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ladybird/Kernel/init.cpp

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Kernel: Expand PATA driver to support multiple hard drives (#365) The previous implementation of the PIIX3/4 PATA/IDE channel driver only supported a single drive, as the object model was wrong (the channel inherits the IRQ, not the disk drive itself). This fixes it by 'attaching' two `PATADiskDevices` to a `PATAChannel`, which makes more sense. The reading/writing code is presented as is, which violates the spec outlined by Seagate in the linked datasheet. That spec is rather old, so it might not be 100% up to date, though may cause issues on real hardware, so until we can actually test it, this will suffice.
2019-07-28 23:44:01 +10:00
#include "Devices/PATADiskDevice.h"
Kernel: Run clang-format on everything.
2019-06-07 11:43:58 +02:00
#include "KSyms.h"
#include "Process.h"
#include "RTC.h"
#include "Scheduler.h"
Kernel: Add serial_debug cmdline parameter serial_debug will output all the kprintf and dbgprintf data to COM1 at 8-N-1 57600 baud. this is particularly useful for debugging the boot process on live hardware. Note: it must be the first parameter in the boot cmdline.
2019-08-11 14:43:38 +10:00
#include "kstdio.h"
Kernel: Run clang-format on everything.
2019-06-07 11:43:58 +02:00
#include <AK/Types.h>
Kernel: Create support for PCI ECAM The new PCI subsystem is initialized during runtime. PCI::Initializer is supposed to be called during early boot, to perform a few tests, and initialize the proper configuration space access mechanism. Kernel boot parameters can be specified by a user to determine what tests will occur, to aid debugging on problematic machines. After that, PCI::Initializer should be dismissed. PCI::IOAccess is a class that is derived from PCI::Access class and implements PCI configuration space access mechanism via x86 IO ports. PCI::MMIOAccess is a class that is derived from PCI::Access and implements PCI configurtaion space access mechanism via memory access. The new PCI subsystem also supports determination of IO/MMIO space needed by a device by checking a given BAR. In addition, Every device or component that use the PCI subsystem has changed to match the last changes.
2019-12-31 13:04:30 +02:00
#include <Kernel/ACPI/ACPIDynamicParser.h>
#include <Kernel/ACPI/ACPIStaticParser.h>
#include <Kernel/ACPI/DMIDecoder.h>
APIC: Enable APIC and start APs
2019-10-16 10:27:00 -06:00
#include <Kernel/Arch/i386/APIC.h>
Kernel: Move CPU feature detection to Arch/x86/CPU.{cpp.h} We now refuse to boot on machines that don't support PAE since all of our paging code depends on it. Also let's only enable SSE and PGE support if the CPU advertises it.
2020-01-01 12:56:21 +01:00
#include <Kernel/Arch/i386/CPU.h>
Kernel: Move PIC.cpp into Arch/i386/
2019-07-09 14:18:03 +02:00
#include <Kernel/Arch/i386/PIC.h>
Kernel: Move i8253.cpp => Arch/i386/PIT.cpp
2019-07-09 14:23:12 +02:00
#include <Kernel/Arch/i386/PIT.h>
Kernel: Initial FDC Device Driver (#315) A basic Floppy Disk Controller device driver for any system later than (and including) the IBM AT. The driver is based on the documentation supplied by QEMU, which is the datasheet for the Intel 82078 Floppy Disk controller (found here: https://wiki.qemu.org/images/f/f0/29047403.pdf) Naturally, floppy disks are a _very_ outdated storage medium, however, as Serenity is a throwback to aesthetic 90s computing, it's a definite must have. Not to mention that there are still a lot of floppy disks around, with countless petabytes of software on them, so it would be nice if people could create images of said disks with serenity. The code for this is mostly clean. however there are a LOT of values specified in the datasheet, so some of them might be wrong, not to mention that the actual specification itself is rather dirt and seemingly hacked together. I'm also only supporting 3.5" floppy disks, without PIO polling (DMA only), so if you want anything more/less than 1.44MB HD Floppys, you'll have to do it yourself.
2019-07-17 23:51:51 +10:00
#include <Kernel/CMOS.h>
Kernel: Run clang-format on everything.
2019-06-07 11:43:58 +02:00
#include <Kernel/Devices/BXVGADevice.h>
#include <Kernel/Devices/DebugLogDevice.h>
#include <Kernel/Devices/DiskPartition.h>
Kernel: Initial FDC Device Driver (#315) A basic Floppy Disk Controller device driver for any system later than (and including) the IBM AT. The driver is based on the documentation supplied by QEMU, which is the datasheet for the Intel 82078 Floppy Disk controller (found here: https://wiki.qemu.org/images/f/f0/29047403.pdf) Naturally, floppy disks are a _very_ outdated storage medium, however, as Serenity is a throwback to aesthetic 90s computing, it's a definite must have. Not to mention that there are still a lot of floppy disks around, with countless petabytes of software on them, so it would be nice if people could create images of said disks with serenity. The code for this is mostly clean. however there are a LOT of values specified in the datasheet, so some of them might be wrong, not to mention that the actual specification itself is rather dirt and seemingly hacked together. I'm also only supporting 3.5" floppy disks, without PIO polling (DMA only), so if you want anything more/less than 1.44MB HD Floppys, you'll have to do it yourself.
2019-07-17 23:51:51 +10:00
#include <Kernel/Devices/FloppyDiskDevice.h>
Kernel: Run clang-format on everything.
2019-06-07 11:43:58 +02:00
#include <Kernel/Devices/FullDevice.h>
PartitionTable: Initial GPT Support, Adding Block Limit Also added a script to handle creation of GPT partitioned disk (with GRUB config file). Block limit will be used to disallow potential access to other partitions.
2019-10-07 03:12:37 +03:00
#include <Kernel/Devices/GPTPartitionTable.h>
Kernel: Run clang-format on everything.
2019-06-07 11:43:58 +02:00
#include <Kernel/Devices/KeyboardDevice.h>
Kernel: Implement MBR partition loader (#168) This implements a basic MBR partition loader, which removes the reliance on a hard-coded filesystem offset in the stage2 init.
2019-06-02 22:57:44 +10:00
#include <Kernel/Devices/MBRPartitionTable.h>
Kernel: Implement generic VGA device using multiboot info This implements a very basic VGA device using the information provided to us by the bootloader in the multiboot header. This allows Serenity to boot to the desktop on basically any halfway modern system.
2019-08-18 14:54:52 +10:00
#include <Kernel/Devices/MBVGADevice.h>
Kernel: Move devices into Kernel/Devices/.
2019-04-03 12:36:40 +02:00
#include <Kernel/Devices/NullDevice.h>
Kernel: Expand PATA driver to support multiple hard drives (#365) The previous implementation of the PIIX3/4 PATA/IDE channel driver only supported a single drive, as the object model was wrong (the channel inherits the IRQ, not the disk drive itself). This fixes it by 'attaching' two `PATADiskDevices` to a `PATAChannel`, which makes more sense. The reading/writing code is presented as is, which violates the spec outlined by Seagate in the linked datasheet. That spec is rather old, so it might not be 100% up to date, though may cause issues on real hardware, so until we can actually test it, this will suffice.
2019-07-28 23:44:01 +10:00
#include <Kernel/Devices/PATAChannel.h>
Kernel: Run clang-format on everything.
2019-06-07 11:43:58 +02:00
#include <Kernel/Devices/PS2MouseDevice.h>
Kernel: Move devices into Kernel/Devices/.
2019-04-03 12:36:40 +02:00
#include <Kernel/Devices/RandomDevice.h>
Kernel: Expand PATA driver to support multiple hard drives (#365) The previous implementation of the PIIX3/4 PATA/IDE channel driver only supported a single drive, as the object model was wrong (the channel inherits the IRQ, not the disk drive itself). This fixes it by 'attaching' two `PATADiskDevices` to a `PATAChannel`, which makes more sense. The reading/writing code is presented as is, which violates the spec outlined by Seagate in the linked datasheet. That spec is rather old, so it might not be 100% up to date, though may cause issues on real hardware, so until we can actually test it, this will suffice.
