Sweden-Number/dlls/hidclass.sys/descriptor.c

977 lines
34 KiB
C

/*
* HID descriptor parsing
*
* Copyright (C) 2015 Aric Stewart
*
* 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 <stdlib.h>
#include <stdio.h>
#include "hid.h"
#include "wine/debug.h"
#include "wine/list.h"
WINE_DEFAULT_DEBUG_CHANNEL(hid);
/* Flags that are defined in the document
"Device Class Definition for Human Interface Devices" */
enum {
INPUT_DATA_CONST = 0x01, /* Data (0) | Constant (1) */
INPUT_ARRAY_VAR = 0x02, /* Array (0) | Variable (1) */
INPUT_ABS_REL = 0x04, /* Absolute (0) | Relative (1) */
INPUT_WRAP = 0x08, /* No Wrap (0) | Wrap (1) */
INPUT_LINEAR = 0x10, /* Linear (0) | Non Linear (1) */
INPUT_PREFSTATE = 0x20, /* Preferred State (0) | No Preferred (1) */
INPUT_NULL = 0x40, /* No Null position (0) | Null state(1) */
INPUT_VOLATILE = 0x80, /* Non Volatile (0) | Volatile (1) */
INPUT_BITFIELD = 0x100 /* Bit Field (0) | Buffered Bytes (1) */
};
enum {
TAG_TYPE_MAIN = 0x0,
TAG_TYPE_GLOBAL,
TAG_TYPE_LOCAL,
TAG_TYPE_RESERVED,
};
enum {
TAG_MAIN_INPUT = 0x08,
TAG_MAIN_OUTPUT = 0x09,
TAG_MAIN_FEATURE = 0x0B,
TAG_MAIN_COLLECTION = 0x0A,
TAG_MAIN_END_COLLECTION = 0x0C
};
enum {
TAG_GLOBAL_USAGE_PAGE = 0x0,
TAG_GLOBAL_LOGICAL_MINIMUM,
TAG_GLOBAL_LOGICAL_MAXIMUM,
TAG_GLOBAL_PHYSICAL_MINIMUM,
TAG_GLOBAL_PHYSICAL_MAXIMUM,
TAG_GLOBAL_UNIT_EXPONENT,
TAG_GLOBAL_UNIT,
TAG_GLOBAL_REPORT_SIZE,
TAG_GLOBAL_REPORT_ID,
TAG_GLOBAL_REPORT_COUNT,
TAG_GLOBAL_PUSH,
TAG_GLOBAL_POP
};
enum {
TAG_LOCAL_USAGE = 0x0,
TAG_LOCAL_USAGE_MINIMUM,
TAG_LOCAL_USAGE_MAXIMUM,
TAG_LOCAL_DESIGNATOR_INDEX,
TAG_LOCAL_DESIGNATOR_MINIMUM,
TAG_LOCAL_DESIGNATOR_MAXIMUM,
TAG_LOCAL_STRING_INDEX,
TAG_LOCAL_STRING_MINIMUM,
TAG_LOCAL_STRING_MAXIMUM,
TAG_LOCAL_DELIMITER
};
static const char* const feature_string[] =
{ "Input", "Output", "Feature" };
struct feature {
struct list entry;
HIDP_VALUE_CAPS caps;
HIDP_REPORT_TYPE type;
BOOLEAN isData;
};
static const char* const collection_string[] = {
"Physical",
"Application",
"Logical",
"Report",
"Named Array",
"Usage Switch",
"Usage Modifier",
};
struct collection {
struct list entry;
unsigned int type;
struct collection *parent;
struct list features;
struct list collections;
};
static inline const char *debugstr_hidp_value_caps( HIDP_VALUE_CAPS *caps )
{
if (!caps) return "(null)";
return wine_dbg_sprintf( "RId %d, Usg %02x:%02x-%02x Dat %02x-%02x (%d), Str %d-%d (%d), Des %d-%d (%d), "
"Bits %02x, Als %d, Abs %d, Nul %d, LCol %d LUsg %02x:%02x, BitSz %d, RCnt %d, "
"Unit %x E%+d, Log %+d-%+d, Phy %+d-%+d",
caps->ReportID, caps->UsagePage, caps->Range.UsageMin, caps->Range.UsageMax, caps->Range.DataIndexMin, caps->Range.DataIndexMax, caps->IsRange,
caps->Range.StringMin, caps->Range.StringMax, caps->IsStringRange, caps->Range.DesignatorMin, caps->Range.DesignatorMax, caps->IsDesignatorRange,
caps->BitField, caps->IsAlias, caps->IsAbsolute, caps->HasNull, caps->LinkCollection, caps->LinkUsagePage, caps->LinkUsage, caps->BitSize, caps->ReportCount,
caps->Units, caps->UnitsExp, caps->LogicalMin, caps->LogicalMax, caps->PhysicalMin, caps->PhysicalMax );
}
static void copy_hidp_value_caps( HIDP_VALUE_CAPS *out, const struct hid_value_caps *in )
{
out->UsagePage = in->usage_page;
out->ReportID = in->report_id;
out->LinkCollection = in->link_collection;
out->LinkUsagePage = in->link_usage_page;
out->LinkUsage = in->link_usage;
out->BitField = in->bit_field;
out->IsAlias = FALSE;
out->IsAbsolute = HID_VALUE_CAPS_IS_ABSOLUTE( in );
out->HasNull = HID_VALUE_CAPS_HAS_NULL( in );
out->BitSize = in->bit_size;
out->ReportCount = in->report_count;
