[libsigrokdecode.git] / decoders / edid / edid.py

##
## This file is part of the sigrok project.
##
## Copyright (C) 2012 Bert Vermeulen <bert@biot.com>
##
## This program is free software; you can redistribute it and/or modify
## it under the terms of the GNU General Public License as published by
## the Free Software Foundation; either version 3 of the License, or
## (at your option) any later version.
##
## This program 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 General Public License for more details.
##
## You should have received a copy of the GNU General Public License
## along with this program; if not, see <http://www.gnu.org/licenses/>.
##

'''
EDID 1.3 structure decoder.

Details:
https://en.wikipedia.org/wiki/Extended_display_identification_data
'''

# TODO:
#    - EDID < 1.3
#    - Signal level standard field in basic display parameters block
#    - Additional color point descriptors
#    - Additional standard timing descriptors
#    - Extensions

import sigrokdecode as srd
import os

EDID_HEADER = [0x00, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0x00]
OFF_VENDOR = 8
OFF_VERSION = 18
OFF_BASIC = 20
OFF_CHROM = 25
OFF_EST_TIMING = 35
OFF_STD_TIMING = 38
OFF_DET_TIMING = 54
OFF_NUM_EXT = 126
OFF_CHECKSUM = 127


# Pre-EDID established timing modes
est_modes = [
    "720x400@70Hz",
    "720x400@88Hz",
    "640x480@60Hz",
    "640x480@67Hz",
    "640x480@72Hz",
    "640x480@75Hz",
    "800x600@56Hz",
    "800x600@60Hz",
    "800x600@72Hz",
    "800x600@75Hz",
    "832x624@75Hz",
    "1024x768@87Hz(i)",
    "1024x768@60Hz",
    "1024x768@70Hz",
    "1024x768@75Hz",
    "1280x1024@75Hz",
    "1152x870@75Hz"
]

# X:Y display aspect ratios, as used in standard timing modes
xy_ratio = [
    (16, 10),
    (4, 3),
    (5, 4),
    (16, 9)
]

# Annotation types
ANN_FIELDS = 0
ANN_SECTIONS = 1

class Decoder(srd.Decoder):
    api_version = 1
    id = 'edid'
    name = 'EDID'
    longname = 'Extended display identification data'
    desc = 'A data structure describing the capabilities of a display device.'
    license = 'gplv3+'
    inputs = ['ddc2']
    outputs = ['edid']
    options = {}
    annotations = [
        ['EDID fields', 'EDID structure fields'],
        ['EDID sections', 'EDID structure sections'],
    ]

    def __init__(self, **kwargs):
        self.state = None
        # Received data items, used as an index into samplenum/data
        self.cnt = 0
        # Start/end sample numbers per data item
        self.sn = []
        # Received data
        self.cache = []

    def start(self, metadata):
        self.out_ann = self.add(srd.OUTPUT_ANN, 'edid')

    def decode(self, ss, es, data):
        if type(data) != int:
            raise Exception('malformed ddc2 input: expected 1 byte')
        self.cnt += 1
        self.sn.append( [ss, es] )
        self.cache.append(data)

        if self.state is None:
            # Wait for the EDID header
            if self.cnt >= OFF_VENDOR:
                if self.cache[-8:] == EDID_HEADER:
                    # Throw away any garbage before the header
                    self.sn = self.sn[-8:]
                    self.cache = self.cache[-8:]
                    self.state = 'edid'
                    self.put(ss, es, self.out_ann, [0, ["EDID header"]])
        elif self.state == 'edid':
            if self.cnt == OFF_VERSION:
                self.decode_vid(-10)
                self.decode_pid(-8)
                self.decode_serial(-6)
                self.decode_mfrdate(-2)
            elif self.cnt == OFF_BASIC:
                version = "EDID version: %d.%d" % (self.cache[-2], self.cache[-1])
                self.put(ss, es, self.out_ann, [0, [version]])
            elif self.cnt == OFF_CHROM:
                self.decode_basicdisplay(-5)
            elif self.cnt == OFF_EST_TIMING:
                self.decode_chromaticity(-10)
            elif self.cnt == OFF_STD_TIMING:
                self.decode_est_timing(-3)
            elif self.cnt == OFF_DET_TIMING:
                self.decode_std_timing(-16)
            elif self.cnt == OFF_NUM_EXT:
                self.decode_descriptors(-72)
            elif self.cnt == OFF_CHECKSUM:
                self.put(ss, es, self.out_ann, [0, ["Extensions present: %d" % self.cache[self.cnt-1]]])
            elif self.cnt == OFF_CHECKSUM+1:
                checksum = 0
                for i in range(128):
                    checksum += self.cache[i]
                if checksum % 256 == 0:
                    csstr = "OK"
                else:
                    csstr = "WRONG!"
                self.put(ss, es, self.out_ann, [0, ["Checksum: %d (%s)" % (
                                self.cache[self.cnt-1], csstr)]])
                self.state = 'extensions'
        elif self.state == 'extensions':
            pass

    def ann_field(self, start, end, annotation):
        self.put(self.sn[start][0], self.sn[end][1], self.out_ann, [ANN_FIELDS, [annotation]])

