Esempio n. 1
0
        // public unsafe static void InitialKernelProtect()
        // {
        //     KernelMessage.WriteLine("Protecting Memory...");

        //     // PageDirectoryEntry* pde = (PageDirectoryEntry*)AddrPageDirectory;
        //     // for (int index = 0; index < 1024; index++)
        //     // {
        //     //   pde[index].Writable = false;
        //     // }

        //     // PageTable.PageTableEntry* pte = (PageTable.PageTableEntry*)PageTable.AddrPageTable;
        //     // for (int index = 0; index < 1024 * 32; index++)
        //     //   pte[index].Writable = false;

        //     // InitialKernelProtect_MakeWritable_ByRegion(0, 90 * 1024 * 1024);

        //     KernelMessage.WriteLine("Reload CR3 to {0:X8}", PageTable.AddrPageDirectory);
        //     Native.SetCR3(PageTable.AddrPageDirectory);
        //     //Native.Invlpg();
        //     KernelMessage.WriteLine("Protecting Memory done");
        // }

        // public unsafe static void InitialKernelProtect_MakeWritable_ByRegion(uint startVirtAddr, uint endVirtAddr)
        // {
        //     InitialKernelProtect_MakeWritable_BySize(startVirtAddr, endVirtAddr - startVirtAddr);
        // }

        // public unsafe static void InitialKernelProtect_MakeWritable_BySize(uint virtAddr, uint size)
        // {
        //     var pages = KMath.DivCeil(size, 4096);
        //     for (var i = 0; i < pages; i++)
        //     {
        //         var entry = PageTable.GetTableEntry(virtAddr);
        //         entry->Writable = true;
        //     }
        // }

        public static void Tests()
        {
            var ar = new KList <uint>(sizeof(uint));

            ar.Add(44);
            ar.Add(55);
            KernelMessage.WriteLine("CNT: {0}", ManagedMemoy.AllocationCount);
            foreach (var num in ar)
            {
                KernelMessage.WriteLine("VAL: {0}", num);
            }
            KernelMessage.WriteLine("CNT: {0}", ManagedMemoy.AllocationCount);
            ar.Destroy();

            KernelMessage.WriteLine("Pages free: {0}", PageFrameManager.PagesAvailable);

            for (var i = 0; i < 10000; i++)
            {
                var s = new int[] { 1, 2, 3, 4, };
                s[1] = 5;
                Memory.FreeObject(s);
            }
            KernelMessage.WriteLine("Pages free: {0}", PageFrameManager.PagesAvailable);
            //Memory.FreeObject(s);
        }
Esempio n. 2
0
 public static void Setup()
 {
     KernelMessage.WriteLine("Setup Native Calls");
     prog1Addr      = KernelElf.Native.GetPhysAddrOfSymbol("test_proc1");
     prog2Addr      = KernelElf.Native.GetPhysAddrOfSymbol("test_proc2");
     bochsDebugAddr = KernelElf.Native.GetPhysAddrOfSymbol("bochs_debug");
 }
Esempio n. 3
0
        public static void Setup()
        {
            var addr = Initial_FindIFreePage();

            KernelMessage.Path("KernelMemoryMapManager", "Initial Page: {0:X}", addr);

            // 80KB should be enough
            // TODO: Check if really 80KB are available after this address.
            InitialMap = new KernelMemoryMap(addr, 0x1000 * 20, BootInfoMemoryType.KernelMemoryMap);
            Memory.InitialKernelProtect_MakeWritable_BySize(InitialMap.Start, InitialMap.Size);

            Header = (KernelMemoryMapHeader *)InitialMap.Start;

            var arrayOffset1 = 0x1000;
            var arrayOffset2 = 0x3000;

            Header->SystemUsable = new KernelMemoryMapArray((KernelMemoryMap *)(InitialMap.Start + arrayOffset1), 50);
            Header->Used         = new KernelMemoryMapArray((KernelMemoryMap *)(InitialMap.Start + arrayOffset2), 100);

            for (uint i = 0; i < BootInfo.Header->MemoryMapLength; i++)
            {
                var map  = BootInfo.Header->MemoryMapArray[i];
                var kmap = new KernelMemoryMap(map.Start, map.Size, map.Type);
                if (kmap.Type == BootInfoMemoryType.SystemUsable)
                {
                    Header->SystemUsable.Add(kmap);
                }
                else
                {
                    Header->Used.Add(kmap);
                }
            }
            Header->Used.Add(InitialMap);
            //Debug_FillAvailableMemory();
        }
Esempio n. 4
0
        unsafe static ElfHelper FromSectionName(string name)
        {
            var sec  = Main.GetSectionHeader(name);
            var addr = Main.GetSectionPhysAddr(sec);

