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Alexander Kuleshov 2017-07-08 00:22:46 +06:00
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@ -364,7 +364,7 @@ ptr = (unsigned long)kzalloc(alloc_size, GFP_NOWAIT);
As I already mentioned, the Linux group scheduling mechanism allows to specify a hierarcy. The root of such hierarcies is the `root_runqueuetask_group` task group structure. This structure contains many fields, but we are interested in `se`, `rt_se`, `cfs_rq` and `rt_rq` for this moment: As I already mentioned, the Linux group scheduling mechanism allows to specify a hierarcy. The root of such hierarcies is the `root_runqueuetask_group` task group structure. This structure contains many fields, but we are interested in `se`, `rt_se`, `cfs_rq` and `rt_rq` for this moment:
The first two are instances of `sched_entity` structure. It is defined in the [include/linux/sched.h](https://github.com/torvalds/linux/blob/master/include/linux/sched.h) kernel header filed and used by the scheduler as an unit of scheduling. The first two are instances of `sched_entity` structure. It is defined in the [include/linux/sched.h](https://github.com/torvalds/linux/blob/master/include/linux/sched.h) kernel header filed and used by the scheduler as a unit of scheduling.
```C ```C
struct task_group { struct task_group {

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@ -3,7 +3,7 @@
This chapter describes the `system call` concept in the linux kernel. This chapter describes the `system call` concept in the linux kernel.
* [Introduction to system call concept](syscall-1.md) - this part is introduction to the `system call` concept in the Linux kernel. * [Introduction to system call concept](syscall-1.md) - this part is introduction to the `system call` concept in the Linux kernel.
* [How the Linux kernel handles a system call](syscall-2.md) - this part describes how the Linux kernel handles a system call from an userspace application. * [How the Linux kernel handles a system call](syscall-2.md) - this part describes how the Linux kernel handles a system call from a userspace application.
* [vsyscall and vDSO](syscall-3.md) - third part describes `vsyscall` and `vDSO` concepts. * [vsyscall and vDSO](syscall-3.md) - third part describes `vsyscall` and `vDSO` concepts.
* [How the Linux kernel runs a program](syscall-4.md) - this part describes startup process of a program. * [How the Linux kernel runs a program](syscall-4.md) - this part describes startup process of a program.
* [Implementation of the open system call](syscall-5.md) - this part describes implementation of the [open](http://man7.org/linux/man-pages/man2/open.2.html) system call. * [Implementation of the open system call](syscall-5.md) - this part describes implementation of the [open](http://man7.org/linux/man-pages/man2/open.2.html) system call.

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@ -84,7 +84,7 @@ wrmsrl(MSR_LSTAR, entry_SYSCALL_64);
in the [arch/x86/kernel/cpu/common.c](https://github.com/torvalds/linux/blob/master/arch/x86/kernel/cpu/common.c) source code file. in the [arch/x86/kernel/cpu/common.c](https://github.com/torvalds/linux/blob/master/arch/x86/kernel/cpu/common.c) source code file.
