matos/core/uaddrspace.c
2024-02-08 23:15:29 +01:00

409 lines
12 KiB
C

#include "uaddrspace.h"
#include "alloc.h"
#include "kernel.h"
#include "klibc.h"
#include "list.h"
#include "mem.h"
#include "mmuContext.h"
#include "paging.h"
#include "process.h"
#include "stdarg.h"
#include "thread.h"
#include "types.h"
#include <assert.h>
#include <stddef.h>
#include <stdint.h>
struct uAddrSpace {
struct process *process; // The process that is represented by this AS
struct mmu_context *ctx; // The corresponding MMU configuration
struct uAddrVirtualReg *listVirtualReg; // List of Virtual Region used by this process
uaddr_t heapStart; // Start of the Head
size_t heapSize; // Heap size -> modified by brk()
};
static int hasOverlap(uaddr_t addr1, size_t size1, uaddr_t addr2, size_t size2)
{
return max(addr1, addr2) < min(addr1 + size1, addr2 + size2);
}
static struct uAddrVirtualReg *findVirtualRegionFromAddr(struct uAddrSpace *as, uaddr_t uaddr, size_t size)
{
struct uAddrVirtualReg *reg;
int idx;
list_foreach_named(as->listVirtualReg, reg, idx, prevInAddrSpace, nextInAddrSpace)
{
if (hasOverlap(reg->addr, reg->size, uaddr, size))
return reg;
}
return NULL;
}
static struct uAddrVirtualReg *findVirtualRegionBeforeAddr(struct uAddrSpace *as,
uaddr_t uaddr)
{
struct uAddrVirtualReg *reg, *prev = NULL;
int idx;
list_foreach_named(as->listVirtualReg, reg, idx, prevInAddrSpace, nextInAddrSpace)
{
if (uaddr > reg->addr)
break;
prev = reg;
}
return prev;
}
/**
* Find a address not alreay used in the virtual region of the AS.
* This address will be equals to uaddr if possible and could take size
*/
static uaddr_t findFreeAddrInVirtualRegion(struct uAddrSpace *as, uaddr_t uaddr, size_t size)
{
struct uAddrVirtualReg *reg, *regNext, *regOver;
if (uaddr < PAGING_BASE_USER_ADDRESS)
uaddr = PAGING_BASE_USER_ADDRESS;
if(uaddr > PAGING_TOP_USER_ADDRESS - size)
uaddr = PAGING_TOP_USER_ADDRESS - size;
reg = findVirtualRegionFromAddr(as, uaddr, size);
if (!reg)
return uaddr;
int idx;
regOver = reg;
//Find last region that overlap
list_foreach_named(reg->nextInAddrSpace, regNext, idx, prevInAddrSpace, nextInAddrSpace){
if(!hasOverlap(uaddr, size, regNext->addr, regNext->size))
break;
regOver = regNext;
}
uaddr = regOver->addr + regOver->size;
list_foreach_named(regOver->nextInAddrSpace, regNext, idx, prevInAddrSpace,
nextInAddrSpace)
{
if (!hasOverlap(uaddr, size, regNext->addr, regNext->size) &&
uaddr <= (PAGING_TOP_USER_ADDRESS - size)) {
return uaddr;
}
if (reg == regNext) // Already checked region
break;
uaddr = regNext->addr + regNext->size;
}
return (uaddr_t)NULL;
}
struct uAddrSpace *uAddrSpaceCreate(struct process *proc)
{
struct uAddrSpace *addr = (struct uAddrSpace *)zalloc(sizeof(struct uAddrSpace));
if (addr == NULL)
return NULL;
addr->ctx = mmuContextCreate();
if (addr->ctx == NULL) {
free(addr);
return NULL;
}
addr->process = proc;
list_init(addr->listVirtualReg);
return addr;
}
int uAddrSpaceDelete(struct uAddrSpace *addr)
{
struct uAddrVirtualReg *reg;
list_collapse_named(addr->listVirtualReg, reg, nextInAddrSpace, prevInAddrSpace) {
if (reg->res == NULL) {
// This is memory allocated for the heap just unmap it to free it
pr_devel("Freeing heap 0x%lx for process %s\n", reg->addr,
processGetName(addr->process));
pageUnmap(reg->addr);
free(reg);
} else {
if(reg->res->ops){
if(reg->res->ops->unmap)
reg->res->ops->unmap(reg, reg->addr, reg->size);
