Author | Tokens | Token Proportion | Commits | Commit Proportion |
---|---|---|---|---|
Sakari Ailus | 4711 | 100.00% | 3 | 100.00% |
Total | 4711 | 3 |
// SPDX-License-Identifier: GPL-2.0 OR BSD-3-Clause /* * CCS static data binary parser library * * Copyright 2019--2020 Intel Corporation */ #include <linux/device.h> #include <linux/errno.h> #include <linux/limits.h> #include <linux/mm.h> #include <linux/slab.h> #include "ccs-data-defs.h" struct bin_container { void *base; void *now; void *end; size_t size; }; static void *bin_alloc(struct bin_container *bin, size_t len) { void *ptr; len = ALIGN(len, 8); if (bin->end - bin->now < len) return NULL; ptr = bin->now; bin->now += len; return ptr; } static void bin_reserve(struct bin_container *bin, size_t len) { bin->size += ALIGN(len, 8); } static int bin_backing_alloc(struct bin_container *bin) { bin->base = bin->now = kvzalloc(bin->size, GFP_KERNEL); if (!bin->base) return -ENOMEM; bin->end = bin->base + bin->size; return 0; } #define is_contained(var, endp) \ (sizeof(*var) <= (endp) - (void *)(var)) #define has_headroom(ptr, headroom, endp) \ ((headroom) <= (endp) - (void *)(ptr)) #define is_contained_with_headroom(var, headroom, endp) \ (sizeof(*var) + (headroom) <= (endp) - (void *)(var)) static int ccs_data_parse_length_specifier(const struct __ccs_data_length_specifier *__len, size_t *__hlen, size_t *__plen, const void *endp) { size_t hlen, plen; if (!is_contained(__len, endp)) return -ENODATA; switch (__len->length >> CCS_DATA_LENGTH_SPECIFIER_SIZE_SHIFT) { case CCS_DATA_LENGTH_SPECIFIER_1: hlen = sizeof(*__len); plen = __len->length & ((1 << CCS_DATA_LENGTH_SPECIFIER_SIZE_SHIFT) - 1); break; case CCS_DATA_LENGTH_SPECIFIER_2: { struct __ccs_data_length_specifier2 *__len2 = (void *)__len; if (!is_contained(__len2, endp)) return -ENODATA; hlen = sizeof(*__len2); plen = ((size_t) (__len2->length[0] & ((1 << CCS_DATA_LENGTH_SPECIFIER_SIZE_SHIFT) - 1)) << 8) + __len2->length[1]; break; } case CCS_DATA_LENGTH_SPECIFIER_3: { struct __ccs_data_length_specifier3 *__len3 = (void *)__len; if (!is_contained(__len3, endp)) return -ENODATA; hlen = sizeof(*__len3); plen = ((size_t) (__len3->length[0] & ((1 << CCS_DATA_LENGTH_SPECIFIER_SIZE_SHIFT) - 1)) << 16) + (__len3->length[0] << 8) + __len3->length[1]; break; } default: return -EINVAL; } if (!has_headroom(__len, hlen + plen, endp)) return -ENODATA; *__hlen = hlen; *__plen = plen; return 0; } static u8 ccs_data_parse_format_version(const struct __ccs_data_block *block) { return block->id >> CCS_DATA_BLOCK_HEADER_ID_VERSION_SHIFT; } static u8 ccs_data_parse_block_id(const struct __ccs_data_block *block, bool is_first) { if (!is_first) return block->id; return block->id & ((1 << CCS_DATA_BLOCK_HEADER_ID_VERSION_SHIFT) - 1); } static int ccs_data_parse_version(struct bin_container *bin, struct ccs_data_container *ccsdata, const void *payload, const void *endp) { const struct __ccs_data_block_version *v = payload; struct ccs_data_block_version *vv; if (v + 1 != endp) return -ENODATA; if (!bin->base) { bin_reserve(bin, sizeof(*ccsdata->version)); return 0; } ccsdata->version = bin_alloc(bin, sizeof(*ccsdata->version)); if (!ccsdata->version) return -ENOMEM; vv = ccsdata->version; vv->version_major = ((u16)v->static_data_version_major[0] << 8) + v->static_data_version_major[1]; vv->version_minor = ((u16)v->static_data_version_minor[0] << 8) + v->static_data_version_minor[1]; vv->date_year = ((u16)v->year[0] << 8) + v->year[1]; vv->date_month = v->month; vv->date_day = v->day; return 0; } static void print_ccs_data_version(struct device *dev, struct ccs_data_block_version *v) { dev_dbg(dev, "static data version %4.4x.%4.4x, date %4.4u-%2.2u-%2.2u\n", v->version_major, v->version_minor, v->date_year, v->date_month, v->date_day); } static int ccs_data_block_parse_header(const struct __ccs_data_block *block, bool is_first, unsigned int *__block_id, const void **payload, const struct __ccs_data_block **next_block, const void *endp, struct device *dev, bool verbose) { size_t plen, hlen; u8 block_id; int rval; if (!is_contained(block, endp)) return -ENODATA; rval = ccs_data_parse_length_specifier(&block->length, &hlen, &plen, endp); if (rval < 0) return rval; block_id = ccs_data_parse_block_id(block, is_first); if (verbose) dev_dbg(dev, "Block ID 0x%2.2x, header length %zu, payload length %zu\n", block_id, hlen, plen); if (!has_headroom(&block->length, hlen + plen, endp)) return -ENODATA; if (__block_id) *__block_id = block_id; if (payload) *payload = (void *)&block->length + hlen; if (next_block) *next_block = (void *)&block->length + hlen + plen; return 0; } static int ccs_data_parse_regs(struct bin_container *bin, struct ccs_reg **__regs, size_t *__num_regs, const void *payload, const void *endp, struct device *dev) { struct ccs_reg *regs_base = NULL, *regs = NULL; size_t num_regs = 0; u16 addr = 0; if (bin->base && __regs) { regs = regs_base = bin_alloc(bin, sizeof(*regs) * *__num_regs); if (!regs) return -ENOMEM; } while (payload < endp && num_regs < INT_MAX) { const struct __ccs_data_block_regs *r = payload; size_t len; const void *data; if (!is_contained(r, endp)) return -ENODATA; switch (r->reg_len >> CCS_DATA_BLOCK_REGS_SEL_SHIFT) { case CCS_DATA_BLOCK_REGS_SEL_REGS: addr += r->reg_len & CCS_DATA_BLOCK_REGS_ADDR_MASK; len = ((r->reg_len & CCS_DATA_BLOCK_REGS_LEN_MASK) >> CCS_DATA_BLOCK_REGS_LEN_SHIFT) + 1; if (!is_contained_with_headroom(r, len, endp)) return -ENODATA; data = r + 1; break; case CCS_DATA_BLOCK_REGS_SEL_REGS2: { const struct __ccs_data_block_regs2 *r2 = payload; if (!is_contained(r2, endp)) return -ENODATA; addr += ((u16)(r2->reg_len & CCS_DATA_BLOCK_REGS_2_ADDR_MASK) << 8) + r2->addr; len = ((r2->reg_len & CCS_DATA_BLOCK_REGS_2_LEN_MASK) >> CCS_DATA_BLOCK_REGS_2_LEN_SHIFT) + 1; if (!is_contained_with_headroom(r2, len, endp)) return -ENODATA; data = r2 + 1; break; } case CCS_DATA_BLOCK_REGS_SEL_REGS3: { const struct __ccs_data_block_regs3 *r3 = payload; if (!is_contained(r3, endp)) return -ENODATA; addr = ((u16)r3->addr[0] << 8) + r3->addr[1]; len = (r3->reg_len & CCS_DATA_BLOCK_REGS_3_LEN_MASK) + 