/* * dev_interface.cpp * * Home page of code is: http://smartmontools.sourceforge.net * * Copyright (C) 2008-13 Christian Franke * * 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 2, or (at your option) * any later version. * * You should have received a copy of the GNU General Public License * (for example COPYING); If not, see . * */ #include "config.h" #include "int64.h" #include "dev_interface.h" #include "dev_tunnelled.h" #include "atacmds.h" // ATA_SMART_CMD/STATUS #include "utility.h" #include #include #include #if defined(HAVE_GETTIMEOFDAY) #include #elif defined(HAVE_FTIME) #include #endif const char * dev_interface_cpp_cvsid = "$Id: dev_interface.cpp,v 1.1.1.3 2013/07/22 01:17:35 misho Exp $" DEV_INTERFACE_H_CVSID; ///////////////////////////////////////////////////////////////////////////// // smart_device smart_device::smart_device(smart_interface * intf, const char * dev_name, const char * dev_type, const char * req_type) : m_intf(intf), m_info(dev_name, dev_type, req_type), m_ata_ptr(0), m_scsi_ptr(0) { } smart_device::smart_device(do_not_use_in_implementation_classes) : m_intf(0), m_ata_ptr(0), m_scsi_ptr(0) { throw std::logic_error("smart_device: wrong constructor called in implementation class"); } smart_device::~smart_device() throw() { } bool smart_device::is_syscall_unsup() const { if (get_errno() == ENOSYS) return true; #ifdef ENOTSUP if (get_errno() == ENOTSUP) return true; #endif return false; } bool smart_device::set_err(int no, const char * msg, ...) { if (!msg) return set_err(no); m_err.no = no; va_list ap; va_start(ap, msg); m_err.msg = vstrprintf(msg, ap); va_end(ap); return false; } bool smart_device::set_err(int no) { return smi()->set_err_var(&m_err, no); } smart_device * smart_device::autodetect_open() { open(); return this; } bool smart_device::owns(const smart_device * /*dev*/) const { return false; } void smart_device::release(const smart_device * /*dev*/) { } ///////////////////////////////////////////////////////////////////////////// // ata_device ata_in_regs_48bit::ata_in_regs_48bit() : features_16(features, prev.features), sector_count_16(sector_count, prev.sector_count), lba_low_16(lba_low, prev.lba_low), lba_mid_16(lba_mid, prev.lba_mid), lba_high_16(lba_high, prev.lba_high), lba_48( lba_low, lba_mid, lba_high, prev.lba_low, prev.lba_mid, prev.lba_high) { } ata_out_regs_48bit::ata_out_regs_48bit() : sector_count_16(sector_count, prev.sector_count), lba_low_16(lba_low, prev.lba_low), lba_mid_16(lba_mid, prev.lba_mid), lba_high_16(lba_high, prev.lba_high), lba_48( lba_low, lba_mid, lba_high, prev.lba_low, prev.lba_mid, prev.lba_high) { } ata_cmd_in::ata_cmd_in() : direction(no_data), buffer(0), size(0) { } ata_cmd_out::ata_cmd_out() { } bool ata_device::ata_pass_through(const ata_cmd_in & in) { ata_cmd_out dummy; return ata_pass_through(in, dummy); } bool ata_device::ata_cmd_is_supported(const ata_cmd_in & in, unsigned flags, const char * type /* = 0 */) { // Check DATA IN/OUT switch (in.direction) { case ata_cmd_in::no_data: break; case ata_cmd_in::data_in: break; case ata_cmd_in::data_out: break; default: return set_err(EINVAL, "Invalid data direction %d", (int)in.direction); } // Check buffer size if (in.direction == ata_cmd_in::no_data) { if (in.size) return set_err(EINVAL, "Buffer size %u > 0 for NO DATA command", in.size); } else { if (!in.buffer) return set_err(EINVAL, "Buffer not set for DATA IN/OUT command"); unsigned count = (in.in_regs.prev.sector_count<<16)|in.in_regs.sector_count; // TODO: Add check for sector count == 0 if (count * 512 != in.size) return set_err(EINVAL, "Sector count %u does not match buffer size %u", count, in.size); } // Check features const char * errmsg = 0; if (in.direction == ata_cmd_in::data_out && !(flags & supports_data_out)) errmsg = "DATA OUT ATA commands not implemented"; else if ( in.out_needed.is_set() && !(flags & supports_output_regs) && !( in.in_regs.command == ATA_SMART_CMD && in.in_regs.features == ATA_SMART_STATUS && (flags & supports_smart_status))) errmsg = "Read of ATA output registers not implemented"; else if (!(in.size == 0 || in.size == 512) && !(flags & supports_multi_sector)) errmsg = "Multi-sector ATA commands not implemented"; else if (in.in_regs.is_48bit_cmd() && !(flags & (supports_48bit_hi_null|supports_48bit))) errmsg = "48-bit ATA commands not implemented"; else if (in.in_regs.is_real_48bit_cmd() && !