/*
Copyright 2011 David Robillard <http://drobilla.net>
Redistribution and use in source and binary forms, with or without
modification, are permitted provided that the following conditions are met:
1. Redistributions of source code must retain the above copyright notice,
this list of conditions and the following disclaimer.
2. Redistributions in binary form must reproduce the above copyright
notice, this list of conditions and the following disclaimer in the
documentation and/or other materials provided with the distribution.
THIS SOFTWARE IS PROVIDED ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES,
INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY
AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE
AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY,
OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF
THE POSSIBILITY OF SUCH DAMAGE.
*/
#include <assert.h>
#include <stdarg.h>
#include <stdbool.h>
#include <stdint.h>
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include "serd_internal.h"
#define NS_XSD "http://www.w3.org/2001/XMLSchema#"
#define NS_RDF "http://www.w3.org/1999/02/22-rdf-syntax-ns#"
#define TRY_THROW(exp) if (!(exp)) goto except;
#define TRY_RET(exp) if (!(exp)) return 0;
#define STACK_PAGE_SIZE 4096
#define READ_BUF_LEN 4096
typedef struct {
const uint8_t* filename;
unsigned line;
unsigned col;
} Cursor;
typedef uint32_t uchar;
typedef size_t Ref;
typedef struct {
SerdType type;
Ref value;
Ref datatype;
Ref lang;
} Node;
typedef struct {
const Node* graph;
const Node* subject;
const Node* predicate;
} ReadContext;
/** Measured UTF-8 string. */
typedef struct {
size_t n_bytes; ///< Size in bytes including trailing null byte
size_t n_chars; ///< Length in characters
uint8_t buf[]; ///< Buffer
} SerdString;
static const Node INTERNAL_NODE_NULL = { 0, 0, 0, 0 };
struct SerdReaderImpl {
void* handle;
SerdBaseSink base_sink;
SerdPrefixSink prefix_sink;
SerdStatementSink statement_sink;
SerdEndSink end_sink;
Node rdf_type;
Node rdf_first;
Node rdf_rest;
Node rdf_nil;
FILE* fd;
SerdStack stack;
Cursor cur;
uint8_t* buf;
const uint8_t* blank_prefix;
unsigned next_id;
int err;
uint8_t* read_buf;
int32_t read_head; ///< Offset into read_buf
bool from_file; ///< True iff reading from @ref fd
bool eof;
#ifdef SUIL_STACK_CHECK
Ref* alloc_stack; ///< Stack of push offsets
size_t n_allocs; ///< Number of stack pushes
#endif
};
struct SerdReadStateImpl {
SerdEnv env;
SerdNode base_uri_node;
SerdURI base_uri;
};
typedef enum {
SERD_SUCCESS = 0, ///< Completed successfully
SERD_FAILURE = 1, ///< Non-fatal failure
SERD_ERROR = 2, ///< Fatal error
} SerdStatus;
static inline int
error(SerdReader reader, const char* fmt, ...)
{
va_list args;
va_start(args, fmt);
fprintf(stderr, "error: %s:%u:%u: ",
reader->cur.filename, reader->cur.line, reader->cur.col);
vfprintf(stderr, fmt, args);
return 0;
}
static Node
make_node(SerdType type, Ref value, Ref datatype, Ref lang)
{
const Node ret = { type, value, datatype, lang };
return ret;
}
static inline bool
page(SerdReader reader)
{
assert(reader->from_file);
reader->read_head = 0;
const size_t n_read = fread(reader->read_buf, 1, READ_BUF_LEN, reader->fd);
if (n_read == 0) {
reader->read_buf[0] = '\0';
reader->eof = true;
return false;
} else if (n_read < READ_BUF_LEN) {
reader->read_buf[n_read] = '\0';
}
return true;
}
static inline bool
peek_string(SerdReader reader, uint8_t* pre, int n)
{
uint8_t* ptr = reader->read_buf + reader->read_head;
for (int i = 0; i < n; ++i) {
if (reader->from_file && (reader->read_head + i >= READ_BUF_LEN)) {
if (!page(reader)) {
return false;
}
ptr = reader->read_buf;
reader->read_head = -i;
memcpy(reader->read_buf + reader->read_head, pre, i);
assert(reader->read_buf[reader->read_head] == pre[0]);
}
if ((pre[i] = *ptr++) == '\0') {
return false;
}
}
return true;
}
static inline uint8_t
peek_byte(SerdReader reader)
{
return reader->read_buf[reader->read_head];
}
static inline uint8_t
eat_byte(SerdReader reader, const uint8_t byte)
{
const uint8_t c = peek_byte(reader);
++reader->read_head;
switch (c) {
case '\n': ++reader->cur.line; reader->cur.col = 0; break;
default: ++reader->cur.col;
}
if (c != byte) {
return error(reader, "expected `%c', not `%c'\n", byte, c);
}
if (reader->from_file && (reader->read_head == READ_BUF_LEN)) {
TRY_RET(page(reader));
assert(reader->read_head < READ_BUF_LEN);
}
if (reader->read_buf[reader->read_head] == '\0') {
reader->eof = true;
}
return c;
}
static inline void
eat_string(SerdReader reader, const char* str, unsigned n)
{
for (unsigned i = 0; i < n; ++i) {
