#include "../syscall/skeleton.h" #include "../debug/kernelpanic.h" #include "../debug/output.h" #include "../device/textstream.h" #include "../interrupt/guard.h" #include "../sync/semaphore.h" #include "../thread/scheduler.h" void *operator new(size_t, void *); #include "../user/app1/appl.h" extern Application apps[]; namespace Syscall { namespace Skeleton { 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; } size_t write(Vault &vault, uint32_t id, const void *buffer, size_t size, int x, int y) { (void)id; int dummy; if(x == -1 && y != -1) vault.kout.getPos(x, dummy); if(x != -1 && y == -1) vault.kout.getPos(dummy, y); if(x == -1 && y == -1) vault.kout.getPos(x, y); vault.kout.setPos(x, y); for(size_t i = 0; i= vault.MAX_SEMS) { return false; // out‐of‐range 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; // out‐of‐range 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(); } } // namespace Skeleton } // namespace Syscall