fastboot/fuzzy_fastboot/main.cpp

/*
 * Copyright (C) 2018 The Android Open Source Project
 * 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.
 *
 * 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.
 */
#include <errno.h>
#include <fcntl.h>
#include <stdint.h>
#include <stdio.h>
#include <sys/stat.h>
#include <sys/time.h>
#include <sys/types.h>
#include <unistd.h>
#include <chrono>
#include <cstdlib>
#include <fstream>
#include <map>
#include <random>
#include <regex>
#include <set>
#include <thread>
#include <vector>

#include <android-base/file.h>
#include <android-base/parseint.h>
#include <android-base/stringprintf.h>
#include <android-base/strings.h>
#include <gtest/gtest.h>
#include <sparse/sparse.h>

#include "fastboot_driver.h"
#include "usb.h"

#include "extensions.h"
#include "fixtures.h"
#include "test_utils.h"
#include "transport_sniffer.h"

namespace fastboot {

extension::Configuration config;  // The parsed XML config

std::string SEARCH_PATH;
std::string OUTPUT_PATH;

// gtest's INSTANTIATE_TEST_CASE_P() must be at global scope,
// so our autogenerated tests must be as well
std::vector<std::pair<std::string, extension::Configuration::GetVar>> GETVAR_XML_TESTS;
std::vector<std::tuple<std::string, bool, extension::Configuration::CommandTest>> OEM_XML_TESTS;
std::vector<std::pair<std::string, extension::Configuration::PartitionInfo>> PARTITION_XML_TESTS;
std::vector<std::pair<std::string, extension::Configuration::PartitionInfo>>
        PARTITION_XML_WRITEABLE;
std::vector<std::pair<std::string, extension::Configuration::PartitionInfo>>
        PARTITION_XML_WRITE_HASHABLE;
std::vector<std::pair<std::string, extension::Configuration::PartitionInfo>>
        PARTITION_XML_WRITE_PARSED;
std::vector<std::pair<std::string, extension::Configuration::PartitionInfo>>
        PARTITION_XML_WRITE_HASH_NONPARSED;
std::vector<std::pair<std::string, extension::Configuration::PartitionInfo>>
        PARTITION_XML_USERDATA_CHECKSUM_WRITEABLE;
std::vector<std::pair<std::string, extension::Configuration::PackedInfoTest>>
        PACKED_XML_SUCCESS_TESTS;
std::vector<std::pair<std::string, extension::Configuration::PackedInfoTest>> PACKED_XML_FAIL_TESTS;
// This only has 1 or zero elements so it will disappear from gtest when empty
std::vector<std::pair<std::string, extension::Configuration::PartitionInfo>>
        SINGLE_PARTITION_XML_WRITE_HASHABLE;

const std::string DEFAULT_OUPUT_NAME = "out.img";
// const char scratch_partition[] = "userdata";
const std::vector<std::string> CMDS{"boot",    "continue", "download:",   "erase:", "flash:",
                                    "getvar:", "reboot",   "set_active:", "upload"};

// For pretty printing we need all these overloads
::std::ostream& operator<<(::std::ostream& os, const RetCode& ret) {
    return os << FastBootDriver::RCString(ret);
}

bool PartitionHash(FastBootDriver* fb, const std::string& part, std::string* hash, int* retcode,
                   std::string* err_msg) {
    if (config.checksum.empty()) {
        return -1;
    }

    std::string resp;
    std::vector<std::string> info;
    const std::string cmd = config.checksum + ' ' + part;
    RetCode ret;
    if ((ret = fb->RawCommand(cmd, &resp, &info)) != SUCCESS) {
        *err_msg =
                android::base::StringPrintf("Hashing partition with command '%s' failed with: %s",
                                            cmd.c_str(), fb->RCString(ret).c_str());
        return false;
    }
    std::stringstream imploded;
    std::copy(info.begin(), info.end(), std::ostream_iterator<std::string>(imploded, "\n"));

    // If payload, we validate that as well
    const std::vector<std::string> args = SplitBySpace(config.checksum_parser);
    std::vector<std::string> prog_args(args.begin() + 1, args.end());
    prog_args.push_back(resp);                          // Pass in the full command
    prog_args.push_back(SEARCH_PATH + imploded.str());  // Pass in the save location

    int pipe;
    pid_t pid = StartProgram(args[0], prog_args, &pipe);
    if (pid <= 0) {
        *err_msg = android::base::StringPrintf("Launching hash parser '%s' failed with: %s",
                                               config.checksum_parser.c_str(), strerror(errno));
        return false;
    }
    *retcode = WaitProgram(pid, pipe, hash);
    if (*retcode) {
        // In this case the stderr pipe is a log message
        *err_msg = android::base::StringPrintf("Hash parser '%s' failed with: %s",
                                               config.checksum_parser.c_str(), hash->c_str());
        return false;
    }

    return true;
}

bool SparseToBuf(sparse_file* sf, std::vector<char>* out, bool with_crc = false) {
    int64_t len = sparse_file_len(sf, true, with_crc);
    if (len <= 0) {
        return false;
    }
    out->clear();
    auto cb = [](void* priv, const void* data, size_t len) {
        auto vec = static_cast<std::vector<char>*>(priv);
        const char* cbuf = static_cast<const char*>(data);
        vec->insert(vec->end(), cbuf, cbuf + len);
        return 0;
    };

    return !sparse_file_callback(sf, true, with_crc, cb, out);
}

// Only allow alphanumeric, _, -, and .
const auto not_allowed = [](char c) -> int {
    return !(isalnum(c) || c == '_' || c == '-' || c == '.');
};

// Test that USB even works
TEST(USBFunctionality, USBConnect) {
    const auto matcher = [](usb_ifc_info* info) -> int {
        return FastBootTest::MatchFastboot(info, fastboot::FastBootTest::device_serial);
    };
    Transport* transport = nullptr;
    for (int i = 0; i < FastBootTest::MAX_USB_TRIES && !transport; i++) {
        transport = usb_open(matcher);
        std::this_thread::sleep_for(std::chrono::milliseconds(10));
    }
    ASSERT_NE(transport, nullptr) << "Could not find the fastboot device after: "
                                  << 10 * FastBootTest::MAX_USB_TRIES << "ms";
    if (transport) {
        transport->Close();
        delete transport;
    }
}

// Test commands related to super partition
TEST_F(LogicalPartitionCompliance, SuperPartition) {
    ASSERT_TRUE(UserSpaceFastboot());
    std::string partition_type;
    // getvar partition-type:super must fail for retrofit devices because the
    // partition does not exist.
    if (fb->GetVar("partition-type:super", &partition_type) == SUCCESS) {
        std::string is_logical;
        EXPECT_EQ(fb->GetVar("is-logical:super", &is_logical), SUCCESS)
                << "getvar is-logical:super failed";
        EXPECT_EQ(is_logical, "no") << "super must not be a logical partition";
        std::string super_name;
        EXPECT_EQ(fb->GetVar("super-partition-name", &super_name), SUCCESS)
                << "'getvar super-partition-name' failed";
        EXPECT_EQ(super_name, "super") << "'getvar super-partition-name' must return 'super' for "
                                          "device with a super partition";
    }
}

// Test 'fastboot getvar is-logical'
TEST_F(LogicalPartitionCompliance, GetVarIsLogical) {
    ASSERT_TRUE(UserSpaceFastboot());
    std::string has_slot;
    EXPECT_EQ(fb->GetVar("has-slot:system", &has_slot), SUCCESS) << "getvar has-slot:system failed";
    std::string is_logical_cmd_system = "is-logical:system";
    std::string is_logical_cmd_vendor = "is-logical:vendor";
    std::string is_logical_cmd_boot = "is-logical:boot";
    if (has_slot == "yes") {
        std::string current_slot;
        ASSERT_EQ(fb->GetVar("current-slot", &current_slot), SUCCESS)
                << "getvar current-slot failed";
        std::string slot_suffix = "_" + current_slot;
        is_logical_cmd_system += slot_suffix;
        is_logical_cmd_vendor += slot_suffix;
        is_logical_cmd_boot += slot_suffix;
    }
    std::string is_logical;
    EXPECT_EQ(fb->GetVar(is_logical_cmd_system, &is_logical), SUCCESS)
            << "system must be a logical partition";
    EXPECT_EQ(is_logical, "yes");
    EXPECT_EQ(fb->GetVar(is_logical_cmd_vendor, &is_logical), SUCCESS)
            << "vendor must be a logical partition";
    EXPECT_EQ(is_logical, "yes");
    EXPECT_EQ(fb->GetVar(is_logical_cmd_boot, &is_logical), SUCCESS)
            << "boot must not be logical partition";
    EXPECT_EQ(is_logical, "no");
}

TEST_F(LogicalPartitionCompliance, FastbootRebootTest) {
    ASSERT_TRUE(UserSpaceFastboot());
    GTEST_LOG_(INFO) << "Rebooting back to fastbootd mode";
    fb->RebootTo("fastboot");

    ReconnectFastbootDevice();
    ASSERT_TRUE(UserSpaceFastboot());
}

// Testing creation/resize/delete of logical partitions
TEST_F(LogicalPartitionCompliance, CreateResizeDeleteLP) {
    ASSERT_TRUE(UserSpaceFastboot());
    std::string test_partition_name = "test_partition";
    std::string slot_count;
    // Add suffix to test_partition_name if device is slotted.
    EXPECT_EQ(fb->GetVar("slot-count", &slot_count), SUCCESS) << "getvar slot-count failed";
    int32_t num_slots = strtol(slot_count.c_str(), nullptr, 10);
    if (num_slots > 0) {
        std::string current_slot;
        EXPECT_EQ(fb->GetVar("current-slot", &current_slot), SUCCESS)
                << "getvar current-slot failed";
        std::string slot_suffix = "_" + current_slot;
        test_partition_name += slot_suffix;
    }

    GTEST_LOG_(INFO) << "Testing 'fastboot create-logical-partition' command";
    EXPECT_EQ(fb->CreatePartition(test_partition_name, "0"), SUCCESS)
            << "create-logical-partition failed";
    GTEST_LOG_(INFO) << "Testing 'fastboot resize-logical-partition' command";
    EXPECT_EQ(fb->ResizePartition(test_partition_name, "4096"), SUCCESS)
            << "resize-logical-partition failed";
    std::vector<char> buf(4096);

    GTEST_LOG_(INFO) << "Flashing a logical partition..";
    EXPECT_EQ(fb->FlashPartition(test_partition_name, buf), SUCCESS)
            << "flash logical -partition failed";

    GTEST_LOG_(INFO) << "Testing 'fastboot delete-logical-partition' command";
    EXPECT_EQ(fb->DeletePartition(test_partition_name), SUCCESS)
            << "delete logical-partition failed";
}

