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wine/dlls/webservices/reader.c
Hans Leidekker 18d32bfb55 webservices: Support WS_CHARSET_UTF16LE for buffer input. 
Signed-off-by: Hans Leidekker <hans@codeweavers.com>
Signed-off-by: Alexandre Julliard <julliard@winehq.org>
2020-03-27 21:16:13 +01:00

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/*
* Copyright 2015, 2016 Hans Leidekker for CodeWeavers
*
* This library is free software; you can redistribute it and/or
* modify it under the terms of the GNU Lesser General Public
* License as published by the Free Software Foundation; either
* version 2.1 of the License, or (at your option) any later version.
*
* This library 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
* Lesser General Public License for more details.
*
* You should have received a copy of the GNU Lesser General Public
* License along with this library; if not, write to the Free Software
* Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301, USA
*/
#include <stdarg.h>
#include <assert.h>
#include <float.h>
#include <locale.h>
#include "windef.h"
#include "winbase.h"
#include "winnls.h"
#include "webservices.h"
#include "wine/debug.h"
#include "wine/heap.h"
#include "wine/list.h"
#include "webservices_private.h"
WINE_DEFAULT_DEBUG_CHANNEL(webservices);
ULONG prop_size( const struct prop_desc *desc, ULONG count )
{
ULONG i, ret = count * sizeof(struct prop);
for (i = 0; i < count; i++) ret += desc[i].size;
return ret;
}
void prop_init( const struct prop_desc *desc, ULONG count, struct prop *prop, void *data )
{
ULONG i;
char *ptr = data;
for (i = 0; i < count; i++)
{
prop[i].value = ptr;
prop[i].size = desc[i].size;
prop[i].readonly = desc[i].readonly;
prop[i].writeonly = desc[i].writeonly;
ptr += prop[i].size;
}
}
HRESULT prop_set( const struct prop *prop, ULONG count, ULONG id, const void *value, ULONG size )
{
if (id >= count || size != prop[id].size || prop[id].readonly) return E_INVALIDARG;
memcpy( prop[id].value, value, size );
return S_OK;
}
HRESULT prop_get( const struct prop *prop, ULONG count, ULONG id, void *buf, ULONG size )
{
if (id >= count || size != prop[id].size || prop[id].writeonly) return E_INVALIDARG;
memcpy( buf, prop[id].value, prop[id].size );
return S_OK;
}
struct node *alloc_node( WS_XML_NODE_TYPE type )
{
struct node *ret;
if (!(ret = heap_alloc_zero( sizeof(*ret) ))) return NULL;
ret->hdr.node.nodeType = type;
list_init( &ret->entry );
list_init( &ret->children );
return ret;
}
void free_attribute( WS_XML_ATTRIBUTE *attr )
{
if (!attr) return;
free_xml_string( attr->prefix );
free_xml_string( attr->localName );
free_xml_string( attr->ns );
heap_free( attr->value );
heap_free( attr );
}
void free_node( struct node *node )
{
if (!node) return;
switch (node_type( node ))
{
case WS_XML_NODE_TYPE_ELEMENT:
{
WS_XML_ELEMENT_NODE *elem = &node->hdr;
ULONG i;
for (i = 0; i < elem->attributeCount; i++) free_attribute( elem->attributes[i] );
heap_free( elem->attributes );
free_xml_string( elem->prefix );
free_xml_string( elem->localName );
free_xml_string( elem->ns );
break;
}
case WS_XML_NODE_TYPE_TEXT:
{
WS_XML_TEXT_NODE *text = (WS_XML_TEXT_NODE *)node;
heap_free( text->text );
break;
}
case WS_XML_NODE_TYPE_COMMENT:
{
WS_XML_COMMENT_NODE *comment = (WS_XML_COMMENT_NODE *)node;
heap_free( comment->value.bytes );
break;
}
case WS_XML_NODE_TYPE_CDATA:
case WS_XML_NODE_TYPE_END_CDATA:
case WS_XML_NODE_TYPE_END_ELEMENT:
case WS_XML_NODE_TYPE_EOF:
case WS_XML_NODE_TYPE_BOF:
break;
default:
ERR( "unhandled type %u\n", node_type( node ) );
break;
}
heap_free( node );
}
void destroy_nodes( struct node *node )
{
struct list *ptr;
if (!node) return;
while ((ptr = list_head( &node->children )))
{
struct node *child = LIST_ENTRY( ptr, struct node, entry );
list_remove( &child->entry );
destroy_nodes( child );
}
free_node( node );
}
static WS_XML_ATTRIBUTE *dup_attribute( const WS_XML_ATTRIBUTE *src, WS_XML_WRITER_ENCODING_TYPE enc )
{
WS_XML_ATTRIBUTE *dst;
HRESULT hr;
if (!(dst = heap_alloc_zero( sizeof(*dst) ))) return NULL;
dst->singleQuote = src->singleQuote;
dst->isXmlNs = src->isXmlNs;
if (src->prefix && !(dst->prefix = dup_xml_string( src->prefix, FALSE ))) goto error;
if (src->localName && !(dst->localName = dup_xml_string( src->localName, FALSE ))) goto error;
if (src->ns && !(dst->ns = dup_xml_string( src->ns, FALSE ))) goto error;
if (src->value)
{
switch (enc)
{
case WS_XML_WRITER_ENCODING_TYPE_BINARY:
if ((hr = text_to_text( src->value, NULL, NULL, &dst->value )) != S_OK) goto error;
break;
case WS_XML_WRITER_ENCODING_TYPE_TEXT:
if ((hr = text_to_utf8text( src->value, NULL, NULL, (WS_XML_UTF8_TEXT **)&dst->value )) != S_OK)
goto error;
break;
default:
ERR( "unhandled encoding %u\n", enc );
goto error;
}
}
return dst;
error:
free_attribute( dst );
return NULL;
}
static WS_XML_ATTRIBUTE **dup_attributes( WS_XML_ATTRIBUTE * const *src, ULONG count,
WS_XML_WRITER_ENCODING_TYPE enc )
{
WS_XML_ATTRIBUTE **dst;
ULONG i;
if (!(dst = heap_alloc( sizeof(*dst) * count ))) return NULL;
for (i = 0; i < count; i++)
{
if (!(dst[i] = dup_attribute( src[i], enc )))
{
for (; i > 0; i--) free_attribute( dst[i - 1] );
heap_free( dst );
return NULL;
}
}
return dst;
}
static struct node *dup_element_node( const WS_XML_ELEMENT_NODE *src, WS_XML_WRITER_ENCODING_TYPE enc )
{
struct node *node;
WS_XML_ELEMENT_NODE *dst;
ULONG count = src->attributeCount;
WS_XML_ATTRIBUTE **attrs = src->attributes;
const WS_XML_STRING *prefix = (src->prefix && src->prefix->length) ? src->prefix : NULL;
const WS_XML_STRING *localname = src->localName;
const WS_XML_STRING *ns = src->ns;
if (!(node = alloc_node( WS_XML_NODE_TYPE_ELEMENT ))) return NULL;
dst = &node->hdr;
if (count && !(dst->attributes = dup_attributes( attrs, count, enc ))) goto error;
dst->attributeCount = count;
if (prefix && !(dst->prefix = dup_xml_string( prefix, FALSE ))) goto error;
if (localname && !(dst->localName = dup_xml_string( localname, FALSE ))) goto error;
if (ns && !(dst->ns = dup_xml_string( ns, FALSE ))) goto error;
return node;
error:
free_node( node );
return NULL;
}
static struct node *dup_text_node( const WS_XML_TEXT_NODE *src, WS_XML_WRITER_ENCODING_TYPE enc )
{
struct node *node;
WS_XML_TEXT_NODE *dst;
HRESULT hr;
if (!(node = alloc_node( WS_XML_NODE_TYPE_TEXT ))) return NULL;
dst = (WS_XML_TEXT_NODE *)node;
if (!src->text) return node;
switch (enc)
{
case WS_XML_WRITER_ENCODING_TYPE_BINARY:
hr = text_to_text( src->text, NULL, NULL, &dst->text );
break;
case WS_XML_WRITER_ENCODING_TYPE_TEXT:
hr = text_to_utf8text( src->text, NULL, NULL, (WS_XML_UTF8_TEXT **)&dst->text );
break;
default:
ERR( "unhandled encoding %u\n", enc );
free_node( node );
return NULL;
}
if (hr != S_OK)
{
free_node( node );
return NULL;
}
return node;
}
static struct node *dup_comment_node( const WS_XML_COMMENT_NODE *src )
{
struct node *node;
WS_XML_COMMENT_NODE *dst;
if (!(node = alloc_node( WS_XML_NODE_TYPE_COMMENT ))) return NULL;
dst = (WS_XML_COMMENT_NODE *)node;
if (src->value.length && !(dst->value.bytes = heap_alloc( src->value.length )))
{
free_node( node );
return NULL;
}
memcpy( dst->value.bytes, src->value.bytes, src->value.length );
dst->value.length = src->value.length;
return node;
}
static struct node *dup_node( const struct node *src, WS_XML_WRITER_ENCODING_TYPE enc )
{
switch (node_type( src ))
{
case WS_XML_NODE_TYPE_ELEMENT:
return dup_element_node( &src->hdr, enc );
case WS_XML_NODE_TYPE_TEXT:
return dup_text_node( (const WS_XML_TEXT_NODE *)src, enc );
case WS_XML_NODE_TYPE_COMMENT:
return dup_comment_node( (const WS_XML_COMMENT_NODE *)src );
case WS_XML_NODE_TYPE_CDATA:
case WS_XML_NODE_TYPE_END_CDATA:
case WS_XML_NODE_TYPE_END_ELEMENT:
case WS_XML_NODE_TYPE_EOF:
case WS_XML_NODE_TYPE_BOF:
return alloc_node( node_type( src ) );
default:
ERR( "unhandled type %u\n", node_type( src ) );
break;
}
return NULL;
}
static HRESULT dup_tree( const struct node *src, WS_XML_WRITER_ENCODING_TYPE enc, struct node **dst )
{
struct node *parent;
const struct node *child;
if (!*dst && !(*dst = dup_node( src, enc ))) return E_OUTOFMEMORY;
parent = *dst;
LIST_FOR_EACH_ENTRY( child, &src->children, struct node, entry )
{
HRESULT hr = E_OUTOFMEMORY;
struct node *new_child;
if (!(new_child = dup_node( child, enc )) || (hr = dup_tree( child, enc, &new_child )) != S_OK)
{
destroy_nodes( *dst );
return hr;
}
new_child->parent = parent;
list_add_tail( &parent->children, &new_child->entry );
}
return S_OK;
}
static const struct prop_desc reader_props[] =
{
{ sizeof(ULONG), FALSE }, /* WS_XML_READER_PROPERTY_MAX_DEPTH */
{ sizeof(BOOL), FALSE }, /* WS_XML_READER_PROPERTY_ALLOW_FRAGMENT */
{ sizeof(ULONG), FALSE }, /* WS_XML_READER_PROPERTY_MAX_ATTRIBUTES */
{ sizeof(BOOL), FALSE }, /* WS_XML_READER_PROPERTY_READ_DECLARATION */
{ sizeof(WS_CHARSET), FALSE }, /* WS_XML_READER_PROPERTY_CHARSET */
{ sizeof(ULONGLONG), TRUE }, /* WS_XML_READER_PROPERTY_ROW */
{ sizeof(ULONGLONG), TRUE }, /* WS_XML_READER_PROPERTY_COLUMN */
{ sizeof(ULONG), FALSE }, /* WS_XML_READER_PROPERTY_UTF8_TRIM_SIZE */
{ sizeof(ULONG), FALSE }, /* WS_XML_READER_PROPERTY_STREAM_BUFFER_SIZE */
{ sizeof(BOOL), TRUE }, /* WS_XML_READER_PROPERTY_IN_ATTRIBUTE */
{ sizeof(ULONG), FALSE }, /* WS_XML_READER_PROPERTY_STREAM_MAX_ROOT_MIME_PART_SIZE */
{ sizeof(ULONG), FALSE }, /* WS_XML_READER_PROPERTY_STREAM_MAX_MIME_HEADERS_SIZE */
{ sizeof(ULONG), FALSE }, /* WS_XML_READER_PROPERTY_MAX_MIME_PARTS */
{ sizeof(BOOL), FALSE }, /* WS_XML_READER_PROPERTY_ALLOW_INVALID_CHARACTER_REFERENCES */
{ sizeof(ULONG), FALSE }, /* WS_XML_READER_PROPERTY_MAX_NAMESPACES */
};
enum reader_state
{
READER_STATE_INITIAL,
READER_STATE_BOF,
READER_STATE_STARTELEMENT,
READER_STATE_STARTATTRIBUTE,
READER_STATE_STARTCDATA,
READER_STATE_CDATA,
READER_STATE_TEXT,
READER_STATE_ENDELEMENT,
READER_STATE_ENDCDATA,
READER_STATE_COMMENT,
READER_STATE_EOF
};
struct prefix
{
WS_XML_STRING *str;
WS_XML_STRING *ns;
};
struct reader
{
ULONG magic;
CRITICAL_SECTION cs;
ULONG read_size;
ULONG read_pos;
const unsigned char *read_bufptr;
enum reader_state state;
struct node *root;
struct node *current;
ULONG current_attr;
struct node *last;
struct prefix *prefixes;
ULONG nb_prefixes;
ULONG nb_prefixes_allocated;
WS_XML_READER_ENCODING_TYPE input_enc;
WS_CHARSET input_charset;
WS_XML_READER_INPUT_TYPE input_type;
WS_READ_CALLBACK input_cb;
void *input_cb_state;
struct xmlbuf *input_buf;
unsigned char *input_conv;
ULONG input_size;
ULONG text_conv_offset;
unsigned char *stream_buf;
const WS_XML_DICTIONARY *dict_static;
WS_XML_DICTIONARY *dict;
ULONG prop_count;
struct prop prop[ARRAY_SIZE( reader_props )];
};
#define READER_MAGIC (('R' << 24) | ('E' << 16) | ('A' << 8) | 'D')
static struct reader *alloc_reader(void)
{
static const ULONG count = ARRAY_SIZE( reader_props );
struct reader *ret;
ULONG size = sizeof(*ret) + prop_size( reader_props, count );
if (!(ret = heap_alloc_zero( size ))) return NULL;
if (!(ret->prefixes = heap_alloc_zero( sizeof(*ret->prefixes) )))
{
heap_free( ret );
return NULL;
}
ret->nb_prefixes = ret->nb_prefixes_allocated = 1;
ret->magic = READER_MAGIC;
InitializeCriticalSection( &ret->cs );
ret->cs.DebugInfo->Spare[0] = (DWORD_PTR)(__FILE__ ": reader.cs");
prop_init( reader_props, count, ret->prop, &ret[1] );
ret->prop_count = count;
return ret;
}
static void clear_prefixes( struct prefix *prefixes, ULONG count )
{
ULONG i;
for (i = 0; i < count; i++)
{
free_xml_string( prefixes[i].str );
prefixes[i].str = NULL;
free_xml_string( prefixes[i].ns );
prefixes[i].ns = NULL;
}
}
static HRESULT set_prefix( struct prefix *prefix, const WS_XML_STRING *str, const WS_XML_STRING *ns )
{
if (str)
{
free_xml_string( prefix->str );
if (!(prefix->str = dup_xml_string( str, FALSE ))) return E_OUTOFMEMORY;
}
if (prefix->ns) free_xml_string( prefix->ns );
if (!(prefix->ns = dup_xml_string( ns, FALSE ))) return E_OUTOFMEMORY;
return S_OK;
}
static HRESULT bind_prefix( struct reader *reader, const WS_XML_STRING *prefix, const WS_XML_STRING *ns )
{
ULONG i;
HRESULT hr;
for (i = 0; i < reader->nb_prefixes; i++)
{
if (WsXmlStringEquals( prefix, reader->prefixes[i].str, NULL ) == S_OK)
return set_prefix( &reader->prefixes[i], NULL, ns );
}
if (i >= reader->nb_prefixes_allocated)
{
ULONG new_size = reader->nb_prefixes_allocated * sizeof(*reader->prefixes) * 2;
struct prefix *tmp = heap_realloc_zero( reader->prefixes, new_size );
if (!tmp) return E_OUTOFMEMORY;
reader->prefixes = tmp;
reader->nb_prefixes_allocated *= 2;
}
if ((hr = set_prefix( &reader->prefixes[i], prefix, ns )) != S_OK) return hr;
reader->nb_prefixes++;
return S_OK;
}
static const WS_XML_STRING *get_namespace( struct reader *reader, const WS_XML_STRING *prefix )
{
ULONG i;
for (i = 0; i < reader->nb_prefixes; i++)
{
if (WsXmlStringEquals( prefix, reader->prefixes[i].str, NULL ) == S_OK)
return reader->prefixes[i].ns;
}
return NULL;
}
static void read_insert_eof( struct reader *reader, struct node *eof )
{
if (!reader->root) reader->root = eof;
else
{
eof->parent = reader->root;
list_add_tail( &reader->root->children, &eof->entry );
}
reader->current = reader->last = eof;
}
static void read_insert_bof( struct reader *reader, struct node *bof )
{
reader->root->parent = bof;
list_add_tail( &bof->children, &reader->root->entry );
reader->current = reader->last = reader->root = bof;
}
static void read_insert_node( struct reader *reader, struct node *parent, struct node *node )
{
node->parent = parent;
list_add_before( list_tail( &parent->children ), &node->entry );
reader->current = reader->last = node;
}
static void free_reader( struct reader *reader )
{
destroy_nodes( reader->root );
clear_prefixes( reader->prefixes, reader->nb_prefixes );
heap_free( reader->prefixes );
heap_free( reader->stream_buf );
heap_free( reader->input_conv );
reader->cs.DebugInfo->Spare[0] = 0;
DeleteCriticalSection( &reader->cs );
heap_free( reader );
}
static HRESULT init_reader( struct reader *reader )
{
static const WS_XML_STRING empty = {0, NULL};
struct node *node;
HRESULT hr;
reader->state = READER_STATE_INITIAL;
destroy_nodes( reader->root );
reader->root = reader->current = NULL;
reader->current_attr = 0;
clear_prefixes( reader->prefixes, reader->nb_prefixes );
reader->nb_prefixes = 1;
if ((hr = bind_prefix( reader, &empty, &empty )) != S_OK) return hr;
if (!(node = alloc_node( WS_XML_NODE_TYPE_EOF ))) return E_OUTOFMEMORY;
read_insert_eof( reader, node );
reader->input_enc = WS_XML_READER_ENCODING_TYPE_TEXT;
reader->input_charset = WS_CHARSET_UTF8;
reader->dict_static = NULL;
reader->dict = NULL;
return S_OK;
}
/**************************************************************************
* WsCreateReader [webservices.@]
*/
HRESULT WINAPI WsCreateReader( const WS_XML_READER_PROPERTY *properties, ULONG count,
WS_XML_READER **handle, WS_ERROR *error )
{
struct reader *reader;
ULONG i, max_depth = 32, max_attrs = 128, max_ns = 32;
BOOL read_decl = TRUE;
HRESULT hr;
TRACE( "%p %u %p %p\n", properties, count, handle, error );
if (error) FIXME( "ignoring error parameter\n" );
if (!handle) return E_INVALIDARG;
if (!(reader = alloc_reader())) return E_OUTOFMEMORY;
prop_set( reader->prop, reader->prop_count, WS_XML_READER_PROPERTY_MAX_DEPTH, &max_depth, sizeof(max_depth) );
prop_set( reader->prop, reader->prop_count, WS_XML_READER_PROPERTY_MAX_ATTRIBUTES, &max_attrs, sizeof(max_attrs) );
prop_set( reader->prop, reader->prop_count, WS_XML_READER_PROPERTY_READ_DECLARATION, &read_decl, sizeof(read_decl) );
prop_set( reader->prop, reader->prop_count, WS_XML_READER_PROPERTY_MAX_NAMESPACES, &max_ns, sizeof(max_ns) );
for (i = 0; i < count; i++)
{
hr = prop_set( reader->prop, reader->prop_count, properties[i].id, properties[i].value,
properties[i].valueSize );
if (hr != S_OK)
{
free_reader( reader );
return hr;
}
}
if ((hr = init_reader( reader )) != S_OK)
{
free_reader( reader );
return hr;
}
TRACE( "created %p\n", reader );
*handle = (WS_XML_READER *)reader;
return S_OK;
}
/**************************************************************************
* WsFreeReader [webservices.@]
*/
void WINAPI WsFreeReader( WS_XML_READER *handle )
{
struct reader *reader = (struct reader *)handle;
TRACE( "%p\n", handle );
if (!reader) return;
EnterCriticalSection( &reader->cs );
if (reader->magic != READER_MAGIC)
{
LeaveCriticalSection( &reader->cs );
return;
}
reader->magic = 0;
LeaveCriticalSection( &reader->cs );
free_reader( reader );
}
static HRESULT read_more_data( struct reader *reader, ULONG min_size, const WS_ASYNC_CONTEXT *ctx,
WS_ERROR *error )
{
ULONG size = 0, max_size;
if (reader->read_size - reader->read_pos >= min_size) return S_OK;
if (reader->input_type != WS_XML_READER_INPUT_TYPE_STREAM) return WS_E_INVALID_FORMAT;
if (min_size > reader->input_size) return WS_E_QUOTA_EXCEEDED;
if (reader->read_pos)
{
memmove( reader->stream_buf, reader->stream_buf + reader->read_pos, reader->read_size - reader->read_pos );
reader->read_size -= reader->read_pos;
reader->read_pos = 0;
}
max_size = reader->input_size - reader->read_size;
reader->input_cb( reader->input_cb_state, reader->stream_buf + reader->read_size, max_size, &size, ctx, error );
if (size < min_size) return WS_E_QUOTA_EXCEEDED;
reader->read_size += size;
return S_OK;
}
/**************************************************************************
* WsFillReader [webservices.@]
*/
HRESULT WINAPI WsFillReader( WS_XML_READER *handle, ULONG min_size, const WS_ASYNC_CONTEXT *ctx,
WS_ERROR *error )
{
struct reader *reader = (struct reader *)handle;
HRESULT hr;
TRACE( "%p %u %p %p\n", handle, min_size, ctx, error );
if (error) FIXME( "ignoring error parameter\n" );
if (ctx) FIXME( "ignoring ctx parameter\n" );
if (!reader) return E_INVALIDARG;
EnterCriticalSection( &reader->cs );
if (reader->magic != READER_MAGIC)
{
LeaveCriticalSection( &reader->cs );
return E_INVALIDARG;
}
if (reader->input_type == WS_XML_READER_INPUT_TYPE_STREAM)
{
hr = read_more_data( reader, min_size, ctx, error );
}
else
{
reader->read_size = min( min_size, reader->input_size );
reader->read_pos = 0;
hr = S_OK;
}
LeaveCriticalSection( &reader->cs );
TRACE( "returning %08x\n", hr );
return hr;
}
/**************************************************************************
* WsGetNamespaceFromPrefix [webservices.@]
*/
HRESULT WINAPI WsGetNamespaceFromPrefix( WS_XML_READER *handle, const WS_XML_STRING *prefix,
BOOL required, const WS_XML_STRING **ns, WS_ERROR *error )
{
static const WS_XML_STRING xml = {3, (BYTE *)"xml"};
static const WS_XML_STRING xmlns = {5, (BYTE *)"xmlns"};
static const WS_XML_STRING empty_ns = {0, NULL};
static const WS_XML_STRING xml_ns = {36, (BYTE *)"http://www.w3.org/XML/1998/namespace"};
static const WS_XML_STRING xmlns_ns = {29, (BYTE *)"http://www.w3.org/2000/xmlns/"};
struct reader *reader = (struct reader *)handle;
BOOL found = FALSE;
HRESULT hr = S_OK;
TRACE( "%p %s %d %p %p\n", handle, debugstr_xmlstr(prefix), required, ns, error );
if (error) FIXME( "ignoring error parameter\n" );
if (!reader || !prefix || !ns) return E_INVALIDARG;
EnterCriticalSection( &reader->cs );
if (reader->magic != READER_MAGIC)
{
LeaveCriticalSection( &reader->cs );
return E_INVALIDARG;
}
if (reader->state != READER_STATE_STARTELEMENT) hr = WS_E_INVALID_OPERATION;
else if (!prefix->length)
{
*ns = &empty_ns;
found = TRUE;
}
else if (WsXmlStringEquals( prefix, &xml, NULL ) == S_OK)
{
*ns = &xml_ns;
found = TRUE;
}
else if (WsXmlStringEquals( prefix, &xmlns, NULL ) == S_OK)
{
*ns = &xmlns_ns;
found = TRUE;
}
else
{
WS_XML_ELEMENT_NODE *elem = &reader->current->hdr;
ULONG i;
for (i = 0; i < elem->attributeCount; i++)
{
if (!elem->attributes[i]->isXmlNs) continue;
if (WsXmlStringEquals( prefix, elem->attributes[i]->prefix, NULL ) == S_OK)
{
*ns = elem->attributes[i]->ns;
found = TRUE;
break;
}
}
}
LeaveCriticalSection( &reader->cs );
if (hr == S_OK && !found)
{
if (required) hr = WS_E_INVALID_FORMAT;
else
{
*ns = NULL;
hr = S_FALSE;
}
}
TRACE( "returning %08x\n", hr );
return hr;
}
/**************************************************************************
* WsGetReaderNode [webservices.@]
*/
HRESULT WINAPI WsGetReaderNode( WS_XML_READER *handle, const WS_XML_NODE **node,
WS_ERROR *error )
{
struct reader *reader = (struct reader *)handle;
HRESULT hr = S_OK;
TRACE( "%p %p %p\n", handle, node, error );
if (error) FIXME( "ignoring error parameter\n" );
if (!reader || !node) return E_INVALIDARG;
EnterCriticalSection( &reader->cs );
if (reader->magic != READER_MAGIC)
{
LeaveCriticalSection( &reader->cs );
return E_INVALIDARG;
}
*node = &reader->current->hdr.node;
LeaveCriticalSection( &reader->cs );
TRACE( "returning %08x\n", hr );
return S_OK;
}
static HRESULT get_charset( struct reader *reader, void *buf, ULONG size )
{
if (!buf || size != sizeof(reader->input_charset)) return E_INVALIDARG;
if (!reader->input_charset) return WS_E_INVALID_FORMAT;
*(WS_CHARSET *)buf = reader->input_charset;
return S_OK;
}
/**************************************************************************
* WsGetReaderProperty [webservices.@]
*/
HRESULT WINAPI WsGetReaderProperty( WS_XML_READER *handle, WS_XML_READER_PROPERTY_ID id,
void *buf, ULONG size, WS_ERROR *error )
{
struct reader *reader = (struct reader *)handle;
HRESULT hr;
TRACE( "%p %u %p %u %p\n", handle, id, buf, size, error );
if (error) FIXME( "ignoring error parameter\n" );
if (!reader) return E_INVALIDARG;
EnterCriticalSection( &reader->cs );
if (reader->magic != READER_MAGIC)
{
LeaveCriticalSection( &reader->cs );
return E_INVALIDARG;
}
if (!reader->input_type) hr = WS_E_INVALID_OPERATION;
else if (id == WS_XML_READER_PROPERTY_CHARSET) hr = get_charset( reader, buf, size );
else hr = prop_get( reader->prop, reader->prop_count, id, buf, size );
LeaveCriticalSection( &reader->cs );
TRACE( "returning %08x\n", hr );
return hr;
}
/**************************************************************************
* WsGetXmlAttribute [webservices.@]
*/
HRESULT WINAPI WsGetXmlAttribute( WS_XML_READER *handle, const WS_XML_STRING *attr,
WS_HEAP *heap, WCHAR **str, ULONG *len, WS_ERROR *error )
{
FIXME( "%p %s %p %p %p %p: stub\n", handle, debugstr_xmlstr(attr), heap, str, len, error );
return E_NOTIMPL;
}
WS_XML_UTF8_TEXT *alloc_utf8_text( const BYTE *data, ULONG len )
{
WS_XML_UTF8_TEXT *ret;
if (!(ret = heap_alloc( sizeof(*ret) + len ))) return NULL;
ret->text.textType = WS_XML_TEXT_TYPE_UTF8;
ret->value.length = len;
ret->value.bytes = len ? (BYTE *)(ret + 1) : NULL;
ret->value.dictionary = NULL;
ret->value.id = 0;
if (data) memcpy( ret->value.bytes, data, len );
return ret;
}
WS_XML_UTF16_TEXT *alloc_utf16_text( const BYTE *data, ULONG len )
{
WS_XML_UTF16_TEXT *ret;
if (!(ret = heap_alloc( sizeof(*ret) + len ))) return NULL;
ret->text.textType = WS_XML_TEXT_TYPE_UTF16;
ret->byteCount = len;
ret->bytes = len ? (BYTE *)(ret + 1) : NULL;
if (data) memcpy( ret->bytes, data, len );
return ret;
}
WS_XML_BASE64_TEXT *alloc_base64_text( const BYTE *data, ULONG len )
{
WS_XML_BASE64_TEXT *ret;
if (!(ret = heap_alloc( sizeof(*ret) + len ))) return NULL;
ret->text.textType = WS_XML_TEXT_TYPE_BASE64;
ret->length = len;
ret->bytes = len ? (BYTE *)(ret + 1) : NULL;
if (data) memcpy( ret->bytes, data, len );
return ret;
}
WS_XML_BOOL_TEXT *alloc_bool_text( BOOL value )
{
WS_XML_BOOL_TEXT *ret;
if (!(ret = heap_alloc( sizeof(*ret) ))) return NULL;
ret->text.textType = WS_XML_TEXT_TYPE_BOOL;
ret->value = value;
return ret;
}
WS_XML_INT32_TEXT *alloc_int32_text( INT32 value )
{
WS_XML_INT32_TEXT *ret;
if (!(ret = heap_alloc( sizeof(*ret) ))) return NULL;
ret->text.textType = WS_XML_TEXT_TYPE_INT32;
ret->value = value;
return ret;
}
WS_XML_INT64_TEXT *alloc_int64_text( INT64 value )
{
WS_XML_INT64_TEXT *ret;
if (!(ret = heap_alloc( sizeof(*ret) ))) return NULL;
ret->text.textType = WS_XML_TEXT_TYPE_INT64;
ret->value = value;
return ret;
}
WS_XML_UINT64_TEXT *alloc_uint64_text( UINT64 value )
{
WS_XML_UINT64_TEXT *ret;