2019-07-28 23:44:01 +10:00
#include <Kernel/Devices/SB16.h>
Kernel: Implement serial port driver This implements a basic 8250 UART serial port driver. It does not currently handle (or enable) interrupts, nor any runtime configuration.
2019-06-08 23:24:34 +10:00
#include <Kernel/Devices/SerialDevice.h>
Kernel: Run clang-format on everything.
2019-06-07 11:43:58 +02:00
#include <Kernel/Devices/ZeroDevice.h>
#include <Kernel/FileSystem/DevPtsFS.h>
Kernel: Move FS-related files into Kernel/FileSystem/
2019-04-03 12:25:24 +02:00
#include <Kernel/FileSystem/Ext2FileSystem.h>
#include <Kernel/FileSystem/ProcFS.h>
Kernel: Add TmpFS This is an FS that stores all of its contents directly in memory. It's mounted on /tmp by default.
2019-08-15 18:16:45 +03:00
#include <Kernel/FileSystem/TmpFS.h>
Kernel: Run clang-format on everything.
2019-06-07 11:43:58 +02:00
#include <Kernel/FileSystem/VirtualFileSystem.h>
Kernel: Add a simple slab allocator for small allocations This is a freelist allocator with static size classes that works as a complement to the generic kmalloc(). It's a lot faster than kmalloc() since allocation just means popping from the freelist. It's also significantly more compact when there are a lot of objects smaller than the minimum kmalloc chunk size (32 bytes.) This patch enables it for the Region and PhysicalPage classes. In the PhysicalPage (8 bytes) case, it's a huge improvement since we no longer waste 75% of the storage allocated. There are also a number of ways this can be improved, so let's keep working on it going forward.
2019-09-16 10:19:44 +02:00
#include <Kernel/Heap/SlabAllocator.h>
Kernel: Move kmalloc() into a Kernel/Heap/ directory
2019-09-16 09:01:44 +02:00
#include <Kernel/Heap/kmalloc.h>
Kernel: Run clang-format on everything.
2019-06-07 11:43:58 +02:00
#include <Kernel/KParams.h>
#include <Kernel/Multiboot.h>
Kernel: Move networking related files into Kernel/Net/.
2019-04-02 19:54:38 +02:00
#include <Kernel/Net/E1000NetworkAdapter.h>
Kernel: Remove specific devices from network code By setting up the devices in init() and looping over the registered network adapters in NetworkTask_main, we can remove the remaining hard-coded adapter references from the network code. This also assigns IPs according to the default range supplied by QEMU in its slirp networking mode.
2019-08-28 21:53:01 +10:00
#include <Kernel/Net/LoopbackAdapter.h>
Kernel: Move networking related files into Kernel/Net/.
2019-04-02 19:54:38 +02:00
#include <Kernel/Net/NetworkTask.h>
Kernel: Implement rtl8139 network interface driver
2019-08-22 01:06:55 +10:00
#include <Kernel/Net/RTL8139NetworkAdapter.h>
Kernel: Create support for PCI ECAM The new PCI subsystem is initialized during runtime. PCI::Initializer is supposed to be called during early boot, to perform a few tests, and initialize the proper configuration space access mechanism. Kernel boot parameters can be specified by a user to determine what tests will occur, to aid debugging on problematic machines. After that, PCI::Initializer should be dismissed. PCI::IOAccess is a class that is derived from PCI::Access class and implements PCI configuration space access mechanism via x86 IO ports. PCI::MMIOAccess is a class that is derived from PCI::Access and implements PCI configurtaion space access mechanism via memory access. The new PCI subsystem also supports determination of IO/MMIO space needed by a device by checking a given BAR. In addition, Every device or component that use the PCI subsystem has changed to match the last changes.
2019-12-31 13:04:30 +02:00
#include <Kernel/PCI/Access.h>
#include <Kernel/PCI/Initializer.h>
Kernel: Randomize the stack canary on startup
2020-01-06 13:05:40 +01:00
#include <Kernel/Random.h>
Kernel: Run clang-format on everything.
2019-06-07 11:43:58 +02:00
#include <Kernel/TTY/PTYMultiplexer.h>
#include <Kernel/TTY/VirtualConsole.h>
#include <Kernel/VM/MemoryManager.h>
Import the "gerbert" kernel I worked on earlier this year. It's a lot crappier than I remembered it. It's gonna need a lot of work.
2018-10-16 11:01:38 +02:00
Start working on virtual consoles/TTYs. This is a mess right now, but I'd rather commit as I go.
2018-10-30 13:59:29 +01:00
VirtualConsole* tty0;
VirtualConsole* tty1;
Kernel: Rename Keyboard to KeyboardDevice.
2019-02-17 08:39:09 +01:00
KeyboardDevice* keyboard;
Add a simple PS/2 mouse device. It's not hooked up to anything just yet, but it does read movement deltas.
2019-01-11 02:28:53 +01:00
PS2MouseDevice* ps2mouse;
Kernel: First cut of a sb16 driver Also add an AudioServer that (right now) doesn't do much. It tries to open, parse, and play a wav file. In the future, it can do more. My general thinking here here is that /dev/audio will be "owned" by AudioServer, and we'll do mixing in software before passing buffers off to the kernel to play, but we have to start somewhere.
2019-07-12 19:28:01 +02:00
SB16* sb16;
Kernel+LibC: Add a DebugLogDevice that forwards everything to I/O port 0xe9. This is then used to implement the userspace dbgprintf() in a far more efficient way than what we had before. :^)
2019-04-18 16:08:52 +02:00
DebugLogDevice* dev_debuglog;
Kernel: Make sure processes always start out with fds 0, 1 and 2 open. If we don't have a TTY for the process, fall back to /dev/null.
2019-02-12 11:25:25 +01:00
NullDevice* dev_null;
Kernel: Implement serial port driver This implements a basic 8250 UART serial port driver. It does not currently handle (or enable) interrupts, nor any runtime configuration.
2019-06-08 23:24:34 +10:00
SerialDevice* ttyS0;
SerialDevice* ttyS1;
SerialDevice* ttyS2;
SerialDevice* ttyS3;
Rework WindowServer to use select() in its main event loop. The system can finally idle without burning CPU. :^) There are some issues with scheduling making the mouse cursor sloppy and unresponsive that need to be dealt with.
2019-01-16 17:20:58 +01:00
VFS* vfs;
Start working on virtual consoles/TTYs. This is a mess right now, but I'd rather commit as I go.
2018-10-30 13:59:29 +01:00
Use modern C++ attributes instead of __attribute__ voodoo. This is quite nice, although I wish [[gnu::always_inline]] implied inline. Also "gnu::" is kind of a wart, but whatcha gonna do.
2019-02-15 12:30:48 +01:00
[[noreturn]] static void init_stage2()
Import the "gerbert" kernel I worked on earlier this year. It's a lot crappier than I remembered it. It's gonna need a lot of work.
2018-10-16 11:01:38 +02:00
{
Syscall::initialize();
VFS mounts an ext2fs root! :^)
2018-10-17 11:44:06 +02:00
auto dev_zero = make<ZeroDevice>();
Add the basic character devices to kernel.
2018-10-16 14:33:16 +02:00
auto dev_full = make<FullDevice>();
auto dev_random = make<RandomDevice>();
Add a PTY multiplexer (/dev/ptmx) device. When you open /dev/ptmx, you get a file descriptor pointing to one of the available MasterPTY's. If none are available, you get an EBUSY. This makes it possible to open multiple (up to 4) Terminals. :^) To support this, I also added a CharacterDevice::open() that gets control when VFS is opening a CharacterDevice. This is useful when we want to return a custom FileDescriptor like we do here.
2019-01-16 13:36:10 +01:00
auto dev_ptmx = make<PTYMultiplexer>();
Kernel: Implement MBR partition loader (#168) This implements a basic MBR partition loader, which removes the reliance on a hard-coded filesystem offset in the stage2 init.
2019-06-02 22:57:44 +10:00
Kernel: Use KParams::has() instead of !KParams::get().is_null() Also rename a local variable to be consistent with what it represents.
