[+] AuDebug tests

[+] AuSwInfo win ver checks
[+] Print network adapters
[*] Update time
[*] Update IO
[*] Added extended process map tests
[*] Added UDP stream test server
[+] Added cert pinning callback demo
[*] Updated runtime
[+] Added readme
[+] Added crypto tests (missing quite a bit still. old tests could be copied over)
This commit is contained in:
Reece Wilson 2022-12-14 20:43:22 +00:00
parent 1f5c51f2ab
commit d22eb40b4e
25 changed files with 1757 additions and 216 deletions

@ -1 +1 @@
Subproject commit af438c8c172478c9f6f9c71e2ede533898def63b
Subproject commit 122fc74a669596e200481ada884497854d07c5d1

@ -1 +1 @@
Subproject commit 401cf0996267da87b7d4d98c46a7a15ceeb11013
Subproject commit 85a575eb9531d92c67cae5a547206494b55f4ebf

@ -1 +1 @@
Subproject commit cf2290444cb0554aa9f7605679f476d945109034
Subproject commit 1e9053b9383167eca317a941945ecf5d6a61aed4

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@ -0,0 +1,81 @@
# Hello
Aurora runtime *basic* tests and demos for barebones use cases.
# Getting ready
```
git clone --recursive https://gitea.reece.sx/AuroraSupport/HelloAurora
```
# Building
## Building for Windows
Tools required: MSVC (modernish?), premake5
No special steps are required. Assuming premake is present in %PATH%, run .\Win_x64_NoToolkit.bat and open the sln generated in the .\Build\Workspace directory.
Cross-arch: `--target-x86_[32/64]` can be added to either family of scripts to readd the specified architecture.
Important: if you wish to work with JavaScript projects in the future, you must ensure you have an x86_64 build of premake5.
## Building for Linux
* Procure or build; and install libc++ (clangs native not fit-for-linux STL)
Build:
```
git clone https://github.com/llvm/llvm-project.git
cd llvm-project
mkdir build
cmake \
-G Ninja \
-DCMAKE_BUILD_TYPE=Release \
-DCMAKE_INSTALL_PREFIX=/usr \
-DCMAKE_C_COMPILER=clang \
-DCMAKE_CXX_COMPILER=clang++ \
-DLLVM_ENABLE_RUNTIMES="libcxx;libcxxabi" \
-DLLVM_EXTERNAL_LIT=/usr/bin/lit \
-DLIBCXX_INSTALL_EXPERIMENTAL_LIBRARY=NO \
-B build \
-S llvm
ninja -C build cxx cxxabi
ninja -C build check-cxx check-cxxabi
ninja -C build install-cxx install-cxxabi
```
Note: We use libc++ as a one-size-fits-all cross-platform STL solution. Its' core platform abstraction might suck, but it does well to maintain modern container and utility support. Plus, it's the defacto standard for embedded systems, meme web technology, and non-standard pc things including games consoles and mac. Pipeline and software dependencies can be better optimized and QA'd once normalized to one or two main STL targets. The bits that do suck, like thread primitives, aren't used by most developers who care about performance anyway. The quirks that are there, like locale fetch issues, don't affect us.
* Procure or compile; and install premake
Build:
```
git clone https://gitea.reece.sx/AuroraPipeline/premake
cd premake
make -f Bootstrap.mak linux
cp bin/release/premake5 /usr/bin/premake5
chmod +x /usr/bin/premake5
```
* Run the final premake script
```
./Linux_x64_NoToolkit.sh
```
* Compile...
```
cd Build/Workspace
make -jthreadsN config=[debug/stage/ship]_linux
```
Cross-arch: none yet.
# Regeneration/rebuild
Repeat the last batch/bash script; and rerun make/msbuild, or reload all in Visual Studio

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@ -96,6 +96,36 @@ static void DumpAddressSpace()
AuLogInfo("");
}
static void PrintWindowsVersion()
{
AuLogInfo("IsWindowsXPOrGreater() : {}. \n"
"IsWindowsXPSP1OrGreater() : {}. \n"
"IsWindowsXPSP2OrGreater() : {}. \n"
"IsWindowsXPSP3OrGreater() : {}. \n"
"IsWindowsVistaOrGreater() : {}. \n"
"IsWindowsVistaSP1OrGreater() : {}. \n"
"IsWindowsVistaSP2OrGreater() : {}. \n"
"IsWindows7OrGreater() : {}. \n"
"IsWindows7SP1OrGreater() : {}. \n"
"IsWindows8OrGreater() : {}. \n"
"IsWindows8Point1OrGreater() : {}. \n"
"IsWindows10OrGreater() : {}. \n"
"IsWindows11OrGreater() : {}. \n",
AuSwInfo::IsWindowsXPOrGreater(),
AuSwInfo::IsWindowsXPSP1OrGreater(),
AuSwInfo::IsWindowsXPSP2OrGreater(),
AuSwInfo::IsWindowsXPSP3OrGreater(),
AuSwInfo::IsWindowsVistaOrGreater(),
AuSwInfo::IsWindowsVistaSP1OrGreater(),
AuSwInfo::IsWindowsVistaSP2OrGreater(),
AuSwInfo::IsWindows7OrGreater(),
AuSwInfo::IsWindows7SP1OrGreater(),
AuSwInfo::IsWindows8OrGreater(),
AuSwInfo::IsWindows8Point1OrGreater(),
AuSwInfo::IsWindows10OrGreater(),
AuSwInfo::IsWindows11OrGreater());
}
void RunTests()
{
Aurora::RuntimeStartInfo info;
@ -106,4 +136,5 @@ void RunTests()
PrintRamSpecs();
PrintCPUSpecs();
DumpAddressSpace();
PrintWindowsVersion();
}