    def lookup_pnpid(self, pnpid):
        pnpid_file = os.path.dirname(__file__) + '/pnpids.txt'
        if os.path.exists(pnpid_file):
            for line in open(pnpid_file).readlines():
                if line.find(pnpid + ';') == 0:
                    return line[4:].strip()
        return ''

    def decode_vid(self, offset):
        pnpid = chr(64 + ((self.cache[offset] & 0x7c) >> 2))
        pnpid += chr(64 + (((self.cache[offset] & 0x03) << 3)
                           | ((self.cache[offset+1] & 0xe0) >> 5)))
        pnpid += chr(64 + (self.cache[offset+1] & 0x1f))
        vendor = self.lookup_pnpid(pnpid)
        if vendor:
            pnpid += " (%s)" % vendor
        self.ann_field(offset, offset+1, pnpid)

    def decode_pid(self, offset):
        pidstr = "Product 0x%.2x%.2x" % (self.cache[offset+1], self.cache[offset])
        self.ann_field(offset, offset+1, pidstr)

    def decode_serial(self, offset):
        serialnum = (self.cache[offset+3] << 24) \
                + (self.cache[offset+2] << 16) \
                + (self.cache[offset+1] << 8) \
                + self.cache[offset]
        serialstr = ''
        is_alnum = True
        for i in range(4):
            if not chr(self.cache[offset+3-i]).isalnum():
                is_alnum = False
                break
            serialstr += chr(self.cache[offset+3-i])
        if is_alnum:
            serial = serialstr
        else:
            serial = str(serialnum)
        self.ann_field(offset, offset+3, "Serial " + serial)

    def decode_mfrdate(self, offset):
        datestr = ''
        if self.cache[offset]:
            datestr += "week %d, " % self.cache[offset]
        datestr += str(1990 + self.cache[offset+1])
        if datestr:
            self.ann_field(offset, offset+1, "Manufactured " + datestr)

    def decode_basicdisplay(self, offset):
        # Video input definition
        vid = self.cache[offset]
        if vid & 0x80:
            # Digital
            self.ann_field(offset, offset, "Video input: VESA DFP 1.")
        else:
            # Analog
            sls = (vid & 60) >> 5
            self.ann_field(offset, offset, "Signal level standard: %.2x" % sls)
            if vid & 0x10:
                self.ann_field(offset, offset, "Blank-to-black setup expected")
            syncs = ''
            if vid & 0x08:
                syncs += 'separate syncs, '
            if vid & 0x04:
                syncs += 'composite syncs, '
            if vid & 0x02:
                syncs += 'sync on green, '
            if vid & 0x01:
                syncs += 'Vsync serration required, '
            if syncs:
                self.ann_field(offset, offset, "Supported syncs: %s" % syncs[:-2])
        # Max horizontal/vertical image size
        if self.cache[offset+1] != 0 and self.cache[offset+2] != 0:
            # Projectors have this set to 0
            sizestr = "%dx%dcm" % (self.cache[offset+1], self.cache[offset+2])
            self.ann_field(offset+1, offset+2, "Physical size: " + sizestr)
        # Display transfer characteristic (gamma)
        if self.cache[offset+3] != 0xff:
            gamma = (self.cache[offset+3] + 100) / 100
            self.ann_field(offset+3, offset+3, "Gamma: %1.2f" % gamma)
        # Feature support
        fs = self.cache[offset+4]
        dpms = ''
        if fs & 0x80:
            dpms += 'standby, '
        if fs & 0x40:
            dpms += 'suspend, '
        if fs & 0x20:
            dpms += 'active off, '
        if dpms:
            self.ann_field(offset+4, offset+4, "DPMS support: %s" % dpms[:-2])
        dt = (fs & 0x18) >> 3
        dtstr = ''
        if dt == 0:
            dtstr = 'Monochrome'
        elif dt == 1:
            dtstr = 'RGB color'
        elif dt == 2:
            dtstr = 'non-RGB multicolor' 
        if dtstr:
            self.ann_field(offset+4, offset+4, "Display type: %s" % dtstr)
        if fs & 0x04:
            self.ann_field(offset+4, offset+4, "Color space: standard sRGB")
        # Save this for when we decode the first detailed timing descriptor
        self.have_preferred_timing = (fs & 0x02) == 0x02
        if fs & 0x01:
            gft = ''
        else:
            gft = 'not '
        self.ann_field(offset+4, offset+4, "Generalized timing formula: %ssupported" % gft)

    def convert_color(self, value):
        # Convert from 10-bit packet format to float
        outval = 0.0
        for i in range(10):
            if value & 0x01:
                outval += 2 ** -(10-i)
            value >>= 1
        return outval

    def decode_chromaticity(self, offset):
        redx = (self.cache[offset+2] << 2) + ((self.cache[offset] & 0xc0) >> 6)
        redy = (self.cache[offset+3] << 2) + ((self.cache[offset] & 0x30) >> 4)
        self.ann_field(offset, offset+9, "Chromacity red: X %1.3f, Y %1.3f" % (
                        self.convert_color(redx), self.convert_color(redy)))

