ui/events/ozone/evdev/event_device_info.cc - mojo-tools - Git at Google

 // Copyright 2013 The Chromium Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.

 #include "ui/events/ozone/evdev/event_device_info.h"

 #include <linux/input.h>

 #include "base/logging.h"
 #include "base/threading/thread_restrictions.h"

 #if !defined(EVIOCGMTSLOTS)
 #define EVIOCGMTSLOTS(len) _IOC(_IOC_READ, 'E', 0x0a, len)
 #endif

 namespace ui {

 namespace {

 // USB vendor and product strings are pragmatically limited to 126
 // characters each, so device names more than twice that should be
 // unusual.
 const size_t kMaximumDeviceNameLength = 256;

 bool GetEventBits(int fd, unsigned int type, void* buf, unsigned int size) {
   if (ioctl(fd, EVIOCGBIT(type, size), buf) < 0) {
     PLOG(ERROR) << "EVIOCGBIT(" << type << ", " << size << ") on fd " << fd;
     return false;
   }

   return true;
 }

 bool GetPropBits(int fd, void* buf, unsigned int size) {
   if (ioctl(fd, EVIOCGPROP(size), buf) < 0) {
     PLOG(ERROR) << "EVIOCGPROP(" << size << ") on fd " << fd;
     return false;
   }

   return true;
 }

 bool GetAbsInfo(int fd, int code, struct input_absinfo* absinfo) {
   if (ioctl(fd, EVIOCGABS(code), absinfo)) {
     PLOG(ERROR) << "EVIOCGABS(" << code << ") on fd " << fd;
     return false;
   }
   return true;
 }

 bool GetDeviceName(int fd, std::string* name) {
   char device_name[kMaximumDeviceNameLength];
   if (ioctl(fd, EVIOCGNAME(kMaximumDeviceNameLength - 1), &device_name) < 0) {
     PLOG(INFO) << "Can't read device name on fd " << fd;
     return false;
   }
   *name = device_name;
   return true;
 }

 bool GetDeviceIdentifiers(int fd, uint16_t* vendor, uint16_t* product) {
   struct input_id evdev_id;
   if (ioctl(fd, EVIOCGID, &evdev_id) < 0) {
     PLOG(INFO) << "Can't read device name on fd " << fd;
     return false;
   }
   *vendor = evdev_id.vendor;
   *product = evdev_id.product;
   return true;
 }

 // |request| needs to be the equivalent to:
 // struct input_mt_request_layout {
 //   uint32_t code;
 //   int32_t values[num_slots];
 // };
 //
 // |size| is num_slots + 1 (for code).
 bool GetSlotValues(int fd, int32_t* request, unsigned int size) {
   size_t data_size = size * sizeof(*request);

   if (ioctl(fd, EVIOCGMTSLOTS(data_size), request) < 0) {
     PLOG(ERROR) << "EVIOCGMTSLOTS(" << request[0] << ") on fd " << fd;
     return false;
   }

   return true;
 }

 void AssignBitset(const unsigned long* src,
                   size_t src_len,
                   unsigned long* dst,
                   size_t dst_len) {
   memcpy(dst, src, std::min(src_len, dst_len) * sizeof(unsigned long));
   if (src_len < dst_len)
     memset(&dst[src_len], 0, (dst_len - src_len) * sizeof(unsigned long));
 }

 }  // namespace

 EventDeviceInfo::EventDeviceInfo() {
   memset(ev_bits_, 0, sizeof(ev_bits_));
   memset(key_bits_, 0, sizeof(key_bits_));
   memset(rel_bits_, 0, sizeof(rel_bits_));
   memset(abs_bits_, 0, sizeof(abs_bits_));
   memset(msc_bits_, 0, sizeof(msc_bits_));
   memset(sw_bits_, 0, sizeof(sw_bits_));
   memset(led_bits_, 0, sizeof(led_bits_));
   memset(prop_bits_, 0, sizeof(prop_bits_));
   memset(abs_info_, 0, sizeof(abs_info_));
 }