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@ -0,0 +1,396 @@
/***
Copyright (C) 2022 J Reece Wilson (a/k/a "Reece"). All rights reserved.
File: Main.cpp
Date: 2022-2-18
Author: Reece
***/
#include <AuroraRuntime.hpp>
#include <Aurora/Crypto/HashCash/HashCash.hpp>
#include <Aurora/Crypto/BCrypt/BCrypt.hpp>
#include <gtest/gtest.h>
#include <Aurora/Crypto/HashCash/HashCash.hpp>
static const auto kPassword = "testpassword";
TEST(Crypto, HashCash)
{
}
TEST(BCrypt, RoundTrip)
{
auto salt = AuCrypto::BCrypt::GenSalt(14);
ASSERT_FALSE(salt.empty());
AuLogDbg("salt: {}", salt);
auto hash = AuCrypto::BCrypt::HashPassword(kPassword, salt);
ASSERT_FALSE(hash.empty());
AuLogDbg("password: {}", hash);
ASSERT_TRUE(AuCrypto::BCrypt::CheckPassword(kPassword, hash));
}
TEST(BCrypt, KnownGood)
{
// Trust me bro
}
TEST(BCryptSalt, T_10)
{
auto salt = AuCrypto::BCrypt::GenSalt(10);
ASSERT_FALSE(salt.empty());
AuLogDbg("salt 10: {}", salt);
auto hash = AuCrypto::BCrypt::HashPassword(kPassword, salt);
ASSERT_FALSE(hash.empty());
AuLogDbg("password: {}", hash);
}
TEST(BCryptSalt, T_11)
{
auto salt = AuCrypto::BCrypt::GenSalt(11);
ASSERT_FALSE(salt.empty());
AuLogDbg("salt 11: {}", salt);
auto hash = AuCrypto::BCrypt::HashPassword(kPassword, salt);
ASSERT_FALSE(hash.empty());
AuLogDbg("password: {}", hash);
}
TEST(BCryptSalt, T_12)
{
auto salt = AuCrypto::BCrypt::GenSalt(12);
ASSERT_FALSE(salt.empty());
AuLogDbg("salt 12: {}", salt);
auto hash = AuCrypto::BCrypt::HashPassword(kPassword, salt);
ASSERT_FALSE(hash.empty());
AuLogDbg("password: {}", hash);
}
TEST(BCryptSalt, T_13)
{
auto salt = AuCrypto::BCrypt::GenSalt(13);
ASSERT_FALSE(salt.empty());
AuLogDbg("salt 13: {}", salt);
auto hash = AuCrypto::BCrypt::HashPassword(kPassword, salt);
ASSERT_FALSE(hash.empty());
AuLogDbg("password: {}", hash);
}
TEST(BCryptSalt, T_14)
{
auto salt = AuCrypto::BCrypt::GenSalt(14);
ASSERT_FALSE(salt.empty());
AuLogDbg("salt 14: {}", salt);
auto hash = AuCrypto::BCrypt::HashPassword(kPassword, salt);
ASSERT_FALSE(hash.empty());
AuLogDbg("password: {}", hash);
}
TEST(BCryptSalt, T_15)
{
auto salt = AuCrypto::BCrypt::GenSalt(15);
ASSERT_FALSE(salt.empty());
AuLogDbg("salt 15: {}", salt);
auto hash = AuCrypto::BCrypt::HashPassword(kPassword, salt);
ASSERT_FALSE(hash.empty());
AuLogDbg("password: {}", hash);
}
TEST(BCryptSalt, T_16)
{
auto salt = AuCrypto::BCrypt::GenSalt(16);
ASSERT_FALSE(salt.empty());
AuLogDbg("salt 16: {}", salt);
auto hash = AuCrypto::BCrypt::HashPassword(kPassword, salt);
ASSERT_FALSE(hash.empty());
AuLogDbg("password: {}", hash);
}
TEST(BCryptSalt, T_17)
{
auto salt = AuCrypto::BCrypt::GenSalt(17);
ASSERT_FALSE(salt.empty());
AuLogDbg("salt 17: {}", salt);
auto hash = AuCrypto::BCrypt::HashPassword(kPassword, salt);
ASSERT_FALSE(hash.empty());
AuLogDbg("password: {}", hash);
}
#define ADD_HASHCASH(n) \
TEST(HashCash, Power_## n) \
{ \
auto token = AuRng::RngU64(); \
auto answer = AuCrypto::HashCash::FindAnswer(token, n); \
ASSERT_TRUE(AuCrypto::HashCash::CheckSalt(token, n, answer)); \
}
ADD_HASHCASH(18) //
ADD_HASHCASH(19) //
ADD_HASHCASH(20) //
ADD_HASHCASH(21) //
ADD_HASHCASH(22) //
ADD_HASHCASH(23) //
ADD_HASHCASH(24) //
ADD_HASHCASH(25) //
ADD_HASHCASH(26) //
ADD_HASHCASH(27) //
//ADD_HASHCASH(28) // 47936
//ADD_HASHCASH(32) //
TEST(RSA, RSARng)
{
auto pRSAPrivate = AuCrypto::RSA::NewRSAKeyShared(4096);
ASSERT_TRUE(bool(pRSAPrivate));
}
TEST(RSACerts, GenerateOne)
{
auto pRSAPrivate = AuCrypto::RSA::NewRSAKeyShared(4096);
ASSERT_TRUE(bool(pRSAPrivate));
AuCrypto::X509::CertRequest request;
request.pSelfSigningRSAKey = pRSAPrivate;
request.pRSAKey = pRSAPrivate->ToPublic();
request.bSubjectKeyId = true;
request.name.commonName = "Aurora Test";
request.name.state = "Shithole";
request.name.countryCode = "GB";
request.name.name = "Firstname Lastname";
request.digest = AuHashing::EHashType::eSHA2_64;
auto cert = AuCrypto::X509::GenerateCertificate(request);
ASSERT_TRUE(bool(cert));
ASSERT_TRUE(AuFS::WriteFile("./SelfSigned_RSA.crt", cert.GetResult()));
}
TEST(ECCCerts, GenerateNist521)
{
auto pECCPrivate = AuCrypto::ECC::NewECCShared(AuCrypto::ECC::EECCCurve::eCurve521);
ASSERT_TRUE(bool(pECCPrivate));
AuByteBuffer a;
pECCPrivate->AsPublicECC(a);
auto pECCPublic = AuCrypto::ECC::OpenPublicECCShared(a);
ASSERT_TRUE(bool(pECCPublic));
AuCrypto::X509::CertRequest request;
request.pSelfSigningECCKey = pECCPrivate;
request.pECCKey = pECCPublic;
request.bSubjectKeyId = true;
request.name.commonName = "Aurora Test";
request.name.state = "Shithole";
request.name.countryCode = "GB";
request.name.name = "Firstname Lastname";
request.digest = AuHashing::EHashType::eSHA2_64;
auto cert = AuCrypto::X509::GenerateCertificate(request);
ASSERT_TRUE(bool(cert));
ASSERT_TRUE(AuFS::WriteFile("./SelfSigned_N521.crt", cert.GetResult()));
}
TEST(ECCCerts, GenerateSECP256K1)
{
auto pECCPrivate = AuCrypto::ECC::NewECCShared(AuCrypto::ECC::EECCCurve::eCurveSECP256K1);
ASSERT_TRUE(bool(pECCPrivate));
AuByteBuffer a;
pECCPrivate->AsPublicECC(a);
auto pECCPublic = AuCrypto::ECC::OpenPublicECCShared(a);
ASSERT_TRUE(bool(pECCPublic));
AuCrypto::X509::CertRequest request;
request.pSelfSigningECCKey = pECCPrivate;
request.pECCKey = pECCPublic;
request.bSubjectKeyId = true;
request.name.commonName = "Aurora Test";
request.name.state = "Shithole";
request.name.countryCode = "GB";
request.name.name = "Firstname Lastname";
request.digest = AuHashing::EHashType::eSHA2_64;
request.usage.push_back(AuCrypto::X509::EExtendedUsage::eCodeSigning);
request.usage.push_back(AuCrypto::X509::EExtendedUsage::eOCSPSigning);
auto cert = AuCrypto::X509::GenerateCertificate(request);
ASSERT_TRUE(bool(cert));
ASSERT_TRUE(AuFS::WriteFile("./SelfSigned_256K1.crt", cert.GetResult()));
}
TEST(ECCReimport, SECP256K1)
{
auto pECCPrivate = AuCrypto::ECC::NewECCShared(AuCrypto::ECC::EECCCurve::eCurveSECP256K1);
ASSERT_TRUE(bool(pECCPrivate));
AuByteBuffer a;
pECCPrivate->AsPublicECC(a);
auto pECCPublic = AuCrypto::ECC::OpenPublicECCShared(a);
ASSERT_TRUE(bool(pECCPublic));
}
TEST(ECCReimport, SECP256K1Private)
{
auto pECCPrivate = AuCrypto::ECC::NewECCShared(AuCrypto::ECC::EECCCurve::eCurveSECP256K1);
ASSERT_TRUE(bool(pECCPrivate));
AuByteBuffer a;
pECCPrivate->AsPrivateECC(a);
auto pECCPublic = AuCrypto::ECC::OpenPrivateECCShared(a);
ASSERT_TRUE(bool(pECCPublic));
}
TEST(ECCReimport, x25519)
{
auto pECCPrivate = AuCrypto::ECC::NewECCShared(AuCrypto::ECC::EECCCurve::eCurveX25519);
ASSERT_TRUE(bool(pECCPrivate));
AuByteBuffer a;
pECCPrivate->AsPublicECC(a);
auto pECCPublic = AuCrypto::ECC::OpenPublicECCShared(a);
ASSERT_TRUE(bool(pECCPublic));
}
TEST(ECCReimport, x25519Private)
{
auto pECCPrivate = AuCrypto::ECC::NewECCShared(AuCrypto::ECC::EECCCurve::eCurveX25519);
ASSERT_TRUE(bool(pECCPrivate));
AuByteBuffer a;
pECCPrivate->AsPrivateECC(a);
auto pECCPublic = AuCrypto::ECC::OpenPrivateECCShared(a);
ASSERT_TRUE(bool(pECCPublic));
}
TEST(ECCReimport, ed25519)
{
auto pECCPrivate = AuCrypto::ECC::NewECCShared(AuCrypto::ECC::EECCCurve::eCurveEd25519);
ASSERT_TRUE(bool(pECCPrivate));
AuByteBuffer a;
pECCPrivate->AsPublicECC(a);
auto pECCPublic = AuCrypto::ECC::OpenPublicECCShared(a);
ASSERT_TRUE(bool(pECCPublic));
}
TEST(ECCReimport, ed25519Private)
{
auto pECCPrivate = AuCrypto::ECC::NewECCShared(AuCrypto::ECC::EECCCurve::eCurveEd25519);
ASSERT_TRUE(bool(pECCPrivate));
AuByteBuffer a;
pECCPrivate->AsPrivateECC(a);
auto pECCPublic = AuCrypto::ECC::OpenPrivateECCShared(a);
ASSERT_TRUE(bool(pECCPublic));
}
//
//TEST(ECCCerts, x25519)
//{
// auto pECCPrivate = AuCrypto::ECC::NewECCShared(AuCrypto::ECC::EECCCurve::eCurveEd25519);
// ASSERT_TRUE(bool(pECCPrivate));
//
// AuByteBuffer a;
// pECCPrivate->AsPublicECC(a);
// auto pECCPublic = AuCrypto::ECC::OpenPublicECCShared(a);
//
// AuCrypto::X509::CertRequest request;
// request.pSelfSigningECCKey = pECCPrivate;
// request.pECCKey = pECCPublic;
// request.bSubjectKeyId = true;
// request.name.commonName = "Aurora Test";
// request.name.state = "Shithole";
// request.name.countryCode = "GB";
// request.name.name = "Firstname Lastname";
//
// auto cert = AuCrypto::X509::GenerateCertificate(request);
// ASSERT_TRUE(bool(cert));
//
// ASSERT_TRUE(AuFS::WriteFile("./SelfSigned_X25519.crt", cert.GetResult()));
//}
TEST(RSA, RSAExportImport)
{
}
TEST(RSA, RSAEncrypt)
{
}
TEST(RSA, RSAVerify)
{
}
TEST(ECC, ECCVerify)
{
}
TEST(ECC, ECCECDH)
{
}
TEST(PEM, A)
{
}
TEST(CBC, AES)
{
char IV[16];
char key[24];
AuRng::RngFillArray(IV);
AuRng::RngFillArray(key);
auto pContext = AuCrypto::CBC::NewContextUnique();
auto pContext2 = AuCrypto::CBC::NewContextUnique();
ASSERT_TRUE(pContext);
ASSERT_TRUE(pContext2);
ASSERT_TRUE(pContext->Initialize(key, IV));
ASSERT_TRUE(pContext2->Initialize(key, IV));
char textBuffer[] { "The quick brown fox jumps over the lazy dog!!!!" };
char textBuffer2[] { "The quick brown fox jumps over the lazy dog!!!!" };
ASSERT_TRUE(AuCrypto::AES::CBCEncrypt(AuUnsafeRaiiToShared(pContext), textBuffer));
EXPECT_NE(AuMemcmp(textBuffer, textBuffer2, sizeof(textBuffer2)), 0);
ASSERT_TRUE(AuCrypto::AES::CBCDecrypt(AuUnsafeRaiiToShared(pContext2), textBuffer));
EXPECT_EQ(AuMemcmp(textBuffer, textBuffer2, sizeof(textBuffer2)), 0);
}
TEST(CBC, TDES)
{
char IV[16];
char key[24];
AuRng::RngFillArray(IV);
AuRng::RngFillArray(key);
auto pContext = AuCrypto::CBC::NewContextUnique();
auto pContext2 = AuCrypto::CBC::NewContextUnique();
ASSERT_TRUE(pContext);
ASSERT_TRUE(pContext2);
ASSERT_TRUE(pContext->Initialize(key, IV));
ASSERT_TRUE(pContext2->Initialize(key, IV));
char textBuffer[] { "The quick brown fox jumps over the lazy dog!!!!" };
char textBuffer2[] { "The quick brown fox jumps over the lazy dog!!!!" };
ASSERT_TRUE(AuCrypto::TDES::CBCEncrypt(AuUnsafeRaiiToShared(pContext), textBuffer));
EXPECT_NE(AuMemcmp(textBuffer, textBuffer2, sizeof(textBuffer2)), 0);
ASSERT_TRUE(AuCrypto::TDES::CBCDecrypt(AuUnsafeRaiiToShared(pContext2), textBuffer));
EXPECT_EQ(AuMemcmp(textBuffer, textBuffer2, sizeof(textBuffer2)), 0);
}
void RunTests()
{
Aurora::RuntimeStartInfo info;
info.console.fio.enableLogging = false;
Aurora::RuntimeStart(info);
}

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@ -301,6 +301,33 @@ TEST(Resolve, GoogleAAAA)
}
}
TEST(Adapters, Print)
{
auto pNetProcessor = AuNet::NewNetworkInterface();
ASSERT_TRUE(bool(pNetProcessor));
AuLogInfo("Hostname: {}", pNetProcessor->GetInterfacesService()->GetHostname());
auto ifaces = pNetProcessor->GetInterfacesService()->GetAdapters();
for (const auto &pAdapter : ifaces)
{
AuString dns = "";
for (const auto &dnsIP : pAdapter->GetDNS())
{
dns += fmt::format(" dns-server={}", dnsIP.ToString());
}
AuLogInfo("Found adapter interface (family: {}): \n\tName: {}\n\tDevice: {}\n\tAddress: {}\n\tMulticast: {}\n\tGateway: {}\n\tDNS: {}\n\n",
AuNet::EIPProtocolToString(pAdapter->ToFamily()),
pAdapter->ToName(),
pAdapter->ToDevice(),
pAdapter->ToAddress().ToString(),
pAdapter->ToBroadcastAddress().ToString(),
pAdapter->ToGateway().ToString(),
dns);
}
}
void RunTests()
{
Aurora::RuntimeStartInfo info;

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@ -0,0 +1,15 @@
/***
Copyright (C) 2022 J Reece Wilson (a/k/a "Reece"). All rights reserved.
File: Main.cpp
Date: 2022-2-18
Author: Reece
***/
#include <AuroraRuntime.hpp>
void RunTests()
{
Aurora::RuntimeStartInfo info;
info.console.fio.enableLogging = false;
Aurora::RuntimeStart(info);
}

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@ -0,0 +1,15 @@
/***
Copyright (C) 2022 J Reece Wilson (a/k/a "Reece"). All rights reserved.
File: Main.cpp
Date: 2022-2-18
Author: Reece
***/
#include <AuroraRuntime.hpp>
void RunTests()
{
Aurora::RuntimeStartInfo info;
info.console.fio.enableLogging = false;
Aurora::RuntimeStart(info);
}

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@ -0,0 +1,133 @@
/***
Copyright (C) 2022 J Reece Wilson (a/k/a "Reece"). All rights reserved.
File: Main.cpp
Date: 2022-2-18
Author: Reece
***/
#include <AuroraRuntime.hpp>
#include <gtest/gtest.h>
TEST(ErrorStack, A)
{
AuErrorStack errors;
SysPushErrorIO("Something something IO error");
SysPushErrorIO("Something something IO error 1");
SysPushErrorIO("Something something IO error 2 {}", "hello worlds");
ASSERT_TRUE(errors.HasCaptured());
ASSERT_TRUE(errors.HasMultipleOccurred());
ASSERT_TRUE(errors.FirstMessage()->pNextThreadMesage);
ASSERT_TRUE(errors.FirstMessage()->pNextThreadMesage->pNextThreadMesage);
AuLogDbg("{}, {}, {}",
*errors.ToString(),
errors.FirstMessage()->pNextThreadMesage->ToString(),
errors.FirstMessage()->pNextThreadMesage->pNextThreadMesage->ToString());
}
TEST(ErrorStack, B)
{
AuErrorStack errors;
try
{
AU_THROW_CONST_STRING("Hello error stack");
}
catch (...)
{
}
ASSERT_TRUE(errors.HasCaptured());
AuLogDbg("{}", *errors.ToString());
}
TEST(CatchMessage, B)
{
try
{
AU_THROW_CONST_STRING("Hello try/catch");
}
catch (...)
{
AuLogDbg("caught message: {}", AuDebug::GetLastException());
}
}
TEST(DemoFormattedThrow, a)
{
try
{
AU_THROW_FORMATTED("hello people {}", 23423423);
}
catch (...)
{
}
}
TEST(DemoTelemetryPoke, TelemetryHint)
{
try
{
errno = 3269420;
AU_THROW_CONST_STRING("Hello telemetry");
}
catch (...)
{
AuDebug::CheckErrors(); // techincally not required for exception logging
}
}
TEST(Demo, ThrowStringLiteral)
{
try
{
throw "hello most modern platforms";
}
catch (...)
{
}
}
TEST(DemoTelemetryPoke, ErrnoHint)
{
errno = 3269420;
AuDebug::CheckErrors();
}
TEST(DemoSysError, AA)
{
SysPushErrorGeneric("Hello World");
}
TEST(DemoAssert, A)
{
SysAssertExp(true, "i will not fail {}", 100);
SysAssert(true, "i will not fail {}", 100);
SysAssertDbgExp(true, "i will not fail {} (our clients fucking suck. i hate them.)", 100);
SysAssertDbg(true, "i will not fail {} (our clients fucking suck. i hate them.)", 100);
}
TEST(DemoPanic, ASDASd)
{
//SysPanic("bye bye {}", 234);
}
// tests/demos:
// TODO: function name demangling]
// TODo: stack trace printing/expansion
void RunTests()
{
Aurora::RuntimeStartInfo info;
info.console.fio.enableLogging = false;
Aurora::RuntimeStart(info);
}

