/*
This file is part of Fennix Kernel.
Fennix Kernel is free software: you can redistribute it and/or
modify it under the terms of the GNU General Public License as
published by the Free Software Foundation, either version 3 of
the License, or (at your option) any later version.
Fennix Kernel is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with Fennix Kernel. If not, see <https://www.gnu.org/licenses/>.
*/
#include <cpu.hpp>
#include <memory.hpp>
#include <convert.h>
#include <debug.h>
#include <smp.hpp>
#include "../kernel.h"
#if defined(a64)
using namespace CPU::x64;
#elif defined(a32)
using namespace CPU::x32;
#elif defined(aa64)
#endif
namespace CPU
{
static bool SSEEnabled = false;
const char *Vendor()
{
static char Vendor[13] = {0};
if (Vendor[0] != 0)
return Vendor;
#if defined(a64)
uint32_t eax, ebx, ecx, edx;
x64::cpuid(0x0, &eax, &ebx, &ecx, &edx);
memcpy(Vendor + 0, &ebx, 4);
memcpy(Vendor + 4, &edx, 4);
memcpy(Vendor + 8, &ecx, 4);
#elif defined(a32)
uint32_t eax, ebx, ecx, edx;
x32::cpuid(0x0, &eax, &ebx, &ecx, &edx);
memcpy(Vendor + 0, &ebx, 4);
memcpy(Vendor + 4, &edx, 4);
memcpy(Vendor + 8, &ecx, 4);
#elif defined(aa64)
#error "Not implemented"
#endif
return Vendor;
}
const char *Name()
{
static char Name[49] = {0};
if (Name[0] != 0)
return Name;
#if defined(a64)
uint32_t eax, ebx, ecx, edx;
x64::cpuid(0x80000002, &eax, &ebx, &ecx, &edx);
memcpy(Name + 0, &eax, 4);
memcpy(Name + 4, &ebx, 4);
memcpy(Name + 8, &ecx, 4);
memcpy(Name + 12, &edx, 4);
x64::cpuid(0x80000003, &eax, &ebx, &ecx, &edx);
memcpy(Name + 16, &eax, 4);
memcpy(Name + 20, &ebx, 4);
memcpy(Name + 24, &ecx, 4);
memcpy(Name + 28, &edx, 4);
x64::cpuid(0x80000004, &eax, &ebx, &ecx, &edx);
memcpy(Name + 32, &eax, 4);
memcpy(Name + 36, &ebx, 4);
memcpy(Name + 40, &ecx, 4);
memcpy(Name + 44, &edx, 4);
#elif defined(a32)
uint32_t eax, ebx, ecx, edx;
x32::cpuid(0x80000002, &eax, &ebx, &ecx, &edx);
memcpy(Name + 0, &eax, 4);
memcpy(Name + 4, &ebx, 4);
memcpy(Name + 8, &ecx, 4);
memcpy(Name + 12, &edx, 4);
x32::cpuid(0x80000003, &eax, &ebx, &ecx, &edx);
memcpy(Name + 16, &eax, 4);
memcpy(Name + 20, &ebx, 4);
memcpy(Name + 24, &ecx, 4);
memcpy(Name + 28, &edx, 4);
x32::cpuid(0x80000004, &eax, &ebx, &ecx, &edx);
memcpy(Name + 32, &eax, 4);
memcpy(Name + 36, &ebx, 4);
memcpy(Name + 40, &ecx, 4);
memcpy(Name + 44, &edx, 4);
#elif defined(aa64)
#error "Not implemented"
#endif
return Name;
}
const char *Hypervisor()
{
static char Hypervisor[13] = {0};
if (Hypervisor[0] != 0)
return Hypervisor;
#if defined(a64)
uint32_t eax, ebx, ecx, edx;
x64::cpuid(0x1, &eax, &ebx, &ecx, &edx);
if (!(ecx & (1 << 31))) /* Intel & AMD are the same */
{
Hypervisor[0] = 'N';
Hypervisor[1] = 'o';
Hypervisor[2] = 'n';
Hypervisor[3] = 'e';
return Hypervisor;
}
x64::cpuid(0x40000000, &eax, &ebx, &ecx, &edx);
memcpy(Hypervisor + 0, &ebx, 4);
memcpy(Hypervisor + 4, &ecx, 4);
memcpy(Hypervisor + 8, &edx, 4);
#elif defined(a32)
uint32_t eax, ebx, ecx, edx;
x32::cpuid(0x1, &eax, &ebx, &ecx, &edx);
if (!(ecx & (1 << 31))) /* Intel & AMD are the same */
{
Hypervisor[0] = 'N';
Hypervisor[1] = 'o';
Hypervisor[2] = 'n';