So, the `syscall` instruction invokes a handler of a given system call. But how does it know which handler to call? Actually it gets this information from the general purpose [registers](https://en.wikipedia.org/wiki/Processor_register). As you can see in the system call [table](https://github.com/torvalds/linux/blob/master/arch/x86/entry/syscalls/syscall_64.tbl), each system call has an unique number. In our example, first system call is - `write` that writes data to the given file. Let's look in the system call table and try to find `write` system call. As we can see, the [write](https://github.com/torvalds/linux/blob/master/arch/x86/entry/syscalls/syscall_64.tbl#L10) system call has number - `1`. We pass the number of this system call through the `rax` register in our example. The next general purpose registers: `%rdi`, `%rsi` and `%rdx` take parameters of the `write` syscall. In our case, they are [file descriptor](https://en.wikipedia.org/wiki/File_descriptor) (`1` is [stdout](https://en.wikipedia.org/wiki/Standard_streams#Standard_output_.28stdout.29) in our case), second parameter is the pointer to our string, and the third is size of data. Yes, you heard right. Parameters for a system call. As I already wrote above, a system call is a just `C` function in the kernel space. In our case first system call is write. This system call defined in the [fs/read_write.c](https://github.com/torvalds/linux/blob/master/fs/read_write.c) source code file and looks like: So, the `syscall` instruction invokes a handler of a given system call. But how does it know which handler to call? Actually it gets this information from the general purpose [registers](https://en.wikipedia.org/wiki/Processor_register). As you can see in the system call [table](https://github.com/torvalds/linux/blob/master/arch/x86/entry/syscalls/syscall_64.tbl), each system call has a unique number. In our example, first system call is - `write` that writes data to the given file. Let's look in the system call table and try to find `write` system call. As we can see, the [write](https://github.com/torvalds/linux/blob/master/arch/x86/entry/syscalls/syscall_64.tbl#L10) system call has number - `1`. We pass the number of this system call through the `rax` register in our example. The next general purpose registers: `%rdi`, `%rsi` and `%rdx` take parameters of the `write` syscall. In our case, they are [file descriptor](https://en.wikipedia.org/wiki/File_descriptor) (`1` is [stdout](https://en.wikipedia.org/wiki/Standard_streams#Standard_output_.28stdout.29) in our case), second parameter is the pointer to our string, and the third is size of data. Yes, you heard right. Parameters for a system call. As I already wrote above, a system call is a just `C` function in the kernel space. In our case first system call is write. This system call defined in the [fs/read_write.c](https://github.com/torvalds/linux/blob/master/fs/read_write.c) source code file and looks like:
```C ```C
SYSCALL_DEFINE3(write, unsigned int, fd, const char __user *, buf, SYSCALL_DEFINE3(write, unsigned int, fd, const char __user *, buf,

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@ -4,7 +4,7 @@ System calls in the Linux kernel. Part 3.
vsyscalls and vDSO vsyscalls and vDSO
-------------------------------------------------------------------------------- --------------------------------------------------------------------------------
This is the third part of the [chapter](http://0xax.gitbooks.io/linux-insides/content/SysCall/index.html) that describes system calls in the Linux kernel and we saw preparations after a system call caused by an userspace application and process of handling of a system call in the previous [part](http://0xax.gitbooks.io/linux-insides/content/SysCall/syscall-2.html). In this part we will look at two concepts that are very close to the system call concept, they are called `vsyscall` and `vdso`. This is the third part of the [chapter](http://0xax.gitbooks.io/linux-insides/content/SysCall/index.html) that describes system calls in the Linux kernel and we saw preparations after a system call caused by a userspace application and process of handling of a system call in the previous [part](http://0xax.gitbooks.io/linux-insides/content/SysCall/syscall-2.html). In this part we will look at two concepts that are very close to the system call concept, they are called `vsyscall` and `vdso`.
We already know what is a `system call`. This is special routine in the Linux kernel which userspace application asks to do privileged tasks, like to read or to write to a file, to open a socket and etc. As you may know, invoking a system call is an expensive operation in the Linux kernel, because the processor must interrupt the currently executing task and switch context to kernel mode, subsequently jumping again into userspace after the system call handler finishes its work. These two mechanisms - `vsyscall` and `vdso` are designed to speed up this process for certain system calls and in this part we will try to understand how these mechanisms work. We already know what is a `system call`. This is special routine in the Linux kernel which userspace application asks to do privileged tasks, like to read or to write to a file, to open a socket and etc. As you may know, invoking a system call is an expensive operation in the Linux kernel, because the processor must interrupt the currently executing task and switch context to kernel mode, subsequently jumping again into userspace after the system call handler finishes its work. These two mechanisms - `vsyscall` and `vdso` are designed to speed up this process for certain system calls and in this part we will try to understand how these mechanisms work.