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@ -8,14 +8,14 @@
#include <AuroraRuntime.hpp>
#include <gtest/gtest.h>
TEST(Benchmark, CurrentInternalClockMS)
TEST(Benchmark, HighResClockMS)
{
SysBenchmark("CurrentInternalClockMS");
SysBenchmark("HighResClockMS");
AuUInt c {};
for (int i = 0; i < 100'000'000; i++)
{
c += AuTime::CurrentInternalClockMS();
c += AuTime::HighResClockMS();
}
}

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@ -9,14 +9,135 @@
#include <Aurora/IO/IOExperimental.hpp>
#include <gtest/gtest.h>
TEST(IO, Proceessor_SoftAbort)
//TEST(IO, Proceessor_SoftAbort)
//{
// static int counter {};
// static int counter2 {};
// static int counter3 {};
// static int counter4 {};
// auto pIODrivenQueue = AuIO::NewIOProcessorNoQueue(false);
// ASSERT_TRUE(bool(pIODrivenQueue));
//
// auto timer = AuIO::NewWaitableIOTimer();
//
// auto listener = AuMakeShared<AuIO::IIOEventListenerFunctional>();
// listener->Tick_SelfIOEventFunctional = [&]()
// {
// AuLogDbg("SelfIO event fired");
// counter++;
// };
// listener->Tick_AnyFunctional = []()
// {
// AuLogDbg("* tick event fired");
// counter2++;
// };
// listener->OnNominalCompletionFunctional = [&]()
// {
// AuLogDbg("* complete");
// counter3++;
// };
// listener->OnFailureCompletionFunctional = [&]()
// {
// AuLogDbg("* failure");
// counter4++;
// };
//
// timer->SetConstantTick(AuMSToNS<AuUInt64>(500));
//
// AuLogDbg("Start watch");
// auto watch = pIODrivenQueue->StartIOWatch(timer, listener);
//
// for (int i = 0; i < 4; i++)
// {
// auto pumpedEvents = pIODrivenQueue->RunTick();
// AuLogDbg("{} ln: {} io watches ticked", __LINE__, pumpedEvents);
// }
//
// AuLogDbg("Aborting / SOFT");
// watch->StopWatch();
//
// // Nop
// watch->FailWatch();
//
// auto pumpedEvents = pIODrivenQueue->RunTick();
// AuLogDbg("{} ln: {} io watches ticked", __LINE__, pumpedEvents);
//
// ASSERT_EQ(counter, 4);
// ASSERT_EQ(counter2, 4);
// ASSERT_EQ(counter3, 1);
// ASSERT_EQ(counter4, 0);
//
//}
//
//TEST(IO, Proceessor_FailAbort)
//{
// static int counter {};
// static int counter2 {};
// static int counter3 {};
// static int counter4 {};
// auto pIODrivenQueue = AuIO::NewIOProcessorNoQueue(false);
// ASSERT_TRUE(bool(pIODrivenQueue));
//
// auto timer = AuIO::NewWaitableIOTimer();
//
// auto listener = AuMakeShared<AuIO::IIOEventListenerFunctional>();
// listener->Tick_SelfIOEventFunctional = [&]()
// {
// AuLogDbg("SelfIO event fired");
// counter++;
// };
// listener->Tick_AnyFunctional = []()
// {
// AuLogDbg("* tick event fired");
// counter2++;
// };
// listener->OnNominalCompletionFunctional = [&]()
// {
// AuLogDbg("* complete");
// counter3++;
// };
// listener->OnFailureCompletionFunctional = [&]()
// {
// AuLogDbg("* failure");
// counter4++;
// };
//
// timer->SetConstantTick(AuMSToNS<AuUInt64>(500));
//
// AuLogDbg("Start watch");
// auto watch = pIODrivenQueue->StartIOWatch(timer, listener);
//
// for (int i = 0; i < 4; i++)
// {
// auto pumpedEvents = pIODrivenQueue->RunTick();
// AuLogDbg("{} ln: {} io watches ticked", __LINE__, pumpedEvents);
// }
//
// AuLogDbg("Aborting / HARD");
// watch->FailWatch();
//
// // Nop
// watch->StopWatch();
//
// auto pumpedEvents = pIODrivenQueue->RunTick();
// AuLogDbg("{} ln: {} io watches ticked", __LINE__, pumpedEvents);
//
// ASSERT_EQ(counter, 4);
// ASSERT_EQ(counter2, 4);
// ASSERT_EQ(counter3, 0);
// ASSERT_EQ(counter4, 1);
//
//}
#if 0
TEST(IO, AA)
{
static int counter {};
static int counter2 {};
static int counter3 {};
static int counter4 {};
auto ioDrivenQueue = AuIO::NewIOProcessorNoQueue(false);
ASSERT_TRUE(bool(ioDrivenQueue));
auto pIODrivenQueue = AuIO::NewIOProcessorNoQueue(false);
ASSERT_TRUE(bool(pIODrivenQueue));
auto timer = AuIO::NewWaitableIOTimer();
@ -42,74 +163,15 @@ TEST(IO, Proceessor_SoftAbort)
counter4++;
};
timer->SetConstantTick(AuMSToNS<AuUInt64>(500));
timer->SetConstantTick(AuMSToNS<AuUInt64>(5));
AuLogDbg("Start watch");
auto watch = ioDrivenQueue->StartIOWatch(timer, listener);
auto watch = pIODrivenQueue->StartIOWatch(timer, listener);
for (int i = 0; i < 4; i++)
for (int i = 0; i < 10'000'000; i++)
{
auto pumpedEvents = ioDrivenQueue->RunTick();
AuLogDbg("{} ln: {} io watches ticked", __LINE__, pumpedEvents);
}
AuLogDbg("Aborting / SOFT");
watch->StopWatch();
// Nop
watch->FailWatch();
auto pumpedEvents = ioDrivenQueue->RunTick();
AuLogDbg("{} ln: {} io watches ticked", __LINE__, pumpedEvents);
ASSERT_EQ(counter, 4);
ASSERT_EQ(counter2, 4);
ASSERT_EQ(counter3, 1);
ASSERT_EQ(counter4, 0);
}
TEST(IO, Proceessor_FailAbort)
{
static int counter {};
static int counter2 {};
static int counter3 {};
static int counter4 {};
auto ioDrivenQueue = AuIO::NewIOProcessorNoQueue(false);
ASSERT_TRUE(bool(ioDrivenQueue));
auto timer = AuIO::NewWaitableIOTimer();
auto listener = AuMakeShared<AuIO::IIOEventListenerFunctional>();
listener->Tick_SelfIOEventFunctional = [&]()
{
AuLogDbg("SelfIO event fired");
counter++;
};
listener->Tick_AnyFunctional = []()
{
AuLogDbg("* tick event fired");
counter2++;
};
listener->OnNominalCompletionFunctional = [&]()
{
AuLogDbg("* complete");
counter3++;
};
listener->OnFailureCompletionFunctional = [&]()
{
AuLogDbg("* failure");
counter4++;
};
timer->SetConstantTick(AuMSToNS<AuUInt64>(500));
AuLogDbg("Start watch");
auto watch = ioDrivenQueue->StartIOWatch(timer, listener);
for (int i = 0; i < 4; i++)
{
auto pumpedEvents = ioDrivenQueue->RunTick();
SysBenchmark("Root tick");
auto pumpedEvents = pIODrivenQueue->RunTick();
AuLogDbg("{} ln: {} io watches ticked", __LINE__, pumpedEvents);
}
@ -119,62 +181,61 @@ TEST(IO, Proceessor_FailAbort)
// Nop
watch->StopWatch();
auto pumpedEvents = ioDrivenQueue->RunTick();
auto pumpedEvents = pIODrivenQueue->RunTick();
AuLogDbg("{} ln: {} io watches ticked", __LINE__, pumpedEvents);
ASSERT_EQ(counter, 4);
ASSERT_EQ(counter2, 4);
ASSERT_EQ(counter3, 0);
ASSERT_EQ(counter4, 1);
}
#endif
TEST(IO, ReadFileThroughPipeProcessor2MBReadsEQ)
TEST(IO, WriteMassive200MBFileBenchmarkDisk)
{
// Write 20MB of RNG asynchronously
AuByteBuffer rngbuffer(512 * 1024 * 40, AuUInt(AuHwInfo::GetPageSize()));
AuByteBuffer rngbuffer(200 * 1024 * 1024, AuUInt(AuHwInfo::GetPageSize()));
{
auto stream = AuIOFS::OpenAsyncUnique("./AsyncFilePIPE", AuIOFS::EFileOpenMode::eReadWrite, true);
auto stream = AuIOFS::OpenAsyncUnique("./AsyncFilePIPE2", AuIOFS::EFileOpenMode::eReadWrite, true);
ASSERT_TRUE(bool(stream));
AuRng::RngFillRange(rngbuffer);
auto transaction = stream->NewTransaction();
ASSERT_TRUE(bool(transaction));
auto pTransaction = stream->NewTransaction();
ASSERT_TRUE(bool(pTransaction));
transaction->SetCallback(AuMakeShared<AuIO::IAsyncFinishedSubscriberFunctional>([=](AuUInt64 offset, AuUInt32 length)
pTransaction->SetCallback(AuMakeShared<AuIO::IAsyncFinishedSubscriberFunctional>([=](AuUInt64 offset, AuUInt32 length)
{
AuLogDbg("AIO 1 callback: {} {} {}", offset, length, transaction->GetOSErrorCode());
SysAssert(length == 512 * 1024 * 40);
AuLogDbg("AIO 1 callback: {} {} {}", offset, length, pTransaction->GetOSErrorCode());
//SysAssert(length == 200 * 1024 * 40);
}));
AuMemoryViewRead readView(rngbuffer);
ASSERT_TRUE(transaction->StartWrite(0, AuUnsafeRaiiToShared(&readView)));
ASSERT_TRUE(pTransaction->StartWrite(0, AuUnsafeRaiiToShared(&readView)));
AuLogDbg("AIO 1: waiting....");
ASSERT_TRUE(transaction->Wait(0));
ASSERT_TRUE(pTransaction->Wait(0));
AuLogDbg("AIO 1: wait complete....");
ASSERT_TRUE(transaction->NewLoopSource()->IsSignaled());
ASSERT_TRUE(transaction->Complete());
ASSERT_TRUE(pTransaction->NewLoopSource()->IsSignaled());
ASSERT_TRUE(pTransaction->Complete());
}
{
SysBenchmark("Total write time");
// Create the io processor
auto ioDrivenQueue = AuIO::NewIOProcessorNoQueue(false);
ASSERT_TRUE(bool(ioDrivenQueue));
auto pIODrivenQueue = AuIO::NewIOProcessorNoQueue(false);
ASSERT_TRUE(bool(pIODrivenQueue));
auto pipeProcessor = ioDrivenQueue->ToPipeProcessor();
ASSERT_TRUE(bool(pipeProcessor));
auto pPipeProcessor = pIODrivenQueue->ToPipeProcessor();
ASSERT_TRUE(bool(pPipeProcessor));
// Open the file and prepare an async transaction for the pipe processor to use
// Open the file and prepare an async pTransaction for the pipe processor to use
auto stream = AuIOFS::OpenAsyncUnique("./AsyncFilePIPE", AuIOFS::EFileOpenMode::eRead, true);
auto stream = AuIOFS::OpenAsyncUnique("./AsyncFilePIPE2", AuIOFS::EFileOpenMode::eRead, true);
ASSERT_TRUE(bool(stream));
auto transaction = stream->NewTransaction();
ASSERT_TRUE(bool(transaction));
auto pTransaction = stream->NewTransaction();
ASSERT_TRUE(bool(pTransaction));
// Create an event listener for the callbacks
@ -199,7 +260,121 @@ TEST(IO, ReadFileThroughPipeProcessor2MBReadsEQ)
// Setup the IOPipeRequest
AuIO::IOPipeRequestAIO aio;
aio.pAsyncTransaction = transaction;
aio.pAsyncTransaction = pTransaction;
aio.pListener = listener;
aio.bIsStream = false;
aio.output.type = AuIO::EPipeCallbackType::eTryHandleBufferedPart;
aio.uPageLengthOrZero = 1024 * 1024 *5; // read in 2MB chunks
aio.uBufferLengthOrZero = 1024 * 1024 * 5; // read in 2MB chunks
static auto localCount = 0;
localCount = 0;
auto onData = AuMakeShared<AuIO::IIOBufferedStreamAvailableFunctional>();
AuByteBuffer outBuffer;
onData->OnDataAvailableFunctional = [&](AuByteBuffer &view)
{
AuLogDbg("Pipe processing: {}, tick: {}", view.RemainingBytes(), localCount++);
outBuffer.Write(view.readPtr, view.RemainingBytes());
view.Skip(view.RemainingBytes());
return true;
};
aio.output.handleBufferedStream.pOnData = onData;
// Finally create the damn pipe
auto filePipe = pPipeProcessor->NewAIOPipe(aio);
ASSERT_TRUE(bool(filePipe));
ASSERT_TRUE(filePipe->Start());
// Main loop
while (pIODrivenQueue->HasItems())
{
// Since we aren't using an external loop queue, we manually pump the processor in here under this spinloop
// If we were using a loop queue, we wouldn't need to do anything at all. You could still technically
// use pIODrivenQueue->ToQueue()->WaitAny() to trigger the tick.
pIODrivenQueue->RunTick(); // also: TryTick and ManualTick
AuLogDbg("throughput benchmark: {} mb/s", filePipe->GetPredictedThroughput() / 1024 / 1024);
}
//ASSERT_EQ(localCount, 10);
ASSERT_EQ(outBuffer, rngbuffer);
}
}
TEST(IO, ReadFileThroughpPipeProcessor2MBReadsEQ)
{
// Write 20MB of RNG asynchronously
