qemu/tcg/ia64/tcg-target.c

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tcg: initial ia64 support A few words about design choices: * On IA64, instructions should be grouped by bundle, and dependencies between instructions declared. A first version of this code tried to schedule instructions automatically, but was very complex and too invasive for the current common TCG code (ops not ending at instruction boundaries, code retranslation breaking already generated code, etc.) It was also not very efficient, as dependencies between TCG ops is not available. Instead the option taken by the current implementation does not try to fill the bundle by scheduling instructions, but by providing ops not available as an ia64 instruction, and by offering 22-bit constant loading for most of the instructions. With both options the bundle are filled at approximately the same level. * Up to 128 registers can be affected to a function on IA64, but TCG limits this number to 64, which is actually more than enough. The register affectation is the following: - r0: used to map a constant argument with value 0 - r1: global pointer - r2, r3: internal use - r4 to r6: not used to avoid saving them - r7: env structure - r8 to r11: free for TCG (call clobbered) - r12: stack pointer - r13: thread pointer - r14 to r31: free for TCG (call clobbered) - r32: reserved (return address) - r33: reserved (PFS) - r33 to r63: free for TCG * The IA64 architecture has only 64-bit registers and no 32-bit instructions (the only exception being cmp4). Therefore 64-bit registers and instructions are used for 32-bit ops. The adopted strategy is the same as the ABI, that is the higher 32 bits are undefined. Most ops (and, or, add, shl, etc.) can directly use the 64-bit registers, while some others have to sign-extend (sar, div, etc.) or zero-extend (shr, divu, etc.) the register first. Signed-off-by: Aurelien Jarno <aurelien@aurel32.net>
2010-03-29 04:12:51 +04:00
/*
* Tiny Code Generator for QEMU
*
* Copyright (c) 2009-2010 Aurelien Jarno <aurelien@aurel32.net>
* Based on i386/tcg-target.c - Copyright (c) 2008 Fabrice Bellard
*
* Permission is hereby granted, free of charge, to any person obtaining a copy
* of this software and associated documentation files (the "Software"), to deal
* in the Software without restriction, including without limitation the rights
* to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
* copies of the Software, and to permit persons to whom the Software is
* furnished to do so, subject to the following conditions:
*
* The above copyright notice and this permission notice shall be included in
* all copies or substantial portions of the Software.
*
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
* IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
* FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL
* THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
* LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
* OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
* THE SOFTWARE.
*/
/*
* Register definitions
*/
#ifndef NDEBUG
static const char * const tcg_target_reg_names[TCG_TARGET_NB_REGS] = {
"r0", "r1", "r2", "r3", "r4", "r5", "r6", "r7",
"r8", "r9", "r10", "r11", "r12", "r13", "r14", "r15",
"r16", "r17", "r18", "r19", "r20", "r21", "r22", "r23",
"r24", "r25", "r26", "r27", "r28", "r29", "r30", "r31",
"r32", "r33", "r34", "r35", "r36", "r37", "r38", "r39",
"r40", "r41", "r42", "r43", "r44", "r45", "r46", "r47",
"r48", "r49", "r50", "r51", "r52", "r53", "r54", "r55",
"r56", "r57", "r58", "r59", "r60", "r61", "r62", "r63",
};
#endif
#ifdef CONFIG_USE_GUEST_BASE
#define TCG_GUEST_BASE_REG TCG_REG_R55
#else
#define TCG_GUEST_BASE_REG TCG_REG_R0
#endif
#ifndef GUEST_BASE
#define GUEST_BASE 0
#endif
tcg: initial ia64 support A few words about design choices: * On IA64, instructions should be grouped by bundle, and dependencies between instructions declared. A first version of this code tried to schedule instructions automatically, but was very complex and too invasive for the current common TCG code (ops not ending at instruction boundaries, code retranslation breaking already generated code, etc.) It was also not very efficient, as dependencies between TCG ops is not available. Instead the option taken by the current implementation does not try to fill the bundle by scheduling instructions, but by providing ops not available as an ia64 instruction, and by offering 22-bit constant loading for most of the instructions. With both options the bundle are filled at approximately the same level. * Up to 128 registers can be affected to a function on IA64, but TCG limits this number to 64, which is actually more than enough. The register affectation is the following: - r0: used to map a constant argument with value 0 - r1: global pointer - r2, r3: internal use - r4 to r6: not used to avoid saving them - r7: env structure - r8 to r11: free for TCG (call clobbered) - r12: stack pointer - r13: thread pointer - r14 to r31: free for TCG (call clobbered) - r32: reserved (return address) - r33: reserved (PFS) - r33 to r63: free for TCG * The IA64 architecture has only 64-bit registers and no 32-bit instructions (the only exception being cmp4). Therefore 64-bit registers and instructions are used for 32-bit ops. The adopted strategy is the same as the ABI, that is the higher 32 bits are undefined. Most ops (and, or, add, shl, etc.) can directly use the 64-bit registers, while some others have to sign-extend (sar, div, etc.) or zero-extend (shr, divu, etc.) the register first. Signed-off-by: Aurelien Jarno <aurelien@aurel32.net>
2010-03-29 04:12:51 +04:00
/* Branch registers */
enum {
TCG_REG_B0 = 0,
TCG_REG_B1,
TCG_REG_B2,
TCG_REG_B3,
TCG_REG_B4,
TCG_REG_B5,
TCG_REG_B6,
TCG_REG_B7,
};
/* Floating point registers */
enum {
TCG_REG_F0 = 0,
TCG_REG_F1,
TCG_REG_F2,
TCG_REG_F3,
TCG_REG_F4,
TCG_REG_F5,
TCG_REG_F6,
TCG_REG_F7,
TCG_REG_F8,
TCG_REG_F9,
TCG_REG_F10,
TCG_REG_F11,
TCG_REG_F12,
TCG_REG_F13,
TCG_REG_F14,
TCG_REG_F15,
};
/* Predicate registers */
enum {
TCG_REG_P0 = 0,
TCG_REG_P1,
TCG_REG_P2,
TCG_REG_P3,
TCG_REG_P4,
TCG_REG_P5,
TCG_REG_P6,
TCG_REG_P7,
TCG_REG_P8,
TCG_REG_P9,
TCG_REG_P10,
TCG_REG_P11,
TCG_REG_P12,
TCG_REG_P13,
TCG_REG_P14,
TCG_REG_P15,
};
/* Application registers */
enum {
TCG_REG_PFS = 64,
};
static const int tcg_target_reg_alloc_order[] = {
TCG_REG_R33,
tcg: initial ia64 support A few words about design choices: * On IA64, instructions should be grouped by bundle, and dependencies between instructions declared. A first version of this code tried to schedule instructions automatically, but was very complex and too invasive for the current common TCG code (ops not ending at instruction boundaries, code retranslation breaking already generated code, etc.) It was also not very efficient, as dependencies between TCG ops is not available. Instead the option taken by the current implementation does not try to fill the bundle by scheduling instructions, but by providing ops not available as an ia64 instruction, and by offering 22-bit constant loading for most of the instructions. With both options the bundle are filled at approximately the same level. * Up to 128 registers can be affected to a function on IA64, but TCG limits this number to 64, which is actually more than enough. The register affectation is the following: - r0: used to map a constant argument with value 0 - r1: global pointer - r2, r3: internal use - r4 to r6: not used to avoid saving them - r7: env structure - r8 to r11: free for TCG (call clobbered) - r12: stack pointer - r13: thread pointer - r14 to r31: free for TCG (call clobbered) - r32: reserved (return address) - r33: reserved (PFS) - r33 to r63: free for TCG * The IA64 architecture has only 64-bit registers and no 32-bit instructions (the only exception being cmp4). Therefore 64-bit registers and instructions are used for 32-bit ops. The adopted strategy is the same as the ABI, that is the higher 32 bits are undefined. Most ops (and, or, add, shl, etc.) can directly use the 64-bit registers, while some others have to sign-extend (sar, div, etc.) or zero-extend (shr, divu, etc.) the register first. Signed-off-by: Aurelien Jarno <aurelien@aurel32.net>
2010-03-29 04:12:51 +04:00
TCG_REG_R35,
TCG_REG_R36,
TCG_REG_R37,
TCG_REG_R38,
TCG_REG_R39,
TCG_REG_R40,
TCG_REG_R41,
TCG_REG_R42,
TCG_REG_R43,
TCG_REG_R44,
TCG_REG_R45,
TCG_REG_R46,
TCG_REG_R47,
TCG_REG_R48,
TCG_REG_R49,
TCG_REG_R50,
TCG_REG_R51,
TCG_REG_R52,
TCG_REG_R53,
TCG_REG_R54,
TCG_REG_R55,
TCG_REG_R14,
TCG_REG_R15,
TCG_REG_R16,
TCG_REG_R17,
TCG_REG_R18,
TCG_REG_R19,
TCG_REG_R20,
TCG_REG_R21,
TCG_REG_R22,
TCG_REG_R23,
TCG_REG_R24,
TCG_REG_R25,
TCG_REG_R26,
TCG_REG_R27,
TCG_REG_R28,
TCG_REG_R29,
TCG_REG_R30,
TCG_REG_R31,
TCG_REG_R56,
TCG_REG_R57,
TCG_REG_R58,
TCG_REG_R59,
TCG_REG_R60,
TCG_REG_R61,
TCG_REG_R62,
TCG_REG_R63,
TCG_REG_R8,
TCG_REG_R9,
TCG_REG_R10,
TCG_REG_R11
};
static const int tcg_target_call_iarg_regs[8] = {
TCG_REG_R56,
TCG_REG_R57,
TCG_REG_R58,
TCG_REG_R59,
TCG_REG_R60,
TCG_REG_R61,
TCG_REG_R62,
TCG_REG_R63,
};
static const int tcg_target_call_oarg_regs[] = {
TCG_REG_R8
tcg: initial ia64 support A few words about design choices: * On IA64, instructions should be grouped by bundle, and dependencies between instructions declared. A first version of this code tried to schedule instructions automatically, but was very complex and too invasive for the current common TCG code (ops not ending at instruction boundaries, code retranslation breaking already generated code, etc.) It was also not very efficient, as dependencies between TCG ops is not available. Instead the option taken by the current implementation does not try to fill the bundle by scheduling instructions, but by providing ops not available as an ia64 instruction, and by offering 22-bit constant loading for most of the instructions. With both options the bundle are filled at approximately the same level. * Up to 128 registers can be affected to a function on IA64, but TCG limits this number to 64, which is actually more than enough. The register affectation is the following: - r0: used to map a constant argument with value 0 - r1: global pointer - r2, r3: internal use - r4 to r6: not used to avoid saving them - r7: env structure - r8 to r11: free for TCG (call clobbered) - r12: stack pointer - r13: thread pointer - r14 to r31: free for TCG (call clobbered) - r32: reserved (return address) - r33: reserved (PFS) - r33 to r63: free for TCG * The IA64 architecture has only 64-bit registers and no 32-bit instructions (the only exception being cmp4). Therefore 64-bit registers and instructions are used for 32-bit ops. The adopted strategy is the same as the ABI, that is the higher 32 bits are undefined. Most ops (and, or, add, shl, etc.) can directly use the 64-bit registers, while some others have to sign-extend (sar, div, etc.) or zero-extend (shr, divu, etc.) the register first. Signed-off-by: Aurelien Jarno <aurelien@aurel32.net>
2010-03-29 04:12:51 +04:00
};
/*
* opcode formation
*/
/* bundle templates: stops (double bar in the IA64 manual) are marked with
an uppercase letter. */
enum {
mii = 0x00,
miI = 0x01,
mIi = 0x02,
mII = 0x03,
mlx = 0x04,
mLX = 0x05,
mmi = 0x08,
mmI = 0x09,
Mmi = 0x0a,
MmI = 0x0b,
mfi = 0x0c,
mfI = 0x0d,
mmf = 0x0e,
mmF = 0x0f,
mib = 0x10,
miB = 0x11,
mbb = 0x12,
mbB = 0x13,
bbb = 0x16,
bbB = 0x17,
mmb = 0x18,
mmB = 0x19,
mfb = 0x1c,
mfB = 0x1d,
};
enum {
OPC_ADD_A1 = 0x10000000000ull,
OPC_AND_A1 = 0x10060000000ull,
OPC_AND_A3 = 0x10160000000ull,
OPC_ANDCM_A1 = 0x10068000000ull,
OPC_ANDCM_A3 = 0x10168000000ull,
OPC_ADDS_A4 = 0x10800000000ull,
OPC_ADDL_A5 = 0x12000000000ull,
OPC_ALLOC_M34 = 0x02c00000000ull,
OPC_BR_DPTK_FEW_B1 = 0x08400000000ull,
OPC_BR_SPTK_MANY_B1 = 0x08000001000ull,
OPC_BR_SPTK_MANY_B4 = 0x00100001000ull,
OPC_BR_CALL_SPTK_MANY_B5 = 0x02100001000ull,
OPC_BR_RET_SPTK_MANY_B4 = 0x00108001100ull,
OPC_BRL_SPTK_MANY_X3 = 0x18000001000ull,
OPC_CMP_LT_A6 = 0x18000000000ull,
OPC_CMP_LTU_A6 = 0x1a000000000ull,
OPC_CMP_EQ_A6 = 0x1c000000000ull,
OPC_CMP4_LT_A6 = 0x18400000000ull,
OPC_CMP4_LTU_A6 = 0x1a400000000ull,
OPC_CMP4_EQ_A6 = 0x1c400000000ull,
OPC_DEP_I14 = 0x0ae00000000ull,
OPC_DEP_I15 = 0x08000000000ull,
tcg: initial ia64 support A few words about design choices: * On IA64, instructions should be grouped by bundle, and dependencies between instructions declared. A first version of this code tried to schedule instructions automatically, but was very complex and too invasive for the current common TCG code (ops not ending at instruction boundaries, code retranslation breaking already generated code, etc.) It was also not very efficient, as dependencies between TCG ops is not available. Instead the option taken by the current implementation does not try to fill the bundle by scheduling instructions, but by providing ops not available as an ia64 instruction, and by offering 22-bit constant loading for most of the instructions. With both options the bundle are filled at approximately the same level. * Up to 128 registers can be affected to a function on IA64, but TCG limits this number to 64, which is actually more than enough. The register affectation is the following: - r0: used to map a constant argument with value 0 - r1: global pointer - r2, r3: internal use - r4 to r6: not used to avoid saving them - r7: env structure - r8 to r11: free for TCG (call clobbered) - r12: stack pointer - r13: thread pointer - r14 to r31: free for TCG (call clobbered) - r32: reserved (return address) - r33: reserved (PFS) - r33 to r63: free for TCG * The IA64 architecture has only 64-bit registers and no 32-bit instructions (the only exception being cmp4). Therefore 64-bit registers and instructions are used for 32-bit ops. The adopted strategy is the same as the ABI, that is the higher 32 bits are undefined. Most ops (and, or, add, shl, etc.) can directly use the 64-bit registers, while some others have to sign-extend (sar, div, etc.) or zero-extend (shr, divu, etc.) the register first. Signed-off-by: Aurelien Jarno <aurelien@aurel32.net>
2010-03-29 04:12:51 +04:00
OPC_DEP_Z_I12 = 0x0a600000000ull,
OPC_EXTR_I11 = 0x0a400002000ull,
OPC_EXTR_U_I11 = 0x0a400000000ull,
OPC_FCVT_FX_TRUNC_S1_F10 = 0x004d0000000ull,
OPC_FCVT_FXU_TRUNC_S1_F10 = 0x004d8000000ull,
OPC_FCVT_XF_F11 = 0x000e0000000ull,
OPC_FMA_S1_F1 = 0x10400000000ull,
OPC_FNMA_S1_F1 = 0x18400000000ull,
OPC_FRCPA_S1_F6 = 0x00600000000ull,
OPC_GETF_SIG_M19 = 0x08708000000ull,
OPC_LD1_M1 = 0x08000000000ull,
OPC_LD1_M3 = 0x0a000000000ull,
OPC_LD2_M1 = 0x08040000000ull,
OPC_LD2_M3 = 0x0a040000000ull,
OPC_LD4_M1 = 0x08080000000ull,
OPC_LD4_M3 = 0x0a080000000ull,
OPC_LD8_M1 = 0x080c0000000ull,
OPC_LD8_M3 = 0x0a0c0000000ull,
OPC_MUX1_I3 = 0x0eca0000000ull,
OPC_NOP_B9 = 0x04008000000ull,
OPC_NOP_F16 = 0x00008000000ull,
OPC_NOP_I18 = 0x00008000000ull,
OPC_NOP_M48 = 0x00008000000ull,
OPC_MOV_I21 = 0x00e00100000ull,
OPC_MOV_RET_I21 = 0x00e00500000ull,
OPC_MOV_I22 = 0x00188000000ull,
OPC_MOV_I_I26 = 0x00150000000ull,
OPC_MOVL_X2 = 0x0c000000000ull,
OPC_OR_A1 = 0x10070000000ull,
OPC_SETF_EXP_M18 = 0x0c748000000ull,
OPC_SETF_SIG_M18 = 0x0c708000000ull,
OPC_SHL_I7 = 0x0f240000000ull,
OPC_SHR_I5 = 0x0f220000000ull,
OPC_SHR_U_I5 = 0x0f200000000ull,
OPC_SHRP_I10 = 0x0ac00000000ull,
OPC_SXT1_I29 = 0x000a0000000ull,
OPC_SXT2_I29 = 0x000a8000000ull,
OPC_SXT4_I29 = 0x000b0000000ull,
OPC_ST1_M4 = 0x08c00000000ull,
OPC_ST2_M4 = 0x08c40000000ull,
OPC_ST4_M4 = 0x08c80000000ull,
OPC_ST8_M4 = 0x08cc0000000ull,
OPC_SUB_A1 = 0x10028000000ull,
OPC_SUB_A3 = 0x10128000000ull,
OPC_UNPACK4_L_I2 = 0x0f860000000ull,
OPC_XMA_L_F2 = 0x1d000000000ull,
OPC_XOR_A1 = 0x10078000000ull,
OPC_ZXT1_I29 = 0x00080000000ull,
OPC_ZXT2_I29 = 0x00088000000ull,
