c-ipfs/include/ipfs/merkledag/node.h
2017-04-20 17:56:03 -05:00

296 lines
11 KiB
C

/**
* An implementation of an IPFS node
* Copying the go-ipfs-node project
*/
#ifndef IPFS_NODE_H
#define IPFS_NODE_H
#include "ipfs/cid/cid.h"
/*====================================================================================
*
* Structures
*
*===================================================================================*/
struct NodeLink
{
size_t hash_size;
unsigned char* hash;
char* name;
size_t t_size;
struct NodeLink* next;
};
struct HashtableNode
{
// saved in protobuf
size_t data_size;
unsigned char* data;
struct NodeLink* head_link;
// not saved in protobuf
unsigned char* encoded;
// a base32 representation of the multihash
unsigned char* hash;
size_t hash_size;
};
/*====================================================================================
*
* Functions
*
*===================================================================================*/
/*====================================================================================
* Link Functions
*===================================================================================*/
/* Create_Link
* @Param name: The name of the link (char *)
* @Param ahash: An Qmhash
* @param hash_size the size of the hash
* @param node_link a pointer to the new struct NodeLink
* @returns true(1) on success
*/
int ipfs_node_link_create(char * name, unsigned char * ahash, size_t hash_size, struct NodeLink** node_link);
/****
* Allocate memory for a new NodeLink
* @param node_link a pointer to the newly allocated memory
* @returns true(1) on success
*/
int ipfs_node_link_new(struct NodeLink** node_link);
/* ipfs_node_link_free
* @param L: Free the link you have allocated.
*/
int ipfs_node_link_free(struct NodeLink * node_link);
/***
* Node protobuf functions
*/
/***
* Get the approximate size needed to protobuf encode this link
* @param link the link to examine
* @returns the maximum size that should be needed
*/
size_t ipfs_node_link_protobuf_encode_size(const struct NodeLink* link);
/***
* Encode a NodeLink into protobuf format
* @param link the link
* @param buffer where to put the encoded results
* @param max_buffer_length the max size that should be put in buffer
* @pram bytes_written the amount of the buffer used
* @returns true(1) on success
*/
int ipfs_node_link_protobuf_encode(const struct NodeLink* link, unsigned char* buffer, size_t max_buffer_length, size_t* bytes_written);
/****
* Decode from a byte array into a NodeLink
* @param buffer the byte array
* @param buffer_length the length of the byte array
* @param link the pointer to the new NodeLink (NOTE: Will be allocated in this function)
* @param bytes_read the amount of bytes read by this function
* @returns true(1) on success
*/
int ipfs_node_link_protobuf_decode(unsigned char* buffer, size_t buffer_length, struct NodeLink** link);
/***
* return an approximate size of the encoded node
* @param node the node to examine
* @returns the max size of an encoded stream of bytes, if it were encoded
*/
size_t ipfs_hashtable_node_protobuf_encode_size(const struct HashtableNode* node);
/***
* Encode a node into a protobuf byte stream
* @param node the node to encode
* @param buffer where to put it
* @param max_buffer_length the length of buffer
* @param bytes_written how much of buffer was used
* @returns true(1) on success
*/
int ipfs_hashtable_node_protobuf_encode(const struct HashtableNode* node, unsigned char* buffer, size_t max_buffer_length, size_t* bytes_written);
/***
* Decode a stream of bytes into a Node structure
* @param buffer where to get the bytes from
* @param buffer_length the length of buffer
* @param node pointer to the Node to be created
* @returns true(1) on success
*/
int ipfs_hashtable_node_protobuf_decode(unsigned char* buffer, size_t buffer_length, struct HashtableNode** node);
/*====================================================================================
* Node Functions
*===================================================================================*/
/****
* Creates an empty node, allocates the required memory
* @param node the pointer to the memory allocated
* @returns true(1) on success, otherwise false(0)
*/
int ipfs_hashtable_node_new(struct HashtableNode** node);
/***
* Allocates memory for a node, and sets the data section to indicate
* that this node is a directory
* @param node the node to initialize
* @returns true(1) on success, otherwise false(0)
*/
int ipfs_hashtable_node_create_directory(struct HashtableNode** node);
/***
* Determine if this node is actually a directory
* @param node the node to examine
* @returns true(1) if this node is a directory. Otherwise, false(0)
*/
int ipfs_hashtable_node_is_directory(struct HashtableNode* node);
/**
* sets the Cid into the struct element titled cached
* @param node the node to work with
* @param cid the cid
* @returns true(1) on success
*/
int ipfs_hashtable_node_set_hash(struct HashtableNode* node, const unsigned char* hash, size_t hash_size);
/*ipfs_node_set_data
* Sets the data of a node
* @param Node: The node which you want to set data in.
