src/kernel/x86_32/alloc.c - bluejay - Git - code.swisschili.sh

 #include "alloc.h"
 #include "io.h"
 #include "kheap.h"
 #include "kint.h"
 #include "log.h"
 #include "paging.h"

 extern uint end;
 static size_t palloc_base = (size_t)&end;
 static size_t malloc_base = (size_t)&end + 0x8000;

 #define HEADER_SIZE sizeof(struct heap_alloc_header)
 #define FOOTER_SIZE sizeof(struct heap_alloc_footer)

 static struct min_heap heap = {0};

 void *_kmalloc(size_t size, bool align, void **phys)
 {
 	if (align && (palloc_base & 0xfff)) // if not yet aligned
 	{
 		palloc_base &= ~0xfff;
 		palloc_base += 0x1000;
 	}

 	if (phys)
 	{
 		*phys = (void *)VIRT_TO_PHYS((void *)palloc_base);
 	}

 	size_t addr = palloc_base;
 	palloc_base += size;

 	if (palloc_base >= malloc_base)
 	{
 		kpanic("fatal error: placeholder kmalloc has overrun malloc() memory,"
 			   " cannot recover.");
 	}

 	return (void *)addr;
 }

 void *kmalloc(size_t size)
 {
 	return _kmalloc(size, false, NULL);
 }

 void *kmalloc_a(size_t size)
 {
 	return _kmalloc(size, true, NULL);
 }

 void *kmalloc_ap(size_t size, void **p)
 {
 	return _kmalloc(size, true, p);
 }

 // Proper allocators

 void init_allocator()
 {
 	heap.size = 1;
 	int size = 0xC0400000 - malloc_base;
 	heap.elements[0] = (struct heap_entry){
 		.key = size,
 		.address = malloc_base,
 	};
 	memset((void *)malloc_base, 0, size);

 	struct heap_alloc_header *h = (struct heap_alloc_header *)malloc_base;
 	h->magic = HEAP_MAGIC;
 	h->size = size;
 	h->allocated = false;
 }

 void *malloc(size_t size)
 {
 	bool ok;
 	size_t full_size = size + HEADER_SIZE + FOOTER_SIZE;
 	int i;

 	struct heap_entry e = heap_lookup_min(&heap, full_size, &ok, false, &i);

 	if (ok)
 	{
 		// Found smallest hole
 		struct heap_alloc_header *h = (struct heap_alloc_header *)e.address;

 		kassert(!h->allocated,
 				"Gap already allocated (this should never happen)");

 		size_t old_size = h->size;

 		if (full_size == old_size)
 		{
 			// Completely used, no need to change anything!
 			heap_delete(&heap, i);
 		}
 		else
 		{
 			// If there isn't very much space left
 			size_t new_size = old_size - full_size;
 			if (new_size <= HEADER_SIZE + FOOTER_SIZE + 8)
 			{
 				full_size = old_size;
 				heap_delete(&heap, i);
 			}
 			else
 			{
 				struct heap_alloc_footer *old_f =
 					(struct heap_alloc_footer *)(e.address + old_size -
 												 FOOTER_SIZE);

 				// Else create a new header
 				size_t new_header_addr = e.address + full_size;
 				struct heap_alloc_header *h =
 					(struct heap_alloc_header *)new_header_addr;

 				h->size = new_size;
 				old_f->size = new_size;

 				heap_decrease(&heap, i,
 							  (struct heap_entry){
 								  .key = new_size,
 								  .address = new_header_addr,
 							  });
 			}

 			struct heap_alloc_footer *f =
 				(struct heap_alloc_footer *)(e.address + full_size -
 											 FOOTER_SIZE);

 			h->allocated = true;
 			h->magic = HEAP_MAGIC;
 			h->size = full_size;
 			f->size = h->size;
 		}

 		return (void *)(e.address + HEADER_SIZE);
 	}
 	else
 	{
 		// We need more memory :L
 		kpanic("Whoops, malloc ran out of memory");
 	}
 }

 void free(void *mem)
 {
 	if (!mem)
 		return; // freeing NULL ptr

 	struct heap_alloc_header *base =
 		(struct heap_alloc_header *)((size_t)mem - HEADER_SIZE);

 	if (base->magic != HEAP_MAGIC)
 	{
 		kpanic("Freeing memory not allocated with malloc()");
 	}