if(reg->res->ops->close)
reg->res->ops->close(reg);
}
free(reg);
}
}
return mmuContextUnref(addr->ctx);
}
/**
* Find the associated uAddrVirtualReg associated to the unmap space and free them;
*/
int uAddrSpaceUnmap(struct uAddrSpace *as, uaddr_t uaddr, size_t size)
{
if (uaddr < PAGING_BASE_USER_ADDRESS || uaddr > PAGING_TOP_USER_ADDRESS - size)
return -EINVAL;
if (!ALIGN(uaddr, PAGE_SIZE) || size <= 0)
return -EINVAL;
size = ALIGN(size, PAGE_SIZE);
struct uAddrVirtualReg *reg = as->listVirtualReg;
struct uAddrVirtualReg *lastReg = reg ? reg->prevInAddrSpace : NULL;
while (reg != NULL) {
if (reg->addr > uaddr + size)
break;
struct uAddrVirtualReg *next = reg->nextInAddrSpace;
// The Virtual Region is completly inside the unmaped space
if (reg->addr >= uaddr && (reg->addr + reg->size <= uaddr + size)) {
list_delete_named(as->listVirtualReg, reg, prevInAddrSpace, nextInAddrSpace);
list_delete_named(reg->res->listVirtualReg, reg, prevInMappedRes, nextInMappedRes);
if (reg->res->ops && reg->res->ops->close)
reg->res->ops->close(reg);
free(reg);
// Unmaped space is inside and smaller than the VR
// VR should be splitted
} else if (reg->addr > uaddr && (reg->addr + reg->size <= uaddr + size)) {
struct uAddrVirtualReg *new =
(struct uAddrVirtualReg *)zalloc(sizeof(struct uAddrSpace));
if (!new)
return -ENOMEM;
new->addr = uaddr + size;
new->size = reg->addr + reg->size - (uaddr + size);
new->right = reg->right;
new->offset = uaddr + size - reg->addr;
reg->size = uaddr - reg->addr;
list_insert_after_named(as->listVirtualReg, reg, new, prevInAddrSpace,
nextInAddrSpace);
list_insert_after_named(reg->res->listVirtualReg, reg, new, prevInMappedRes,
nextInMappedRes);
if (reg->res->ops && reg->res->ops->unmap)
reg->res->ops->unmap(reg, uaddr, size);
if (new->res->ops &&new->res->ops->open)
new->res->ops->open(new);
break;
// Only affect the beginning
} else if (uaddr <= reg->addr && uaddr + size > reg->addr) {
size_t offset = uaddr + size - reg->addr;
reg->size -= offset;
reg->offset += offset;
reg->addr += offset;
if (reg->res->ops && reg->res->ops->unmap)
reg->res->ops->unmap(reg, uaddr, size);
break;
// Only affect the end
} else if (uaddr > reg->addr && uaddr + size > reg->addr + reg->size) {
size_t unmapSize = reg->addr + reg->size - uaddr;
reg->size = uaddr - reg->addr;
if (reg->res->ops && reg->res->ops->unmap)
reg->res->ops->unmap(reg, uaddr, unmapSize);
}
reg = next;
if (reg == lastReg)
break;
}
int needMMUSetup = as->ctx != getCurrentThread()->squattedContext;
if (needMMUSetup)
threadChangeCurrentContext(as->ctx);
for (vaddr_t addr = uaddr; addr < uaddr + size; addr += PAGE_SIZE) {
pageUnmap(addr);
}
if (needMMUSetup)
threadChangeCurrentContext(NULL);
return 0;
}
struct mmu_context *uAddrSpaceGetMMUContext(struct uAddrSpace *addr)
{
return addr->ctx;
}
int uAddrSpaceSetHeap(struct uAddrSpace *as, uaddr_t addr, size_t size)
{
as->heapStart = addr;
as->heapSize = size;
return 0;
}
uaddr_t sysBrk(struct uAddrSpace *as, uaddr_t newHeapTop)
{
int incSize;
assert(as->heapStart);
if (!newHeapTop || newHeapTop < as->heapStart)
return as->heapStart + as->heapSize;
newHeapTop = ALIGN(newHeapTop, PAGE_SIZE);
if (newHeapTop == as->heapStart + as->heapSize)
return newHeapTop;
incSize = ALIGN(newHeapTop - (as->heapStart + as->heapSize), PAGE_SIZE);
if (incSize < 0){
//TODO how to free allocated page by uAddrSpaceHeapCheckNAlloc