        greenx = (self.cache[offset+4] << 2) + ((self.cache[offset] & 0x0c) >> 6)
        greeny = (self.cache[offset+5] << 2) + ((self.cache[offset] & 0x03) >> 4)
        self.ann_field(offset, offset+9, "Chromacity green: X %1.3f, Y %1.3f" % (
                        self.convert_color(greenx), self.convert_color(greeny)))

        bluex = (self.cache[offset+6] << 2) + ((self.cache[offset+1] & 0xc0) >> 6)
        bluey = (self.cache[offset+7] << 2) + ((self.cache[offset+1] & 0x30) >> 4)
        self.ann_field(offset, offset+9, "Chromacity blue: X %1.3f, Y %1.3f" % (
                        self.convert_color(bluex), self.convert_color(bluey)))

        whitex = (self.cache[offset+8] << 2) + ((self.cache[offset+1] & 0x0c) >> 6)
        whitey = (self.cache[offset+9] << 2) + ((self.cache[offset+1] & 0x03) >> 4)
        self.ann_field(offset, offset+9, "Chromacity white: X %1.3f, Y %1.3f" % (
                        self.convert_color(whitex), self.convert_color(whitey)))

    def decode_est_timing(self, offset):
        # Pre-EDID modes
        bitmap = (self.cache[offset] << 9) \
            + (self.cache[offset+1] << 1) \
            + ((self.cache[offset+2] & 0x80) >> 7)
        modestr = ''
        for i in range(17):
                if bitmap & (1 << (16-i)):
                    modestr += est_modes[i] + ', '
        if modestr:
            self.ann_field(offset, offset+2, "Supported establised modes: %s" % modestr[:-2])

    def decode_std_timing(self, offset):
        modestr = ''
        for i in range(0, 16, 2):
            if self.cache[offset+i] == 0x01 and self.cache[offset+i+1] == 0x01:
                # Unused field
                continue
            x = (self.cache[offset+i] + 31) * 8
            ratio = (self.cache[offset+i+1] & 0xc0) >> 6
            ratio_x, ratio_y = xy_ratio[ratio]
            y = x / ratio_x * ratio_y
            refresh = (self.cache[offset+i+1] & 0x3f) + 60
            modestr += "%dx%d@%dHz, " % (x, y, refresh)
        if modestr:
            self.ann_field(offset, offset+2, "Supported standard modes: %s" % modestr[:-2])

    def decode_detailed_timing(self, offset):
        if offset == -72 and self.have_preferred_timing:
            # Only on first detailed timing descriptor
            section = 'Preferred'
        else:
            section = 'Detailed'
        section += ' timing descriptor'
        self.put(self.sn[offset][0], self.sn[offset+18][1],
             self.out_ann, [ANN_SECTIONS, [section]])

        pixclock = float((self.cache[offset+1] << 8) + self.cache[offset]) / 100
        self.ann_field(offset, offset+1, "Pixel clock: %.2f MHz" % pixclock)

        horiz_active = ((self.cache[offset+4] & 0xf0) << 4) + self.cache[offset+2]
        self.ann_field(offset+2, offset+4, "Horizontal active: %d" % horiz_active)

        horiz_blank = ((self.cache[offset+4] & 0x0f) << 8) + self.cache[offset+3]
        self.ann_field(offset+3, offset+4, "Horizontal blanking: %d" % horiz_blank)

        vert_active = ((self.cache[offset+7] & 0xf0) << 4) + self.cache[offset+5]
        self.ann_field(offset+5, offset+7, "Vertical active: %d" % vert_active)

        vert_blank = ((self.cache[offset+7] & 0x0f) << 8) + self.cache[offset+6]
        self.ann_field(offset+6, offset+7, "Vertical blanking: %d" % vert_blank)

        horiz_sync_off = ((self.cache[offset+11] & 0xc0) << 2) + self.cache[offset+8]
        self.ann_field(offset+8, offset+11, "Horizontal sync offset: %d" % horiz_sync_off)

        horiz_sync_pw = ((self.cache[offset+11] & 0x30) << 4) + self.cache[offset+9]
        self.ann_field(offset+9, offset+11, "Horizontal sync pulse width: %d" % horiz_sync_pw)

        vert_sync_off = ((self.cache[offset+11] & 0x0c) << 2) \
                    + ((self.cache[offset+10] & 0xf0) >> 4)
        self.ann_field(offset+10, offset+11, "Vertical sync offset: %d" % vert_sync_off)

        vert_sync_pw = ((self.cache[offset+11] & 0x03) << 4) \
                    + (self.cache[offset+10] & 0x0f)
        self.ann_field(offset+10, offset+11, "Vertical sync pulse width: %d" % vert_sync_pw)

        horiz_size = ((self.cache[offset+14] & 0xf0) << 4) + self.cache[offset+12]
        vert_size = ((self.cache[offset+14] & 0x0f) << 8) + self.cache[offset+13]
        self.ann_field(offset+12, offset+14, "Physical size: %dx%dmm" % (horiz_size, vert_size))