if (!(ret = heap_alloc( sizeof(*ret) ))) return NULL;
ret->text.textType = WS_XML_TEXT_TYPE_UINT64;
ret->value = value;
return ret;
}
WS_XML_FLOAT_TEXT *alloc_float_text( float value )
{
WS_XML_FLOAT_TEXT *ret;
if (!(ret = heap_alloc( sizeof(*ret) ))) return NULL;
ret->text.textType = WS_XML_TEXT_TYPE_FLOAT;
ret->value = value;
return ret;
}
WS_XML_DOUBLE_TEXT *alloc_double_text( double value )
{
WS_XML_DOUBLE_TEXT *ret;
if (!(ret = heap_alloc( sizeof(*ret) ))) return NULL;
ret->text.textType = WS_XML_TEXT_TYPE_DOUBLE;
ret->value = value;
return ret;
}
WS_XML_GUID_TEXT *alloc_guid_text( const GUID *value )
{
WS_XML_GUID_TEXT *ret;
if (!(ret = heap_alloc( sizeof(*ret) ))) return NULL;
ret->text.textType = WS_XML_TEXT_TYPE_GUID;
ret->value = *value;
return ret;
}
WS_XML_UNIQUE_ID_TEXT *alloc_unique_id_text( const GUID *value )
{
WS_XML_UNIQUE_ID_TEXT *ret;
if (!(ret = heap_alloc( sizeof(*ret) ))) return NULL;
ret->text.textType = WS_XML_TEXT_TYPE_UNIQUE_ID;
ret->value = *value;
return ret;
}
WS_XML_DATETIME_TEXT *alloc_datetime_text( const WS_DATETIME *value )
{
WS_XML_DATETIME_TEXT *ret;
if (!(ret = heap_alloc( sizeof(*ret) ))) return NULL;
ret->text.textType = WS_XML_TEXT_TYPE_DATETIME;
ret->value = *value;
return ret;
}
static inline BOOL read_end_of_data( struct reader *reader )
{
return (read_more_data( reader, 1, NULL, NULL ) != S_OK);
}
static inline const unsigned char *read_current_ptr( struct reader *reader )
{
return &reader->read_bufptr[reader->read_pos];
}
static inline void read_skip( struct reader *reader, unsigned int count )
{
assert( reader->read_pos + count <= reader->read_size );
reader->read_pos += count;
}
static inline HRESULT read_peek( struct reader *reader, unsigned char *bytes, unsigned int len )
{
HRESULT hr;
if ((hr = read_more_data( reader, len, NULL, NULL )) != S_OK) return hr;
memcpy( bytes, read_current_ptr( reader ), len );
return S_OK;
}
static inline HRESULT read_byte( struct reader *reader, unsigned char *byte )
{
HRESULT hr;
if ((hr = read_more_data( reader, 1, NULL, NULL )) != S_OK) return hr;
*byte = *read_current_ptr( reader );
read_skip( reader, 1 );
return S_OK;
}
static inline HRESULT read_bytes( struct reader *reader, unsigned char *bytes, unsigned int len )
{
HRESULT hr;
if ((hr = read_more_data( reader, len, NULL, NULL )) != S_OK) return hr;
memcpy( bytes, read_current_ptr( reader ), len );
read_skip( reader, len );
return S_OK;
}
/* UTF-8 support based on libs/wine/utf8.c */
/* number of following bytes in sequence based on first byte value (for bytes above 0x7f) */
static const char utf8_length[128] =
{
0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0, /* 0x80-0x8f */
0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0, /* 0x90-0x9f */
0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0, /* 0xa0-0xaf */
0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0, /* 0xb0-0xbf */
0,0,1,1,1,1,1,1,1,1,1,1,1,1,1,1, /* 0xc0-0xcf */
1,1,1,1,1,1,1,1,1,1,1,1,1,1,1,1, /* 0xd0-0xdf */
2,2,2,2,2,2,2,2,2,2,2,2,2,2,2,2, /* 0xe0-0xef */
3,3,3,3,3,0,0,0,0,0,0,0,0,0,0,0 /* 0xf0-0xff */
};
/* first byte mask depending on UTF-8 sequence length */
static const unsigned char utf8_mask[4] = { 0x7f, 0x1f, 0x0f, 0x07 };
/* minimum Unicode value depending on UTF-8 sequence length */
static const unsigned int utf8_minval[4] = { 0x0, 0x80, 0x800, 0x10000 };
static inline HRESULT read_utf8_char( struct reader *reader, unsigned int *ret, unsigned int *skip )
{
unsigned int len;
unsigned char ch;
const unsigned char *end;
HRESULT hr;
if ((hr = read_more_data( reader, 1, NULL, NULL )) != S_OK) return hr;
ch = *read_current_ptr( reader );
if (ch < 0x80)
{
*ret = ch;
*skip = 1;
return S_OK;
}
len = utf8_length[ch - 0x80];
if ((hr = read_more_data( reader, len, NULL, NULL )) != S_OK) return hr;
end = read_current_ptr( reader ) + len + 1;
*ret = ch & utf8_mask[len];
switch (len)
{
case 3:
if ((ch = end[-3] ^ 0x80) >= 0x40) break;
*ret = (*ret << 6) | ch;
case 2:
if ((ch = end[-2] ^ 0x80) >= 0x40) break;
*ret = (*ret << 6) | ch;
case 1:
if ((ch = end[-1] ^ 0x80) >= 0x40) break;
*ret = (*ret << 6) | ch;
if (*ret < utf8_minval[len]) break;
*skip = len + 1;
return S_OK;
}
return WS_E_INVALID_FORMAT;
}
static inline BOOL read_isnamechar( unsigned int ch )
{
/* FIXME: incomplete */
return (ch >= 'A' && ch <= 'Z') ||
(ch >= 'a' && ch <= 'z') ||
(ch >= '0' && ch <= '9') ||
ch == '_' || ch == '-' || ch == '.' || ch == ':';
}
static inline BOOL read_isspace( unsigned int ch )
{
return ch == ' ' || ch == '\t' || ch == '\r' || ch == '\n';
}
static inline void read_skip_whitespace( struct reader *reader )
{
for (;;)
{
if (read_more_data( reader, 1, NULL, NULL ) != S_OK || !read_isspace( *read_current_ptr( reader ) )) break;
read_skip( reader, 1 );
}
}
static inline HRESULT read_cmp( struct reader *reader, const char *str, int len )
{
const unsigned char *ptr;
HRESULT hr;
if (len < 0) len = strlen( str );
if ((hr = read_more_data( reader, len, NULL, NULL )) != S_OK) return hr;
ptr = read_current_ptr( reader );
while (len--)
{
if (*str != *ptr) return WS_E_INVALID_FORMAT;
str++; ptr++;
}
return S_OK;
}
static HRESULT read_xmldecl( struct reader *reader )
{
HRESULT hr;
if ((hr = read_more_data( reader, 1, NULL, NULL )) != S_OK) return hr;
if (*read_current_ptr( reader ) != '<' || (hr = read_cmp( reader, "<?", 2 )) != S_OK)
{
reader->state = READER_STATE_BOF;
return S_OK;
}
if ((hr = read_cmp( reader, "<?xml ", 6 )) != S_OK) return hr;
read_skip( reader, 6 );
/* FIXME: parse attributes */
for (;;)
{
if (read_more_data( reader, 1, NULL, NULL ) != S_OK || *read_current_ptr( reader ) == '?' ) break;
read_skip( reader, 1 );
}
if ((hr = read_cmp( reader, "?>", 2 )) != S_OK) return hr;
read_skip( reader, 2 );
reader->state = READER_STATE_BOF;
return S_OK;
}
HRESULT append_attribute( WS_XML_ELEMENT_NODE *elem, WS_XML_ATTRIBUTE *attr )
{
if (elem->attributeCount)
{
WS_XML_ATTRIBUTE **tmp;
if (!(tmp = heap_realloc( elem->attributes, (elem->attributeCount + 1) * sizeof(attr) )))
return E_OUTOFMEMORY;
elem->attributes = tmp;
}
else if (!(elem->attributes = heap_alloc( sizeof(attr) ))) return E_OUTOFMEMORY;
elem->attributes[elem->attributeCount++] = attr;
return S_OK;
}
static inline void init_xml_string( BYTE *bytes, ULONG len, WS_XML_STRING *str )
{
str->length = len;
str->bytes = bytes;
str->dictionary = NULL;
str->id = 0;
}
static HRESULT split_qname( const BYTE *str, ULONG len, WS_XML_STRING *prefix, WS_XML_STRING *localname )
{
BYTE *prefix_bytes = NULL, *localname_bytes = (BYTE *)str, *ptr = (BYTE *)str;
ULONG prefix_len = 0, localname_len = len;
while (len--)
{
if (*ptr == ':')
{
if (ptr == str) return WS_E_INVALID_FORMAT;
prefix_bytes = (BYTE *)str;
prefix_len = ptr - str;
localname_bytes = ptr + 1;
localname_len = len;
break;
}
ptr++;
}
if (!localname_len) return WS_E_INVALID_FORMAT;
init_xml_string( prefix_bytes, prefix_len, prefix );
init_xml_string( localname_bytes, localname_len, localname );
return S_OK;
}
static HRESULT parse_qname( const BYTE *str, ULONG len, WS_XML_STRING **prefix_ret, WS_XML_STRING **localname_ret )
{
WS_XML_STRING prefix, localname;
HRESULT hr;
if ((hr = split_qname( str, len, &prefix, &localname )) != S_OK) return hr;
if (!(*prefix_ret = alloc_xml_string( NULL, prefix.length ))) return E_OUTOFMEMORY;
if (!(*localname_ret = dup_xml_string( &localname, FALSE )))
{
free_xml_string( *prefix_ret );
return E_OUTOFMEMORY;
}
memcpy( (*prefix_ret)->bytes, prefix.bytes, prefix.length );
if (prefix.length && add_xml_string( *prefix_ret ) != S_OK) WARN( "prefix not added to dictionary\n" );
return S_OK;
}
static int codepoint_to_utf8( int cp, unsigned char *dst )
{
if (!cp) return -1;
if (cp < 0x80)
{
*dst = cp;
return 1;
}
if (cp < 0x800)
{
dst[1] = 0x80 | (cp & 0x3f);
cp >>= 6;
dst[0] = 0xc0 | cp;
return 2;
}
if ((cp >= 0xd800 && cp <= 0xdfff) || cp == 0xfffe || cp == 0xffff) return -1;
if (cp < 0x10000)
{
dst[2] = 0x80 | (cp & 0x3f);
cp >>= 6;
dst[1] = 0x80 | (cp & 0x3f);
cp >>= 6;
dst[0] = 0xe0 | cp;
return 3;
}
if (cp >= 0x110000) return -1;
dst[3] = 0x80 | (cp & 0x3f);
cp >>= 6;
dst[2] = 0x80 | (cp & 0x3f);
cp >>= 6;
dst[1] = 0x80 | (cp & 0x3f);
cp >>= 6;
dst[0] = 0xf0 | cp;
return 4;
}
static HRESULT decode_text( const unsigned char *str, ULONG len, unsigned char *ret, ULONG *ret_len )
{
const unsigned char *p = str;
unsigned char *q = ret;
*ret_len = 0;
while (len)
{
if (*p == '&')
{
p++; len--;
if (!len) return WS_E_INVALID_FORMAT;
if (len >= 3 && !memcmp( p, "lt;", 3 ))
{
*q++ = '<';
p += 3;
len -= 3;
}
else if (len >= 3 && !memcmp( p, "gt;", 3 ))
{
*q++ = '>';
p += 3;
len -= 3;
}
else if (len >= 5 && !memcmp( p, "quot;", 5 ))
{
*q++ = '"';
p += 5;
len -= 5;
}
else if (len >= 4 && !memcmp( p, "amp;", 4 ))
{
*q++ = '&';
p += 4;
len -= 4;
}
else if (len >= 5 && !memcmp( p, "apos;", 5 ))
{
*q++ = '\'';
p += 5;
len -= 5;
}
else if (*p == '#')
{
ULONG start, nb_digits, i;
int len_utf8, cp = 0;
p++; len--;
if (!len) return WS_E_INVALID_FORMAT;
if (*p == 'x')
{
p++; len--;
start = len;
while (len && isxdigit( *p )) { p++; len--; };
if (!len) return WS_E_INVALID_FORMAT;
p -= nb_digits = start - len;
if (!nb_digits || nb_digits > 6 || p[nb_digits] != ';') return WS_E_INVALID_FORMAT;
for (i = 0; i < nb_digits; i++)
{
cp *= 16;
if (*p >= '0' && *p <= '9') cp += *p - '0';
else if (*p >= 'a' && *p <= 'f') cp += *p - 'a' + 10;
else cp += *p - 'A' + 10;
p++;
}
}
else if (isdigit( *p ))
{
while (len && *p == '0') { p++; len--; };
if (!len) return WS_E_INVALID_FORMAT;
start = len;
while (len && isdigit( *p )) { p++; len--; };
if (!len) return WS_E_INVALID_FORMAT;
p -= nb_digits = start - len;
if (!nb_digits || nb_digits > 7 || p[nb_digits] != ';') return WS_E_INVALID_FORMAT;
for (i = 0; i < nb_digits; i++)
{
cp *= 10;
cp += *p - '0';
p++;
}
}
else return WS_E_INVALID_FORMAT;
p++; len--;
if ((len_utf8 = codepoint_to_utf8( cp, q )) < 0) return WS_E_INVALID_FORMAT;
*ret_len += len_utf8;
q += len_utf8;
continue;
}
else return WS_E_INVALID_FORMAT;
}
else
{
*q++ = *p++;
len--;
}
*ret_len += 1;
}
return S_OK;
}
static HRESULT read_attribute_value_text( struct reader *reader, WS_XML_ATTRIBUTE *attr )
{
WS_XML_UTF8_TEXT *utf8;
unsigned int len, ch, skip, quote;
const unsigned char *start;
HRESULT hr;
read_skip_whitespace( reader );
if ((hr = read_cmp( reader, "=", 1 )) != S_OK) return hr;
read_skip( reader, 1 );
read_skip_whitespace( reader );
if ((hr = read_cmp( reader, "\"", 1 )) != S_OK && (hr = read_cmp( reader, "'", 1 )) != S_OK) return hr;
if ((hr = read_utf8_char( reader, &quote, &skip )) != S_OK) return hr;
read_skip( reader, 1 );
len = 0;
start = read_current_ptr( reader );
for (;;)
{
if ((hr = read_utf8_char( reader, &ch, &skip )) != S_OK) return hr;
if (ch == quote) break;
read_skip( reader, skip );
len += skip;
}
read_skip( reader, 1 );
if (attr->isXmlNs)
{
if (!(attr->ns = alloc_xml_string( start, len ))) return E_OUTOFMEMORY;
if ((hr = bind_prefix( reader, attr->prefix, attr->ns )) != S_OK) return hr;
if (!(utf8 = alloc_utf8_text( NULL, 0 ))) return E_OUTOFMEMORY;
}
else
{
if (!(utf8 = alloc_utf8_text( NULL, len ))) return E_OUTOFMEMORY;
if ((hr = decode_text( start, len, utf8->value.bytes, &utf8->value.length )) != S_OK)
{
heap_free( utf8 );
return hr;
}
}
attr->value = &utf8->text;
attr->singleQuote = (quote == '\'');
return S_OK;
}
static inline BOOL is_text_type( unsigned char type )
{
return (type >= RECORD_ZERO_TEXT && type <= RECORD_QNAME_DICTIONARY_TEXT_WITH_ENDELEMENT);
}
static HRESULT read_int31( struct reader *reader, ULONG *len )
{
unsigned char byte;
HRESULT hr;
if ((hr = read_byte( reader, &byte )) != S_OK) return hr;
*len = byte & 0x7f;
if (!(byte & 0x80)) return S_OK;
if ((hr = read_byte( reader, &byte )) != S_OK) return hr;
*len += (byte & 0x7f) << 7;
if (!(byte & 0x80)) return S_OK;
if ((hr = read_byte( reader, &byte )) != S_OK) return hr;
*len += (byte & 0x7f) << 14;
if (!(byte & 0x80)) return S_OK;
if ((hr = read_byte( reader, &byte )) != S_OK) return hr;
*len += (byte & 0x7f) << 21;
if (!(byte & 0x80)) return S_OK;
if ((hr = read_byte( reader, &byte )) != S_OK) return hr;
*len += (byte & 0x07) << 28;
return S_OK;
}
static HRESULT read_string( struct reader *reader, WS_XML_STRING **str )
{
ULONG len;
HRESULT hr;
if ((hr = read_int31( reader, &len )) != S_OK) return hr;
if (!(*str = alloc_xml_string( NULL, len ))) return E_OUTOFMEMORY;
if ((hr = read_bytes( reader, (*str)->bytes, len )) == S_OK)
{
if (add_xml_string( *str ) != S_OK) WARN( "string not added to dictionary\n" );
return S_OK;
}
free_xml_string( *str );
return hr;
}
static HRESULT read_dict_string( struct reader *reader, WS_XML_STRING **str )
{
const WS_XML_DICTIONARY *dict;
HRESULT hr;
ULONG id;
if ((hr = read_int31( reader, &id )) != S_OK) return hr;
dict = (id & 1) ? reader->dict : reader->dict_static;
if (!dict || (id >>= 1) >= dict->stringCount) return WS_E_INVALID_FORMAT;
if (!(*str = alloc_xml_string( NULL, 0 ))) return E_OUTOFMEMORY;
*(*str) = dict->strings[id];
return S_OK;
}
static HRESULT read_datetime( struct reader *reader, WS_DATETIME *ret )
{
UINT64 val;
HRESULT hr;
if ((hr = read_bytes( reader, (unsigned char *)&val, sizeof(val) )) != S_OK) return hr;
if ((val & 0x03) == 1) ret->format = WS_DATETIME_FORMAT_UTC;
else if ((val & 0x03) == 2) ret->format = WS_DATETIME_FORMAT_LOCAL;
else ret->format = WS_DATETIME_FORMAT_NONE;
if ((ret->ticks = val >> 2) > TICKS_MAX) return WS_E_INVALID_FORMAT;
return S_OK;
}
static HRESULT lookup_string( struct reader *reader, ULONG id, const WS_XML_STRING **ret )
{
const WS_XML_DICTIONARY *dict = (id & 1) ? reader->dict : reader->dict_static;
if (!dict || (id >>= 1) >= dict->stringCount) return WS_E_INVALID_FORMAT;
*ret = &dict->strings[id];
return S_OK;
}
static HRESULT read_attribute_value_bin( struct reader *reader, WS_XML_ATTRIBUTE *attr )
{
WS_XML_UTF8_TEXT *text_utf8 = NULL;
WS_XML_BASE64_TEXT *text_base64 = NULL;
WS_XML_INT32_TEXT *text_int32;
WS_XML_INT64_TEXT *text_int64;
WS_XML_BOOL_TEXT *text_bool;
const WS_XML_STRING *str;
unsigned char type;
UINT8 val_uint8;
UINT16 val_uint16;
INT32 val_int32;
ULONG len = 0, id;
GUID guid;
HRESULT hr;
if ((hr = read_byte( reader, &type )) != S_OK) return hr;
if (!is_text_type( type )) return WS_E_INVALID_FORMAT;
switch (type)
{
case RECORD_ZERO_TEXT:
{
if (!(text_int32 = alloc_int32_text( 0 ))) return E_OUTOFMEMORY;
attr->value = &text_int32->text;
return S_OK;
}
case RECORD_ONE_TEXT:
{
if (!(text_int32 = alloc_int32_text( 1 ))) return E_OUTOFMEMORY;
attr->value = &text_int32->text;
return S_OK;
}
case RECORD_FALSE_TEXT:
{
if (!(text_bool = alloc_bool_text( FALSE ))) return E_OUTOFMEMORY;
attr->value = &text_bool->text;
return S_OK;
}
case RECORD_TRUE_TEXT:
{
if (!(text_bool = alloc_bool_text( TRUE ))) return E_OUTOFMEMORY;
attr->value = &text_bool->text;
return S_OK;
}
case RECORD_INT8_TEXT:
{
INT8 val_int8;
if ((hr = read_byte( reader, (unsigned char *)&val_int8 )) != S_OK) return hr;
if (!(text_int64 = alloc_int64_text( val_int8 ))) return E_OUTOFMEMORY;
attr->value = &text_int64->text;
return S_OK;
}
case RECORD_INT16_TEXT:
{
INT16 val_int16;
if ((hr = read_bytes( reader, (unsigned char *)&val_int16, sizeof(val_int16) )) != S_OK) return hr;
if (!(text_int64 = alloc_int64_text( val_int16 ))) return E_OUTOFMEMORY;
attr->value = &text_int64->text;
return S_OK;
}
case RECORD_INT32_TEXT:
if ((hr = read_bytes( reader, (unsigned char *)&val_int32, sizeof(val_int32) )) != S_OK) return hr;
if (!(text_int64 = alloc_int64_text( val_int32 ))) return E_OUTOFMEMORY;
attr->value = &text_int64->text;
return S_OK;
case RECORD_INT64_TEXT:
{
INT64 val_int64;
if ((hr = read_bytes( reader, (unsigned char *)&val_int64, sizeof(val_int64) )) != S_OK) return hr;
if (!(text_int64 = alloc_int64_text( val_int64 ))) return E_OUTOFMEMORY;
attr->value = &text_int64->text;
return S_OK;
}
case RECORD_FLOAT_TEXT:
{
WS_XML_FLOAT_TEXT *text_float;
float val_float;
if ((hr = read_bytes( reader, (unsigned char *)&val_float, sizeof(val_float) )) != S_OK) return hr;
if (!(text_float = alloc_float_text( val_float ))) return E_OUTOFMEMORY;
attr->value = &text_float->text;
return S_OK;
}
case RECORD_DOUBLE_TEXT:
{
WS_XML_DOUBLE_TEXT *text_double;
double val_double;
if ((hr = read_bytes( reader, (unsigned char *)&val_double, sizeof(val_double) )) != S_OK) return hr;
if (!(text_double = alloc_double_text( val_double ))) return E_OUTOFMEMORY;
attr->value = &text_double->text;
return S_OK;
}
case RECORD_DATETIME_TEXT:
{
WS_XML_DATETIME_TEXT *text_datetime;
WS_DATETIME datetime;
if ((hr = read_datetime( reader, &datetime )) != S_OK) return hr;
if (!(text_datetime = alloc_datetime_text( &datetime ))) return E_OUTOFMEMORY;
attr->value = &text_datetime->text;
return S_OK;
}
case RECORD_CHARS8_TEXT:
if ((hr = read_byte( reader, (unsigned char *)&val_uint8 )) != S_OK) return hr;
len = val_uint8;
break;
case RECORD_CHARS16_TEXT:
if ((hr = read_bytes( reader, (unsigned char *)&val_uint16, sizeof(val_uint16) )) != S_OK) return hr;
len = val_uint16;
break;
case RECORD_CHARS32_TEXT:
if ((hr = read_bytes( reader, (unsigned char *)&val_int32, sizeof(val_int32) )) != S_OK) return hr;
if (val_int32 < 0) return WS_E_INVALID_FORMAT;
len = val_int32;
break;
case RECORD_BYTES8_TEXT:
if ((hr = read_byte( reader, (unsigned char *)&val_uint8 )) != S_OK) return hr;
if (!(text_base64 = alloc_base64_text( NULL, val_uint8 ))) return E_OUTOFMEMORY;
if ((hr = read_bytes( reader, text_base64->bytes, val_uint8 )) != S_OK)
{
heap_free( text_base64 );
return hr;
}
break;
case RECORD_BYTES16_TEXT:
if ((hr = read_bytes( reader, (unsigned char *)&val_uint16, sizeof(val_uint16) )) != S_OK) return hr;
if (!(text_base64 = alloc_base64_text( NULL, val_uint16 ))) return E_OUTOFMEMORY;
if ((hr = read_bytes( reader, text_base64->bytes, val_uint16 )) != S_OK)
{
heap_free( text_base64 );
return hr;
}
break;
case RECORD_BYTES32_TEXT:
if ((hr = read_bytes( reader, (unsigned char *)&val_int32, sizeof(val_int32) )) != S_OK) return hr;
if (val_int32 < 0) return WS_E_INVALID_FORMAT;
if (!(text_base64 = alloc_base64_text( NULL, val_int32 ))) return E_OUTOFMEMORY;
if ((hr = read_bytes( reader, text_base64->bytes, val_int32 )) != S_OK)
{
heap_free( text_base64 );
return hr;
}
break;
case RECORD_EMPTY_TEXT:
break;
case RECORD_DICTIONARY_TEXT:
if ((hr = read_int31( reader, &id )) != S_OK) return hr;
if ((hr = lookup_string( reader, id, &str )) != S_OK) return hr;
if (!(text_utf8 = alloc_utf8_text( str->bytes, str->length ))) return E_OUTOFMEMORY;
break;
case RECORD_UNIQUE_ID_TEXT:
{
WS_XML_UNIQUE_ID_TEXT *text_unique_id;
if ((hr = read_bytes( reader, (unsigned char *)&guid, sizeof(guid) )) != S_OK) return hr;
if (!(text_unique_id = alloc_unique_id_text( &guid ))) return E_OUTOFMEMORY;
attr->value = &text_unique_id->text;
return S_OK;
}
case RECORD_GUID_TEXT:
{
WS_XML_GUID_TEXT *guid_text;
if ((hr = read_bytes( reader, (unsigned char *)&guid, sizeof(guid) )) != S_OK) return hr;
if (!(guid_text = alloc_guid_text( &guid ))) return E_OUTOFMEMORY;
attr->value = &guid_text->text;
return S_OK;
}
case RECORD_UINT64_TEXT:
{
WS_XML_UINT64_TEXT *text_uint64;
UINT64 val_uint64;
if ((hr = read_bytes( reader, (unsigned char *)&val_uint64, sizeof(val_uint64) )) != S_OK) return hr;
if (!(text_uint64 = alloc_uint64_text( val_uint64 ))) return E_OUTOFMEMORY;
attr->value = &text_uint64->text;
return S_OK;
}
case RECORD_BOOL_TEXT:
{
WS_XML_BOOL_TEXT *text_bool;
BOOL val_bool;
if ((hr = read_bytes( reader, (unsigned char *)&val_bool, sizeof(val_bool) )) != S_OK) return hr;
if (!(text_bool = alloc_bool_text( !!val_bool ))) return E_OUTOFMEMORY;
attr->value = &text_bool->text;
return S_OK;
}
default:
ERR( "unhandled record type %02x\n", type );
return WS_E_NOT_SUPPORTED;
}
if (type >= RECORD_BYTES8_TEXT && type <= RECORD_BYTES32_TEXT)
{
attr->value = &text_base64->text;
return S_OK;
}
if (!text_utf8)
{
if (!(text_utf8 = alloc_utf8_text( NULL, len ))) return E_OUTOFMEMORY;
if (!len) text_utf8->value.bytes = (BYTE *)(text_utf8 + 1); /* quirk */
if ((hr = read_bytes( reader, text_utf8->value.bytes, len )) != S_OK)
{
heap_free( text_utf8 );
return hr;
}
}
attr->value = &text_utf8->text;
return S_OK;
}
static HRESULT read_attribute_text( struct reader *reader, WS_XML_ATTRIBUTE **ret )
{
static const WS_XML_STRING xmlns = {5, (BYTE *)"xmlns"};
WS_XML_ATTRIBUTE *attr;
unsigned int len = 0, ch, skip;
const unsigned char *start;
WS_XML_STRING *prefix, *localname;
HRESULT hr;
if (!(attr = heap_alloc_zero( sizeof(*attr) ))) return E_OUTOFMEMORY;
start = read_current_ptr( reader );
for (;;)
{
if ((hr = read_utf8_char( reader, &ch, &skip )) != S_OK) goto error;
if (!read_isnamechar( ch )) break;
read_skip( reader, skip );
len += skip;
}
if (!len)
{
hr = WS_E_INVALID_FORMAT;
goto error;
}
if ((hr = parse_qname( start, len, &prefix, &localname )) != S_OK) goto error;
if (WsXmlStringEquals( prefix, &xmlns, NULL ) == S_OK)
{
free_xml_string( prefix );
attr->isXmlNs = 1;
if (!(attr->prefix = alloc_xml_string( localname->bytes, localname->length )))
{
free_xml_string( localname );
hr = E_OUTOFMEMORY;
goto error;
}
attr->localName = localname;
}
else if (!prefix->length && WsXmlStringEquals( localname, &xmlns, NULL ) == S_OK)
{
attr->isXmlNs = 1;
attr->prefix = prefix;
attr->localName = localname;
}
else
{
attr->prefix = prefix;
attr->localName = localname;
}
if ((hr = read_attribute_value_text( reader, attr )) != S_OK) goto error;
*ret = attr;
return S_OK;
error:
free_attribute( attr );
return hr;
}
static inline BOOL is_attribute_type( unsigned char type )
{
return (type >= RECORD_SHORT_ATTRIBUTE && type <= RECORD_PREFIX_ATTRIBUTE_Z);
}
static WS_XML_STRING *get_xmlns_localname( struct reader *reader, const WS_XML_STRING *prefix )
{
if (!get_namespace( reader, prefix )) return alloc_xml_string( NULL, 0 );
return alloc_xml_string( prefix->bytes, prefix->length );
}
static HRESULT read_attribute_bin( struct reader *reader, WS_XML_ATTRIBUTE **ret )
{
WS_XML_UTF8_TEXT *utf8;
WS_XML_ATTRIBUTE *attr;
unsigned char type = 0;
HRESULT hr;
if ((hr = read_byte( reader, &type )) != S_OK) return hr;
if (!is_attribute_type( type )) return WS_E_INVALID_FORMAT;
if (!(attr = heap_alloc_zero( sizeof(*attr) ))) return E_OUTOFMEMORY;
if (type >= RECORD_PREFIX_ATTRIBUTE_A && type <= RECORD_PREFIX_ATTRIBUTE_Z)
{
unsigned char ch = type - RECORD_PREFIX_ATTRIBUTE_A + 'a';
if (!(attr->prefix = alloc_xml_string( &ch, 1 )))
{
hr = E_OUTOFMEMORY;
goto error;
}
if ((hr = read_string( reader, &attr->localName )) != S_OK) goto error;
if ((hr = read_attribute_value_bin( reader, attr )) != S_OK) goto error;
}
else if (type >= RECORD_PREFIX_DICTIONARY_ATTRIBUTE_A && type <= RECORD_PREFIX_DICTIONARY_ATTRIBUTE_Z)
{
unsigned char ch = type - RECORD_PREFIX_DICTIONARY_ATTRIBUTE_A + 'a';
if (!(attr->prefix = alloc_xml_string( &ch, 1 )))
{
hr = E_OUTOFMEMORY;
goto error;
}
if ((hr = read_dict_string( reader, &attr->localName )) != S_OK) goto error;
if ((hr = read_attribute_value_bin( reader, attr )) != S_OK) goto error;
}
else
{
switch (type)
{
case RECORD_SHORT_ATTRIBUTE:
if (!(attr->prefix = alloc_xml_string( NULL, 0 )))
{
hr = E_OUTOFMEMORY;
goto error;
}
if ((hr = read_string( reader, &attr->localName )) != S_OK) goto error;
if ((hr = read_attribute_value_bin( reader, attr )) != S_OK) goto error;
break;
case RECORD_ATTRIBUTE:
if ((hr = read_string( reader, &attr->prefix )) != S_OK) goto error;
if ((hr = read_string( reader, &attr->localName )) != S_OK) goto error;
if ((hr = read_attribute_value_bin( reader, attr )) != S_OK) goto error;
break;
case RECORD_SHORT_DICTIONARY_ATTRIBUTE:
if (!(attr->prefix = alloc_xml_string( NULL, 0 )))
{
hr = E_OUTOFMEMORY;
goto error;
}
if ((hr = read_dict_string( reader, &attr->localName )) != S_OK) goto error;
if ((hr = read_attribute_value_bin( reader, attr )) != S_OK) goto error;
break;
case RECORD_DICTIONARY_ATTRIBUTE:
if ((hr = read_string( reader, &attr->prefix )) != S_OK) goto error;
if ((hr = read_dict_string( reader, &attr->localName )) != S_OK) goto error;