1; if (!is_contained_with_headroom(r3, len, endp)) return -ENODATA; data = r3 + 1; break; } default: return -EINVAL; } num_regs++; if (!bin->base) { bin_reserve(bin, len); } else if (__regs) { if (!regs) return -EIO; regs->addr = addr; regs->len = len; regs->value = bin_alloc(bin, len); if (!regs->value) return -ENOMEM; memcpy(regs->value, data, len); regs++; } addr += len; payload = data + len; } if (!bin->base) bin_reserve(bin, sizeof(*regs) * num_regs); if (__num_regs) *__num_regs = num_regs; if (bin->base && __regs) { if (!regs_base) return -EIO; *__regs = regs_base; } return 0; } static int ccs_data_parse_reg_rules(struct bin_container *bin, struct ccs_reg **__regs, size_t *__num_regs, const void *payload, const void *endp, struct device *dev) { int rval; if (!bin->base) return ccs_data_parse_regs(bin, NULL, NULL, payload, endp, dev); rval = ccs_data_parse_regs(bin, NULL, __num_regs, payload, endp, dev); if (rval) return rval; return ccs_data_parse_regs(bin, __regs, __num_regs, payload, endp, dev); } static void assign_ffd_entry(struct ccs_frame_format_desc *desc, const struct __ccs_data_block_ffd_entry *ent) { desc->pixelcode = ent->pixelcode; desc->value = ((u16)ent->value[0] << 8) + ent->value[1]; } static int ccs_data_parse_ffd(struct bin_container *bin, struct ccs_frame_format_descs **ffd, const void *payload, const void *endp, struct device *dev) { const struct __ccs_data_block_ffd *__ffd = payload; const struct __ccs_data_block_ffd_entry *__entry; unsigned int i; if (!is_contained(__ffd, endp)) return -ENODATA; if ((void *)__ffd + sizeof(*__ffd) + ((u32)__ffd->num_column_descs + (u32)__ffd->num_row_descs) * sizeof(struct __ccs_data_block_ffd_entry) != endp) return -ENODATA; if (!bin->base) { bin_reserve(bin, sizeof(**ffd)); bin_reserve(bin, __ffd->num_column_descs * sizeof(struct ccs_frame_format_desc)); bin_reserve(bin, __ffd->num_row_descs * sizeof(struct ccs_frame_format_desc)); return 0; } *ffd = bin_alloc(bin, sizeof(**ffd)); if (!*ffd) return -ENOMEM; (*ffd)->num_column_descs = __ffd->num_column_descs; (*ffd)->num_row_descs = __ffd->num_row_descs; __entry = (void *)(__ffd + 1); (*ffd)->column_descs = bin_alloc(bin, __ffd->num_column_descs * sizeof(*(*ffd)->column_descs)); if (!(*ffd)->column_descs) return -ENOMEM; for (i = 0; i < __ffd->num_column_descs; i++, __entry++) assign_ffd_entry(&(*ffd)->column_descs[i], __entry); (*ffd)->row_descs = bin_alloc(bin, __ffd->num_row_descs * sizeof(*(*ffd)->row_descs)); if (!(*ffd)->row_descs) return -ENOMEM; for (i = 0; i < __ffd->num_row_descs; i++, __entry++) assign_ffd_entry(&(*ffd)->row_descs[i], __entry); if (__entry != endp) return -EPROTO; return 0; } static int ccs_data_parse_pdaf_readout(struct bin_container *bin, struct ccs_pdaf_readout **pdaf_readout, const void *payload, const void *endp, struct device *dev) { const struct __ccs_data_block_pdaf_readout *__pdaf = payload; if (!is_contained(__pdaf, endp)) return -ENODATA; if (!bin->base) { bin_reserve(bin, sizeof(**pdaf_readout)); } else { *pdaf_readout = bin_alloc(bin, sizeof(**pdaf_readout)); if (!