#include "FloppyController.class.h" #include "FloppyDrive.class.h" #include #include #include using namespace Sys; //For outb/inb //*********************************************************** // STATIC, FOR DMA //*********************************************************** Mutex FloppyController::dmaMutex(false); u8int FloppyController::dmabuff[FLOPPY_DMALEN] __attribute__((aligned(0x8000))); bool FloppyController::dmaInit(u8int direction, u32int length) { dmaMutex.waitLock(); union { u8int b[4]; u32int l; } a, c; //Address, count //We want the physical address of dmabuff. We simply remove 0xC0000000, because we've mapped memory linearly. a.l = (u32int) &dmabuff - 0xC0000000; c.l = (u32int) length - 1; if ( (a.l >> 24) || //Address must be under 16mb (c.l >> 16) || //Count must be < 64k (((a.l & 0xFFFF) + c.l) >> 16) //We must not cross a 64k boundary ) { //Something is wrong dmaMutex.unlock(); return false; } u8int mode; switch (direction) { case FD_READ: mode = 0x46; break; case FD_WRITE: mode = 0x4A; break; default: //Invalid direction dmaMutex.unlock(); return false; } outb(0x0a, 0x06); //Mask chan 2 outb(0x0c, 0xff); //Reset flip-flop outb(0x04, a.b[0]); //Address low outb(0x04, a.b[1]); //Address high outb(0x81, a.b[2]); //External page register outb(0x0c, 0xff); //Reset flip-flop outb(0x05, c.b[0]); //Count low outb(0x05, c.b[1]); //Count high outb(0x0b, mode); //Mode outb(0x0a, 0x02); //Unmask chan 2 return true; } void FloppyController::dmaRelease() { dmaMutex.unlock(); } //********************************************************* // FOR THE CONTROLLER //********************************************************* u32int floppyMotorTimer() { //This will be an independant thread while(1) { Task::currentThread->sleep(1000); //Check only every second Vector floppys = Dev::findDevices("block.floppy"); for (u32int i = 0; i < floppys.size(); i++) { FloppyDrive* f = (FloppyDrive*)floppys[i]; if (f->m_motorTimeout > 0 && f->m_motorState == FS_MOTORWAIT) { f->m_motorTimeout--; if (f->m_motorTimeout == 0) f->killMotor(); } } } return 0; } FloppyController::FloppyController(u32int base, u8int irq) : m_driveMutex(false) { m_activeDrive = 0; m_base = base; m_irq = irq; m_drives[0] = NULL; m_drives[1] = NULL; m_first = false; } void FloppyController::detect() { //TODO : do this better FloppyController *fdc = new FloppyController(0x03F0, 6); //Standard controller, IRQ6 and base port 0x03F0 Dev::registerDevice(fdc); outb(0x70, 0x10); //CMOS detect u8int drives = inb(0x71); u8int fdd0 = (drives >> 4), fdd1 = (drives & 0x0F); if (fdd0 != FT_NONE) Dev::registerDevice(new FloppyDrive(fdc, 0, fdd0)); if (fdd1 != FT_NONE) Dev::registerDevice(new FloppyDrive(fdc, 1, fdd1)); fdc->reset(); Vector fdds = Dev::findDevices("block.floppy"); for (u32int i = 0; i < fdds.size(); i++) { Part::registerDevice((BlockDevice*)fdds[i]); //TODO } new Thread(floppyMotorTimer, true); } String FloppyController::getClass() { return "controller.floppy"; } String FloppyController::getName() { String irq = String::number(m_irq); return String("Floppy controller at IRQ ") += irq; } void FloppyController::checkInterrupt(int *st0, int *cyl) { writeCmd(FC_SENSE_INTERRUPT); *st0 = readData(); *cyl = readData(); } void FloppyController::setDOR() { u8int dor = 0x0C; if (m_activeDrive == 1) dor |= 0x01; if (m_drives[0] != NULL and m_drives[0]->m_motorState != 0) dor |= 0x10; if (m_drives[1] != NULL and m_drives[1]->m_motorState != 0) dor |= 0x20; asm volatile ("cli"); outb(m_base + FR_DOR, dor); if (m_first) { //First time we set the DOR, controller initialized Task::currentThread->waitIRQ(m_irq); int st0, cyl; checkInterrupt(&st0, &cyl); m_first = false; } asm volatile ("sti"); //PANIC("test"); } void FloppyController::setActiveDrive(u8int drive) { m_driveMutex.waitLock(); m_activeDrive = drive; setDOR(); } void FloppyController::setNoActiveDrive() { m_driveMutex.unlock(); } bool FloppyController::writeCmd(u8int cmd) { for (int i = 0; i < 600; i++) { if (0x80 & inb(m_base + FR_MSR)) { outb(m_base + FR_FIFO, cmd); return true; } Task::currentThread->sleep(10); } return false; } u8int FloppyController::readData() { for (int i = 0; i < 600; i++) { if (0x80 & inb(m_base + FR_MSR)) { return inb(m_base + FR_FIFO); } Task::currentThread->sleep(10); } return 0; } bool FloppyController::reset() { outb(m_base + FR_DOR, 0x00); //Disable controller m_first = true; setNoActiveDrive(); if (m_drives[0] != NULL) m_drives[0]->m_motorState = 0; if (m_drives[1] != NULL) m_drives[1]->m_motorState = 0; for (int i = 0; i < 2; i++) { if (m_drives[i] != NULL) { if (!m_drives[i]->setup()) return false; } } return true; }