ufdt_convert.c - platform/system/libufdt - Git at Google

 /*
  * Copyright (C) 2016 The Android Open Source Project
  *
  * 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.
  */

 #include "libufdt.h"

 #include "ufdt_node_pool.h"
 #include "ufdt_prop_dict.h"

 struct ufdt *ufdt_construct(void *fdtp, struct ufdt_node_pool *pool) {
   (void)(pool); /* unused parameter */

   /* Inital size is 2, will be exponentially increased when it needed later.
      (2 -> 4 -> 8 -> ...) */
   const int DEFAULT_MEM_SIZE_FDTPS = 2;

   void **fdtps = NULL;
   struct ufdt *res_ufdt = NULL;

   fdtps = (void **)dto_malloc(sizeof(void *) * DEFAULT_MEM_SIZE_FDTPS);
   if (fdtps == NULL) goto error;
   fdtps[0] = fdtp;

   res_ufdt = dto_malloc(sizeof(struct ufdt));
   if (res_ufdt == NULL) goto error;

   res_ufdt->fdtps = fdtps;
   res_ufdt->mem_size_fdtps = DEFAULT_MEM_SIZE_FDTPS;
   res_ufdt->num_used_fdtps = (fdtp != NULL ? 1 : 0);
   res_ufdt->root = NULL;

   return res_ufdt;

 error:
   if (res_ufdt) dto_free(res_ufdt);
   if (fdtps) dto_free(fdtps);

   return NULL;
 }

 void ufdt_destruct(struct ufdt *tree, struct ufdt_node_pool *pool) {
   if (tree == NULL) return;

   ufdt_node_destruct(tree->root, pool);

   dto_free(tree->fdtps);
   dto_free(tree->phandle_table.data);
   dto_free(tree);
 }

 int ufdt_add_fdt(struct ufdt *tree, void *fdtp) {
   if (fdtp == NULL) {
     return -1;
   }

   int i = tree->num_used_fdtps;
   if (i >= tree->mem_size_fdtps) {
     int new_size = tree->mem_size_fdtps * 2;
     void **new_fdtps = dto_malloc(sizeof(void *) * new_size);
     if (new_fdtps == NULL) return -1;

     dto_memcpy(new_fdtps, tree->fdtps, sizeof(void *) * tree->mem_size_fdtps);
     dto_free(tree->fdtps);

     tree->fdtps = new_fdtps;
     tree->mem_size_fdtps = new_size;
   }

   tree->fdtps[i] = fdtp;
   tree->num_used_fdtps = i + 1;

   return 0;
 }

 int ufdt_get_string_off(const struct ufdt *tree, const char *s) {
   /* fdt_create() sets the dt_string_off to the end of fdt buffer,
      and _ufdt_output_strtab_to_fdt() copy all string tables in reversed order.
      So, here the return offset value is base on the end of all string buffers,
      and it should be a minus value. */
   int res_off = 0;
   for (int i = 0; i < tree->num_used_fdtps; i++) {
     void *fdt = tree->fdtps[i];
     const char *strtab_start = (const char *)fdt + fdt_off_dt_strings(fdt);
     int strtab_size = fdt_size_dt_strings(fdt);
     const char *strtab_end = strtab_start + strtab_size;

     /* Check if the string is in the string table */
     if (s >= strtab_start && s < strtab_end) {
       res_off += (s - strtab_end);
       return res_off;
     }

     res_off -= strtab_size;
   }
   /* Can not find the string, return 0 */
   return 0;
 }

 static struct ufdt_node *ufdt_new_node(void *fdtp, int node_offset,
                                        struct ufdt_node_pool *pool) {
   if (fdtp == NULL) {
     dto_error("Failed to get new_node because tree is NULL\n");
     return NULL;
   }

   fdt32_t *fdt_tag_ptr =
       (fdt32_t *)fdt_offset_ptr(fdtp, node_offset, sizeof(fdt32_t));
   struct ufdt_node *res = ufdt_node_construct(fdtp, fdt_tag_ptr, pool);
   return res;
 }