Hypervisor[3] = 'e';
return Hypervisor;
}
x32::cpuid(0x40000000, &eax, &ebx, &ecx, &edx);
memcpy(Hypervisor + 0, &ebx, 4);
memcpy(Hypervisor + 4, &ecx, 4);
memcpy(Hypervisor + 8, &edx, 4);
#elif defined(aa64)
#error "Not implemented"
#endif
return Hypervisor;
}
bool Interrupts(InterruptsType Type)
{
switch (Type)
{
case Check:
{
uintptr_t Flags;
#if defined(a64)
asmv("pushfq");
asmv("popq %0"
: "=r"(Flags));
return Flags & (1 << 9);
#elif defined(a32)
asmv("pushfl");
asmv("popl %0"
: "=r"(Flags));
return Flags & (1 << 9);
#elif defined(aa64)
asmv("mrs %0, cpsr"
: "=r"(Flags));
return Flags & (1 << 7);
#endif
}
case Enable:
{
#if defined(a86)
asmv("sti");
#elif defined(aa64)
asmv("cpsie i");
#endif
return true;
}
case Disable:
{
#if defined(a86)
asmv("cli");
#elif defined(aa64)
asmv("cpsid i");
#endif
return true;
}
default:
assert(!"Unknown InterruptsType");
break;
}
return false;
}
void *PageTable(void *PT)
{
void *ret;
#if defined(a64)
asmv("movq %%cr3, %0"
: "=r"(ret));
if (PT)
{
asmv("movq %0, %%cr3"
:
: "r"(PT)
: "memory");
}
#elif defined(a32)
asmv("movl %%cr3, %0"
: "=r"(ret));
if (PT)
{
asmv("movl %0, %%cr3"
:
: "r"(PT)
: "memory");
}
#elif defined(aa64)
asmv("mrs %0, ttbr0_el1"
: "=r"(ret));
if (PT)
{
asmv("msr ttbr0_el1, %0"
:
: "r"(PT)
: "memory");
}
#endif
return ret;
}
struct SupportedFeat
{
bool PGE = false;
bool SSE = false;
bool UMIP = false;
bool SMEP = false;
bool SMAP = false;
};
SupportedFeat GetCPUFeat()
{
SupportedFeat feat{};
if (strcmp(CPU::Vendor(), x86_CPUID_VENDOR_AMD) == 0)
{
CPU::x86::AMD::CPUID0x00000001 cpuid1;
CPU::x86::AMD::CPUID0x00000007_ECX_0 cpuid7;
feat.PGE = cpuid1.EDX.PGE;
feat.SSE = cpuid1.EDX.SSE;
feat.SMEP = cpuid7.EBX.SMEP;
feat.SMAP = cpuid7.EBX.SMAP;
feat.UMIP = cpuid7.ECX.UMIP;
}
else if (strcmp(CPU::Vendor(), x86_CPUID_VENDOR_INTEL) == 0)
{
CPU::x86::Intel::CPUID0x00000001 cpuid1;
CPU::x86::Intel::CPUID0x00000007_0 cpuid7_0;
feat.PGE = cpuid1.EDX.PGE;
feat.SSE = cpuid1.EDX.SSE;
feat.SMEP = cpuid7_0.EBX.SMEP;
feat.SMAP = cpuid7_0.EBX.SMAP;
feat.UMIP = cpuid7_0.ECX.UMIP;
}
return feat;
}
void InitializeFeatures(int Core)
{
static int BSP = 0;
SupportedFeat feat = GetCPUFeat();
CR0 cr0 = readcr0();
CR4 cr4 = readcr4();
if (Config.SIMD == false)
{
debug("Disabling SSE support...");
feat.SSE = false;
}
if (feat.PGE)
{
debug("Enabling global pages support...");
if (!BSP)
KPrint("Global Pages is supported.");
cr4.PGE = true;
}
bool SSEEnableAfter = false;
/* Not sure if my code is not working properly or something else is the issue. */
if ((strcmp(Hypervisor(), x86_CPUID_VENDOR_VIRTUALBOX) != 0) &&
feat.SSE)
{
debug("Enabling SSE support...");
if (!BSP)
KPrint("SSE is supported.");
cr0.EM = false;
cr0.MP = true;
cr4.OSFXSR = true;
cr4.OSXMMEXCPT = true;
CPUData *CoreData = GetCPU(Core);
CoreData->Data.FPU.mxcsr = 0b0001111110000000;
CoreData->Data.FPU.mxcsrmask = 0b1111111110111111;
CoreData->Data.FPU.fcw = 0b0000001100111111;
fxrstor(&CoreData->Data.FPU);
SSEEnableAfter = true;
}
/* More info in AMD64 Architecture Programmer's Manual
Volume 2: 3.1.1 CR0 Register */
/* Not Write-Through
This is ignored on recent processors.
