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SUSE:SLE-15-SP1:GA
i2c-tools
decode-dimms-hackweek-DDR4.patch
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File decode-dimms-hackweek-DDR4.patch of Package i2c-tools
From: Jean Delvare <jdelvare@suse.de> Subject: decode-dimms: Add support for DDR4 SDRAM memory Patch-mainline: yes Git-commit: f91ab551fa73e4fe831122fb390ac2166e66af67 Git-commit: 56149a6f847933aa6c51392bfe9d513cbc0e443d Git-commit: 9ae51c4a4f8e1e1836470ac7e5fec9c7f6df8ce6 Git-commit: 52cd6c60d6db0e39f00a67f5931c06cccb63e178 Git-commit: eea0b508aaefd687ed559992cece05608418c605 Git-commit: 84da8192c7c409f37c1906b60ef166c58aafc847 This is my hackweek 0x10 project: Add support for DDR4 SDRAM memory modules to decode-dimms * Add preliminary DDR4 support * Decode size and timings of DDR4 * Decode misc parameters of DDR4 * Decode physical characteristics of DDR4 * Documentation update for DDR4 * Verify the CRC of DDR4 data block 1 --- eeprom/decode-dimms | 326 ++++++++++++++++++++++++++++++++++++++++++++++++-- eeprom/decode-dimms.1 | 7 - 2 files changed, 320 insertions(+), 13 deletions(-) --- a/eeprom/decode-dimms +++ b/eeprom/decode-dimms @@ -5,7 +5,7 @@ # Copyright 1998, 1999 Philip Edelbrock <phil@netroedge.com> # modified by Christian Zuckschwerdt <zany@triq.net> # modified by Burkart Lingner <burkart@bollchen.de> -# Copyright (C) 2005-2013 Jean Delvare <jdelvare@suse.de> +# Copyright (C) 2005-2017 Jean Delvare <jdelvare@suse.de> # # 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 @@ -1404,6 +1404,7 @@ sub ddr3_mtb_ftb($$$$) return $byte1 * $mtb + $byte2 * $ftb / 1000; } +# Also works for DDR4 sub ddr3_reference_card($$) { my ($rrc, $ext) = @_; @@ -1702,6 +1703,251 @@ sub decode_ddr3_sdram($) } +# Return combined time in ns +sub ddr4_mtb_ftb($$$$) +{ + my ($byte1, $byte2, $mtb, $ftb) = @_; + + # byte1 is unsigned in ps, but byte2 is signed in ps + $byte2 -= 0x100 if $byte2 & 0x80; + + return ($byte1 * $mtb + $byte2 * $ftb) / 1000; +} + +# Rounded per DDR4 specifications +sub ddr4_core_timings($$$$$) +{ + my ($cas, $ctime, $trcd, $trp, $tras) = @_; + + return $cas . "-" . ceil($trcd/$ctime - 0.025) . + "-" . ceil($trp/$ctime - 0.025) . + "-" . ceil($tras/$ctime - 0.025); +} + +use constant DDR4_UNBUFFERED => 1; +use constant DDR4_REGISTERED => 2; +use constant DDR4_LOAD_REDUCED => 4; + +# Parameter: EEPROM bytes 0-383 (using 1-255) +sub decode_ddr4_sdram($) +{ + my $bytes = shift; + my ($ctime, $ctime_max); + my ($ftb, $mtb); + my $ii; + + my @module_types = ( + { type => "Extended type", }, + { type => "RDIMM", family => DDR4_REGISTERED }, + { type => "UDIMM", family => DDR4_UNBUFFERED }, + { type => "SO-DIMM", family => DDR4_UNBUFFERED }, + { type => "LRDIMM", family => DDR4_LOAD_REDUCED }, + { type => "Mini-RDIMM", family => DDR4_REGISTERED }, + { type => "Mini-UDIMM", family => DDR4_UNBUFFERED }, + { type => "Reserved (0x07)", }, + { type => "72b-SO-RDIMM", family => DDR4_REGISTERED }, + { type => "72b-SO-UDIMM", family => DDR4_UNBUFFERED }, + { type => "Reserved (0x0A)", }, + { type => "Reserved (0x0B)", }, + { type => "16b-SO-DIMM", family => DDR4_UNBUFFERED }, + { type => "32b-SO-DIMM", family => DDR4_UNBUFFERED }, + { type => "Reserved (0x0E)", }, + { type => "No base memory", }, + ); + +# SPD revision + printl_cond($bytes->[1] != 0xff, "SPD Revision", + ($bytes->[1] >> 4) . "." . ($bytes->[1] & 0xf)); + + printl("Module Type", $module_types[$bytes->[3] & 0x0f]->{type}); + +# CRC of block 1 + my $crc_calc = calculate_crc($bytes, 128, 126); + my $crc_spd = ($bytes->[255] << 8) | $bytes->[254]; + my $crc_block_1_ok = $crc_calc == $crc_spd; + printl("EEPROM CRC of bytes 128-253", $crc_block_1_ok ? + sprintf("OK (0x\%04X)", $crc_calc) : + sprintf("Bad\n(found 0x\%04X, calculated 0x\%04X)", + $crc_spd, $crc_calc)); + +# time bases + if (($bytes->[17] & 0x03) != 0x00 || ($bytes->[17] & 0xc0) != 0x00) { + print STDERR "Unknown time base values, can't decode\n"; + return; + } + $ftb = 1; # ps + $mtb = 125; # ps + +# speed + prints("Memory Characteristics"); + + $ctime = ddr4_mtb_ftb($bytes->[18], $bytes->[125], $mtb, $ftb); + $ctime_max = ddr4_mtb_ftb($bytes->[19], $bytes->[124], $mtb, $ftb); + + my $ddrclk = 2 * (1000 / $ctime); + my $tbits = 8 << ($bytes->[13] & 7); + my $pcclk = int ($ddrclk * $tbits / 8); + # Round down to comply with Jedec + $pcclk = $pcclk - ($pcclk % 100); + $ddrclk = int ($ddrclk); + printl("Maximum module speed", "$ddrclk MHz (PC4-${pcclk})"); + +# Size computation + my $sdram_width = 4 << ($bytes->[12] & 0x07); + my $ranks = (($bytes->[12] >> 3) & 0x07) + 1; + my $signal_loading = $bytes->[6] & 0x03; + my $die_count = (($bytes->[6] >> 4) & 0x07) + 1; + my $cap = (256 << ($bytes->[4] & 0x0f)) / 8; + $cap *= (8 << ($bytes->[13] & 0x07)) / $sdram_width; + $cap *= $ranks; + $cap *= $die_count if $signal_loading == 0x02; # 3DS + printl("Size", $cap . " MB"); + + printl("Banks x Rows x Columns x Bits", + join(' x ', (1 << ($bytes->[4] >> 6)) * (4 << (($bytes->[4] >> 4) & 0x03)), + ((($bytes->[5] >> 3) & 7) + 12), + ( ($bytes->[5] & 7) + 9), + (8 << ($bytes->[13] & 0x07)))); + + printl("SDRAM Device Width", "$sdram_width bits"); + printl("Ranks", $ranks); + printl_cond($ranks > 1, "Rank Mix", + $bytes->[12] & 0x40 ? "Asymmetrical" : "Symmetrical"); + printl_cond($bytes->[13] & 0x18, "Bus Width Extension", ($bytes->[13] & 0x18)." bits"); + + my $taa; + my $trcd; + my $trp; + my $tras; + + $taa = ddr4_mtb_ftb($bytes->[24], $bytes->[123], $mtb, $ftb); + $trcd = ddr4_mtb_ftb($bytes->[25], $bytes->[122], $mtb, $ftb); + $trp = ddr4_mtb_ftb($bytes->[26], $bytes->[121], $mtb, $ftb); + $tras = ((($bytes->[27] & 0x0f) << 8) + $bytes->[28]) * $mtb / 1000; + + printl("AA-RCD-RP-RAS (cycles)", + ddr4_core_timings(ceil($taa/$ctime - 0.025), $ctime, + $trcd, $trp, $tras)); + +# latencies + my %cas; + my $cas_sup = ($bytes->[23] << 24) + ($bytes->[22] << 16) + + ($bytes->[21] << 8) + $bytes->[20]; + my $base_cas = $bytes->[23] & 0x80 ? 