diff --git a/tests/avocado/acpi-bits/bits-tests/smbios.py2 b/tests/avocado/acpi-bits/bits-tests/smbios.py2 new file mode 100644 index 0000000000..9667d0542c --- /dev/null +++ b/tests/avocado/acpi-bits/bits-tests/smbios.py2 @@ -0,0 +1,2430 @@ +# Copyright (c) 2015, Intel Corporation +# All rights reserved. +# +# Redistribution and use in source and binary forms, with or without +# modification, are permitted provided that the following conditions are met: +# +# * Redistributions of source code must retain the above copyright notice, +# this list of conditions and the following disclaimer. +# * Redistributions in binary form must reproduce the above copyright notice, +# this list of conditions and the following disclaimer in the documentation +# and/or other materials provided with the distribution. +# * Neither the name of Intel Corporation nor the names of its contributors +# may be used to endorse or promote products derived from this software +# without specific prior written permission. +# +# THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND +# ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED +# WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE +# DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR +# ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES +# (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; +# LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON +# ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT +# (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS +# SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. + +"""SMBIOS/DMI module.""" + +import bits +import bitfields +import ctypes +import redirect +import struct +import uuid +import unpack +import ttypager +import sys + +class SMBIOS(unpack.Struct): + def __new__(cls): + if sys.platform == "BITS-EFI": + import efi + sm_ptr = efi.system_table.ConfigurationTableDict.get(efi.SMBIOS_TABLE_GUID) + else: + address = 0xF0000 + mem = bits.memory(0xF0000, 0x10000) + for offset in range(0, len(mem), 16): + signature = (ctypes.c_char * 4).from_address(address + offset).value + if signature == "_SM_": + entry_point_length = ctypes.c_ubyte.from_address(address + offset + 5).value + csum = sum(map(ord, mem[offset:offset + entry_point_length])) & 0xff + if csum == 0: + sm_ptr = address + offset + break + else: + return None + + if not sm_ptr: + return None + + sm = super(SMBIOS, cls).__new__(cls) + sm._header_memory = bits.memory(sm_ptr, 0x1f) + return sm + + def __init__(self): + super(SMBIOS, self).__init__() + u = unpack.Unpackable(self._header_memory) + self.add_field('header', Header(u)) + self._structure_memory = bits.memory(self.header.structure_table_address, self.header.structure_table_length) + u = unpack.Unpackable(self._structure_memory) + self.add_field('structures', unpack.unpack_all(u, _smbios_structures, self), unpack.format_each("\n\n{!r}")) + + def structure_type(self, num): + '''Dumps structure of given Type if present''' + try: + types_present = [self.structures[x].smbios_structure_type for x in range(len(self.structures))] + matrix = dict() + for index in range(len(types_present)): + if types_present.count(types_present[index]) == 1: + matrix[types_present[index]] = self.structures[index] + else: # if multiple structures of the same type, return a list of structures for the type number + if matrix.has_key(types_present[index]): + matrix[types_present[index]].append(self.structures[index]) + else: + matrix[types_present[index]] = [self.structures[index]] + return matrix[num] + except: + print "Failure: Type {} - not found".format(num) + +class Header(unpack.Struct): + def __new__(cls, u): + return super(Header, cls).__new__(cls) + + def __init__(self, u): + super(Header, self).__init__() + self.raw_data = u.unpack_rest() + u = unpack.Unpackable(self.raw_data) + self.add_field('anchor_string', u.unpack_one("4s")) + self.add_field('checksum', u.unpack_one("B")) + self.add_field('length', u.unpack_one("B")) + self.add_field('major_version', u.unpack_one("B")) + self.add_field('minor_version', u.unpack_one("B")) + self.add_field('max_structure_size', u.unpack_one(" len(self.strings): + return "(error: string index out of range)" + return self.strings[i - 1] + +class BIOSInformation(SmbiosBaseStructure): + smbios_structure_type = 0 + + def __init__(self, u, sm): + super(BIOSInformation, self).__init__(u, sm) + u = self.u + try: + self.add_field('vendor', u.unpack_one("B"), self.fmtstr) + self.add_field('version', u.unpack_one("B"), self.fmtstr) + self.add_field('starting_address_segment', u.unpack_one("= (2,"4"): + characteristic_bytes = 2 + else: + characteristic_bytes = self.length - 0x12 + self.add_field('characteristics_extensions', [u.unpack_one("B") for b in range(characteristic_bytes)]) + if (sm.header.major_version, minor_version_str) >= (2,"4"): + self.add_field('major_release', u.unpack_one("B")) + self.add_field('minor_release', u.unpack_one("B")) + self.add_field('ec_major_release', u.unpack_one("B")) + self.add_field('ec_minor_release', u.unpack_one("B")) + except: + self.decode_failure = True + print "Error parsing BIOSInformation" + import traceback + traceback.print_exc() + self.fini() + +class SystemInformation(SmbiosBaseStructure): + smbios_structure_type = 1 + + def __init__(self, u, sm): + super(SystemInformation, self).__init__(u, sm) + u = self.u + try: + self.add_field('manufacturer', u.unpack_one("B"), self.fmtstr) + self.add_field('product_name', u.unpack_one("B"), self.fmtstr) + self.add_field('version', u.unpack_one("B"), self.fmtstr) + self.add_field('serial_number', u.unpack_one("B"), self.fmtstr) + if self.length > 0x8: + self.add_field('uuid', uuid.UUID(bytes_le=u.unpack_one("16s"))) + wakeup_types = { + 0: 'Reserved', + 1: 'Other', + 2: 'Unknown', + 3: 'APM Timer', + 4: 'Modem Ring', + 5: 'LAN Remote', + 6: 'Power Switch', + 7: 'PCI PME#', + 8: 'AC Power Restored' + } + self.add_field('wakeup_type', u.unpack_one("B"), unpack.format_table("{}", wakeup_types)) + if self.length > 0x19: + self.add_field('sku_number', u.unpack_one("B"), self.fmtstr) + self.add_field('family', u.unpack_one("B"), self.fmtstr) + except: + self.decode_failure = True + print "Error parsing SystemInformation" + import traceback + traceback.print_exc() + self.fini() + +_board_types = { + 1: 'Unknown', + 2: 'Other', + 3: 'Server Blade', + 4: 'Connectivity Switch', + 5: 'System Management Module', + 6: 'Processor Module', + 7: 'I/O Module', + 8: 'Memory Module', + 9: 'Daughter Board', + 0xA: 'Motherboard', + 0xB: 'Processor/Memory Module', + 0xC: 'Processor/IO Module', + 0xD: 'Interconnect Board' +} + +class BaseboardInformation(SmbiosBaseStructure): + smbios_structure_type = 2 + + def __init__(self, u, sm): + super(BaseboardInformation, self).__init__(u, sm) + u = self.u + try: + self.add_field('manufacturer', u.unpack_one("B"), self.fmtstr) + self.add_field('product', u.unpack_one("B"), self.fmtstr) + self.add_field('version', u.unpack_one("B"), self.fmtstr) + self.add_field('serial_number', u.unpack_one("B"), self.fmtstr) + + if self.length > 0x8: + self.add_field('asset_tag', u.unpack_one("B"), self.fmtstr) + + if self.length > 0x9: + self.add_field('feature_flags', u.unpack_one("B")) + self.add_field('hosting_board', bool(bitfields.getbits(self.feature_flags, 0)), "feature_flags[0]={}") + self.add_field('requires_daughter_card', bool(bitfields.getbits(self.feature_flags, 1)), "feature_flags[1]={}") + self.add_field('removable', bool(bitfields.getbits(self.feature_flags, 2)), "feature_flags[2]={}") + self.add_field('replaceable', bool(bitfields.getbits(self.feature_flags, 3)), "feature_flags[3]={}") + self.add_field('hot_swappable', bool(bitfields.getbits(self.feature_flags, 4)), "feature_flags[4]={}") + + if self.length > 0xA: + self.add_field('location', u.unpack_one("B"), self.fmtstr) + + if self.length > 0xB: + self.add_field('chassis_handle', u.unpack_one(" 0xD: + self.add_field('board_type', u.unpack_one("B"), unpack.format_table("{}", _board_types)) + + if self.length > 0xE: + self.add_field('handle_count', u.unpack_one("B")) + if self.handle_count > 0: + self.add_field('contained_object_handles', tuple(u.unpack_one(" 9: + chassis_states = { + 0x01: 'Other', + 0x02: 'Unknown', + 0x03: 'Safe', + 0x04: 'Warning', + 0x05: 'Critical', + 0x06: 'Non-recoverable', + } + self.add_field('bootup_state', u.unpack_one("B"), unpack.format_table("{}", chassis_states)) + self.add_field('power_supply_state', u.unpack_one("B"), unpack.format_table("{}", chassis_states)) + self.add_field('thermal_state', u.unpack_one("B"), unpack.format_table("{}", chassis_states)) + security_states = { + 0x01: 'Other', + 0x02: 'Unknown', + 0x03: 'None', + 0x04: 'External interface locked out', + 0x05: 'External interface enabled', + } + self.add_field('security_status', u.unpack_one("B"), unpack.format_table("{}", security_states)) + if self.length > 0xd: + self.add_field('oem_defined', u.unpack_one(" 0x11: + self.add_field('height', u.unpack_one("B")) + self.add_field('num_power_cords', u.unpack_one("B")) + self.add_field('contained_element_count', u.unpack_one("B")) + self.add_field('contained_element_length', u.unpack_one("B")) + if getattr(self, 'contained_element_count', 0): + self.add_field('contained_elements', tuple(SystemEnclosureContainedElement(u, self.contained_element_length) for i in range(self.contained_element_count))) + if self.length > (0x15 + (getattr(self, 'contained_element_count', 0) * getattr(self, 'contained_element_length', 0))): + self.add_field('sku_number', u.unpack_one("B"), self.fmtstr) + except: + self.decode_failure = True + print "Error parsing SystemEnclosure" + import traceback + traceback.print_exc() + self.fini() + +class SystemEnclosureContainedElement(unpack.Struct): + def __init__(self, u, length): + super(SystemEnclosureContainedElement, self).