out->UnitsExp = in->units_exp;
out->Units = in->units;
out->LogicalMin = in->logical_min;
out->LogicalMax = in->logical_max;
out->PhysicalMin = in->physical_min;
out->PhysicalMax = in->physical_max;
if (!(out->IsRange = in->is_range))
out->NotRange.Usage = in->usage_min;
else
{
out->Range.UsageMin = in->usage_min;
out->Range.UsageMax = in->usage_max;
}
if (!(out->IsStringRange = in->is_string_range))
out->NotRange.StringIndex = in->string_min;
else
{
out->Range.StringMin = in->string_min;
out->Range.StringMax = in->string_max;
}
if ((out->IsDesignatorRange = in->is_designator_range))
out->NotRange.DesignatorIndex = in->designator_min;
else
{
out->Range.DesignatorMin = in->designator_min;
out->Range.DesignatorMax = in->designator_max;
}
}
static void debug_feature(struct feature *feature)
{
if (!feature)
return;
TRACE( "[Feature type %s %s]\n", feature_string[feature->type], (feature->isData) ? "Data" : "Const" );
TRACE("Feature %s\n", debugstr_hidp_value_caps(&feature->caps));
}
static void debug_collection(struct collection *collection)
{
struct feature *fentry;
struct collection *centry;
if (TRACE_ON(hid))
{
TRACE( "START Collection <<< %s, parent: %p, %i features, %i collections\n",
collection_string[collection->type], collection->parent,
list_count( &collection->features ), list_count( &collection->collections ) );
LIST_FOR_EACH_ENTRY(fentry, &collection->features, struct feature, entry)
debug_feature(fentry);
LIST_FOR_EACH_ENTRY(centry, &collection->collections, struct collection, entry)
debug_collection(centry);
TRACE( ">>> END Collection\n" );
}
}
static void debug_print_report(const char* type, WINE_HIDP_PREPARSED_DATA *data,
WINE_HID_REPORT *report)
{
WINE_HID_ELEMENT *elems = HID_ELEMS(data);
unsigned int i;
TRACE("START Report %i <<< %s report : bitSize: %i elementCount: %i\n",
report->reportID,
type,
report->bitSize,
report->elementCount);
for (i = 0; i < report->elementCount; i++)
{
WINE_HID_ELEMENT *elem = elems + report->elementIdx + i;
TRACE("%s: %s, StartBit %d, BitCount %d\n", type, debugstr_hidp_value_caps(&elem->caps), elem->valueStartBit, elem->bitCount);
}
TRACE(">>> END Report %i\n",report->reportID);
}
static void debug_print_preparsed(WINE_HIDP_PREPARSED_DATA *data)
{
unsigned int i, end;
if (TRACE_ON(hid))
{
TRACE("START PREPARSED Data <<< dwSize: %i Usage: %i, UsagePage: %i, "
"InputReportByteLength: %i, tOutputReportByteLength: %i, "
"FeatureReportByteLength: %i, NumberLinkCollectionNodes: %i, "
"NumberInputButtonCaps: %i, NumberInputValueCaps: %i, "
"NumberInputDataIndices: %i, NumberOutputButtonCaps: %i, "
"NumberOutputValueCaps: %i, NumberOutputDataIndices: %i, "
"NumberFeatureButtonCaps: %i, NumberFeatureValueCaps: %i, "
"NumberFeatureDataIndices: %i, reportCount[HidP_Input]: %i, "
"reportCount[HidP_Output]: %i, reportCount[HidP_Feature]: %i, "
"elementOffset: %i\n",
data->dwSize,
data->caps.Usage,
data->caps.UsagePage,
data->caps.InputReportByteLength,
data->caps.OutputReportByteLength,
data->caps.FeatureReportByteLength,
data->caps.NumberLinkCollectionNodes,
data->caps.NumberInputButtonCaps,
data->caps.NumberInputValueCaps,
data->caps.NumberInputDataIndices,
data->caps.NumberOutputButtonCaps,
data->caps.NumberOutputValueCaps,
data->caps.NumberOutputDataIndices,
data->caps.NumberFeatureButtonCaps,
data->caps.NumberFeatureValueCaps,
data->caps.NumberFeatureDataIndices,
data->reportCount[HidP_Input],
data->reportCount[HidP_Output],
data->reportCount[HidP_Feature],
data->elementOffset);
end = data->reportCount[HidP_Input];
for (i = 0; i < end; i++)
{
debug_print_report("INPUT", data, &data->reports[i]);