 EventDeviceInfo::~EventDeviceInfo() {}

 bool EventDeviceInfo::Initialize(int fd) {
   if (!GetEventBits(fd, 0, ev_bits_, sizeof(ev_bits_)))
     return false;

   if (!GetEventBits(fd, EV_KEY, key_bits_, sizeof(key_bits_)))
     return false;

   if (!GetEventBits(fd, EV_REL, rel_bits_, sizeof(rel_bits_)))
     return false;

   if (!GetEventBits(fd, EV_ABS, abs_bits_, sizeof(abs_bits_)))
     return false;

   if (!GetEventBits(fd, EV_MSC, msc_bits_, sizeof(msc_bits_)))
     return false;

   if (!GetEventBits(fd, EV_SW, sw_bits_, sizeof(sw_bits_)))
     return false;

   if (!GetEventBits(fd, EV_LED, led_bits_, sizeof(led_bits_)))
     return false;

   if (!GetPropBits(fd, prop_bits_, sizeof(prop_bits_)))
     return false;

   for (unsigned int i = 0; i < ABS_CNT; ++i)
     if (HasAbsEvent(i))
       if (!GetAbsInfo(fd, i, &abs_info_[i]))
         return false;

   int max_num_slots = GetAbsMtSlotCount();

   // |request| is MT code + slots.
   int32_t request[max_num_slots + 1];
   int32_t* request_code = &request[0];
   int32_t* request_slots = &request[1];
   for (unsigned int i = EVDEV_ABS_MT_FIRST; i <= EVDEV_ABS_MT_LAST; ++i) {
     if (!HasAbsEvent(i))
       continue;

     memset(request, 0, sizeof(request));
     *request_code = i;
     if (!GetSlotValues(fd, request, max_num_slots + 1))
       LOG(WARNING) << "Failed to get multitouch values for code " << i;

     std::vector<int32_t>* slots = &slot_values_[i - EVDEV_ABS_MT_FIRST];
     slots->assign(request_slots, request_slots + max_num_slots);
   }

   if (!GetDeviceName(fd, &name_))
     return false;

   if (!GetDeviceIdentifiers(fd, &vendor_id_, &product_id_))
     return false;

   return true;
 }

 void EventDeviceInfo::SetEventTypes(const unsigned long* ev_bits, size_t len) {
   AssignBitset(ev_bits, len, ev_bits_, arraysize(ev_bits_));
 }

 void EventDeviceInfo::SetKeyEvents(const unsigned long* key_bits, size_t len) {
   AssignBitset(key_bits, len, key_bits_, arraysize(key_bits_));
 }

 void EventDeviceInfo::SetRelEvents(const unsigned long* rel_bits, size_t len) {
   AssignBitset(rel_bits, len, rel_bits_, arraysize(rel_bits_));
 }

 void EventDeviceInfo::SetAbsEvents(const unsigned long* abs_bits, size_t len) {
   AssignBitset(abs_bits, len, abs_bits_, arraysize(abs_bits_));
 }

 void EventDeviceInfo::SetMscEvents(const unsigned long* msc_bits, size_t len) {
   AssignBitset(msc_bits, len, msc_bits_, arraysize(msc_bits_));
 }

 void EventDeviceInfo::SetSwEvents(const unsigned long* sw_bits, size_t len) {
   AssignBitset(sw_bits, len, sw_bits_, arraysize(sw_bits_));
 }

 void EventDeviceInfo::SetLedEvents(const unsigned long* led_bits, size_t len) {
   AssignBitset(led_bits, len, led_bits_, arraysize(led_bits_));
 }

 void EventDeviceInfo::SetProps(const unsigned long* prop_bits, size_t len) {
   AssignBitset(prop_bits, len, prop_bits_, arraysize(prop_bits_));
 }

 void EventDeviceInfo::SetAbsInfo(unsigned int code,
                                  const input_absinfo& abs_info) {
   if (code > ABS_MAX)
     return;

   memcpy(&abs_info_[code], &abs_info, sizeof(abs_info));
 }

 void EventDeviceInfo::SetAbsMtSlots(unsigned int code,
                                     const std::vector<int32_t>& values) {
   DCHECK_EQ(GetAbsMtSlotCount(), values.size());
   int index = code - EVDEV_ABS_MT_FIRST;
   if (index < 0 || index >= EVDEV_ABS_MT_COUNT)
     return;
   slot_values_[index] = values;
 }

 void EventDeviceInfo::SetAbsMtSlot(unsigned int code,
                                    unsigned int slot,
                                    uint32_t value) {
   int index = code - EVDEV_ABS_MT_FIRST;
   if (index < 0 || index >= EVDEV_ABS_MT_COUNT)
     return;
   slot_values_[index][slot] = value;
 }