2019-11-06 11:45:52 +01:00
bool text_debug = KParams::the().has("text_debug");
Kernel: Add a kernel boot parameter to force PIO mode Also added an option in the run script to force PIO operation mode with the IDE controller. In addition, we're no longer limited to PIIX3 and PIIX4 chipsets for DMA
2019-11-13 19:29:16 +02:00
bool force_pio = KParams::the().has("force_pio");
Kernel: Enabling Text mode debugging (#696) Also added an option to start Serenity with text mode in QEMU in the run script.
2019-10-29 17:41:40 +02:00
Kernel: Parse cmdline for root filesystem e.g. root=/dev/hda1 This introduces very basic handling of the kernel command line to choose the root filesystem at startup. Given that we currently only support a single IDE hard drive, it's hard-coded to look for `/dev/hda` at the start of the argument. If there is nothing following this, or if the parameter is empty, init_stage2 will try to load the ext2 filesystem from the start of the device. This is intended to be the default behaviour when running development builds, as it is faster to set up and doesn't require a working grub installation. If `/dev/hda` is followed by a number, init_stage2 will try to read an MBR partition header from the drive, then load the requested partition. It will reject non-numeric trailing data, and anything outside of partitions one through four.
2019-06-04 22:03:35 +10:00
auto root = KParams::the().get("root");
if (root.is_empty()) {
root = "/dev/hda";
}
Kernel: Implement MBR partition loader (#168) This implements a basic MBR partition loader, which removes the reliance on a hard-coded filesystem offset in the stage2 init.
2019-06-02 22:57:44 +10:00
Kernel: Parse cmdline for root filesystem e.g. root=/dev/hda1 This introduces very basic handling of the kernel command line to choose the root filesystem at startup. Given that we currently only support a single IDE hard drive, it's hard-coded to look for `/dev/hda` at the start of the argument. If there is nothing following this, or if the parameter is empty, init_stage2 will try to load the ext2 filesystem from the start of the device. This is intended to be the default behaviour when running development builds, as it is faster to set up and doesn't require a working grub installation. If `/dev/hda` is followed by a number, init_stage2 will try to read an MBR partition header from the drive, then load the requested partition. It will reject non-numeric trailing data, and anything outside of partitions one through four.
2019-06-04 22:03:35 +10:00
if (!root.starts_with("/dev/hda")) {
kprintf("init_stage2: root filesystem must be on the first IDE hard drive (/dev/hda)\n");
Kernel: Implement MBR partition loader (#168) This implements a basic MBR partition loader, which removes the reliance on a hard-coded filesystem offset in the stage2 init.
2019-06-02 22:57:44 +10:00
hang();
}
Kernel: Add a kernel boot parameter to force PIO mode Also added an option in the run script to force PIO operation mode with the IDE controller. In addition, we're no longer limited to PIIX3 and PIIX4 chipsets for DMA
2019-11-13 19:29:16 +02:00
auto pata0 = PATAChannel::create(PATAChannel::ChannelType::Primary, force_pio);
Kernel: Expand PATA driver to support multiple hard drives (#365) The previous implementation of the PIIX3/4 PATA/IDE channel driver only supported a single drive, as the object model was wrong (the channel inherits the IRQ, not the disk drive itself). This fixes it by 'attaching' two `PATADiskDevices` to a `PATAChannel`, which makes more sense. The reading/writing code is presented as is, which violates the spec outlined by Seagate in the linked datasheet. That spec is rather old, so it might not be 100% up to date, though may cause issues on real hardware, so until we can actually test it, this will suffice.
2019-07-28 23:44:01 +10:00
NonnullRefPtr<DiskDevice> root_dev = *pata0->master_device();
Kernel: Parse cmdline for root filesystem e.g. root=/dev/hda1 This introduces very basic handling of the kernel command line to choose the root filesystem at startup. Given that we currently only support a single IDE hard drive, it's hard-coded to look for `/dev/hda` at the start of the argument. If there is nothing following this, or if the parameter is empty, init_stage2 will try to load the ext2 filesystem from the start of the device. This is intended to be the default behaviour when running development builds, as it is faster to set up and doesn't require a working grub installation. If `/dev/hda` is followed by a number, init_stage2 will try to read an MBR partition header from the drive, then load the requested partition. It will reject non-numeric trailing data, and anything outside of partitions one through four.
2019-06-04 22:03:35 +10:00
root = root.substring(strlen("/dev/hda"), root.length() - strlen("/dev/hda"));
if (root.length()) {
bool ok;
unsigned partition_number = root.to_uint(ok);
if (!ok) {
kprintf("init_stage2: couldn't parse partition number from root kernel parameter\n");
hang();
}
if (partition_number < 1 || partition_number > 4) {
kprintf("init_stage2: invalid partition number %d; expected 1 to 4\n", partition_number);
hang();
}
Kernel: Remove use of copy_ref() in favor of regular RefPtr copies. This is obviously more readable. If we ever run into a situation where ref count churn is actually causing trouble in the future, we can deal with it then. For now, let's keep it simple. :^)
2019-07-11 15:38:47 +02:00
MBRPartitionTable mbr(root_dev);
PartitionTable: Initial GPT Support, Adding Block Limit Also added a script to handle creation of GPT partitioned disk (with GRUB config file). Block limit will be used to disallow potential access to other partitions.
2019-10-07 03:12:37 +03:00
Kernel: Parse cmdline for root filesystem e.g. root=/dev/hda1 This introduces very basic handling of the kernel command line to choose the root filesystem at startup. Given that we currently only support a single IDE hard drive, it's hard-coded to look for `/dev/hda` at the start of the argument. If there is nothing following this, or if the parameter is empty, init_stage2 will try to load the ext2 filesystem from the start of the device. This is intended to be the default behaviour when running development builds, as it is faster to set up and doesn't require a working grub installation. If `/dev/hda` is followed by a number, init_stage2 will try to read an MBR partition header from the drive, then load the requested partition. It will reject non-numeric trailing data, and anything outside of partitions one through four.
2019-06-04 22:03:35 +10:00
if (!mbr.initialize()) {
kprintf("init_stage2: couldn't read MBR from disk\n");
hang();
}
PartitionTable: Initial GPT Support, Adding Block Limit Also added a script to handle creation of GPT partitioned disk (with GRUB config file). Block limit will be used to disallow potential access to other partitions.
2019-10-07 03:12:37 +03:00
if (mbr.is_protective_mbr()) {
dbgprintf("GPT Partitioned Storage Detected!\n");
GPTPartitionTable gpt(root_dev);
if (!gpt.initialize()) {
kprintf("init_stage2: couldn't read GPT from disk\n");
hang();
}
auto partition = gpt.partition(partition_number);
if (!partition) {
kprintf("init_stage2: couldn't get partition %d\n", partition_number);
hang();
}
root_dev = *partition;
} else {
dbgprintf("MBR Partitioned Storage Detected!\n");
auto partition = mbr.partition(partition_number);
if (!partition) {
kprintf("init_stage2: couldn't get partition %d\n", partition_number);
hang();
}
root_dev = *partition;
Kernel: Parse cmdline for root filesystem e.g. root=/dev/hda1 This introduces very basic handling of the kernel command line to choose the root filesystem at startup. Given that we currently only support a single IDE hard drive, it's hard-coded to look for `/dev/hda` at the start of the argument. If there is nothing following this, or if the parameter is empty, init_stage2 will try to load the ext2 filesystem from the start of the device. This is intended to be the default behaviour when running development builds, as it is faster to set up and doesn't require a working grub installation. If `/dev/hda` is followed by a number, init_stage2 will try to read an MBR partition header from the drive, then load the requested partition. It will reject non-numeric trailing data, and anything outside of partitions one through four.
2019-06-04 22:03:35 +10:00
}
Kernel: Implement MBR partition loader (#168) This implements a basic MBR partition loader, which removes the reliance on a hard-coded filesystem offset in the stage2 init.
2019-06-02 22:57:44 +10:00
}
Kernel: Remove use of copy_ref() in favor of regular RefPtr copies. This is obviously more readable. If we ever run into a situation where ref count churn is actually causing trouble in the future, we can deal with it then. For now, let's keep it simple. :^)
2019-07-11 15:38:47 +02:00
auto e2fs = Ext2FS::create(root_dev);
Kernel: Implement MBR partition loader (#168) This implements a basic MBR partition loader, which removes the reliance on a hard-coded filesystem offset in the stage2 init.