 static struct ufdt_node *fdt_to_ufdt_tree(void *fdtp, int cur_fdt_tag_offset,
                                           int *next_fdt_tag_offset, int cur_tag,
                                           struct ufdt_node_pool *pool) {
   if (fdtp == NULL) {
     return NULL;
   }
   uint32_t tag;
   struct ufdt_node *res, *child_node;

   res = NULL;
   child_node = NULL;
   tag = cur_tag;

   switch (tag) {
     case FDT_END_NODE:
     case FDT_NOP:
     case FDT_END:
       break;

     case FDT_PROP:
       res = ufdt_new_node(fdtp, cur_fdt_tag_offset, pool);
       break;

     case FDT_BEGIN_NODE:
       res = ufdt_new_node(fdtp, cur_fdt_tag_offset, pool);

       do {
         cur_fdt_tag_offset = *next_fdt_tag_offset;
         tag = fdt_next_tag(fdtp, cur_fdt_tag_offset, next_fdt_tag_offset);
         child_node = fdt_to_ufdt_tree(fdtp, cur_fdt_tag_offset,
                                       next_fdt_tag_offset, tag, pool);
         ufdt_node_add_child(res, child_node);
       } while (tag != FDT_END_NODE);
       break;

     default:
       break;
   }

   return res;
 }

 void ufdt_print(struct ufdt *tree) {
   ufdt_node_print(tree->root, 0);
 }

 struct ufdt_node *ufdt_get_node_by_path_len(struct ufdt *tree, const char *path,
                                             int len) {
   /*
    * RARE: aliases
    * In device tree, we can assign some alias to specific nodes by defining
    * these relation in "/aliases" node.
    * The node has the form:
    * {
    *   a = "/a_for_apple";
    *   b = "/b_for_banana";
    * };
    * So the path "a/subnode_1" should be expanded to "/a_for_apple/subnode_1".
    */
   if (*path != '/') {
     const char *end = path + len;

     const char *next_slash;
     next_slash = dto_memchr(path, '/', end - path);
     if (!next_slash) next_slash = end;

     struct ufdt_node *aliases_node =
         ufdt_node_get_node_by_path(tree->root, "/aliases");
     aliases_node = ufdt_node_get_property_by_name_len(aliases_node, path,
                                                       next_slash - path);

     int path_len = 0;
     const char *alias_path =
         ufdt_node_get_fdt_prop_data(aliases_node, &path_len);

     if (alias_path == NULL) {
       dto_error("Failed to find alias %s\n", path);
       return NULL;
     }

     struct ufdt_node *target_node =
         ufdt_node_get_node_by_path_len(tree->root, alias_path, path_len);

     return ufdt_node_get_node_by_path_len(target_node, next_slash,
                                           end - next_slash);
   }
   return ufdt_node_get_node_by_path_len(tree->root, path, len);
 }

 struct ufdt_node *ufdt_get_node_by_path(struct ufdt *tree, const char *path) {
   return ufdt_get_node_by_path_len(tree, path, dto_strlen(path));
 }

 struct ufdt_node *ufdt_get_node_by_phandle(struct ufdt *tree,
                                            uint32_t phandle) {
   struct ufdt_node *res = NULL;
   /*
    * Do binary search in phandle_table.data.
    * [s, e) means the possible range which contains target node.
    */
   int s = 0, e = tree->phandle_table.len;
   while (e - s > 1) {
     int mid = s + ((e - s) >> 1);
     uint32_t mid_phandle = tree->phandle_table.data[mid].phandle;
     if (phandle < mid_phandle)
       e = mid;
     else
       s = mid;
   }
   if (e - s > 0 && tree->phandle_table.data[s].phandle == phandle) {
     res = tree->phandle_table.data[s].node;
   }
   return res;
 }

 static int count_phandle_node(struct ufdt_node *node) {
   if (node == NULL) return 0;
   if (ufdt_node_tag(node) != FDT_BEGIN_NODE) return 0;
   int res = 0;
   if (ufdt_node_get_phandle(node) > 0) res++;
   struct ufdt_node **it;
   for_each_child(it, node) { res += count_phandle_node(*it); }
   return res;
 }

