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/*******************************************************************************
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Copyright(C) Jonas 'Sortie' Termansen 2011, 2012.
This file is part of Sortix.
Sortix is free software: you can redistribute it and/or modify it under the
terms of the GNU General Public License as published by the Free Software
Foundation, either version 3 of the License, or (at your option) any later
version.
Sortix is distributed in the hope that it will be useful, but WITHOUT ANY
WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS
FOR A PARTICULAR PURPOSE. See the GNU General Public License for more
details.
You should have received a copy of the GNU General Public License along with
Sortix. If not, see <http://www.gnu.org/licenses/>.
com.cpp
Handles communication to COM serial ports.
*******************************************************************************/
#include <sortix/kernel/platform.h>
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#include <sortix/kernel/kthread.h>
#include <libmaxsi/error.h>
#include "interrupt.h"
#include "stream.h"
#include "syscall.h"
#include "thread.h"
Multithreaded kernel and improvement of signal handling. Pardon the big ass-commit, this took months to develop and debug and the refactoring got so far that a clean merge became impossible. The good news is that this commit does quite a bit of cleaning up and generally improves the kernel quality. This makes the kernel fully pre-emptive and multithreaded. This was done by rewriting the interrupt code, the scheduler, introducing new threading primitives, and rewriting large parts of the kernel. During the past few commits the kernel has had its device drivers thread secured; this commit thread secures large parts of the core kernel. There still remains some parts of the kernel that is _not_ thread secured, but this is not a problem at this point. Each user-space thread has an associated kernel stack that it uses when it goes into kernel mode. This stack is by default 8 KiB since that value works for me and is also used by Linux. Strange things tends to happen on x86 in case of a stack overflow - there is no ideal way to catch such a situation right now. The system call conventions were changed, too. The %edx register is now used to provide the errno value of the call, instead of the kernel writing it into a registered global variable. The system call code has also been updated to better reflect the native calling conventions: not all registers have to be preserved. This makes system calls faster and simplifies the assembly. In the kernel, there is no longer the event.h header or the hacky method of 'resuming system calls' that closely resembles cooperative multitasking. If a system call wants to block, it should just block. The signal handling was also improved significantly. At this point, signals cannot interrupt kernel threads (but can always interrupt user-space threads if enabled), which introduces some problems with how a SIGINT could interrupt a blocking read, for instance. This commit introduces and uses a number of new primitives such as kthread_lock_mutex_signal() that attempts to get the lock but fails if a signal is pending. In this manner, the kernel is safer as kernel threads cannot be shut down inconveniently, but in return for complexity as blocking operations must check they if they should fail. Process exiting has also been refactored significantly. The _exit(2) system call sets the exit code and sends SIGKILL to all the threads in the process. Once all the threads have cleaned themselves up and exited, a worker thread calls the process's LastPrayer() method that unmaps memory, deletes the address space, notifies the parent, etc. This provides a very robust way to terminate processes as even half-constructed processes (during a failing fork for instance) can be gracefully terminated. I have introduced a number of kernel threads to help avoid threading problems and simplify kernel design. For instance, there is now a functional generic kernel worker thread that any kernel thread can schedule jobs for. Interrupt handlers run with interrupts off (hence they cannot call kthread_ functions as it may deadlock the system if another thread holds the lock) therefore they cannot use the standard kernel worker threads. Instead, they use a special purpose interrupt worker thread that works much like the generic one expect that interrupt handlers can safely queue work with interrupts off. Note that this also means that interrupt handlers cannot allocate memory or print to the kernel log/screen as such mechanisms uses locks. I'll introduce a lock free algorithm for such cases later on. The boot process has also changed. The original kernel init thread in kernel.cpp creates a new bootstrap thread and becomes the system idle thread. Note that pid=0 now means the kernel, as there is no longer a system idle process. The bootstrap thread launches all the kernel worker threads and then creates a new process and loads /bin/init into it and then creates a thread in pid=1, which starts the system. The bootstrap thread then quietly waits for pid=1 to exit after which it shuts down/reboots/panics the system. In general, the introduction of race conditions and dead locks have forced me to revise a lot of the design and make sure it was thread secure. Since early parts of the kernel was quite hacky, I had to refactor such code. So it seems that the risk of dead locks forces me to write better code. Note that a real preemptive multithreaded kernel simplifies the construction of blocking system calls. My hope is that this will trigger a clean up of the filesystem code that current is almost beyond repair. Almost all of the kernel was modified during this refactoring. To the extent possible, these changes have been backported to older non-multithreaded kernel, but many changes were tightly coupled and went into this commit. Of interest is the implementation of the kthread_ api based on the design of pthreads; this library allows easy synchronization mechanisms and includes C++-style scoped locks. This commit also introduces new worker threads and tested mechanisms for interrupt handlers to schedule work in a kernel worker thread. A lot of code have been rewritten from scratch and has become a lot more stable and correct. Share and enjoy!