2019-06-02 22:57:44 +10:00
if (!e2fs->initialize()) {
Kernel: Parse cmdline for root filesystem e.g. root=/dev/hda1 This introduces very basic handling of the kernel command line to choose the root filesystem at startup. Given that we currently only support a single IDE hard drive, it's hard-coded to look for `/dev/hda` at the start of the argument. If there is nothing following this, or if the parameter is empty, init_stage2 will try to load the ext2 filesystem from the start of the device. This is intended to be the default behaviour when running development builds, as it is faster to set up and doesn't require a working grub installation. If `/dev/hda` is followed by a number, init_stage2 will try to read an MBR partition header from the drive, then load the requested partition. It will reject non-numeric trailing data, and anything outside of partitions one through four.
2019-06-04 22:03:35 +10:00
kprintf("init_stage2: couldn't open root filesystem\n");
Kernel: Implement MBR partition loader (#168) This implements a basic MBR partition loader, which removes the reliance on a hard-coded filesystem offset in the stage2 init.
2019-06-02 22:57:44 +10:00
hang();
}
Integrate ext2 from VFS into Kernel.
2018-10-17 10:55:43 +02:00
Kernel: Just hang if VFS::mount_root() fails
2019-11-17 18:58:25 +01:00
if (!vfs->mount_root(e2fs)) {
kprintf("VFS::mount_root failed\n");
hang();
}
VFS mounts an ext2fs root! :^)
2018-10-17 11:44:06 +02:00
Kernel: Add a basic chroot() syscall :^) The chroot() syscall now allows the superuser to isolate a process into a specific subtree of the filesystem. This is not strictly permanent, as it is also possible for a superuser to break *out* of a chroot, but it is a useful mechanism for isolating unprivileged processes. The VFS now uses the current process's root_directory() as the root for path resolution purposes. The root directory is stored as an uncached Custody in the Process object.
2020-01-10 23:14:04 +01:00
current->process().set_root_directory(vfs->root_custody());
Kernel: Introduce threads, and refactor everything in support of it. The scheduler now operates on threads, rather than on processes. Each process has a main thread, and can have any number of additional threads. The process exits when the main thread exits. This patch doesn't actually spawn any additional threads, it merely does all the plumbing needed to make it possible. :^)
2019-03-23 22:03:17 +01:00
dbgprintf("Load ksyms\n");
Move kernel symbolication code out of init.cpp and into its own KSym files. Also use a simple array of { dword, const char* } for the KSyms and put the whole shebang in kmalloc_eternal() memory. This was a fugly source of kmalloc perma-frag.
2018-12-24 22:59:10 +01:00
load_ksyms();
Kernel: Introduce threads, and refactor everything in support of it. The scheduler now operates on threads, rather than on processes. Each process has a main thread, and can have any number of additional threads. The process exits when the main thread exits. This patch doesn't actually spawn any additional threads, it merely does all the plumbing needed to make it possible. :^)
2019-03-23 22:03:17 +01:00
dbgprintf("Loaded ksyms\n");
Add a very hackish /proc/PID/stack. It walks the stack and identifies anything that looks like a kernel symbol. This could be a lot more sophisticated.
2018-10-26 22:32:35 +02:00
Kernel: Initial FDC Device Driver (#315) A basic Floppy Disk Controller device driver for any system later than (and including) the IBM AT. The driver is based on the documentation supplied by QEMU, which is the datasheet for the Intel 82078 Floppy Disk controller (found here: https://wiki.qemu.org/images/f/f0/29047403.pdf) Naturally, floppy disks are a _very_ outdated storage medium, however, as Serenity is a throwback to aesthetic 90s computing, it's a definite must have. Not to mention that there are still a lot of floppy disks around, with countless petabytes of software on them, so it would be nice if people could create images of said disks with serenity. The code for this is mostly clean. however there are a LOT of values specified in the datasheet, so some of them might be wrong, not to mention that the actual specification itself is rather dirt and seemingly hacked together. I'm also only supporting 3.5" floppy disks, without PIO polling (DMA only), so if you want anything more/less than 1.44MB HD Floppys, you'll have to do it yourself.
2019-07-17 23:51:51 +10:00
// Now, detect whether or not there are actually any floppy disks attached to the system
u8 detect = CMOS::read(0x10);
RefPtr<FloppyDiskDevice> fd0;
RefPtr<FloppyDiskDevice> fd1;
if ((detect >> 4) & 0x4) {
fd0 = FloppyDiskDevice::create(FloppyDiskDevice::DriveType::Master);
kprintf("fd0 is 1.44MB floppy drive\n");
} else {
kprintf("fd0 type unsupported! Type == 0x%x\n", detect >> 4);
}
if (detect & 0x0f) {
Kernel: fix typo regarding floppy drives in init_stage2
2019-07-30 11:29:45 +10:00
fd1 = FloppyDiskDevice::create(FloppyDiskDevice::DriveType::Slave);
Kernel: Initial FDC Device Driver (#315) A basic Floppy Disk Controller device driver for any system later than (and including) the IBM AT. The driver is based on the documentation supplied by QEMU, which is the datasheet for the Intel 82078 Floppy Disk controller (found here: https://wiki.qemu.org/images/f/f0/29047403.pdf) Naturally, floppy disks are a _very_ outdated storage medium, however, as Serenity is a throwback to aesthetic 90s computing, it's a definite must have. Not to mention that there are still a lot of floppy disks around, with countless petabytes of software on them, so it would be nice if people could create images of said disks with serenity. The code for this is mostly clean. however there are a LOT of values specified in the datasheet, so some of them might be wrong, not to mention that the actual specification itself is rather dirt and seemingly hacked together. I'm also only supporting 3.5" floppy disks, without PIO polling (DMA only), so if you want anything more/less than 1.44MB HD Floppys, you'll have to do it yourself.
2019-07-17 23:51:51 +10:00
kprintf("fd1 is 1.44MB floppy drive");
} else {
kprintf("fd1 type unsupported! Type == 0x%x\n", detect & 0x0f);
}
Virtual consoles kinda work! We now make three VirtualConsoles at boot: tty0, tty1, and tty2. We launch an instance of /bin/sh in each one. You switch between them with Alt+1/2/3 How very very cool :^)
2018-10-30 15:33:37 +01:00
int error;
Kernel: Don't bother trying to pass environment to init's testing processes.
2019-02-12 10:19:52 +01:00
Kernel: Disable VGA console in graphical mode
2019-08-18 12:04:09 +10:00
// SystemServer will start WindowServer, which will be doing graphics.
// From this point on we don't want to touch the VGA text terminal or
// accept keyboard input.
Kernel: Use KParams::has() instead of !KParams::get().is_null() Also rename a local variable to be consistent with what it represents.
2019-11-06 11:45:52 +01:00
if (text_debug) {
Kernel: Enabling Text mode debugging (#696) Also added an option to start Serenity with text mode in QEMU in the run script.
2019-10-29 17:41:40 +02:00
tty0->set_graphical(false);
Kernel: Get rid of "main thread" concept The idea of all processes reliably having a main thread was nice in some ways, but cumbersome in others. More importantly, it didn't match up with POSIX thread semantics, so let's move away from it. This thread gets rid of Process::main_thread() and you now we just have a bunch of Thread objects floating around each Process. When the finalizer nukes the last Thread in a Process, it will also tear down the Process. There's a bunch of more things to fix around this, but this is where we get started :^)
2019-12-22 11:35:02 +01:00
Thread* thread = nullptr;
Process::create_user_process(thread, "/bin/Shell", (uid_t)0, (gid_t)0, (pid_t)0, error, {}, {}, tty0);
Kernel: Enabling Text mode debugging (#696) Also added an option to start Serenity with text mode in QEMU in the run script.