 bool EventDeviceInfo::HasEventType(unsigned int type) const {
   if (type > EV_MAX)
     return false;
   return EvdevBitIsSet(ev_bits_, type);
 }

 bool EventDeviceInfo::HasKeyEvent(unsigned int code) const {
   if (code > KEY_MAX)
     return false;
   return EvdevBitIsSet(key_bits_, code);
 }

 bool EventDeviceInfo::HasRelEvent(unsigned int code) const {
   if (code > REL_MAX)
     return false;
   return EvdevBitIsSet(rel_bits_, code);
 }

 bool EventDeviceInfo::HasAbsEvent(unsigned int code) const {
   if (code > ABS_MAX)
     return false;
   return EvdevBitIsSet(abs_bits_, code);
 }

 bool EventDeviceInfo::HasMscEvent(unsigned int code) const {
   if (code > MSC_MAX)
     return false;
   return EvdevBitIsSet(msc_bits_, code);
 }

 bool EventDeviceInfo::HasSwEvent(unsigned int code) const {
   if (code > SW_MAX)
     return false;
   return EvdevBitIsSet(sw_bits_, code);
 }

 bool EventDeviceInfo::HasLedEvent(unsigned int code) const {
   if (code > LED_MAX)
     return false;
   return EvdevBitIsSet(led_bits_, code);
 }

 bool EventDeviceInfo::HasProp(unsigned int code) const {
   if (code > INPUT_PROP_MAX)
     return false;
   return EvdevBitIsSet(prop_bits_, code);
 }

 int32_t EventDeviceInfo::GetAbsMinimum(unsigned int code) const {
   return abs_info_[code].minimum;
 }

 int32_t EventDeviceInfo::GetAbsMaximum(unsigned int code) const {
   return abs_info_[code].maximum;
 }

 int32_t EventDeviceInfo::GetAbsValue(unsigned int code) const {
   return abs_info_[code].value;
 }

 uint32_t EventDeviceInfo::GetAbsMtSlotCount() const {
   if (!HasAbsEvent(ABS_MT_SLOT))
     return 0;
   return GetAbsMaximum(ABS_MT_SLOT) + 1;
 }

 int32_t EventDeviceInfo::GetAbsMtSlotValue(unsigned int code,
                                            unsigned int slot) const {
   unsigned int index = code - EVDEV_ABS_MT_FIRST;
   DCHECK(index < EVDEV_ABS_MT_COUNT);
   return slot_values_[index][slot];
 }

 int32_t EventDeviceInfo::GetAbsMtSlotValueWithDefault(
     unsigned int code,
     unsigned int slot,
     int32_t default_value) const {
   if (!HasAbsEvent(code))
     return default_value;
   return GetAbsMtSlotValue(code, slot);
 }

 bool EventDeviceInfo::HasAbsXY() const {
   return HasAbsEvent(ABS_X) && HasAbsEvent(ABS_Y);
 }

 bool EventDeviceInfo::HasMTAbsXY() const {
   return HasAbsEvent(ABS_MT_POSITION_X) && HasAbsEvent(ABS_MT_POSITION_Y);
 }

 bool EventDeviceInfo::HasRelXY() const {
   return HasRelEvent(REL_X) && HasRelEvent(REL_Y);
 }

 bool EventDeviceInfo::HasMultitouch() const {
   return HasAbsEvent(ABS_MT_SLOT);
 }

 bool EventDeviceInfo::HasDirect() const {
   bool has_direct = HasProp(INPUT_PROP_DIRECT);
   bool has_pointer = HasProp(INPUT_PROP_POINTER);
   if (has_direct || has_pointer)
     return has_direct;

   switch (ProbeLegacyAbsoluteDevice()) {
     case LegacyAbsoluteDeviceType::LADT_TOUCHSCREEN:
       return true;

     case LegacyAbsoluteDeviceType::LADT_TABLET:
     case LegacyAbsoluteDeviceType::LADT_TOUCHPAD:
     case LegacyAbsoluteDeviceType::LADT_NONE:
       return false;
   }

   NOTREACHED();
   return false;
 }

 bool EventDeviceInfo::HasPointer() const {
   bool has_direct = HasProp(INPUT_PROP_DIRECT);
   bool has_pointer = HasProp(INPUT_PROP_POINTER);
   if (has_direct || has_pointer)
     return has_pointer;

   switch (ProbeLegacyAbsoluteDevice()) {
     case LegacyAbsoluteDeviceType::LADT_TOUCHPAD:
     case LegacyAbsoluteDeviceType::LADT_TABLET:
       return true;

     case LegacyAbsoluteDeviceType::LADT_TOUCHSCREEN:
     case LegacyAbsoluteDeviceType::LADT_NONE:
       return false;
   }

