c-ipfs/include/ipfs/merkledag/node.h
jmjatlanta c8fdb084e4 Moving closer to binary compatability with go version of ipfs
The files are now stored in the same format. Now it is necessary to
reverse engineer the directory structure
2016-12-21 06:40:19 -05:00

279 lines
9.7 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 Node
{
// saved in protobuf
size_t data_size;
unsigned char* data;
struct NodeLink* head_link;
// not saved in protobuf
unsigned char* encoded;
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(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(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_node_protobuf_encode_size(struct Node* 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_node_protobuf_encode(struct Node* 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_node_protobuf_decode(unsigned char* buffer, size_t buffer_length, struct Node** node);
/*====================================================================================
* Node Functions
*===================================================================================*/
/*ipfs_node_new
* Creates an empty node, allocates the required memory
* Returns a fresh new node with no data set in it.
*/
int ipfs_node_new(struct Node** 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_node_set_hash(struct Node* 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_node_set_data(struct Node * 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_node_set_encoded(struct Node * 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_node_get_data(struct Node * 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_node_free(struct Node * 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_node_get_link_by_name(struct Node * 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_node_remove_link_by_name(char * Name, struct Node * 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_node_add_link(struct Node * 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_node_new_from_link(struct NodeLink * mylink, struct Node** 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_node_new_from_data(unsigned char * data, size_t data_size, struct Node** 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_node_new_from_encoded(unsigned char * data, struct Node** 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 Node * 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