eat_byte(reader, ((const uint8_t*)str)[i]);
}
}
#ifdef SUIL_STACK_CHECK
static inline bool
stack_is_top_string(SerdReader reader, Ref ref)
{
return ref == reader->alloc_stack[reader->n_allocs - 1];
}
#endif
static inline intptr_t
pad_size(intptr_t size)
{
return (size + 7) & (~7);
}
// Make a new string from a non-UTF-8 C string (internal use only)
static Ref
push_string(SerdReader reader, const char* c_str, size_t n_bytes)
{
// Align strings to 64-bits (assuming malloc/realloc are aligned to 64-bits)
const size_t stack_size = pad_size((intptr_t)reader->stack.size);
const size_t pad = stack_size - reader->stack.size;
uint8_t* mem = serd_stack_push(
&reader->stack, pad + sizeof(SerdString) + n_bytes) + pad;
SerdString* const str = (SerdString*)mem;
str->n_bytes = n_bytes;
str->n_chars = n_bytes - 1;
memcpy(str->buf, c_str, n_bytes);
#ifdef SUIL_STACK_CHECK
reader->alloc_stack = realloc(reader->alloc_stack,
sizeof(uint8_t*) * (++reader->n_allocs));
reader->alloc_stack[reader->n_allocs - 1] = (mem - reader->stack.buf);
#endif
return (uint8_t*)str - reader->stack.buf;
}
static inline SerdString*
deref(SerdReader reader, const Ref ref)
{
if (ref) {
return (SerdString*)(reader->stack.buf + ref);
}
return NULL;
}
static inline void
push_byte(SerdReader reader, Ref ref, const uint8_t c)
{
#ifdef SUIL_STACK_CHECK
assert(stack_is_top_string(reader, ref));
#endif
serd_stack_push(&reader->stack, 1);
SerdString* const str = deref(reader, ref);
++str->n_bytes;
if ((c & 0xC0) != 0x80) {
// Does not start with `10', start of a new character
++str->n_chars;
}
assert(str->n_bytes > str->n_chars);
str->buf[str->n_bytes - 2] = c;
str->buf[str->n_bytes - 1] = '\0';
}
static void
pop_string(SerdReader reader, Ref ref)
{
if (ref) {
if (ref == reader->rdf_nil.value
|| ref == reader->rdf_first.value
|| ref == reader->rdf_rest.value) {
return;
}
#ifdef SUIL_STACK_CHECK
if (!stack_is_top_string(reader, ref)) {
fprintf(stderr, "attempt to pop non-top string %s\n",
deref(reader, ref)->buf);
fprintf(stderr, "top: %s\n",
deref(reader, reader->alloc_stack[reader->n_allocs - 1])->buf);
}
assert(stack_is_top_string(reader, ref));
--reader->n_allocs;
#endif
serd_stack_pop(&reader->stack, deref(reader, ref)->n_bytes);
}
}
static inline SerdNode
public_node_from_ref(SerdReader reader, SerdType type, Ref ref)
{
if (!ref) {
return SERD_NODE_NULL;
}
const SerdString* str = deref(reader, ref);
const SerdNode public = { type, str->n_bytes, str->n_chars, str->buf };
return public;
}
static inline SerdNode
public_node(SerdReader reader, const Node* private)
{
return public_node_from_ref(reader, private->type, private->value);
}
static inline bool
emit_statement(SerdReader reader,
const Node* g, const Node* s, const Node* p, const Node* o)
{
assert(s->value && p->value && o->value);
const SerdNode graph = g ? public_node(reader, g) : SERD_NODE_NULL;
const SerdNode subject = public_node(reader, s);
const SerdNode predicate = public_node(reader, p);
const SerdNode object = public_node(reader, o);
const SerdNode object_datatype = public_node_from_ref(reader, SERD_URI, o->datatype);
const SerdNode object_lang = public_node_from_ref(reader, SERD_LITERAL, o->lang);
return reader->statement_sink(reader->handle,
&graph,
&subject,
&predicate,
&object,
&object_datatype,
&object_lang);
}
static bool read_collection(SerdReader reader, ReadContext ctx, Node* dest);
static bool read_predicateObjectList(SerdReader reader, ReadContext ctx);
// [40] hex ::= [#x30-#x39] | [#x41-#x46]
static inline uint8_t
read_hex(SerdReader reader)
{
const uint8_t c = peek_byte(reader);
if (in_range(c, 0x30, 0x39) || in_range(c, 0x41, 0x46)) {
return eat_byte(reader, c);
} else {
return error(reader, "illegal hexadecimal digit `%c'\n", c);
}
}
static inline bool
read_hex_escape(SerdReader reader, unsigned length, Ref dest)
{
uint8_t buf[9] = { 0, 0, 0, 0, 0, 0, 0, 0, 0 };
for (unsigned i = 0; i < length; ++i) {
buf[i] = read_hex(reader);
}
uint32_t c;
sscanf((const char*)buf, "%X", &c);
unsigned size = 0;
if (c < 0x00000080) {
size = 1;
} else if (c < 0x00000800) {
size = 2;
} else if (c < 0x00010000) {
size = 3;
} else if (c < 0x00200000) {
size = 4;
} else {
return false;
}
// Build output in buf
// (Note # of bytes = # of leading 1 bits in first byte)
switch (size) {
case 4:
buf[3] = 0x80 | (uint8_t)(c & 0x3F);
c >>= 6;
c |= (16 << 12); // set bit 4
case 3:
buf[2] = 0x80 | (uint8_t)(c & 0x3F);
c >>= 6;
c |= (32 << 6); // set bit 5
case 2:
buf[1] = 0x80 | (uint8_t)(c & 0x3F);
c >>= 6;
c |= 0xC0; // set bits 6 and 7
case 1:
buf[0] = (uint8_t)c;