// Conformance tests
TEST_F(Conformance, GetVar) {
    std::string product;
    EXPECT_EQ(fb->GetVar("product", &product), SUCCESS) << "getvar:product failed";
    EXPECT_NE(product, "") << "getvar:product response was empty string";
    EXPECT_EQ(std::count_if(product.begin(), product.end(), not_allowed), 0)
            << "getvar:product response contained illegal chars";
    EXPECT_LE(product.size(), FB_RESPONSE_SZ - 4) << "getvar:product response was too large";
}

TEST_F(Conformance, GetVarVersionBootloader) {
    std::string var;
    EXPECT_EQ(fb->GetVar("version-bootloader", &var), SUCCESS)
            << "getvar:version-bootloader failed";
    EXPECT_NE(var, "") << "getvar:version-bootloader response was empty string";
    EXPECT_EQ(std::count_if(var.begin(), var.end(), not_allowed), 0)
            << "getvar:version-bootloader response contained illegal chars";
    EXPECT_LE(var.size(), FB_RESPONSE_SZ - 4) << "getvar:version-bootloader response was too large";
}

TEST_F(Conformance, GetVarVersionBaseband) {
    std::string var;
    EXPECT_EQ(fb->GetVar("version-baseband", &var), SUCCESS) << "getvar:version-baseband failed";
    EXPECT_NE(var, "") << "getvar:version-baseband response was empty string";
    EXPECT_EQ(std::count_if(var.begin(), var.end(), not_allowed), 0)
            << "getvar:version-baseband response contained illegal chars";
    EXPECT_LE(var.size(), FB_RESPONSE_SZ - 4) << "getvar:version-baseband response was too large";
}

TEST_F(Conformance, GetVarSerialNo) {
    std::string var;
    EXPECT_EQ(fb->GetVar("serialno", &var), SUCCESS) << "getvar:serialno failed";
    EXPECT_NE(var, "") << "getvar:serialno can not be empty string";
    EXPECT_EQ(std::count_if(var.begin(), var.end(), isalnum), var.size())
            << "getvar:serialno must be alpha-numeric";
    EXPECT_LE(var.size(), FB_RESPONSE_SZ - 4) << "getvar:serialno response is too long";
}

TEST_F(Conformance, GetVarSecure) {
    std::string var;
    EXPECT_EQ(fb->GetVar("secure", &var), SUCCESS);
    EXPECT_TRUE(var == "yes" || var == "no");
}

TEST_F(Conformance, GetVarOffModeCharge) {
    std::string var;
    EXPECT_EQ(fb->GetVar("off-mode-charge", &var), SUCCESS) << "getvar:off-mode-charge failed";
    EXPECT_TRUE(var == "0" || var == "1") << "getvar:off-mode-charge response must be '0' or '1'";
}

TEST_F(Conformance, GetVarVariant) {
    std::string var;
    EXPECT_EQ(fb->GetVar("variant", &var), SUCCESS) << "getvar:variant failed";
    EXPECT_NE(var, "") << "getvar:variant response can not be empty";
    EXPECT_LE(var.size(), FB_RESPONSE_SZ - 4) << "getvar:variant response is too large";
}

TEST_F(Conformance, GetVarRevision) {
    std::string var;
    EXPECT_EQ(fb->GetVar("hw-revision", &var), SUCCESS) << "getvar:hw-revision failed";
    EXPECT_NE(var, "") << "getvar:battery-voltage response was empty";
    EXPECT_EQ(std::count_if(var.begin(), var.end(), not_allowed), 0)
            << "getvar:hw-revision contained illegal ASCII chars";
    EXPECT_LE(var.size(), FB_RESPONSE_SZ - 4) << "getvar:hw-revision response was too large";
}

TEST_F(Conformance, GetVarBattVoltage) {
    std::string var;
    EXPECT_EQ(fb->GetVar("battery-voltage", &var), SUCCESS) << "getvar:battery-voltage failed";
    EXPECT_NE(var, "") << "getvar:battery-voltage response was empty";
    EXPECT_EQ(std::count_if(var.begin(), var.end(), not_allowed), 0)
            << "getvar:battery-voltage response contains illegal ASCII chars";
    EXPECT_LE(var.size(), FB_RESPONSE_SZ - 4)
            << "getvar:battery-voltage response is too large: " + var;
}

TEST_F(Conformance, GetVarBattVoltageOk) {
    std::string var;
    EXPECT_EQ(fb->GetVar("battery-soc-ok", &var), SUCCESS) << "getvar:battery-soc-ok failed";
    EXPECT_TRUE(var == "yes" || var == "no") << "getvar:battery-soc-ok must be 'yes' or 'no'";
}

void AssertHexUint32(const std::string& name, const std::string& var) {
    ASSERT_NE(var, "") << "getvar:" << name << " responded with empty string";
    // This must start with 0x
    ASSERT_FALSE(isspace(var.front()))
            << "getvar:" << name << " responded with a string with leading whitespace";
    ASSERT_FALSE(var.compare(0, 2, "0x"))
            << "getvar:" << name << " responded with a string that does not start with 0x...";
    int64_t size = strtoll(var.c_str(), nullptr, 16);
    ASSERT_GT(size, 0) << "'" + var + "' is not a valid response from getvar:" << name;
    // At most 32-bits
    ASSERT_LE(size, std::numeric_limits<uint32_t>::max())
            << "getvar:" << name << " must fit in a uint32_t";
    ASSERT_LE(var.size(), FB_RESPONSE_SZ - 4)
            << "getvar:" << name << " responded with too large of string: " + var;
}

TEST_F(Conformance, GetVarDownloadSize) {
    std::string var;
    EXPECT_EQ(fb->GetVar("max-download-size", &var), SUCCESS) << "getvar:max-download-size failed";
    AssertHexUint32("max-download-size", var);
}

// If fetch is supported, getvar:max-fetch-size must return a hex string.
TEST_F(Conformance, GetVarFetchSize) {
    std::string var;
    if (SUCCESS != fb->GetVar("max-fetch-size", &var)) {
        GTEST_SKIP() << "getvar:max-fetch-size failed";
    }
    AssertHexUint32("max-fetch-size", var);
}

TEST_F(Conformance, GetVarAll) {
    std::vector<std::string> vars;
    EXPECT_EQ(fb->GetVarAll(&vars), SUCCESS) << "getvar:all failed";
    EXPECT_GT(vars.size(), 0) << "getvar:all did not respond with any INFO responses";
    for (const auto& s : vars) {
        EXPECT_LE(s.size(), FB_RESPONSE_SZ - 4)
                << "getvar:all included an INFO response: 'INFO" + s << "' which is too long";
    }
}

TEST_F(Conformance, UnlockAbility) {
    std::string resp;
    std::vector<std::string> info;
    // Userspace fastboot implementations do not have a way to get this
    // information.
    if (UserSpaceFastboot()) {
        GTEST_LOG_(INFO) << "This test is skipped for userspace fastboot.";
        return;
    }
    EXPECT_EQ(fb->RawCommand("flashing get_unlock_ability", &resp, &info), SUCCESS)
            << "'flashing get_unlock_ability' failed";
    // There are two ways this can be reported, through info or the actual response
    char last;
    if (!resp.empty()) {  // must be in the response
        last = resp.back();
    } else {  // else must be in info
        ASSERT_FALSE(info.empty()) << "'flashing get_unlock_ability' returned empty response";
        ASSERT_FALSE(info.back().empty()) << "Expected non-empty info response";
        last = info.back().back();
    }
    ASSERT_TRUE(last == '1' || last == '0') << "Unlock ability must report '0' or '1' in response";
}

TEST_F(Conformance, PartitionInfo) {
    std::vector<std::tuple<std::string, uint64_t>> parts;
    EXPECT_EQ(fb->Partitions(&parts), SUCCESS) << "getvar:all failed";
    EXPECT_GT(parts.size(), 0)
            << "getvar:all did not report any partition-size: through INFO responses";
    std::set<std::string> allowed{"ext4", "f2fs", "raw"};
    for (const auto& p : parts) {
        EXPECT_GE(std::get<1>(p), 0);
        std::string part(std::get<0>(p));
        std::set<std::string> allowed{"ext4", "f2fs", "raw"};
        std::string resp;
        EXPECT_EQ(fb->GetVar("partition-type:" + part, &resp), SUCCESS);
        EXPECT_NE(allowed.find(resp), allowed.end()) << "getvar:partition-type:" + part << " was '"
                                                     << resp << "' this is not a valid type";
        const std::string cmd = "partition-size:" + part;
        EXPECT_EQ(fb->GetVar(cmd, &resp), SUCCESS);

        // This must start with 0x
        EXPECT_FALSE(isspace(resp.front()))
                << cmd + " responded with a string with leading whitespace";
        EXPECT_FALSE(resp.compare(0, 2, "0x"))
                << cmd + "responded with a string that does not start with 0x...";
        uint64_t size;
        ASSERT_TRUE(android::base::ParseUint(resp, &size))
                << "'" + resp + "' is not a valid response from " + cmd;
    }
}

TEST_F(Conformance, Slots) {
    std::string var;
    ASSERT_EQ(fb->GetVar("slot-count", &var), SUCCESS) << "getvar:slot-count failed";
    ASSERT_EQ(std::count_if(var.begin(), var.end(), isdigit), var.size())
            << "'" << var << "' is not all digits which it should be for getvar:slot-count";
    int32_t num_slots = strtol(var.c_str(), nullptr, 10);

    // Can't run out of alphabet letters...
    ASSERT_LE(num_slots, 26) << "What?! You can't have more than 26 slots";

    std::vector<std::tuple<std::string, uint64_t>> parts;
    EXPECT_EQ(fb->Partitions(&parts), SUCCESS) << "getvar:all failed";

    std::map<std::string, std::set<char>> part_slots;
    if (num_slots > 0) {
        EXPECT_EQ(fb->GetVar("current-slot", &var), SUCCESS) << "getvar:current-slot failed";

        for (const auto& p : parts) {
            std::string part(std::get<0>(p));
            std::regex reg("([[:graph:]]*)_([[:lower:]])");
            std::smatch sm;

            if (std::regex_match(part, sm, reg)) {  // This partition has slots
                std::string part_base(sm[1]);
                std::string slot(sm[2]);
                EXPECT_EQ(fb->GetVar("has-slot:" + part_base, &var), SUCCESS)
                        << "'getvar:has-slot:" << part_base << "' failed";
                EXPECT_EQ(var, "yes") << "'getvar:has-slot:" << part_base << "' was not 'yes'";
                EXPECT_TRUE(islower(slot.front()))
                        << "'" << slot.front() << "' is an invalid slot-suffix for " << part_base;
                std::set<char> tmp{slot.front()};
                part_slots.emplace(part_base, tmp);
                part_slots.at(part_base).insert(slot.front());
            } else {
                EXPECT_EQ(fb->GetVar("has-slot:" + part, &var), SUCCESS)
                        << "'getvar:has-slot:" << part << "' failed";
                EXPECT_EQ(var, "no") << "'getvar:has-slot:" << part << "' should be no";
            }
        }
        // Ensure each partition has the correct slot suffix
        for (const auto& iter : part_slots) {
            const std::set<char>& char_set = iter.second;
            std::string chars;
            for (char c : char_set) {
                chars += c;
                chars += ',';
            }
            EXPECT_EQ(char_set.size(), num_slots)
                    << "There should only be slot suffixes from a to " << 'a' + num_slots - 1
                    << " instead encountered: " << chars;
            for (const char c : char_set) {
                EXPECT_GE(c, 'a') << "Encountered invalid slot suffix of '" << c << "'";
                EXPECT_LT(c, 'a' + num_slots) << "Encountered invalid slot suffix of '" << c << "'";
            }
        }
    }
}

