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spec_syntax.c
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spec_syntax.c
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/**
* Copyright (C) 2011 Anders Sundman <[email protected]>
*
* This file is part of mfterm.
*
* mfterm is free software: you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation, either version 3 of the License, or
* (at your option) any later version.
*
* mfterm is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with mfterm. If not, see <http://www.gnu.org/licenses/>.
*/
#include <stdlib.h>
#include <string.h>
#include <stdio.h>
#include <stddef.h>
#include "util.h"
#include "spec_syntax.h"
// Forward declarations
int sp_parse();
extern FILE* sp_in;
// Parse the input file and set up type_root and instance_root.
// Return 0 on success.
int spec_import(FILE* input) {
// Parse the input to build a type hierarchy
sp_in = input;
if (sp_parse()) {
printf("Syntax Error: Specification not imported\n");
goto error;
}
// Check for missing definitions
type_t* partial = tt_contains_partial_types();
if (partial) {
printf("Error: Incomplete declaration '%s' in specification.\n",
partial->composite_extras->name);
goto error;
}
// Make sure we have a root type defined
if (type_root == NULL) {
printf("Error: No root type '.' found in specification.\n");
goto error;
}
// Create the instance tree
instance_root = make_instance_tree(type_root);
printf("Specification sucessfully imported.\n");
return 0;
error:
clear_instance_tree();
tt_clear();
return 1;
}
// The primitive Byte type
type_t byte_type = {
.type_category = BYTE_TYPE,
.composite_extras = NULL,
};
// The primitive Bit type
type_t bit_type = {
.type_category = BIT_TYPE,
.composite_extras = NULL,
};
// Allocate and return a composite type instance. The type will assume
// ownership of the heap allocated name.
type_t* make_composite_type(char* name) {
type_t* t = malloc(sizeof(type_t));
t->type_category = COMPOSITE_TYPE;
t->composite_extras = (composite_type_extras_t*)
malloc(sizeof(composite_type_extras_t));
if (name)
t->composite_extras->name = name;
else
t->composite_extras->name = NULL; // Anonymous type
t->composite_extras->fields = NULL;
return t;
}
// Free a composite type. This function will also free it's fields.
void free_composite_type(type_t* t) {
// Free the fields
field_list_t* iter = t->composite_extras->fields;
while (iter) {
field_list_t* tmp = iter;
iter = iter->next_;
free_field(tmp->field);
free(tmp);
}
// Free the type data
free(t->composite_extras->name);
free(t->composite_extras);
free(t);
}
// Allocate a new field with the given parameters. Anonymous '-'
// filler fields use NULL as name. The field will assume ownership of
// the heap allocated name.
field_t* make_field(char* name, type_t* type, size_t length) {
field_t* f = (field_t*) malloc(sizeof(field_t));
f->name = name; // NULL for fillers
f->type = type;
f->length = length;
return f;
}
// Free the memory used by a field.
void free_field(field_t* field) {
if (field == NULL)
return;
free(field->name);
free(field);
}
// Add a field to an existing list of fields or, if the field_list
// parameter is NULL, create a new field list. The order of fields is
// significant and this function will append the field to the end of
// the field_list.
field_list_t* append_field(field_list_t* field_list, field_t* field) {
// Create the list node
field_list_t* flist = (field_list_t*) malloc(sizeof(field_list_t));
flist->field = field;
flist->next_ = NULL;
// Create the list or append to the end
if (field_list != NULL) {
field_list_t* it = field_list;
while(it->next_)
it = it->next_;
it->next_ = flist;
}
else {
field_list = flist; // Won't effect the inarg
}
// Return the start of the list
return field_list;
}
// Search the field list for a field with the given name
field_t* get_field(field_list_t* field_list, const char* name) {
if (name == NULL || field_list == NULL)
return NULL;
field_list_t* it = field_list;
while(it) {
field_t* f = it->field;
if (f && f->name && strcmp(f->name, name) == 0)
return f;
it = it->next_;
}
// Not found
return NULL;
}
// The global instance of the type table. If there isn't any, the
// variable will be NULL. All the type table operations (tt_) operate
// on this global variable.