}
for (unsigned i = 0; i < size; ++i) {
push_byte(reader, dest, buf[i]);
}
return true;
}
static inline bool
read_character_escape(SerdReader reader, Ref dest)
{
switch (peek_byte(reader)) {
case '\\':
push_byte(reader, dest, eat_byte(reader, '\\'));
return true;
case 'u':
eat_byte(reader, 'u');
return read_hex_escape(reader, 4, dest);
case 'U':
eat_byte(reader, 'U');
return read_hex_escape(reader, 8, dest);
default:
return false;
}
}
static inline bool
read_echaracter_escape(SerdReader reader, Ref dest)
{
switch (peek_byte(reader)) {
case 't':
eat_byte(reader, 't');
push_byte(reader, dest, '\t');
return true;
case 'n':
eat_byte(reader, 'n');
push_byte(reader, dest, '\n');
return true;
case 'r':
eat_byte(reader, 'r');
push_byte(reader, dest, '\r');
return true;
default:
return read_character_escape(reader, dest);
}
}
static inline bool
read_scharacter_escape(SerdReader reader, Ref dest)
{
switch (peek_byte(reader)) {
case '"':
push_byte(reader, dest, eat_byte(reader, '"'));
return true;
default:
return read_echaracter_escape(reader, dest);
}
}
static inline bool
read_ucharacter_escape(SerdReader reader, Ref dest)
{
switch (peek_byte(reader)) {
case '>':
push_byte(reader, dest, eat_byte(reader, '>'));
return true;
default:
return read_echaracter_escape(reader, dest);
}
}
// [38] character ::= '\u' hex hex hex hex
// | '\U' hex hex hex hex hex hex hex hex
// | '\\'
// | [#x20-#x5B] | [#x5D-#x10FFFF]
static inline SerdStatus
read_character(SerdReader reader, Ref dest)
{
const uint8_t c = peek_byte(reader);
assert(c != '\\'); // Only called from methods that handle escapes first
switch (c) {
case '\0':
error(reader, "unexpected end of file\n", peek_byte(reader));
return SERD_ERROR;
default:
if (c < 0x20) { // ASCII control character
error(reader, "unexpected control character\n");
return SERD_ERROR;
} else if (c <= 0x7E) { // Printable ASCII
push_byte(reader, dest, eat_byte(reader, c));
return SERD_SUCCESS;
} else { // Wide UTF-8 character
unsigned size = 1;
if ((c & 0xE0) == 0xC0) { // Starts with `110'
size = 2;
} else if ((c & 0xF0) == 0xE0) { // Starts with `1110'
size = 3;
} else if ((c & 0xF8) == 0xF0) { // Starts with `11110'
size = 4;
} else {
error(reader, "invalid character\n");
return SERD_ERROR;
}
for (unsigned i = 0; i < size; ++i) {
push_byte(reader, dest, eat_byte(reader, peek_byte(reader)));
}
return SERD_SUCCESS;
}
}
}
// [39] echaracter ::= character | '\t' | '\n' | '\r'
static inline SerdStatus
read_echaracter(SerdReader reader, Ref dest)
{
uint8_t c = peek_byte(reader);
switch (c) {
case '\\':
eat_byte(reader, '\\');
if (read_echaracter_escape(reader, peek_byte(reader))) {
return SERD_SUCCESS;
} else {
error(reader, "illegal escape `\\%c'\n", peek_byte(reader));
return SERD_ERROR;
}
default:
return read_character(reader, dest);
}
}
// [43] lcharacter ::= echaracter | '\"' | #x9 | #xA | #xD
static inline SerdStatus
read_lcharacter(SerdReader reader, Ref dest)
{
const uint8_t c = peek_byte(reader);
uint8_t pre[3];
switch (c) {
case '"':
peek_string(reader, pre, 3);
if (pre[1] == '\"' && pre[2] == '\"') {
eat_byte(reader, '\"');
eat_byte(reader, '\"');
eat_byte(reader, '\"');
return SERD_FAILURE;
} else {
push_byte(reader, dest, eat_byte(reader, '"'));
return SERD_SUCCESS;
}
case '\\':
eat_byte(reader, '\\');
if (read_scharacter_escape(reader, dest)) {
return SERD_SUCCESS;
} else {
error(reader, "illegal escape `\\%c'\n", peek_byte(reader));
return SERD_ERROR;
}
case 0x9: case 0xA: case 0xD:
push_byte(reader, dest, eat_byte(reader, c));
return SERD_SUCCESS;
default:
return read_echaracter(reader, dest);
}
}
// [42] scharacter ::= ( echaracter - #x22 ) | '\"'
static inline SerdStatus
read_scharacter(SerdReader reader, Ref dest)
{
uint8_t c = peek_byte(reader);
switch (c) {
case '\\':
eat_byte(reader, '\\');
if (read_scharacter_escape(reader, dest)) {
return SERD_SUCCESS;
} else {
error(reader, "illegal escape `\\%c'\n", peek_byte(reader));
return SERD_ERROR;
}
case '\"':
return SERD_FAILURE;
default:
return read_character(reader, dest);
}
}
// Spec: [41] ucharacter ::= ( character - #x3E ) | '\>'
// Impl: [41] ucharacter ::= ( echaracter - #x3E ) | '\>'
static inline SerdStatus
read_ucharacter(SerdReader reader, Ref dest)
{
const uint8_t c = peek_byte(reader);
switch (c) {
case '\\':
eat_byte(reader, '\\');
if (read_ucharacter_escape(reader, dest)) {
return SERD_SUCCESS;
} else {
return error(reader, "illegal escape `\\%c'\n", peek_byte(reader));
}
case '>':
return SERD_FAILURE;
default:
return read_character(reader, dest);
}
}
// [10] comment ::= '#' ( [^#xA #xD] )*
