This commit is contained in:
quackerd 2020-06-23 16:20:23 +08:00
parent a9f2b48a95
commit e573ec96b8
Signed by: d
GPG Key ID: 590A22374D0B819F
12 changed files with 130 additions and 92 deletions

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@ -22,11 +22,11 @@ set(TOOLCHAINS
LD
DMP)
FOREACH(f IN LISTS TOOLCHAINS)
if(NOT ${f})
FOREACH (f IN LISTS TOOLCHAINS)
if (NOT ${f})
message(FATAL_ERROR "Toolchain ${f} cannot be found.")
endif()
endforeach(f)
endif ()
endforeach (f)
set(CC_WARN_IGNORE
-Wno-gnu-statement-expression # this means we can assign the return val of the last statment in a block, useful in MAX, MIN, etc.
@ -78,15 +78,15 @@ set(SUBMODULES
test)
# process submodules
FOREACH(f IN LISTS SUBMODULES)
FOREACH (f IN LISTS SUBMODULES)
add_subdirectory(${f})
endforeach(f)
endforeach (f)
# process dependencies
FOREACH(f IN LISTS SUBMODULES)
FOREACH (f IN LISTS SUBMODULES)
set(OBJS ${OBJS} ${OBJS_${f}})
set(TARGETS ${TARGETS} ${TARGET_${f}})
endforeach(f)
endforeach (f)
# set target names
@ -136,9 +136,11 @@ add_custom_target(${proj}_iso ALL
# hack for clion not parsing custom targets
if ($ENV{CLION_IDE})
SET(CMAKE_C_COMPILER ${CC})
include_directories(${INC})
add_executable(kernel ${G_CC_SRC})
add_definitions(-DKOPT_DBG)
target_compile_options(kernel PRIVATE ${CC_FLAGS})
endif()
endif ()

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@ -1,6 +1,7 @@
#include <arch/brute.h>
void arch_brute()
ATTR_NORETURN void
arch_brute()
{
while(1) {}
}

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@ -1,65 +1,81 @@
#include <common/cdef.h>
#include <common/consts.h>
#include <ke/print.h>
#include <arch/print.h>
#include <arch/brute.h>
#include <mm/phys.h>
#include <arch/mlayout.h>
#include <arch/pmap.h>
#include <mm/phys.h>
// private headers
#include "multiboot2.h"
#include "pmap_p.h"
static const char* _loader_name;
// kernel entry point
extern void kmain();
extern void
kmain();
ATTR_USED void
arch_main(void *mb_info)
/*
* process muliboot info and populate various subsystems
* after this mate, the original multiboot info can be safely discarded
*/
static void
proc_mbinfo(void *mb_info)
{
/* init printf related stuff */
arch_print_init();
kprintf("Processing multiboot info @ 0x%p...\n", mb_info);
uint8 mmap_detected = 0;