(flags & supports_48bit)) errmsg = "48-bit ATA commands not fully implemented"; if (errmsg) return set_err(ENOSYS, "%s%s%s%s", errmsg, (type ? " [" : ""), (type ? type : ""), (type ? "]" : "")); return true; } bool ata_device::ata_identify_is_cached() const { return false; } ///////////////////////////////////////////////////////////////////////////// // tunnelled_device_base tunnelled_device_base::tunnelled_device_base(smart_device * tunnel_dev) : smart_device(never_called), m_tunnel_base_dev(tunnel_dev) { } tunnelled_device_base::~tunnelled_device_base() throw() { delete m_tunnel_base_dev; } bool tunnelled_device_base::is_open() const { return (m_tunnel_base_dev && m_tunnel_base_dev->is_open()); } bool tunnelled_device_base::open() { if (!m_tunnel_base_dev) return set_err(ENOSYS); if (!m_tunnel_base_dev->open()) return set_err(m_tunnel_base_dev->get_err()); return true; } bool tunnelled_device_base::close() { if (!m_tunnel_base_dev) return true; if (!m_tunnel_base_dev->close()) return set_err(m_tunnel_base_dev->get_err()); return true; } bool tunnelled_device_base::owns(const smart_device * dev) const { return (m_tunnel_base_dev && (m_tunnel_base_dev == dev)); } void tunnelled_device_base::release(const smart_device * dev) { if (m_tunnel_base_dev == dev) m_tunnel_base_dev = 0; } ///////////////////////////////////////////////////////////////////////////// // smart_interface // Pointer to (usually singleton) interface object returned by ::smi() smart_interface * smart_interface::s_instance; std::string smart_interface::get_os_version_str() { return SMARTMONTOOLS_BUILD_HOST; } std::string smart_interface::get_valid_dev_types_str() { // default std::string s = "ata, scsi, sat[,auto][,N][+TYPE], usbcypress[,X], usbjmicron[,p][,x][,N], usbsunplus"; // append custom std::string s2 = get_valid_custom_dev_types_str(); if (!s2.empty()) { s += ", "; s += s2; } return s; } std::string smart_interface::get_app_examples(const char * /*appname*/) { return ""; } int64_t smart_interface::get_timer_usec() { #if defined(HAVE_GETTIMEOFDAY) #if defined(HAVE_CLOCK_GETTIME) && defined(CLOCK_MONOTONIC) { static bool have_clock_monotonic = true; if (have_clock_monotonic) { struct timespec ts; if (!clock_gettime(CLOCK_MONOTONIC, &ts)) return ts.tv_sec * 1000000LL + ts.tv_nsec/1000; have_clock_monotonic = false; } } #endif { struct timeval tv; gettimeofday(&tv, 0); return tv.tv_sec * 1000000LL + tv.tv_usec; } #elif defined(HAVE_FTIME) { struct timeb tb; ftime(&tb); return tb.time * 1000000LL + tb.millitm * 1000; } #else return -1; #endif } bool smart_interface::disable_system_auto_standby(bool /*disable*/) { return set_err(ENOSYS); } bool smart_interface::set_err(int no, const char * msg, ...) { if (!msg) return set_err(no); m_err.no = no; va_list ap; va_start(ap, msg); m_err.msg = vstrprintf(msg, ap); va_end(ap); return false; } bool smart_interface::set_err(int no) { return set_err_var(&m_err, no); } bool smart_interface::set_err_var(smart_device::error_info * err, int no) { err->no = no; err->msg = get_msg_for_errno(no); if (err->msg.empty() && no != 0) err->msg = strprintf("Unknown error %d", no); return false; } const char * smart_interface::get_msg_for_errno(int no) { return strerror(no); } ///////////////////////////////////////////////////////////////////////////// // Default device factory smart_device * smart_interface::get_smart_device(const char * name, const char * type) { clear_err(); // Call platform specific autodetection if no device type specified smart_device * dev; if (!type || !*type) { dev = autodetect_smart_device(name); if (!dev && !get_errno()) set_err(EINVAL, "Unable to detect device type"); return dev; } // First check for platform specific device types dev = get_custom_smart_device(name, type); if (dev || get_errno()) return dev; if (!strcmp(type, "ata")) dev = get_ata_device(name, type); else if (!strcmp(type, "scsi")) dev = get_scsi_device(name, type); else if ( ((!strncmp(type, "sat", 3) && (!type[3] || strchr(",+", type[3]))) || (!strncmp(type, "usb", 3)))) { // Split "sat...+base..." -> ("sat...", "base...") unsigned satlen = strcspn(type, "+"); std::string sattype(type, satlen); const char * basetype = (type[satlen] ? type+satlen+1 : ""); // Recurse to allocate base device, default is standard SCSI if (!*basetype) basetype = "scsi"; smart_device_auto_ptr basedev( get_smart_device(name, basetype) ); if (!basedev) { set_err(EINVAL, "Type '%s+...': %s", sattype.c_str(), get_errmsg()); return 0; } // Result must be SCSI if (!basedev->is_scsi()) { set_err(EINVAL, "Type '%s+...': Device type '%s' is not SCSI", sattype.c_str(), basetype); return 0; } // Attach SAT tunnel ata_device * satdev = get_sat_device(sattype.c_str(), basedev->to_scsi()); if (!satdev) return 0; basedev.release(); return satdev; } else { set_err(EINVAL, "Unknown device type '%s'", type); return 0; } if (!dev && !get_errno()) set_err(EINVAL, "Not a device of type '%s'", type); return dev; } smart_device * smart_interface::get_custom_smart_device(const char * /*name*/, const char * /*type*/) { return 0; } std::string smart_interface::get_valid_custom_dev_types_str() { return ""; }