优化内存分配函数的调用方法

include/kernel/memm.h

@@ -64,9 +64,6 @@ typedef struct __allocator_iterator_t
 {
     allocator_t *allocator;
     struct __allocator_iterator_t *left, *right;
-
-    // 这个节点的内存空间处于的那个分配器
-    allocator_t *owned_allocator;
 } allocator_iterator_t;
 
 /*
@@ -137,13 +134,19 @@ pid=0时为内核分配
 所有内存在内核空间都有对物理内存空间的直接映射，也就是线性地址与物理地址相同，称为内核地址
 
 allocator对象在进程与内核之间传递时一律使用内核空间的映射地址
+
+## 要求在返回的地址前16字节处保留8字节空间作为它所在的allocator地址，并且不需要分配器的具体实现做这个事
  */
-void *memm_allocate(usize size, usize pid, allocator_t **allocator);
+void *memm_allocate(usize size, usize pid);
+#define memm_addr_set_allocator(mem, allocator) \
+    *(allocator_t **)(mem - 16) = allocator;
+#define memm_addr_get_allocator(mem) \
+    ((*(allocator_t **)(mem - 16)))
 
 /*
 释放内存
  */
-void memm_free(allocator_t *allocator, void *mem);
+void memm_free(void *mem);
 
 /*
 寻找大小合适的一组页

include/kernel/memm/allocator/raw.h

@@ -2,13 +2,16 @@
 #define RAW_H 1
 
 #include <types.h>
+#include <kernel/memm.h>
 
 #define MEMM_RAW_ALLOCATOR 1
 
 typedef struct __raw_allocator_cell
 {
-    usize capacity; // 是content的长度
+    usize capacity;         // 是content的长度
-    usize length;   // 是实际使用的长度
+    usize length;           // 是实际使用的长度
+    allocator_t *allocator; // 所在的分配器
+    usize reserved;
     u8 content[0];
 } raw_allocator_cell;
 #define raw_allocator_next_cell(cell) (raw_allocator_cell *)((void *)((cell)->content) + (cell)->capacity)

include/kernel/tty.h

@@ -59,8 +59,6 @@ typedef struct __tty
     tty_typeinfo typeinfo;
     tty_mode mode;
     tty_text_state text;
-
-    allocator_t *allocator;
 } tty;
 
 // tty控制器

include/libk/lst.h

@@ -16,10 +16,6 @@ typedef struct __lst_line_t
 typedef struct __lst_iterator_t
 {
     lst_line_t line;
-    // 这个指针是kernel/memm.h中的allocator_t *
-    // 代表当前lst_line_index_t对象在allocate时使用的allocator
-    // 用的话会造成递归include
-    void *allocator;
     struct __lst_iterator_t *next;
 } lst_iterator_t;
 

src/kernel/memm/memm.c

@@ -29,7 +29,6 @@ mem_manager_t *memm_new(usize mem_size)
     alcatr_ind->allocator = allocator0;
     alcatr_ind->left = nullptr;
     alcatr_ind->right = nullptr;
-    alcatr_ind->owned_allocator = allocator0;
 
     memory_manager.allocators = alcatr_ind;
 
@@ -159,11 +158,12 @@ static void insert_allocator(allocator_iterator_t *iter, allocator_iterator_t *i
     }
 }
 
-void *memm_allocate(usize size, usize pid, allocator_t **allocator)
+void *memm_allocate(usize size, usize pid)
 {
     usize orgsize = size;
     // 从分配器树中分配内存
-    void *ptr = memm_find_and_allocate(memory_manager.allocators, size, pid, allocator);
+    allocator_t *allocator;
+    void *ptr = memm_find_and_allocate(memory_manager.allocators, size, pid, &allocator);
     if (ptr != nullptr)
         goto after_allocation;
 
@@ -190,11 +190,9 @@ void *memm_allocate(usize size, usize pid, allocator_t **allocator)
     allocator_t *new_allocator =
         memm_allocator_new((void *)(allocator_start * MEMM_PAGE_SIZE), size * MEMM_PAGE_SIZE,
                            MEMM_RAW_ALLOCATOR, pid);
-    *allocator = new_allocator;
+    allocator = new_allocator;
 
-    allocator_t *all;
+    allocator_iterator_t *allind = memm_allocate(sizeof(allocator_iterator_t), 0);
-    allocator_iterator_t *allind = memm_allocate(sizeof(allocator_iterator_t), 0, &all);
-    allind->owned_allocator = all;
     allind->allocator = new_allocator;
     allind->left = nullptr;
     allind->right = nullptr;
@@ -202,6 +200,7 @@ void *memm_allocate(usize size, usize pid, allocator_t **allocator)
     ptr = new_allocator->allocate(&new_allocator->allocator_instance, orgsize, 0);
 
 after_allocation:
+    memm_addr_set_allocator(ptr, allocator);
     if (pid != 0)
     { // TODO 进程管理中应该有一个用户地址-内核地址映射表
       // 在进程分配时将页映射到用户空间中，并将这个映射关系记录进这个表中
@@ -210,8 +209,9 @@ after_allocation:
     return ptr;
 }
 
-void memm_free(allocator_t *allocator, void *mem)
+void memm_free(void *mem)
 {
+    allocator_t *allocator = memm_addr_get_allocator(mem);
     if (is_user_address((u64)mem))
     { // TODO 对于用户空间的地址需要先转换到内核地址后释放
     }

src/kernel/tty/tty.c

@@ -16,12 +16,10 @@ tty_controller_t *tty_controller_new()
 
 tty *tty_new(tty_type type, tty_mode mode)
 {
-    allocator_t *allocator;
+    tty *__tty = memm_allocate(sizeof(tty), 0);
-    tty *__tty = memm_allocate(sizeof(tty), 0, &allocator);
     memset(__tty, 0, sizeof(tty));
     __tty->type = type;
     __tty->mode = mode;
-    __tty->allocator = allocator;
     tty *res = nullptr;
     for (usize i = 0; i < TTY_MAX_NUM; ++i)
     {

src/libk/lst.c

@@ -7,11 +7,9 @@
 
 lst_iterator_t *lst_new(usize start, usize end)
 {
-    allocator_t *allocator;
+    lst_iterator_t *lst = memm_allocate(sizeof(lst_iterator_t), 0);
-    lst_iterator_t *lst = memm_allocate(sizeof(lst_iterator_t), 0, &allocator);
     lst->line.left = start;
     lst->line.right = end;
-    lst->allocator = allocator;
     lst->next = nullptr;
     return lst;
 }
@@ -130,9 +128,7 @@ bool lst_add(lst_iterator_t *lst, usize left, usize right, bool force)
                 lst->line.left = left;
             else
             {
-                allocator_t *alloctr;
+                lst_iterator_t *new_node = memm_allocate(sizeof(lst_iterator_t), 0);
-                lst_iterator_t *new_node = memm_allocate(sizeof(lst_iterator_t), 0, &alloctr);
-                new_node->allocator = alloctr;
                 new_node->line = line;
                 new_node->next = lst;
                 if (last != nullptr)
@@ -169,7 +165,7 @@ bool lst_add(lst_iterator_t *lst, usize left, usize right, bool force)
                     }
                     tmplast = *tmpnode;
                     lst_iterator_t *t = lst_next(tmpnode);
-                    memm_free(tmpnode->allocator, tmpnode);
+                    memm_free(tmpnode);
                     tmpnode = t;
                 }
                 lst->line.right = max(tmplast.line.right, right);