH_ARM { /* "hi3630" -> HiSilicon Kirin 920 */ .platform = "hi3630", .series = cpuinfo_arm_chipset_series_hisilicon_kirin, .model = 920, }, #endif /* CPUINFO_ARCH_ARM */ { /* "hi3635" -> HiSilicon Kirin 930 */ .platform = "hi3635", .series = cpuinfo_arm_chipset_series_hisilicon_kirin, .model = 930, }, { /* "hi3650" -> HiSilicon Kirin 950 */ .platform = "hi3650", .series = cpuinfo_arm_chipset_series_hisilicon_kirin, .model = 950, }, { /* "hi3660" -> HiSilicon Kirin 960 */ .platform = "hi3660", .series = cpuinfo_arm_chipset_series_hisilicon_kirin, .model = 960, }, #if CPUINFO_ARCH_ARM { /* "mp523x" -> Renesas MP5232 */ .platform = "mp523x", .series = cpuinfo_arm_chipset_series_renesas_mp, .model = 5232, }, #endif /* CPUINFO_ARCH_ARM */ { /* "BEETHOVEN" (Huawei MadiaPad M3) -> HiSilicon Kirin 950 */ .platform = "BEETHOVEN", .series = cpuinfo_arm_chipset_series_hisilicon_kirin, .model = 950, }, #if CPUINFO_ARCH_ARM { /* "hws7701u" (Huawei MediaPad 7 Youth) -> Rockchip RK3168 */ .platform = "hws7701u", .series = cpuinfo_arm_chipset_series_rockchip_rk, .model = 3168, }, { /* "g2mv" (LG G2 mini LTE) -> Nvidia Tegra SL460N */ .platform = "g2mv", .series = cpuinfo_arm_chipset_series_nvidia_tegra_sl, .model = 460, .suffix = 'N', }, { /* "K00F" (Asus MeMO Pad 10) -> Rockchip RK3188 */ .platform = "K00F", .series = cpuinfo_arm_chipset_series_rockchip_rk, .model = 3188, }, { /* "T7H" (HP Slate 7) -> Rockchip RK3066 */ .platform = "T7H", .series = cpuinfo_arm_chipset_series_rockchip_rk, .model = 3066, }, { /* "tuna" (Samsung Galaxy Nexus) -> Texas Instruments OMAP4460 */ .platform = "tuna", .series = cpuinfo_arm_chipset_series_texas_instruments_omap, .model = 4460, }, { /* "grouper" (Asus Nexus 7 2012) -> Nvidia Tegra T30L */ .platform = "grouper", .series = cpuinfo_arm_chipset_series_nvidia_tegra_t, .model = 30, .suffix = 'L', }, #endif /* CPUINFO_ARCH_ARM */ { /* "flounder" (HTC Nexus 9) -> Nvidia Tegra T132 */ .platform = "flounder", .series = cpuinfo_arm_chipset_series_nvidia_tegra_t, .model = 132, }, { /* "dragon" (Google Pixel C) -> Nvidia Tegra T210 */ .platform = "dragon", .series = cpuinfo_arm_chipset_series_nvidia_tegra_t, .model = 210, }, { /* "sailfish" (Google Pixel) -> Qualcomm MSM8996PRO */ .platform = "sailfish", .series = cpuinfo_arm_chipset_series_qualcomm_msm, .model = 8996, .suffix = 'P', }, { /* "marlin" (Google Pixel XL) -> Qualcomm MSM8996PRO */ .platform = "marlin", .series = cpuinfo_arm_chipset_series_qualcomm_msm, .model = 8996, .suffix = 'P', }, }; /* * Decodes chipset name from ro.product.board Android system property. * For some chipsets, the function relies frequency and on number of cores for chipset detection. * * @param[in] platform - ro.product.board value. * @param cores - number of cores in the chipset. * @param max_cpu_freq_max - maximum of /sys/devices/system/cpu/cpu/cpofreq/cpu_freq_max values. * * @returns Decoded chipset name. If chipset could not be decoded, the resulting structure would use `unknown` vendor * and series identifiers. */ struct cpuinfo_arm_chipset cpuinfo_arm_android_decode_chipset_from_ro_product_board( const char ro_product_board[restrict static CPUINFO_BUILD_PROP_VALUE_MAX], uint32_t cores, uint32_t max_cpu_freq_max) { struct cpuinfo_arm_chipset chipset; const char* board = ro_product_board; const size_t board_length = strnlen(ro_product_board, CPUINFO_BUILD_PROP_VALUE_MAX); const char* board_end = ro_product_board + board_length; /* Check Qualcomm MSM/APQ signature */ if (match_msm_apq(board, board_end, &chipset)) { cpuinfo_log_debug( "matched Qualcomm MSM/APQ signature in ro.product.board string \"%.*s\"", (int) board_length, board); return chipset; } /* Check universaXXXX (Samsung Exynos) signature */ if (match_universal(board, board_end, &chipset)) { cpuinfo_log_debug( "matched UNIVERSAL (Samsung Exynos) signature in ro.product.board string \"%.*s\"", (int) board_length, board); return chipset; } #if CPUINFO_ARCH_ARM /* Check SMDK (Samsung Exynos) signature */ if (match_and_parse_smdk(board, board_end, cores, &chipset)) { cpuinfo_log_debug( "matched SMDK (Samsung Exynos) signature in ro.product.board string \"%.*s\"", (int) board_length, board); return chipset; } #endif /* Check MediaTek MT signature */ if (match_mt(board, board_end, true, &chipset)) { cpuinfo_log_debug( "matched MediaTek MT signature in ro.product.board string \"%.*s\"", (int) board_length, board); return chipset; } /* Check Spreadtrum SC signature */ if (match_sc(board, board_end, &chipset)) { cpuinfo_log_debug( "matched Spreadtrum SC signature in ro.product.board string \"%.*s\"", (int) board_length, board); return chipset; } #if CPUINFO_ARCH_ARM /* Check Marvell PXA signature */ if (match_pxa(board, board_end, &chipset)) { cpuinfo_log_debug( "matched Marvell PXA signature in ro.product.board string \"%.*s\"", (int) board_length, board); return chipset; } /* Check Leadcore LCxxxx signature */ if (match_lc(board, board_end, &chipset)) { cpuinfo_log_debug( "matched Leadcore LC signature in ro.product.board string \"%.*s\"", (int) board_length, board); return chipset; } /* * Compare to tabulated ro.product.board values for Broadcom chipsets and decode chipset from frequency and * number of cores. */ if (match_and_parse_broadcom(board, board_end, cores, max_cpu_freq_max, &chipset)) { cpuinfo_log_debug( "found ro.product.board string \"%.*s\" in Broadcom chipset table", (int) board_length, board); return chipset; } #endif /* Compare to tabulated ro.product.board values for Huawei devices which don't report chipset elsewhere */ if (match_and_parse_huawei(board, board_end, &chipset)) { cpuinfo_log_debug( "found ro.product.board string \"%.