static void
read_comment(SerdReader reader)
{
eat_byte(reader, '#');
uint8_t c;
while (((c = peek_byte(reader)) != 0xA) && (c != 0xD)) {
eat_byte(reader, c);
}
}
// [24] ws ::= #x9 | #xA | #xD | #x20 | comment
static inline bool
read_ws(SerdReader reader)
{
const uint8_t c = peek_byte(reader);
switch (c) {
case 0x9: case 0xA: case 0xD: case 0x20:
eat_byte(reader, c);
return true;
case '#':
read_comment(reader);
return true;
default:
return false;
}
}
static inline void
read_ws_star(SerdReader reader)
{
while (read_ws(reader)) {}
}
static inline bool
read_ws_plus(SerdReader reader)
{
TRY_RET(read_ws(reader));
read_ws_star(reader);
return true;
}
// [37] longSerdString ::= #x22 #x22 #x22 lcharacter* #x22 #x22 #x22
static Ref
read_longString(SerdReader reader)
{
eat_string(reader, "\"\"\"", 3);
Ref str = push_string(reader, "", 1);
SerdStatus st;
while (!(st = read_lcharacter(reader, str))) {}
if (st != SERD_ERROR) {
return str;
}
pop_string(reader, str);
return 0;
}
// [36] string ::= #x22 scharacter* #x22
static Ref
read_string(SerdReader reader)
{
eat_byte(reader, '\"');
Ref str = push_string(reader, "", 1);
SerdStatus st;
while (!(st = read_scharacter(reader, str))) {}
if (st != SERD_ERROR) {
eat_byte(reader, '\"');
return str;
}
pop_string(reader, str);
return 0;
}
// [35] quotedString ::= string | longSerdString
static Ref
read_quotedString(SerdReader reader)
{
uint8_t pre[3];
peek_string(reader, pre, 3);
assert(pre[0] == '\"');
switch (pre[1]) {
case '\"':
if (pre[2] == '\"')
return read_longString(reader);
else
return read_string(reader);
default:
return read_string(reader);
}
}
// [34] relativeURI ::= ucharacter*
static inline Ref
read_relativeURI(SerdReader reader)
{
Ref str = push_string(reader, "", 1);
SerdStatus st;
while (!(st = read_ucharacter(reader, str))) {}
if (st != SERD_ERROR) {
return str;
}
pop_string(reader, str);
return 0;
}
// [30] nameStartChar ::= [A-Z] | "_" | [a-z]
// | [#x00C0-#x00D6] | [#x00D8-#x00F6] | [#x00F8-#x02FF] | [#x0370-#x037D]
// | [#x037F-#x1FFF] | [#x200C-#x200D] | [#x2070-#x218F] | [#x2C00-#x2FEF]
// | [#x3001-#xD7FF] | [#xF900-#xFDCF] | [#xFDF0-#xFFFD] | [#x10000-#xEFFFF]
static inline uchar
read_nameStartChar(SerdReader reader, bool required)
{
const uint8_t c = peek_byte(reader);
if (c == '_' || is_alpha(c)) {
return eat_byte(reader, c);
} else {
if (required) {
error(reader, "illegal character `%c'\n", c);
}
return 0;
}
}
// [31] nameChar ::= nameStartChar | '-' | [0-9]
// | #x00B7 | [#x0300-#x036F] | [#x203F-#x2040]
static inline uchar
read_nameChar(SerdReader reader)
{
uchar c = read_nameStartChar(reader, false);
if (c)
return c;
switch ((c = peek_byte(reader))) {
case '-': case 0xB7: case '0': case '1': case '2': case '3': case '4':
case '5': case '6': case '7': case '8': case '9':
return eat_byte(reader, c);
default:
// TODO: 0x300-0x036F | 0x203F-0x2040
return 0;
}
return 0;
}
// [33] prefixName ::= ( nameStartChar - '_' ) nameChar*
static Ref
read_prefixName(SerdReader reader)
{
uint8_t c = peek_byte(reader);
if (c == '_') {
error(reader, "unexpected `_'\n");
return 0;
}
TRY_RET(c = read_nameStartChar(reader, false));
Ref str = push_string(reader, "", 1);
push_byte(reader, str, c);
while ((c = read_nameChar(reader)) != 0) {
push_byte(reader, str, c);
}
return str;
}
// [32] name ::= nameStartChar nameChar*
static Ref
read_name(SerdReader reader, Ref dest, bool required)
{
uchar c = read_nameStartChar(reader, required);
if (!c) {
if (required) {
error(reader, "illegal character at start of name\n");
}
return 0;
}
do {
push_byte(reader, dest, c);
} while ((c = read_nameChar(reader)) != 0);
return dest;
}
// [29] language ::= [a-z]+ ('-' [a-z0-9]+ )*
static Ref
read_language(SerdReader reader)
{
const uint8_t start = peek_byte(reader);
if (!in_range(start, 'a', 'z')) {
error(reader, "unexpected `%c'\n", start);
return 0;
}
Ref str = push_string(reader, "", 1);
push_byte(reader, str, eat_byte(reader, start));
uint8_t c;
while ((c = peek_byte(reader)) && in_range(c, 'a', 'z')) {
push_byte(reader, str, eat_byte(reader, c));
}
if (peek_byte(reader) == '-') {
push_byte(reader, str, eat_byte(reader, '-'));
while ((c = peek_byte(reader)) && (
in_range(c, 'a', 'z') || in_range(c, '0', '9'))) {
push_byte(reader, str, eat_byte(reader, c));
}
}
return str;
}
// [28] uriref ::= '<' relativeURI '>'
static Ref
read_uriref(SerdReader reader)
{
TRY_RET(eat_byte(reader, '<'));
Ref const str = read_relativeURI(reader);
if (str && eat_byte(reader, '>')) {
return str;
}
pop_string(reader, str);
return 0;
}
// [27] qname ::= prefixName? ':' name?