            KernelMessage.WriteLine("Found embedded ELF at {0:X8}", addr);
            return(FromAddress(addr));
        }
Esempio n. 5
0
 public static void Break()
 {
     KernelMessage.Write("<BREAK>");
     while (true)
     {
         Native.Nop();
     }
 }
Esempio n. 6
0
        public static void Setup()
        {
            KernelMessage.WriteLine("Setup IDT");

            IDTAddr = PageFrameManager.AllocatePage(PageFrameRequestFlags.Default)->PhysicalAddress;
            KernelMessage.WriteLine("Address of IDT: {0:X8}", IDTAddr);

            // Setup IDT table
            Mosa.Runtime.Internal.MemoryClear(new IntPtr((uint)IDTAddr), 6);
            Intrinsic.Store16(new IntPtr((uint)IDTAddr), (Offset.TotalSize * 256) - 1);
            Intrinsic.Store32(new IntPtr((uint)IDTAddr), 2, IDTAddr + 6);

            KernelMessage.Write("Set IDT table entries...");
            SetTableEntries();
            KernelMessage.WriteLine("done");

            handlers = new InterruptInfo[256];
            for (var i = 0; i <= 255; i++)
            {
                var info = new InterruptInfo
                {
                    Interrupt      = i,
                    CountStatistcs = true,
                    Trace          = true,
                    Handler        = UndefinedHandler
                };
                if (i == (int)KnownInterrupt.ClockTimer)
                {
                    info.Trace          = false;
                    info.CountStatistcs = false;
                }
                handlers[i] = info;
            }

            SetInterruptHandler(KnownInterrupt.DivideError, InterruptsHandlers.DivideError);
            SetInterruptHandler(KnownInterrupt.ArithmeticOverflowException, InterruptsHandlers.ArithmeticOverflowException);
            SetInterruptHandler(KnownInterrupt.BoundCheckError, InterruptsHandlers.BoundCheckError);
            SetInterruptHandler(KnownInterrupt.InvalidOpcode, InterruptsHandlers.InvalidOpcode);
            SetInterruptHandler(KnownInterrupt.CoProcessorNotAvailable, InterruptsHandlers.CoProcessorNotAvailable);
            SetInterruptHandler(KnownInterrupt.DoubleFault, InterruptsHandlers.DoubleFault);
            SetInterruptHandler(KnownInterrupt.CoProcessorSegmentOverrun, InterruptsHandlers.CoProcessorSegmentOverrun);
            SetInterruptHandler(KnownInterrupt.InvalidTSS, InterruptsHandlers.InvalidTSS);
            SetInterruptHandler(KnownInterrupt.SegmentNotPresent, InterruptsHandlers.SegmentNotPresent);
            SetInterruptHandler(KnownInterrupt.StackException, InterruptsHandlers.StackException);
            SetInterruptHandler(KnownInterrupt.GeneralProtectionException, InterruptsHandlers.GeneralProtectionException);
            SetInterruptHandler(KnownInterrupt.PageFault, InterruptsHandlers.PageFault);
            SetInterruptHandler(KnownInterrupt.CoProcessorError, InterruptsHandlers.CoProcessorError);
            SetInterruptHandler(KnownInterrupt.SIMDFloatinPointException, InterruptsHandlers.SIMDFloatinPointException);
            SetInterruptHandler(KnownInterrupt.ClockTimer, InterruptsHandlers.ClockTimer);

            KernelMessage.Write("Enabling interrupts...");
            var idtAddr = (uint)IDTAddr;

            Native.Lidt(idtAddr);
            Native.Sti();
            KernelMessage.WriteLine("done");
        }
Esempio n. 7
0
        public static void Setup()
        {
            KernelMessage.WriteLine("Setup ELF Headers");
            //KernelMessage.WriteLine("Image Header:");
            //KernelMemory.DumpToConsoleLine(Address.KernelElfSection, 124);

