/*- * Copyright (c) 2015-2016 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 #include #include #ifdef _KERNEL #include #include #else /* !_KERNEL */ #include #include #include #include #endif /* _KERNEL */ #include "bhnd_nvram_private.h" #include "bhnd_nvram_data_spromvar.h" static int bhnd_sprom_opcode_sort_idx(const void *lhs, const void *rhs); static int bhnd_nvram_opcode_idx_vid_compare(const void *key, const void *rhs); static int bhnd_sprom_opcode_reset(bhnd_sprom_opcode_state *state); static int bhnd_sprom_opcode_set_type(bhnd_sprom_opcode_state *state, bhnd_nvram_type type); static int bhnd_sprom_opcode_set_var(bhnd_sprom_opcode_state *state, size_t vid); static int bhnd_sprom_opcode_clear_var(bhnd_sprom_opcode_state *state); static int bhnd_sprom_opcode_flush_bind(bhnd_sprom_opcode_state *state); static int bhnd_sprom_opcode_read_opval32(bhnd_sprom_opcode_state *state, uint8_t type, uint32_t *opval); static int bhnd_sprom_opcode_step(bhnd_sprom_opcode_state *state, uint8_t *opcode); #define SPROM_OP_BAD(_state, _fmt, ...) \ BHND_NV_LOG("bad encoding at %td: " _fmt, \ (_state)->input - (_state)->layout->bindings, ##__VA_ARGS__) /** * Initialize SPROM opcode evaluation state. * * @param state The opcode state to be initialized. * @param layout The SPROM layout to be parsed by this instance. * * * @retval 0 success * @retval non-zero If initialization fails, a regular unix error code will be * returned. */ int bhnd_sprom_opcode_init(bhnd_sprom_opcode_state *state, const struct bhnd_sprom_layout *layout) { bhnd_sprom_opcode_idx_entry *idx; size_t num_vars, num_idx; int error; idx = NULL; state->layout = layout; state->idx = NULL; state->num_idx = 0; /* Initialize interpretation state */ if ((error = bhnd_sprom_opcode_reset(state))) return (error); /* Allocate and populate our opcode index */ num_idx = state->layout->num_vars; idx = bhnd_nv_calloc(num_idx, sizeof(*idx)); if (idx == NULL) return (ENOMEM); for (num_vars = 0; num_vars < num_idx; num_vars++) { /* Seek to next entry */ if ((error = bhnd_sprom_opcode_next_var(state))) { SPROM_OP_BAD(state, "error reading expected variable " "entry: %d\n", error); bhnd_nv_free(idx); return (error); } /* Record entry state in our index */ error = bhnd_sprom_opcode_init_entry(state, &idx[num_vars]); if (error) { SPROM_OP_BAD(state, "error initializing index for " "entry: %d\n", error); bhnd_nv_free(idx); return (error); } } /* Should have reached end of binding table; next read must return * ENOENT */ if ((error = bhnd_sprom_opcode_next_var(state)) != ENOENT) { BHND_NV_LOG("expected EOF parsing binding table: %d\n", error); bhnd_nv_free(idx); return (ENXIO); } /* Reset interpretation state */ if ((error = bhnd_sprom_opcode_reset(state))) { bhnd_nv_free(idx); return (error); } /* Make index available to opcode state evaluation */ qsort(idx, num_idx, sizeof(idx[0]), bhnd_sprom_opcode_sort_idx); state->idx = idx; state->num_idx = num_idx; return (0); } /** * Reset SPROM opcode evaluation state; future evaluation will be performed * starting at the first opcode. * * @param state The opcode state to be reset. * * @retval 0 success * @retval non-zero If reset fails, a regular unix error code will be returned. */ static int bhnd_sprom_opcode_reset(bhnd_sprom_opcode_state *state) { memset(&state->var, 0, sizeof(state->var)); state->input = state->layout->bindings; state->offset = 0; state->vid = 0; state->var_state = SPROM_OPCODE_VAR_STATE_NONE; bit_set(state->revs, state->layout->rev); return (0); } /** * Free any resources associated with @p state. * * @param state An opcode state previously successfully initialized with * bhnd_sprom_opcode_init(). */ void bhnd_sprom_opcode_fini(bhnd_sprom_opcode_state *state) { bhnd_nv_free(state->idx); } /** * Sort function used to prepare our index for querying; sorts * bhnd_sprom_opcode_idx_entry values by variable ID, ascending. */ static int bhnd_sprom_opcode_sort_idx(const void *lhs, const void *rhs) { const bhnd_sprom_opcode_idx_entry *l, *r; l = lhs; r = rhs; if (l->vid < r->vid) return (-1); if (l->vid > r->vid) return (1); return (0); } /** * Binary search comparison function used by bhnd_sprom_opcode_index_find(); * searches bhnd_sprom_opcode_idx_entry values by variable ID, ascending. */ static int bhnd_nvram_opcode_idx_vid_compare(const void *key, const void *rhs) { const bhnd_sprom_opcode_idx_entry *entry; size_t vid; vid = *(const size_t *)key; entry = rhs; if (vid < entry->vid) return (-1); if (vid > entry->vid) return (1); return (0); } /** * Locate an index entry for the variable with @p name, or NULL if not found. * * @param state The opcode state to be queried. * @param name The name to search for. * * @retval non-NULL If @p name is found, its index entry value will be * returned. * @retval NULL If @p name is not found. */ bhnd_sprom_opcode_idx_entry * bhnd_sprom_opcode_index_find(bhnd_sprom_opcode_state *state, const char *name) { const struct bhnd_nvram_vardefn *var; size_t vid; /* Determine the variable ID for the given name */ if ((var = bhnd_nvram_find_vardefn(name)) == NULL) return (NULL); vid = bhnd_nvram_get_vardefn_id(var); /* Search our index for the variable ID */ return (bsearch(&vid, state->idx, state->num_idx, sizeof(state->idx[0]), bhnd_nvram_opcode_idx_vid_compare)); } /** * Iterate over all index entries in @p state. * * @param state The opcode state to be iterated. * @param[in,out] prev An entry previously returned by * bhnd_sprom_opcode_index_next(), or a NULL value * to begin iteration. * * @return Returns the next index entry name, or NULL if all entries have * been iterated. */ bhnd_sprom_opcode_idx_entry * bhnd_sprom_opcode_index_next(bhnd_sprom_opcode_state *state, bhnd_sprom_opcode_idx_entry *prev) { size_t idxpos; /* Get next index position */ if (prev == NULL) { idxpos = 0; } else { /* Determine current position */ idxpos = (size_t)(prev - state->idx); BHND_NV_ASSERT(idxpos < state->num_idx, ("invalid index %zu", idxpos)); /* Advance to next entry */ idxpos++; } /* Check for EOF */ if (idxpos == state->num_idx) return (NULL); return (&state->idx[idxpos]); } /** * Initialize @p entry with the current variable's opcode state. * * @param state The opcode state to be saved. * @param[out] entry The opcode index entry to be initialized from @p state. * * @retval 0 success * @retval ENXIO if @p state cannot be serialized as an index entry. */ int bhnd_sprom_opcode_init_entry(bhnd_sprom_opcode_state *state, bhnd_sprom_opcode_idx_entry *entry) { size_t opcodes; /* We limit the SPROM index representations to the minimal type widths * capable of covering all known layouts */ /* Save SPROM image offset */ if (state->offset > UINT16_MAX) { SPROM_OP_BAD(state, "cannot index large offset %u\n", state->offset); return (ENXIO); } entry->offset = state->offset; /* Save current variable ID */ if (state->vid > UINT16_MAX) { SPROM_OP_BAD(state, "cannot index large vid %zu\n", state->vid); return (ENXIO); } entry->vid = state->vid; /* Save opcode position */ opcodes = (state->input - state->layout->bindings); if (opcodes > UINT16_MAX) { SPROM_OP_BAD(state, "cannot index large opcode offset " "%zu\n", opcodes); return (ENXIO); } entry->opcodes = opcodes; return (0); } /** * Reset SPROM opcode evaluation state and seek to the @p entry's position. * * @param state The opcode state to be reset. * @param entry The indexed entry to which we'll seek the opcode state. */ int bhnd_sprom_opcode_seek(bhnd_sprom_opcode_state *state, bhnd_sprom_opcode_idx_entry *entry) { int error; BHND_NV_ASSERT(entry->opcodes < state->layout->bindings_size, ("index entry references invalid opcode position")); /* Reset state */ if ((error = bhnd_sprom_opcode_reset(state))) return (error); /* Seek to the indexed sprom opcode offset */ state->input = state->layout->bindings + entry->opcodes; /* Restore the indexed sprom data offset and VID */ state->offset = entry->offset; /* Restore the indexed sprom variable ID */ if ((error = bhnd_sprom_opcode_set_var(state, entry->vid))) return (error); return (0); } /** * Set the current revision range for @p state. This also resets * variable state. * * @param state The opcode state to update * @param start The first revision in the range. * @param end The last revision in the range. * * @retval 0 success * @retval non-zero If updating @p state fails, a regular unix error code will * be returned. */ static inline int bhnd_sprom_opcode_set_revs(bhnd_sprom_opcode_state *state, uint8_t start, uint8_t end) { int error; /* Validate the revision range */ if (start > SPROM_OP_REV_MAX || end > SPROM_OP_REV_MAX || end < start) { SPROM_OP_BAD(state, "invalid revision range: %hhu-%hhu\n", start, end); return (EINVAL); } /* Clear variable state */ if ((error = bhnd_sprom_opcode_clear_var(state))) return (error); /* Reset revision mask */ memset(state->revs, 0x0, sizeof(state->revs)); bit_nset(state->revs, start, end); return (0); } /** * Set the current variable's value mask for @p state. * * @param state The opcode state to update * @param mask The mask to be set * * @retval 0 success * @retval non-zero If updating @p state fails, a regular unix error code will * be returned. */ static inline int bhnd_sprom_opcode_set_mask(bhnd_sprom_opcode_state *state, uint32_t mask) { if (state->var_state != SPROM_OPCODE_VAR_STATE_OPEN) { SPROM_OP_BAD(state, "no open variable definition\n"); return (EINVAL); } state->var.mask = mask; return (0); } /** * Set the current variable's value shift for @p state. * * @param state The opcode state to update * @param shift The shift to be set * * @retval 0 success * @retval non-zero If updating @p state fails, a regular unix error code will * be returned. */ static inline int bhnd_sprom_opcode_set_shift(bhnd_sprom_opcode_state *state, int8_t shift) { if (state->var_state != SPROM_OPCODE_VAR_STATE_OPEN) { SPROM_OP_BAD(state, "no open variable definition\n"); return (EINVAL); } state->var.shift = shift; return (0); } /** * Register a new BIND/BINDN operation with @p state. * * @param state The opcode state to update. * @param count The number of elements to be bound. * @param skip_in The number of input elements to skip after each bind. * @param skip_in_negative If true, the input skip should be subtracted from * the current offset after each bind. If false, the input skip should be * added. * @param skip_out The number of output elements to skip after each bind. * * @retval 0 success * @retval EINVAL if a variable definition is not open. * @retval EINVAL if @p skip_in and @p count would trigger an overflow or * underflow when applied to the current input offset. * @retval ERANGE if @p skip_in would overflow uint32_t when multiplied by * @p count and the scale value. * @retval ERANGE if @p skip_out would overflow uint32_t when multiplied by * @p count and the scale value. * @retval non-zero If updating @p state otherwise fails, a regular unix error * code will be returned. */ static inline int bhnd_sprom_opcode_set_bind(bhnd_sprom_opcode_state *state, uint8_t count, uint8_t skip_in, bool skip_in_negative, uint8_t skip_out) { uint32_t iskip_total; uint32_t iskip_scaled; int error; /* Must have an open variable */ if (state->var_state != SPROM_OPCODE_VAR_STATE_OPEN) { SPROM_OP_BAD(state, "no open variable definition\n"); SPROM_OP_BAD(state, "BIND outside of variable definition\n"); return (EINVAL); } /* Cannot overwite an existing bind definition */ if (state->var.have_bind) { SPROM_OP_BAD(state, "BIND overwrites existing definition\n"); return (EINVAL); } /* Must have a count of at least 1 */ if (count == 0) { SPROM_OP_BAD(state, "BIND with zero count\n"); return (EINVAL); } /* Scale skip_in by the current type width */ iskip_scaled = skip_in; if ((error = bhnd_sprom_opcode_apply_scale(state, &iskip_scaled))) return (error); /* Calculate total input bytes skipped: iskip_scaled * count) */ if (iskip_scaled > 0 && UINT32_MAX / iskip_scaled < count) { SPROM_OP_BAD(state, "skip_in %hhu would overflow", skip_in); return (EINVAL); } iskip_total = iskip_scaled * count; /* Verify that the skip_in value won't under/overflow the current * input offset. */ if (skip_in_negative) { if (iskip_total > state->offset) { SPROM_OP_BAD(state, "skip_in %hhu would underflow " "offset %u\n", skip_in, state->offset); return (EINVAL); } } else { if (UINT32_MAX - iskip_total < state->offset) { SPROM_OP_BAD(state, "skip_in %hhu would overflow " "offset %u\n", skip_in, state->offset); return (EINVAL); } } /* Set the actual count and skip values */ state->var.have_bind = true; state->var.bind.count = count; state->var.bind.skip_in = skip_in; state->var.bind.skip_out = skip_out; state->var.bind.skip_in_negative = skip_in_negative; /* Update total bind count for the current variable */ state->var.bind_total++; return (0); } /** * Apply and clear the current opcode bind state, if any. * * @param state The opcode state to update. * * @retval 0 success * @retval non-zero If updating @p state otherwise fails, a regular unix error * code will be returned. */ static int bhnd_sprom_opcode_flush_bind(bhnd_sprom_opcode_state *state) { int error; uint32_t skip; /* Nothing to do? */ if (state->var_state != SPROM_OPCODE_VAR_STATE_OPEN || !state->var.have_bind) return (0); /* Apply SPROM offset adjustment */ if (state->var.bind.count > 0) { skip = state->var.bind.skip_in * state->var.bind.count; if ((error = bhnd_sprom_opcode_apply_scale(state, &skip))) return (error); if (state->var.bind.skip_in_negative) { state->offset -= skip; } else { state->offset += skip; } } /* Clear bind state */ memset(&state->var.bind, 0, sizeof(state->var.bind)); state->var.have_bind = false; return (0); } /** * Set the current type to @p type, and reset type-specific * stream state. * * @param state The opcode state to update. * @param type The new type. * * @retval 0 success * @retval EINVAL if @p vid is not a valid variable ID. */ static int bhnd_sprom_opcode_set_type(bhnd_sprom_opcode_state *state, bhnd_nvram_type type) { bhnd_nvram_type base_type; size_t width; uint32_t mask; /* Must have an open variable definition */ if (state->var_state != SPROM_OPCODE_VAR_STATE_OPEN) { SPROM_OP_BAD(state, "type set outside variable definition\n"); return (EINVAL); } /* Fetch type width for use as our scale value */ width = bhnd_nvram_type_width(type); if (width == 0) { SPROM_OP_BAD(state, "unsupported variable-width type: %d\n", type); return (EINVAL); } else if (width > UINT32_MAX) { SPROM_OP_BAD(state, "invalid type width %zu for type: %d\n", width, type); return (EINVAL); } /* Determine default mask value for the element type */ base_type = bhnd_nvram_base_type(type); switch (base_type) { case BHND_NVRAM_TYPE_UINT8: case BHND_NVRAM_TYPE_INT8: case BHND_NVRAM_TYPE_CHAR: mask = UINT8_MAX; break; case BHND_NVRAM_TYPE_UINT16: case BHND_NVRAM_TYPE_INT16: mask = UINT16_MAX; break; case BHND_NVRAM_TYPE_UINT32: case BHND_NVRAM_TYPE_INT32: mask = UINT32_MAX; break; case BHND_NVRAM_TYPE_STRING: /* fallthrough (unused by SPROM) */ default: SPROM_OP_BAD(state, "unsupported type: %d\n", type); return (EINVAL); } /* Update state */ state->var.base_type = base_type; state->var.mask = mask; state->var.scale = (uint32_t)width; return (0); } /** * Clear current variable state, if any. * * @param state The opcode state to update. */ static int bhnd_sprom_opcode_clear_var(bhnd_sprom_opcode_state *state) { if (state->var_state == SPROM_OPCODE_VAR_STATE_NONE) return (0); BHND_NV_ASSERT(state->var_state == SPROM_OPCODE_VAR_STATE_DONE, ("incomplete variable definition")); BHND_NV_ASSERT(!state->var.have_bind, ("stale bind state")); memset(&state->var, 0, sizeof(state->var)); state->var_state = SPROM_OPCODE_VAR_STATE_NONE; return (0); } /** * Set the current variable's array element count to @p nelem. * * @param state The opcode state to update. * @param nelem The new array length. * * @retval 0 success * @retval EINVAL if no open variable definition exists. * @retval EINVAL if @p nelem is zero. * @retval ENXIO if @p nelem is greater than one, and