23 : 7; + + for ($ii = 0; $ii < 30; $ii++) { + if ($cas_sup & (1 << $ii)) { + $cas{$base_cas + $ii}++; + } + } + printl("Supported CAS Latencies", cas_latencies(keys %cas)); + +# standard DDR4 speeds + prints("Timings at Standard Speeds"); + foreach my $ctime_at_speed (15/24, 15/22, 15/20, 15/18, 15/16, 15/14, 15/12) { + my $best_cas = 0; + + # Find min CAS latency at this speed + for ($ii = 29; $ii >= 0; $ii--) { + next unless ($cas_sup & (1 << $ii)); + if (ceil($taa/$ctime_at_speed - 0.025) <= $base_cas + $ii) { + $best_cas = $base_cas + $ii; + } + } + + printl_cond($best_cas && $ctime_at_speed >= $ctime + && $ctime_at_speed <= $ctime_max, + "AA-RCD-RP-RAS (cycles)" . as_ddr(4, $ctime_at_speed), + ddr4_core_timings($best_cas, $ctime_at_speed, + $trcd, $trp, $tras)); + } + +# more timing information + prints("Timing Parameters"); + + printl("Minimum Cycle Time (tCKmin)", tns3($ctime)); + printl("Maximum Cycle Time (tCKmax)", tns3($ctime_max)); + printl("Minimum CAS Latency Time (tAA)", tns3($taa)); + printl("Minimum RAS to CAS Delay (tRCD)", tns3($trcd)); + printl("Minimum Row Precharge Delay (tRP)", tns3($trp)); + printl("Minimum Active to Precharge Delay (tRAS)", tns3($tras)); + printl("Minimum Active to Auto-Refresh Delay (tRC)", + tns3(ddr4_mtb_ftb((($bytes->[27] & 0xf0) << 4) + $bytes->[29], + $bytes->[120], $mtb, $ftb))); + printl("Minimum Recovery Delay (tRFC1)", + tns3((($bytes->[31] << 8) + $bytes->[30]) * $mtb / 1000)); + printl("Minimum Recovery Delay (tRFC2)", + tns3((($bytes->[33] << 8) + $bytes->[32]) * $mtb / 1000)); + printl("Minimum Recovery Delay (tRFC4)", + tns3((($bytes->[35] << 8) + $bytes->[34]) * $mtb / 1000)); + printl("Minimum Four Activate Window Delay (tFAW)", + tns3(((($bytes->[36] & 0x0f) << 8) + $bytes->[37]) * $mtb / 1000)); + printl("Minimum Row Active to Row Active Delay (tRRD_S)", + tns3(ddr4_mtb_ftb($bytes->[38], $bytes->[119], $mtb, $ftb))); + printl("Minimum Row Active to Row Active Delay (tRRD_L)", + tns3(ddr4_mtb_ftb($bytes->[39], $bytes->[118], $mtb, $ftb))); + printl("Minimum CAS to CAS Delay (tCCD_L)", + tns3(ddr4_mtb_ftb($bytes->[40], $bytes->[117], $mtb, $ftb))); + + # Optional? + my $twr = ((($bytes->[41] & 0x0f) << 8) + $bytes->[42]) * $mtb / 1000; + printl_cond($twr, "Minimum Write Recovery Time (tWR)", tns3($twr)); + my $twtr = ((($bytes->[43] & 0x0f) << 8) + $bytes->[44]) * $mtb / 1000; + printl_cond($twtr, "Minimum Write to Read Time (tWTR_S)", tns3($twtr)); + $twtr = ((($bytes->[43] & 0xf0) << 4) + $bytes->[45]) * $mtb / 1000; + printl_cond($twtr, "Minimum Write to Read Time (tWTR_L)", tns3($twtr)); + +# miscellaneous stuff + prints("Other Information"); + + my $package_type = ($bytes->[6] & 0x80) == 0x00 ? "Monolithic" : + $signal_loading == 0x01 ? "Multi-load stack" : + $signal_loading == 0x02 ? "3DS" : "Unknown"; + $package_type .= sprintf(" (%u dies)", $die_count) if $die_count >= 2; + printl("Package Type", $package_type); + + my @mac = ("Untested", + "700 K", "600 K", "500 K", "400 K", "300 K", "200 K", + undef, "Unlimited"); + my $mac = $bytes->[7] & 0x0f; + printl_cond(defined $mac[$mac], "Maximum Activate Count", $mac[$mac]); + + my $ppr = $bytes->[9] >> 6; + printl("Post Package Repair", + $ppr == 0x00 ? "Not supported" : + $ppr == 0x01 ? "One row per bank group" : "Unknown"); + printl_cond($ppr != 0x00, "Soft PPR", $bytes->[9] & 0x20 ? + "Supported" : "Not