if ((hr = read_attribute_value_bin( reader, attr )) != S_OK) goto error;
break;
case RECORD_SHORT_XMLNS_ATTRIBUTE:
if (!(attr->prefix = alloc_xml_string( NULL, 0 )))
{
hr = E_OUTOFMEMORY;
goto error;
}
if (!(attr->localName = get_xmlns_localname( reader, attr->prefix )))
{
hr = E_OUTOFMEMORY;
goto error;
}
if ((hr = read_string( reader, &attr->ns )) != S_OK) goto error;
if ((hr = bind_prefix( reader, attr->prefix, attr->ns )) != S_OK) goto error;
attr->isXmlNs = 1;
break;
case RECORD_XMLNS_ATTRIBUTE:
if ((hr = read_string( reader, &attr->prefix )) != S_OK) goto error;
if (!(attr->localName = get_xmlns_localname( reader, attr->prefix )))
{
hr = E_OUTOFMEMORY;
goto error;
}
if ((hr = read_string( reader, &attr->ns )) != S_OK) goto error;
if ((hr = bind_prefix( reader, attr->prefix, attr->ns )) != S_OK) goto error;
attr->isXmlNs = 1;
break;
case RECORD_SHORT_DICTIONARY_XMLNS_ATTRIBUTE:
if (!(attr->prefix = alloc_xml_string( NULL, 0 )))
{
hr = E_OUTOFMEMORY;
goto error;
}
if (!(attr->localName = get_xmlns_localname( reader, attr->prefix )))
{
hr = E_OUTOFMEMORY;
goto error;
}
if ((hr = read_dict_string( reader, &attr->ns )) != S_OK) goto error;
if (!(utf8 = alloc_utf8_text( NULL, 0 )))
{
hr = E_OUTOFMEMORY;
goto error;
}
attr->value = &utf8->text;
if ((hr = bind_prefix( reader, attr->prefix, attr->ns )) != S_OK) goto error;
attr->isXmlNs = 1;
break;
case RECORD_DICTIONARY_XMLNS_ATTRIBUTE:
if ((hr = read_string( reader, &attr->prefix )) != S_OK) goto error;
if (!(attr->localName = get_xmlns_localname( reader, attr->prefix )))
{
hr = E_OUTOFMEMORY;
goto error;
}
if ((hr = read_dict_string( reader, &attr->ns )) != S_OK) goto error;
if (!(utf8 = alloc_utf8_text( NULL, 0 )))
{
hr = E_OUTOFMEMORY;
goto error;
}
attr->value = &utf8->text;
if ((hr = bind_prefix( reader, attr->prefix, attr->ns )) != S_OK) goto error;
attr->isXmlNs = 1;
break;
default:
ERR( "unhandled record type %02x\n", type );
return WS_E_NOT_SUPPORTED;
}
}
*ret = attr;
return S_OK;
error:
free_attribute( attr );
return hr;
}
static inline struct node *find_parent( struct reader *reader )
{
if (node_type( reader->current ) == WS_XML_NODE_TYPE_END_ELEMENT)
{
if (is_valid_parent( reader->current->parent->parent )) return reader->current->parent->parent;
return NULL;
}
if (is_valid_parent( reader->current )) return reader->current;
if (is_valid_parent( reader->current->parent )) return reader->current->parent;
return NULL;
}
static HRESULT set_namespaces( struct reader *reader, WS_XML_ELEMENT_NODE *elem )
{
static const WS_XML_STRING xml = {3, (BYTE *)"xml"};
const WS_XML_STRING *ns;
ULONG i;
if (!(ns = get_namespace( reader, elem->prefix ))) return WS_E_INVALID_FORMAT;
if (!(elem->ns = dup_xml_string( ns, FALSE ))) return E_OUTOFMEMORY;
for (i = 0; i < elem->attributeCount; i++)
{
WS_XML_ATTRIBUTE *attr = elem->attributes[i];
if (attr->isXmlNs || WsXmlStringEquals( attr->prefix, &xml, NULL ) == S_OK) continue;
if (!(ns = get_namespace( reader, attr->prefix ))) return WS_E_INVALID_FORMAT;
if (!(attr->ns = alloc_xml_string( NULL, ns->length ))) return E_OUTOFMEMORY;
if (attr->ns->length) memcpy( attr->ns->bytes, ns->bytes, ns->length );
}
return S_OK;
}
static WS_XML_ELEMENT_NODE *alloc_element_pair(void)
{
struct node *node, *end;
if (!(node = alloc_node( WS_XML_NODE_TYPE_ELEMENT ))) return NULL;
if (!(end = alloc_node( WS_XML_NODE_TYPE_END_ELEMENT )))
{
free_node( node );
return NULL;
}
list_add_tail( &node->children, &end->entry );
end->parent = node;
return &node->hdr;
}
static HRESULT read_attributes_text( struct reader *reader, WS_XML_ELEMENT_NODE *elem )
{
WS_XML_ATTRIBUTE *attr;
HRESULT hr;
reader->current_attr = 0;
for (;;)
{
read_skip_whitespace( reader );
if (read_cmp( reader, ">", 1 ) == S_OK || read_cmp( reader, "/>", 2 ) == S_OK) break;
if ((hr = read_attribute_text( reader, &attr )) != S_OK) return hr;
if ((hr = append_attribute( elem, attr )) != S_OK)
{
free_attribute( attr );
return hr;
}
reader->current_attr++;
}
return S_OK;
}
static HRESULT read_element_text( struct reader *reader )
{
unsigned int len = 0, ch, skip;
const unsigned char *start;
unsigned char buf[2];
struct node *node = NULL, *parent;
WS_XML_ELEMENT_NODE *elem;
HRESULT hr;
if (read_end_of_data( reader ))
{
reader->current = LIST_ENTRY( list_tail( &reader->root->children ), struct node, entry );
reader->last = reader->current;
reader->state = READER_STATE_EOF;
return S_OK;
}
if ((hr = read_peek( reader, buf, 2 )) != S_OK) return hr;
if (buf[0] != '<' || !read_isnamechar( buf[1] )) return WS_E_INVALID_FORMAT;
read_skip( reader, 1 );
if (!(elem = alloc_element_pair())) return E_OUTOFMEMORY;
node = (struct node *)elem;
start = read_current_ptr( reader );
for (;;)
{
if ((hr = read_utf8_char( reader, &ch, &skip )) != S_OK) goto error;
if (!read_isnamechar( ch )) break;
read_skip( reader, skip );
len += skip;
}
if (!len)
{
hr = WS_E_INVALID_FORMAT;
goto error;
}
if (!(parent = find_parent( reader ))) goto error;
if ((hr = parse_qname( start, len, &elem->prefix, &elem->localName )) != S_OK) goto error;
if ((hr = read_attributes_text( reader, elem )) != S_OK) goto error;
if ((hr = set_namespaces( reader, elem )) != S_OK) goto error;
read_insert_node( reader, parent, node );
reader->state = READER_STATE_STARTELEMENT;
return S_OK;
error:
destroy_nodes( node );
return hr;
}
static inline BOOL is_element_type( unsigned char type )
{
return (type >= RECORD_SHORT_ELEMENT && type <= RECORD_PREFIX_ELEMENT_Z);
}
static HRESULT read_attributes_bin( struct reader *reader, WS_XML_ELEMENT_NODE *elem )
{
WS_XML_ATTRIBUTE *attr;
unsigned char type;
HRESULT hr;
reader->current_attr = 0;
for (;;)
{
if ((hr = read_peek( reader, &type, 1 )) != S_OK) return hr;
if (!is_attribute_type( type )) break;
if ((hr = read_attribute_bin( reader, &attr )) != S_OK) return hr;
if ((hr = append_attribute( elem, attr )) != S_OK)
{
free_attribute( attr );
return hr;
}
reader->current_attr++;
}
return S_OK;
}
static HRESULT read_element_bin( struct reader *reader )
{
struct node *node = NULL, *parent;
WS_XML_ELEMENT_NODE *elem;
unsigned char type;
HRESULT hr;
if ((hr = read_byte( reader, &type )) != S_OK) return hr;
if (!is_element_type( type )) return WS_E_INVALID_FORMAT;
if (!(elem = alloc_element_pair())) return E_OUTOFMEMORY;
node = (struct node *)elem;
if (type >= RECORD_PREFIX_ELEMENT_A && type <= RECORD_PREFIX_ELEMENT_Z)
{
unsigned char ch = type - RECORD_PREFIX_ELEMENT_A + 'a';
if (!(elem->prefix = alloc_xml_string( &ch, 1 )))
{
hr = E_OUTOFMEMORY;
goto error;
}
if ((hr = read_string( reader, &elem->localName )) != S_OK) goto error;
}
else if (type >= RECORD_PREFIX_DICTIONARY_ELEMENT_A && type <= RECORD_PREFIX_DICTIONARY_ELEMENT_Z)
{
unsigned char ch = type - RECORD_PREFIX_DICTIONARY_ELEMENT_A + 'a';
if (!(elem->prefix = alloc_xml_string( &ch, 1 )))
{
hr = E_OUTOFMEMORY;
goto error;
}
if ((hr = read_dict_string( reader, &elem->localName )) != S_OK) goto error;
}
else
{
switch (type)
{
case RECORD_SHORT_ELEMENT:
if (!(elem->prefix = alloc_xml_string( NULL, 0 )))
{
hr = E_OUTOFMEMORY;
goto error;
}
if ((hr = read_string( reader, &elem->localName )) != S_OK) goto error;
break;
case RECORD_ELEMENT:
if ((hr = read_string( reader, &elem->prefix )) != S_OK) goto error;
if ((hr = read_string( reader, &elem->localName )) != S_OK) goto error;
break;
case RECORD_SHORT_DICTIONARY_ELEMENT:
if (!(elem->prefix = alloc_xml_string( NULL, 0 )))
{
hr = E_OUTOFMEMORY;
goto error;
}
if ((hr = read_dict_string( reader, &elem->localName )) != S_OK) goto error;
break;
case RECORD_DICTIONARY_ELEMENT:
if ((hr = read_string( reader, &elem->prefix )) != S_OK) goto error;
if ((hr = read_dict_string( reader, &elem->localName )) != S_OK) goto error;
break;
default:
ERR( "unhandled record type %02x\n", type );
return WS_E_NOT_SUPPORTED;
}
}
if (!(parent = find_parent( reader )))
{
hr = WS_E_INVALID_FORMAT;
goto error;
}
if ((hr = read_attributes_bin( reader, elem )) != S_OK) goto error;
if ((hr = set_namespaces( reader, elem )) != S_OK) goto error;
read_insert_node( reader, parent, node );
reader->state = READER_STATE_STARTELEMENT;
return S_OK;
error:
destroy_nodes( node );
return hr;
}
static HRESULT read_text_text( struct reader *reader )
{
unsigned int len = 0, ch, skip;
const unsigned char *start;
struct node *node, *parent;
WS_XML_TEXT_NODE *text;
WS_XML_UTF8_TEXT *utf8;
HRESULT hr;
start = read_current_ptr( reader );
for (;;)
{
if (read_end_of_data( reader )) break;
if ((hr = read_utf8_char( reader, &ch, &skip )) != S_OK) return hr;
if (ch == '<') break;
read_skip( reader, skip );
len += skip;
}
if (!(parent = find_parent( reader ))) return WS_E_INVALID_FORMAT;
if (!(node = alloc_node( WS_XML_NODE_TYPE_TEXT ))) return E_OUTOFMEMORY;
text = (WS_XML_TEXT_NODE *)node;
if (!(utf8 = alloc_utf8_text( NULL, len )))
{
heap_free( node );
return E_OUTOFMEMORY;
}
if ((hr = decode_text( start, len, utf8->value.bytes, &utf8->value.length )) != S_OK)
{
heap_free( utf8 );
heap_free( node );
return hr;
}
text->text = &utf8->text;
read_insert_node( reader, parent, node );
reader->state = READER_STATE_TEXT;
reader->text_conv_offset = 0;
return S_OK;
}
static struct node *alloc_utf8_text_node( const BYTE *data, ULONG len, WS_XML_UTF8_TEXT **ret )
{
struct node *node;
WS_XML_UTF8_TEXT *utf8;
WS_XML_TEXT_NODE *text;
if (!(node = alloc_node( WS_XML_NODE_TYPE_TEXT ))) return NULL;
if (!(utf8 = alloc_utf8_text( data, len )))
{
heap_free( node );
return NULL;
}
text = (WS_XML_TEXT_NODE *)node;
text->text = &utf8->text;
if (ret) *ret = utf8;
return node;
}
static struct node *alloc_base64_text_node( const BYTE *data, ULONG len, WS_XML_BASE64_TEXT **ret )
{
struct node *node;
WS_XML_BASE64_TEXT *base64;
WS_XML_TEXT_NODE *text;
if (!(node = alloc_node( WS_XML_NODE_TYPE_TEXT ))) return NULL;
if (!(base64 = alloc_base64_text( data, len )))
{
heap_free( node );
return NULL;
}
text = (WS_XML_TEXT_NODE *)node;
text->text = &base64->text;
if (ret) *ret = base64;
return node;
}
static struct node *alloc_bool_text_node( BOOL value )
{
struct node *node;
WS_XML_BOOL_TEXT *text_bool;
WS_XML_TEXT_NODE *text;
if (!(node = alloc_node( WS_XML_NODE_TYPE_TEXT ))) return NULL;
if (!(text_bool = alloc_bool_text( value )))
{
heap_free( node );
return NULL;
}
text = (WS_XML_TEXT_NODE *)node;
text->text = &text_bool->text;
return node;
}
static struct node *alloc_int32_text_node( INT32 value )
{
struct node *node;
WS_XML_INT32_TEXT *text_int32;
WS_XML_TEXT_NODE *text;
if (!(node = alloc_node( WS_XML_NODE_TYPE_TEXT ))) return NULL;
if (!(text_int32 = alloc_int32_text( value )))
{
heap_free( node );
return NULL;
}
text = (WS_XML_TEXT_NODE *)node;
text->text = &text_int32->text;
return node;
}
static struct node *alloc_int64_text_node( INT64 value )
{
struct node *node;
WS_XML_INT64_TEXT *text_int64;
WS_XML_TEXT_NODE *text;
if (!(node = alloc_node( WS_XML_NODE_TYPE_TEXT ))) return NULL;
if (!(text_int64 = alloc_int64_text( value )))
{
heap_free( node );
return NULL;
}
text = (WS_XML_TEXT_NODE *)node;
text->text = &text_int64->text;
return node;
}
static struct node *alloc_float_text_node( float value )
{
struct node *node;
WS_XML_FLOAT_TEXT *text_float;
WS_XML_TEXT_NODE *text;
if (!(node = alloc_node( WS_XML_NODE_TYPE_TEXT ))) return NULL;
if (!(text_float = alloc_float_text( value )))
{
heap_free( node );
return NULL;
}
text = (WS_XML_TEXT_NODE *)node;
text->text = &text_float->text;
return node;
}
static struct node *alloc_double_text_node( double value )
{
struct node *node;
WS_XML_DOUBLE_TEXT *text_double;
WS_XML_TEXT_NODE *text;
if (!(node = alloc_node( WS_XML_NODE_TYPE_TEXT ))) return NULL;
if (!(text_double = alloc_double_text( value )))
{
heap_free( node );
return NULL;
}
text = (WS_XML_TEXT_NODE *)node;
text->text = &text_double->text;
return node;
}
static struct node *alloc_datetime_text_node( const WS_DATETIME *value )
{
struct node *node;
WS_XML_DATETIME_TEXT *text_datetime;
WS_XML_TEXT_NODE *text;
if (!(node = alloc_node( WS_XML_NODE_TYPE_TEXT ))) return NULL;
if (!(text_datetime = alloc_datetime_text( value )))
{
heap_free( node );
return NULL;
}
text = (WS_XML_TEXT_NODE *)node;
text->text = &text_datetime->text;
return node;
}
static struct node *alloc_unique_id_text_node( const GUID *value )
{
struct node *node;
WS_XML_UNIQUE_ID_TEXT *text_unique_id;
WS_XML_TEXT_NODE *text;
if (!(node = alloc_node( WS_XML_NODE_TYPE_TEXT ))) return NULL;
if (!(text_unique_id = alloc_unique_id_text( value )))
{
heap_free( node );
return NULL;
}
text = (WS_XML_TEXT_NODE *)node;
text->text = &text_unique_id->text;
return node;
}
static struct node *alloc_guid_text_node( const GUID *value )
{
struct node *node;
WS_XML_GUID_TEXT *text_guid;
WS_XML_TEXT_NODE *text;
if (!(node = alloc_node( WS_XML_NODE_TYPE_TEXT ))) return NULL;
if (!(text_guid = alloc_guid_text( value )))
{
heap_free( node );
return NULL;
}
text = (WS_XML_TEXT_NODE *)node;
text->text = &text_guid->text;
return node;
}
static struct node *alloc_uint64_text_node( UINT64 value )
{
struct node *node;
WS_XML_UINT64_TEXT *text_uint64;
WS_XML_TEXT_NODE *text;
if (!(node = alloc_node( WS_XML_NODE_TYPE_TEXT ))) return NULL;
if (!(text_uint64 = alloc_uint64_text( value )))
{
heap_free( node );
return NULL;
}
text = (WS_XML_TEXT_NODE *)node;
text->text = &text_uint64->text;
return node;
}
static HRESULT append_text_bytes( struct reader *reader, WS_XML_TEXT_NODE *node, ULONG len )
{
WS_XML_BASE64_TEXT *new, *old = (WS_XML_BASE64_TEXT *)node->text;
HRESULT hr;
if (!(new = alloc_base64_text( NULL, old->length + len ))) return E_OUTOFMEMORY;
memcpy( new->bytes, old->bytes, old->length );
if ((hr = read_bytes( reader, new->bytes + old->length, len )) != S_OK) return hr;
heap_free( old );
node->text = &new->text;
return S_OK;
}
static HRESULT read_text_bytes( struct reader *reader, unsigned char type )
{
struct node *node = NULL, *parent;
WS_XML_BASE64_TEXT *base64;
HRESULT hr;
ULONG len;
if (!(parent = find_parent( reader ))) return WS_E_INVALID_FORMAT;
for (;;)
{
switch (type)
{
case RECORD_BYTES8_TEXT:
case RECORD_BYTES8_TEXT_WITH_ENDELEMENT:
{
UINT8 len_uint8;
if ((hr = read_byte( reader, (unsigned char *)&len_uint8 )) != S_OK) goto error;
len = len_uint8;
break;
}
case RECORD_BYTES16_TEXT:
case RECORD_BYTES16_TEXT_WITH_ENDELEMENT:
{
UINT16 len_uint16;
if ((hr = read_bytes( reader, (unsigned char *)&len_uint16, sizeof(len_uint16) )) != S_OK) goto error;
len = len_uint16;
break;
}
case RECORD_BYTES32_TEXT:
case RECORD_BYTES32_TEXT_WITH_ENDELEMENT:
{
INT32 len_int32;
if ((hr = read_bytes( reader, (unsigned char *)&len_int32, sizeof(len_int32) )) != S_OK) goto error;
if (len_int32 < 0)
{
hr = WS_E_INVALID_FORMAT;
goto error;
}
len = len_int32;
break;
}
default:
ERR( "unexpected type %u\n", type );
hr = E_INVALIDARG;
goto error;
}
if (!node)
{
if (!(node = alloc_base64_text_node( NULL, len, &base64 ))) return E_OUTOFMEMORY;
if ((hr = read_bytes( reader, base64->bytes, len )) != S_OK) goto error;
}
else if ((hr = append_text_bytes( reader, (WS_XML_TEXT_NODE *)node, len )) != S_OK) goto error;
if (type & 1)
{
node->flags |= NODE_FLAG_TEXT_WITH_IMPLICIT_END_ELEMENT;
break;
}
if ((hr = read_peek( reader, &type, 1 )) != S_OK) goto error;
if (type < RECORD_BYTES8_TEXT || type > RECORD_BYTES32_TEXT_WITH_ENDELEMENT) break;
read_skip( reader, 1 );
}
read_insert_node( reader, parent, node );
reader->state = READER_STATE_TEXT;
reader->text_conv_offset = 0;
return S_OK;
error:
free_node( node );
return hr;
}
static HRESULT read_text_bin( struct reader *reader )
{
struct node *node = NULL, *parent;
unsigned char type;
WS_XML_UTF8_TEXT *utf8;
INT32 val_int32;
UINT8 val_uint8;
UINT16 val_uint16;
ULONG len, id;
GUID uuid;
HRESULT hr;
if ((hr = read_byte( reader, &type )) != S_OK) return hr;
if (!is_text_type( type ) || !(parent = find_parent( reader ))) return WS_E_INVALID_FORMAT;
switch (type)
{
case RECORD_ZERO_TEXT:
case RECORD_ZERO_TEXT_WITH_ENDELEMENT:
if (!(node = alloc_int32_text_node( 0 ))) return E_OUTOFMEMORY;
break;
case RECORD_ONE_TEXT:
case RECORD_ONE_TEXT_WITH_ENDELEMENT:
if (!(node = alloc_int32_text_node( 1 ))) return E_OUTOFMEMORY;
break;
case RECORD_FALSE_TEXT:
case RECORD_FALSE_TEXT_WITH_ENDELEMENT:
if (!(node = alloc_bool_text_node( FALSE ))) return E_OUTOFMEMORY;
break;
case RECORD_TRUE_TEXT:
case RECORD_TRUE_TEXT_WITH_ENDELEMENT:
if (!(node = alloc_bool_text_node( TRUE ))) return E_OUTOFMEMORY;
break;
case RECORD_INT8_TEXT:
case RECORD_INT8_TEXT_WITH_ENDELEMENT:
{
INT8 val_int8;
if ((hr = read_byte( reader, (unsigned char *)&val_int8 )) != S_OK) return hr;
if (!(node = alloc_int32_text_node( val_int8 ))) return E_OUTOFMEMORY;
break;
}
case RECORD_INT16_TEXT:
case RECORD_INT16_TEXT_WITH_ENDELEMENT:
{
INT16 val_int16;
if ((hr = read_bytes( reader, (unsigned char *)&val_int16, sizeof(val_int16) )) != S_OK) return hr;
if (!(node = alloc_int32_text_node( val_int16 ))) return E_OUTOFMEMORY;
break;
}
case RECORD_INT32_TEXT:
case RECORD_INT32_TEXT_WITH_ENDELEMENT:
if ((hr = read_bytes( reader, (unsigned char *)&val_int32, sizeof(val_int32) )) != S_OK) return hr;
if (!(node = alloc_int32_text_node( val_int32 ))) return E_OUTOFMEMORY;
break;
case RECORD_INT64_TEXT:
case RECORD_INT64_TEXT_WITH_ENDELEMENT:
{
INT64 val_int64;
if ((hr = read_bytes( reader, (unsigned char *)&val_int64, sizeof(val_int64) )) != S_OK) return hr;
if (!(node = alloc_int64_text_node( val_int64 ))) return E_OUTOFMEMORY;
break;
}
case RECORD_FLOAT_TEXT:
case RECORD_FLOAT_TEXT_WITH_ENDELEMENT:
{
float val_float;
if ((hr = read_bytes( reader, (unsigned char *)&val_float, sizeof(val_float) )) != S_OK) return hr;
if (!(node = alloc_float_text_node( val_float ))) return E_OUTOFMEMORY;
break;
}
case RECORD_DOUBLE_TEXT:
case RECORD_DOUBLE_TEXT_WITH_ENDELEMENT:
{
double val_double;
if ((hr = read_bytes( reader, (unsigned char *)&val_double, sizeof(val_double) )) != S_OK) return hr;
if (!(node = alloc_double_text_node( val_double ))) return E_OUTOFMEMORY;
break;
}
case RECORD_DATETIME_TEXT:
case RECORD_DATETIME_TEXT_WITH_ENDELEMENT:
{
WS_DATETIME datetime;
if ((hr = read_datetime( reader, &datetime )) != S_OK) return hr;
if (!(node = alloc_datetime_text_node( &datetime ))) return E_OUTOFMEMORY;
break;
}
case RECORD_CHARS8_TEXT:
case RECORD_CHARS8_TEXT_WITH_ENDELEMENT:
if ((hr = read_byte( reader, (unsigned char *)&val_uint8 )) != S_OK) return hr;
len = val_uint8;
break;
case RECORD_CHARS16_TEXT:
case RECORD_CHARS16_TEXT_WITH_ENDELEMENT:
if ((hr = read_bytes( reader, (unsigned char *)&val_uint16, sizeof(val_uint16) )) != S_OK) return hr;
len = val_uint16;
break;
case RECORD_CHARS32_TEXT:
case RECORD_CHARS32_TEXT_WITH_ENDELEMENT:
if ((hr = read_bytes( reader, (unsigned char *)&val_int32, sizeof(val_int32) )) != S_OK) return hr;
if (val_int32 < 0) return WS_E_INVALID_FORMAT;
len = val_int32;
break;
case RECORD_BYTES8_TEXT:
case RECORD_BYTES8_TEXT_WITH_ENDELEMENT:
case RECORD_BYTES16_TEXT:
case RECORD_BYTES16_TEXT_WITH_ENDELEMENT:
case RECORD_BYTES32_TEXT:
case RECORD_BYTES32_TEXT_WITH_ENDELEMENT:
return read_text_bytes( reader, type );
case RECORD_EMPTY_TEXT:
case RECORD_EMPTY_TEXT_WITH_ENDELEMENT:
len = 0;
break;
case RECORD_DICTIONARY_TEXT:
case RECORD_DICTIONARY_TEXT_WITH_ENDELEMENT:
{
const WS_XML_STRING *str;
if ((hr = read_int31( reader, &id )) != S_OK) return hr;
if ((hr = lookup_string( reader, id, &str )) != S_OK) return hr;
if (!(node = alloc_utf8_text_node( str->bytes, str->length, NULL ))) return E_OUTOFMEMORY;
break;
}
case RECORD_UNIQUE_ID_TEXT:
case RECORD_UNIQUE_ID_TEXT_WITH_ENDELEMENT:
if ((hr = read_bytes( reader, (unsigned char *)&uuid, sizeof(uuid) )) != S_OK) return hr;
if (!(node = alloc_unique_id_text_node( &uuid ))) return E_OUTOFMEMORY;
break;
case RECORD_GUID_TEXT:
case RECORD_GUID_TEXT_WITH_ENDELEMENT:
if ((hr = read_bytes( reader, (unsigned char *)&uuid, sizeof(uuid) )) != S_OK) return hr;
if (!(node = alloc_guid_text_node( &uuid ))) return E_OUTOFMEMORY;
break;
case RECORD_UINT64_TEXT:
case RECORD_UINT64_TEXT_WITH_ENDELEMENT:
{
UINT64 val_uint64;
if ((hr = read_bytes( reader, (unsigned char *)&val_uint64, sizeof(val_uint64) )) != S_OK) return hr;
if (!(node = alloc_uint64_text_node( val_uint64 ))) return E_OUTOFMEMORY;
break;
}
case RECORD_BOOL_TEXT:
case RECORD_BOOL_TEXT_WITH_ENDELEMENT:
{
BOOL val_bool;
if ((hr = read_bytes( reader, (unsigned char *)&val_bool, sizeof(val_bool) )) != S_OK) return hr;
if (!(node = alloc_bool_text_node( !!val_bool ))) return E_OUTOFMEMORY;
break;
}
default:
ERR( "unhandled record type %02x\n", type );
return WS_E_NOT_SUPPORTED;
}
if (!node)
{
if (!(node = alloc_utf8_text_node( NULL, len, &utf8 ))) return E_OUTOFMEMORY;
if (!len) utf8->value.bytes = (BYTE *)(utf8 + 1); /* quirk */
if ((hr = read_bytes( reader, utf8->value.bytes, len )) != S_OK)
{
free_node( node );
return hr;
}
}
if (type & 1) node->flags |= NODE_FLAG_TEXT_WITH_IMPLICIT_END_ELEMENT;
read_insert_node( reader, parent, node );
reader->state = READER_STATE_TEXT;
reader->text_conv_offset = 0;
return S_OK;
}
static HRESULT read_node_text( struct reader * );
static HRESULT read_startelement_text( struct reader *reader )
{
HRESULT hr;
if (read_cmp( reader, "<?", 2 ) == S_OK)
{
if ((hr = read_xmldecl( reader )) != S_OK) return hr;
}
read_skip_whitespace( reader );
if (read_cmp( reader, "<", 1 ) == S_OK)
{
if ((hr = read_element_text( reader )) != S_OK) return hr;
}
if (read_cmp( reader, "/>", 2 ) == S_OK)
{
read_skip( reader, 2 );
reader->current = LIST_ENTRY( list_tail( &reader->current->children ), struct node, entry );
reader->last = reader->current;
reader->state = READER_STATE_ENDELEMENT;
return S_OK;
}
else if (read_cmp( reader, ">", 1 ) == S_OK)
{
read_skip( reader, 1 );
return read_node_text( reader );
}
return WS_E_INVALID_FORMAT;
}
static HRESULT read_node_bin( struct reader * );
static HRESULT read_startelement_bin( struct reader *reader )
{
if (node_type( reader->current ) != WS_XML_NODE_TYPE_ELEMENT) return WS_E_INVALID_FORMAT;
return read_node_bin( reader );
}
static HRESULT read_startelement( struct reader *reader )
{
switch (reader->input_enc)
{
case WS_XML_READER_ENCODING_TYPE_TEXT: return read_startelement_text( reader );
case WS_XML_READER_ENCODING_TYPE_BINARY: return read_startelement_bin( reader );
default:
ERR( "unhandled encoding %u\n", reader->input_enc );
return WS_E_NOT_SUPPORTED;
}
}
static HRESULT read_to_startelement_text( struct reader *reader, BOOL *found )
{
HRESULT hr;
switch (reader->state)
{
case READER_STATE_INITIAL:
if ((hr = read_xmldecl( reader )) != S_OK) return hr;
break;
case READER_STATE_STARTELEMENT:
if (found) *found = TRUE;
return S_OK;
default:
break;
}
read_skip_whitespace( reader );
if ((hr = read_element_text( reader )) == S_OK && found)
{
if (reader->state == READER_STATE_STARTELEMENT)
*found = TRUE;
else
*found = FALSE;
}
return hr;
}
static HRESULT read_to_startelement_bin( struct reader *reader, BOOL *found )
{
HRESULT hr;
if (reader->state == READER_STATE_STARTELEMENT)
{
if (found) *found = TRUE;
return S_OK;
}
if ((hr = read_element_bin( reader )) == S_OK && found)
{
if (reader->state == READER_STATE_STARTELEMENT)
*found = TRUE;
else
*found = FALSE;
}
return hr;
}
static HRESULT read_to_startelement( struct reader *reader, BOOL *found )
{
switch (reader->input_enc)
{
case WS_XML_READER_ENCODING_TYPE_TEXT: return read_to_startelement_text( reader, found );
case WS_XML_READER_ENCODING_TYPE_BINARY: return read_to_startelement_bin( reader, found );
default:
ERR( "unhandled encoding %u\n", reader->input_enc );
return WS_E_NOT_SUPPORTED;
}
}
static int cmp_name( const unsigned char *name1, ULONG len1, const unsigned char *name2, ULONG len2 )
{
ULONG i;
if (len1 != len2) return 1;
for (i = 0; i < len1; i++) { if (toupper( name1[i] ) != toupper( name2[i] )) return 1; }
return 0;
}
static struct node *find_startelement( struct reader *reader, const WS_XML_STRING *prefix,
const WS_XML_STRING *localname )
{
struct node *parent;
const WS_XML_STRING *str;