for (struct multiboot_tag *tag = (struct multiboot_tag *) ((uintptr) mb_info + 8);
tag->type != MULTIBOOT_TAG_TYPE_END;
tag = (struct multiboot_tag *) ((multiboot_uint8_t *) tag
+ ((tag->size + 7) & ~7u))) {
// kprintf("Tag 0x%p: %d, Size %d\n", (void *) tag, tag->type, tag->size);
PDBG("Tag 0x%p: %d, Size %d", (void *) tag, tag->type, tag->size);
switch (tag->type) {
case MULTIBOOT_TAG_TYPE_MMAP:
kprintf("Found multiboot memory map.\n");
mmap_detected = 1;
PDBG("Detected MultiBoot memory map.");
for (struct multiboot_mmap_entry *entry = ((struct multiboot_tag_mmap *) tag)->entries;
(multiboot_uint8_t *) entry < (multiboot_uint8_t *) tag + tag->size;
entry = (multiboot_memory_map_t *) ((uintptr) entry +
((struct multiboot_tag_mmap *) tag)->entry_size)) {
kprintf("Adding to pmap seg: base = 0x%lx,"
" length = 0x%lx, type = 0x%x.\n",
PDBG("Adding to pmap seg: base = 0x%lx,"
" length = 0x%lx, type = 0x%x.",
(ulong) entry->addr,
(ulong) entry->len,
entry->type);
if (entry->type == MULTIBOOT_MEMORY_AVAILABLE) {
// add physical segments to mm phys subsystem
arch_mem_addseg(entry->addr, entry->len);
archp_mem_addseg(entry->addr, entry->len);
}
}
break;
case MULTIBOOT_TAG_TYPE_BOOT_LOADER_NAME:
kprintf("Found multiboot loader name.\n");
_loader_name = ((struct multiboot_tag_string *) tag)->string;
PDBG("Detected bootloader: %s", ((struct multiboot_tag_string *) tag)->string);
break;
default:
kprintf("Ignoring multiboot tag type: %d size: 0x%x\n", tag->type, tag->size);
PDBG("Ignoring MultiBoot tag type: %d size: 0x%x", tag->type, tag->size);
break;
}
}
kprintf("BoND is loaded by: %s\n", _loader_name);
kprintf("kernel start: 0x%p end: 0x%p\n", (void*)KERN_IMG_START, (void*)ARCH_ML_KIMAGE_STOP);
if (!mmap_detected) {
BRUTE("proc_mbinfo: could not find MMAP tag.");
}
}
kprintf("Initializing memory...");
arch_mem_init();
ATTR_USED void
arch_main(void *mb_info)
{
arch_print_init();
PINFO("BoND %s. Kernel loaded at: 0x%p size: 0x%lx.", KVERSION, (void *) ARCH_ML_KIMAGE_START,
(usize) (ARCH_ML_KIMAGE_STOP - ARCH_ML_KIMAGE_START));
PINFO("Processing MultiBoot struct at 0x%p...", mb_info);
proc_mbinfo(mb_info);
// at this point we don't need access to multiboot info anymore -> we can freely overwrite this region
PINFO("Initializing early memory...");
archp_mem_init();
kmain();
}