 	// Check free block before this one

 	struct heap_alloc_footer *prev_f =
 		(struct heap_alloc_footer *)((size_t)mem - HEADER_SIZE - FOOTER_SIZE);

 	// Header of block before this one
 	struct heap_alloc_header *prev_h =
 		(struct heap_alloc_header *)((size_t)prev_f - prev_f->size +
 									 FOOTER_SIZE);

 	// Header of block after this one
 	struct heap_alloc_header *next_h =
 		(struct heap_alloc_header *)((size_t)mem - HEADER_SIZE + base->size);

 	size_t size = base->size;
 	size_t start = (size_t)base;

 	if (prev_h->magic == HEAP_MAGIC && !prev_h->allocated)
 	{
 		size += prev_h->size;
 		start = (size_t)prev_h;
 	}
 	if (next_h->magic == HEAP_MAGIC && !next_h->allocated)
 	{
 		size += next_h->size;
 	}

 	struct heap_alloc_header *h = (struct heap_alloc_header *)start;
 	h->allocated = false;
 	h->magic = HEAP_MAGIC;
 	h->size = size;

 	// Add entry into heap

 	struct heap_entry entry = {
 		.key = size,
 		.address = start,
 	};

 	heap_insert(&heap, entry);
 }

 void *realloc(void *mem, size_t size)
 {
 	if (!mem)
 		return NULL; // freeing NULL ptr

 	struct heap_alloc_header *base =
 		(struct heap_alloc_header *)((size_t)mem - HEADER_SIZE);
 	struct heap_alloc_header *next =
 		(struct heap_alloc_header *)((size_t)base + base->size);

 	if (!next->allocated &&
 		next->size + base->size - HEADER_SIZE - FOOTER_SIZE >= size)
 	{
 		// Okay, we can just expand this block
 		// Actually, need to check if there is enough space remaining for an
 		// additional block, otherwise, just add that memory to this block (
 		// same as is done in malloc )

 		struct heap_alloc_footer *f;

 		size_t remaining =
 			base->size + next->size - size - HEADER_SIZE - FOOTER_SIZE;

 		struct heap_entry old_entry = {
 			.key = next->size,
 			.address = (size_t)next,
 		};

 		if (remaining <= HEADER_SIZE + FOOTER_SIZE + 8)
 		{
 			// Just join this into the same memory chunk
 			f = (struct heap_alloc_footer *)(next + next->size - FOOTER_SIZE);

 			heap_delete_entry(&heap, old_entry);
 		}
 		else
 		{
 			f = mem + size;
 			struct heap_alloc_header *new_h =
 				(struct heap_alloc_header *)(f + FOOTER_SIZE);

 			struct heap_alloc_footer *new_f =
 				(struct heap_alloc_footer *)(new_h + remaining - FOOTER_SIZE);

 			new_h->allocated = false;
 			new_h->size = new_f->size = remaining;
 			new_h->magic = HEAP_MAGIC;

 			struct heap_entry entry = {
 				.key = remaining,
 				.address = (size_t)new_h,
 			};

 			heap_decrease_entry(&heap, old_entry, entry);
 		}

 		size_t full_size = (size_t)f - (size_t)base + FOOTER_SIZE;

 		f->size = full_size;
 		base->size = full_size;
 		base->magic = HEAP_MAGIC;
 		base->allocated = true;

 		return mem;
 	}
 	else
 	{
 		void *new = malloc(size);
 		if (!new)
 			return new;

 		memcpy(new, mem, base->size - HEADER_SIZE - FOOTER_SIZE);
 		free(mem);

 		return new;
 	}
 }

 void test_allocator()
 {
 	int *one = malloc(sizeof(int));
 	int *two = malloc(sizeof(int));