for (parent = reader->current; parent; parent = parent->parent)
{
if (node_type( parent ) == WS_XML_NODE_TYPE_ELEMENT)
{
str = parent->hdr.prefix;
if (cmp_name( str->bytes, str->length, prefix->bytes, prefix->length )) continue;
str = parent->hdr.localName;
if (cmp_name( str->bytes, str->length, localname->bytes, localname->length )) continue;
return parent;
}
}
return NULL;
}
static HRESULT read_endelement_text( struct reader *reader )
{
struct node *parent;
unsigned int len = 0, ch, skip;
const unsigned char *start;
WS_XML_STRING prefix, localname;
HRESULT hr;
if ((hr = read_cmp( reader, "</", 2 )) != S_OK) return hr;
read_skip( reader, 2 );
start = read_current_ptr( reader );
for (;;)
{
if ((hr = read_utf8_char( reader, &ch, &skip )) != S_OK) return hr;
if (ch == '>')
{
read_skip( reader, 1 );
break;
}
if (!read_isnamechar( ch )) return WS_E_INVALID_FORMAT;
read_skip( reader, skip );
len += skip;
}
if ((hr = split_qname( start, len, &prefix, &localname )) != S_OK) return hr;
if (!(parent = find_startelement( reader, &prefix, &localname ))) return WS_E_INVALID_FORMAT;
reader->current = LIST_ENTRY( list_tail( &parent->children ), struct node, entry );
reader->last = reader->current;
reader->state = READER_STATE_ENDELEMENT;
return S_OK;
}
static HRESULT read_endelement_bin( struct reader *reader )
{
struct node *parent;
unsigned char type;
HRESULT hr;
if (!(reader->current->flags & NODE_FLAG_TEXT_WITH_IMPLICIT_END_ELEMENT))
{
if ((hr = read_byte( reader, &type )) != S_OK) return hr;
if (type != RECORD_ENDELEMENT) return WS_E_INVALID_FORMAT;
}
if (!(parent = find_parent( reader ))) return WS_E_INVALID_FORMAT;
reader->current = LIST_ENTRY( list_tail( &parent->children ), struct node, entry );
reader->last = reader->current;
reader->state = READER_STATE_ENDELEMENT;
return S_OK;
}
static HRESULT read_endelement( struct reader *reader )
{
if (reader->state == READER_STATE_EOF) return WS_E_INVALID_FORMAT;
if (read_end_of_data( reader ))
{
reader->current = LIST_ENTRY( list_tail( &reader->root->children ), struct node, entry );
reader->last = reader->current;
reader->state = READER_STATE_EOF;
return S_OK;
}
switch (reader->input_enc)
{
case WS_XML_READER_ENCODING_TYPE_TEXT: return read_endelement_text( reader );
case WS_XML_READER_ENCODING_TYPE_BINARY: return read_endelement_bin( reader );
default:
ERR( "unhandled encoding %u\n", reader->input_enc );
return WS_E_NOT_SUPPORTED;
}
}
static HRESULT read_comment_text( struct reader *reader )
{
unsigned int len = 0, ch, skip;
const unsigned char *start;
struct node *node, *parent;
WS_XML_COMMENT_NODE *comment;
HRESULT hr;
if ((hr = read_cmp( reader, "<!--", 4 )) != S_OK) return hr;
read_skip( reader, 4 );
start = read_current_ptr( reader );
for (;;)
{
if (read_cmp( reader, "-->", 3 ) == S_OK)
{
read_skip( reader, 3 );
break;
}
if ((hr = read_utf8_char( reader, &ch, &skip )) != S_OK) return hr;
read_skip( reader, skip );
len += skip;
}
if (!(parent = find_parent( reader ))) return WS_E_INVALID_FORMAT;
if (!(node = alloc_node( WS_XML_NODE_TYPE_COMMENT ))) return E_OUTOFMEMORY;
comment = (WS_XML_COMMENT_NODE *)node;
if (!(comment->value.bytes = heap_alloc( len )))
{
heap_free( node );
return E_OUTOFMEMORY;
}
memcpy( comment->value.bytes, start, len );
comment->value.length = len;
read_insert_node( reader, parent, node );
reader->state = READER_STATE_COMMENT;
return S_OK;
}
static HRESULT read_comment_bin( struct reader *reader )
{
struct node *node, *parent;
WS_XML_COMMENT_NODE *comment;
unsigned char type;
ULONG len;
HRESULT hr;
if ((hr = read_byte( reader, &type )) != S_OK) return hr;
if (type != RECORD_COMMENT) return WS_E_INVALID_FORMAT;
if ((hr = read_int31( reader, &len )) != S_OK) return hr;
if (!(parent = find_parent( reader ))) return WS_E_INVALID_FORMAT;
if (!(node = alloc_node( WS_XML_NODE_TYPE_COMMENT ))) return E_OUTOFMEMORY;
comment = (WS_XML_COMMENT_NODE *)node;
if (!(comment->value.bytes = heap_alloc( len )))
{
heap_free( node );
return E_OUTOFMEMORY;
}
if ((hr = read_bytes( reader, comment->value.bytes, len )) != S_OK)
{
free_node( node );
return E_OUTOFMEMORY;
}
comment->value.length = len;
read_insert_node( reader, parent, node );
reader->state = READER_STATE_COMMENT;
return S_OK;
}
static HRESULT read_startcdata( struct reader *reader )
{
struct node *node, *endnode, *parent;
HRESULT hr;
if ((hr = read_cmp( reader, "<![CDATA[", 9 )) != S_OK) return hr;
read_skip( reader, 9 );
if (!(parent = find_parent( reader ))) return WS_E_INVALID_FORMAT;
if (!(node = alloc_node( WS_XML_NODE_TYPE_CDATA ))) return E_OUTOFMEMORY;
if (!(endnode = alloc_node( WS_XML_NODE_TYPE_END_CDATA )))
{
heap_free( node );
return E_OUTOFMEMORY;
}
list_add_tail( &node->children, &endnode->entry );
endnode->parent = node;
read_insert_node( reader, parent, node );
reader->state = READER_STATE_STARTCDATA;
return S_OK;
}
static HRESULT read_cdata( struct reader *reader )
{
unsigned int len = 0, ch, skip;
const unsigned char *start;
struct node *node;
WS_XML_TEXT_NODE *text;
WS_XML_UTF8_TEXT *utf8;
HRESULT hr;
start = read_current_ptr( reader );
for (;;)
{
if (read_cmp( reader, "]]>", 3 ) == S_OK) break;
if ((hr = read_utf8_char( reader, &ch, &skip )) != S_OK) return hr;
read_skip( reader, skip );
len += skip;
}
if (!(node = alloc_node( WS_XML_NODE_TYPE_TEXT ))) return E_OUTOFMEMORY;
text = (WS_XML_TEXT_NODE *)node;
if (!(utf8 = alloc_utf8_text( start, len )))
{
heap_free( node );
return E_OUTOFMEMORY;
}
text->text = &utf8->text;
read_insert_node( reader, reader->current, node );
reader->state = READER_STATE_CDATA;
return S_OK;
}
static HRESULT read_endcdata( struct reader *reader )
{
struct node *parent;
HRESULT hr;
if ((hr = read_cmp( reader, "]]>", 3 )) != S_OK) return hr;
read_skip( reader, 3 );
if (node_type( reader->current ) == WS_XML_NODE_TYPE_TEXT) parent = reader->current->parent;
else parent = reader->current;
reader->current = LIST_ENTRY( list_tail( &parent->children ), struct node, entry );
reader->last = reader->current;
reader->state = READER_STATE_ENDCDATA;
return S_OK;
}
static HRESULT read_node_text( struct reader *reader )
{
HRESULT hr;
for (;;)
{
if (read_end_of_data( reader ))
{
reader->current = LIST_ENTRY( list_tail( &reader->root->children ), struct node, entry );
reader->last = reader->current;
reader->state = READER_STATE_EOF;
return S_OK;
}
if (reader->state == READER_STATE_STARTCDATA) return read_cdata( reader );
else if (reader->state == READER_STATE_CDATA) return read_endcdata( reader );
else if (read_cmp( reader, "<?", 2 ) == S_OK)
{
if ((hr = read_xmldecl( reader )) != S_OK) return hr;
}
else if (read_cmp( reader, "</", 2 ) == S_OK) return read_endelement_text( reader );
else if (read_cmp( reader, "<![CDATA[", 9 ) == S_OK) return read_startcdata( reader );
else if (read_cmp( reader, "<!--", 4 ) == S_OK) return read_comment_text( reader );
else if (read_cmp( reader, "<", 1 ) == S_OK) return read_element_text( reader );
else if (read_cmp( reader, "/>", 2 ) == S_OK || read_cmp( reader, ">", 1 ) == S_OK)
{
return read_startelement_text( reader );
}
else return read_text_text( reader );
}
}
static HRESULT read_node_bin( struct reader *reader )
{
unsigned char type;
HRESULT hr;
if (reader->current->flags & NODE_FLAG_TEXT_WITH_IMPLICIT_END_ELEMENT)
{
reader->current = LIST_ENTRY( list_tail( &reader->current->parent->children ), struct node, entry );
reader->last = reader->current;
reader->state = READER_STATE_ENDELEMENT;
return S_OK;
}
if (read_end_of_data( reader ))
{
reader->current = LIST_ENTRY( list_tail( &reader->root->children ), struct node, entry );
reader->last = reader->current;
reader->state = READER_STATE_EOF;
return S_OK;
}
if ((hr = read_peek( reader, &type, 1 )) != S_OK) return hr;
if (type == RECORD_ENDELEMENT)
{
return read_endelement_bin( reader );
}
else if (type == RECORD_COMMENT)
{
return read_comment_bin( reader );
}
else if (type >= RECORD_SHORT_ELEMENT && type <= RECORD_PREFIX_ELEMENT_Z)
{
return read_element_bin( reader );
}
else if (type >= RECORD_ZERO_TEXT && type <= RECORD_QNAME_DICTIONARY_TEXT_WITH_ENDELEMENT)
{
return read_text_bin( reader );
}
FIXME( "unhandled record type %02x\n", type );
return WS_E_NOT_SUPPORTED;
}
static HRESULT read_node( struct reader *reader )
{
switch (reader->input_enc)
{
case WS_XML_READER_ENCODING_TYPE_TEXT: return read_node_text( reader );
case WS_XML_READER_ENCODING_TYPE_BINARY: return read_node_bin( reader );
default:
ERR( "unhandled encoding %u\n", reader->input_enc );
return WS_E_NOT_SUPPORTED;
}
}
HRESULT copy_node( WS_XML_READER *handle, WS_XML_WRITER_ENCODING_TYPE enc, struct node **node )
{
struct reader *reader = (struct reader *)handle;
const struct list *ptr;
const struct node *start;
HRESULT hr;
EnterCriticalSection( &reader->cs );
if (reader->magic != READER_MAGIC)
{
LeaveCriticalSection( &reader->cs );
return E_INVALIDARG;
}
if (reader->current != reader->root) ptr = &reader->current->entry;
else /* copy whole tree */
{
if (!read_end_of_data( reader ))
{
for (;;)
{
if ((hr = read_node( reader )) != S_OK) goto done;
if (node_type( reader->current ) == WS_XML_NODE_TYPE_EOF) break;
}
}
ptr = list_head( &reader->root->children );
}
start = LIST_ENTRY( ptr, struct node, entry );
if (node_type( start ) == WS_XML_NODE_TYPE_EOF) hr = WS_E_INVALID_OPERATION;
else hr = dup_tree( start, enc, node );
done:
LeaveCriticalSection( &reader->cs );
return hr;
}
/**************************************************************************
* WsReadEndElement [webservices.@]
*/
HRESULT WINAPI WsReadEndElement( WS_XML_READER *handle, WS_ERROR *error )
{
struct reader *reader = (struct reader *)handle;
HRESULT hr;
TRACE( "%p %p\n", handle, error );
if (error) FIXME( "ignoring error parameter\n" );
if (!reader) return E_INVALIDARG;
EnterCriticalSection( &reader->cs );
if (reader->magic != READER_MAGIC)
{
LeaveCriticalSection( &reader->cs );
return E_INVALIDARG;
}
hr = read_endelement( reader );
LeaveCriticalSection( &reader->cs );
TRACE( "returning %08x\n", hr );
return hr;
}
/**************************************************************************
* WsReadNode [webservices.@]
*/
HRESULT WINAPI WsReadNode( WS_XML_READER *handle, WS_ERROR *error )
{
struct reader *reader = (struct reader *)handle;
HRESULT hr;
TRACE( "%p %p\n", handle, error );
if (error) FIXME( "ignoring error parameter\n" );
if (!reader) return E_INVALIDARG;
EnterCriticalSection( &reader->cs );
if (reader->magic != READER_MAGIC)
{
LeaveCriticalSection( &reader->cs );
return E_INVALIDARG;
}
hr = read_node( reader );
LeaveCriticalSection( &reader->cs );
TRACE( "returning %08x\n", hr );
return hr;
}
static HRESULT skip_node( struct reader *reader )
{
const struct node *parent;
HRESULT hr;
if (node_type( reader->current ) == WS_XML_NODE_TYPE_EOF) return WS_E_INVALID_OPERATION;
if (node_type( reader->current ) == WS_XML_NODE_TYPE_ELEMENT) parent = reader->current;
else parent = NULL;
for (;;)
{
if ((hr = read_node( reader )) != S_OK || !parent) break;
if (node_type( reader->current ) != WS_XML_NODE_TYPE_END_ELEMENT) continue;
if (reader->current->parent == parent) return read_node( reader );
}
return hr;
}
/**************************************************************************
* WsSkipNode [webservices.@]
*/
HRESULT WINAPI WsSkipNode( WS_XML_READER *handle, WS_ERROR *error )
{
struct reader *reader = (struct reader *)handle;
HRESULT hr;
TRACE( "%p %p\n", handle, error );
if (error) FIXME( "ignoring error parameter\n" );
if (!reader) return E_INVALIDARG;
EnterCriticalSection( &reader->cs );
if (reader->magic != READER_MAGIC)
{
LeaveCriticalSection( &reader->cs );
return E_INVALIDARG;
}
hr = skip_node( reader );
LeaveCriticalSection( &reader->cs );
TRACE( "returning %08x\n", hr );
return hr;
}
/**************************************************************************
* WsReadStartElement [webservices.@]
*/
HRESULT WINAPI WsReadStartElement( WS_XML_READER *handle, WS_ERROR *error )
{
struct reader *reader = (struct reader *)handle;
HRESULT hr;
TRACE( "%p %p\n", handle, error );
if (error) FIXME( "ignoring error parameter\n" );
if (!reader) return E_INVALIDARG;
EnterCriticalSection( &reader->cs );
if (reader->magic != READER_MAGIC)
{
LeaveCriticalSection( &reader->cs );
return E_INVALIDARG;
}
hr = read_startelement( reader );
LeaveCriticalSection( &reader->cs );
TRACE( "returning %08x\n", hr );
return hr;
}
/**************************************************************************
* WsReadToStartElement [webservices.@]
*/
HRESULT WINAPI WsReadToStartElement( WS_XML_READER *handle, const WS_XML_STRING *localname,
const WS_XML_STRING *ns, BOOL *found, WS_ERROR *error )
{
struct reader *reader = (struct reader *)handle;
HRESULT hr;
TRACE( "%p %s %s %p %p\n", handle, debugstr_xmlstr(localname), debugstr_xmlstr(ns), found, error );
if (error) FIXME( "ignoring error parameter\n" );
if (!reader) return E_INVALIDARG;
if (localname || ns) FIXME( "name and/or namespace not verified\n" );
EnterCriticalSection( &reader->cs );
if (reader->magic != READER_MAGIC)
{
LeaveCriticalSection( &reader->cs );
return E_INVALIDARG;
}
hr = read_to_startelement( reader, found );
LeaveCriticalSection( &reader->cs );
TRACE( "returning %08x\n", hr );
return hr;
}
BOOL move_to_root_element( struct node *root, struct node **current )
{
struct list *ptr;
struct node *node;
if (!(ptr = list_head( &root->children ))) return FALSE;
node = LIST_ENTRY( ptr, struct node, entry );
if (node_type( node ) == WS_XML_NODE_TYPE_ELEMENT)
{
*current = node;
return TRUE;
}
while ((ptr = list_next( &root->children, &node->entry )))
{
struct node *next = LIST_ENTRY( ptr, struct node, entry );
if (node_type( next ) == WS_XML_NODE_TYPE_ELEMENT)
{
*current = next;
return TRUE;
}
node = next;
}
return FALSE;
}
BOOL move_to_next_element( struct node **current )
{
struct list *ptr;
struct node *node = *current, *parent = (*current)->parent;
if (!parent) return FALSE;
while ((ptr = list_next( &parent->children, &node->entry )))
{
struct node *next = LIST_ENTRY( ptr, struct node, entry );
if (node_type( next ) == WS_XML_NODE_TYPE_ELEMENT)
{
*current = next;
return TRUE;
}
node = next;
}
return FALSE;
}
BOOL move_to_prev_element( struct node **current )
{
struct list *ptr;
struct node *node = *current, *parent = (*current)->parent;
if (!parent) return FALSE;
while ((ptr = list_prev( &parent->children, &node->entry )))
{
struct node *prev = LIST_ENTRY( ptr, struct node, entry );
if (node_type( prev ) == WS_XML_NODE_TYPE_ELEMENT)
{
*current = prev;
return TRUE;
}
node = prev;
}
return FALSE;
}
BOOL move_to_child_element( struct node **current )
{
struct list *ptr;
struct node *child, *node = *current;
if (!(ptr = list_head( &node->children ))) return FALSE;
child = LIST_ENTRY( ptr, struct node, entry );
if (node_type( child ) == WS_XML_NODE_TYPE_ELEMENT)
{
*current = child;
return TRUE;
}
while ((ptr = list_next( &node->children, &child->entry )))
{
struct node *next = LIST_ENTRY( ptr, struct node, entry );
if (node_type( next ) == WS_XML_NODE_TYPE_ELEMENT)
{
*current = next;
return TRUE;
}
child = next;
}
return FALSE;
}
BOOL move_to_end_element( struct node **current )
{
struct list *ptr;
struct node *node = *current;
if (node_type( node ) != WS_XML_NODE_TYPE_ELEMENT) return FALSE;
if ((ptr = list_tail( &node->children )))
{
struct node *tail = LIST_ENTRY( ptr, struct node, entry );
if (node_type( tail ) == WS_XML_NODE_TYPE_END_ELEMENT)
{
*current = tail;
return TRUE;
}
}
return FALSE;
}
BOOL move_to_parent_element( struct node **current )
{
struct node *parent = (*current)->parent;
if (parent && (node_type( parent ) == WS_XML_NODE_TYPE_ELEMENT ||
node_type( parent ) == WS_XML_NODE_TYPE_BOF))
{
*current = parent;
return TRUE;
}
return FALSE;
}
BOOL move_to_first_node( struct node **current )
{
struct list *ptr;
struct node *node = *current;
if ((ptr = list_head( &node->parent->children )))
{
*current = LIST_ENTRY( ptr, struct node, entry );
return TRUE;
}
return FALSE;
}
BOOL move_to_next_node( struct node **current )
{
struct list *ptr;
struct node *node = *current;
if ((ptr = list_next( &node->parent->children, &node->entry )))
{
*current = LIST_ENTRY( ptr, struct node, entry );
return TRUE;
}
return FALSE;
}
BOOL move_to_prev_node( struct node **current )
{
struct list *ptr;
struct node *node = *current;
if ((ptr = list_prev( &node->parent->children, &node->entry )))
{
*current = LIST_ENTRY( ptr, struct node, entry );
return TRUE;
}
return FALSE;
}
BOOL move_to_bof( struct node *root, struct node **current )
{
*current = root;
return TRUE;
}
BOOL move_to_eof( struct node *root, struct node **current )
{
struct list *ptr;
if ((ptr = list_tail( &root->children )))
{
*current = LIST_ENTRY( ptr, struct node, entry );
return TRUE;
}
return FALSE;
}
BOOL move_to_child_node( struct node **current )
{
struct list *ptr;
struct node *node = *current;
if ((ptr = list_head( &node->children )))
{
*current = LIST_ENTRY( ptr, struct node, entry );
return TRUE;
}
return FALSE;
}
BOOL move_to_parent_node( struct node **current )
{
struct node *parent = (*current)->parent;
if (!parent) return FALSE;
*current = parent;
return TRUE;
}
static HRESULT read_move_to( struct reader *reader, WS_MOVE_TO move, BOOL *found )
{
BOOL success = FALSE;
HRESULT hr = S_OK;
if (!read_end_of_data( reader ))
{
struct node *saved_current = reader->current;
while (reader->state != READER_STATE_EOF && (hr = read_node( reader )) == S_OK) { /* nothing */ };
if (hr != S_OK) return hr;
reader->current = saved_current;
}
switch (move)
{
case WS_MOVE_TO_ROOT_ELEMENT:
success = move_to_root_element( reader->root, &reader->current );
break;
case WS_MOVE_TO_NEXT_ELEMENT:
success = move_to_next_element( &reader->current );
break;
case WS_MOVE_TO_PREVIOUS_ELEMENT:
success = move_to_prev_element( &reader->current );
break;
case WS_MOVE_TO_CHILD_ELEMENT:
success = move_to_child_element( &reader->current );
break;
case WS_MOVE_TO_END_ELEMENT:
success = move_to_end_element( &reader->current );
break;
case WS_MOVE_TO_PARENT_ELEMENT:
success = move_to_parent_element( &reader->current );
break;
case WS_MOVE_TO_FIRST_NODE:
success = move_to_first_node( &reader->current );
break;
case WS_MOVE_TO_NEXT_NODE:
success = move_to_next_node( &reader->current );
break;
case WS_MOVE_TO_PREVIOUS_NODE:
success = move_to_prev_node( &reader->current );
break;
case WS_MOVE_TO_CHILD_NODE:
success = move_to_child_node( &reader->current );
break;
case WS_MOVE_TO_BOF:
success = move_to_bof( reader->root, &reader->current );
break;
case WS_MOVE_TO_EOF:
success = move_to_eof( reader->root, &reader->current );
break;
default:
FIXME( "unhandled move %u\n", move );
return E_NOTIMPL;
}
if (found)
{
*found = success;
return S_OK;
}
return success ? S_OK : WS_E_INVALID_FORMAT;
}
/**************************************************************************
* WsMoveReader [webservices.@]
*/
HRESULT WINAPI WsMoveReader( WS_XML_READER *handle, WS_MOVE_TO move, BOOL *found, WS_ERROR *error )
{
struct reader *reader = (struct reader *)handle;
HRESULT hr;
TRACE( "%p %u %p %p\n", handle, move, found, error );
if (error) FIXME( "ignoring error parameter\n" );
if (!reader) return E_INVALIDARG;
EnterCriticalSection( &reader->cs );
if (reader->magic != READER_MAGIC)
{
LeaveCriticalSection( &reader->cs );
return E_INVALIDARG;
}
if (reader->input_type != WS_XML_READER_INPUT_TYPE_BUFFER) hr = WS_E_INVALID_OPERATION;
else hr = read_move_to( reader, move, found );
LeaveCriticalSection( &reader->cs );
TRACE( "returning %08x\n", hr );
return hr;
}
/**************************************************************************
* WsReadStartAttribute [webservices.@]
*/
HRESULT WINAPI WsReadStartAttribute( WS_XML_READER *handle, ULONG index, WS_ERROR *error )
{
struct reader *reader = (struct reader *)handle;
const WS_XML_ELEMENT_NODE *elem;
HRESULT hr = S_OK;
TRACE( "%p %u %p\n", handle, index, error );
if (error) FIXME( "ignoring error parameter\n" );
if (!reader) return E_INVALIDARG;
EnterCriticalSection( &reader->cs );
if (reader->magic != READER_MAGIC)
{
LeaveCriticalSection( &reader->cs );
return E_INVALIDARG;
}
elem = &reader->current->hdr;
if (reader->state != READER_STATE_STARTELEMENT || index >= elem->attributeCount) hr = WS_E_INVALID_FORMAT;
else
{
reader->current_attr = index;
reader->state = READER_STATE_STARTATTRIBUTE;
}
LeaveCriticalSection( &reader->cs );
TRACE( "returning %08x\n", hr );
return S_OK;
}
/**************************************************************************
* WsReadEndAttribute [webservices.@]
*/
HRESULT WINAPI WsReadEndAttribute( WS_XML_READER *handle, WS_ERROR *error )
{
struct reader *reader = (struct reader *)handle;
HRESULT hr = S_OK;
TRACE( "%p %p\n", handle, error );
if (error) FIXME( "ignoring error parameter\n" );
if (!reader) return E_INVALIDARG;
EnterCriticalSection( &reader->cs );
if (reader->magic != READER_MAGIC)
{
LeaveCriticalSection( &reader->cs );
return E_INVALIDARG;
}
if (reader->state != READER_STATE_STARTATTRIBUTE) hr = WS_E_INVALID_FORMAT;
else reader->state = READER_STATE_STARTELEMENT;
LeaveCriticalSection( &reader->cs );
TRACE( "returning %08x\n", hr );
return hr;
}
static HRESULT str_to_bool( const unsigned char *str, ULONG len, BOOL *ret )
{
if (len == 4 && !memcmp( str, "true", 4 )) *ret = TRUE;
else if (len == 1 && !memcmp( str, "1", 1 )) *ret = TRUE;
else if (len == 5 && !memcmp( str, "false", 5 )) *ret = FALSE;
else if (len == 1 && !memcmp( str, "0", 1 )) *ret = FALSE;
else return WS_E_INVALID_FORMAT;
return S_OK;
}
static HRESULT str_to_int64( const unsigned char *str, ULONG len, INT64 min, INT64 max, INT64 *ret )
{
BOOL negative = FALSE;
const unsigned char *ptr = str;
*ret = 0;
while (len && read_isspace( *ptr )) { ptr++; len--; }
while (len && read_isspace( ptr[len - 1] )) { len--; }
if (!len) return WS_E_INVALID_FORMAT;
if (*ptr == '-')
{
negative = TRUE;
ptr++;
len--;
}
if (!len) return WS_E_INVALID_FORMAT;
while (len--)
{
int val;
if (!isdigit( *ptr )) return WS_E_INVALID_FORMAT;
val = *ptr - '0';
if (negative) val = -val;
if ((!negative && (*ret > max / 10 || *ret * 10 > max - val)) ||
(negative && (*ret < min / 10 || *ret * 10 < min - val)))
{
return WS_E_NUMERIC_OVERFLOW;
}
*ret = *ret * 10 + val;
ptr++;
}
return S_OK;
}
static HRESULT str_to_uint64( const unsigned char *str, ULONG len, UINT64 max, UINT64 *ret )
{
const unsigned char *ptr = str;
*ret = 0;
while (len && read_isspace( *ptr )) { ptr++; len--; }
while (len && read_isspace( ptr[len - 1] )) { len--; }
if (!len) return WS_E_INVALID_FORMAT;
while (len--)
{
unsigned int val;
if (!isdigit( *ptr )) return WS_E_INVALID_FORMAT;
val = *ptr - '0';
if ((*ret > max / 10 || *ret * 10 > max - val)) return WS_E_NUMERIC_OVERFLOW;
*ret = *ret * 10 + val;
ptr++;
}
return S_OK;
}
static HRESULT str_to_double( const unsigned char *str, ULONG len, double *ret )
{
BOOL found_sign = FALSE, found_exponent = FALSE, found_digit = FALSE, found_decimal = FALSE;
static const unsigned __int64 nan = 0xfff8000000000000;
static const unsigned __int64 inf = 0x7ff0000000000000;
static const unsigned __int64 inf_min = 0xfff0000000000000;
const char *p = (const char *)str;
double tmp;
ULONG i;
while (len && read_isspace( *p )) { p++; len--; }
while (len && read_isspace( p[len - 1] )) { len--; }
if (!len) return WS_E_INVALID_FORMAT;
if (len == 3 && !memcmp( p, "NaN", 3 ))
{
*(unsigned __int64 *)ret = nan;
return S_OK;
}
if (len == 3 && !memcmp( p, "INF", 3 ))
{
*(unsigned __int64 *)ret = inf;
return S_OK;
}
if (len == 4 && !memcmp( p, "-INF", 4 ))
{
*(unsigned __int64 *)ret = inf_min;
return S_OK;
}
for (i = 0; i < len; i++)
{
if (p[i] >= '0' && p[i] <= '9')
{
found_digit = TRUE;
continue;
}
if (!found_sign && !found_digit && (p[i] == '+' || p[i] == '-'))
{
found_sign = TRUE;
continue;
}
if (!found_exponent && found_digit && (p[i] == 'e' || p[i] == 'E'))
{
found_exponent = found_decimal = TRUE;
found_digit = found_sign = FALSE;
continue;
}
if (!found_decimal && p[i] == '.')