static Ref
read_qname(SerdReader reader)
{
Ref prefix = read_prefixName(reader);
if (!prefix) {
prefix = push_string(reader, "", 1);
}
TRY_THROW(eat_byte(reader, ':'));
push_byte(reader, prefix, ':');
Ref str = read_name(reader, prefix, false);
return str ? str : prefix;
except:
pop_string(reader, prefix);
return 0;
}
static bool
read_0_9(SerdReader reader, Ref str, bool at_least_one)
{
uint8_t c;
if (at_least_one) {
if (!is_digit((c = peek_byte(reader)))) {
return error(reader, "expected digit\n");
}
push_byte(reader, str, eat_byte(reader, c));
}
while (is_digit((c = peek_byte(reader)))) {
push_byte(reader, str, eat_byte(reader, c));
}
return true;
}
// [19] exponent ::= [eE] ('-' | '+')? [0-9]+
// [18] decimal ::= ( '-' | '+' )? ( [0-9]+ '.' [0-9]*
// | '.' ([0-9])+
// | ([0-9])+ )
// [17] double ::= ( '-' | '+' )? ( [0-9]+ '.' [0-9]* exponent
// | '.' ([0-9])+ exponent
// | ([0-9])+ exponent )
// [16] integer ::= ( '-' | '+' ) ? [0-9]+
static bool
read_number(SerdReader reader, Node* dest)
{
#define XSD_DECIMAL NS_XSD "decimal"
#define XSD_DOUBLE NS_XSD "double"
#define XSD_INTEGER NS_XSD "integer"
Ref str = push_string(reader, "", 1);
uint8_t c = peek_byte(reader);
bool has_decimal = false;
Ref datatype = 0;
if (c == '-' || c == '+') {
push_byte(reader, str, eat_byte(reader, c));
}
if ((c = peek_byte(reader)) == '.') {
has_decimal = true;
// decimal case 2 (e.g. '.0' or `-.0' or `+.0')
push_byte(reader, str, eat_byte(reader, c));
TRY_THROW(read_0_9(reader, str, true));
} else {
// all other cases ::= ( '-' | '+' ) [0-9]+ ( . )? ( [0-9]+ )? ...
TRY_THROW(read_0_9(reader, str, true));
if ((c = peek_byte(reader)) == '.') {
has_decimal = true;
push_byte(reader, str, eat_byte(reader, c));
TRY_THROW(read_0_9(reader, str, false));
}
}
c = peek_byte(reader);
if (c == 'e' || c == 'E') {
// double
push_byte(reader, str, eat_byte(reader, c));
switch ((c = peek_byte(reader))) {
case '+': case '-':
push_byte(reader, str, eat_byte(reader, c));
default: break;
}
read_0_9(reader, str, true);
datatype = push_string(reader, XSD_DOUBLE, strlen(XSD_DOUBLE) + 1);
} else if (has_decimal) {
datatype = push_string(reader, XSD_DECIMAL, strlen(XSD_DECIMAL) + 1);
} else {
datatype = push_string(reader, XSD_INTEGER, strlen(XSD_INTEGER) + 1);
}
*dest = make_node(SERD_LITERAL, str, datatype, 0);
assert(dest->value);
return true;
except:
pop_string(reader, datatype);
pop_string(reader, str);
return false;
}
// [25] resource ::= uriref | qname
static bool
read_resource(SerdReader reader, Node* dest)
{
switch (peek_byte(reader)) {
case '<':
*dest = make_node(SERD_URI, read_uriref(reader), 0, 0);
break;
default:
*dest = make_node(SERD_CURIE, read_qname(reader), 0, 0);
}
return (dest->value != 0);
}
// [14] literal ::= quotedString ( '@' language )? | datatypeSerdString
// | integer | double | decimal | boolean
static bool
read_literal(SerdReader reader, Node* dest)
{
Ref str = 0;
Node datatype = INTERNAL_NODE_NULL;
const uint8_t c = peek_byte(reader);
if (c == '-' || c == '+' || c == '.' || is_digit(c)) {
return read_number(reader, dest);
} else if (c == '\"') {
str = read_quotedString(reader);
if (!str) {
return false;
}
Ref lang = 0;
switch (peek_byte(reader)) {
case '^':
eat_byte(reader, '^');
eat_byte(reader, '^');
TRY_THROW(read_resource(reader, &datatype));
break;
case '@':
eat_byte(reader, '@');
TRY_THROW(lang = read_language(reader));
}
*dest = make_node(SERD_LITERAL, str, datatype.value, lang);
} else {
return error(reader, "Unknown literal type\n");
}
return true;
except:
pop_string(reader, str);
return false;
}
// [12] predicate ::= resource
static bool
read_predicate(SerdReader reader, Node* dest)
{
return read_resource(reader, dest);
}
// [9] verb ::= predicate | 'a'
static bool
read_verb(SerdReader reader, Node* dest)
{
uint8_t pre[2];
peek_string(reader, pre, 2);
switch (pre[0]) {
case 'a':
switch (pre[1]) {
case 0x9: case 0xA: case 0xD: case 0x20:
eat_byte(reader, 'a');
*dest = make_node(SERD_URI,
push_string(reader, NS_RDF "type", 48), 0, 0);
return true;
default: break; // fall through
}
default:
return read_predicate(reader, dest);
}
}
// [26] nodeID ::= '_:' name
static Ref
read_nodeID(SerdReader reader)
{
eat_byte(reader, '_');
eat_byte(reader, ':');
Ref str = push_string(reader, "", 1);
return read_name(reader, str, true);
}