type_table_t* type_table = NULL;
// The root type of the type hierarchy
type_t* type_root = NULL;
// Internal functions for allocating and freeing type table list nodes.
type_table_t* tt_make_node_(type_t* t);
void tt_free_node_(type_table_t* tt);
// Clear the type table - freeing the memory used by the table and by
// all the types.
void tt_clear() {
// Reset the root
type_root = NULL;
// Free all types and the table itself
type_table_t* it = type_table;
while(it) {
type_table_t* next = it->next_;
free_composite_type(it->type);
tt_free_node_(it);
it = next;
};
type_table = NULL;
}
// Add a type to the type table.
type_t* tt_add_type(type_t* t) {
if (type_table == NULL) {
type_table = tt_make_node_(t);
}
else {
type_table_t* it = type_table;
while(it->next_)
it = it->next_;
it->next_ = tt_make_node_(t);
}
return t;
}
// Search the type table for a type with the given name. The first
// type found will be returned. If no type is found, NULL is returned.
type_t* tt_get_type(const char* type_name) {
if (type_name == NULL)
return NULL;
type_table_t* it = type_table;
while(it) {
// Anonymous types (name == NULL) will never match
if (it->type->composite_extras->name &&
strcmp(type_name, it->type->composite_extras->name) == 0)
return it->type; // Type was found!
it = it->next_;
}
// Not found
return NULL;
}
// Check if there are any partially declared types in the type
// table. Return a pointer to the first incomplete type or NULL if
// none exists.
type_t* tt_contains_partial_types() {
type_table_t* it = type_table;
while(it) {
if (it->type->composite_extras->decl_status == PARTIAL_DECL)
return it->type;
it = it->next_;
}
return NULL;
}
// Allocate a new list entry for the type table
type_table_t* tt_make_node_(type_t* t) {
type_table_t* tt = malloc(sizeof(type_table_t));
tt->type = t;
tt->next_ = NULL;
return tt;
}
// Free a type table list entry (this won't free the type)
void tt_free_node_(type_table_t* tt) {
free(tt);
}
// The global variable representing the root instance; it is an
// instanciation of the '.' type.
instance_t* instance_root = NULL;
// Forward decls of internal functions used during creation and
// destruction of the instance tree.
void clear_instance_tree_(instance_t* root);
void make_instance_(instance_t* root,
size_t* obytes, size_t* obits,
size_t* sbytes, size_t* sbits);
instance_t* make_byte_instance_(field_t* field, size_t* obytes, size_t* obits);
instance_t* make_bit_instance_(field_t* field, size_t* obytes, size_t* obits);
instance_t* make_composite_instance_(field_t* field,
size_t* obytes, size_t* obits);
instance_list_t* append_instance_(instance_list_t** end_ptr,
instance_t* new_field);
// Create an instance tree matching the type tree starting at
// type_root. The global instance tree is constructed with type_root '.'.
instance_t* make_instance_tree(type_t* type_root) {
instance_t* root = malloc(sizeof(instance_t));
root->offset_bytes = 0;
root->offset_bits = 0;
root->size_bytes = 0;
root->size_bits = 0;
root->field = make_field(strdup("."), type_root, 1);
root->fields = NULL;
size_t obytes = 0;
size_t obits = 0;
make_instance_(root, &obytes, &obits,
&(root->size_bytes), &(root->size_bits));
return root;
}
// Clear the global instance tree. Free it and set instance_root NULL
void clear_instance_tree() {
if (instance_root == NULL)
return;
clear_instance_tree_(instance_root);
instance_root = NULL;
}
/* Get the child instance with a given name. Only look to children, */
/* not grand children. If no child with the given name exists, return */
/* null. */
instance_t* get_instance_child(instance_t* inst, const char* name) {
if (name == NULL)
return NULL;
return get_instance_child_n(inst, name, strlen(name));
}
/**
* Like get_instance_child(inst, name), but name does not have to be
* null terminated. Instead the length of the name string is given by
* the last argument.
