zircon/kernel/hypervisor/trap_map.cc - fuchsia - Git at Google

 // Copyright 2017 The Fuchsia Authors
 //
 // Use of this source code is governed by a MIT-style
 // license that can be found in the LICENSE file or at
 // https://opensource.org/licenses/MIT

 #include <lib/ktrace.h>
 #include <zircon/errors.h>
 #include <zircon/syscalls/hypervisor.h>
 #include <zircon/types.h>

 #include <fbl/alloc_checker.h>
 #include <fbl/auto_lock.h>
 #include <hypervisor/ktrace.h>
 #include <hypervisor/trap_map.h>
 #include <kernel/range_check.h>

 namespace {

 constexpr size_t kMaxPacketsPerRange = 256;

 bool ValidRange(uint32_t kind, zx_gpaddr_t addr, size_t len) {
   if (len == 0) {
     return false;
   }
   zx_gpaddr_t end;
   if (add_overflow(addr, len, &end)) {
     return false;
   }
 #ifdef ARCH_X86
   if (kind == ZX_GUEST_TRAP_IO && end > UINT16_MAX) {
     return false;
   }
 #endif  // ARCH_X86
   return true;
 }

 }  // namespace

 namespace hypervisor {

 BlockingPortAllocator::BlockingPortAllocator() : semaphore_(kMaxPacketsPerRange) {}

 zx::status<> BlockingPortAllocator::Init() {
   zx_status_t status = arena_.Init("hypervisor-packets", kMaxPacketsPerRange);
   return zx::make_status(status);
 }

 PortPacket* BlockingPortAllocator::AllocBlocking() {
   ktrace_vcpu(TAG_VCPU_BLOCK, VCPU_PORT);
   zx_status_t status = semaphore_.Wait(Deadline::infinite());
   ktrace_vcpu(TAG_VCPU_UNBLOCK, VCPU_PORT);
   if (status != ZX_OK) {
     return nullptr;
   }
   return Alloc();
 }

 PortPacket* BlockingPortAllocator::Alloc() {
   return arena_.New(this /* handle */, this /* allocator */);
 }

 void BlockingPortAllocator::Free(PortPacket* port_packet) {
   arena_.Delete(port_packet);
   semaphore_.Post();
 }

 Trap::Trap(uint32_t kind, zx_gpaddr_t addr, size_t len, fbl::RefPtr<PortDispatcher> port,
            uint64_t key)
     : kind_(kind), addr_(addr), len_(len), port_(ktl::move(port)), key_(key) {}

 Trap::~Trap() {
   if (port_ == nullptr) {
     return;
   }
   port_->CancelQueued(&port_allocator_ /* handle */, key_);
 }

 zx::status<> Trap::Init() { return port_allocator_.Init(); }

 zx::status<> Trap::Queue(const zx_port_packet_t& packet, StateInvalidator* invalidator) {
   if (invalidator != nullptr) {
     invalidator->Invalidate();
   }
   if (port_ == nullptr) {
     return zx::error(ZX_ERR_NOT_FOUND);
   }
   PortPacket* port_packet = port_allocator_.AllocBlocking();
   if (port_packet == nullptr) {
     return zx::error(ZX_ERR_NO_MEMORY);
   }
   port_packet->packet = packet;
   zx_status_t status = port_->Queue(port_packet, ZX_SIGNAL_NONE);
   if (status != ZX_OK) {
     port_allocator_.Free(port_packet);
     if (status == ZX_ERR_BAD_HANDLE) {
       // If the last handle to the port has been closed, then we're in a bad state.
       status = ZX_ERR_BAD_STATE;
     }
   }
   return zx::make_status(status);
 }

 zx::status<> TrapMap::InsertTrap(uint32_t kind, zx_gpaddr_t addr, size_t len,
                                  fbl::RefPtr<PortDispatcher> port, uint64_t key) {
   if (!ValidRange(kind, addr, len)) {
     return zx::error(ZX_ERR_OUT_OF_RANGE);
   }
   TrapTree* traps = TreeOf(kind);
   if (traps == nullptr) {
     return zx::error(ZX_ERR_INVALID_ARGS);
   }

   fbl::AllocChecker ac;
   ktl::unique_ptr<Trap> range(new (&ac) Trap(kind, addr, len, ktl::move(port), key));
   if (!ac.check()) {
     return zx::error(ZX_ERR_NO_MEMORY);
   }
   if (auto result = range->Init(); result.is_error()) {
     return result.take_error();
   }

