In Linux, RAM is divided into kernel space and user space to manage memory and protect the kernel from user applications. Here's a breakdown of how this division works, along with details on high memory, low memory, and crashkernel allocation:
Kernel Space vs. User Space
Kernel Space: This area is reserved for running the kernel, kernel extensions, and most device drivers. User-space applications cannot directly access this memory.
User Space: This is the memory area where application software and some drivers execute, typically with one address space per process.
The separation ensures that processes are protected from each other and that the kernel is protected from user-space applications.
Memory Division
1. Address Space: On some architectures like x86-64 ppc64, the virtual address space is split into two halves. The bottom half is for user-space allocations, and the top half is for kernel allocations. For example, on x86, there can be a 3G/1G split, where 3GB is for user space and 1GB for the kernel.
2. Memory Allocation: Memory is allocated as needed within the address space. The address space split determines the use of virtual addresses but doesn’t dictate physical memory use. The kernel allocates memory for its own binary and any additional needs, which cannot be swapped out.
3. Memory Mapping: The kernel manages memory mapping with the help of hardware (MMU - memory management unit). The kernel maintains its own mappings shared by all processes, and each process gets its own user-space mapping.
High Memory vs. Low Memory
Applicability: The "high/low memory" split is primarily relevant to 32-bit architectures with relatively large physical RAM (more than ~1 GB). On 64-bit architectures or systems with smaller physical address spaces, the entire physical space can be accessed from the kernel virtual memory space, and all physical memory is considered "low memory".
Low Memory: In Linux systems, low memory is typically used for the kernel. A portion of the kernel virtual address space can be mapped as a single contiguous chunk into physical "low memory".
High Memory: High memory is often used for application space. It is a range of the kernel's memory space where data to be accessed is placed.
In essence, high memory is a region of kernel memory used to map physical memory that cannot be contiguously mapped with the rest of the kernel's virtual memory.
Crashkernel Memory Allocation:
Crashkernel is a reserved memory region that can be used to boot a second kernel in case of a system crash, enabling crash analysis and debugging. Its is design that some part of the this allocated in Low memory and other part at high memory
GRUB (GRand Unified Bootloader) is a boot loader that loads the Linux kernel, presenting a menu of operating systems or kernels to choose from at system startup. It allows users to select which OS to boot and pass arguments to the kernel. GRUB's RAM usage occurs in the real mode area (RMA), which is a part of RAM used by GRUB for its operations and to load boot components. The current size of the RMA is 768 MB. However, GRUB2 might fail with an out-of-memory error depending on bigger size of kernel image or the initramfs
The memory layout of a program is divided into segments, each with a specific purpose. These segments include the text segment, data segment (initialized and uninitialized), heap, and stack. In the context of memory allocation, the parameters you've provided describe the boundaries and limits of memory usage for a program. Here's an explanation of each term:
memory_limit: This sets the maximum amount of memory in bytes that a script is allowed to allocate. It helps prevent poorly written scripts from using up all available memory. A value of 0 here (0000000000000000) likely means there is no memory limit. However, in some contexts, it might represent the initial memory limit which can be changed. In PHP, setting `memory_limit` to -1 means the script can use all the memory that is left over from the operating system and other important processes running.
alloc_bottom: This indicates the starting address of the memory region available for allocation. In your example, it's 0000000010350000.
alloc_top: This represents the highest address up to which memory can be allocated. Here, it's 0000000030000000.
alloc_top_hi: This could indicate a higher boundary for memory allocation, possibly in a system that uses segmented memory management. In this case, it's 0000000100000000.
rmo_top: This might refer to the top of the read-only memory region. It is 0000000030000000 in your layout.
ram_top: This likely indicates the top address of the available RAM. It's 0000000100000000 in your example.
The stack segment is near the top of memory with a high address, while the text, data, and heap segments have lower addresses. When a function is called, stack memory is allocated for it, and when a new local variable is declared, more stack memory is allocated, causing the stack to grow downwards. Stack memory allocation and deallocation are done automatically. The heap is where dynamic memory allocation takes place using functions like `malloc()` and `calloc()`. Unlike the stack, heap memory allocation is not continuous, and users can free heap memory, causing fragmentation.
Here's the conversion for each of your memory parameters:
memory_limit: 0000000000000000 (hex) = 0 bytes. It means there is no memory limit imposed.
alloc_bottom: 0000000010350000 (hex) = 271,151,104 bytes.
alloc_top: 0000000030000000 (hex) = 805,306,368 bytes.
alloc_top_hi: 0000000100000000 (hex) = 4,294,967,296 bytes.
rmo_top:0000000030000000 (hex) = 805,306,368 bytes.
ram_top:0000000100000000 (hex) = 4,294,967,296 bytes.
Now, calculating the sizes of memory ranges:
1) Allocation Range (alloc_bottom to alloc_top):
alloc_top - alloc_bottom + 1 = 805,306,368 - 271,151,104 + 1 = 534,155,265$$ bytes
In MB: $$534,155,265 / 1,048,576 \approx 509.41MB
2) Upper Allocation Range (alloc_bottom to alloc_top_hi):
alloc_top_hi - alloc_bottom + 1 = 4,294,967,296 - 271,151,104 + 1 = 4,023,816,193$$ bytes
In GB: 4,023,816,193 / 1,073,741,824 approx 3.75GB
3) RMO Size (from alloc_bottom to rmo_top):
rmo_top - alloc_bottom + 1 = 805,306,368 - 271,151,104 + 1 = 534,155,265 bytes
approx 509.41MB
4) RAM Size (from alloc_bottom to ram_top):
ram_top - alloc_bottom + 1 = 4,294,967,296 - 271,151,104 + 1 = 4,023,816,193bytes
approx 3.75GB
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The Real Mode Area (RMA) in the context of the Linux kernel and boot process refers to the region of memory where the system initially operates in real mode before transitioning to protected mode. In real mode, the processor can address only 1 MB of memory.
Here's a breakdown of how the RMA fits into the boot process:
1. Real Mode Operation: When the computer starts, it boots into real mode. In this mode, the processor has a limited addressing capability (1MB).
2. GRUB Loading: GRUB (or any bootloader) operates initially in real mode. It loads the kernel image into memory using BIOS disk I/O services.
3. Memory Arrangement: In real mode, RAM is organized such that the kernel image is loaded into memory by the boot loader. A small part of the kernel containing real-mode code is loaded below the 640K barrier, while the larger part that runs in protected mode is loaded after the first megabyte.
4. Transition to Protected Mode: After loading the necessary components, the system switches from real mode to protected mode, which allows access to more memory and advanced features.
5. Memory Addressing: In Real Mode, memory access is done using Segmentation via a segment:offset system.