OPC_ZXT4_I29 = 0x00090000000ull,
};
static inline uint64_t tcg_opc_a1(int qp, uint64_t opc, int r1,
int r2, int r3)
{
return opc
| ((r3 & 0x7f) << 20)
| ((r2 & 0x7f) << 13)
| ((r1 & 0x7f) << 6)
| (qp & 0x3f);
}
static inline uint64_t tcg_opc_a3(int qp, uint64_t opc, int r1,
uint64_t imm, int r3)
{
return opc
| ((imm & 0x80) << 29) /* s */
| ((imm & 0x7f) << 13) /* imm7b */
| ((r3 & 0x7f) << 20)
| ((r1 & 0x7f) << 6)
| (qp & 0x3f);
}
static inline uint64_t tcg_opc_a4(int qp, uint64_t opc, int r1,
uint64_t imm, int r3)
{
return opc
| ((imm & 0x2000) << 23) /* s */
| ((imm & 0x1f80) << 20) /* imm6d */
| ((imm & 0x007f) << 13) /* imm7b */
| ((r3 & 0x7f) << 20)
| ((r1 & 0x7f) << 6)
| (qp & 0x3f);
}
static inline uint64_t tcg_opc_a5(int qp, uint64_t opc, int r1,
uint64_t imm, int r3)
{
return opc
| ((imm & 0x200000) << 15) /* s */
| ((imm & 0x1f0000) << 6) /* imm5c */
| ((imm & 0x00ff80) << 20) /* imm9d */
| ((imm & 0x00007f) << 13) /* imm7b */
| ((r3 & 0x03) << 20)
| ((r1 & 0x7f) << 6)
| (qp & 0x3f);
}
static inline uint64_t tcg_opc_a6(int qp, uint64_t opc, int p1,
int p2, int r2, int r3)
{
return opc
| ((p2 & 0x3f) << 27)
| ((r3 & 0x7f) << 20)
| ((r2 & 0x7f) << 13)
| ((p1 & 0x3f) << 6)
| (qp & 0x3f);
}
static inline uint64_t tcg_opc_b1(int qp, uint64_t opc, uint64_t imm)
{
return opc
| ((imm & 0x100000) << 16) /* s */
| ((imm & 0x0fffff) << 13) /* imm20b */
| (qp & 0x3f);
}
static inline uint64_t tcg_opc_b4(int qp, uint64_t opc, int b2)
{
return opc
| ((b2 & 0x7) << 13)
| (qp & 0x3f);
}
static inline uint64_t tcg_opc_b5(int qp, uint64_t opc, int b1, int b2)
{
return opc
| ((b2 & 0x7) << 13)
| ((b1 & 0x7) << 6)
| (qp & 0x3f);
}
static inline uint64_t tcg_opc_b9(int qp, uint64_t opc, uint64_t imm)
{
return opc
| ((imm & 0x100000) << 16) /* i */
| ((imm & 0x0fffff) << 6) /* imm20a */
| (qp & 0x3f);
}
static inline uint64_t tcg_opc_f1(int qp, uint64_t opc, int f1,
int f3, int f4, int f2)
{
return opc
| ((f4 & 0x7f) << 27)
| ((f3 & 0x7f) << 20)
| ((f2 & 0x7f) << 13)
| ((f1 & 0x7f) << 6)
| (qp & 0x3f);
}
static inline uint64_t tcg_opc_f2(int qp, uint64_t opc, int f1,
int f3, int f4, int f2)
{
return opc
| ((f4 & 0x7f) << 27)
| ((f3 & 0x7f) << 20)
| ((f2 & 0x7f) << 13)
| ((f1 & 0x7f) << 6)
| (qp & 0x3f);
}
static inline uint64_t tcg_opc_f6(int qp, uint64_t opc, int f1,
int p2, int f2, int f3)
{
return opc
| ((p2 & 0x3f) << 27)
| ((f3 & 0x7f) << 20)
| ((f2 & 0x7f) << 13)
| ((f1 & 0x7f) << 6)
| (qp & 0x3f);
}
static inline uint64_t tcg_opc_f10(int qp, uint64_t opc, int f1, int f2)
{
return opc
| ((f2 & 0x7f) << 13)
| ((f1 & 0x7f) << 6)
| (qp & 0x3f);
}
static inline uint64_t tcg_opc_f11(int qp, uint64_t opc, int f1, int f2)
{
return opc
| ((f2 & 0x7f) << 13)
| ((f1 & 0x7f) << 6)
| (qp & 0x3f);
}
static inline uint64_t tcg_opc_f16(int qp, uint64_t opc, uint64_t imm)
{
return opc
| ((imm & 0x100000) << 16) /* i */
| ((imm & 0x0fffff) << 6) /* imm20a */
| (qp & 0x3f);
}
static inline uint64_t tcg_opc_i2(int qp, uint64_t opc, int r1,
int r2, int r3)
{
return opc
| ((r3 & 0x7f) << 20)
| ((r2 & 0x7f) << 13)
| ((r1 & 0x7f) << 6)
| (qp & 0x3f);
}
static inline uint64_t tcg_opc_i3(int qp, uint64_t opc, int r1,
int r2, int mbtype)
{
return opc
| ((mbtype & 0x0f) << 20)
| ((r2 & 0x7f) << 13)
| ((r1 & 0x7f) << 6)
| (qp & 0x3f);
}
static inline uint64_t tcg_opc_i5(int qp, uint64_t opc, int r1,
int r3, int r2)
{
return opc
| ((r3 & 0x7f) << 20)
| ((r2 & 0x7f) << 13)
| ((r1 & 0x7f) << 6)
| (qp & 0x3f);
}
static inline uint64_t tcg_opc_i7(int qp, uint64_t opc, int r1,
int r2, int r3)
{
return opc
| ((r3 & 0x7f) << 20)
| ((r2 & 0x7f) << 13)
| ((r1 & 0x7f) << 6)
| (qp & 0x3f);
}
static inline uint64_t tcg_opc_i10(int qp, uint64_t opc, int r1,
int r2, int r3, uint64_t count)
{
return opc
| ((count & 0x3f) << 27)
| ((r3 & 0x7f) << 20)
| ((r2 & 0x7f) << 13)
| ((r1 & 0x7f) << 6)
| (qp & 0x3f);
}
static inline uint64_t tcg_opc_i11(int qp, uint64_t opc, int r1,
int r3, uint64_t pos, uint64_t len)
{
return opc
| ((len & 0x3f) << 27)
| ((r3 & 0x7f) << 20)
| ((pos & 0x3f) << 14)
| ((r1 & 0x7f) << 6)
| (qp & 0x3f);
}
static inline uint64_t tcg_opc_i12(int qp, uint64_t opc, int r1,
int r2, uint64_t pos, uint64_t len)
{
return opc
| ((len & 0x3f) << 27)
| ((pos & 0x3f) << 20)
| ((r2 & 0x7f) << 13)
| ((r1 & 0x7f) << 6)
| (qp & 0x3f);
}
static inline uint64_t tcg_opc_i14(int qp, uint64_t opc, int r1, uint64_t imm,
int r3, uint64_t pos, uint64_t len)
{
return opc
| ((imm & 0x01) << 36)
| ((len & 0x3f) << 27)
| ((r3 & 0x7f) << 20)
| ((pos & 0x3f) << 14)
| ((r1 & 0x7f) << 6)
| (qp & 0x3f);
}
static inline uint64_t tcg_opc_i15(int qp, uint64_t opc, int r1, int r2,
int r3, uint64_t pos, uint64_t len)
{
return opc
| ((pos & 0x3f) << 31)
| ((len & 0x0f) << 27)
| ((r3 & 0x7f) << 20)
| ((r2 & 0x7f) << 13)
| ((r1 & 0x7f) << 6)
| (qp & 0x3f);
}
tcg: initial ia64 support A few words about design choices: * On IA64, instructions should be grouped by bundle, and dependencies between instructions declared. A first version of this code tried to schedule instructions automatically, but was very complex and too invasive for the current common TCG code (ops not ending at instruction boundaries, code retranslation breaking already generated code, etc.) It was also not very efficient, as dependencies between TCG ops is not available. Instead the option taken by the current implementation does not try to fill the bundle by scheduling instructions, but by providing ops not available as an ia64 instruction, and by offering 22-bit constant loading for most of the instructions. With both options the bundle are filled at approximately the same level. * Up to 128 registers can be affected to a function on IA64, but TCG limits this number to 64, which is actually more than enough. The register affectation is the following: - r0: used to map a constant argument with value 0 - r1: global pointer - r2, r3: internal use - r4 to r6: not used to avoid saving them - r7: env structure - r8 to r11: free for TCG (call clobbered) - r12: stack pointer - r13: thread pointer - r14 to r31: free for TCG (call clobbered) - r32: reserved (return address) - r33: reserved (PFS) - r33 to r63: free for TCG * The IA64 architecture has only 64-bit registers and no 32-bit instructions (the only exception being cmp4). Therefore 64-bit registers and instructions are used for 32-bit ops. The adopted strategy is the same as the ABI, that is the higher 32 bits are undefined. Most ops (and, or, add, shl, etc.) can directly use the 64-bit registers, while some others have to sign-extend (sar, div, etc.) or zero-extend (shr, divu, etc.) the register first. Signed-off-by: Aurelien Jarno <aurelien@aurel32.net>
2010-03-29 04:12:51 +04:00
static inline uint64_t tcg_opc_i18(int qp, uint64_t opc, uint64_t imm)
{
return opc
| ((imm & 0x100000) << 16) /* i */
| ((imm & 0x0fffff) << 6) /* imm20a */
| (qp & 0x3f);
}
static inline uint64_t tcg_opc_i21(int qp, uint64_t opc, int b1,
int r2, uint64_t imm)
{
return opc
| ((imm & 0x1ff) << 24)
| ((r2 & 0x7f) << 13)
| ((b1 & 0x7) << 6)
| (qp & 0x3f);
}
static inline uint64_t tcg_opc_i22(int qp, uint64_t opc, int r1, int b2)
{
return opc
| ((b2 & 0x7) << 13)
| ((r1 & 0x7f) << 6)
| (qp & 0x3f);
}
static inline uint64_t tcg_opc_i26(int qp, uint64_t opc, int ar3, int r2)
{
return opc
| ((ar3 & 0x7f) << 20)
| ((r2 & 0x7f) << 13)
| (qp & 0x3f);
}
static inline uint64_t tcg_opc_i29(int qp, uint64_t opc, int r1, int r3)
{
return opc
| ((r3 & 0x7f) << 20)
| ((r1 & 0x7f) << 6)
| (qp & 0x3f);
}
static inline uint64_t tcg_opc_l2(uint64_t imm)
{
return (imm & 0x7fffffffffc00000ull) >> 22;
}
static inline uint64_t tcg_opc_l3(uint64_t imm)
{
return (imm & 0x07fffffffff00000ull) >> 18;
}
static inline uint64_t tcg_opc_m1(int qp, uint64_t opc, int r1, int r3)
{
return opc
| ((r3 & 0x7f) << 20)
| ((r1 & 0x7f) << 6)
| (qp & 0x3f);
}
static inline uint64_t tcg_opc_m3(int qp, uint64_t opc, int r1,
int r3, uint64_t imm)
{
return opc
| ((imm & 0x100) << 28) /* s */
| ((imm & 0x080) << 20) /* i */
| ((imm & 0x07f) << 13) /* imm7b */
| ((r3 & 0x7f) << 20)
| ((r1 & 0x7f) << 6)
| (qp & 0x3f);
}
static inline uint64_t tcg_opc_m4(int qp, uint64_t opc, int r2, int r3)
{
return opc
| ((r3 & 0x7f) << 20)
| ((r2 & 0x7f) << 13)
| (qp & 0x3f);
}
static inline uint64_t tcg_opc_m18(int qp, uint64_t opc, int f1, int r2)
{
return opc
| ((r2 & 0x7f) << 13)
| ((f1 & 0x7f) << 6)
| (qp & 0x3f);
}
static inline uint64_t tcg_opc_m19(int qp, uint64_t opc, int r1, int f2)
{
return opc
| ((f2 & 0x7f) << 13)
| ((r1 & 0x7f) << 6)
| (qp & 0x3f);
}
static inline uint64_t tcg_opc_m34(int qp, uint64_t opc, int r1,
int sof, int sol, int sor)
{
return opc
| ((sor & 0x0f) << 27)
| ((sol & 0x7f) << 20)
| ((sof & 0x7f) << 13)
| ((r1 & 0x7f) << 6)
| (qp & 0x3f);
}
static inline uint64_t tcg_opc_m48(int qp, uint64_t opc, uint64_t imm)
{
return opc
| ((imm & 0x100000) << 16) /* i */
| ((imm & 0x0fffff) << 6) /* imm20a */
| (qp & 0x3f);
}
static inline uint64_t tcg_opc_x2(int qp, uint64_t opc,
int r1, uint64_t imm)
{
return opc
| ((imm & 0x8000000000000000ull) >> 27) /* i */
| (imm & 0x0000000000200000ull) /* ic */
| ((imm & 0x00000000001f0000ull) << 6) /* imm5c */
| ((imm & 0x000000000000ff80ull) << 20) /* imm9d */
| ((imm & 0x000000000000007full) << 13) /* imm7b */
| ((r1 & 0x7f) << 6)
| (qp & 0x3f);
}
static inline uint64_t tcg_opc_x3(int qp, uint64_t opc, uint64_t imm)
{
return opc
| ((imm & 0x0800000000000000ull) >> 23) /* i */
| ((imm & 0x00000000000fffffull) << 13) /* imm20b */
| (qp & 0x3f);
}
/*
* Relocations
*/
static inline void reloc_pcrel21b (void *pc, tcg_target_long target)
{
uint64_t imm;
int64_t disp;
int slot;
slot = (tcg_target_long) pc & 3;
pc = (void *)((tcg_target_long) pc & ~3);
disp = target - (tcg_target_long) pc;
imm = (uint64_t) disp >> 4;
switch(slot) {
case 0:
*(uint64_t *)(pc + 0) = (*(uint64_t *)(pc + 8) & 0xfffffdc00003ffffull)
| ((imm & 0x100000) << 21) /* s */
| ((imm & 0x0fffff) << 18); /* imm20b */
break;
case 1:
*(uint64_t *)(pc + 8) = (*(uint64_t *)(pc + 8) & 0xfffffffffffb8000ull)
| ((imm & 0x100000) >> 2) /* s */
| ((imm & 0x0fffe0) >> 5); /* imm20b */
*(uint64_t *)(pc + 0) = (*(uint64_t *)(pc + 0) & 0x07ffffffffffffffull)
| ((imm & 0x00001f) << 59); /* imm20b */
break;
case 2:
*(uint64_t *)(pc + 8) = (*(uint64_t *)(pc + 8) & 0xf700000fffffffffull)
| ((imm & 0x100000) << 39) /* s */
| ((imm & 0x0fffff) << 36); /* imm20b */
break;
}
}
static inline uint64_t get_reloc_pcrel21b (void *pc)
{
int64_t low, high;
int slot;
slot = (tcg_target_long) pc & 3;
pc = (void *)((tcg_target_long) pc & ~3);
low = (*(uint64_t *)(pc + 0));
high = (*(uint64_t *)(pc + 8));
switch(slot) {
case 0:
return ((low >> 21) & 0x100000) + /* s */
((low >> 18) & 0x0fffff); /* imm20b */
case 1:
return ((high << 2) & 0x100000) + /* s */
((high << 5) & 0x0fffe0) + /* imm20b */
((low >> 59) & 0x00001f); /* imm20b */
case 2:
return ((high >> 39) & 0x100000) + /* s */
((high >> 36) & 0x0fffff); /* imm20b */
default:
tcg_abort();
}
}
static inline void reloc_pcrel60b (void *pc, tcg_target_long target)
{
int64_t disp;
uint64_t imm;
disp = target - (tcg_target_long) pc;
imm = (uint64_t) disp >> 4;
*(uint64_t *)(pc + 8) = (*(uint64_t *)(pc + 8) & 0xf700000fff800000ull)
| (imm & 0x0800000000000000ull) /* s */
| ((imm & 0x07fffff000000000ull) >> 36) /* imm39 */
| ((imm & 0x00000000000fffffull) << 36); /* imm20b */
*(uint64_t *)(pc + 0) = (*(uint64_t *)(pc + 0) & 0x00003fffffffffffull)
| ((imm & 0x0000000ffff00000ull) << 28); /* imm39 */
}
static inline uint64_t get_reloc_pcrel60b (void *pc)
{
int64_t low, high;
low = (*(uint64_t *)(pc + 0));
high = (*(uint64_t *)(pc + 8));
return ((high) & 0x0800000000000000ull) + /* s */
((high >> 36) & 0x00000000000fffffull) + /* imm20b */
((high << 36) & 0x07fffff000000000ull) + /* imm39 */
((low >> 28) & 0x0000000ffff00000ull); /* imm39 */
}
static void patch_reloc(uint8_t *code_ptr, int type,
tcg_target_long value, tcg_target_long addend)
{
value += addend;
switch (type) {
case R_IA64_PCREL21B:
reloc_pcrel21b(code_ptr, value);
break;
case R_IA64_PCREL60B:
reloc_pcrel60b(code_ptr, value);
default:
tcg_abort();
}
}
/*
* Constraints
*/
/* parse target specific constraints */
static int target_parse_constraint(TCGArgConstraint *ct, const char **pct_str)
{
const char *ct_str;
ct_str = *pct_str;
switch(ct_str[0]) {
case 'r':
ct->ct |= TCG_CT_REG;
tcg_regset_set(ct->u.regs, 0xffffffffffffffffull);
break;
case 'I':
ct->ct |= TCG_CT_CONST_S22;
break;
case 'S':
ct->ct |= TCG_CT_REG;
tcg_regset_set(ct->u.regs, 0xffffffffffffffffull);
#if defined(CONFIG_SOFTMMU)
tcg_regset_reset_reg(ct->u.regs, TCG_REG_R56);
tcg_regset_reset_reg(ct->u.regs, TCG_REG_R57);
#endif
break;
case 'Z':
/* We are cheating a bit here, using the fact that the register
r0 is also the register number 0. Hence there is no need
to check for const_args in each instruction. */
ct->ct |= TCG_CT_CONST_ZERO;
break;
default:
return -1;
}
ct_str++;
*pct_str = ct_str;
return 0;
}
/* test if a constant matches the constraint */
static inline int tcg_target_const_match(tcg_target_long val,
const TCGArgConstraint *arg_ct)
{
int ct;
ct = arg_ct->ct;
if (ct & TCG_CT_CONST)
return 1;
else if ((ct & TCG_CT_CONST_ZERO) && val == 0)
return 1;
else if ((ct & TCG_CT_CONST_S22) && val == ((int32_t)val << 10) >> 10)
return 1;
else
return 0;
}
/*
* Code generation
*/
static uint8_t *tb_ret_addr;
static inline void tcg_out_bundle(TCGContext *s, int template,
uint64_t slot0, uint64_t slot1,
uint64_t slot2)
{
template &= 0x1f; /* 5 bits */
slot0 &= 0x1ffffffffffull; /* 41 bits */
slot1 &= 0x1ffffffffffull; /* 41 bits */
slot2 &= 0x1ffffffffffull; /* 41 bits */
*(uint64_t *)(s->code_ptr + 0) = (slot1 << 46) | (slot0 << 5) | template;
*(uint64_t *)(s->code_ptr + 8) = (slot2 << 23) | (slot1 >> 18);
s->code_ptr += 16;
}
static inline void tcg_out_mov(TCGContext *s, TCGType type,
TCGReg ret, TCGReg arg)
tcg: initial ia64 support A few words about design choices: * On IA64, instructions should be grouped by bundle, and dependencies between instructions declared. A first version of this code tried to schedule instructions automatically, but was very complex and too invasive for the current common TCG code (ops not ending at instruction boundaries, code retranslation breaking already generated code, etc.) It was also not very efficient, as dependencies between TCG ops is not available. Instead the option taken by the current implementation does not try to fill the bundle by scheduling instructions, but by providing ops not available as an ia64 instruction, and by offering 22-bit constant loading for most of the instructions. With both options the bundle are filled at approximately the same level. * Up to 128 registers can be affected to a function on IA64, but TCG limits this number to 64, which is actually more than enough. The register affectation is the following: - r0: used to map a constant argument with value 0 - r1: global pointer - r2, r3: internal use - r4 to r6: not used to avoid saving them - r7: env structure - r8 to r11: free for TCG (call clobbered) - r12: stack pointer - r13: thread pointer - r14 to r31: free for TCG (call clobbered) - r32: reserved (return address) - r33: reserved (PFS) - r33 to r63: free for TCG * The IA64 architecture has only 64-bit registers and no 32-bit instructions (the only exception being cmp4). Therefore 64-bit registers and instructions are used for 32-bit ops. The adopted strategy is the same as the ABI, that is the higher 32 bits are undefined. Most ops (and, or, add, shl, etc.) can directly use the 64-bit registers, while some others have to sign-extend (sar, div, etc.) or zero-extend (shr, divu, etc.) the register first. Signed-off-by: Aurelien Jarno <aurelien@aurel32.net>
2010-03-29 04:12:51 +04:00
{
tcg_out_bundle(s, mmI,
tcg_opc_m48(TCG_REG_P0, OPC_NOP_M48, 0),