__init__() + self.start_offset = u.offset + self.raw_data = u.unpack_raw(length) + self.u = unpack.Unpackable(self.raw_data) + u = self.u + self.add_field('contained_element_type', u.unpack_one("B")) + type_selections = { + 0: 'SMBIOS baseboard type enumeration', + 1: 'SMBIOS structure type enumeration', + } + self.add_field('type_select', bitfields.getbits(self.contained_element_type, 7), unpack.format_table("contained_element_type[7]={}", type_selections)) + self.add_field('type', bitfields.getbits(self.contained_element_type, 6, 0)) + if self.type_select == 0: + self.add_field('smbios_board_type', self.type, unpack.format_table("{}", _board_types)) + else: + self.add_field('smbios_structure_type', self.type) + self.add_field('minimum', u.unpack_one("B")) + self.add_field('maximum', u.unpack_one("B")) + if not u.at_end(): + self.add_field('data', u.unpack_rest()) + del self.u + +class ProcessorInformation(SmbiosBaseStructure): + smbios_structure_type = 4 + + def __init__(self, u, sm): + super(ProcessorInformation, self).__init__(u, sm) + u = self.u + try: + self.add_field('socket_designation', u.unpack_one("B"), self.fmtstr) + processor_types = { + 0x01: 'Other', + 0x02: 'Unknown', + 0x03: 'Central Processor', + 0x04: 'Math Processor', + 0x05: 'DSP Processor', + 0x06: 'Video Processor', + } + self.add_field('processor_type', u.unpack_one("B"), unpack.format_table("{}", processor_types)) + self.add_field('processor_family', u.unpack_one("B")) + self.add_field('processor_manufacturer', u.unpack_one("B"), self.fmtstr) + self.add_field('processor_id', u.unpack_one(" 0x1A: + self.add_field('l1_cache_handle', u.unpack_one(" 0x20: + self.add_field('serial_number', u.unpack_one("B"), self.fmtstr) + self.add_field('asset_tag', u.unpack_one("B"), self.fmtstr) + self.add_field('part_number', u.unpack_one("B"), self.fmtstr) + if self.length > 0x24: + self.add_field('core_count', u.unpack_one("B")) + self.add_field('core_enabled', u.unpack_one("B")) + self.add_field('thread_count', u.unpack_one("B")) + self.add_field('processor_characteristics', u.unpack_one(" 0x28: + self.add_field('processor_family_2', u.unpack_one(" 0x2A: + self.add_field('core_count2', u.unpack_one(" 0x0F: + self.add_field('cache_speed', u.unpack_one("B")) + if self.length > 0x10: + _error_correction = { + 0x01: 'Other', + 0x02: 'Unknown', + 0x03: 'None', + 0x04: 'Parity', + 0x05: 'Single-bit ECC', + 0x06: 'Multi-bit ECC' + } + self.add_field('error_correction', u.unpack_one("B"), unpack.format_table("{}", _error_correction)) + if self.length > 0x10: + _system_cache_type = { + 0x01: 'Other', + 0x02: 'Unknown', + 0x03: 'Instruction', + 0x04: 'Data', + 0x05: 'Unified' + } + self.add_field('system_cache_type', u.unpack_one("B"), unpack.format_table("{}", _system_cache_type)) + if self.length > 0x12: + _associativity = { + 0x01: 'Other', + 0x02: 'Unknown', + 0x03: 'Direct Mapped', + 0x04: '2-way Set-Associative', + 0x05: '4-way Set-Associative', + 0x06: 'Fully Associative', + 0x07: '8-way Set-Associative', + 0x08: '16-way Set-Associative', + 0x09: '12-way Set-Associative', + 0x0A: '24-way Set-Associative', + 0x0B: '32-way Set-Associative', + 0x0C: '48-way Set-Associative', + 0x0D: '64-way Set-Associative', + 0x0E: '20-way Set-Associative' + } + self.add_field('associativity', u.unpack_one("B"), unpack.format_table("{}", _associativity)) + + except: + self.decode_failure = True + print "Error parsing CacheInformation" + import traceback + traceback.print_exc() + self.fini() + +class PortConnectorInfo(SmbiosBaseStructure): + smbios_structure_type = 8 + + def __init__(self, u, sm): + super(PortConnectorInfo, self).__init__(u, sm) + u = self.u + try: + self.add_field('internal_reference_designator', u.unpack_one("B"), self.fmtstr) + connector_types = { + 0x00: 'None', + 0x01: 'Centronics', + 0x02: 'Mini Centronics', + 0x03: 'Proprietary', + 0x04: 'DB-25 pin male', + 0x05: 'DB-25 pin female', + 0x06: 'DB-15 pin male', + 0x07: 'DB-15 pin female', + 0x08: 'DB-9 pin male', + 0x09: 'DB-9 pin female', + 0x0A: 'RJ-11', + 0x0B: 'RJ-45', + 0x0C: '50-pin MiniSCSI', + 0x0D: 'Mini-DIN', + 0x0E: 'Micro-DIN', + 0x0F: 'PS/2', + 0x10: 'Infrared', + 0x11: 'HP-HIL', + 0x12: 'Access Bus (USB)', + 0x13: 'SSA SCSI', + 0x14: 'Circular DIN-8 male', + 0x15: 'Circular DIN-8 female', + 0x16: 'On Board IDE', + 0x17: 'On Board Floppy', + 0x18: '9-pin Dual Inline (pin 10 cut)', + 0x19: '25-pin Dual Inline (pin 26 cut)', + 0x1A: '50-pin Dual Inline', + 0x1B: '68-pin Dual Inline', + 0x1C: 'On Board Sound Input from CD-ROM', + 0x1D: 'Mini-Centronics Type-14', + 0x1E: 'Mini-Centronics Type-26', + 0x1F: 'Mini-jack (headphones)', + 0x20: 'BNC', + 0x21: '1394', + 0x22: 'SAS/SATA Plug Receptacle', + 0xA0: 'PC-98', + 0xA1: 'PC-98Hireso', + 0xA2: 'PC-H98', + 0xA3: 'PC-98Note', + 0xA4: 'PC-98Full', + 0xFF: 'Other', + } + self.add_field('internal_connector_type', u.unpack_one("B"), unpack.format_table("{}", connector_types)) + self.add_field('external_reference_designator', u.unpack_one("B"), self.fmtstr) + self.add_field('external_connector_type', u.unpack_one("B"), unpack.format_table("{}", connector_types)) + port_types = { + 0x00: 'None', + 0x01: 'Parallel Port XT/AT Compatible', + 0x02: 'Parallel Port PS/2', + 0x03: 'Parallel Port ECP', + 0x04: 'Parallel Port EPP', + 0x05: 'Parallel Port ECP/EPP', + 0x06: 'Serial Port XT/AT Compatible', + 0x07: 'Serial Port 16450 Compatible', + 0x08: 'Serial Port 16550 Compatible', + 0x09: 'Serial Port 16550A Compatible', + 0x0A: 'SCSI Port', + 0x0B: 'MIDI Port', + 0x0C: 'Joy Stick Port', + 0x0D: 'Keyboard Port', + 0x0E: 'Mouse Port', + 0x0F: 'SSA SCSI', + 0x10: 'USB', + 0x11: 'FireWire (IEEE P1394)', + 0x12: 'PCMCIA Type I2', + 0x13: 'PCMCIA Type II', + 0x14: 'PCMCIA Type III', + 0x15: 'Cardbus', + 0x16: 'Access Bus Port', + 0x17: 'SCSI II', + 0x18: 'SCSI Wide', + 0x19: 'PC-98', + 0x1A: 'PC-98-Hireso', + 0x1B: 'PC-H98', + 0x1C: 'Video Port', + 0x1D: 'Audio Port', + 0x1E: 'Modem Port', + 0x1F: 'Network Port', + 0x20: 'SATA', + 0x21: 'SAS', + 0xA0: '8251 Compatible', + 0xA1: '8251 FIFO Compatible', + 0xFF: 'Other', + } + self.add_field('port_type', u.unpack_one("B"), unpack.format_table("{}", port_types)) + except: + self.decodeFailure = True + print "Error parsing PortConnectorInfo" + import traceback + traceback.print_exc() + self.fini() + +class SystemSlots(SmbiosBaseStructure): + smbios_structure_type = 9 + + def __init__(self, u, sm): + super(SystemSlots, self).__init__(u, sm) + u = self.u + try: + self.add_field('designation', u.unpack_one("B"), self.fmtstr) + _slot_types = { + 0x01: 'Other', + 0x02: 'Unknown', + 0x03: 'ISA', + 0x04: 'MCA', + 0x05: 'EISA', + 0x06: 'PCI', + 0x07: 'PC Card (PCMCIA)', + 0x08: 'VL-VESA', + 0x09: 'Proprietary', + 0x0A: 'Processor Card Slot', + 0x0B: 'Proprietary Memory Card Slot', + 0x0C: 'I/O Riser Card Slot', + 0x0D: 'NuBus', + 0x0E: 'PCI 66MHz Capable', + 0x0F: 'AGP', + 0x10: 'AGP 2X', + 0x11: 'AGP 4X', + 0x12: 'PCI-X', + 0x13: 'AGP 8X', + 0xA0: 'PC-98/C20', + 0xA1: 'PC-98/C24', + 0xA2: 'PC-98/E', + 0xA3: 'PC-98/Local Bus', + 0xA4: 'PC-98/Card', + 0xA5: 'PCI Express', + 0xA6: 'PCI Express x1', + 0xA7: 'PCI Express x2', + 0xA8: 'PCI Express x4', + 0xA9: 'PCI Express x8', + 0xAA: 'PCI Express x16', + 0xAB: 'PCI Express Gen 2', + 0xAC: 'PCI Express Gen 2 x1', + 0xAD: 'PCI Express Gen 2 x2', + 0xAE: 'PCI Express Gen 2 x4', + 0xAF: 'PCI Express Gen 2 x8', + 0xB0: 'PCI Express Gen 2 x16', + 0xB1: 'PCI Express Gen 3', + 0xB2: 'PCI Express Gen 3 x1', + 0xB3: 'PCI Express Gen 3 x2', + 0xB4: 'PCI Express Gen 3 x4', + 0xB5: 'PCI Express Gen 3 x8', + 0xB6: 'PCI Express Gen 3 x16', + } + self.add_field('slot_type', u.unpack_one("B"), unpack.format_table("{}", _slot_types)) + _slot_data_bus_widths = { + 0x01: 'Other', + 0x02: 'Unknown', + 0x03: '8 bit', + 0x04: '16 bit', + 0x05: '32 bit', + 0x06: '64 bit', + 0x07: '128 bit', + 0x08: '1x or x1', + 0x09: '2x or x2', + 0x0A: '4x or x4', + 0x0B: '8x or x8', + 0x0C: '12x or x12', + 0x0D: '16x or x16', + 0x0E: '32x or x32', + } + self.add_field('slot_data_bus_width', u.unpack_one('B'), unpack.format_table("{}", _slot_data_bus_widths)) + _current_usages = { + 0x01: 'Other', + 0x02: 'Unknown', + 0x03: 'Available', + 0x04: 'In use', + } + self.add_field('current_usage', u.unpack_one('B'), unpack.format_table("{}", _current_usages)) + _slot_lengths = { + 0x01: 'Other', + 0x02: 'Unknown', + 0x03: 'Short Length', + 0x04: 'Long Length', + } + self.add_field('slot_length', u.unpack_one('B'), unpack.format_table("{}", _slot_lengths)) + self.add_field('slot_id', u.unpack_one(' 0x0C: + self.add_field('characteristics2', u.unpack_one('B')) + self.add_field('supports_PME', bool(bitfields.getbits(self.characteristics2, 0)), "characteristics2[0]={}") + self.add_field('supports_hot_plug', bool(bitfields.getbits(self.characteristics2, 1)), "characteristics2[1]={}") + self.add_field('supports_smbus', bool(bitfields.getbits(self.characteristics2, 2)), "characteristics2[2]={}") + if self.length > 0x0D: + self.add_field('segment_group_number', u.unpack_one(' 0x05: + self.add_field('flags', u.unpack_one('B')) + self.add_field('abbreviated_format', bool(bitfields.getbits(self.flags, 0)), "flags[0]={}") + if self.length > 0x6: + u.skip(15) + self.add_field('current_language', u.unpack_one('B'), self.fmtstr) + except: + self.decodeFailure = True + print "Error parsing BIOSLanguageInformation" + import traceback + traceback.print_exc() + self.fini() + +class GroupAssociations(SmbiosBaseStructure): + smbios_structure_type = 14 + + def __init__(self, u, sm): + super(GroupAssociations, self).