return as->heapStart + as->heapSize;
}
as->heapSize += incSize;
return as->heapStart + as->heapSize;
}
int uAddrSpaceHeapCheckNAlloc(struct uAddrSpace *as, vaddr_t addr)
{
struct uAddrVirtualReg *newReg;
int right = PAGING_MEM_USER | PAGING_MEM_WRITE | PAGING_MEM_READ;
pr_devel("Checking 0x%lx inside 0x%lx and 0x%lx\n", addr, as->heapStart,
as->heapStart + as->heapSize);
if (addr < as->heapStart || addr >= as->heapStart + as->heapSize) {
return -1;
}
pr_devel("Alloc heap for process %s\n", processGetName(as->process));
vaddr_t addrAlign = ALIGN_DOWN(addr, PAGE_SIZE);
paddr_t ppage = allocPhyPage(1);
if (0 != pageMap(addrAlign, ppage, right))
goto free_ppage;
newReg = zalloc(sizeof(struct uAddrVirtualReg));
if (newReg == NULL)
goto free_ppage;
newReg->addr = addrAlign;
newReg->size = PAGE_SIZE;
newReg->right = right;
list_add_tail_named(as->listVirtualReg, newReg, nextInAddrSpace, prevInAddrSpace);
unrefPhyPage(ppage);
return 0;
free_ppage:
unrefPhyPage(ppage);
return -1;
}
int uAddrSpaceMmap(struct uAddrSpace *as, uaddr_t *uaddr, size_t size, uint32_t rights,
uint32_t flags, struct mappedRessource *res, uint32_t offset )
{
int ret = 0;
uaddr_t hint_uaddr = *uaddr;
if (res == NULL || res->ops == NULL || res->ops->nopage == NULL)
return -ENOENT;
if (!IS_ALIGNED(hint_uaddr, PAGE_SIZE) || size <= 0)
return -EINVAL;
if (flags & UA_MAP_SHARED) {
if (((rights & PAGING_MEM_READ) && !(res->allowedRight & PAGING_MEM_READ)) ||
((rights & PAGING_MEM_WRITE) && !(res->allowedRight & PAGING_MEM_WRITE)) ||
((rights & PAGING_MEM_EXEC) && !(res->allowedRight & PAGING_MEM_EXEC)))
return -EPERM;
}
struct uAddrVirtualReg *reg =
(struct uAddrVirtualReg *)malloc(sizeof(struct uAddrVirtualReg));
if (!reg)
return -ENOMEM;
if (flags & UA_MAP_FIXED) {
if (hint_uaddr < PAGING_BASE_USER_ADDRESS ||
hint_uaddr > PAGING_TOP_USER_ADDRESS - size) {
ret = -EINVAL;
goto free_reg;
}
ret = uAddrSpaceUnmap(as, hint_uaddr, size);
if (ret)
goto free_reg;
} else {
hint_uaddr = findFreeAddrInVirtualRegion(as, hint_uaddr, size);
if (!hint_uaddr) {
ret = -ENOMEM;
goto free_reg;
}
}
reg->addr = hint_uaddr;
reg->size = size;
reg->right = rights;
reg->res = res;
reg->offset = offset;
// TODO merge it with prev/next one
// keep the AddrSpace list sorted
struct uAddrVirtualReg *prev = findVirtualRegionBeforeAddr(as, hint_uaddr);
if (prev)
list_insert_after_named(as->listVirtualReg, prev, reg, prevInAddrSpace,
nextInAddrSpace);
else
list_add_tail_named(as->listVirtualReg, reg, prevInAddrSpace, nextInAddrSpace);
list_add_tail_named(reg->res->listVirtualReg, reg, prevInMappedRes, nextInMappedRes);
if (res->onResMapped) {
int cbret = res->onResMapped(reg);
if (cbret) {
pr_devel("Call back failed on ressource mmaped\n");
ret = uAddrSpaceUnmap(as, reg->addr, reg->size);
}
}
if (res->ops->open)
res->ops->open(reg);
*uaddr = hint_uaddr;
return ret;
free_reg:
free(reg);
return ret;
}
/**
* Check if @param faultAddr could be managed by the uAddrVirtualReg from @param as
**/
int uAddrSpaceSolvePageFault(struct uAddrSpace *as, vaddr_t faultAddr, int isWriteAccess)
{
struct uAddrVirtualReg *reg;
int rights = PAGING_MEM_READ;
reg = findVirtualRegionFromAddr(as, faultAddr, 1);
if (reg == NULL)
return -EFAULT;
if (isWriteAccess && !(reg->right & PAGING_MEM_WRITE))
return -EACCES;
if (isWriteAccess)
rights |= PAGING_MEM_WRITE;
if (reg->res->ops->nopage(reg, faultAddr, rights))
return -EFAULT;
return 0;
}