AuByteBuffer rngbuffer(512 * 1024 * 40, AuUInt(AuHwInfo::GetPageSize()));
{
auto stream = AuIOFS::OpenAsyncUnique("./AsyncFilePIPE", AuIOFS::EFileOpenMode::eReadWrite, true);
ASSERT_TRUE(bool(stream));
AuRng::RngFillRange(rngbuffer);
auto pTransaction = stream->NewTransaction();
ASSERT_TRUE(bool(pTransaction));
pTransaction->SetCallback(AuMakeShared<AuIO::IAsyncFinishedSubscriberFunctional>([=](AuUInt64 offset, AuUInt32 length)
{
AuLogDbg("AIO 1 callback: {} {} {}", offset, length, pTransaction->GetOSErrorCode());
SysAssert(length == 512 * 1024 * 40);
}));
AuMemoryViewRead readView(rngbuffer);
ASSERT_TRUE(pTransaction->StartWrite(0, AuUnsafeRaiiToShared(&readView)));
AuLogDbg("AIO 1: waiting....");
ASSERT_TRUE(pTransaction->Wait(0));
AuLogDbg("AIO 1: wait complete....");
ASSERT_TRUE(pTransaction->NewLoopSource()->IsSignaled());
ASSERT_TRUE(pTransaction->Complete());
}
{
// Create the io processor
auto pIODrivenQueue = AuIO::NewIOProcessorNoQueue(false);
ASSERT_TRUE(bool(pIODrivenQueue));
auto pPipeProcessor = pIODrivenQueue->ToPipeProcessor();
ASSERT_TRUE(bool(pPipeProcessor));
// Open the file and prepare an async pTransaction for the pipe processor to use
auto stream = AuIOFS::OpenAsyncUnique("./AsyncFilePIPE", AuIOFS::EFileOpenMode::eRead, true);
ASSERT_TRUE(bool(stream));
auto pTransaction = stream->NewTransaction();
ASSERT_TRUE(bool(pTransaction));
// Create an event listener for the callbacks
auto listener = AuMakeShared<AuIO::IIOPipeEventListenerFunctional>();
ASSERT_TRUE(bool(listener));
listener->OnPipeSuccessEventFunctional = []()
{
AuLogInfo("File IO pipe complete");
};
listener->OnPipeFailureEventFunctional = []()
{
AuLogInfo("File IO pipe failure");
};
listener->OnPipePartialEventFunctional = [](AuUInt tranferred)
{
AuLogInfo("on part: {}", tranferred);
};
// Setup the IOPipeRequest
AuIO::IOPipeRequestAIO aio;
aio.pAsyncTransaction = pTransaction;
aio.pListener = listener;
aio.bIsStream = false;
aio.output.type = AuIO::EPipeCallbackType::eTryHandleBufferedPart;
@ -222,19 +397,19 @@ TEST(IO, ReadFileThroughPipeProcessor2MBReadsEQ)
// Finally create the damn pipe
auto filePipe = pipeProcessor->NewAIOPipe(aio);
auto filePipe = pPipeProcessor->NewAIOPipe(aio);
ASSERT_TRUE(bool(filePipe));
ASSERT_TRUE(filePipe->Start());
// Main loop
while (ioDrivenQueue->HasItems())
while (pIODrivenQueue->HasItems())
{
// Since we aren't using an external loop queue, we manually pump the processor in here under this spinloop
// If we were using a loop queue, we wouldn't need to do anything at all. You could still technically
// use ioDrivenQueue->ToQueue()->WaitAny() to trigger the tick.
// use pIODrivenQueue->ToQueue()->WaitAny() to trigger the tick.
ioDrivenQueue->RunTick(); // also: TryTick and ManualTick
pIODrivenQueue->RunTick(); // also: TryTick and ManualTick
}
ASSERT_EQ(localCount, 10);
@ -242,9 +417,9 @@ TEST(IO, ReadFileThroughPipeProcessor2MBReadsEQ)
}
}
TEST(IO, ReadFileThroughPipeProcessorDefaultConfigEQ)
TEST(IO, ReadFileThroughpPipeProcessorDefaultConfigEQ)
{
// Write 20MB of RNG asynchronously
// Write 20MB of RNG using overlapped IO (we will block regardless bc its a test)
AuByteBuffer rngbuffer(512 * 1024 * 40, AuUInt(AuHwInfo::GetPageSize()));
{
auto stream = AuIOFS::OpenAsyncUnique("./AsyncFilePIPE", AuIOFS::EFileOpenMode::eReadWrite, true);
@ -252,41 +427,41 @@ TEST(IO, ReadFileThroughPipeProcessorDefaultConfigEQ)
AuRng::RngFillRange(rngbuffer);
auto transaction = stream->NewTransaction();
ASSERT_TRUE(bool(transaction));
auto pTransaction = stream->NewTransaction();
ASSERT_TRUE(bool(pTransaction));
transaction->SetCallback(AuMakeShared<AuIO::IAsyncFinishedSubscriberFunctional>([=](AuUInt64 offset, AuUInt32 length)
pTransaction->SetCallback(AuMakeShared<AuIO::IAsyncFinishedSubscriberFunctional>([=](AuUInt64 offset, AuUInt32 length)
{
AuLogDbg("AIO 1 callback: {} {}", offset, length);
}));
AuMemoryViewRead readView(rngbuffer);
ASSERT_TRUE(transaction->StartWrite(0, AuUnsafeRaiiToShared(&readView)));
ASSERT_TRUE(pTransaction->StartWrite(0, AuUnsafeRaiiToShared(&readView)));
AuLogDbg("AIO 1: waiting....");
ASSERT_TRUE(transaction->Wait(0));
ASSERT_TRUE(pTransaction->Wait(0));
AuLogDbg("AIO 1: wait complete....");
ASSERT_TRUE(transaction->NewLoopSource()->IsSignaled());
ASSERT_TRUE(transaction->Complete());
ASSERT_TRUE(pTransaction->NewLoopSource()->IsSignaled());
ASSERT_TRUE(pTransaction->Complete());
}
{
// Create the io processor
auto ioDrivenQueue = AuIO::NewIOProcessorNoQueue(false);
ASSERT_TRUE(bool(ioDrivenQueue));
auto pIODrivenQueue = AuIO::NewIOProcessorNoQueue(false);
ASSERT_TRUE(bool(pIODrivenQueue));
auto pipeProcessor = ioDrivenQueue->ToPipeProcessor();
ASSERT_TRUE(bool(pipeProcessor));
auto pPipeProcessor = pIODrivenQueue->ToPipeProcessor();
ASSERT_TRUE(bool(pPipeProcessor));
// Open the file and prepare an async transaction for the pipe processor to use
// Open the file and prepare an async pTransaction for the pipe processor to use
auto stream = AuIOFS::OpenAsyncUnique("./AsyncFilePIPE", AuIOFS::EFileOpenMode::eRead, true);
ASSERT_TRUE(bool(stream));
auto transaction = stream->NewTransaction();
ASSERT_TRUE(bool(transaction));
auto pTransaction = stream->NewTransaction();
ASSERT_TRUE(bool(pTransaction));
// Create an event listener for the callbacks
@ -311,7 +486,7 @@ TEST(IO, ReadFileThroughPipeProcessorDefaultConfigEQ)
// Setup the IOPipeRequest
AuIO::IOPipeRequestAIO aio;
aio.pAsyncTransaction = transaction;
aio.pAsyncTransaction = pTransaction;
aio.pListener = listener;
aio.bIsStream = false;
aio.output.type = AuIO::EPipeCallbackType::eTryHandleBufferedPart;
@ -332,23 +507,23 @@ TEST(IO, ReadFileThroughPipeProcessorDefaultConfigEQ)
// Finally create the damn pipe
auto filePipe = pipeProcessor->NewAIOPipe(aio);
auto filePipe = pPipeProcessor->NewAIOPipe(aio);
ASSERT_TRUE(bool(filePipe));
ASSERT_TRUE(filePipe->Start());
// Main loop
while (ioDrivenQueue->HasItems())
while (pIODrivenQueue->HasItems())
{
ioDrivenQueue->RunTick(); // also: TryTick and ManualTick
pIODrivenQueue->RunTick(); // also: TryTick and ManualTick
}
ASSERT_EQ(outBuffer, rngbuffer);
}
}
static void ReadFileThroughPipeProcessorCongested(int i)
static void ReadFileThroughpPipeProcessorCongested(int i)
{
// Write 20MB of RNG asynchronously
// Write 20MB of RNG using overlapped IO (we will block regardless bc its a test)
{
auto stream = AuIOFS::OpenAsyncUnique("./AsyncFilePIPE", AuIOFS::EFileOpenMode::eReadWrite, true);
ASSERT_TRUE(bool(stream));
@ -356,42 +531,42 @@ static void ReadFileThroughPipeProcessorCongested(int i)
AuByteBuffer rngbuffer(512 * 1024 * 40, AuUInt(AuHwInfo::GetPageSize()));
AuRng::RngFillRange(rngbuffer);
auto transaction = stream->NewTransaction();
ASSERT_TRUE(bool(transaction));
auto pTransaction = stream->NewTransaction();
ASSERT_TRUE(bool(pTransaction));
transaction->SetCallback(AuMakeShared<AuIO::IAsyncFinishedSubscriberFunctional>([=](AuUInt64 offset, AuUInt32 length)
pTransaction->SetCallback(AuMakeShared<AuIO::IAsyncFinishedSubscriberFunctional>([=](AuUInt64 offset, AuUInt32 length)
{
AuLogDbg("AIO 1 callback: {} {}", offset, length);
SysAssert(length == 512 * 1024 * 40);
}));
AuMemoryViewRead readView(rngbuffer);
ASSERT_TRUE(transaction->StartWrite(0, AuUnsafeRaiiToShared(&readView)));
ASSERT_TRUE(pTransaction->StartWrite(0, AuUnsafeRaiiToShared(&readView)));
AuLogDbg("AIO 1: waiting....");
ASSERT_TRUE(transaction->Wait(0));
ASSERT_TRUE(pTransaction->Wait(0));
AuLogDbg("AIO 1: wait complete....");
ASSERT_TRUE(transaction->NewLoopSource()->IsSignaled());
ASSERT_TRUE(transaction->Complete());
ASSERT_TRUE(pTransaction->NewLoopSource()->IsSignaled());
ASSERT_TRUE(pTransaction->Complete());
}
{
// Create the io processor
auto ioDrivenQueue = AuIO::NewIOProcessorNoQueue(false);
ASSERT_TRUE(bool(ioDrivenQueue));
auto pIODrivenQueue = AuIO::NewIOProcessorNoQueue(false);
ASSERT_TRUE(bool(pIODrivenQueue));
auto pipeProcessor = ioDrivenQueue->ToPipeProcessor();
ASSERT_TRUE(bool(pipeProcessor));
auto pPipeProcessor = pIODrivenQueue->ToPipeProcessor();
ASSERT_TRUE(bool(pPipeProcessor));
// Open the file and prepare an async transaction for the pipe processor to use
// Open the file and prepare an async pTransaction for the pipe processor to use
auto stream = AuIOFS::OpenAsyncUnique("./AsyncFilePIPE", AuIOFS::EFileOpenMode::eRead, true);
ASSERT_TRUE(bool(stream));
auto transaction = stream->NewTransaction();
ASSERT_TRUE(bool(transaction));
auto pTransaction = stream->NewTransaction();
ASSERT_TRUE(bool(pTransaction));
// Create an event listener for the callbacks
@ -416,7 +591,7 @@ static void ReadFileThroughPipeProcessorCongested(int i)
// Setup the IOPipeRequest
AuIO::IOPipeRequestAIO aio;
aio.pAsyncTransaction = transaction;
aio.pAsyncTransaction = pTransaction;
aio.pListener = listener;
aio.bIsStream = false;
aio.output.type = AuIO::EPipeCallbackType::eTryHandleBufferedPart;
@ -438,39 +613,39 @@ static void ReadFileThroughPipeProcessorCongested(int i)
// Finally create the damn pipe
auto filePipe = pipeProcessor->NewAIOPipe(aio);
auto filePipe = pPipeProcessor->NewAIOPipe(aio);
ASSERT_TRUE(bool(filePipe));
ASSERT_TRUE(filePipe->Start());
// Main loop
while (ioDrivenQueue->HasItems())
while (pIODrivenQueue->HasItems())
{
// Since we aren't using an external loop queue, we manually pump the processor in here under this spinloop
// If we were using a loop queue, we wouldn't need to do anything at all. You could still technically
// use ioDrivenQueue->ToQueue()->WaitAny() to trigger the tick.
// use pIODrivenQueue->ToQueue()->WaitAny() to trigger the tick.
ioDrivenQueue->RunTick(); // also: TryTick and ManualTick
pIODrivenQueue->RunTick(); // also: TryTick and ManualTick
}
SysAssert(localCount == ((512 * 1024 * 40) / aio.uPageLengthOrZero));
}
}
TEST(IO, ReadFileThroughPipeProcessorCongestedFourth)
TEST(IO, ReadFileThroughpPipeProcessorCongestedFourth)
{
ReadFileThroughPipeProcessorCongested(4);
ReadFileThroughpPipeProcessorCongested(4);
}
TEST(IO, ReadFileThroughPipeProcessorCongestedHalf)
TEST(IO, ReadFileThroughpPipeProcessorCongestedHalf)
{
ReadFileThroughPipeProcessorCongested(2);
ReadFileThroughpPipeProcessorCongested(2);
}
TEST(IO, ReadFileThroughPipeProcessorCongestedThird)
TEST(IO, ReadFileThroughpPipeProcessorCongestedThird)
{
ReadFileThroughPipeProcessorCongested(3);
ReadFileThroughpPipeProcessorCongested(3);
}