        horiz_border = self.cache[offset+15]
        if horiz_border:
            self.ann_field(offset+15, offset+15, "Horizontal border: %d pixels" % horiz_border)
        vert_border = self.cache[offset+16]
        if vert_border:
            self.ann_field(offset+16, offset+16, "Vertical border: %d lines" % vert_border)

        features = 'Flags: '
        if self.cache[offset+17] & 0x80:
            features += 'interlaced, '
        stereo = (self.cache[offset+17] & 0x60) >> 5
        if stereo:
            if self.cache[offset+17] & 0x01:
                features += '2-way interleaved stereo ('
                features += ['right image on even lines', 'left image on even lines',
                             'side-by-side'][stereo-1]
                features += '), '
            else:
                features += 'field sequential stereo ('
                features += ['right image on sync=1', 'left image on sync=1',
                             '4-way interleaved'][stereo-1]
                features += '), '
        sync = (self.cache[offset+17] & 0x18) >> 3
        sync2 = (self.cache[offset+17] & 0x06) >> 1
        posneg = ['negative', 'positive']
        features += 'sync type '
        if sync == 0x00:
            features += 'analog composite (serrate on RGB)'
        elif sync == 0x01:
            features += 'bipolar analog composite (serrate on RGB)'
        elif sync == 0x02:
            features += 'digital composite (serrate on composite polarity ' \
                    + (posneg[sync2 & 0x01]) + ')'
        elif sync == 0x03:
            features += 'digital separate ('
            features += 'Vsync polarity ' + (posneg[sync2 >> 1])
            features += ', Hsync polarity ' + (posneg[sync2 & 0x01])
            features += ')'
        features += ', '
        self.ann_field(offset+17, offset+17, features[:-2])

    def decode_descriptor(self, offset):
        tag = self.cache[offset+3]
        if tag == 0xff:
            # Monitor serial number
            text = bytes(self.cache[offset+5:][:13]).decode(encoding='cp437', errors='replace')
            self.ann_field(offset, offset+17, "Serial number: %s" % text.strip())
        elif tag == 0xfe:
            # Text
            text = bytes(self.cache[offset+5:][:13]).decode(encoding='cp437', errors='replace')
            self.ann_field(offset, offset+17, "Info: %s" % text.strip())
        elif tag == 0xfc:
            # Monitor name
            text = bytes(self.cache[offset+5:][:13]).decode(encoding='cp437', errors='replace')
            self.ann_field(offset, offset+17, "Model name: %s" % text.strip())
        elif tag == 0xfd:
            # Monitor range limits
            self.put(self.sn[offset][0], self.sn[offset+17][1], self.out_ann,
                     [ANN_SECTIONS, ["Monitor range limits"]])
            self.ann_field(offset+5, offset+5, "Minimum vertical rate: %dHz" % 
                           self.cache[offset+5])
            self.ann_field(offset+6, offset+6, "Maximum vertical rate: %dHz" % 
                           self.cache[offset+6])
            self.ann_field(offset+7, offset+7, "Minimum horizontal rate: %dkHz" % 
                           self.cache[offset+7])
            self.ann_field(offset+8, offset+8, "Maximum horizontal rate: %dkHz" % 
                           self.cache[offset+8])
            self.ann_field(offset+9, offset+9, "Maximum pixel clock: %dMHz" % 
                           (self.cache[offset+9] * 10))
            if self.cache[offset+10] == 0x02:
                # Secondary GTF curve supported
                self.ann_field(offset+10, offset+17, "Secondary timing formula supported")
        elif tag == 0xfb:
            # Additional color point data
            self.put(self.sn[offset][0], self.sn[offset+17][1], self.out_ann,
                     [ANN_SECTIONS, ["Additional color point data"]])
        elif tag == 0xfa:
            # Additional standard timing definitions
            self.put(self.sn[offset][0], self.sn[offset+17][1], self.out_ann,
                     [ANN_SECTIONS, ["Additional standard timing definitions"]])
        else:
            self.put(self.sn[offset][0], self.sn[offset+17][1], self.out_ann,
                     [ANN_SECTIONS, ["Unknown descriptor"]])

