// ACME - a crossassembler for producing 6502/65c02/65816 code. // Copyright (C) 1998-2014 Marco Baye // Have a look at "acme.c" for further info // // tree stuff #include "tree.h" #include "config.h" #include "dynabuf.h" #include "global.h" #include "platform.h" // Functions // Compute hash value by exclusive ORing the node's ID string and write // output to struct. // This function is not allowed to change GlobalDynaBuf! hash_t make_hash(struct ronode *node) { register char byte; register const char *read; register hash_t tmp = 0; read = node->id_string; while ((byte = *read++)) tmp = ((tmp << 7) | (tmp >> (8 * sizeof(hash_t) - 7))) ^ byte; node->hash_value = tmp; return tmp; } // Link a predefined data set to a tree void add_node_to_tree(struct ronode **tree, struct ronode *node_to_add) { hash_t hash; // compute hash value hash = make_hash(node_to_add); while (*tree) { // compare HashValue if (hash > (*tree)->hash_value) tree = &((*tree)->greater_than); else tree = &((*tree)->less_than_or_equal); } *tree = node_to_add; // add new leaf to tree // New nodes are always added as leaves, so there's no need to copy a second // pointer. And because the PREDEF* macros contain NULL as init values, it is // not necessary to clear the new node's greater_than and less_than_or_equal // fields. } // Add predefined tree items to given tree. The PREDEF* macros set HashValue // to 1 in all entries but the last. The last entry contains 0. void Tree_add_table(struct ronode **tree, struct ronode *table_to_add) { // Caution when trying to optimise this. :) while (table_to_add->hash_value) add_node_to_tree(tree, table_to_add++); add_node_to_tree(tree, table_to_add); } // Search for a given ID string in a given tree. // Compute the hash of the given string and then use that to try to find a // tree item that matches the given data (HashValue and DynaBuf-String). // Store "body" component in node_body and return TRUE. // Return FALSE if no matching item found. int Tree_easy_scan(struct ronode *tree, void **node_body, struct dynabuf *dyna_buf) { struct ronode wanted; // temporary storage const char *p1, *p2; char b1, b2; hash_t hash; wanted.id_string = dyna_buf->buffer; hash = make_hash(&wanted); while (tree) { // compare HashValue if (hash > tree->hash_value) { // wanted hash is bigger than current, so go // to tree branch with bigger hashes tree = tree->greater_than; continue; } if (hash == tree->hash_value) { p1 = wanted.id_string; p2 = tree->id_string; do { b1 = *p1++; b2 = *p2++; } while ((b1 == b2) && b1); if (b1 == b2) { // store body data *node_body = tree->body; return TRUE; } } // either the wanted hash is smaller or // it was exact but didn't match tree = tree->less_than_or_equal; } return FALSE ; // indicate failure } // Search for a "RAM tree" item. Compute the hash of string in GlobalDynaBuf // and then use that to try to find a tree item that matches the given data // (HashValue, ID_Number, GlobalDynaBuf-String). Save pointer to found tree // item in given location. // If no matching item is found, check the "create" flag. If it is set, create // a new tree item, link to tree, fill with data and store its pointer. If the // "create" flag is zero, store NULL as result. // Returns whether item was created. int Tree_hard_scan(struct rwnode **result, struct rwnode **forest, int id_number, int create) { struct ronode wanted; // temporary storage struct rwnode **current_node; struct rwnode *new_leaf_node; const char *p1, *p2; char b1, b2; hash_t byte_hash; wanted.id_string = GLOBALDYNABUF_CURRENT; // incorporate ID number into hash value byte_hash = make_hash(&wanted) ^ id_number; wanted.hash_value = byte_hash; // correct struct's hash PLATFORM_UINT2CHAR(byte_hash); // transform into byte current_node = &(forest[byte_hash]); // point into table while (*current_node) { // compare HashValue if (wanted.hash_value > (*current_node)->hash_value) { // wanted hash is bigger than current, so go // to tree branch with bigger hashes current_node = &((*current_node)->greater_than); continue; } if (wanted.hash_value == (*current_node)->hash_value) { if (id_number == (*current_node)->id_number) { p1 = wanted.id_string; p2 = (*current_node)->id_string; do { b1 = *p1++; b2 = *p2++; } while ((b1 == b2) && b1); if (b1 == b2) { // store node pointer *result = *current_node; // return FALSE because node // was not created return FALSE; } } } // either the wanted hash is smaller or // it was exact but didn't match current_node = &((*current_node)->less_than_or_equal); } // node wasn't found. Check whether to create it if (create == FALSE) { *result = NULL; // indicate failure return FALSE; // return FALSE because node was not created } // create new node new_leaf_node = safe_malloc(sizeof(*new_leaf_node)); new_leaf_node->greater_than = NULL; new_leaf_node->less_than_or_equal = NULL; new_leaf_node->hash_value = wanted.hash_value; new_leaf_node->id_number = id_number; new_leaf_node->id_string = DynaBuf_get_copy(GlobalDynaBuf); // make permanent copy // add new leaf to tree *current_node = new_leaf_node; // store pointer to new node in result location *result = new_leaf_node; return TRUE; // return TRUE because node was created } // Call given function for each object of matching type in the given tree. // Calls itself recursively. void dump_tree(struct rwnode *node, int id_number, void (*fn)(struct rwnode *, FILE *), FILE *env) { if (node->id_number == id_number) fn(node, env); if (node->greater_than) dump_tree(node->greater_than, id_number, fn, env); if (node->less_than_or_equal) dump_tree(node->less_than_or_equal, id_number, fn, env); } // Calls Tree_dump_tree for each non-zero entry of the given tree table. void Tree_dump_forest(struct rwnode **forest, int id_number, void (*fn)(struct rwnode *, FILE *), FILE *env) { int ii; for (ii = 255; ii >= 0; --ii) { if (*forest) dump_tree(*forest, id_number, fn, env); ++forest; } }