static Ref
blank_id(SerdReader reader)
{
const char* prefix = reader->blank_prefix
? (const char*)reader->blank_prefix
: "genid";
char str[32]; // FIXME: ensure length of reader->blank_prefix is OK
const int len = snprintf(str, sizeof(str), "%s%u",
prefix, reader->next_id++);
return push_string(reader, str, len + 1);
}
// Spec: [21] blank ::= nodeID | '[]'
// | '[' predicateObjectList ']' | collection
// Impl: [21] blank ::= nodeID | '[ ws* ]'
// | '[' ws* predicateObjectList ws* ']' | collection
static bool
read_blank(SerdReader reader, ReadContext ctx, Node* dest)
{
switch (peek_byte(reader)) {
case '_':
*dest = make_node(SERD_BLANK_ID, read_nodeID(reader), 0, 0);
return true;
case '[':
eat_byte(reader, '[');
read_ws_star(reader);
if (peek_byte(reader) == ']') {
eat_byte(reader, ']');
*dest = make_node(SERD_BLANK_ID, blank_id(reader), 0, 0);
if (ctx.subject) {
TRY_RET(emit_statement(reader, ctx.graph, ctx.subject, ctx.predicate, dest));
}
return true;
}
*dest = make_node(SERD_ANON_BEGIN, blank_id(reader), 0, 0);
if (ctx.subject) {
TRY_RET(emit_statement(reader, ctx.graph, ctx.subject, ctx.predicate, dest));
dest->type = SERD_ANON;
}
ctx.subject = dest;
read_predicateObjectList(reader, ctx);
read_ws_star(reader);
eat_byte(reader, ']');
if (reader->end_sink) {
const SerdNode end = public_node(reader, dest);
reader->end_sink(reader->handle, &end);
}
return true;
case '(':
if (read_collection(reader, ctx, dest)) {
if (ctx.subject) {
TRY_RET(emit_statement(reader, ctx.graph, ctx.subject, ctx.predicate, dest));
}
return true;
}
return false;
default:
return error(reader, "illegal blank node\n");
}
}
inline static bool
is_object_end(const uint8_t c)
{
switch (c) {
case 0x9: case 0xA: case 0xD: case 0x20: case '\0':
case '#': case '.': case ';':
return true;
default:
return false;
}
}
// [13] object ::= resource | blank | literal
// Recurses, calling statement_sink for every statement encountered.
// Leaves stack in original calling state (i.e. pops everything it pushes).
static bool
read_object(SerdReader reader, ReadContext ctx)
{
static const char* const XSD_BOOLEAN = NS_XSD "boolean";
static const size_t XSD_BOOLEAN_LEN = 40;
uint8_t pre[6];
bool ret = false;
bool emit = (ctx.subject != 0);
Node o = INTERNAL_NODE_NULL;
const uint8_t c = peek_byte(reader);
switch (c) {
case '\0':
case ')':
return false;
case '[': case '(':
emit = false;
// fall through
case '_':
TRY_THROW(ret = read_blank(reader, ctx, &o));
break;
case '<': case ':':
TRY_THROW(ret = read_resource(reader, &o));
break;
case '\"': case '+': case '-':
case '0': case '1': case '2': case '3': case '4':
case '5': case '6': case '7': case '8': case '9':
TRY_THROW(ret = read_literal(reader, &o));
break;
case '.':
TRY_THROW(ret = read_literal(reader, &o));
break;
default:
/* Either a boolean literal, or a qname.
Unfortunately there is no way to distinguish these without
readahead, since `true' or `false' could be the start of a qname.
*/
peek_string(reader, pre, 6);
if (!memcmp(pre, "true", 4) && is_object_end(pre[4])) {
eat_string(reader, "true", 4);
const Ref value = push_string(reader, "true", 5);
const Ref datatype = push_string(reader, XSD_BOOLEAN, XSD_BOOLEAN_LEN + 1);
o = make_node(SERD_LITERAL, value, datatype, 0);
} else if (!memcmp(pre, "false", 5) && is_object_end(pre[5])) {
eat_string(reader, "false", 5);
const Ref value = push_string(reader, "false", 6);
const Ref datatype = push_string(reader, XSD_BOOLEAN, XSD_BOOLEAN_LEN + 1);
o = make_node(SERD_LITERAL, value, datatype, 0);
} else if (!is_object_end(c)) {
o = make_node(SERD_CURIE, read_qname(reader), 0, 0);
}
ret = o.value;
}
if (ret && emit) {
assert(o.value);
ret = emit_statement(reader, ctx.graph, ctx.subject, ctx.predicate, &o);
}
except:
pop_string(reader, o.lang);
pop_string(reader, o.datatype);
pop_string(reader, o.value);
return ret;
}
// Spec: [8] objectList ::= object ( ',' object )*
// Impl: [8] objectList ::= object ( ws* ',' ws* object )*
static bool
read_objectList(SerdReader reader, ReadContext ctx)
{
TRY_RET(read_object(reader, ctx));
read_ws_star(reader);
while (peek_byte(reader) == ',') {
eat_byte(reader, ',');
read_ws_star(reader);
TRY_RET(read_object(reader, ctx));
read_ws_star(reader);
}
return true;
}
// Spec: [7] predicateObjectList ::= verb objectList
// (';' verb objectList)* (';')?