    def decode_descriptors(self, offset):
        # 4 consecutive 18-byte descriptor blocks
        for i in range(offset, 0, 18):
            if self.cache[i] != 0 and self.cache[i+1] != 0:
                self.decode_detailed_timing(i)
            else:
                if self.cache[i+2] == 0 or self.cache[i+4] == 0 or True:
                    self.decode_descriptor(i)
Commit	Line	Data
91b2e171 BV	1	##
	2	## This file is part of the sigrok project.
	3	##
	4	## Copyright (C) 2012 Bert Vermeulen <bert@biot.com>
	5	##
	6	## This program is free software; you can redistribute it and/or modify
	7	## it under the terms of the GNU General Public License as published by
	8	## the Free Software Foundation; either version 3 of the License, or
	9	## (at your option) any later version.
	10	##
	11	## This program is distributed in the hope that it will be useful,
	12	## but WITHOUT ANY WARRANTY; without even the implied warranty of
	13	## MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
	14	## GNU General Public License for more details.
	15	##
	16	## You should have received a copy of the GNU General Public License
	17	## along with this program; if not, see <http://www.gnu.org/licenses/>.
	18	##
	19
	20	'''
	21	EDID 1.3 structure decoder.
	22
	23	Details:
	24	https://en.wikipedia.org/wiki/Extended_display_identification_data
	25	'''
	26
	27	# TODO:
	28	# - EDID < 1.3
	29	# - Signal level standard field in basic display parameters block
	30	# - Additional color point descriptors
	31	# - Additional standard timing descriptors
	32	# - Extensions
	33
	34	import sigrokdecode as srd
	35	import os
	36
	37	EDID_HEADER = [0x00, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0x00]
	38	OFF_VENDOR = 8
	39	OFF_VERSION = 18
	40	OFF_BASIC = 20
	41	OFF_CHROM = 25
	42	OFF_EST_TIMING = 35
	43	OFF_STD_TIMING = 38
	44	OFF_DET_TIMING = 54
	45	OFF_NUM_EXT = 126
	46	OFF_CHECKSUM = 127
	47
	48
	49	# Pre-EDID established timing modes
	50	est_modes = [
	51	"720x400@70Hz",
	52	"720x400@88Hz",
	53	"640x480@60Hz",
	54	"640x480@67Hz",
	55	"640x480@72Hz",
	56	"640x480@75Hz",
	57	"800x600@56Hz",
	58	"800x600@60Hz",
	59	"800x600@72Hz",
	60	"800x600@75Hz",
	61	"832x624@75Hz",
	62	"1024x768@87Hz(i)",
	63	"1024x768@60Hz",
	64	"1024x768@70Hz",
65	"1024x768@75Hz",
66	"1280x1024@75Hz",
67	"1152x870@75Hz"
68	]
69
70	# X:Y display aspect ratios, as used in standard timing modes
71	xy_ratio = [
72	(16, 10),
73	(4, 3),
74	(5, 4),
75	(16, 9)
76	]
77
78	# Annotation types
79	ANN_FIELDS = 0
80	ANN_SECTIONS = 1
81
82	class Decoder(srd.Decoder):
83	api_version = 1
84	id = 'edid'
85	name = 'EDID'
86	longname = 'Extended display identification data'
87	desc = 'A data structure describing the capabilities of a display device.'
88	license = 'gplv3+'
89	inputs = ['ddc2']
90	outputs = ['edid']
91	options = {}
92	annotations = [
93	['EDID fields', 'EDID structure fields'],
94	['EDID sections', 'EDID structure sections'],
95	]
96
97	def __init__(self, **kwargs):
98	self.state = None
99	# Received data items, used as an index into samplenum/data
100	self.cnt = 0
101	# Start/end sample numbers per data item
102	self.sn = []
103	# Received data
104	self.cache = []
105
106	def start(self, metadata):
107	self.out_ann = self.add(srd.OUTPUT_ANN, 'edid')
108
109	def decode(self, ss, es, data):
110	if type(data) != int:
111	raise Exception('malformed ddc2 input: expected 1 byte')
112	self.cnt += 1
113	self.sn.append( [ss, es] )
114	self.cache.append(data)
115
116	if self.state is None:
117	# Wait for the EDID header
118	if self.cnt >= OFF_VENDOR:
119	if self.cache[-8:] == EDID_HEADER:
120	# Throw away any garbage before the header
121	self.sn = self.sn[-8:]
122	self.cache = self.cache[-8:]
123	self.state = 'edid'
124	self.put(ss, es, self.out_ann, [0, ["EDID header"]])
125	elif self.state == 'edid':
126	if self.cnt == OFF_VERSION:
127	self.decode_vid(-10)
128	self.decode_pid(-8)
129	self.decode_serial(-6)
130	self.decode_mfrdate(-2)
131	elif self.cnt == OFF_BASIC:
132	version = "EDID version: %d.%d" % (self.cache[-2], self.cache[-1])
133	self.put(ss, es, self.out_ann, [0, [version]])
134	elif self.cnt == OFF_CHROM:
135	self.decode_basicdisplay(-5)
136	elif self.cnt == OFF_EST_TIMING:
137	self.decode_chromaticity(-10)
138	elif self.cnt == OFF_STD_TIMING:
