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403 lines
13 KiB
C++
403 lines
13 KiB
C++
//
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// Target.hpp
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// Clock Signal
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//
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// Created by Thomas Harte on 17/08/2019.
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// Copyright © 2019 Thomas Harte. All rights reserved.
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//
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#ifndef SCSI_Target_hpp
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#define SCSI_Target_hpp
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#include "SCSI.hpp"
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#include "../../../Outputs/Log.hpp"
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#include <cassert>
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#include <cstring>
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#include <functional>
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namespace SCSI {
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namespace Target {
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/*!
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Encapsulates the arguments supplied for a target SCSI command during
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the command phase plus any other data read since then.
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*/
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class CommandState {
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public:
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CommandState(const std::vector<uint8_t> &command, const std::vector<uint8_t> &received);
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// For read and write commands.
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struct ReadWrite {
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uint32_t address, number_of_blocks;
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};
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ReadWrite read_write_specs() const;
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// For inquiry commands.
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size_t allocated_inquiry_bytes() const;
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// For mode sense commands.
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struct ModeSense {
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bool exclude_block_descriptors = false;
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enum class PageControlValues {
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Current = 0,
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Changeable = 1,
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Default = 2,
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Saved = 3
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} page_control_values = PageControlValues::Current;
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uint8_t page_code;
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uint8_t subpage_code;
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uint16_t allocated_bytes;
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};
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ModeSense mode_sense_specs() const;
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struct ModeSelect {
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bool content_is_vendor_specific = true;
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bool revert_to_default = false;
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bool save_pages = false;
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uint16_t parameter_list_length = 0;
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};
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ModeSelect mode_select_specs() const;
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struct ReadBuffer {
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enum class Mode {
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CombinedHeaderAndData = 0,
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VendorSpecific = 1,
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Data = 2,
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Descriptor = 3,
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Reserved = 4
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} mode = Mode::CombinedHeaderAndData;
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uint8_t buffer_id = 0;
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uint32_t buffer_offset = 0, buffer_length = 0;
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};
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ReadBuffer read_buffer_specs() const;
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const std::vector<uint8_t> &received_data() const {
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return received_;
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}
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private:
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uint32_t address() const;
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uint16_t number_of_blocks() const;
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const std::vector<uint8_t> &data_;
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const std::vector<uint8_t> &received_;
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};
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/*!
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A Responder is supplied both (i) to the initial call-in to an Executor; and
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(ii) to all continuations provided by that Executor. It allows the next
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set of bus interactions to be dictated.
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*/
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struct Responder {
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using continuation = std::function<void(const CommandState &, Responder &)>;
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enum class Status {
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Good = 0x00,
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CheckCondition = 0x02,
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ConditionMet = 0x04,
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Busy = 0x08,
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Intermediate = 0x10,
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IntermediateConditionMet = 0x14,
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ReservationConflict = 0x18,
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CommandTerminated = 0x22,
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TaskSetFull = 0x28,
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ACAActive = 0x30,
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TaskAborted = 0x40
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};
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enum class Message {
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CommandComplete = 0x00
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};
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/*!
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Causes the SCSI device to send @c data to the initiator and
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call @c next when done.
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*/
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virtual void send_data(std::vector<uint8_t> &&data, continuation next) = 0;
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/*!
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Causes the SCSI device to receive @c length bytes from the initiator and
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call @c next when done. The bytes will be accessible via the CommandInput object.
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*/
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virtual void receive_data(size_t length, continuation next) = 0;
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/*!
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Communicates the supplied status to the initiator.
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*/
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virtual void send_status(Status, continuation next) = 0;
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/*!
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Communicates the supplied message to the initiator.
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*/
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virtual void send_message(Message, continuation next) = 0;
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/*!
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Ends the SCSI command.
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*/
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virtual void end_command() = 0;
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/*!
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Terminates a SCSI command, sending the proper sequence of status and message phases.
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*/
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void terminate_command(Status status) {
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send_status(status, [] (const Target::CommandState &, Target::Responder &responder) {
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responder.send_message(Target::Responder::Message::CommandComplete, [] (const Target::CommandState &, Target::Responder &responder) {
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responder.end_command();
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});
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});
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}
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};
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/*!
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Executors contain device-specific logic; when the target has completed
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the command phase it will call the appropriate method on its executor,
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supplying it with the command's arguments.
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If you implement a method, you should push a result and return @c true.
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Return @c false if you do not implement a method (or, just inherit from
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the basic executor below, and don't implement anything you don't support).