   NOTREACHED();
   return false;
 }

 bool EventDeviceInfo::HasStylus() const {
   return HasKeyEvent(BTN_TOOL_PEN) || HasKeyEvent(BTN_STYLUS) ||
          HasKeyEvent(BTN_STYLUS2);
 }

 bool EventDeviceInfo::HasKeyboard() const {
   if (!HasEventType(EV_KEY))
     return false;

   // Check first 31 keys: If we have all of them, consider it a full
   // keyboard. This is exactly what udev does for ID_INPUT_KEYBOARD.
   for (int key = KEY_ESC; key <= KEY_D; ++key)
     if (!HasKeyEvent(key))
       return false;

   return true;
 }

 bool EventDeviceInfo::HasMouse() const {
   return HasRelXY();
 }

 bool EventDeviceInfo::HasTouchpad() const {
   return HasAbsXY() && HasPointer() && !HasStylus();
 }

 bool EventDeviceInfo::HasTablet() const {
   return HasAbsXY() && HasPointer() && HasStylus();
 }

 bool EventDeviceInfo::HasTouchscreen() const {
   return HasAbsXY() && HasDirect();
 }

 EventDeviceInfo::LegacyAbsoluteDeviceType
 EventDeviceInfo::ProbeLegacyAbsoluteDevice() const {
   if (!HasAbsXY())
     return LegacyAbsoluteDeviceType::LADT_NONE;

   if (HasStylus())
     return LegacyAbsoluteDeviceType::LADT_TABLET;

   if (HasKeyEvent(BTN_TOOL_FINGER) && HasKeyEvent(BTN_TOUCH))
     return LegacyAbsoluteDeviceType::LADT_TOUCHPAD;

   if (HasKeyEvent(BTN_TOUCH) || HasKeyEvent(BTN_LEFT))
     return LegacyAbsoluteDeviceType::LADT_TOUCHSCREEN;

   return LegacyAbsoluteDeviceType::LADT_NONE;
 }

 }  // namespace ui
	// Copyright 2013 The Chromium Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.

	#include "ui/events/ozone/evdev/event_device_info.h"

	#include <linux/input.h>

	#include "base/logging.h"
	#include "base/threading/thread_restrictions.h"

	#if !defined(EVIOCGMTSLOTS)
	#define EVIOCGMTSLOTS(len) _IOC(_IOC_READ, 'E', 0x0a, len)
	#endif

	namespace ui {

	namespace {

	// USB vendor and product strings are pragmatically limited to 126
	// characters each, so device names more than twice that should be
	// unusual.
	const size_t kMaximumDeviceNameLength = 256;

	bool GetEventBits(int fd, unsigned int type, void* buf, unsigned int size) {
	if (ioctl(fd, EVIOCGBIT(type, size), buf) < 0) {
	PLOG(ERROR) << "EVIOCGBIT(" << type << ", " << size << ") on fd " << fd;
	return false;
	}

	return true;
	}

	bool GetPropBits(int fd, void* buf, unsigned int size) {
	if (ioctl(fd, EVIOCGPROP(size), buf) < 0) {
	PLOG(ERROR) << "EVIOCGPROP(" << size << ") on fd " << fd;
	return false;
	}

	return true;
	}

	bool GetAbsInfo(int fd, int code, struct input_absinfo* absinfo) {
	if (ioctl(fd, EVIOCGABS(code), absinfo)) {
	PLOG(ERROR) << "EVIOCGABS(" << code << ") on fd " << fd;
	return false;
	}
	return true;
	}

	bool GetDeviceName(int fd, std::string* name) {
	char device_name[kMaximumDeviceNameLength];
	if (ioctl(fd, EVIOCGNAME(kMaximumDeviceNameLength - 1), &device_name) < 0) {
	PLOG(INFO) << "Can't read device name on fd " << fd;
	return false;
	}
	*name = device_name;
	return true;
	}

	bool GetDeviceIdentifiers(int fd, uint16_t* vendor, uint16_t* product) {
	struct input_id evdev_id;
	if (ioctl(fd, EVIOCGID, &evdev_id) < 0) {
	PLOG(INFO) << "Can't read device name on fd " << fd;
	return false;
	}
	*vendor = evdev_id.vendor;
	*product = evdev_id.product;
	return true;
	}