// Impl: [7] predicateObjectList ::= verb ws+ objectList
// (ws* ';' ws* verb ws+ objectList)* (';')?
static bool
read_predicateObjectList(SerdReader reader, ReadContext ctx)
{
if (reader->eof) {
return false;
}
Node predicate = INTERNAL_NODE_NULL;
TRY_RET(read_verb(reader, &predicate));
TRY_THROW(read_ws_plus(reader));
ctx.predicate = &predicate;
TRY_THROW(read_objectList(reader, ctx));
pop_string(reader, predicate.value);
predicate.value = 0;
read_ws_star(reader);
while (peek_byte(reader) == ';') {
eat_byte(reader, ';');
read_ws_star(reader);
switch (peek_byte(reader)) {
case '.': case ']':
return true;
default:
TRY_THROW(read_verb(reader, &predicate));
ctx.predicate = &predicate;
TRY_THROW(read_ws_plus(reader));
TRY_THROW(read_objectList(reader, ctx));
pop_string(reader, predicate.value);
predicate.value = 0;
read_ws_star(reader);
}
}
return true;
except:
pop_string(reader, predicate.value);
return false;
}
/** Recursive helper for read_collection. */
static bool
read_collection_rec(SerdReader reader, ReadContext ctx)
{
read_ws_star(reader);
if (peek_byte(reader) == ')') {
eat_byte(reader, ')');
TRY_RET(emit_statement(reader, NULL, ctx.subject,
&reader->rdf_rest, &reader->rdf_nil));
return false;
} else {
const Node rest = make_node(SERD_BLANK_ID, blank_id(reader), 0, 0);
TRY_RET(emit_statement(reader, ctx.graph, ctx.subject, &reader->rdf_rest, &rest));
ctx.subject = &rest;
ctx.predicate = &reader->rdf_first;
if (read_object(reader, ctx)) {
read_collection_rec(reader, ctx);
pop_string(reader, rest.value);
return true;
} else {
pop_string(reader, rest.value);
return false;
}
}
}
// [22] itemList ::= object+
// [23] collection ::= '(' itemList? ')'
static bool
read_collection(SerdReader reader, ReadContext ctx, Node* dest)
{
TRY_RET(eat_byte(reader, '('));
read_ws_star(reader);
if (peek_byte(reader) == ')') { // Empty collection
eat_byte(reader, ')');
*dest = reader->rdf_nil;
return true;
}
*dest = make_node(SERD_BLANK_ID, blank_id(reader), 0, 0);
ctx.subject = dest;
ctx.predicate = &reader->rdf_first;
if (!read_object(reader, ctx)) {
return error(reader, "unexpected end of collection\n");
}
ctx.subject = dest;
return read_collection_rec(reader, ctx);
}
// [11] subject ::= resource | blank
static Node
read_subject(SerdReader reader, ReadContext ctx)
{
Node subject = INTERNAL_NODE_NULL;
switch (peek_byte(reader)) {
case '[': case '(': case '_':
read_blank(reader, ctx, &subject);
break;
default:
read_resource(reader, &subject);
}
return subject;
}
// Spec: [6] triples ::= subject predicateObjectList
// Impl: [6] triples ::= subject ws+ predicateObjectList
static bool
read_triples(SerdReader reader, ReadContext ctx)
{
const Node subject = read_subject(reader, ctx);
bool ret = false;
if (subject.value != 0) {
ctx.subject = &subject;
TRY_RET(read_ws_plus(reader));
ret = read_predicateObjectList(reader, ctx);
pop_string(reader, subject.value);
}
ctx.subject = ctx.predicate = 0;
return ret;
}
// [5] base ::= '@base' ws+ uriref
static bool
read_base(SerdReader reader)
{
// `@' is already eaten in read_directive
eat_string(reader, "base", 4);
TRY_RET(read_ws_plus(reader));
Ref uri;
TRY_RET(uri = read_uriref(reader));
const SerdNode uri_node = public_node_from_ref(reader, SERD_URI, uri);
reader->base_sink(reader->handle, &uri_node);
pop_string(reader, uri);
return true;
}
// Spec: [4] prefixID ::= '@prefix' ws+ prefixName? ':' uriref
// Impl: [4] prefixID ::= '@prefix' ws+ prefixName? ':' ws* uriref
static bool
read_prefixID(SerdReader reader)
{
// `@' is already eaten in read_directive
eat_string(reader, "prefix", 6);
TRY_RET(read_ws_plus(reader));
bool ret = false;
Ref name = read_prefixName(reader);
if (!name) {
name = push_string(reader, "", 1);
}
TRY_THROW(eat_byte(reader, ':') == ':');
read_ws_star(reader);
Ref uri = 0;
TRY_THROW(uri = read_uriref(reader));
const SerdNode name_node = public_node_from_ref(reader, SERD_LITERAL, name);
const SerdNode uri_node = public_node_from_ref(reader, SERD_URI, uri);
ret = reader->prefix_sink(reader->handle, &name_node, &uri_node);
pop_string(reader, uri);
except:
pop_string(reader, name);
return ret;
}
// [3] directive ::= prefixID | base
static bool
read_directive(SerdReader reader)
{
eat_byte(reader, '@');
switch (peek_byte(reader)) {
case 'b':
return read_base(reader);
case 'p':
return read_prefixID(reader);
default:
return error(reader, "illegal directive\n");
}
}
// Spec: [1] statement ::= directive '.' | triples '.' | ws+