*pdaf_readout) return -ENOMEM; (*pdaf_readout)->pdaf_readout_info_order = __pdaf->pdaf_readout_info_order; } return ccs_data_parse_ffd(bin, !bin->base ? NULL : &(*pdaf_readout)->ffd, __pdaf + 1, endp, dev); } static int ccs_data_parse_rules(struct bin_container *bin, struct ccs_rule **__rules, size_t *__num_rules, const void *payload, const void *endp, struct device *dev) { struct ccs_rule *rules_base = NULL, *rules = NULL, *next_rule = NULL; size_t num_rules = 0; const void *__next_rule = payload; int rval; if (bin->base) { rules_base = next_rule = bin_alloc(bin, sizeof(*rules) * *__num_rules); if (!rules_base) return -ENOMEM; } while (__next_rule < endp) { size_t rule_hlen, rule_plen, rule_plen2; const u8 *__rule_type; const void *rule_payload; /* Size of a single rule */ rval = ccs_data_parse_length_specifier(__next_rule, &rule_hlen, &rule_plen, endp); if (rval < 0) return rval; __rule_type = __next_rule + rule_hlen; if (!is_contained(__rule_type, endp)) return -ENODATA; rule_payload = __rule_type + 1; rule_plen2 = rule_plen - sizeof(*__rule_type); switch (*__rule_type) { case CCS_DATA_BLOCK_RULE_ID_IF: { const struct __ccs_data_block_rule_if *__if_rules = rule_payload; const size_t __num_if_rules = rule_plen2 / sizeof(*__if_rules); struct ccs_if_rule *if_rule; if (!has_headroom(__if_rules, sizeof(*__if_rules) * __num_if_rules, rule_payload + rule_plen2)) return -ENODATA; /* Also check there is no extra data */ if (__if_rules + __num_if_rules != rule_payload + rule_plen2) return -EINVAL; if (!bin->base) { bin_reserve(bin, sizeof(*if_rule) * __num_if_rules); num_rules++; } else { unsigned int i; if (!next_rule) return -EIO; rules = next_rule; next_rule++; if_rule = bin_alloc(bin, sizeof(*if_rule) * __num_if_rules); if (!if_rule) return -ENOMEM; for (i = 0; i < __num_if_rules; i++) { if_rule[i].addr = ((u16)__if_rules[i].addr[0] << 8) + __if_rules[i].addr[1]; if_rule[i].value = __if_rules[i].value; if_rule[i].mask = __if_rules[i].mask; } rules->if_rules = if_rule; rules->num_if_rules = __num_if_rules; } break; } case CCS_DATA_BLOCK_RULE_ID_READ_ONLY_REGS: rval = ccs_data_parse_reg_rules(bin, &rules->read_only_regs, &rules->num_read_only_regs, rule_payload, rule_payload + rule_plen2, dev); if (rval) return rval; break; case CCS_DATA_BLOCK_RULE_ID_FFD: rval = ccs_data_parse_ffd(bin, &rules->frame_format, rule_payload, rule_payload + rule_plen2, dev); if (rval) return rval; break; case CCS_DATA_BLOCK_RULE_ID_MSR: rval = ccs_data_parse_reg_rules(bin, &rules->manufacturer_regs, &rules->num_manufacturer_regs, rule_payload, rule_payload + rule_plen2, dev); if (rval) return rval; break; case CCS_DATA_BLOCK_RULE_ID_PDAF_READOUT: rval = ccs_data_parse_pdaf_readout(bin, &rules->pdaf_readout, rule_payload, rule_payload + rule_plen2, dev); if (rval) return rval; break; default: dev_dbg(dev, "Don't know how to handle rule type %u!