}
end += data->reportCount[HidP_Output];
for (; i < end; i++)
{
debug_print_report("OUTPUT", data, &data->reports[i]);
}
end += data->reportCount[HidP_Feature];
for (; i < end; i++)
{
debug_print_report("FEATURE", data, &data->reports[i]);
}
TRACE(">>> END Preparsed Data\n");
}
}
struct hid_parser_state
{
HIDP_CAPS caps;
USAGE usages_page[256];
USAGE usages_min[256];
USAGE usages_max[256];
DWORD usages_size;
struct hid_value_caps items;
struct hid_value_caps *stack;
DWORD stack_size;
DWORD global_idx;
DWORD collection_idx;
struct hid_value_caps *collections;
DWORD collections_size;
struct hid_value_caps *values[3];
ULONG values_size[3];
ULONG bit_size[3][256];
USHORT *byte_size[3]; /* pointers to caps */
USHORT *value_idx[3]; /* pointers to caps */
USHORT *data_idx[3]; /* pointers to caps */
};
static BOOL array_reserve( struct hid_value_caps **array, DWORD *array_size, DWORD index )
{
if (index < *array_size) return TRUE;
if ((*array_size = *array_size ? (*array_size * 3 / 2) : 32) <= index) return FALSE;
if (!(*array = realloc( *array, *array_size * sizeof(**array) ))) return FALSE;
return TRUE;
}
static void copy_global_items( struct hid_value_caps *dst, const struct hid_value_caps *src )
{
dst->usage_page = src->usage_page;
dst->logical_min = src->logical_min;
dst->logical_max = src->logical_max;
dst->physical_min = src->physical_min;
dst->physical_max = src->physical_max;
dst->units_exp = src->units_exp;
dst->units = src->units;
dst->bit_size = src->bit_size;
dst->report_id = src->report_id;
dst->report_count = src->report_count;
}
static void copy_collection_items( struct hid_value_caps *dst, const struct hid_value_caps *src )
{
dst->link_collection = src->link_collection;
dst->link_usage_page = src->link_usage_page;
dst->link_usage = src->link_usage;
}
static void reset_local_items( struct hid_parser_state *state )
{
struct hid_value_caps tmp;
copy_global_items( &tmp, &state->items );
copy_collection_items( &tmp, &state->items );
memset( &state->items, 0, sizeof(state->items) );
copy_global_items( &state->items, &tmp );
copy_collection_items( &state->items, &tmp );
memset( &state->usages_page, 0, sizeof(state->usages_page) );
memset( &state->usages_min, 0, sizeof(state->usages_min) );
memset( &state->usages_max, 0, sizeof(state->usages_max) );
state->usages_size = 0;
}
static BOOL parse_global_push( struct hid_parser_state *state )
{
if (!array_reserve( &state->stack, &state->stack_size, state->global_idx ))
{
ERR( "HID parser stack overflow!\n" );
return FALSE;
}
copy_global_items( state->stack + state->global_idx, &state->items );
state->global_idx++;
return TRUE;
}
static BOOL parse_global_pop( struct hid_parser_state *state )
{
if (!state->global_idx)
{
ERR( "HID parser global stack underflow!\n" );
return FALSE;
}
state->global_idx--;
copy_global_items( &state->items, state->stack + state->global_idx );
return TRUE;
}
static BOOL parse_local_usage( struct hid_parser_state *state, USAGE usage_page, USAGE usage )
{
if (!usage_page) usage_page = state->items.usage_page;
if (state->items.is_range) state->usages_size = 0;
state->usages_page[state->usages_size] = usage_page;
state->usages_min[state->usages_size] = usage;
state->usages_max[state->usages_size] = usage;
state->items.usage_min = usage;
state->items.usage_max = usage;
state->items.is_range = FALSE;
if (state->usages_size++ == 255) ERR( "HID parser usages stack overflow!\n" );
return state->usages_size <= 255;
}
static void parse_local_usage_min( struct hid_parser_state *state, USAGE usage_page, USAGE usage )
{