// Impl: [1] statement ::= directive ws* '.' | triples ws* '.' | ws+
static bool
read_statement(SerdReader reader)
{
ReadContext ctx = { 0, 0, 0 };
read_ws_star(reader);
if (reader->eof) {
return true;
}
switch (peek_byte(reader)) {
case '@':
TRY_RET(read_directive(reader));
break;
default:
TRY_RET(read_triples(reader, ctx));
break;
}
read_ws_star(reader);
return eat_byte(reader, '.');
}
// [1] turtleDoc ::= statement
static bool
read_turtleDoc(SerdReader reader)
{
while (!reader->eof) {
TRY_RET(read_statement(reader));
}
return true;
}
SERD_API
SerdReader
serd_reader_new(SerdSyntax syntax,
void* handle,
SerdBaseSink base_sink,
SerdPrefixSink prefix_sink,
SerdStatementSink statement_sink,
SerdEndSink end_sink)
{
const Cursor cur = { NULL, 0, 0 };
SerdReader me = malloc(sizeof(struct SerdReaderImpl));
me->handle = handle;
me->base_sink = base_sink;
me->prefix_sink = prefix_sink;
me->statement_sink = statement_sink;
me->end_sink = end_sink;
me->fd = 0;
me->stack = serd_stack_new(STACK_PAGE_SIZE);
me->cur = cur;
me->blank_prefix = NULL;
me->next_id = 1;
me->read_buf = 0;
me->read_head = 0;
me->eof = false;
#ifdef SERD_STACK_CHECK
me->alloc_stack = 0;
me->n_allocs = 0;
#endif
#define RDF_FIRST NS_RDF "first"
#define RDF_REST NS_RDF "rest"
#define RDF_NIL NS_RDF "nil"
me->rdf_first = make_node(SERD_URI, push_string(me, RDF_FIRST, 49), 0, 0);
me->rdf_rest = make_node(SERD_URI, push_string(me, RDF_REST, 48), 0, 0);
me->rdf_nil = make_node(SERD_URI, push_string(me, RDF_NIL, 47), 0, 0);
return me;
}
SERD_API
void
serd_reader_free(SerdReader reader)
{
SerdReader const me = (SerdReader)reader;
pop_string(me, me->rdf_nil.value);
pop_string(me, me->rdf_rest.value);
pop_string(me, me->rdf_first.value);
#ifdef SERD_STACK_CHECK
free(me->alloc_stack);
#endif
free(me->stack.buf);
free(me);
}
SERD_API
void
serd_reader_set_blank_prefix(SerdReader reader,
const uint8_t* prefix)
{
reader->blank_prefix = prefix;
}
SERD_API
bool
serd_reader_read_file(SerdReader me, FILE* file, const uint8_t* name)
{
const Cursor cur = { name, 1, 1 };
me->fd = file;
me->read_buf = (uint8_t*)malloc(READ_BUF_LEN * 2);
me->read_head = 0;
me->cur = cur;
me->from_file = true;
/* Read into the second page of the buffer. Occasionally peek_string
will move the read_head to before this point when readahead causes
a page fault.
*/
memset(me->read_buf, '\0', READ_BUF_LEN * 2);
me->read_buf += READ_BUF_LEN;
const bool ret = !page(me) || read_turtleDoc(me);
free(me->read_buf - READ_BUF_LEN);
me->fd = 0;
me->read_buf = NULL;
return ret;
}
SERD_API
bool
serd_reader_read_string(SerdReader me, const uint8_t* utf8)
{
const Cursor cur = { (const uint8_t*)"(string)", 1, 1 };
me->read_buf = (uint8_t*)utf8;
me->read_head = 0;
me->cur = cur;
me->from_file = false;
const bool ret = read_turtleDoc(me);
me->read_buf = NULL;
return ret;
}
SERD_API
SerdReadState
serd_read_state_new(SerdEnv env,
const uint8_t* base_uri_str)
{
SerdReadState state = malloc(sizeof(struct SerdReadStateImpl));
SerdURI base_base_uri = SERD_URI_NULL;
state->env = env;
state->base_uri_node = serd_node_new_uri_from_string(
base_uri_str, &base_base_uri, &state->base_uri);
return state;
}
SERD_API
void
serd_read_state_free(SerdReadState state)
{
serd_node_free(&state->base_uri_node);
free(state);
}
SERD_API
SerdNode
serd_read_state_get_base_uri(SerdReadState state,
SerdURI* out)
{
*out = state->base_uri;
return state->base_uri_node;
}
SERD_API
bool
serd_read_state_set_base_uri(SerdReadState state,
const SerdNode* uri_node)
{
// Resolve base URI and create a new node and URI for it
SerdURI base_uri;
SerdNode base_uri_node = serd_node_new_uri_from_node(
uri_node, &state->base_uri, &base_uri);
if (base_uri_node.buf) {
// Replace the current base URI
serd_node_free(&state->base_uri_node);
state->base_uri_node = base_uri_node;
state->base_uri = base_uri;
return true;
}
return false;
}
SERD_API
bool
serd_read_state_set_prefix(SerdReadState state,
const SerdNode* name,
const SerdNode* uri_node)
{
if (serd_uri_string_has_scheme(uri_node->buf)) {
// Set prefix to absolute URI
serd_env_add(state->env, name, uri_node);
return true;
} else {
// Resolve relative URI and create a new node and URI for it
SerdURI abs_uri;
SerdNode abs_uri_node = serd_node_new_uri_from_node(
uri_node, &state->base_uri, &abs_uri);
if (!abs_uri_node.buf) {
return false;
}
// Set prefix to resolved (absolute) URI
serd_env_add(state->env, name, &abs_uri_node);
serd_node_free(&abs_uri_node);
return true;
}
return false;
}