#include "arch/x86/utility.hh"
#include "arch/x86/x86_traits.hh"
#include "cpu/base.hh"
+#include "fputils/fp80.h"
#include "sim/system.hh"
namespace X86ISA {
uint64_t
getArgument(ThreadContext *tc, int &number, uint16_t size, bool fp)
{
- panic("getArgument() not implemented for x86!\n");
- M5_DUMMY_RETURN
+ if (fp) {
+ panic("getArgument(): Floating point arguments not implemented\n");
+ } else if (size != 8) {
+ panic("getArgument(): Can only handle 64-bit arguments.\n");
+ }
+
+ // The first 6 integer arguments are passed in registers, the rest
+ // are passed on the stack.
+ const int int_reg_map[] = {
+ INTREG_RDI, INTREG_RSI, INTREG_RDX,
+ INTREG_RCX, INTREG_R8, INTREG_R9
+ };
+ if (number < sizeof(int_reg_map) / sizeof(*int_reg_map)) {
+ return tc->readIntReg(int_reg_map[number]);
+ } else {
+ panic("getArgument(): Don't know how to handle stack arguments.\n");
+ }
}
void initCPU(ThreadContext *tc, int cpuId)
tc->setMiscReg(MISCREG_APIC_BASE, lApicBase);
Interrupts * interrupts = dynamic_cast<Interrupts *>(
- tc->getCpuPtr()->getInterruptController());
+ tc->getCpuPtr()->getInterruptController(0));
assert(interrupts);
interrupts->setRegNoEffect(APIC_ID, cpuId << 24);
void startupCPU(ThreadContext *tc, int cpuId)
{
if (cpuId == 0 || !FullSystem) {
- tc->activate(Cycles(0));
+ tc->activate();
} else {
// This is an application processor (AP). It should be initialized to
// look like only the BIOS POST has run on it and put then put it into
// a halted state.
- tc->suspend(Cycles(0));
+ tc->suspend();
}
}
// need to be considered while copying state. That will likely not be
// true in the future.
for (int i = 0; i < NUM_MISCREGS; ++i) {
- if ( ( i != MISCREG_CR1 &&
- !(i > MISCREG_CR4 && i < MISCREG_CR8) &&
- !(i > MISCREG_CR8 && i <= MISCREG_CR15) ) == false) {
+ if (!isValidMiscReg(i))
continue;
- }
+
dest->setMiscRegNoEffect(i, src->readMiscRegNoEffect(i));
}
{
//copy int regs
for (int i = 0; i < NumIntRegs; ++i)
- dest->setIntReg(i, src->readIntReg(i));
+ dest->setIntRegFlat(i, src->readIntRegFlat(i));
//copy float regs
for (int i = 0; i < NumFloatRegs; ++i)
- dest->setFloatRegBits(i, src->readFloatRegBits(i));
+ dest->setFloatRegBitsFlat(i, src->readFloatRegBitsFlat(i));
+ //copy condition-code regs
+ for (int i = 0; i < NumCCRegs; ++i)
+ dest->setCCRegFlat(i, src->readCCRegFlat(i));
copyMiscRegs(src, dest);
dest->pcState(src->pcState());
}
getRFlags(ThreadContext *tc)
{
const uint64_t ncc_flags(tc->readMiscRegNoEffect(MISCREG_RFLAGS));
- const uint64_t cc_flags(tc->readIntReg(X86ISA::INTREG_PSEUDO(0)));
- const uint64_t cfof_bits(tc->readIntReg(X86ISA::INTREG_PSEUDO(1)));
- const uint64_t df_bit(tc->readIntReg(X86ISA::INTREG_PSEUDO(2)));
+ const uint64_t cc_flags(tc->readCCReg(X86ISA::CCREG_ZAPS));
+ const uint64_t cfof_bits(tc->readCCReg(X86ISA::CCREG_CFOF));
+ const uint64_t df_bit(tc->readCCReg(X86ISA::CCREG_DF));
// ecf (PSEUDO(3)) & ezf (PSEUDO(4)) are only visible to
// microcode, so we can safely ignore them.