if (!usage_page) usage_page = state->items.usage_page;
if (!state->items.is_range) state->usages_max[0] = 0;
state->usages_page[0] = usage_page;
state->usages_min[0] = usage;
state->items.usage_min = usage;
state->items.is_range = TRUE;
state->usages_size = 1;
}
static void parse_local_usage_max( struct hid_parser_state *state, USAGE usage_page, USAGE usage )
{
if (!usage_page) usage_page = state->items.usage_page;
if (!state->items.is_range) state->usages_min[0] = 0;
state->usages_page[0] = usage_page;
state->usages_max[0] = usage;
state->items.usage_max = usage;
state->items.is_range = TRUE;
state->usages_size = 1;
}
static BOOL parse_new_collection( struct hid_parser_state *state )
{
if (!array_reserve( &state->stack, &state->stack_size, state->collection_idx ))
{
ERR( "HID parser stack overflow!\n" );
return FALSE;
}
if (!array_reserve( &state->collections, &state->collections_size, state->caps.NumberLinkCollectionNodes ))
{
ERR( "HID parser collections overflow!\n" );
return FALSE;
}
copy_collection_items( state->stack + state->collection_idx, &state->items );
state->collection_idx++;
state->items.usage_min = state->usages_min[0];
state->items.usage_max = state->usages_max[0];
state->collections[state->caps.NumberLinkCollectionNodes] = state->items;
state->items.link_collection = state->caps.NumberLinkCollectionNodes;
state->items.link_usage_page = state->items.usage_page;
state->items.link_usage = state->items.usage_min;
if (!state->caps.NumberLinkCollectionNodes)
{
state->caps.UsagePage = state->items.usage_page;
state->caps.Usage = state->items.usage_min;
}
state->caps.NumberLinkCollectionNodes++;
reset_local_items( state );
return TRUE;
}
static BOOL parse_end_collection( struct hid_parser_state *state )
{
if (!state->collection_idx)
{
ERR( "HID parser collection stack underflow!\n" );
return FALSE;
}
state->collection_idx--;
copy_collection_items( &state->items, state->stack + state->collection_idx );
reset_local_items( state );
return TRUE;
}
static BOOL parse_new_value_caps( struct hid_parser_state *state, HIDP_REPORT_TYPE type, struct collection *collection )
{
struct hid_value_caps *value;
USAGE usage_page = state->items.usage_page;
DWORD usages_size = max(1, state->usages_size);
USHORT *byte_size = state->byte_size[type];
USHORT *value_idx = state->value_idx[type];
USHORT *data_idx = state->data_idx[type];
ULONG *bit_size = &state->bit_size[type][state->items.report_id];
struct feature *feature;
int j;
for (j = 0; j < state->items.report_count; j++)
{
if (!(feature = calloc( 1, sizeof(*feature) ))) return -1;
list_add_tail( &collection->features, &feature->entry );
feature->type = type;
feature->isData = ((state->items.bit_field & INPUT_DATA_CONST) == 0);
copy_hidp_value_caps( &feature->caps, &state->items );
if (j < state->usages_size) feature->caps.NotRange.Usage = state->usages_min[j];
feature->caps.ReportCount = 1;
if (j + 1 >= state->usages_size)
{
feature->caps.ReportCount += state->items.report_count - (j + 1);
break;
}
}
if (!*bit_size) *bit_size = 8;
*bit_size += state->items.bit_size * state->items.report_count;
*byte_size = max( *byte_size, (*bit_size + 7) / 8 );
state->items.start_bit = *bit_size;
if (!state->items.report_count)
{
reset_local_items( state );
return TRUE;
}
if (!array_reserve( &state->values[type], &state->values_size[type], *value_idx + usages_size ))
{
ERR( "HID parser values overflow!\n" );
return FALSE;
}
value = state->values[type] + *value_idx;
state->items.report_count -= usages_size - 1;
while (usages_size--)
{
state->items.start_bit -= state->items.report_count * state->items.bit_size;
