sandbox/base/memory_test.c

#include "socks/queue.h"
#include <stdint.h>
#include <stdio.h>
#include <stddef.h>
#include <stdlib.h>
#include <inttypes.h>
#include <time.h>
#include <assert.h>
#include <sys/mman.h>
#include <socks/types.h>
#include <socks/util.h>
#include <socks/memblock.h>
#include <socks/vm.h>

/* we're working with 512MiB of simulated system RAM */
#define MEMORY_SIZE_MB 512

#define ALLOC_START_MB 16
#define ALLOC_END_MB 32

#define MEMPTR(offset) ((uintptr_t)system_memory + (offset))
#define MB_TO_BYTES(v) ((size_t)(v) * 0x100000)

#define PHYS_TO_VIRT(p) ((void *)((uintptr_t)system_memory + (p)))
#define VIRT_TO_PHYS(p) ((void *)((p) - (uintptr_t)system_memory))

struct mem_map_region {
	phys_addr_t base;
	phys_addr_t limit;
	enum { REGION_FREE, REGION_RESERVED } status;
};

static struct mem_map_region mem_map[] = {
	{ .base = 0x00000000, .limit = 0x0000ffff, .status = REGION_RESERVED },
	{ .base = 0x00010000, .limit = 0x0004ffff, .status = REGION_FREE },
	{ .base = 0x00050000, .limit = 0x0005ffff, .status = REGION_RESERVED },
	{ .base = 0x00060000, .limit = 0x000fffff, .status = REGION_FREE },
	{ .base = 0x00100000, .limit = 0x001fffff, .status = REGION_RESERVED },
	{ .base = 0x00200000, .limit = 0x005fffff, .status = REGION_FREE },
	{ .base = 0x00600000, .limit = 0x007fffff, .status = REGION_RESERVED },
	{ .base = 0x00800000, .limit = MB_TO_BYTES(MEMORY_SIZE_MB) - 1, .status = REGION_FREE },
};

/* virtual address of where system memory is mapped */
static void *system_memory = NULL;

static void print_free_pages(vm_zone_t *z)
{
	printf(" * %s:\n", z->z_info.zd_name);
	
	for (int i = VM_PAGE_MIN_ORDER; i <= VM_PAGE_MAX_ORDER; i++) {
		if (queue_length(&z->z_free_pages[i]) == 0) {
			continue;
		}

		char size_str[64];
		data_size_to_string(vm_page_order_to_bytes(i), size_str, sizeof size_str);
		
		printf("  - %u pages with size %s (order-%u)\n", queue_length(&z->z_free_pages[i]), size_str, i); 
	}
}

static void print_all_pages(void)
{
	for (phys_addr_t i = 0; i < UINTPTR_MAX; ) {
		vm_page_t *pg = vm_page_get(i);
		if (!pg) {
			break;
		}

		vm_zone_t *z = vm_page_get_zone(pg);
		printf(" * %08" PRIxPTR ": %s order-%u (%zu bytes) %s\n",
			i,
			z ? z->z_info.zd_name : "[none]",
			pg->p_order,
			vm_page_order_to_bytes(pg->p_order),
			pg->p_flags & VM_PAGE_RESERVED ? "reserved" : "free");
		i += vm_page_order_to_bytes(pg->p_order);
	}
}

int memory_test(void)
{
	srand(time(NULL));
	system_memory = mmap(
			NULL,
			MB_TO_BYTES(MEMORY_SIZE_MB),
			PROT_READ | PROT_WRITE,
			MAP_PRIVATE | MAP_ANONYMOUS,
			-1, 0);

	if (system_memory == MAP_FAILED) {
		perror("mmap");
		fprintf(stderr, "cannot allocate simulated system RAM buffer\n");
		return -1;
	}

	phys_addr_t pmem_base = UINTPTR_MAX, pmem_limit = 0;
	size_t nr_mem_map_entries = sizeof mem_map / sizeof mem_map[0];

	for (size_t i = 0; i < nr_mem_map_entries; i++) {
		if (mem_map[i].base < pmem_base) {
			pmem_base = mem_map[i].base;
		}