tcg_opc_m48(TCG_REG_P0, OPC_NOP_M48, 0),
tcg_opc_a4(TCG_REG_P0, OPC_ADDS_A4, ret, 0, arg));
}
static inline void tcg_out_movi(TCGContext *s, TCGType type,
TCGReg reg, tcg_target_long arg)
tcg: initial ia64 support A few words about design choices: * On IA64, instructions should be grouped by bundle, and dependencies between instructions declared. A first version of this code tried to schedule instructions automatically, but was very complex and too invasive for the current common TCG code (ops not ending at instruction boundaries, code retranslation breaking already generated code, etc.) It was also not very efficient, as dependencies between TCG ops is not available. Instead the option taken by the current implementation does not try to fill the bundle by scheduling instructions, but by providing ops not available as an ia64 instruction, and by offering 22-bit constant loading for most of the instructions. With both options the bundle are filled at approximately the same level. * Up to 128 registers can be affected to a function on IA64, but TCG limits this number to 64, which is actually more than enough. The register affectation is the following: - r0: used to map a constant argument with value 0 - r1: global pointer - r2, r3: internal use - r4 to r6: not used to avoid saving them - r7: env structure - r8 to r11: free for TCG (call clobbered) - r12: stack pointer - r13: thread pointer - r14 to r31: free for TCG (call clobbered) - r32: reserved (return address) - r33: reserved (PFS) - r33 to r63: free for TCG * The IA64 architecture has only 64-bit registers and no 32-bit instructions (the only exception being cmp4). Therefore 64-bit registers and instructions are used for 32-bit ops. The adopted strategy is the same as the ABI, that is the higher 32 bits are undefined. Most ops (and, or, add, shl, etc.) can directly use the 64-bit registers, while some others have to sign-extend (sar, div, etc.) or zero-extend (shr, divu, etc.) the register first. Signed-off-by: Aurelien Jarno <aurelien@aurel32.net>
2010-03-29 04:12:51 +04:00
{
tcg_out_bundle(s, mLX,
tcg_opc_m48(TCG_REG_P0, OPC_NOP_M48, 0),
tcg_opc_l2 (arg),
tcg_opc_x2 (TCG_REG_P0, OPC_MOVL_X2, reg, arg));
}
static void tcg_out_br(TCGContext *s, int label_index)
{
TCGLabel *l = &s->labels[label_index];
/* We pay attention here to not modify the branch target by reading
the existing value and using it again. This ensure that caches and
memory are kept coherent during retranslation. */
tcg: initial ia64 support A few words about design choices: * On IA64, instructions should be grouped by bundle, and dependencies between instructions declared. A first version of this code tried to schedule instructions automatically, but was very complex and too invasive for the current common TCG code (ops not ending at instruction boundaries, code retranslation breaking already generated code, etc.) It was also not very efficient, as dependencies between TCG ops is not available. Instead the option taken by the current implementation does not try to fill the bundle by scheduling instructions, but by providing ops not available as an ia64 instruction, and by offering 22-bit constant loading for most of the instructions. With both options the bundle are filled at approximately the same level. * Up to 128 registers can be affected to a function on IA64, but TCG limits this number to 64, which is actually more than enough. The register affectation is the following: - r0: used to map a constant argument with value 0 - r1: global pointer - r2, r3: internal use - r4 to r6: not used to avoid saving them - r7: env structure - r8 to r11: free for TCG (call clobbered) - r12: stack pointer - r13: thread pointer - r14 to r31: free for TCG (call clobbered) - r32: reserved (return address) - r33: reserved (PFS) - r33 to r63: free for TCG * The IA64 architecture has only 64-bit registers and no 32-bit instructions (the only exception being cmp4). Therefore 64-bit registers and instructions are used for 32-bit ops. The adopted strategy is the same as the ABI, that is the higher 32 bits are undefined. Most ops (and, or, add, shl, etc.) can directly use the 64-bit registers, while some others have to sign-extend (sar, div, etc.) or zero-extend (shr, divu, etc.) the register first. Signed-off-by: Aurelien Jarno <aurelien@aurel32.net>
2010-03-29 04:12:51 +04:00
tcg_out_bundle(s, mmB,
tcg_opc_m48(TCG_REG_P0, OPC_NOP_M48, 0),
tcg_opc_m48(TCG_REG_P0, OPC_NOP_M48, 0),
tcg_opc_b1 (TCG_REG_P0, OPC_BR_SPTK_MANY_B1,
get_reloc_pcrel21b(s->code_ptr + 2)));
if (l->has_value) {
reloc_pcrel21b((s->code_ptr - 16) + 2, l->u.value);
} else {
tcg_out_reloc(s, (s->code_ptr - 16) + 2,
R_IA64_PCREL21B, label_index, 0);
}
}
static inline void tcg_out_call(TCGContext *s, TCGArg addr)
{
tcg_out_bundle(s, MmI,
tcg_opc_m1 (TCG_REG_P0, OPC_LD8_M1, TCG_REG_R2, addr),
tcg_opc_a4 (TCG_REG_P0, OPC_ADDS_A4, TCG_REG_R3, 8, addr),
tcg_opc_i21(TCG_REG_P0, OPC_MOV_I21,
TCG_REG_B6, TCG_REG_R2, 0));
tcg_out_bundle(s, mmB,
tcg_opc_m1 (TCG_REG_P0, OPC_LD8_M1, TCG_REG_R1, TCG_REG_R3),
tcg_opc_m48(TCG_REG_P0, OPC_NOP_M48, 0),
tcg_opc_b5 (TCG_REG_P0, OPC_BR_CALL_SPTK_MANY_B5,
TCG_REG_B0, TCG_REG_B6));
}
static void tcg_out_exit_tb(TCGContext *s, tcg_target_long arg)
{
int64_t disp;
uint64_t imm;
tcg_out_movi(s, TCG_TYPE_PTR, TCG_REG_R8, arg);
disp = tb_ret_addr - s->code_ptr;
imm = (uint64_t)disp >> 4;
tcg_out_bundle(s, mLX,
tcg_opc_m48(TCG_REG_P0, OPC_NOP_M48, 0),
tcg_opc_l3 (imm),
tcg_opc_x3 (TCG_REG_P0, OPC_BRL_SPTK_MANY_X3, imm));
}
static inline void tcg_out_goto_tb(TCGContext *s, TCGArg arg)
{
if (s->tb_jmp_offset) {
/* direct jump method */
tcg_abort();
} else {
/* indirect jump method */
tcg_out_movi(s, TCG_TYPE_PTR, TCG_REG_R2,
(tcg_target_long)(s->tb_next + arg));
tcg_out_bundle(s, MmI,
tcg_opc_m1 (TCG_REG_P0, OPC_LD8_M1,
TCG_REG_R2, TCG_REG_R2),
tcg_opc_m48(TCG_REG_P0, OPC_NOP_M48, 0),
tcg_opc_i21(TCG_REG_P0, OPC_MOV_I21, TCG_REG_B6,
TCG_REG_R2, 0));
tcg_out_bundle(s, mmB,
tcg_opc_m48(TCG_REG_P0, OPC_NOP_M48, 0),
tcg_opc_m48(TCG_REG_P0, OPC_NOP_M48, 0),
tcg_opc_b4 (TCG_REG_P0, OPC_BR_SPTK_MANY_B4,
TCG_REG_B6));
}
s->tb_next_offset[arg] = s->code_ptr - s->code_buf;
}
static inline void tcg_out_jmp(TCGContext *s, TCGArg addr)
{
tcg_out_bundle(s, mmI,
tcg_opc_m48(TCG_REG_P0, OPC_NOP_M48, 0),
tcg_opc_m48(TCG_REG_P0, OPC_NOP_M48, 0),
tcg_opc_i21(TCG_REG_P0, OPC_MOV_I21, TCG_REG_B6, addr, 0));
tcg_out_bundle(s, mmB,
tcg_opc_m48(TCG_REG_P0, OPC_NOP_M48, 0),
tcg_opc_m48(TCG_REG_P0, OPC_NOP_M48, 0),
tcg_opc_b4(TCG_REG_P0, OPC_BR_SPTK_MANY_B4, TCG_REG_B6));
}
static inline void tcg_out_ld_rel(TCGContext *s, uint64_t opc_m4, TCGArg arg,
TCGArg arg1, tcg_target_long arg2)
{
if (arg2 == ((int16_t)arg2 >> 2) << 2) {
tcg_out_bundle(s, MmI,
tcg_opc_a4(TCG_REG_P0, OPC_ADDS_A4,
TCG_REG_R2, arg2, arg1),
tcg_opc_m1 (TCG_REG_P0, opc_m4, arg, TCG_REG_R2),
tcg_opc_i18(TCG_REG_P0, OPC_NOP_I18, 0));
} else {
tcg_out_movi(s, TCG_TYPE_PTR, TCG_REG_R2, arg2);
tcg_out_bundle(s, MmI,
tcg_opc_a1 (TCG_REG_P0, OPC_ADD_A1,
TCG_REG_R2, TCG_REG_R2, arg1),
tcg_opc_m1 (TCG_REG_P0, opc_m4, arg, TCG_REG_R2),
tcg_opc_i18(TCG_REG_P0, OPC_NOP_I18, 0));
}
}
static inline void tcg_out_st_rel(TCGContext *s, uint64_t opc_m4, TCGArg arg,
TCGArg arg1, tcg_target_long arg2)
{
if (arg2 == ((int16_t)arg2 >> 2) << 2) {
tcg_out_bundle(s, MmI,
tcg_opc_a4(TCG_REG_P0, OPC_ADDS_A4,
TCG_REG_R2, arg2, arg1),
tcg_opc_m4 (TCG_REG_P0, opc_m4, arg, TCG_REG_R2),
tcg_opc_i18(TCG_REG_P0, OPC_NOP_I18, 0));
} else {
tcg_out_movi(s, TCG_TYPE_PTR, TCG_REG_R2, arg2);
tcg_out_bundle(s, MmI,
tcg_opc_a1 (TCG_REG_P0, OPC_ADD_A1,
TCG_REG_R2, TCG_REG_R2, arg1),
tcg_opc_m4 (TCG_REG_P0, opc_m4, arg, TCG_REG_R2),
tcg_opc_i18(TCG_REG_P0, OPC_NOP_I18, 0));
}
}
static inline void tcg_out_ld(TCGContext *s, TCGType type, TCGReg arg,
TCGReg arg1, tcg_target_long arg2)
tcg: initial ia64 support A few words about design choices: * On IA64, instructions should be grouped by bundle, and dependencies between instructions declared. A first version of this code tried to schedule instructions automatically, but was very complex and too invasive for the current common TCG code (ops not ending at instruction boundaries, code retranslation breaking already generated code, etc.) It was also not very efficient, as dependencies between TCG ops is not available. Instead the option taken by the current implementation does not try to fill the bundle by scheduling instructions, but by providing ops not available as an ia64 instruction, and by offering 22-bit constant loading for most of the instructions. With both options the bundle are filled at approximately the same level. * Up to 128 registers can be affected to a function on IA64, but TCG limits this number to 64, which is actually more than enough. The register affectation is the following: - r0: used to map a constant argument with value 0 - r1: global pointer - r2, r3: internal use - r4 to r6: not used to avoid saving them - r7: env structure - r8 to r11: free for TCG (call clobbered) - r12: stack pointer - r13: thread pointer - r14 to r31: free for TCG (call clobbered) - r32: reserved (return address) - r33: reserved (PFS) - r33 to r63: free for TCG * The IA64 architecture has only 64-bit registers and no 32-bit instructions (the only exception being cmp4). Therefore 64-bit registers and instructions are used for 32-bit ops. The adopted strategy is the same as the ABI, that is the higher 32 bits are undefined. Most ops (and, or, add, shl, etc.) can directly use the 64-bit registers, while some others have to sign-extend (sar, div, etc.) or zero-extend (shr, divu, etc.) the register first. Signed-off-by: Aurelien Jarno <aurelien@aurel32.net>
2010-03-29 04:12:51 +04:00
{
if (type == TCG_TYPE_I32) {
tcg_out_ld_rel(s, OPC_LD4_M1, arg, arg1, arg2);
} else {
tcg_out_ld_rel(s, OPC_LD8_M1, arg, arg1, arg2);
}
}
static inline void tcg_out_st(TCGContext *s, TCGType type, TCGReg arg,
TCGReg arg1, tcg_target_long arg2)
tcg: initial ia64 support A few words about design choices: * On IA64, instructions should be grouped by bundle, and dependencies between instructions declared. A first version of this code tried to schedule instructions automatically, but was very complex and too invasive for the current common TCG code (ops not ending at instruction boundaries, code retranslation breaking already generated code, etc.) It was also not very efficient, as dependencies between TCG ops is not available. Instead the option taken by the current implementation does not try to fill the bundle by scheduling instructions, but by providing ops not available as an ia64 instruction, and by offering 22-bit constant loading for most of the instructions. With both options the bundle are filled at approximately the same level. * Up to 128 registers can be affected to a function on IA64, but TCG limits this number to 64, which is actually more than enough. The register affectation is the following: - r0: used to map a constant argument with value 0 - r1: global pointer - r2, r3: internal use - r4 to r6: not used to avoid saving them - r7: env structure - r8 to r11: free for TCG (call clobbered) - r12: stack pointer - r13: thread pointer - r14 to r31: free for TCG (call clobbered) - r32: reserved (return address) - r33: reserved (PFS) - r33 to r63: free for TCG * The IA64 architecture has only 64-bit registers and no 32-bit instructions (the only exception being cmp4). Therefore 64-bit registers and instructions are used for 32-bit ops. The adopted strategy is the same as the ABI, that is the higher 32 bits are undefined. Most ops (and, or, add, shl, etc.) can directly use the 64-bit registers, while some others have to sign-extend (sar, div, etc.) or zero-extend (shr, divu, etc.) the register first. Signed-off-by: Aurelien Jarno <aurelien@aurel32.net>
2010-03-29 04:12:51 +04:00
{
if (type == TCG_TYPE_I32) {
tcg_out_st_rel(s, OPC_ST4_M4, arg, arg1, arg2);
} else {
tcg_out_st_rel(s, OPC_ST8_M4, arg, arg1, arg2);
}
}
static inline void tcg_out_alu(TCGContext *s, uint64_t opc_a1, TCGArg ret,
TCGArg arg1, int const_arg1,
TCGArg arg2, int const_arg2)
{
uint64_t opc1, opc2;
if (const_arg1 && arg1 != 0) {
opc1 = tcg_opc_a5(TCG_REG_P0, OPC_ADDL_A5,
TCG_REG_R2, arg1, TCG_REG_R0);
arg1 = TCG_REG_R2;
} else {
opc1 = tcg_opc_m48(TCG_REG_P0, OPC_NOP_M48, 0);
}
if (const_arg2 && arg2 != 0) {
opc2 = tcg_opc_a5(TCG_REG_P0, OPC_ADDL_A5,
TCG_REG_R3, arg2, TCG_REG_R0);
arg2 = TCG_REG_R3;
} else {
opc2 = tcg_opc_i18(TCG_REG_P0, OPC_NOP_I18, 0);
}
tcg_out_bundle(s, mII,
opc1,
opc2,
tcg_opc_a1(TCG_REG_P0, opc_a1, ret, arg1, arg2));
}
static inline void tcg_out_eqv(TCGContext *s, TCGArg ret,
TCGArg arg1, int const_arg1,
TCGArg arg2, int const_arg2)
{
tcg_out_bundle(s, mII,
tcg_opc_m48(TCG_REG_P0, OPC_NOP_M48, 0),
tcg_opc_a1 (TCG_REG_P0, OPC_XOR_A1, ret, arg1, arg2),
tcg_opc_a3 (TCG_REG_P0, OPC_ANDCM_A3, ret, -1, ret));
}
static inline void tcg_out_nand(TCGContext *s, TCGArg ret,
TCGArg arg1, int const_arg1,
TCGArg arg2, int const_arg2)
{
tcg_out_bundle(s, mII,
tcg_opc_m48(TCG_REG_P0, OPC_NOP_M48, 0),
tcg_opc_a1 (TCG_REG_P0, OPC_AND_A1, ret, arg1, arg2),
tcg_opc_a3 (TCG_REG_P0, OPC_ANDCM_A3, ret, -1, ret));
}
static inline void tcg_out_nor(TCGContext *s, TCGArg ret,
TCGArg arg1, int const_arg1,
TCGArg arg2, int const_arg2)
{
tcg_out_bundle(s, mII,
tcg_opc_m48(TCG_REG_P0, OPC_NOP_M48, 0),
tcg_opc_a1 (TCG_REG_P0, OPC_OR_A1, ret, arg1, arg2),
tcg_opc_a3 (TCG_REG_P0, OPC_ANDCM_A3, ret, -1, ret));
}
static inline void tcg_out_orc(TCGContext *s, TCGArg ret,
TCGArg arg1, int const_arg1,
TCGArg arg2, int const_arg2)
{
tcg_out_bundle(s, mII,
tcg_opc_m48(TCG_REG_P0, OPC_NOP_M48, 0),
tcg_opc_a3 (TCG_REG_P0, OPC_ANDCM_A3, TCG_REG_R2, -1, arg2),
tcg_opc_a1 (TCG_REG_P0, OPC_OR_A1, ret, arg1, TCG_REG_R2));
}
static inline void tcg_out_mul(TCGContext *s, TCGArg ret,
TCGArg arg1, TCGArg arg2)
{
tcg_out_bundle(s, mmI,
tcg_opc_m18(TCG_REG_P0, OPC_SETF_SIG_M18, TCG_REG_F6, arg1),
tcg_opc_m18(TCG_REG_P0, OPC_SETF_SIG_M18, TCG_REG_F7, arg2),
tcg_opc_i18(TCG_REG_P0, OPC_NOP_I18, 0));
tcg_out_bundle(s, mmF,
tcg_opc_m48(TCG_REG_P0, OPC_NOP_M48, 0),
tcg_opc_m48(TCG_REG_P0, OPC_NOP_M48, 0),
tcg_opc_f2 (TCG_REG_P0, OPC_XMA_L_F2, TCG_REG_F6, TCG_REG_F6,
TCG_REG_F7, TCG_REG_F0));
tcg_out_bundle(s, miI,
tcg_opc_m19(TCG_REG_P0, OPC_GETF_SIG_M19, ret, TCG_REG_F6),
tcg_opc_i18(TCG_REG_P0, OPC_NOP_I18, 0),
tcg_opc_i18(TCG_REG_P0, OPC_NOP_I18, 0));
}
static inline void tcg_out_sar_i32(TCGContext *s, TCGArg ret, TCGArg arg1,
TCGArg arg2, int const_arg2)
{
if (const_arg2) {
tcg_out_bundle(s, miI,
tcg_opc_m48(TCG_REG_P0, OPC_NOP_M48, 0),
tcg_opc_i18(TCG_REG_P0, OPC_NOP_I18, 0),
tcg_opc_i11(TCG_REG_P0, OPC_EXTR_I11,
ret, arg1, arg2, 31 - arg2));
} else {
tcg_out_bundle(s, mII,
tcg_opc_a3 (TCG_REG_P0, OPC_AND_A3,
TCG_REG_R3, 0x1f, arg2),
tcg_opc_i29(TCG_REG_P0, OPC_SXT4_I29, TCG_REG_R2, arg1),
tcg_opc_i5 (TCG_REG_P0, OPC_SHR_I5, ret,
TCG_REG_R2, TCG_REG_R3));
}
}
static inline void tcg_out_sar_i64(TCGContext *s, TCGArg ret, TCGArg arg1,
TCGArg arg2, int const_arg2)
{
if (const_arg2) {
tcg_out_bundle(s, miI,
tcg_opc_m48(TCG_REG_P0, OPC_NOP_M48, 0),
tcg_opc_i18(TCG_REG_P0, OPC_NOP_I18, 0),
tcg_opc_i11(TCG_REG_P0, OPC_EXTR_I11,
ret, arg1, arg2, 63 - arg2));
} else {
tcg_out_bundle(s, miI,
tcg_opc_m48(TCG_REG_P0, OPC_NOP_M48, 0),
tcg_opc_i18(TCG_REG_P0, OPC_NOP_I18, 0),
tcg_opc_i5 (TCG_REG_P0, OPC_SHR_I5, ret, arg1, arg2));
}
}
static inline void tcg_out_shl_i32(TCGContext *s, TCGArg ret, TCGArg arg1,
TCGArg arg2, int const_arg2)
{
if (const_arg2) {
tcg_out_bundle(s, miI,
tcg_opc_m48(TCG_REG_P0, OPC_NOP_M48, 0),
tcg_opc_i18(TCG_REG_P0, OPC_NOP_I18, 0),
tcg_opc_i12(TCG_REG_P0, OPC_DEP_Z_I12, ret,
arg1, 63 - arg2, 31 - arg2));
} else {
tcg_out_bundle(s, mII,
tcg_opc_m48(TCG_REG_P0, OPC_NOP_M48, 0),