\n", *__rule_type); return -EINVAL; } __next_rule = __next_rule + rule_hlen + rule_plen; } if (!bin->base) { bin_reserve(bin, sizeof(*rules) * num_rules); *__num_rules = num_rules; } else { if (!rules_base) return -EIO; *__rules = rules_base; } return 0; } static int ccs_data_parse_pdaf(struct bin_container *bin, struct ccs_pdaf_pix_loc **pdaf, const void *payload, const void *endp, struct device *dev) { const struct __ccs_data_block_pdaf_pix_loc *__pdaf = payload; const struct __ccs_data_block_pdaf_pix_loc_block_desc_group *__bdesc_group; const struct __ccs_data_block_pdaf_pix_loc_pixel_desc *__pixel_desc; unsigned int i; u16 num_block_desc_groups; u8 max_block_type_id = 0; const u8 *__num_pixel_descs; if (!is_contained(__pdaf, endp)) return -ENODATA; if (bin->base) { *pdaf = bin_alloc(bin, sizeof(**pdaf)); if (!*pdaf) return -ENOMEM; } else { bin_reserve(bin, sizeof(**pdaf)); } num_block_desc_groups = ((u16)__pdaf->num_block_desc_groups[0] << 8) + __pdaf->num_block_desc_groups[1]; if (bin->base) { (*pdaf)->main_offset_x = ((u16)__pdaf->main_offset_x[0] << 8) + __pdaf->main_offset_x[1]; (*pdaf)->main_offset_y = ((u16)__pdaf->main_offset_y[0] << 8) + __pdaf->main_offset_y[1]; (*pdaf)->global_pdaf_type = __pdaf->global_pdaf_type; (*pdaf)->block_width = __pdaf->block_width; (*pdaf)->block_height = __pdaf->block_height; (*pdaf)->num_block_desc_groups = num_block_desc_groups; } __bdesc_group = (const void *)(__pdaf + 1); if (bin->base) { (*pdaf)->block_desc_groups = bin_alloc(bin, sizeof(struct ccs_pdaf_pix_loc_block_desc_group) * num_block_desc_groups); if (!(*pdaf)->block_desc_groups) return -ENOMEM; } else { bin_reserve(bin, sizeof(struct ccs_pdaf_pix_loc_block_desc_group) * num_block_desc_groups); } for (i = 0; i < num_block_desc_groups; i++) { const struct __ccs_data_block_pdaf_pix_loc_block_desc *__bdesc; u16 num_block_descs; unsigned int j; if (!is_contained(__bdesc_group, endp)) return -ENODATA; num_block_descs = ((u16)__bdesc_group->num_block_descs[0] << 8) + __bdesc_group->num_block_descs[1]; if (bin->base) { (*pdaf)->block_desc_groups[i].repeat_y = __bdesc_group->repeat_y; (*pdaf)->block_desc_groups[i].num_block_descs = num_block_descs; } __bdesc = (const void *)(__bdesc_group + 1); if (bin->base) { (*pdaf)->block_desc_groups[i].block_descs = bin_alloc(bin, sizeof(struct ccs_pdaf_pix_loc_block_desc) * num_block_descs); if (!(*pdaf)->block_desc_groups[i].block_descs) return -ENOMEM; } else { bin_reserve(bin, sizeof(struct ccs_pdaf_pix_loc_block_desc) * num_block_descs); } for (j = 0; j < num_block_descs; j++, __bdesc++) { struct ccs_pdaf_pix_loc_block_desc *bdesc; if (!is_contained(__bdesc, endp)) return -ENODATA; if (max_block_type_id <= __bdesc->block_type_id) max_block_type_id = __bdesc->block_type_id + 1; if (!bin->base) continue; bdesc = &(*pdaf)->block_desc_groups[i].block_descs[j]; bdesc->repeat_x = ((u16)__bdesc->repeat_x[0] << 8) + __bdesc->repeat_x[1]; if (__bdesc->block_type_id >= num_block_descs) return -EINVAL; bdesc->block_type_id = __bdesc->block_type_id; } __bdesc_group = (const void *)__bdesc; } __num_pixel_descs = (const void *)__bdesc_group; if (bin->base) { (*pdaf)->pixel_desc_groups = bin_alloc(bin, sizeof(struct ccs_pdaf_pix_loc_pixel_desc_group) * max_block_type_id); if (!