   Guard<SpinLock, IrqSave> guard{&lock_};
   auto iter = traps->upper_bound(addr);
   // If `upper_bound()` does not return `end()`, check if the range intersects.
   if (iter.IsValid() && Intersects(addr, len, iter->addr(), iter->len())) {
     return zx::error(ZX_ERR_ALREADY_EXISTS);
   }
   // Decrement the iterator, and check if the next range intersects.
   if (--iter; iter.IsValid() && Intersects(addr, len, iter->addr(), iter->len())) {
     return zx::error(ZX_ERR_ALREADY_EXISTS);
   }
   traps->insert(ktl::move(range));
   return zx::ok();
 }

 zx::status<Trap*> TrapMap::FindTrap(uint32_t kind, zx_gpaddr_t addr) {
   TrapTree* traps = TreeOf(kind);
   if (traps == nullptr) {
     return zx::error(ZX_ERR_INVALID_ARGS);
   }

   Trap* found;
   {
     Guard<SpinLock, IrqSave> guard{&lock_};
     auto iter = --traps->upper_bound(addr);
     if (!iter.IsValid()) {
       return zx::error(ZX_ERR_NOT_FOUND);
     }
     found = &*iter;
   }
   if (!found->Contains(addr)) {
     return zx::error(ZX_ERR_NOT_FOUND);
   }
   return zx::ok(found);
 }

 TrapMap::TrapTree* TrapMap::TreeOf(uint32_t kind) {
   switch (kind) {
     case ZX_GUEST_TRAP_BELL:
     case ZX_GUEST_TRAP_MEM:
       return &mem_traps_;
 #ifdef ARCH_X86
     case ZX_GUEST_TRAP_IO:
       return &io_traps_;
 #endif  // ARCH_X86
     default:
       return nullptr;
   }
 }

 }  // namespace hypervisor
	// Copyright 2017 The Fuchsia Authors
	//
	// Use of this source code is governed by a MIT-style
	// license that can be found in the LICENSE file or at
	// https://opensource.org/licenses/MIT

	#include <lib/ktrace.h>
	#include <zircon/errors.h>
	#include <zircon/syscalls/hypervisor.h>
	#include <zircon/types.h>

	#include <fbl/alloc_checker.h>
	#include <fbl/auto_lock.h>
	#include <hypervisor/ktrace.h>
	#include <hypervisor/trap_map.h>
	#include <kernel/range_check.h>

	namespace {

	constexpr size_t kMaxPacketsPerRange = 256;

	bool ValidRange(uint32_t kind, zx_gpaddr_t addr, size_t len) {
	if (len == 0) {
	return false;
	}
	zx_gpaddr_t end;
	if (add_overflow(addr, len, &end)) {
	return false;
	}
	#ifdef ARCH_X86
	if (kind == ZX_GUEST_TRAP_IO && end > UINT16_MAX) {
	return false;
	}
	#endif // ARCH_X86
	return true;
	}

	} // namespace

	namespace hypervisor {

	BlockingPortAllocator::BlockingPortAllocator() : semaphore_(kMaxPacketsPerRange) {}

	zx::status<> BlockingPortAllocator::Init() {
	zx_status_t status = arena_.Init("hypervisor-packets", kMaxPacketsPerRange);
	return zx::make_status(status);
	}

	PortPacket* BlockingPortAllocator::AllocBlocking() {
	ktrace_vcpu(TAG_VCPU_BLOCK, VCPU_PORT);
	zx_status_t status = semaphore_.Wait(Deadline::infinite());
	ktrace_vcpu(TAG_VCPU_UNBLOCK, VCPU_PORT);
	if (status != ZX_OK) {
	return nullptr;
	}
	return Alloc();
	}

	PortPacket* BlockingPortAllocator::Alloc() {
	return arena_.New(this /* handle /, this / allocator */);
	}

	void BlockingPortAllocator::Free(PortPacket* port_packet) {
	arena_.Delete(port_packet);
	semaphore_.Post();
	}