tcg_opc_a3 (TCG_REG_P0, OPC_AND_A3, TCG_REG_R2,
0x1f, arg2),
tcg_opc_i7 (TCG_REG_P0, OPC_SHL_I7, ret,
arg1, TCG_REG_R2));
}
}
static inline void tcg_out_shl_i64(TCGContext *s, TCGArg ret, TCGArg arg1,
TCGArg arg2, int const_arg2)
{
if (const_arg2) {
tcg_out_bundle(s, miI,
tcg_opc_m48(TCG_REG_P0, OPC_NOP_M48, 0),
tcg_opc_i18(TCG_REG_P0, OPC_NOP_I18, 0),
tcg_opc_i12(TCG_REG_P0, OPC_DEP_Z_I12, ret,
arg1, 63 - arg2, 63 - arg2));
} else {
tcg_out_bundle(s, miI,
tcg_opc_m48(TCG_REG_P0, OPC_NOP_M48, 0),
tcg_opc_i18(TCG_REG_P0, OPC_NOP_I18, 0),
tcg_opc_i7 (TCG_REG_P0, OPC_SHL_I7, ret,
arg1, arg2));
}
}
static inline void tcg_out_shr_i32(TCGContext *s, TCGArg ret, TCGArg arg1,
TCGArg arg2, int const_arg2)
{
if (const_arg2) {
tcg_out_bundle(s, miI,
tcg_opc_m48(TCG_REG_P0, OPC_NOP_M48, 0),
tcg_opc_i18(TCG_REG_P0, OPC_NOP_I18, 0),
tcg_opc_i11(TCG_REG_P0, OPC_EXTR_U_I11, ret,
arg1, arg2, 31 - arg2));
} else {
tcg_out_bundle(s, mII,
tcg_opc_a3 (TCG_REG_P0, OPC_AND_A3, TCG_REG_R3,
0x1f, arg2),
tcg_opc_i29(TCG_REG_P0, OPC_ZXT4_I29, TCG_REG_R2, arg1),
tcg_opc_i5 (TCG_REG_P0, OPC_SHR_U_I5, ret,
TCG_REG_R2, TCG_REG_R3));
}
}
static inline void tcg_out_shr_i64(TCGContext *s, TCGArg ret, TCGArg arg1,
TCGArg arg2, int const_arg2)
{
if (const_arg2) {
tcg_out_bundle(s, miI,
tcg_opc_m48(TCG_REG_P0, OPC_NOP_M48, 0),
tcg_opc_i18(TCG_REG_P0, OPC_NOP_I18, 0),
tcg_opc_i11(TCG_REG_P0, OPC_EXTR_U_I11, ret,
arg1, arg2, 63 - arg2));
} else {
tcg_out_bundle(s, miI,
tcg_opc_m48(TCG_REG_P0, OPC_NOP_M48, 0),
tcg_opc_i18(TCG_REG_P0, OPC_NOP_I18, 0),
tcg_opc_i5 (TCG_REG_P0, OPC_SHR_U_I5, ret,
arg1, arg2));
}
}
static inline void tcg_out_rotl_i32(TCGContext *s, TCGArg ret, TCGArg arg1,
TCGArg arg2, int const_arg2)
{
if (const_arg2) {
tcg_out_bundle(s, mII,
tcg_opc_m48(TCG_REG_P0, OPC_NOP_M48, 0),
tcg_opc_i2 (TCG_REG_P0, OPC_UNPACK4_L_I2,
TCG_REG_R2, arg1, arg1),
tcg_opc_i11(TCG_REG_P0, OPC_EXTR_U_I11, ret,
TCG_REG_R2, 32 - arg2, 31));
} else {
tcg_out_bundle(s, miI,
tcg_opc_m48(TCG_REG_P0, OPC_NOP_M48, 0),
tcg_opc_i2 (TCG_REG_P0, OPC_UNPACK4_L_I2,
TCG_REG_R2, arg1, arg1),
tcg_opc_a3 (TCG_REG_P0, OPC_AND_A3, TCG_REG_R3,
0x1f, arg2));
tcg_out_bundle(s, mII,
tcg_opc_m48(TCG_REG_P0, OPC_NOP_M48, 0),
tcg_opc_a3 (TCG_REG_P0, OPC_SUB_A3, TCG_REG_R3,
0x20, TCG_REG_R3),
tcg_opc_i5 (TCG_REG_P0, OPC_SHR_U_I5, ret,
TCG_REG_R2, TCG_REG_R3));
}
}
static inline void tcg_out_rotl_i64(TCGContext *s, TCGArg ret, TCGArg arg1,
TCGArg arg2, int const_arg2)
{
if (const_arg2) {
tcg_out_bundle(s, miI,
tcg_opc_m48(TCG_REG_P0, OPC_NOP_M48, 0),
tcg_opc_i18(TCG_REG_P0, OPC_NOP_I18, 0),
tcg_opc_i10(TCG_REG_P0, OPC_SHRP_I10, ret, arg1,
arg1, 0x40 - arg2));
} else {
tcg_out_bundle(s, mII,
tcg_opc_a3 (TCG_REG_P0, OPC_SUB_A3, TCG_REG_R2,
0x40, arg2),
tcg_opc_i7 (TCG_REG_P0, OPC_SHL_I7, TCG_REG_R3,
arg1, arg2),
tcg_opc_i5 (TCG_REG_P0, OPC_SHR_U_I5, TCG_REG_R2,
arg1, TCG_REG_R2));
tcg_out_bundle(s, miI,
tcg_opc_m48(TCG_REG_P0, OPC_NOP_M48, 0),
tcg_opc_i18(TCG_REG_P0, OPC_NOP_I18, 0),
tcg_opc_a1 (TCG_REG_P0, OPC_OR_A1, ret,
TCG_REG_R2, TCG_REG_R3));
}
}
static inline void tcg_out_rotr_i32(TCGContext *s, TCGArg ret, TCGArg arg1,
TCGArg arg2, int const_arg2)
{
if (const_arg2) {
tcg_out_bundle(s, mII,
tcg_opc_m48(TCG_REG_P0, OPC_NOP_M48, 0),
tcg_opc_i2 (TCG_REG_P0, OPC_UNPACK4_L_I2,
TCG_REG_R2, arg1, arg1),
tcg_opc_i11(TCG_REG_P0, OPC_EXTR_U_I11, ret,
TCG_REG_R2, arg2, 31));
} else {
tcg_out_bundle(s, mII,
tcg_opc_a3 (TCG_REG_P0, OPC_AND_A3, TCG_REG_R3,
0x1f, arg2),
tcg_opc_i2 (TCG_REG_P0, OPC_UNPACK4_L_I2,
TCG_REG_R2, arg1, arg1),
tcg_opc_i5 (TCG_REG_P0, OPC_SHR_U_I5, ret,
TCG_REG_R2, TCG_REG_R3));
}
}
static inline void tcg_out_rotr_i64(TCGContext *s, TCGArg ret, TCGArg arg1,
TCGArg arg2, int const_arg2)
{
if (const_arg2) {
tcg_out_bundle(s, miI,
tcg_opc_m48(TCG_REG_P0, OPC_NOP_M48, 0),
tcg_opc_i18(TCG_REG_P0, OPC_NOP_I18, 0),
tcg_opc_i10(TCG_REG_P0, OPC_SHRP_I10, ret, arg1,
arg1, arg2));
} else {
tcg_out_bundle(s, mII,
tcg_opc_a3 (TCG_REG_P0, OPC_SUB_A3, TCG_REG_R2,
0x40, arg2),
tcg_opc_i5 (TCG_REG_P0, OPC_SHR_U_I5, TCG_REG_R3,
arg1, arg2),
tcg_opc_i7 (TCG_REG_P0, OPC_SHL_I7, TCG_REG_R2,
arg1, TCG_REG_R2));
tcg_out_bundle(s, miI,
tcg_opc_m48(TCG_REG_P0, OPC_NOP_M48, 0),
tcg_opc_i18(TCG_REG_P0, OPC_NOP_I18, 0),
tcg_opc_a1 (TCG_REG_P0, OPC_OR_A1, ret,
TCG_REG_R2, TCG_REG_R3));
}
}
static inline void tcg_out_ext(TCGContext *s, uint64_t opc_i29,
TCGArg ret, TCGArg arg)
{
tcg_out_bundle(s, miI,
tcg_opc_m48(TCG_REG_P0, OPC_NOP_M48, 0),
tcg_opc_i18(TCG_REG_P0, OPC_NOP_I18, 0),
tcg_opc_i29(TCG_REG_P0, opc_i29, ret, arg));
}
static inline void tcg_out_bswap16(TCGContext *s, TCGArg ret, TCGArg arg)
{
tcg_out_bundle(s, mII,
tcg_opc_m48(TCG_REG_P0, OPC_NOP_M48, 0),
tcg_opc_i12(TCG_REG_P0, OPC_DEP_Z_I12, ret, arg, 15, 15),
tcg_opc_i3 (TCG_REG_P0, OPC_MUX1_I3, ret, ret, 0xb));
}
static inline void tcg_out_bswap32(TCGContext *s, TCGArg ret, TCGArg arg)
{
tcg_out_bundle(s, mII,
tcg_opc_m48(TCG_REG_P0, OPC_NOP_M48, 0),
tcg_opc_i12(TCG_REG_P0, OPC_DEP_Z_I12, ret, arg, 31, 31),
tcg_opc_i3 (TCG_REG_P0, OPC_MUX1_I3, ret, ret, 0xb));
}
static inline void tcg_out_bswap64(TCGContext *s, TCGArg ret, TCGArg arg)
{
tcg_out_bundle(s, miI,
tcg: initial ia64 support A few words about design choices: * On IA64, instructions should be grouped by bundle, and dependencies between instructions declared. A first version of this code tried to schedule instructions automatically, but was very complex and too invasive for the current common TCG code (ops not ending at instruction boundaries, code retranslation breaking already generated code, etc.) It was also not very efficient, as dependencies between TCG ops is not available. Instead the option taken by the current implementation does not try to fill the bundle by scheduling instructions, but by providing ops not available as an ia64 instruction, and by offering 22-bit constant loading for most of the instructions. With both options the bundle are filled at approximately the same level. * Up to 128 registers can be affected to a function on IA64, but TCG limits this number to 64, which is actually more than enough. The register affectation is the following: - r0: used to map a constant argument with value 0 - r1: global pointer - r2, r3: internal use - r4 to r6: not used to avoid saving them - r7: env structure - r8 to r11: free for TCG (call clobbered) - r12: stack pointer - r13: thread pointer - r14 to r31: free for TCG (call clobbered) - r32: reserved (return address) - r33: reserved (PFS) - r33 to r63: free for TCG * The IA64 architecture has only 64-bit registers and no 32-bit instructions (the only exception being cmp4). Therefore 64-bit registers and instructions are used for 32-bit ops. The adopted strategy is the same as the ABI, that is the higher 32 bits are undefined. Most ops (and, or, add, shl, etc.) can directly use the 64-bit registers, while some others have to sign-extend (sar, div, etc.) or zero-extend (shr, divu, etc.) the register first. Signed-off-by: Aurelien Jarno <aurelien@aurel32.net>
2010-03-29 04:12:51 +04:00
tcg_opc_m48(TCG_REG_P0, OPC_NOP_M48, 0),
tcg_opc_i18(TCG_REG_P0, OPC_NOP_I18, 0),
tcg_opc_i3 (TCG_REG_P0, OPC_MUX1_I3, ret, arg, 0xb));
}
static inline void tcg_out_deposit(TCGContext *s, TCGArg ret, TCGArg a1,
TCGArg a2, int const_a2, int pos, int len)
{
uint64_t i1 = 0, i2 = 0;
int cpos = 63 - pos, lm1 = len - 1;
if (const_a2) {
/* Truncate the value of a constant a2 to the width of the field. */
int mask = (1u << len) - 1;
a2 &= mask;
if (a2 == 0 || a2 == mask) {
/* 1-bit signed constant inserted into register. */
i2 = tcg_opc_i14(TCG_REG_P0, OPC_DEP_I14, ret, a2, a1, cpos, lm1);
} else {
/* Otherwise, load any constant into a temporary. Do this into
the first I slot to help out with cross-unit delays. */
i1 = tcg_opc_a5(TCG_REG_P0, OPC_ADDL_A5,
TCG_REG_R2, a2, TCG_REG_R0);
a2 = TCG_REG_R2;
}
}
if (i2 == 0) {
i2 = tcg_opc_i15(TCG_REG_P0, OPC_DEP_I15, ret, a2, a1, cpos, lm1);
}
tcg_out_bundle(s, (i1 ? mII : miI),
tcg_opc_m48(TCG_REG_P0, OPC_NOP_M48, 0),
i1 ? i1 : tcg_opc_i18(TCG_REG_P0, OPC_NOP_I18, 0),
i2);
}
tcg: initial ia64 support A few words about design choices: * On IA64, instructions should be grouped by bundle, and dependencies between instructions declared. A first version of this code tried to schedule instructions automatically, but was very complex and too invasive for the current common TCG code (ops not ending at instruction boundaries, code retranslation breaking already generated code, etc.) It was also not very efficient, as dependencies between TCG ops is not available. Instead the option taken by the current implementation does not try to fill the bundle by scheduling instructions, but by providing ops not available as an ia64 instruction, and by offering 22-bit constant loading for most of the instructions. With both options the bundle are filled at approximately the same level. * Up to 128 registers can be affected to a function on IA64, but TCG limits this number to 64, which is actually more than enough. The register affectation is the following: - r0: used to map a constant argument with value 0 - r1: global pointer - r2, r3: internal use - r4 to r6: not used to avoid saving them - r7: env structure - r8 to r11: free for TCG (call clobbered) - r12: stack pointer - r13: thread pointer - r14 to r31: free for TCG (call clobbered) - r32: reserved (return address) - r33: reserved (PFS) - r33 to r63: free for TCG * The IA64 architecture has only 64-bit registers and no 32-bit instructions (the only exception being cmp4). Therefore 64-bit registers and instructions are used for 32-bit ops. The adopted strategy is the same as the ABI, that is the higher 32 bits are undefined. Most ops (and, or, add, shl, etc.) can directly use the 64-bit registers, while some others have to sign-extend (sar, div, etc.) or zero-extend (shr, divu, etc.) the register first. Signed-off-by: Aurelien Jarno <aurelien@aurel32.net>
2010-03-29 04:12:51 +04:00
static inline uint64_t tcg_opc_cmp_a(int qp, TCGCond cond, TCGArg arg1,
TCGArg arg2, int cmp4)
{
uint64_t opc_eq_a6, opc_lt_a6, opc_ltu_a6;
if (cmp4) {
opc_eq_a6 = OPC_CMP4_EQ_A6;
opc_lt_a6 = OPC_CMP4_LT_A6;
opc_ltu_a6 = OPC_CMP4_LTU_A6;
} else {
opc_eq_a6 = OPC_CMP_EQ_A6;
opc_lt_a6 = OPC_CMP_LT_A6;
opc_ltu_a6 = OPC_CMP_LTU_A6;
}
switch (cond) {
case TCG_COND_EQ:
return tcg_opc_a6 (qp, opc_eq_a6, TCG_REG_P6, TCG_REG_P7, arg1, arg2);
case TCG_COND_NE:
return tcg_opc_a6 (qp, opc_eq_a6, TCG_REG_P7, TCG_REG_P6, arg1, arg2);
case TCG_COND_LT:
return tcg_opc_a6 (qp, opc_lt_a6, TCG_REG_P6, TCG_REG_P7, arg1, arg2);
case TCG_COND_LTU:
return tcg_opc_a6 (qp, opc_ltu_a6, TCG_REG_P6, TCG_REG_P7, arg1, arg2);
case TCG_COND_GE:
return tcg_opc_a6 (qp, opc_lt_a6, TCG_REG_P7, TCG_REG_P6, arg1, arg2);
case TCG_COND_GEU:
return tcg_opc_a6 (qp, opc_ltu_a6, TCG_REG_P7, TCG_REG_P6, arg1, arg2);
case TCG_COND_LE:
return tcg_opc_a6 (qp, opc_lt_a6, TCG_REG_P7, TCG_REG_P6, arg2, arg1);
case TCG_COND_LEU:
return tcg_opc_a6 (qp, opc_ltu_a6, TCG_REG_P7, TCG_REG_P6, arg2, arg1);
case TCG_COND_GT:
return tcg_opc_a6 (qp, opc_lt_a6, TCG_REG_P6, TCG_REG_P7, arg2, arg1);
case TCG_COND_GTU:
return tcg_opc_a6 (qp, opc_ltu_a6, TCG_REG_P6, TCG_REG_P7, arg2, arg1);
default:
tcg_abort();
break;
}
}
static inline void tcg_out_brcond(TCGContext *s, TCGCond cond, TCGArg arg1,
int const_arg1, TCGArg arg2, int const_arg2,
int label_index, int cmp4)
{
TCGLabel *l = &s->labels[label_index];
uint64_t opc1, opc2;
if (const_arg1 && arg1 != 0) {
opc1 = tcg_opc_a5(TCG_REG_P0, OPC_ADDL_A5, TCG_REG_R2,
arg1, TCG_REG_R0);
arg1 = TCG_REG_R2;
} else {
opc1 = tcg_opc_m48(TCG_REG_P0, OPC_NOP_M48, 0);
}
if (const_arg2 && arg2 != 0) {
opc2 = tcg_opc_a5(TCG_REG_P0, OPC_ADDL_A5, TCG_REG_R3,
arg2, TCG_REG_R0);
arg2 = TCG_REG_R3;
} else {
opc2 = tcg_opc_i18(TCG_REG_P0, OPC_NOP_I18, 0);
}
tcg_out_bundle(s, mII,
opc1,
opc2,
tcg_opc_cmp_a(TCG_REG_P0, cond, arg1, arg2, cmp4));
tcg_out_bundle(s, mmB,
tcg_opc_m48(TCG_REG_P0, OPC_NOP_M48, 0),
tcg_opc_m48(TCG_REG_P0, OPC_NOP_M48, 0),
tcg_opc_b1 (TCG_REG_P6, OPC_BR_DPTK_FEW_B1,
get_reloc_pcrel21b(s->code_ptr + 2)));
if (l->has_value) {
reloc_pcrel21b((s->code_ptr - 16) + 2, l->u.value);
} else {
tcg_out_reloc(s, (s->code_ptr - 16) + 2,
R_IA64_PCREL21B, label_index, 0);
}
}
static inline void tcg_out_setcond(TCGContext *s, TCGCond cond, TCGArg ret,
TCGArg arg1, TCGArg arg2, int cmp4)
{
tcg_out_bundle(s, MmI,
tcg_opc_cmp_a(TCG_REG_P0, cond, arg1, arg2, cmp4),
tcg_opc_a5(TCG_REG_P6, OPC_ADDL_A5, ret, 1, TCG_REG_R0),
tcg_opc_a5(TCG_REG_P7, OPC_ADDL_A5, ret, 0, TCG_REG_R0));
}
static inline void tcg_out_movcond(TCGContext *s, TCGCond cond, TCGArg ret,
TCGArg c1, TCGArg c2,
TCGArg v1, int const_v1,
TCGArg v2, int const_v2, int cmp4)
{
uint64_t opc1, opc2;
if (const_v1) {
opc1 = tcg_opc_a5(TCG_REG_P6, OPC_ADDL_A5, ret, v1, TCG_REG_R0);
} else if (ret == v1) {
opc1 = tcg_opc_m48(TCG_REG_P0, OPC_NOP_M48, 0);
} else {
opc1 = tcg_opc_a4(TCG_REG_P6, OPC_ADDS_A4, ret, 0, v1);
}
if (const_v2) {
opc2 = tcg_opc_a5(TCG_REG_P7, OPC_ADDL_A5, ret, v2, TCG_REG_R0);
} else if (ret == v2) {
opc2 = tcg_opc_m48(TCG_REG_P0, OPC_NOP_M48, 0);
} else {
opc2 = tcg_opc_a4(TCG_REG_P7, OPC_ADDS_A4, ret, 0, v2);
}
tcg_out_bundle(s, MmI,
tcg_opc_cmp_a(TCG_REG_P0, cond, c1, c2, cmp4),
opc1,
opc2);
}
tcg: initial ia64 support A few words about design choices: * On IA64, instructions should be grouped by bundle, and dependencies between instructions declared. A first version of this code tried to schedule instructions automatically, but was very complex and too invasive for the current common TCG code (ops not ending at instruction boundaries, code retranslation breaking already generated code, etc.) It was also not very efficient, as dependencies between TCG ops is not available. Instead the option taken by the current implementation does not try to fill the bundle by scheduling instructions, but by providing ops not available as an ia64 instruction, and by offering 22-bit constant loading for most of the instructions. With both options the bundle are filled at approximately the same level. * Up to 128 registers can be affected to a function on IA64, but TCG limits this number to 64, which is actually more than enough. The register affectation is the following: - r0: used to map a constant argument with value 0 - r1: global pointer - r2, r3: internal use - r4 to r6: not used to avoid saving them - r7: env structure - r8 to r11: free for TCG (call clobbered) - r12: stack pointer - r13: thread pointer - r14 to r31: free for TCG (call clobbered) - r32: reserved (return address) - r33: reserved (PFS) - r33 to r63: free for TCG * The IA64 architecture has only 64-bit registers and no 32-bit instructions (the only exception being cmp4). Therefore 64-bit registers and instructions are used for 32-bit ops. The adopted strategy is the same as the ABI, that is the higher 32 bits are undefined. Most ops (and, or, add, shl, etc.) can directly use the 64-bit registers, while some others have to sign-extend (sar, div, etc.) or zero-extend (shr, divu, etc.) the register first. Signed-off-by: Aurelien Jarno <aurelien@aurel32.net>
2010-03-29 04:12:51 +04:00
#if defined(CONFIG_SOFTMMU)
#include "../../softmmu_defs.h"
/* Load and compare a TLB entry, and return the result in (p6, p7).
R2 is loaded with the address of the addend TLB entry.
R57 is loaded with the address, zero extented on 32-bit targets. */