state->items.usage_page = state->usages_page[usages_size];
state->items.usage_min = state->usages_min[usages_size];
state->items.usage_max = state->usages_max[usages_size];
state->items.data_index_min = *data_idx;
state->items.data_index_max = *data_idx + state->items.usage_max - state->items.usage_min;
if (state->items.usage_max || state->items.usage_min) *data_idx = state->items.data_index_max + 1;
*value++ = state->items;
*value_idx += 1;
state->items.report_count = 1;
}
state->items.usage_page = usage_page;
reset_local_items( state );
return TRUE;
}
static void init_parser_state( struct hid_parser_state *state )
{
memset( state, 0, sizeof(*state) );
state->byte_size[HidP_Input] = &state->caps.InputReportByteLength;
state->byte_size[HidP_Output] = &state->caps.OutputReportByteLength;
state->byte_size[HidP_Feature] = &state->caps.FeatureReportByteLength;
state->value_idx[HidP_Input] = &state->caps.NumberInputValueCaps;
state->value_idx[HidP_Output] = &state->caps.NumberOutputValueCaps;
state->value_idx[HidP_Feature] = &state->caps.NumberFeatureValueCaps;
state->data_idx[HidP_Input] = &state->caps.NumberInputDataIndices;
state->data_idx[HidP_Output] = &state->caps.NumberOutputDataIndices;
state->data_idx[HidP_Feature] = &state->caps.NumberFeatureDataIndices;
}
static void free_parser_state( struct hid_parser_state *state )
{
if (state->global_idx) ERR( "%u unpopped device caps on the stack\n", state->global_idx );
if (state->collection_idx) ERR( "%u unpopped device collection on the stack\n", state->collection_idx );
free( state->stack );
free( state->collections );
free( state->values[HidP_Input] );
free( state->values[HidP_Output] );
free( state->values[HidP_Feature] );
free( state );
}
static void parse_collection(unsigned int bSize, int itemVal,
struct collection *collection)
{
if (bSize)
{
collection->type = itemVal;
if (itemVal >= 0x07 && itemVal <= 0x7F) {
ERR(" (Reserved 0x%x )\n", itemVal);
}
else if (itemVal >= 0x80 && itemVal <= 0xFF) {
ERR(" (Vendor Defined 0x%x )\n", itemVal);
}
}
}
static int parse_descriptor( BYTE *descriptor, unsigned int index, unsigned int length,
struct collection *collection, struct hid_parser_state *state )
{
int i;
UINT32 value;
INT32 signed_value;
for (i = index; i < length;)
{
BYTE item = descriptor[i++];
int size = item & 0x03;
if (size == 3) size = 4;
if (length - i < size)
{
ERR("Need %d bytes to read item value\n", size);
return -1;
}
if (size == 0) signed_value = value = 0;
else if (size == 1) signed_value = (INT8)(value = *(UINT8 *)(descriptor + i));
else if (size == 2) signed_value = (INT16)(value = *(UINT16 *)(descriptor + i));
else if (size == 4) signed_value = (INT32)(value = *(UINT32 *)(descriptor + i));
else
{
ERR("Unexpected item value size %d.\n", size);
return -1;
}
i += size;
state->items.bit_field = value;
#define SHORT_ITEM(tag,type) (((tag)<<4)|((type)<<2))
switch (item & SHORT_ITEM(0xf,0x3))
{
case SHORT_ITEM(TAG_MAIN_INPUT, TAG_TYPE_MAIN):
if (!parse_new_value_caps( state, HidP_Input, collection )) return -1;
break;
case SHORT_ITEM(TAG_MAIN_OUTPUT, TAG_TYPE_MAIN):
if (!parse_new_value_caps( state, HidP_Output, collection )) return -1;
break;
case SHORT_ITEM(TAG_MAIN_FEATURE, TAG_TYPE_MAIN):
if (!parse_new_value_caps( state, HidP_Feature, collection )) return -1;
break;
case SHORT_ITEM(TAG_MAIN_COLLECTION, TAG_TYPE_MAIN):
{
struct collection *subcollection;
if (!(subcollection = calloc(1, sizeof(struct collection)))) return -1;
list_add_tail(&collection->collections, &subcollection->entry);
subcollection->parent = collection;
/* Only set our collection once...