the current variable does * not have an array type. * @retval ENXIO if @p nelem exceeds the array length of the NVRAM variable * definition. */ static int bhnd_sprom_opcode_set_nelem(bhnd_sprom_opcode_state *state, uint8_t nelem) { const struct bhnd_nvram_vardefn *var; /* Must have a defined variable */ if (state->var_state != SPROM_OPCODE_VAR_STATE_OPEN) { SPROM_OP_BAD(state, "array length set without open variable " "state"); return (EINVAL); } /* Locate the actual variable definition */ if ((var = bhnd_nvram_get_vardefn(state->vid)) == NULL) { SPROM_OP_BAD(state, "unknown variable ID: %zu\n", state->vid); return (EINVAL); } /* Must be greater than zero */ if (nelem == 0) { SPROM_OP_BAD(state, "invalid nelem: %hhu\n", nelem); return (EINVAL); } /* If the variable is not an array-typed value, the array length * must be 1 */ if (!bhnd_nvram_is_array_type(var->type) && nelem != 1) { SPROM_OP_BAD(state, "nelem %hhu on non-array %zu\n", nelem, state->vid); return (ENXIO); } /* Cannot exceed the variable's defined array length */ if (nelem > var->nelem) { SPROM_OP_BAD(state, "nelem %hhu exceeds %zu length %hhu\n", nelem, state->vid, var->nelem); return (ENXIO); } /* Valid length; update state */ state->var.nelem = nelem; return (0); } /** * Set the current variable ID to @p vid, and reset variable-specific * stream state. * * @param state The opcode state to update. * @param vid The new variable ID. * * @retval 0 success * @retval EINVAL if @p vid is not a valid variable ID. */ static int bhnd_sprom_opcode_set_var(bhnd_sprom_opcode_state *state, size_t vid) { const struct bhnd_nvram_vardefn *var; int error; BHND_NV_ASSERT(state->var_state == SPROM_OPCODE_VAR_STATE_NONE, ("overwrite of open variable definition")); /* Locate the variable definition */ if ((var = bhnd_nvram_get_vardefn(vid)) == NULL) { SPROM_OP_BAD(state, "unknown variable ID: %zu\n", vid); return (EINVAL); } /* Update vid and var state */ state->vid = vid; state->var_state = SPROM_OPCODE_VAR_STATE_OPEN; /* Initialize default variable record values */ memset(&state->var, 0x0, sizeof(state->var)); /* Set initial base type */ if ((error = bhnd_sprom_opcode_set_type(state, var->type))) return (error); /* Set default array length */ if ((error = bhnd_sprom_opcode_set_nelem(state, var->nelem))) return (error); return (0); } /** * Mark the currently open variable definition as complete. * * @param state The opcode state to update. * * @retval 0 success * @retval EINVAL if no incomplete open variable definition exists. */ static int bhnd_sprom_opcode_end_var(bhnd_sprom_opcode_state *state) { if (state->var_state != SPROM_OPCODE_VAR_STATE_OPEN) { SPROM_OP_BAD(state, "no open variable definition\n"); return (EINVAL); } state->var_state = SPROM_OPCODE_VAR_STATE_DONE; return (0); } /** * Apply the current scale to @p value. * * @param state The SPROM opcode state. * @param[in,out] value The value to scale * * @retval 0 success * @retval EINVAL if no open variable definition exists. * @retval EINVAL if applying the current scale would overflow. */ int bhnd_sprom_opcode_apply_scale(bhnd_sprom_opcode_state *state, uint32_t *value) { /* Must have a defined variable (and thus, scale) */ if (state->var_state != SPROM_OPCODE_VAR_STATE_OPEN) { SPROM_OP_BAD(state, "scaled value encoded without open " "variable state"); return (EINVAL); } /* Applying the scale value must not overflow */ if (UINT32_MAX / state->var.scale < *value) { SPROM_OP_BAD(state, "cannot represent %" PRIu32 " * %" PRIu32 "\n", *value, state->var.scale); return (EINVAL); } *value = (*value) * state->var.scale; return (0); } /** * Read a SPROM_OP_DATA_* value from @p opcodes. * * @param state The SPROM opcode state. * @param type The SROM_OP_DATA_* type to be read. * @param opval On success, the 32bit data representation. If @p type is signed, * the value will be appropriately sign extended and may be directly cast to * int32_t. * * @retval 0 success * @retval non-zero If reading the value otherwise fails, a regular unix error * code will be returned. */ static int bhnd_sprom_opcode_read_opval32(bhnd_sprom_opcode_state *state, uint8_t type, uint32_t *opval) { const uint8_t *p; int error; p = state->input; switch (type) { case SPROM_OP_DATA_I8: /* Convert to signed value first, then sign extend */ *opval = (int32_t)(int8_t)(*p); p += 1; break; case SPROM_OP_DATA_U8: *opval = *p; p += 1; break; case SPROM_OP_DATA_U8_SCALED: *opval = *p; if ((error = bhnd_sprom_opcode_apply_scale(state, opval))) return (error); p += 1; break; case SPROM_OP_DATA_U16: *opval = le16dec(p); p += 2; break; case SPROM_OP_DATA_U32: *opval = le32dec(p); p += 4; break; default: SPROM_OP_BAD(state, "unsupported data type: %hhu\n", type); return (EINVAL); } /* Update read address */ state->input = p; return (0); } /** * Return true if our layout revision is currently defined by the SPROM * opcode state. * * This may be used to test whether the current opcode stream state applies * to the layout that we are actually parsing. * * A given opcode stream may cover multiple layout revisions, switching * between them prior to defining a set of variables. */ static inline bool bhnd_sprom_opcode_matches_layout_rev(bhnd_sprom_opcode_state *state) { return (bit_test(state->revs, state->layout->rev)); } /** * When evaluating @p state and @p opcode, rewrite @p opcode based on the * current evaluation state. * * This allows the insertion of implicit opcodes into interpretation of the * opcode stream. * * If @p opcode is rewritten, it should be returned from * bhnd_sprom_opcode_step() instead of the opcode parsed from @p state's opcode * stream. * * If @p opcode remains unmodified, then bhnd_sprom_opcode_step() should * proceed to standard evaluation. */ static int bhnd_sprom_opcode_rewrite_opcode(bhnd_sprom_opcode_state *state, uint8_t *opcode) { uint8_t op; int error; op = SPROM_OPCODE_OP(*opcode); switch (state->var_state) { case SPROM_OPCODE_VAR_STATE_NONE: /* No open variable definition */ return (0); case SPROM_OPCODE_VAR_STATE_OPEN: /* Open variable definition; check for implicit closure. */ /* * If a variable definition contains no explicit bind * instructions prior to closure, we must generate a DO_BIND * instruction with count and skip values of 1. */ if (SPROM_OP_IS_VAR_END(op) && state->var.bind_total == 0) { uint8_t count, skip_in, skip_out; bool skip_in_negative; /* Create bind with skip_in/skip_out of 1, count of 1 */ count = 1; skip_in = 1; skip_out = 1; skip_in_negative = false; error = bhnd_sprom_opcode_set_bind(state, count, skip_in, skip_in_negative, skip_out); if (error) return (error); /* Return DO_BIND */ *opcode = SPROM_OPCODE_DO_BIND | (0 << SPROM_OP_BIND_SKIP_IN_SIGN) | (1 << SPROM_OP_BIND_SKIP_IN_SHIFT) | (1 << SPROM_OP_BIND_SKIP_OUT_SHIFT); return (0); } /* * If a variable is implicitly closed (e.g. by a new variable * definition), we must generate a VAR_END instruction. */ if (SPROM_OP_IS_IMPLICIT_VAR_END(op)) { /* Mark as complete */ if ((error = bhnd_sprom_opcode_end_var(state))) return (error); /* Return VAR_END */ *opcode = SPROM_OPCODE_VAR_END; return (0); } break; case SPROM_OPCODE_VAR_STATE_DONE: /* Previously completed variable definition. Discard variable * state */ return (bhnd_sprom_opcode_clear_var(state)); } /* Nothing to do */ return (0); } /** * Evaluate one opcode from @p state. * * @param state The opcode state to be evaluated. * @param[out] opcode On success, the evaluated opcode * * @retval 0 success * @retval ENOENT if EOF is reached * @retval non-zero if evaluation otherwise fails, a regular unix error * code will be returned. */ static int bhnd_sprom_opcode_step(bhnd_sprom_opcode_state *state, uint8_t *opcode) { int error; while (*state->input != SPROM_OPCODE_EOF) { uint32_t val; uint8_t op, rewrite, immd; /* Fetch opcode */ *opcode = *state->input; op = SPROM_OPCODE_OP(*opcode); immd = SPROM_OPCODE_IMM(*opcode); /* Clear any existing bind state */ if ((error = bhnd_sprom_opcode_flush_bind(state))) return (error); /* Insert