{
found_decimal = TRUE;
continue;
}
return WS_E_INVALID_FORMAT;
}
if (!found_digit && !found_exponent)
{
*ret = 0;
return S_OK;
}
if (_snscanf_l( p, len, "%lf", c_locale, &tmp ) != 1) return WS_E_INVALID_FORMAT;
*ret = tmp;
return S_OK;
}
static HRESULT str_to_float( const unsigned char *str, ULONG len, float *ret )
{
static const unsigned int inf = 0x7f800000;
static const unsigned int inf_min = 0xff800000;
const unsigned char *p = str;
double val;
HRESULT hr;
while (len && read_isspace( *p )) { p++; len--; }
while (len && read_isspace( p[len - 1] )) { len--; }
if (!len) return WS_E_INVALID_FORMAT;
if (len == 3 && !memcmp( p, "INF", 3 ))
{
*(unsigned int *)ret = inf;
return S_OK;
}
if (len == 4 && !memcmp( p, "-INF", 4 ))
{
*(unsigned int *)ret = inf_min;
return S_OK;
}
if ((hr = str_to_double( p, len, &val )) != S_OK) return hr;
*ret = val;
return S_OK;
}
HRESULT str_to_guid( const unsigned char *str, ULONG len, GUID *ret )
{
static const unsigned char hex[] =
{
0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0, /* 0x00 */
0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0, /* 0x10 */
0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0, /* 0x20 */
0,1,2,3,4,5,6,7,8,9,0,0,0,0,0,0, /* 0x30 */
0,10,11,12,13,14,15,0,0,0,0,0,0,0,0,0, /* 0x40 */
0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0, /* 0x50 */
0,10,11,12,13,14,15 /* 0x60 */
};
const unsigned char *p = str;
ULONG i;
while (len && read_isspace( *p )) { p++; len--; }
while (len && read_isspace( p[len - 1] )) { len--; }
if (len != 36) return WS_E_INVALID_FORMAT;
if (p[8] != '-' || p[13] != '-' || p[18] != '-' || p[23] != '-')
return WS_E_INVALID_FORMAT;
for (i = 0; i < 36; i++)
{
if (i == 8 || i == 13 || i == 18 || i == 23) continue;
if (p[i] > 'f' || (!hex[p[i]] && p[i] != '0')) return WS_E_INVALID_FORMAT;
}
ret->Data1 = hex[p[0]] << 28 | hex[p[1]] << 24 | hex[p[2]] << 20 | hex[p[3]] << 16 |
hex[p[4]] << 12 | hex[p[5]] << 8 | hex[p[6]] << 4 | hex[p[7]];
ret->Data2 = hex[p[9]] << 12 | hex[p[10]] << 8 | hex[p[11]] << 4 | hex[p[12]];
ret->Data3 = hex[p[14]] << 12 | hex[p[15]] << 8 | hex[p[16]] << 4 | hex[p[17]];
ret->Data4[0] = hex[p[19]] << 4 | hex[p[20]];
ret->Data4[1] = hex[p[21]] << 4 | hex[p[22]];
ret->Data4[2] = hex[p[24]] << 4 | hex[p[25]];
ret->Data4[3] = hex[p[26]] << 4 | hex[p[27]];
ret->Data4[4] = hex[p[28]] << 4 | hex[p[29]];
ret->Data4[5] = hex[p[30]] << 4 | hex[p[31]];
ret->Data4[6] = hex[p[32]] << 4 | hex[p[33]];
ret->Data4[7] = hex[p[34]] << 4 | hex[p[35]];
return S_OK;
}
static HRESULT str_to_string( const unsigned char *str, ULONG len, WS_HEAP *heap, WS_STRING *ret )
{
int len_utf16 = MultiByteToWideChar( CP_UTF8, 0, (const char *)str, len, NULL, 0 );
if (!(ret->chars = ws_alloc( heap, len_utf16 * sizeof(WCHAR) ))) return WS_E_QUOTA_EXCEEDED;
MultiByteToWideChar( CP_UTF8, 0, (const char *)str, len, ret->chars, len_utf16 );
ret->length = len_utf16;
return S_OK;
}
static HRESULT str_to_unique_id( const unsigned char *str, ULONG len, WS_HEAP *heap, WS_UNIQUE_ID *ret )
{
if (len == 45 && !memcmp( str, "urn:uuid:", 9 ))
{
ret->uri.length = 0;
ret->uri.chars = NULL;
return str_to_guid( str + 9, len - 9, &ret->guid );
}
memset( &ret->guid, 0, sizeof(ret->guid) );
return str_to_string( str, len, heap, &ret->uri );
}
static inline unsigned char decode_char( unsigned char c )
{
if (c >= 'A' && c <= 'Z') return c - 'A';
if (c >= 'a' && c <= 'z') return c - 'a' + 26;
if (c >= '0' && c <= '9') return c - '0' + 52;
if (c == '+') return 62;
if (c == '/') return 63;
return 64;
}
static ULONG decode_base64( const unsigned char *base64, ULONG len, unsigned char *buf )
{
ULONG i = 0;
unsigned char c0, c1, c2, c3;
const unsigned char *p = base64;
while (len > 4)
{
if ((c0 = decode_char( p[0] )) > 63) return 0;
if ((c1 = decode_char( p[1] )) > 63) return 0;
if ((c2 = decode_char( p[2] )) > 63) return 0;
if ((c3 = decode_char( p[3] )) > 63) return 0;
buf[i + 0] = (c0 << 2) | (c1 >> 4);
buf[i + 1] = (c1 << 4) | (c2 >> 2);
buf[i + 2] = (c2 << 6) | c3;
len -= 4;
i += 3;
p += 4;
}
if (p[2] == '=')
{
if ((c0 = decode_char( p[0] )) > 63) return 0;
if ((c1 = decode_char( p[1] )) > 63) return 0;
buf[i] = (c0 << 2) | (c1 >> 4);
i++;
}
else if (p[3] == '=')
{
if ((c0 = decode_char( p[0] )) > 63) return 0;
if ((c1 = decode_char( p[1] )) > 63) return 0;
if ((c2 = decode_char( p[2] )) > 63) return 0;
buf[i + 0] = (c0 << 2) | (c1 >> 4);
buf[i + 1] = (c1 << 4) | (c2 >> 2);
i += 2;
}
else
{
if ((c0 = decode_char( p[0] )) > 63) return 0;
if ((c1 = decode_char( p[1] )) > 63) return 0;
if ((c2 = decode_char( p[2] )) > 63) return 0;
if ((c3 = decode_char( p[3] )) > 63) return 0;
buf[i + 0] = (c0 << 2) | (c1 >> 4);
buf[i + 1] = (c1 << 4) | (c2 >> 2);
buf[i + 2] = (c2 << 6) | c3;
i += 3;
}
return i;
}
static HRESULT str_to_bytes( const unsigned char *str, ULONG len, WS_HEAP *heap, WS_BYTES *ret )
{
const unsigned char *p = str;
while (len && read_isspace( *p )) { p++; len--; }
while (len && read_isspace( p[len - 1] )) { len--; }
if (len % 4) return WS_E_INVALID_FORMAT;
if (!(ret->bytes = ws_alloc( heap, len * 3 / 4 ))) return WS_E_QUOTA_EXCEEDED;
ret->length = decode_base64( p, len, ret->bytes );
return S_OK;
}
static HRESULT str_to_xml_string( const unsigned char *str, ULONG len, WS_HEAP *heap, WS_XML_STRING *ret )
{
if (!(ret->bytes = ws_alloc( heap, len ))) return WS_E_QUOTA_EXCEEDED;
memcpy( ret->bytes, str, len );
ret->length = len;
ret->dictionary = NULL;
ret->id = 0;
return S_OK;
}
static HRESULT copy_xml_string( WS_HEAP *heap, const WS_XML_STRING *src, WS_XML_STRING *dst )
{
if (!(dst->bytes = ws_alloc( heap, src->length ))) return WS_E_QUOTA_EXCEEDED;
memcpy( dst->bytes, src->bytes, src->length );
dst->length = src->length;
return S_OK;
}
static HRESULT str_to_qname( struct reader *reader, const unsigned char *str, ULONG len, WS_HEAP *heap,
WS_XML_STRING *prefix_ret, WS_XML_STRING *localname_ret, WS_XML_STRING *ns_ret )
{
const unsigned char *p = str;
WS_XML_STRING prefix, localname;
const WS_XML_STRING *ns;
HRESULT hr;
while (len && read_isspace( *p )) { p++; len--; }
while (len && read_isspace( p[len - 1] )) { len--; }
if ((hr = split_qname( p, len, &prefix, &localname )) != S_OK) return hr;
if (!(ns = get_namespace( reader, &prefix ))) return WS_E_INVALID_FORMAT;
if (prefix_ret && (hr = copy_xml_string( heap, &prefix, prefix_ret )) != S_OK) return hr;
if ((hr = copy_xml_string( heap, &localname, localname_ret )) != S_OK)
{
ws_free( heap, prefix_ret->bytes, prefix_ret->length );
return hr;
}
if ((hr = copy_xml_string( heap, ns, ns_ret )) != S_OK)
{
ws_free( heap, prefix_ret->bytes, prefix_ret->length );
ws_free( heap, localname_ret->bytes, localname_ret->length );
return hr;
}
return S_OK;
}
static HRESULT read_qualified_name( struct reader *reader, WS_HEAP *heap, WS_XML_STRING *prefix,
WS_XML_STRING *localname, WS_XML_STRING *ns )
{
const WS_XML_TEXT_NODE *node = (const WS_XML_TEXT_NODE *)reader->current;
const WS_XML_UTF8_TEXT *utf8 = (const WS_XML_UTF8_TEXT *)node->text;
return str_to_qname( reader, utf8->value.bytes, utf8->value.length, heap, prefix, localname, ns );
}
/**************************************************************************
* WsReadQualifiedName [webservices.@]
*/
HRESULT WINAPI WsReadQualifiedName( WS_XML_READER *handle, WS_HEAP *heap, WS_XML_STRING *prefix,
WS_XML_STRING *localname, WS_XML_STRING *ns,
WS_ERROR *error )
{
struct reader *reader = (struct reader *)handle;
HRESULT hr;
TRACE( "%p %p %p %p %p %p\n", handle, heap, prefix, localname, ns, error );
if (error) FIXME( "ignoring error parameter\n" );
if (!reader || !heap) return E_INVALIDARG;
EnterCriticalSection( &reader->cs );
if (reader->magic != READER_MAGIC)
{
LeaveCriticalSection( &reader->cs );
return E_INVALIDARG;
}
if (!reader->input_type) hr = WS_E_INVALID_OPERATION;
else if (!localname) hr = E_INVALIDARG;
else if (reader->state != READER_STATE_TEXT) hr = WS_E_INVALID_FORMAT;
else hr = read_qualified_name( reader, heap, prefix, localname, ns );
LeaveCriticalSection( &reader->cs );
TRACE( "returning %08x\n", hr );
return hr;
}
static const int month_offsets[2][12] =
{
{0, 31, 59, 90, 120, 151, 181, 212, 243, 273, 304, 334},
{0, 31, 60, 91, 121, 152, 182, 213, 244, 274, 305, 335}
};
static inline int valid_day( int year, int month, int day )
{
return day > 0 && day <= month_days[leap_year( year )][month - 1];
}
static inline int leap_days_before( int year )
{
return (year - 1) / 4 - (year - 1) / 100 + (year - 1) / 400;
}
static HRESULT str_to_datetime( const unsigned char *bytes, ULONG len, WS_DATETIME *ret )
{
const unsigned char *p = bytes, *q;
int year, month, day, hour, min, sec, sec_frac = 0, tz_hour, tz_min, tz_neg;
while (len && read_isspace( *p )) { p++; len--; }
while (len && read_isspace( p[len - 1] )) { len--; }
q = p;
while (len && isdigit( *q )) { q++; len--; };
if (q - p != 4 || !len || *q != '-') return WS_E_INVALID_FORMAT;
year = (p[0] - '0') * 1000 + (p[1] - '0') * 100 + (p[2] - '0') * 10 + p[3] - '0';
if (year < 1) return WS_E_INVALID_FORMAT;
p = ++q; len--;
while (len && isdigit( *q )) { q++; len--; };
if (q - p != 2 || !len || *q != '-') return WS_E_INVALID_FORMAT;
month = (p[0] - '0') * 10 + p[1] - '0';
if (month < 1 || month > 12) return WS_E_INVALID_FORMAT;
p = ++q; len--;
while (len && isdigit( *q )) { q++; len--; };
if (q - p != 2 || !len || *q != 'T') return WS_E_INVALID_FORMAT;
day = (p[0] - '0') * 10 + p[1] - '0';
if (!valid_day( year, month, day )) return WS_E_INVALID_FORMAT;
p = ++q; len--;
while (len && isdigit( *q )) { q++; len--; };
if (q - p != 2 || !len || *q != ':') return WS_E_INVALID_FORMAT;
hour = (p[0] - '0') * 10 + p[1] - '0';
if (hour > 24) return WS_E_INVALID_FORMAT;
p = ++q; len--;
while (len && isdigit( *q )) { q++; len--; };
if (q - p != 2 || !len || *q != ':') return WS_E_INVALID_FORMAT;
min = (p[0] - '0') * 10 + p[1] - '0';
if (min > 59 || (min > 0 && hour == 24)) return WS_E_INVALID_FORMAT;
p = ++q; len--;
while (len && isdigit( *q )) { q++; len--; };
if (q - p != 2 || !len) return WS_E_INVALID_FORMAT;
sec = (p[0] - '0') * 10 + p[1] - '0';
if (sec > 59 || (sec > 0 && hour == 24)) return WS_E_INVALID_FORMAT;
if (*q == '.')
{
unsigned int i, nb_digits, mul = TICKS_PER_SEC / 10;
p = ++q; len--;
while (len && isdigit( *q )) { q++; len--; };
nb_digits = q - p;
if (nb_digits < 1 || nb_digits > 7) return WS_E_INVALID_FORMAT;
for (i = 0; i < nb_digits; i++)
{
sec_frac += (p[i] - '0') * mul;
mul /= 10;
}
}
if (*q == 'Z')
{
if (--len) return WS_E_INVALID_FORMAT;
tz_hour = tz_min = tz_neg = 0;
ret->format = WS_DATETIME_FORMAT_UTC;
}
else if (*q == '+' || *q == '-')
{
tz_neg = (*q == '-') ? 1 : 0;
p = ++q; len--;
while (len && isdigit( *q )) { q++; len--; };
if (q - p != 2 || !len || *q != ':') return WS_E_INVALID_FORMAT;
tz_hour = (p[0] - '0') * 10 + p[1] - '0';
if (tz_hour > 14) return WS_E_INVALID_FORMAT;
p = ++q; len--;
while (len && isdigit( *q )) { q++; len--; };
if (q - p != 2 || len) return WS_E_INVALID_FORMAT;
tz_min = (p[0] - '0') * 10 + p[1] - '0';
if (tz_min > 59 || (tz_min > 0 && tz_hour == 14)) return WS_E_INVALID_FORMAT;
ret->format = WS_DATETIME_FORMAT_LOCAL;
}
else return WS_E_INVALID_FORMAT;
ret->ticks = ((year - 1) * 365 + leap_days_before( year )) * TICKS_PER_DAY;
ret->ticks += month_offsets[leap_year( year )][month - 1] * TICKS_PER_DAY;
ret->ticks += (day - 1) * TICKS_PER_DAY;
ret->ticks += hour * TICKS_PER_HOUR;
ret->ticks += min * TICKS_PER_MIN;
ret->ticks += sec * TICKS_PER_SEC;
ret->ticks += sec_frac;
if (tz_neg)
{
if (tz_hour * TICKS_PER_HOUR + tz_min * TICKS_PER_MIN + ret->ticks > TICKS_MAX)
return WS_E_INVALID_FORMAT;
ret->ticks += tz_hour * TICKS_PER_HOUR;
ret->ticks += tz_min * TICKS_PER_MIN;
}
else
{
if (tz_hour * TICKS_PER_HOUR + tz_min * TICKS_PER_MIN > ret->ticks)
return WS_E_INVALID_FORMAT;
ret->ticks -= tz_hour * TICKS_PER_HOUR;
ret->ticks -= tz_min * TICKS_PER_MIN;
}
return S_OK;
}
/**************************************************************************
* WsDateTimeToFileTime [webservices.@]
*/
HRESULT WINAPI WsDateTimeToFileTime( const WS_DATETIME *dt, FILETIME *ft, WS_ERROR *error )
{
unsigned __int64 ticks;
TRACE( "%p %p %p\n", dt, ft, error );
if (error) FIXME( "ignoring error parameter\n" );
if (!dt || !ft) return E_INVALIDARG;
if (dt->ticks < TICKS_1601_01_01) return WS_E_INVALID_FORMAT;
ticks = dt->ticks - TICKS_1601_01_01;
ft->dwHighDateTime = ticks >> 32;
ft->dwLowDateTime = (DWORD)ticks;
return S_OK;
}
/**************************************************************************
* WsFileTimeToDateTime [webservices.@]
*/
HRESULT WINAPI WsFileTimeToDateTime( const FILETIME *ft, WS_DATETIME *dt, WS_ERROR *error )
{
unsigned __int64 ticks;
TRACE( "%p %p %p\n", ft, dt, error );
if (error) FIXME( "ignoring error parameter\n" );
if (!dt || !ft) return E_INVALIDARG;
ticks = ((unsigned __int64)ft->dwHighDateTime << 32) | ft->dwLowDateTime;
if (ticks > MAX_UINT64 - TICKS_1601_01_01) return WS_E_NUMERIC_OVERFLOW;
if (ticks + TICKS_1601_01_01 > TICKS_MAX) return WS_E_INVALID_FORMAT;
dt->ticks = ticks + TICKS_1601_01_01;
dt->format = WS_DATETIME_FORMAT_UTC;
return S_OK;
}
static BOOL find_attribute( struct reader *reader, const WS_XML_STRING *localname,
const WS_XML_STRING *ns, ULONG *index )
{
ULONG i;
WS_XML_ELEMENT_NODE *elem = &reader->current->hdr;
if (!localname)
{
*index = reader->current_attr;
return TRUE;
}
for (i = 0; i < elem->attributeCount; i++)
{
const WS_XML_STRING *localname2 = elem->attributes[i]->localName;
const WS_XML_STRING *ns2 = elem->attributes[i]->ns;
if (!cmp_name( localname->bytes, localname->length, localname2->bytes, localname2->length ) &&
!cmp_name( ns->bytes, ns->length, ns2->bytes, ns2->length ))
{
*index = i;
return TRUE;
}
}
return FALSE;
}
/**************************************************************************
* WsFindAttribute [webservices.@]
*/
HRESULT WINAPI WsFindAttribute( WS_XML_READER *handle, const WS_XML_STRING *localname,
const WS_XML_STRING *ns, BOOL required, ULONG *index,
WS_ERROR *error )
{
struct reader *reader = (struct reader *)handle;
HRESULT hr = S_OK;
TRACE( "%p %s %s %d %p %p\n", handle, debugstr_xmlstr(localname), debugstr_xmlstr(ns),
required, index, error );
if (error) FIXME( "ignoring error parameter\n" );
if (!reader || !localname || !ns || !index) return E_INVALIDARG;
EnterCriticalSection( &reader->cs );
if (reader->magic != READER_MAGIC)
{
LeaveCriticalSection( &reader->cs );
return E_INVALIDARG;
}
if (node_type( reader->current ) != WS_XML_NODE_TYPE_ELEMENT) hr = WS_E_INVALID_OPERATION;
else if (!find_attribute( reader, localname, ns, index ))
{
if (required) hr = WS_E_INVALID_FORMAT;
else
{
*index = ~0u;
hr = S_FALSE;
}
}
LeaveCriticalSection( &reader->cs );
TRACE( "returning %08x\n", hr );
return hr;
}
static HRESULT get_node_text( struct reader *reader, const WS_XML_TEXT **ret )
{
WS_XML_TEXT_NODE *node = (WS_XML_TEXT_NODE *)&reader->current->hdr.node;
*ret = node->text;
return S_OK;
}
static HRESULT get_attribute_text( struct reader *reader, ULONG index, const WS_XML_TEXT **ret )
{
WS_XML_ELEMENT_NODE *elem = &reader->current->hdr;
*ret = elem->attributes[index]->value;
return S_OK;
}
static BOOL match_element( const struct node *node, const WS_XML_STRING *localname, const WS_XML_STRING *ns )
{
const WS_XML_ELEMENT_NODE *elem = (const WS_XML_ELEMENT_NODE *)node;
if (node_type( node ) != WS_XML_NODE_TYPE_ELEMENT) return FALSE;
return WsXmlStringEquals( localname, elem->localName, NULL ) == S_OK &&
WsXmlStringEquals( ns, elem->ns, NULL ) == S_OK;
}
static HRESULT read_next_node( struct reader *reader )
{
if (reader->current == reader->last) return read_node( reader );
if (move_to_child_node( &reader->current )) return S_OK;
if (move_to_next_node( &reader->current )) return S_OK;
if (!move_to_parent_node( &reader->current )) return WS_E_INVALID_FORMAT;
if (move_to_next_node( &reader->current )) return S_OK;
return WS_E_INVALID_FORMAT;
}
struct reader_pos
{
struct node *node;
ULONG attr;
};
static void save_reader_position( const struct reader *reader, struct reader_pos *pos )
{
pos->node = reader->current;
pos->attr = reader->current_attr;
}
static void restore_reader_position( struct reader *reader, const struct reader_pos *pos )
{
reader->current = pos->node;
reader->current_attr = pos->attr;
}
static HRESULT get_text( struct reader *reader, WS_TYPE_MAPPING mapping, const WS_XML_STRING *localname,
const WS_XML_STRING *ns, const WS_XML_TEXT **ret, BOOL *found )
{
switch (mapping)
{
case WS_ATTRIBUTE_TYPE_MAPPING:
{
ULONG i;
WS_XML_ELEMENT_NODE *elem = &reader->current->hdr;
*found = FALSE;
for (i = 0; i < elem->attributeCount; i++)
{
const WS_XML_STRING *localname2 = elem->attributes[i]->localName;
const WS_XML_STRING *ns2 = elem->attributes[i]->ns;
if (cmp_name( localname->bytes, localname->length, localname2->bytes, localname2->length )) continue;
if (!ns->length || !cmp_name( ns->bytes, ns->length, ns2->bytes, ns2->length ))
{
*found = TRUE;
break;
}
}
if (!*found) return S_OK;
return get_attribute_text( reader, i, ret );
}
case WS_ELEMENT_TYPE_MAPPING:
case WS_ELEMENT_CONTENT_TYPE_MAPPING:
case WS_ANY_ELEMENT_TYPE_MAPPING:
{
*found = TRUE;
if (localname)
{
struct reader_pos pos;
HRESULT hr;
if (!match_element( reader->current, localname, ns ))
{
*found = FALSE;
return S_OK;
}
save_reader_position( reader, &pos );
if ((hr = read_next_node( reader )) != S_OK) return hr;
if (node_type( reader->current ) != WS_XML_NODE_TYPE_TEXT)
{
restore_reader_position( reader, &pos );
*found = FALSE;
return S_OK;
}
}
if (node_type( reader->current ) != WS_XML_NODE_TYPE_TEXT)
{
*found = FALSE;
return S_OK;
}
return get_node_text( reader, ret );
}
default:
FIXME( "mapping %u not supported\n", mapping );
return E_NOTIMPL;
}
}
static HRESULT text_to_bool( const WS_XML_TEXT *text, BOOL *val )
{
HRESULT hr;
switch (text->textType)
{
case WS_XML_TEXT_TYPE_UTF8:
{
const WS_XML_UTF8_TEXT *text_utf8 = (const WS_XML_UTF8_TEXT *)text;
hr = str_to_bool( text_utf8->value.bytes, text_utf8->value.length, val );
break;
}
case WS_XML_TEXT_TYPE_BOOL:
{
const WS_XML_BOOL_TEXT *text_bool = (const WS_XML_BOOL_TEXT *)text;
*val = text_bool->value;
hr = S_OK;
break;
}
default:
FIXME( "unhandled text type %u\n", text->textType );
return E_NOTIMPL;
}
return hr;
}
static HRESULT read_type_bool( struct reader *reader, WS_TYPE_MAPPING mapping,
const WS_XML_STRING *localname, const WS_XML_STRING *ns,
const WS_BOOL_DESCRIPTION *desc, WS_READ_OPTION option,
WS_HEAP *heap, void *ret, ULONG size, BOOL *found )
{
const WS_XML_TEXT *text;
HRESULT hr;
BOOL val = FALSE;
if (desc)
{
FIXME( "description not supported\n" );
return E_NOTIMPL;
}
if ((hr = get_text( reader, mapping, localname, ns, &text, found )) != S_OK) return hr;
if (*found && (hr = text_to_bool( text, &val )) != S_OK) return hr;
switch (option)
{
case WS_READ_REQUIRED_VALUE:
if (!*found) return WS_E_INVALID_FORMAT;
/* fall through */
case WS_READ_NILLABLE_VALUE:
if (size != sizeof(val)) return E_INVALIDARG;
*(BOOL *)ret = val;
break;
case WS_READ_REQUIRED_POINTER:
if (!*found) return WS_E_INVALID_FORMAT;
/* fall through */
case WS_READ_OPTIONAL_POINTER:
case WS_READ_NILLABLE_POINTER:
{
BOOL *heap_val = NULL;
if (size != sizeof(heap_val)) return E_INVALIDARG;
if (*found)
{
if (!(heap_val = ws_alloc( heap, sizeof(*heap_val) ))) return WS_E_QUOTA_EXCEEDED;
*heap_val = val;
}
*(BOOL **)ret = heap_val;
break;
}
default:
FIXME( "read option %u not supported\n", option );
return E_NOTIMPL;
}
return S_OK;
}
static HRESULT text_to_int8( const WS_XML_TEXT *text, INT64 *val )
{
HRESULT hr;
switch (text->textType)
{
case WS_XML_TEXT_TYPE_UTF8:
{
const WS_XML_UTF8_TEXT *text_utf8 = (const WS_XML_UTF8_TEXT *)text;
hr = str_to_int64( text_utf8->value.bytes, text_utf8->value.length, MIN_INT8, MAX_INT8, val );
break;
}
case WS_XML_TEXT_TYPE_INT32:
{
const WS_XML_INT32_TEXT *text_int32 = (const WS_XML_INT32_TEXT *)text;
assert( text_int32->value >= MIN_INT8 );
assert( text_int32->value <= MAX_INT8 );
*val = text_int32->value;
hr = S_OK;
break;
}
default:
FIXME( "unhandled text type %u\n", text->textType );
return E_NOTIMPL;
}
return hr;
}
static HRESULT read_type_int8( struct reader *reader, WS_TYPE_MAPPING mapping,
const WS_XML_STRING *localname, const WS_XML_STRING *ns,
const WS_INT8_DESCRIPTION *desc, WS_READ_OPTION option,
WS_HEAP *heap, void *ret, ULONG size, BOOL *found )
{
const WS_XML_TEXT *text;
HRESULT hr;
INT64 val = 0;
if (desc)
{
FIXME( "description not supported\n" );
return E_NOTIMPL;
}
if ((hr = get_text( reader, mapping, localname, ns, &text, found )) != S_OK) return hr;
if (*found && (hr = text_to_int8( text, &val )) != S_OK) return hr;
switch (option)
{
case WS_READ_REQUIRED_VALUE:
if (!*found) return WS_E_INVALID_FORMAT;
/* fall through */
case WS_READ_NILLABLE_VALUE:
if (size != sizeof(INT8)) return E_INVALIDARG;
*(INT8 *)ret = val;
break;
case WS_READ_REQUIRED_POINTER:
if (!*found) return WS_E_INVALID_FORMAT;
/* fall through */
case WS_READ_OPTIONAL_POINTER:
case WS_READ_NILLABLE_POINTER:
{
INT8 *heap_val = NULL;
if (size != sizeof(heap_val)) return E_INVALIDARG;
if (*found)
{
if (!(heap_val = ws_alloc( heap, sizeof(*heap_val) ))) return WS_E_QUOTA_EXCEEDED;
*heap_val = val;
}
*(INT8 **)ret = heap_val;
break;
}
default:
FIXME( "read option %u not supported\n", option );
return E_NOTIMPL;
}
return S_OK;
}
static HRESULT text_to_int16( const WS_XML_TEXT *text, INT64 *val )
{
HRESULT hr;
switch (text->textType)
{
case WS_XML_TEXT_TYPE_UTF8:
{
const WS_XML_UTF8_TEXT *text_utf8 = (const WS_XML_UTF8_TEXT *)text;
hr = str_to_int64( text_utf8->value.bytes, text_utf8->value.length, MIN_INT16, MAX_INT16, val );
break;
}
case WS_XML_TEXT_TYPE_INT32:
{
const WS_XML_INT32_TEXT *text_int32 = (const WS_XML_INT32_TEXT *)text;
assert( text_int32->value >= MIN_INT16 );
assert( text_int32->value <= MAX_INT16 );
*val = text_int32->value;
hr = S_OK;
break;
}
default:
FIXME( "unhandled text type %u\n", text->textType );
return E_NOTIMPL;
}
return hr;
}
static HRESULT read_type_int16( struct reader *reader, WS_TYPE_MAPPING mapping,
const WS_XML_STRING *localname, const WS_XML_STRING *ns,
const WS_INT16_DESCRIPTION *desc, WS_READ_OPTION option,
WS_HEAP *heap, void *ret, ULONG size, BOOL *found )
{
const WS_XML_TEXT *text;
HRESULT hr;
INT64 val = 0;
if (desc)
{
FIXME( "description not supported\n" );
return E_NOTIMPL;
}
if ((hr = get_text( reader, mapping, localname, ns, &text, found )) != S_OK) return hr;
if (*found && (hr = text_to_int16( text, &val )) != S_OK) return hr;
switch (option)
{
case WS_READ_REQUIRED_VALUE:
if (!*found) return WS_E_INVALID_FORMAT;
/* fall through */
case WS_READ_NILLABLE_VALUE:
if (size != sizeof(INT16)) return E_INVALIDARG;
*(INT16 *)ret = val;
break;
case WS_READ_REQUIRED_POINTER:
if (!*found) return WS_E_INVALID_FORMAT;
/* fall through */
case WS_READ_OPTIONAL_POINTER:
case WS_READ_NILLABLE_POINTER:
{
INT16 *heap_val = NULL;
if (size != sizeof(heap_val)) return E_INVALIDARG;
if (*found)
{
if (!(heap_val = ws_alloc( heap, sizeof(*heap_val) ))) return WS_E_QUOTA_EXCEEDED;
*heap_val = val;
}
*(INT16 **)ret = heap_val;
break;
}
default:
FIXME( "read option %u not supported\n", option );
return E_NOTIMPL;
}
return S_OK;
}
static HRESULT text_to_int32( const WS_XML_TEXT *text, INT64 *val )
{
HRESULT hr;
switch (text->textType)
{
case WS_XML_TEXT_TYPE_UTF8:
{
const WS_XML_UTF8_TEXT *text_utf8 = (const WS_XML_UTF8_TEXT *)text;
hr = str_to_int64( text_utf8->value.bytes, text_utf8->value.length, MIN_INT32, MAX_INT32, val );
break;
}
case WS_XML_TEXT_TYPE_INT32:
{
const WS_XML_INT32_TEXT *text_int32 = (const WS_XML_INT32_TEXT *)text;
*val = text_int32->value;
hr = S_OK;
break;
}
default:
FIXME( "unhandled text type %u\n", text->textType );
return E_NOTIMPL;
}
return hr;
}
static HRESULT read_type_int32( struct reader *reader, WS_TYPE_MAPPING mapping,
const WS_XML_STRING *localname, const WS_XML_STRING *ns,
const WS_INT32_DESCRIPTION *desc, WS_READ_OPTION option,
WS_HEAP *heap, void *ret, ULONG size, BOOL *found )
{
const WS_XML_TEXT *text;
HRESULT hr;
INT64 val = 0;
if (desc)
{
FIXME( "description not supported\n" );
return E_NOTIMPL;
}
if ((hr = get_text( reader, mapping, localname, ns, &text, found )) != S_OK) return hr;
if (*found && (hr = text_to_int32( text, &val )) != S_OK) return hr;
switch (option)
{
case WS_READ_REQUIRED_VALUE:
if (!*found) return WS_E_INVALID_FORMAT;
/* fall through */
case WS_READ_NILLABLE_VALUE:
if (size != sizeof(INT32)) return E_INVALIDARG;
*(INT32 *)ret = val;