TEST_F(Conformance, SetActive) {
    std::string var;
    ASSERT_EQ(fb->GetVar("slot-count", &var), SUCCESS) << "getvar:slot-count failed";
    ASSERT_EQ(std::count_if(var.begin(), var.end(), isdigit), var.size())
            << "'" << var << "' is not all digits which it should be for getvar:slot-count";
    int32_t num_slots = strtol(var.c_str(), nullptr, 10);

    // Can't run out of alphabet letters...
    ASSERT_LE(num_slots, 26) << "You can't have more than 26 slots";

    for (char c = 'a'; c < 'a' + num_slots; c++) {
        const std::string slot(&c, &c + 1);
        ASSERT_EQ(fb->SetActive(slot), SUCCESS) << "Set active for slot '" << c << "' failed";
        ASSERT_EQ(fb->GetVar("current-slot", &var), SUCCESS) << "getvar:current-slot failed";
        EXPECT_EQ(var, slot) << "getvar:current-slot repots incorrect slot after setting it";
    }
}

TEST_F(Conformance, LockAndUnlockPrompt) {
    std::string resp;
    ASSERT_EQ(fb->GetVar("unlocked", &resp), SUCCESS) << "getvar:unlocked failed";
    ASSERT_TRUE(resp == "yes" || resp == "no")
            << "Device did not respond with 'yes' or 'no' for getvar:unlocked";
    bool curr = resp == "yes";
    if (UserSpaceFastboot()) {
        GTEST_LOG_(INFO) << "This test is skipped for userspace fastboot.";
        return;
    }

    for (int i = 0; i < 2; i++) {
        std::string action = !curr ? "unlock" : "lock";
        printf("Device should prompt to '%s' bootloader, select 'no'\n", action.c_str());
        SetLockState(!curr, false);
        ASSERT_EQ(fb->GetVar("unlocked", &resp), SUCCESS) << "getvar:unlocked failed";
        ASSERT_EQ(resp, curr ? "yes" : "no") << "The locked/unlocked state of the bootloader "
                                                "incorrectly changed after selecting no";
        printf("Device should prompt to '%s' bootloader, select 'yes'\n", action.c_str());
        SetLockState(!curr, true);
        ASSERT_EQ(fb->GetVar("unlocked", &resp), SUCCESS) << "getvar:unlocked failed";
        ASSERT_EQ(resp, !curr ? "yes" : "no") << "The locked/unlocked state of the bootloader "
                                                 "failed to change after selecting yes";
        curr = !curr;
    }
}

TEST_F(Conformance, SparseBlockSupport0) {
    // The sparse block size can be any multiple of 4
    std::string var;
    EXPECT_EQ(fb->GetVar("max-download-size", &var), SUCCESS) << "getvar:max-download-size failed";
    int64_t size = strtoll(var.c_str(), nullptr, 16);

    // It is reasonable to expect it to handle a single dont care block equal to its DL size
    for (int64_t bs = 4; bs < size; bs <<= 1) {
        SparseWrapper sparse(bs, bs);
        ASSERT_TRUE(*sparse) << "Sparse file creation failed on: " << bs;
        EXPECT_EQ(fb->Download(*sparse), SUCCESS) << "Download sparse failed: " << sparse.Rep();
        EXPECT_EQ(fb->Flash("userdata"), SUCCESS) << "Flashing sparse failed: " << sparse.Rep();
    }
}

TEST_F(Conformance, SparseBlockSupport1) {
    // The sparse block size can be any multiple of 4
    std::string var;
    EXPECT_EQ(fb->GetVar("max-download-size", &var), SUCCESS) << "getvar:max-download-size failed";
    int64_t size = strtoll(var.c_str(), nullptr, 16);

    // handle a packed block to half its max download size block
    for (int64_t bs = 4; bs < size / 2; bs <<= 1) {
        SparseWrapper sparse(bs, bs);
        ASSERT_TRUE(*sparse) << "Sparse file creation failed on: " << bs;
        std::vector<char> buf = RandomBuf(bs);
        ASSERT_EQ(sparse_file_add_data(*sparse, buf.data(), buf.size(), 0), 0)
                << "Adding data failed to sparse file: " << sparse.Rep();
        EXPECT_EQ(fb->Download(*sparse), SUCCESS) << "Download sparse failed: " << sparse.Rep();
        EXPECT_EQ(fb->Flash("userdata"), SUCCESS) << "Flashing sparse failed: " << sparse.Rep();
    }
}

// A single don't care download
TEST_F(Conformance, SparseDownload0) {
    SparseWrapper sparse(4096, 4096);
    ASSERT_TRUE(*sparse) << "Sparse image creation failed";
    EXPECT_EQ(fb->Download(*sparse), SUCCESS) << "Download sparse failed: " << sparse.Rep();
    EXPECT_EQ(fb->Flash("userdata"), SUCCESS) << "Flashing sparse failed: " << sparse.Rep();
}

TEST_F(Conformance, SparseDownload1) {
    SparseWrapper sparse(4096, 10 * 4096);
    ASSERT_TRUE(*sparse) << "Sparse image creation failed";
    std::vector<char> buf = RandomBuf(4096);
    ASSERT_EQ(sparse_file_add_data(*sparse, buf.data(), buf.size(), 9), 0)
            << "Adding data failed to sparse file: " << sparse.Rep();
    EXPECT_EQ(fb->Download(*sparse), SUCCESS) << "Download sparse failed: " << sparse.Rep();
    EXPECT_EQ(fb->Flash("userdata"), SUCCESS) << "Flashing sparse failed: " << sparse.Rep();
}

TEST_F(Conformance, SparseDownload2) {
    SparseWrapper sparse(4096, 4097);
    ASSERT_TRUE(*sparse) << "Sparse image creation failed";
    std::vector<char> buf = RandomBuf(4096);
    ASSERT_EQ(sparse_file_add_data(*sparse, buf.data(), buf.size(), 0), 0)
            << "Adding data failed to sparse file: " << sparse.Rep();
    std::vector<char> buf2 = RandomBuf(1);
    ASSERT_EQ(sparse_file_add_data(*sparse, buf.data(), buf.size(), 1), 0)
            << "Adding data failed to sparse file: " << sparse.Rep();
    EXPECT_EQ(fb->Download(*sparse), SUCCESS) << "Download sparse failed: " << sparse.Rep();
    EXPECT_EQ(fb->Flash("userdata"), SUCCESS) << "Flashing sparse failed: " << sparse.Rep();
}

TEST_F(Conformance, SparseDownload3) {
    std::string var;
    EXPECT_EQ(fb->GetVar("max-download-size", &var), SUCCESS) << "getvar:max-download-size failed";
    int size = strtoll(var.c_str(), nullptr, 16);

    SparseWrapper sparse(4096, size);
    ASSERT_TRUE(*sparse) << "Sparse image creation failed";
    // Don't want this to take forever
    unsigned num_chunks = std::min(1000, size / (2 * 4096));
    for (int i = 0; i < num_chunks; i++) {
        std::vector<char> buf;
        int r = random_int(0, 2);
        // Three cases
        switch (r) {
            case 0:
                break;  // Dont Care chunnk
            case 1:     // Buffer
                buf = RandomBuf(4096);
                ASSERT_EQ(sparse_file_add_data(*sparse, buf.data(), buf.size(), i), 0)
                        << "Adding data failed to sparse file: " << sparse.Rep();
                break;
            case 2:  // fill
                ASSERT_EQ(sparse_file_add_fill(*sparse, 0xdeadbeef, 4096, i), 0)
                        << "Adding fill to sparse file failed: " << sparse.Rep();
                break;
        }
    }
    EXPECT_EQ(fb->Download(*sparse), SUCCESS) << "Download sparse failed: " << sparse.Rep();
    EXPECT_EQ(fb->Flash("userdata"), SUCCESS) << "Flashing sparse failed: " << sparse.Rep();
}

TEST_F(Conformance, SparseVersionCheck) {
    SparseWrapper sparse(4096, 4096);
    ASSERT_TRUE(*sparse) << "Sparse image creation failed";
    std::vector<char> buf;
    ASSERT_TRUE(SparseToBuf(*sparse, &buf)) << "Sparse buffer creation failed";
    // Invalid, right after magic
    buf[4] = 0xff;
    ASSERT_EQ(DownloadCommand(buf.size()), SUCCESS) << "Device rejected download command";
    ASSERT_EQ(SendBuffer(buf), SUCCESS) << "Downloading payload failed";

    // It can either reject this download or reject it during flash
    if (HandleResponse() != DEVICE_FAIL) {
        EXPECT_EQ(fb->Flash("userdata"), DEVICE_FAIL)
                << "Flashing an invalid sparse version should fail " << sparse.Rep();
    }
}

TEST_F(UnlockPermissions, Download) {
    std::vector<char> buf{'a', 'o', 's', 'p'};
    EXPECT_EQ(fb->Download(buf), SUCCESS) << "Download 4-byte payload failed";
}

TEST_F(UnlockPermissions, DownloadFlash) {
    std::vector<char> buf{'a', 'o', 's', 'p'};
    EXPECT_EQ(fb->Download(buf), SUCCESS) << "Download failed in unlocked mode";
    ;
    std::vector<std::tuple<std::string, uint64_t>> parts;
    EXPECT_EQ(fb->Partitions(&parts), SUCCESS) << "getvar:all failed in unlocked mode";
}

// If the implementation supports getvar:max-fetch-size, it must also support fetch:vendor_boot*.
TEST_F(UnlockPermissions, FetchVendorBoot) {
    std::string var;
    uint64_t fetch_size;
    if (fb->GetVar("max-fetch-size", &var) != SUCCESS) {
        GTEST_SKIP() << "This test is skipped because fetch is not supported.";
    }
    ASSERT_FALSE(var.empty());
    ASSERT_TRUE(android::base::ParseUint(var, &fetch_size)) << var << " is not an integer";
    std::vector<std::tuple<std::string, uint64_t>> parts;
    EXPECT_EQ(fb->Partitions(&parts), SUCCESS) << "getvar:all failed";
    for (const auto& [partition, partition_size] : parts) {
        if (!android::base::StartsWith(partition, "vendor_boot")) continue;
        TemporaryFile fetched;

        uint64_t offset = 0;
        while (offset < partition_size) {
            uint64_t chunk_size = std::min(fetch_size, partition_size - offset);
            auto ret = fb->FetchToFd(partition, fetched.fd, offset, chunk_size);
            ASSERT_EQ(fastboot::RetCode::SUCCESS, ret)
                    << "Unable to fetch " << partition << " (offset=" << offset
                    << ", size=" << chunk_size << ")";
            offset += chunk_size;
        }
    }
}