139	self.decode_est_timing(-3)
140	elif self.cnt == OFF_DET_TIMING:
141	self.decode_std_timing(-16)
142	elif self.cnt == OFF_NUM_EXT:
143	self.decode_descriptors(-72)
144	elif self.cnt == OFF_CHECKSUM:
145	self.put(ss, es, self.out_ann, [0, ["Extensions present: %d" % self.cache[self.cnt-1]]])
146	elif self.cnt == OFF_CHECKSUM+1:
147	checksum = 0
148	for i in range(128):
149	checksum += self.cache[i]
150	if checksum % 256 == 0:
151	csstr = "OK"
152	else:
153	csstr = "WRONG!"
154	self.put(ss, es, self.out_ann, [0, ["Checksum: %d (%s)" % (
155	self.cache[self.cnt-1], csstr)]])
156	self.state = 'extensions'
157	elif self.state == 'extensions':
158	pass
159
160	def ann_field(self, start, end, annotation):
161	self.put(self.sn[start][0], self.sn[end][1], self.out_ann, [ANN_FIELDS, [annotation]])
162
163	def lookup_pnpid(self, pnpid):
164	pnpid_file = os.path.dirname(__file__) + '/pnpids.txt'
165	if os.path.exists(pnpid_file):
166	for line in open(pnpid_file).readlines():
167	if line.find(pnpid + ';') == 0:
168	return line[4:].strip()
169	return ''
170
171	def decode_vid(self, offset):
172	pnpid = chr(64 + ((self.cache[offset] & 0x7c) >> 2))
173	pnpid += chr(64 + (((self.cache[offset] & 0x03) << 3)
174	\| ((self.cache[offset+1] & 0xe0) >> 5)))
175	pnpid += chr(64 + (self.cache[offset+1] & 0x1f))
176	vendor = self.lookup_pnpid(pnpid)
177	if vendor:
178	pnpid += " (%s)" % vendor
179	self.ann_field(offset, offset+1, pnpid)
180
181	def decode_pid(self, offset):
182	pidstr = "Product 0x%.2x%.2x" % (self.cache[offset+1], self.cache[offset])
183	self.ann_field(offset, offset+1, pidstr)
184
185	def decode_serial(self, offset):
186	serialnum = (self.cache[offset+3] << 24) \
187	+ (self.cache[offset+2] << 16) \
188	+ (self.cache[offset+1] << 8) \
189	+ self.cache[offset]
190	serialstr = ''
191	is_alnum = True
192	for i in range(4):
193	if not chr(self.cache[offset+3-i]).isalnum():
194	is_alnum = False
195	break
196	serialstr += chr(self.cache[offset+3-i])
197	if is_alnum:
198	serial = serialstr
199	else:
200	serial = str(serialnum)
201	self.ann_field(offset, offset+3, "Serial " + serial)
202
203	def decode_mfrdate(self, offset):
204	datestr = ''
205	if self.cache[offset]:
206	datestr += "week %d, " % self.cache[offset]
207	datestr += str(1990 + self.cache[offset+1])
208	if datestr:
209	self.ann_field(offset, offset+1, "Manufactured " + datestr)
210
211	def decode_basicdisplay(self, offset):
212	# Video input definition
213	vid = self.cache[offset]
214	if vid & 0x80:
215	# Digital
216	self.ann_field(offset, offset, "Video input: VESA DFP 1.")
217	else:
218	# Analog
219	sls = (vid & 60) >> 5
220	self.ann_field(offset, offset, "Signal level standard: %.2x" % sls)
221	if vid & 0x10:
222	self.ann_field(offset, offset, "Blank-to-black setup expected")
223	syncs = ''
224	if vid & 0x08:
225	syncs += 'separate syncs, '
226	if vid & 0x04:
227	syncs += 'composite syncs, '
228	if vid & 0x02:
229	syncs += 'sync on green, '
230	if vid & 0x01:
231	syncs += 'Vsync serration required, '
232	if syncs:
233	self.ann_field(offset, offset, "Supported syncs: %s" % syncs[:-2])
234	# Max horizontal/vertical image size
235	if self.cache[offset+1] != 0 and self.cache[offset+2] != 0:
236	# Projectors have this set to 0
237	sizestr = "%dx%dcm" % (self.cache[offset+1], self.cache[offset+2])
238	self.ann_field(offset+1, offset+2, "Physical size: " + sizestr)
239	# Display transfer characteristic (gamma)
240	if self.cache[offset+3] != 0xff:
241	gamma = (self.cache[offset+3] + 100) / 100
242	self.ann_field(offset+3, offset+3, "Gamma: %1.2f" % gamma)
243	# Feature support
244	fs = self.cache[offset+4]
245	dpms = ''
246	if fs & 0x80:
247	dpms += 'standby, '
248	if fs & 0x40:
249	dpms += 'suspend, '
250	if fs & 0x20:
251	dpms += 'active off, '
252	if dpms:
253	self.ann_field(offset+4, offset+4, "DPMS support: %s" % dpms[:-2])
254	dt = (fs & 0x18) >> 3
255	dtstr = ''
256	if dt == 0:
257	dtstr = 'Monochrome'
258	elif dt == 1:
259	dtstr = 'RGB color'
260	elif dt == 2:
261	dtstr = 'non-RGB multicolor'
262	if dtstr:
263	self.ann_field(offset+4, offset+4, "Display type: %s" % dtstr)
264	if fs & 0x04:
265	self.ann_field(offset+4, offset+4, "Color space: standard sRGB")
266	# Save this for when we decode the first detailed timing descriptor
267	self.have_preferred_timing = (fs & 0x02) == 0x02