__init__(u, sm) + u = self.u + try: + self.add_field('group_name', u.unpack_one("B"), self.fmtstr) + self.add_field('item_type', u.unpack_one('B')) + self.add_field('item_handle', u.unpack_one(' 0x14: + _log_header_formats = { + 0: 'No header', + 1: 'Type 1 log header', + xrange(2, 0x7f): 'Available for future assignment', + xrange(0x80, 0xff): 'BIOS vendor or OEM-specific format' + } + self.add_field('log_header_format', u.unpack_one("B"), unpack.format_table("{}", _log_header_formats)) + if self.length > 0x15: + self.add_field('num_supported_log_type_descriptors', u.unpack_one('B')) + if self.length > 0x16: + self.add_field('length_log_type_descriptor', u.unpack_one('B')) + if self.length != (0x17 + (self.num_supported_log_type_descriptors * self.length_log_type_descriptor)): + print "Error: structure length ({}) != 0x17 + (num_supported_log_type_descriptors ({}) * length_log_type_descriptor({}))".format(self.length, self.num_supported_log_type_descriptors, self.length_log_type_descriptor) + print "structure length = {}".format(self.length) + print "num_supported_log_type_descriptors = {}".format(self.num_supported_log_type_descriptors) + print "length_log_type_descriptor = {}".format(self.length_log_type_descriptor) + self.decodeFailure = True + self.add_field('descriptors', tuple(EventLogDescriptor.unpack(u) for i in range(self.num_supported_log_type_descriptors)), unpack.format_each("\n{!r}")) + except: + self.decodeFailure = True + print "Error parsing SystemEventLog" + import traceback + traceback.print_exc() + self.fini() + +class EventLogDescriptor(unpack.Struct): + @staticmethod + def _unpack(u): + _event_log_type_descriptors = { + 0x00: 'Reserved', + 0x01: 'Single-bit ECC memory error', + 0x02: 'Multi-bit ECC memory error', + 0x03: 'Parity memory error', + 0x04: 'Bus time-out', + 0x05: 'I/O Channel Check', + 0x06: 'Software NMI', + 0x07: 'POST Memory Resize', + 0x08: 'POST Error', + 0x09: 'PCI Parity Error', + 0x0A: 'PCI System Error', + 0x0B: 'CPU Failure', + 0x0C: 'EISA FailSafe Timer time-out', + 0x0D: 'Correctable memory log disabled', + 0x0E: 'Logging disabled for a specific Event Type - too many errors of the same type received in a short amount of time', + 0x0F: 'Reserved', + 0x10: 'System Limit Exceeded', + 0x11: 'Asynchronous hardware timer expired and issued a system reset', + 0x12: 'System configuration information', + 0x13: 'Hard-disk information', + 0x14: 'System reconfigured', + 0x15: 'Uncorrectable CPU-complex error', + 0x16: 'Log Area Reset/Cleared', + 0x17: 'System boot', + xrange(0x18, 0x7F): 'Unused, available for assignment', + xrange(0x80, 0xFE): 'Availalbe for system- and OEM-specific assignments', + 0xFF: 'End of log' + } + yield 'log_type', u.unpack_one('B'), unpack.format_table("{}", _event_log_type_descriptors) + _event_log_format = { + 0x00: 'None', + 0x01: 'Handle', + 0x02: 'Multiple-Event', + 0x03: 'Multiple-Event Handle', + 0x04: 'POST Results Bitmap', + 0x05: 'System Management Type', + 0x06: 'Multiple-Event System Management Type', + xrange(0x80, 0xFF): 'OEM assigned' + } + yield 'variable_data_format_type', u.unpack_one('B'), unpack.format_table("{}", _event_log_format) + +class PhysicalMemoryArray(SmbiosBaseStructure): + smbios_structure_type = 16 + + def __init__(self, u, sm): + super(PhysicalMemoryArray, self).__init__(u, sm) + u = self.u + try: + if self.length > 0x4: + _location_field = { + 0x01: "Other", + 0x02: "Unknown", + 0x03: "System board or motherboard", + 0x04: "ISA add-on card", + 0x05: "EISA add-on card", + 0x06: "PCI add-on card", + 0x07: "MCA add-on card", + 0x08: "PCMCIA add-on card", + 0x09: "Proprietary add-on card", + 0x0A: "NuBus", + 0xA0: "PC-98/C20 add-on card", + 0xA1: "PC-98/C24 add-on card", + 0xA2: "PC-98/E add-on card", + 0xA3: "PC-98/Local bus add-on card" + } + self.add_field('location', u.unpack_one("B"), unpack.format_table("{}", _location_field)) + if self.length > 0x05: + _use = { + 0x01: "Other", + 0x02: "Unknown", + 0x03: "System memory", + 0x04: "Video memory", + 0x05: "Flash memory", + 0x06: "Non-volatile RAM", + 0x07: "Cache memory" + } + self.add_field('use', u.unpack_one('B'), unpack.format_table("{}", _use)) + if self.length > 0x06: + _error_correction = { + 0x01: "Other", + 0x02: "Unknown", + 0x03: "None", + 0x04: "Parity", + 0x05: "Single-bit ECC", + 0x06: "Multi-bit ECC", + 0x07: "CRC" + } + self.add_field('memory_error_correction', u.unpack_one('B'), unpack.format_table("{}", _error_correction)) + if self.length > 0x07: + self.add_field('maximum_capacity', u.unpack_one(' 0x0B: + self.add_field('memory_error_information_handle', u.unpack_one(' 0x0D: + self.add_field('num_memory_devices', u.unpack_one(' 0x0F: + self.add_field('extended_maximum_capacity', u.unpack_one(' 0x4: + self.add_field('physical_memory_array_handle', u.unpack_one(" 0x6: + self.add_field('memory_error_information_handle', u.unpack_one(" 0x8: + self.add_field('total_width', u.unpack_one(" 0xA: + self.add_field('data_width', u.unpack_one(" 0xC: + self.add_field('size', u.unpack_one(" 0xE: + _form_factors = { + 0x01: 'Other', + 0x02: 'Unknown', + 0x03: 'SIMM', + 0x04: 'SIP', + 0x05: 'Chip', + 0x06: 'DIP', + 0x07: 'ZIP', + 0x08: 'Proprietary Card', + 0x09: 'DIMM', + 0x0A: 'TSOP', + 0x0B: 'Row of chips', + 0x0C: 'RIMM', + 0x0D: 'SODIMM', + 0x0E: 'SRIMM', + 0x0F: 'FB-DIMM' + } + self.add_field('form_factor', u.unpack_one("B"), unpack.format_table("{}", _form_factors)) + if self.length > 0xF: + self.add_field('device_set', u.unpack_one("B")) + if self.length > 0x10: + self.add_field('device_locator', u.unpack_one("B"), self.fmtstr) + if self.length > 0x11: + self.add_field('bank_locator', u.unpack_one("B"), self.fmtstr) + if self.length > 0x12: + _memory_types = { + 0x01: 'Other', + 0x02: 'Unknown', + 0x03: 'DRAM', + 0x04: 'EDRAM', + 0x05: 'VRAM', + 0x06: 'SRAM', + 0x07: 'RAM', + 0x08: 'ROM', + 0x09: 'FLASH', + 0x0A: 'EEPROM', + 0x0B: 'FEPROM', + 0x0C: 'EPROM', + 0x0D: 'CDRAM', + 0x0E: '3DRAM', + 0x0F: 'SDRAM', + 0x10: 'SGRAM', + 0x11: 'RDRAM', + 0x12: 'DDR', + 0x13: 'DDR2', + 0x14: 'DDR2 FB-DIMM', + xrange(0x15, 0x17): 'Reserved', + 0x18: 'DDR3', + 0x19: 'FBD2' + } + self.add_field('memory_type', u.unpack_one("B"), unpack.format_table("{}", _memory_types)) + if self.length > 0x13: + self.add_field('type_detail', u.unpack_one(' 0x15: + self.add_field('speed', u.unpack_one(" 0x17: + self.add_field('manufacturer', u.unpack_one("B"), self.fmtstr) + if self.length > 0x18: + self.add_field('serial_number', u.unpack_one("B"), self.fmtstr) + if self.length > 0x19: + self.add_field('asset_tag', u.unpack_one("B"), self.fmtstr) + if self.length > 0x1A: + self.add_field('part_number', u.unpack_one("B"), self.fmtstr) + if self.length > 0x1B: + self.add_field('attributes', u.unpack_one("B")) + self.add_field('rank', bitfields.getbits(self.attributes, 3, 0), "attributes[3:0]={}") + if self.length > 0x1C: + if self.size == 0x7FFF: + self.add_field('extended_size', u.unpack_one(' 0x20: + self.add_field('configured_memory_clock_speed', u.unpack_one(" 0x22: + self.add_field('minimum_voltage', u.unpack_one(" 0x24: + self.add_field('maximum_voltage', u.unpack_one(" 0x26: + self.add_field('configured_voltage', u.unpack_one(" 0x4: + _error_types = { + 0x01: 'Other', + 0x02: 'Unknown', + 0x03: 'OK', + 0x04: 'Bad read', + 0x05: 'Parity error', + 0x06: 'Single-bit error', + 0x07: 'Double-bit error', + 0x08: 'Multi-bit error', + 0x09: 'Nibble error', + 0x0A: 'Checksum error', + 0x0B: 'CRC error', + 0x0C: 'Corrected single-bit error', + 0x0D: 'Corrected error', + 0x0E: 'Uncorrectable error' + } + self.add_field('error_type', u.unpack_one("B"), unpack.format_table("{}", _error_types)) + if self.length > 0x5: + _error_granularity_field = { + 0x01: 'Other', + 0x02: 'Unknown', + 0x03: 'Device level', + 0x04: 'Memory partition