 	*one = 1;
 	*two = 2;

 	int *array = malloc(sizeof(int[12]));

 	for (int i = 0; i < 12; i++)
 		array[i] = i;

 	kprintf(DEBUG "Allocated one, two, array[3] = %d, %d, %d\n", *one, *two,
 			array[3]);
 	kprintf(DEBUG "[%x, %x, %x]\n", one, two, array);

 	kprintf(DEBUG "Freeing two\n");
 	free(two);
 	int *four = malloc(sizeof(int));
 	*four = 4;
 	kprintf(DEBUG "Allocated four = %d (%x)\n", *four, four);
 }
	#include "alloc.h"
	#include "io.h"
	#include "kheap.h"
	#include "kint.h"
	#include "log.h"
	#include "paging.h"

	extern uint end;
	static size_t palloc_base = (size_t)&end;
	static size_t malloc_base = (size_t)&end + 0x8000;

	#define HEADER_SIZE sizeof(struct heap_alloc_header)
	#define FOOTER_SIZE sizeof(struct heap_alloc_footer)

	static struct min_heap heap = {0};

	void _kmalloc(size_t size, bool align, void *phys)
	{
	if (align && (palloc_base & 0xfff)) // if not yet aligned
	{
	palloc_base &= ~0xfff;
	palloc_base += 0x1000;
	}

	if (phys)
	{
	phys = (void )VIRT_TO_PHYS((void *)palloc_base);
	}

	size_t addr = palloc_base;
	palloc_base += size;

	if (palloc_base >= malloc_base)
	{
	kpanic("fatal error: placeholder kmalloc has overrun malloc() memory,"
	" cannot recover.");
	}

	return (void *)addr;
	}

	void *kmalloc(size_t size)
	{
	return _kmalloc(size, false, NULL);
	}

	void *kmalloc_a(size_t size)
	{
	return _kmalloc(size, true, NULL);
	}

	void kmalloc_ap(size_t size, void *p)
	{
	return _kmalloc(size, true, p);
	}

	// Proper allocators

	void init_allocator()
	{
	heap.size = 1;
	int size = 0xC0400000 - malloc_base;
	heap.elements[0] = (struct heap_entry){
	.key = size,
	.address = malloc_base,
	};
	memset((void *)malloc_base, 0, size);

	struct heap_alloc_header h = (struct heap_alloc_header )malloc_base;
	h->magic = HEAP_MAGIC;
	h->size = size;
	h->allocated = false;
	}

	void *malloc(size_t size)
	{
	bool ok;
	size_t full_size = size + HEADER_SIZE + FOOTER_SIZE;
	int i;

	struct heap_entry e = heap_lookup_min(&heap, full_size, &ok, false, &i);

	if (ok)
	{
	// Found smallest hole
	struct heap_alloc_header h = (struct heap_alloc_header )e.address;

	kassert(!h->allocated,
	"Gap already allocated (this should never happen)");

	size_t old_size = h->size;

	if (full_size == old_size)
	{
	// Completely used, no need to change anything!
	heap_delete(&heap, i);
	}
	else
	{
	// If there isn't very much space left
	size_t new_size = old_size - full_size;
	if (new_size <= HEADER_SIZE + FOOTER_SIZE + 8)
	{
	full_size = old_size;
	heap_delete(&heap, i);
	}
	else
	{
	struct heap_alloc_footer *old_f =
	(struct heap_alloc_footer *)(e.address + old_size -
	FOOTER_SIZE);

	// Else create a new header
	size_t new_header_addr = e.address + full_size;
	struct heap_alloc_header *h =
	(struct heap_alloc_header *)new_header_addr;

	h->size = new_size;
	old_f->size = new_size;

	heap_decrease(&heap, i,
	(struct heap_entry){
	.key = new_size,
	.address = new_header_addr,
	});
	}

	struct heap_alloc_footer *f =
	(struct heap_alloc_footer *)(e.address + full_size -
	FOOTER_SIZE);

	h->allocated = true;
	h->magic = HEAP_MAGIC;
	h->size = full_size;
	f->size = h->size;
	}

	return (void *)(e.address + HEADER_SIZE);
	}
	else
	{
	// We need more memory :L
	kpanic("Whoops, malloc ran out of memory");
	}
	}

	void free(void *mem)
	{
	if (!mem)
	return; // freeing NULL ptr

	struct heap_alloc_header *base =
	(struct heap_alloc_header *)((size_t)mem - HEADER_SIZE);

	if (base->magic != HEAP_MAGIC)
	{
	kpanic("Freeing memory not allocated with malloc()");
	}

