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dyncom: Remove unused/unnecessary VFP cruft

This commit is contained in:
Lioncash 2015-04-17 20:44:54 -04:00
parent 3ee9f6c5d8
commit d66a12c6f6
7 changed files with 15 additions and 823 deletions

View File

@ -6,7 +6,6 @@ set(SRCS
arm/dyncom/arm_dyncom_interpreter.cpp
arm/dyncom/arm_dyncom_run.cpp
arm/dyncom/arm_dyncom_thumb.cpp
arm/interpreter/armcopro.cpp
arm/interpreter/arminit.cpp
arm/interpreter/armsupp.cpp
arm/skyeye_common/vfp/vfp.cpp

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@ -1,142 +0,0 @@
/* armcopro.c -- co-processor interface: ARM6 Instruction Emulator.
Copyright (C) 1994, 2000 Advanced RISC Machines Ltd.
This program 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 2 of the License, or
(at your option) any later version.
This program 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 this program; if not, write to the Free Software
Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA. */
#include "core/arm/skyeye_common/armdefs.h"
#include "core/arm/skyeye_common/armemu.h"
#include "core/arm/skyeye_common/vfp/vfp.h"
// Dummy Co-processors.
static unsigned int NoCoPro3R(ARMul_State* state, unsigned int a, ARMword b)
{
return ARMul_CANT;
}
static unsigned int NoCoPro4R(ARMul_State* state, unsigned int a, ARMword b, ARMword c)
{
return ARMul_CANT;
}
static unsigned int NoCoPro4W(ARMul_State* state, unsigned int a, ARMword b, ARMword* c)
{
return ARMul_CANT;
}
static unsigned int NoCoPro5R(ARMul_State* state, unsigned int a, ARMword b, ARMword c, ARMword d)
{
return ARMul_CANT;
}
static unsigned int NoCoPro5W(ARMul_State* state, unsigned int a, ARMword b, ARMword* c, ARMword* d)
{
return ARMul_CANT;
}
// Install co-processor instruction handlers in this routine.
void ARMul_CoProInit(ARMul_State* state)
{
// Initialise tham all first.
for (unsigned int i = 0; i < 16; i++)
ARMul_CoProDetach(state, i);
// Install CoPro Instruction handlers here.
// The format is:
// ARMul_CoProAttach (state, CP Number, Init routine, Exit routine
// LDC routine, STC routine, MRC routine, MCR routine,
// CDP routine, Read Reg routine, Write Reg routine).
if (state->is_v6) {
ARMul_CoProAttach(state, 10, VFPInit, NULL, VFPLDC, VFPSTC,
VFPMRC, VFPMCR, VFPMRRC, VFPMCRR, VFPCDP, NULL, NULL);
ARMul_CoProAttach(state, 11, VFPInit, NULL, VFPLDC, VFPSTC,
VFPMRC, VFPMCR, VFPMRRC, VFPMCRR, VFPCDP, NULL, NULL);
/*ARMul_CoProAttach (state, 15, MMUInit, NULL, NULL, NULL,
MMUMRC, MMUMCR, NULL, NULL, NULL, NULL, NULL);*/
}
// No handlers below here.
// Call all the initialisation routines.
for (unsigned int i = 0; i < 16; i++) {
if (state->CPInit[i])
(state->CPInit[i]) (state);
}
}
// Install co-processor finalisation routines in this routine.
void ARMul_CoProExit(ARMul_State * state)
{
for (unsigned int i = 0; i < 16; i++)
if (state->CPExit[i])
(state->CPExit[i]) (state);
// Detach all handlers.
for (unsigned int i = 0; i < 16; i++)
ARMul_CoProDetach(state, i);
}
// Routines to hook Co-processors into ARMulator.
void
ARMul_CoProAttach(ARMul_State* state,
unsigned number,
ARMul_CPInits* init,
ARMul_CPExits* exit,
ARMul_LDCs* ldc,
ARMul_STCs* stc,
ARMul_MRCs* mrc,
ARMul_MCRs* mcr,
ARMul_MRRCs* mrrc,
ARMul_MCRRs* mcrr,
ARMul_CDPs* cdp,
ARMul_CPReads* read, ARMul_CPWrites* write)
{
if (init != NULL)
state->CPInit[number] = init;
if (exit != NULL)
state->CPExit[number] = exit;
if (ldc != NULL)
state->LDC[number] = ldc;
if (stc != NULL)
state->STC[number] = stc;
if (mrc != NULL)
state->MRC[number] = mrc;
if (mcr != NULL)
state->MCR[number] = mcr;
if (mrrc != NULL)
state->MRRC[number] = mrrc;
if (mcrr != NULL)
state->MCRR[number] = mcrr;
if (cdp != NULL)
state->CDP[number] = cdp;
if (read != NULL)
state->CPRead[number] = read;
if (write != NULL)
state->CPWrite[number] = write;
}
void ARMul_CoProDetach(ARMul_State* state, unsigned number)
{
ARMul_CoProAttach(state, number, NULL, NULL,
NoCoPro4R, NoCoPro4W, NoCoPro4W, NoCoPro4R,
NoCoPro5W, NoCoPro5R, NoCoPro3R, NULL, NULL);
state->CPInit[number] = NULL;
state->CPExit[number] = NULL;
state->CPRead[number] = NULL;
state->CPWrite[number] = NULL;
}

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@ -19,6 +19,7 @@
#include "core/mem_map.h"
#include "core/arm/skyeye_common/armdefs.h"
#include "core/arm/skyeye_common/armemu.h"
#include "core/arm/skyeye_common/vfp/vfp.h"
/***************************************************************************\
* Returns a new instantiation of the ARMulator's state *
@ -61,10 +62,6 @@ void ARMul_SelectProcessor(ARMul_State* state, unsigned properties)
state->is_v5e = (properties & ARM_v5e_Prop) != 0;
state->is_v6 = (properties & ARM_v6_Prop) != 0;
state->is_v7 = (properties & ARM_v7_Prop) != 0;
// Only initialse the coprocessor support once we
// know what kind of chip we are dealing with.
ARMul_CoProInit(state);
}
// Resets certain MPCore CP15 values to their ARM-defined reset values.
@ -130,6 +127,8 @@ static void ResetMPCoreCP15Registers(ARMul_State* cpu)
\***************************************************************************/
void ARMul_Reset(ARMul_State* state)
{
VFPInit(state);
state->NextInstr = 0;
state->Reg[15] = 0;

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@ -55,18 +55,6 @@ typedef u16 ARMhword; // must be 16 bits wide
typedef u8 ARMbyte; // must be 8 bits wide
typedef struct ARMul_State ARMul_State;
typedef unsigned ARMul_CPInits(ARMul_State* state);
typedef unsigned ARMul_CPExits(ARMul_State* state);
typedef unsigned ARMul_LDCs(ARMul_State* state, unsigned type, ARMword instr, ARMword value);
typedef unsigned ARMul_STCs(ARMul_State* state, unsigned type, ARMword instr, ARMword* value);
typedef unsigned ARMul_MRCs(ARMul_State* state, unsigned type, ARMword instr, ARMword* value);
typedef unsigned ARMul_MCRs(ARMul_State* state, unsigned type, ARMword instr, ARMword value);
typedef unsigned ARMul_MRRCs(ARMul_State* state, unsigned type, ARMword instr, ARMword* value1, ARMword* value2);
typedef unsigned ARMul_MCRRs(ARMul_State* state, unsigned type, ARMword instr, ARMword value1, ARMword value2);
typedef unsigned ARMul_CDPs(ARMul_State* state, unsigned type, ARMword instr);
typedef unsigned ARMul_CPReads(ARMul_State* state, unsigned reg, ARMword* value);
typedef unsigned ARMul_CPWrites(ARMul_State* state, unsigned reg, ARMword value);
#define VFP_REG_NUM 64
struct ARMul_State
{
@ -117,20 +105,6 @@ struct ARMul_State
unsigned NextInstr;
unsigned VectorCatch; // Caught exception mask
ARMul_CPInits* CPInit[16]; // Coprocessor initialisers
ARMul_CPExits* CPExit[16]; // Coprocessor finalisers
ARMul_LDCs* LDC[16]; // LDC instruction
ARMul_STCs* STC[16]; // STC instruction
ARMul_MRCs* MRC[16]; // MRC instruction
ARMul_MCRs* MCR[16]; // MCR instruction
ARMul_MRRCs* MRRC[16]; // MRRC instruction
ARMul_MCRRs* MCRR[16]; // MCRR instruction
ARMul_CDPs* CDP[16]; // CDP instruction
ARMul_CPReads* CPRead[16]; // Read CP register
ARMul_CPWrites* CPWrite[16]; // Write CP register
unsigned char* CPData[16]; // Coprocessor data
unsigned char const* CPRegWords[16]; // Map of coprocessor register sizes
unsigned NresetSig; // Reset the processor
unsigned NfiqSig;
unsigned NirqSig;

View File

@ -57,12 +57,3 @@ enum {
};
#define FLUSHPIPE state->NextInstr |= PRIMEPIPE
// Coprocessor support functions.
extern void ARMul_CoProInit(ARMul_State*);
extern void ARMul_CoProExit(ARMul_State*);
extern void ARMul_CoProAttach(ARMul_State*, unsigned, ARMul_CPInits*,
ARMul_CPExits*, ARMul_LDCs*, ARMul_STCs*,
ARMul_MRCs*, ARMul_MCRs*, ARMul_MRRCs*, ARMul_MCRRs*,
ARMul_CDPs*, ARMul_CPReads*, ARMul_CPWrites*);
extern void ARMul_CoProDetach(ARMul_State*, unsigned);

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@ -37,296 +37,18 @@ unsigned VFPInit(ARMul_State* state)
return 0;
}
unsigned VFPMRC(ARMul_State* state, unsigned type, u32 instr, u32* value)
void VMSR(ARMul_State* state, ARMword reg, ARMword Rt)
{
/* MRC<c> <coproc>,<opc1>,<Rt>,<CRn>,<CRm>{,<opc2>} */
int CoProc = BITS(instr, 8, 11); /* 10 or 11 */
int OPC_1 = BITS(instr, 21, 23);
int Rt = BITS(instr, 12, 15);
int CRn = BITS(instr, 16, 19);
int CRm = BITS(instr, 0, 3);
int OPC_2 = BITS(instr, 5, 7);
/* TODO check access permission */
/* CRn/opc1 CRm/opc2 */
if (CoProc == 10 || CoProc == 11)
if (reg == 1)
{
if (OPC_1 == 0x0 && CRm == 0 && (OPC_2 & 0x3) == 0)
state->VFP[VFP_FPSCR] = state->Reg[Rt];
}
else if (reg == 8)
{
/* VMOV r to s */
/* Transfering Rt is not mandatory, as the value of interest is pointed by value */
VMOVBRS(state, BIT(instr, 20), Rt, BIT(instr, 7)|CRn<<1, value);
return ARMul_DONE;
state->VFP[VFP_FPEXC] = state->Reg[Rt];
}
if (OPC_1 == 0x7 && CRm == 0 && OPC_2 == 0)
{
VMRS(state, CRn, Rt, value);
return ARMul_DONE;
}
}
LOG_WARNING(Core_ARM11, "Can't identify %x, CoProc %x, OPC_1 %x, Rt %x, CRn %x, CRm %x, OPC_2 %x\n",
instr, CoProc, OPC_1, Rt, CRn, CRm, OPC_2);
return ARMul_CANT;
}
unsigned VFPMCR(ARMul_State* state, unsigned type, u32 instr, u32 value)
{
/* MCR<c> <coproc>,<opc1>,<Rt>,<CRn>,<CRm>{,<opc2>} */
int CoProc = BITS(instr, 8, 11); /* 10 or 11 */
int OPC_1 = BITS(instr, 21, 23);
int Rt = BITS(instr, 12, 15);
int CRn = BITS(instr, 16, 19);
int CRm = BITS(instr, 0, 3);
int OPC_2 = BITS(instr, 5, 7);
/* TODO check access permission */
/* CRn/opc1 CRm/opc2 */
if (CoProc == 10 || CoProc == 11)
{
if (OPC_1 == 0x0 && CRm == 0 && (OPC_2 & 0x3) == 0)
{
/* VMOV s to r */
/* Transfering Rt is not mandatory, as the value of interest is pointed by value */
VMOVBRS(state, BIT(instr, 20), Rt, BIT(instr, 7)|CRn<<1, &value);
return ARMul_DONE;
}
if (OPC_1 == 0x7 && CRm == 0 && OPC_2 == 0)
{
VMSR(state, CRn, Rt);
return ARMul_DONE;
}
if ((OPC_1 & 0x4) == 0 && CoProc == 11 && CRm == 0)
{
VFP_DEBUG_UNIMPLEMENTED(VMOVBRC);
return ARMul_DONE;
}
if (CoProc == 11 && CRm == 0)
{
VFP_DEBUG_UNIMPLEMENTED(VMOVBCR);
return ARMul_DONE;
}
}
LOG_WARNING(Core_ARM11, "Can't identify %x, CoProc %x, OPC_1 %x, Rt %x, CRn %x, CRm %x, OPC_2 %x\n",
instr, CoProc, OPC_1, Rt, CRn, CRm, OPC_2);
return ARMul_CANT;
}
unsigned VFPMRRC(ARMul_State* state, unsigned type, u32 instr, u32* value1, u32* value2)
{
/* MCRR<c> <coproc>,<opc1>,<Rt>,<Rt2>,<CRm> */
int CoProc = BITS(instr, 8, 11); /* 10 or 11 */
int OPC_1 = BITS(instr, 4, 7);
int Rt = BITS(instr, 12, 15);
int Rt2 = BITS(instr, 16, 19);
int CRm = BITS(instr, 0, 3);
if (CoProc == 10 || CoProc == 11)
{
if (CoProc == 10 && (OPC_1 & 0xD) == 1)
{
VMOVBRRSS(state, BIT(instr, 20), Rt, Rt2, BIT(instr, 5)<<4|CRm, value1, value2);
return ARMul_DONE;
}
if (CoProc == 11 && (OPC_1 & 0xD) == 1)
{
/* Transfering Rt and Rt2 is not mandatory, as the value of interest is pointed by value1 and value2 */
VMOVBRRD(state, BIT(instr, 20), Rt, Rt2, BIT(instr, 5)<<4|CRm, value1, value2);
return ARMul_DONE;
}
}
LOG_WARNING(Core_ARM11, "Can't identify %x, CoProc %x, OPC_1 %x, Rt %x, Rt2 %x, CRm %x\n",
instr, CoProc, OPC_1, Rt, Rt2, CRm);
return ARMul_CANT;
}
unsigned VFPMCRR(ARMul_State* state, unsigned type, u32 instr, u32 value1, u32 value2)
{
/* MCRR<c> <coproc>,<opc1>,<Rt>,<Rt2>,<CRm> */
int CoProc = BITS(instr, 8, 11); /* 10 or 11 */
int OPC_1 = BITS(instr, 4, 7);
int Rt = BITS(instr, 12, 15);
int Rt2 = BITS(instr, 16, 19);
int CRm = BITS(instr, 0, 3);
/* TODO check access permission */
/* CRn/opc1 CRm/opc2 */
if (CoProc == 11 || CoProc == 10)
{
if (CoProc == 10 && (OPC_1 & 0xD) == 1)
{
VMOVBRRSS(state, BIT(instr, 20), Rt, Rt2, BIT(instr, 5)<<4|CRm, &value1, &value2);
return ARMul_DONE;
}
if (CoProc == 11 && (OPC_1 & 0xD) == 1)
{
/* Transfering Rt and Rt2 is not mandatory, as the value of interest is pointed by value1 and value2 */
VMOVBRRD(state, BIT(instr, 20), Rt, Rt2, BIT(instr, 5)<<4|CRm, &value1, &value2);
return ARMul_DONE;
}
}
LOG_WARNING(Core_ARM11, "Can't identify %x, CoProc %x, OPC_1 %x, Rt %x, Rt2 %x, CRm %x\n",
instr, CoProc, OPC_1, Rt, Rt2, CRm);
return ARMul_CANT;
}
unsigned VFPSTC(ARMul_State* state, unsigned type, u32 instr, u32 * value)
{
/* STC{L}<c> <coproc>,<CRd>,[<Rn>],<option> */
int CoProc = BITS(instr, 8, 11); /* 10 or 11 */
int CRd = BITS(instr, 12, 15);
int Rn = BITS(instr, 16, 19);
int imm8 = BITS(instr, 0, 7);
int P = BIT(instr, 24);
int U = BIT(instr, 23);
int D = BIT(instr, 22);
int W = BIT(instr, 21);
/* TODO check access permission */
/* VSTM */
if ( (P|U|D|W) == 0 ) {
LOG_ERROR(Core_ARM11, "In %s, UNDEFINED\n", __FUNCTION__);
exit(-1);
}
if (CoProc == 10 || CoProc == 11) {
#if 1
if (P == 0 && U == 0 && W == 0) {
LOG_ERROR(Core_ARM11, "VSTM Related encodings\n");
exit(-1);
}
if (P == U && W == 1) {
LOG_ERROR(Core_ARM11, "UNDEFINED\n");
exit(-1);
}
#endif
if (P == 1 && W == 0)
{
return VSTR(state, type, instr, value);
}
if (P == 1 && U == 0 && W == 1 && Rn == 0xD)
{
return VPUSH(state, type, instr, value);
}
return VSTM(state, type, instr, value);
}
LOG_WARNING(Core_ARM11, "Can't identify %x, CoProc %x, CRd %x, Rn %x, imm8 %x, P %x, U %x, D %x, W %x\n",
instr, CoProc, CRd, Rn, imm8, P, U, D, W);
return ARMul_CANT;
}
unsigned VFPLDC(ARMul_State* state, unsigned type, u32 instr, u32 value)
{
/* LDC{L}<c> <coproc>,<CRd>,[<Rn>] */
int CoProc = BITS(instr, 8, 11); /* 10 or 11 */
int CRd = BITS(instr, 12, 15);
int Rn = BITS(instr, 16, 19);
int imm8 = BITS(instr, 0, 7);
int P = BIT(instr, 24);
int U = BIT(instr, 23);
int D = BIT(instr, 22);
int W = BIT(instr, 21);
/* TODO check access permission */
if ( (P|U|D|W) == 0 ) {
LOG_ERROR(Core_ARM11, "In %s, UNDEFINED\n", __FUNCTION__);
exit(-1);
}
if (CoProc == 10 || CoProc == 11)
{
if (P == 1 && W == 0)
{
return VLDR(state, type, instr, value);
}
if (P == 0 && U == 1 && W == 1 && Rn == 0xD)
{
return VPOP(state, type, instr, value);
}
return VLDM(state, type, instr, value);
}
LOG_WARNING(Core_ARM11, "Can't identify %x, CoProc %x, CRd %x, Rn %x, imm8 %x, P %x, U %x, D %x, W %x\n",
instr, CoProc, CRd, Rn, imm8, P, U, D, W);
return ARMul_CANT;
}
unsigned VFPCDP(ARMul_State* state, unsigned type, u32 instr)
{
/* CDP<c> <coproc>,<opc1>,<CRd>,<CRn>,<CRm>,<opc2> */
int CoProc = BITS(instr, 8, 11); /* 10 or 11 */
int OPC_1 = BITS(instr, 20, 23);
int CRd = BITS(instr, 12, 15);
int CRn = BITS(instr, 16, 19);
int CRm = BITS(instr, 0, 3);
int OPC_2 = BITS(instr, 5, 7);
/* TODO check access permission */
/* CRn/opc1 CRm/opc2 */
if (CoProc == 10 || CoProc == 11)
{
if ((OPC_1 & 0xB) == 0xB && BITS(instr, 4, 7) == 0)
{
unsigned int single = BIT(instr, 8) == 0;
unsigned int d = (single ? BITS(instr, 12,15)<<1 | BIT(instr, 22) : BITS(instr, 12,15) | BIT(instr, 22)<<4);
unsigned int imm;
instr = BITS(instr, 16, 19) << 4 | BITS(instr, 0, 3); // FIXME dirty workaround to get a correct imm
if (single)
imm = BIT(instr, 7)<<31 | (BIT(instr, 6)==0)<<30 | (BIT(instr, 6) ? 0x1f : 0)<<25 | BITS(instr, 0, 5)<<19;
else
imm = BIT(instr, 7)<<31 | (BIT(instr, 6)==0)<<30 | (BIT(instr, 6) ? 0xff : 0)<<22 | BITS(instr, 0, 5)<<16;
VMOVI(state, single, d, imm);
return ARMul_DONE;
}
if ((OPC_1 & 0xB) == 0xB && CRn == 0 && (OPC_2 & 0x6) == 0x2)
{
unsigned int single = BIT(instr, 8) == 0;
unsigned int d = (single ? BITS(instr, 12,15)<<1 | BIT(instr, 22) : BITS(instr, 12,15) | BIT(instr, 22)<<4);
unsigned int m = (single ? BITS(instr, 0, 3)<<1 | BIT(instr, 5) : BITS(instr, 0, 3) | BIT(instr, 5)<<4);
VMOVR(state, single, d, m);
return ARMul_DONE;
}
int exceptions = 0;
if (CoProc == 10)
exceptions = vfp_single_cpdo(state, instr, state->VFP[VFP_FPSCR]);
else
exceptions = vfp_double_cpdo(state, instr, state->VFP[VFP_FPSCR]);
vfp_raise_exceptions(state, exceptions, instr, state->VFP[VFP_FPSCR]);
return ARMul_DONE;
}
LOG_WARNING(Core_ARM11, "Can't identify %x\n", instr);
return ARMul_CANT;
}
/* ----------- MRC ------------ */
void VMOVBRS(ARMul_State* state, ARMword to_arm, ARMword t, ARMword n, ARMword* value)
{
if (to_arm)
@ -338,43 +60,7 @@ void VMOVBRS(ARMul_State* state, ARMword to_arm, ARMword t, ARMword n, ARMword*
state->ExtReg[n] = *value;
}
}
void VMRS(ARMul_State* state, ARMword reg, ARMword Rt, ARMword* value)
{
if (reg == 1)
{
if (Rt != 15)
{
*value = state->VFP[VFP_FPSCR];
}
else
{
*value = state->VFP[VFP_FPSCR] ;
}
}
else
{
switch (reg)
{
case 0:
*value = state->VFP[VFP_FPSID];
break;
case 6:
/* MVFR1, VFPv3 only ? */
LOG_TRACE(Core_ARM11, "\tr%d <= MVFR1 unimplemented\n", Rt);
break;
case 7:
/* MVFR0, VFPv3 only? */
LOG_TRACE(Core_ARM11, "\tr%d <= MVFR0 unimplemented\n", Rt);
break;
case 8:
*value = state->VFP[VFP_FPEXC];
break;
default:
LOG_TRACE(Core_ARM11, "\tSUBARCHITECTURE DEFINED\n");
break;
}
}
}
void VMOVBRRD(ARMul_State* state, ARMword to_arm, ARMword t, ARMword t2, ARMword n, ARMword* value1, ARMword* value2)
{
if (to_arm)
@ -402,301 +88,6 @@ void VMOVBRRSS(ARMul_State* state, ARMword to_arm, ARMword t, ARMword t2, ARMwor
}
}
/* ----------- MCR ------------ */
void VMSR(ARMul_State* state, ARMword reg, ARMword Rt)
{
if (reg == 1)
{
state->VFP[VFP_FPSCR] = state->Reg[Rt];
}
else if (reg == 8)
{
state->VFP[VFP_FPEXC] = state->Reg[Rt];
}
}
/* Memory operation are not inlined, as old Interpreter and Fast interpreter
don't have the same memory operation interface.
Old interpreter framework does one access to coprocessor per data, and
handles already data write, as well as address computation,
which is not the case for Fast interpreter. Therefore, implementation
of vfp instructions in old interpreter and fast interpreter are separate. */
/* ----------- STC ------------ */
int VSTR(ARMul_State* state, int type, ARMword instr, ARMword* value)
{
static int i = 0;
static int single_reg, add, d, n, imm32, regs;
if (type == ARMul_FIRST)
{
single_reg = BIT(instr, 8) == 0; // Double precision
add = BIT(instr, 23);
imm32 = BITS(instr, 0,7)<<2; // may not be used
d = single_reg ? BITS(instr, 12, 15)<<1|BIT(instr, 22) : BIT(instr, 22)<<4|BITS(instr, 12, 15); /* Base register */
n = BITS(instr, 16, 19); // destination register
i = 0;
regs = 1;
return ARMul_DONE;
}
else if (type == ARMul_DATA)
{
if (single_reg)
{
*value = state->ExtReg[d+i];
i++;
if (i < regs)
return ARMul_INC;
else
return ARMul_DONE;
}
else
{
/* FIXME Careful of endianness, may need to rework this */
*value = state->ExtReg[d*2+i];
i++;
if (i < regs*2)
return ARMul_INC;
else
return ARMul_DONE;
}
}
return -1;
}
int VPUSH(ARMul_State* state, int type, ARMword instr, ARMword* value)
{
static int i = 0;
static int single_regs, d, imm32, regs;
if (type == ARMul_FIRST)
{
single_regs = BIT(instr, 8) == 0; // Single precision
d = single_regs ? BITS(instr, 12, 15)<<1|BIT(instr, 22) : BIT(instr, 22)<<4|BITS(instr, 12, 15); // Base register
imm32 = BITS(instr, 0,7)<<2; // may not be used
regs = single_regs ? BITS(instr, 0, 7) : BITS(instr, 1, 7); // FSTMX if regs is odd
state->Reg[R13] = state->Reg[R13] - imm32;
i = 0;
return ARMul_DONE;
}
else if (type == ARMul_DATA)
{
if (single_regs)
{
*value = state->ExtReg[d + i];
i++;
if (i < regs)
return ARMul_INC;
else
return ARMul_DONE;
}
else
{
/* FIXME Careful of endianness, may need to rework this */
*value = state->ExtReg[d*2 + i];
i++;
if (i < regs*2)
return ARMul_INC;
else
return ARMul_DONE;
}
}
return -1;
}
int VSTM(ARMul_State* state, int type, ARMword instr, ARMword* value)
{
static int i = 0;
static int single_regs, add, wback, d, n, imm32, regs;
if (type == ARMul_FIRST)
{
single_regs = BIT(instr, 8) == 0; // Single precision
add = BIT(instr, 23);
wback = BIT(instr, 21); // write-back
d = single_regs ? BITS(instr, 12, 15)<<1|BIT(instr, 22) : BIT(instr, 22)<<4|BITS(instr, 12, 15); // Base register
n = BITS(instr, 16, 19); // destination register
imm32 = BITS(instr, 0,7) * 4; // may not be used
regs = single_regs ? BITS(instr, 0, 7) : BITS(instr, 0, 7)>>1; // FSTMX if regs is odd
if (wback) {
state->Reg[n] = (add ? state->Reg[n] + imm32 : state->Reg[n] - imm32);
}
i = 0;
return ARMul_DONE;
}
else if (type == ARMul_DATA)
{
if (single_regs)
{
*value = state->ExtReg[d + i];
i++;
if (i < regs)
return ARMul_INC;
else
return ARMul_DONE;
}
else
{
/* FIXME Careful of endianness, may need to rework this */
*value = state->ExtReg[d*2 + i];
i++;
if (i < regs*2)
return ARMul_INC;
else
return ARMul_DONE;
}
}
return -1;
}
/* ----------- LDC ------------ */
int VPOP(ARMul_State* state, int type, ARMword instr, ARMword value)
{
static int i = 0;
static int single_regs, d, imm32, regs;
if (type == ARMul_FIRST)
{
single_regs = BIT(instr, 8) == 0; // Single precision
d = single_regs ? BITS(instr, 12, 15)<<1|BIT(instr, 22) : BIT(instr, 22)<<4|BITS(instr, 12, 15); // Base register
imm32 = BITS(instr, 0, 7)<<2; // may not be used
regs = single_regs ? BITS(instr, 0, 7) : BITS(instr, 1, 7); // FLDMX if regs is odd
state->Reg[R13] = state->Reg[R13] + imm32;
i = 0;
return ARMul_DONE;
}
else if (type == ARMul_TRANSFER)
{
return ARMul_DONE;
}
else if (type == ARMul_DATA)
{
if (single_regs)
{
state->ExtReg[d + i] = value;
i++;
if (i < regs)
return ARMul_INC;
else
return ARMul_DONE;
}
else
{
/* FIXME Careful of endianness, may need to rework this */
state->ExtReg[d*2 + i] = value;
i++;
if (i < regs*2)
return ARMul_INC;
else
return ARMul_DONE;
}
}
return -1;
}
int VLDR(ARMul_State* state, int type, ARMword instr, ARMword value)
{
static int i = 0;
static int single_reg, add, d, n, imm32, regs;
if (type == ARMul_FIRST)
{
single_reg = BIT(instr, 8) == 0; // Double precision
add = BIT(instr, 23);
imm32 = BITS(instr, 0, 7)<<2; // may not be used
d = single_reg ? BITS(instr, 12, 15)<<1|BIT(instr, 22) : BIT(instr, 22)<<4|BITS(instr, 12, 15); // Base register
n = BITS(instr, 16, 19); // destination register
i = 0;
regs = 1;
return ARMul_DONE;
}
else if (type == ARMul_TRANSFER)
{
return ARMul_DONE;
}
else if (type == ARMul_DATA)
{
if (single_reg)
{
state->ExtReg[d+i] = value;
i++;
if (i < regs)
return ARMul_INC;
else
return ARMul_DONE;
}
else
{
/* FIXME Careful of endianness, may need to rework this */
state->ExtReg[d*2+i] = value;
i++;
if (i < regs*2)
return ARMul_INC;
else
return ARMul_DONE;
}
}
return -1;
}
int VLDM(ARMul_State* state, int type, ARMword instr, ARMword value)
{
static int i = 0;
static int single_regs, add, wback, d, n, imm32, regs;
if (type == ARMul_FIRST)
{
single_regs = BIT(instr, 8) == 0; // Single precision
add = BIT(instr, 23);
wback = BIT(instr, 21); // write-back
d = single_regs ? BITS(instr, 12, 15)<<1|BIT(instr, 22) : BIT(instr, 22)<<4|BITS(instr, 12, 15); // Base register
n = BITS(instr, 16, 19); // destination register
imm32 = BITS(instr, 0, 7) * 4; // may not be used
regs = single_regs ? BITS(instr, 0, 7) : BITS(instr, 0, 7)>>1; // FLDMX if regs is odd
if (wback) {
state->Reg[n] = (add ? state->Reg[n] + imm32 : state->Reg[n] - imm32);
}
i = 0;
return ARMul_DONE;
}
else if (type == ARMul_DATA)
{
if (single_regs)
{
state->ExtReg[d + i] = value;
i++;
if (i < regs)
return ARMul_INC;
else
return ARMul_DONE;
}
else
{
/* FIXME Careful of endianness, may need to rework this */
state->ExtReg[d*2 + i] = value;
i++;
if (i < regs*2)
return ARMul_INC;
else
return ARMul_DONE;
}
}
return -1;
}
/* ----------- CDP ------------ */
void VMOVI(ARMul_State* state, ARMword single, ARMword d, ARMword imm)
{
if (single)

View File

@ -28,13 +28,6 @@
#define CHECK_VFP_CDP_RET vfp_raise_exceptions(cpu, ret, inst_cream->instr, cpu->VFP[VFP_FPSCR]);
unsigned VFPInit(ARMul_State* state);
unsigned VFPMRC(ARMul_State* state, unsigned type, ARMword instr, ARMword* value);
unsigned VFPMCR(ARMul_State* state, unsigned type, ARMword instr, ARMword value);
unsigned VFPMRRC(ARMul_State* state, unsigned type, ARMword instr, ARMword* value1, ARMword* value2);
unsigned VFPMCRR(ARMul_State* state, unsigned type, ARMword instr, ARMword value1, ARMword value2);
unsigned VFPSTC(ARMul_State* state, unsigned type, ARMword instr, ARMword* value);
unsigned VFPLDC(ARMul_State* state, unsigned type, ARMword instr, ARMword value);
unsigned VFPCDP(ARMul_State* state, unsigned type, ARMword instr);
s32 vfp_get_float(ARMul_State* state, u32 reg);
void vfp_put_float(ARMul_State* state, s32 val, u32 reg);
@ -44,23 +37,10 @@ void vfp_raise_exceptions(ARMul_State* state, u32 exceptions, u32 inst, u32 fpsc
u32 vfp_single_cpdo(ARMul_State* state, u32 inst, u32 fpscr);
u32 vfp_double_cpdo(ARMul_State* state, u32 inst, u32 fpscr);
// MRC
void VMRS(ARMul_State* state, ARMword reg, ARMword Rt, ARMword* value);
void VMSR(ARMul_State* state, ARMword reg, ARMword Rt);
void VMOVBRS(ARMul_State* state, ARMword to_arm, ARMword t, ARMword n, ARMword* value);
void VMOVBRRD(ARMul_State* state, ARMword to_arm, ARMword t, ARMword t2, ARMword n, ARMword* value1, ARMword* value2);
void VMOVBRRSS(ARMul_State* state, ARMword to_arm, ARMword t, ARMword t2, ARMword n, ARMword* value1, ARMword* value2);
void VMOVI(ARMul_State* state, ARMword single, ARMword d, ARMword imm);
void VMOVR(ARMul_State* state, ARMword single, ARMword d, ARMword imm);
// MCR
void VMSR(ARMul_State* state, ARMword reg, ARMword Rt);
// STC
int VSTM(ARMul_State* state, int type, ARMword instr, ARMword* value);
int VPUSH(ARMul_State* state, int type, ARMword instr, ARMword* value);
int VSTR(ARMul_State* state, int type, ARMword instr, ARMword* value);
// LDC
int VLDM(ARMul_State* state, int type, ARMword instr, ARMword value);
int VPOP(ARMul_State* state, int type, ARMword instr, ARMword value);
int VLDR(ARMul_State* state, int type, ARMword instr, ARMword value);