We do not properly handle composite devices yet. */
list_init(&subcollection->features);
list_init(&subcollection->collections);
parse_collection(size, value, subcollection);
if (!parse_new_collection( state )) return -1;
if ((i = parse_descriptor( descriptor, i, length, subcollection, state )) < 0) return i;
continue;
}
case SHORT_ITEM(TAG_MAIN_END_COLLECTION, TAG_TYPE_MAIN):
if (!parse_end_collection( state )) return -1;
return i;
case SHORT_ITEM(TAG_GLOBAL_USAGE_PAGE, TAG_TYPE_GLOBAL):
state->items.usage_page = value;
break;
case SHORT_ITEM(TAG_GLOBAL_LOGICAL_MINIMUM, TAG_TYPE_GLOBAL):
state->items.logical_min = signed_value;
break;
case SHORT_ITEM(TAG_GLOBAL_LOGICAL_MAXIMUM, TAG_TYPE_GLOBAL):
state->items.logical_max = signed_value;
break;
case SHORT_ITEM(TAG_GLOBAL_PHYSICAL_MINIMUM, TAG_TYPE_GLOBAL):
state->items.physical_min = signed_value;
break;
case SHORT_ITEM(TAG_GLOBAL_PHYSICAL_MAXIMUM, TAG_TYPE_GLOBAL):
state->items.physical_max = signed_value;
break;
case SHORT_ITEM(TAG_GLOBAL_UNIT_EXPONENT, TAG_TYPE_GLOBAL):
state->items.units_exp = signed_value;
break;
case SHORT_ITEM(TAG_GLOBAL_UNIT, TAG_TYPE_GLOBAL):
state->items.units = signed_value;
break;
case SHORT_ITEM(TAG_GLOBAL_REPORT_SIZE, TAG_TYPE_GLOBAL):
state->items.bit_size = value;
break;
case SHORT_ITEM(TAG_GLOBAL_REPORT_ID, TAG_TYPE_GLOBAL):
state->items.report_id = value;
break;
case SHORT_ITEM(TAG_GLOBAL_REPORT_COUNT, TAG_TYPE_GLOBAL):
state->items.report_count = value;
break;
case SHORT_ITEM(TAG_GLOBAL_PUSH, TAG_TYPE_GLOBAL):
if (!parse_global_push( state )) return -1;
break;
case SHORT_ITEM(TAG_GLOBAL_POP, TAG_TYPE_GLOBAL):
if (!parse_global_pop( state )) return -1;
break;
case SHORT_ITEM(TAG_LOCAL_USAGE, TAG_TYPE_LOCAL):
if (!parse_local_usage( state, value >> 16, value & 0xffff )) return -1;
break;
case SHORT_ITEM(TAG_LOCAL_USAGE_MINIMUM, TAG_TYPE_LOCAL):
parse_local_usage_min( state, value >> 16, value & 0xffff );
break;
case SHORT_ITEM(TAG_LOCAL_USAGE_MAXIMUM, TAG_TYPE_LOCAL):
parse_local_usage_max( state, value >> 16, value & 0xffff );
break;
case SHORT_ITEM(TAG_LOCAL_DESIGNATOR_INDEX, TAG_TYPE_LOCAL):
state->items.designator_min = state->items.designator_max = value;
state->items.is_designator_range = FALSE;
break;
case SHORT_ITEM(TAG_LOCAL_DESIGNATOR_MINIMUM, TAG_TYPE_LOCAL):
state->items.designator_min = value;
state->items.is_designator_range = TRUE;
break;
case SHORT_ITEM(TAG_LOCAL_DESIGNATOR_MAXIMUM, TAG_TYPE_LOCAL):
state->items.designator_max = value;
state->items.is_designator_range = TRUE;
break;
case SHORT_ITEM(TAG_LOCAL_STRING_INDEX, TAG_TYPE_LOCAL):
state->items.string_min = state->items.string_max = value;
state->items.is_string_range = FALSE;
break;
case SHORT_ITEM(TAG_LOCAL_STRING_MINIMUM, TAG_TYPE_LOCAL):
state->items.string_min = value;
state->items.is_string_range = TRUE;
break;
case SHORT_ITEM(TAG_LOCAL_STRING_MAXIMUM, TAG_TYPE_LOCAL):
state->items.string_max = value;
state->items.is_string_range = TRUE;
break;
case SHORT_ITEM(TAG_LOCAL_DELIMITER, TAG_TYPE_LOCAL):
FIXME("delimiter %d not implemented!\n", value);
return -1;
default:
FIXME("item type %x not implemented!\n", item);
return -1;
}
#undef SHORT_ITEM
}
return i;
}
static void build_elements(WINE_HID_REPORT *wine_report, WINE_HID_ELEMENT *elems,
struct feature* feature, USHORT *data_index)
{
WINE_HID_ELEMENT *wine_element = elems + wine_report->elementIdx + wine_report->elementCount;
ULONG index_count;
if (!feature->isData)
{
wine_report->bitSize += feature->caps.BitSize * feature->caps.ReportCount;
return;
}
wine_element->valueStartBit = wine_report->bitSize;
wine_element->bitCount = (feature->caps.BitSize * feature->caps.ReportCount);
wine_report->bitSize += wine_element->bitCount;
wine_element->caps = feature->caps;
if (wine_element->caps.IsRange)
{