2019-10-29 17:41:40 +02:00
if (error != 0) {
kprintf("init_stage2: error spawning Shell: %d\n", error);
hang();
}
Kernel: Refactor scheduler to use dynamic thread priorities Threads now have numeric priorities with a base priority in the 1-99 range. Whenever a runnable thread is *not* scheduled, its effective priority is incremented by 1. This is tracked in Thread::m_extra_priority. The effective priority of a thread is m_priority + m_extra_priority. When a runnable thread *is* scheduled, its m_extra_priority is reset to zero and the effective priority returns to base. This means that lower-priority threads will always eventually get scheduled to run, once its effective priority becomes high enough to exceed the base priority of threads "above" it. The previous values for ThreadPriority (Low, Normal and High) are now replaced as follows: Low -> 10 Normal -> 30 High -> 50 In other words, it will take 20 ticks for a "Low" priority thread to get to "Normal" effective priority, and another 20 to reach "High". This is not perfect, and I've used some quite naive data structures, but I think the mechanism will allow us to build various new and interesting optimizations, and we can figure out better data structures later on. :^)
2019-12-30 18:46:17 +01:00
thread->set_priority(THREAD_PRIORITY_HIGH);
Kernel: Enabling Text mode debugging (#696) Also added an option to start Serenity with text mode in QEMU in the run script.
2019-10-29 17:41:40 +02:00
} else {
tty0->set_graphical(true);
Kernel: Get rid of "main thread" concept The idea of all processes reliably having a main thread was nice in some ways, but cumbersome in others. More importantly, it didn't match up with POSIX thread semantics, so let's move away from it. This thread gets rid of Process::main_thread() and you now we just have a bunch of Thread objects floating around each Process. When the finalizer nukes the last Thread in a Process, it will also tear down the Process. There's a bunch of more things to fix around this, but this is where we get started :^)
2019-12-22 11:35:02 +01:00
Thread* thread = nullptr;
Process::create_user_process(thread, "/bin/SystemServer", (uid_t)0, (gid_t)0, (pid_t)0, error, {}, {}, tty0);
Kernel: Enabling Text mode debugging (#696) Also added an option to start Serenity with text mode in QEMU in the run script.
2019-10-29 17:41:40 +02:00
if (error != 0) {
kprintf("init_stage2: error spawning SystemServer: %d\n", error);
hang();
}
Kernel: Refactor scheduler to use dynamic thread priorities Threads now have numeric priorities with a base priority in the 1-99 range. Whenever a runnable thread is *not* scheduled, its effective priority is incremented by 1. This is tracked in Thread::m_extra_priority. The effective priority of a thread is m_priority + m_extra_priority. When a runnable thread *is* scheduled, its m_extra_priority is reset to zero and the effective priority returns to base. This means that lower-priority threads will always eventually get scheduled to run, once its effective priority becomes high enough to exceed the base priority of threads "above" it. The previous values for ThreadPriority (Low, Normal and High) are now replaced as follows: Low -> 10 Normal -> 30 High -> 50 In other words, it will take 20 ticks for a "Low" priority thread to get to "Normal" effective priority, and another 20 to reach "High". This is not perfect, and I've used some quite naive data structures, but I think the mechanism will allow us to build various new and interesting optimizations, and we can figure out better data structures later on. :^)
2019-12-30 18:46:17 +01:00
thread->set_priority(THREAD_PRIORITY_HIGH);
Kernel: Get rid of "main thread" concept The idea of all processes reliably having a main thread was nice in some ways, but cumbersome in others. More importantly, it didn't match up with POSIX thread semantics, so let's move away from it. This thread gets rid of Process::main_thread() and you now we just have a bunch of Thread objects floating around each Process. When the finalizer nukes the last Thread in a Process, it will also tear down the Process. There's a bunch of more things to fix around this, but this is where we get started :^)
2019-12-22 11:35:02 +01:00
}
{
Thread* thread = nullptr;
Process::create_kernel_process(thread, "NetworkTask", NetworkTask_main);
LibC: Implement gethostbyname() by talking to the DNSLookupServer. We now talk to the lookup server over a local socket and it does the lookup on our behalf. Including some retry logic, which is nice, because it seems like DNS requests disappear in the ether pretty damn often where I am.
2019-03-20 01:15:22 +01:00
}
Kernel: Run NetworkTask in init stage 2 to allow use of locks
2019-08-28 10:56:05 +10:00
Kernel: Introduce threads, and refactor everything in support of it. The scheduler now operates on threads, rather than on processes. Each process has a main thread, and can have any number of additional threads. The process exits when the main thread exits. This patch doesn't actually spawn any additional threads, it merely does all the plumbing needed to make it possible. :^)
2019-03-23 22:03:17 +01:00
current->process().sys$exit(0);
Finally unbreak the colonel process and make it the true idle process.
2018-11-07 23:13:38 +01:00
ASSERT_NOT_REACHED();
A lot of hacking: - More work on funneling console output through Console. - init() now breaks off into a separate task ASAP. - ..this leaves the "colonel" task as a simple hlt idle loop. - Mask all IRQs on startup (except IRQ2 for slave passthru) - Fix underallocation bug in Task::allocateRegion(). - Remember how many times each Task has been scheduled. The panel and scheduling banner are disabled until I get things working nicely in the (brave) new Console world.
2018-10-22 11:15:16 +02:00
}
Kernel: Make better use of the multiboot info. Define the multiboot info struct properly so we don't have to grab at byte offsets in the memory access checker code. Also print kernel command line in init().
2019-06-02 09:50:18 +02:00
extern "C" {
multiboot_info_t* multiboot_info_ptr;
}
Kernel: Move CPU feature detection to Arch/x86/CPU.{cpp.h} We now refuse to boot on machines that don't support PAE since all of our paging code depends on it. Also let's only enable SSE and PGE support if the CPU advertises it.
2020-01-01 12:56:21 +01:00
typedef void (*ctor_func_t)();
Kernel: Add bare minimum for global constructors (#707) Add text.startup to the .text block, add .ctors as well. Use them in init.cpp to call global constructors after gtd and idt init. That way any funky constructors should be ok. Also defines some Itanium C++ ABI methods that probably shouldn't be, but without them the linker gets very angry. If the code ever actually tries to use __dso_handle or call __cxa_atexit, there's bigger problems with the kernel. Bit of a hack would be an understatement but hey. It works :)
2019-10-31 12:01:13 -06:00
// Defined in the linker script
extern ctor_func_t start_ctors;
extern ctor_func_t end_ctors;
// Define some Itanium C++ ABI methods to stop the linker from complaining
// If we actually call these something has gone horribly wrong
Kernel: Move CPU feature detection to Arch/x86/CPU.{cpp.h} We now refuse to boot on machines that don't support PAE since all of our paging code depends on it. Also let's only enable SSE and PGE support if the CPU advertises it.
2020-01-01 12:56:21 +01:00
void* __dso_handle __attribute__((visibility("hidden")));
Kernel: Add bare minimum for global constructors (#707) Add text.startup to the .text block, add .ctors as well. Use them in init.cpp to call global constructors after gtd and idt init. That way any funky constructors should be ok. Also defines some Itanium C++ ABI methods that probably shouldn't be, but without them the linker gets very angry. If the code ever actually tries to use __dso_handle or call __cxa_atexit, there's bigger problems with the kernel. Bit of a hack would be an understatement but hey. It works :)
2019-10-31 12:01:13 -06:00
Kernel: Move CPU feature detection to Arch/x86/CPU.{cpp.h} We now refuse to boot on machines that don't support PAE since all of our paging code depends on it. Also let's only enable SSE and PGE support if the CPU advertises it.
2020-01-01 12:56:21 +01:00
extern "C" int __cxa_atexit(void (*)(void*), void*, void*)
Kernel: Add bare minimum for global constructors (#707) Add text.startup to the .text block, add .ctors as well. Use them in init.cpp to call global constructors after gtd and idt init. That way any funky constructors should be ok. Also defines some Itanium C++ ABI methods that probably shouldn't be, but without them the linker gets very angry. If the code ever actually tries to use __dso_handle or call __cxa_atexit, there's bigger problems with the kernel. Bit of a hack would be an understatement but hey. It works :)
2019-10-31 12:01:13 -06:00
{
ASSERT_NOT_REACHED();
return 0;
}
Kernel: Randomize the stack canary on startup
2020-01-06 13:05:40 +01:00
extern u32 __stack_chk_guard;
u32 __stack_chk_guard;
Kernel: Removing hardcoded offsets from Memory Manager Now the kernel page directory and the page tables are located at a safe address, to prevent from paging data colliding with garbage.