break;
case WS_READ_REQUIRED_POINTER:
if (!*found) return WS_E_INVALID_FORMAT;
/* fall through */
case WS_READ_OPTIONAL_POINTER:
case WS_READ_NILLABLE_POINTER:
{
INT32 *heap_val = NULL;
if (size != sizeof(heap_val)) return E_INVALIDARG;
if (*found)
{
if (!(heap_val = ws_alloc( heap, sizeof(*heap_val) ))) return WS_E_QUOTA_EXCEEDED;
*heap_val = val;
}
*(INT32 **)ret = heap_val;
break;
}
default:
FIXME( "read option %u not supported\n", option );
return E_NOTIMPL;
}
return S_OK;
}
static HRESULT text_to_int64( const WS_XML_TEXT *text, INT64 *val )
{
HRESULT hr;
switch (text->textType)
{
case WS_XML_TEXT_TYPE_UTF8:
{
const WS_XML_UTF8_TEXT *text_utf8 = (const WS_XML_UTF8_TEXT *)text;
hr = str_to_int64( text_utf8->value.bytes, text_utf8->value.length, MIN_INT64, MAX_INT64, val );
break;
}
case WS_XML_TEXT_TYPE_INT64:
{
const WS_XML_INT64_TEXT *text_int64 = (const WS_XML_INT64_TEXT *)text;
*val = text_int64->value;
hr = S_OK;
break;
}
default:
FIXME( "unhandled text type %u\n", text->textType );
return E_NOTIMPL;
}
return hr;
}
static HRESULT read_type_int64( struct reader *reader, WS_TYPE_MAPPING mapping,
const WS_XML_STRING *localname, const WS_XML_STRING *ns,
const WS_INT64_DESCRIPTION *desc, WS_READ_OPTION option,
WS_HEAP *heap, void *ret, ULONG size, BOOL *found )
{
const WS_XML_TEXT *text;
HRESULT hr;
INT64 val = 0;
if (desc)
{
FIXME( "description not supported\n" );
return E_NOTIMPL;
}
if ((hr = get_text( reader, mapping, localname, ns, &text, found )) != S_OK) return hr;
if (*found && (hr = text_to_int64( text, &val )) != S_OK) return hr;
switch (option)
{
case WS_READ_REQUIRED_VALUE:
if (!*found) return WS_E_INVALID_FORMAT;
/* fall through */
case WS_READ_NILLABLE_VALUE:
if (size != sizeof(val)) return E_INVALIDARG;
*(INT64 *)ret = val;
break;
case WS_READ_REQUIRED_POINTER:
if (!*found) return WS_E_INVALID_FORMAT;
/* fall through */
case WS_READ_OPTIONAL_POINTER:
case WS_READ_NILLABLE_POINTER:
{
INT64 *heap_val = NULL;
if (size != sizeof(heap_val)) return E_INVALIDARG;
if (*found)
{
if (!(heap_val = ws_alloc( heap, sizeof(*heap_val) ))) return WS_E_QUOTA_EXCEEDED;
*heap_val = val;
}
*(INT64 **)ret = heap_val;
break;
}
default:
FIXME( "read option %u not supported\n", option );
return E_NOTIMPL;
}
return S_OK;
}
static HRESULT text_to_uint8( const WS_XML_TEXT *text, UINT64 *val )
{
HRESULT hr;
switch (text->textType)
{
case WS_XML_TEXT_TYPE_UTF8:
{
const WS_XML_UTF8_TEXT *text_utf8 = (const WS_XML_UTF8_TEXT *)text;
hr = str_to_uint64( text_utf8->value.bytes, text_utf8->value.length, MAX_UINT8, val );
break;
}
case WS_XML_TEXT_TYPE_UINT64:
{
const WS_XML_UINT64_TEXT *text_uint64 = (const WS_XML_UINT64_TEXT *)text;
assert( text_uint64->value <= MAX_UINT8 );
*val = text_uint64->value;
hr = S_OK;
break;
}
default:
FIXME( "unhandled text type %u\n", text->textType );
return E_NOTIMPL;
}
return hr;
}
static HRESULT read_type_uint8( struct reader *reader, WS_TYPE_MAPPING mapping,
const WS_XML_STRING *localname, const WS_XML_STRING *ns,
const WS_UINT8_DESCRIPTION *desc, WS_READ_OPTION option,
WS_HEAP *heap, void *ret, ULONG size, BOOL *found )
{
const WS_XML_TEXT *text;
HRESULT hr;
UINT64 val = 0;
if (desc)
{
FIXME( "description not supported\n" );
return E_NOTIMPL;
}
if ((hr = get_text( reader, mapping, localname, ns, &text, found )) != S_OK) return hr;
if (*found && (hr = text_to_uint8( text, &val )) != S_OK) return hr;
switch (option)
{
case WS_READ_REQUIRED_VALUE:
if (!*found) return WS_E_INVALID_FORMAT;
/* fall through */
case WS_READ_NILLABLE_VALUE:
if (size != sizeof(UINT8)) return E_INVALIDARG;
*(UINT8 *)ret = val;
break;
case WS_READ_REQUIRED_POINTER:
if (!*found) return WS_E_INVALID_FORMAT;
/* fall through */
case WS_READ_OPTIONAL_POINTER:
case WS_READ_NILLABLE_POINTER:
{
UINT8 *heap_val = NULL;
if (size != sizeof(heap_val)) return E_INVALIDARG;
if (*found)
{
if (!(heap_val = ws_alloc( heap, sizeof(*heap_val) ))) return WS_E_QUOTA_EXCEEDED;
*heap_val = val;
}
*(UINT8 **)ret = heap_val;
break;
}
default:
FIXME( "read option %u not supported\n", option );
return E_NOTIMPL;
}
return S_OK;
}
static HRESULT text_to_uint16( const WS_XML_TEXT *text, UINT64 *val )
{
HRESULT hr;
switch (text->textType)
{
case WS_XML_TEXT_TYPE_UTF8:
{
const WS_XML_UTF8_TEXT *text_utf8 = (const WS_XML_UTF8_TEXT *)text;
hr = str_to_uint64( text_utf8->value.bytes, text_utf8->value.length, MAX_UINT16, val );
break;
}
case WS_XML_TEXT_TYPE_INT32:
{
const WS_XML_INT32_TEXT *text_int32 = (const WS_XML_INT32_TEXT *)text;
assert( text_int32->value >= 0 );
assert( text_int32->value <= MAX_UINT16 );
*val = text_int32->value;
hr = S_OK;
break;
}
case WS_XML_TEXT_TYPE_UINT64:
{
const WS_XML_UINT64_TEXT *text_uint64 = (const WS_XML_UINT64_TEXT *)text;
assert( text_uint64->value <= MAX_UINT16 );
*val = text_uint64->value;
hr = S_OK;
break;
}
default:
FIXME( "unhandled text type %u\n", text->textType );
return E_NOTIMPL;
}
return hr;
}
static HRESULT read_type_uint16( struct reader *reader, WS_TYPE_MAPPING mapping,
const WS_XML_STRING *localname, const WS_XML_STRING *ns,
const WS_UINT16_DESCRIPTION *desc, WS_READ_OPTION option,
WS_HEAP *heap, void *ret, ULONG size, BOOL *found )
{
const WS_XML_TEXT *text;
HRESULT hr;
UINT64 val = 0;
if (desc)
{
FIXME( "description not supported\n" );
return E_NOTIMPL;
}
if ((hr = get_text( reader, mapping, localname, ns, &text, found )) != S_OK) return hr;
if (*found && (hr = text_to_uint16( text, &val )) != S_OK) return hr;
switch (option)
{
case WS_READ_REQUIRED_VALUE:
if (!*found) return WS_E_INVALID_FORMAT;
/* fall through */
case WS_READ_NILLABLE_VALUE:
if (size != sizeof(UINT16)) return E_INVALIDARG;
*(UINT16 *)ret = val;
break;
case WS_READ_REQUIRED_POINTER:
if (!*found) return WS_E_INVALID_FORMAT;
/* fall through */
case WS_READ_OPTIONAL_POINTER:
case WS_READ_NILLABLE_POINTER:
{
UINT16 *heap_val = NULL;
if (size != sizeof(heap_val)) return E_INVALIDARG;
if (*found)
{
if (!(heap_val = ws_alloc( heap, sizeof(*heap_val) ))) return WS_E_QUOTA_EXCEEDED;
*heap_val = val;
}
*(UINT16 **)ret = heap_val;
break;
}
default:
FIXME( "read option %u not supported\n", option );
return E_NOTIMPL;
}
return S_OK;
}
static HRESULT text_to_uint32( const WS_XML_TEXT *text, UINT64 *val )
{
HRESULT hr;
switch (text->textType)
{
case WS_XML_TEXT_TYPE_UTF8:
{
const WS_XML_UTF8_TEXT *text_utf8 = (const WS_XML_UTF8_TEXT *)text;
hr = str_to_uint64( text_utf8->value.bytes, text_utf8->value.length, MAX_UINT32, val );
break;
}
case WS_XML_TEXT_TYPE_INT32:
{
const WS_XML_INT32_TEXT *text_int32 = (const WS_XML_INT32_TEXT *)text;
assert( text_int32->value >= 0 );
*val = text_int32->value;
hr = S_OK;
break;
}
case WS_XML_TEXT_TYPE_UINT64:
{
const WS_XML_UINT64_TEXT *text_uint64 = (const WS_XML_UINT64_TEXT *)text;
assert( text_uint64->value <= MAX_UINT32 );
*val = text_uint64->value;
hr = S_OK;
break;
}
default:
FIXME( "unhandled text type %u\n", text->textType );
return E_NOTIMPL;
}
return hr;
}
static HRESULT read_type_uint32( struct reader *reader, WS_TYPE_MAPPING mapping,
const WS_XML_STRING *localname, const WS_XML_STRING *ns,
const WS_UINT32_DESCRIPTION *desc, WS_READ_OPTION option,
WS_HEAP *heap, void *ret, ULONG size, BOOL *found )
{
const WS_XML_TEXT *text;
HRESULT hr;
UINT64 val = 0;
if (desc)
{
FIXME( "description not supported\n" );
return E_NOTIMPL;
}
if ((hr = get_text( reader, mapping, localname, ns, &text, found )) != S_OK) return hr;
if (*found && (hr = text_to_uint32( text, &val )) != S_OK) return hr;
switch (option)
{
case WS_READ_REQUIRED_VALUE:
if (!*found) return WS_E_INVALID_FORMAT;
/* fall through */
case WS_READ_NILLABLE_VALUE:
if (size != sizeof(UINT32)) return E_INVALIDARG;
*(UINT32 *)ret = val;
break;
case WS_READ_REQUIRED_POINTER:
if (!*found) return WS_E_INVALID_FORMAT;
/* fall through */
case WS_READ_OPTIONAL_POINTER:
case WS_READ_NILLABLE_POINTER:
{
UINT32 *heap_val = NULL;
if (size != sizeof(heap_val)) return E_INVALIDARG;
if (*found)
{
if (!(heap_val = ws_alloc( heap, sizeof(*heap_val) ))) return WS_E_QUOTA_EXCEEDED;
*heap_val = val;
}
*(UINT32 **)ret = heap_val;
break;
}
default:
FIXME( "read option %u not supported\n", option );
return E_NOTIMPL;
}
return S_OK;
}
static HRESULT text_to_uint64( const WS_XML_TEXT *text, UINT64 *val )
{
HRESULT hr;
switch (text->textType)
{
case WS_XML_TEXT_TYPE_UTF8:
{
const WS_XML_UTF8_TEXT *text_utf8 = (const WS_XML_UTF8_TEXT *)text;
hr = str_to_uint64( text_utf8->value.bytes, text_utf8->value.length, MAX_UINT64, val );
break;
}
case WS_XML_TEXT_TYPE_INT32:
{
const WS_XML_INT32_TEXT *text_int32 = (const WS_XML_INT32_TEXT *)text;
*val = text_int32->value;
hr = S_OK;
break;
}
case WS_XML_TEXT_TYPE_INT64:
{
const WS_XML_INT64_TEXT *text_int64 = (const WS_XML_INT64_TEXT *)text;
*val = text_int64->value;
hr = S_OK;
break;
}
case WS_XML_TEXT_TYPE_UINT64:
{
const WS_XML_UINT64_TEXT *text_uint64 = (const WS_XML_UINT64_TEXT *)text;
*val = text_uint64->value;
hr = S_OK;
break;
}
default:
FIXME( "unhandled text type %u\n", text->textType );
return E_NOTIMPL;
}
return hr;
}
static HRESULT read_type_uint64( struct reader *reader, WS_TYPE_MAPPING mapping,
const WS_XML_STRING *localname, const WS_XML_STRING *ns,
const WS_UINT64_DESCRIPTION *desc, WS_READ_OPTION option,
WS_HEAP *heap, void *ret, ULONG size, BOOL *found )
{
const WS_XML_TEXT *text;
HRESULT hr;
UINT64 val = 0;
if (desc)
{
FIXME( "description not supported\n" );
return E_NOTIMPL;
}
if ((hr = get_text( reader, mapping, localname, ns, &text, found )) != S_OK) return hr;
if (*found && (hr = text_to_uint64( text, &val )) != S_OK) return hr;
switch (option)
{
case WS_READ_REQUIRED_VALUE:
if (!*found) return WS_E_INVALID_FORMAT;
/* fall through */
case WS_READ_NILLABLE_VALUE:
if (size != sizeof(val)) return E_INVALIDARG;
*(UINT64 *)ret = val;
break;
case WS_READ_REQUIRED_POINTER:
if (!*found) return WS_E_INVALID_FORMAT;
/* fall through */
case WS_READ_OPTIONAL_POINTER:
case WS_READ_NILLABLE_POINTER:
{
UINT64 *heap_val = NULL;
if (size != sizeof(heap_val)) return E_INVALIDARG;
if (*found)
{
if (!(heap_val = ws_alloc( heap, sizeof(*heap_val) ))) return WS_E_QUOTA_EXCEEDED;
*heap_val = val;
}
*(UINT64 **)ret = heap_val;
break;
}
default:
FIXME( "read option %u not supported\n", option );
return E_NOTIMPL;
}
return S_OK;
}
static HRESULT text_to_float( const WS_XML_TEXT *text, float *val )
{
HRESULT hr;
switch (text->textType)
{
case WS_XML_TEXT_TYPE_UTF8:
{
const WS_XML_UTF8_TEXT *text_utf8 = (const WS_XML_UTF8_TEXT *)text;
hr = str_to_float( text_utf8->value.bytes, text_utf8->value.length, val );
break;
}
case WS_XML_TEXT_TYPE_FLOAT:
{
const WS_XML_FLOAT_TEXT *text_float = (const WS_XML_FLOAT_TEXT *)text;
*val = text_float->value;
hr = S_OK;
break;
}
default:
FIXME( "unhandled text type %u\n", text->textType );
return E_NOTIMPL;
}
return hr;
}
static HRESULT read_type_float( struct reader *reader, WS_TYPE_MAPPING mapping,
const WS_XML_STRING *localname, const WS_XML_STRING *ns,
const WS_FLOAT_DESCRIPTION *desc, WS_READ_OPTION option,
WS_HEAP *heap, void *ret, ULONG size, BOOL *found )
{
const WS_XML_TEXT *text;
HRESULT hr;
float val = 0.0;
if (desc) FIXME( "ignoring description\n" );
if ((hr = get_text( reader, mapping, localname, ns, &text, found )) != S_OK) return hr;
if (*found && (hr = text_to_float( text, &val )) != S_OK) return hr;
switch (option)
{
case WS_READ_REQUIRED_VALUE:
if (!*found) return WS_E_INVALID_FORMAT;
/* fall through */
case WS_READ_NILLABLE_VALUE:
if (size != sizeof(val)) return E_INVALIDARG;
*(float *)ret = val;
break;
case WS_READ_REQUIRED_POINTER:
if (!*found) return WS_E_INVALID_FORMAT;
/* fall through */
case WS_READ_OPTIONAL_POINTER:
case WS_READ_NILLABLE_POINTER:
{
float *heap_val = NULL;
if (size != sizeof(heap_val)) return E_INVALIDARG;
if (*found)
{
if (!(heap_val = ws_alloc( heap, sizeof(*heap_val) ))) return WS_E_QUOTA_EXCEEDED;
*heap_val = val;
}
*(float **)ret = heap_val;
break;
}
default:
FIXME( "read option %u not supported\n", option );
return E_NOTIMPL;
}
return S_OK;
}
static HRESULT text_to_double( const WS_XML_TEXT *text, double *val )
{
HRESULT hr;
switch (text->textType)
{
case WS_XML_TEXT_TYPE_UTF8:
{
const WS_XML_UTF8_TEXT *text_utf8 = (const WS_XML_UTF8_TEXT *)text;
hr = str_to_double( text_utf8->value.bytes, text_utf8->value.length, val );
break;
}
case WS_XML_TEXT_TYPE_DOUBLE:
{
const WS_XML_DOUBLE_TEXT *text_double = (const WS_XML_DOUBLE_TEXT *)text;
*val = text_double->value;
hr = S_OK;
break;
}
default:
FIXME( "unhandled text type %u\n", text->textType );
return E_NOTIMPL;
}
return hr;
}
static HRESULT read_type_double( struct reader *reader, WS_TYPE_MAPPING mapping,
const WS_XML_STRING *localname, const WS_XML_STRING *ns,
const WS_DOUBLE_DESCRIPTION *desc, WS_READ_OPTION option,
WS_HEAP *heap, void *ret, ULONG size, BOOL *found )
{
const WS_XML_TEXT *text;
HRESULT hr;
double val = 0.0;
if (desc) FIXME( "ignoring description\n" );
if ((hr = get_text( reader, mapping, localname, ns, &text, found )) != S_OK) return hr;
if (*found && (hr = text_to_double( text, &val )) != S_OK) return hr;
switch (option)
{
case WS_READ_REQUIRED_VALUE:
if (!*found) return WS_E_INVALID_FORMAT;
/* fall through */
case WS_READ_NILLABLE_VALUE:
if (size != sizeof(val)) return E_INVALIDARG;
*(double *)ret = val;
break;
case WS_READ_REQUIRED_POINTER:
if (!*found) return WS_E_INVALID_FORMAT;
/* fall through */
case WS_READ_OPTIONAL_POINTER:
case WS_READ_NILLABLE_POINTER:
{
double *heap_val = NULL;
if (size != sizeof(heap_val)) return E_INVALIDARG;
if (*found)
{
if (!(heap_val = ws_alloc( heap, sizeof(*heap_val) ))) return WS_E_QUOTA_EXCEEDED;
*heap_val = val;
}
*(double **)ret = heap_val;
break;
}
default:
FIXME( "read option %u not supported\n", option );
return E_NOTIMPL;
}
return S_OK;
}
static HRESULT text_to_wsz( const WS_XML_TEXT *text, WS_HEAP *heap, WCHAR **ret )
{
const WS_XML_UTF8_TEXT *utf8 = (const WS_XML_UTF8_TEXT *)text;
int len;
assert( text->textType == WS_XML_TEXT_TYPE_UTF8 );
len = MultiByteToWideChar( CP_UTF8, 0, (char *)utf8->value.bytes, utf8->value.length, NULL, 0 );
if (!(*ret = ws_alloc( heap, (len + 1) * sizeof(WCHAR) ))) return E_OUTOFMEMORY;
MultiByteToWideChar( CP_UTF8, 0, (char *)utf8->value.bytes, utf8->value.length, *ret, len );
(*ret)[len] = 0;
return S_OK;
}
static HRESULT read_type_wsz( struct reader *reader, WS_TYPE_MAPPING mapping,
const WS_XML_STRING *localname, const WS_XML_STRING *ns,
const WS_WSZ_DESCRIPTION *desc, WS_READ_OPTION option,
WS_HEAP *heap, WCHAR **ret, ULONG size, BOOL *found )
{
const WS_XML_TEXT *text;
HRESULT hr;
WCHAR *str = NULL;
if (desc)
{
FIXME( "description not supported\n" );
return E_NOTIMPL;
}
if ((hr = get_text( reader, mapping, localname, ns, &text, found )) != S_OK) return hr;
if (*found && (hr = text_to_wsz( text, heap, &str )) != S_OK) return hr;
switch (option)
{
case WS_READ_REQUIRED_POINTER:
if (!str && !(str = ws_alloc_zero( heap, sizeof(*str) ))) return WS_E_QUOTA_EXCEEDED;
/* fall through */
case WS_READ_OPTIONAL_POINTER:
case WS_READ_NILLABLE_POINTER:
if (size != sizeof(str)) return E_INVALIDARG;
*ret = str;
break;
default:
FIXME( "read option %u not supported\n", option );
return E_NOTIMPL;
}
return S_OK;
}
static HRESULT get_enum_value( const WS_XML_TEXT *text, const WS_ENUM_DESCRIPTION *desc, int *ret )
{
const WS_XML_UTF8_TEXT *utf8 = (const WS_XML_UTF8_TEXT *)text;
ULONG i;
assert( text->textType == WS_XML_TEXT_TYPE_UTF8 );
for (i = 0; i < desc->valueCount; i++)
{
if (WsXmlStringEquals( &utf8->value, desc->values[i].name, NULL ) == S_OK)
{
*ret = desc->values[i].value;
return S_OK;
}
}
return WS_E_INVALID_FORMAT;
}
static HRESULT read_type_enum( struct reader *reader, WS_TYPE_MAPPING mapping,
const WS_XML_STRING *localname, const WS_XML_STRING *ns,
const WS_ENUM_DESCRIPTION *desc, WS_READ_OPTION option,
WS_HEAP *heap, void *ret, ULONG size, BOOL *found )
{
const WS_XML_TEXT *text;
HRESULT hr;
int val = 0;
if (!desc) return E_INVALIDARG;
if ((hr = get_text( reader, mapping, localname, ns, &text, found )) != S_OK) return hr;
if (*found && (hr = get_enum_value( text, desc, &val )) != S_OK) return hr;
switch (option)
{
case WS_READ_REQUIRED_VALUE:
if (!*found) return WS_E_INVALID_FORMAT;
/* fall through */
case WS_READ_NILLABLE_VALUE:
if (size != sizeof(val)) return E_INVALIDARG;
*(int *)ret = val;
break;
case WS_READ_REQUIRED_POINTER:
if (!*found) return WS_E_INVALID_FORMAT;
/* fall through */
case WS_READ_OPTIONAL_POINTER:
case WS_READ_NILLABLE_POINTER:
{
int *heap_val = NULL;
if (size != sizeof(heap_val)) return E_INVALIDARG;
if (*found)
{
if (!(heap_val = ws_alloc( heap, sizeof(*heap_val) ))) return WS_E_QUOTA_EXCEEDED;
*heap_val = val;
}
*(int **)ret = heap_val;
break;
}
default:
FIXME( "read option %u not supported\n", option );
return E_NOTIMPL;
}
return S_OK;
}
static HRESULT text_to_datetime( const WS_XML_TEXT *text, WS_DATETIME *val )
{
HRESULT hr;
switch (text->textType)
{
case WS_XML_TEXT_TYPE_UTF8:
{
const WS_XML_UTF8_TEXT *text_utf8 = (const WS_XML_UTF8_TEXT *)text;
hr = str_to_datetime( text_utf8->value.bytes, text_utf8->value.length, val );
break;
}
case WS_XML_TEXT_TYPE_DATETIME:
{
const WS_XML_DATETIME_TEXT *text_datetime = (const WS_XML_DATETIME_TEXT *)text;
*val = text_datetime->value;
hr = S_OK;
break;
}
default:
FIXME( "unhandled text type %u\n", text->textType );
return E_NOTIMPL;
}
return hr;
}
static HRESULT read_type_datetime( struct reader *reader, WS_TYPE_MAPPING mapping,
const WS_XML_STRING *localname, const WS_XML_STRING *ns,
const WS_DATETIME_DESCRIPTION *desc, WS_READ_OPTION option,
WS_HEAP *heap, void *ret, ULONG size, BOOL *found )
{
const WS_XML_TEXT *text;
HRESULT hr;
WS_DATETIME val = {0, WS_DATETIME_FORMAT_UTC};
if (desc) FIXME( "ignoring description\n" );
if ((hr = get_text( reader, mapping, localname, ns, &text, found )) != S_OK) return hr;
if (*found && (hr = text_to_datetime( text, &val )) != S_OK) return hr;
switch (option)
{
case WS_READ_REQUIRED_VALUE:
if (!*found) return WS_E_INVALID_FORMAT;
/* fall through */
case WS_READ_NILLABLE_VALUE:
if (size != sizeof(val)) return E_INVALIDARG;
*(WS_DATETIME *)ret = val;
break;
case WS_READ_REQUIRED_POINTER:
if (!*found) return WS_E_INVALID_FORMAT;
/* fall through */
case WS_READ_OPTIONAL_POINTER:
case WS_READ_NILLABLE_POINTER:
{
WS_DATETIME *heap_val = NULL;
if (size != sizeof(heap_val)) return E_INVALIDARG;
if (*found)
{
if (!(heap_val = ws_alloc( heap, sizeof(*heap_val) ))) return WS_E_QUOTA_EXCEEDED;
*heap_val = val;
}
*(WS_DATETIME **)ret = heap_val;
break;
}
default:
FIXME( "read option %u not supported\n", option );
return E_NOTIMPL;
}
return S_OK;
}
static HRESULT text_to_guid( const WS_XML_TEXT *text, GUID *val )
{
HRESULT hr;
switch (text->textType)
{
case WS_XML_TEXT_TYPE_UTF8:
{
const WS_XML_UTF8_TEXT *text_utf8 = (const WS_XML_UTF8_TEXT *)text;
hr = str_to_guid( text_utf8->value.bytes, text_utf8->value.length, val );
break;
}
case WS_XML_TEXT_TYPE_GUID:
{
const WS_XML_GUID_TEXT *text_guid = (const WS_XML_GUID_TEXT *)text;
*val = text_guid->value;
hr = S_OK;
break;
}
default:
FIXME( "unhandled text type %u\n", text->textType );
return E_NOTIMPL;
}
return hr;
}
static HRESULT read_type_guid( struct reader *reader, WS_TYPE_MAPPING mapping,
const WS_XML_STRING *localname, const WS_XML_STRING *ns,
const WS_GUID_DESCRIPTION *desc, WS_READ_OPTION option,
WS_HEAP *heap, void *ret, ULONG size, BOOL *found )
{
const WS_XML_TEXT *text;
GUID val = {0};
HRESULT hr;
if (desc) FIXME( "ignoring description\n" );
if ((hr = get_text( reader, mapping, localname, ns, &text, found )) != S_OK) return hr;
if (*found && (hr = text_to_guid( text, &val )) != S_OK) return hr;
switch (option)
{
case WS_READ_REQUIRED_VALUE:
if (!*found) return WS_E_INVALID_FORMAT;
/* fall through */
case WS_READ_NILLABLE_VALUE:
if (size != sizeof(val)) return E_INVALIDARG;
*(GUID *)ret = val;
break;
case WS_READ_REQUIRED_POINTER:
if (!*found) return WS_E_INVALID_FORMAT;
/* fall through */
case WS_READ_OPTIONAL_POINTER:
case WS_READ_NILLABLE_POINTER:
{
GUID *heap_val = NULL;
if (size != sizeof(heap_val)) return E_INVALIDARG;
if (*found)
{
if (!(heap_val = ws_alloc( heap, sizeof(*heap_val) ))) return WS_E_QUOTA_EXCEEDED;
*heap_val = val;
}
*(GUID **)ret = heap_val;
break;
}
default:
FIXME( "read option %u not supported\n", option );
return E_NOTIMPL;
}
return S_OK;
}
static HRESULT text_to_unique_id( const WS_XML_TEXT *text, WS_HEAP *heap, WS_UNIQUE_ID *val )
{
HRESULT hr;
switch (text->textType)
{
case WS_XML_TEXT_TYPE_UTF8:
{
const WS_XML_UTF8_TEXT *text_utf8 = (const WS_XML_UTF8_TEXT *)text;
hr = str_to_unique_id( text_utf8->value.bytes, text_utf8->value.length, heap, val );
break;
}
case WS_XML_TEXT_TYPE_UNIQUE_ID:
{
const WS_XML_UNIQUE_ID_TEXT *text_unique_id = (const WS_XML_UNIQUE_ID_TEXT *)text;
val->guid = text_unique_id->value;
val->uri.length = 0;
val->uri.chars = NULL;
hr = S_OK;
break;
}
default:
FIXME( "unhandled text type %u\n", text->textType );
return E_NOTIMPL;
}
return hr;
}
static HRESULT read_type_unique_id( struct reader *reader, WS_TYPE_MAPPING mapping,
const WS_XML_STRING *localname, const WS_XML_STRING *ns,
const WS_UNIQUE_ID_DESCRIPTION *desc, WS_READ_OPTION option,
WS_HEAP *heap, void *ret, ULONG size, BOOL *found )
{
const WS_XML_TEXT *text;
WS_UNIQUE_ID val = {{0}};
HRESULT hr;
if (desc) FIXME( "ignoring description\n" );
if ((hr = get_text( reader, mapping, localname, ns, &text, found )) != S_OK) return hr;
if (*found && (hr = text_to_unique_id( text, heap, &val )) != S_OK) return hr;
switch (option)
{
case WS_READ_REQUIRED_VALUE:
if (!*found) return WS_E_INVALID_FORMAT;
/* fall through */
case WS_READ_NILLABLE_VALUE:
if (size != sizeof(val)) return E_INVALIDARG;
*(WS_UNIQUE_ID *)ret = val;
break;
case WS_READ_REQUIRED_POINTER:
if (!*found) return WS_E_INVALID_FORMAT;
/* fall through */
case WS_READ_OPTIONAL_POINTER:
case WS_READ_NILLABLE_POINTER:
{
WS_UNIQUE_ID *heap_val = NULL;
if (size != sizeof(heap_val)) return E_INVALIDARG;
if (*found)
{
if (!(heap_val = ws_alloc( heap, sizeof(*heap_val) ))) return WS_E_QUOTA_EXCEEDED;
*heap_val = val;
}
*(WS_UNIQUE_ID **)ret = heap_val;
break;
}
default:
FIXME( "read option %u not supported\n", option );
return E_NOTIMPL;
}
return S_OK;
}
static HRESULT text_to_string( const WS_XML_TEXT *text, WS_HEAP *heap, WS_STRING *val )
{
HRESULT hr;
switch (text->textType)
{
case WS_XML_TEXT_TYPE_UTF8:
{
const WS_XML_UTF8_TEXT *text_utf8 = (const WS_XML_UTF8_TEXT *)text;
hr = str_to_string( text_utf8->value.bytes, text_utf8->value.length, heap, val );
break;
}
case WS_XML_TEXT_TYPE_UTF16:
{
const WS_XML_UTF16_TEXT *text_utf16 = (const WS_XML_UTF16_TEXT *)text;
if (!(val->chars = ws_alloc( heap, text_utf16->byteCount ))) return WS_E_QUOTA_EXCEEDED;
memcpy( val->chars, text_utf16->bytes, text_utf16->byteCount );
val->length = text_utf16->byteCount / sizeof(WCHAR);
hr = S_OK;
break;
}
default:
FIXME( "unhandled text type %u\n", text->textType );
return E_NOTIMPL;
}
return hr;
}
static HRESULT read_type_string( struct reader *reader, WS_TYPE_MAPPING mapping,
const WS_XML_STRING *localname, const WS_XML_STRING *ns,
const WS_STRING_DESCRIPTION *desc, WS_READ_OPTION option,
WS_HEAP *heap, void *ret, ULONG size, BOOL *found )
{
const WS_XML_TEXT *text;
WS_STRING val = {0};
HRESULT hr;
if (desc) FIXME( "ignoring description\n" );
if ((hr = get_text( reader, mapping, localname, ns, &text, found )) != S_OK) return hr;
if (*found && (hr = text_to_string( text, heap, &val )) != S_OK) return hr;
switch (option)
{
case WS_READ_REQUIRED_VALUE:
case WS_READ_NILLABLE_VALUE:
if (size != sizeof(val)) return E_INVALIDARG;
*(WS_STRING *)ret = val;
break;
case WS_READ_REQUIRED_POINTER:
{
WS_STRING *heap_val;
if (size != sizeof(heap_val)) return E_INVALIDARG;
if (!(heap_val = ws_alloc( heap, sizeof(*heap_val) ))) return WS_E_QUOTA_EXCEEDED;
*heap_val = val;
*(WS_STRING **)ret = heap_val;
break;
}
case WS_READ_OPTIONAL_POINTER:
case WS_READ_NILLABLE_POINTER:
{
WS_STRING *heap_val = NULL;
if (size != sizeof(heap_val)) return E_INVALIDARG;
if (*found)
{
if (!(heap_val = ws_alloc( heap, sizeof(*heap_val) ))) return WS_E_QUOTA_EXCEEDED;
*heap_val = val;
}
*(WS_STRING **)ret = heap_val;
break;
}
default:
FIXME( "read option %u not supported\n", option );
return E_NOTIMPL;
}
return S_OK;
}
static HRESULT text_to_bytes( const WS_XML_TEXT *text, WS_HEAP *heap, WS_BYTES *val )
{
HRESULT hr;
switch (text->textType)
{
case WS_XML_TEXT_TYPE_UTF8:
{
const WS_XML_UTF8_TEXT *text_utf8 = (const WS_XML_UTF8_TEXT *)text;