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#include "signal.h"
#include "fs/devfs.h"
#include "com.h"
using namespace Maxsi;
namespace Sortix {
namespace COM {
// It appears this code is unable to get interrupts working correctly. Somehow
// we don't get interrupts upon receiving data, at least under VirtualBox. This
// hack changes the code such that it polls occasionally instead. Hopefully this
// won't cause data loss, but I suspect that it will.
// TODO: It appears that this code causes kernel instability, possibly due to
// the broken way blocking system calls are implemented in Sortix.
#define POLL_HACK 1
// Another alternative is to use the polling code in a completely blocking
// manner. While this may give nicer transfer speeds and less data loss, it
// locks up the whole system.
#define POLL_BLOCKING 0
// Yet another alternative is to use POLL_HACK, but return EGAIN and let user-
// space call retry, rather than relying on the broken syscall interstructure.
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#ifndef GOT_ACTUAL_KTHREAD
#define POLL_EAGAIN 1
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#else
#define POLL_EAGAIN 0
#endif
#if !POLL_EAGAIN && !POLL_HACK && defined(GOT_ACTUAL_KTHREAD)
#error The interrupt-based code was broken in the kthread branch.
#error You need to port this to the new thread/interrupt API.
#warning Oh, and fix the above mentioned bugs too.
#endif
const uint16_t TXR = 0; // Transmit register
const uint16_t RXR = 0; // Receive register
const uint16_t IER = 1; // Interrupt Enable
const uint16_t IIR = 2; // Interrupt ID
const uint16_t FCR = 2; // FIFO control
const uint16_t LCR = 3; // Line control
const uint16_t MCR = 4; // Modem control
const uint16_t LSR = 5; // Line Status
const uint16_t MSR = 6; // Modem Status
const uint16_t SCR = 7; // Scratch Register
const uint16_t DLL = 0; // Divisor Latch Low
const uint16_t DLM = 1; // Divisor latch High
const uint8_t LCR_DLAB = 0x80; // Divisor latch access bit
const uint8_t LCR_SBC = 0x40; // Set break control
const uint8_t LCR_SPAR = 0x20; // Stick parity (?)
const uint8_t LCR_EPAR = 0x10; // Even parity select
const uint8_t LCR_PARITY = 0x08; // Parity Enable
const uint8_t LCR_STOP = 0x04; // Stop bits: 0=1 bit, 1=2 bits
const uint8_t LCR_WLEN5 = 0x00; // Wordlength: 5 bits
const uint8_t LCR_WLEN6 = 0x01; // Wordlength: 6 bits
const uint8_t LCR_WLEN7 = 0x02; // Wordlength: 7 bits
const uint8_t LCR_WLEN8 = 0x03; // Wordlength: 8 bits
const uint8_t LSR_TEMT = 0x40; // Transmitter empty
const uint8_t LSR_THRE = 0x20; // Transmit-hold-register empty
const uint8_t LSR_READY = 0x1; // Data received
const uint8_t LSR_BOTH_EMPTY = LSR_TEMT | LSR_THRE;
const uint8_t IIR_NO_INTERRUPT = (1U<<0U);
const uint8_t IIR_INTERRUPT_TYPE = ((1U<<1U) | (1U<<2U) | (1U<<3U));
const uint8_t IIR_TIMEOUT = ((1U<<2U) | (1U<<3U));
const uint8_t IIR_RECV_LINE_STATUS = ((1U<<1U) | (1U<<2U));
const uint8_t IIR_RECV_DATA = (1U<<2U);
const uint8_t IIR_SENT_DATA = (1U<<1U);
const uint8_t IIR_MODEM_STATUS = 0;
const uint8_t IER_DATA = (1U<<0U);
const uint8_t IER_SENT = (1U<<1U);
const uint8_t IER_LINE_STATUS = (1U<<2U);
const uint8_t IER_MODEM_STATUS = (1U<<3U);
const uint8_t IER_SLEEP_MODE = (1U<<4U);
const uint8_t IER_LOW_POWER = (1U<<5U);
const unsigned BASE_BAUD = 1843200/16;
const unsigned UART8250 = 1;
const unsigned UART16450 = 2;
const unsigned UART16550 = 3;
const unsigned UART16550A = 4;
const unsigned UART16750 = 5;
const size_t NUMCOMPORTS = 4;
// The IO base ports of each COM port.
