#include <cpu.hpp>
#include <memory.hpp>
#include <convert.h>
#include <debug.h>
#include "../kernel.h"
namespace CPU
{
char *Vendor()
{
static char Vendor[13];
#if defined(__amd64__)
uint32_t rax, rbx, rcx, rdx;
x64::cpuid(0x0, &rax, &rbx, &rcx, &rdx);
memcpy(Vendor + 0, &rbx, 4);
memcpy(Vendor + 4, &rdx, 4);
memcpy(Vendor + 8, &rcx, 4);
#elif defined(__i386__)
uint32_t rax, rbx, rcx, rdx;
x32::cpuid(0x0, &rax, &rbx, &rcx, &rdx);
memcpy(Vendor + 0, &rbx, 4);
memcpy(Vendor + 4, &rdx, 4);
memcpy(Vendor + 8, &rcx, 4);
#elif defined(__aarch64__)
asmv("mrs %0, MIDR_EL1"
: "=r"(Vendor[0]));
#endif
return Vendor;
}
char *Name()
{
static char Name[49];
#if defined(__amd64__)
uint32_t rax, rbx, rcx, rdx;
x64::cpuid(0x80000002, &rax, &rbx, &rcx, &rdx);
memcpy(Name + 0, &rax, 4);
memcpy(Name + 4, &rbx, 4);
memcpy(Name + 8, &rcx, 4);
memcpy(Name + 12, &rdx, 4);
x64::cpuid(0x80000003, &rax, &rbx, &rcx, &rdx);
memcpy(Name + 16, &rax, 4);
memcpy(Name + 20, &rbx, 4);
memcpy(Name + 24, &rcx, 4);
memcpy(Name + 28, &rdx, 4);
x64::cpuid(0x80000004, &rax, &rbx, &rcx, &rdx);
memcpy(Name + 32, &rax, 4);
memcpy(Name + 36, &rbx, 4);
memcpy(Name + 40, &rcx, 4);
memcpy(Name + 44, &rdx, 4);
#elif defined(__i386__)
uint32_t rax, rbx, rcx, rdx;
x32::cpuid(0x80000002, &rax, &rbx, &rcx, &rdx);
memcpy(Name + 0, &rax, 4);
memcpy(Name + 4, &rbx, 4);
memcpy(Name + 8, &rcx, 4);
memcpy(Name + 12, &rdx, 4);
x32::cpuid(0x80000003, &rax, &rbx, &rcx, &rdx);
memcpy(Name + 16, &rax, 4);
memcpy(Name + 20, &rbx, 4);
memcpy(Name + 24, &rcx, 4);
memcpy(Name + 28, &rdx, 4);
x32::cpuid(0x80000004, &rax, &rbx, &rcx, &rdx);
memcpy(Name + 32, &rax, 4);
memcpy(Name + 36, &rbx, 4);
memcpy(Name + 40, &rcx, 4);
memcpy(Name + 44, &rdx, 4);
#elif defined(__aarch64__)
asmv("mrs %0, MIDR_EL1"
: "=r"(Name[0]));
#endif
return Name;
}
char *Hypervisor()
{
static char Hypervisor[13];
#if defined(__amd64__)
uint32_t rax, rbx, rcx, rdx;
x64::cpuid(0x40000000, &rax, &rbx, &rcx, &rdx);
memcpy(Hypervisor + 0, &rbx, 4);
memcpy(Hypervisor + 4, &rcx, 4);
memcpy(Hypervisor + 8, &rdx, 4);
#elif defined(__i386__)
uint32_t rax, rbx, rcx, rdx;
x64::cpuid(0x40000000, &rax, &rbx, &rcx, &rdx);
memcpy(Hypervisor + 0, &rbx, 4);
memcpy(Hypervisor + 4, &rcx, 4);
memcpy(Hypervisor + 8, &rdx, 4);
#elif defined(__aarch64__)
asmv("mrs %0, MIDR_EL1"
: "=r"(Hypervisor[0]));
#endif
return Hypervisor;
}
bool Interrupts(InterruptsType Type)
{
switch (Type)
{
case Check:
{
uintptr_t Flags;
#if defined(__amd64__)
asmv("pushfq");
asmv("popq %0"
: "=r"(Flags));
return Flags & (1 << 9);
#elif defined(__i386__)
asmv("pushfl");
asmv("popl %0"
: "=r"(Flags));
return Flags & (1 << 9);
#elif defined(__aarch64__)
asmv("mrs %0, daif"
: "=r"(Flags));
return !(Flags & (1 << 2));
#endif
}
case Enable:
{
#if defined(__amd64__) || defined(__i386__)
asmv("sti");
#elif defined(__aarch64__)
asmv("msr daifclr, #2");
#endif
return true;
}
case Disable:
{