 static void set_phandle_table_entry(struct ufdt_node *node,
                                     struct ufdt_phandle_table_entry *data,
                                     int *cur) {
   if (node == NULL || ufdt_node_tag(node) != FDT_BEGIN_NODE) return;
   int ph = ufdt_node_get_phandle(node);
   if (ph > 0) {
     data[*cur].phandle = ph;
     data[*cur].node = node;
     (*cur)++;
   }
   struct ufdt_node **it;
   for_each_node(it, node) set_phandle_table_entry(*it, data, cur);
   return;
 }

 int phandle_table_entry_cmp(const void *pa, const void *pb) {
   uint32_t ph_a = ((const struct ufdt_phandle_table_entry *)pa)->phandle;
   uint32_t ph_b = ((const struct ufdt_phandle_table_entry *)pb)->phandle;
   if (ph_a < ph_b)
     return -1;
   else if (ph_a == ph_b)
     return 0;
   else
     return 1;
 }

 struct ufdt_static_phandle_table build_phandle_table(struct ufdt *tree) {
   struct ufdt_static_phandle_table res;
   res.len = count_phandle_node(tree->root);
   res.data = dto_malloc(sizeof(struct ufdt_phandle_table_entry) * res.len);
   int cur = 0;
   set_phandle_table_entry(tree->root, res.data, &cur);
   dto_qsort(res.data, res.len, sizeof(struct ufdt_phandle_table_entry),
             phandle_table_entry_cmp);
   return res;
 }

 struct ufdt *ufdt_from_fdt(void *fdtp, size_t fdt_size,
                            struct ufdt_node_pool *pool) {
   (void)(fdt_size); /* unused parameter */

   int start_offset = fdt_path_offset(fdtp, "/");
   if (start_offset < 0) {
     return ufdt_construct(NULL, pool);
   }

   struct ufdt *res_tree = ufdt_construct(fdtp, pool);
   int end_offset;
   int start_tag = fdt_next_tag(fdtp, start_offset, &end_offset);
   res_tree->root =
       fdt_to_ufdt_tree(fdtp, start_offset, &end_offset, start_tag, pool);

   res_tree->phandle_table = build_phandle_table(res_tree);

   return res_tree;
 }

 static int _ufdt_get_property_nameoff(const struct ufdt *tree, const char *name,
                                       const struct ufdt_prop_dict *dict) {
   int res;
   const struct fdt_property *same_name_prop = ufdt_prop_dict_find(dict, name);
   if (same_name_prop != NULL) {
     /* There is a property with same name, just use its string offset */
     res = fdt32_to_cpu(same_name_prop->nameoff);
   } else {
     /* Get the string offset from the string table of the current tree */
     res = ufdt_get_string_off(tree, name);
     if (res == 0) {
       dto_error("Cannot find property name in string table: %s\n", name);
       return 0;
     }
   }
   return res;
 }

 static int _ufdt_output_property_to_fdt(
     const struct ufdt *tree, void *fdtp,
     const struct ufdt_node_fdt_prop *prop_node, struct ufdt_prop_dict *dict) {
   int nameoff = _ufdt_get_property_nameoff(tree, prop_node->name, dict);
   if (nameoff == 0) return -1;

   int data_len = 0;
   void *data = ufdt_node_get_fdt_prop_data(&prop_node->parent, &data_len);
   int aligned_data_len = (data_len + (FDT_TAGSIZE - 1)) & ~(FDT_TAGSIZE - 1);

   int new_propoff = fdt_size_dt_struct(fdtp);
   int new_prop_size = sizeof(struct fdt_property) + aligned_data_len;
   struct fdt_property *new_prop =
       (struct fdt_property *)((char *)fdtp + fdt_off_dt_struct(fdtp) +
                               new_propoff);
   char *fdt_end = (char *)fdtp + fdt_totalsize(fdtp);
   if ((char *)new_prop + new_prop_size > fdt_end) {
     dto_error("Not enough space for adding property.\n");
     return -1;
   }
   fdt_set_size_dt_struct(fdtp, new_propoff + new_prop_size);