if (wine_element->caps.BitSize == 1) index_count = wine_element->bitCount - 1;
else index_count = wine_element->caps.Range.UsageMax - wine_element->caps.Range.UsageMin;
wine_element->caps.Range.DataIndexMin = *data_index;
wine_element->caps.Range.DataIndexMax = *data_index + index_count;
*data_index = *data_index + index_count + 1;
}
else
{
wine_element->caps.NotRange.DataIndex = *data_index;
wine_element->caps.NotRange.Reserved4 = *data_index;
*data_index = *data_index + 1;
}
wine_report->elementCount++;
}
static void count_elements(struct feature* feature, USHORT *buttons, USHORT *values)
{
if (!feature->isData)
return;
if (feature->caps.BitSize == 1)
(*buttons)++;
else
(*values)++;
}
struct preparse_ctx
{
int report_count[3];
int elem_count;
int report_elem_count[3][256];
int elem_alloc;
BOOL report_created[3][256];
};
static void create_preparse_ctx(const struct collection *base, struct preparse_ctx *ctx)
{
struct feature *f;
struct collection *c;
LIST_FOR_EACH_ENTRY(f, &base->features, struct feature, entry)
{
ctx->elem_count++;
ctx->report_elem_count[f->type][f->caps.ReportID]++;
if (ctx->report_elem_count[f->type][f->caps.ReportID] != 1)
continue;
ctx->report_count[f->type]++;
}
LIST_FOR_EACH_ENTRY(c, &base->collections, struct collection, entry)
create_preparse_ctx(c, ctx);
}
static void preparse_collection(const struct collection *root, const struct collection *base,
WINE_HIDP_PREPARSED_DATA *data, struct preparse_ctx *ctx)
{
WINE_HID_ELEMENT *elem = HID_ELEMS(data);
struct feature *f;
struct collection *c;
LIST_FOR_EACH_ENTRY(f, &base->features, struct feature, entry)
{
WINE_HID_REPORT *report;
if (!ctx->report_created[f->type][f->caps.ReportID])
{
ctx->report_created[f->type][f->caps.ReportID] = TRUE;
data->reportIdx[f->type][f->caps.ReportID] = data->reportCount[f->type]++;
if (f->type > 0) data->reportIdx[f->type][f->caps.ReportID] += ctx->report_count[0];
if (f->type > 1) data->reportIdx[f->type][f->caps.ReportID] += ctx->report_count[1];
report = &data->reports[data->reportIdx[f->type][f->caps.ReportID]];
report->reportID = f->caps.ReportID;
/* Room for the reportID */
report->bitSize = 8;
report->elementIdx = ctx->elem_alloc;
ctx->elem_alloc += ctx->report_elem_count[f->type][f->caps.ReportID];
}
report = &data->reports[data->reportIdx[f->type][f->caps.ReportID]];
switch (f->type)
{
case HidP_Input:
build_elements(report, elem, f, &data->caps.NumberInputDataIndices);
count_elements(f, &data->caps.NumberInputButtonCaps, &data->caps.NumberInputValueCaps);
break;
case HidP_Output:
build_elements(report, elem, f, &data->caps.NumberOutputDataIndices);
count_elements(f, &data->caps.NumberOutputButtonCaps, &data->caps.NumberOutputValueCaps);
break;
case HidP_Feature:
build_elements(report, elem, f, &data->caps.NumberFeatureDataIndices);
count_elements(f, &data->caps.NumberFeatureButtonCaps, &data->caps.NumberFeatureValueCaps);
break;
}
}
LIST_FOR_EACH_ENTRY(c, &base->collections, struct collection, entry)
preparse_collection(root, c, data, ctx);
}
static WINE_HIDP_PREPARSED_DATA *build_preparsed_data( struct collection *base_collection,
struct hid_parser_state *state )
{
WINE_HIDP_PREPARSED_DATA *data;
struct hid_value_caps *caps;
unsigned int report_count;
unsigned int size;
DWORD i, button, filler, caps_len, caps_off;
struct preparse_ctx ctx;
unsigned int element_off;
memset(&ctx, 0, sizeof(ctx));
create_preparse_ctx(base_collection, &ctx);
report_count = ctx.report_count[HidP_Input] + ctx.report_count[HidP_Output]
+ ctx.report_count[HidP_Feature];
element_off = FIELD_OFFSET(WINE_HIDP_PREPARSED_DATA, reports[report_count]);
size = element_off + (ctx.elem_count * sizeof(WINE_HID_ELEMENT));
caps_len = state->caps.NumberInputValueCaps + state->caps.NumberOutputValueCaps +
state->caps.NumberFeatureValueCaps + state->caps.NumberLinkCollectionNodes;
caps_off = size;