		if (mem_map[i].limit > pmem_limit) {
			pmem_limit = mem_map[i].limit;
		}
	}

	memblock_add(pmem_base, pmem_limit + 1);

	for (size_t i = 0; i < nr_mem_map_entries; i++) {
		if (mem_map[i].status == REGION_RESERVED) {
			memblock_reserve(mem_map[i].base, mem_map[i].limit - mem_map[i].base + 1);
		}
	}

	printf("allocated %u MiB (0x%zx bytes) of memory to act as system RAM at %p\n", MEMORY_SIZE_MB, MB_TO_BYTES(MEMORY_SIZE_MB), system_memory);

	printf("sizeof(vm_page_t) = %zu bytes\n", sizeof(vm_page_t));

	uintptr_t voffset = (uintptr_t)system_memory;

	memblock_init(MB_TO_BYTES(ALLOC_START_MB) + voffset, MB_TO_BYTES(ALLOC_END_MB) + voffset, voffset);

	printf("memblock heap initialised in 0x%zx-0x%zx\n", MB_TO_BYTES(ALLOC_START_MB), MB_TO_BYTES(ALLOC_END_MB));

	for (int i = 0; i < 4; i++) {
		int size = 512 + (rand() % 16384);

		phys_addr_t alloc = memblock_alloc_phys(size);
		printf("allocated %d bytes at 0x%" PRIxPTR "\n", size, alloc);
	}

	vm_zone_descriptor_t zones[] = {
		{ .zd_id = VM_ZONE_DMA, .zd_name = "dma", .zd_base = 0x0, .zd_limit = MB_TO_BYTES(16) - 1 },
		{ .zd_id = VM_ZONE_NORMAL, .zd_name = "normal", .zd_base = MB_TO_BYTES(16), .zd_limit = MB_TO_BYTES(1024) - 1 },
		{ .zd_id = VM_ZONE_HIGHMEM, .zd_name = "highmem", .zd_base = MB_TO_BYTES(1024), .zd_limit = UINTPTR_MAX },
	};

	vm_bootstrap(zones, sizeof zones / sizeof zones[0]);

	printf("memory regions:\n");

	memblock_iter_t it;
	for_each_mem_range(&it, 0, 0x100000) {
		printf("\t%08" PRIxPTR "-%08" PRIxPTR "\n",
				it.it_base,
				it.it_limit);
	}

	printf("reserved regions:\n");
	for_each_reserved_mem_range(&it, 0, 0x100000) {
		printf("\t%08" PRIxPTR "-%08" PRIxPTR " (%s)\n",
				it.it_base,
				it.it_limit,
				it.it_status == MEMBLOCK_ALLOC ? "allocated" : "reserved");
	}

	printf("free regions:\n");
	for_each_free_mem_range(&it, 0, ULLONG_MAX) {
		printf("\t%08" PRIxPTR "-%08" PRIxPTR "\n",
				it.it_base,
				it.it_limit);
	}

	vm_pg_data_t *pg_data = vm_pg_data_get(0);
	printf("free pages:\n");
	for (int i = VM_ZONE_MIN; i <= VM_ZONE_MAX; i++) {
		print_free_pages(&pg_data->pg_zones[i]);
	}

	printf("all pages:\n");
	print_all_pages();

	vm_page_t *pg = vm_page_alloc(VM_PAGE_128K, 0);
	printf("allocated 128K at 0x%lx\n", vm_page_get_paddr(pg));

	vm_page_t *a, *b;
	if (vm_page_split(pg, &a, &b) == 0) {
		printf("split page into two 64K pages at 0x%lx and 0x%lx:\n", vm_page_get_paddr(a), vm_page_get_paddr(b));

		assert(a->p_flags & VM_PAGE_HEAD);
		assert(b->p_flags & VM_PAGE_HEAD);