tcg: initial ia64 support A few words about design choices: * On IA64, instructions should be grouped by bundle, and dependencies between instructions declared. A first version of this code tried to schedule instructions automatically, but was very complex and too invasive for the current common TCG code (ops not ending at instruction boundaries, code retranslation breaking already generated code, etc.) It was also not very efficient, as dependencies between TCG ops is not available. Instead the option taken by the current implementation does not try to fill the bundle by scheduling instructions, but by providing ops not available as an ia64 instruction, and by offering 22-bit constant loading for most of the instructions. With both options the bundle are filled at approximately the same level. * Up to 128 registers can be affected to a function on IA64, but TCG limits this number to 64, which is actually more than enough. The register affectation is the following: - r0: used to map a constant argument with value 0 - r1: global pointer - r2, r3: internal use - r4 to r6: not used to avoid saving them - r7: env structure - r8 to r11: free for TCG (call clobbered) - r12: stack pointer - r13: thread pointer - r14 to r31: free for TCG (call clobbered) - r32: reserved (return address) - r33: reserved (PFS) - r33 to r63: free for TCG * The IA64 architecture has only 64-bit registers and no 32-bit instructions (the only exception being cmp4). Therefore 64-bit registers and instructions are used for 32-bit ops. The adopted strategy is the same as the ABI, that is the higher 32 bits are undefined. Most ops (and, or, add, shl, etc.) can directly use the 64-bit registers, while some others have to sign-extend (sar, div, etc.) or zero-extend (shr, divu, etc.) the register first. Signed-off-by: Aurelien Jarno <aurelien@aurel32.net>
2010-03-29 04:12:51 +04:00
static inline void tcg_out_qemu_tlb(TCGContext *s, TCGArg addr_reg,
int s_bits, uint64_t offset_rw,
uint64_t offset_addend)
{
tcg_out_bundle(s, mII,
tcg_opc_m48(TCG_REG_P0, OPC_NOP_M48, 0),
tcg: initial ia64 support A few words about design choices: * On IA64, instructions should be grouped by bundle, and dependencies between instructions declared. A first version of this code tried to schedule instructions automatically, but was very complex and too invasive for the current common TCG code (ops not ending at instruction boundaries, code retranslation breaking already generated code, etc.) It was also not very efficient, as dependencies between TCG ops is not available. Instead the option taken by the current implementation does not try to fill the bundle by scheduling instructions, but by providing ops not available as an ia64 instruction, and by offering 22-bit constant loading for most of the instructions. With both options the bundle are filled at approximately the same level. * Up to 128 registers can be affected to a function on IA64, but TCG limits this number to 64, which is actually more than enough. The register affectation is the following: - r0: used to map a constant argument with value 0 - r1: global pointer - r2, r3: internal use - r4 to r6: not used to avoid saving them - r7: env structure - r8 to r11: free for TCG (call clobbered) - r12: stack pointer - r13: thread pointer - r14 to r31: free for TCG (call clobbered) - r32: reserved (return address) - r33: reserved (PFS) - r33 to r63: free for TCG * The IA64 architecture has only 64-bit registers and no 32-bit instructions (the only exception being cmp4). Therefore 64-bit registers and instructions are used for 32-bit ops. The adopted strategy is the same as the ABI, that is the higher 32 bits are undefined. Most ops (and, or, add, shl, etc.) can directly use the 64-bit registers, while some others have to sign-extend (sar, div, etc.) or zero-extend (shr, divu, etc.) the register first. Signed-off-by: Aurelien Jarno <aurelien@aurel32.net>
2010-03-29 04:12:51 +04:00
tcg_opc_i11(TCG_REG_P0, OPC_EXTR_U_I11, TCG_REG_R2,
addr_reg, TARGET_PAGE_BITS, CPU_TLB_BITS - 1),
tcg_opc_i12(TCG_REG_P0, OPC_DEP_Z_I12, TCG_REG_R2,
TCG_REG_R2, 63 - CPU_TLB_ENTRY_BITS,
63 - CPU_TLB_ENTRY_BITS));
tcg_out_bundle(s, mII,
tcg_opc_a5 (TCG_REG_P0, OPC_ADDL_A5, TCG_REG_R2,
offset_rw, TCG_REG_R2),
#if TARGET_LONG_BITS == 32
tcg_opc_i29(TCG_REG_P0, OPC_ZXT4_I29, TCG_REG_R57, addr_reg),
tcg: initial ia64 support A few words about design choices: * On IA64, instructions should be grouped by bundle, and dependencies between instructions declared. A first version of this code tried to schedule instructions automatically, but was very complex and too invasive for the current common TCG code (ops not ending at instruction boundaries, code retranslation breaking already generated code, etc.) It was also not very efficient, as dependencies between TCG ops is not available. Instead the option taken by the current implementation does not try to fill the bundle by scheduling instructions, but by providing ops not available as an ia64 instruction, and by offering 22-bit constant loading for most of the instructions. With both options the bundle are filled at approximately the same level. * Up to 128 registers can be affected to a function on IA64, but TCG limits this number to 64, which is actually more than enough. The register affectation is the following: - r0: used to map a constant argument with value 0 - r1: global pointer - r2, r3: internal use - r4 to r6: not used to avoid saving them - r7: env structure - r8 to r11: free for TCG (call clobbered) - r12: stack pointer - r13: thread pointer - r14 to r31: free for TCG (call clobbered) - r32: reserved (return address) - r33: reserved (PFS) - r33 to r63: free for TCG * The IA64 architecture has only 64-bit registers and no 32-bit instructions (the only exception being cmp4). Therefore 64-bit registers and instructions are used for 32-bit ops. The adopted strategy is the same as the ABI, that is the higher 32 bits are undefined. Most ops (and, or, add, shl, etc.) can directly use the 64-bit registers, while some others have to sign-extend (sar, div, etc.) or zero-extend (shr, divu, etc.) the register first. Signed-off-by: Aurelien Jarno <aurelien@aurel32.net>
2010-03-29 04:12:51 +04:00
#else
tcg_opc_a4(TCG_REG_P0, OPC_ADDS_A4, TCG_REG_R57,
tcg: initial ia64 support A few words about design choices: * On IA64, instructions should be grouped by bundle, and dependencies between instructions declared. A first version of this code tried to schedule instructions automatically, but was very complex and too invasive for the current common TCG code (ops not ending at instruction boundaries, code retranslation breaking already generated code, etc.) It was also not very efficient, as dependencies between TCG ops is not available. Instead the option taken by the current implementation does not try to fill the bundle by scheduling instructions, but by providing ops not available as an ia64 instruction, and by offering 22-bit constant loading for most of the instructions. With both options the bundle are filled at approximately the same level. * Up to 128 registers can be affected to a function on IA64, but TCG limits this number to 64, which is actually more than enough. The register affectation is the following: - r0: used to map a constant argument with value 0 - r1: global pointer - r2, r3: internal use - r4 to r6: not used to avoid saving them - r7: env structure - r8 to r11: free for TCG (call clobbered) - r12: stack pointer - r13: thread pointer - r14 to r31: free for TCG (call clobbered) - r32: reserved (return address) - r33: reserved (PFS) - r33 to r63: free for TCG * The IA64 architecture has only 64-bit registers and no 32-bit instructions (the only exception being cmp4). Therefore 64-bit registers and instructions are used for 32-bit ops. The adopted strategy is the same as the ABI, that is the higher 32 bits are undefined. Most ops (and, or, add, shl, etc.) can directly use the 64-bit registers, while some others have to sign-extend (sar, div, etc.) or zero-extend (shr, divu, etc.) the register first. Signed-off-by: Aurelien Jarno <aurelien@aurel32.net>
2010-03-29 04:12:51 +04:00
0, addr_reg),
#endif
tcg_opc_a1 (TCG_REG_P0, OPC_ADD_A1, TCG_REG_R2,
TCG_REG_R2, TCG_AREG0));
tcg_out_bundle(s, mII,
tcg_opc_m3 (TCG_REG_P0,
(TARGET_LONG_BITS == 32
? OPC_LD4_M3 : OPC_LD8_M3), TCG_REG_R56,
tcg: initial ia64 support A few words about design choices: * On IA64, instructions should be grouped by bundle, and dependencies between instructions declared. A first version of this code tried to schedule instructions automatically, but was very complex and too invasive for the current common TCG code (ops not ending at instruction boundaries, code retranslation breaking already generated code, etc.) It was also not very efficient, as dependencies between TCG ops is not available. Instead the option taken by the current implementation does not try to fill the bundle by scheduling instructions, but by providing ops not available as an ia64 instruction, and by offering 22-bit constant loading for most of the instructions. With both options the bundle are filled at approximately the same level. * Up to 128 registers can be affected to a function on IA64, but TCG limits this number to 64, which is actually more than enough. The register affectation is the following: - r0: used to map a constant argument with value 0 - r1: global pointer - r2, r3: internal use - r4 to r6: not used to avoid saving them - r7: env structure - r8 to r11: free for TCG (call clobbered) - r12: stack pointer - r13: thread pointer - r14 to r31: free for TCG (call clobbered) - r32: reserved (return address) - r33: reserved (PFS) - r33 to r63: free for TCG * The IA64 architecture has only 64-bit registers and no 32-bit instructions (the only exception being cmp4). Therefore 64-bit registers and instructions are used for 32-bit ops. The adopted strategy is the same as the ABI, that is the higher 32 bits are undefined. Most ops (and, or, add, shl, etc.) can directly use the 64-bit registers, while some others have to sign-extend (sar, div, etc.) or zero-extend (shr, divu, etc.) the register first. Signed-off-by: Aurelien Jarno <aurelien@aurel32.net>
2010-03-29 04:12:51 +04:00
TCG_REG_R2, offset_addend - offset_rw),
tcg_opc_i14(TCG_REG_P0, OPC_DEP_I14, TCG_REG_R3, 0,
TCG_REG_R57, 63 - s_bits,
TARGET_PAGE_BITS - s_bits - 1),
tcg: initial ia64 support A few words about design choices: * On IA64, instructions should be grouped by bundle, and dependencies between instructions declared. A first version of this code tried to schedule instructions automatically, but was very complex and too invasive for the current common TCG code (ops not ending at instruction boundaries, code retranslation breaking already generated code, etc.) It was also not very efficient, as dependencies between TCG ops is not available. Instead the option taken by the current implementation does not try to fill the bundle by scheduling instructions, but by providing ops not available as an ia64 instruction, and by offering 22-bit constant loading for most of the instructions. With both options the bundle are filled at approximately the same level. * Up to 128 registers can be affected to a function on IA64, but TCG limits this number to 64, which is actually more than enough. The register affectation is the following: - r0: used to map a constant argument with value 0 - r1: global pointer - r2, r3: internal use - r4 to r6: not used to avoid saving them - r7: env structure - r8 to r11: free for TCG (call clobbered) - r12: stack pointer - r13: thread pointer - r14 to r31: free for TCG (call clobbered) - r32: reserved (return address) - r33: reserved (PFS) - r33 to r63: free for TCG * The IA64 architecture has only 64-bit registers and no 32-bit instructions (the only exception being cmp4). Therefore 64-bit registers and instructions are used for 32-bit ops. The adopted strategy is the same as the ABI, that is the higher 32 bits are undefined. Most ops (and, or, add, shl, etc.) can directly use the 64-bit registers, while some others have to sign-extend (sar, div, etc.) or zero-extend (shr, divu, etc.) the register first. Signed-off-by: Aurelien Jarno <aurelien@aurel32.net>
2010-03-29 04:12:51 +04:00
tcg_opc_a6 (TCG_REG_P0, OPC_CMP_EQ_A6, TCG_REG_P6,
TCG_REG_P7, TCG_REG_R3, TCG_REG_R56));
tcg: initial ia64 support A few words about design choices: * On IA64, instructions should be grouped by bundle, and dependencies between instructions declared. A first version of this code tried to schedule instructions automatically, but was very complex and too invasive for the current common TCG code (ops not ending at instruction boundaries, code retranslation breaking already generated code, etc.) It was also not very efficient, as dependencies between TCG ops is not available. Instead the option taken by the current implementation does not try to fill the bundle by scheduling instructions, but by providing ops not available as an ia64 instruction, and by offering 22-bit constant loading for most of the instructions. With both options the bundle are filled at approximately the same level. * Up to 128 registers can be affected to a function on IA64, but TCG limits this number to 64, which is actually more than enough. The register affectation is the following: - r0: used to map a constant argument with value 0 - r1: global pointer - r2, r3: internal use - r4 to r6: not used to avoid saving them - r7: env structure - r8 to r11: free for TCG (call clobbered) - r12: stack pointer - r13: thread pointer - r14 to r31: free for TCG (call clobbered) - r32: reserved (return address) - r33: reserved (PFS) - r33 to r63: free for TCG * The IA64 architecture has only 64-bit registers and no 32-bit instructions (the only exception being cmp4). Therefore 64-bit registers and instructions are used for 32-bit ops. The adopted strategy is the same as the ABI, that is the higher 32 bits are undefined. Most ops (and, or, add, shl, etc.) can directly use the 64-bit registers, while some others have to sign-extend (sar, div, etc.) or zero-extend (shr, divu, etc.) the register first. Signed-off-by: Aurelien Jarno <aurelien@aurel32.net>
2010-03-29 04:12:51 +04:00
}
/* helper signature: helper_ld_mmu(CPUState *env, target_ulong addr,
int mmu_idx) */
static const void * const qemu_ld_helpers[4] = {
helper_ldb_mmu,
helper_ldw_mmu,
helper_ldl_mmu,
helper_ldq_mmu,
};
tcg: initial ia64 support A few words about design choices: * On IA64, instructions should be grouped by bundle, and dependencies between instructions declared. A first version of this code tried to schedule instructions automatically, but was very complex and too invasive for the current common TCG code (ops not ending at instruction boundaries, code retranslation breaking already generated code, etc.) It was also not very efficient, as dependencies between TCG ops is not available. Instead the option taken by the current implementation does not try to fill the bundle by scheduling instructions, but by providing ops not available as an ia64 instruction, and by offering 22-bit constant loading for most of the instructions. With both options the bundle are filled at approximately the same level. * Up to 128 registers can be affected to a function on IA64, but TCG limits this number to 64, which is actually more than enough. The register affectation is the following: - r0: used to map a constant argument with value 0 - r1: global pointer - r2, r3: internal use - r4 to r6: not used to avoid saving them - r7: env structure - r8 to r11: free for TCG (call clobbered) - r12: stack pointer - r13: thread pointer - r14 to r31: free for TCG (call clobbered) - r32: reserved (return address) - r33: reserved (PFS) - r33 to r63: free for TCG * The IA64 architecture has only 64-bit registers and no 32-bit instructions (the only exception being cmp4). Therefore 64-bit registers and instructions are used for 32-bit ops. The adopted strategy is the same as the ABI, that is the higher 32 bits are undefined. Most ops (and, or, add, shl, etc.) can directly use the 64-bit registers, while some others have to sign-extend (sar, div, etc.) or zero-extend (shr, divu, etc.) the register first. Signed-off-by: Aurelien Jarno <aurelien@aurel32.net>