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*/
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struct Executor {
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/* Group 0 commands. */
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bool test_unit_ready(const CommandState &, Responder &responder) {
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/* "Returns zero status if addressed unit is powered on and ready. */
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responder.terminate_command(Target::Responder::Status::Good);
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return true;
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}
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bool rezero_unit(const CommandState &, Responder &) { return false; }
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bool request_sense(const CommandState &, Responder &) { return false; }
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bool format_unit(const CommandState &, Responder &) { return false; }
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bool seek(const CommandState &, Responder &) { return false; }
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bool reserve_unit(const CommandState &, Responder &) { return false; }
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bool release_unit(const CommandState &, Responder &) { return false; }
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bool read_diagnostic(const CommandState &, Responder &) { return false; }
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bool write_diagnostic(const CommandState &, Responder &) { return false; }
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/// Mode sense: the default implementation will call into the appropriate
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/// structured getter.
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bool mode_sense(const CommandState &state, Responder &responder) {
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const auto specs = state.mode_sense_specs();
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std::vector<uint8_t> response = {
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specs.page_code,
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uint8_t(specs.allocated_bytes)
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};
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switch(specs.page_code) {
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default:
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printf("Unknown mode sense page code %02x\n", specs.page_code);
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response.resize(specs.allocated_bytes);
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break;
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case 0x30:
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response.resize(34);
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strcpy(reinterpret_cast<char *>(&response[14]), "APPLE COMPUTER, INC"); // This seems to be required to satisfy the Apple HD SC Utility.
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break;
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}
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if(specs.allocated_bytes < response.size()) {
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response.resize(specs.allocated_bytes);
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}
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responder.send_data(std::move(response), [] (const Target::CommandState &, Target::Responder &responder) {
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responder.terminate_command(Target::Responder::Status::Good);
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});
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return true;
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}
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bool mode_select(const CommandState &state, Responder &responder) {
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const auto specs = state.mode_select_specs();
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responder.receive_data(specs.parameter_list_length, [] (const Target::CommandState &, Target::Responder &responder) {
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// TODO: parse data according to current sense mode.
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responder.terminate_command(Target::Responder::Status::Good);
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});
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return true;
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}
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/// Inquiry: the default implementation will call the structured version and
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/// package appropriately.
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struct Inquiry {
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enum class DeviceType {
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DirectAccess = 0,
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SequentialAccess = 1,
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Printer = 2,
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Processor = 3,
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WriteOnceMultipleRead = 4,
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ReadOnlyDirectAccess = 5,
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Scanner = 6,
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OpticalMemory = 7,
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MediumChanger = 8,
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Communications = 9,
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} device_type = DeviceType::DirectAccess;
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bool is_removeable = false;
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uint8_t iso_standard = 0, ecma_standard = 0, ansi_standard = 0;
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bool supports_asynchronous_events = false;
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bool supports_terminate_io_process = false;
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bool supports_relative_addressing = false;
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bool supports_synchronous_transfer = true;
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bool supports_linked_commands = false;
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bool supports_command_queing = false;
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bool supports_soft_reset = false;
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char vendor_identifier[9] = "";
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char product_identifier[17] = "";
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char product_revision_level[5] = "";
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Inquiry(const char *vendor, const char *product, const char *revision) {
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assert(strlen(vendor) <= 8);
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assert(strlen(product) <= 16);
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assert(strlen(revision) <= 4);
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strcpy(vendor_identifier, vendor);
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strcpy(product_identifier, product);
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strcpy(product_revision_level, revision);
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}
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Inquiry() = default;
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};
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Inquiry inquiry_values() {
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return Inquiry();
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}
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bool inquiry(const CommandState &state, Responder &responder) {
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const Inquiry inq = inquiry_values();
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// Set up the easy fields.
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std::vector<uint8_t> response = {
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uint8_t(inq.device_type),
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uint8_t(inq.is_removeable ? 0x80 : 0x00),
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uint8_t((inq.iso_standard << 5) | (inq.ecma_standard << 3) | (inq.ansi_standard)),
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uint8_t((inq.supports_asynchronous_events ? 0x80 : 0x00) | (inq.supports_terminate_io_process ? 0x40 : 0x00) | 0x02),
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32, /* Additional length: 36 - 4. */
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0x00, /* Reserved. */
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0x00, /* Reserved. */
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uint8_t(
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(inq.supports_relative_addressing ? 0x80 : 0x00) |
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/* b6: supports 32-bit data; b5: supports 16-bit data. */
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(inq.supports_synchronous_transfer ? 0x10 : 0x00) |
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(inq.supports_linked_commands ? 0x08 : 0x00) |
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/* b3: reserved. */
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(inq.supports_command_queing ? 0x02 : 0x00) |
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(inq.supports_soft_reset ? 0x01 : 0x00)
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),
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0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, /* Space for the vendor ID. */
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0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00,
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0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, /* Space for the product ID. */
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0x00, 0x00, 0x00, 0x00 /* Space for the revision level. */
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};
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auto copy_string = [] (uint8_t *destination, const char *source, size_t length) -> void {
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// Determine length of source and copy in as much as possible.