static uint16_t comports[1+NUMCOMPORTS];
// The results of running HardwareProbe on each COM port.
unsigned hwversion[1+NUMCOMPORTS];
// Uses various characteristics of the UART chips to determine the hardware.
static unsigned HardwareProbe(uint16_t port)
{
// Set the value "0xE7" to the FCR to test the status of the FIFO flags.
CPU::OutPortB(port + FCR, 0xE7);
uint8_t iir = CPU::InPortB(port + IIR);
if ( iir & (1U<<6U) )
{
if ( iir & (1<<7U) )
{
return (iir & (1U<<5U)) ? UART16750 : UART16550A;
}
return UART16550;
}
// See if the scratch register returns what we write into it. The 8520
// doesn't do it. This is technically undefined behavior, but it is useful
// to detect hardware versions.
uint16_t anyvalue = 0x2A;
CPU::OutPortB(port + SCR, anyvalue);
return CPU::InPortB(port + SCR) == anyvalue ? UART16450 : UART8250;
}
static inline void WaitForEmptyBuffers(uint16_t port)
{
while ( (CPU::InPortB(port + LSR) & LSR_BOTH_EMPTY) != LSR_BOTH_EMPTY ) { }
}
static inline bool IsLineReady(uint16_t port)
{
return CPU::InPortB(port + LSR) & LSR_READY;
}
static inline bool CanWriteByte(uint16_t port)
{
return CPU::InPortB(port + LSR) & LSR_THRE;
}
ssize_t ReadBlocking(uint16_t port, void* buf, size_t size)
{
if ( SSIZE_MAX < size ) { size = SSIZE_MAX; }
uint8_t* buffer = (uint8_t*) buf;
uint8_t interruptsenabled = CPU::InPortB(port + IER);
CPU::OutPortB(port + IER, 0);
for ( size_t i = 0; i < size; i++ )
{
while ( !IsLineReady(port) ) { }
buffer[i] = CPU::InPortB(port + RXR);
}
WaitForEmptyBuffers(port);
CPU::OutPortB(port + IER, interruptsenabled);
return size;
}
ssize_t WriteBlocking(uint16_t port, const void* buf, size_t size)
{
if ( SSIZE_MAX < size ) { size = SSIZE_MAX; }
const uint8_t* buffer = (const uint8_t*) buf;
uint8_t interruptsenabled = CPU::InPortB(port + IER);
CPU::OutPortB(port + IER, 0);
for ( size_t i = 0; i < size; i++ )
{
while ( !CanWriteByte(port) ) { }
CPU::OutPortB(port + TXR, buffer[i]);
}
WaitForEmptyBuffers(port);
CPU::OutPortB(port + IER, interruptsenabled);
return size;
}
void EarlyInit()
{
// We can fetch COM port information from the BIOS Data Area.