TEST_F(LockPermissions, DownloadFlash) {
    std::vector<char> buf{'a', 'o', 's', 'p'};
    EXPECT_EQ(fb->Download(buf), SUCCESS) << "Download failed in locked mode";
    std::vector<std::tuple<std::string, uint64_t>> parts;
    EXPECT_EQ(fb->Partitions(&parts), SUCCESS) << "getvar:all failed in locked mode";
    std::string resp;
    for (const auto& tup : parts) {
        EXPECT_EQ(fb->Flash(std::get<0>(tup), &resp), DEVICE_FAIL)
                << "Device did not respond with FAIL when trying to flash '" << std::get<0>(tup)
                << "' in locked mode";
        EXPECT_GT(resp.size(), 0)
                << "Device sent empty error message after FAIL";  // meaningful error message
    }
}

TEST_F(LockPermissions, Erase) {
    std::vector<std::tuple<std::string, uint64_t>> parts;
    EXPECT_EQ(fb->Partitions(&parts), SUCCESS) << "getvar:all failed";
    std::string resp;
    for (const auto& tup : parts) {
        EXPECT_EQ(fb->Erase(std::get<0>(tup), &resp), DEVICE_FAIL)
                << "Device did not respond with FAIL when trying to erase '" << std::get<0>(tup)
                << "' in locked mode";
        EXPECT_GT(resp.size(), 0) << "Device sent empty error message after FAIL";
    }
}

TEST_F(LockPermissions, SetActive) {
    std::vector<std::tuple<std::string, uint64_t>> parts;
    EXPECT_EQ(fb->Partitions(&parts), SUCCESS) << "getvar:all failed";

    std::string resp;
    EXPECT_EQ(fb->GetVar("slot-count", &resp), SUCCESS) << "getvar:slot-count failed";
    int32_t num_slots = strtol(resp.c_str(), nullptr, 10);

    for (const auto& tup : parts) {
        std::string part(std::get<0>(tup));
        std::regex reg("([[:graph:]]*)_([[:lower:]])");
        std::smatch sm;

        if (std::regex_match(part, sm, reg)) {  // This partition has slots
            std::string part_base(sm[1]);
            for (char c = 'a'; c < 'a' + num_slots; c++) {
                // We should not be able to SetActive any of these
                EXPECT_EQ(fb->SetActive(part_base + '_' + c, &resp), DEVICE_FAIL)
                        << "set:active:" << part_base + '_' + c << " did not fail in locked mode";
            }
        }
    }
}

TEST_F(LockPermissions, Boot) {
    std::vector<char> buf;
    buf.resize(1000);
    EXPECT_EQ(fb->Download(buf), SUCCESS) << "A 1000 byte download failed";
    std::string resp;
    ASSERT_EQ(fb->Boot(&resp), DEVICE_FAIL)
            << "The device did not respond with failure for 'boot' when locked";
    EXPECT_GT(resp.size(), 0) << "No error message was returned by device after FAIL";
}

TEST_F(LockPermissions, FetchVendorBoot) {
    std::vector<std::tuple<std::string, uint64_t>> parts;
    EXPECT_EQ(fb->Partitions(&parts), SUCCESS) << "getvar:all failed";
    for (const auto& [partition, _] : parts) {
        TemporaryFile fetched;
        ASSERT_EQ(fb->FetchToFd(partition, fetched.fd, 0, 0), DEVICE_FAIL)
                << "fetch:" << partition << ":0:0 did not fail in locked mode";
    }
}

TEST_F(Fuzz, DownloadSize) {
    std::string var;
    EXPECT_EQ(fb->GetVar("max-download-size", &var), SUCCESS) << "getvar:max-download-size failed";
    int64_t size = strtoll(var.c_str(), nullptr, 0);
    EXPECT_GT(size, 0) << '\'' << var << "' is not a valid response for getvar:max-download-size";

    EXPECT_EQ(DownloadCommand(size + 1), DEVICE_FAIL)
            << "Device reported max-download-size as '" << size
            << "' but did not reject a download of " << size + 1;

    std::vector<char> buf(size);
    EXPECT_EQ(fb->Download(buf), SUCCESS) << "Device reported max-download-size as '" << size
                                          << "' but downloading a payload of this size failed";
    ASSERT_TRUE(UsbStillAvailible()) << USB_PORT_GONE;
}

TEST_F(Fuzz, DownloadPartialBuf) {
    std::vector<char> buf{'a', 'o', 's', 'p'};
    ASSERT_EQ(DownloadCommand(buf.size() + 1), SUCCESS)
            << "Download command for " << buf.size() + 1 << " bytes failed";

    std::string resp;
    RetCode ret = SendBuffer(buf);
    EXPECT_EQ(ret, SUCCESS) << "Device did not accept partial payload download";
    // Send the partial buffer, then cancel it with a reset
    EXPECT_EQ(transport->Reset(), 0) << "USB reset failed";

    ASSERT_TRUE(UsbStillAvailible()) << USB_PORT_GONE;
    // The device better still work after all that if we unplug and replug
    EXPECT_EQ(fb->GetVar("product", &resp), SUCCESS) << "getvar:product failed";
}

TEST_F(Fuzz, DownloadOverRun) {
    std::vector<char> buf(1000, 'F');
    ASSERT_EQ(DownloadCommand(10), SUCCESS) << "Device rejected download request for 10 bytes";
    // There are two ways to handle this
    // Accept download, but send error response
    // Reject the download outright
    std::string resp;
    RetCode ret = SendBuffer(buf);
    if (ret == SUCCESS) {
        // If it accepts the buffer, it better send back an error response
        EXPECT_EQ(HandleResponse(&resp), DEVICE_FAIL)
                << "After sending too large of a payload for a download command, device accepted "
                   "payload and did not respond with FAIL";
    } else {
        EXPECT_EQ(ret, IO_ERROR) << "After sending too large of a payload for a download command, "
                                    "device did not return error";
    }

    ASSERT_TRUE(UsbStillAvailible()) << USB_PORT_GONE;
    // The device better still work after all that if we unplug and replug
    EXPECT_EQ(transport->Reset(), 0) << "USB reset failed";
    EXPECT_EQ(fb->GetVar("product", &resp), SUCCESS)
            << "Device did not respond with SUCCESS to getvar:product.";
}

TEST_F(Fuzz, DownloadInvalid1) {
    EXPECT_EQ(DownloadCommand(0), DEVICE_FAIL)
            << "Device did not respond with FAIL for malformed download command 'download:0'";
}

TEST_F(Fuzz, DownloadInvalid2) {
    std::string cmd("download:1");
    EXPECT_EQ(fb->RawCommand("download:1"), DEVICE_FAIL)
            << "Device did not respond with FAIL for malformed download command '" << cmd << "'";
}

TEST_F(Fuzz, DownloadInvalid3) {
    std::string cmd("download:-1");
    EXPECT_EQ(fb->RawCommand("download:-1"), DEVICE_FAIL)
            << "Device did not respond with FAIL for malformed download command '" << cmd << "'";
}

TEST_F(Fuzz, DownloadInvalid4) {
    std::string cmd("download:-01000000");
    EXPECT_EQ(fb->RawCommand(cmd), DEVICE_FAIL)
            << "Device did not respond with FAIL for malformed download command '" << cmd << "'";
}

TEST_F(Fuzz, DownloadInvalid5) {
    std::string cmd("download:-0100000");
    EXPECT_EQ(fb->RawCommand(cmd), DEVICE_FAIL)
            << "Device did not respond with FAIL for malformed download command '" << cmd << "'";
}

TEST_F(Fuzz, DownloadInvalid6) {
    std::string cmd("download:");
    EXPECT_EQ(fb->RawCommand(cmd), DEVICE_FAIL)
            << "Device did not respond with FAIL for malformed download command '" << cmd << "'";
}

TEST_F(Fuzz, DownloadInvalid7) {
    std::string cmd("download:01000000\0999", sizeof("download:01000000\0999"));
    EXPECT_EQ(fb->RawCommand(cmd), DEVICE_FAIL)
            << "Device did not respond with FAIL for malformed download command '" << cmd << "'";
}

TEST_F(Fuzz, DownloadInvalid8) {
    std::string cmd("download:01000000\0dkjfvijafdaiuybgidabgybr",
                    sizeof("download:01000000\0dkjfvijafdaiuybgidabgybr"));
    EXPECT_EQ(fb->RawCommand(cmd), DEVICE_FAIL)
            << "Device did not respond with FAIL for malformed download command '" << cmd << "'";
}

TEST_F(Fuzz, GetVarAllSpam) {
    auto start = std::chrono::high_resolution_clock::now();
    std::chrono::duration<double> elapsed;
    unsigned i = 1;
    do {
        std::vector<std::string> vars;
        ASSERT_EQ(fb->GetVarAll(&vars), SUCCESS) << "Device did not respond with success after "
                                                 << i << "getvar:all commands in a row";
        ASSERT_GT(vars.size(), 0)
                << "Device did not send any INFO responses after getvar:all command";
        elapsed = std::chrono::high_resolution_clock::now() - start;
    } while (i++, elapsed.count() < 5);
}

TEST_F(Fuzz, BadCommandTooLarge) {
    std::string s = RandomString(FB_COMMAND_SZ + 1, rand_legal);
    EXPECT_EQ(fb->RawCommand(s), DEVICE_FAIL)
            << "Device did not respond with failure after sending length " << s.size()
            << " string of random ASCII chars";
    std::string s1 = RandomString(1000, rand_legal);
    EXPECT_EQ(fb->RawCommand(s1), DEVICE_FAIL)
            << "Device did not respond with failure after sending length " << s1.size()
            << " string of random ASCII chars";
    std::string s2 = RandomString(1000, rand_illegal);
    EXPECT_EQ(fb->RawCommand(s2), DEVICE_FAIL)
            << "Device did not respond with failure after sending length " << s1.size()
            << " string of random non-ASCII chars";
    std::string s3 = RandomString(1000, rand_char);
    EXPECT_EQ(fb->RawCommand(s3), DEVICE_FAIL)
            << "Device did not respond with failure after sending length " << s1.size()
            << " string of random chars";
}