268	if fs & 0x01:
269	gft = ''
270	else:
271	gft = 'not '
272	self.ann_field(offset+4, offset+4, "Generalized timing formula: %ssupported" % gft)
273
274	def convert_color(self, value):
275	# Convert from 10-bit packet format to float
276	outval = 0.0
277	for i in range(10):
278	if value & 0x01:
279	outval += 2 ** -(10-i)
280	value >>= 1
281	return outval
282
283	def decode_chromaticity(self, offset):
284	redx = (self.cache[offset+2] << 2) + ((self.cache[offset] & 0xc0) >> 6)
285	redy = (self.cache[offset+3] << 2) + ((self.cache[offset] & 0x30) >> 4)
286	self.ann_field(offset, offset+9, "Chromacity red: X %1.3f, Y %1.3f" % (
287	self.convert_color(redx), self.convert_color(redy)))
288
289	greenx = (self.cache[offset+4] << 2) + ((self.cache[offset] & 0x0c) >> 6)
290	greeny = (self.cache[offset+5] << 2) + ((self.cache[offset] & 0x03) >> 4)
291	self.ann_field(offset, offset+9, "Chromacity green: X %1.3f, Y %1.3f" % (
292	self.convert_color(greenx), self.convert_color(greeny)))
293
294	bluex = (self.cache[offset+6] << 2) + ((self.cache[offset+1] & 0xc0) >> 6)
295	bluey = (self.cache[offset+7] << 2) + ((self.cache[offset+1] & 0x30) >> 4)
296	self.ann_field(offset, offset+9, "Chromacity blue: X %1.3f, Y %1.3f" % (
297	self.convert_color(bluex), self.convert_color(bluey)))
298
299	whitex = (self.cache[offset+8] << 2) + ((self.cache[offset+1] & 0x0c) >> 6)
300	whitey = (self.cache[offset+9] << 2) + ((self.cache[offset+1] & 0x03) >> 4)
301	self.ann_field(offset, offset+9, "Chromacity white: X %1.3f, Y %1.3f" % (
302	self.convert_color(whitex), self.convert_color(whitey)))
303
304	def decode_est_timing(self, offset):
305	# Pre-EDID modes
306	bitmap = (self.cache[offset] << 9) \
307	+ (self.cache[offset+1] << 1) \
308	+ ((self.cache[offset+2] & 0x80) >> 7)
309	modestr = ''
310	for i in range(17):
311	if bitmap & (1 << (16-i)):
312	modestr += est_modes[i] + ', '
313	if modestr:
314	self.ann_field(offset, offset+2, "Supported establised modes: %s" % modestr[:-2])
315
316	def decode_std_timing(self, offset):
317	modestr = ''
318	for i in range(0, 16, 2):
319	if self.cache[offset+i] == 0x01 and self.cache[offset+i+1] == 0x01:
320	# Unused field
321	continue
322	x = (self.cache[offset+i] + 31) * 8
323	ratio = (self.cache[offset+i+1] & 0xc0) >> 6
324	ratio_x, ratio_y = xy_ratio[ratio]
325	y = x / ratio_x * ratio_y
326	refresh = (self.cache[offset+i+1] & 0x3f) + 60
327	modestr += "%dx%d@%dHz, " % (x, y, refresh)
328	if modestr:
329	self.ann_field(offset, offset+2, "Supported standard modes: %s" % modestr[:-2])
330
331	def decode_detailed_timing(self, offset):
332	if offset == -72 and self.have_preferred_timing:
333	# Only on first detailed timing descriptor
334	section = 'Preferred'
335	else:
336	section = 'Detailed'
337	section += ' timing descriptor'
338	self.put(self.sn[offset][0], self.sn[offset+18][1],
339	self.out_ann, [ANN_SECTIONS, [section]])
340
341	pixclock = float((self.cache[offset+1] << 8) + self.cache[offset]) / 100
342	self.ann_field(offset, offset+1, "Pixel clock: %.2f MHz" % pixclock)
343
344	horiz_active = ((self.cache[offset+4] & 0xf0) << 4) + self.cache[offset+2]
345	self.ann_field(offset+2, offset+4, "Horizontal active: %d" % horiz_active)
346
347	horiz_blank = ((self.cache[offset+4] & 0x0f) << 8) + self.cache[offset+3]
348	self.ann_field(offset+3, offset+4, "Horizontal blanking: %d" % horiz_blank)
349
350	vert_active = ((self.cache[offset+7] & 0xf0) << 4) + self.cache[offset+5]
351	self.ann_field(offset+5, offset+7, "Vertical active: %d" % vert_active)
352
353	vert_blank = ((self.cache[offset+7] & 0x0f) << 8) + self.cache[offset+6]
354	self.ann_field(offset+6, offset+7, "Vertical blanking: %d" % vert_blank)
355
356	horiz_sync_off = ((self.cache[offset+11] & 0xc0) << 2) + self.cache[offset+8]
357	self.ann_field(offset+8, offset+11, "Horizontal sync offset: %d" % horiz_sync_off)
358
359	horiz_sync_pw = ((self.cache[offset+11] & 0x30) << 4) + self.cache[offset+9]
360	self.ann_field(offset+9, offset+11, "Horizontal sync pulse width: %d" % horiz_sync_pw)
361
362	vert_sync_off = ((self.cache[offset+11] & 0x0c) << 2) \
363	+ ((self.cache[offset+10] & 0xf0) >> 4)
364	self.ann_field(offset+10, offset+11, "Vertical sync offset: %d" % vert_sync_off)
365
366	vert_sync_pw = ((self.cache[offset+11] & 0x03) << 4) \