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const auto source_length = std::min(strlen(source), length);
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memcpy(destination, source, source_length);
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// Fill the rest with spaces.
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memset(&destination[source_length], ' ', length - source_length);
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};
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copy_string(&response[8], inq.vendor_identifier, 8);
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copy_string(&response[16], inq.product_identifier, 16);
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copy_string(&response[32], inq.product_revision_level, 4);
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// Truncate if requested.
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const auto allocated_bytes = state.allocated_inquiry_bytes();
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if(allocated_bytes < response.size()) {
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response.resize(allocated_bytes);
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}
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responder.send_data(std::move(response), [] (const Target::CommandState &, Target::Responder &responder) {
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responder.terminate_command(Target::Responder::Status::Good);
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});
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return true;
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}
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/* Group 0/1 commands. */
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bool read(const CommandState &, Responder &) { return false; }
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bool write(const CommandState &, Responder &) { return false; }
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/* Group 1 commands. */
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bool read_capacity(const CommandState &, Responder &) { return false; }
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bool write_and_verify(const CommandState &, Responder &) { return false; }
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bool verify(const CommandState &, Responder &) { return false; }
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bool search_data_equal(const CommandState &, Responder &) { return false; }
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bool search_data_high(const CommandState &, Responder &) { return false; }
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bool search_data_low(const CommandState &, Responder &) { return false; }
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bool read_buffer(const CommandState &state, Responder &responder) {
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// Since I have no idea what earthly function READ BUFFER is meant to allow,
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// the default implementation just returns an empty buffer of the requested size.
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const auto specs = state.read_buffer_specs();
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responder.send_data(std::vector<uint8_t>(specs.buffer_length), [] (const Target::CommandState &, Target::Responder &responder) {
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responder.terminate_command(Target::Responder::Status::Good);
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});
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return true;
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}
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/* Group 5 commands. */
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bool set_block_limits(const CommandState &, Responder &) { return false; }
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};
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/*!
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A template for any SCSI target; provides the necessary bus glue to
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receive and respond to commands. Specific targets should be implemented
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as Executors.
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*/
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template <typename Executor> class Target: public Bus::Observer, public Responder {
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public:
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/*!
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Instantiates a target attached to @c bus,
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with SCSI ID @c scsi_id — a number in the range 0 to 7.
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Received commands will be handed to the Executor to perform.
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*/
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Target(Bus &bus, int scsi_id);
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inline Executor *operator->() {
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return &executor_;
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}
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private:
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Executor executor_;
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// Bus::Observer.
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void scsi_bus_did_change(Bus *, BusState new_state, double time_since_change) final;
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// Responder
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void send_data(std::vector<uint8_t> &&data, continuation next) final;
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void receive_data(size_t length, continuation next) final;
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void send_status(Status, continuation next) final;
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void send_message(Message, continuation next) final;
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void end_command() final;
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// Instance storage.
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Bus &bus_;
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const BusState scsi_id_mask_;
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const size_t scsi_bus_device_id_;
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enum class Phase {
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AwaitingSelection,
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Command,
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ReceivingData,
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SendingData,
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SendingStatus,
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SendingMessage
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} phase_ = Phase::AwaitingSelection;
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BusState bus_state_ = DefaultBusState;
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void set_device_output(BusState state) {
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expected_control_state_ = state & (Line::Control | Line::Input | Line::Message);
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bus_.set_device_output(scsi_bus_device_id_, state);
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}
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BusState expected_control_state_ = DefaultBusState;
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void begin_command(uint8_t first_byte);
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std::vector<uint8_t> command_;
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Status status_;
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Message message_;
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size_t command_pointer_ = 0;
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bool dispatch_command();
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std::vector<uint8_t> data_;
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size_t data_pointer_ = 0;
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continuation next_function_;
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};
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#include "TargetImplementation.hpp"
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}
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}
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#endif /* SCSI_Target_hpp */
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