void
setRFlags(ThreadContext *tc, uint64_t val)
{
- tc->setIntReg(X86ISA::INTREG_PSEUDO(0), val & ccFlagMask);
- tc->setIntReg(X86ISA::INTREG_PSEUDO(1), val & cfofMask);
- tc->setIntReg(X86ISA::INTREG_PSEUDO(2), val & DFBit);
+ tc->setCCReg(X86ISA::CCREG_ZAPS, val & ccFlagMask);
+ tc->setCCReg(X86ISA::CCREG_CFOF, val & cfofMask);
+ tc->setCCReg(X86ISA::CCREG_DF, val & DFBit);
// Internal microcode registers (ECF & EZF)
- tc->setIntReg(X86ISA::INTREG_PSEUDO(3), 0);
- tc->setIntReg(X86ISA::INTREG_PSEUDO(4), 0);
+ tc->setCCReg(X86ISA::CCREG_ECF, 0);
+ tc->setCCReg(X86ISA::CCREG_EZF, 0);
// Update the RFLAGS misc reg with whatever didn't go into the
// magic registers.
tc->setMiscReg(MISCREG_RFLAGS, val & ~(ccFlagMask | cfofMask | DFBit));
}
+uint8_t
+convX87TagsToXTags(uint16_t ftw)
+{
+ uint8_t ftwx(0);
+ for (int i = 0; i < 8; ++i) {
+ // Extract the tag for the current element on the FP stack
+ const unsigned tag((ftw >> (2 * i)) & 0x3);
+
+ /*
+ * Check the type of the current FP element. Valid values are:
+ * 0 == Valid
+ * 1 == Zero
+ * 2 == Special (Nan, unsupported, infinity, denormal)
+ * 3 == Empty
+ */
+ // The xsave version of the tag word only keeps track of
+ // whether the element is empty or not. Set the corresponding
+ // bit in the ftwx if it's not empty,
+ if (tag != 0x3)
+ ftwx |= 1 << i;
+ }
+
+ return ftwx;
+}
+
+uint16_t
+convX87XTagsToTags(uint8_t ftwx)
+{
+ uint16_t ftw(0);
+ for (int i = 0; i < 8; ++i) {
+ const unsigned xtag(((ftwx >> i) & 0x1));
+
+ // The xtag for an x87 stack position is 0 for empty stack positions.
+ if (!xtag) {
+ // Set the tag word to 3 (empty) for the current element.
+ ftw |= 0x3 << (2 * i);
+ } else {
+ // TODO: We currently assume that non-empty elements are
+ // valid (0x0), but we should ideally reconstruct the full
+ // state (valid/zero/special).
+ }
+ }
+
+ return ftw;
+}
+
+uint16_t
+genX87Tags(uint16_t ftw, uint8_t top, int8_t spm)
+{
+ const uint8_t new_top((top + spm + 8) % 8);
+
+ if (spm > 0) {
+ // Removing elements from the stack. Flag the elements as empty.
+ for (int i = top; i != new_top; i = (i + 1 + 8) % 8)
+ ftw |= 0x3 << (2 * i);
+ } else if (spm < 0) {
+ // Adding elements to the stack. Flag the new elements as
+ // valid. We should ideally decode them and "do the right
+ // thing".
+ for (int i = new_top; i != top; i = (i + 1 + 8) % 8)
+ ftw &= ~(0x3 << (2 * i));
+ }
+
+ return ftw;
+}
+
+double
+loadFloat80(const void *_mem)
+{
+ const fp80_t *fp80((const fp80_t *)_mem);
+
+ return fp80_cvtd(*fp80);
+}
+
+void
+storeFloat80(void *_mem, double value)
+{
+ fp80_t *fp80((fp80_t *)_mem);
+
+ *fp80 = fp80_cvfd(value);
+}
+
} // namespace X86_ISA