*s\" in Huawei chipset table", (int) board_length, board); return chipset; } /* Compare to tabulated ro.product.board values for popular chipsets/devices which can't be otherwise detected */ for (size_t i = 0; i < CPUINFO_COUNT_OF(special_board_map_entries); i++) { if (strncmp(special_board_map_entries[i].platform, board, board_length) == 0 && special_board_map_entries[i].platform[board_length] == 0) { cpuinfo_log_debug( "found ro.product.board string \"%.*s\" in special chipset table", (int) board_length, board); /* Create chipset name from entry */ return (struct cpuinfo_arm_chipset) { .vendor = chipset_series_vendor[special_board_map_entries[i].series], .series = (enum cpuinfo_arm_chipset_series) special_board_map_entries[i].series, .model = special_board_map_entries[i].model, .suffix = { [0] = special_board_map_entries[i].suffix, /* The suffix of MSM8996PRO is truncated at the first letter, reconstruct it here. */ [1] = special_board_map_entries[i].suffix == 'P' ? 'R' : 0, [2] = special_board_map_entries[i].suffix == 'P' ? 'O' : 0, }, }; } } return (struct cpuinfo_arm_chipset) { .vendor = cpuinfo_arm_chipset_vendor_unknown, .series = cpuinfo_arm_chipset_series_unknown, }; } struct amlogic_map_entry { char ro_board_platform[6]; uint16_t model; uint8_t series; char suffix[3]; }; static const struct amlogic_map_entry amlogic_map_entries[] = { #if CPUINFO_ARCH_ARM { /* "meson3" -> Amlogic AML8726-M */ .ro_board_platform = "meson3", .series = cpuinfo_arm_chipset_series_amlogic_aml, .model = 8726, .suffix = "-M", }, { /* "meson6" -> Amlogic AML8726-MX */ .ro_board_platform = "meson6", .series = cpuinfo_arm_chipset_series_amlogic_aml, .model = 8726, .suffix = "-MX", }, { /* "meson8" -> Amlogic S805 */ .ro_board_platform = "meson8", .series = cpuinfo_arm_chipset_series_amlogic_s, .model = 805, }, #endif /* CPUINFO_ARCH_ARM */ { /* "gxbaby" -> Amlogic S905 */ .ro_board_platform = "gxbaby", .series = cpuinfo_arm_chipset_series_amlogic_s, .model = 905, }, { /* "gxl" -> Amlogic S905X */ .ro_board_platform = "gxl", .series = cpuinfo_arm_chipset_series_amlogic_s, .model = 905, .suffix = "X", }, { /* "gxm" -> Amlogic S912 */ .ro_board_platform = "gxm", .series = cpuinfo_arm_chipset_series_amlogic_s, .model = 912, }, }; static const struct special_map_entry special_platform_map_entries[] = { #if CPUINFO_ARCH_ARM { /* "hi6620oem" -> HiSilicon Kirin 910T */ .platform = "hi6620oem", .series = cpuinfo_arm_chipset_series_hisilicon_kirin, .model = 910, .suffix = 'T', }, #endif /* CPUINFO_ARCH_ARM */ { /* "hi6250" -> HiSilicon Kirin 650 */ .platform = "hi6250", .series = cpuinfo_arm_chipset_series_hisilicon_kirin, .model = 650, }, { /* "hi6210sft" -> HiSilicon Kirin 620 */ .platform = "hi6210sft", .series = cpuinfo_arm_chipset_series_hisilicon_kirin, .model = 620, }, #if CPUINFO_ARCH_ARM { /* "hi3630" -> HiSilicon Kirin 920 */ .platform = "hi3630", .series = cpuinfo_arm_chipset_series_hisilicon_kirin, .model = 920, }, #endif /* CPUINFO_ARCH_ARM */ { /* "hi3635" -> HiSilicon Kirin 930 */ .platform = "hi3635", .series = cpuinfo_arm_chipset_series_hisilicon_kirin, .model = 930, }, { /* "hi3650" -> HiSilicon Kirin 950 */ .platform = "hi3650", .series = cpuinfo_arm_chipset_series_hisilicon_kirin, .model = 950, }, { /* "hi3660" -> HiSilicon Kirin 960 */ .platform = "hi3660", .series = cpuinfo_arm_chipset_series_hisilicon_kirin, .model = 960, }, #if CPUINFO_ARCH_ARM { /* "k3v2oem1" -> HiSilicon K3V2 */ .platform = "k3v2oem1", .series = cpuinfo_arm_chipset_series_hisilicon_k3v, .model = 2, }, { /* "k3v200" -> HiSilicon K3V2 */ .platform = "k3v200", .series = cpuinfo_arm_chipset_series_hisilicon_k3v, .model = 2, }, { /* "montblanc" -> NovaThor U8500 */ .platform = "montblanc", .series = cpuinfo_arm_chipset_series_novathor_u, .model = 8500, }, #endif /* CPUINFO_ARCH_ARM */ { /* "song" -> Pinecone Surge S1 */ .platform = "song", .series = cpuinfo_arm_chipset_series_pinecone_surge_s, .model = 1, }, #if CPUINFO_ARCH_ARM { /* "rk322x" -> RockChip RK3229 */ .platform = "rk322x", .series = cpuinfo_arm_chipset_series_rockchip_rk, .model = 3229, }, #endif /* CPUINFO_ARCH_ARM */ { /* "tegra132" -> Nvidia Tegra T132 */ .platform = "tegra132", .series = cpuinfo_arm_chipset_series_nvidia_tegra_t, .model = 132, }, { /* "tegra210_dragon" -> Nvidia Tegra T210 */ .platform = "tegra210_dragon", .series = cpuinfo_arm_chipset_series_nvidia_tegra_t, .model = 210, }, #if CPUINFO_ARCH_ARM { /* "tegra4" -> Nvidia Tegra T114 */ .platform = "tegra4", .series = cpuinfo_arm_chipset_series_nvidia_tegra_t, .model = 114, }, { /* "s5pc110" -> Samsung Exynos 3110 */ .platform = "s5pc110", .series = cpuinfo_arm_chipset_series_samsung_exynos, .model = 3110, }, #endif /* CPUINFO_ARCH_ARM */ }; /* * Decodes chipset name from ro.board.platform Android system property. * For some chipsets, the function relies frequency and on number of cores for chipset detection. * * @param[in] platform - ro.board.platform value. * @param cores - number of cores in the chipset. * @param max_cpu_freq_max - maximum of /sys/devices/system/cpu/cpu/cpofreq/cpu_freq_max values. * * @returns Decoded chipset name. If chipset could not be decoded, the resulting structure would use `unknown` vendor * and series identifiers. */ struct cpuinfo_arm_chipset cpuinfo_arm_android_decode_chipset_from_ro_board_platform( const char platform[restrict static CPUINFO_BUILD_PROP_VALUE_MAX], uint32_t cores, uint32_t max_cpu_freq_max) { struct cpuinfo_arm_chipset chipset; const size_t platform_length = strnlen(platform, CPUINFO_BUILD_PROP_VALUE_MAX); const char* platform_end = platform + platform_length; /* Check Qualcomm MSM/APQ signature */ if (match_msm_apq(platform, platform_end, &chipset)) { cpuinfo_log_debug( "matched Qualcomm MSM/APQ signature in ro.board.platform string \"%.*s\"", (int) platform_length, platform); return chipset; } /* Check exynosXXXX (Samsung Exynos) signature */ if (match_exynos(platform, platform_end, &chipset)) { cpuinfo_log_debug( "matched exynosXXXX (Samsung Exynos) signature in ro.board.platform string \"%.