level' + } + self.add_field('error_granularity', u.unpack_one("B"), unpack.format_table("{}", _error_granularity_field)) + if self.length > 0x6: + _error_operation_field = { + 0x01: 'Other', + 0x02: 'Unknown', + 0x03: 'Read', + 0x04: 'Write', + 0x05: 'Partial write' + } + self.add_field('error_operation', u.unpack_one("B"), unpack.format_table("{}", _error_operation_field)) + if self.length > 0x7: + self.add_field('vendor_syndrome', u.unpack_one(" 0xB: + self.add_field('memory_array_error_address', u.unpack_one(" 0xF: + self.add_field('device_error_address', u.unpack_one(" 0x13: + self.add_field('error_resolution', u.unpack_one(" 0x4: + self.add_field('starting_address', u.unpack_one(" 0x8: + self.add_field('ending_address', u.unpack_one(" 0xC: + self.add_field('memory_array_handle', u.unpack_one(" 0xE: + self.add_field('partition_width', u.unpack_one("B")) + if self.length > 0xF: + # valid if starting_address = FFFF FFFF + if self.starting_address == 0xFFFFFFFF: + self.add_field('extended_starting_address', u.unpack_one(" 0x17: + self.add_field('extended_ending_address', u.unpack_one(" 0x4: + self.add_field('starting_address', u.unpack_one(" 0x8: + self.add_field('ending_address', u.unpack_one(" 0xC: + self.add_field('memory_device_handle', u.unpack_one(" 0xE: + self.add_field('memory_array_mapped_address_handle', u.unpack_one(" 0x10: + self.add_field('partition_row_position', u.unpack_one("B")) + if self.length > 0x11: + self.add_field('interleave_position', u.unpack_one("B")) + if self.length > 0x12: + self.add_field('interleave_data_depth', u.unpack_one("B")) + if self.length > 0x13: + # valid if starting_address = FFFF FFFF + if self.starting_address == 0xFFFFFFFF: + self.add_field('extended_starting_address', u.unpack_one(" 0x1B: + self.add_field('extended_ending_address', u.unpack_one(" 0x4: + _pointing_device_types = { + 0x01: 'Other', + 0x02: 'Unknown', + 0x03: 'Mouse', + 0x04: 'Track Ball', + 0x05: 'Track Point', + 0x06: 'Glide Point', + 0x07: 'Touch Pad', + 0x08: 'Touch Screen', + 0x09: 'Optical Sensor' + } + self.add_field('pointing_device_type', u.unpack_one("B"), unpack.format_table("{}", _pointing_device_types)) + if self.length > 0x5: + _interfaces = { + 0x01: 'Other', + 0x02: 'Unknown', + 0x03: 'Serial', + 0x04: 'PS/2', + 0x05: 'Infared', + 0x06: 'HP-HIL', + 0x07: 'Bus mouse', + 0x08: 'ADB (Apple Desktop Bus)', + 0x09: 'Bus mouse DB-9', + 0x0A: 'Bus mouse micro-DIN', + 0x0B: 'USB' + } + self.add_field('interface', u.unpack_one("B"), unpack.format_table("{}", _interfaces)) + if self.length > 0x6: + self.add_field('num_buttons', u.unpack_one("B")) + except: + self.decodeFailure = True + print "Error parsing BuiltInPointingDevice" + import traceback + traceback.print_exc() + self.fini() + +class PortableBattery(SmbiosBaseStructure): + smbios_structure_type = 22 + + def __init__(self, u, sm): + super(PortableBattery, self).__init__(u, sm) + u = self.u + try: + if self.length > 0x4: + self.add_field('location', u.unpack_one("B"), self.fmtstr) + if self.length > 0x5: + self.add_field('manufacturer', u.unpack_one("B"), self.fmtstr) + if self.length > 0x6: + self.add_field('manufacturer_date', u.unpack_one("B"), self.fmtstr) + if self.length > 0x7: + self.add_field('serial_number', u.unpack_one("B"), self.fmtstr) + if self.length > 0x8: + self.add_field('device_name', u.unpack_one("B"), self.fmtstr) + if self.length > 0x9: + _device_chemistry = { + 0x01: 'Other', + 0x02: 'Unknown', + 0x03: 'Lead Acid', + 0x04: 'Nickel Cadmium', + 0x05: 'Nickel metal hydride', + 0x06: 'Lithium-ion', + 0x07: 'Zinc air', + 0x08: 'Lithium Polymer' + } + self.add_field('device_chemistry', u.unpack_one("B"), unpack.format_table("{}", _device_chemistry)) + if self.length > 0xA: + self.add_field('design_capacity', u.unpack_one(" 0xC: + self.add_field('design_voltage', u.unpack_one(" 0xE: + self.add_field('sbds_version_number', u.unpack_one("B"), self.fmtstr) + if self.length > 0xF: + self.add_field('max_error_battery_data', u.unpack_one("B"), self.fmtstr) + if self.length > 0x10: + if self.serial_number == 0: + self.add_field('sbds_serial_number', u.unpack_one(" 0x12: + if self.manufacturer_date == 0: + self.add_field('sbds_manufacture_date', u.unpack_one(" 0x14: + if self.device_chemistry == 0x02: + self.add_field('sbds_device_chemistry', u.unpack_one("B"), self.fmtstr) + else: + u.skip(1) + if self.length > 0x15: + self.add_field('design_capacity_multiplier', u.unpack_one("B")) + if self.length > 0x16: + self.add_field('oem_specific', u.unpack_one(" 0x4: + self.add_field('capabilities', u.unpack_one("B")) + self.add_field('contains_watchdog_timer', bool(bitfields.getbits(self.capabilities, 5)), "capabilities[5]={}") + _boot_option = { + 0b00: 'Reserved, do not use', + 0b01: 'Operating System', + 0b10: 'System utilities', + 0b11: 'Do not reboot' + } + self.add_field('boot_option_on_limit', bitfields.getbits(self.capabilities, 4, 3), unpack.format_table("capabilities[4:3]={}", _boot_option)) + self.add_field('boot_option_after_watchdog_reset', bitfields.getbits(self.capabilities, 2, 1), unpack.format_table("capabilities[2:1]={}", _boot_option)) + self.add_field('system_reset_enabled_by_user', bool(bitfields.getbits(self.capabilities, 0)), "capabilities[0]={}") + if self.length > 0x5: + self.add_field('reset_count', u.unpack_one(" 0x5: + self.add_field('reset_limit', u.unpack_one(" 0x9: + self.add_field('timer_interval', u.unpack_one(" 0xB: + self.add_field('timeout', u.unpack_one(" 0x4: + self.add_field('hardware_security_settings', u.unpack_one("B")) + _status = { + 0x00: 'Disabled', + 0x01: 'Enabled', + 0x02: 'Not Implemented', + 0x03: 'Unknown' + } + self.add_field('power_on_password_status', bitfields.getbits(self.hardware_security_settings, 7, 6), unpack.format_table("hardware_security_settings[7:6]={}", _status)) + self.add_field('keyboard_password_status', bitfields.getbits(self.hardware_security_settings, 5, 4), unpack.format_table("hardware_security_settings[5:4]={}", _status)) + self.add_field('admin_password_status', bitfields.getbits(self.hardware_security_settings, 3, 2), unpack.format_table("hardware_security_settings0[3:2]={}", _status)) + self.add_field('front_panel_reset_status', bitfields.getbits(self.hardware_security_settings, 1, 0), unpack.format_table("hardware_security_settings[1:0]={}", _status)) + except: + self.decodeFailure = True + print "Error parsing HardwareSecurity" + import traceback + traceback.print_exc() + self.fini() + +class SystemPowerControls(SmbiosBaseStructure): + smbios_structure_type = 25 + + def __init__(self, u, sm): + super(SystemPowerControls, self).__init__(u, sm) + u = self.u + try: + if self.length > 0x4: + self.add_field('next_scheduled_poweron_month', u.unpack_one("B")) + self.add_field('next_scheduled_poweron_day_of_month', u.unpack_one("B")) + self.add_field('next_scheduled_poweron_hour', u.unpack_one("B")) + self.add_field('next_scheduled_poweron_minute', u.unpack_one("B")) + self.add_field('next_scheduled_poweron_second', u.unpack_one("B")) + except: + self.decodeFailure = True + print "Error parsing SystemPowerControls" + import traceback + traceback.print_exc() + self.fini() + +class VoltageProbe(SmbiosBaseStructure): + smbios_structure_type = 26 + + def __init__(self, u, sm): + super(VoltageProbe, self).__init__(u, sm) + u = self.u + try: + if self.length > 0x4: + self.add_field('description', u.unpack_one("B"), self.fmtstr) + if self.length > 0x5: + self.add_field('location_and_status', u.unpack_one("B")) + _status = { + 0b001: 'Other', + 0b010: 'Unknown', + 0b011: 'OK', + 0b100: 'Non-critical', + 0b101: 'Critical', + 0b110: 'Non-recoverable' + } + _location = { + 0b00001: 'Other', + 0b00010: 'Unknown', + 0b00011: 'Processor', + 0b00100: 'Disk', + 0b00101: 'Peripheral Bay', + 0b00110: 'System Management Module', + 0b00111: 'Motherboard', + 0b01000: 'Memory Module', + 0b01001: 'Processor Module', + 0b01010: 'Power Unit', + 0b01011: 'Add-in Card' + } + self.add_field('status', bitfields.getbits(self.location_and_status, 7, 5), unpack.format_table("location_and_status[7:5]={}", _status)) + self.add_field('location', bitfields.getbits(self.location_and_status, 4, 0), unpack.format_table("location_and_status[4:0]={}", _location)) + if self.length > 0x6: + self.add_field('max_value', u.unpack_one(" 0x8: + self.add_field('min_value', u.unpack_one(" 0xA: + self.add_field('resolution', u.unpack_one(" 0xC: + self.add_field('tolerance', u.unpack_one(" 0xE: + self.add_field('accuracy', u.unpack_one(" 0x10: + self.add_field('oem_defined', u.unpack_one(" 0x14: + self.add_field('nominal_value', u.unpack_one(" 0x4: + self.add_field('temperature_probe_handle', u.unpack_one(" 0x6: + self.add_field('device_type_and_status', u.unpack_one("B")) + _status = { + 0b001: 'Other', + 0b010: 'Unknown', + 0b011: 'OK', + 0b100: 'Non-critical', + 0b101: 'Critical', + 0b110: 'Non-recoverable' + } + _type = { + 0b00001: 'Other', + 0b00010: 'Unknown', + 0b00011: 'Fan', + 0b00100: 'Centrifugal Blower', + 0b00101: 'Chip Fan', + 0b00110: 'Cabinet Fan', + 0b00111: 'Power Supply Fan', + 0b01000: 'Heat Pipe', + 0b01001: 'Integrated Refrigeration', + 0b10000: 'Active Cooling', + 0b10001: 'Passive Cooling' + } + self.add_field('status', bitfields.getbits(self.device_type_and_status, 7, 5), unpack.format_table("device_type_and_status[7:5]={}", _status)) + self.add_field('device_type', bitfields.getbits(self.device_type_and_status, 4, 0), unpack.format_table("device_type_and_status[4:0]={}", _type)) + if self.length > 0x7: + self.add_field('cooling_unit_group', u.unpack_one("B")) + if self.length > 0x8: + self.add_field('OEM_defined', u.unpack_one(" 0xC: + self.add_field('nominal_speed', u.unpack_one(" 0xE: + self.add_field('description', u.unpack_one("B"), self.fmtstr) + except: + self.decodeFailure = True + print "Error parsing CoolingDevice" + import traceback + traceback.print_exc() + self.fini() + +class TemperatureProbe(SmbiosBaseStructure): + smbios_structure_type = 28 + + def __init__(self, u, sm): + super(TemperatureProbe, self).