            Main   = FromAddress(Address.KernelElfSection);
            Native = FromSectionName("native");
        }
Esempio n. 8
0
        public static BootInfoMemory AllocateMemoryMap(USize size, BootInfoMemoryType type)
        {
            var map = new BootInfoMemory();

            map.Start      = PageStartAddr;
            map.Size       = size;
            map.Type       = type;
            PageStartAddr += size;

            KernelMessage.WriteLine("Allocated MemoryMap of Type {0} at {1:X8} with Size {2:X8}", (uint)type, map.Start, map.Size);

            return(map);
        }
Esempio n. 9
0
        public static void Setup()
        {
            KernelMessage.WriteLine("Multiboot Flags: {0:X}", Multiboot.Flags);
            BootInfo            = (BootInfoHeader *)Address.KernelBootInfo;
            BootInfo->Magic     = lonos.kernel.core.BootInfoHeader.BootInfoMagic;
            BootInfo->HeapStart = KMath.AlignValueCeil(Address.OriginalKernelElfSection + LoaderStart.OriginalKernelElf.TotalFileSize, 0x1000);
            BootInfo->HeapSize  = 0;

            BootInfo->InstalledPhysicalMemory = 128 * 1024 * 1024;

            SetupVideoInfo();
            SetupMemoryMap();
        }
Esempio n. 10
0
        static void MapKernelImage()
        {
            var phys    = Address.KernelElfSection;
            var diff    = Address.KernelBaseVirt - Address.KernelBasePhys;
            var endPhys = phys + OriginalKernelElf.TotalFileSize;
            var addr    = phys;

            KernelMessage.WriteLine("Mapping Kernel Image from physical {0:X8} to virtual {1:X8}", phys, phys + diff);
            while (addr < endPhys)
            {
                PageTable.MapVirtualAddressToPhysical(addr + diff, addr);
                addr += 0x1000;
            }
        }
Esempio n. 11
0
        public unsafe static void Setup()
        {
            kmallocAllocator = new Allocator();

            var ptr = (byte *)RawVirtualFrameAllocator.RequestRawVirtalMemoryPages(KMath.AlignValueCeil(Allocator.headSize, 4096));

            for (var i = 0; i < Allocator.headSize; i++)
            {
                *(ptr + i) = 0;
            }
            kmallocAllocator.list_heads = (malloc_meta **)ptr;
            ManagedMemoy.useAllocator   = true;

            KernelMessage.WriteLine("Memory free: {0} MB", (PageFrameManager.PagesAvailable * 4096) / 1024 / 1024);
        }
Esempio n. 12
0
        public unsafe static void DumpElfInfo()
        {
            var secArray  = OriginalKernelElf.SectionHeaderArray;
            var secLength = OriginalKernelElf.SectionHeaderCount;

            KernelMessage.WriteLine("Found {0} Kernel Sections:", secLength);

            for (uint i = 0; i < secLength; i++)
            {
                var sec  = OriginalKernelElf.GetSectionHeader(i);
                var name = OriginalKernelElf.GeSectionName(sec);
                var sb   = new StringBuffer(name);
                KernelMessage.WriteLine(sb);
            }
        }
Esempio n. 13
0
        /// <summary>
        /// Video Stage
        /// </summary>
        public unsafe static void InitFrameBuffer()
        {
            if (!BootInfo.Header->FBPresent || BootInfo.Header->VBEMode < 0x100)
            {
                KernelMessage.Path("fb", "not present");
                return;
            }

            KernelMessage.WriteLine("InitFrameBuffer");

            fb = new FrameBuffer(BootInfo.Header->FbInfo.FbAddr, BootInfo.Header->FbInfo.FbWidth, BootInfo.Header->FbInfo.FbHeight, BootInfo.Header->FbInfo.FbPitch, 8);
            fb.Init();

            FrameBufferTextScreen = new FrameBufferTextScreenDevice(fb);
            Console.SetOutputDevice(FrameBufferTextScreen);
        }
Esempio n. 14
0
        /// <summary>
        /// Sets up the PageTable
        /// </summary>
        public static void Setup(Addr addrPageDirectory, Addr addrPageTable)
        {
            KernelMessage.WriteLine("Setup PageTable");

            AddrPageDirectory = addrPageDirectory;
            AddrPageTable     = addrPageTable;

            // Setup Page Directory
            PageDirectoryEntry *pde = (PageDirectoryEntry *)AddrPageDirectory;

            for (int index = 0; index < 1024; index++)
            {
                pde[index]                = new PageDirectoryEntry();
                pde[index].Present        = true;
                pde[index].Writable       = true;
                pde[index].User           = true;
                pde[index].PageTableEntry = (PageTableEntry *)(uint)(AddrPageTable + (index * 4096));
            }