	// \|request\| needs to be the equivalent to:
	// struct input_mt_request_layout {
	// uint32_t code;
	// int32_t values[num_slots];
	// };
	//
	// \|size\| is num_slots + 1 (for code).
	bool GetSlotValues(int fd, int32_t* request, unsigned int size) {
	size_t data_size = size * sizeof(*request);

	if (ioctl(fd, EVIOCGMTSLOTS(data_size), request) < 0) {
	PLOG(ERROR) << "EVIOCGMTSLOTS(" << request[0] << ") on fd " << fd;
	return false;
	}

	return true;
	}

	void AssignBitset(const unsigned long* src,
	size_t src_len,
	unsigned long* dst,
	size_t dst_len) {
	memcpy(dst, src, std::min(src_len, dst_len) * sizeof(unsigned long));
	if (src_len < dst_len)
	memset(&dst[src_len], 0, (dst_len - src_len) * sizeof(unsigned long));
	}

	} // namespace

	EventDeviceInfo::EventDeviceInfo() {
	memset(ev_bits_, 0, sizeof(ev_bits_));
	memset(key_bits_, 0, sizeof(key_bits_));
	memset(rel_bits_, 0, sizeof(rel_bits_));
	memset(abs_bits_, 0, sizeof(abs_bits_));
	memset(msc_bits_, 0, sizeof(msc_bits_));
	memset(sw_bits_, 0, sizeof(sw_bits_));
	memset(led_bits_, 0, sizeof(led_bits_));
	memset(prop_bits_, 0, sizeof(prop_bits_));
	memset(abs_info_, 0, sizeof(abs_info_));
	}

	EventDeviceInfo::~EventDeviceInfo() {}

	bool EventDeviceInfo::Initialize(int fd) {
	if (!GetEventBits(fd, 0, ev_bits_, sizeof(ev_bits_)))
	return false;

	if (!GetEventBits(fd, EV_KEY, key_bits_, sizeof(key_bits_)))
	return false;

	if (!GetEventBits(fd, EV_REL, rel_bits_, sizeof(rel_bits_)))
	return false;

	if (!GetEventBits(fd, EV_ABS, abs_bits_, sizeof(abs_bits_)))
	return false;

	if (!GetEventBits(fd, EV_MSC, msc_bits_, sizeof(msc_bits_)))
	return false;

	if (!GetEventBits(fd, EV_SW, sw_bits_, sizeof(sw_bits_)))
	return false;

	if (!GetEventBits(fd, EV_LED, led_bits_, sizeof(led_bits_)))
	return false;

	if (!GetPropBits(fd, prop_bits_, sizeof(prop_bits_)))
	return false;

	for (unsigned int i = 0; i < ABS_CNT; ++i)
	if (HasAbsEvent(i))
	if (!GetAbsInfo(fd, i, &abs_info_[i]))
	return false;

	int max_num_slots = GetAbsMtSlotCount();

	// \|request\| is MT code + slots.
	int32_t request[max_num_slots + 1];
	int32_t* request_code = &request[0];
	int32_t* request_slots = &request[1];
	for (unsigned int i = EVDEV_ABS_MT_FIRST; i <= EVDEV_ABS_MT_LAST; ++i) {
	if (!HasAbsEvent(i))
	continue;

	memset(request, 0, sizeof(request));
	*request_code = i;
	if (!GetSlotValues(fd, request, max_num_slots + 1))
	LOG(WARNING) << "Failed to get multitouch values for code " << i;

	std::vector<int32_t>* slots = &slot_values_[i - EVDEV_ABS_MT_FIRST];
	slots->assign(request_slots, request_slots + max_num_slots);
	}

	if (!GetDeviceName(fd, &name_))
	return false;

	if (!GetDeviceIdentifiers(fd, &vendor_id_, &product_id_))
	return false;

	return true;
	}

	void EventDeviceInfo::SetEventTypes(const unsigned long* ev_bits, size_t len) {
	AssignBitset(ev_bits, len, ev_bits_, arraysize(ev_bits_));
	}

	void EventDeviceInfo::SetKeyEvents(const unsigned long* key_bits, size_t len) {
	AssignBitset(key_bits, len, key_bits_, arraysize(key_bits_));
	}