TEST_F(Fuzz, CommandTooLarge) {
    for (const std::string& s : CMDS) {
        std::string rs = RandomString(1000, rand_char);
        EXPECT_EQ(fb->RawCommand(s + rs), DEVICE_FAIL)
                << "Device did not respond with failure after '" << s + rs << "'";
        ASSERT_TRUE(UsbStillAvailible()) << USB_PORT_GONE;
        std::string resp;
        EXPECT_EQ(fb->GetVar("product", &resp), SUCCESS)
                << "Device is unresponsive to getvar command";
    }
}

TEST_F(Fuzz, CommandMissingArgs) {
    for (const std::string& s : CMDS) {
        if (s.back() == ':') {
            EXPECT_EQ(fb->RawCommand(s), DEVICE_FAIL)
                    << "Device did not respond with failure after '" << s << "'";
            std::string sub(s.begin(), s.end() - 1);
            EXPECT_EQ(fb->RawCommand(sub), DEVICE_FAIL)
                    << "Device did not respond with failure after '" << sub << "'";
        } else {
            std::string rs = RandomString(10, rand_illegal);
            EXPECT_EQ(fb->RawCommand(rs + s), DEVICE_FAIL)
                    << "Device did not respond with failure after '" << rs + s << "'";
        }
        std::string resp;
        EXPECT_EQ(fb->GetVar("product", &resp), SUCCESS)
                << "Device is unresponsive to getvar command";
    }
}

TEST_F(Fuzz, SparseZeroLength) {
    SparseWrapper sparse(4096, 0);
    ASSERT_TRUE(*sparse) << "Sparse image creation failed";
    RetCode ret = fb->Download(*sparse);
    // Two ways to handle it
    if (ret != DEVICE_FAIL) {  // if lazily parsed it better fail on a flash
        EXPECT_EQ(fb->Flash("userdata"), DEVICE_FAIL)
                << "Flashing zero length sparse image did not fail: " << sparse.Rep();
    }
    ret = fb->Download(*sparse, true);
    if (ret != DEVICE_FAIL) {  // if lazily parsed it better fail on a flash
        EXPECT_EQ(fb->Flash("userdata"), DEVICE_FAIL)
                << "Flashing zero length sparse image did not fail " << sparse.Rep();
    }
}

TEST_F(Fuzz, SparseTooManyChunks) {
    SparseWrapper sparse(4096, 4096);  // 1 block, but we send two chunks that will use 2 blocks
    ASSERT_TRUE(*sparse) << "Sparse image creation failed";
    std::vector<char> buf = RandomBuf(4096);
    ASSERT_EQ(sparse_file_add_data(*sparse, buf.data(), buf.size(), 0), 0)
            << "Adding data failed to sparse file: " << sparse.Rep();
    // We take advantage of the fact the sparse library does not check this
    ASSERT_EQ(sparse_file_add_fill(*sparse, 0xdeadbeef, 4096, 1), 0)
            << "Adding fill to sparse file failed: " << sparse.Rep();

    RetCode ret = fb->Download(*sparse);
    // Two ways to handle it
    if (ret != DEVICE_FAIL) {  // if lazily parsed it better fail on a flash
        EXPECT_EQ(fb->Flash("userdata"), DEVICE_FAIL)
                << "Flashing sparse image with 'total_blks' in header 1 too small did not fail "
                << sparse.Rep();
    }
    ret = fb->Download(*sparse, true);
    if (ret != DEVICE_FAIL) {  // if lazily parsed it better fail on a flash
        EXPECT_EQ(fb->Flash("userdata"), DEVICE_FAIL)
                << "Flashing sparse image with 'total_blks' in header 1 too small did not fail "
                << sparse.Rep();
    }
}

TEST_F(Fuzz, USBResetSpam) {
    auto start = std::chrono::high_resolution_clock::now();
    std::chrono::duration<double> elapsed;
    int i = 0;
    do {
        ASSERT_EQ(transport->Reset(), 0) << "USB Reset failed after " << i << " resets in a row";
        elapsed = std::chrono::high_resolution_clock::now() - start;
    } while (i++, elapsed.count() < 5);
    std::string resp;
    EXPECT_EQ(fb->GetVar("product", &resp), SUCCESS)
            << "getvar failed after " << i << " USB reset(s) in a row";
}

TEST_F(Fuzz, USBResetCommandSpam) {
    auto start = std::chrono::high_resolution_clock::now();
    std::chrono::duration<double> elapsed;
    do {
        std::string resp;
        std::vector<std::string> all;
        ASSERT_EQ(transport->Reset(), 0) << "USB Reset failed";
        EXPECT_EQ(fb->GetVarAll(&all), SUCCESS) << "getvar:all failed after USB reset";
        EXPECT_EQ(fb->GetVar("product", &resp), SUCCESS) << "getvar:product failed";
        elapsed = std::chrono::high_resolution_clock::now() - start;
    } while (elapsed.count() < 10);
}

TEST_F(Fuzz, USBResetAfterDownload) {
    std::vector<char> buf;
    buf.resize(1000000);
    EXPECT_EQ(DownloadCommand(buf.size()), SUCCESS) << "Download command failed";
    EXPECT_EQ(transport->Reset(), 0) << "USB Reset failed";
    std::vector<std::string> all;
    EXPECT_EQ(fb->GetVarAll(&all), SUCCESS) << "getvar:all failed after USB reset.";
}

// Getvar XML tests
TEST_P(ExtensionsGetVarConformance, VarExists) {
    std::string resp;
    EXPECT_EQ(fb->GetVar(GetParam().first, &resp), SUCCESS);
}

TEST_P(ExtensionsGetVarConformance, VarMatchesRegex) {
    std::string resp;
    ASSERT_EQ(fb->GetVar(GetParam().first, &resp), SUCCESS);
    std::smatch sm;
    std::regex_match(resp, sm, GetParam().second.regex);
    EXPECT_FALSE(sm.empty()) << "The regex did not match";
}

INSTANTIATE_TEST_CASE_P(XMLGetVar, ExtensionsGetVarConformance,
                        ::testing::ValuesIn(GETVAR_XML_TESTS));

TEST_P(AnyPartition, ReportedGetVarAll) {
    // As long as the partition is reported in INFO, it would be tested by generic Conformance
    std::vector<std::tuple<std::string, uint64_t>> parts;
    ASSERT_EQ(fb->Partitions(&parts), SUCCESS) << "getvar:all failed";
    const std::string name = GetParam().first;
    if (GetParam().second.slots) {
        auto matcher = [&](const std::tuple<std::string, uint32_t>& tup) {
            return std::get<0>(tup) == name + "_a";
        };
        EXPECT_NE(std::find_if(parts.begin(), parts.end(), matcher), parts.end())
                << "partition '" + name + "_a' not reported in getvar:all";
    } else {
        auto matcher = [&](const std::tuple<std::string, uint32_t>& tup) {
            return std::get<0>(tup) == name;
        };
        EXPECT_NE(std::find_if(parts.begin(), parts.end(), matcher), parts.end())
                << "partition '" + name + "' not reported in getvar:all";
    }
}

TEST_P(AnyPartition, Hashable) {
    const std::string name = GetParam().first;
    if (!config.checksum.empty()) {  // We can use hash to validate
        for (const auto& part_name : real_parts) {
            // Get hash
            std::string hash;
            int retcode;
            std::string err_msg;
            if (GetParam().second.hashable) {
                ASSERT_TRUE(PartitionHash(fb.get(), part_name, &hash, &retcode, &err_msg))
                        << err_msg;
                EXPECT_EQ(retcode, 0) << err_msg;
            } else {  // Make sure it fails
                const std::string cmd = config.checksum + ' ' + part_name;
                EXPECT_EQ(fb->RawCommand(cmd), DEVICE_FAIL)
                        << part_name + " is marked as non-hashable, but hashing did not fail";
            }
        }
    }
}

TEST_P(WriteablePartition, FlashCheck) {
    const std::string name = GetParam().first;
    auto part_info = GetParam().second;

    for (const auto& part_name : real_parts) {
        std::vector<char> buf = RandomBuf(max_flash, rand_char);
        EXPECT_EQ(fb->FlashPartition(part_name, buf), part_info.parsed ? DEVICE_FAIL : SUCCESS)
                << "A partition with an image parsed by the bootloader should reject random "
                   "garbage "
                   "otherwise it should succeed";
    }
}

TEST_P(WriteablePartition, EraseCheck) {
    const std::string name = GetParam().first;

    for (const auto& part_name : real_parts) {
        ASSERT_EQ(fb->Erase(part_name), SUCCESS) << "Erasing " + part_name + " failed";
    }
}

TEST_P(WriteHashNonParsedPartition, EraseZerosData) {
    const std::string name = GetParam().first;

    for (const auto& part_name : real_parts) {
        std::string err_msg;
        int retcode;
        const std::vector<char> buf = RandomBuf(max_flash, rand_char);
        // Partition is too big to write to entire thing
        // This can eventually be supported by using sparse images if too large
        if (max_flash < part_size) {
            std::string hash_before, hash_after;
            ASSERT_EQ(fb->FlashPartition(part_name, buf), SUCCESS);
            ASSERT_TRUE(PartitionHash(fb.get(), part_name, &hash_before, &retcode, &err_msg))
                    << err_msg;
            ASSERT_EQ(retcode, 0) << err_msg;
            ASSERT_EQ(fb->Erase(part_name), SUCCESS) << "Erasing " + part_name + " failed";
            ASSERT_TRUE(PartitionHash(fb.get(), part_name, &hash_after, &retcode, &err_msg))
                    << err_msg;
            ASSERT_EQ(retcode, 0) << err_msg;
            EXPECT_NE(hash_before, hash_after)
                    << "The partition hash for " + part_name +
                               " did not change after erasing a known value";
        } else {
            std::string hash_zeros, hash_ones, hash_middle, hash_after;
            const std::vector<char> buf_zeros(max_flash, 0);
            const std::vector<char> buf_ones(max_flash, -1);  // All bits are set to 1
            ASSERT_EQ(fb->FlashPartition(part_name, buf_zeros), SUCCESS);
            ASSERT_TRUE(PartitionHash(fb.get(), part_name, &hash_zeros, &retcode, &err_msg))
                    << err_msg;
            ASSERT_EQ(retcode, 0) << err_msg;
            ASSERT_EQ(fb->FlashPartition(part_name, buf_ones), SUCCESS);
            ASSERT_TRUE(PartitionHash(fb.get(), part_name, &hash_ones, &retcode, &err_msg))
                    << err_msg;
            ASSERT_EQ(retcode, 0) << err_msg;
            ASSERT_NE(hash_zeros, hash_ones)
                    << "Hashes of partion should not be the same when all bytes are 0xFF or 0x00";
            ASSERT_EQ(fb->FlashPartition(part_name, buf), SUCCESS);
            ASSERT_TRUE(PartitionHash(fb.get(), part_name, &hash_middle, &retcode, &err_msg))
                    << err_msg;
            ASSERT_EQ(retcode, 0) << err_msg;
            ASSERT_NE(hash_zeros, hash_middle)
                    << "Hashes of partion are the same when all bytes are 0x00 or test payload";
            ASSERT_NE(hash_ones, hash_middle)
                    << "Hashes of partion are the same when all bytes are 0xFF or test payload";
            ASSERT_EQ(fb->Erase(part_name), SUCCESS) << "Erasing " + part_name + " failed";
            ASSERT_TRUE(PartitionHash(fb.get(), part_name, &hash_after, &retcode, &err_msg))
                    << err_msg;
            ASSERT_EQ(retcode, 0) << err_msg;
            EXPECT_TRUE(hash_zeros == hash_after || hash_ones == hash_after)
                    << "Erasing " + part_name + " should set all the bytes to 0xFF or 0x00";
        }
    }
}