2010-03-29 04:12:51 +04:00
static inline void tcg_out_qemu_ld(TCGContext *s, const TCGArg *args, int opc)
{
int addr_reg, data_reg, mem_index, s_bits, bswap;
uint64_t opc_ld_m1[4] = { OPC_LD1_M1, OPC_LD2_M1, OPC_LD4_M1, OPC_LD8_M1 };
uint64_t opc_ext_i29[8] = { OPC_ZXT1_I29, OPC_ZXT2_I29, OPC_ZXT4_I29, 0,
OPC_SXT1_I29, OPC_SXT2_I29, OPC_SXT4_I29, 0 };
data_reg = *args++;
addr_reg = *args++;
mem_index = *args;
s_bits = opc & 3;
#ifdef TARGET_WORDS_BIGENDIAN
bswap = 1;
#else
bswap = 0;
#endif
/* Read the TLB entry */
tcg_out_qemu_tlb(s, addr_reg, s_bits,
offsetof(CPUArchState, tlb_table[mem_index][0].addr_read),
offsetof(CPUArchState, tlb_table[mem_index][0].addend));
tcg: initial ia64 support A few words about design choices: * On IA64, instructions should be grouped by bundle, and dependencies between instructions declared. A first version of this code tried to schedule instructions automatically, but was very complex and too invasive for the current common TCG code (ops not ending at instruction boundaries, code retranslation breaking already generated code, etc.) It was also not very efficient, as dependencies between TCG ops is not available. Instead the option taken by the current implementation does not try to fill the bundle by scheduling instructions, but by providing ops not available as an ia64 instruction, and by offering 22-bit constant loading for most of the instructions. With both options the bundle are filled at approximately the same level. * Up to 128 registers can be affected to a function on IA64, but TCG limits this number to 64, which is actually more than enough. The register affectation is the following: - r0: used to map a constant argument with value 0 - r1: global pointer - r2, r3: internal use - r4 to r6: not used to avoid saving them - r7: env structure - r8 to r11: free for TCG (call clobbered) - r12: stack pointer - r13: thread pointer - r14 to r31: free for TCG (call clobbered) - r32: reserved (return address) - r33: reserved (PFS) - r33 to r63: free for TCG * The IA64 architecture has only 64-bit registers and no 32-bit instructions (the only exception being cmp4). Therefore 64-bit registers and instructions are used for 32-bit ops. The adopted strategy is the same as the ABI, that is the higher 32 bits are undefined. Most ops (and, or, add, shl, etc.) can directly use the 64-bit registers, while some others have to sign-extend (sar, div, etc.) or zero-extend (shr, divu, etc.) the register first. Signed-off-by: Aurelien Jarno <aurelien@aurel32.net>
2010-03-29 04:12:51 +04:00
/* P6 is the fast path, and P7 the slow path */
tcg_out_bundle(s, mLX,
tcg_opc_a4 (TCG_REG_P7, OPC_ADDS_A4,
TCG_REG_R56, 0, TCG_AREG0),
tcg: initial ia64 support A few words about design choices: * On IA64, instructions should be grouped by bundle, and dependencies between instructions declared. A first version of this code tried to schedule instructions automatically, but was very complex and too invasive for the current common TCG code (ops not ending at instruction boundaries, code retranslation breaking already generated code, etc.) It was also not very efficient, as dependencies between TCG ops is not available. Instead the option taken by the current implementation does not try to fill the bundle by scheduling instructions, but by providing ops not available as an ia64 instruction, and by offering 22-bit constant loading for most of the instructions. With both options the bundle are filled at approximately the same level. * Up to 128 registers can be affected to a function on IA64, but TCG limits this number to 64, which is actually more than enough. The register affectation is the following: - r0: used to map a constant argument with value 0 - r1: global pointer - r2, r3: internal use - r4 to r6: not used to avoid saving them - r7: env structure - r8 to r11: free for TCG (call clobbered) - r12: stack pointer - r13: thread pointer - r14 to r31: free for TCG (call clobbered) - r32: reserved (return address) - r33: reserved (PFS) - r33 to r63: free for TCG * The IA64 architecture has only 64-bit registers and no 32-bit instructions (the only exception being cmp4). Therefore 64-bit registers and instructions are used for 32-bit ops. The adopted strategy is the same as the ABI, that is the higher 32 bits are undefined. Most ops (and, or, add, shl, etc.) can directly use the 64-bit registers, while some others have to sign-extend (sar, div, etc.) or zero-extend (shr, divu, etc.) the register first. Signed-off-by: Aurelien Jarno <aurelien@aurel32.net>
2010-03-29 04:12:51 +04:00
tcg_opc_l2 ((tcg_target_long) qemu_ld_helpers[s_bits]),
tcg_opc_x2 (TCG_REG_P7, OPC_MOVL_X2, TCG_REG_R2,
(tcg_target_long) qemu_ld_helpers[s_bits]));
tcg_out_bundle(s, MmI,
tcg_opc_m3 (TCG_REG_P0, OPC_LD8_M3, TCG_REG_R3,
TCG_REG_R2, 8),
tcg_opc_a1 (TCG_REG_P6, OPC_ADD_A1, TCG_REG_R3,
TCG_REG_R3, TCG_REG_R57),
tcg: initial ia64 support A few words about design choices: * On IA64, instructions should be grouped by bundle, and dependencies between instructions declared. A first version of this code tried to schedule instructions automatically, but was very complex and too invasive for the current common TCG code (ops not ending at instruction boundaries, code retranslation breaking already generated code, etc.) It was also not very efficient, as dependencies between TCG ops is not available. Instead the option taken by the current implementation does not try to fill the bundle by scheduling instructions, but by providing ops not available as an ia64 instruction, and by offering 22-bit constant loading for most of the instructions. With both options the bundle are filled at approximately the same level. * Up to 128 registers can be affected to a function on IA64, but TCG limits this number to 64, which is actually more than enough. The register affectation is the following: - r0: used to map a constant argument with value 0 - r1: global pointer - r2, r3: internal use - r4 to r6: not used to avoid saving them - r7: env structure - r8 to r11: free for TCG (call clobbered) - r12: stack pointer - r13: thread pointer - r14 to r31: free for TCG (call clobbered) - r32: reserved (return address) - r33: reserved (PFS) - r33 to r63: free for TCG * The IA64 architecture has only 64-bit registers and no 32-bit instructions (the only exception being cmp4). Therefore 64-bit registers and instructions are used for 32-bit ops. The adopted strategy is the same as the ABI, that is the higher 32 bits are undefined. Most ops (and, or, add, shl, etc.) can directly use the 64-bit registers, while some others have to sign-extend (sar, div, etc.) or zero-extend (shr, divu, etc.) the register first. Signed-off-by: Aurelien Jarno <aurelien@aurel32.net>
2010-03-29 04:12:51 +04:00
tcg_opc_i21(TCG_REG_P7, OPC_MOV_I21, TCG_REG_B6,
TCG_REG_R3, 0));
if (bswap && s_bits == 1) {
tcg_out_bundle(s, MmI,
tcg_opc_m1 (TCG_REG_P6, opc_ld_m1[s_bits],
TCG_REG_R8, TCG_REG_R3),
tcg_opc_m1 (TCG_REG_P7, OPC_LD8_M1, TCG_REG_R1, TCG_REG_R2),
tcg_opc_i12(TCG_REG_P6, OPC_DEP_Z_I12,
TCG_REG_R8, TCG_REG_R8, 15, 15));
} else if (bswap && s_bits == 2) {
tcg_out_bundle(s, MmI,
tcg_opc_m1 (TCG_REG_P6, opc_ld_m1[s_bits],
TCG_REG_R8, TCG_REG_R3),
tcg_opc_m1 (TCG_REG_P7, OPC_LD8_M1, TCG_REG_R1, TCG_REG_R2),
tcg_opc_i12(TCG_REG_P6, OPC_DEP_Z_I12,
TCG_REG_R8, TCG_REG_R8, 31, 31));
} else {
tcg_out_bundle(s, mmI,
tcg_opc_m1 (TCG_REG_P6, opc_ld_m1[s_bits],
TCG_REG_R8, TCG_REG_R3),
tcg_opc_m1 (TCG_REG_P7, OPC_LD8_M1, TCG_REG_R1, TCG_REG_R2),
tcg_opc_i18(TCG_REG_P0, OPC_NOP_I18, 0));
}
if (!bswap || s_bits == 0) {
tcg_out_bundle(s, miB,
tcg_opc_a5 (TCG_REG_P7, OPC_ADDL_A5, TCG_REG_R58,
mem_index, TCG_REG_R0),
tcg: initial ia64 support A few words about design choices: * On IA64, instructions should be grouped by bundle, and dependencies between instructions declared. A first version of this code tried to schedule instructions automatically, but was very complex and too invasive for the current common TCG code (ops not ending at instruction boundaries, code retranslation breaking already generated code, etc.) It was also not very efficient, as dependencies between TCG ops is not available. Instead the option taken by the current implementation does not try to fill the bundle by scheduling instructions, but by providing ops not available as an ia64 instruction, and by offering 22-bit constant loading for most of the instructions. With both options the bundle are filled at approximately the same level. * Up to 128 registers can be affected to a function on IA64, but TCG limits this number to 64, which is actually more than enough. The register affectation is the following: - r0: used to map a constant argument with value 0 - r1: global pointer - r2, r3: internal use - r4 to r6: not used to avoid saving them - r7: env structure - r8 to r11: free for TCG (call clobbered) - r12: stack pointer - r13: thread pointer - r14 to r31: free for TCG (call clobbered) - r32: reserved (return address) - r33: reserved (PFS) - r33 to r63: free for TCG * The IA64 architecture has only 64-bit registers and no 32-bit instructions (the only exception being cmp4). Therefore 64-bit registers and instructions are used for 32-bit ops. The adopted strategy is the same as the ABI, that is the higher 32 bits are undefined. Most ops (and, or, add, shl, etc.) can directly use the 64-bit registers, while some others have to sign-extend (sar, div, etc.) or zero-extend (shr, divu, etc.) the register first. Signed-off-by: Aurelien Jarno <aurelien@aurel32.net>
2010-03-29 04:12:51 +04:00
tcg_opc_i18(TCG_REG_P0, OPC_NOP_I18, 0),
tcg_opc_b5 (TCG_REG_P7, OPC_BR_CALL_SPTK_MANY_B5,
TCG_REG_B0, TCG_REG_B6));
} else {
tcg_out_bundle(s, miB,
tcg_opc_a5 (TCG_REG_P7, OPC_ADDL_A5, TCG_REG_R58,
mem_index, TCG_REG_R0),
tcg: initial ia64 support A few words about design choices: * On IA64, instructions should be grouped by bundle, and dependencies between instructions declared. A first version of this code tried to schedule instructions automatically, but was very complex and too invasive for the current common TCG code (ops not ending at instruction boundaries, code retranslation breaking already generated code, etc.) It was also not very efficient, as dependencies between TCG ops is not available. Instead the option taken by the current implementation does not try to fill the bundle by scheduling instructions, but by providing ops not available as an ia64 instruction, and by offering 22-bit constant loading for most of the instructions. With both options the bundle are filled at approximately the same level. * Up to 128 registers can be affected to a function on IA64, but TCG limits this number to 64, which is actually more than enough. The register affectation is the following: - r0: used to map a constant argument with value 0 - r1: global pointer - r2, r3: internal use - r4 to r6: not used to avoid saving them - r7: env structure - r8 to r11: free for TCG (call clobbered) - r12: stack pointer - r13: thread pointer - r14 to r31: free for TCG (call clobbered) - r32: reserved (return address) - r33: reserved (PFS) - r33 to r63: free for TCG * The IA64 architecture has only 64-bit registers and no 32-bit instructions (the only exception being cmp4). Therefore 64-bit registers and instructions are used for 32-bit ops. The adopted strategy is the same as the ABI, that is the higher 32 bits are undefined. Most ops (and, or, add, shl, etc.) can directly use the 64-bit registers, while some others have to sign-extend (sar, div, etc.) or zero-extend (shr, divu, etc.) the register first. Signed-off-by: Aurelien Jarno <aurelien@aurel32.net>
2010-03-29 04:12:51 +04:00
tcg_opc_i3 (TCG_REG_P6, OPC_MUX1_I3,
TCG_REG_R8, TCG_REG_R8, 0xb),
tcg_opc_b5 (TCG_REG_P7, OPC_BR_CALL_SPTK_MANY_B5,
TCG_REG_B0, TCG_REG_B6));
}
if (opc == 3) {
tcg_out_bundle(s, miI,
tcg_opc_m48(TCG_REG_P0, OPC_NOP_M48, 0),
tcg_opc_i18(TCG_REG_P0, OPC_NOP_I18, 0),
tcg_opc_a4 (TCG_REG_P0, OPC_ADDS_A4,
data_reg, 0, TCG_REG_R8));
} else {
tcg_out_bundle(s, miI,
tcg_opc_m48(TCG_REG_P0, OPC_NOP_M48, 0),
tcg_opc_i18(TCG_REG_P0, OPC_NOP_I18, 0),
tcg_opc_i29(TCG_REG_P0, opc_ext_i29[opc],
data_reg, TCG_REG_R8));
}
}
/* helper signature: helper_st_mmu(CPUState *env, target_ulong addr,
uintxx_t val, int mmu_idx) */
static const void * const qemu_st_helpers[4] = {
helper_stb_mmu,
helper_stw_mmu,
helper_stl_mmu,
helper_stq_mmu,
};
tcg: initial ia64 support A few words about design choices: * On IA64, instructions should be grouped by bundle, and dependencies between instructions declared. A first version of this code tried to schedule instructions automatically, but was very complex and too invasive for the current common TCG code (ops not ending at instruction boundaries, code retranslation breaking already generated code, etc.) It was also not very efficient, as dependencies between TCG ops is not available. Instead the option taken by the current implementation does not try to fill the bundle by scheduling instructions, but by providing ops not available as an ia64 instruction, and by offering 22-bit constant loading for most of the instructions. With both options the bundle are filled at approximately the same level. * Up to 128 registers can be affected to a function on IA64, but TCG limits this number to 64, which is actually more than enough. The register affectation is the following: - r0: used to map a constant argument with value 0 - r1: global pointer - r2, r3: internal use - r4 to r6: not used to avoid saving them - r7: env structure - r8 to r11: free for TCG (call clobbered) - r12: stack pointer - r13: thread pointer - r14 to r31: free for TCG (call clobbered) - r32: reserved (return address) - r33: reserved (PFS) - r33 to r63: free for TCG * The IA64 architecture has only 64-bit registers and no 32-bit instructions (the only exception being cmp4). Therefore 64-bit registers and instructions are used for 32-bit ops. The adopted strategy is the same as the ABI, that is the higher 32 bits are undefined. Most ops (and, or, add, shl, etc.) can directly use the 64-bit registers, while some others have to sign-extend (sar, div, etc.) or zero-extend (shr, divu, etc.) the register first. Signed-off-by: Aurelien Jarno <aurelien@aurel32.net>
2010-03-29 04:12:51 +04:00
static inline void tcg_out_qemu_st(TCGContext *s, const TCGArg *args, int opc)
{
int addr_reg, data_reg, mem_index, bswap;
uint64_t opc_st_m4[4] = { OPC_ST1_M4, OPC_ST2_M4, OPC_ST4_M4, OPC_ST8_M4 };
data_reg = *args++;
addr_reg = *args++;
mem_index = *args;
#ifdef TARGET_WORDS_BIGENDIAN
bswap = 1;
#else
bswap = 0;
#endif
tcg_out_qemu_tlb(s, addr_reg, opc,
offsetof(CPUArchState, tlb_table[mem_index][0].addr_write),
offsetof(CPUArchState, tlb_table[mem_index][0].addend));