local opcode based on current state? */ rewrite = *opcode; if ((error = bhnd_sprom_opcode_rewrite_opcode(state, &rewrite))) return (error); if (rewrite != *opcode) { /* Provide rewritten opcode */ *opcode = rewrite; /* We must keep evaluating until we hit a state * applicable to the SPROM revision we're parsing */ if (!bhnd_sprom_opcode_matches_layout_rev(state)) continue; return (0); } /* Advance input */ state->input++; switch (op) { case SPROM_OPCODE_VAR_IMM: if ((error = bhnd_sprom_opcode_set_var(state, immd))) return (error); break; case SPROM_OPCODE_VAR_REL_IMM: error = bhnd_sprom_opcode_set_var(state, state->vid + immd); if (error) return (error); break; case SPROM_OPCODE_VAR: error = bhnd_sprom_opcode_read_opval32(state, immd, &val); if (error) return (error); if ((error = bhnd_sprom_opcode_set_var(state, val))) return (error); break; case SPROM_OPCODE_VAR_END: if ((error = bhnd_sprom_opcode_end_var(state))) return (error); break; case SPROM_OPCODE_NELEM: immd = *state->input; if ((error = bhnd_sprom_opcode_set_nelem(state, immd))) return (error); state->input++; break; case SPROM_OPCODE_DO_BIND: case SPROM_OPCODE_DO_BINDN: { uint8_t count, skip_in, skip_out; bool skip_in_negative; /* Fetch skip arguments */ skip_in = (immd & SPROM_OP_BIND_SKIP_IN_MASK) >> SPROM_OP_BIND_SKIP_IN_SHIFT; skip_in_negative = ((immd & SPROM_OP_BIND_SKIP_IN_SIGN) != 0); skip_out = (immd & SPROM_OP_BIND_SKIP_OUT_MASK) >> SPROM_OP_BIND_SKIP_OUT_SHIFT; /* Fetch count argument (if any) */ if (op == SPROM_OPCODE_DO_BINDN) { /* Count is provided as trailing U8 */ count = *state->input; state->input++; } else { count = 1; } /* Set BIND state */ error = bhnd_sprom_opcode_set_bind(state, count, skip_in, skip_in_negative, skip_out); if (error) return (error); break; } case SPROM_OPCODE_DO_BINDN_IMM: { uint8_t count, skip_in, skip_out; bool skip_in_negative; /* Implicit skip_in/skip_out of 1, count encoded as immd * value */ count = immd; skip_in = 1; skip_out = 1; skip_in_negative = false; error = bhnd_sprom_opcode_set_bind(state, count, skip_in, skip_in_negative, skip_out); if (error) return (error); break; } case SPROM_OPCODE_REV_IMM: error = bhnd_sprom_opcode_set_revs(state, immd, immd); if (error) return (error); break; case SPROM_OPCODE_REV_RANGE: { uint8_t range; uint8_t rstart, rend; /* Revision range is encoded in next byte, as * { uint8_t start:4, uint8_t end:4 } */ range = *state->input; rstart = (range & SPROM_OP_REV_START_MASK) >> SPROM_OP_REV_START_SHIFT; rend = (range & SPROM_OP_REV_END_MASK) >> SPROM_OP_REV_END_SHIFT; /* Update revision bitmask */ error = bhnd_sprom_opcode_set_revs(state, rstart, rend); if (error) return (error); /* Advance input */ state->input++; break; } case SPROM_OPCODE_MASK_IMM: if ((error = bhnd_sprom_opcode_set_mask(state, immd))) return (error); break; case SPROM_OPCODE_MASK: error = bhnd_sprom_opcode_read_opval32(state, immd, &val); if (error) return (error); if ((error = bhnd_sprom_opcode_set_mask(state, val))) return (error); break; case SPROM_OPCODE_SHIFT_IMM: error = bhnd_sprom_opcode_set_shift(state, immd * 2); if (error) return (error); break; case SPROM_OPCODE_SHIFT: { int8_t shift; if (immd == SPROM_OP_DATA_I8) { shift = (int8_t)(*state->input); } else if (immd == SPROM_OP_DATA_U8) { val = *state->input; if (val > INT8_MAX) { SPROM_OP_BAD(state, "invalid shift " "value: %#x\n", val); } shift = val; } else { SPROM_OP_BAD(state, "unsupported shift data " "type: %#hhx\n", immd); return (EINVAL); } if ((error = bhnd_sprom_opcode_set_shift(state, shift))) return (error); state->input++; break; } case SPROM_OPCODE_OFFSET_REL_IMM: /* Fetch unscaled relative offset */ val = immd; /* Apply scale */ error = bhnd_sprom_opcode_apply_scale(state, &val); if (error) return (error); /* Adding val must not overflow our offset */ if (UINT32_MAX - state->offset < val) { BHND_NV_LOG("offset out of range\n"); return (EINVAL); } /* Adjust offset */ state->offset += val; break; case SPROM_OPCODE_OFFSET: error = bhnd_sprom_opcode_read_opval32(state, immd, &val); if (error) return (error); state->offset = val; break; case SPROM_OPCODE_TYPE: /* Type follows as U8 */ immd = *state->input; state->input++; /* fall through */ case SPROM_OPCODE_TYPE_IMM: switch (immd) { case BHND_NVRAM_TYPE_UINT8: case BHND_NVRAM_TYPE_UINT16: case BHND_NVRAM_TYPE_UINT32: case BHND_NVRAM_TYPE_UINT64: case BHND_NVRAM_TYPE_INT8: case BHND_NVRAM_TYPE_INT16: case BHND_NVRAM_TYPE_INT32: case BHND_NVRAM_TYPE_INT64: case BHND_NVRAM_TYPE_CHAR: case BHND_NVRAM_TYPE_STRING: error = bhnd_sprom_opcode_set_type(state, (bhnd_nvram_type)immd); if (error) return (error); break; default: BHND_NV_LOG("unrecognized type %#hhx\n", immd); return (EINVAL); } break; default: BHND_NV_LOG("unrecognized opcode %#hhx\n", *opcode); return (EINVAL); } /* We must keep evaluating until we hit a state applicable to * the SPROM revision we're parsing */ if (bhnd_sprom_opcode_matches_layout_rev(state)) return (0); } /* End of opcode stream */ return (ENOENT); } /** * Reset SPROM opcode evaluation state, seek to the @p entry's position, * and perform complete evaluation of the variable's opcodes. * * @param state The opcode state to be to be evaluated. * @param entry The indexed variable location. * * @retval 0 success * @retval non-zero If evaluation fails, a regular unix error code will be * returned. */ int bhnd_sprom_opcode_eval_var(bhnd_sprom_opcode_state *state, bhnd_sprom_opcode_idx_entry *entry) { uint8_t opcode; int error; /* Seek to entry */ if ((error = bhnd_sprom_opcode_seek(state, entry))) return (error); /* Parse full variable definition */ while ((error = bhnd_sprom_opcode_step(state, &opcode)) == 0) { /* Iterate until VAR_END */ if (SPROM_OPCODE_OP(opcode) != SPROM_OPCODE_VAR_END) continue; BHND_NV_ASSERT(state->var_state == SPROM_OPCODE_VAR_STATE_DONE, ("incomplete variable definition")); return (0); } /* Error parsing definition */ return (error); } /** * Evaluate @p state until the next variable definition is found. * * @param state The opcode state to be evaluated. * * @retval 0 success * @retval ENOENT if no additional variable definitions are available. * @retval non-zero if evaluation otherwise fails, a regular unix error * code will be returned. */ int bhnd_sprom_opcode_next_var(bhnd_sprom_opcode_state *state) { uint8_t opcode; int error; /* Step until we hit a variable opcode */ while ((error = bhnd_sprom_opcode_step(state, &opcode)) == 0) { switch (SPROM_OPCODE_OP(opcode)) { case SPROM_OPCODE_VAR: case SPROM_OPCODE_VAR_IMM: case SPROM_OPCODE_VAR_REL_IMM: BHND_NV_ASSERT( state->var_state == SPROM_OPCODE_VAR_STATE_OPEN, ("missing variable definition")); return (0); default: continue; } } /* Reached EOF, or evaluation failed */ return (error); } /** * Evaluate @p state until the next binding for the current variable definition * is found. * * @param state The opcode state to be evaluated. * * @retval 0 success * @retval ENOENT if no additional binding opcodes are found prior to reaching * a new variable definition, or the end of @p state's binding opcodes. * @retval non-zero if evaluation otherwise fails, a regular unix error * code will be returned. */ int bhnd_sprom_opcode_next_binding(bhnd_sprom_opcode_state *state) { uint8_t opcode; int error; if (state->var_state != SPROM_OPCODE_VAR_STATE_OPEN) return (EINVAL); /* Step until we hit a bind opcode, or a new variable */ while ((error = bhnd_sprom_opcode_step(state, &opcode)) == 0) { switch (SPROM_OPCODE_OP(opcode)) { case SPROM_OPCODE_DO_BIND: case SPROM_OPCODE_DO_BINDN: case SPROM_OPCODE_DO_BINDN_IMM: /* Found next bind */ BHND_NV_ASSERT( state->var_state == SPROM_OPCODE_VAR_STATE_OPEN, ("missing variable definition")); BHND_NV_ASSERT(state->var.have_bind, ("missing bind")); return (0); case SPROM_OPCODE_VAR_END: /* No further binding opcodes */ BHND_NV_ASSERT( state->var_state == SPROM_OPCODE_VAR_STATE_DONE, ("variable definition still available")); return (ENOENT); } } /* Not found, or evaluation failed */ return (error); }