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11c01ab7f67092354f2760fa60d34932442e8958
bsb2/kernel/syscall/skeleton.cc

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#include "../syscall/skeleton.h"
#include "../debug/kernelpanic.h"
#include "../debug/output.h"
#include "../device/textstream.h"
#include "../interrupt/guard.h"
#include "../memory/page.h"
#include "../sync/semaphore.h"
#include "../thread/scheduler.h"
#include "../memory/pageframealloc.h"
#include "../memory/pagetable.h"
#include "../arch/idt.h"
void *operator new(size_t, void *);
//#include "../user/app1/appl.h"
//extern Application apps[];
uint8_t mapNumber = 0;
namespace Syscall {
namespace Skeleton {
void invlpg(uintptr_t virt_addr) {
asm volatile("invlpg (%0)" : : "r" (virt_addr) : "memory");
}
size_t test(Vault &vault, size_t p1, size_t p2, size_t p3, size_t p4,
size_t p5) {
(void)vault;
vault.kout << "test(" << p1 << ", " << p2 << ", " << p3 << ", " << p4
<< ", " << p5 << ");" << endl;
return 0xdeadbeef;
}
int getpid(Vault &vault) {
Thread *me = vault.scheduler.active();
//unsigned id = 0;
//while (&apps[id++] != me); // TODO find better pid source
//return id;
return me->id;
}
size_t write(Vault &vault, uint32_t id, const void *buffer, size_t size, int x, int y) {
(void)id;
TextStream* out;
switch (id) {
case 1:
out = &vault.kout;
break;
case 2:
out = &dout;
break;
default:
out = &vault.kout;
}
int dummy;
if(x == -1 && y != -1)
out->getPos(x, dummy);
if(x != -1 && y == -1)
out->getPos(dummy, y);
if(x == -1 && y == -1)
out->getPos(x, y);
out->setPos(x, y);
for(size_t i = 0; i<size; i++)
*out << ((char*)buffer)[i];
out->flush();
return 0;
}
size_t read(Vault &vault, uint32_t id, void *buf, size_t len) {
(void)id;
size_t read_cnt = 0;
while(read_cnt < len){
Key key;
vault.keys_sem.p(vault);
vault.keys.consume(key);
if(key.valid())
((char*)buf)[read_cnt++] = key.ascii();
else
break;
}
return read_cnt;
}
void sleep(Vault &vault, size_t ms) {
vault.bellringer.sleep(vault, ms);
}
bool sem_init(Vault &vault, size_t id, uint32_t value) {
if (id >= vault.MAX_SEMS) {
return false; // outofrange id
}
if (vault.sems[id].used==1){
return false; //already in use
}
vault.sems[id].counter=value;
return true;
}
bool sem_destroy(Vault &vault, size_t id) {
if (id >= vault.MAX_SEMS) {
return false; // outofrange id
}
if (vault.sems[id].used==0){
return false; //already in free
}
vault.sems[id].used=0;
vault.sems[id].counter=0;
return true;
}
bool sem_signal(Vault &vault, size_t id) {
vault.sems[id].v(vault);
return true;
}
bool sem_wait(Vault &vault, size_t id) {
vault.sems[id].p(vault);
return true;
}
void exit(Vault &vault) {
vault.scheduler.exit();
unmap(vault, (void*) 0x4000000, 512 );
}
void kill(Vault &vault, size_t pid){
//vault.scheduler.kill(&apps[pid]);
}
void* map(Vault *vault, size_t size) {
size_t num_pages = (size + 4096 - 1) / 4096;
//pagetable_t* subbytable = vault->scheduler.active()->subtable;
four_lvl_paging_t* search_table = vault->scheduler.active()->paging_tree;
void* ptr = getFreeVirtSpace(search_table->l4, num_pages);
if (ptr == nullptr) {
return nullptr;
}
// map all used pages
for (size_t i = 0; i < num_pages; ++i) {
// allocate each page with allocator
void* frame = PageFrameAllocator::alloc(false);
setMapping((uintptr_t)ptr, frame, search_table->l4);
}
return ptr;
}
int unmap(Vault &vault, void* start, size_t size) {
uint32_t NumberOfPages = (size/4096);
four_lvl_paging_t* search_table = vault.scheduler.active()->paging_tree;
uint32_t startIndex = ((uintptr_t)start)>>12;
memset(start, 0, size);
for(uint32_t i=startIndex; i<(startIndex+NumberOfPages); i++){
uintptr_t frame = isMapped(i<<12, search_table->l4);
setMapping(i<<12, 0, search_table->l4);
PageFrameAllocator::free(frame);
invlpg(i<<12);
}
return 0;
}
bool copy_from_phys(Vault& vault, uintptr_t src_paddr, void* dest_vaddr, size_t size) {