View File

@ -12,26 +12,28 @@ TEST(Map, FSNoLock)
{
int size = 4096 * 4;
AuByteBuffer rngbuffer(size);
ASSERT_TRUE(rngbuffer);
{
auto fsInit = AuIOFS::OpenShared("./FSMap", AuIOFS::EFileOpenMode::eWrite);
ASSERT_TRUE(bool(fsInit));
auto pFile = AuIOFS::OpenShared("./FSMap", AuIOFS::EFileOpenMode::eWrite);
ASSERT_TRUE(bool(pFile));
AuRng::RngFillRange(rngbuffer);
fsInit->Write(AuMemoryViewStreamRead(rngbuffer));
pFile->Write(AuMemoryViewStreamRead(rngbuffer));
pFile->Flush();
}
{
auto fsMap = AuIOFS::OpenShared("./FSMap", AuIOFS::EFileOpenMode::eReadWrite, AuFS::EFileAdvisoryLockLevel::eNoSafety);
ASSERT_TRUE(bool(fsMap));
auto shared = AuProcess::GetGlobalProcessSpace();
SysAssert(shared);
auto pStream = AuProcess::GetGlobalProcessSpace();
ASSERT_TRUE(bool(pStream));
auto obj = shared->MapFileByObject(fsMap, 0, size, AuIOFS::EFileOpenMode::eRead, AuFS::EFileAdvisoryLockLevel::eBlockWrite);
auto obj = pStream->MapFileByObject(fsMap, 0, size, AuIOFS::EFileOpenMode::eRead, AuFS::EFileAdvisoryLockLevel::eBlockWrite);
ASSERT_TRUE(bool(obj));
ASSERT_TRUE(memcmp(obj->GetBasePointer(), rngbuffer.base, size) == 0);
ASSERT_TRUE(AuMemcmp(obj->GetBasePointer(), rngbuffer.base, size) == 0);
}
}
@ -39,79 +41,80 @@ TEST(Map, FSNestedReadLock)
{
int size = 4096 * 4;
AuByteBuffer rngbuffer(size);
ASSERT_TRUE(rngbuffer);
{
auto fsInit = AuIOFS::OpenShared("./FSMap", AuIOFS::EFileOpenMode::eWrite);
ASSERT_TRUE(bool(fsInit));
auto pFile = AuIOFS::OpenShared("./FSMap", AuIOFS::EFileOpenMode::eWrite);
ASSERT_TRUE(bool(pFile));
AuRng::RngFillRange(rngbuffer);
fsInit->Write(AuMemoryViewStreamRead(rngbuffer));
pFile->Write(AuMemoryViewStreamRead(rngbuffer));
}
{
auto fsMap = AuIOFS::OpenShared("./FSMap", AuIOFS::EFileOpenMode::eReadWrite, AuFS::EFileAdvisoryLockLevel::eBlockWrite);
ASSERT_TRUE(bool(fsMap));
auto shared = AuProcess::GetGlobalProcessSpace();
SysAssert(shared);
auto pStream = AuProcess::GetGlobalProcessSpace();
ASSERT_TRUE(bool(pStream));
auto obj = shared->MapFileByObject(fsMap, 0, size, AuIOFS::EFileOpenMode::eRead, AuFS::EFileAdvisoryLockLevel::eBlockWrite);
auto obj = pStream->MapFileByObject(fsMap, 0, size, AuIOFS::EFileOpenMode::eRead, AuFS::EFileAdvisoryLockLevel::eBlockWrite);
ASSERT_TRUE(bool(obj));
ASSERT_TRUE(memcmp(obj->GetBasePointer(), rngbuffer.base, size) == 0);
ASSERT_TRUE(AuMemcmp(obj->GetBasePointer(), rngbuffer.base, size) == 0);
}
}
TEST(Map, FSNestedReadLock2)
{
int size = 4096 * 4;
AuByteBuffer rngbuffer(size);
ASSERT_TRUE(rngbuffer);
{
auto fsInit = AuIOFS::OpenShared("./FSMap", AuIOFS::EFileOpenMode::eWrite);
ASSERT_TRUE(bool(fsInit));
auto pFile = AuIOFS::OpenShared("./FSMap", AuIOFS::EFileOpenMode::eWrite);
ASSERT_TRUE(bool(pFile));
AuRng::RngFillRange(rngbuffer);
fsInit->Write(AuMemoryViewStreamRead(rngbuffer));
pFile->Write(AuMemoryViewStreamRead(rngbuffer));
}
{
auto fsMap = AuIOFS::OpenShared("./FSMap", AuIOFS::EFileOpenMode::eRead, AuFS::EFileAdvisoryLockLevel::eBlockWrite);
ASSERT_TRUE(bool(fsMap));
auto shared = AuProcess::GetGlobalProcessSpace();
SysAssert(shared);
auto pStream = AuProcess::GetGlobalProcessSpace();
ASSERT_TRUE(bool(pStream));
auto obj = shared->MapFileByObject(fsMap, 0, size, AuIOFS::EFileOpenMode::eRead, AuFS::EFileAdvisoryLockLevel::eBlockWrite);
auto obj = pStream->MapFileByObject(fsMap, 0, size, AuIOFS::EFileOpenMode::eRead, AuFS::EFileAdvisoryLockLevel::eBlockWrite);
ASSERT_TRUE(bool(obj));
ASSERT_TRUE(memcmp(obj->GetBasePointer(), rngbuffer.base, size) == 0);
ASSERT_TRUE(AuMemcmp(obj->GetBasePointer(), rngbuffer.base, size) == 0);
}
}
TEST(Map, FSNestedReadLockFail1)
{
int size = 4096 * 4;
AuByteBuffer rngbuffer(size);
ASSERT_TRUE(rngbuffer);
{
auto fsInit = AuIOFS::OpenShared("./FSMap", AuIOFS::EFileOpenMode::eWrite);
ASSERT_TRUE(bool(fsInit));
auto pFile = AuIOFS::OpenShared("./FSMap", AuIOFS::EFileOpenMode::eWrite);
ASSERT_TRUE(bool(pFile));
AuRng::RngFillRange(rngbuffer);
fsInit->Write(AuMemoryViewStreamRead(rngbuffer));
pFile->Write(AuMemoryViewStreamRead(rngbuffer));
}
{
auto fsMap = AuIOFS::OpenShared("./FSMap", AuIOFS::EFileOpenMode::eRead, AuFS::EFileAdvisoryLockLevel::eBlockWrite);
ASSERT_TRUE(bool(fsMap));
auto shared = AuProcess::GetGlobalProcessSpace();
SysAssert(shared);
auto pStream = AuProcess::GetGlobalProcessSpace();
ASSERT_TRUE(bool(pStream));
auto obj = shared->MapFileByObject(fsMap, 0, size, AuIOFS::EFileOpenMode::eWrite, AuFS::EFileAdvisoryLockLevel::eBlockWrite);
auto obj = pStream->MapFileByObject(fsMap, 0, size, AuIOFS::EFileOpenMode::eWrite, AuFS::EFileAdvisoryLockLevel::eBlockWrite);
ASSERT_TRUE(!bool(obj));
}
}
@ -127,23 +130,169 @@ TEST(Map, IPC)
auto handleString = memory->ExportToString();
ASSERT_TRUE(bool(handleString.size()));
AuLogDbg("Exported shared view handle: {}", handleString);
AuLogDbg("Exported pStream view handle: {}", handleString);
{
auto shared = AuProcess::GetGlobalProcessSpace();
SysAssert(shared);
auto pStream = AuProcess::GetGlobalProcessSpace();
ASSERT_TRUE(bool(pStream));
auto obj = shared->MapIPCMemory(handleString, 0, 4096, AuIOFS::EFileOpenMode::eWrite);
auto obj = pStream->MapIPCMemory(handleString, 0, 4096, AuIOFS::EFileOpenMode::eWrite);
ASSERT_TRUE(bool(obj));
AuLogDbg("Shared Memory String: {}", (char *)obj->GetBasePointer());
ASSERT_TRUE(memcmp(obj->GetBasePointer(), obj->GetBasePointer(), kHelloWorld.size() - 1) == 0);
ASSERT_TRUE(AuMemcmp(obj->GetBasePointer(), obj->GetBasePointer(), kHelloWorld.size() - 1) == 0);
}
}
TEST(Reserve, HasInterface)
{
ASSERT_TRUE(bool(AuProcess::ReserveAddressSpace(4096 * 2)));
}
TEST(Reserve, TestMap2SubSections)
{
int size = 4096 * 4;
AuByteBuffer rngbuffer(size);
ASSERT_TRUE(rngbuffer);
{
auto pFile = AuIOFS::OpenShared("./FSMap", AuIOFS::EFileOpenMode::eWrite);
ASSERT_TRUE(bool(pFile));
AuRng::RngFillRange(rngbuffer);
pFile->Write(AuMemoryViewStreamRead(rngbuffer));
}
{
auto fsMap = AuIOFS::OpenShared("./FSMap", AuIOFS::EFileOpenMode::eReadWrite, AuFS::EFileAdvisoryLockLevel::eBlockWrite);
ASSERT_TRUE(bool(fsMap));
auto pStream = AuProcess::ReserveAddressSpace(size * 2);
ASSERT_TRUE(bool(pStream));
auto obj = pStream->MapFileByObjectEx(0, fsMap, 0, size, AuIOFS::EFileOpenMode::eRead, AuFS::EFileAdvisoryLockLevel::eBlockWrite);
ASSERT_TRUE(bool(obj));
ASSERT_TRUE(AuMemcmp(obj->GetBasePointer(), rngbuffer.base, size) == 0);
auto obj2 = pStream->MapFileByObjectEx(size, fsMap, 0, size, AuIOFS::EFileOpenMode::eRead, AuFS::EFileAdvisoryLockLevel::eBlockWrite);
ASSERT_TRUE(bool(obj2));
ASSERT_TRUE(AuMemcmp(obj2->GetBasePointer(), rngbuffer.base, size) == 0);
ASSERT_EQ(obj2->GetBasePointer(), obj->GetPointer(size));
}
}
TEST(Reserve, TestReMap2SubSections)
{
int size = 4096 * 4;
AuByteBuffer rngbuffer(size);
AuByteBuffer rngbuffer2(size);
ASSERT_TRUE(rngbuffer);
ASSERT_TRUE(rngbuffer2);
{
auto pFile = AuIOFS::OpenShared("./FSMap", AuIOFS::EFileOpenMode::eWrite);
ASSERT_TRUE(bool(pFile));
AuRng::RngFillRange(rngbuffer);
pFile->Write(AuMemoryViewStreamRead(rngbuffer));
}
{
auto pFile = AuIOFS::OpenShared("./FSMap2", AuIOFS::EFileOpenMode::eWrite);
ASSERT_TRUE(bool(pFile));
AuRng::RngFillRange(rngbuffer2);
pFile->Write(AuMemoryViewStreamRead(rngbuffer2));
}
{
auto fsMap = AuIOFS::OpenShared("./FSMap", AuIOFS::EFileOpenMode::eReadWrite, AuFS::EFileAdvisoryLockLevel::eBlockWrite);
ASSERT_TRUE(bool(fsMap));
auto fsMap2 = AuIOFS::OpenShared("./FSMap2", AuIOFS::EFileOpenMode::eReadWrite, AuFS::EFileAdvisoryLockLevel::eBlockWrite);
ASSERT_TRUE(bool(fsMap2));
auto pStream = AuProcess::ReserveAddressSpace(size * 2);
ASSERT_TRUE(bool(pStream));
auto obj = pStream->MapFileByObjectEx(0, fsMap, 0, size, AuIOFS::EFileOpenMode::eRead, AuFS::EFileAdvisoryLockLevel::eBlockWrite);
ASSERT_TRUE(bool(obj));
ASSERT_TRUE(AuMemcmp(obj->GetBasePointer(), rngbuffer.base, size) == 0);
auto obj2 = pStream->MapFileByObjectEx(size, fsMap, 0, size, AuIOFS::EFileOpenMode::eRead, AuFS::EFileAdvisoryLockLevel::eBlockWrite);
ASSERT_TRUE(bool(obj2));
ASSERT_TRUE(AuMemcmp(obj2->GetBasePointer(), rngbuffer.base, size) == 0);
ASSERT_EQ(obj2->GetBasePointer(), obj->GetPointer(size));
obj->Unmap();
auto obj3 = pStream->MapFileByObjectEx(0, fsMap2, 0, size, AuIOFS::EFileOpenMode::eRead, AuFS::EFileAdvisoryLockLevel::eBlockWrite);
ASSERT_TRUE(bool(obj3));
ASSERT_TRUE(AuMemcmp(obj3->GetBasePointer(), rngbuffer2.base, size) == 0);
}
}
TEST(Reserve, TestReMap2SubSections_Fail)
{
int size = 4096 * 4;
AuByteBuffer rngbuffer(size);
AuByteBuffer rngbuffer2(size);
ASSERT_TRUE(rngbuffer);
ASSERT_TRUE(rngbuffer2);
{
auto pFile = AuIOFS::OpenShared("./FSMap", AuIOFS::EFileOpenMode::eWrite);
ASSERT_TRUE(bool(pFile));
AuRng::RngFillRange(rngbuffer);
pFile->Write(AuMemoryViewStreamRead(rngbuffer));
}
{
auto pFile = AuIOFS::OpenShared("./FSMap2", AuIOFS::EFileOpenMode::eWrite);
ASSERT_TRUE(bool(pFile));
AuRng::RngFillRange(rngbuffer2);
pFile->Write(AuMemoryViewStreamRead(rngbuffer2));
}
{
auto fsMap = AuIOFS::OpenShared("./FSMap", AuIOFS::EFileOpenMode::eReadWrite, AuFS::EFileAdvisoryLockLevel::eBlockWrite);
ASSERT_TRUE(bool(fsMap));
auto fsMap2 = AuIOFS::OpenShared("./FSMap2", AuIOFS::EFileOpenMode::eReadWrite, AuFS::EFileAdvisoryLockLevel::eBlockWrite);
ASSERT_TRUE(bool(fsMap));
auto pStream = AuProcess::ReserveAddressSpace(size * 2);
ASSERT_TRUE(bool(pStream));
auto obj = pStream->MapFileByObjectEx(0, fsMap, 0, size, AuIOFS::EFileOpenMode::eRead, AuFS::EFileAdvisoryLockLevel::eBlockWrite);
ASSERT_TRUE(bool(obj));
ASSERT_TRUE(AuMemcmp(obj->GetBasePointer(), rngbuffer.base, size) == 0);
auto obj2 = pStream->MapFileByObjectEx(size, fsMap, 0, size, AuIOFS::EFileOpenMode::eRead, AuFS::EFileAdvisoryLockLevel::eBlockWrite);
ASSERT_TRUE(bool(obj2));
ASSERT_TRUE(AuMemcmp(obj2->GetBasePointer(), rngbuffer.base, size) == 0);
ASSERT_EQ(obj2->GetBasePointer(), obj->GetPointer(size));
auto obj3 = pStream->MapFileByObjectEx(0, fsMap2, 0, size, AuIOFS::EFileOpenMode::eRead, AuFS::EFileAdvisoryLockLevel::eBlockWrite);
ASSERT_FALSE(bool(obj3));
}
}
void RunTests()
{
Aurora::RuntimeStartInfo info;