		size_t nr_frames = vm_page_order_to_pages(VM_PAGE_128K);
		for (size_t i = 0; i < nr_frames; i++) {
			printf("  0x%lx: order:%u, flags:0x%x\n", vm_page_get_paddr(a + i), a[i].p_order, a[i].p_flags);
			assert(a[i].p_flags & VM_PAGE_HUGE);
			assert((a[i].p_flags & VM_PAGE_RESERVED) == 0);
		}
	}

	munmap(system_memory, MB_TO_BYTES(MEMORY_SIZE_MB));
	return 0;
}
sandbox: vm: encode vm_page zone id within p_flags 2023-02-01 12:26:49 +00:00			`#include "socks/queue.h"`
sandbox: extra page stats output 2023-01-29 20:10:35 +00:00			`#include <stdint.h>`
sandbox: re-organise test functions 2023-01-26 20:36:11 +00:00			`#include <stdio.h>`
			`#include <stddef.h>`
			`#include <stdlib.h>`
			`#include <inttypes.h>`
			`#include <time.h>`
			`#include <assert.h>`
			`#include <sys/mman.h>`
			`#include <socks/types.h>`
sandbox: vm: encode vm_page zone id within p_flags 2023-02-01 12:26:49 +00:00			`#include <socks/util.h>`
sandbox: re-organise test functions 2023-01-26 20:36:11 +00:00			`#include <socks/memblock.h>`
			`#include <socks/vm.h>`

			`/* we're working with 512MiB of simulated system RAM */`
			`#define MEMORY_SIZE_MB 512`

			`#define ALLOC_START_MB 16`
sandbox: increase memblock heap area size 2023-01-29 11:14:33 +00:00			`#define ALLOC_END_MB 32`
sandbox: re-organise test functions 2023-01-26 20:36:11 +00:00
			`#define MEMPTR(offset) ((uintptr_t)system_memory + (offset))`
			`#define MB_TO_BYTES(v) ((size_t)(v) * 0x100000)`

			`#define PHYS_TO_VIRT(p) ((void *)((uintptr_t)system_memory + (p)))`
			`#define VIRT_TO_PHYS(p) ((void *)((p) - (uintptr_t)system_memory))`

			`struct mem_map_region {`
			`phys_addr_t base;`
			`phys_addr_t limit;`
			`enum { REGION_FREE, REGION_RESERVED } status;`
			`};`

			`static struct mem_map_region mem_map[] = {`
			`{ .base = 0x00000000, .limit = 0x0000ffff, .status = REGION_RESERVED },`
			`{ .base = 0x00010000, .limit = 0x0004ffff, .status = REGION_FREE },`
			`{ .base = 0x00050000, .limit = 0x0005ffff, .status = REGION_RESERVED },`
			`{ .base = 0x00060000, .limit = 0x000fffff, .status = REGION_FREE },`
			`{ .base = 0x00100000, .limit = 0x001fffff, .status = REGION_RESERVED },`
			`{ .base = 0x00200000, .limit = 0x005fffff, .status = REGION_FREE },`
			`{ .base = 0x00600000, .limit = 0x007fffff, .status = REGION_RESERVED },`
			`{ .base = 0x00800000, .limit = MB_TO_BYTES(MEMORY_SIZE_MB) - 1, .status = REGION_FREE },`
			`};`

			`/* virtual address of where system memory is mapped */`
			`static void *system_memory = NULL;`

sandbox: vm: encode vm_page zone id within p_flags 2023-02-01 12:26:49 +00:00			`static void print_free_pages(vm_zone_t *z)`
sandbox: extra page stats output 2023-01-29 20:10:35 +00:00			`{`
sandbox: vm: encode vm_page zone id within p_flags 2023-02-01 12:26:49 +00:00			`printf(" * %s:\n", z->z_info.zd_name);`

sandbox: extra page stats output 2023-01-29 20:10:35 +00:00			`for (int i = VM_PAGE_MIN_ORDER; i <= VM_PAGE_MAX_ORDER; i++) {`
sandbox: vm: encode vm_page zone id within p_flags 2023-02-01 12:26:49 +00:00			`if (queue_length(&z->z_free_pages[i]) == 0) {`
			`continue;`
sandbox: extra page stats output 2023-01-29 20:10:35 +00:00			`}`
sandbox: vm: encode vm_page zone id within p_flags 2023-02-01 12:26:49 +00:00
			`char size_str[64];`
			`data_size_to_string(vm_page_order_to_bytes(i), size_str, sizeof size_str);`