size_t offset = Page::offset(src_paddr);
size_t total_size = size + offset;
four_lvl_paging_t* search_table = vault.scheduler.active()->paging_tree;
uintptr_t src_vaddr = (uintptr_t)getFreeVirtSpace(search_table->l4, (total_size/4096)+1); // page aligned pointer
if (src_vaddr == 0) {
return false;
}
src_vaddr += offset;
for(uint8_t i =0; i<size/4096 +1; i++){
setMapping(src_vaddr+(uintptr_t)(i*4096), (void*)(src_paddr+(uintptr_t)(i*4096)), search_table->l4);
}
memcpy(dest_vaddr, (void*)src_vaddr, size);
for(uint8_t i =0; i<size/4096 +1; i++){
setMapping((uintptr_t)(src_vaddr), 0, search_table->l4);
}
return true;
}
bool send(Vault& v, int pid, const void* sbuffer, size_t ssize, void* rbuffer, size_t rsize) {
Thread* current_thread = v.scheduler.active();
Thread* target_thread = v.thread_list[pid];
//uintptr_t sbuffer_ptr = isMapped((uintptr_t)sbuffer,v.scheduler.active()->paging_tree->l4) + ((uintptr_t)sbuffer&0xFFF);
IpcStruct msg = {
.ptr = (uintptr_t)sbuffer,
.size = ssize,
.pid = current_thread->id,
.is_answer = false,
.queue_link = nullptr
};
target_thread->ipc_queue.enqueue(msg);
target_thread->ipc_sem.v(v);
while (true) {
current_thread->ipc_sem.p(v);
if (msg.is_answer) {
break;
}
DBG_VERBOSE << "" << endl;
}
// Kopiere Antwort
if (!copy_from_phys(v, msg.ptr, rbuffer, rsize)) {
return false;
}
return true;
}
int receive(Vault& v, void* buffer, size_t size) {
// DBG_VERBOSE << "Receive syscall for thread " << dec << v.scheduler.active()->id << endl;
Thread* thread = v.scheduler.active();
// Warte auf Nachricht
//if (thread->ipc_queue.is_empty()) {
thread->ipc_sem.p(v);
//}
IpcStruct* ipc = thread->ipc_queue.first();
if (ipc == nullptr) return -1;
size_t copy_len = (size < ipc->size) ? size:ipc->size;
// Buffer holen
for(uint32_t i=0; i<(copy_len/4096)+1; i++){
uintptr_t paddr = isMapped((ipc->ptr)+(i*4096), v.thread_list[ipc->pid]->paging_tree->l4);
if (!copy_from_phys(v, paddr, buffer, copy_len)) {
return -3;
}
}
return ipc->pid;
}
bool reply(Vault& v, const void* buffer, size_t size) {
Thread* current_thread = v.scheduler.active();
IpcStruct* ipc = current_thread->ipc_queue.dequeue();
//noting to reply to
if(!ipc)
return false;
// if (!ipc || ipc->pid < 0 || static_cast<size_t>(ipc->pid) >= v.thread_count) return false;
Thread* other_thread = v.thread_list[ipc->pid];
if (other_thread == nullptr) return false;
uintptr_t phys_ptr = isMapped((uintptr_t)buffer, current_thread->paging_tree->l4 );
ipc->ptr = phys_ptr + ((uintptr_t)buffer & 0xFFF);
ipc->size = size;
ipc->pid = current_thread->id;
ipc->is_answer = true;
// Sender aufwecken
other_thread->ipc_sem.v(v);
return true;
}
void copy_stack(Thread* parent, Thread* child){
uintptr_t dest_frame = isMapped((uintptr_t)child->StackPointer.user, child->paging_tree->l4);
void* dest_vaddr = getFreeVirtSpace(parent->paging_tree->l4, 1);
setMapping((uintptr_t)dest_vaddr, (void*)dest_frame, parent->paging_tree->l4);
memcpy(dest_vaddr, (void*)0x6000000/*((uintptr_t)parent->StackPointer.user & ~0xFFF)*/, 4096);
setMapping((uintptr_t)dest_vaddr, 0, parent->paging_tree->l4);
}
int fork(Vault &vault, InterruptContext *user_context) {
Thread* parent = vault.scheduler.active();
Thread* child = new Thread(false, (void*)user_context->ip, parent->code_paddr, parent->code_pagenum);
//copy_pagetable(parent->paging_tree, child->paging_tree);
copy_stack(parent, child);
child->StackPointer.user = (void*)user_context->sp;
vault.thread_list[child->id] = child;
//return parent pid to child
prepareContext(child->StackPointer.isr, child->context, Thread::kickoff, reinterpret_cast<uintptr_t>(child), parent->id, 0);
vault.scheduler.ready(child);
// return child pid to parent
return child->id;
}
} // namespace Skeleton
} // namespace Syscall
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