Supported"); + + printl("Module Nominal Voltage", + $bytes->[11] & 0x01 ? "1.2 V" : + $bytes->[11] & 0x02 ? "Unknown (1.2 V endurant)" : "Unknown"); + + printl("Thermal Sensor", + $bytes->[14] & 0x80 ? "TSE2004 compliant" : "No"); + +# type-specific settings + return unless $crc_block_1_ok || $opt_igncheck; + + if ($module_types[$bytes->[3] & 0x0f]->{family} == DDR4_UNBUFFERED || + $module_types[$bytes->[3] & 0x0f]->{family} == DDR4_REGISTERED || + $module_types[$bytes->[3] & 0x0f]->{family} == DDR4_LOAD_REDUCED) { + prints("Physical Characteristics"); + + my $height = $bytes->[128] & 0x1f; + printl("Module Height", + $height == 0x00 ? "15 mm or less" : + $height == 0x1f ? "more than 45 mm" : + sprintf("%u mm", $height + 15)); + printl("Module Thickness", + sprintf("%d mm front, %d mm back", + ($bytes->[129] & 0x0f) + 1, + (($bytes->[129] >> 4) & 15) + 1)); + printl("Module Reference Card", + ddr3_reference_card($bytes->[130], $bytes->[128])); + } +} + # Parameter: EEPROM bytes 0-127 (using 4-5) sub decode_direct_rambus($) { @@ -1747,6 +1993,10 @@ sub decode_rambus($) "DDR SDRAM" => \&decode_ddr_sdram, "DDR2 SDRAM" => \&decode_ddr2_sdram, "DDR3 SDRAM" => \&decode_ddr3_sdram, + "DDR4 SDRAM" => \&decode_ddr4_sdram, + "DDR4E SDRAM" => \&decode_ddr4_sdram, + "LPDDR4 SDRAM" => \&decode_ddr4_sdram, + "LPDDR4X SDRAM" => \&decode_ddr4_sdram, "Direct Rambus" => \&decode_direct_rambus, "Rambus" => \&decode_rambus, ); @@ -1819,6 +2069,35 @@ sub decode_ddr3_mfg_data($) sprintf("0x%02X%02X", $bytes->[146], $bytes->[147])); } +# Parameter: EEPROM bytes 0-383 (using 320-351) +sub decode_ddr4_mfg_data($) +{ + my $bytes = shift; + + prints("Manufacturer Data"); + + printl("Module Manufacturer", + manufacturer_ddr3($bytes->[320], $bytes->[321])); + + printl_cond(spd_written(@{$bytes}[350..351]), + "DRAM Manufacturer", + manufacturer_ddr3($bytes->[350], $bytes->[351])); + + printl_mfg_location_code($bytes->[322]); + + printl_cond(spd_written(@{$bytes}[323..324]), + "Manufacturing Date", + manufacture_date($bytes->[323], $bytes->[324])); + + printl_mfg_assembly_serial(@{$bytes}[325..328]); + + printl("Part Number", part_number(@{$bytes}[329..348])); + + printl_cond(spd_written(@{$bytes}[349]), + "Revision Code", + sprintf("0x%02X", $bytes->[349])); +} + # Parameter: EEPROM bytes 0-127 (using 64-98) sub decode_manufacturing_information($) { @@ -1941,8 +2220,14 @@ sub read_hexdump($) sub spd_sizes($) { my $bytes = shift; + my $type = $bytes->[2]; - if ($bytes->[2] >= 9) { + if ($type == 12 || $type == 14 || $type == 16 || $type == 17) { + # DDR4 + my $spd_len = 256 * (($bytes->[0] >> 4) & 7); + my $used = 128 * ($bytes->[0] & 15); + return ($spd_len, $used); + } elsif ($type >= 9) { # For FB-DIMM and newer, decode number of bytes written my $spd_len = ($bytes->[0] >> 4) & 7; my $size = 64 << ($bytes->[0] & 15); @@ -2014,15 +2299,14 @@ sub checksum($) } # Calculate and verify CRC -sub check_crc($) +sub calculate_crc($$$) { - my $bytes = shift; + my ($bytes, $start, $len) = @_; my $crc = 0; - my $crc_cover = $bytes->[0] & 0x80 ? 