            // Map the first 128MB of memory (32786 4K pages) (why 128MB?)
            for (int index = 0; index < 1024 * 32; index++)
            {
                PageTableEntry *pte = (PageTableEntry *)AddrPageTable;
                pte[index]                 = new PageTableEntry();
                pte[index].Present         = true;
                pte[index].Writable        = true;
                pte[index].User            = true;
                pte[index].PhysicalAddress = (uint)(index * 4096);
            }

            // Unmap the first page for null pointer exceptions
            MapVirtualAddressToPhysical(0x0, 0x0, false);

            // Set CR3 register on processor - sets page directory
            KernelMessage.WriteLine("Set CR3 to {0:X8}", PageTable.AddrPageDirectory);
            Native.SetCR3(AddrPageDirectory);

            KernelMessage.Write("Enable Paging... ");

            // Set CR0.WP
            Native.SetCR0(Native.GetCR0() | 0x10000);

            // Set CR0 register on processor - turns on virtual memory
            Native.SetCR0(Native.GetCR0() | 0x80000000);

            KernelMessage.WriteLine("Done");
        }
Esempio n. 15
0
        public static void ApplyMode(uint mode)
        {
            // https://de.wikibooks.org/wiki/Interrupts_80x86/_INT_10#Funktion_00h:_Setze_Bildschirmmodus_(EGA/VGA)
            KernelMessage.WriteLine("Screen VBE Mode: {0}", mode);
            switch (mode)
            {
            case 1:
                Rows    = 25;
                Columns = 40;
                break;

            case 3:
                Rows    = 25;
                Columns = 80;
                break;
            }
        }
Esempio n. 16
0
        public static KernelMemoryMap Allocate(USize size, BootInfoMemoryType type)
        {
            var cnt = Header->Used.Count;

            for (uint i = 0; i < cnt; i++)
            {
                var map = Header->Used.Items[i];
                if (CheckPageIsUsableAfterMap(map, size))
                {
                    var newMap = new KernelMemoryMap(map.Start + map.Size, size, type);
                    Header->Used.Add(newMap);
                    KernelMessage.Path("KernelMemoryMapManager", "Allocated: at {0:X8}, size {1:X8}, type {2}", newMap.Start, size, (uint)type);
                    return(newMap);
                }
            }
            return(KernelMemoryMap.Empty);
        }
Esempio n. 17
0
        /// <summary>
        /// Currently unused, because Kernel is loaded via from kernel.loader
        /// </summary>

        /*unsafe static ElfHelper FromMultiBootInfo(MultiBootInfo* multiBootInfo)
         * {
         *  var helper = new ElfHelper
         *  {
         *      SectionHeaderArray = (ElfSectionHeader*)multiBootInfo->ElfSectionHeader->Addr,
         *      StringTableSectionHeaderIndex = multiBootInfo->ElfSectionHeader->Shndx,
         *      SectionHeaderCount = multiBootInfo->ElfSectionHeader->Count
         *  };
         *  helper.Init();
         *  return helper;
         * }*/

        unsafe static ElfHelper FromAddress(Addr elfStart)
        {
            var elfHeader = (ElfHeader *)elfStart;

            if (elfHeader->Ident1 != ElfHeader.Magic1)
            {
                KernelMessage.WriteLine("No valid ELF found at {0:X8}", elfStart);
                // TODO: Throw Excetion
            }
            var helper = new ElfHelper
            {
                PhyOffset                     = elfStart,
                SectionHeaderArray            = (ElfSectionHeader *)(elfStart + elfHeader->ShOff),
                SectionHeaderCount            = elfHeader->ShNum,
                StringTableSectionHeaderIndex = elfHeader->ShStrNdx
            };

            helper.Init();
            return(helper);
        }
Esempio n. 18
0
        public static void SetupStage2()
        {
            if (Header->Magic != BootInfoHeader.BootInfoMagic)
            {
                Present = false;
                KernelMessage.WriteLine("bootinfo not present");
                return;
            }

            Present = true;
            KernelMessage.WriteLine("bootinfo present");

            var mapLen = Header->MemoryMapLength;