   new_prop->tag = cpu_to_fdt32(FDT_PROP);
   new_prop->nameoff = cpu_to_fdt32(nameoff);
   new_prop->len = cpu_to_fdt32(data_len);
   dto_memcpy(new_prop->data, data, data_len);

   ufdt_prop_dict_add(dict, new_prop);

   return 0;
 }

 static int _ufdt_output_node_to_fdt(const struct ufdt *tree, void *fdtp,
                                     const struct ufdt_node *node,
                                     struct ufdt_prop_dict *dict) {
   uint32_t tag = ufdt_node_tag(node);

   if (tag == FDT_PROP) {
     return _ufdt_output_property_to_fdt(
         tree, fdtp, (const struct ufdt_node_fdt_prop *)node, dict);
   }

   int err = fdt_begin_node(fdtp, ufdt_node_name(node));
   if (err < 0) return -1;

   struct ufdt_node **it;
   for_each_prop(it, node) {
     err = _ufdt_output_node_to_fdt(tree, fdtp, *it, dict);
     if (err < 0) return -1;
   }

   for_each_node(it, node) {
     err = _ufdt_output_node_to_fdt(tree, fdtp, *it, dict);
     if (err < 0) return -1;
   }

   err = fdt_end_node(fdtp);
   if (err < 0) return -1;

   return 0;
 }

 static int _ufdt_output_strtab_to_fdt(const struct ufdt *tree, void *fdt) {
   /* Currently, we don't know the final dt_struct size, so we copy all
      string tables to the end of the target fdt buffer in reversed order.
      At last, fdt_finish() will adjust dt_string offset */
   const char *struct_top =
       (char *)fdt + fdt_off_dt_struct(fdt) + fdt_size_dt_struct(fdt);
   char *dest = (char *)fdt + fdt_totalsize(fdt);

   int dest_size = 0;
   for (int i = 0; i < tree->num_used_fdtps; i++) {
     void *src_fdt = tree->fdtps[i];
     const char *src_strtab = (const char *)src_fdt + fdt_off_dt_strings(src_fdt);
     int strtab_size = fdt_size_dt_strings(src_fdt);

     dest -= strtab_size;
     if (dest < struct_top) {
       dto_error("Not enough space for string table.\n");
       return -1;
     }

     dto_memcpy(dest, src_strtab, strtab_size);

     dest_size += strtab_size;
   }

   fdt_set_size_dt_strings(fdt, dest_size);

   return 0;
 }

 int ufdt_to_fdt(const struct ufdt *tree, void *buf, int buf_size) {
   if (tree->num_used_fdtps == 0) return -1;

   int err;
   err = fdt_create(buf, buf_size);
   if (err < 0) return -1;

   /* Here we output the memory reserve map of the ONLY FIRST fdt,
      to be in compliance with the DTO behavior of libfdt. */
   int n_mem_rsv = fdt_num_mem_rsv(tree->fdtps[0]);
   for (int i = 0; i < n_mem_rsv; i++) {
     uint64_t addr, size;
     fdt_get_mem_rsv(tree->fdtps[0], i, &addr, &size);
     fdt_add_reservemap_entry(buf, addr, size);
   }

   err = fdt_finish_reservemap(buf);
   if (err < 0) return -1;

   err = _ufdt_output_strtab_to_fdt(tree, buf);
   if (err < 0) return -1;

   struct ufdt_prop_dict dict;
   err = ufdt_prop_dict_construct(&dict, buf);
   if (err < 0) return -1;

   err = _ufdt_output_node_to_fdt(tree, buf, tree->root, &dict);
   if (err < 0) return -1;

   ufdt_prop_dict_destruct(&dict);

   err = fdt_finish(buf);
   if (err < 0) return -1;