View File

@ -0,0 +1,193 @@
/***
Copyright (C) 2022 J Reece Wilson (a/k/a "Reece"). All rights reserved.
File: Main.cpp
Date: 2022-2-18
Author: Reece
***/
#include <AuroraRuntime.hpp>
#include <Aurora/Crypto/HashCash/HashCash.hpp>
#include <Aurora/Crypto/BCrypt/BCrypt.hpp>
#include <gtest/gtest.h>
#include <Aurora/IO/IOExperimental.hpp>
#include <Aurora/IO/Protocol/Protocol.hpp>
static const unsigned char compressMe[779]
{
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0x72, 0x65, 0x73, 0x65, 0x72, 0x76, 0x65, 0x64, 0x2E, 0x0D, 0x0A, 0x0D,
0x0A, 0x20, 0x20, 0x20, 0x20, 0x46, 0x69, 0x6C, 0x65, 0x3A, 0x20, 0x4F,
0x70, 0x65, 0x6E, 0x2E, 0x55, 0x6E, 0x69, 0x78, 0x2E, 0x63, 0x70, 0x70,
0x0D, 0x0A, 0x20, 0x20, 0x20, 0x20, 0x44, 0x61, 0x74, 0x65, 0x3A, 0x20,
0x32, 0x30, 0x32, 0x31, 0x2D, 0x36, 0x2D, 0x31, 0x32, 0x0D, 0x0A, 0x20,
0x20, 0x20, 0x20, 0x41, 0x75, 0x74, 0x68, 0x6F, 0x72, 0x3A, 0x20, 0x52,
0x65, 0x65, 0x63, 0x65, 0x0D, 0x0A, 0x2A, 0x2A, 0x2A, 0x2F, 0x0D, 0x0A,
0x23, 0x70, 0x72, 0x61, 0x67, 0x6D, 0x61, 0x20, 0x6F, 0x6E, 0x63, 0x65,
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0x0A, 0x20, 0x20, 0x20, 0x20, 0x41, 0x55, 0x4B, 0x4E, 0x5F, 0x53, 0x59,
0x4D, 0x20, 0x76, 0x6F, 0x69, 0x64, 0x20, 0x4F, 0x70, 0x65, 0x6E, 0x55,
0x72, 0x69, 0x28, 0x63, 0x6F, 0x6E, 0x73, 0x74, 0x20, 0x41, 0x75, 0x53,
0x74, 0x72, 0x69, 0x6E, 0x67, 0x20, 0x26, 0x75, 0x72, 0x69, 0x29, 0x0D,
0x0A, 0x20, 0x20, 0x20, 0x20, 0x7B, 0x0D, 0x0A, 0x20, 0x20, 0x20, 0x20,
0x20, 0x20, 0x20, 0x20, 0x55, 0x6E, 0x69, 0x78, 0x4F, 0x70, 0x65, 0x6E,
0x41, 0x73, 0x79, 0x6E, 0x63, 0x28, 0x75, 0x72, 0x69, 0x29, 0x3B, 0x0D,
0x0A, 0x20, 0x20, 0x20, 0x20, 0x7D, 0x0D, 0x0A, 0x0D, 0x0A, 0x20, 0x20,
0x20, 0x20, 0x41, 0x55, 0x4B, 0x4E, 0x5F, 0x53, 0x59, 0x4D, 0x20, 0x76,
0x6F, 0x69, 0x64, 0x20, 0x4F, 0x70, 0x65, 0x6E, 0x46, 0x69, 0x6C, 0x65,
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0x69, 0x6E, 0x67, 0x20, 0x26, 0x66, 0x69, 0x6C, 0x65, 0x29, 0x0D, 0x0A,
0x20, 0x20, 0x20, 0x20, 0x7B, 0x0D, 0x0A, 0x20, 0x20, 0x20, 0x20, 0x20,
0x20, 0x20, 0x20, 0x55, 0x6E, 0x69, 0x78, 0x4F, 0x70, 0x65, 0x6E, 0x41,
0x73, 0x79, 0x6E, 0x63, 0x28, 0x49, 0x4F, 0x3A, 0x3A, 0x46, 0x53, 0x3A,
0x3A, 0x4E, 0x6F, 0x72, 0x6D, 0x61, 0x6C, 0x69, 0x7A, 0x65, 0x50, 0x61,
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0x3B, 0x0D, 0x0A, 0x20, 0x20, 0x20, 0x20, 0x7D, 0x0D, 0x0A, 0x7D
};
static AuByteBuffer GetCompressableBlob()
{
AuByteBuffer compressMeBytes;
for (int i = 0; i < 100000; i++)
{
compressMeBytes.Write(compressMe, AuArraySize(compressMe));
}
return compressMeBytes;
}
TEST(DecompressAllInSingleTick, deflate)
{
auto compressMeBytes = GetCompressableBlob();
// Legacy API
AuIO::Buffered::BlobWriter compressed;
{
AuIO::Buffered::BlobReader reader(AuMove(compressMeBytes));
AuCompression::CompressionPipe pipe;
AuCompression::CompressInfo info (AuCompression::ECompressionType::eDeflate);
pipe.pReadPipe = AuUnsafeRaiiToShared(&reader);
pipe.pWritePipe = AuUnsafeRaiiToShared(&compressed);
ASSERT_TRUE(AuCompression::Compress(pipe, info));
}
// compress over. ignore me
auto pProtoStack = AuIO::Protocol::NewBufferedProtocolStack(compressed.GetBuffer()->size());
ASSERT_TRUE(pProtoStack);
// Ingest via AsStreamWriter/AsWritableByteBuffer, read-back through AsReadableByteBuffer or AsStreamReader later
ASSERT_EQ(pProtoStack->AsStreamWriter()->Write(AuMemoryViewRead(*compressed.GetBuffer())), AuIO::EStreamError::eErrorNone);
// Setup an interceptor (an interface of data in, data out given nonlinear memory views)
AuCompression::DecompressInfo info(AuCompression::ECompressionType::eDeflate);
info.uInternalStreamSize = 100 * 1024 * 1024;
auto pCompressionInterceptor = AuCompression::NewDecompressionInterceptor(info);
ASSERT_TRUE(pProtoStack->AppendInterceptorEx(pCompressionInterceptor, info.uInternalStreamSize));
// Do (all) work
pProtoStack->DoTick();
// Read
auto pRawBuffer = pProtoStack->AsReadableByteBuffer();
AuLogDbg("{}::{}", (void *)compressMeBytes.base, compressMeBytes.RemainingBytes());
AuLogDbg("{}::{}", (void *)pRawBuffer->base, pRawBuffer->RemainingBytes());
ASSERT_EQ(compressMeBytes.RemainingBytes(), pRawBuffer->RemainingBytes());
}
TEST(DecompressAllInSingleTick, zstd)
{
auto compressMeBytes = GetCompressableBlob();
// Legacy API
AuIO::Buffered::BlobWriter compressed;
{
AuIO::Buffered::BlobReader reader(AuMove(compressMeBytes));
AuCompression::CompressionPipe pipe;
AuCompression::CompressInfo info(AuCompression::ECompressionType::eZSTD);
pipe.pReadPipe = AuUnsafeRaiiToShared(&reader);
pipe.pWritePipe = AuUnsafeRaiiToShared(&compressed);
ASSERT_TRUE(AuCompression::Compress(pipe, info));
}
// compress over. ignore me
auto pProtoStack = AuIO::Protocol::NewBufferedProtocolStack(compressed.GetBuffer()->size());
ASSERT_TRUE(pProtoStack);
// Ingest via AsStreamWriter/AsWritableByteBuffer, read-back through AsReadableByteBuffer or AsStreamReader later
ASSERT_EQ(pProtoStack->AsStreamWriter()->Write(AuMemoryViewRead(*compressed.GetBuffer())), AuIO::EStreamError::eErrorNone);
// Setup an interceptor (an interface of data in, data out given nonlinear memory views)
AuCompression::DecompressInfo info(AuCompression::ECompressionType::eZSTD);
info.uInternalStreamSize = 100 * 1024 * 1024;
auto pCompressionInterceptor = AuCompression::NewDecompressionInterceptor(info);
ASSERT_TRUE(pProtoStack->AppendInterceptorEx(pCompressionInterceptor, info.uInternalStreamSize));
// Do (all) work
pProtoStack->DoTick();
// Read
auto pRawBuffer = pProtoStack->AsReadableByteBuffer();
AuLogDbg("{}::{}", (void *)compressMeBytes.base, compressMeBytes.RemainingBytes());
AuLogDbg("{}::{}", (void *)pRawBuffer->base, pRawBuffer->RemainingBytes());
ASSERT_EQ(compressMeBytes.RemainingBytes(), pRawBuffer->RemainingBytes());
}
TEST(ProcessAllFramesInStreamBuffer, StreamProtos)
{
// TODO: ...
// (AppendSingleFrameProcessor)
}
void RunTests()
{
Aurora::RuntimeStartInfo info;
info.console.fio.enableLogging = false;
Aurora::RuntimeStart(info);
}