hr = str_to_bytes( text_utf8->value.bytes, text_utf8->value.length, heap, val );
break;
}
case WS_XML_TEXT_TYPE_BASE64:
{
const WS_XML_BASE64_TEXT *text_base64 = (const WS_XML_BASE64_TEXT *)text;
if (!(val->bytes = ws_alloc( heap, text_base64->length ))) return WS_E_QUOTA_EXCEEDED;
memcpy( val->bytes, text_base64->bytes, text_base64->length );
val->length = text_base64->length;
hr = S_OK;
break;
}
default:
FIXME( "unhandled text type %u\n", text->textType );
return E_NOTIMPL;
}
return hr;
}
static HRESULT read_type_bytes( struct reader *reader, WS_TYPE_MAPPING mapping,
const WS_XML_STRING *localname, const WS_XML_STRING *ns,
const WS_BYTES_DESCRIPTION *desc, WS_READ_OPTION option,
WS_HEAP *heap, void *ret, ULONG size, BOOL *found )
{
const WS_XML_TEXT *text;
WS_BYTES val = {0};
HRESULT hr;
if (desc) FIXME( "ignoring description\n" );
if ((hr = get_text( reader, mapping, localname, ns, &text, found )) != S_OK) return hr;
if (*found && (hr = text_to_bytes( text, heap, &val )) != S_OK) return hr;
switch (option)
{
case WS_READ_REQUIRED_VALUE:
case WS_READ_NILLABLE_VALUE:
if (size != sizeof(val)) return E_INVALIDARG;
*(WS_BYTES *)ret = val;
break;
case WS_READ_REQUIRED_POINTER:
{
WS_BYTES *heap_val;
if (size != sizeof(heap_val)) return E_INVALIDARG;
if (!(heap_val = ws_alloc( heap, sizeof(*heap_val) ))) return WS_E_QUOTA_EXCEEDED;
*heap_val = val;
*(WS_BYTES **)ret = heap_val;
break;
}
case WS_READ_OPTIONAL_POINTER:
case WS_READ_NILLABLE_POINTER:
{
WS_BYTES *heap_val = NULL;
if (size != sizeof(heap_val)) return E_INVALIDARG;
if (*found)
{
if (!(heap_val = ws_alloc( heap, sizeof(*heap_val) ))) return WS_E_QUOTA_EXCEEDED;
*heap_val = val;
}
*(WS_BYTES **)ret = heap_val;
break;
}
default:
FIXME( "read option %u not supported\n", option );
return E_NOTIMPL;
}
return S_OK;
}
static HRESULT text_to_xml_string( const WS_XML_TEXT *text, WS_HEAP *heap, WS_XML_STRING *val )
{
const WS_XML_UTF8_TEXT *utf8 = (const WS_XML_UTF8_TEXT *)text;
assert( text->textType == WS_XML_TEXT_TYPE_UTF8 );
return str_to_xml_string( utf8->value.bytes, utf8->value.length, heap, val );
}
static HRESULT read_type_xml_string( struct reader *reader, WS_TYPE_MAPPING mapping,
const WS_XML_STRING *localname, const WS_XML_STRING *ns,
const WS_XML_STRING_DESCRIPTION *desc, WS_READ_OPTION option,
WS_HEAP *heap, void *ret, ULONG size, BOOL *found )
{
const WS_XML_TEXT *text;
WS_XML_STRING val = {0};
HRESULT hr;
if (desc) FIXME( "ignoring description\n" );
if ((hr = get_text( reader, mapping, localname, ns, &text, found )) != S_OK) return hr;
if (*found && (hr = text_to_xml_string( text, heap, &val )) != S_OK) return hr;
switch (option)
{
case WS_READ_REQUIRED_VALUE:
case WS_READ_NILLABLE_VALUE:
if (size != sizeof(val)) return E_INVALIDARG;
*(WS_XML_STRING *)ret = val;
break;
case WS_READ_REQUIRED_POINTER:
{
WS_XML_STRING *heap_val;
if (size != sizeof(heap_val)) return E_INVALIDARG;
if (!(heap_val = ws_alloc( heap, sizeof(*heap_val) ))) return WS_E_QUOTA_EXCEEDED;
*heap_val = val;
*(WS_XML_STRING **)ret = heap_val;
break;
}
case WS_READ_OPTIONAL_POINTER:
case WS_READ_NILLABLE_POINTER:
{
WS_XML_STRING *heap_val = NULL;
if (size != sizeof(heap_val)) return E_INVALIDARG;
if (*found)
{
if (!(heap_val = ws_alloc( heap, sizeof(*heap_val) ))) return WS_E_QUOTA_EXCEEDED;
*heap_val = val;
}
*(WS_XML_STRING **)ret = heap_val;
break;
}
default:
FIXME( "read option %u not supported\n", option );
return E_NOTIMPL;
}
return S_OK;
}
static HRESULT text_to_qname( struct reader *reader, const WS_XML_TEXT *text, WS_HEAP *heap, WS_XML_QNAME *val )
{
HRESULT hr;
switch (text->textType)
{
case WS_XML_TEXT_TYPE_UTF8:
{
const WS_XML_UTF8_TEXT *text_utf8 = (const WS_XML_UTF8_TEXT *)text;
hr = str_to_qname( reader, text_utf8->value.bytes, text_utf8->value.length, heap, NULL,
&val->localName, &val->ns );
break;
}
case WS_XML_TEXT_TYPE_QNAME:
{
const WS_XML_QNAME_TEXT *text_qname = (const WS_XML_QNAME_TEXT *)text;
if ((hr = copy_xml_string( heap, text_qname->localName, &val->localName )) != S_OK) return hr;
if ((hr = copy_xml_string( heap, text_qname->ns, &val->ns )) != S_OK)
{
ws_free( heap, val->localName.bytes, val->localName.length );
return hr;
}
break;
}
default:
FIXME( "unhandled text type %u\n", text->textType );
return E_NOTIMPL;
}
return hr;
}
static HRESULT read_type_qname( struct reader *reader, WS_TYPE_MAPPING mapping,
const WS_XML_STRING *localname, const WS_XML_STRING *ns,
const WS_XML_QNAME_DESCRIPTION *desc, WS_READ_OPTION option,
WS_HEAP *heap, void *ret, ULONG size, BOOL *found )
{
const WS_XML_TEXT *text;
WS_XML_QNAME val = {{0}};
HRESULT hr;
if (desc) FIXME( "ignoring description\n" );
if (node_type( reader->current ) != WS_XML_NODE_TYPE_ELEMENT) return WS_E_INVALID_FORMAT;
if ((hr = read_startelement( reader )) != S_OK) return hr;
if (node_type( reader->current ) != WS_XML_NODE_TYPE_TEXT) return WS_E_INVALID_FORMAT;
if ((hr = get_text( reader, mapping, localname, ns, &text, found )) != S_OK) return hr;
if (*found && (hr = text_to_qname( reader, text, heap, &val )) != S_OK) return hr;
switch (option)
{
case WS_READ_REQUIRED_VALUE:
if (!*found) return WS_E_INVALID_FORMAT;
/* fall through */
case WS_READ_NILLABLE_VALUE:
if (size != sizeof(val)) return E_INVALIDARG;
*(WS_XML_QNAME *)ret = val;
break;
case WS_READ_REQUIRED_POINTER:
if (!*found) return WS_E_INVALID_FORMAT;
/* fall through */
case WS_READ_OPTIONAL_POINTER:
case WS_READ_NILLABLE_POINTER:
{
WS_XML_QNAME *heap_val = NULL;
if (size != sizeof(heap_val)) return E_INVALIDARG;
if (*found)
{
if (!(heap_val = ws_alloc( heap, sizeof(*heap_val) ))) return WS_E_QUOTA_EXCEEDED;
*heap_val = val;
}
*(WS_XML_QNAME **)ret = heap_val;
break;
}
default:
FIXME( "read option %u not supported\n", option );
return E_NOTIMPL;
}
return S_OK;
}
static HRESULT read_type_description( struct reader *reader, WS_TYPE_MAPPING mapping,
const WS_XML_STRING *localname, const WS_XML_STRING *ns,
const WS_STRUCT_DESCRIPTION *desc, WS_READ_OPTION option,
WS_HEAP *heap, void *ret, ULONG size, BOOL *found )
{
switch (option)
{
case WS_READ_REQUIRED_POINTER:
case WS_READ_OPTIONAL_POINTER:
{
if (size != sizeof(desc)) return E_INVALIDARG;
*(const WS_STRUCT_DESCRIPTION **)ret = desc;
*found = TRUE;
break;
}
default:
FIXME( "read option %u not supported\n", option );
return E_NOTIMPL;
}
return S_OK;
}
static BOOL is_empty_text_node( const struct node *node )
{
const WS_XML_TEXT_NODE *text = (const WS_XML_TEXT_NODE *)node;
if (node_type( node ) != WS_XML_NODE_TYPE_TEXT) return FALSE;
switch (text->text->textType)
{
case WS_XML_TEXT_TYPE_UTF8:
{
ULONG i;
const WS_XML_UTF8_TEXT *utf8 = (const WS_XML_UTF8_TEXT *)text->text;
for (i = 0; i < utf8->value.length; i++) if (!read_isspace( utf8->value.bytes[i] )) return FALSE;
return TRUE;
}
case WS_XML_TEXT_TYPE_BASE64:
{
const WS_XML_BASE64_TEXT *base64 = (const WS_XML_BASE64_TEXT *)text->text;
return !base64->length;
}
case WS_XML_TEXT_TYPE_BOOL:
case WS_XML_TEXT_TYPE_INT32:
case WS_XML_TEXT_TYPE_INT64:
case WS_XML_TEXT_TYPE_UINT64:
case WS_XML_TEXT_TYPE_FLOAT:
case WS_XML_TEXT_TYPE_DOUBLE:
case WS_XML_TEXT_TYPE_DECIMAL:
case WS_XML_TEXT_TYPE_GUID:
case WS_XML_TEXT_TYPE_UNIQUE_ID:
case WS_XML_TEXT_TYPE_DATETIME:
return FALSE;
default:
ERR( "unhandled text type %u\n", text->text->textType );
return FALSE;
}
}
/* skips comment and empty text nodes */
static HRESULT read_type_next_node( struct reader *reader )
{
for (;;)
{
HRESULT hr;
WS_XML_NODE_TYPE type;
if ((hr = read_next_node( reader )) != S_OK) return hr;
type = node_type( reader->current );
if (type == WS_XML_NODE_TYPE_COMMENT ||
(type == WS_XML_NODE_TYPE_TEXT && is_empty_text_node( reader->current ))) continue;
return S_OK;
}
}
static HRESULT read_type_next_element_node( struct reader *reader, const WS_XML_STRING *localname,
const WS_XML_STRING *ns )
{
struct reader_pos pos;
HRESULT hr;
if (!localname) return S_OK; /* assume reader is already correctly positioned */
if (reader->current == reader->last)
{
BOOL found;
if ((hr = read_to_startelement( reader, &found )) != S_OK) return hr;
if (!found) return WS_E_INVALID_FORMAT;
}
if (match_element( reader->current, localname, ns )) return S_OK;
save_reader_position( reader, &pos );
if ((hr = read_type_next_node( reader )) != S_OK) return hr;
if (match_element( reader->current, localname, ns )) return S_OK;
restore_reader_position( reader, &pos );
return WS_E_INVALID_FORMAT;
}
ULONG get_type_size( WS_TYPE type, const void *desc )
{
switch (type)
{
case WS_INT8_TYPE:
case WS_UINT8_TYPE:
return sizeof(INT8);
case WS_INT16_TYPE:
case WS_UINT16_TYPE:
return sizeof(INT16);
case WS_BOOL_TYPE:
case WS_INT32_TYPE:
case WS_UINT32_TYPE:
case WS_ENUM_TYPE:
return sizeof(INT32);
case WS_INT64_TYPE:
case WS_UINT64_TYPE:
return sizeof(INT64);
case WS_FLOAT_TYPE:
return sizeof(float);
case WS_DOUBLE_TYPE:
return sizeof(double);
case WS_DATETIME_TYPE:
return sizeof(WS_DATETIME);
case WS_GUID_TYPE:
return sizeof(GUID);
case WS_UNIQUE_ID_TYPE:
return sizeof(WS_UNIQUE_ID);
case WS_STRING_TYPE:
return sizeof(WS_STRING);
case WS_WSZ_TYPE:
return sizeof(WCHAR *);
case WS_BYTES_TYPE:
return sizeof(WS_BYTES);
case WS_XML_STRING_TYPE:
return sizeof(WS_XML_STRING);
case WS_XML_QNAME_TYPE:
return sizeof(WS_XML_QNAME);
case WS_DESCRIPTION_TYPE:
return sizeof(WS_STRUCT_DESCRIPTION *);
case WS_STRUCT_TYPE:
{
const WS_STRUCT_DESCRIPTION *desc_struct = desc;
return desc_struct->size;
}
case WS_UNION_TYPE:
{
const WS_UNION_DESCRIPTION *desc_union = desc;
return desc_union->size;
}
case WS_ANY_ATTRIBUTES_TYPE:
return 0;
default:
ERR( "unhandled type %u\n", type );
return 0;
}
}
static WS_READ_OPTION get_field_read_option( WS_TYPE type, ULONG options )
{
if (options & WS_FIELD_POINTER)
{
if (options & WS_FIELD_NILLABLE) return WS_READ_NILLABLE_POINTER;
if (options & WS_FIELD_OPTIONAL) return WS_READ_OPTIONAL_POINTER;
return WS_READ_REQUIRED_POINTER;
}
switch (type)
{
case WS_BOOL_TYPE:
case WS_INT8_TYPE:
case WS_INT16_TYPE:
case WS_INT32_TYPE:
case WS_INT64_TYPE:
case WS_UINT8_TYPE:
case WS_UINT16_TYPE:
case WS_UINT32_TYPE:
case WS_UINT64_TYPE:
case WS_FLOAT_TYPE:
case WS_DOUBLE_TYPE:
case WS_DATETIME_TYPE:
case WS_GUID_TYPE:
case WS_UNIQUE_ID_TYPE:
case WS_STRING_TYPE:
case WS_BYTES_TYPE:
case WS_XML_STRING_TYPE:
case WS_XML_QNAME_TYPE:
case WS_STRUCT_TYPE:
case WS_ENUM_TYPE:
case WS_UNION_TYPE:
if (options & (WS_FIELD_OPTIONAL|WS_FIELD_NILLABLE)) return WS_READ_NILLABLE_VALUE;
return WS_READ_REQUIRED_VALUE;
case WS_WSZ_TYPE:
case WS_DESCRIPTION_TYPE:
if (options & WS_FIELD_NILLABLE) return WS_READ_NILLABLE_POINTER;
if (options & WS_FIELD_OPTIONAL) return WS_READ_OPTIONAL_POINTER;
return WS_READ_REQUIRED_POINTER;
default:
FIXME( "unhandled type %u\n", type );
return 0;
}
}
static HRESULT read_type_field( struct reader *, const WS_STRUCT_DESCRIPTION *, const WS_FIELD_DESCRIPTION *,
WS_HEAP *, char *, ULONG );
static HRESULT read_type_union( struct reader *reader, const WS_UNION_DESCRIPTION *desc, WS_HEAP *heap, void *ret,
ULONG size, BOOL *found )
{
struct reader_pos pos;
HRESULT hr;
ULONG i;
if (size != desc->size) return E_INVALIDARG;
save_reader_position( reader, &pos );
if ((hr = read_type_next_node( reader )) != S_OK) return hr;
for (i = 0; i < desc->fieldCount; i++)
{
if ((*found = match_element( reader->current, desc->fields[i]->field.localName, desc->fields[i]->field.ns )))
break;
}
if (!*found)
{
*(int *)((char *)ret + desc->enumOffset) = desc->noneEnumValue;
restore_reader_position( reader, &pos );
}
else
{
ULONG offset = desc->fields[i]->field.offset;
if ((hr = read_type_field( reader, NULL, &desc->fields[i]->field, heap, ret, offset )) != S_OK) return hr;
*(int *)((char *)ret + desc->enumOffset) = desc->fields[i]->value;
}
return S_OK;
}
static HRESULT read_type( struct reader *, WS_TYPE_MAPPING, WS_TYPE, const WS_XML_STRING *,
const WS_XML_STRING *, const void *, WS_READ_OPTION, WS_HEAP *,
void *, ULONG, BOOL * );
static HRESULT read_type_array( struct reader *reader, const WS_FIELD_DESCRIPTION *desc, WS_HEAP *heap,
void **ret, ULONG *count )
{
HRESULT hr;
ULONG item_size, nb_items = 0, nb_allocated = 1, offset = 0;
WS_READ_OPTION option;
BOOL found;
char *buf;
if (!(option = get_field_read_option( desc->type, desc->options ))) return E_INVALIDARG;
/* wrapper element */
if (desc->localName && ((hr = read_type_next_element_node( reader, desc->localName, desc->ns )) != S_OK))
return hr;
if (option == WS_READ_REQUIRED_VALUE || option == WS_READ_NILLABLE_VALUE)
item_size = get_type_size( desc->type, desc->typeDescription );
else
item_size = sizeof(void *);
if (!(buf = ws_alloc_zero( heap, item_size ))) return WS_E_QUOTA_EXCEEDED;
for (;;)
{
if (nb_items >= nb_allocated)
{
SIZE_T old_size = nb_allocated * item_size, new_size = old_size * 2;
if (!(buf = ws_realloc_zero( heap, buf, old_size, new_size ))) return WS_E_QUOTA_EXCEEDED;
nb_allocated *= 2;
}
if (desc->type == WS_UNION_TYPE)
{
hr = read_type_union( reader, desc->typeDescription, heap, buf + offset, item_size, &found );
if (hr != S_OK)
{
ws_free( heap, buf, nb_allocated * item_size );
return hr;
}
if (!found) break;
}
else
{
hr = read_type( reader, WS_ELEMENT_TYPE_MAPPING, desc->type, desc->itemLocalName, desc->itemNs,
desc->typeDescription, option, heap, buf + offset, item_size, &found );
if (hr == WS_E_INVALID_FORMAT) break;
if (hr != S_OK)
{
ws_free( heap, buf, nb_allocated * item_size );
return hr;
}
}
offset += item_size;
nb_items++;
}
if (desc->localName && ((hr = read_type_next_node( reader )) != S_OK)) return hr;
if (desc->itemRange && (nb_items < desc->itemRange->minItemCount || nb_items > desc->itemRange->maxItemCount))
{
TRACE( "number of items %u out of range (%u-%u)\n", nb_items, desc->itemRange->minItemCount,
desc->itemRange->maxItemCount );
ws_free( heap, buf, nb_allocated * item_size );
return WS_E_INVALID_FORMAT;
}
*count = nb_items;
*ret = buf;
return S_OK;
}
static HRESULT read_type_text( struct reader *reader, const WS_FIELD_DESCRIPTION *desc,
WS_READ_OPTION option, WS_HEAP *heap, void *ret, ULONG size )
{
struct reader_pos pos;
BOOL found;
HRESULT hr;
if (reader->current == reader->last)
{
if ((hr = read_to_startelement( reader, &found )) != S_OK) return hr;
if (!found) return WS_E_INVALID_FORMAT;
}
save_reader_position( reader, &pos );
if ((hr = read_next_node( reader )) != S_OK) return hr;
hr = read_type( reader, WS_ANY_ELEMENT_TYPE_MAPPING, desc->type, NULL, NULL,
desc->typeDescription, option, heap, ret, size, &found );
if (hr == S_OK && !found) restore_reader_position( reader, &pos );
return hr;
}
static HRESULT read_type_field( struct reader *reader, const WS_STRUCT_DESCRIPTION *desc_struct,
const WS_FIELD_DESCRIPTION *desc, WS_HEAP *heap, char *buf, ULONG offset )
{
char *ptr;
WS_READ_OPTION option;
ULONG size;
HRESULT hr;
BOOL found;
if (!desc) return E_INVALIDARG;
if (desc->options & ~(WS_FIELD_POINTER|WS_FIELD_OPTIONAL|WS_FIELD_NILLABLE|WS_FIELD_NILLABLE_ITEM))
{
FIXME( "options %08x not supported\n", desc->options );
return E_NOTIMPL;
}
if (!(option = get_field_read_option( desc->type, desc->options ))) return E_INVALIDARG;
if (option == WS_READ_REQUIRED_VALUE || option == WS_READ_NILLABLE_VALUE)
size = get_type_size( desc->type, desc->typeDescription );
else
size = sizeof(void *);
ptr = buf + offset;
switch (desc->mapping)
{
case WS_TYPE_ATTRIBUTE_FIELD_MAPPING:
hr = read_type( reader, WS_ATTRIBUTE_TYPE_MAPPING, desc->type, desc->localName, desc->ns,
desc_struct, option, heap, ptr, size, &found );
break;
case WS_ATTRIBUTE_FIELD_MAPPING:
hr = read_type( reader, WS_ATTRIBUTE_TYPE_MAPPING, desc->type, desc->localName, desc->ns,
desc->typeDescription, option, heap, ptr, size, &found );
break;
case WS_ELEMENT_FIELD_MAPPING:
hr = read_type( reader, WS_ELEMENT_TYPE_MAPPING, desc->type, desc->localName, desc->ns,
desc->typeDescription, option, heap, ptr, size, &found );
break;
case WS_ELEMENT_CHOICE_FIELD_MAPPING:
{
if (desc->type != WS_UNION_TYPE || !desc->typeDescription ||
(desc->options & (WS_FIELD_POINTER|WS_FIELD_NILLABLE))) return E_INVALIDARG;
hr = read_type_union( reader, desc->typeDescription, heap, ptr, size, &found );
break;
}
case WS_REPEATING_ELEMENT_FIELD_MAPPING:
case WS_REPEATING_ELEMENT_CHOICE_FIELD_MAPPING:
{
ULONG count;
hr = read_type_array( reader, desc, heap, (void **)ptr, &count );
if (hr == S_OK) *(ULONG *)(buf + desc->countOffset) = count;
break;
}
case WS_TEXT_FIELD_MAPPING:
hr = read_type_text( reader, desc, option, heap, ptr, size );
break;
default:
FIXME( "unhandled field mapping %u\n", desc->mapping );
return E_NOTIMPL;
}
if (hr == WS_E_INVALID_FORMAT)
{
switch (option)
{
case WS_READ_REQUIRED_VALUE:
case WS_READ_REQUIRED_POINTER:
return WS_E_INVALID_FORMAT;
case WS_READ_NILLABLE_VALUE:
if (desc->defaultValue) memcpy( ptr, desc->defaultValue->value, desc->defaultValue->valueSize );
return S_OK;
case WS_READ_OPTIONAL_POINTER:
case WS_READ_NILLABLE_POINTER:
*(void **)ptr = NULL;
return S_OK;
default:
ERR( "unhandled option %u\n", option );
return E_NOTIMPL;
}
}
return hr;
}
static HRESULT read_type_struct( struct reader *reader, WS_TYPE_MAPPING mapping, const WS_XML_STRING *localname,
const WS_XML_STRING *ns, const WS_STRUCT_DESCRIPTION *desc, WS_READ_OPTION option,
WS_HEAP *heap, void *ret, ULONG size, BOOL *found )
{
ULONG i, offset;
HRESULT hr;
char *buf;
if (!desc) return E_INVALIDARG;
if (desc->structOptions & ~WS_STRUCT_IGNORE_TRAILING_ELEMENT_CONTENT)
{
FIXME( "struct options %08x not supported\n",
desc->structOptions & ~WS_STRUCT_IGNORE_TRAILING_ELEMENT_CONTENT );
}
switch (option)
{
case WS_READ_REQUIRED_POINTER:
case WS_READ_OPTIONAL_POINTER:
case WS_READ_NILLABLE_POINTER:
if (size != sizeof(void *)) return E_INVALIDARG;
if (!(buf = ws_alloc_zero( heap, desc->size ))) return WS_E_QUOTA_EXCEEDED;
break;
case WS_READ_REQUIRED_VALUE:
case WS_READ_NILLABLE_VALUE:
if (size != desc->size) return E_INVALIDARG;
buf = ret;
break;
default:
FIXME( "unhandled read option %u\n", option );
return E_NOTIMPL;
}
for (i = 0; i < desc->fieldCount; i++)
{
offset = desc->fields[i]->offset;
if ((hr = read_type_field( reader, desc, desc->fields[i], heap, buf, offset )) != S_OK) break;
}
switch (option)
{
case WS_READ_REQUIRED_POINTER:
if (hr != S_OK)
{
ws_free( heap, buf, desc->size );
return hr;
}
*(char **)ret = buf;
break;
case WS_READ_OPTIONAL_POINTER:
case WS_READ_NILLABLE_POINTER:
if (is_nil_value( buf, desc->size ))
{
ws_free( heap, buf, desc->size );
buf = NULL;
}
*(char **)ret = buf;
break;
case WS_READ_REQUIRED_VALUE:
case WS_READ_NILLABLE_VALUE:
if (hr != S_OK) return hr;
break;
default:
ERR( "unhandled read option %u\n", option );
return E_NOTIMPL;
}
if (desc->structOptions & WS_STRUCT_IGNORE_TRAILING_ELEMENT_CONTENT)
{
struct node *parent = find_parent( reader );
parent->flags |= NODE_FLAG_IGNORE_TRAILING_ELEMENT_CONTENT;
}
*found = TRUE;
return S_OK;
}
static HRESULT start_mapping( struct reader *reader, WS_TYPE_MAPPING mapping, const WS_XML_STRING *localname,
const WS_XML_STRING *ns )
{
switch (mapping)
{
case WS_ELEMENT_TYPE_MAPPING:
case WS_ELEMENT_CONTENT_TYPE_MAPPING:
return read_type_next_element_node( reader, localname, ns );
case WS_ANY_ELEMENT_TYPE_MAPPING:
case WS_ATTRIBUTE_TYPE_MAPPING:
return S_OK;
default:
FIXME( "unhandled mapping %u\n", mapping );
return E_NOTIMPL;
}
}
static HRESULT read_type_endelement_node( struct reader *reader )
{
const struct node *parent = find_parent( reader );
HRESULT hr;
for (;;)
{
if ((hr = read_type_next_node( reader )) != S_OK) return hr;
if (node_type( reader->current ) == WS_XML_NODE_TYPE_END_ELEMENT && reader->current->parent == parent)
{
return S_OK;
}
if (read_end_of_data( reader ) || !(parent->flags & NODE_FLAG_IGNORE_TRAILING_ELEMENT_CONTENT)) break;
}
return WS_E_INVALID_FORMAT;
}
static HRESULT end_mapping( struct reader *reader, WS_TYPE_MAPPING mapping )
{
switch (mapping)
{
case WS_ELEMENT_TYPE_MAPPING:
return read_type_endelement_node( reader );
case WS_ELEMENT_CONTENT_TYPE_MAPPING:
return read_type_next_node( reader );
case WS_ATTRIBUTE_TYPE_MAPPING:
default:
return S_OK;
}
}
static BOOL is_true_text( const WS_XML_TEXT *text )
{
switch (text->textType)
{
case WS_XML_TEXT_TYPE_UTF8:
{
const WS_XML_UTF8_TEXT *text_utf8 = (const WS_XML_UTF8_TEXT *)text;
if (text_utf8->value.length == 4 && !memcmp( text_utf8->value.bytes, "true", 4 )) return TRUE;
return FALSE;
}
case WS_XML_TEXT_TYPE_BOOL:
{
const WS_XML_BOOL_TEXT *text_bool = (const WS_XML_BOOL_TEXT *)text;
return text_bool->value;
}
default:
ERR( "unhandled text type %u\n", text->textType );
return FALSE;
}
}
static HRESULT is_nil_element( const WS_XML_ELEMENT_NODE *elem )
{
static const WS_XML_STRING localname = {3, (BYTE *)"nil"};
static const WS_XML_STRING ns = {41, (BYTE *)"http://www.w3.org/2001/XMLSchema-instance"};
ULONG i;
for (i = 0; i < elem->attributeCount; i++)
{
if (elem->attributes[i]->isXmlNs) continue;
if (WsXmlStringEquals( elem->attributes[i]->localName, &localname, NULL ) == S_OK &&
WsXmlStringEquals( elem->attributes[i]->ns, &ns, NULL ) == S_OK &&
is_true_text( elem->attributes[i]->value )) return TRUE;
}
return FALSE;
}
static HRESULT read_type( struct reader *reader, WS_TYPE_MAPPING mapping, WS_TYPE type,
const WS_XML_STRING *localname, const WS_XML_STRING *ns, const void *desc,
WS_READ_OPTION option, WS_HEAP *heap, void *value, ULONG size, BOOL *found )
{
HRESULT hr;
if ((hr = start_mapping( reader, mapping, localname, ns )) != S_OK) return hr;
if (mapping == WS_ELEMENT_TYPE_MAPPING && is_nil_element( &reader->current->hdr ))
{
if (option != WS_READ_NILLABLE_POINTER && option != WS_READ_NILLABLE_VALUE) return WS_E_INVALID_FORMAT;
*found = TRUE;
return end_mapping( reader, mapping );
}
switch (type)
{
case WS_BOOL_TYPE:
hr = read_type_bool( reader, mapping, localname, ns, desc, option, heap, value, size, found );
break;
case WS_INT8_TYPE:
hr = read_type_int8( reader, mapping, localname, ns, desc, option, heap, value, size, found );
break;
case WS_INT16_TYPE:
hr = read_type_int16( reader, mapping, localname, ns, desc, option, heap, value, size, found );
break;
case WS_INT32_TYPE:
hr = read_type_int32( reader, mapping, localname, ns, desc, option, heap, value, size, found );
break;
case WS_INT64_TYPE:
hr = read_type_int64( reader, mapping, localname, ns, desc, option, heap, value, size, found );
break;
case WS_UINT8_TYPE:
hr = read_type_uint8( reader, mapping, localname, ns, desc, option, heap, value, size, found );
break;
case WS_UINT16_TYPE:
hr = read_type_uint16( reader, mapping, localname, ns, desc, option, heap, value, size, found );
break;
case WS_UINT32_TYPE:
hr = read_type_uint32( reader, mapping, localname, ns, desc, option, heap, value, size, found );
break;
case WS_UINT64_TYPE:
hr = read_type_uint64( reader, mapping, localname, ns, desc, option, heap, value, size, found );
break;
case WS_FLOAT_TYPE:
hr = read_type_float( reader, mapping, localname, ns, desc, option, heap, value, size, found );
break;
case WS_DOUBLE_TYPE:
hr = read_type_double( reader, mapping, localname, ns, desc, option, heap, value, size, found );
break;
case WS_DATETIME_TYPE:
hr = read_type_datetime( reader, mapping, localname, ns, desc, option, heap, value, size, found );
break;
case WS_GUID_TYPE:
hr = read_type_guid( reader, mapping, localname, ns, desc, option, heap, value, size, found );
break;
case WS_UNIQUE_ID_TYPE:
hr = read_type_unique_id( reader, mapping, localname, ns, desc, option, heap, value, size, found );
break;
case WS_STRING_TYPE:
hr = read_type_string( reader, mapping, localname, ns, desc, option, heap, value, size, found );
break;
case WS_WSZ_TYPE:
hr = read_type_wsz( reader, mapping, localname, ns, desc, option, heap, value, size, found );
break;
case WS_BYTES_TYPE:
hr = read_type_bytes( reader, mapping, localname, ns, desc, option, heap, value, size, found );
break;
case WS_XML_STRING_TYPE:
hr = read_type_xml_string( reader, mapping, localname, ns, desc, option, heap, value, size, found );
break;
case WS_XML_QNAME_TYPE:
hr = read_type_qname( reader, mapping, localname, ns, desc, option, heap, value, size, found );
break;
case WS_DESCRIPTION_TYPE:
hr = read_type_description( reader, mapping, localname, ns, desc, option, heap, value, size, found );
break;
case WS_STRUCT_TYPE:
hr = read_type_struct( reader, mapping, localname, ns, desc, option, heap, value, size, found );
break;
case WS_ENUM_TYPE:
hr = read_type_enum( reader, mapping, localname, ns, desc, option, heap, value, size, found );
break;
default:
FIXME( "type %u not supported\n", type );
return E_NOTIMPL;
}
if (hr != S_OK) return hr;
