/*- * Copyright (c) 2016 Landon Fuller * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer, * without modification. * 2. Redistributions in binary form must reproduce at minimum a disclaimer * similar to the "NO WARRANTY" disclaimer below ("Disclaimer") and any * redistribution must be conditioned upon including a substantially * similar Disclaimer requirement for further binary redistribution. * * NO WARRANTY * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS * ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT * LIMITED TO, THE IMPLIED WARRANTIES OF NONINFRINGEMENT, MERCHANTIBILITY * AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL * THE COPYRIGHT HOLDERS OR CONTRIBUTORS BE LIABLE FOR SPECIAL, EXEMPLARY, * OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER * IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF * THE POSSIBILITY OF SUCH DAMAGES. */ #include #ifdef _KERNEL #include #include #include #include #else /* !_KERNEL */ #include #include #include #include #include #endif /* _KERNEL */ #include "bhnd_nvram_private.h" #include "bhnd_nvram_datavar.h" #include "bhnd_nvram_data_bcmvar.h" /* * Broadcom-RAW NVRAM data class. * * The Broadcom NVRAM NUL-delimited ASCII format is used by most * Broadcom SoCs. * * The NVRAM data is encoded as a stream of NUL-terminated 'key=value' * strings; the end of the stream is denoted by a single extra NUL character. */ struct bhnd_nvram_bcmraw; /** BCM-RAW NVRAM data class instance */ struct bhnd_nvram_bcmraw { struct bhnd_nvram_data nv; /**< common instance state */ char *data; /**< backing buffer */ size_t size; /**< buffer size */ size_t count; /**< variable count */ }; BHND_NVRAM_DATA_CLASS_DEFN(bcmraw, "Broadcom (RAW)", BHND_NVRAM_DATA_CAP_DEVPATHS, sizeof(struct bhnd_nvram_bcmraw)) static int bhnd_nvram_bcmraw_probe(struct bhnd_nvram_io *io) { char envp[16]; size_t envp_len; size_t io_size; int error; io_size = bhnd_nvram_io_getsize(io); /* * Fetch initial bytes */ envp_len = bhnd_nv_ummin(sizeof(envp), io_size); if ((error = bhnd_nvram_io_read(io, 0x0, envp, envp_len))) return (error); /* An empty BCM-RAW buffer should still contain a single terminating * NUL */ if (envp_len == 0) return (ENXIO); if (envp_len == 1) { if (envp[0] != '\0') return (ENXIO); return (BHND_NVRAM_DATA_PROBE_MAYBE); } /* Must contain only printable ASCII characters delimited * by NUL record delimiters */ for (size_t i = 0; i < envp_len; i++) { char c = envp[i]; /* If we hit a newline, this is probably BCM-TXT */ if (c == '\n') return (ENXIO); if (c == '\0' && !bhnd_nv_isprint(c)) continue; } /* A valid BCM-RAW buffer should contain a terminating NUL for * the last record, followed by a final empty record terminated by * NUL */ envp_len = 2; if (io_size < envp_len) return (ENXIO); if ((error = bhnd_nvram_io_read(io, io_size-envp_len, envp, envp_len))) return (error); if (envp[0] != '\0' || envp[1] != '\0') return (ENXIO); return (BHND_NVRAM_DATA_PROBE_MAYBE + 1); } static int bhnd_nvram_bcmraw_getvar_direct(struct bhnd_nvram_io *io, const char *name, void *buf, size_t *len, bhnd_nvram_type type) { return (bhnd_nvram_bcm_getvar_direct_common(io, name, buf, len, type, false)); } static int bhnd_nvram_bcmraw_serialize(bhnd_nvram_data_class *cls, bhnd_nvram_plist *props, bhnd_nvram_plist *options, void *outp, size_t *olen) { bhnd_nvram_prop *prop; size_t limit, nbytes; int error; /* Determine output byte limit */ if (outp != NULL) limit = *olen; else limit = 0; nbytes = 0; /* Write all properties */ prop = NULL; while ((prop = bhnd_nvram_plist_next(props, prop)) != NULL) { const char *name; char *p; size_t prop_limit; size_t name_len, value_len; if (outp == NULL || limit < nbytes) { p = NULL; prop_limit = 0; } else { p = ((char *)outp) + nbytes; prop_limit = limit - nbytes; } /* Fetch and write name + '=' to output */ name = bhnd_nvram_prop_name(prop); name_len = strlen(name) + 1; if (prop_limit > name_len) { memcpy(p, name, name_len - 1); p[name_len - 1] = '='; prop_limit -= name_len; p += name_len; } else { prop_limit = 0; p = NULL; } /* Advance byte count */ if (SIZE_MAX - nbytes < name_len) return (EFTYPE); /* would overflow size_t */ nbytes += name_len; /* Attempt to write NUL-terminated value to output */ value_len = prop_limit; error = bhnd_nvram_prop_encode(prop, p, &value_len, BHND_NVRAM_TYPE_STRING); /* If encoding failed for any reason other than ENOMEM (which * we'll detect and report after encoding all properties), * return immediately */ if (error && error != ENOMEM) { BHND_NV_LOG("error serializing %s to required type " "%s: %d\n", name, bhnd_nvram_type_name(BHND_NVRAM_TYPE_STRING), error); return (error); } /* Advance byte count */ if (SIZE_MAX - nbytes < value_len) return (EFTYPE); /* would overflow size_t */ nbytes += value_len; } /* Write terminating '\0' */ if (limit > nbytes) *((char *)outp + nbytes) = '\0'; if (nbytes == SIZE_MAX) return (EFTYPE); /* would overflow size_t */ else nbytes++; /* Provide required length */ *olen = nbytes; if (limit < *olen) { if (outp == NULL) return (0); return (ENOMEM); } return (0); } /** * Initialize @p bcm with the provided NVRAM data mapped by @p src. * * @param bcm A newly allocated data instance. */ static int bhnd_nvram_bcmraw_init(struct bhnd_nvram_bcmraw *bcm, struct bhnd_nvram_io *src) { size_t io_size; size_t capacity, offset; int error; /* Fetch the input image size */ io_size = bhnd_nvram_io_getsize(src); /* Allocate a buffer large enough to hold the NVRAM image, and * an extra EOF-signaling NUL (on the chance it's missing from the * source data) */ if (io_size == SIZE_MAX) return (ENOMEM); capacity = io_size + 1 /* room for extra NUL */; bcm->size = io_size; if ((bcm->data = bhnd_nv_malloc(capacity)) == NULL) return (ENOMEM); /* Copy in the NVRAM image */ if ((error = bhnd_nvram_io_read(src, 0x0, bcm->data, io_size))) return (error); /* Process the buffer */ bcm->count = 0; for (offset = 0; offset < bcm->size; offset++) { char *envp; const char *name, *value; size_t envp_len; size_t name_len, value_len; /* Parse the key=value string */ envp = (char *) (bcm->data + offset); envp_len = strnlen(envp, bcm->size - offset); error = bhnd_nvram_parse_env(envp, envp_len, '=', &name, &name_len, &value, &value_len); if (error) { BHND_NV_LOG("error parsing envp at offset %#zx: %d\n", offset, error); return (error); } /* Insert a '\0' character, replacing the '=' delimiter and * allowing us to vend references directly to the variable * name */ *(envp + name_len) = '\0'; /* Add to variable count */ bcm->count++; /* Seek past the value's terminating '\0' */ offset += envp_len; if (offset == io_size) { BHND_NV_LOG("missing terminating NUL at offset %#zx\n", offset); return (EINVAL); } /* If we hit EOF without finding a terminating NUL * byte, we need to append it */ if (++offset == bcm->size) { BHND_NV_ASSERT(offset < capacity, ("appending past end of buffer")); bcm->size++; *(bcm->data + offset) = '\0'; } /* Check for explicit EOF (encoded as a single empty NUL * terminated string) */ if (*(bcm->data + offset) == '\0') break; } /* Reclaim