*/
instance_t* get_instance_child_n(instance_t* inst,
const char* name,
size_t nlen) {
if (inst == NULL || name == NULL || nlen == 0)
return NULL;
instance_list_t* iter = inst->fields;
while(iter) {
field_t* f = iter->instance->field;
// Make sure the field has a name (isn't anaonymous) before comparing.
if (f && f->name &&
strlen(f->name) == nlen &&
strncmp(f->name, name, nlen) == 0)
return iter->instance;
iter = iter->next_;
}
return NULL;
}
/**
* Parse a specification path of the form '.fu.bar.baz' and return the
* instance pointed to by baz. In case the path doesn't point to a
* loaded instance, return NULL. */
instance_t* parse_spec_path(const char* path) {
const char* lastpath;
instance_t* inst;
// Parse the path up to the last instance
if (parse_partial_spec_path(path, &lastpath, &inst) != 0)
return NULL;
// Find and return the leaf node
return get_instance_child(inst, lastpath);
}
/**
* Parse the path to produce a parent section and an instance that
* points to the head of the parent.
*
* The format is .fu.bar.ba(z). Where .fu.bar.ba is the path, fu, bar
* and baz are nested fields. The function should return parent_end
* pointing into path to the point after the last '.', i.e. to the 'b'
* in the last 'ba'. parent_inst will point to bar.
*
* The function returns 0 on success.
*/
int parse_partial_spec_path(const char* path,
const char** parent_end,
instance_t** parent_inst) {
// Check input. Paths start with '.'
if (path == NULL || path[0] != '.')
return 1;
instance_t* inst = instance_root;
const char* remaining_path = path + 1;
char* tok_end;
while((tok_end = strchr(remaining_path, '.')) != NULL) {
// There is still a part of the path before the last '.'
ptrdiff_t tok_name = tok_end - remaining_path;
if (tok_name <= 0)
return 1;
inst = get_instance_child_n(inst, remaining_path, (size_t)tok_name);
// Exit early (error in ancestor path)
if (inst == NULL)
return 1;
// Remove the token and the '.' from the start of remaining string
remaining_path = tok_end + 1;
}
// Set the output arguments
if (parent_end != NULL)
*parent_end = remaining_path;
if (parent_inst != NULL)
*parent_inst = inst;
return 0;
}
// Count the number of fields in the instance
int instance_fields_count(instance_t* inst) {
if (inst == NULL)
return 0;
int count = 0;
instance_list_t* it = inst->fields;
while (it) {
++count;
it = it->next_;
}
return count;
}
void clear_instance_tree_(instance_t* root) {
instance_list_t* iter = root->fields;
while (iter) {
instance_list_t* tmp = iter->next_;
clear_instance_tree_(iter->instance);
free(iter);
iter = tmp;
}
free(root);
}
void make_instance_(instance_t* root,
size_t* obytes, size_t* obits,
size_t* sbytes, size_t* sbits) {
// Pointers to the matching type field and instance field beign processed.
field_list_t* tf_iter = root->field->type->composite_extras->fields;
instance_list_t* if_iter = root->fields;
// Iterate over all the type fields and add matching instance fields.
while(tf_iter) {
field_t* f = tf_iter->field;
// Create the child sub-tree or instance.
instance_t* child;
// Byte
if (f->type == &byte_type) {
child = make_byte_instance_(f, obytes, obits);
}
// Bit
else if (f->type == &bit_type) {
child = make_bit_instance_(f, obytes, obits);
}
// Composite type
else {
child = make_composite_instance_(f, obytes, obits);
child->size_bytes = 0;
child->size_bits = 0;
make_instance_(child, obytes, obits,
&(child->size_bytes), &(child->size_bits));
// Update size with bits % 8
child->size_bytes =
child->size_bytes * f->length +
(child->size_bits * f->length) / 8;
child->size_bits = (child->size_bits * f->length) % 8;
}
// Add the new instance or instance tree, to the root instance
// field list.
if_iter = if_iter == NULL ?
append_instance_(&(root->fields), child) :
append_instance_(&(if_iter->next_), child);
// Note that we are changing the value of the input parameters here
// this is part of the 'return value' of the function. Wrap the
// bit size mod 8.