			`printf(" - %u pages with size %s (order-%u)\n", queue_length(&z->z_free_pages[i]), size_str, i);`
sandbox: extra page stats output 2023-01-29 20:10:35 +00:00			`}`
			`}`

			`static void print_all_pages(void)`
			`{`
			`for (phys_addr_t i = 0; i < UINTPTR_MAX; ) {`
			`vm_page_t *pg = vm_page_get(i);`
			`if (!pg) {`
			`break;`
			`}`

sandbox: vm: encode vm_page zone id within p_flags 2023-02-01 12:26:49 +00:00			`vm_zone_t *z = vm_page_get_zone(pg);`
sandbox: extra page stats output 2023-01-29 20:10:35 +00:00			`printf(" * %08" PRIxPTR ": %s order-%u (%zu bytes) %s\n",`
			`i,`
sandbox: vm: encode vm_page zone id within p_flags 2023-02-01 12:26:49 +00:00			`z ? z->z_info.zd_name : "[none]",`
sandbox: extra page stats output 2023-01-29 20:10:35 +00:00			`pg->p_order,`
			`vm_page_order_to_bytes(pg->p_order),`
			`pg->p_flags & VM_PAGE_RESERVED ? "reserved" : "free");`
			`i += vm_page_order_to_bytes(pg->p_order);`
			`}`
			`}`

sandbox: re-organise test functions 2023-01-26 20:36:11 +00:00			`int memory_test(void)`
			`{`
			`srand(time(NULL));`
			`system_memory = mmap(`
			`NULL,`
			`MB_TO_BYTES(MEMORY_SIZE_MB),`
			`PROT_READ \| PROT_WRITE,`
			`MAP_PRIVATE \| MAP_ANONYMOUS,`
			`-1, 0);`

			`if (system_memory == MAP_FAILED) {`
			`perror("mmap");`
			`fprintf(stderr, "cannot allocate simulated system RAM buffer\n");`
			`return -1;`
			`}`

			`phys_addr_t pmem_base = UINTPTR_MAX, pmem_limit = 0;`
			`size_t nr_mem_map_entries = sizeof mem_map / sizeof mem_map[0];`

			`for (size_t i = 0; i < nr_mem_map_entries; i++) {`
			`if (mem_map[i].base < pmem_base) {`
			`pmem_base = mem_map[i].base;`
			`}`

			`if (mem_map[i].limit > pmem_limit) {`
			`pmem_limit = mem_map[i].limit;`
			`}`
			`}`

			`memblock_add(pmem_base, pmem_limit + 1);`

			`for (size_t i = 0; i < nr_mem_map_entries; i++) {`
			`if (mem_map[i].status == REGION_RESERVED) {`
			`memblock_reserve(mem_map[i].base, mem_map[i].limit - mem_map[i].base + 1);`
			`}`
			`}`

			`printf("allocated %u MiB (0x%zx bytes) of memory to act as system RAM at %p\n", MEMORY_SIZE_MB, MB_TO_BYTES(MEMORY_SIZE_MB), system_memory);`

			`printf("sizeof(vm_page_t) = %zu bytes\n", sizeof(vm_page_t));`

			`uintptr_t voffset = (uintptr_t)system_memory;`

			`memblock_init(MB_TO_BYTES(ALLOC_START_MB) + voffset, MB_TO_BYTES(ALLOC_END_MB) + voffset, voffset);`

			`printf("memblock heap initialised in 0x%zx-0x%zx\n", MB_TO_BYTES(ALLOC_START_MB), MB_TO_BYTES(ALLOC_END_MB));`