tcg: initial ia64 support A few words about design choices: * On IA64, instructions should be grouped by bundle, and dependencies between instructions declared. A first version of this code tried to schedule instructions automatically, but was very complex and too invasive for the current common TCG code (ops not ending at instruction boundaries, code retranslation breaking already generated code, etc.) It was also not very efficient, as dependencies between TCG ops is not available. Instead the option taken by the current implementation does not try to fill the bundle by scheduling instructions, but by providing ops not available as an ia64 instruction, and by offering 22-bit constant loading for most of the instructions. With both options the bundle are filled at approximately the same level. * Up to 128 registers can be affected to a function on IA64, but TCG limits this number to 64, which is actually more than enough. The register affectation is the following: - r0: used to map a constant argument with value 0 - r1: global pointer - r2, r3: internal use - r4 to r6: not used to avoid saving them - r7: env structure - r8 to r11: free for TCG (call clobbered) - r12: stack pointer - r13: thread pointer - r14 to r31: free for TCG (call clobbered) - r32: reserved (return address) - r33: reserved (PFS) - r33 to r63: free for TCG * The IA64 architecture has only 64-bit registers and no 32-bit instructions (the only exception being cmp4). Therefore 64-bit registers and instructions are used for 32-bit ops. The adopted strategy is the same as the ABI, that is the higher 32 bits are undefined. Most ops (and, or, add, shl, etc.) can directly use the 64-bit registers, while some others have to sign-extend (sar, div, etc.) or zero-extend (shr, divu, etc.) the register first. Signed-off-by: Aurelien Jarno <aurelien@aurel32.net>
2010-03-29 04:12:51 +04:00
/* P6 is the fast path, and P7 the slow path */
tcg_out_bundle(s, mLX,
tcg_opc_a4 (TCG_REG_P7, OPC_ADDS_A4,
TCG_REG_R56, 0, TCG_AREG0),
tcg: initial ia64 support A few words about design choices: * On IA64, instructions should be grouped by bundle, and dependencies between instructions declared. A first version of this code tried to schedule instructions automatically, but was very complex and too invasive for the current common TCG code (ops not ending at instruction boundaries, code retranslation breaking already generated code, etc.) It was also not very efficient, as dependencies between TCG ops is not available. Instead the option taken by the current implementation does not try to fill the bundle by scheduling instructions, but by providing ops not available as an ia64 instruction, and by offering 22-bit constant loading for most of the instructions. With both options the bundle are filled at approximately the same level. * Up to 128 registers can be affected to a function on IA64, but TCG limits this number to 64, which is actually more than enough. The register affectation is the following: - r0: used to map a constant argument with value 0 - r1: global pointer - r2, r3: internal use - r4 to r6: not used to avoid saving them - r7: env structure - r8 to r11: free for TCG (call clobbered) - r12: stack pointer - r13: thread pointer - r14 to r31: free for TCG (call clobbered) - r32: reserved (return address) - r33: reserved (PFS) - r33 to r63: free for TCG * The IA64 architecture has only 64-bit registers and no 32-bit instructions (the only exception being cmp4). Therefore 64-bit registers and instructions are used for 32-bit ops. The adopted strategy is the same as the ABI, that is the higher 32 bits are undefined. Most ops (and, or, add, shl, etc.) can directly use the 64-bit registers, while some others have to sign-extend (sar, div, etc.) or zero-extend (shr, divu, etc.) the register first. Signed-off-by: Aurelien Jarno <aurelien@aurel32.net>
2010-03-29 04:12:51 +04:00
tcg_opc_l2 ((tcg_target_long) qemu_st_helpers[opc]),
tcg_opc_x2 (TCG_REG_P7, OPC_MOVL_X2, TCG_REG_R2,
(tcg_target_long) qemu_st_helpers[opc]));
tcg_out_bundle(s, MmI,
tcg_opc_m3 (TCG_REG_P0, OPC_LD8_M3, TCG_REG_R3,
TCG_REG_R2, 8),
tcg_opc_a1 (TCG_REG_P6, OPC_ADD_A1, TCG_REG_R3,
TCG_REG_R3, TCG_REG_R57),
tcg: initial ia64 support A few words about design choices: * On IA64, instructions should be grouped by bundle, and dependencies between instructions declared. A first version of this code tried to schedule instructions automatically, but was very complex and too invasive for the current common TCG code (ops not ending at instruction boundaries, code retranslation breaking already generated code, etc.) It was also not very efficient, as dependencies between TCG ops is not available. Instead the option taken by the current implementation does not try to fill the bundle by scheduling instructions, but by providing ops not available as an ia64 instruction, and by offering 22-bit constant loading for most of the instructions. With both options the bundle are filled at approximately the same level. * Up to 128 registers can be affected to a function on IA64, but TCG limits this number to 64, which is actually more than enough. The register affectation is the following: - r0: used to map a constant argument with value 0 - r1: global pointer - r2, r3: internal use - r4 to r6: not used to avoid saving them - r7: env structure - r8 to r11: free for TCG (call clobbered) - r12: stack pointer - r13: thread pointer - r14 to r31: free for TCG (call clobbered) - r32: reserved (return address) - r33: reserved (PFS) - r33 to r63: free for TCG * The IA64 architecture has only 64-bit registers and no 32-bit instructions (the only exception being cmp4). Therefore 64-bit registers and instructions are used for 32-bit ops. The adopted strategy is the same as the ABI, that is the higher 32 bits are undefined. Most ops (and, or, add, shl, etc.) can directly use the 64-bit registers, while some others have to sign-extend (sar, div, etc.) or zero-extend (shr, divu, etc.) the register first. Signed-off-by: Aurelien Jarno <aurelien@aurel32.net>
2010-03-29 04:12:51 +04:00
tcg_opc_i21(TCG_REG_P7, OPC_MOV_I21, TCG_REG_B6,
TCG_REG_R3, 0));
if (!bswap || opc == 0) {
tcg_out_bundle(s, mii,
tcg: initial ia64 support A few words about design choices: * On IA64, instructions should be grouped by bundle, and dependencies between instructions declared. A first version of this code tried to schedule instructions automatically, but was very complex and too invasive for the current common TCG code (ops not ending at instruction boundaries, code retranslation breaking already generated code, etc.) It was also not very efficient, as dependencies between TCG ops is not available. Instead the option taken by the current implementation does not try to fill the bundle by scheduling instructions, but by providing ops not available as an ia64 instruction, and by offering 22-bit constant loading for most of the instructions. With both options the bundle are filled at approximately the same level. * Up to 128 registers can be affected to a function on IA64, but TCG limits this number to 64, which is actually more than enough. The register affectation is the following: - r0: used to map a constant argument with value 0 - r1: global pointer - r2, r3: internal use - r4 to r6: not used to avoid saving them - r7: env structure - r8 to r11: free for TCG (call clobbered) - r12: stack pointer - r13: thread pointer - r14 to r31: free for TCG (call clobbered) - r32: reserved (return address) - r33: reserved (PFS) - r33 to r63: free for TCG * The IA64 architecture has only 64-bit registers and no 32-bit instructions (the only exception being cmp4). Therefore 64-bit registers and instructions are used for 32-bit ops. The adopted strategy is the same as the ABI, that is the higher 32 bits are undefined. Most ops (and, or, add, shl, etc.) can directly use the 64-bit registers, while some others have to sign-extend (sar, div, etc.) or zero-extend (shr, divu, etc.) the register first. Signed-off-by: Aurelien Jarno <aurelien@aurel32.net>
2010-03-29 04:12:51 +04:00
tcg_opc_m1 (TCG_REG_P7, OPC_LD8_M1,
TCG_REG_R1, TCG_REG_R2),
tcg_opc_a4 (TCG_REG_P7, OPC_ADDS_A4, TCG_REG_R58,
0, data_reg),
tcg: initial ia64 support A few words about design choices: * On IA64, instructions should be grouped by bundle, and dependencies between instructions declared. A first version of this code tried to schedule instructions automatically, but was very complex and too invasive for the current common TCG code (ops not ending at instruction boundaries, code retranslation breaking already generated code, etc.) It was also not very efficient, as dependencies between TCG ops is not available. Instead the option taken by the current implementation does not try to fill the bundle by scheduling instructions, but by providing ops not available as an ia64 instruction, and by offering 22-bit constant loading for most of the instructions. With both options the bundle are filled at approximately the same level. * Up to 128 registers can be affected to a function on IA64, but TCG limits this number to 64, which is actually more than enough. The register affectation is the following: - r0: used to map a constant argument with value 0 - r1: global pointer - r2, r3: internal use - r4 to r6: not used to avoid saving them - r7: env structure - r8 to r11: free for TCG (call clobbered) - r12: stack pointer - r13: thread pointer - r14 to r31: free for TCG (call clobbered) - r32: reserved (return address) - r33: reserved (PFS) - r33 to r63: free for TCG * The IA64 architecture has only 64-bit registers and no 32-bit instructions (the only exception being cmp4). Therefore 64-bit registers and instructions are used for 32-bit ops. The adopted strategy is the same as the ABI, that is the higher 32 bits are undefined. Most ops (and, or, add, shl, etc.) can directly use the 64-bit registers, while some others have to sign-extend (sar, div, etc.) or zero-extend (shr, divu, etc.) the register first. Signed-off-by: Aurelien Jarno <aurelien@aurel32.net>
2010-03-29 04:12:51 +04:00
tcg_opc_i18(TCG_REG_P0, OPC_NOP_I18, 0));
} else if (opc == 1) {
tcg_out_bundle(s, miI,
tcg: initial ia64 support A few words about design choices: * On IA64, instructions should be grouped by bundle, and dependencies between instructions declared. A first version of this code tried to schedule instructions automatically, but was very complex and too invasive for the current common TCG code (ops not ending at instruction boundaries, code retranslation breaking already generated code, etc.) It was also not very efficient, as dependencies between TCG ops is not available. Instead the option taken by the current implementation does not try to fill the bundle by scheduling instructions, but by providing ops not available as an ia64 instruction, and by offering 22-bit constant loading for most of the instructions. With both options the bundle are filled at approximately the same level. * Up to 128 registers can be affected to a function on IA64, but TCG limits this number to 64, which is actually more than enough. The register affectation is the following: - r0: used to map a constant argument with value 0 - r1: global pointer - r2, r3: internal use - r4 to r6: not used to avoid saving them - r7: env structure - r8 to r11: free for TCG (call clobbered) - r12: stack pointer - r13: thread pointer - r14 to r31: free for TCG (call clobbered) - r32: reserved (return address) - r33: reserved (PFS) - r33 to r63: free for TCG * The IA64 architecture has only 64-bit registers and no 32-bit instructions (the only exception being cmp4). Therefore 64-bit registers and instructions are used for 32-bit ops. The adopted strategy is the same as the ABI, that is the higher 32 bits are undefined. Most ops (and, or, add, shl, etc.) can directly use the 64-bit registers, while some others have to sign-extend (sar, div, etc.) or zero-extend (shr, divu, etc.) the register first. Signed-off-by: Aurelien Jarno <aurelien@aurel32.net>
2010-03-29 04:12:51 +04:00
tcg_opc_m1 (TCG_REG_P7, OPC_LD8_M1,
TCG_REG_R1, TCG_REG_R2),
tcg_opc_i18(TCG_REG_P0, OPC_NOP_I18, 0),
tcg: initial ia64 support A few words about design choices: * On IA64, instructions should be grouped by bundle, and dependencies between instructions declared. A first version of this code tried to schedule instructions automatically, but was very complex and too invasive for the current common TCG code (ops not ending at instruction boundaries, code retranslation breaking already generated code, etc.) It was also not very efficient, as dependencies between TCG ops is not available. Instead the option taken by the current implementation does not try to fill the bundle by scheduling instructions, but by providing ops not available as an ia64 instruction, and by offering 22-bit constant loading for most of the instructions. With both options the bundle are filled at approximately the same level. * Up to 128 registers can be affected to a function on IA64, but TCG limits this number to 64, which is actually more than enough. The register affectation is the following: - r0: used to map a constant argument with value 0 - r1: global pointer - r2, r3: internal use - r4 to r6: not used to avoid saving them - r7: env structure - r8 to r11: free for TCG (call clobbered) - r12: stack pointer - r13: thread pointer - r14 to r31: free for TCG (call clobbered) - r32: reserved (return address) - r33: reserved (PFS) - r33 to r63: free for TCG * The IA64 architecture has only 64-bit registers and no 32-bit instructions (the only exception being cmp4). Therefore 64-bit registers and instructions are used for 32-bit ops. The adopted strategy is the same as the ABI, that is the higher 32 bits are undefined. Most ops (and, or, add, shl, etc.) can directly use the 64-bit registers, while some others have to sign-extend (sar, div, etc.) or zero-extend (shr, divu, etc.) the register first. Signed-off-by: Aurelien Jarno <aurelien@aurel32.net>
2010-03-29 04:12:51 +04:00
tcg_opc_i12(TCG_REG_P6, OPC_DEP_Z_I12,
TCG_REG_R2, data_reg, 15, 15));
tcg_out_bundle(s, miI,
tcg_opc_a4 (TCG_REG_P7, OPC_ADDS_A4, TCG_REG_R58,
0, data_reg),
tcg_opc_i18(TCG_REG_P0, OPC_NOP_I18, 0),
tcg: initial ia64 support A few words about design choices: * On IA64, instructions should be grouped by bundle, and dependencies between instructions declared. A first version of this code tried to schedule instructions automatically, but was very complex and too invasive for the current common TCG code (ops not ending at instruction boundaries, code retranslation breaking already generated code, etc.) It was also not very efficient, as dependencies between TCG ops is not available. Instead the option taken by the current implementation does not try to fill the bundle by scheduling instructions, but by providing ops not available as an ia64 instruction, and by offering 22-bit constant loading for most of the instructions. With both options the bundle are filled at approximately the same level. * Up to 128 registers can be affected to a function on IA64, but TCG limits this number to 64, which is actually more than enough. The register affectation is the following: - r0: used to map a constant argument with value 0 - r1: global pointer - r2, r3: internal use - r4 to r6: not used to avoid saving them - r7: env structure - r8 to r11: free for TCG (call clobbered) - r12: stack pointer - r13: thread pointer - r14 to r31: free for TCG (call clobbered) - r32: reserved (return address) - r33: reserved (PFS) - r33 to r63: free for TCG * The IA64 architecture has only 64-bit registers and no 32-bit instructions (the only exception being cmp4). Therefore 64-bit registers and instructions are used for 32-bit ops. The adopted strategy is the same as the ABI, that is the higher 32 bits are undefined. Most ops (and, or, add, shl, etc.) can directly use the 64-bit registers, while some others have to sign-extend (sar, div, etc.) or zero-extend (shr, divu, etc.) the register first. Signed-off-by: Aurelien Jarno <aurelien@aurel32.net>
2010-03-29 04:12:51 +04:00
tcg_opc_i3 (TCG_REG_P6, OPC_MUX1_I3,
TCG_REG_R2, TCG_REG_R2, 0xb));
data_reg = TCG_REG_R2;
} else if (opc == 2) {
tcg_out_bundle(s, miI,