__init__(u, sm) + u = self.u + try: + if self.length > 0x4: + self.add_field('description', u.unpack_one("B"), self.fmtstr) + if self.length > 0x5: + self.add_field('location_and_status', u.unpack_one("B")) + _status = { + 0b001: 'Other', + 0b010: 'Unknown', + 0b011: 'OK', + 0b100: 'Non-critical', + 0b101: 'Critical', + 0b110: 'Non-recoverable' + } + _location = { + 0b00001: 'Other', + 0b00010: 'Unknown', + 0b00011: 'Processor', + 0b00100: 'Disk', + 0b00101: 'Peripheral Bay', + 0b00110: 'System Management Module', + 0b00111: 'Motherboard', + 0b01000: 'Memory Module', + 0b01001: 'Processor Module', + 0b01010: 'Power Unit', + 0b01011: 'Add-in Card', + 0b01100: 'Front Panel Board', + 0b01101: 'Back Panel Board', + 0b01110: 'Power System Board', + 0b01111: 'Drive Back Plane' + } + self.add_field('status', bitfields.getbits(self.location_and_status, 7, 5), unpack.format_table("location_and_status[7:5]={}", _status)) + self.add_field('location', bitfields.getbits(self.location_and_status, 4, 0), unpack.format_table("location_and_status[4:0]={}", _location)) + if self.length > 0x6: + self.add_field('maximum_value', u.unpack_one(" 0x8: + self.add_field('minimum_value', u.unpack_one(" 0xA: + self.add_field('resolution', u.unpack_one(" 0xC: + self.add_field('tolerance', u.unpack_one(" 0xE: + self.add_field('accuracy', u.unpack_one(" 0x10: + self.add_field('OEM_defined', u.unpack_one(" 0x14: + self.add_field('nominal_value', u.unpack_one(" 0x4: + self.add_field('description', u.unpack_one("B"), self.fmtstr) + if self.length > 0x5: + self.add_field('location_and_status', u.unpack_one("B")) + _status = { + 0b001: 'Other', + 0b010: 'Unknown', + 0b011: 'OK', + 0b100: 'Non-critical', + 0b101: 'Critical', + 0b110: 'Non-recoverable' + } + _location = { + 0b00001: 'Other', + 0b00010: 'Unknown', + 0b00011: 'Processor', + 0b00100: 'Disk', + 0b00101: 'Peripheral Bay', + 0b00110: 'System Management Module', + 0b00111: 'Motherboard', + 0b01000: 'Memory Module', + 0b01001: 'Processor Module', + 0b01010: 'Power Unit', + 0b01011: 'Add-in Card', + 0b01100: 'Front Panel Board', + 0b01101: 'Back Panel Board', + 0b01110: 'Power System Board', + 0b01111: 'Drive Back Plane' + } + self.add_field('status', bitfields.getbits(self.location_and_status, 7, 5), unpack.format_table("location_and_status[7:5]={}", _status)) + self.add_field('location', bitfields.getbits(self.location_and_status, 4, 0), unpack.format_table("location_and_status[4:0]={}", _location)) + if self.length > 0x6: + self.add_field('maximum_value', u.unpack_one(" 0x8: + self.add_field('minimum_value', u.unpack_one(" 0xA: + self.add_field('resolution', u.unpack_one(" 0xC: + self.add_field('tolerance', u.unpack_one(" 0xE: + self.add_field('accuracy', u.unpack_one(" 0x10: + self.add_field('OEM_defined', u.unpack_one(" 0x14: + self.add_field('nominal_value', u.unpack_one(" 0x4: + self.add_field('manufacturer_name', u.unpack_one("B"), self.fmtstr) + if self.length > 0x5: + self.add_field('connections', u.unpack_one("B")) + self.add_field('outbound_connection_enabled', bool(bitfields.getbits(self.connections, 1)), "connections[1]={}") + self.add_field('inbound_connection_enabled', bool(bitfields.getbits(self.connections, 0)), "connections[0]={}") + except: + self.decodeFailure = True + print "Error parsing OutOfBandRemoteAccess" + import traceback + traceback.print_exc() + self.fini() + +class BootIntegrityServicesEntryPoint(SmbiosBaseStructure): + smbios_structure_type = 31 + +class SystemBootInformation(SmbiosBaseStructure): + smbios_structure_type = 32 + + def __init__(self, u, sm): + super(SystemBootInformation, self).__init__(u, sm) + u = self.u + try: + if self.length > 0xA: + u.skip(6) + _boot_status = { + 0: 'No errors detected', + 1: 'No bootable media', + 2: '"normal" operating system failed to load', + 3: 'Firmware-detected hardware failure, including "unknown" failure types', + 4: 'Operating system-detected hardware failure', + 5: 'User-requested boot, usually through a keystroke', + 6: 'System security violation', + 7: 'Previously-requested image', + 8: 'System watchdog timer expired, causing the system to reboot', + xrange(9,127): 'Reserved for future assignment', + xrange(128, 191): 'Vendor/OEM-specific implementations', + xrange(192, 255): 'Product-specific implementations' + } + self.add_field('boot_status', u.unpack_one("B"), unpack.format_table("{}", _boot_status)) + except: + self.decodeFailure = True + print "Error parsing SystemBootInformation" + import traceback + traceback.print_exc() + self.fini() + +class MemoryErrorInfo64Bit(SmbiosBaseStructure): + smbios_structure_type = 33 + + def __init__(self, u, sm): + super(MemoryErrorInfo64Bit, self).__init__(u, sm) + u = self.u + try: + if self.length > 0x4: + _error_types = { + 0x01: 'Other', + 0x02: 'Unknown', + 0x03: 'OK', + 0x04: 'Bad read', + 0x05: 'Parity error', + 0x06: 'Single-bit error', + 0x07: 'Double-bit error', + 0x08: 'Multi-bit error', + 0x09: 'Nibble error', + 0x0A: 'Checksum error', + 0x0B: 'CRC error', + 0x0C: 'Corrected single-bit error', + 0x0D: 'Corrected error', + 0x0E: 'Uncorrectable error' + } + self.add_field('error_type', u.unpack_one("B"), unpack.format_table("{}", _error_types)) + if self.length > 0x5: + _error_granularity_field = { + 0x01: 'Other', + 0x02: 'Unknown', + 0x03: 'Device level', + 0x04: 'Memory partition level' + } + self.add_field('error_granularity', u.unpack_one("B"), unpack.format_table("{}", _error_granularity_field)) + if self.length > 0x6: + _error_operation_field = { + 0x01: 'Other', + 0x02: 'Unknown', + 0x03: 'Read', + 0x04: 'Write', + 0x05: 'Partial write' + } + self.add_field('error_operation', u.unpack_one("B"), unpack.format_table("{}", _error_operation_field)) + if self.length > 0x7: + self.add_field('vendor_syndrome', u.unpack_one(" 0xB: + self.add_field('memory_array_error_address', u.unpack_one(" 0xF: + self.add_field('device_error_address', u.unpack_one(" 0x13: + self.add_field('error_resolution', u.unpack_one(" 0x4: + self.add_field('description', u.unpack_one("B"), self.fmtstr) + if self.length > 0x5: + _type = { + 0x01: 'Other', + 0x02: 'Unknown', + 0x03: 'National Semiconductor LM75', + 0x04: 'National Semiconductor LM78', + 0x05: 'National Semiconductor LM79', + 0x06: 'National Semiconductor LM80', + 0x07: 'National Semiconductor LM81', + 0x08: 'Analog Devices ADM9240', + 0x09: 'Dallas Semiconductor DS1780', + 0x0A: 'Maxim 1617', + 0x0B: 'Genesys GL518SM', + 0x0C: 'Winbond W83781D', + 0x0D: 'Holtek HT82H791' + } + self.add_field('device_type', u.unpack_one("B"), unpack.format_table("{}", _type)) + if self.length > 0x6: + self.add_field('address', u.unpack_one(" 0xA: + _address_type = { + 0x01: 'Other', + 0x02: 'Unknown', + 0x03: 'I/O Port', + 0x04: 'Memory', + 0x05: 'SM Bus' + } + self.add_field('address_type', u.unpack_one("B"), unpack.format_table("{}", _address_type)) + except: + self.decodeFailure = True + print "Error parsing ManagementDevice" + import traceback + traceback.print_exc() + self.fini() + +class ManagementDeviceComponent(SmbiosBaseStructure): + smbios_structure_type = 35 + + def __init__(self, u, sm): + super(ManagementDeviceComponent, self).