	void EventDeviceInfo::SetRelEvents(const unsigned long* rel_bits, size_t len) {
	AssignBitset(rel_bits, len, rel_bits_, arraysize(rel_bits_));
	}

	void EventDeviceInfo::SetAbsEvents(const unsigned long* abs_bits, size_t len) {
	AssignBitset(abs_bits, len, abs_bits_, arraysize(abs_bits_));
	}

	void EventDeviceInfo::SetMscEvents(const unsigned long* msc_bits, size_t len) {
	AssignBitset(msc_bits, len, msc_bits_, arraysize(msc_bits_));
	}

	void EventDeviceInfo::SetSwEvents(const unsigned long* sw_bits, size_t len) {
	AssignBitset(sw_bits, len, sw_bits_, arraysize(sw_bits_));
	}

	void EventDeviceInfo::SetLedEvents(const unsigned long* led_bits, size_t len) {
	AssignBitset(led_bits, len, led_bits_, arraysize(led_bits_));
	}

	void EventDeviceInfo::SetProps(const unsigned long* prop_bits, size_t len) {
	AssignBitset(prop_bits, len, prop_bits_, arraysize(prop_bits_));
	}

	void EventDeviceInfo::SetAbsInfo(unsigned int code,
	const input_absinfo& abs_info) {
	if (code > ABS_MAX)
	return;

	memcpy(&abs_info_[code], &abs_info, sizeof(abs_info));
	}

	void EventDeviceInfo::SetAbsMtSlots(unsigned int code,
	const std::vector<int32_t>& values) {
	DCHECK_EQ(GetAbsMtSlotCount(), values.size());
	int index = code - EVDEV_ABS_MT_FIRST;
	if (index < 0 \|\| index >= EVDEV_ABS_MT_COUNT)
	return;
	slot_values_[index] = values;
	}

	void EventDeviceInfo::SetAbsMtSlot(unsigned int code,
	unsigned int slot,
	uint32_t value) {
	int index = code - EVDEV_ABS_MT_FIRST;
	if (index < 0 \|\| index >= EVDEV_ABS_MT_COUNT)
	return;
	slot_values_[index][slot] = value;
	}

	bool EventDeviceInfo::HasEventType(unsigned int type) const {
	if (type > EV_MAX)
	return false;
	return EvdevBitIsSet(ev_bits_, type);
	}

	bool EventDeviceInfo::HasKeyEvent(unsigned int code) const {
	if (code > KEY_MAX)
	return false;
	return EvdevBitIsSet(key_bits_, code);
	}

	bool EventDeviceInfo::HasRelEvent(unsigned int code) const {
	if (code > REL_MAX)
	return false;
	return EvdevBitIsSet(rel_bits_, code);
	}

	bool EventDeviceInfo::HasAbsEvent(unsigned int code) const {
	if (code > ABS_MAX)
	return false;
	return EvdevBitIsSet(abs_bits_, code);
	}

	bool EventDeviceInfo::HasMscEvent(unsigned int code) const {
	if (code > MSC_MAX)
	return false;
	return EvdevBitIsSet(msc_bits_, code);
	}

	bool EventDeviceInfo::HasSwEvent(unsigned int code) const {
	if (code > SW_MAX)
	return false;
	return EvdevBitIsSet(sw_bits_, code);
	}

	bool EventDeviceInfo::HasLedEvent(unsigned int code) const {
	if (code > LED_MAX)
	return false;
	return EvdevBitIsSet(led_bits_, code);
	}

	bool EventDeviceInfo::HasProp(unsigned int code) const {
	if (code > INPUT_PROP_MAX)
	return false;
	return EvdevBitIsSet(prop_bits_, code);
	}

	int32_t EventDeviceInfo::GetAbsMinimum(unsigned int code) const {
	return abs_info_[code].minimum;
	}

	int32_t EventDeviceInfo::GetAbsMaximum(unsigned int code) const {
	return abs_info_[code].maximum;
	}

	int32_t EventDeviceInfo::GetAbsValue(unsigned int code) const {
	return abs_info_[code].value;
	}

	uint32_t EventDeviceInfo::GetAbsMtSlotCount() const {
	if (!HasAbsEvent(ABS_MT_SLOT))
	return 0;
	return GetAbsMaximum(ABS_MT_SLOT) + 1;
	}

	int32_t EventDeviceInfo::GetAbsMtSlotValue(unsigned int code,
	unsigned int slot) const {
	unsigned int index = code - EVDEV_ABS_MT_FIRST;
	DCHECK(index < EVDEV_ABS_MT_COUNT);
	return slot_values_[index][slot];
	}