	Trap::Trap(uint32_t kind, zx_gpaddr_t addr, size_t len, fbl::RefPtr<PortDispatcher> port,
	uint64_t key)
	: kind_(kind), addr_(addr), len_(len), port_(ktl::move(port)), key_(key) {}

	Trap::~Trap() {
	if (port_ == nullptr) {
	return;
	}
	port_->CancelQueued(&port_allocator_ /* handle */, key_);
	}

	zx::status<> Trap::Init() { return port_allocator_.Init(); }

	zx::status<> Trap::Queue(const zx_port_packet_t& packet, StateInvalidator* invalidator) {
	if (invalidator != nullptr) {
	invalidator->Invalidate();
	}
	if (port_ == nullptr) {
	return zx::error(ZX_ERR_NOT_FOUND);
	}
	PortPacket* port_packet = port_allocator_.AllocBlocking();
	if (port_packet == nullptr) {
	return zx::error(ZX_ERR_NO_MEMORY);
	}
	port_packet->packet = packet;
	zx_status_t status = port_->Queue(port_packet, ZX_SIGNAL_NONE);
	if (status != ZX_OK) {
	port_allocator_.Free(port_packet);
	if (status == ZX_ERR_BAD_HANDLE) {
	// If the last handle to the port has been closed, then we're in a bad state.
	status = ZX_ERR_BAD_STATE;
	}
	}
	return zx::make_status(status);
	}

	zx::status<> TrapMap::InsertTrap(uint32_t kind, zx_gpaddr_t addr, size_t len,
	fbl::RefPtr<PortDispatcher> port, uint64_t key) {
	if (!ValidRange(kind, addr, len)) {
	return zx::error(ZX_ERR_OUT_OF_RANGE);
	}
	TrapTree* traps = TreeOf(kind);
	if (traps == nullptr) {
	return zx::error(ZX_ERR_INVALID_ARGS);
	}

	fbl::AllocChecker ac;
	ktl::unique_ptr<Trap> range(new (&ac) Trap(kind, addr, len, ktl::move(port), key));
	if (!ac.check()) {
	return zx::error(ZX_ERR_NO_MEMORY);
	}
	if (auto result = range->Init(); result.is_error()) {
	return result.take_error();
	}

	Guard<SpinLock, IrqSave> guard{&lock_};
	auto iter = traps->upper_bound(addr);
	// If `upper_bound()` does not return `end()`, check if the range intersects.
	if (iter.IsValid() && Intersects(addr, len, iter->addr(), iter->len())) {
	return zx::error(ZX_ERR_ALREADY_EXISTS);
	}
	// Decrement the iterator, and check if the next range intersects.
	if (--iter; iter.IsValid() && Intersects(addr, len, iter->addr(), iter->len())) {
	return zx::error(ZX_ERR_ALREADY_EXISTS);
	}
	traps->insert(ktl::move(range));
	return zx::ok();
	}

	zx::status<Trap*> TrapMap::FindTrap(uint32_t kind, zx_gpaddr_t addr) {
	TrapTree* traps = TreeOf(kind);
	if (traps == nullptr) {
	return zx::error(ZX_ERR_INVALID_ARGS);
	}

	Trap* found;
	{
	Guard<SpinLock, IrqSave> guard{&lock_};
	auto iter = --traps->upper_bound(addr);
	if (!iter.IsValid()) {
	return zx::error(ZX_ERR_NOT_FOUND);
	}
	found = &*iter;
	}
	if (!found->Contains(addr)) {
	return zx::error(ZX_ERR_NOT_FOUND);
	}
	return zx::ok(found);
	}

	TrapMap::TrapTree* TrapMap::TreeOf(uint32_t kind) {
	switch (kind) {
	case ZX_GUEST_TRAP_BELL:
	case ZX_GUEST_TRAP_MEM:
	return &mem_traps_;
	#ifdef ARCH_X86
	case ZX_GUEST_TRAP_IO:
	return &io_traps_;
	#endif // ARCH_X86
	default:
	return nullptr;
	}
	}

	} // namespace hypervisor