*sbytes = *sbytes + child->size_bytes + (*sbits + child->size_bits) / 8;
*sbits = (*sbits + child->size_bits) % 8;
tf_iter = tf_iter->next_;
}
}
instance_t* make_byte_instance_(field_t* field, size_t* obytes, size_t* obits) {
instance_t* i = malloc(sizeof(instance_t));
i->field = field;
i->fields = NULL;
i->offset_bytes = *obytes;
i->offset_bits = *obits;
i->size_bytes = field->length;
i->size_bits = 0;
*obytes += i->size_bytes;
// *obits += 0;
return i;
}
instance_t* make_bit_instance_(field_t* field, size_t* obytes, size_t* obits) {
instance_t* i = malloc(sizeof(instance_t));
i->field = field;
i->fields = NULL;
i->offset_bytes = *obytes;
i->offset_bits = *obits;
// Bits % 8, overflow in bytes field
i->size_bytes = field->length / 8;
i->size_bits = field->length % 8;
*obytes += i->size_bytes + (*obits + i->size_bits) / 8;
*obits = (*obits + i->size_bits) % 8;
return i;
}
instance_t* make_composite_instance_(field_t* field,
size_t* obytes, size_t* obits) {
instance_t* i = malloc(sizeof(instance_t));
i->field = field;
i->fields = NULL;
i->offset_bytes = *obytes;
i->offset_bits = *obits;
// The size will be updated later, after recusion into all child fields.
i->size_bytes = 0;
i->size_bits = 0;
return i;
}
instance_list_t* append_instance_(instance_list_t** end_ptr,
instance_t* new_field) {
instance_list_t* il = (instance_list_t*) malloc(sizeof(instance_list_t));
il->instance = new_field;
il->next_ = NULL;
*end_ptr = il;
return il;
}
// Forward declaration
void print_instance_tree_(instance_t* i, int indent);
void print_instance_(instance_t* i);
void print_instance_tree() {
if (instance_root == NULL) {
printf("No specification loaded.\n");
return;
}
printf("[%zu, %zu] [%zu, %zu] -- . (root)\n",
instance_root->offset_bytes,
instance_root->offset_bits,
instance_root->size_bytes,
instance_root->size_bits);
print_instance_tree_(instance_root, 1);
}
void print_instance_tree_(instance_t* root, int indent) {
// For each field of the root instance
instance_list_t* il = root->fields;
while(il) {
// Indent
int count = (indent - 1) * 2;
while(count--)
printf(" ");
printf("+- ");
// Print instance field
instance_t* inst = il->instance;
print_instance_(inst);
if (inst->field->type->composite_extras != NULL)
print_instance_tree_(inst, indent + 1);
il = il->next_;
}
}
void print_instance_(instance_t* i) {
if (i->field->type == &byte_type) {
printf("[%zu, %zu] [%zu, %zu] -- Byte[%zu] %s\n",
i->offset_bytes,
i->offset_bits,
i->size_bytes,
i->size_bits,
i->field->length,
i->field->name);
}
else if (i->field->type == &bit_type) {
printf("[%zu, %zu] [%zu, %zu] -- Bit[%zu] %s\n",
i->offset_bytes,
i->offset_bits,
i->size_bytes,
i->size_bits,
i->field->length,
i->field->name);
}
else {
printf("[%zu, %zu] [%zu, %zu] -- %s[%zu] %s\n",
i->offset_bytes,
i->offset_bits,
i->size_bytes,
i->size_bits,
i->field->type->composite_extras->name,
i->field->length,
i->field->name);
}
}