volatile uint16_t* const bioscomports = (uint16_t* const) 0x0400UL;
for ( size_t i = 1; i <= NUMCOMPORTS; i++ )
{
comports[i] = bioscomports[i-1];
if ( !comports[i] ) { continue; }
hwversion[i] = HardwareProbe(comports[i]);
CPU::OutPortB(comports[i] + IER, 0x0);
}
}
class DevCOMPort : public DevStream
{
public:
typedef DevStream BaseClass;
public:
DevCOMPort(uint16_t port);
virtual ~DevCOMPort();
public:
virtual ssize_t Read(uint8_t* dest, size_t count);
virtual ssize_t Write(const uint8_t* src, size_t count);
virtual bool IsReadable();
virtual bool IsWritable();
public:
void OnInterrupt();
private:
uint16_t port;
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kthread_mutex_t portlock;
#ifdef GOT_FAKE_KTHREAD
Event dataevent;
Event sentevent;
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#endif
};
DevCOMPort::DevCOMPort(uint16_t port)
{
this->port = port;
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this->portlock = KTHREAD_MUTEX_INITIALIZER;
}
DevCOMPort::~DevCOMPort()
{
}
bool DevCOMPort::IsReadable() { return true; }
bool DevCOMPort::IsWritable() { return true; }
#if POLL_HACK
const unsigned TRIES = 1000;
ssize_t DevCOMPort::Read(uint8_t* dest, size_t count)
{
if ( !count ) { return 0; }
if ( SSIZE_MAX < count ) { count = SSIZE_MAX; }
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ScopedLock lock(&portlock);
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#ifdef GOT_ACTUAL_KTHREAD
while ( !(CPU::InPortB(port + LSR) & LSR_READY) )
if ( Signal::IsPending() )
{
Error::Set(EINTR);
return -1;
}
#else
uint8_t lsr;
for ( unsigned i = 0; i < TRIES; i++ )
{
lsr = CPU::InPortB(port + LSR);
if ( lsr & LSR_READY ) { break; }
}
if ( !(lsr & LSR_READY) )
{
#if POLL_EAGAIN
Error::Set(EAGAIN);
#else
Error::Set(EBLOCKING);
Syscall::Yield();
#endif
return -1;
}
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#endif
size_t sofar = 0;
do
{
if ( count <= sofar ) { break; }
dest[sofar++] = CPU::InPortB(port + RXR);
} while ( CPU::InPortB(port + LSR) & LSR_READY);
return sofar;
}
ssize_t DevCOMPort::Write(const uint8_t* src, size_t count)
{
if ( !count ) { return 0; }
if ( SSIZE_MAX < count ) { count = SSIZE_MAX; };
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ScopedLock lock(&portlock);
#ifdef GOT_ACTUAL_KTHREAD
while ( !(CPU::InPortB(port + LSR) & LSR_THRE) )
if ( Signal::IsPending() )
{
Error::Set(EINTR);
return -1;
}
#else
uint8_t lsr;
for ( unsigned i = 0; i < TRIES; i++ )
{
lsr = CPU::InPortB(port + LSR);
if ( lsr & LSR_THRE ) { break; }
}
if ( !(lsr & LSR_THRE) )
{
#if POLL_EAGAIN
Error::Set(EAGAIN);
#else
Error::Set(EBLOCKING);
Syscall::Yield();
#endif
return -1;
}
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#endif
size_t sofar = 0;
do
{
if ( count <= sofar ) { break; }
CPU::OutPortB(port + TXR, src[sofar++]);
} while ( CPU::InPortB(port + LSR) & LSR_THRE );
return sofar;
}
#else
ssize_t DevCOMPort::Read(uint8_t* dest, size_t count)
{
if ( !count ) { return 0; }
if ( SSIZE_MAX < count ) { count = SSIZE_MAX; }
#if POLL_BLOCKING
return ReadBlocking(port, dest, 1);
#endif
uint8_t lsr = CPU::InPortB(port + LSR);
if ( !(lsr & LSR_READY) )
{
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#ifdef GOT_ACTUAL_KTHREAD
Panic("Can't wait for com data receive event");
#else