__init__(u, sm) + u = self.u + try: + if self.length > 0x4: + self.add_field('description', u.unpack_one("B"), self.fmtstr) + if self.length > 0x5: + self.add_field('management_device_handle', u.unpack_one(" 0x7: + self.add_field('component_handle', u.unpack_one(" 0x9: + self.add_field('threshold_handle', u.unpack_one(" 0x4: + self.add_field('lower_threshold_noncritical', u.unpack_one(" 0x6: + self.add_field('upper_threshold_noncritical', u.unpack_one(" 0x8: + self.add_field('lower_threshold_critical', u.unpack_one(" 0xA: + self.add_field('upper_threshold_critical', u.unpack_one(" 0xC: + self.add_field('lower_threshold_nonrecoverable', u.unpack_one(" 0xE: + self.add_field('upper_threshold_nonrecoverable', u.unpack_one(" 0x4: + _channel_type = { + 0x01: 'Other', + 0x02: 'Unknown', + 0x03: 'RamBus', + 0x04: 'SyncLink' + } + self.add_field('channel_type', u.unpack_one("B"), unpack.format_table("{}", _channel_type)) + if self.length > 0x6: + self.add_field('max_channel_load', u.unpack_one("B")) + if self.length > 0x8: + self.add_field('memory_device_count', u.unpack_one("B")) + if self.length > 0xA: + self.add_field('memory_device_load', u.unpack_one("B")) + if self.length > 0xC: + self.add_field('memory_device_handle', u.unpack_one(" 0x4: + self.add_field('power_unit_group', u.unpack_one("B")) + if self.length > 0x5: + self.add_field('location', u.unpack_one("B"), self.fmtstr) + if self.length > 0x6: + self.add_field('device_name', u.unpack_one("B"), self.fmtstr) + if self.length > 0x7: + self.add_field('manufacturer', u.unpack_one("B"), self.fmtstr) + if self.length > 0x8: + self.add_field('serial_number', u.unpack_one("B"), self.fmtstr) + if self.length > 0x9: + self.add_field('asset_tag', u.unpack_one("B"), self.fmtstr) + if self.length > 0xA: + self.add_field('model_part_number', u.unpack_one("B"), self.fmtstr) + if self.length > 0xB: + self.add_field('revision_level', u.unpack_one("B"), self.fmtstr) + if self.length > 0xC: + self.add_field('max_power_capacity', u.unpack_one(" 0xE: + self.add_field('power_supply_characteristics', u.unpack_one(" 0x10: + self.add_field('input_voltage_probe_handle', u.unpack_one(" 0x12: + self.add_field('cooling_device_handle', u.unpack_one(" 0x14: + self.add_field('input_current_probe_handle', u.unpack_one(" 0x4: + self.add_field('num_additional_information_entries', u.unpack_one("B")) + if self.length > 0x5: + self.add_field('additional_information_entry_length', u.unpack_one("B")) + self.add_field('referenced_handle', u.unpack_one(" 0x4: + self.add_field('reference_designation', u.unpack_one("B"), self.fmtstr) + if self.length > 0x5: + self.add_field('device_type', u.unpack_one("B")) + self.add_field('device_enabled', bool(bitfields.getbits(self.device_type, 7)), "device_type[7]={}") + _device_types = { + 0x01: 'Other', + 0x02: 'Unknown', + 0x03: 'Video', + 0x04: 'SCSI Controller', + 0x05: 'Ethernet', + 0x06: 'Token Ring', + 0x07: 'Sound', + 0x08: 'PATA Controller', + 0x09: 'SATA Controller', + 0x0A: 'SAS Controller' + } + self.add_field('type_of_device', bitfields.getbits(self.device_type, 6, 0), unpack.format_table("device_type[6:0]={}", _device_types)) + if self.length > 0x6: + self.add_field('device_type_instance', u.unpack_one("B")) + if self.length > 0x7: + self.add_field('segment_group_number', u.unpack_one(" 0x9: + self.add_field('bus_number', u.unpack_one("B"), self.fmtstr) + if self.length > 0xA: + self.add_field('device_and_function_number', u.unpack_one("B")) + self.add_field('device_number', bitfields.getbits(self.device_type, 7, 3), "device_and_function_number[7:3]={}") + self.add_field('function_number', bitfields.getbits(self.device_type, 2, 0), "device_and_function_number[2:0]={}") + except: + self.decodeFailure = True + print "Error parsing OnboardDevicesExtendedInformation" + import traceback + traceback.print_exc() + self.fini() + +class ManagementControllerHostInterface(SmbiosBaseStructure): + smbios_structure_type = 42 + + def __init__(self, u, sm): + super(ManagementControllerHostInterface, self).__init__(u, sm) + u = self.u + try: + if self.length > 0x4: + _interface_types = { + 0x00: 'Reserved', + 0x01: 'Reserved', + 0x02: 'KCS: Keyboard Controller Style', + 0x03: '8250 UART Register Compatible', + 0x04: '16450 UART Register Compatible', + 0x05: '16550/16550A UART Register Compatible', + 0x06: '16650/16650A UART Register Compatible', + 0x07: '16750/16750A UART Register Compatible', + 0x08: '16850/16850A UART Register Compatible', + 0xF0: 'OEM' + } + self.add_field('interface_type', u.unpack_one("B"), unpack.format_table("{}", _interface_types)) + if self.length > 0x5: + self.add_field('mc_host_interface_data', u.unpack_rest(), self.fmtstr) + except: + self.decodeFailure = True + print "Error parsing ManagementControllerHostInterface" + import traceback + traceback.print_exc() + self.fini() + +class Inactive(SmbiosBaseStructure): + smbios_structure_type = 126 + + def __init__(self, u, sm): + super(Inactive, self).__init__(u, sm) + self.fini() + +class EndOfTable(SmbiosBaseStructure): + smbios_structure_type = 127 + + def __init__(self, u, sm): + super(EndOfTable, self).__init__(u, sm) + self.fini() + +class SmbiosStructureUnknown(SmbiosBaseStructure): + smbios_structure_type = None + + def __init__(self, u, sm): + super(SmbiosStructureUnknown, self).__init__(u, sm) + self.fini() + +_smbios_structures = [ + BIOSInformation, + SystemInformation, + BaseboardInformation, + SystemEnclosure, + ProcessorInformation, + MemoryControllerInformation, + MemoryModuleInformation, + CacheInformation, + PortConnectorInfo, + SystemSlots, + OnBoardDevicesInformation, + OEMStrings, + SystemConfigOptions, + BIOSLanguageInformation, + GroupAssociations, + SystemEventLog, + PhysicalMemoryArray, + MemoryDevice, + MemoryErrorInfo32Bit, + MemoryArrayMappedAddress, + MemoryDeviceMappedAddress, + BuiltInPointingDevice, + PortableBattery, + SystemReset, + HardwareSecurity, + SystemPowerControls, + VoltageProbe, + CoolingDevice, + TemperatureProbe, + ElectricalCurrentProbe, + OutOfBandRemoteAccess, + BootIntegrityServicesEntryPoint, + SystemBootInformation, + MemoryErrorInfo64Bit, + ManagementDevice, + ManagementDeviceComponent, + ManagementDeviceThresholdData, + MemoryChannel, + IPMIDeviceInformation, + SystemPowerSupply, + AdditionalInformation, + OnboardDevicesExtendedInformation, + ManagementControllerHostInterface, + Inactive, + EndOfTable, + SmbiosStructureUnknown, # Must always come last +] + +def log_smbios_info(): + with redirect.logonly(): + try: + sm = SMBIOS() + print + if sm is None: + print "No SMBIOS structures found" + return + output = {} + known_types = (0, 1) + for sm_struct in sm.structures: + if sm_struct.type in known_types: + output.setdefault(sm_struct.type, []).append(sm_struct) + if len(output) == len(known_types): + break + + print "SMBIOS information:" + for key in sorted(known_types): + for s in output.get(key, ["No structure of type {} found".format(key)]): + print ttypager._wrap("{}: {}".format(key, s)) + except: + print "Error parsing SMBIOS information:" + import traceback + traceback.print_exc() + +def dump_raw(): + try: + sm = SMBIOS() + if sm: + s = "SMBIOS -- Raw bytes and structure decode.\n\n" + + s += str(sm.header) + '\n' + s += bits.dumpmem(sm._header_memory) + '\n' + + s += "Raw bytes for the SMBIOS structures\n" + s += bits.dumpmem(sm._structure_memory) + '\n' + + for sm_struct in sm.structures: + s += str(sm_struct) + '\n' + s += bits.dumpmem(sm_struct.raw_data) + + s += "Strings:\n" + for n in range(1, len(getattr(sm_struct, "strings", [])) + 1): + s += str(sm_struct.fmtstr(n)) + '\n' + s += bits.dumpmem(sm_struct.raw_strings) + '\n' + else: + s = "No SMBIOS structures found" + ttypager.ttypager_wrap(s, indent=False) + except: + print "Error parsing SMBIOS information:" + import traceback + traceback.print_exc() + +def dump(): + try: + sm = SMBIOS() + if sm: + s = str(sm) + else: + s = "No SMBIOS structures found" + ttypager.ttypager_wrap(s, indent=False) + except: + print "Error parsing SMBIOS information:" + import traceback + traceback.print_exc() + +def annex_a_conformance(): + try: + sm = SMBIOS() + + # check: 1. The table anchor string "_SM_" is present in the address range 0xF0000 to 0xFFFFF on a 16-byte bound + + def table_entry_point_verification(): + ''' Verify table entry-point''' + if (sm.header.length < 0x1F): + print "Failure: Table entry-point - The entry-point Length must be at least 0x1F" + if sm.header.checksum != 0: + print "Failure: Table entry-point - The entry-point checksum must evaluate to 0" + if ((sm.header.major_version < 2) and (sm.header.minor_version < 4)): + print "Failure: Table entry-point - SMBIOS version must be at least 2.4" + if (sm.header.intermediate_anchor_string == '_DMI_'): + print "Failure: Table entry-point - The Intermediate Anchor String must be '_DMI_'" + if (sm.header.intermediate_checksum != 0): + print "Failure: Table entry-point - The Intermediate checksum must evaluate to 0" + + #check: 3. The structure-table is traversable and conforms to the entry-point specifications: + + def req_structures(): + '''Checks for required structures and corresponding data''' + types_present = [sm.structures[x].smbios_structure_type for x in range(len(sm.structures))] + required = [0, 1, 4, 7, 9, 16, 17, 19, 31, 32] + for s in required: + if s not in set(types_present): + print "Failure: Type {} required but not found".format(s) + + else: + if s == 0: + if types_present.count(s) > 1: + print "Failure: Type {} - One and only one structure of this type must be present.".format(s) + if sm.structure_type(s).length < 0x18: + print "Failure: Type {} - The structure Length field must be at least 0x18".format(s) + if sm.structure_type(s).version is None: + print "Failure: Type {} - BIOS Version string must be present and non-null.".format(s) + if sm.structure_type(s).release_date is None: + print "Failure: Type {} - BIOS Release Date string must be present, non-null, and include a 4-digit year".format(s) + if bitfields.getbits(sm.structure_type(s).characteristics, 3, 0) != 0 or bitfields.getbits(sm.structure_type(s).characteristics, 31, 4) == 0: + print "Failure: Type {} - BIOS Characteristics: bits 3:0 must all be 0, and at least one of bits 31:4 must be set to 1.".format(s) + elif s == 1: + if types_present.count(s) > 1: + print "Failure: Type {} - One and only one structure of this type must be present.".format(s) + if sm.structure_type(s).length < 0x1B: + print "Failure: Type {} - The structure Length field must be at least 0x1B".format(s) + if sm.structure_type(s).manufacturer == None: + print "Failure: Type {} - Manufacturer string must be present and non-null.".format(s) + if sm.structure_type(s).product_name == None: + print "Failure: Type {} - Product Name string must be present and non-null".format(s) + if sm.structure_type(s).uuid == '00000000 00000000' and sm.structure_type(s).uuid == 'FFFFFFFF FFFFFFFF': + print "Failure: Type {} - UUID field must be neither 00000000 00000000 nor FFFFFFFF FFFFFFFF.".format(s) + if sm.structure_type(s).wakeup_type == 00 and sm.structure_type(s).wakeup_type == 0x02: + print "Failure: Type {} - Wake-up Type field must be neither 00h (Reserved) nor 02h (Unknown).".format(s) + # continue for remaining required types + + # check remaining conformance guidelines + + table_entry_point_verification() + req_structures() + except: + print "Error checking ANNEX A conformance guidelines" + import traceback + traceback.print_exc() diff --git a/tests/avocado/acpi-bits/bits-tests/testacpi.py2 b/tests/avocado/acpi-bits/bits-tests/testacpi.py2 new file mode 100644 index 0000000000..9ec452f330 --- /dev/null +++ b/tests/avocado/acpi-bits/bits-tests/testacpi.py2 @@ -0,0 +1,283 @@ +# Copyright (c) 2015, Intel Corporation +# All rights reserved. +# +# Redistribution and use in source and binary forms, with or without +# modification, are permitted provided that the following conditions are met: +# +# * Redistributions of source code must retain the above copyright notice, +# this list of conditions and the following disclaimer. +# * Redistributions in binary form must reproduce the above copyright notice, +# this list of conditions and the following disclaimer in the documentation +# and/or other materials provided with the distribution. +# * Neither the name of Intel Corporation nor the names of its contributors +# may be used to endorse or promote products derived from this software +# without specific prior written permission. +# +# THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND +# ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED +# WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE +# DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR +# ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES +# (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; +# LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON +# ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT +# (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS +# SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. + +"""Tests for ACPI""" + +import acpi +import bits +import bits.mwait +import struct +import testutil +import testsuite +import time + +def register_tests(): + testsuite.add_test("ACPI _MAT (Multiple APIC Table Entry) under Processor objects", test_mat, submenu="ACPI Tests") + testsuite.add_test("ACPI _PSS (Pstate) table conformance tests", test_pss, submenu="ACPI Tests") + testsuite.add_test("ACPI _PSS (Pstate) runtime tests", test_pstates, submenu="ACPI Tests") + testsuite.add_test("ACPI DSDT (Differentiated System Description Table)", test_dsdt, submenu="ACPI Tests") + testsuite.add_test("ACPI FACP (Fixed ACPI Description Table)", test_facp, submenu="ACPI Tests") + testsuite.add_test("ACPI HPET (High Precision Event Timer Table)", test_hpet, submenu="ACPI Tests") + testsuite.add_test("ACPI MADT (Multiple APIC Description Table)", test_apic, submenu="ACPI Tests") + testsuite.add_test("ACPI MPST (Memory Power State Table)", test_mpst, submenu="ACPI Tests") + testsuite.add_test("ACPI RSDP (Root System Description Pointer Structure)", test_rsdp, submenu="ACPI Tests") + testsuite.add_test("ACPI XSDT (Extended System Description Table)", test_xsdt, submenu="ACPI Tests") + +def test_mat(): + cpupaths = acpi.get_cpupaths() + apic = acpi.parse_apic() + procid_apicid = apic.procid_apicid + uid_x2apicid = apic.uid_x2apicid + for cpupath in cpupaths: + # Find the ProcId defined by the processor object + processor = acpi.evaluate(cpupath) + # Find the UID defined by the processor object's _UID method + uid = acpi.evaluate(cpupath + "._UID") + mat_buffer = acpi.evaluate(cpupath + "._MAT") + if mat_buffer is None: + continue + # Process each _MAT subtable + mat = acpi._MAT(mat_buffer) + for index, subtable in enumerate(mat): + if subtable.subtype == acpi.MADT_TYPE_LOCAL_APIC: + if subtable.flags.bits.enabled: + testsuite.test("{} Processor declaration ProcId = _MAT ProcId".format(cpupath), processor.ProcId == subtable.proc_id) + testsuite.print_detail("{} ProcId ({:#02x}) != _MAT ProcId ({:#02x})".format(cpupath, processor.ProcId, subtable.proc_id)) + testsuite.print_detail("Processor Declaration: {}".format(processor)) + testsuite.print_detail("_MAT entry[{}]: {}".format(index, subtable)) + if testsuite.test("{} with local APIC in _MAT has local APIC in MADT".format(cpupath), processor.ProcId in procid_apicid): + testsuite.test("{} ApicId derived using Processor declaration ProcId = _MAT ApicId".format(cpupath), procid_apicid[processor.ProcId] == subtable.apic_id) + testsuite.print_detail("{} ApicId derived from MADT ({:#02x}) != _MAT ApicId ({:#02x})".format(cpupath, procid_apicid[processor.ProcId], subtable.apic_id)) + testsuite.print_detail("Processor Declaration: {}".format(processor)) + testsuite.print_detail("_MAT entry[{}]: {}".format(index, subtable)) + if subtable.subtype == acpi.MADT_TYPE_LOCAL_X2APIC: + if subtable.flags.bits.enabled: + if testsuite.test("{} with x2Apic in _MAT has _UID".format(cpupath), uid is not None): + testsuite.test("{}._UID = _MAT UID".format(cpupath), uid == subtable.uid) + testsuite.print_detail("{}._UID ({:#x}) != _MAT UID ({:#x})".format(cpupath, uid, subtable.uid)) + testsuite.print_detail("_MAT entry[{}]: {}".format(index, subtable)) + if testsuite.test("{} with _MAT x2Apic has x2Apic in MADT".format(cpupath), subtable.uid in uid_x2apicid): + testsuite.test("{} x2ApicId derived from MADT using UID = _MAT x2ApicId".format(cpupath), uid_x2apicid[subtable.uid] == subtable.x2apicid) + testsuite.print_detail("{} x2ApicId derived from MADT ({:#02x}) != _MAT x2ApicId ({:#02x})".format(cpupath, uid_x2apicid[subtable.uid], subtable.x2apicid)) + testsuite.print_detail("_MAT entry[{}]: {}".format(index, subtable)) + +def test_pss(): + uniques = acpi.parse_cpu_method("_PSS") + # We special-case None here to avoid a double-failure for CPUs without a _PSS + testsuite.test("_PSS must be identical for all CPUs", len(uniques) <= 1 or (len(uniques) == 2 and None in uniques)) + for pss, cpupaths in uniques.iteritems(): + if not testsuite.test("_PSS must exist", pss is not None): + testsuite.print_detail(acpi.factor_commonprefix(cpupaths)) + testsuite.print_detail('No _PSS exists') + continue + + if not testsuite.test("_PSS must not be empty", pss.pstates): + testsuite.print_detail(acpi.factor_commonprefix(cpupaths)) + testsuite.print_detail('_PSS is empty') + continue + + testsuite.print_detail(acpi.factor_commonprefix(cpupaths)) + for index, pstate in enumerate(pss.pstates): + testsuite.print_detail("P[{}]: {}".format(index, pstate)) + + testsuite.test("_PSS must contain at most 16 Pstates", len(pss.pstates) <= 16) + testsuite.test("_PSS must have no duplicate Pstates", len(pss.pstates) == len(set(pss.pstates))) + + frequencies = [p.core_frequency for p in pss.pstates] + testsuite.test("_PSS must list Pstates in descending order of frequency", frequencies == sorted(frequencies, reverse=True)) + + testsuite.test("_PSS must have Pstates with no duplicate frequencies", len(frequencies) == len(set(frequencies))) + + dissipations = [p.power for p in pss.pstates] + testsuite.test("_PSS must list Pstates in descending order of power dissipation", dissipations == sorted(dissipations, reverse=True)) + +def test_pstates(): + """Execute and verify frequency for each Pstate in the _PSS""" + IA32_PERF_CTL = 0x199 + with bits.mwait.use_hint(), bits.preserve_msr(IA32_PERF_CTL): + cpupath_procid = acpi.find_procid() + cpupath_uid = acpi.find_uid() + apic = acpi.parse_apic() + procid_apicid = apic.procid_apicid + uid_x2apicid = apic.uid_x2apicid + def cpupath_apicid(cpupath): + if procid_apicid is not None: + procid = cpupath_procid.get(cpupath, None) + if procid is not None: + apicid = procid_apicid.get(procid, None) + if apicid is not None: + return apicid + if uid_x2apicid is not None: + uid = cpupath_uid.get(cpupath, None) + if uid is not None: + apicid = uid_x2apicid.get(uid, None) + if apicid is not None: + return apicid + return bits.cpus()[0] + + bclk = testutil.adjust_to_nearest(bits.bclk(), 100.0/12) * 1000000 + + uniques = acpi.parse_cpu_method("_PSS") + for pss, cpupaths in uniques.iteritems(): + if not testsuite.test("_PSS must exist", pss is not