/* Copyright 2013-2014 IBM Corp. * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or * implied. * See the License for the specific language governing permissions and * limitations under the License. */ /* This is based on the hostboot ecc code */ #include #include #include #include #include "libflash.h" #include "ecc.h" /* Bit field identifiers for syndrome calculations. */ enum eccbitfields { GD = 0xff, //< Good, ECC matches. UE = 0xfe, //< Uncorrectable. E0 = 71, //< Error in ECC bit 0 E1 = 70, //< Error in ECC bit 1 E2 = 69, //< Error in ECC bit 2 E3 = 68, //< Error in ECC bit 3 E4 = 67, //< Error in ECC bit 4 E5 = 66, //< Error in ECC bit 5 E6 = 65, //< Error in ECC bit 6 E7 = 64 //< Error in ECC bit 7 /* 0-63 Correctable bit in byte */ }; /* * Matrix used for ECC calculation. * * Each row of this is the set of data word bits that are used for * the calculation of the corresponding ECC bit. The parity of the * bitset is the value of the ECC bit. * * ie. ECC[n] = eccMatrix[n] & data * * Note: To make the math easier (and less shifts in resulting code), * row0 = ECC7. HW numbering is MSB, order here is LSB. * * These values come from the HW design of the ECC algorithm. */ static uint64_t eccmatrix[] = { 0x0000e8423c0f99ffull, 0x00e8423c0f99ff00ull, 0xe8423c0f99ff0000ull, 0x423c0f99ff0000e8ull, 0x3c0f99ff0000e842ull, 0x0f99ff0000e8423cull, 0x99ff0000e8423c0full, 0xff0000e8423c0f99ull }; /** * Syndrome calculation matrix. * * Maps syndrome to flipped bit. * * To perform ECC correction, this matrix is a look-up of the bit * that is bad based on the binary difference of the good and bad * ECC. This difference is called the "syndrome". * * When a particular bit is on in the data, it cause a column from * eccMatrix being XOR'd into the ECC field. This column is the * "effect" of each bit. If a bit is flipped in the data then its * "effect" is missing from the ECC. You can calculate ECC on unknown * quality data and compare the ECC field between the calculated * value and the stored value. If the difference is zero, then the * data is clean. If the difference is non-zero, you look up the * difference in the syndrome table to identify the "effect" that * is missing, which is the bit that is flipped. * * Notice that ECC bit flips are recorded by a single "effect" * bit (ie. 0x1, 0x2, 0x4, 0x8 ...) and double bit flips are identified * by the UE status in the table. * * Bits are in MSB order. */ static enum eccbitfields syndromematrix[] = { GD, E7, E6, UE, E5, UE, UE, 47, E4, UE, UE, 37, UE, 35, 39, UE, E3, UE, UE, 48, UE, 30, 29, UE, UE, 57, 27, UE, 31, UE, UE, UE, E2, UE, UE, 17, UE, 18, 40, UE, UE, 58, 22, UE, 21, UE, UE, UE, UE, 16, 49, UE, 19, UE, UE, UE, 23, UE, UE, UE, UE, 20, UE, UE, E1, UE, UE, 51, UE, 46, 9, UE, UE, 34, 10, UE, 32, UE, UE, 36, UE, 62, 50, UE, 14, UE, UE, UE, 13, UE, UE, UE, UE, UE, UE, UE, UE, 61, 8, UE, 41, UE, UE, UE, 11, UE, UE, UE, UE, UE, UE, UE, 15, UE, UE, UE, UE, UE, UE, UE, UE, UE, 12, UE, UE, UE, UE, UE, E0, UE, UE, 55, UE, 45, 43, UE, UE, 56, 38, UE, 1, UE, UE, UE, UE, 25, 26, UE, 2, UE, UE, UE, 24, UE, UE, UE, UE, UE, 28, UE, UE, 59, 54, UE, 42, UE, UE, 44, 6, UE, UE, UE, UE, UE, UE, UE, 5, UE, UE, UE, UE, UE, UE, UE, UE, UE, UE, UE, UE, UE, UE, UE, UE, 63, 53, UE, 0, UE, UE, UE, 33, UE, UE, UE, UE, UE, UE, UE, 3, UE, UE, 52, UE, UE, UE, UE, UE, UE, UE, UE, UE, UE, UE, UE, 7, UE, UE, UE, UE, UE, UE, UE, UE, 60, UE, UE, UE, UE, UE, UE, UE, UE, UE, UE, 4, UE, UE, UE, UE, UE, UE, UE, UE, UE, UE, UE, }; /** * Create the ECC field corresponding to a 8-byte data field * * @data: The 8 byte data to generate ECC for. * @return: The 1 byte ECC corresponding to the data. */ static uint8_t eccgenerate(uint64_t data) { int i; uint8_t result = 0; for (i = 0; i < 8; i++) result |= __builtin_parityll(eccmatrix[i] & data) << i; return result; } /** * Verify the data and ECC match or indicate how they are wrong. * * @data: The data to check ECC on. * @ecc: The [supposed] ECC for the data. * * @return: eccBitfield or 0-64. * * @retval GD - Indicates the data is good (matches ECC). * @retval UE - Indicates the data is uncorrectable. * @retval all others - Indication of which bit is incorrect. */ static enum eccbitfields eccverify(uint64_t data, uint8_t ecc) { return syndromematrix[eccgenerate(data) ^ ecc]; } /* IBM bit ordering */ static inline uint64_t eccflipbit(uint64_t data, uint8_t bit) { if (bit > 63) return data; return data ^ (1ul << (63 - bit)); } static int eccbyte(uint64_t *dst, struct ecc64 *src) { uint8_t ecc, badbit; uint64_t data; data = src->data; ecc = src->ecc; badbit = eccverify(be64_to_cpu(data), ecc); if (badbit == UE) { FL_ERR("ECC: uncorrectable error: %016lx %02x\n", (long unsigned int)be64_to_cpu(data), ecc); return badbit; } *dst = data; if (badbit <= UE) FL_INF("ECC: correctable error: %i\n", badbit); if (badbit < 64) *dst = (uint64_t)be64_to_cpu(eccflipbit(be64_to_cpu(data), badbit)); return 0; } static uint64_t *inc_uint64_by(const void *p, uint64_t i) { return (uint64_t *)(((char *)p) + i); } static struct ecc64 *inc_ecc64_by(struct ecc64 *p, uint64_t i) { return (struct ecc64 *)(((char *)p) + i); } static uint64_t whole_ecc_bytes(uint64_t i) { return i & ~(BYTES_PER_ECC - 1); } static uint64_t whole_ecc_structs(uint64_t i) { return whole_ecc_bytes(i) >> 3; } /** * Copy data from an input buffer with ECC to an output buffer without ECC. * Correct it along the way and check for errors. * * @dst: destination buffer without ECC * @src: source buffer with ECC * @len: number of bytes of data to copy (without ecc). * Must be 8 byte aligned. * * @return: Success or error * * @retval: 0 - success * @retfal: other - fail */ int memcpy_from_ecc(uint64_t *dst, struct ecc64 *src, uint64_t len) { uint32_t i; if (len & 0x7) { /* TODO: we could probably handle this */ FL_ERR("ECC data length must be 8 byte aligned length:%" PRIx64 "\n", len); return -1; } /* Handle in chunks of 8 bytes, so adjust the length */ len >>= 3; for (i = 0; i < len; i++) { int rc; rc = eccbyte(dst, src + i); if (rc) return rc; dst++; } return 0; } /** * Copy data from an input buffer with ECC to an output buffer without ECC. * Correct it along the way and check for errors. * * Unlike memcmp_from_ecc() which requires that the first byte into * dst be the first byte in src (which must also be aligned to a * struct ecc64 struct boundary) this function can cope with the first * byte in dst not being the first byte in src. * * Note: src MUST still be aligned to a struct ecc64 otherwise ECC * calculations are impossible. * * The alignment parameter species the number of bytes present at the * start of src that should be skipped and not written to dst. Once * again, these bytes must be in src otherwise the ECC cannot be * checked. * * len also doesn't have any value limitation for this function. Of * course src must contain an exact multiple of struct ecc64 otherwise * ECC calculation cannot be performed but this function won't copy * the entirety of the last src data word if len is not mutiple of 8 * * @dst: destination buffer without ECC * @src: source buffer with ECC * @len: number of bytes of data to copy (without ecc). * @alignment: number of leading bytes in src which shouldn't be * copied to dst * @return: Success or error * * @retval: 0 - success * @retfal: other - fail */ int memcpy_from_ecc_unaligned(uint64_t *dst, struct ecc64 *src, uint64_t len, uint8_t alignment) { char data[BYTES_PER_ECC]; uint8_t bytes_wanted; int rc; if (alignment > 8) return -1; bytes_wanted = BYTES_PER_ECC - alignment; /* * Only actually do the first calculation if an alignment is * required - otherwise jump straight to memcpy_from_ecc() */ if (alignment) { rc = eccbyte((uint64_t *)data, src); if (rc) return rc; memcpy(dst, &data[alignment], bytes_wanted); src = inc_ecc64_by(src, sizeof(struct ecc64)); dst = inc_uint64_by(dst, bytes_wanted); len -= bytes_wanted; } if (len >= BYTES_PER_ECC) { rc = memcpy_from_ecc(dst, src, whole_ecc_bytes(len)); if (rc) return rc; /* * It helps to let the compiler to the pointer arithmetic * here, (dst and src are different types) */ dst += whole_ecc_structs(len); src += whole_ecc_structs(len); len -= whole_ecc_bytes(len); } if (len) { rc = eccbyte((uint64_t *)data, src); if (rc) return rc; memcpy(dst, data, len); } return 0; } /** * Copy data from an input buffer without ECC to an output buffer with ECC. * * @dst: destination buffer with ECC * @src: source buffer without ECC * @len: number of bytes of data to copy (without ecc, length of src). * Note: dst must be big enough to hold ecc bytes as well. * Must be 8 byte aligned. * * @return: success or failure * * @retval: 0 - success * @retfal: other - fail */ int memcpy_to_ecc(struct ecc64 *dst, const uint64_t *src, uint64_t len) { struct ecc64 ecc_word; uint64_t i; if (len & 0x7) { /* TODO: we could probably handle this */ FL_ERR("Data to add ECC bytes to must be 8 byte aligned length: %" PRIx64 "\n", len); return -1; } /* Handle in chunks of 8 bytes, so adjust the length */ len >>= 3; for (i = 0; i < len; i++) { ecc_word.ecc = eccgenerate(be64_to_cpu(*(src + i))); ecc_word.data = *(src + i); *(dst + i) = ecc_word; } return 0; } /** * Copy data from an input buffer without ECC to an output buffer with ECC. * * Unlike memcmp_to_ecc() which requires that the first byte in src be * the first byte of a struct ecc64 structure this function does not * have this requirement. * * Like memcpy_to_ecc_unaligned() the alignment parameter specfies the * number of bytes in the first src word that are missing and would be * required to form a struct ecc64 structure. * * It must be noted here that extra work IN THE CALLER must be done * if your data is unaligned. In order to peform ECC calculations * whatever portions of the ecc words are missing in src must be in * dst. * * For example, if there is an alignment value of 1 then this means * there is 1 byte (of the total of 8 bytes) missing in src which is * needed to calculate the first ECC byte. Therefore the first byte of * dst MUST CONTAIN IT! * * The same problem exists for the end of the buffer where src may not * end exactly aligned, if this is the case dst must contain the * required bytes to calculate the last ECC byte - they should be in * dst where they would normally be found if src did contain those * bytes. * * @dst: destination buffer with ECC * @src: source buffer without ECC * @len: number of bytes of data to copy (without ecc, length of src). * @alignment: The number of bytes 'missing' from the start of src to * be struct ecc64 aligned * * Note: dst must be big enough to hold ecc bytes as well. * Must be 8 byte aligned. * * @return: success or failure * * @retval: 0 - success * @retfal: other - fail */ int memcpy_to_ecc_unaligned(struct ecc64 *dst, const uint64_t *src, uint64_t len, uint8_t alignment) { struct ecc64 ecc_word; uint8_t bytes_wanted; int rc; bytes_wanted = BYTES_PER_ECC - alignment; /* * Only actually do the first calculation if an alignment is * required - otherwise jump straight to memcpy_to_ecc() */ if (alignment) { ecc_word.data = dst->data; memcpy(inc_uint64_by(&ecc_word.data, alignment), src, bytes_wanted); ecc_word.ecc = eccgenerate(be64_to_cpu(ecc_word.data)); memcpy(dst, inc_ecc64_by(&ecc_word, alignment), sizeof(struct ecc64) - alignment); dst = inc_ecc64_by(dst, sizeof(struct ecc64) - alignment); src = inc_uint64_by(src, bytes_wanted); len -= bytes_wanted; } if (len >= BYTES_PER_ECC) { rc = memcpy_to_ecc(dst, src, whole_ecc_bytes(len)); if (rc) return rc; /* * It helps to let the compiler to the pointer arithmetic * here, (dst and src are different types) */ dst += whole_ecc_structs(len); src += whole_ecc_structs(len); len -= whole_ecc_bytes(len); } if (len) { bytes_wanted = BYTES_PER_ECC - len; ecc_word.data = *src; memcpy(inc_uint64_by(&ecc_word.data, len), inc_ecc64_by(dst, len), bytes_wanted); ecc_word.ecc = eccgenerate(be64_to_cpu(ecc_word.data)); *dst = ecc_word; } return 0; }