dataevent.Register();
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#endif
Error::Set(EBLOCKING);
return -1;
}
size_t sofar = 0;
do
{
if ( count <= sofar ) { break; }
dest[sofar++] = CPU::InPortB(port + RXR);
} while ( CPU::InPortB(port + LSR) & LSR_READY);
return sofar;
}
ssize_t DevCOMPort::Write(const uint8_t* src, size_t count)
{
if ( !count ) { return 0; }
if ( SSIZE_MAX < count ) { count = SSIZE_MAX; };
#if POLL_BLOCKING
return WriteBlocking(port, src, 1);
#endif
uint8_t lsr = CPU::InPortB(port + LSR);
if ( !(lsr & LSR_THRE) )
{
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#ifdef GOT_ACTUAL_KTHREAD
Panic("Can't wait for com data sent event");
#else
sentevent.Register();
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#endif
Error::Set(EBLOCKING);
return -1;
}
size_t sofar = 0;
do
{
if ( count <= sofar ) { break; }
CPU::OutPortB(port + TXR, src[sofar++]);
} while ( CPU::InPortB(port + LSR) & LSR_THRE );
return sofar;
}
#endif
void DevCOMPort::OnInterrupt()
{
#if POLL_HACK || POLL_BLOCKING
return;
#endif
uint8_t iir = CPU::InPortB(port + IIR);
if ( iir & IIR_NO_INTERRUPT ) { return; }
uint8_t intrtype = iir & IIR_INTERRUPT_TYPE;
switch ( intrtype )
{
case IIR_TIMEOUT:
CPU::InPortB(port + RXR);
break;
case IIR_RECV_LINE_STATUS:
// TODO: Proper error handling!
CPU::InPortB(port + LSR);
break;
case IIR_RECV_DATA:
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#ifdef GOT_ACTUAL_KTHREAD
Panic("Can't wait for com data sent event");
#else
dataevent.Signal();
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#endif
break;
case IIR_SENT_DATA:
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#ifdef GOT_ACTUAL_KTHREAD
Panic("Can't wait for com data sent event");
#else
sentevent.Signal();
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#endif
CPU::InPortB(port + IIR);
break;
case IIR_MODEM_STATUS:
CPU::InPortB(port + MSR);
break;
}
}
DevCOMPort* comdevices[1+NUMCOMPORTS];
static void UARTIRQHandler(CPU::InterruptRegisters* /*regs*/, void* /*user*/)
{
for ( size_t i = 1; i <= NUMCOMPORTS; i++ )
{
if ( !comdevices[i] ) { continue; }
comdevices[i]->OnInterrupt();
}
}
void Init()
{
for ( size_t i = 1; i <= NUMCOMPORTS; i++ )
{
if ( !comports[i] ) { comdevices[i] = NULL; continue; }
comdevices[i] = new DevCOMPort(comports[i]);
if ( !comdevices[i] )
{
PanicF("Unable to allocate device for COM port %zu at 0x%x", i,
comports[i]);
}
char name[5] = "comN";
name[3] = '0' + i;
if ( !DeviceFS::RegisterDevice(name, comdevices[i]) )
{
PanicF("Unable to register device /dev/%s", name);
}
}
Interrupt::RegisterHandler(Interrupt::IRQ3, UARTIRQHandler, NULL);
Interrupt::RegisterHandler(Interrupt::IRQ4, UARTIRQHandler, NULL);
// Initialize the ports so we can transfer data.
for ( size_t i = 1; i <= NUMCOMPORTS; i++ )
{
uint16_t port = comports[i];
if ( !port ) { continue; }
#if POLL_HACK || POLL_BLOCKING
uint8_t interrupts = 0;
#else
uint8_t interrupts = IER_DATA
| IER_SENT
| IER_LINE_STATUS
| IER_MODEM_STATUS;
#endif
CPU::OutPortB(port + FCR, 0);
CPU::OutPortB(port + LCR, 0x80);
CPU::OutPortB(port + DLL, 0xC);
CPU::OutPortB(port + DLM, 0x0);
CPU::OutPortB(port + LCR, 0x3); // 8n1
CPU::OutPortB(port + MCR, 0x3); // DTR + RTS
CPU::OutPortB(port + IER, interrupts);
}
}
} // namespace COM
} // namespace Sortix