2019-11-08 16:37:33 +02:00
extern "C" [[noreturn]] void init(u32 physical_address_for_kernel_page_tables)
A lot of hacking: - More work on funneling console output through Console. - init() now breaks off into a separate task ASAP. - ..this leaves the "colonel" task as a simple hlt idle loop. - Mask all IRQs on startup (except IRQ2 for slave passthru) - Fix underallocation bug in Task::allocateRegion(). - Remember how many times each Task has been scheduled. The panel and scheduling banner are disabled until I get things working nicely in the (brave) new Console world.
2018-10-22 11:15:16 +02:00
{
Kernel: Add serial_debug cmdline parameter serial_debug will output all the kprintf and dbgprintf data to COM1 at 8-N-1 57600 baud. this is particularly useful for debugging the boot process on live hardware. Note: it must be the first parameter in the boot cmdline.
2019-08-11 14:43:38 +10:00
// this is only used one time, directly below here. we can't use this part
// of libc at this point in the boot process, or we'd just pull strstr in
// from <string.h>.
Kernel: Move kmalloc() into a Kernel/Heap/ directory
2019-09-16 09:01:44 +02:00
auto bad_prefix_check = [](const char* str, const char* search) -> bool {
Kernel: Add serial_debug cmdline parameter serial_debug will output all the kprintf and dbgprintf data to COM1 at 8-N-1 57600 baud. this is particularly useful for debugging the boot process on live hardware. Note: it must be the first parameter in the boot cmdline.
2019-08-11 14:43:38 +10:00
while (*search)
if (*search++ != *str++)
return false;
return true;
};
// serial_debug will output all the kprintf and dbgprintf data to COM1 at
// 8-N-1 57600 baud. this is particularly useful for debugging the boot
// process on live hardware.
//
// note: it must be the first option in the boot cmdline.
if (multiboot_info_ptr->cmdline && bad_prefix_check(reinterpret_cast<const char*>(multiboot_info_ptr->cmdline), "serial_debug"))
set_serial_debug(true);
Kernel: Move CPU feature detection to Arch/x86/CPU.{cpp.h} We now refuse to boot on machines that don't support PAE since all of our paging code depends on it. Also let's only enable SSE and PGE support if the CPU advertises it.
2020-01-01 12:56:21 +01:00
detect_cpu_features();
Kernel: Initialize the CPU to allow SSE on startup. I still need to add support for SSE to the context switching code, but now at least one process can use it.
2019-03-27 13:40:00 +01:00
A lot of hacking: - More work on funneling console output through Console. - init() now breaks off into a separate task ASAP. - ..this leaves the "colonel" task as a simple hlt idle loop. - Mask all IRQs on startup (except IRQ2 for slave passthru) - Fix underallocation bug in Task::allocateRegion(). - Remember how many times each Task has been scheduled. The panel and scheduling banner are disabled until I get things working nicely in the (brave) new Console world.
2018-10-22 11:15:16 +02:00
kmalloc_init();
Kernel: Add a simple slab allocator for small allocations This is a freelist allocator with static size classes that works as a complement to the generic kmalloc(). It's a lot faster than kmalloc() since allocation just means popping from the freelist. It's also significantly more compact when there are a lot of objects smaller than the minimum kmalloc chunk size (32 bytes.) This patch enables it for the Region and PhysicalPage classes. In the PhysicalPage (8 bytes) case, it's a huge improvement since we no longer waste 75% of the storage allocated. There are also a number of ways this can be improved, so let's keep working on it going forward.
2019-09-16 10:19:44 +02:00
slab_alloc_init();
A lot of hacking: - More work on funneling console output through Console. - init() now breaks off into a separate task ASAP. - ..this leaves the "colonel" task as a simple hlt idle loop. - Mask all IRQs on startup (except IRQ2 for slave passthru) - Fix underallocation bug in Task::allocateRegion(). - Remember how many times each Task has been scheduled. The panel and scheduling banner are disabled until I get things working nicely in the (brave) new Console world.
2018-10-22 11:15:16 +02:00
Kernel: Add KParams class for accessing kernel cmdline parameters (#188)
2019-06-04 20:54:27 +10:00
// must come after kmalloc_init because we use AK_MAKE_ETERNAL in KParams
new KParams(String(reinterpret_cast<const char*>(multiboot_info_ptr->cmdline)));
Kernel: Use KParams::has() instead of !KParams::get().is_null() Also rename a local variable to be consistent with what it represents.
2019-11-06 11:45:52 +01:00
bool text_debug = KParams::the().has("text_debug");
Kernel: Create support for PCI ECAM The new PCI subsystem is initialized during runtime. PCI::Initializer is supposed to be called during early boot, to perform a few tests, and initialize the proper configuration space access mechanism. Kernel boot parameters can be specified by a user to determine what tests will occur, to aid debugging on problematic machines. After that, PCI::Initializer should be dismissed. PCI::IOAccess is a class that is derived from PCI::Access class and implements PCI configuration space access mechanism via x86 IO ports. PCI::MMIOAccess is a class that is derived from PCI::Access and implements PCI configurtaion space access mechanism via memory access. The new PCI subsystem also supports determination of IO/MMIO space needed by a device by checking a given BAR. In addition, Every device or component that use the PCI subsystem has changed to match the last changes.
2019-12-31 13:04:30 +02:00
bool complete_acpi_disable = KParams::the().has("noacpi");
bool dynamic_acpi_disable = KParams::the().has("noacpi_aml");
bool pci_mmio_disable = KParams::the().has("nopci_mmio");
bool pci_force_probing = KParams::the().has("pci_nodmi");
bool dmi_unreliable = KParams::the().has("dmi_unreliable");
MemoryManager::initialize(physical_address_for_kernel_page_tables);
if (dmi_unreliable) {
DMIDecoder::initialize_untrusted();
} else {
DMIDecoder::initialize();
}
if (complete_acpi_disable) {
ACPIParser::initialize_limited();
} else {
if (!dynamic_acpi_disable) {
ACPIDynamicParser::initialize_without_rsdp();
} else {
ACPIStaticParser::initialize_without_rsdp();
}
}
// Sample test to see if the ACPI parser is working...
kprintf("ACPI: HPET table @ P 0x%x\n", ACPIParser::the().find_table("HPET"));
PCI::Initializer::the().test_and_initialize(pci_mmio_disable, pci_force_probing);
PCI::Initializer::the().dismiss();
Kernel: Enabling Text mode debugging (#696) Also added an option to start Serenity with text mode in QEMU in the run script.
2019-10-29 17:41:40 +02:00
Kernel: Have devices automagically register themselves with the VFS.
2019-02-17 10:38:07 +01:00
vfs = new VFS;
Kernel+LibC: Add a DebugLogDevice that forwards everything to I/O port 0xe9. This is then used to implement the userspace dbgprintf() in a far more efficient way than what we had before. :^)
2019-04-18 16:08:52 +02:00
dev_debuglog = new DebugLogDevice;
Kernel: Have devices automagically register themselves with the VFS.
2019-02-17 10:38:07 +01:00
Fix bug where Console::the() was initialized too late. Yet another problem due to lack of BSS zeroing in the kernel loader...
2018-10-30 23:01:48 +01:00
auto console = make<Console>();
Kernel: Move CPU feature detection to Arch/x86/CPU.{cpp.h} We now refuse to boot on machines that don't support PAE since all of our paging code depends on it. Also let's only enable SSE and PGE support if the CPU advertises it.
2020-01-01 12:56:21 +01:00
kprintf("Starting SerenityOS...\n");
if (g_cpu_supports_sse) {
sse_init();
kprintf("x86: SSE support enabled\n");
}
Kernel: Enable x86 UMIP (User Mode Instruction Prevention) if supported This prevents code running outside of kernel mode from using the following instructions: * SGDT - Store Global Descriptor Table * SIDT - Store Interrupt Descriptor Table * SLDT - Store Local Descriptor Table * SMSW - Store Machine Status Word * STR - Store Task Register There's no need for userspace to be able to use these instructions so let's just disable them to prevent information leakage.