(*pdaf)->pixel_desc_groups) return -ENOMEM; (*pdaf)->num_pixel_desc_grups = max_block_type_id; } else { bin_reserve(bin, sizeof(struct ccs_pdaf_pix_loc_pixel_desc_group) * max_block_type_id); } for (i = 0; i < max_block_type_id; i++) { struct ccs_pdaf_pix_loc_pixel_desc_group *pdgroup = NULL; unsigned int j; if (!is_contained(__num_pixel_descs, endp)) return -ENODATA; if (bin->base) { pdgroup = &(*pdaf)->pixel_desc_groups[i]; pdgroup->descs = bin_alloc(bin, sizeof(struct ccs_pdaf_pix_loc_pixel_desc) * *__num_pixel_descs); if (!pdgroup->descs) return -ENOMEM; pdgroup->num_descs = *__num_pixel_descs; } else { bin_reserve(bin, sizeof(struct ccs_pdaf_pix_loc_pixel_desc) * *__num_pixel_descs); } __pixel_desc = (const void *)(__num_pixel_descs + 1); for (j = 0; j < *__num_pixel_descs; j++, __pixel_desc++) { struct ccs_pdaf_pix_loc_pixel_desc *pdesc; if (!is_contained(__pixel_desc, endp)) return -ENODATA; if (!bin->base) continue; if (!pdgroup) return -EIO; pdesc = &pdgroup->descs[j]; pdesc->pixel_type = __pixel_desc->pixel_type; pdesc->small_offset_x = __pixel_desc->small_offset_x; pdesc->small_offset_y = __pixel_desc->small_offset_y; } __num_pixel_descs = (const void *)(__pixel_desc + 1); } return 0; } static int ccs_data_parse_license(struct bin_container *bin, char **__license, size_t *__license_length, const void *payload, const void *endp) { size_t size = endp - payload; char *license; if (!bin->base) { bin_reserve(bin, size); return 0; } license = bin_alloc(bin, size); if (!license) return -ENOMEM; memcpy(license, payload, size); *__license = license; *__license_length = size; return 0; } static int ccs_data_parse_end(bool *end, const void *payload, const void *endp, struct device *dev) { const struct __ccs_data_block_end *__end = payload; if (__end + 1 != endp) { dev_dbg(dev, "Invalid end block length %u\n", (unsigned int)(endp - payload)); return -ENODATA; } *end = true; return 0; } static int __ccs_data_parse(struct bin_container *bin, struct ccs_data_container *ccsdata, const void *data, size_t len, struct device *dev, bool verbose) { const struct __ccs_data_block *block = data; const struct __ccs_data_block *endp = data + len; unsigned int version; bool is_first = true; int rval; version = ccs_data_parse_format_version(block); if (version != CCS_STATIC_DATA_VERSION) { dev_dbg(dev, "Don't know how to handle version %u\n", version); return -EINVAL; } if (verbose) dev_dbg(dev, "Parsing CCS static data version %u\n", version); if (!bin->base) *ccsdata = (struct ccs_data_container){ 0 }; while (block < endp) { const struct __ccs_data_block *next_block; unsigned int block_id; const void *payload; rval = ccs_data_block_parse_header(block, is_first, &block_id, &payload, &next_block, endp, dev, bin->base ? false : verbose); if (rval < 0) return rval; switch (block_id) { case CCS_DATA_BLOCK_ID_DUMMY: break; case CCS_DATA_BLOCK_ID_DATA_VERSION: rval = ccs_data_parse_version(bin, ccsdata, payload, next_block); if (rval < 0) return rval; break; case CCS_DATA_BLOCK_ID_SENSOR_READ_ONLY_REGS: rval = ccs_data_parse_regs( bin, &ccsdata->sensor_read_only_regs, &ccsdata->num_sensor_read_only_regs, payload, next_block, dev); if (rval < 0) return rval; break; case CCS_DATA_BLOCK_ID_SENSOR_MANUFACTURER_REGS: rval = ccs_data_parse_regs( bin, &ccsdata->sensor_manufacturer_regs, &ccsdata->num_sensor_manufacturer_regs, payload, next_block, dev); if (rval < 0) return rval; break; case CCS_DATA_BLOCK_ID_MODULE_READ_ONLY_REGS: rval = ccs_data_parse_regs( bin, &ccsdata->module_read_only_regs, &ccsdata->num_module_read_only_regs, payload, next_block, dev); if (rval < 0) return rval; break; case CCS_DATA_BLOCK_ID_MODULE_MANUFACTURER_REGS: rval = ccs_data_parse_regs( bin, &ccsdata->module_manufacturer_regs, &ccsdata->num_module_manufacturer_regs, payload, next_block, dev); if (rval < 0) return rval; break; case CCS_DATA_BLOCK_ID_SENSOR_PDAF_PIXEL_LOCATION: rval = ccs_data_parse_pdaf(bin, &ccsdata->sensor_pdaf, payload, next_block, dev); if (rval < 0) return rval; break; case CCS_DATA_BLOCK_ID_MODULE_PDAF_PIXEL_LOCATION: rval = ccs_data_parse_pdaf(bin, &ccsdata->module_pdaf, payload, next_block, dev); if (rval < 0) return rval; break; case CCS_DATA_BLOCK_ID_SENSOR_RULE_BASED_BLOCK: rval = ccs_data_parse_rules( bin, &ccsdata->sensor_rules, &ccsdata->num_sensor_rules, payload, next_block, dev); if (rval < 0) return rval; break; case CCS_DATA_BLOCK_ID_MODULE_RULE_BASED_BLOCK: rval = ccs_data_parse_rules( bin, &ccsdata->module_rules, &ccsdata->num_module_rules, payload, next_block, dev); if (rval < 0) return rval; break; case CCS_DATA_BLOCK_ID_LICENSE: rval = ccs_data_parse_license(bin, &ccsdata->license, &ccsdata->license_length, payload, next_block); if (rval < 0) return rval; break; case CCS_DATA_BLOCK_ID_END: rval = ccs_data_parse_end(&ccsdata->end, payload, next_block, dev); if (rval < 0) return rval; break; default: dev_dbg(dev, "WARNING: not handling block ID 0x%2.2x\n", block_id); } block = next_block; is_first = false; } return 0; } /** * ccs_data_parse - Parse a CCS static data file into a usable in-memory * data structure * @ccsdata: CCS static data in-memory data structure * @data: CCS static data binary * @len: Length of @data * @dev: Device the data is related to (used for printing debug messages) * @verbose: Whether to be verbose or not */ int ccs_data_parse(struct ccs_data_container *ccsdata, const void *data, size_t len, struct device *dev, bool verbose) { struct bin_container bin = { 0 }; int rval; rval = __ccs_data_parse(&bin, ccsdata, data, len, dev, verbose); if (rval) return rval; rval = bin_backing_alloc(&bin); if (rval) return rval; rval = __ccs_data_parse(&bin, ccsdata, data, len, dev, false); if (rval) goto out_free; if (verbose && ccsdata->version) print_ccs_data_version(dev, ccsdata->version); if (bin.now != bin.end) { rval = -EPROTO; dev_dbg(dev, "parsing mismatch; base %p; now %p; end %p\n", bin.base, bin.now, bin.end); goto out_free; } ccsdata->backing = bin.base; return 0; out_free: kvfree(bin.base); return rval; }
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