116 : 125; - my $crc_ptr = 0; + my $crc_ptr = $start; my $crc_bit; - while ($crc_ptr <= $crc_cover) { + while ($crc_ptr < $start + $len) { $crc = $crc ^ ($bytes->[$crc_ptr] << 8); for ($crc_bit = 0; $crc_bit < 8; $crc_bit++) { if ($crc & 0x8000) { @@ -2033,7 +2317,15 @@ sub check_crc($) } $crc_ptr++; } - $crc &= 0xffff; + + return $crc & 0xffff; +} + +sub check_crc($) +{ + my $bytes = shift; + my $crc_cover = $bytes->[0] & 0x80 ? 116 : 125; + my $crc = calculate_crc($bytes, 0, $crc_cover + 1); my $dimm_crc = ($bytes->[127] << 8) | $bytes->[126]; return ("EEPROM CRC of bytes 0-$crc_cover", @@ -2136,7 +2428,9 @@ sub get_dimm_list my (@dirs, $dir, $opened, $file, @files); if ($use_sysfs) { - @dirs = ('/sys/bus/i2c/drivers/eeprom', '/sys/bus/i2c/drivers/at24'); + @dirs = ('/sys/bus/i2c/drivers/eeprom', + '/sys/bus/i2c/drivers/at24', + '/sys/bus/i2c/drivers/ee1004'); # DDR4 } else { @dirs = ('/proc/sys/dev/sensors'); } @@ -2154,7 +2448,9 @@ sub get_dimm_list # or spd (driver at24) my $attr = sysfs_device_attribute("$dir/$file", "name"); next unless defined $attr && - ($attr eq "eeprom" || $attr eq "spd"); + ($attr eq "eeprom" || + $attr eq "spd" || + $attr eq "ee1004"); # DDR4 } else { next unless $file =~ /^eeprom-/; } @@ -2285,6 +2581,9 @@ for $current (0 .. $#dimm) { "DDR SGRAM", "DDR SDRAM", # 6, 7 "DDR2 SDRAM", "FB-DIMM", # 8, 9 "FB-DIMM Probe", "DDR3 SDRAM", # 10, 11 + "DDR4 SDRAM", "Reserved", # 12, 13 + "DDR4E SDRAM", "LPDDR3 SDRAM", # 14, 15 + "LPDDR4 SDRAM", "LPDDR4X SDRAM", # 16, 17 ); if ($bytes[2] < @type_list) { $type = $type_list[$bytes[2]]; @@ -2300,6 +2599,13 @@ for $current (0 .. $#dimm) { # Decode DDR3-specific manufacturing data in bytes # 117-149 decode_ddr3_mfg_data(\@bytes) + } elsif ($type eq "DDR4 SDRAM" || + $type eq "DDR4E SDRAM" || + $type eq "LPDDR4 SDRAM" || + $type eq "LPDDR4X SDRAM") { + # Decode DDR4-specific manufacturing data in bytes + # 320-383 + decode_ddr4_mfg_data(\@bytes) } else { # Decode next 35 bytes (64-98, common to most # memory types) --- a/eeprom/decode-dimms.1 +++ b/eeprom/decode-dimms.1 @@ -1,6 +1,7 @@ .\" .\" decode-dimms.1 - manpage for the i2c-tools/decode-dimms utility .\" Copyright (C) 2013 Jaromir Capik +.\" Copyright (C) 2017 Jean Delvare .\" .\" 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 @@ -16,7 +17,7 @@ .\" with this program; if not, write to the Free Software Foundation, Inc., .\" 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA. .\" -.TH decode-dimms 1 "Oct 2013" "i2c-tools" "User Commands" +.TH decode-dimms 1 "Nov 2017" "i2c-tools" "User Commands" .SH NAME decode-dimms \- decode the information found in memory module SPD EEPROMs .SH SYNOPSIS @@ -31,8 +32,8 @@ The purpose of the .B decode-dimms tool is to decode the information found in memory module SPD EEPROMs. The SPD data is read either from the running system or dump files. -In the former case, the tool requires either the eeprom kernel module -or the at24 kernel module to be loaded. +In the former case, the tool requires a kernel module to be loaded: +eeprom, at24 or ee1004 (for DDR4 SDRAM.) .SH PARAMETERS .TP .B \-f, --format
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