2020-01-01 13:02:32 +01:00
if (g_cpu_supports_umip) {
asm volatile(
"mov %cr4, %eax\n"
"orl $0x800, %eax\n"
"mov %eax, %cr4\n");
kprintf("x86: UMIP support enabled\n");
}
Kernel: Disable x86 RDTSC instruction in userspace It's still possible to read the TSC via the read_tsc() syscall, but we will now clear some of the bottom bits for unprivileged users.
2020-01-01 18:18:02 +01:00
if (g_cpu_supports_tsc) {
asm volatile(
"mov %cr4, %eax\n"
"orl $0x4, %eax\n"
"mov %eax, %cr4\n");
kprintf("x86: RDTSC support restricted\n");
}
Kernel: Add a more expressive API for getting random bytes We now have these API's in <Kernel/Random.h>: - get_fast_random_bytes(u8* buffer, size_t buffer_size) - get_good_random_bytes(u8* buffer, size_t buffer_size) - get_fast_random<T>() - get_good_random<T>() Internally they both use x86 RDRAND if available, otherwise they fall back to the same LCG we had in RandomDevice all along. The main purpose of this patch is to give kernel code a way to better express its needs for random data. Randomness is something that will require a lot more work, but this is hopefully a step in the right direction.
2020-01-03 12:36:30 +01:00
if (g_cpu_supports_rdrand) {
kprintf("x86: Using RDRAND for good randomness\n");
} else {
kprintf("x86: No RDRAND support detected. Randomness will be shitty\n");
}
Kernel: Randomize the stack canary on startup
2020-01-06 13:05:40 +01:00
__stack_chk_guard = get_good_random<u32>();
Add gettimeofday() syscall and LibC wrappers gettimeofday() and time(). This only has second accuracy right now, I'll work out subseconds later.
2018-10-25 17:29:49 +02:00
RTC::initialize();
A lot of hacking: - More work on funneling console output through Console. - init() now breaks off into a separate task ASAP. - ..this leaves the "colonel" task as a simple hlt idle loop. - Mask all IRQs on startup (except IRQ2 for slave passthru) - Fix underallocation bug in Task::allocateRegion(). - Remember how many times each Task has been scheduled. The panel and scheduling banner are disabled until I get things working nicely in the (brave) new Console world.
2018-10-22 11:15:16 +02:00
PIC::initialize();
gdt_init();
idt_init();
Kernel: Add bare minimum for global constructors (#707) Add text.startup to the .text block, add .ctors as well. Use them in init.cpp to call global constructors after gtd and idt init. That way any funky constructors should be ok. Also defines some Itanium C++ ABI methods that probably shouldn't be, but without them the linker gets very angry. If the code ever actually tries to use __dso_handle or call __cxa_atexit, there's bigger problems with the kernel. Bit of a hack would be an understatement but hey. It works :)
2019-10-31 12:01:13 -06:00
// call global constructors after gtd and itd init
for (ctor_func_t* ctor = &start_ctors; ctor < &end_ctors; ctor++)
(*ctor)();
Kernel: Rename Keyboard to KeyboardDevice.
2019-02-17 08:39:09 +01:00
keyboard = new KeyboardDevice;
Add a simple PS/2 mouse device. It's not hooked up to anything just yet, but it does read movement deltas.
2019-01-11 02:28:53 +01:00
ps2mouse = new PS2MouseDevice;
Kernel: First cut of a sb16 driver Also add an AudioServer that (right now) doesn't do much. It tries to open, parse, and play a wav file. In the future, it can do more. My general thinking here here is that /dev/audio will be "owned" by AudioServer, and we'll do mixing in software before passing buffers off to the kernel to play, but we have to start somewhere.
2019-07-12 19:28:01 +02:00
sb16 = new SB16;
Kernel: Make sure processes always start out with fds 0, 1 and 2 open. If we don't have a TTY for the process, fall back to /dev/null.
2019-02-12 11:25:25 +01:00
dev_null = new NullDevice;
Kernel: Add serial_debug cmdline parameter serial_debug will output all the kprintf and dbgprintf data to COM1 at 8-N-1 57600 baud. this is particularly useful for debugging the boot process on live hardware. Note: it must be the first parameter in the boot cmdline.
2019-08-11 14:43:38 +10:00
if (!get_serial_debug())
ttyS0 = new SerialDevice(SERIAL_COM1_ADDR, 64);
Kernel: Implement serial port driver This implements a basic 8250 UART serial port driver. It does not currently handle (or enable) interrupts, nor any runtime configuration.
2019-06-08 23:24:34 +10:00
ttyS1 = new SerialDevice(SERIAL_COM2_ADDR, 65);
ttyS2 = new SerialDevice(SERIAL_COM3_ADDR, 66);
ttyS3 = new SerialDevice(SERIAL_COM4_ADDR, 67);
Virtual consoles kinda work! We now make three VirtualConsoles at boot: tty0, tty1, and tty2. We launch an instance of /bin/sh in each one. You switch between them with Alt+1/2/3 How very very cool :^)
2018-10-30 15:33:37 +01:00
VirtualConsole::initialize();
tty0 = new VirtualConsole(0, VirtualConsole::AdoptCurrentVGABuffer);
tty1 = new VirtualConsole(1);
Convert VirtualConsole to the new coding style. I'm still playing around with finding a style that I like. This is starting to feel pleasing to the eye. I guess this is how long it took me to break free from the habit of my previous Qt/WK coding style.
2018-11-01 14:09:21 +01:00
VirtualConsole::switch_to(0);
Virtual consoles kinda work! We now make three VirtualConsoles at boot: tty0, tty1, and tty2. We launch an instance of /bin/sh in each one. You switch between them with Alt+1/2/3 How very very cool :^)
2018-10-30 15:33:37 +01:00
APIC: Enable APIC and start APs
2019-10-16 10:27:00 -06:00
if (APIC::init())
APIC::enable(0);
A lot of hacking: - More work on funneling console output through Console. - init() now breaks off into a separate task ASAP. - ..this leaves the "colonel" task as a simple hlt idle loop. - Mask all IRQs on startup (except IRQ2 for slave passthru) - Fix underallocation bug in Task::allocateRegion(). - Remember how many times each Task has been scheduled. The panel and scheduling banner are disabled until I get things working nicely in the (brave) new Console world.
2018-10-22 11:15:16 +02:00
PIT::initialize();
Kernel: Print out PCI devices during boot This will make boot logs much more useful on real hardware, by showing exactly what Serenity is trying to boot on.
2019-08-11 14:51:30 +10:00
PCI::enumerate_all([](const PCI::Address& address, PCI::ID id) {
Kernel: Create support for PCI ECAM The new PCI subsystem is initialized during runtime. PCI::Initializer is supposed to be called during early boot, to perform a few tests, and initialize the proper configuration space access mechanism. Kernel boot parameters can be specified by a user to determine what tests will occur, to aid debugging on problematic machines. After that, PCI::Initializer should be dismissed. PCI::IOAccess is a class that is derived from PCI::Access class and implements PCI configuration space access mechanism via x86 IO ports. PCI::MMIOAccess is a class that is derived from PCI::Access and implements PCI configurtaion space access mechanism via memory access. The new PCI subsystem also supports determination of IO/MMIO space needed by a device by checking a given BAR. In addition, Every device or component that use the PCI subsystem has changed to match the last changes.
2019-12-31 13:04:30 +02:00
kprintf("PCI: device @ %w:%b:%b.%d [%w:%w]\n",
address.seg(),
Kernel: Print out PCI devices during boot This will make boot logs much more useful on real hardware, by showing exactly what Serenity is trying to boot on.
2019-08-11 14:51:30 +10:00
address.bus(),
address.slot(),
address.function(),
id.vendor_id,
Kernel: Move kmalloc() into a Kernel/Heap/ directory
2019-09-16 09:01:44 +02:00
id.device_id);
Kernel: Print out PCI devices during boot This will make boot logs much more useful on real hardware, by showing exactly what Serenity is trying to boot on.
2019-08-11 14:51:30 +10:00
});
Kernel: Use KParams::has() instead of !KParams::get().is_null() Also rename a local variable to be consistent with what it represents.
2019-11-06 11:45:52 +01:00
if (text_debug) {
Kernel: Enabling Text mode debugging (#696) Also added an option to start Serenity with text mode in QEMU in the run script.