			`for (int i = 0; i < 4; i++) {`
			`int size = 512 + (rand() % 16384);`

			`phys_addr_t alloc = memblock_alloc_phys(size);`
			`printf("allocated %d bytes at 0x%" PRIxPTR "\n", size, alloc);`
			`}`

sandbox: vm: organise pages into zoned blocks 2023-01-28 19:24:28 +00:00			`vm_zone_descriptor_t zones[] = {`
			`{ .zd_id = VM_ZONE_DMA, .zd_name = "dma", .zd_base = 0x0, .zd_limit = MB_TO_BYTES(16) - 1 },`
			`{ .zd_id = VM_ZONE_NORMAL, .zd_name = "normal", .zd_base = MB_TO_BYTES(16), .zd_limit = MB_TO_BYTES(1024) - 1 },`
			`{ .zd_id = VM_ZONE_HIGHMEM, .zd_name = "highmem", .zd_base = MB_TO_BYTES(1024), .zd_limit = UINTPTR_MAX },`
			`};`

			`vm_bootstrap(zones, sizeof zones / sizeof zones[0]);`
sandbox: re-organise test functions 2023-01-26 20:36:11 +00:00
			`printf("memory regions:\n");`

			`memblock_iter_t it;`
			`for_each_mem_range(&it, 0, 0x100000) {`
			`printf("\t%08" PRIxPTR "-%08" PRIxPTR "\n",`
			`it.it_base,`
			`it.it_limit);`
			`}`

			`printf("reserved regions:\n");`
			`for_each_reserved_mem_range(&it, 0, 0x100000) {`
			`printf("\t%08" PRIxPTR "-%08" PRIxPTR " (%s)\n",`
			`it.it_base,`
			`it.it_limit,`
			`it.it_status == MEMBLOCK_ALLOC ? "allocated" : "reserved");`
			`}`

			`printf("free regions:\n");`
			`for_each_free_mem_range(&it, 0, ULLONG_MAX) {`
			`printf("\t%08" PRIxPTR "-%08" PRIxPTR "\n",`
			`it.it_base,`
			`it.it_limit);`
			`}`

sandbox: extra page stats output 2023-01-29 20:10:35 +00:00			`vm_pg_data_t *pg_data = vm_pg_data_get(0);`
			`printf("free pages:\n");`
			`for (int i = VM_ZONE_MIN; i <= VM_ZONE_MAX; i++) {`
sandbox: vm: encode vm_page zone id within p_flags 2023-02-01 12:26:49 +00:00			`print_free_pages(&pg_data->pg_zones[i]);`
sandbox: extra page stats output 2023-01-29 20:10:35 +00:00			`}`

			`printf("all pages:\n");`
			`print_all_pages();`

sandbox: vm: add page splitting, merging, and allocation 2023-02-01 15:03:42 +00:00			`vm_page_t *pg = vm_page_alloc(VM_PAGE_128K, 0);`
			`printf("allocated 128K at 0x%lx\n", vm_page_get_paddr(pg));`

			`vm_page_t a, b;`
			`if (vm_page_split(pg, &a, &b) == 0) {`
			`printf("split page into two 64K pages at 0x%lx and 0x%lx:\n", vm_page_get_paddr(a), vm_page_get_paddr(b));`

			`assert(a->p_flags & VM_PAGE_HEAD);`
			`assert(b->p_flags & VM_PAGE_HEAD);`

			`size_t nr_frames = vm_page_order_to_pages(VM_PAGE_128K);`
			`for (size_t i = 0; i < nr_frames; i++) {`
			`printf(" 0x%lx: order:%u, flags:0x%x\n", vm_page_get_paddr(a + i), a[i].p_order, a[i].p_flags);`
			`assert(a[i].p_flags & VM_PAGE_HUGE);`
			`assert((a[i].p_flags & VM_PAGE_RESERVED) == 0);`
			`}`
			`}`

sandbox: re-organise test functions 2023-01-26 20:36:11 +00:00			`munmap(system_memory, MB_TO_BYTES(MEMORY_SIZE_MB));`
			`return 0;`
			`}`