   /*
    * IMPORTANT: fdt_totalsize(buf) might be less than buf_size
    * so this is needed to make use of remain spaces.
    */
   return fdt_open_into(buf, buf, buf_size);
 }
	/*
	* Copyright (C) 2016 The Android Open Source Project
	*
	* 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.
	*/

	#include "libufdt.h"

	#include "ufdt_node_pool.h"
	#include "ufdt_prop_dict.h"

	struct ufdt ufdt_construct(void fdtp, struct ufdt_node_pool *pool) {
	(void)(pool); /* unused parameter */

	/* Inital size is 2, will be exponentially increased when it needed later.
	(2 -> 4 -> 8 -> ...) */
	const int DEFAULT_MEM_SIZE_FDTPS = 2;

	void **fdtps = NULL;
	struct ufdt *res_ufdt = NULL;

	fdtps = (void *)dto_malloc(sizeof(void ) * DEFAULT_MEM_SIZE_FDTPS);
	if (fdtps == NULL) goto error;
	fdtps[0] = fdtp;

	res_ufdt = dto_malloc(sizeof(struct ufdt));
	if (res_ufdt == NULL) goto error;

	res_ufdt->fdtps = fdtps;
	res_ufdt->mem_size_fdtps = DEFAULT_MEM_SIZE_FDTPS;
	res_ufdt->num_used_fdtps = (fdtp != NULL ? 1 : 0);
	res_ufdt->root = NULL;

	return res_ufdt;

	error:
	if (res_ufdt) dto_free(res_ufdt);
	if (fdtps) dto_free(fdtps);

	return NULL;
	}

	void ufdt_destruct(struct ufdt tree, struct ufdt_node_pool pool) {
	if (tree == NULL) return;

	ufdt_node_destruct(tree->root, pool);

	dto_free(tree->fdtps);
	dto_free(tree->phandle_table.data);
	dto_free(tree);
	}

	int ufdt_add_fdt(struct ufdt tree, void fdtp) {
	if (fdtp == NULL) {
	return -1;
	}

	int i = tree->num_used_fdtps;
	if (i >= tree->mem_size_fdtps) {
	int new_size = tree->mem_size_fdtps * 2;
	void *new_fdtps = dto_malloc(sizeof(void ) * new_size);
	if (new_fdtps == NULL) return -1;

	dto_memcpy(new_fdtps, tree->fdtps, sizeof(void ) tree->mem_size_fdtps);
	dto_free(tree->fdtps);

	tree->fdtps = new_fdtps;
	tree->mem_size_fdtps = new_size;
	}

	tree->fdtps[i] = fdtp;
	tree->num_used_fdtps = i + 1;

	return 0;
	}

	int ufdt_get_string_off(const struct ufdt tree, const char s) {
	/* fdt_create() sets the dt_string_off to the end of fdt buffer,
	and _ufdt_output_strtab_to_fdt() copy all string tables in reversed order.
	So, here the return offset value is base on the end of all string buffers,
	and it should be a minus value. */
	int res_off = 0;
	for (int i = 0; i < tree->num_used_fdtps; i++) {
	void *fdt = tree->fdtps[i];
	const char strtab_start = (const char )fdt + fdt_off_dt_strings(fdt);
	int strtab_size = fdt_size_dt_strings(fdt);
	const char *strtab_end = strtab_start + strtab_size;

	/* Check if the string is in the string table */
	if (s >= strtab_start && s < strtab_end) {
	res_off += (s - strtab_end);
	return res_off;
	}

	res_off -= strtab_size;
	}
	/* Can not find the string, return 0 */
	return 0;
	}

	static struct ufdt_node ufdt_new_node(void fdtp, int node_offset,
	struct ufdt_node_pool *pool) {
	if (fdtp == NULL) {
	dto_error("Failed to get new_node because tree is NULL\n");
	return NULL;
	}

	fdt32_t *fdt_tag_ptr =
	(fdt32_t *)fdt_offset_ptr(fdtp, node_offset, sizeof(fdt32_t));
	struct ufdt_node *res = ufdt_node_construct(fdtp, fdt_tag_ptr, pool);
	return res;
	}