#if defined(__amd64__) || defined(__i386__)
asmv("cli");
#elif defined(__aarch64__)
asmv("msr daifset, #2");
#endif
return true;
}
}
return false;
}
void *PageTable(void *PT)
{
#if defined(__amd64__)
if (PT)
asmv("movq %0, %%cr3"
:
: "r"(PT));
else
asmv("movq %%cr3, %0"
: "=r"(PT));
#elif defined(__i386__)
if (PT)
asmv("movl %0, %%cr3"
:
: "r"(PT));
else
asmv("movl %%cr3, %0"
: "=r"(PT));
#elif defined(__aarch64__)
if (PT)
asmv("msr ttbr0_el1, %0"
:
: "r"(PT));
else
asmv("mrs %0, ttbr0_el1"
: "=r"(PT));
#endif
return PT;
}
void InitializeFeatures()
{
#if defined(__amd64__)
static int BSP = 0;
x64::CR0 cr0 = x64::readcr0();
x64::CR4 cr4 = x64::readcr4();
uint32_t rax, rbx, rcx, rdx;
x64::cpuid(0x1, &rax, &rbx, &rcx, &rdx);
if (rdx & x64::CPUID_FEAT_RDX_PGE)
{
debug("Enabling global pages support...");
if (!BSP)
KPrint("Global Pages is supported.");
cr4.PGE = 1;
}
if (rdx & x64::CPUID_FEAT_RDX_SSE)
{
debug("Enabling SSE support...");
if (!BSP)
KPrint("SSE is supported.");
cr0.EM = 0;
cr0.MP = 1;
cr4.OSFXSR = 1;
cr4.OSXMMEXCPT = 1;
}
if (!BSP)
KPrint("Enabling CPU cache.");
cr0.NW = 0;
cr0.CD = 0;
cr0.WP = 1;
x64::writecr0(cr0);
debug("Enabling UMIP, SMEP & SMAP support...");
x64::cpuid(0x1, &rax, &rbx, &rcx, &rdx);
if (rdx & x64::CPUID_FEAT_RDX_UMIP) // https://en.wikipedia.org/wiki/Control_register
{
if (!BSP)
KPrint("UMIP is supported.");
debug("UMIP is supported.");
// cr4.UMIP = 1;
}
if (rdx & x64::CPUID_FEAT_RDX_SMEP) // https://en.wikipedia.org/wiki/Control_register#SMEP
// https://web.archive.org/web/20160312223150/http://ncsi.com/nsatc11/presentations/wednesday/emerging_technologies/fischer.pdf
{
if (!BSP)
KPrint("SMEP is supported.");
debug("SMEP is supported.");
// cr4.SMEP = 1;
}
if (rdx & x64::CPUID_FEAT_RDX_SMAP) // https://en.wikipedia.org/wiki/Supervisor_Mode_Access_Prevention
{
if (!BSP)
KPrint("SMAP is supported.");
debug("SMAP is supported.");
// cr4.SMAP = 1;
}
if (strcmp(Hypervisor(), x86_CPUID_VENDOR_VIRTUALBOX) != 0 &&
strcmp(Hypervisor(), x86_CPUID_VENDOR_TCG) != 0)
{
debug("Writing CR4...");
x64::writecr4(cr4);
debug("Wrote CR4.");
}
else
{
if (!BSP)
{
if (strcmp(Hypervisor(), x86_CPUID_VENDOR_VIRTUALBOX) == 0)
KPrint("VirtualBox detected. Not using UMIP, SMEP & SMAP");
else if (strcmp(Hypervisor(), x86_CPUID_VENDOR_TCG) == 0)
KPrint("QEMU (TCG) detected. Not using UMIP, SMEP & SMAP");
}
}
debug("Enabling PAT support...");
x64::wrmsr(x64::MSR_CR_PAT, 0x6 | (0x0 << 8) | (0x1 << 16));
if (!BSP++)
trace("Features for BSP initialized.");
#elif defined(__i386__)
#elif defined(__aarch64__)
#endif
}
uintptr_t Counter()
{
// TODO: Get the counter from the x2APIC or any other timer that is available. (TSC is not available on all CPUs)
uintptr_t Counter;
#if defined(__amd64__)
asmv("rdtsc"
: "=A"(Counter));
#elif defined(__i386__)
asmv("rdtsc"
: "=A"(Counter));
#elif defined(__aarch64__)
asmv("mrs %0, cntvct_el0"
: "=r"(Counter));
#endif
return Counter;
}
}