View File

@ -89,6 +89,51 @@ static AuByteBuffer GetCompressableBlob()
return compressMeBytes;
}
TEST(Demo, One)
{
auto compressMeBytes = GetCompressableBlob();
AuIO::Buffered::BlobReader reader(AuUnsafeRaiiToShared(&compressMeBytes));
AuCompression::CompressInfo compressStream { AuCompression::ECompressionType::eZSTD };
compressStream.uInternalStreamSize = compressMeBytes.size();
compressStream.uCompressionLevel = 7;
// Create a compressor given a shared IStreamReader and CompressInfo
auto pCompressor = AuCompression::CompressorShared(AuUnsafeRaiiToShared(&reader), compressStream);
ASSERT_TRUE(bool(pCompressor));
// Consume exactly `compressMeBytes.RemainingBytes()` from the reader
// (optionally: use ReadEx to ad-hoc read from the underlying stream)
auto uToConsume = compressMeBytes.RemainingBytes();
auto readWrittenBytes = pCompressor->Ingest(uToConsume);
ASSERT_EQ(readWrittenBytes.first, uToConsume);
// Compression requires a finalize or a flush before read
ASSERT_TRUE(pCompressor->Finish());
// Assert deflated blob > inflated blob
ASSERT_LE(pCompressor->GetAvailableProcessedBytes(), readWrittenBytes.first);
// Take from the underlying buffer
AuByteBuffer deflatedCopy(pCompressor->GetAvailableProcessedBytes());
auto uBytesCopied = pCompressor->Read(AuMemoryViewWrite(deflatedCopy.writePtr, deflatedCopy.length));
ASSERT_TRUE(uBytesCopied);
deflatedCopy.writePtr += uBytesCopied;
ASSERT_TRUE(AuFS::WriteFile("Test File.zstd", deflatedCopy));
}
TEST(Demo, One2)
{
auto compressMeBytes = GetCompressableBlob();
AuIO::Buffered::BlobReader reader(AuUnsafeRaiiToShared(&compressMeBytes));
AuByteBuffer expandableBuffer;
ASSERT_TRUE(AuCompression::Compress(compressMeBytes, expandableBuffer, 14));
ASSERT_TRUE(AuFS::WriteFile("Test File 2.zstd", expandableBuffer));
}
static void TestBasicCompression(AuCompression::ECompressionType type)
{
auto compressMeBytes = GetCompressableBlob();
@ -98,13 +143,13 @@ static void TestBasicCompression(AuCompression::ECompressionType type)
{
AuIO::Buffered::BlobReader reader(AuMove(compressMeBytes));
AuCompression::CompressionPipe pipe;
AuCompression::CompressionInfo info;
AuCompression::CompressInfo info;
info.type = type;
pipe.pReadPipe = AuUnsafeRaiiToShared(&reader);
pipe.pWritePipe = AuUnsafeRaiiToShared(&compressed);
info.compressionLevel = 4;
info.uCompressionLevel = 4;
ASSERT_TRUE(AuCompression::Compress(pipe, info));
}
compressed.GetBuffer()->ResetReadPointer();
@ -132,17 +177,17 @@ static void TestBasicCompression(AuCompression::ECompressionType type)
auto decompressLength = decompressed.GetBuffer()->size();
AuCompression::DecompressInfo decompressStream {type};
decompressStream.internalStreamSize = decompressLength;
decompressStream.uInternalStreamSize = decompressLength + 1;
AuIO::Buffered::BlobReader reader(compressed.GetBuffer());
auto decompressor = AuCompression::DecompressorShared(AuUnsafeRaiiToShared(&reader), decompressStream);
auto readWrittenBytes = decompressor->Ingest(decompressLength);
//ASSERT_EQ(readWrittenBytes, AuMakePair(AuUInt32(compressed.GetBuffer()->size()), AuUInt32(decompressLength)));
//ASSERT_LE(readWrittenBytes.first, readWrittenBytes.second);
auto readWrittenBytes = decompressor->Ingest(compressed.GetBuffer()->RemainingBytes());
AuByteBuffer inflated(decompressLength);
ASSERT_TRUE(decompressor->Read(AuMemoryViewWrite(inflated.data(), inflated.size())));
AuByteBuffer inflated(decompressor->GetAvailableProcessedBytes());
auto uWritten = decompressor->Read(AuMemoryViewWrite(inflated.data(), inflated.size()));
ASSERT_TRUE(uWritten);
inflated.writePtr += uWritten;
ASSERT_EQ(inflated, *decompressed.GetBuffer());
}
@ -156,9 +201,9 @@ static void TestBasicCompression(AuCompression::ECompressionType type)
{
auto decompressLength = decompressed.GetBuffer()->size();
AuCompression::CompressionInfo compressStream{ type };
compressStream.internalStreamSize = decompressLength * 10;
compressStream.compressionLevel = 4;
AuCompression::CompressInfo compressStream{ type };
compressStream.uInternalStreamSize = decompressLength * 10;
compressStream.uCompressionLevel = 4;
AuIO::Buffered::BlobReader reader(decompressed.GetBuffer());
auto compressor = AuCompression::CompressorShared(AuUnsafeRaiiToShared(&reader), compressStream);
@ -167,12 +212,11 @@ static void TestBasicCompression(AuCompression::ECompressionType type)
compressor->Finish();
readWrittenBytes = { 0, compressor->GetAvailableProcessedBytes() };
//ASSERT_GE(readWrittenBytes.first, readWrittenBytes.second);
//AuLogDbg("{} {}, {}", readWrittenBytes.first, readWrittenBytes.second, compressor->GetAvailableProcessedBytes());
deflated2 = AuByteBuffer(compressor->GetAvailableProcessedBytes());
ASSERT_TRUE(compressor->Read(AuMemoryViewWrite(deflated2.data(), deflated2.size())));
deflated2.writePtr += deflated2.length;
deflated2 = AuByteBuffer(readWrittenBytes.second);
auto uRead = compressor->Read(AuMemoryViewWrite(deflated2.writePtr, readWrittenBytes.second));
ASSERT_EQ(uRead, readWrittenBytes.second);
deflated2.writePtr += uRead;
}
deflated2.ResetReadPointer();
@ -181,18 +225,18 @@ static void TestBasicCompression(AuCompression::ECompressionType type)
auto decompressLength = decompressed.GetBuffer()->size();
AuCompression::DecompressInfo decompressStream{ type };
decompressStream.internalStreamSize = decompressLength;
decompressStream.uInternalStreamSize = decompressLength + 1;
deflated2.readPtr = deflated2.base;
AuIO::Buffered::BlobReader reader(deflated2);
auto decompressor = AuCompression::DecompressorShared(AuUnsafeRaiiToShared(&reader), decompressStream);
auto readWrittenBytes = decompressor->Ingest(deflated2.size());
//AuLogDbg("2> {} {}, {} {} {}", readWrittenBytes.first, readWrittenBytes.second, decompressor->GetAvailableProcessedBytes(), AuUInt32(deflated2.size()), AuUInt32(decompressLength));
//ASSERT_EQ(readWrittenBytes, AuMakePair(AuUInt32(deflated2.size()), AuUInt32(decompressLength)));
auto readWrittenBytes = decompressor->Ingest(deflated2.RemainingBytes());
AuByteBuffer inflated(decompressLength);
ASSERT_TRUE(decompressor->Read(AuMemoryViewWrite(inflated.data(), inflated.size())));
auto bytes = decompressor->GetAvailableProcessedBytes();
AuByteBuffer inflated(bytes);
auto uRead = decompressor->Read(AuMemoryViewWrite(inflated.writePtr, bytes));
inflated.writePtr += uRead;
decompressed.GetBuffer()->ResetReadPointer();
ASSERT_EQ(inflated, *decompressed.GetBuffer());

View File

@ -127,7 +127,24 @@ TEST(Net, TLSGoogle)
#define ENABLE_TLS
#if defined(ENABLE_TLS)
Aurora::IO::TLS::TLSMeta tlsMeta;
//tlsMeta.sSNIServerName = "google.com";
tlsMeta.bIsClient = true;
tlsMeta.client.sSNIServerName = "google.com";
tlsMeta.pCertPin = AuMakeSharedThrow<AuIO::TLS::IPinCertificateFunctional>([]
(const AuSPtr<AuIO::TLS::ICertificateChain> &pChain,
const AuMemoryViewRead &derCertificate) -> bool
{
AuLogDbg("Incoming handshake...");
for (AuUInt32 i = 0; i < pChain->GetCertificateCount(); i++)
{
auto details = pChain->GetCertificateDetails(i);
auto cert = pChain->GetCertificate(i);
AuLogDbg("{}: {} (from {})", i, details.subject.commonName, details.issuer.commonName);
}
return true;
});
auto pContext = Aurora::IO::TLS::NewTLSContextEx(socket->ToChannel()->NewProtocolSendStack(),
socket->ToChannel()->NewProtocolRecvStack(),
tlsMeta);