* @param Data, the data you want to assign to the node
* Sets pointers of encoded & cached to NULL /following go method
* returns 1 on success 0 on failure
*/
int ipfs_hashtable_node_set_data(struct HashtableNode * N, unsigned char * Data, size_t data_size);
/*ipfs_node_set_encoded
* @param NODE: the node you wish to alter (struct Node *)
* @param Data: The data you wish to set in encoded.(unsigned char *)
* returns 1 on success 0 on failure
*/
int ipfs_hashtable_node_set_encoded(struct HashtableNode * N, unsigned char * Data);
/*ipfs_node_get_data
* Gets data from a node
* @param Node: = The node you want to get data from. (unsigned char *)
* Returns data of node.
*/
unsigned char * ipfs_hashtable_node_get_data(struct HashtableNode * N);
/*ipfs_node_free
* Once you are finished using a node, always delete it using this.
* It will take care of the links inside it.
* @param N: the node you want to free. (struct Node *)
*/
int ipfs_hashtable_node_free(struct HashtableNode * N);
/*ipfs_node_get_link_by_name
* Returns a copy of the link with given name
* @param Name: (char * name) searches for link with this name
* Returns the link struct if it's found otherwise returns NULL
*/
struct NodeLink * ipfs_hashtable_node_get_link_by_name(struct HashtableNode * N, char * Name);
/*ipfs_node_remove_link_by_name
* Removes a link from node if found by name.
* @param name: Name of link (char * name)
* returns 1 on success, 0 on failure.
*/
int ipfs_hashtable_node_remove_link_by_name(char * Name, struct HashtableNode * mynode);
/* ipfs_node_add_link
* Adds a link to your node
* @param mynode: &yournode
* @param mylink: the CID you want to create a node from
* @param linksz: sizeof(your cid here)
* Returns your node with the newly added link
*/
int ipfs_hashtable_node_add_link(struct HashtableNode * mynode, struct NodeLink * mylink);
/*ipfs_node_new_from_link
* Create a node from a link
* @param mylink: the link you want to create it from. (struct Cid *)
* @param node the pointer to the new node
* @returns true(1) on success
*/
int ipfs_hashtable_node_new_from_link(struct NodeLink * mylink, struct HashtableNode** node);
/*ipfs_node_new_from_data
* @param data: bytes buffer you want to create the node from
* @param data_size the size of the data
* @param node the pointer to the new node
* @returns true(1) on success
*/
int ipfs_hashtable_node_new_from_data(unsigned char * data, size_t data_size, struct HashtableNode** node);
/***
* create a Node struct from encoded data
* @param data: encoded bytes buffer you want to create the node from. Note: this copies the pointer, not a memcpy
* @param node a pointer to the node that will be created
* @returns true(1) on success
*/
int ipfs_hashtable_node_new_from_encoded(unsigned char * data, struct HashtableNode** node);
/*Node_Resolve_Max_Size
* !!!This shouldn't concern you!
*Gets the ammount of words that will be returned by Node_Resolve
*@Param1: The string that will be processed (eg: char * sentence = "foo/bar/bin")
*Returns either -1 if something went wrong or the ammount of words that would be processed.
*/
int Node_Resolve_Max_Size(char * input1);
/*Node_Resolve Basically stores everything in a pointer array eg: char * bla[Max_Words_]
* !!!This shouldn't concern you!!!
*@param1: Pointer array(char * foo[x], X=Whatever ammount there is. should be used with the helper function Node_Resolve_Max_Size)
*@param2: Sentence to gather words/paths from (Eg: char * meh = "foo/bar/bin")
*@Returns 1 or 0, 0 if something went wrong, 1 if everything went smoothly.
*/
int Node_Resolve(char ** result, char * input1);
/**************************************************************************************************************************************
*|||||||||||||||||||||||||||||||||||||||| !!!! IMPORTANT !!! ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||*
**************************************************************************************************************************************
* Not sure where this is used, I'm making something to easen it up for all of you.
* This in itself will get all the links for you in a link[] array inside Link_Proc
* the memory allocation for storage will be noted in the ammount of links.
* After being done with this, you have to free the array for which you will have a function specially made for you.
*
* What this does:
* It searches for links using a path like /foo/bar/bin/, if links with those names are found in the node you specify, it stores them
* in a custom struct, Link_Proc; which is what Node_Resolve_Link returns.
* Notes:
* Use it, free it, it's all already laid out for you.
* There will also be a tutorial demonstrating it in the same folder here so everyone can understand this.
*/
struct Link_Proc
{
char * remaining_links; // Not your concern.
int ammount; //This will store the ammount of links, so you know what to process.
struct NodeLink * links[]; // Link array
};
/*Node_Resolve_Links
* Processes a path returning all links.
* @param N: The node you want to get links from
* @param path: The "foo/bar/bin" path
*/
struct Link_Proc * Node_Resolve_Links(struct HashtableNode * N, char * path);
/*Free_link_Proc
* frees the Link_Proc struct you created.
* @param1: Link_Proc struct (struct Link_Proc *)
*/
void Free_Link_Proc(struct Link_Proc * LPRC);
/*Node_Tree() Basically a unix-like ls
*@Param1: Result char * foo[strlen(sentence)]
*@Param2: char sentence[] = foo/bar/bin/whatever
*Return: 0 if failure, 1 if success
*/
int Node_Tree(char * result, char * input1); //I don't know where you use this but here it is.
#endif