// Only partitions that we can write and hash (name, fixture), TEST_P is (Fixture, test_name)
INSTANTIATE_TEST_CASE_P(XMLPartitionsWriteHashNonParsed, WriteHashNonParsedPartition,
                        ::testing::ValuesIn(PARTITION_XML_WRITE_HASH_NONPARSED));

INSTANTIATE_TEST_CASE_P(XMLPartitionsWriteHashable, WriteHashablePartition,
                        ::testing::ValuesIn(PARTITION_XML_WRITE_HASHABLE));

// only partitions writeable
INSTANTIATE_TEST_CASE_P(XMLPartitionsWriteable, WriteablePartition,
                        ::testing::ValuesIn(PARTITION_XML_WRITEABLE));

// Every partition
INSTANTIATE_TEST_CASE_P(XMLPartitionsAll, AnyPartition, ::testing::ValuesIn(PARTITION_XML_TESTS));

// Partition Fuzz tests
TEST_P(FuzzWriteablePartition, BoundsCheck) {
    const std::string name = GetParam().first;
    auto part_info = GetParam().second;

    for (const auto& part_name : real_parts) {
        // try and flash +1 too large, first erase and get a hash, make sure it does not change
        std::vector<char> buf = RandomBuf(max_flash + 1);  // One too large
        if (part_info.hashable) {
            std::string hash_before, hash_after, err_msg;
            int retcode;
            ASSERT_EQ(fb->Erase(part_name), SUCCESS) << "Erasing " + part_name + " failed";
            ASSERT_TRUE(PartitionHash(fb.get(), part_name, &hash_before, &retcode, &err_msg))
                    << err_msg;
            ASSERT_EQ(retcode, 0) << err_msg;
            EXPECT_EQ(fb->FlashPartition(part_name, buf), DEVICE_FAIL)
                    << "Flashing an image 1 byte too large to " + part_name + " did not fail";
            ASSERT_TRUE(PartitionHash(fb.get(), part_name, &hash_after, &retcode, &err_msg))
                    << err_msg;
            ASSERT_EQ(retcode, 0) << err_msg;
            EXPECT_EQ(hash_before, hash_after)
                    << "Flashing too large of an image resulted in a changed partition hash for " +
                               part_name;
        } else {
            EXPECT_EQ(fb->FlashPartition(part_name, buf), DEVICE_FAIL)
                    << "Flashing an image 1 byte too large to " + part_name + " did not fail";
        }
    }
}

INSTANTIATE_TEST_CASE_P(XMLFuzzPartitionsWriteable, FuzzWriteablePartition,
                        ::testing::ValuesIn(PARTITION_XML_WRITEABLE));

// A parsed partition should have magic and such that is checked by the bootloader
// Attempting to flash a random single byte should definately fail
TEST_P(FuzzWriteableParsedPartition, FlashGarbageImageSmall) {
    const std::string name = GetParam().first;
    auto part_info = GetParam().second;

    for (const auto& part_name : real_parts) {
        std::vector<char> buf = RandomBuf(1);
        if (part_info.hashable) {
            std::string hash_before, hash_after, err_msg;
            int retcode;
            ASSERT_EQ(fb->Erase(part_name), SUCCESS) << "Erasing " + part_name + " failed";
            ASSERT_TRUE(PartitionHash(fb.get(), part_name, &hash_before, &retcode, &err_msg))
                    << err_msg;
            ASSERT_EQ(retcode, 0) << err_msg;
            EXPECT_EQ(fb->FlashPartition(part_name, buf), DEVICE_FAIL)
                    << "A parsed partition should fail on a single byte";
            ASSERT_TRUE(PartitionHash(fb.get(), part_name, &hash_after, &retcode, &err_msg))
                    << err_msg;
            ASSERT_EQ(retcode, 0) << err_msg;
            EXPECT_EQ(hash_before, hash_after)
                    << "Flashing a single byte to parsed partition  " + part_name +
                               " should fail and not change the partition hash";
        } else {
            EXPECT_EQ(fb->FlashPartition(part_name, buf), DEVICE_FAIL)
                    << "Flashing a 1 byte image to a parsed partition should fail";
        }
    }
}

TEST_P(FuzzWriteableParsedPartition, FlashGarbageImageLarge) {
    const std::string name = GetParam().first;
    auto part_info = GetParam().second;

    for (const auto& part_name : real_parts) {
        std::vector<char> buf = RandomBuf(max_flash);
        if (part_info.hashable) {
            std::string hash_before, hash_after, err_msg;
            int retcode;
            ASSERT_EQ(fb->Erase(part_name), SUCCESS) << "Erasing " + part_name + " failed";
            ASSERT_TRUE(PartitionHash(fb.get(), part_name, &hash_before, &retcode, &err_msg))
                    << err_msg;
            ASSERT_EQ(retcode, 0) << err_msg;
            EXPECT_EQ(fb->FlashPartition(part_name, buf), DEVICE_FAIL)
                    << "A parsed partition should not accept randomly generated images";
            ASSERT_TRUE(PartitionHash(fb.get(), part_name, &hash_after, &retcode, &err_msg))
                    << err_msg;
            ASSERT_EQ(retcode, 0) << err_msg;
            EXPECT_EQ(hash_before, hash_after)
                    << "The hash of the partition has changed after attempting to flash garbage to "
                       "a parsed partition";
        } else {
            EXPECT_EQ(fb->FlashPartition(part_name, buf), DEVICE_FAIL)
                    << "A parsed partition should not accept randomly generated images";
        }
    }
}

TEST_P(FuzzWriteableParsedPartition, FlashGarbageImageLarge2) {
    const std::string name = GetParam().first;
    auto part_info = GetParam().second;

    for (const auto& part_name : real_parts) {
        std::vector<char> buf(max_flash, -1);  // All 1's
        if (part_info.hashable) {
            std::string hash_before, hash_after, err_msg;
            int retcode;
            ASSERT_EQ(fb->Erase(part_name), SUCCESS) << "Erasing " + part_name + " failed";
            ASSERT_TRUE(PartitionHash(fb.get(), part_name, &hash_before, &retcode, &err_msg))
                    << err_msg;
            ASSERT_EQ(retcode, 0) << err_msg;
            EXPECT_EQ(fb->FlashPartition(part_name, buf), DEVICE_FAIL)
                    << "A parsed partition should not accept a image of all 0xFF";
            ASSERT_TRUE(PartitionHash(fb.get(), part_name, &hash_after, &retcode, &err_msg))
                    << err_msg;
            ASSERT_EQ(retcode, 0) << err_msg;
            EXPECT_EQ(hash_before, hash_after)
                    << "The hash of the partition has changed after attempting to flash garbage to "
                       "a parsed partition";
        } else {
            EXPECT_EQ(fb->FlashPartition(part_name, buf), DEVICE_FAIL)
                    << "A parsed partition should not accept a image of all 0xFF";
        }
    }
}

TEST_P(FuzzWriteableParsedPartition, FlashGarbageImageLarge3) {
    const std::string name = GetParam().first;
    auto part_info = GetParam().second;

    for (const auto& part_name : real_parts) {
        std::vector<char> buf(max_flash, 0);  // All 0's
        if (part_info.hashable) {
            std::string hash_before, hash_after, err_msg;
            int retcode;
            ASSERT_EQ(fb->Erase(part_name), SUCCESS) << "Erasing " + part_name + " failed";
            ASSERT_TRUE(PartitionHash(fb.get(), part_name, &hash_before, &retcode, &err_msg))
                    << err_msg;
            ASSERT_EQ(retcode, 0) << err_msg;
            EXPECT_EQ(fb->FlashPartition(part_name, buf), DEVICE_FAIL)
                    << "A parsed partition should not accept a image of all 0x00";
            ASSERT_TRUE(PartitionHash(fb.get(), part_name, &hash_after, &retcode, &err_msg))
                    << err_msg;
            ASSERT_EQ(retcode, 0) << err_msg;
            EXPECT_EQ(hash_before, hash_after)
                    << "The hash of the partition has changed after attempting to flash garbage to "
                       "a parsed partition";
        } else {
            EXPECT_EQ(fb->FlashPartition(part_name, buf), DEVICE_FAIL)
                    << "A parsed partition should not accept a image of all 0x00";
        }
    }
}

INSTANTIATE_TEST_CASE_P(XMLFuzzPartitionsWriteableParsed, FuzzWriteableParsedPartition,
                        ::testing::ValuesIn(PARTITION_XML_WRITE_PARSED));

// Make sure all attempts to flash things are rejected
TEST_P(FuzzAnyPartitionLocked, RejectFlash) {
    std::vector<char> buf = RandomBuf(5);
    for (const auto& part_name : real_parts) {
        ASSERT_EQ(fb->FlashPartition(part_name, buf), DEVICE_FAIL)
                << "Flashing a partition should always fail in locked mode";
    }
}

INSTANTIATE_TEST_CASE_P(XMLFuzzAnyPartitionLocked, FuzzAnyPartitionLocked,
                        ::testing::ValuesIn(PARTITION_XML_TESTS));

// Test flashing unlock erases userdata
TEST_P(UserdataPartition, UnlockErases) {
    // Get hash after an erase
    int retcode;
    std::string err_msg, hash_before, hash_buf, hash_after;
    ASSERT_EQ(fb->Erase("userdata"), SUCCESS) << "Erasing uesrdata failed";
    ASSERT_TRUE(PartitionHash(fb.get(), "userdata", &hash_before, &retcode, &err_msg)) << err_msg;
    ASSERT_EQ(retcode, 0) << err_msg;

    // Write garbage
    std::vector<char> buf = RandomBuf(max_flash / 2);
    ASSERT_EQ(fb->FlashPartition("userdata", buf), SUCCESS);
    ASSERT_TRUE(PartitionHash(fb.get(), "userdata", &hash_buf, &retcode, &err_msg)) << err_msg;
    ASSERT_EQ(retcode, 0) << err_msg;

    // Validity check of hash
    EXPECT_NE(hash_before, hash_buf)
            << "Writing a random buffer to 'userdata' had the same hash as after erasing it";
    SetLockState(true);  // Lock the device