	int32_t EventDeviceInfo::GetAbsMtSlotValueWithDefault(
	unsigned int code,
	unsigned int slot,
	int32_t default_value) const {
	if (!HasAbsEvent(code))
	return default_value;
	return GetAbsMtSlotValue(code, slot);
	}

	bool EventDeviceInfo::HasAbsXY() const {
	return HasAbsEvent(ABS_X) && HasAbsEvent(ABS_Y);
	}

	bool EventDeviceInfo::HasMTAbsXY() const {
	return HasAbsEvent(ABS_MT_POSITION_X) && HasAbsEvent(ABS_MT_POSITION_Y);
	}

	bool EventDeviceInfo::HasRelXY() const {
	return HasRelEvent(REL_X) && HasRelEvent(REL_Y);
	}

	bool EventDeviceInfo::HasMultitouch() const {
	return HasAbsEvent(ABS_MT_SLOT);
	}

	bool EventDeviceInfo::HasDirect() const {
	bool has_direct = HasProp(INPUT_PROP_DIRECT);
	bool has_pointer = HasProp(INPUT_PROP_POINTER);
	if (has_direct \|\| has_pointer)
	return has_direct;

	switch (ProbeLegacyAbsoluteDevice()) {
	case LegacyAbsoluteDeviceType::LADT_TOUCHSCREEN:
	return true;

	case LegacyAbsoluteDeviceType::LADT_TABLET:
	case LegacyAbsoluteDeviceType::LADT_TOUCHPAD:
	case LegacyAbsoluteDeviceType::LADT_NONE:
	return false;
	}

	NOTREACHED();
	return false;
	}

	bool EventDeviceInfo::HasPointer() const {
	bool has_direct = HasProp(INPUT_PROP_DIRECT);
	bool has_pointer = HasProp(INPUT_PROP_POINTER);
	if (has_direct \|\| has_pointer)
	return has_pointer;

	switch (ProbeLegacyAbsoluteDevice()) {
	case LegacyAbsoluteDeviceType::LADT_TOUCHPAD:
	case LegacyAbsoluteDeviceType::LADT_TABLET:
	return true;

	case LegacyAbsoluteDeviceType::LADT_TOUCHSCREEN:
	case LegacyAbsoluteDeviceType::LADT_NONE:
	return false;
	}

	NOTREACHED();
	return false;
	}

	bool EventDeviceInfo::HasStylus() const {
	return HasKeyEvent(BTN_TOOL_PEN) \|\| HasKeyEvent(BTN_STYLUS) \|\|
	HasKeyEvent(BTN_STYLUS2);
	}

	bool EventDeviceInfo::HasKeyboard() const {
	if (!HasEventType(EV_KEY))
	return false;

	// Check first 31 keys: If we have all of them, consider it a full
	// keyboard. This is exactly what udev does for ID_INPUT_KEYBOARD.
	for (int key = KEY_ESC; key <= KEY_D; ++key)
	if (!HasKeyEvent(key))
	return false;

	return true;
	}

	bool EventDeviceInfo::HasMouse() const {
	return HasRelXY();
	}

	bool EventDeviceInfo::HasTouchpad() const {
	return HasAbsXY() && HasPointer() && !HasStylus();
	}

	bool EventDeviceInfo::HasTablet() const {
	return HasAbsXY() && HasPointer() && HasStylus();
	}

	bool EventDeviceInfo::HasTouchscreen() const {
	return HasAbsXY() && HasDirect();
	}

	EventDeviceInfo::LegacyAbsoluteDeviceType
	EventDeviceInfo::ProbeLegacyAbsoluteDevice() const {
	if (!HasAbsXY())
	return LegacyAbsoluteDeviceType::LADT_NONE;

	if (HasStylus())
	return LegacyAbsoluteDeviceType::LADT_TABLET;

	if (HasKeyEvent(BTN_TOOL_FINGER) && HasKeyEvent(BTN_TOUCH))
	return LegacyAbsoluteDeviceType::LADT_TOUCHPAD;

	if (HasKeyEvent(BTN_TOUCH) \|\| HasKeyEvent(BTN_LEFT))
	return LegacyAbsoluteDeviceType::LADT_TOUCHSCREEN;

	return LegacyAbsoluteDeviceType::LADT_NONE;
	}

	} // namespace ui