any unused space in the backing buffer */ if (offset < bcm->size) { bcm->data = bhnd_nv_reallocf(bcm->data, bcm->size); if (bcm->data == NULL) return (ENOMEM); } return (0); } static int bhnd_nvram_bcmraw_new(struct bhnd_nvram_data *nv, struct bhnd_nvram_io *io) { struct bhnd_nvram_bcmraw *bcm; int error; bcm = (struct bhnd_nvram_bcmraw *)nv; /* Parse the BCM input data and initialize our backing * data representation */ if ((error = bhnd_nvram_bcmraw_init(bcm, io))) { bhnd_nvram_bcmraw_free(nv); return (error); } return (0); } static void bhnd_nvram_bcmraw_free(struct bhnd_nvram_data *nv) { struct bhnd_nvram_bcmraw *bcm = (struct bhnd_nvram_bcmraw *)nv; if (bcm->data != NULL) bhnd_nv_free(bcm->data); } static bhnd_nvram_plist * bhnd_nvram_bcmraw_options(struct bhnd_nvram_data *nv) { return (NULL); } static size_t bhnd_nvram_bcmraw_count(struct bhnd_nvram_data *nv) { struct bhnd_nvram_bcmraw *bcm = (struct bhnd_nvram_bcmraw *)nv; return (bcm->count); } static uint32_t bhnd_nvram_bcmraw_caps(struct bhnd_nvram_data *nv) { return (BHND_NVRAM_DATA_CAP_READ_PTR|BHND_NVRAM_DATA_CAP_DEVPATHS); } static const char * bhnd_nvram_bcmraw_next(struct bhnd_nvram_data *nv, void **cookiep) { struct bhnd_nvram_bcmraw *bcm; const char *envp; bcm = (struct bhnd_nvram_bcmraw *)nv; if (*cookiep == NULL) { /* Start at the first NVRAM data record */ envp = bcm->data; } else { /* Seek to next record */ envp = *cookiep; envp += strlen(envp) + 1; /* key + '\0' */ envp += strlen(envp) + 1; /* value + '\0' */ } /* EOF? */ if (*envp == '\0') return (NULL); *cookiep = (void *)(uintptr_t)envp; return (envp); } static void * bhnd_nvram_bcmraw_find(struct bhnd_nvram_data *nv, const char *name) { return (bhnd_nvram_data_generic_find(nv, name)); } static int bhnd_nvram_bcmraw_getvar_order(struct bhnd_nvram_data *nv, void *cookiep1, void *cookiep2) { if (cookiep1 < cookiep2) return (-1); if (cookiep1 > cookiep2) return (1); return (0); } static int bhnd_nvram_bcmraw_getvar(struct bhnd_nvram_data *nv, void *cookiep, void *buf, size_t *len, bhnd_nvram_type type) { return (bhnd_nvram_data_generic_rp_getvar(nv, cookiep, buf, len, type)); } static int bhnd_nvram_bcmraw_copy_val(struct bhnd_nvram_data *nv, void *cookiep, bhnd_nvram_val **value) { return (bhnd_nvram_data_generic_rp_copy_val(nv, cookiep, value)); } static const void * bhnd_nvram_bcmraw_getvar_ptr(struct bhnd_nvram_data *nv, void *cookiep, size_t *len, bhnd_nvram_type *type) { const char *envp; /* Cookie points to key\0value\0 -- get the value address */ envp = cookiep; envp += strlen(envp) + 1; /* key + '\0' */ *len = strlen(envp) + 1; /* value + '\0' */ *type = BHND_NVRAM_TYPE_STRING; return (envp); } static const char * bhnd_nvram_bcmraw_getvar_name(struct bhnd_nvram_data *nv, void *cookiep) { /* Cookie points to key\0value\0 */ return (cookiep); } static int bhnd_nvram_bcmraw_filter_setvar(struct bhnd_nvram_data *nv, const char *name, bhnd_nvram_val *value, bhnd_nvram_val **result) { bhnd_nvram_val *str; int error; /* Name (trimmed of any path prefix) must be valid */ if (!bhnd_nvram_validate_name(bhnd_nvram_trim_path_name(name))) return (EINVAL); /* Value must be bcm-formatted string */ error = bhnd_nvram_val_convert_new(&str, &bhnd_nvram_val_bcm_string_fmt, value, BHND_NVRAM_VAL_DYNAMIC); if (error) return (error); /* Success. Transfer result ownership to the caller. */ *result = str; return (0); } static int bhnd_nvram_bcmraw_filter_unsetvar(struct bhnd_nvram_data *nv, const char *name) { /* We permit deletion of any variable */ return (0); }