2019-10-29 17:41:40 +02:00
dbgprintf("Text mode enabled\n");
Kernel: Implement generic VGA device using multiboot info This implements a very basic VGA device using the information provided to us by the bootloader in the multiboot header. This allows Serenity to boot to the desktop on basically any halfway modern system.
2019-08-18 14:54:52 +10:00
} else {
Kernel: Enabling Text mode debugging (#696) Also added an option to start Serenity with text mode in QEMU in the run script.
2019-10-29 17:41:40 +02:00
if (multiboot_info_ptr->framebuffer_type == 1 || multiboot_info_ptr->framebuffer_type == 2) {
new MBVGADevice(
PhysicalAddress((u32)(multiboot_info_ptr->framebuffer_addr)),
multiboot_info_ptr->framebuffer_pitch,
multiboot_info_ptr->framebuffer_width,
multiboot_info_ptr->framebuffer_height);
} else {
new BXVGADevice;
}
Kernel: Implement generic VGA device using multiboot info This implements a very basic VGA device using the information provided to us by the bootloader in the multiboot header. This allows Serenity to boot to the desktop on basically any halfway modern system.
2019-08-18 14:54:52 +10:00
}
Kernel: Much improved BochsVGA (BXVGA) support. Instead of cowboy-calling the VESA BIOS in the bootloader, find the emulator VGA adapter by scanning the PCI bus. Then set up the desired video mode by sending device commands.
2019-02-06 10:17:26 +01:00
Kernel: Remove specific devices from network code By setting up the devices in init() and looping over the registered network adapters in NetworkTask_main, we can remove the remaining hard-coded adapter references from the network code. This also assigns IPs according to the default range supplied by QEMU in its slirp networking mode.
2019-08-28 21:53:01 +10:00
LoopbackAdapter::the();
Kernel: Start adding support for E1000 network adapters.
2019-03-10 15:25:33 +01:00
auto e1000 = E1000NetworkAdapter::autodetect();
Kernel: Implement rtl8139 network interface driver
2019-08-22 01:06:55 +10:00
auto rtl8139 = RTL8139NetworkAdapter::autodetect();
Kernel: Start adding support for E1000 network adapters.
2019-03-10 15:25:33 +01:00
Process now maps regions immediately when they are allocated. This avoids having to do a separate MM.mapRegionsForTask() pass. Also, more Task => Process renaming that I apparently hadn't saved yet.
2018-11-01 13:15:46 +01:00
Process::initialize();
Kernel: Introduce threads, and refactor everything in support of it. The scheduler now operates on threads, rather than on processes. Each process has a main thread, and can have any number of additional threads. The process exits when the main thread exits. This patch doesn't actually spawn any additional threads, it merely does all the plumbing needed to make it possible. :^)
2019-03-23 22:03:17 +01:00
Thread::initialize();
Kernel: Get rid of "main thread" concept The idea of all processes reliably having a main thread was nice in some ways, but cumbersome in others. More importantly, it didn't match up with POSIX thread semantics, so let's move away from it. This thread gets rid of Process::main_thread() and you now we just have a bunch of Thread objects floating around each Process. When the finalizer nukes the last Thread in a Process, it will also tear down the Process. There's a bunch of more things to fix around this, but this is where we get started :^)
2019-12-22 11:35:02 +01:00
Thread* init_stage2_thread = nullptr;
Process::create_kernel_process(init_stage2_thread, "init_stage2", init_stage2);
Thread* syncd_thread = nullptr;
Process::create_kernel_process(syncd_thread, "syncd", [] {
The syncd loop can just be a lambda.
2018-12-24 23:10:48 +01:00
for (;;) {
Kernel: Use a lookup table for syscalls Instead of the big ugly switch statement, build a lookup table using the syscall enumeration macro. This greatly simplifies the syscall implementation. :^)
2019-11-09 22:18:16 +01:00
VFS::the().sync();
Kernel: Make block() and yield() automatically call Scheduler::yield(). This exposed some places we were accidentally doing a double yield().
2019-03-24 01:52:10 +01:00
current->sleep(1 * TICKS_PER_SECOND);
The syncd loop can just be a lambda.
2018-12-24 23:10:48 +01:00
}
});
Kernel: Get rid of "main thread" concept The idea of all processes reliably having a main thread was nice in some ways, but cumbersome in others. More importantly, it didn't match up with POSIX thread semantics, so let's move away from it. This thread gets rid of Process::main_thread() and you now we just have a bunch of Thread objects floating around each Process. When the finalizer nukes the last Thread in a Process, it will also tear down the Process. There's a bunch of more things to fix around this, but this is where we get started :^)
2019-12-22 11:35:02 +01:00
Process::create_kernel_process(g_finalizer, "Finalizer", [] {
Kernel: Refactor scheduler to use dynamic thread priorities Threads now have numeric priorities with a base priority in the 1-99 range. Whenever a runnable thread is *not* scheduled, its effective priority is incremented by 1. This is tracked in Thread::m_extra_priority. The effective priority of a thread is m_priority + m_extra_priority. When a runnable thread *is* scheduled, its m_extra_priority is reset to zero and the effective priority returns to base. This means that lower-priority threads will always eventually get scheduled to run, once its effective priority becomes high enough to exceed the base priority of threads "above" it. The previous values for ThreadPriority (Low, Normal and High) are now replaced as follows: Low -> 10 Normal -> 30 High -> 50 In other words, it will take 20 ticks for a "Low" priority thread to get to "Normal" effective priority, and another 20 to reach "High". This is not perfect, and I've used some quite naive data structures, but I think the mechanism will allow us to build various new and interesting optimizations, and we can figure out better data structures later on. :^)
2019-12-30 18:46:17 +01:00
current->set_priority(THREAD_PRIORITY_LOW);
Kernel: Add a Finalizer process to take care of dying processes. Instead of processes themselves getting scheduled to finish dying, let's have a Finalizer process that wakes up whenever someone is dying. This way we can do all kinds of lock-taking in process cleanup without risking reentering the scheduler.
2019-02-06 18:45:21 +01:00
for (;;) {
Kernel: Use a WaitQueue to implement finalizer wakeup This gets rid of the special "Lurking" thread state and replaces it with a generic WaitQueue :^)
2019-12-01 19:17:17 +01:00
current->wait_on(*g_finalizer_wait_queue);
Kernel: Introduce threads, and refactor everything in support of it. The scheduler now operates on threads, rather than on processes. Each process has a main thread, and can have any number of additional threads. The process exits when the main thread exits. This patch doesn't actually spawn any additional threads, it merely does all the plumbing needed to make it possible. :^)
2019-03-23 22:03:17 +01:00
Thread::finalize_dying_threads();
Kernel: Add a Finalizer process to take care of dying processes. Instead of processes themselves getting scheduled to finish dying, let's have a Finalizer process that wakes up whenever someone is dying. This way we can do all kinds of lock-taking in process cleanup without risking reentering the scheduler.
2019-02-06 18:45:21 +01:00
}
});
Add a "syncd" kernel process that periodically calls sync().
2018-12-20 02:41:55 +01:00
Move the scheduler code to its own class. This is very mechanical.
2018-11-07 22:15:02 +01:00
Scheduler::pick_next();
A lot of hacking: - More work on funneling console output through Console. - init() now breaks off into a separate task ASAP. - ..this leaves the "colonel" task as a simple hlt idle loop. - Mask all IRQs on startup (except IRQ2 for slave passthru) - Fix underallocation bug in Task::allocateRegion(). - Remember how many times each Task has been scheduled. The panel and scheduling banner are disabled until I get things working nicely in the (brave) new Console world.
2018-10-22 11:15:16 +02:00
sti();
Kernel: Stop idling after handling an IRQ If we receive an IRQ while the idle task is running, prevent it from re-halting the CPU after the IRQ handler returns. Instead have the idle task yield to the scheduler, so we can see if the IRQ has unblocked something.
2019-09-14 19:44:22 +02:00
Scheduler::idle_loop();
ASSERT_NOT_REACHED();
Import the "gerbert" kernel I worked on earlier this year. It's a lot crappier than I remembered it. It's gonna need a lot of work.
2018-10-16 11:01:38 +02:00
}
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