	static struct ufdt_node fdt_to_ufdt_tree(void fdtp, int cur_fdt_tag_offset,
	int *next_fdt_tag_offset, int cur_tag,
	struct ufdt_node_pool *pool) {
	if (fdtp == NULL) {
	return NULL;
	}
	uint32_t tag;
	struct ufdt_node res, child_node;

	res = NULL;
	child_node = NULL;
	tag = cur_tag;

	switch (tag) {
	case FDT_END_NODE:
	case FDT_NOP:
	case FDT_END:
	break;

	case FDT_PROP:
	res = ufdt_new_node(fdtp, cur_fdt_tag_offset, pool);
	break;

	case FDT_BEGIN_NODE:
	res = ufdt_new_node(fdtp, cur_fdt_tag_offset, pool);

	do {
	cur_fdt_tag_offset = *next_fdt_tag_offset;
	tag = fdt_next_tag(fdtp, cur_fdt_tag_offset, next_fdt_tag_offset);
	child_node = fdt_to_ufdt_tree(fdtp, cur_fdt_tag_offset,
	next_fdt_tag_offset, tag, pool);
	ufdt_node_add_child(res, child_node);
	} while (tag != FDT_END_NODE);
	break;

	default:
	break;
	}

	return res;
	}

	void ufdt_print(struct ufdt *tree) {
	ufdt_node_print(tree->root, 0);
	}

	struct ufdt_node ufdt_get_node_by_path_len(struct ufdt tree, const char *path,
	int len) {
	/*
	* RARE: aliases
	* In device tree, we can assign some alias to specific nodes by defining
	* these relation in "/aliases" node.
	* The node has the form:
	* {
	* a = "/a_for_apple";
	* b = "/b_for_banana";
	* };
	* So the path "a/subnode_1" should be expanded to "/a_for_apple/subnode_1".
	*/
	if (*path != '/') {
	const char *end = path + len;

	const char *next_slash;
	next_slash = dto_memchr(path, '/', end - path);
	if (!next_slash) next_slash = end;

	struct ufdt_node *aliases_node =
	ufdt_node_get_node_by_path(tree->root, "/aliases");
	aliases_node = ufdt_node_get_property_by_name_len(aliases_node, path,
	next_slash - path);

	int path_len = 0;
	const char *alias_path =
	ufdt_node_get_fdt_prop_data(aliases_node, &path_len);

	if (alias_path == NULL) {
	dto_error("Failed to find alias %s\n", path);
	return NULL;
	}

	struct ufdt_node *target_node =
	ufdt_node_get_node_by_path_len(tree->root, alias_path, path_len);

	return ufdt_node_get_node_by_path_len(target_node, next_slash,
	end - next_slash);
	}
	return ufdt_node_get_node_by_path_len(tree->root, path, len);
	}

	struct ufdt_node ufdt_get_node_by_path(struct ufdt tree, const char *path) {
	return ufdt_get_node_by_path_len(tree, path, dto_strlen(path));
	}

	struct ufdt_node ufdt_get_node_by_phandle(struct ufdt tree,
	uint32_t phandle) {
	struct ufdt_node *res = NULL;
	/*
	* Do binary search in phandle_table.data.
	* [s, e) means the possible range which contains target node.
	*/
	int s = 0, e = tree->phandle_table.len;
	while (e - s > 1) {
	int mid = s + ((e - s) >> 1);
	uint32_t mid_phandle = tree->phandle_table.data[mid].phandle;
	if (phandle < mid_phandle)
	e = mid;
	else
	s = mid;
	}
	if (e - s > 0 && tree->phandle_table.data[s].phandle == phandle) {
	res = tree->phandle_table.data[s].node;
	}
	return res;
	}

	static int count_phandle_node(struct ufdt_node *node) {
	if (node == NULL) return 0;
	if (ufdt_node_tag(node) != FDT_BEGIN_NODE) return 0;
	int res = 0;
	if (ufdt_node_get_phandle(node) > 0) res++;
	struct ufdt_node **it;
	for_each_child(it, node) { res += count_phandle_node(*it); }
	return res;
	}