*/
cr0.NW = false;
/* Cache Disable
Wether the CPU should cache memory or not.
If it's enabled, PWT and PCD are ignored.
*/
cr0.CD = false;
/* Write Protect
When set, the supervisor can't write to read-only pages.
*/
cr0.WP = true;
/* Alignment check
The CPU checks the alignment of memory operands
and generates #AC if the alignment is incorrect.
The condition for an alignment check is:
- The AM flag in CR0 is set.
- The AC flag in the RFLAGS register is set.
- CPL is 3.
*/
cr0.AM = true;
debug("Updating CR0...");
writecr0(cr0);
debug("Updated CR0.");
debug("CPU Prevention Features:%s%s%s",
feat.SMEP ? " SMEP" : "",
feat.SMAP ? " SMAP" : "",
feat.UMIP ? " UMIP" : "");
/* User-Mode Instruction Prevention
This prevents user-mode code from executing these instructions:
SGDT, SIDT, SLDT, SMSW, STR
If any of these instructions are executed with CPL > 0, a #GP is generated.
*/
// cr4.UMIP = feat.UMIP;
/* Supervisor Mode Execution Prevention
This prevents user-mode code from executing code in the supervisor mode.
*/
cr4.SMEP = feat.SMEP;
/* Supervisor Mode Access Prevention
This prevents supervisor-mode code from accessing user-mode pages.
*/
cr4.SMAP = feat.SMAP;
debug("Updating CR4...");
writecr4(cr4);
debug("Updated CR4.");
debug("Enabling PAT support...");
wrmsr(MSR_CR_PAT, 0x6 | (0x0 << 8) | (0x1 << 16));
if (!BSP++)
trace("Features for BSP initialized.");
if (SSEEnableAfter)
{
SSEEnabled = true;
debug("SSE support enabled.");
}
}
uint64_t Counter()
{
// TODO: Get the counter from the x2APIC or any other timer that is available. (TSC is not available on all CPUs)
uint64_t Counter;
#if defined(a86)
uint32_t eax, edx;
asmv("rdtsc"
: "=a"(eax),
"=d"(edx));
Counter = ((uint64_t)eax) | (((uint64_t)edx) << 32);
#elif defined(aa64)
asmv("mrs %0, cntvct_el0"
: "=r"(Counter));
#endif
return Counter;
}
uint64_t CheckSIMD()
{
if (unlikely(!SSEEnabled))
return SIMD_NONE;
#warning "TODO: Proper SIMD support"
return SIMD_NONE;
#if defined(a86)
static uint64_t SIMDType = SIMD_NONE;
if (likely(SIMDType != SIMD_NONE))
return SIMDType;
if (strcmp(CPU::Vendor(), x86_CPUID_VENDOR_AMD) == 0)
{
CPU::x86::AMD::CPUID0x00000001 cpuid;
asmv("cpuid"
: "=a"(cpuid.EAX.raw), "=b"(cpuid.EBX.raw),
"=c"(cpuid.ECX.raw), "=d"(cpuid.EDX.raw)
: "a"(0x1));
if (cpuid.ECX.SSE42)
SIMDType |= SIMD_SSE42;
else if (cpuid.ECX.SSE41)
SIMDType |= SIMD_SSE41;
else if (cpuid.ECX.SSSE3)
SIMDType |= SIMD_SSSE3;
else if (cpuid.ECX.SSE3)
SIMDType |= SIMD_SSE3;
else if (cpuid.EDX.SSE2)