367	+ (self.cache[offset+10] & 0x0f)
368	self.ann_field(offset+10, offset+11, "Vertical sync pulse width: %d" % vert_sync_pw)
369
370	horiz_size = ((self.cache[offset+14] & 0xf0) << 4) + self.cache[offset+12]
371	vert_size = ((self.cache[offset+14] & 0x0f) << 8) + self.cache[offset+13]
372	self.ann_field(offset+12, offset+14, "Physical size: %dx%dmm" % (horiz_size, vert_size))
373
374	horiz_border = self.cache[offset+15]
375	if horiz_border:
376	self.ann_field(offset+15, offset+15, "Horizontal border: %d pixels" % horiz_border)
377	vert_border = self.cache[offset+16]
378	if vert_border:
379	self.ann_field(offset+16, offset+16, "Vertical border: %d lines" % vert_border)
380
381	features = 'Flags: '
382	if self.cache[offset+17] & 0x80:
383	features += 'interlaced, '
384	stereo = (self.cache[offset+17] & 0x60) >> 5
385	if stereo:
386	if self.cache[offset+17] & 0x01:
387	features += '2-way interleaved stereo ('
388	features += ['right image on even lines', 'left image on even lines',
389	'side-by-side'][stereo-1]
390	features += '), '
391	else:
392	features += 'field sequential stereo ('
393	features += ['right image on sync=1', 'left image on sync=1',
394	'4-way interleaved'][stereo-1]
395	features += '), '
396	sync = (self.cache[offset+17] & 0x18) >> 3
397	sync2 = (self.cache[offset+17] & 0x06) >> 1
398	posneg = ['negative', 'positive']
399	features += 'sync type '
400	if sync == 0x00:
401	features += 'analog composite (serrate on RGB)'
402	elif sync == 0x01:
403	features += 'bipolar analog composite (serrate on RGB)'
404	elif sync == 0x02:
405	features += 'digital composite (serrate on composite polarity ' \
406	+ (posneg[sync2 & 0x01]) + ')'
407	elif sync == 0x03:
408	features += 'digital separate ('
409	features += 'Vsync polarity ' + (posneg[sync2 >> 1])
410	features += ', Hsync polarity ' + (posneg[sync2 & 0x01])
411	features += ')'
412	features += ', '
413	self.ann_field(offset+17, offset+17, features[:-2])
414
415	def decode_descriptor(self, offset):
416	tag = self.cache[offset+3]
417	if tag == 0xff:
418	# Monitor serial number
419	text = bytes(self.cache[offset+5:][:13]).decode(encoding='cp437', errors='replace')
420	self.ann_field(offset, offset+17, "Serial number: %s" % text.strip())
421	elif tag == 0xfe:
422	# Text
423	text = bytes(self.cache[offset+5:][:13]).decode(encoding='cp437', errors='replace')
424	self.ann_field(offset, offset+17, "Info: %s" % text.strip())
425	elif tag == 0xfc:
426	# Monitor name
427	text = bytes(self.cache[offset+5:][:13]).decode(encoding='cp437', errors='replace')
428	self.ann_field(offset, offset+17, "Model name: %s" % text.strip())
429	elif tag == 0xfd:
430	# Monitor range limits
431	self.put(self.sn[offset][0], self.sn[offset+17][1], self.out_ann,
432	[ANN_SECTIONS, ["Monitor range limits"]])
433	self.ann_field(offset+5, offset+5, "Minimum vertical rate: %dHz" %
434	self.cache[offset+5])
435	self.ann_field(offset+6, offset+6, "Maximum vertical rate: %dHz" %
436	self.cache[offset+6])
437	self.ann_field(offset+7, offset+7, "Minimum horizontal rate: %dkHz" %
438	self.cache[offset+7])
439	self.ann_field(offset+8, offset+8, "Maximum horizontal rate: %dkHz" %
440	self.cache[offset+8])
441	self.ann_field(offset+9, offset+9, "Maximum pixel clock: %dMHz" %
442	(self.cache[offset+9] * 10))
443	if self.cache[offset+10] == 0x02:
444	# Secondary GTF curve supported
445	self.ann_field(offset+10, offset+17, "Secondary timing formula supported")
446	elif tag == 0xfb:
447	# Additional color point data
448	self.put(self.sn[offset][0], self.sn[offset+17][1], self.out_ann,
449	[ANN_SECTIONS, ["Additional color point data"]])
450	elif tag == 0xfa:
451	# Additional standard timing definitions
452	self.put(self.sn[offset][0], self.sn[offset+17][1], self.out_ann,
453	[ANN_SECTIONS, ["Additional standard timing definitions"]])
454	else:
455	self.put(self.sn[offset][0], self.sn[offset+17][1], self.out_ann,
456	[ANN_SECTIONS, ["Unknown descriptor"]])
457
458	def decode_descriptors(self, offset):
459	# 4 consecutive 18-byte descriptor blocks
460	for i in range(offset, 0, 18):
461	if self.cache[i] != 0 and self.cache[i+1] != 0:
462	self.decode_detailed_timing(i)
463	else:
464	if self.cache[i+2] == 0 or self.cache[i+4] == 0 or True:
465	self.decode_descriptor(i)
466
467
468
469