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@ -3,26 +3,26 @@
#include <mm/phys.h>
#include <common/libkern.h>
#include "pmap_p.h"
#include "paging.h"
struct arch_pmap_segs {
mm_paddr start;
mm_paddr stop;
struct arch_pmap_segs
{
mm_paddr base;
usize len;
};
// the physical memory segments information obtained from multiboot info
static struct arch_pmap_segs _phys_segs[ARCH_PMAP_MAX_PHYS_SEGS];
static usize _phys_segs_sz = 0;
static struct arch_pmap_segs phys_segs[ARCH_PMAP_MAX_PHYS_SEGS];
static usize phys_segs_sz = 0;
// the base addr for mm_page structures
static mm_paddr _mm_pages_base;
// initializes _pmap region
static void
_pmap_init(mm_paddr *cur_addr, arch_pml4e *kern_pml4)
pmap_init(mm_paddr *cur_addr, arch_pml4e *kern_pml4)
{
usize high_mem = _phys_segs[_phys_segs_sz - 1].stop;
usize high_mem = phys_segs[phys_segs_sz - 1].stop;
if (high_mem >= ARCH_ML_MAX_RAM) {
BRUTE("Only supports maximum %ld bytes RAM", ARCH_ML_MAX_RAM);
@ -44,16 +44,16 @@ _pmap_init(mm_paddr *cur_addr, arch_pml4e *kern_pml4)
}
static void
_mm_pg_init(mm_paddr *cur_addr, arch_pml4e *kern_pml4)
mm_pg_init(mm_paddr *cur_addr, arch_pml4e *kern_pml4)
{
}
// initializes kernel mapping
static void
_kern_mapping_init(mm_paddr *cur_addr, arch_pml4e *kern_pml4)
kern_mapping_init(mm_paddr *cur_addr, arch_pml4e *kern_pml4)
{
// map the kernel with 2MB mapping now
// map the kernel with 4KB mapping now
KASSERT((ARCH_ML_KIMAGE_PADDR & (PDE_MAPPING_SZ - 1)) == 0, "kernel vaddr not 2MB aligned.");
KASSERT(((uintptr) KERN_IMG_START & (PDE_MAPPING_SZ - 1)) == 0, "kernel paddr not 2MB aligned.");
@ -97,29 +97,32 @@ arch_pmap_map(mm_paddr paddr, ATTR_UNUSED usize sz)
mm_paddr
arch_paddr_to_mm_page(mm_paddr paddr)
{
return (paddr / ARCH_KPAGE_SZ) * sizeof(struct mm_page) + _mm_pages_base;
return (paddr / ARCH_KPAGE_SZ) * sizeof(struct mm_phys_page) + _mm_pages_base;
}
// adds an available physical segment to _phys_segs
// adds an available physical segment to phys_segs
void
arch_mem_addseg(mm_paddr start, usize len)
archp_mem_addseg(mm_paddr start, usize len)
{
KASSERT(_phys_segs_sz < ARCH_PMAP_MAX_PHYS_SEGS, "too many physical segments!");
_phys_segs[_phys_segs_sz].start = start;
_phys_segs[_phys_segs_sz].stop = start + len - 1;
_phys_segs_sz++;
if (phys_segs_sz >= ARCH_PMAP_MAX_PHYS_SEGS) {
BRUTE("archp_mem_addseg: too many physical segments.");
}
phys_segs[phys_segs_sz].base = start;
phys_segs[phys_segs_sz].len = start + len - 1;
phys_segs_sz++;
}
// sets up paging for kernel and mm_pages for mm_phys
// specifically, we do:
// 1. Map the kernel to KERN_BASE
// 2. Allocate mm_page for the all physical memory (avail and unavail) and put them after the kernel paddr
// 2.5. Map all mm_page (s) to KERN_MM_PAGE_START
// 3. Direct map all available physical memory to PMAP_BASE
// 4. Save the mapping and switch the page table to the new table
// 5. Save the information to mm_phys for future phys setup
/* sets up initial paging and mm_phys_pages
* specifically, we do:
* 1. Map the kernel to KERN_BASE
* 2. Allocate mm_page for the all physical memory (avail and unavail) and put them after the kernel paddr
* 2.5. Map all mm_page (s) to KERN_MM_PAGE_START
* 3. Direct map all available physical memory to PMAP_BASE
* 4. Save the mapping and switch the page table to the new table
* 5. Save the information to mm_phys for future phys setup
*/
void
arch_mem_init()
archp_mem_init()
{
// we use 2M (PDE) pages to map the kernel so align the physical address to 2MB
mm_paddr cur_addr = ALIGN_UP2(ARCH_ML_KIMAGE_PADDR, PDE_MAPPING_SZ);
@ -129,13 +132,13 @@ arch_mem_init()
memset(kern_pml4, 0, ARCH_KPAGE_SZ);
cur_addr += ARCH_KPAGE_SZ;
_kern_mapping_init(&cur_addr, kern_pml4);
_mm_pg_init(&cur_addr, kern_pml4);
_pmap_init(&cur_addr, kern_pml4);
kern_mapping_init(&cur_addr, kern_pml4);
mm_pg_init(&cur_addr, kern_pml4);
pmap_init(&cur_addr, kern_pml4);
// copy the physical segments information to mm_phys
for (usize i = 0; i < _phys_segs_sz; i++) {
mm_phys_add_phys_seg(_phys_segs[i].start, _phys_segs[i].stop);
for (usize i = 0; i < phys_segs_sz; i++) {
mm_phys_add_phys_seg(phys_segs[i].start, phys_segs[i].stop);
}
// add reserved segment information to mm_phys