SIMDType |= SIMD_SSE2;
else if (cpuid.EDX.SSE)
SIMDType |= SIMD_SSE;
#ifdef DEBUG
if (cpuid.ECX.SSE42)
debug("SSE4.2 is supported.");
if (cpuid.ECX.SSE41)
debug("SSE4.1 is supported.");
if (cpuid.ECX.SSSE3)
debug("SSSE3 is supported.");
if (cpuid.ECX.SSE3)
debug("SSE3 is supported.");
if (cpuid.EDX.SSE2)
debug("SSE2 is supported.");
if (cpuid.EDX.SSE)
debug("SSE is supported.");
#endif
return SIMDType;
}
else if (strcmp(CPU::Vendor(), x86_CPUID_VENDOR_INTEL) == 0)
{
CPU::x86::Intel::CPUID0x00000001 cpuid;
asmv("cpuid"
: "=a"(cpuid.EAX.raw), "=b"(cpuid.EBX.raw), "=c"(cpuid.ECX.raw), "=d"(cpuid.EDX.raw)
: "a"(0x1));
if (cpuid.ECX.SSE4_2)
SIMDType |= SIMD_SSE42;
else if (cpuid.ECX.SSE4_1)
SIMDType |= SIMD_SSE41;
else if (cpuid.ECX.SSSE3)
SIMDType |= SIMD_SSSE3;
else if (cpuid.ECX.SSE3)
SIMDType |= SIMD_SSE3;
else if (cpuid.EDX.SSE2)
SIMDType |= SIMD_SSE2;
else if (cpuid.EDX.SSE)
SIMDType |= SIMD_SSE;
#ifdef DEBUG
if (cpuid.ECX.SSE4_2)
debug("SSE4.2 is supported.");
if (cpuid.ECX.SSE4_1)
debug("SSE4.1 is supported.");
if (cpuid.ECX.SSSE3)
debug("SSSE3 is supported.");
if (cpuid.ECX.SSE3)
debug("SSE3 is supported.");
if (cpuid.EDX.SSE2)
debug("SSE2 is supported.");
if (cpuid.EDX.SSE)
debug("SSE is supported.");
#endif
return SIMDType;
}
debug("No SIMD support.");
#endif // a64 || a32
return SIMD_NONE;
}
bool CheckSIMD(x86SIMDType Type)
{
if (unlikely(!SSEEnabled))
return false;
#if defined(a86)
if (strcmp(CPU::Vendor(), x86_CPUID_VENDOR_AMD) == 0)
{
CPU::x86::AMD::CPUID0x00000001 cpuid;
asmv("cpuid"
: "=a"(cpuid.EAX.raw), "=b"(cpuid.EBX.raw), "=c"(cpuid.ECX.raw), "=d"(cpuid.EDX.raw)
: "a"(0x1));
if (Type == SIMD_SSE42)
return cpuid.ECX.SSE42;
else if (Type == SIMD_SSE41)
return cpuid.ECX.SSE41;
else if (Type == SIMD_SSSE3)
return cpuid.ECX.SSSE3;
else if (Type == SIMD_SSE3)
return cpuid.ECX.SSE3;
else if (Type == SIMD_SSE2)
return cpuid.EDX.SSE2;
else if (Type == SIMD_SSE)
return cpuid.EDX.SSE;
}
else if (strcmp(CPU::Vendor(), x86_CPUID_VENDOR_INTEL) == 0)
{
CPU::x86::Intel::CPUID0x00000001 cpuid;
asmv("cpuid"
: "=a"(cpuid.EAX.raw), "=b"(cpuid.EBX.raw), "=c"(cpuid.ECX.raw), "=d"(cpuid.EDX.raw)
: "a"(0x1));
if (Type == SIMD_SSE42)
return cpuid.ECX.SSE4_2;
else if (Type == SIMD_SSE41)
return cpuid.ECX.SSE4_1;
else if (Type == SIMD_SSSE3)
return cpuid.ECX.SSSE3;
else if (Type == SIMD_SSE3)
return cpuid.ECX.SSE3;
else if (Type == SIMD_SSE2)
return cpuid.EDX.SSE2;
else if (Type == SIMD_SSE)
return cpuid.EDX.SSE;
}
#endif // a64 || a32
return false;
}
}