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@ -0,0 +1,131 @@
/***
Copyright (C) 2022 J Reece Wilson (a/k/a "Reece"). All rights reserved.
File: Main.cpp
Date: 2022-2-18
Author: Reece
***/
#include <AuroraRuntime.hpp>
#include <Aurora/IO/IOExperimental.hpp>
#include <Aurora/IO/Net/NetExperimental.hpp>
#include <gtest/gtest.h>
TEST(Net, ServerDemo)
{
auto app = AuAsync::GetAsyncApp();
auto pIoProcessor1 = AuIO::NewIOProcessorOnThread(false, { AuAsync::GetSharedAsyncApp(), 0, 1 });
ASSERT_TRUE(bool(pIoProcessor1));
auto pIoProcessor2 = AuIO::NewIOProcessorOnThread(false, { AuAsync::GetSharedAsyncApp(), 0, 2 });
ASSERT_TRUE(bool(pIoProcessor2));
auto pNetProcessor = AuNet::NewNetworkInterface();
ASSERT_TRUE(bool(pNetProcessor));
auto pNetWorker = pNetProcessor->GetWorkersService()->Attach(pIoProcessor1);
ASSERT_TRUE(bool(pNetWorker));
auto pNetWorker2 = pNetProcessor->GetWorkersService()->Attach(pIoProcessor2);
ASSERT_TRUE(bool(pNetWorker2));
auto pSocketFactory = AuMakeShared<AuNet::ISocketDriverFactoryFunctional>();
ASSERT_TRUE(bool(pSocketFactory));
pSocketFactory->NewSocketDriverFunctional = []() -> AuSPtr<AuNet::ISocketDriver>
{
struct TempDriver : AuNet::ISocketDriverFunctional
{
AuSPtr<AuNet::ISocket> pDriverSocket;
};
auto pRealDriver = AuMakeSharedPanic<TempDriver>();
pRealDriver->OnPreestablishFunctional = [=](const AuSPtr<AuNet::ISocket> &socket) -> bool
{
pRealDriver->pDriverSocket = socket;
return true;
};
pRealDriver->OnEstablishFunctional = [=]()
{
AuLogDbg("New session on thread: {}", AuThreads::GetThreadId());
auto pChannel = pRealDriver->pDriverSocket->ToChannel();
pChannel->AsStreamWriter()->Write(AuMemoryViewRead("Hello World", 11));
};
pRealDriver->OnFatalErrorReportedFunctional = [=](const AuNet::NetError &error)
{
AuLogDbg("[2] On error: {}", NetErrorToExtendedString(error));
};
pRealDriver->OnStreamUpdatedFunctional = [=]()
{
auto pChannel = pRealDriver->pDriverSocket->ToChannel();
auto pReader = pChannel->AsReadableByteBuffer();
AuString message;
message.resize(pReader->RemainingBytes());
pReader->Read(message.data(), message.size());
AuLogDbg("[2] Got: {}", message);
};
pRealDriver->OnFinalizeFunctional = [=]()
{
AuResetMember(*pRealDriver.get()); // reset circular dependence on captured pRealDriver
AuLogDbg("[2] Finalize");
};
return pRealDriver;
};
auto pServerDriver = AuMakeShared<AuNet::ISocketServerDriverFunctional>();
ASSERT_TRUE(bool(pServerDriver));
pServerDriver->OnBindFunctional = [&]()
{
AuLogDbg("[1] On bind");
};
pServerDriver->OnFatalErrorReportedFunctional = [&](const AuNet::NetError &error)
{
AuLogDbg("[1] On error: {}", NetErrorToExtendedString(error));
};
pServerDriver->OnFinalizeFunctional = [&]()
{
AuLogDbg("[1] On finalize");
};
AuNet::NetSocketBind nsSocketBind;
nsSocketBind.pDriver = pServerDriver;
nsSocketBind.ip = AuNet::IPAddress("127.0.0.1");
nsSocketBind.protocol = AuNet::ETransportProtocol::eProtocolTCP;
nsSocketBind.uPort = 8087;
nsSocketBind.pFactory = pSocketFactory;
nsSocketBind.bMultiThreaded = true;
auto pSocket = pNetProcessor->GetSocketService()->NewServer(nsSocketBind);
ASSERT_TRUE(bool(pSocket));
app->Main();
}
void RunTests()
{
Aurora::RuntimeStartInfo info;
info.async.enableSchedularThread = true;
info.async.schedularFrequency = 2;
info.async.sysPumpFrequency = 2;
info.async.enableSysPumpFreqnecy = true;
info.console.fio.enableLogging = false;
info.console.asyncVSLog = false;
Aurora::RuntimeStart(info);
auto app = AuAsync::GetAsyncApp();
app->Create({ 0, 0 });
app->Spawn({ 0, 1 });
app->Spawn({ 0, 2 });
}

View File

@ -63,7 +63,7 @@ TEST(Net, ServerDemo)
pRealDriver->OnFinalizeFunctional = [=]()
{
pRealDriver->~TempDriver(); // reset circular dependence on captured pRealDriver
AuResetMember(*pRealDriver.get()); // reset circular dependence on captured pRealDriver
AuLogDbg("[2] Finalize");
};

View File

@ -0,0 +1,113 @@
/***
Copyright (C) 2022 J Reece Wilson (a/k/a "Reece"). All rights reserved.
File: Main.cpp
Date: 2022-2-18
Author: Reece
***/
#include <AuroraRuntime.hpp>
#include <Aurora/IO/IOExperimental.hpp>
#include <Aurora/IO/Net/NetExperimental.hpp>
#include <gtest/gtest.h>
TEST(Net, ServerDemo)
{
auto pIoProcessor = AuIO::NewIOProcessorNoQueue(false);
ASSERT_TRUE(bool(pIoProcessor));
auto pNetProcessor = AuNet::NewNetworkInterface();
ASSERT_TRUE(bool(pNetProcessor));
auto pNetWorker = pNetProcessor->GetWorkersService()->Attach(pIoProcessor);
ASSERT_TRUE(bool(pNetWorker));
auto pSocketFactory = AuMakeShared<AuNet::ISocketDriverFactoryFunctional>();
ASSERT_TRUE(bool(pSocketFactory));
pSocketFactory->NewSocketDriverFunctional = []() -> AuSPtr<AuNet::ISocketDriver>
{
struct TempDriver : AuNet::ISocketDriverFunctional
{
AuSPtr<AuNet::ISocket> pDriverSocket;
};
auto pRealDriver = AuMakeShared<TempDriver>();
pRealDriver->OnPreestablishFunctional = [=](const AuSPtr<AuNet::ISocket> &socket) -> bool
{
pRealDriver->pDriverSocket = socket;
return true;
};
pRealDriver->OnEstablishFunctional = [=]()
{
auto pChannel = pRealDriver->pDriverSocket->ToChannel();
AuLogDbg("[2] New channel created");
pChannel->AsStreamWriter()->Write(AuMemoryViewRead("Hello World", 11));
};
pRealDriver->OnFatalErrorReportedFunctional = [=](const AuNet::NetError &error)
{
AuLogDbg("[2] On error: {}", NetErrorToExtendedString(error));
};
pRealDriver->OnStreamUpdatedFunctional = [=]()
{
auto pChannel = pRealDriver->pDriverSocket->ToChannel();
auto pReader = pChannel->AsReadableByteBuffer();
AuString message;
message.resize(pReader->RemainingBytes());
pReader->Read(message.data(), message.size());
AuLogDbg("[2] Got: {}", message);
};
pRealDriver->OnFinalizeFunctional = [=]()
{
AuResetMember(*pRealDriver.get()); // reset circular dependence on captured pRealDriver
AuLogDbg("[2] Finalize");
};
return pRealDriver;
};
auto pServerDriver = AuMakeShared<AuNet::ISocketServerDriverFunctional>();
ASSERT_TRUE(bool(pServerDriver));
pServerDriver->OnBindFunctional = [&]()
{
AuLogDbg("[1] On bind");
};
pServerDriver->OnFatalErrorReportedFunctional = [&](const AuNet::NetError &error)
{
AuLogDbg("[1] On error: {}", NetErrorToExtendedString(error));
};
pServerDriver->OnFinalizeFunctional = [&]()
{
AuLogDbg("[1] On finalize");
};
AuNet::NetSocketBind nsSocketBind;
nsSocketBind.pDriver = pServerDriver;
nsSocketBind.ip = AuNet::IPAddress("127.0.0.1");
nsSocketBind.protocol = AuNet::ETransportProtocol::eProtocolUDP;
nsSocketBind.uPort = 8087;
nsSocketBind.pFactory = pSocketFactory;
auto pSocket = pNetProcessor->GetSocketService()->NewServer(nsSocketBind);
ASSERT_TRUE(bool(pSocket));
while (pIoProcessor->HasItems())
{
pIoProcessor->RunTick();
}
}
void RunTests()
{
Aurora::RuntimeStartInfo info;
info.console.fio.enableLogging = false;
Aurora::RuntimeStart(info);
}

View File

@ -24,15 +24,34 @@ TEST(UDP, DatagramServer)
auto pDriver = AuMakeShared<AuNet::IDatagramDriverFunctional>();
ASSERT_TRUE(bool(pDriver));
AuSPtr<AuNet::IDatagramServer> pSocket;
pDriver->OnBindFunctional = []()
{
AuLogDbg("[UDP] On bind");
};
pDriver->OnPacketFunctional = [](const AuNet::NetEndpoint &client,
const AuSPtr<AuByteBuffer> &pPacket)
pDriver->OnPacketFunctional = [&](const AuNet::NetEndpoint &client,
const AuSPtr<AuByteBuffer> &pInboundPacket)
{
AuLogDbg("[UDP] On packet");
struct Packet : AuMemoryViewRead
{
AuByteBuffer buffer;
};
auto pPacket = AuMakeSharedPanic<Packet>();
pPacket->buffer.Write<AuUInt32>(0xAAAABBBB);
pPacket->buffer.Write<AuUInt32>(0x13371337);
pPacket->buffer.Write("Hello World");
pPacket->buffer.Write<AuUInt32>(0xAAAABBBB);
pPacket->buffer.Write<AuUInt32>(0x13371337);
pPacket->buffer.WriteFrom(*pInboundPacket);
pPacket->ptr = pPacket->buffer.readPtr;
pPacket->length = pPacket->buffer.RemainingBytes();
SysAssert(!pPacket->buffer.flagWriteError);
pSocket->SendPacket(client, pPacket, {});
};
pDriver->OnErrorFunctional = [](const AuNet::NetError &error)
@ -56,7 +75,7 @@ TEST(UDP, DatagramServer)
nsDatagramBind.uPort = 8087;
nsDatagramBind.pDriver = pDriver;
auto pSocket = pNetProcessor->GetDatagramService()->NewDatagramServer(nsDatagramBind);
pSocket = pNetProcessor->GetDatagramService()->NewDatagramServer(nsDatagramBind);
ASSERT_TRUE(bool(pSocket));
while (pIoProcessor->HasItems())

@ -1 +1 @@
Subproject commit 7274ec186442c96e4c7dcc99c684a03e5db2ff48
Subproject commit 9c332145b71c36a5bad9688312c79184f98601ff

2
Vendor/mbedtls vendored

@ -1 +1 @@
Subproject commit 13784a572a40e5f5e756ab325b67655348fd67a8
Subproject commit 742439e92315ab4185a78a8de6c5a0795ed336d9

2
Vendor/nlohmannjson vendored

@ -1 +1 @@
Subproject commit 09fb4819ff4b35a6ba5d391f87e4e44f25ad6789
Subproject commit a3e6e26dc83a726b292f5be0492fcc408663ce55

2
Vendor/o1heap vendored

@ -1 +1 @@
Subproject commit b026aef3b155282556b9c88c75398d0054b17bc5
Subproject commit f30d520343f50d456cdb90089a24d5e9953fc07c

View File

@ -0,0 +1,2 @@
cd .\Build_Scripts
win_x86.bat %* --target-x86_64