	static void set_phandle_table_entry(struct ufdt_node *node,
	struct ufdt_phandle_table_entry *data,
	int *cur) {
	if (node == NULL \|\| ufdt_node_tag(node) != FDT_BEGIN_NODE) return;
	int ph = ufdt_node_get_phandle(node);
	if (ph > 0) {
	data[*cur].phandle = ph;
	data[*cur].node = node;
	(*cur)++;
	}
	struct ufdt_node **it;
	for_each_node(it, node) set_phandle_table_entry(*it, data, cur);
	return;
	}

	int phandle_table_entry_cmp(const void pa, const void pb) {
	uint32_t ph_a = ((const struct ufdt_phandle_table_entry *)pa)->phandle;
	uint32_t ph_b = ((const struct ufdt_phandle_table_entry *)pb)->phandle;
	if (ph_a < ph_b)
	return -1;
	else if (ph_a == ph_b)
	return 0;
	else
	return 1;
	}

	struct ufdt_static_phandle_table build_phandle_table(struct ufdt *tree) {
	struct ufdt_static_phandle_table res;
	res.len = count_phandle_node(tree->root);
	res.data = dto_malloc(sizeof(struct ufdt_phandle_table_entry) * res.len);
	int cur = 0;
	set_phandle_table_entry(tree->root, res.data, &cur);
	dto_qsort(res.data, res.len, sizeof(struct ufdt_phandle_table_entry),
	phandle_table_entry_cmp);
	return res;
	}

	struct ufdt ufdt_from_fdt(void fdtp, size_t fdt_size,
	struct ufdt_node_pool *pool) {
	(void)(fdt_size); /* unused parameter */

	int start_offset = fdt_path_offset(fdtp, "/");
	if (start_offset < 0) {
	return ufdt_construct(NULL, pool);
	}

	struct ufdt *res_tree = ufdt_construct(fdtp, pool);
	int end_offset;
	int start_tag = fdt_next_tag(fdtp, start_offset, &end_offset);
	res_tree->root =
	fdt_to_ufdt_tree(fdtp, start_offset, &end_offset, start_tag, pool);

	res_tree->phandle_table = build_phandle_table(res_tree);

	return res_tree;
	}

	static int _ufdt_get_property_nameoff(const struct ufdt tree, const char name,
	const struct ufdt_prop_dict *dict) {
	int res;
	const struct fdt_property *same_name_prop = ufdt_prop_dict_find(dict, name);
	if (same_name_prop != NULL) {
	/* There is a property with same name, just use its string offset */
	res = fdt32_to_cpu(same_name_prop->nameoff);
	} else {
	/* Get the string offset from the string table of the current tree */
	res = ufdt_get_string_off(tree, name);
	if (res == 0) {
	dto_error("Cannot find property name in string table: %s\n", name);
	return 0;
	}
	}
	return res;
	}

	static int _ufdt_output_property_to_fdt(
	const struct ufdt tree, void fdtp,
	const struct ufdt_node_fdt_prop prop_node, struct ufdt_prop_dict dict) {
	int nameoff = _ufdt_get_property_nameoff(tree, prop_node->name, dict);
	if (nameoff == 0) return -1;

	int data_len = 0;
	void *data = ufdt_node_get_fdt_prop_data(&prop_node->parent, &data_len);
	int aligned_data_len = (data_len + (FDT_TAGSIZE - 1)) & ~(FDT_TAGSIZE - 1);

	int new_propoff = fdt_size_dt_struct(fdtp);
	int new_prop_size = sizeof(struct fdt_property) + aligned_data_len;
	struct fdt_property *new_prop =
	(struct fdt_property )((char )fdtp + fdt_off_dt_struct(fdtp) +
	new_propoff);
	char fdt_end = (char )fdtp + fdt_totalsize(fdtp);
	if ((char *)new_prop + new_prop_size > fdt_end) {
	dto_error("Not enough space for adding property.\n");
	return -1;
	}
	fdt_set_size_dt_struct(fdtp, new_propoff + new_prop_size);