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@ -33,7 +33,7 @@ int main(int argc, char *argv) {
} }
``` ```
In this case, the open is the function from standard library, but not system call. The standard library will call related system call for us. The `open` call will return a [file descriptor](https://en.wikipedia.org/wiki/File_descriptor) which is just an unique number within our process which is associated with the opened file. Now as we opened a file and got file descriptor as result of `open` call, we may start to interact with this file. We can write into, read from it and etc. List of opened file by a process is available via [proc](https://en.wikipedia.org/wiki/Procfs) filesystem: In this case, the open is the function from standard library, but not system call. The standard library will call related system call for us. The `open` call will return a [file descriptor](https://en.wikipedia.org/wiki/File_descriptor) which is just a unique number within our process which is associated with the opened file. Now as we opened a file and got file descriptor as result of `open` call, we may start to interact with this file. We can write into, read from it and etc. List of opened file by a process is available via [proc](https://en.wikipedia.org/wiki/Procfs) filesystem:
``` ```
$ sudo ls /proc/1/fd/ $ sudo ls /proc/1/fd/

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@ -87,7 +87,7 @@ The availability of more precise techniques for time intervals measurement is ha
Generic timeofday and clock source management framework moved a lot of timekeeping code into the architecture independent portion of the code, with the architecture-dependent portion reduced to defining and managing low-level hardware pieces of clocksources. It takes a large amount of funds to measure the time interval on different architectures with different hardware, and it is very complex. Implementation of the each clock related service is strongly associated with an individual hardware device and as you can understand, it results in similar implementations for different architectures. Generic timeofday and clock source management framework moved a lot of timekeeping code into the architecture independent portion of the code, with the architecture-dependent portion reduced to defining and managing low-level hardware pieces of clocksources. It takes a large amount of funds to measure the time interval on different architectures with different hardware, and it is very complex. Implementation of the each clock related service is strongly associated with an individual hardware device and as you can understand, it results in similar implementations for different architectures.
Within this framework, each clock source is required to maintain a representation of time as a monotonically increasing value. As we can see in the Linux kernel code, nanoseconds are the favorite choice for the time value units of a clock source in this time. One of the main point of the clock source framework is to allow an user to select clock source among a range of available hardware devices supporting clock functions when configuring the system and selecting, accessing and scaling different clock sources. Within this framework, each clock source is required to maintain a representation of time as a monotonically increasing value. As we can see in the Linux kernel code, nanoseconds are the favorite choice for the time value units of a clock source in this time. One of the main point of the clock source framework is to allow a user to select clock source among a range of available hardware devices supporting clock functions when configuring the system and selecting, accessing and scaling different clock sources.
The clocksource structure The clocksource structure
-------------------------------------------------------------------------------- --------------------------------------------------------------------------------

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@ -208,7 +208,7 @@ Here we can see the definition of the structure with the two fields of 2-bytes a
+-------------------------------------------------------------------------------+ +-------------------------------------------------------------------------------+
``` ```
To form an index into the IDT, the processor scales the exception or interrupt vector by sixteen. The processor handles the occurrence of exceptions and interrupts just like it handles calls of a procedure when it sees the `call` instruction. A processor uses an unique number or `vector number` of the interrupt or the exception as the index to find the necessary `Interrupt Descriptor Table` entry. Now let's take a closer look at an `IDT` entry. To form an index into the IDT, the processor scales the exception or interrupt vector by sixteen. The processor handles the occurrence of exceptions and interrupts just like it handles calls of a procedure when it sees the `call` instruction. A processor uses a unique number or `vector number` of the interrupt or the exception as the index to find the necessary `Interrupt Descriptor Table` entry. Now let's take a closer look at an `IDT` entry.
As we can see, `IDT` entry on the diagram consists of the following fields: As we can see, `IDT` entry on the diagram consists of the following fields: