void BX_CPU_C::iret32_stack_return_from_v86(bxInstruction_c *i)
{
if (BX_CPU_THIS_PTR get_IOPL() < 3) {
// trap to virtual 8086 monitor
BX_DEBUG(("IRET in vm86 with IOPL != 3, VME = 0"));
exception(BX_GP_EXCEPTION, 0);
}
Bit32u eip, cs_raw, flags32;
// Build a mask of the following bits:
// ID,VIP,VIF,AC,VM,RF,x,NT,IOPL,OF,DF,IF,TF,SF,ZF,x,AF,x,PF,x,CF
Bit32u change_mask = EFlagsOSZAPCMask | EFlagsTFMask | EFlagsIFMask
| EFlagsDFMask | EFlagsNTMask | EFlagsRFMask;
#if BX_CPU_LEVEL >= 4
change_mask |= (EFlagsIDMask | EFlagsACMask); // ID/AC
#endif
eip = pop_32();
cs_raw = pop_32();
flags32 = pop_32();
load_seg_reg(&BX_CPU_THIS_PTR sregs[BX_SEG_REG_CS], (Bit16u) cs_raw);
EIP = eip;
// VIF, VIP, VM, IOPL unchanged
writeEFlags(flags32, change_mask);
}
void BX_CPU_C::stack_return_to_v86(Bit32u new_eip, Bit32u raw_cs_selector, Bit32u flags32)
{
Bit32u temp_ESP, new_esp;
Bit16u raw_es_selector, raw_ds_selector, raw_fs_selector,
raw_gs_selector, raw_ss_selector;
// Must be 32bit effective opsize, VM is set in upper 16bits of eFLAGS
// and CPL = 0 to get here
// ----------------
// | | OLD GS | eSP+32
// | | OLD FS | eSP+28
// | | OLD DS | eSP+24
// | | OLD ES | eSP+20
// | | OLD SS | eSP+16
// | OLD ESP | eSP+12
// | OLD EFLAGS | eSP+8
// | | OLD CS | eSP+4
// | OLD EIP | eSP+0
// ----------------
if (BX_CPU_THIS_PTR sregs[BX_SEG_REG_SS].cache.u.segment.d_b)
temp_ESP = ESP;
else
temp_ESP = SP;
// load SS:ESP from stack
new_esp = read_virtual_dword_32(BX_SEG_REG_SS, temp_ESP+12);
raw_ss_selector = (Bit16u) read_virtual_dword_32(BX_SEG_REG_SS, temp_ESP+16);
// load ES,DS,FS,GS from stack
raw_es_selector = (Bit16u) read_virtual_dword_32(BX_SEG_REG_SS, temp_ESP+20);
raw_ds_selector = (Bit16u) read_virtual_dword_32(BX_SEG_REG_SS, temp_ESP+24);
raw_fs_selector = (Bit16u) read_virtual_dword_32(BX_SEG_REG_SS, temp_ESP+28);
raw_gs_selector = (Bit16u) read_virtual_dword_32(BX_SEG_REG_SS, temp_ESP+32);
writeEFlags(flags32, EFlagsValidMask);
// load CS:IP from stack; already read and passed as args
BX_CPU_THIS_PTR sregs[BX_SEG_REG_CS].selector.value = raw_cs_selector;
EIP = new_eip & 0xffff;
BX_CPU_THIS_PTR sregs[BX_SEG_REG_ES].selector.value = raw_es_selector;
BX_CPU_THIS_PTR sregs[BX_SEG_REG_DS].selector.value = raw_ds_selector;
BX_CPU_THIS_PTR sregs[BX_SEG_REG_FS].selector.value = raw_fs_selector;
BX_CPU_THIS_PTR sregs[BX_SEG_REG_GS].selector.value = raw_gs_selector;
BX_CPU_THIS_PTR sregs[BX_SEG_REG_SS].selector.value = raw_ss_selector;
ESP = new_esp; // full 32 bit are loaded
init_v8086_mode();
}
void BX_CPU_C::iret16_stack_return_from_v86(bxInstruction_c *i)
{
if ((BX_CPU_THIS_PTR get_IOPL() < 3) && (BX_CR4_VME_ENABLED == 0)) {
// trap to virtual 8086 monitor
BX_DEBUG(("IRET in vm86 with IOPL != 3, VME = 0"));
exception(BX_GP_EXCEPTION, 0);
}
Bit16u ip, cs_raw, flags16;
ip = pop_16();
cs_raw = pop_16();
flags16 = pop_16();
#if BX_CPU_LEVEL >= 5
if (BX_CPU_THIS_PTR cr4.get_VME() && BX_CPU_THIS_PTR get_IOPL() < 3)
{
if (((flags16 & EFlagsIFMask) && BX_CPU_THIS_PTR get_VIP()) ||
(flags16 & EFlagsTFMask))
{
BX_DEBUG(("iret16_stack_return_from_v86(): #GP(0) in VME mode"));
exception(BX_GP_EXCEPTION, 0);
}
load_seg_reg(&BX_CPU_THIS_PTR sregs[BX_SEG_REG_CS], cs_raw);
EIP = (Bit32u) ip;
// IF, IOPL unchanged, EFLAGS.VIF = TMP_FLAGS.IF
Bit32u changeMask = EFlagsOSZAPCMask | EFlagsTFMask |
EFlagsDFMask | EFlagsNTMask | EFlagsVIFMask;
Bit32u flags32 = (Bit32u) flags16;
if (flags16 & EFlagsIFMask) flags32 |= EFlagsVIFMask;
writeEFlags(flags32, changeMask);
return;
}
#endif
load_seg_reg(&BX_CPU_THIS_PTR sregs[BX_SEG_REG_CS], cs_raw);
EIP = (Bit32u) ip;
write_flags(flags16, /*IOPL*/ 0, /*IF*/ 1);
}
void BX_CPU_C::task_switch(bx_selector_t *tss_selector,
bx_descriptor_t *tss_descriptor, unsigned source,
Bit32u dword1, Bit32u dword2)
{
Bit32u obase32; // base address of old TSS
Bit32u nbase32; // base address of new TSS
Bit32u temp32, newCR3;
Bit16u raw_cs_selector, raw_ss_selector, raw_ds_selector, raw_es_selector,
raw_fs_selector, raw_gs_selector, raw_ldt_selector;
Bit16u temp16, trap_word;
bx_selector_t cs_selector, ss_selector, ds_selector, es_selector,
fs_selector, gs_selector, ldt_selector;
bx_descriptor_t cs_descriptor, ss_descriptor, ldt_descriptor;
Bit32u old_TSS_max, new_TSS_max, old_TSS_limit, new_TSS_limit;
Bit32u newEAX, newECX, newEDX, newEBX;
Bit32u newESP, newEBP, newESI, newEDI;
Bit32u newEFLAGS, newEIP;
BX_DEBUG(("TASKING: ENTER"));
invalidate_prefetch_q();
// Discard any traps and inhibits for new context; traps will
// resume upon return.
BX_CPU_THIS_PTR debug_trap = 0;
BX_CPU_THIS_PTR inhibit_mask = 0;
// STEP 1: The following checks are made before calling task_switch(),
// for JMP & CALL only. These checks are NOT made for exceptions,
// interrupts & IRET.
//
// 1) TSS DPL must be >= CPL
// 2) TSS DPL must be >= TSS selector RPL
// 3) TSS descriptor is not busy.
// TSS must be present, else #NP(TSS selector)
if (tss_descriptor->p==0) {
BX_ERROR(("task_switch: TSS descriptor is not present !"));
exception(BX_NP_EXCEPTION, tss_selector->value & 0xfffc, 0);
}
// STEP 2: The processor performs limit-checking on the target TSS
// to verify that the TSS limit is greater than or equal
// to 67h (2Bh for 16-bit TSS).
// Gather info about old TSS
if (BX_CPU_THIS_PTR tr.cache.type <= 3) {
old_TSS_max = 0x29;
}
else {
old_TSS_max = 0x5F;
}
// Gather info about new TSS
if (tss_descriptor->type <= 3) { // {1,3}
new_TSS_max = 0x2B;
}
else { // tss_descriptor->type = {9,11}
new_TSS_max = 0x67;
}
obase32 = (Bit32u) BX_CPU_THIS_PTR tr.cache.u.system.base; // old TSS.base
old_TSS_limit = BX_CPU_THIS_PTR tr.cache.u.system.limit_scaled;
nbase32 = (Bit32u) tss_descriptor->u.system.base; // new TSS.base
new_TSS_limit = tss_descriptor->u.system.limit_scaled;
// TSS must have valid limit, else #TS(TSS selector)
if (tss_selector->ti || tss_descriptor->valid==0 ||
new_TSS_limit < new_TSS_max)
{
BX_ERROR(("task_switch(): new TSS limit < %d", new_TSS_max));
exception(BX_TS_EXCEPTION, tss_selector->value & 0xfffc, 0);
}
if (old_TSS_limit < old_TSS_max) {
BX_ERROR(("task_switch(): old TSS limit < %d", old_TSS_max));
exception(BX_TS_EXCEPTION, BX_CPU_THIS_PTR tr.selector.value & 0xfffc, 0);
}
if (obase32 == nbase32) {
BX_INFO(("TASK SWITCH: switching to the same TSS !"));
}
// Check that old TSS, new TSS, and all segment descriptors
// used in the task switch are paged in.
if (BX_CPU_THIS_PTR cr0.get_PG())
{
dtranslate_linear(obase32, 0, BX_WRITE); // new TSS
dtranslate_linear(obase32 + old_TSS_max, 0, BX_WRITE);
dtranslate_linear(nbase32, 0, BX_READ); // old TSS
dtranslate_linear(nbase32 + new_TSS_max, 0, BX_READ);
// ??? Humm, we check the new TSS region with READ above,
// but sometimes we need to write the link field in that
// region. We also sometimes update other fields, perhaps
// we need to WRITE check them here also, so that we keep
// the written state consistent (ie, we don't encounter a
// page fault in the middle).
if (source == BX_TASK_FROM_CALL_OR_INT)
{
dtranslate_linear(nbase32, 0, BX_WRITE);
dtranslate_linear(nbase32 + 2, 0, BX_WRITE);
}
}
// Privilege and busy checks done in CALL, JUMP, INT, IRET
// STEP 3: Save the current task state in the TSS. Up to this point,
// any exception that occurs aborts the task switch without
// changing the processor state.
/* save current machine state in old task's TSS */
Bit32u oldEFLAGS = read_eflags();
/* if moving to busy task, clear NT bit */
if (tss_descriptor->type == BX_SYS_SEGMENT_BUSY_286_TSS ||
tss_descriptor->type == BX_SYS_SEGMENT_BUSY_386_TSS)
{
oldEFLAGS &= ~EFlagsNTMask;
}
if (BX_CPU_THIS_PTR tr.cache.type <= 3) {
temp16 = IP; access_write_linear(Bit32u(obase32 + 14), 2, 0, &temp16);
temp16 = oldEFLAGS; access_write_linear(Bit32u(obase32 + 16), 2, 0, &temp16);
temp16 = AX; access_write_linear(Bit32u(obase32 + 18), 2, 0, &temp16);
temp16 = CX; access_write_linear(Bit32u(obase32 + 20), 2, 0, &temp16);
temp16 = DX; access_write_linear(Bit32u(obase32 + 22), 2, 0, &temp16);
temp16 = BX; access_write_linear(Bit32u(obase32 + 24), 2, 0, &temp16);
temp16 = SP; access_write_linear(Bit32u(obase32 + 26), 2, 0, &temp16);
temp16 = BP; access_write_linear(Bit32u(obase32 + 28), 2, 0, &temp16);
temp16 = SI; access_write_linear(Bit32u(obase32 + 30), 2, 0, &temp16);
temp16 = DI; access_write_linear(Bit32u(obase32 + 32), 2, 0, &temp16);
temp16 = BX_CPU_THIS_PTR sregs[BX_SEG_REG_ES].selector.value;
access_write_linear(Bit32u(obase32 + 34), 2, 0, &temp16);
temp16 = BX_CPU_THIS_PTR sregs[BX_SEG_REG_CS].selector.value;
access_write_linear(Bit32u(obase32 + 36), 2, 0, &temp16);
temp16 = BX_CPU_THIS_PTR sregs[BX_SEG_REG_SS].selector.value;
access_write_linear(Bit32u(obase32 + 38), 2, 0, &temp16);
temp16 = BX_CPU_THIS_PTR sregs[BX_SEG_REG_DS].selector.value;
access_write_linear(Bit32u(obase32 + 40), 2, 0, &temp16);
}
else {
temp32 = EIP; access_write_linear(Bit32u(obase32 + 0x20), 4, 0, &temp32);
temp32 = oldEFLAGS; access_write_linear(Bit32u(obase32 + 0x24), 4, 0, &temp32);
temp32 = EAX; access_write_linear(Bit32u(obase32 + 0x28), 4, 0, &temp32);
temp32 = ECX; access_write_linear(Bit32u(obase32 + 0x2c), 4, 0, &temp32);
temp32 = EDX; access_write_linear(Bit32u(obase32 + 0x30), 4, 0, &temp32);
temp32 = EBX; access_write_linear(Bit32u(obase32 + 0x34), 4, 0, &temp32);
temp32 = ESP; access_write_linear(Bit32u(obase32 + 0x38), 4, 0, &temp32);
temp32 = EBP; access_write_linear(Bit32u(obase32 + 0x3c), 4, 0, &temp32);
temp32 = ESI; access_write_linear(Bit32u(obase32 + 0x40), 4, 0, &temp32);
temp32 = EDI; access_write_linear(Bit32u(obase32 + 0x44), 4, 0, &temp32);
temp16 = BX_CPU_THIS_PTR sregs[BX_SEG_REG_ES].selector.value;
access_write_linear(Bit32u(obase32 + 0x48), 2, 0, &temp16);
temp16 = BX_CPU_THIS_PTR sregs[BX_SEG_REG_CS].selector.value;
access_write_linear(Bit32u(obase32 + 0x4c), 2, 0, &temp16);
temp16 = BX_CPU_THIS_PTR sregs[BX_SEG_REG_SS].selector.value;
access_write_linear(Bit32u(obase32 + 0x50), 2, 0, &temp16);
temp16 = BX_CPU_THIS_PTR sregs[BX_SEG_REG_DS].selector.value;
access_write_linear(Bit32u(obase32 + 0x54), 2, 0, &temp16);
temp16 = BX_CPU_THIS_PTR sregs[BX_SEG_REG_FS].selector.value;
access_write_linear(Bit32u(obase32 + 0x58), 2, 0, &temp16);
temp16 = BX_CPU_THIS_PTR sregs[BX_SEG_REG_GS].selector.value;
access_write_linear(Bit32u(obase32 + 0x5c), 2, 0, &temp16);
}
// effect on link field of new task
if (source == BX_TASK_FROM_CALL_OR_INT)
{
// set to selector of old task's TSS
temp16 = BX_CPU_THIS_PTR tr.selector.value;
access_write_linear(nbase32, 2, 0, &temp16);
}
// STEP 4: The new-task state is loaded from the TSS
if (tss_descriptor->type <= 3) {
access_read_linear(Bit32u(nbase32 + 14), 2, 0, BX_READ, &temp16);
newEIP = temp16; // zero out upper word
access_read_linear(Bit32u(nbase32 + 16), 2, 0, BX_READ, &temp16);
newEFLAGS = temp16;
// incoming TSS is 16bit:
// - upper word of general registers is set to 0xFFFF
// - upper word of eflags is zero'd
// - FS, GS are zero'd
// - upper word of eIP is zero'd
access_read_linear(Bit32u(nbase32 + 18), 2, 0, BX_READ, &temp16);
newEAX = 0xffff0000 | temp16;
access_read_linear(Bit32u(nbase32 + 20), 2, 0, BX_READ, &temp16);
newECX = 0xffff0000 | temp16;
access_read_linear(Bit32u(nbase32 + 22), 2, 0, BX_READ, &temp16);
newEDX = 0xffff0000 | temp16;
access_read_linear(Bit32u(nbase32 + 24), 2, 0, BX_READ, &temp16);
newEBX = 0xffff0000 | temp16;
access_read_linear(Bit32u(nbase32 + 26), 2, 0, BX_READ, &temp16);
newESP = 0xffff0000 | temp16;
access_read_linear(Bit32u(nbase32 + 28), 2, 0, BX_READ, &temp16);
newEBP = 0xffff0000 | temp16;
access_read_linear(Bit32u(nbase32 + 30), 2, 0, BX_READ, &temp16);
newESI = 0xffff0000 | temp16;
access_read_linear(Bit32u(nbase32 + 32), 2, 0, BX_READ, &temp16);
newEDI = 0xffff0000 | temp16;
access_read_linear(Bit32u(nbase32 + 34), 2, 0, BX_READ, &raw_es_selector);
access_read_linear(Bit32u(nbase32 + 36), 2, 0, BX_READ, &raw_cs_selector);
access_read_linear(Bit32u(nbase32 + 38), 2, 0, BX_READ, &raw_ss_selector);
access_read_linear(Bit32u(nbase32 + 40), 2, 0, BX_READ, &raw_ds_selector);
access_read_linear(Bit32u(nbase32 + 42), 2, 0, BX_READ, &raw_ldt_selector);
raw_fs_selector = 0; // use a NULL selector
raw_gs_selector = 0; // use a NULL selector
// No CR3 change for 286 task switch
newCR3 = 0; // keep compiler happy (not used)
trap_word = 0; // keep compiler happy (not used)
}
else {
if (BX_CPU_THIS_PTR cr0.get_PG())
access_read_linear(Bit32u(nbase32 + 0x1c), 4, 0, BX_READ, &newCR3);
else
newCR3 = 0; // keep compiler happy (not used)
access_read_linear(Bit32u(nbase32 + 0x20), 4, 0, BX_READ, &newEIP);
access_read_linear(Bit32u(nbase32 + 0x24), 4, 0, BX_READ, &newEFLAGS);
access_read_linear(Bit32u(nbase32 + 0x28), 4, 0, BX_READ, &newEAX);
access_read_linear(Bit32u(nbase32 + 0x2c), 4, 0, BX_READ, &newECX);
access_read_linear(Bit32u(nbase32 + 0x30), 4, 0, BX_READ, &newEDX);
access_read_linear(Bit32u(nbase32 + 0x34), 4, 0, BX_READ, &newEBX);
access_read_linear(Bit32u(nbase32 + 0x38), 4, 0, BX_READ, &newESP);
access_read_linear(Bit32u(nbase32 + 0x3c), 4, 0, BX_READ, &newEBP);
access_read_linear(Bit32u(nbase32 + 0x40), 4, 0, BX_READ, &newESI);
access_read_linear(Bit32u(nbase32 + 0x44), 4, 0, BX_READ, &newEDI);
access_read_linear(Bit32u(nbase32 + 0x48), 2, 0, BX_READ, &raw_es_selector);
access_read_linear(Bit32u(nbase32 + 0x4c), 2, 0, BX_READ, &raw_cs_selector);
access_read_linear(Bit32u(nbase32 + 0x50), 2, 0, BX_READ, &raw_ss_selector);
access_read_linear(Bit32u(nbase32 + 0x54), 2, 0, BX_READ, &raw_ds_selector);
access_read_linear(Bit32u(nbase32 + 0x58), 2, 0, BX_READ, &raw_fs_selector);
access_read_linear(Bit32u(nbase32 + 0x5c), 2, 0, BX_READ, &raw_gs_selector);
access_read_linear(Bit32u(nbase32 + 0x60), 2, 0, BX_READ, &raw_ldt_selector);
access_read_linear(Bit32u(nbase32 + 0x64), 2, 0, BX_READ, &trap_word);
}
// Step 5: If CALL, interrupt, or JMP, set busy flag in new task's
// TSS descriptor. If IRET, leave set.
if (source == BX_TASK_FROM_JUMP || source == BX_TASK_FROM_CALL_OR_INT)
{
// set the new task's busy bit
Bit32u laddr = (Bit32u)(BX_CPU_THIS_PTR gdtr.base) + (tss_selector->index<<3) + 4;
access_read_linear(laddr, 4, 0, BX_READ, &dword2);
dword2 |= 0x200;
access_write_linear(laddr, 4, 0, &dword2);
}
// Step 6: If JMP or IRET, clear busy bit in old task TSS descriptor,
// otherwise leave set.
// effect on Busy bit of old task
if (source == BX_TASK_FROM_JUMP || source == BX_TASK_FROM_IRET) {
// Bit is cleared
Bit32u laddr = (Bit32u) BX_CPU_THIS_PTR gdtr.base + (BX_CPU_THIS_PTR tr.selector.index<<3) + 4;
access_read_linear(laddr, 4, 0, BX_READ, &temp32);
temp32 &= ~0x200;
access_write_linear(laddr, 4, 0, &temp32);
}
//
// Commit point. At this point, we commit to the new
// context. If an unrecoverable error occurs in further
// processing, we complete the task switch without performing
// additional access and segment availablility checks and
// generate the appropriate exception prior to beginning
// execution of the new task.
//
// Step 7: Load the task register with the segment selector and
// descriptor for the new task TSS.
BX_CPU_THIS_PTR tr.selector = *tss_selector;
BX_CPU_THIS_PTR tr.cache = *tss_descriptor;
BX_CPU_THIS_PTR tr.cache.type |= 2; // mark TSS in TR as busy
// Step 8: Set TS flag in the CR0 image stored in the new task TSS.
BX_CPU_THIS_PTR cr0.set_TS(1);
// Task switch clears LE/L3/L2/L1/L0 in DR7
BX_CPU_THIS_PTR dr7 &= ~0x00000155;
// Step 9: If call or interrupt, set the NT flag in the eflags
// image stored in new task's TSS. If IRET or JMP,
// NT is restored from new TSS eflags image. (no change)
// effect on NT flag of new task
if (source == BX_TASK_FROM_CALL_OR_INT) {
newEFLAGS |= EFlagsNTMask; // NT flag is set
}
// Step 10: Load the new task (dynamic) state from new TSS.
// Any errors associated with loading and qualification of
// segment descriptors in this step occur in the new task's
// context. State loaded here includes LDTR, CR3,
// EFLAGS, EIP, general purpose registers, and segment
// descriptor parts of the segment registers.
if ((tss_descriptor->type >= 9) && BX_CPU_THIS_PTR cr0.get_PG()) {
// change CR3 only if it actually modified
if (newCR3 != BX_CPU_THIS_PTR cr3) {
SetCR3(newCR3); // Tell paging unit about new cr3 value
BX_DEBUG (("task_switch changing CR3 to 0x" FMT_PHY_ADDRX, newCR3));
BX_INSTR_TLB_CNTRL(BX_CPU_ID, BX_INSTR_TASKSWITCH, newCR3);
}
}
BX_CPU_THIS_PTR prev_rip = EIP = newEIP;
EAX = newEAX;
ECX = newECX;
EDX = newEDX;
EBX = newEBX;
ESP = newESP;
EBP = newEBP;
ESI = newESI;
EDI = newEDI;
writeEFlags(newEFLAGS, EFlagsValidMask);
// Fill in selectors for all segment registers. If errors
// occur later, the selectors will at least be loaded.
parse_selector(raw_cs_selector, &cs_selector);
BX_CPU_THIS_PTR sregs[BX_SEG_REG_CS].selector = cs_selector;
parse_selector(raw_ds_selector, &ds_selector);
BX_CPU_THIS_PTR sregs[BX_SEG_REG_DS].selector = ds_selector;
parse_selector(raw_es_selector, &es_selector);
BX_CPU_THIS_PTR sregs[BX_SEG_REG_ES].selector = es_selector;
parse_selector(raw_ss_selector, &ss_selector);
BX_CPU_THIS_PTR sregs[BX_SEG_REG_SS].selector = ss_selector;
parse_selector(raw_fs_selector, &fs_selector);
BX_CPU_THIS_PTR sregs[BX_SEG_REG_FS].selector = fs_selector;
parse_selector(raw_gs_selector, &gs_selector);
BX_CPU_THIS_PTR sregs[BX_SEG_REG_GS].selector = gs_selector;
parse_selector(raw_ldt_selector, &ldt_selector);
BX_CPU_THIS_PTR ldtr.selector = ldt_selector;
// Start out with invalid descriptor caches, fill in
// with values only as they are validated.
BX_CPU_THIS_PTR ldtr.cache.valid = 0;
BX_CPU_THIS_PTR ldtr.cache.u.system.limit = 0;
BX_CPU_THIS_PTR ldtr.cache.u.system.limit_scaled = 0;
BX_CPU_THIS_PTR sregs[BX_SEG_REG_ES].cache.valid = 0;
BX_CPU_THIS_PTR sregs[BX_SEG_REG_CS].cache.valid = 0;
BX_CPU_THIS_PTR sregs[BX_SEG_REG_SS].cache.valid = 0;
BX_CPU_THIS_PTR sregs[BX_SEG_REG_DS].cache.valid = 0;
BX_CPU_THIS_PTR sregs[BX_SEG_REG_FS].cache.valid = 0;
BX_CPU_THIS_PTR sregs[BX_SEG_REG_GS].cache.valid = 0;
// LDTR
if (ldt_selector.ti) {
// LDT selector must be in GDT
BX_INFO(("task_switch(exception after commit point): bad LDT selector TI=1"));
exception(BX_TS_EXCEPTION, raw_ldt_selector & 0xfffc, 0);
}
if ((raw_ldt_selector & 0xfffc) != 0) {
bx_bool good = fetch_raw_descriptor2(&ldt_selector, &dword1, &dword2);
if (!good) {
BX_ERROR(("task_switch(exception after commit point): bad LDT fetch"));
exception(BX_TS_EXCEPTION, raw_ldt_selector & 0xfffc, 0);
}
parse_descriptor(dword1, dword2, &ldt_descriptor);
// LDT selector of new task is valid, else #TS(new task's LDT)
if (ldt_descriptor.valid==0 ||
ldt_descriptor.type!=BX_SYS_SEGMENT_LDT ||
ldt_descriptor.segment)
{
BX_ERROR(("task_switch(exception after commit point): bad LDT segment"));
exception(BX_TS_EXCEPTION, raw_ldt_selector & 0xfffc, 0);
}
// LDT of new task is present in memory, else #TS(new tasks's LDT)
if (! IS_PRESENT(ldt_descriptor)) {
BX_ERROR(("task_switch(exception after commit point): LDT not present"));
exception(BX_TS_EXCEPTION, raw_ldt_selector & 0xfffc, 0);
}
// All checks pass, fill in LDTR shadow cache
BX_CPU_THIS_PTR ldtr.cache = ldt_descriptor;
}
else {
// NULL LDT selector is OK, leave cache invalid
}
if (v8086_mode()) {
// load seg regs as 8086 registers
load_seg_reg(&BX_CPU_THIS_PTR sregs[BX_SEG_REG_CS], raw_cs_selector);
load_seg_reg(&BX_CPU_THIS_PTR sregs[BX_SEG_REG_SS], raw_ss_selector);
load_seg_reg(&BX_CPU_THIS_PTR sregs[BX_SEG_REG_DS], raw_ds_selector);
load_seg_reg(&BX_CPU_THIS_PTR sregs[BX_SEG_REG_ES], raw_es_selector);
load_seg_reg(&BX_CPU_THIS_PTR sregs[BX_SEG_REG_FS], raw_fs_selector);
load_seg_reg(&BX_CPU_THIS_PTR sregs[BX_SEG_REG_GS], raw_gs_selector);
}
else {
// SS
if ((raw_ss_selector & 0xfffc) != 0)
{
bx_bool good = fetch_raw_descriptor2(&ss_selector, &dword1, &dword2);
if (!good) {
BX_ERROR(("task_switch(exception after commit point): bad SS fetch"));
exception(BX_TS_EXCEPTION, raw_ss_selector & 0xfffc, 0);
}
parse_descriptor(dword1, dword2, &ss_descriptor);
// SS selector must be within its descriptor table limits else #TS(SS)
// SS descriptor AR byte must must indicate writable data segment,
// else #TS(SS)
if (ss_descriptor.valid==0 || ss_descriptor.segment==0 ||
IS_CODE_SEGMENT(ss_descriptor.type) ||
!IS_DATA_SEGMENT_WRITEABLE(ss_descriptor.type))
{
BX_ERROR(("task_switch(exception after commit point): SS not valid or writeable segment"));
exception(BX_TS_EXCEPTION, raw_ss_selector & 0xfffc, 0);
}
//
// Stack segment is present in memory, else #SS(new stack segment)
//
if (! IS_PRESENT(ss_descriptor)) {
BX_ERROR(("task_switch(exception after commit point): SS not present"));
exception(BX_SS_EXCEPTION, raw_ss_selector & 0xfffc, 0);
}
// Stack segment DPL matches CS.RPL, else #TS(new stack segment)
if (ss_descriptor.dpl != cs_selector.rpl) {
BX_ERROR(("task_switch(exception after commit point): SS.rpl != CS.RPL"));
exception(BX_TS_EXCEPTION, raw_ss_selector & 0xfffc, 0);
}
// Stack segment DPL matches selector RPL, else #TS(new stack segment)
if (ss_descriptor.dpl != ss_selector.rpl) {
BX_ERROR(("task_switch(exception after commit point): SS.dpl != SS.rpl"));
exception(BX_TS_EXCEPTION, raw_ss_selector & 0xfffc, 0);
}
// All checks pass, fill in shadow cache
BX_CPU_THIS_PTR sregs[BX_SEG_REG_SS].cache = ss_descriptor;
}
else {
// SS selector is valid, else #TS(new stack segment)
BX_ERROR(("task_switch(exception after commit point): SS NULL"));
exception(BX_TS_EXCEPTION, raw_ss_selector & 0xfffc, 0);
}
// if new selector is not null then perform following checks:
// index must be within its descriptor table limits else #TS(selector)
// AR byte must indicate data or readable code else #TS(selector)
// if data or non-conforming code then:
// DPL must be >= CPL else #TS(selector)
// DPL must be >= RPL else #TS(selector)
// AR byte must indicate PRESENT else #NP(selector)
// load cache with new segment descriptor and set valid bit
// CS
if ((raw_cs_selector & 0xfffc) != 0) {
bx_bool good = fetch_raw_descriptor2(&cs_selector, &dword1, &dword2);
if (!good) {
BX_ERROR(("task_switch(exception after commit point): bad CS fetch"));
exception(BX_TS_EXCEPTION, raw_cs_selector & 0xfffc, 0);
}
parse_descriptor(dword1, dword2, &cs_descriptor);
// CS descriptor AR byte must indicate code segment else #TS(CS)
if (cs_descriptor.valid==0 || cs_descriptor.segment==0 ||
IS_DATA_SEGMENT(cs_descriptor.type))
{
BX_ERROR(("task_switch(exception after commit point): CS not valid executable seg"));
exception(BX_TS_EXCEPTION, raw_cs_selector & 0xfffc, 0);
}
// if non-conforming then DPL must equal selector RPL else #TS(CS)
if (IS_CODE_SEGMENT_NON_CONFORMING(cs_descriptor.type) &&
cs_descriptor.dpl != cs_selector.rpl)
{
BX_ERROR(("task_switch(exception after commit point): non-conforming: CS.dpl!=CS.RPL"));
exception(BX_TS_EXCEPTION, raw_cs_selector & 0xfffc, 0);
}
// if conforming then DPL must be <= selector RPL else #TS(CS)
if (IS_CODE_SEGMENT_CONFORMING(cs_descriptor.type) &&
cs_descriptor.dpl > cs_selector.rpl)
{
BX_ERROR(("task_switch(exception after commit point): conforming: CS.dpl>RPL"));
exception(BX_TS_EXCEPTION, raw_cs_selector & 0xfffc, 0);
}
// Code segment is present in memory, else #NP(new code segment)
if (! IS_PRESENT(cs_descriptor)) {
BX_ERROR(("task_switch(exception after commit point): CS.p==0"));
exception(BX_NP_EXCEPTION, raw_cs_selector & 0xfffc, 0);
}
// All checks pass, fill in shadow cache
BX_CPU_THIS_PTR sregs[BX_SEG_REG_CS].cache = cs_descriptor;
}
else {
// If new cs selector is null #TS(CS)
BX_ERROR(("task_switch(exception after commit point): CS NULL"));
exception(BX_TS_EXCEPTION, raw_cs_selector & 0xfffc, 0);
}
#if BX_SUPPORT_ICACHE
BX_CPU_THIS_PTR updateFetchModeMask();
#endif
#if BX_CPU_LEVEL >= 4 && BX_SUPPORT_ALIGNMENT_CHECK
handleAlignmentCheck(); // task switch, CPL was modified
#endif
task_switch_load_selector(&BX_CPU_THIS_PTR sregs[BX_SEG_REG_DS],
&ds_selector, raw_ds_selector, cs_selector.rpl);
task_switch_load_selector(&BX_CPU_THIS_PTR sregs[BX_SEG_REG_ES],
&es_selector, raw_es_selector, cs_selector.rpl);
task_switch_load_selector(&BX_CPU_THIS_PTR sregs[BX_SEG_REG_FS],
&fs_selector, raw_fs_selector, cs_selector.rpl);
task_switch_load_selector(&BX_CPU_THIS_PTR sregs[BX_SEG_REG_GS],
&gs_selector, raw_gs_selector, cs_selector.rpl);
}
if ((tss_descriptor->type>=9) && (trap_word & 0x1)) {
BX_CPU_THIS_PTR debug_trap |= 0x00008000; // BT flag in DR6
BX_CPU_THIS_PTR async_event = 1; // so processor knows to check
BX_INFO(("task_switch: T bit set in new TSS"));
}
//
// Step 14: Begin execution of new task.
//
BX_DEBUG(("TASKING: LEAVE"));
}