            KernelMessage.WriteLine("Maps: {0}", mapLen);
            for (uint i = 0; i < mapLen; i++)
            {
                var mm = Header->MemoryMapArray[i];
                KernelMessage.WriteLine("Map Start={0:X8}, Size={1:X8}, Type={2}", mm.Start, mm.Size, (uint)mm.Type);
            }
        }
Esempio n. 19
0
        public static void DumpToConsole(uint addr, uint length)
        {
            var sb = new StringBuffer();

            sb.Append("{0:X}+{1:D} ", addr, length);
            KernelMessage.Write(sb);
            sb.Clear();

            for (uint a = addr; a < addr + length; a++)
            {
                sb.Clear();

                if (a != addr)
                {
                    sb.Append(" ");
                }
                var m = Native.Get8(a);
                sb.Append(m, 16, 2);
                KernelMessage.Write(sb);
            }
        }
Esempio n. 20
0
        /// <summary>
        /// Sets up the GDT table and entries
        /// </summary>
        public static void Setup(Addr addr)
        {
            KernelMessage.Write("Setup GDT...");

            gdtTableAddress = addr;

            table = (DescriptorTable *)gdtTableAddress;
            table->Clear();
            table->AdressOfEntries = gdtTableAddress + DescriptorTable.StructSize;

            //Null segment
            var nullEntry = DescriptorTableEntry.CreateNullDescriptor();

            table->AddEntry(nullEntry);

            //code segment
            var codeEntry = DescriptorTableEntry.CreateCode(0, 0xFFFFFFFF);

            codeEntry.CodeSegment_Readable = true;
            codeEntry.PriviligeRing        = 0;
            codeEntry.Present     = true;
            codeEntry.AddressMode = DescriptorTableEntry.EAddressMode.Bits32;
            codeEntry.Granularity = true;
            table->AddEntry(codeEntry);

            //data segment
            var dataEntry = DescriptorTableEntry.CreateData(0, 0xFFFFFFFF);

            dataEntry.DataSegment_Writable = true;
            dataEntry.PriviligeRing        = 0;
            dataEntry.Present     = true;
            dataEntry.AddressMode = DescriptorTableEntry.EAddressMode.Bits32;
            dataEntry.Granularity = true;
            table->AddEntry(dataEntry);

            Flush();

            KernelMessage.WriteLine("Done");
        }
Esempio n. 21
0
        static void SetupVideoInfo()
        {
            KernelMessage.WriteLine("VBE present: {0}", Multiboot.VBEPresent ? "yes" : "no");
            if (Multiboot.VBEPresent)
            {
                KernelMessage.WriteLine("VBE Mode: {0}", Multiboot.VBEMode);
            }
            BootInfo->VBEPresent = Multiboot.VBEPresent;
            BootInfo->VBEMode    = Multiboot.VBEMode;

            KernelMessage.WriteLine("FrameBuffer present: {0}", Multiboot.FBPresent ? "yes" : "no");
            BootInfo->FBPresent = Multiboot.FBPresent;

            BootInfo->FbInfo           = new BootInfoFramebufferInfo();
            BootInfo->FbInfo.FbAddr    = Multiboot.multiBootInfo->FbAddr;
            BootInfo->FbInfo.FbPitch   = Multiboot.multiBootInfo->FbPitch;
            BootInfo->FbInfo.FbWidth   = Multiboot.multiBootInfo->FbWidth;
            BootInfo->FbInfo.FbHeight  = Multiboot.multiBootInfo->FbHeight;
            BootInfo->FbInfo.FbBpp     = Multiboot.multiBootInfo->FbBpp;
            BootInfo->FbInfo.FbType    = Multiboot.multiBootInfo->FbType;
            BootInfo->FbInfo.ColorInfo = Multiboot.multiBootInfo->ColorInfo;
        }
Esempio n. 22
0
        /// <summary>
        /// Setups the free memory.
        /// </summary>
        unsafe void SetupFreeMemory()
        {
            if (!BootInfo.Present)
            {
                return;
            }

            for (var i = 0; i < KernelMemoryMapManager.Header->Used.Count; i++)
            {
                var map = KernelMemoryMapManager.Header->Used.Items[i];
                if (map.Start >= BootInfo.Header->InstalledPhysicalMemory)
                {
                    continue;
                }
                KernelMessage.WriteLine("{0:X}", map.Start);
                var page = GetPhysPage(map.Start);
                if (page == null)
                {
                    continue;
                }
                page->Status = PageStatus.Used;
                PagesUsed++;
            }
        }
Esempio n. 23
0
        public static void Setup()
        {
            KernelMessage.WriteLine("Setup PIC");
            byte masterMask = Native.In8(PIC1_Data);
            byte slaveMask  = Native.In8(PIC2_Data);