*s\"", (int) platform_length, platform); return chipset; } /* Check MediaTek MT signature */ if (match_mt(platform, platform_end, true, &chipset)) { cpuinfo_log_debug( "matched MediaTek MT signature in ro.board.platform string \"%.*s\"", (int) platform_length, platform); return chipset; } /* Check HiSilicon Kirin signature */ if (match_kirin(platform, platform_end, &chipset)) { cpuinfo_log_debug( "matched HiSilicon Kirin signature in ro.board.platform string \"%.*s\"", (int) platform_length, platform); return chipset; } /* Check Spreadtrum SC signature */ if (match_sc(platform, platform_end, &chipset)) { cpuinfo_log_debug( "matched Spreadtrum SC signature in ro.board.platform string \"%.*s\"", (int) platform_length, platform); return chipset; } /* Check Rockchip RK signature */ if (match_rk(platform, platform_end, &chipset)) { cpuinfo_log_debug( "matched Rockchip RK signature in ro.board.platform string \"%.*s\"", (int) platform_length, platform); return chipset; } #if CPUINFO_ARCH_ARM /* Check Leadcore LCxxxx signature */ if (match_lc(platform, platform_end, &chipset)) { cpuinfo_log_debug( "matched Leadcore LC signature in ro.board.platform string \"%.*s\"", (int) platform_length, platform); return chipset; } #endif /* Compare to tabulated ro.board.platform values for Huawei devices which don't report chipset elsewhere */ if (match_and_parse_huawei(platform, platform_end, &chipset)) { cpuinfo_log_debug( "found ro.board.platform string \"%.*s\" in Huawei chipset table", (int) platform_length, platform); return chipset; } #if CPUINFO_ARCH_ARM /* * Compare to known ro.board.platform values for Broadcom devices and * detect chipset from frequency and number of cores */ if (match_and_parse_broadcom(platform, platform_end, cores, max_cpu_freq_max, &chipset)) { cpuinfo_log_debug( "found ro.board.platform string \"%.*s\" in Broadcom chipset table", (int) platform_length, platform); return chipset; } /* * Compare to ro.board.platform value ("omap4") for OMAP4xxx chipsets. * Upon successful match, detect OMAP4430 from frequency and number of cores. */ if (platform_length == 5 && cores == 2 && max_cpu_freq_max == 1008000 && memcmp(platform, "omap4", 5) == 0) { cpuinfo_log_debug( "matched Texas Instruments OMAP4 signature in ro.board.platform string \"%.*s\"", (int) platform_length, platform); return (struct cpuinfo_arm_chipset) { .vendor = cpuinfo_arm_chipset_vendor_texas_instruments, .series = cpuinfo_arm_chipset_series_texas_instruments_omap, .model = 4430, }; } #endif /* * Compare to tabulated ro.board.platform values for Amlogic chipsets/devices which can't be otherwise detected. * The tabulated Amlogic ro.board.platform values have not more than 6 characters. */ if (platform_length <= 6) { for (size_t i = 0; i < CPUINFO_COUNT_OF(amlogic_map_entries); i++) { if (strncmp(amlogic_map_entries[i].ro_board_platform, platform, 6) == 0) { cpuinfo_log_debug( "found ro.board.platform string \"%.*s\" in Amlogic chipset table", (int) platform_length, platform); /* Create chipset name from entry */ return (struct cpuinfo_arm_chipset) { .vendor = cpuinfo_arm_chipset_vendor_amlogic, .series = (enum cpuinfo_arm_chipset_series) amlogic_map_entries[i].series, .model = amlogic_map_entries[i].model, .suffix = { [0] = amlogic_map_entries[i].suffix[0], [1] = amlogic_map_entries[i].suffix[1], [2] = amlogic_map_entries[i].suffix[2], }, }; } } } /* Compare to tabulated ro.board.platform values for popular chipsets/devices which can't be otherwise detected */ for (size_t i = 0; i < CPUINFO_COUNT_OF(special_platform_map_entries); i++) { if (strncmp(special_platform_map_entries[i].platform, platform, platform_length) == 0 && special_platform_map_entries[i].platform[platform_length] == 0) { /* Create chipset name from entry */ cpuinfo_log_debug( "found ro.board.platform string \"%.*s\" in special chipset table", (int) platform_length, platform); return (struct cpuinfo_arm_chipset) { .vendor = chipset_series_vendor[special_platform_map_entries[i].series], .series = (enum cpuinfo_arm_chipset_series) special_platform_map_entries[i].series, .model = special_platform_map_entries[i].model, .suffix = { [0] = special_platform_map_entries[i].suffix, }, }; } } /* None of the ro.board.platform signatures matched, indicate unknown chipset */ return (struct cpuinfo_arm_chipset) { .vendor = cpuinfo_arm_chipset_vendor_unknown, .series = cpuinfo_arm_chipset_series_unknown, }; } /* * Decodes chipset name from ro.mediatek.platform Android system property. * * @param[in] platform - ro.mediatek.platform value. * * @returns Decoded chipset name. If chipset could not be decoded, the resulting structure would use `unknown` * vendor and series identifiers. */ struct cpuinfo_arm_chipset cpuinfo_arm_android_decode_chipset_from_ro_mediatek_platform( const char platform[restrict static CPUINFO_BUILD_PROP_VALUE_MAX]) { struct cpuinfo_arm_chipset chipset; const char* platform_end = platform + strnlen(platform, CPUINFO_BUILD_PROP_VALUE_MAX); /* Check MediaTek MT signature */ if (match_mt(platform, platform_end, false, &chipset)) { return chipset; } return (struct cpuinfo_arm_chipset) { .vendor = cpuinfo_arm_chipset_vendor_unknown, .series = cpuinfo_arm_chipset_series_unknown, }; } /* * Decodes chipset name from ro.arch Android system property. * * The ro.arch property is matched only against Samsung Exynos signature. Systems with other chipset rarely * configure ro.arch Android system property, and can be decoded through other properties, but some Exynos * chipsets are identified only in ro.arch. * * @param[in] arch - ro.arch value. * * @returns Decoded chipset name. If chipset could not be decoded, the resulting structure would use `unknown` * vendor and series identifiers. */ struct cpuinfo_arm_chipset cpuinfo_arm_android_decode_chipset_from_ro_arch( const char arch[restrict static CPUINFO_BUILD_PROP_VALUE_MAX]) { struct cpuinfo_arm_chipset chipset; const char* arch_end = arch + strnlen(arch, CPUINFO_BUILD_PROP_VALUE_MAX); /* Check Samsung exynosXXXX signature */ if (match_exynos(arch, arch_end, &chipset)) { return chipset; } return (struct cpuinfo_arm_chipset) { .vendor = cpuinfo_arm_chipset_vendor_unknown, .series = cpuinfo_arm_chipset_series_unknown, }; } /* * Decodes chipset name from ro.chipname or ro.hardware.chipname Android system property. * * @param[in] chipname - ro.chipname or ro.hardware.chipname value. * * @returns Decoded chipset name. If chipset could not be decoded, the resulting structure would use `unknown` vendor * and series identifiers. */ struct cpuinfo_arm_chipset cpuinfo_arm_android_decode_chipset_from_ro_chipname( const char chipname[restrict static CPUINFO_BUILD_PROP_VALUE_MAX]) { struct cpuinfo_arm_chipset chipset; const size_t chipname_length = strnlen(chipname, CPUINFO_BUILD_PROP_VALUE_MAX); const char* chipname_end = chipname + chipname_length; /* Check Qualcomm MSM/APQ signatures */ if (match_msm_apq(chipname, chipname_end, &chipset)) { cpuinfo_log_debug( "matched Qualcomm MSM/APQ signature in ro.chipname string \"%.*s\"", (int) chipname_length, chipname); return chipset; } /* Check SMxxxx (Qualcomm Snapdragon) signature */ if (match_sm(chipname, chipname_end, &chipset)) { cpuinfo_log_debug( "matched Qualcomm SM signature in /proc/cpuinfo Hardware string \"%.*s\"", (int) chipname_length, chipname); return chipset; } /* Check exynosXXXX (Samsung Exynos) signature */ if (match_exynos(chipname, chipname_end, &chipset)) { cpuinfo_log_debug( "matched exynosXXXX (Samsung Exynos) signature in ro.chipname string \"%.*s\"", (int) chipname_length, chipname); return chipset; } /* Check universalXXXX (Samsung Exynos) signature */ if (match_universal(chipname, chipname_end, &chipset)) { cpuinfo_log_debug( "matched UNIVERSAL (Samsung Exynos) signature in ro.chipname Hardware string \"%.*s\"", (int) chipname_length, chipname); return chipset; } /* Check MediaTek MT signature */ if (match_mt(chipname, chipname_end, true, &chipset)) { cpuinfo_log_debug( "matched MediaTek MT signature in ro.chipname string \"%.*s\"", (int) chipname_length, chipname); return chipset; } /* Check Spreadtrum SC signature */ if (match_sc(chipname, chipname_end, &chipset)) { cpuinfo_log_debug( "matched Spreadtrum SC signature in ro.chipname string \"%.*s\"", (int) chipname_length, chipname); return chipset; } #if CPUINFO_ARCH_ARM /* Check Marvell PXA signature */ if (match_pxa(chipname, chipname_end, &chipset)) { cpuinfo_log_debug( "matched Marvell PXA signature in ro.chipname string \"%.*s\"", (int) chipname_length, chipname); return chipset; } /* Compare to ro.chipname value ("mp523x") for Renesas MP5232 which can't be otherwise detected */ if (chipname_length == 6 && memcmp(chipname, "mp523x", 6) == 0) { cpuinfo_log_debug( "matched Renesas MP5232 signature in ro.chipname string \"%.*s\"", (int) chipname_length, chipname); return (struct cpuinfo_arm_chipset) { .vendor = cpuinfo_arm_chipset_vendor_renesas, .series = cpuinfo_arm_chipset_series_renesas_mp, .model = 5232, }; } #endif return (struct cpuinfo_arm_chipset) { .vendor = cpuinfo_arm_chipset_vendor_unknown, .series = cpuinfo_arm_chipset_series_unknown, }; } #endif /* __ANDROID__ */ /* * Fix common bugs, typos, and renames in chipset name. * * @param[in,out] chipset - chipset name to fix. * @param cores - number of cores in the chipset. * @param max_cpu_freq_max - maximum of /sys/devices/system/cpu/cpu/cpofreq/cpu_freq_max values. */ void cpuinfo_arm_fixup_chipset( struct cpuinfo_arm_chipset chipset[restrict static 1], uint32_t cores, uint32_t max_cpu_freq_max) { switch (chipset->series) { case cpuinfo_arm_chipset_series_qualcomm_msm: /* Check if there is suffix */ if (chipset->suffix[0] == 0) { /* No suffix, but the model may be misreported */ switch (chipset->model) { case 8216: /* MSM8216 was renamed to MSM8916 */ cpuinfo_log_info("reinterpreted MSM8216 chipset as MSM8916"); chipset->model = 8916; break; case 8916: /* Common bug: MSM8939 (Octa-core) reported as MSM8916 (Quad-core) */ switch (cores) { case 4: break; case 8: cpuinfo_log_info("reinterpreted MSM8916 chipset with 8 cores as MSM8939"); chipset->model = 8939; break; default: cpuinfo_log_warning("system reported invalid %"PRIu32"-core MSM%"PRIu32" chipset", cores, chipset->model); chipset->model = 0; } break; case 8937: /* Common bug: MSM8917 (Quad-core) reported as MSM8937 (Octa-core) */ switch (cores) { case 4: cpuinfo_log_info("reinterpreted MSM8937 chipset with 4 cores as MSM8917"); chipset->model = 8917; break; case 8: break; default: cpuinfo_log_warning("system reported invalid %"PRIu32"-core MSM%"PRIu32" chipset", cores, chipset->model); chipset->model = 0; } break; case 8960: /* Common bug: APQ8064 (Quad-core) reported as MSM8960 (Dual-core) */ switch (cores) { case 2: break; case 4: cpuinfo_log_info("reinterpreted MSM8960 chipset with 4 cores as APQ8064"); chipset->series = cpuinfo_arm_chipset_series_qualcomm_apq; chipset->model = 8064; break; default: cpuinfo_log_warning("system reported invalid %"PRIu32"-core MSM%"PRIu32" chipset", cores, chipset->model); chipset->model = 0; } break; case 8996: /* Common bug: MSM8994 (Octa-core) reported as MSM8996 (Quad-core) */ switch (cores) { case 4: break; case 8: cpuinfo_log_info("reinterpreted MSM8996 chipset with 8 cores as MSM8994"); chipset->model = 8994; break; default: cpuinfo_log_warning("system reported invalid %"PRIu32"-core MSM%"PRIu32" chipset", cores, chipset->model); chipset->model = 0; } break; #if CPUINFO_ARCH_ARM case 8610: /* Common bug: MSM8612 (Quad-core) reported as MSM8610 (Dual-core) */ switch (cores) { case 2: break; case 4: cpuinfo_log_info("reinterpreted MSM8610 chipset with 4 cores as MSM8612"); chipset->model = 8612; break; default: cpuinfo_log_warning("system reported invalid %"PRIu32"-core MSM%"PRIu32" chipset", cores, chipset->model); chipset->model = 0; } break; #endif /* CPUINFO_ARCH_ARM */ } } else { /* Suffix may need correction */ const uint32_t suffix_word = load_u32le(chipset->suffix); if (suffix_word == UINT32_C(0x004D534D) /* "\0MSM" = reverse("MSM\0") */) { /* * Common bug: model name repeated twice, e.g. "MSM8916MSM8916" * In this case, model matching code parses the second "MSM" as a suffix */ chipset->suffix[0] = 0; chipset->suffix[1] = 0; chipset->suffix[2] = 0; } else { switch (chipset->model) { case 8976: /* MSM8976SG -> MSM8976PRO */ if (suffix_word == UINT32_C(0x00004753) /* "\0\0GS" = reverse("SG\0\0") */ ) { chipset->suffix[0] = 'P'; chipset->suffix[1] = 'R'; chipset->suffix[2] = 'O'; } break; case 8996: /* MSM8996PRO -> MSM8996PRO-AB or MSM8996PRO-AC */ if (suffix_word == UINT32_C(0x004F5250) /* "\0ORP" = reverse("PRO\0") */ ) { chipset->suffix[3] = '-'; chipset->suffix[4] = 'A'; chipset->suffix[5] = 'B' + (char) (max_cpu_freq_max >= 2188800); } break; } } } break; case cpuinfo_arm_chipset_series_qualcomm_apq: { /* Suffix may need correction */ const uint32_t expected_apq = load_u32le(chipset->suffix); if (expected_apq == UINT32_C(0x00515041) /* "\0QPA" = reverse("APQ\0") */) { /* * Common bug: model name repeated twice, e.g. "APQ8016APQ8016" * In this case, model matching code parses the second "APQ" as a suffix */ chipset->suffix[0] = 0; chipset->suffix[1] = 0; chipset->suffix[2] = 0; } break; } case cpuinfo_arm_chipset_series_samsung_exynos: switch (chipset->model) { #if CPUINFO_ARCH_ARM case 4410: /* Exynos 4410 was renamed to Exynos 4412 */ chipset->model = 4412; break; case 5420: /* Common bug: Exynos 5260 (Hexa-core) reported as Exynos 5420 (Quad-core) */ switch (cores) { case 4: break; case 6: cpuinfo_log_info("reinterpreted Exynos 5420 chipset with 6 cores as Exynos 5260"); chipset->model = 5260; break; default: cpuinfo_log_warning("system reported invalid %"PRIu32"-core Exynos 5420 chipset", cores); chipset->model = 0; } break; #endif /* CPUINFO_ARCH_ARM */ case 7580: /* Common bug: Exynos 7578 (Quad-core) reported as Exynos 7580 (Octa-core) */ switch (cores) { case 4: cpuinfo_log_info("reinterpreted Exynos 7580 chipset with 4 cores as Exynos 7578"); chipset->model = 7578; break; case 8: break; default: cpuinfo_log_warning("system reported invalid %"PRIu32"-core Exynos 7580 chipset", cores); chipset->model = 0; } break; } break; case cpuinfo_arm_chipset_series_mediatek_mt: if (chipset->model == 6752) { /* Common bug: MT6732 (Quad-core) reported as MT6752 (Octa-core) */ switch (cores) { case 4: cpuinfo_log_info("reinterpreted MT6752 chipset with 4 cores as MT6732"); chipset->model = 6732; break; case 8: break; default: cpuinfo_log_warning("system reported invalid %"PRIu32"-core MT6752 chipset", cores); chipset->model = 0; } } if (chipset->suffix[0] == 'T') { /* Normalization: "TURBO" and "TRUBO" (apparently a typo) -> "T" */ const uint32_t suffix_word = load_u32le(chipset->suffix + 1); switch (suffix_word) { case UINT32_C(0x4F425255): /* "OBRU" = reverse("URBO") */ case UINT32_C(0x4F425552): /* "OBUR" = reverse("RUBO") */ if (chipset->suffix[5] == 0) { chipset->suffix[1] = 0; chipset->suffix[2] = 0; chipset->suffix[3] = 0; chipset->suffix[4] = 0; } break; } } break; case cpuinfo_arm_chipset_series_rockchip_rk: if (chipset->model == 3288) { /* Common bug: Rockchip RK3399 (Hexa-core) always reported as RK3288 (Quad-core) */ switch (cores) { case 4: break; case 6: cpuinfo_log_info("reinterpreted RK3288 chipset with 6 cores as RK3399"); chipset->model = 3399; break; default: cpuinfo_log_warning("system reported invalid %"PRIu32"-core RK3288 chipset", cores); chipset->model = 0; } } break; default: break; } } /* Map from ARM chipset vendor ID to its string representation */ static const char* chipset_vendor_string[cpuinfo_arm_chipset_vendor_max] = { [cpuinfo_arm_chipset_vendor_unknown] = "Unknown", [cpuinfo_arm_chipset_vendor_qualcomm] = "Qualcomm", [cpuinfo_arm_chipset_vendor_mediatek] = "MediaTek", [cpuinfo_arm_chipset_vendor_samsung] = "Samsung", [cpuinfo_arm_chipset_vendor_hisilicon] = "HiSilicon", [cpuinfo_arm_chipset_vendor_actions] = "Actions", [cpuinfo_arm_chipset_vendor_allwinner] = "Allwinner", [cpuinfo_arm_chipset_vendor_amlogic] = "Amlogic", [cpuinfo_arm_chipset_vendor_broadcom] = "Broadcom", [cpuinfo_arm_chipset_vendor_lg] = "LG", [cpuinfo_arm_chipset_vendor_leadcore] = "Leadcore", [cpuinfo_arm_chipset_vendor_marvell] = "Marvell", [cpuinfo_arm_chipset_vendor_mstar] = "MStar", [cpuinfo_arm_chipset_vendor_novathor] = "NovaThor", [cpuinfo_arm_chipset_vendor_nvidia] = "Nvidia", [cpuinfo_arm_chipset_vendor_pinecone] = "Pinecone", [cpuinfo_arm_chipset_vendor_renesas] = "Renesas", [cpuinfo_arm_chipset_vendor_rockchip] = "Rockchip", [cpuinfo_arm_chipset_vendor_spreadtrum] = "Spreadtrum", [cpuinfo_arm_chipset_vendor_telechips] = "Telechips", [cpuinfo_arm_chipset_vendor_texas_instruments] = "Texas Instruments", [cpuinfo_arm_chipset_vendor_wondermedia] = "WonderMedia", }; /* Map from ARM chipset series ID to its string representation */ static const char* chipset_series_string[cpuinfo_arm_chipset_series_max] = { [cpuinfo_arm_chipset_series_unknown] = NULL, [cpuinfo_arm_chipset_series_qualcomm_qsd] = "QSD", [cpuinfo_arm_chipset_series_qualcomm_msm] = "MSM", [cpuinfo_arm_chipset_series_qualcomm_apq] = "APQ", [cpuinfo_arm_chipset_series_qualcomm_snapdragon] = "Snapdragon ", [cpuinfo_arm_chipset_series_mediatek_mt] = "MT", [cpuinfo_arm_chipset_series_samsung_exynos] = "Exynos ", [cpuinfo_arm_chipset_series_hisilicon_k3v] = "K3V", [cpuinfo_arm_chipset_series_hisilicon_hi] = "Hi", [cpuinfo_arm_chipset_series_hisilicon_kirin] = "Kirin ", [cpuinfo_arm_chipset_series_actions_atm] = "ATM", [cpuinfo_arm_chipset_series_allwinner_a] = "A", [cpuinfo_arm_chipset_series_amlogic_aml] = "AML", [cpuinfo_arm_chipset_series_amlogic_s] = "S", [cpuinfo_arm_chipset_series_broadcom_bcm] = "BCM", [cpuinfo_arm_chipset_series_lg_nuclun] = "Nuclun ", [cpuinfo_arm_chipset_series_leadcore_lc] = "LC", [cpuinfo_arm_chipset_series_marvell_pxa] = "PXA", [cpuinfo_arm_chipset_series_mstar_6a] = "6A", [cpuinfo_arm_chipset_series_novathor_u] = "U", [cpuinfo_arm_chipset_series_nvidia_tegra_t] = "Tegra T", [cpuinfo_arm_chipset_series_nvidia_tegra_ap] = "Tegra AP", [cpuinfo_arm_chipset_series_nvidia_tegra_sl] = "Tegra SL", [cpuinfo_arm_chipset_series_pinecone_surge_s] = "Surge S", [cpuinfo_arm_chipset_series_renesas_mp] = "MP", [cpuinfo_arm_chipset_series_rockchip_rk] = "RK", [cpuinfo_arm_chipset_series_spreadtrum_sc] = "SC", [cpuinfo_arm_chipset_series_telechips_tcc] = "TCC", [cpuinfo_arm_chipset_series_texas_instruments_omap] = "OMAP", [cpuinfo_arm_chipset_series_wondermedia_wm] = "WM", }; /* Convert chipset name represented by cpuinfo_arm_chipset structure to a string representation */ void cpuinfo_arm_chipset_to_string( const struct cpuinfo_arm_chipset chipset[restrict static 1], char name[restrict static CPUINFO_ARM_CHIPSET_NAME_MAX]) { enum cpuinfo_arm_chipset_vendor vendor = chipset->vendor; if (vendor >= cpuinfo_arm_chipset_vendor_max) { vendor = cpuinfo_arm_chipset_vendor_unknown; } enum cpuinfo_arm_chipset_series series = chipset->series; if (series >= cpuinfo_arm_chipset_series_max) { series = cpuinfo_arm_chipset_series_unknown; } const char* vendor_string = chipset_vendor_string[vendor]; const char* series_string = chipset_series_string[series]; const uint32_t model = chipset->model; if (model == 0) { if (series == cpuinfo_arm_chipset_series_unknown) { strncpy(name, vendor_string, CPUINFO_ARM_CHIPSET_NAME_MAX); } else { snprintf(name, CPUINFO_ARM_CHIPSET_NAME_MAX, "%s %s", vendor_string, series_string); } } else { const size_t suffix_length = strnlen(chipset->suffix, CPUINFO_ARM_CHIPSET_SUFFIX_MAX); snprintf(name, CPUINFO_ARM_CHIPSET_NAME_MAX, "%s %s%"PRIu32"%.*s", vendor_string, series_string, model, (int) suffix_length, chipset->suffix); } } #ifdef __ANDROID__ static inline struct cpuinfo_arm_chipset disambiguate_qualcomm_chipset( const struct cpuinfo_arm_chipset proc_cpuinfo_hardware_chipset[restrict static 1], const struct cpuinfo_arm_chipset ro_product_board_chipset[restrict static 1], const struct cpuinfo_arm_chipset ro_board_platform_chipset[restrict static 1], const struct cpuinfo_arm_chipset ro_chipname_chipset[restrict static 1], const struct cpuinfo_arm_chipset ro_hardware_chipname_chipset[restrict static 1]) { if (ro_hardware_chipname_chipset->series != cpuinfo_arm_chipset_series_unknown) { return *ro_hardware_chipname_chipset; } if (ro_chipname_chipset->series != cpuinfo_arm_chipset_series_unknown) { return *ro_chipname_chipset; } if (proc_cpuinfo_hardware_chipset->series != cpuinfo_arm_chipset_series_unknown) { return *proc_cpuinfo_hardware_chipset; } if (ro_product_board_chipset->series != cpuinfo_arm_chipset_series_unknown) { return *ro_product_board_chipset; } return *ro_board_platform_chipset; } static inline struct cpuinfo_arm_chipset disambiguate_mediatek_chipset( const struct cpuinfo_arm_chipset proc_cpuinfo_hardware_chipset[restrict static 1], const struct cpuinfo_arm_chipset ro_product_board_chipset[restrict static 1], const struct cpuinfo_arm_chipset ro_board_platform_chipset[restrict static 1], const struct cpuinfo_arm_chipset ro_mediatek_platform_chipset[restrict static 1], const struct cpuinfo_arm_chipset ro_chipname_chipset[restrict static 1]) { if (ro_chipname_chipset->series != cpuinfo_arm_chipset_series_unknown) { return *ro_chipname_chipset; } if (proc_cpuinfo_hardware_chipset->series != cpuinfo_arm_chipset_series_unknown) { return *proc_cpuinfo_hardware_chipset; } if (ro_product_board_chipset->series != cpuinfo_arm_chipset_series_unknown) { return *ro_product_board_chipset; } if (ro_board_platform_chipset->series != cpuinfo_arm_chipset_series_unknown) { return *ro_board_platform_chipset; } return *ro_mediatek_platform_chipset; } static inline struct cpuinfo_arm_chipset disambiguate_hisilicon_chipset( const struct cpuinfo_arm_chipset proc_cpuinfo_hardware_chipset[restrict static 1], const struct cpuinfo_arm_chipset ro_product_board_chipset[restrict static 1], const struct cpuinfo_arm_chipset ro_board_platform_chipset[restrict static 1]) { if (proc_cpuinfo_hardware_chipset->series != cpuinfo_arm_chipset_series_unknown) { return *proc_cpuinfo_hardware_chipset; } if (ro_product_board_chipset->series != cpuinfo_arm_chipset_series_unknown) { return *ro_product_board_chipset; } return *ro_board_platform_chipset; } static inline struct cpuinfo_arm_chipset disambiguate_amlogic_chipset( const struct cpuinfo_arm_chipset proc_cpuinfo_hardware_chipset[restrict static 1], const struct cpuinfo_arm_chipset ro_board_platform_chipset[restrict static 1]) { if (proc_cpuinfo_hardware_chipset->series != cpuinfo_arm_chipset_series_unknown) { return *proc_cpuinfo_hardware_chipset; } return *ro_board_platform_chipset; } static inline struct cpuinfo_arm_chipset disambiguate_marvell_chipset( const struct cpuinfo_arm_chipset proc_cpuinfo_hardware_chipset[restrict static 1], const struct cpuinfo_arm_chipset ro_product_board_chipset[restrict static 1], const struct cpuinfo_arm_chipset ro_chipname_chipset[restrict static 1]) { if (ro_chipname_chipset->series != cpuinfo_arm_chipset_series_unknown) { return *ro_chipname_chipset; } if (ro_product_board_chipset->series != cpuinfo_arm_chipset_series_unknown) { return *ro_product_board_chipset; } return *proc_cpuinfo_hardware_chipset; } static inline struct cpuinfo_arm_chipset disambiguate_rockchip_chipset( const struct cpuinfo_arm_chipset proc_cpuinfo_hardware_chipset[restrict static 1], const struct cpuinfo_arm_chipset ro_product_board_chipset[restrict static 1], const struct cpuinfo_arm_chipset ro_board_platform_chipset[restrict static 1]) { if (ro_product_board_chipset->series != cpuinfo_arm_chipset_series_unknown) { return *ro_product_board_chipset; } if (proc_cpuinfo_hardware_chipset->series != cpuinfo_arm_chipset_series_unknown) { return *proc_cpuinfo_hardware_chipset; } return *ro_board_platform_chipset; } static inline struct cpuinfo_arm_chipset disambiguate_spreadtrum_chipset( const struct cpuinfo_arm_chipset proc_cpuinfo_hardware_chipset[restrict static 1], const struct cpuinfo_arm_chipset ro_product_board_chipset[restrict static 1], const struct cpuinfo_arm_chipset ro_board_platform_chipset[restrict static 1], const struct cpuinfo_arm_chipset ro_chipname_chipset[restrict static 1]) { if (ro_chipname_chipset->series != cpuinfo_arm_chipset_series_unknown) { return *ro_chipname_chipset; } if (ro_product_board_chipset->series != cpuinfo_arm_chipset_series_unknown) { return *ro_product_board_chipset; } if (proc_cpuinfo_hardware_chipset->series != cpuinfo_arm_chipset_series_unknown) { return *proc_cpuinfo_hardware_chipset; } return *ro_board_platform_chipset; } /* * Decodes chipset name from Android system properties: * - /proc/cpuinfo Hardware string * - ro.product.board * - ro.board.platform * - ro.mediatek.platform * - ro.chipname * For some chipsets, the function relies frequency and on number of cores for chipset detection. * * @param[in] properties - structure with the Android system properties described above. * @param cores - number of cores in the chipset. * @param max_cpu_freq_max - maximum of /sys/devices/system/cpu/cpu/cpofreq/cpu_freq_max values. * * @returns Decoded chipset name. If chipset could not be decoded, the resulting structure would use `unknown` vendor * and series identifiers. */ struct cpuinfo_arm_chipset cpuinfo_arm_android_decode_chipset( const struct cpuinfo_android_properties properties[restrict static 1], uint32_t cores, uint32_t max_cpu_freq_max) { struct cpuinfo_arm_chipset chipset = { .vendor = cpuinfo_arm_chipset_vendor_unknown, .series = cpuinfo_arm_chipset_series_unknown, }; const bool tegra_platform = is_tegra( properties->ro_board_platform, properties->ro_board_platform + strnlen(properties->ro_board_platform, CPUINFO_BUILD_PROP_VALUE_MAX)); struct cpuinfo_arm_chipset chipsets[cpuinfo_android_chipset_property_max] = { [cpuinfo_android_chipset_property_proc_cpuinfo_hardware] = cpuinfo_arm_linux_decode_chipset_from_proc_cpuinfo_hardware( properties->proc_cpuinfo_hardware, cores, max_cpu_freq_max, tegra_platform), [cpuinfo_android_chipset_property_ro_product_board] = cpuinfo_arm_android_decode_chipset_from_ro_product_board( properties->ro_product_board, cores, max_cpu_freq_max), [cpuinfo_android_chipset_property_ro_board_platform] = cpuinfo_arm_android_decode_chipset_from_ro_board_platform( properties->ro_board_platform, cores, max_cpu_freq_max), [cpuinfo_android_chipset_property_ro_mediatek_platform] = cpuinfo_arm_android_decode_chipset_from_ro_mediatek_platform(properties->ro_mediatek_platform), [cpuinfo_android_chipset_property_ro_arch] = cpuinfo_arm_android_decode_chipset_from_ro_arch(properties->ro_arch), [cpuinfo_android_chipset_property_ro_chipname] = cpuinfo_arm_android_decode_chipset_from_ro_chipname(properties->ro_chipname), [cpuinfo_android_chipset_property_ro_hardware_chipname] = cpuinfo_arm_android_decode_chipset_from_ro_chipname(properties->ro_hardware_chipname), }; enum cpuinfo_arm_chipset_vendor vendor = cpuinfo_arm_chipset_vendor_unknown; for (size_t i = 0; i < cpuinfo_android_chipset_property_max; i++) { const enum cpuinfo_arm_chipset_vendor decoded_vendor = chipsets[i].vendor; if (decoded_vendor != cpuinfo_arm_chipset_vendor_unknown) { if (vendor == cpuinfo_arm_chipset_vendor_unknown) { vendor = decoded_vendor; } else if (vendor != decoded_vendor) { /* Parsing different system properties produces different chipset vendors. This situation is rare. */ cpuinfo_log_error( "chipset detection failed: different chipset vendors reported in different system properties"); goto finish; } } } if (vendor == cpuinfo_arm_chipset_vendor_unknown) { cpuinfo_log_warning( "chipset detection failed: none of the system properties matched known signatures"); goto finish; } /* Fix common bugs in reported chipsets */ for (size_t i = 0; i < cpuinfo_android_chipset_property_max; i++) { cpuinfo_arm_fixup_chipset(&chipsets[i], cores, max_cpu_freq_max); } /* * Propagate suffixes: consider all pairs of chipsets, if both chipsets in the pair are from the same series, * and one's suffix is a prefix of another's chipset suffix, use the longest suffix. */ for (size_t i = 0; i < cpuinfo_android_chipset_property_max; i++) { const size_t chipset_i_suffix_length = strnlen(chipsets[i].suffix, CPUINFO_ARM_CHIPSET_SUFFIX_MAX); for (size_t j = 0; j < i; j++) { if (chipsets[i].series == chipsets[j].series) { const size_t chipset_j_suffix_length = strnlen(chipsets[j].suffix, CPUINFO_ARM_CHIPSET_SUFFIX_MAX); if (chipset_i_suffix_length != chipset_j_suffix_length) { const size_t common_prefix_length = (chipset_i_suffix_length < chipset_j_suffix_length) ? chipset_i_suffix_length : chipset_j_suffix_length; if (common_prefix_length == 0 || memcmp(chipsets[i].suffix, chipsets[j].suffix, common_prefix_length) == 0) { if (chipset_i_suffix_length > chipset_j_suffix_length) { memcpy(chipsets[j].suffix, chipsets[i].suffix, chipset_i_suffix_length); } else { memcpy(chipsets[i].suffix, chipsets[j].suffix, chipset_j_suffix_length); } } } } } } for (size_t i = 0; i < cpuinfo_android_chipset_property_max; i++) { if (chipsets[i].series != cpuinfo_arm_chipset_series_unknown) { if (chipset.series == cpuinfo_arm_chipset_series_unknown) { chipset = chipsets[i]; } else if (chipsets[i].series != chipset.series || chipsets[i].model != chipset.model || strncmp(chipsets[i].suffix, chipset.suffix, CPUINFO_ARM_CHIPSET_SUFFIX_MAX) != 0) { cpuinfo_log_info( "different chipsets reported in different system properties; " "vendor-specific disambiguation heuristic would be used"); switch (vendor) { case cpuinfo_arm_chipset_vendor_qualcomm: return disambiguate_qualcomm_chipset( &chipsets[cpuinfo_android_chipset_property_proc_cpuinfo_hardware], &chipsets[cpuinfo_android_chipset_property_ro_product_board], &chipsets[cpuinfo_android_chipset_property_ro_board_platform], &chipsets[cpuinfo_android_chipset_property_ro_chipname], &chipsets[cpuinfo_android_chipset_property_ro_hardware_chipname]); case cpuinfo_arm_chipset_vendor_mediatek: return disambiguate_mediatek_chipset( &chipsets[cpuinfo_android_chipset_property_proc_cpuinfo_hardware], &chipsets[cpuinfo_android_chipset_property_ro_product_board], &chipsets[cpuinfo_android_chipset_property_ro_board_platform], &chipsets[cpuinfo_android_chipset_property_ro_mediatek_platform], &chipsets[cpuinfo_android_chipset_property_ro_chipname]); case cpuinfo_arm_chipset_vendor_hisilicon: return disambiguate_hisilicon_chipset( &chipsets[cpuinfo_android_chipset_property_proc_cpuinfo_hardware], &chipsets[cpuinfo_android_chipset_property_ro_product_board], &chipsets[cpuinfo_android_chipset_property_ro_board_platform]); case cpuinfo_arm_chipset_vendor_amlogic: return disambiguate_amlogic_chipset( &chipsets[cpuinfo_android_chipset_property_proc_cpuinfo_hardware], &chipsets[cpuinfo_android_chipset_property_ro_board_platform]); case cpuinfo_arm_chipset_vendor_marvell: return disambiguate_marvell_chipset( &chipsets[cpuinfo_android_chipset_property_proc_cpuinfo_hardware], &chipsets[cpuinfo_android_chipset_property_ro_product_board], &chipsets[cpuinfo_android_chipset_property_ro_chipname]); case cpuinfo_arm_chipset_vendor_rockchip: return disambiguate_rockchip_chipset( &chipsets[cpuinfo_android_chipset_property_proc_cpuinfo_hardware], &chipsets[cpuinfo_android_chipset_property_ro_product_board], &chipsets[cpuinfo_android_chipset_property_ro_board_platform]); case cpuinfo_arm_chipset_vendor_spreadtrum: return disambiguate_spreadtrum_chipset( &chipsets[cpuinfo_android_chipset_property_proc_cpuinfo_hardware], &chipsets[cpuinfo_android_chipset_property_ro_product_board], &chipsets[cpuinfo_android_chipset_property_ro_board_platform], &chipsets[cpuinfo_android_chipset_property_ro_chipname]); default: cpuinfo_log_error( "chipset detection failed: " "could not disambiguate different chipsets reported in different system properties"); /* chipset variable contains valid, but inconsistent chipset information, overwrite it */ chipset = (struct cpuinfo_arm_chipset) { .vendor = cpuinfo_arm_chipset_vendor_unknown, .series = cpuinfo_arm_chipset_series_unknown, }; goto finish; } } } } finish: return chipset; } #else /* !defined(__ANDROID__) */ /* * Fix commonly misreported Broadcom BCM models on Raspberry Pi boards. * * @param[in,out] chipset - chipset name to fix. * @param[in] revision - /proc/cpuinfo Revision string. */ void cpuinfo_arm_fixup_raspberry_pi_chipset( struct cpuinfo_arm_chipset chipset[restrict static 1], const char revision[restrict static CPUINFO_HARDWARE_VALUE_MAX]) { const size_t revision_length = strnlen(revision, CPUINFO_REVISION_VALUE_MAX); /* Parse revision codes according to https://www.raspberrypi.org/documentation/hardware/raspberrypi/revision-codes/README.md */ #if CPUINFO_ARCH_ARM if (revision_length == 4) { /* * Old-style revision codes. * All Raspberry Pi models with old-style revision code use Broadcom BCM2835. */ /* BCM2835 often misreported as BCM2708 */ if (chipset->model == 2708) { chipset->model = 2835; } return; } #endif if ((size_t) (revision_length - 5) <= (size_t) (8 - 5) /* 5 <= length(revision) <= 8 */) { /* New-style revision codes */ uint32_t model = 0; switch (revision[revision_length - 4]) { case '0': /* BCM2835 */ model = 2835; break; case '1': /* BCM2836 */ model = 2836; break; case '2': /* BCM2837 */ model = 2837; break; case '3': /* BCM2711 */ model = 2711; break; } if (model != 0) { chipset->model = model; chipset->suffix[0] = 0; } } } /* * Decodes chipset name from /proc/cpuinfo Hardware string. * For some chipsets, the function relies frequency and on number of cores for chipset detection. * * @param[in] hardware - /proc/cpuinfo Hardware string. * @param cores - number of cores in the chipset. * @param max_cpu_freq_max - maximum of /sys/devices/system/cpu/cpu/cpofreq/cpu_freq_max values. * * @returns Decoded chipset name. If chipset could not be decoded, the resulting structure would use `unknown` vendor * and series identifiers. */ struct cpuinfo_arm_chipset cpuinfo_arm_linux_decode_chipset( const char hardware[restrict static CPUINFO_HARDWARE_VALUE_MAX], const char revision[restrict static CPUINFO_REVISION_VALUE_MAX], uint32_t cores, uint32_t max_cpu_freq_max) { struct cpuinfo_arm_chipset chipset = cpuinfo_arm_linux_decode_chipset_from_proc_cpuinfo_hardware( hardware, cores, max_cpu_freq_max, false); if (chipset.vendor == cpuinfo_arm_chipset_vendor_unknown) { cpuinfo_log_warning( "chipset detection failed: /proc/cpuinfo Hardware string did not match known signatures"); } else if (chipset.vendor == cpuinfo_arm_chipset_vendor_broadcom) { /* Raspberry Pi kernel reports bogus chipset models; detect chipset from RPi revision */ cpuinfo_arm_fixup_raspberry_pi_chipset(&chipset, revision); } else { cpuinfo_arm_fixup_chipset(&chipset, cores, max_cpu_freq_max); } return chipset; } #endif