	new_prop->tag = cpu_to_fdt32(FDT_PROP);
	new_prop->nameoff = cpu_to_fdt32(nameoff);
	new_prop->len = cpu_to_fdt32(data_len);
	dto_memcpy(new_prop->data, data, data_len);

	ufdt_prop_dict_add(dict, new_prop);

	return 0;
	}

	static int _ufdt_output_node_to_fdt(const struct ufdt tree, void fdtp,
	const struct ufdt_node *node,
	struct ufdt_prop_dict *dict) {
	uint32_t tag = ufdt_node_tag(node);

	if (tag == FDT_PROP) {
	return _ufdt_output_property_to_fdt(
	tree, fdtp, (const struct ufdt_node_fdt_prop *)node, dict);
	}

	int err = fdt_begin_node(fdtp, ufdt_node_name(node));
	if (err < 0) return -1;

	struct ufdt_node **it;
	for_each_prop(it, node) {
	err = _ufdt_output_node_to_fdt(tree, fdtp, *it, dict);
	if (err < 0) return -1;
	}

	for_each_node(it, node) {
	err = _ufdt_output_node_to_fdt(tree, fdtp, *it, dict);
	if (err < 0) return -1;
	}

	err = fdt_end_node(fdtp);
	if (err < 0) return -1;

	return 0;
	}

	static int _ufdt_output_strtab_to_fdt(const struct ufdt tree, void fdt) {
	/* Currently, we don't know the final dt_struct size, so we copy all
	string tables to the end of the target fdt buffer in reversed order.
	At last, fdt_finish() will adjust dt_string offset */
	const char *struct_top =
	(char *)fdt + fdt_off_dt_struct(fdt) + fdt_size_dt_struct(fdt);
	char dest = (char )fdt + fdt_totalsize(fdt);

	int dest_size = 0;
	for (int i = 0; i < tree->num_used_fdtps; i++) {
	void *src_fdt = tree->fdtps[i];
	const char src_strtab = (const char )src_fdt + fdt_off_dt_strings(src_fdt);
	int strtab_size = fdt_size_dt_strings(src_fdt);

	dest -= strtab_size;
	if (dest < struct_top) {
	dto_error("Not enough space for string table.\n");
	return -1;
	}

	dto_memcpy(dest, src_strtab, strtab_size);

	dest_size += strtab_size;
	}

	fdt_set_size_dt_strings(fdt, dest_size);

	return 0;
	}

	int ufdt_to_fdt(const struct ufdt tree, void buf, int buf_size) {
	if (tree->num_used_fdtps == 0) return -1;

	int err;
	err = fdt_create(buf, buf_size);
	if (err < 0) return -1;

	/* Here we output the memory reserve map of the ONLY FIRST fdt,
	to be in compliance with the DTO behavior of libfdt. */
	int n_mem_rsv = fdt_num_mem_rsv(tree->fdtps[0]);
	for (int i = 0; i < n_mem_rsv; i++) {
	uint64_t addr, size;
	fdt_get_mem_rsv(tree->fdtps[0], i, &addr, &size);
	fdt_add_reservemap_entry(buf, addr, size);
	}

	err = fdt_finish_reservemap(buf);
	if (err < 0) return -1;

	err = _ufdt_output_strtab_to_fdt(tree, buf);
	if (err < 0) return -1;

	struct ufdt_prop_dict dict;
	err = ufdt_prop_dict_construct(&dict, buf);
	if (err < 0) return -1;

	err = _ufdt_output_node_to_fdt(tree, buf, tree->root, &dict);
	if (err < 0) return -1;

	ufdt_prop_dict_destruct(&dict);

	err = fdt_finish(buf);
	if (err < 0) return -1;

	/*
	* IMPORTANT: fdt_totalsize(buf) might be less than buf_size
	* so this is needed to make use of remain spaces.
	*/
	return fdt_open_into(buf, buf, buf_size);
	}