// Copyright (c) 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 "base/x11/edid_parser_x11.h" #include #include #include #include "base/hash.h" #include "base/message_loop/message_loop.h" #include "base/strings/string_util.h" #include "base/sys_byteorder.h" namespace { // Returns 64-bit persistent ID for the specified manufacturer's ID and // product_code_hash, and the index of the output it is connected to. // |output_index| is used to distinguish the displays of the same type. For // example, swapping two identical display between two outputs will not be // treated as swap. The 'serial number' field in EDID isn't used here because // it is not guaranteed to have unique number and it may have the same fixed // value (like 0). int64 GetID(uint16 manufacturer_id, uint32 product_code_hash, uint8 output_index) { return ((static_cast(manufacturer_id) << 40) | (static_cast(product_code_hash) << 8) | output_index); } bool IsRandRAvailable() { int randr_version_major = 0; int randr_version_minor = 0; static bool is_randr_available = XRRQueryVersion( base::MessagePumpX11::GetDefaultXDisplay(), &randr_version_major, &randr_version_minor); return is_randr_available; } } // namespace namespace base { bool GetEDIDProperty(XID output, unsigned long* nitems, unsigned char** prop) { if (!IsRandRAvailable()) return false; Display* display = base::MessagePumpX11::GetDefaultXDisplay(); static Atom edid_property = XInternAtom( base::MessagePumpX11::GetDefaultXDisplay(), RR_PROPERTY_RANDR_EDID, false); bool has_edid_property = false; int num_properties = 0; Atom* properties = XRRListOutputProperties(display, output, &num_properties); for (int i = 0; i < num_properties; ++i) { if (properties[i] == edid_property) { has_edid_property = true; break; } } XFree(properties); if (!has_edid_property) return false; Atom actual_type; int actual_format; unsigned long bytes_after; XRRGetOutputProperty(display, output, edid_property, 0, // offset 128, // length false, // _delete false, // pending AnyPropertyType, // req_type &actual_type, &actual_format, nitems, &bytes_after, prop); DCHECK_EQ(XA_INTEGER, actual_type); DCHECK_EQ(8, actual_format); return true; } bool GetDisplayId(XID output_id, size_t output_index, int64* display_id_out) { unsigned long nitems = 0; unsigned char* prop = NULL; if (!GetEDIDProperty(output_id, &nitems, &prop)) return false; bool result = GetDisplayIdFromEDID(prop, nitems, output_index, display_id_out); XFree(prop); return result; } bool GetDisplayIdFromEDID(const unsigned char* prop, unsigned long nitems, size_t output_index, int64* display_id_out) { uint16 manufacturer_id = 0; std::string product_name; // ParseOutputDeviceData fails if it doesn't have product_name. ParseOutputDeviceData(prop, nitems, &manufacturer_id, &product_name); // Generates product specific value from product_name instead of product code. // See crbug.com/240341 uint32 product_code_hash = product_name.empty() ? 0 : base::Hash(product_name); if (manufacturer_id != 0) { // An ID based on display's index will be assigned later if this call // fails. *display_id_out = GetID( manufacturer_id, product_code_hash, output_index); return true; } return false; } bool ParseOutputDeviceData(const unsigned char* prop, unsigned long nitems, uint16* manufacturer_id, std::string* human_readable_name) { // See http://en.wikipedia.org/wiki/Extended_display_identification_data // for the details of EDID data format. We use the following data: // bytes 8-9: manufacturer EISA ID, in big-endian // bytes 54-125: four descriptors (18-bytes each) which may contain // the display name. const unsigned int kManufacturerOffset = 8; const unsigned int kManufacturerLength = 2; const unsigned int kDescriptorOffset = 54; const unsigned int kNumDescriptors = 4; const unsigned int kDescriptorLength = 18; // The specifier types. const unsigned char kMonitorNameDescriptor = 0xfc; if (manufacturer_id) { if (nitems < kManufacturerOffset + kManufacturerLength) { LOG(ERROR) << "too short EDID data: manifacturer id"; return false; } *manufacturer_id = *reinterpret_cast(prop + kManufacturerOffset); #if defined(ARCH_CPU_LITTLE_ENDIAN) *manufacturer_id = base::ByteSwap(*manufacturer_id); #endif } if (!human_readable_name) return true; human_readable_name->clear(); for (unsigned int i = 0; i < kNumDescriptors; ++i) { if (nitems < kDescriptorOffset + (i + 1) * kDescriptorLength) break; const unsigned char* desc_buf = prop + kDescriptorOffset + i * kDescriptorLength; // If the descriptor contains the display name, it has the following // structure: // bytes 0-2, 4: \0 // byte 3: descriptor type, defined above. // bytes 5-17: text data, ending with \r, padding with spaces // we should check bytes 0-2 and 4, since it may have other values in // case that the descriptor contains other type of data. if (desc_buf[0] == 0 && desc_buf[1] == 0 && desc_buf[2] == 0 && desc_buf[4] == 0) { if (desc_buf[3] == kMonitorNameDescriptor) { std::string found_name( reinterpret_cast(desc_buf + 5), kDescriptorLength - 5); TrimWhitespaceASCII(found_name, TRIM_TRAILING, human_readable_name); break; } } } // Verify if the |human_readable_name| consists of printable characters only. for (size_t i = 0; i < human_readable_name->size(); ++i) { char c = (*human_readable_name)[i]; if (!isascii(c) || !isprint(c)) { human_readable_name->clear(); LOG(ERROR) << "invalid EDID: human unreadable char in name"; return false; } } return true; } } // namespace base