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@ -1,12 +0,0 @@
#pragma once
#include <arch/mlayout.h>
#define ARCH_PMAP_TO_PHYS(pmaddr) ((pmaddr) - ARCH_ML_PMAP_START)
#define ARCH_PHYS_TO_PMAP(paddr) (ARCH_ML_PMAP_START + (paddr))
void
arch_mem_init();
void
arch_mem_addseg(uintptr start, usize len);

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@ -1,3 +1,5 @@
#pragma once
#include <common/cdef.h>
void arch_brute();
ATTR_NORETURN void
arch_brute();

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@ -22,6 +22,15 @@ arch_pmap_mapdev(mm_paddr paddr, usize size);
#define ARCH_VADDR_ATTR_UNCACHED (0x2u)
#define ARCH_VADDR_ATTR_READONLY (0x4u)
#define ARCH_VADDR_ATTR_NX (0x8u)
int
arch_map_vaddr(void * base, mm_paddr paddr, uintptr vaddr, usize sz, uint attr);
// module-private functions
#define ARCH_PMAP_TO_PHYS(pmaddr) ((pmaddr) - ARCH_ML_PMAP_START)
#define ARCH_PHYS_TO_PMAP(paddr) (ARCH_ML_PMAP_START + (paddr))
void
archp_mem_init();
void
archp_mem_addseg(uintptr start, usize len);

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@ -36,5 +36,7 @@ typedef unsigned short ushort;
#define ATTR_SECTION(x) __attribute__ ((section (#x)))
#define ATTR_ALIGN(x) __attribute__((aligned (x)))
#define ATTR_FMT_PRINTF __attribute__((format (printf, 1, 2)))
#define ATTR_NORETURN _Noreturn
#define BOCHS_BREAK __asm__("xchg %bx, %bx")

3
inc/common/consts.h Normal file
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@ -0,0 +1,3 @@
#pragma once
#define KVERSION ("0.1")

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@ -8,3 +8,13 @@ kprintf(const char *fmt, ...);
int
kvprintf(const char *fmt, va_list args);
#ifdef KOPT_DBG
#define PDBG(fmt, ...) (kprintf("[DEBUG] " fmt "\n", ##__VA_ARGS__))
#else
#define PDBG(fmt, ...)
#endif
#define PWARN(fmt, ...) (kprintf("[WARN] " fmt "\n", ##__VA_ARGS__))
#define PINFO(fmt, ...) (kprintf("[INFO] " fmt "\n", ##__VA_ARGS__))
#define PERR(fmt, ...) (kprintf("[ERROR] " fmt "\n", ##__VA_ARGS__))

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@ -6,23 +6,24 @@
typedef uintptr mm_paddr;
struct mm_page {
struct mm_phys_page {
struct ke_spin_lock page_lock; // page lock
mm_paddr phys_addr; // physical address of the page
uint8 phys_order; // order of the page in the buddy allocator
uint8 phys_pool; // which pool it belongs to in the buddy allocator
struct list_entry phys_flist_ent; // list entry for the free list in the buddy allocator
};
uint8 order; // order of the page in the buddy allocator
uint8 free;
} ATTR_ALIGN(8);
// maximum allocated page sz = 2^10 * 4096
#define MM_PHYS_ORDER_MAX (10)
#define MM_PHYS_ORDER_FREE (MM_PAGE_ORDER_MAX + 1)
#define MM_PHYS_POOL_DMA (0)
#define MM_PHYS_POOL_GENERIC (1)
// DMA ZONE, 0 - 16MB
#define MM_PHYS_ARENA_DMA (0)
#define MM_PHYS_ARENA_MAX_ADDR (16 * 1024 * 1024)
// GENERIC ZONE
#define MM_PHYS_ARENA_GENERIC (1)
#define MM_PHYS_MAX_POOLS (MM_PHYS_POOL_DMA + 1)
void
mm_phys_add_phys_seg(mm_paddr start, usize len);
void
mm_phys_add_reserved_seg(mm_paddr start, usize len);

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@ -6,6 +6,7 @@ struct mm_phys_seg {
mm_paddr stop;
};
static ATTR_UNUSED struct list_entry _freelist[MM_PHYS_MAX_POOLS][MM_PHYS_ORDER_MAX];
static struct mm_phys_seg _phys_segs[ARCH_PMAP_MAX_PHYS_SEGS];