size += caps_len * sizeof(*caps);
if (!(data = calloc(1, size))) return NULL;
data->magic = HID_MAGIC;
data->dwSize = size;
data->caps = state->caps;
data->new_caps = state->caps;
data->elementOffset = element_off;
data->value_caps_offset = caps_off;
data->value_caps_count[HidP_Input] = state->caps.NumberInputValueCaps;
data->value_caps_count[HidP_Output] = state->caps.NumberOutputValueCaps;
data->value_caps_count[HidP_Feature] = state->caps.NumberFeatureValueCaps;
data->caps.NumberInputValueCaps = data->caps.NumberInputButtonCaps = data->caps.NumberInputDataIndices = 0;
data->caps.NumberOutputValueCaps = data->caps.NumberOutputButtonCaps = data->caps.NumberOutputDataIndices = 0;
data->caps.NumberFeatureValueCaps = data->caps.NumberFeatureButtonCaps = data->caps.NumberFeatureDataIndices = 0;
preparse_collection(base_collection, base_collection, data, &ctx);
/* fixup value vs button vs filler counts */
caps = HID_INPUT_VALUE_CAPS( data );
memcpy( caps, state->values[0], data->new_caps.NumberInputValueCaps * sizeof(*caps) );
for (i = 0, button = 0, filler = 0; i < data->new_caps.NumberInputValueCaps; ++i)
{
if (!caps[i].usage_min && !caps[i].usage_max) filler++;
else if (HID_VALUE_CAPS_IS_BUTTON( caps + i )) button++;
}
data->new_caps.NumberInputButtonCaps = button;
data->new_caps.NumberInputValueCaps -= filler + button;
caps = HID_OUTPUT_VALUE_CAPS( data );
memcpy( caps, state->values[1], data->new_caps.NumberOutputValueCaps * sizeof(*caps) );
for (i = 0, button = 0, filler = 0; i < data->new_caps.NumberOutputValueCaps; ++i)
{
if (!caps[i].usage_min && !caps[i].usage_max) filler++;
else if (HID_VALUE_CAPS_IS_BUTTON( caps + i )) button++;
}
caps += data->new_caps.NumberOutputValueCaps;
data->new_caps.NumberOutputButtonCaps = button;
data->new_caps.NumberOutputValueCaps -= filler + button;
caps = HID_FEATURE_VALUE_CAPS( data );
memcpy( caps, state->values[2], data->new_caps.NumberFeatureValueCaps * sizeof(*caps) );
for (i = 0, button = 0, filler = 0; i < data->new_caps.NumberFeatureValueCaps; ++i)
{
if (!caps[i].usage_min && !caps[i].usage_max) filler++;
else if (HID_VALUE_CAPS_IS_BUTTON( caps + i )) button++;
}
caps += data->new_caps.NumberFeatureValueCaps;
data->new_caps.NumberFeatureButtonCaps = button;
data->new_caps.NumberFeatureValueCaps -= filler + button;
caps = HID_COLLECTION_VALUE_CAPS( data );
memcpy( caps, state->collections, data->new_caps.NumberLinkCollectionNodes * sizeof(*caps) );
return data;
}
static void free_collection(struct collection *collection)
{
struct feature *fentry, *fnext;
struct collection *centry, *cnext;
LIST_FOR_EACH_ENTRY_SAFE(centry, cnext, &collection->collections, struct collection, entry)
{
list_remove(&centry->entry);
free_collection(centry);
}
LIST_FOR_EACH_ENTRY_SAFE(fentry, fnext, &collection->features, struct feature, entry)
{
list_remove(&fentry->entry);
free(fentry);
}
free(collection);
}
WINE_HIDP_PREPARSED_DATA* ParseDescriptor(BYTE *descriptor, unsigned int length)
{
WINE_HIDP_PREPARSED_DATA *data = NULL;
struct hid_parser_state *state;
struct collection *base;
int i;
if (TRACE_ON(hid))
{
TRACE("descriptor %p, length %u:\n", descriptor, length);
for (i = 0; i < length;)
{
TRACE("%08x ", i);
do { TRACE(" %02x", descriptor[i]); } while (++i % 16 && i < length);
TRACE("\n");
}
}
if (!(state = calloc( 1, sizeof(*state) ))) return NULL;
if (!(base = calloc( 1, sizeof(*base) )))
{
free( state );
return NULL;
}
list_init(&base->features);
list_init(&base->collections);
init_parser_state( state );
if (parse_descriptor( descriptor, 0, length, base, state ) < 0)
{
free_collection(base);
free_parser_state( state );
return NULL;
}
debug_collection(base);
if ((data = build_preparsed_data( base, state )))
debug_print_preparsed(data);
free_collection(base);
free_parser_state( state );
return data;
}