None): + testsuite.print_detail(acpi.factor_commonprefix(cpupaths)) + testsuite.print_detail('No _PSS exists') + continue + + for n, pstate in enumerate(pss.pstates): + for cpupath in cpupaths: + apicid = cpupath_apicid(cpupath) + if apicid is None: + print 'Failed to find apicid for cpupath {}'.format(cpupath) + continue + bits.wrmsr(apicid, IA32_PERF_CTL, pstate.control) + + # Detecting Turbo frequency requires at least 2 pstates + # since turbo frequency = max non-turbo frequency + 1 + turbo = False + if len(pss.pstates) >= 2: + turbo = (n == 0 and pstate.core_frequency == (pss.pstates[1].core_frequency + 1)) + if turbo: + # Needs to busywait, not sleep + start = time.time() + while (time.time() - start < 2): + pass + + for duration in (0.1, 1.0): + frequency_data = bits.cpu_frequency(duration) + # Abort the test if no cpu frequency is not available + if frequency_data is None: + continue + aperf = frequency_data[1] + aperf = testutil.adjust_to_nearest(aperf, bclk/2) + aperf = int(aperf / 1000000) + if turbo: + if aperf >= pstate.core_frequency: + break + else: + if aperf == pstate.core_frequency: + break + + if turbo: + testsuite.test("P{}: Turbo measured frequency {} >= expected {} MHz".format(n, aperf, pstate.core_frequency), aperf >= pstate.core_frequency) + else: + testsuite.test("P{}: measured frequency {} MHz == expected {} MHz".format(n, aperf, pstate.core_frequency), aperf == pstate.core_frequency) + +def test_psd_thread_scope(): + uniques = acpi.parse_cpu_method("_PSD") + if not testsuite.test("_PSD (P-State Dependency) must exist for each processor", None not in uniques): + testsuite.print_detail(acpi.factor_commonprefix(uniques[None])) + testsuite.print_detail('No _PSD exists') + return + unique_num_dependencies = {} + unique_num_entries = {} + unique_revision = {} + unique_domain = {} + unique_coordination_type = {} + unique_num_processors = {} + for value, cpupaths in uniques.iteritems(): + unique_num_dependencies.setdefault(len(value.dependencies), []).extend(cpupaths) + unique_num_entries.setdefault(value.dependencies[0].num_entries, []).extend(cpupaths) + unique_revision.setdefault(value.dependencies[0].revision, []).extend(cpupaths) + unique_domain.setdefault(value.dependencies[0].domain, []).extend(cpupaths) + unique_coordination_type.setdefault(value.dependencies[0].coordination_type, []).extend(cpupaths) + unique_num_processors.setdefault(value.dependencies[0].num_processors, []).extend(cpupaths) + def detail(d, fmt): + for value, cpupaths in sorted(d.iteritems(), key=(lambda (k,v): v)): + testsuite.print_detail(acpi.factor_commonprefix(cpupaths)) + testsuite.print_detail(fmt.format(value)) + + testsuite.test('Dependency count for each processor must be 1', unique_num_dependencies.keys() == [1]) + detail(unique_num_dependencies, 'Dependency count for each processor = {} (Expected 1)') + testsuite.test('_PSD.num_entries must be 5', unique_num_entries.keys() == [5]) + detail(unique_num_entries, 'num_entries = {} (Expected 5)') + testsuite.test('_PSD.revision must be 0', unique_revision.keys() == [0]) + detail(unique_revision, 'revision = {}') + testsuite.test('_PSD.coordination_type must be 0xFE (HW_ALL)', unique_coordination_type.keys() == [0xfe]) + detail(unique_coordination_type, 'coordination_type = {:#x} (Expected 0xFE HW_ALL)') + testsuite.test('_PSD.domain must be unique (thread-scoped) for each processor', len(unique_domain) == len(acpi.get_cpupaths())) + detail(unique_domain, 'domain = {:#x} (Expected a unique value for each processor)') + testsuite.test('_PSD.num_processors must be 1', unique_num_processors.keys() == [1]) + detail(unique_num_processors, 'num_processors = {} (Expected 1)') + +def test_table_checksum(data): + csum = sum(ord(c) for c in data) % 0x100 + testsuite.test('ACPI table cumulative checksum must equal 0', csum == 0) + testsuite.print_detail("Cumulative checksum = {} (Expected 0)".format(csum)) + +def test_apic(): + data = acpi.get_table("APIC") + if data is None: + return + test_table_checksum(data) + apic = acpi.parse_apic() + +def test_dsdt(): + data = acpi.get_table("DSDT") + if data is None: + return + test_table_checksum(data) + +def test_facp(): + data = acpi.get_table("FACP") + if data is None: + return + test_table_checksum(data) + facp = acpi.parse_facp() + +def test_hpet(): + data = acpi.get_table("HPET") + if data is None: + return + test_table_checksum(data) + hpet = acpi.parse_hpet() + +def test_mpst(): + data = acpi.get_table("MPST") + if data is None: + return + test_table_checksum(data) + mpst = acpi.MPST(data) + +def test_rsdp(): + data = acpi.get_table("RSD PTR ") + if data is None: + return + + # Checksum the first 20 bytes per ACPI 1.0 + csum = sum(ord(c) for c in data[:20]) % 0x100 + testsuite.test('ACPI 1.0 table first 20 bytes cummulative checksum must equal 0', csum == 0) + testsuite.print_detail("Cummulative checksum = {} (Expected 0)".format(csum)) + + test_table_checksum(data) + rsdp = acpi.parse_rsdp() + +def test_xsdt(): + data = acpi.get_table("XSDT") + if data is None: + return + test_table_checksum(data) + xsdt = acpi.parse_xsdt() diff --git a/tests/avocado/acpi-bits/bits-tests/testcpuid.py2 b/tests/avocado/acpi-bits/bits-tests/testcpuid.py2 new file mode 100644 index 0000000000..ac55d912e1 --- /dev/null +++ b/tests/avocado/acpi-bits/bits-tests/testcpuid.py2 @@ -0,0 +1,83 @@ +# Copyright (c) 2012, Intel Corporation +# All rights reserved. +# +# Redistribution and use in source and binary forms, with or without +# modification, are permitted provided that the following conditions are met: +# +# * Redistributions of source code must retain the above copyright notice, +# this list of conditions and the following disclaimer. +# * Redistributions in binary form must reproduce the above copyright notice, +# this list of conditions and the following disclaimer in the documentation +# and/or other materials provided with the distribution. +# * Neither the name of Intel Corporation nor the names of its contributors +# may be used to endorse or promote products derived from this software +# without specific prior written permission. +# +# THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND +# ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED +# WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE +# DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR +# ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES +# (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; +# LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON +# ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT +# (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS +# SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. + +"""Tests and helpers for CPUID.""" + +import bits +import testsuite +import testutil + +def cpuid_helper(function, index=None, shift=0, mask=~0, eax_mask=~0, ebx_mask=~0, ecx_mask=~0, edx_mask=~0): + if index is None: + index = 0 + indexdesc = "" + else: + indexdesc = " index {0:#x}".format(index) + + def find_mask(m): + if m == ~0: + return mask + return m + masks = map(find_mask, [eax_mask, ebx_mask, ecx_mask, edx_mask]) + + uniques = {} + for cpu in bits.cpus(): + regs = bits.cpuid_result(*[(r >> shift) & m for r, m in zip(bits.cpuid(cpu, function, index), masks)]) + uniques.setdefault(regs, []).append(cpu) + + desc = ["CPUID function {:#x}{}".format(function, indexdesc)] + + if shift != 0: + desc.append("Register values have been shifted by {}".format(shift)) + if mask != ~0 or eax_mask != ~0 or ebx_mask != ~0 or ecx_mask != ~0 or edx_mask != ~0: + desc.append("Register values have been masked:") + shifted_masks = bits.cpuid_result(*[m << shift for m in masks]) + desc.append("Masks: eax={eax:#010x} ebx={ebx:#010x} ecx={ecx:#010x} edx={edx:#010x}".format(**shifted_masks._asdict())) + + if len(uniques) > 1: + regvalues = zip(*uniques.iterkeys()) + common_masks = bits.cpuid_result(*map(testutil.find_common_mask, regvalues)) + common_values = bits.cpuid_result(*[v[0] & m for v, m in zip(regvalues, common_masks)]) + desc.append('Register values are not unique across all logical processors') + desc.append("Common bits: eax={eax:#010x} ebx={ebx:#010x} ecx={ecx:#010x} edx={edx:#010x}".format(**common_values._asdict())) + desc.append("Mask of common bits: {eax:#010x} {ebx:#010x} {ecx:#010x} {edx:#010x}".format(**common_masks._asdict())) + + for regs in sorted(uniques.iterkeys()): + cpus = uniques[regs] + desc.append("Register value: eax={eax:#010x} ebx={ebx:#010x} ecx={ecx:#010x} edx={edx:#010x}".format(**regs._asdict())) + desc.append("On {0} CPUs: {1}".format(len(cpus), testutil.apicid_list(cpus))) + + return uniques, desc + +def test_cpuid_consistency(text, function, index=None, shift=0, mask=~0, eax_mask=~0, ebx_mask=~0, ecx_mask=~0, edx_mask=~0): + uniques, desc = cpuid_helper(function, index, shift, mask, eax_mask, ebx_mask, ecx_mask, edx_mask) + desc[0] += " Consistency Check" + if text: + desc.insert(0, text) + status = testsuite.test(desc[0], len(uniques) == 1) + for line in desc[1:]: + testsuite.print_detail(line) + return status