	// Check free block before this one

	struct heap_alloc_footer *prev_f =
	(struct heap_alloc_footer *)((size_t)mem - HEADER_SIZE - FOOTER_SIZE);

	// Header of block before this one
	struct heap_alloc_header *prev_h =
	(struct heap_alloc_header *)((size_t)prev_f - prev_f->size +
	FOOTER_SIZE);

	// Header of block after this one
	struct heap_alloc_header *next_h =
	(struct heap_alloc_header *)((size_t)mem - HEADER_SIZE + base->size);

	size_t size = base->size;
	size_t start = (size_t)base;

	if (prev_h->magic == HEAP_MAGIC && !prev_h->allocated)
	{
	size += prev_h->size;
	start = (size_t)prev_h;
	}
	if (next_h->magic == HEAP_MAGIC && !next_h->allocated)
	{
	size += next_h->size;
	}

	struct heap_alloc_header h = (struct heap_alloc_header )start;
	h->allocated = false;
	h->magic = HEAP_MAGIC;
	h->size = size;

	// Add entry into heap

	struct heap_entry entry = {
	.key = size,
	.address = start,
	};

	heap_insert(&heap, entry);
	}

	void realloc(void mem, size_t size)
	{
	if (!mem)
	return NULL; // freeing NULL ptr

	struct heap_alloc_header *base =
	(struct heap_alloc_header *)((size_t)mem - HEADER_SIZE);
	struct heap_alloc_header *next =
	(struct heap_alloc_header *)((size_t)base + base->size);

	if (!next->allocated &&
	next->size + base->size - HEADER_SIZE - FOOTER_SIZE >= size)
	{
	// Okay, we can just expand this block
	// Actually, need to check if there is enough space remaining for an
	// additional block, otherwise, just add that memory to this block (
	// same as is done in malloc )

	struct heap_alloc_footer *f;

	size_t remaining =
	base->size + next->size - size - HEADER_SIZE - FOOTER_SIZE;

	struct heap_entry old_entry = {
	.key = next->size,
	.address = (size_t)next,
	};

	if (remaining <= HEADER_SIZE + FOOTER_SIZE + 8)
	{
	// Just join this into the same memory chunk
	f = (struct heap_alloc_footer *)(next + next->size - FOOTER_SIZE);

	heap_delete_entry(&heap, old_entry);
	}
	else
	{
	f = mem + size;
	struct heap_alloc_header *new_h =
	(struct heap_alloc_header *)(f + FOOTER_SIZE);

	struct heap_alloc_footer *new_f =
	(struct heap_alloc_footer *)(new_h + remaining - FOOTER_SIZE);

	new_h->allocated = false;
	new_h->size = new_f->size = remaining;
	new_h->magic = HEAP_MAGIC;

	struct heap_entry entry = {
	.key = remaining,
	.address = (size_t)new_h,
	};

	heap_decrease_entry(&heap, old_entry, entry);
	}

	size_t full_size = (size_t)f - (size_t)base + FOOTER_SIZE;

	f->size = full_size;
	base->size = full_size;
	base->magic = HEAP_MAGIC;
	base->allocated = true;

	return mem;
	}
	else
	{
	void *new = malloc(size);
	if (!new)
	return new;

	memcpy(new, mem, base->size - HEADER_SIZE - FOOTER_SIZE);
	free(mem);

	return new;
	}
	}

	void test_allocator()
	{
	int *one = malloc(sizeof(int));
	int *two = malloc(sizeof(int));

	*one = 1;
	*two = 2;

	int *array = malloc(sizeof(int[12]));

	for (int i = 0; i < 12; i++)
	array[i] = i;

	kprintf(DEBUG "Allocated one, two, array[3] = %d, %d, %d\n", one, two,
	array[3]);
	kprintf(DEBUG "[%x, %x, %x]\n", one, two, array);

	kprintf(DEBUG "Freeing two\n");
	free(two);
	int *four = malloc(sizeof(int));
	*four = 4;
	kprintf(DEBUG "Allocated four = %d (%x)\n", *four, four);
	}