    SetLockState(false);  // Unlock the device (should cause erase)
    ASSERT_TRUE(PartitionHash(fb.get(), "userdata", &hash_after, &retcode, &err_msg)) << err_msg;
    ASSERT_EQ(retcode, 0) << err_msg;

    EXPECT_NE(hash_after, hash_buf) << "Unlocking the device did not cause the hash of userdata to "
                                       "change (i.e. it was not erased as required)";
    EXPECT_EQ(hash_after, hash_before) << "Unlocking the device did not produce the same hash of "
                                          "userdata as after doing an erase to userdata";
}

// This is a hack to make this test disapeer if there is not a checsum, userdata is not hashable,
// or userdata is not marked to be writeable in testing
INSTANTIATE_TEST_CASE_P(XMLUserdataLocked, UserdataPartition,
                        ::testing::ValuesIn(PARTITION_XML_USERDATA_CHECKSUM_WRITEABLE));

// Packed images test
TEST_P(ExtensionsPackedValid, TestDeviceUnpack) {
    const std::string& packed_name = GetParam().first;
    const std::string& packed_image = GetParam().second.packed_img;
    const std::string& unpacked = GetParam().second.unpacked_dir;

    // First we need to check for existence of images
    const extension::Configuration::PackedInfo& info = config.packed[packed_name];

    const auto flash_part = [&](const std::string fname, const std::string part_name) {
        FILE* to_flash = fopen((SEARCH_PATH + fname).c_str(), "rb");
        ASSERT_NE(to_flash, nullptr) << "'" << fname << "'"
                                     << " failed to open for flashing";
        int fd = fileno(to_flash);
        size_t fsize = lseek(fd, 0, SEEK_END);
        ASSERT_GT(fsize, 0) << fname + " appears to be an empty image";
        ASSERT_EQ(fb->FlashPartition(part_name, fd, fsize), SUCCESS);
        fclose(to_flash);
    };

    // We first need to set the slot count
    std::string var;
    int num_slots = 1;
    if (info.slots) {
        ASSERT_EQ(fb->GetVar("slot-count", &var), SUCCESS) << "Getting slot count failed";
        num_slots = strtol(var.c_str(), nullptr, 10);
    } else {
        for (const auto& part : info.children) {
            EXPECT_FALSE(config.partitions[part].slots)
                    << "A partition can not have slots if the packed image does not";
        }
    }

    for (int i = 0; i < num_slots; i++) {
        std::unordered_map<std::string, std::string> initial_hashes;
        const std::string packed_suffix =
                info.slots ? android::base::StringPrintf("_%c", 'a' + i) : "";

        // Flash the paritions manually and get hash
        for (const auto& part : info.children) {
            const extension::Configuration::PartitionInfo& part_info = config.partitions[part];
            const std::string suffix = part_info.slots ? packed_suffix : "";
            const std::string part_name = part + suffix;

            ASSERT_EQ(fb->Erase(part_name), SUCCESS);
            const std::string fpath = unpacked + '/' + part + ".img";
            ASSERT_NO_FATAL_FAILURE(flash_part(fpath, part_name))
                    << "Failed to flash '" + fpath + "'";
            // If the partition is hashable we store it
            if (part_info.hashable) {
                std::string hash, err_msg;
                int retcode;
                ASSERT_TRUE(PartitionHash(fb.get(), part_name, &hash, &retcode, &err_msg))
                        << err_msg;
                ASSERT_EQ(retcode, 0) << err_msg;
                initial_hashes[part] = hash;
            }
        }

        // erase once at the end, to avoid false positives if flashing does nothing
        for (const auto& part : info.children) {
            const std::string suffix = config.partitions[part].slots ? packed_suffix : "";
            ASSERT_EQ(fb->Erase(part + suffix), SUCCESS);
        }

        // Now we flash the packed image and compare our hashes
        ASSERT_NO_FATAL_FAILURE(flash_part(packed_image, packed_name + packed_suffix));

        for (const auto& part : info.children) {
            const extension::Configuration::PartitionInfo& part_info = config.partitions[part];
            // If the partition is hashable we check it
            if (part_info.hashable) {
                const std::string suffix = part_info.slots ? packed_suffix : "";
                const std::string part_name = part + suffix;
                std::string hash, err_msg;
                int retcode;
                ASSERT_TRUE(PartitionHash(fb.get(), part_name, &hash, &retcode, &err_msg))
                        << err_msg;
                ASSERT_EQ(retcode, 0) << err_msg;
                std::string msg =
                        "The hashes between flashing the packed image and directly flashing '" +
                        part_name + "' does not match";
                EXPECT_EQ(hash, initial_hashes[part]) << msg;
            }
        }
    }
}

INSTANTIATE_TEST_CASE_P(XMLTestPacked, ExtensionsPackedValid,
                        ::testing::ValuesIn(PACKED_XML_SUCCESS_TESTS));

// Packed images test
TEST_P(ExtensionsPackedInvalid, TestDeviceUnpack) {
    const std::string& packed_name = GetParam().first;
    const std::string& packed_image = GetParam().second.packed_img;

    // First we need to check for existence of images
    const extension::Configuration::PackedInfo& info = config.packed[packed_name];

    // We first need to set the slot count
    std::string var;
    int num_slots = 1;
    if (info.slots) {
        ASSERT_EQ(fb->GetVar("slot-count", &var), SUCCESS) << "Getting slot count failed";
        num_slots = strtol(var.c_str(), nullptr, 10);
    } else {
        for (const auto& part : info.children) {
            EXPECT_FALSE(config.partitions[part].slots)
                    << "A partition can not have slots if the packed image does not";
        }
    }

    for (int i = 0; i < num_slots; i++) {
        std::unordered_map<std::string, std::string> initial_hashes;
        const std::string packed_suffix =
                info.slots ? android::base::StringPrintf("_%c", 'a' + i) : "";

        // manually and get hash
        for (const auto& part : info.children) {
            const extension::Configuration::PartitionInfo& part_info = config.partitions[part];
            const std::string suffix = part_info.slots ? packed_suffix : "";
            const std::string part_name = part + suffix;

            // If the partition is hashable we store it
            if (part_info.hashable) {
                std::string hash, err_msg;
                int retcode;
                ASSERT_TRUE(PartitionHash(fb.get(), part_name, &hash, &retcode, &err_msg))
                        << err_msg;
                ASSERT_EQ(retcode, 0) << err_msg;
                initial_hashes[part] = hash;
            }
        }

        // Attempt to flash the invalid file
        FILE* to_flash = fopen((SEARCH_PATH + packed_image).c_str(), "rb");
        ASSERT_NE(to_flash, nullptr) << "'" << packed_image << "'"
                                     << " failed to open for flashing";
        int fd = fileno(to_flash);
        size_t fsize = lseek(fd, 0, SEEK_END);
        ASSERT_GT(fsize, 0) << packed_image + " appears to be an empty image";
        ASSERT_EQ(fb->FlashPartition(packed_name + packed_suffix, fd, fsize), DEVICE_FAIL)
                << "Expected flashing to fail for " + packed_image;
        fclose(to_flash);

        for (const auto& part : info.children) {
            const extension::Configuration::PartitionInfo& part_info = config.partitions[part];
            // If the partition is hashable we check it
            if (part_info.hashable) {
                const std::string suffix = part_info.slots ? packed_suffix : "";
                const std::string part_name = part + suffix;
                std::string hash, err_msg;
                int retcode;
                ASSERT_TRUE(PartitionHash(fb.get(), part_name, &hash, &retcode, &err_msg))
                        << err_msg;
                ASSERT_EQ(retcode, 0) << err_msg;
                std::string msg = "Flashing an invalid image changed the hash of '" + part_name;
                EXPECT_EQ(hash, initial_hashes[part]) << msg;
            }
        }
    }
}

INSTANTIATE_TEST_CASE_P(XMLTestPacked, ExtensionsPackedInvalid,
                        ::testing::ValuesIn(PACKED_XML_FAIL_TESTS));

// OEM xml tests
TEST_P(ExtensionsOemConformance, RunOEMTest) {
    const std::string& cmd = std::get<0>(GetParam());
    // bool restricted = std::get<1>(GetParam());
    const extension::Configuration::CommandTest& test = std::get<2>(GetParam());

    const RetCode expect = (test.expect == extension::FAIL) ? DEVICE_FAIL : SUCCESS;

    // Does the test require staging something?
    if (!test.input.empty()) {  // Non-empty string
        FILE* to_stage = fopen((SEARCH_PATH + test.input).c_str(), "rb");
        ASSERT_NE(to_stage, nullptr) << "'" << test.input << "'"
                                     << " failed to open for staging";
        int fd = fileno(to_stage);
        size_t fsize = lseek(fd, 0, SEEK_END);
        std::string var;
        EXPECT_EQ(fb->GetVar("max-download-size", &var), SUCCESS);
        int64_t size = strtoll(var.c_str(), nullptr, 16);
        EXPECT_LT(fsize, size) << "'" << test.input << "'"
                               << " is too large for staging";
        ASSERT_EQ(fb->Download(fd, fsize), SUCCESS) << "'" << test.input << "'"
                                                    << " failed to download for staging";
        fclose(to_stage);
    }
    // Run the command
    int dsize = -1;
    std::string resp;
    const std::string full_cmd = "oem " + cmd + " " + test.arg;
    ASSERT_EQ(fb->RawCommand(full_cmd, &resp, nullptr, &dsize), expect);

    // This is how we test if indeed data response
    if (test.expect == extension::DATA) {
        EXPECT_GT(dsize, 0);
    }

    // Validate response if neccesary
    if (!test.regex_str.empty()) {
        std::smatch sm;
        std::regex_match(resp, sm, test.regex);
        EXPECT_FALSE(sm.empty()) << "The oem regex did not match";
    }

    // If payload, we validate that as well
    const std::vector<std::string> args = SplitBySpace(test.validator);
    if (args.size()) {
        // Save output
        const std::string save_loc =
                OUTPUT_PATH + (test.output.empty() ? DEFAULT_OUPUT_NAME : test.output);
        std::string resp;
        ASSERT_EQ(fb->Upload(save_loc, &resp), SUCCESS)
                << "Saving output file failed with (" << fb->Error() << ") " << resp;
        // Build the arguments to the validator
        std::vector<std::string> prog_args(args.begin() + 1, args.end());
        prog_args.push_back(full_cmd);  // Pass in the full command
        prog_args.push_back(save_loc);  // Pass in the save location
        // Run the validation program
        int pipe;
        const pid_t pid = StartProgram(args[0], prog_args, &pipe);
        ASSERT_GT(pid, 0) << "Failed to launch validation program: " << args[0];
        std::string error_msg;
        int ret = WaitProgram(pid, pipe, &error_msg);
        EXPECT_EQ(ret, 0) << error_msg;  // Program exited correctly
    }
}