            // ICW1 - Set Initialize Controller & Expect ICW4
            Native.Out8(PIC1_Command, ICW1_Initialization + ICW1_ICW4);

            // ICW2 - interrupt offset
            Native.Out8(PIC1_Data, ICW2_MasterOffset);

            // ICW3
            Native.Out8(PIC1_Data, 4);

            // ICW4 - Set 8086 Mode
            Native.Out8(PIC1_Data, ICW4_8086);

            // OCW1
            Native.Out8(PIC1_Data, masterMask);

            // ICW1 - Set Initialize Controller & Expect ICW4
            Native.Out8(PIC2_Command, ICW1_Initialization + ICW1_ICW4);

            // ICW2 - interrupt offset
            Native.Out8(PIC2_Data, ICW2_SlaveOffset);

            // ICW3
            Native.Out8(PIC2_Data, 2);

            // ICW4 - Set 8086 Mode
            Native.Out8(PIC2_Data, ICW4_8086);

            // OCW1
            Native.Out8(PIC2_Data, slaveMask);
        }
Esempio n. 24
0
 /// <summary>
 /// Pseudeo devices
 /// </summary>
 public static void InitStage1()
 {
     Null = new NullDevice();
     KMsg = new KernelMessageDevice();
     KernelMessage.SetHandler(KMsg);
 }
Esempio n. 25
0
        /// <summary>
        /// Allocate a physical page from the free list
        /// </summary>
        /// <returns>The page</returns>
        Page *Allocate(uint num)
        {
            KernelMessage.Write("Request {0} pages...", num);

            var cnt = 0;

            if (lastAllocatedPage == null)
            {
                lastAllocatedPage = PageArray;
            }

            Page *p = lastAllocatedPage->Next;

            while (true)
            {
                if (p == null)
                {
                    p = PageArray;
                }

                if (p->Status == PageStatus.Free)
                {
                    var head = p;

                    // Found free Page. Check now free range.
                    for (var i = 0; i < num; i++)
                    {
                        if (p == null)
                        {
                            break;                        // Reached end. SorRange is incomplete
                        }
                        if (p->Status != PageStatus.Free) // Used -> so we can abort the searach
                        {
                            break;
                        }

                        if (i == num - 1)
                        { // all loops successful. So we found our range.
                            head->Tail      = p;
                            head->PagesUsed = num;
                            p = head;
                            for (var n = 0; n < num; n++)
                            {
                                p->Status = PageStatus.Used;
                                p->Head   = head;
                                p->Tail   = head->Tail;
                                p         = p->Next;
                                PagesUsed++;
                            }
                            lastAllocatedPage = p;

                            KernelMessage.WriteLine("Allocated from {0:X8} to {1:X8}", (uint)head->PhysicalAddress, (uint)head->Tail->PhysicalAddress);

                            return(head);
                        }

                        p = p->Next;
                    }
                }

                if (p->Tail != null)
                {
                    p = p->Tail;
                }

                p = p->Next;
                if (++cnt > PageCount)
                {
                    break;
                }
            }

            Panic.Error("PageFrameAllocator: No free Page found");
            return(null);
        }
Esempio n. 26
0
        public static void Main()
        {
            //Screen.BackgroundColor = ScreenColor.Green;
            //Screen.Color = ScreenColor.Red;
            //Screen.Clear();
            //Screen.Goto(0, 0);
            //Screen.Write('A');

            //Serial.SetupPort(Serial.COM1);
            //Serial.Write(Serial.COM1, "Hello");

            BootMemory.Setup();

            // Setup Kernel Log
            var kmsgHandler = new KernelMessageWriter();

            KernelMessage.SetHandler(kmsgHandler);
            KernelMessage.WriteLine("<LOADER:CONSOLE:BEGIN>");

            // Parse Boot Informations
            Multiboot.Setup();

            // Parse Kernel ELF section
            SetupOriginalKernelElf();

            // Print all section of Kernel ELF (for information only)
            DumpElfInfo();

            // Copy Section to a final destination
            SetupKernelSection();

            // Collection informations we need to pass to the kernel
            BootInfo_.Setup();