return end_mapping( reader, mapping );
}
/**************************************************************************
* WsReadType [webservices.@]
*/
HRESULT WINAPI WsReadType( WS_XML_READER *handle, WS_TYPE_MAPPING mapping, WS_TYPE type,
const void *desc, WS_READ_OPTION option, WS_HEAP *heap, void *value,
ULONG size, WS_ERROR *error )
{
struct reader *reader = (struct reader *)handle;
BOOL found;
HRESULT hr;
TRACE( "%p %u %u %p %u %p %p %u %p\n", handle, mapping, type, desc, option, heap, value,
size, error );
if (error) FIXME( "ignoring error parameter\n" );
if (!reader || !value) return E_INVALIDARG;
EnterCriticalSection( &reader->cs );
if (reader->magic != READER_MAGIC)
{
LeaveCriticalSection( &reader->cs );
return E_INVALIDARG;
}
if ((hr = read_type( reader, mapping, type, NULL, NULL, desc, option, heap, value, size, &found )) == S_OK)
{
switch (mapping)
{
case WS_ELEMENT_TYPE_MAPPING:
hr = read_node( reader );
break;
default:
break;
}
if (hr == S_OK && !read_end_of_data( reader )) hr = WS_E_INVALID_FORMAT;
}
LeaveCriticalSection( &reader->cs );
TRACE( "returning %08x\n", hr );
return hr;
}
HRESULT read_header( WS_XML_READER *handle, const WS_XML_STRING *localname, const WS_XML_STRING *ns,
WS_TYPE type, const void *desc, WS_READ_OPTION option, WS_HEAP *heap, void *value,
ULONG size )
{
struct reader *reader = (struct reader *)handle;
BOOL found;
HRESULT hr;
EnterCriticalSection( &reader->cs );
if (reader->magic != READER_MAGIC)
{
LeaveCriticalSection( &reader->cs );
return E_INVALIDARG;
}
hr = read_type( reader, WS_ELEMENT_CONTENT_TYPE_MAPPING, type, localname, ns, desc, option, heap,
value, size, &found );
LeaveCriticalSection( &reader->cs );
return hr;
}
/**************************************************************************
* WsReadElement [webservices.@]
*/
HRESULT WINAPI WsReadElement( WS_XML_READER *handle, const WS_ELEMENT_DESCRIPTION *desc,
WS_READ_OPTION option, WS_HEAP *heap, void *value, ULONG size,
WS_ERROR *error )
{
struct reader *reader = (struct reader *)handle;
BOOL found;
HRESULT hr;
TRACE( "%p %p %u %p %p %u %p\n", handle, desc, option, heap, value, size, error );
if (error) FIXME( "ignoring error parameter\n" );
if (!reader || !desc || !value) return E_INVALIDARG;
EnterCriticalSection( &reader->cs );
if (reader->magic != READER_MAGIC)
{
LeaveCriticalSection( &reader->cs );
return E_INVALIDARG;
}
hr = read_type( reader, WS_ELEMENT_TYPE_MAPPING, desc->type, desc->elementLocalName,
desc->elementNs, desc->typeDescription, option, heap, value, size, &found );
LeaveCriticalSection( &reader->cs );
TRACE( "returning %08x\n", hr );
return hr;
}
/**************************************************************************
* WsReadValue [webservices.@]
*/
HRESULT WINAPI WsReadValue( WS_XML_READER *handle, WS_VALUE_TYPE value_type, void *value, ULONG size,
WS_ERROR *error )
{
struct reader *reader = (struct reader *)handle;
WS_TYPE type = map_value_type( value_type );
BOOL found;
HRESULT hr;
TRACE( "%p %u %p %u %p\n", handle, type, value, size, error );
if (error) FIXME( "ignoring error parameter\n" );
if (!reader || !value || type == ~0u) return E_INVALIDARG;
EnterCriticalSection( &reader->cs );
if (reader->magic != READER_MAGIC)
{
LeaveCriticalSection( &reader->cs );
return E_INVALIDARG;
}
hr = read_type( reader, WS_ELEMENT_TYPE_MAPPING, type, NULL, NULL, NULL, WS_READ_REQUIRED_VALUE,
NULL, value, size, &found );
LeaveCriticalSection( &reader->cs );
TRACE( "returning %08x\n", hr );
return hr;
}
/**************************************************************************
* WsReadAttribute [webservices.@]
*/
HRESULT WINAPI WsReadAttribute( WS_XML_READER *handle, const WS_ATTRIBUTE_DESCRIPTION *desc,
WS_READ_OPTION option, WS_HEAP *heap, void *value, ULONG size,
WS_ERROR *error )
{
struct reader *reader = (struct reader *)handle;
BOOL found;
HRESULT hr;
TRACE( "%p %p %u %p %p %u %p\n", handle, desc, option, heap, value, size, error );
if (error) FIXME( "ignoring error parameter\n" );
if (!reader || !desc || !value) return E_INVALIDARG;
EnterCriticalSection( &reader->cs );
if (reader->magic != READER_MAGIC)
{
LeaveCriticalSection( &reader->cs );
return E_INVALIDARG;
}
if (!reader->input_type) hr = WS_E_INVALID_OPERATION;
else hr = read_type( reader, WS_ATTRIBUTE_TYPE_MAPPING, desc->type, desc->attributeLocalName,
desc->attributeNs, desc->typeDescription, option, heap, value, size, &found );
LeaveCriticalSection( &reader->cs );
TRACE( "returning %08x\n", hr );
return hr;
}
static inline BOOL is_utf8( const unsigned char *data, ULONG size, ULONG *offset )
{
static const char bom[] = {0xef,0xbb,0xbf};
return (size >= sizeof(bom) && !memcmp( data, bom, sizeof(bom) ) && (*offset = sizeof(bom))) ||
(size > 2 && !(*offset = 0));
}
static inline BOOL is_utf16le( const unsigned char *data, ULONG size, ULONG *offset )
{
static const char bom[] = {0xff,0xfe};
return (size >= sizeof(bom) && !memcmp( data, bom, sizeof(bom) ) && (*offset = sizeof(bom))) ||
(size >= 4 && data[0] == '<' && !data[1] && !(*offset = 0));
}
static WS_CHARSET detect_charset( const unsigned char *data, ULONG size, ULONG *offset )
{
WS_CHARSET ret = 0;
/* FIXME: parse xml declaration */
if (is_utf16le( data, size, offset )) ret = WS_CHARSET_UTF16LE;
else if (is_utf8( data, size, offset )) ret = WS_CHARSET_UTF8;
else
{
FIXME( "charset not recognized\n" );
return 0;
}
TRACE( "detected charset %u\n", ret );
return ret;
}
static HRESULT utf16le_to_utf8( const unsigned char *data, ULONG size, unsigned char **buf, ULONG *buflen )
{
if (size % sizeof(WCHAR)) return E_INVALIDARG;
*buflen = WideCharToMultiByte( CP_UTF8, 0, (const WCHAR *)data, size / sizeof(WCHAR), NULL, 0, NULL, NULL );
if (!(*buf = heap_alloc( *buflen ))) return E_OUTOFMEMORY;
WideCharToMultiByte( CP_UTF8, 0, (const WCHAR *)data, size / sizeof(WCHAR), (char *)*buf, *buflen, NULL, NULL );
return S_OK;
}
static HRESULT set_input_buffer( struct reader *reader, const unsigned char *data, ULONG size )
{
reader->input_type = WS_XML_READER_INPUT_TYPE_BUFFER;
reader->input_buf = NULL;
if (reader->input_enc == WS_XML_READER_ENCODING_TYPE_TEXT && reader->input_charset == WS_CHARSET_UTF16LE)
{
unsigned char *buf;
ULONG buflen;
HRESULT hr;
if ((hr = utf16le_to_utf8( data, size, &buf, &buflen )) != S_OK) return hr;
heap_free( reader->input_conv );
reader->read_bufptr = reader->input_conv = buf;
reader->read_size = reader->input_size = buflen;
}
else
{
reader->read_bufptr = data;
reader->read_size = reader->input_size = size;
}
reader->read_pos = 0;
reader->text_conv_offset = 0;
return S_OK;
}
static void set_input_stream( struct reader *reader, WS_READ_CALLBACK callback, void *state )
{
reader->input_type = WS_XML_READER_INPUT_TYPE_STREAM;
reader->input_cb = callback;
reader->input_cb_state = state;
reader->input_buf = NULL;
reader->input_size = STREAM_BUFSIZE;
if (reader->read_pos >= reader->read_size) reader->read_size = 0;
else
{
memmove( reader->stream_buf, reader->stream_buf + reader->read_pos, reader->read_size - reader->read_pos );
reader->read_size -= reader->read_pos;
}
reader->read_pos = 0;
reader->read_bufptr = reader->stream_buf;
reader->text_conv_offset = 0;
}
/**************************************************************************
* WsSetInput [webservices.@]
*/
HRESULT WINAPI WsSetInput( WS_XML_READER *handle, const WS_XML_READER_ENCODING *encoding,
const WS_XML_READER_INPUT *input, const WS_XML_READER_PROPERTY *properties,
ULONG count, WS_ERROR *error )
{
struct reader *reader = (struct reader *)handle;
struct node *node;
ULONG i, offset = 0;
HRESULT hr;
TRACE( "%p %p %p %p %u %p\n", handle, encoding, input, properties, count, error );
if (error) FIXME( "ignoring error parameter\n" );
if (!reader) return E_INVALIDARG;
EnterCriticalSection( &reader->cs );
if (reader->magic != READER_MAGIC)
{
LeaveCriticalSection( &reader->cs );
return E_INVALIDARG;
}
for (i = 0; i < count; i++)
{
hr = prop_set( reader->prop, reader->prop_count, properties[i].id, properties[i].value,
properties[i].valueSize );
if (hr != S_OK) goto done;
}
if ((hr = init_reader( reader )) != S_OK) goto done;
switch (encoding->encodingType)
{
case WS_XML_READER_ENCODING_TYPE_TEXT:
{
if (input->inputType == WS_XML_READER_INPUT_TYPE_BUFFER)
{
const WS_XML_READER_TEXT_ENCODING *text = (const WS_XML_READER_TEXT_ENCODING *)encoding;
const WS_XML_READER_BUFFER_INPUT *buf = (const WS_XML_READER_BUFFER_INPUT *)input;
if (text->charSet != WS_CHARSET_AUTO) reader->input_charset = text->charSet;
else reader->input_charset = detect_charset( buf->encodedData, buf->encodedDataSize, &offset );
}
reader->input_enc = WS_XML_READER_ENCODING_TYPE_TEXT;
break;
}
case WS_XML_READER_ENCODING_TYPE_BINARY:
{
const WS_XML_READER_BINARY_ENCODING *bin = (const WS_XML_READER_BINARY_ENCODING *)encoding;
reader->input_enc = WS_XML_READER_ENCODING_TYPE_BINARY;
reader->input_charset = 0;
reader->dict_static = bin->staticDictionary ? bin->staticDictionary : &dict_builtin_static.dict;
reader->dict = bin->dynamicDictionary ? bin->dynamicDictionary : &dict_builtin.dict;
break;
}
default:
FIXME( "encoding type %u not supported\n", encoding->encodingType );
hr = E_NOTIMPL;
goto done;
}
switch (input->inputType)
{
case WS_XML_READER_INPUT_TYPE_BUFFER:
{
const WS_XML_READER_BUFFER_INPUT *buf = (const WS_XML_READER_BUFFER_INPUT *)input;
hr = set_input_buffer( reader, (const unsigned char *)buf->encodedData + offset, buf->encodedDataSize - offset );
if (hr != S_OK) goto done;
break;
}
case WS_XML_READER_INPUT_TYPE_STREAM:
{
const WS_XML_READER_STREAM_INPUT *stream = (const WS_XML_READER_STREAM_INPUT *)input;
if (!reader->stream_buf && !(reader->stream_buf = heap_alloc( STREAM_BUFSIZE )))
{
hr = E_OUTOFMEMORY;
goto done;
}
set_input_stream( reader, stream->readCallback, stream->readCallbackState );
break;
}
default:
FIXME( "input type %u not supported\n", input->inputType );
hr = E_NOTIMPL;
goto done;
}
if (!(node = alloc_node( WS_XML_NODE_TYPE_BOF ))) hr = E_OUTOFMEMORY;
else read_insert_bof( reader, node );
done:
LeaveCriticalSection( &reader->cs );
TRACE( "returning %08x\n", hr );
return hr;
}
static HRESULT set_input_xml_buffer( struct reader *reader, struct xmlbuf *xmlbuf )
{
reader->input_type = WS_XML_READER_INPUT_TYPE_BUFFER;
reader->input_buf = xmlbuf;
reader->input_enc = xmlbuf->encoding;
reader->input_charset = xmlbuf->charset;
reader->dict_static = xmlbuf->dict_static;
reader->dict = xmlbuf->dict;
if (reader->input_enc == WS_XML_READER_ENCODING_TYPE_TEXT && reader->input_charset == WS_CHARSET_UTF16LE)
{
unsigned char *buf;
ULONG buflen;
HRESULT hr;
if ((hr = utf16le_to_utf8( xmlbuf->bytes.bytes, xmlbuf->bytes.length, &buf, &buflen )) != S_OK) return hr;
heap_free( reader->input_conv );
reader->read_bufptr = reader->input_conv = buf;
reader->read_size = reader->input_size = buflen;
}
else
{
reader->read_bufptr = xmlbuf->bytes.bytes;
reader->read_size = reader->input_size = xmlbuf->bytes.length;
}
reader->read_pos = 0;
reader->text_conv_offset = 0;
return S_OK;
}
/**************************************************************************
* WsSetInputToBuffer [webservices.@]
*/
HRESULT WINAPI WsSetInputToBuffer( WS_XML_READER *handle, WS_XML_BUFFER *buffer,
const WS_XML_READER_PROPERTY *properties, ULONG count,
WS_ERROR *error )
{
struct reader *reader = (struct reader *)handle;
struct xmlbuf *xmlbuf = (struct xmlbuf *)buffer;
struct node *node;
HRESULT hr;
ULONG i;
TRACE( "%p %p %p %u %p\n", handle, buffer, properties, count, error );
if (error) FIXME( "ignoring error parameter\n" );
if (!reader || !xmlbuf) return E_INVALIDARG;
EnterCriticalSection( &reader->cs );
if (reader->magic != READER_MAGIC)
{
LeaveCriticalSection( &reader->cs );
return E_INVALIDARG;
}
for (i = 0; i < count; i++)
{
hr = prop_set( reader->prop, reader->prop_count, properties[i].id, properties[i].value,
properties[i].valueSize );
if (hr != S_OK) goto done;
}
if ((hr = init_reader( reader )) != S_OK) goto done;
if ((hr = set_input_xml_buffer( reader, xmlbuf )) != S_OK) goto done;
if (!(node = alloc_node( WS_XML_NODE_TYPE_BOF ))) hr = E_OUTOFMEMORY;
else read_insert_bof( reader, node );
done:
LeaveCriticalSection( &reader->cs );
TRACE( "returning %08x\n", hr );
return hr;
}
/**************************************************************************
* WsGetReaderPosition [webservices.@]
*/
HRESULT WINAPI WsGetReaderPosition( WS_XML_READER *handle, WS_XML_NODE_POSITION *pos, WS_ERROR *error )
{
struct reader *reader = (struct reader *)handle;
HRESULT hr = S_OK;
TRACE( "%p %p %p\n", handle, pos, error );
if (error) FIXME( "ignoring error parameter\n" );
if (!reader || !pos) return E_INVALIDARG;
EnterCriticalSection( &reader->cs );
if (reader->magic != READER_MAGIC)
{
LeaveCriticalSection( &reader->cs );
return E_INVALIDARG;
}
if (!reader->input_buf) hr = WS_E_INVALID_OPERATION;
else
{
pos->buffer = (WS_XML_BUFFER *)reader->input_buf;
pos->node = reader->current;
}
LeaveCriticalSection( &reader->cs );
TRACE( "returning %08x\n", hr );
return hr;
}
/**************************************************************************
* WsSetReaderPosition [webservices.@]
*/
HRESULT WINAPI WsSetReaderPosition( WS_XML_READER *handle, const WS_XML_NODE_POSITION *pos, WS_ERROR *error )
{
struct reader *reader = (struct reader *)handle;
HRESULT hr = S_OK;
TRACE( "%p %p %p\n", handle, pos, error );
if (error) FIXME( "ignoring error parameter\n" );
if (!reader || !pos) return E_INVALIDARG;
EnterCriticalSection( &reader->cs );
if (reader->magic != READER_MAGIC || (struct xmlbuf *)pos->buffer != reader->input_buf)
{
LeaveCriticalSection( &reader->cs );
return E_INVALIDARG;
}
if (!reader->input_buf) hr = WS_E_INVALID_OPERATION;
else reader->current = pos->node;
LeaveCriticalSection( &reader->cs );
TRACE( "returning %08x\n", hr );
return hr;
}
static HRESULT utf8_to_base64( const WS_XML_UTF8_TEXT *utf8, WS_XML_BASE64_TEXT *base64 )
{
if (utf8->value.length % 4) return WS_E_INVALID_FORMAT;
if (!(base64->bytes = heap_alloc( utf8->value.length * 3 / 4 ))) return E_OUTOFMEMORY;
base64->length = decode_base64( utf8->value.bytes, utf8->value.length, base64->bytes );
return S_OK;
}
/**************************************************************************
* WsReadBytes [webservices.@]
*/
HRESULT WINAPI WsReadBytes( WS_XML_READER *handle, void *bytes, ULONG max_count, ULONG *count, WS_ERROR *error )
{
struct reader *reader = (struct reader *)handle;
HRESULT hr = S_OK;
TRACE( "%p %p %u %p %p\n", handle, bytes, max_count, count, error );
if (error) FIXME( "ignoring error parameter\n" );
if (!reader) return E_INVALIDARG;
EnterCriticalSection( &reader->cs );
if (reader->magic != READER_MAGIC)
{
LeaveCriticalSection( &reader->cs );
return E_INVALIDARG;
}
if (!reader->input_type)
{
hr = WS_E_INVALID_OPERATION;
goto done;
}
if (!count)
{
hr = E_INVALIDARG;
goto done;
}
*count = 0;
if (node_type( reader->current ) == WS_XML_NODE_TYPE_TEXT && bytes)
{
const WS_XML_TEXT_NODE *text = (const WS_XML_TEXT_NODE *)reader->current;
WS_XML_BASE64_TEXT base64;
if ((hr = utf8_to_base64( (const WS_XML_UTF8_TEXT *)text->text, &base64 )) != S_OK) goto done;
if (reader->text_conv_offset == base64.length)
{
heap_free( base64.bytes );
hr = read_node( reader );
goto done;
}
*count = min( base64.length - reader->text_conv_offset, max_count );
memcpy( bytes, base64.bytes + reader->text_conv_offset, *count );
reader->text_conv_offset += *count;
heap_free( base64.bytes );
}
done:
LeaveCriticalSection( &reader->cs );
TRACE( "returning %08x\n", hr );
return hr;
}
static HRESULT utf8_to_utf16( const WS_XML_UTF8_TEXT *utf8, WS_XML_UTF16_TEXT *utf16 )
{
int len = MultiByteToWideChar( CP_UTF8, 0, (char *)utf8->value.bytes, utf8->value.length, NULL, 0 );
if (!(utf16->bytes = heap_alloc( len * sizeof(WCHAR) ))) return E_OUTOFMEMORY;
MultiByteToWideChar( CP_UTF8, 0, (char *)utf8->value.bytes, utf8->value.length, (WCHAR *)utf16->bytes, len );
utf16->byteCount = len * sizeof(WCHAR);
return S_OK;
}
/**************************************************************************
* WsReadChars [webservices.@]
*/
HRESULT WINAPI WsReadChars( WS_XML_READER *handle, WCHAR *chars, ULONG max_count, ULONG *count, WS_ERROR *error )
{
struct reader *reader = (struct reader *)handle;
HRESULT hr = S_OK;
TRACE( "%p %p %u %p %p\n", handle, chars, max_count, count, error );
if (error) FIXME( "ignoring error parameter\n" );
if (!reader) return E_INVALIDARG;
EnterCriticalSection( &reader->cs );
if (reader->magic != READER_MAGIC)
{
LeaveCriticalSection( &reader->cs );
return E_INVALIDARG;
}
if (!reader->input_type)
{
hr = WS_E_INVALID_OPERATION;
goto done;
}
if (!count)
{
hr = E_INVALIDARG;
goto done;
}
*count = 0;
if (node_type( reader->current ) == WS_XML_NODE_TYPE_TEXT && chars)
{
const WS_XML_TEXT_NODE *text = (const WS_XML_TEXT_NODE *)reader->current;
WS_XML_UTF16_TEXT utf16;
HRESULT hr;
if ((hr = utf8_to_utf16( (const WS_XML_UTF8_TEXT *)text->text, &utf16 )) != S_OK) goto done;
if (reader->text_conv_offset == utf16.byteCount / sizeof(WCHAR))
{
heap_free( utf16.bytes );
hr = read_node( reader );
goto done;
}
*count = min( utf16.byteCount / sizeof(WCHAR) - reader->text_conv_offset, max_count );
memcpy( chars, utf16.bytes + reader->text_conv_offset * sizeof(WCHAR), *count * sizeof(WCHAR) );
reader->text_conv_offset += *count;
heap_free( utf16.bytes );
}
done:
LeaveCriticalSection( &reader->cs );
TRACE( "returning %08x\n", hr );
return hr;
}
/**************************************************************************
* WsReadCharsUtf8 [webservices.@]
*/
HRESULT WINAPI WsReadCharsUtf8( WS_XML_READER *handle, BYTE *bytes, ULONG max_count, ULONG *count, WS_ERROR *error )
{
struct reader *reader = (struct reader *)handle;
HRESULT hr = S_OK;
TRACE( "%p %p %u %p %p\n", handle, bytes, max_count, count, error );
if (error) FIXME( "ignoring error parameter\n" );
if (!reader) return E_INVALIDARG;
EnterCriticalSection( &reader->cs );
if (reader->magic != READER_MAGIC)
{
LeaveCriticalSection( &reader->cs );
return E_INVALIDARG;
}
if (!reader->input_type)
{
hr = WS_E_INVALID_OPERATION;
goto done;
}
if (!count)
{
hr = E_INVALIDARG;
goto done;
}
*count = 0;
if (node_type( reader->current ) == WS_XML_NODE_TYPE_TEXT && bytes)
{
const WS_XML_TEXT_NODE *text = (const WS_XML_TEXT_NODE *)reader->current;
const WS_XML_UTF8_TEXT *utf8 = (const WS_XML_UTF8_TEXT *)text->text;
if (reader->text_conv_offset == utf8->value.length)
{
hr = read_node( reader );
goto done;
}
*count = min( utf8->value.length - reader->text_conv_offset, max_count );
memcpy( bytes, utf8->value.bytes + reader->text_conv_offset, *count );
reader->text_conv_offset += *count;
}
done:
LeaveCriticalSection( &reader->cs );
TRACE( "returning %08x\n", hr );
return hr;
}
static HRESULT move_to_element( struct reader *reader )
{
HRESULT hr;
if (node_type( reader->current ) == WS_XML_NODE_TYPE_BOF &&
(hr = read_move_to( reader, WS_MOVE_TO_CHILD_NODE, NULL )) != S_OK) return hr;
if (node_type( reader->current ) != WS_XML_NODE_TYPE_ELEMENT) return E_FAIL;
return S_OK;
}
static HRESULT copy_tree( struct reader *reader, WS_XML_WRITER *writer )
{
const struct node *node, *parent;
BOOL done = FALSE;
HRESULT hr;
if ((hr = move_to_element( reader )) != S_OK) return hr;
parent = reader->current;
for (;;)
{
node = reader->current;
if ((hr = WsWriteNode( writer, (const WS_XML_NODE *)node, NULL )) != S_OK) break;
if (node_type( node ) == WS_XML_NODE_TYPE_END_ELEMENT && node->parent == parent) done = TRUE;
if ((hr = read_next_node( reader )) != S_OK || done) break;
}
return hr;
}
/**************************************************************************
* WsReadXmlBuffer [webservices.@]
*/
HRESULT WINAPI WsReadXmlBuffer( WS_XML_READER *handle, WS_HEAP *heap, WS_XML_BUFFER **ret, WS_ERROR *error )
{
struct reader *reader = (struct reader *)handle;
WS_XML_WRITER *writer = NULL;
WS_XML_BUFFER *buffer = NULL;
HRESULT hr;
TRACE( "%p %p %p %p\n", handle, heap, ret, error );
if (error) FIXME( "ignoring error parameter\n" );
if (!reader || !heap) return E_INVALIDARG;
if (!ret) return E_FAIL;
EnterCriticalSection( &reader->cs );
if (reader->magic != READER_MAGIC)
{
LeaveCriticalSection( &reader->cs );
return E_INVALIDARG;
}
if (!reader->input_type) hr = WS_E_INVALID_OPERATION;
else
{
if ((hr = WsCreateWriter( NULL, 0, &writer, NULL )) != S_OK) goto done;
if ((hr = WsCreateXmlBuffer( heap, NULL, 0, &buffer, NULL )) != S_OK) goto done;
if ((hr = WsSetOutputToBuffer( writer, buffer, NULL, 0, NULL )) != S_OK) goto done;
if ((hr = copy_tree( reader, writer )) == S_OK) *ret = buffer;
}
done:
if (hr != S_OK) free_xmlbuf( (struct xmlbuf *)buffer );
WsFreeWriter( writer );
LeaveCriticalSection( &reader->cs );
TRACE( "returning %08x\n", hr );
return hr;
}
HRESULT create_header_buffer( WS_XML_READER *handle, WS_HEAP *heap, WS_XML_BUFFER **ret )
{
struct reader *reader = (struct reader *)handle;
HRESULT hr = WS_E_QUOTA_EXCEEDED;
struct xmlbuf *xmlbuf;
EnterCriticalSection( &reader->cs );
if (reader->magic != READER_MAGIC)
{
LeaveCriticalSection( &reader->cs );
return E_INVALIDARG;
}
if ((xmlbuf = alloc_xmlbuf( heap, reader->read_pos, reader->input_enc, reader->input_charset,
reader->dict_static, reader->dict )))
{
memcpy( xmlbuf->bytes.bytes, reader->read_bufptr, reader->read_pos );
xmlbuf->bytes.length = reader->read_pos;
*ret = (WS_XML_BUFFER *)xmlbuf;
hr = S_OK;
}
LeaveCriticalSection( &reader->cs );
return hr;
}
HRESULT get_param_desc( const WS_STRUCT_DESCRIPTION *desc, USHORT index, const WS_FIELD_DESCRIPTION **ret )
{
if (index >= desc->fieldCount) return E_INVALIDARG;
*ret = desc->fields[index];
return S_OK;
}
static ULONG get_field_size( const WS_FIELD_DESCRIPTION *desc )
{
if (desc->options & WS_FIELD_POINTER) return sizeof(void *);
return get_type_size( desc->type, desc->typeDescription );
}
static HRESULT read_param( struct reader *reader, const WS_FIELD_DESCRIPTION *desc, WS_HEAP *heap, void *ret )
{
if (!ret && !(ret = ws_alloc_zero( heap, get_field_size(desc) ))) return WS_E_QUOTA_EXCEEDED;
return read_type_field( reader, NULL, desc, heap, ret, 0 );
}
static HRESULT read_param_array( struct reader *reader, const WS_FIELD_DESCRIPTION *desc, WS_HEAP *heap,
void **ret, ULONG *count )
{
if (!ret && !(ret = ws_alloc_zero( heap, sizeof(void **) ))) return WS_E_QUOTA_EXCEEDED;
return read_type_array( reader, desc, heap, ret, count );
}
static void set_array_len( const WS_PARAMETER_DESCRIPTION *params, ULONG count, ULONG index, ULONG len,
const void **args )
{
ULONG i, *ptr;
for (i = 0; i < count; i++)
{
if (params[i].outputMessageIndex != index || params[i].parameterType != WS_PARAMETER_TYPE_ARRAY_COUNT)
continue;
if ((ptr = *(ULONG **)args[i])) *ptr = len;
break;
}
}
HRESULT read_output_params( WS_XML_READER *handle, WS_HEAP *heap, const WS_ELEMENT_DESCRIPTION *desc,
const WS_PARAMETER_DESCRIPTION *params, ULONG count, const void **args )
{
struct reader *reader = (struct reader *)handle;
const WS_STRUCT_DESCRIPTION *desc_struct;
const WS_FIELD_DESCRIPTION *desc_field;
ULONG i, len;
HRESULT hr;
if (desc->type != WS_STRUCT_TYPE || !(desc_struct = desc->typeDescription)) return E_INVALIDARG;
EnterCriticalSection( &reader->cs );
if (reader->magic != READER_MAGIC)
{
LeaveCriticalSection( &reader->cs );
return E_INVALIDARG;
}
if ((hr = start_mapping( reader, WS_ELEMENT_TYPE_MAPPING, desc->elementLocalName, desc->elementNs )) != S_OK)
goto done;
for (i = 0; i < count; i++)
{
if (params[i].outputMessageIndex == INVALID_PARAMETER_INDEX) continue;
if (params[i].parameterType == WS_PARAMETER_TYPE_MESSAGES)
{
FIXME( "messages type not supported\n" );
hr = E_NOTIMPL;
goto done;
}
if ((hr = get_param_desc( desc_struct, params[i].outputMessageIndex, &desc_field )) != S_OK) goto done;
if (params[i].parameterType == WS_PARAMETER_TYPE_NORMAL)
{
void *ptr = *(void **)args[i];
if ((hr = read_param( reader, desc_field, heap, ptr )) != S_OK) goto done;
}
else if (params[i].parameterType == WS_PARAMETER_TYPE_ARRAY)
{
void **ptr = *(void ***)args[i];
if ((hr = read_param_array( reader, desc_field, heap, ptr, &len )) != S_OK) goto done;
set_array_len( params, count, params[i].outputMessageIndex, len, args );
}
}
if (desc_struct->structOptions & WS_STRUCT_IGNORE_TRAILING_ELEMENT_CONTENT)
{
struct node *parent = find_parent( reader );
parent->flags |= NODE_FLAG_IGNORE_TRAILING_ELEMENT_CONTENT;
}
hr = end_mapping( reader, WS_ELEMENT_TYPE_MAPPING );
done:
LeaveCriticalSection( &reader->cs );
return hr;
}
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