INSTANTIATE_TEST_CASE_P(XMLOEM, ExtensionsOemConformance, ::testing::ValuesIn(OEM_XML_TESTS));

// Sparse Tests
TEST_P(SparseTestPartition, SparseSingleBlock) {
    const std::string name = GetParam().first;
    auto part_info = GetParam().second;
    const std::string part_name = name + (part_info.slots ? "_a" : "");
    SparseWrapper sparse(4096, 4096);
    ASSERT_TRUE(*sparse) << "Sparse image creation failed";
    std::vector<char> buf = RandomBuf(4096);
    ASSERT_EQ(sparse_file_add_data(*sparse, buf.data(), buf.size(), 0), 0)
            << "Adding data failed to sparse file: " << sparse.Rep();

    EXPECT_EQ(fb->Download(*sparse), SUCCESS) << "Download sparse failed: " << sparse.Rep();
    EXPECT_EQ(fb->Flash(part_name), SUCCESS) << "Flashing sparse failed: " << sparse.Rep();
    std::string hash, hash_new, err_msg;
    int retcode;
    ASSERT_TRUE(PartitionHash(fb.get(), part_name, &hash, &retcode, &err_msg)) << err_msg;
    ASSERT_EQ(retcode, 0) << err_msg;
    // Now flash it the non-sparse way
    EXPECT_EQ(fb->FlashPartition(part_name, buf), SUCCESS) << "Flashing image failed: ";
    ASSERT_TRUE(PartitionHash(fb.get(), part_name, &hash_new, &retcode, &err_msg)) << err_msg;
    ASSERT_EQ(retcode, 0) << err_msg;

    EXPECT_EQ(hash, hash_new) << "Flashing a random buffer of 4096 using sparse and non-sparse "
                                 "methods did not result in the same hash";
}

TEST_P(SparseTestPartition, SparseFill) {
    const std::string name = GetParam().first;
    auto part_info = GetParam().second;
    const std::string part_name = name + (part_info.slots ? "_a" : "");
    int64_t size = (max_dl / 4096) * 4096;
    SparseWrapper sparse(4096, size);
    ASSERT_TRUE(*sparse) << "Sparse image creation failed";
    ASSERT_EQ(sparse_file_add_fill(*sparse, 0xdeadbeef, size, 0), 0)
            << "Adding data failed to sparse file: " << sparse.Rep();

    EXPECT_EQ(fb->Download(*sparse), SUCCESS) << "Download sparse failed: " << sparse.Rep();
    EXPECT_EQ(fb->Flash(part_name), SUCCESS) << "Flashing sparse failed: " << sparse.Rep();
    std::string hash, hash_new, err_msg;
    int retcode;
    ASSERT_TRUE(PartitionHash(fb.get(), part_name, &hash, &retcode, &err_msg)) << err_msg;
    ASSERT_EQ(retcode, 0) << err_msg;
    // Now flash it the non-sparse way
    std::vector<char> buf(size);
    for (auto iter = buf.begin(); iter < buf.end(); iter += 4) {
        iter[0] = 0xef;
        iter[1] = 0xbe;
        iter[2] = 0xad;
        iter[3] = 0xde;
    }
    EXPECT_EQ(fb->FlashPartition(part_name, buf), SUCCESS) << "Flashing image failed: ";
    ASSERT_TRUE(PartitionHash(fb.get(), part_name, &hash_new, &retcode, &err_msg)) << err_msg;
    ASSERT_EQ(retcode, 0) << err_msg;

    EXPECT_EQ(hash, hash_new) << "Flashing a random buffer of 4096 using sparse and non-sparse "
                                 "methods did not result in the same hash";
}

// This tests to make sure it does not overwrite previous flashes
TEST_P(SparseTestPartition, SparseMultiple) {
    const std::string name = GetParam().first;
    auto part_info = GetParam().second;
    const std::string part_name = name + (part_info.slots ? "_a" : "");
    int64_t size = (max_dl / 4096) * 4096;
    SparseWrapper sparse(4096, size / 2);
    ASSERT_TRUE(*sparse) << "Sparse image creation failed";
    ASSERT_EQ(sparse_file_add_fill(*sparse, 0xdeadbeef, size / 2, 0), 0)
            << "Adding data failed to sparse file: " << sparse.Rep();
    EXPECT_EQ(fb->Download(*sparse), SUCCESS) << "Download sparse failed: " << sparse.Rep();
    EXPECT_EQ(fb->Flash(part_name), SUCCESS) << "Flashing sparse failed: " << sparse.Rep();

    SparseWrapper sparse2(4096, size / 2);
    ASSERT_TRUE(*sparse) << "Sparse image creation failed";
    std::vector<char> buf = RandomBuf(size / 2);
    ASSERT_EQ(sparse_file_add_data(*sparse2, buf.data(), buf.size(), (size / 2) / 4096), 0)
            << "Adding data failed to sparse file: " << sparse2.Rep();
    EXPECT_EQ(fb->Download(*sparse2), SUCCESS) << "Download sparse failed: " << sparse2.Rep();
    EXPECT_EQ(fb->Flash(part_name), SUCCESS) << "Flashing sparse failed: " << sparse2.Rep();

    std::string hash, hash_new, err_msg;
    int retcode;
    ASSERT_TRUE(PartitionHash(fb.get(), part_name, &hash, &retcode, &err_msg)) << err_msg;
    ASSERT_EQ(retcode, 0) << err_msg;
    // Now flash it the non-sparse way
    std::vector<char> fbuf(size);
    for (auto iter = fbuf.begin(); iter < fbuf.begin() + size / 2; iter += 4) {
        iter[0] = 0xef;
        iter[1] = 0xbe;
        iter[2] = 0xad;
        iter[3] = 0xde;
    }
    fbuf.assign(buf.begin(), buf.end());
    EXPECT_EQ(fb->FlashPartition(part_name, fbuf), SUCCESS) << "Flashing image failed: ";
    ASSERT_TRUE(PartitionHash(fb.get(), part_name, &hash_new, &retcode, &err_msg)) << err_msg;
    ASSERT_EQ(retcode, 0) << err_msg;

    EXPECT_EQ(hash, hash_new) << "Flashing a random buffer of 4096 using sparse and non-sparse "
                                 "methods did not result in the same hash";
}

INSTANTIATE_TEST_CASE_P(XMLSparseTest, SparseTestPartition,
                        ::testing::ValuesIn(SINGLE_PARTITION_XML_WRITE_HASHABLE));

void GenerateXmlTests(const extension::Configuration& config) {
    // Build the getvar tests
    for (const auto& it : config.getvars) {
        GETVAR_XML_TESTS.push_back(std::make_pair(it.first, it.second));
    }

    // Build the partition tests, to interface with gtest we need to do it this way
    for (const auto& it : config.partitions) {
        const auto tup = std::make_tuple(it.first, it.second);
        PARTITION_XML_TESTS.push_back(tup);  // All partitions

        if (it.second.test == it.second.YES) {
            PARTITION_XML_WRITEABLE.push_back(tup);  // All writeable partitions

            if (it.second.hashable) {
                PARTITION_XML_WRITE_HASHABLE.push_back(tup);  // All write and hashable
                if (!it.second.parsed) {
                    PARTITION_XML_WRITE_HASH_NONPARSED.push_back(
                            tup);  // All write hashed and non-parsed
                }
            }
            if (it.second.parsed) {
                PARTITION_XML_WRITE_PARSED.push_back(tup);  // All write and parsed
            }
        }
    }

    // Build the packed tests, only useful if we have a hash
    if (!config.checksum.empty()) {
        for (const auto& it : config.packed) {
            for (const auto& test : it.second.tests) {
                const auto tup = std::make_tuple(it.first, test);
                if (test.expect == extension::OKAY) {  // only testing the success case
                    PACKED_XML_SUCCESS_TESTS.push_back(tup);
                } else {
                    PACKED_XML_FAIL_TESTS.push_back(tup);
                }
            }
        }
    }

    // This is a hack to make this test disapeer if there is not a checksum, userdata is not
    // hashable, or userdata is not marked to be writeable in testing
    const auto part_info = config.partitions.find("userdata");
    if (!config.checksum.empty() && part_info != config.partitions.end() &&
        part_info->second.hashable &&
        part_info->second.test == extension::Configuration::PartitionInfo::YES) {
        PARTITION_XML_USERDATA_CHECKSUM_WRITEABLE.push_back(
                std::make_tuple(part_info->first, part_info->second));
    }

    if (!PARTITION_XML_WRITE_HASHABLE.empty()) {
        SINGLE_PARTITION_XML_WRITE_HASHABLE.push_back(PARTITION_XML_WRITE_HASHABLE.front());
    }

    // Build oem tests
    for (const auto& it : config.oem) {
        auto oem_cmd = it.second;
        for (const auto& t : oem_cmd.tests) {
            OEM_XML_TESTS.push_back(std::make_tuple(it.first, oem_cmd.restricted, t));
        }
    }
}

}  // namespace fastboot

int main(int argc, char** argv) {
    std::string err;
    // Parse the args
    const std::unordered_map<std::string, std::string> args = fastboot::ParseArgs(argc, argv, &err);
    if (!err.empty()) {
        printf("%s\n", err.c_str());
        return -1;
    }

    if (args.find("config") != args.end()) {
        auto found = args.find("search_path");
        fastboot::SEARCH_PATH = (found != args.end()) ? found->second + "/" : "";
        found = args.find("output_path");
        fastboot::OUTPUT_PATH = (found != args.end()) ? found->second + "/" : "/tmp/";
        if (!fastboot::extension::ParseXml(fastboot::SEARCH_PATH + args.at("config"),
                                           &fastboot::config)) {
            printf("XML config parsing failed\n");
            return -1;
        }
        // To interface with gtest, must set global scope test variables
        fastboot::GenerateXmlTests(fastboot::config);
    }

    if (args.find("serial") != args.end()) {
        fastboot::FastBootTest::device_serial = args.at("serial");
    }

    setbuf(stdout, NULL);  // no buffering

    if (!fastboot::FastBootTest::IsFastbootOverTcp()) {
        printf("<Waiting for Device>\n");
        const auto matcher = [](usb_ifc_info* info) -> int {
            return fastboot::FastBootTest::MatchFastboot(info, fastboot::FastBootTest::device_serial);
        };
        Transport* transport = nullptr;
        while (!transport) {
            transport = usb_open(matcher);
            std::this_thread::sleep_for(std::chrono::milliseconds(10));
        }
        transport->Close();
    }

    if (args.find("serial_port") != args.end()) {
        fastboot::FastBootTest::serial_port = fastboot::ConfigureSerial(args.at("serial_port"));
    }

    ::testing::InitGoogleTest(&argc, argv);
    auto ret = RUN_ALL_TESTS();
    if (fastboot::FastBootTest::serial_port > 0) {
        close(fastboot::FastBootTest::serial_port);
    }
    return ret;
}