            // Setup Global Descriptor Table
            var map = BootMemory.AllocateMemoryMap(0x1000, BootInfoMemoryType.GDT);

            BootInfo_.AddMap(map);
            GDT.Setup(map.Start);

            // Now we enable Paging. It's important that we do not cause a Page Fault Exception,
            // Because IDT is not setup yet, that could handle this kind of exception.

            map = BootMemory.AllocateMemoryMap(PageTable.InitalPageDirectorySize, BootInfoMemoryType.PageDirectory);
            BootInfo_.AddMap(map);
            var map2 = BootMemory.AllocateMemoryMap(PageTable.InitalPageTableSize, BootInfoMemoryType.PageTable);

            BootInfo_.AddMap(map2);
            PageTable.Setup(map.Start, map2.Start);

            // Because Kernel is compiled in virtual address space, we need to remap the pages
            MapKernelImage();

            // Get Entry Point of Kernel
            uint kernelEntry = GetKernelStartAddr();

            if (kernelEntry == 0)
            {
                KernelMessage.WriteLine("No kernel entry point found {0:X8}");
                KernelMessage.WriteLine("Is the name of entry point correct?");
                KernelMessage.WriteLine("Are symbols emitted?");
                KernelMessage.WriteLine("System halt!");
                while (true)
                {
                    Native.Nop();
                }
            }
            KernelMessage.WriteLine("Call Kernel Start at {0:X8}", kernelEntry);

            // Start Kernel.
            CallAddress(kernelEntry);

            // If we hit this code location, the Kernel Main method returned.
            // This would be a general fault. Normally, this code section will overwritten
            // by the kernel, so normally, it can never reach this code position.
            KernelMessage.WriteLine("Unexpected return from Kernel Start");

            Debug.Break();
        }
Esempio n. 27
0
        public unsafe static void Main()
        {
            BootInfo.SetupStage1();

            // Field needs to be explicit set, because InitializeAssembly is not invoked yet.
            Memory.UseKernelWriteProtection = true;
            Memory.InitialKernelProtect();

            ManagedMemoy.InitializeGCMemory();
            Mosa.Runtime.StartUp.InitializeAssembly();
            //Mosa.Runtime.StartUp.InitializeRuntimeMetadata();

            ApiContext.Current = new ApiHost();

            // Setup some pseudo devices
            Devices.InitStage1();

            //Setup Output and Debug devices
            Devices.InitStage2();

            // Write first output
            KernelMessage.WriteLine("<KERNEL:CONSOLE:BEGIN>");
            KernelMessage.WriteLine("Starting Lonos Kernel...");

            // Detect environment (Memory Maps, Video Mode, etc.)
            BootInfo.SetupStage2();

            KernelMemoryMapManager.Setup();
            KernelMemoryMapManager.Allocate(0x1000 * 1000, BootInfoMemoryType.PageDirectory);

            // Read own ELF-Headers and Sections
            KernelElf.Setup();

            // Initialize the embedded code (actually only a little proof of conecept code)
            NativeCalls.Setup();

            //InitialKernelProtect();

            PageFrameManager.Setup();

            KernelMessage.WriteLine("free: {0}", PageFrameManager.PagesAvailable);
            PageFrameManager.AllocatePages(PageFrameRequestFlags.Default, 10);
            KernelMessage.WriteLine("free: {0}", PageFrameManager.PagesAvailable);
            RawVirtualFrameAllocator.Setup();

            Memory.Setup();

            // Now Memory Sub System is working. At this point it's valid
            // to allocate memory dynamicly

            Devices.InitFrameBuffer();

            // Setup Programmable Interrupt Table
            PIC.Setup();

            // Setup Interrupt Descriptor Table
            // Important Note: IDT depends on GDT. Never setup IDT before GDT.
            IDTManager.Setup();

            KernelMessage.WriteLine("Initialize Runtime Metadata");
            Mosa.Runtime.StartUp.InitializeRuntimeMetadata();

            KernelMessage.WriteLine("Performing some tests");
            Tests();

            KernelMessage.WriteLine("Enter Main Loop");
            AppMain();
        }
Esempio n. 28
0
 private static void FreeRawVirtualMemory(uint size)
 {
     KernelMessage.WriteLine("NotImplemented");;
 }
Esempio n. 29
0
 public static void DumpToConsoleLine(uint addr, uint length)
 {
     DumpToConsole(addr, length);
     KernelMessage.Write('\n');
 }