tcg: initial ia64 support A few words about design choices: * On IA64, instructions should be grouped by bundle, and dependencies between instructions declared. A first version of this code tried to schedule instructions automatically, but was very complex and too invasive for the current common TCG code (ops not ending at instruction boundaries, code retranslation breaking already generated code, etc.) It was also not very efficient, as dependencies between TCG ops is not available. Instead the option taken by the current implementation does not try to fill the bundle by scheduling instructions, but by providing ops not available as an ia64 instruction, and by offering 22-bit constant loading for most of the instructions. With both options the bundle are filled at approximately the same level. * Up to 128 registers can be affected to a function on IA64, but TCG limits this number to 64, which is actually more than enough. The register affectation is the following: - r0: used to map a constant argument with value 0 - r1: global pointer - r2, r3: internal use - r4 to r6: not used to avoid saving them - r7: env structure - r8 to r11: free for TCG (call clobbered) - r12: stack pointer - r13: thread pointer - r14 to r31: free for TCG (call clobbered) - r32: reserved (return address) - r33: reserved (PFS) - r33 to r63: free for TCG * The IA64 architecture has only 64-bit registers and no 32-bit instructions (the only exception being cmp4). Therefore 64-bit registers and instructions are used for 32-bit ops. The adopted strategy is the same as the ABI, that is the higher 32 bits are undefined. Most ops (and, or, add, shl, etc.) can directly use the 64-bit registers, while some others have to sign-extend (sar, div, etc.) or zero-extend (shr, divu, etc.) the register first. Signed-off-by: Aurelien Jarno <aurelien@aurel32.net>
2010-03-29 04:12:51 +04:00
tcg_opc_m1 (TCG_REG_P7, OPC_LD8_M1,
TCG_REG_R1, TCG_REG_R2),
tcg_opc_i18(TCG_REG_P0, OPC_NOP_I18, 0),
tcg: initial ia64 support A few words about design choices: * On IA64, instructions should be grouped by bundle, and dependencies between instructions declared. A first version of this code tried to schedule instructions automatically, but was very complex and too invasive for the current common TCG code (ops not ending at instruction boundaries, code retranslation breaking already generated code, etc.) It was also not very efficient, as dependencies between TCG ops is not available. Instead the option taken by the current implementation does not try to fill the bundle by scheduling instructions, but by providing ops not available as an ia64 instruction, and by offering 22-bit constant loading for most of the instructions. With both options the bundle are filled at approximately the same level. * Up to 128 registers can be affected to a function on IA64, but TCG limits this number to 64, which is actually more than enough. The register affectation is the following: - r0: used to map a constant argument with value 0 - r1: global pointer - r2, r3: internal use - r4 to r6: not used to avoid saving them - r7: env structure - r8 to r11: free for TCG (call clobbered) - r12: stack pointer - r13: thread pointer - r14 to r31: free for TCG (call clobbered) - r32: reserved (return address) - r33: reserved (PFS) - r33 to r63: free for TCG * The IA64 architecture has only 64-bit registers and no 32-bit instructions (the only exception being cmp4). Therefore 64-bit registers and instructions are used for 32-bit ops. The adopted strategy is the same as the ABI, that is the higher 32 bits are undefined. Most ops (and, or, add, shl, etc.) can directly use the 64-bit registers, while some others have to sign-extend (sar, div, etc.) or zero-extend (shr, divu, etc.) the register first. Signed-off-by: Aurelien Jarno <aurelien@aurel32.net>
2010-03-29 04:12:51 +04:00
tcg_opc_i12(TCG_REG_P6, OPC_DEP_Z_I12,
TCG_REG_R2, data_reg, 31, 31));
tcg_out_bundle(s, miI,
tcg_opc_a4 (TCG_REG_P7, OPC_ADDS_A4, TCG_REG_R58,
0, data_reg),
tcg_opc_i18(TCG_REG_P0, OPC_NOP_I18, 0),
tcg: initial ia64 support A few words about design choices: * On IA64, instructions should be grouped by bundle, and dependencies between instructions declared. A first version of this code tried to schedule instructions automatically, but was very complex and too invasive for the current common TCG code (ops not ending at instruction boundaries, code retranslation breaking already generated code, etc.) It was also not very efficient, as dependencies between TCG ops is not available. Instead the option taken by the current implementation does not try to fill the bundle by scheduling instructions, but by providing ops not available as an ia64 instruction, and by offering 22-bit constant loading for most of the instructions. With both options the bundle are filled at approximately the same level. * Up to 128 registers can be affected to a function on IA64, but TCG limits this number to 64, which is actually more than enough. The register affectation is the following: - r0: used to map a constant argument with value 0 - r1: global pointer - r2, r3: internal use - r4 to r6: not used to avoid saving them - r7: env structure - r8 to r11: free for TCG (call clobbered) - r12: stack pointer - r13: thread pointer - r14 to r31: free for TCG (call clobbered) - r32: reserved (return address) - r33: reserved (PFS) - r33 to r63: free for TCG * The IA64 architecture has only 64-bit registers and no 32-bit instructions (the only exception being cmp4). Therefore 64-bit registers and instructions are used for 32-bit ops. The adopted strategy is the same as the ABI, that is the higher 32 bits are undefined. Most ops (and, or, add, shl, etc.) can directly use the 64-bit registers, while some others have to sign-extend (sar, div, etc.) or zero-extend (shr, divu, etc.) the register first. Signed-off-by: Aurelien Jarno <aurelien@aurel32.net>
2010-03-29 04:12:51 +04:00
tcg_opc_i3 (TCG_REG_P6, OPC_MUX1_I3,
TCG_REG_R2, TCG_REG_R2, 0xb));
data_reg = TCG_REG_R2;
} else if (opc == 3) {
tcg_out_bundle(s, miI,
tcg_opc_m1 (TCG_REG_P7, OPC_LD8_M1,
TCG_REG_R1, TCG_REG_R2),
tcg_opc_a4 (TCG_REG_P7, OPC_ADDS_A4, TCG_REG_R58,
0, data_reg),
tcg: initial ia64 support A few words about design choices: * On IA64, instructions should be grouped by bundle, and dependencies between instructions declared. A first version of this code tried to schedule instructions automatically, but was very complex and too invasive for the current common TCG code (ops not ending at instruction boundaries, code retranslation breaking already generated code, etc.) It was also not very efficient, as dependencies between TCG ops is not available. Instead the option taken by the current implementation does not try to fill the bundle by scheduling instructions, but by providing ops not available as an ia64 instruction, and by offering 22-bit constant loading for most of the instructions. With both options the bundle are filled at approximately the same level. * Up to 128 registers can be affected to a function on IA64, but TCG limits this number to 64, which is actually more than enough. The register affectation is the following: - r0: used to map a constant argument with value 0 - r1: global pointer - r2, r3: internal use - r4 to r6: not used to avoid saving them - r7: env structure - r8 to r11: free for TCG (call clobbered) - r12: stack pointer - r13: thread pointer - r14 to r31: free for TCG (call clobbered) - r32: reserved (return address) - r33: reserved (PFS) - r33 to r63: free for TCG * The IA64 architecture has only 64-bit registers and no 32-bit instructions (the only exception being cmp4). Therefore 64-bit registers and instructions are used for 32-bit ops. The adopted strategy is the same as the ABI, that is the higher 32 bits are undefined. Most ops (and, or, add, shl, etc.) can directly use the 64-bit registers, while some others have to sign-extend (sar, div, etc.) or zero-extend (shr, divu, etc.) the register first. Signed-off-by: Aurelien Jarno <aurelien@aurel32.net>
2010-03-29 04:12:51 +04:00
tcg_opc_i3 (TCG_REG_P6, OPC_MUX1_I3,
TCG_REG_R2, data_reg, 0xb));
data_reg = TCG_REG_R2;
}
tcg_out_bundle(s, miB,
tcg_opc_m4 (TCG_REG_P6, opc_st_m4[opc],
data_reg, TCG_REG_R3),
tcg_opc_a5 (TCG_REG_P7, OPC_ADDL_A5, TCG_REG_R59,
mem_index, TCG_REG_R0),
tcg_opc_b5 (TCG_REG_P7, OPC_BR_CALL_SPTK_MANY_B5,
TCG_REG_B0, TCG_REG_B6));
tcg: initial ia64 support A few words about design choices: * On IA64, instructions should be grouped by bundle, and dependencies between instructions declared. A first version of this code tried to schedule instructions automatically, but was very complex and too invasive for the current common TCG code (ops not ending at instruction boundaries, code retranslation breaking already generated code, etc.) It was also not very efficient, as dependencies between TCG ops is not available. Instead the option taken by the current implementation does not try to fill the bundle by scheduling instructions, but by providing ops not available as an ia64 instruction, and by offering 22-bit constant loading for most of the instructions. With both options the bundle are filled at approximately the same level. * Up to 128 registers can be affected to a function on IA64, but TCG limits this number to 64, which is actually more than enough. The register affectation is the following: - r0: used to map a constant argument with value 0 - r1: global pointer - r2, r3: internal use - r4 to r6: not used to avoid saving them - r7: env structure - r8 to r11: free for TCG (call clobbered) - r12: stack pointer - r13: thread pointer - r14 to r31: free for TCG (call clobbered) - r32: reserved (return address) - r33: reserved (PFS) - r33 to r63: free for TCG * The IA64 architecture has only 64-bit registers and no 32-bit instructions (the only exception being cmp4). Therefore 64-bit registers and instructions are used for 32-bit ops. The adopted strategy is the same as the ABI, that is the higher 32 bits are undefined. Most ops (and, or, add, shl, etc.) can directly use the 64-bit registers, while some others have to sign-extend (sar, div, etc.) or zero-extend (shr, divu, etc.) the register first. Signed-off-by: Aurelien Jarno <aurelien@aurel32.net>
2010-03-29 04:12:51 +04:00
}
#else /* !CONFIG_SOFTMMU */
static inline void tcg_out_qemu_ld(TCGContext *s, const TCGArg *args, int opc)
{
static uint64_t const opc_ld_m1[4] = {
OPC_LD1_M1, OPC_LD2_M1, OPC_LD4_M1, OPC_LD8_M1
};
static uint64_t const opc_sxt_i29[4] = {
OPC_SXT1_I29, OPC_SXT2_I29, OPC_SXT4_I29, 0
};
int addr_reg, data_reg, s_bits, bswap;
tcg: initial ia64 support A few words about design choices: * On IA64, instructions should be grouped by bundle, and dependencies between instructions declared. A first version of this code tried to schedule instructions automatically, but was very complex and too invasive for the current common TCG code (ops not ending at instruction boundaries, code retranslation breaking already generated code, etc.) It was also not very efficient, as dependencies between TCG ops is not available. Instead the option taken by the current implementation does not try to fill the bundle by scheduling instructions, but by providing ops not available as an ia64 instruction, and by offering 22-bit constant loading for most of the instructions. With both options the bundle are filled at approximately the same level. * Up to 128 registers can be affected to a function on IA64, but TCG limits this number to 64, which is actually more than enough. The register affectation is the following: - r0: used to map a constant argument with value 0 - r1: global pointer - r2, r3: internal use - r4 to r6: not used to avoid saving them - r7: env structure - r8 to r11: free for TCG (call clobbered) - r12: stack pointer - r13: thread pointer - r14 to r31: free for TCG (call clobbered) - r32: reserved (return address) - r33: reserved (PFS) - r33 to r63: free for TCG * The IA64 architecture has only 64-bit registers and no 32-bit instructions (the only exception being cmp4). Therefore 64-bit registers and instructions are used for 32-bit ops. The adopted strategy is the same as the ABI, that is the higher 32 bits are undefined. Most ops (and, or, add, shl, etc.) can directly use the 64-bit registers, while some others have to sign-extend (sar, div, etc.) or zero-extend (shr, divu, etc.) the register first. Signed-off-by: Aurelien Jarno <aurelien@aurel32.net>
2010-03-29 04:12:51 +04:00
data_reg = *args++;
addr_reg = *args++;
s_bits = opc & 3;
#ifdef TARGET_WORDS_BIGENDIAN
bswap = 1;
#else
bswap = 0;
#endif
#if TARGET_LONG_BITS == 32
if (GUEST_BASE != 0) {
tcg_out_bundle(s, mII,
tcg_opc_m48(TCG_REG_P0, OPC_NOP_M48, 0),
tcg_opc_i29(TCG_REG_P0, OPC_ZXT4_I29,
TCG_REG_R3, addr_reg),
tcg_opc_a1 (TCG_REG_P0, OPC_ADD_A1, TCG_REG_R2,
TCG_GUEST_BASE_REG, TCG_REG_R3));
} else {
tcg_out_bundle(s, miI,
tcg_opc_m48(TCG_REG_P0, OPC_NOP_M48, 0),
tcg_opc_i29(TCG_REG_P0, OPC_ZXT4_I29,
TCG_REG_R2, addr_reg),
tcg_opc_i18(TCG_REG_P0, OPC_NOP_I18, 0));
}
tcg: initial ia64 support A few words about design choices: * On IA64, instructions should be grouped by bundle, and dependencies between instructions declared. A first version of this code tried to schedule instructions automatically, but was very complex and too invasive for the current common TCG code (ops not ending at instruction boundaries, code retranslation breaking already generated code, etc.) It was also not very efficient, as dependencies between TCG ops is not available. Instead the option taken by the current implementation does not try to fill the bundle by scheduling instructions, but by providing ops not available as an ia64 instruction, and by offering 22-bit constant loading for most of the instructions. With both options the bundle are filled at approximately the same level. * Up to 128 registers can be affected to a function on IA64, but TCG limits this number to 64, which is actually more than enough. The register affectation is the following: - r0: used to map a constant argument with value 0 - r1: global pointer - r2, r3: internal use - r4 to r6: not used to avoid saving them - r7: env structure - r8 to r11: free for TCG (call clobbered) - r12: stack pointer - r13: thread pointer - r14 to r31: free for TCG (call clobbered) - r32: reserved (return address) - r33: reserved (PFS) - r33 to r63: free for TCG * The IA64 architecture has only 64-bit registers and no 32-bit instructions (the only exception being cmp4). Therefore 64-bit registers and instructions are used for 32-bit ops. The adopted strategy is the same as the ABI, that is the higher 32 bits are undefined. Most ops (and, or, add, shl, etc.) can directly use the 64-bit registers, while some others have to sign-extend (sar, div, etc.) or zero-extend (shr, divu, etc.) the register first. Signed-off-by: Aurelien Jarno <aurelien@aurel32.net>
2010-03-29 04:12:51 +04:00
if (!bswap || s_bits == 0) {
if (s_bits == opc) {
tcg_out_bundle(s, miI,
tcg_opc_m1 (TCG_REG_P0, opc_ld_m1[s_bits],
data_reg, TCG_REG_R2),
tcg_opc_i18(TCG_REG_P0, OPC_NOP_I18, 0),
tcg_opc_i18(TCG_REG_P0, OPC_NOP_I18, 0));
} else {
tcg_out_bundle(s, mII,
tcg_opc_m1 (TCG_REG_P0, opc_ld_m1[s_bits],
data_reg, TCG_REG_R2),
tcg_opc_i18(TCG_REG_P0, OPC_NOP_I18, 0),
tcg_opc_i29(TCG_REG_P0, opc_sxt_i29[s_bits],
data_reg, data_reg));
}
} else if (s_bits == 3) {
tcg_out_bundle(s, mII,
tcg_opc_m1 (TCG_REG_P0, opc_ld_m1[s_bits],
data_reg, TCG_REG_R2),
tcg_opc_i18(TCG_REG_P0, OPC_NOP_I18, 0),
tcg_opc_i3 (TCG_REG_P0, OPC_MUX1_I3,
data_reg, data_reg, 0xb));
} else {
if (s_bits == 1) {
tcg_out_bundle(s, mII,
tcg_opc_m1 (TCG_REG_P0, opc_ld_m1[s_bits],
data_reg, TCG_REG_R2),
tcg_opc_i18(TCG_REG_P0, OPC_NOP_I18, 0),
tcg_opc_i12(TCG_REG_P0, OPC_DEP_Z_I12,
data_reg, data_reg, 15, 15));
} else {
tcg_out_bundle(s, mII,
tcg_opc_m1 (TCG_REG_P0, opc_ld_m1[s_bits],
data_reg, TCG_REG_R2),
tcg_opc_i18(TCG_REG_P0, OPC_NOP_I18, 0),
tcg_opc_i12(TCG_REG_P0, OPC_DEP_Z_I12,
data_reg, data_reg, 31, 31));
}
if (opc == s_bits) {
tcg_out_bundle(s, miI,
tcg_opc_m48(TCG_REG_P0, OPC_NOP_M48, 0),
tcg_opc_i18(TCG_REG_P0, OPC_NOP_I18, 0),
tcg_opc_i3 (TCG_REG_P0, OPC_MUX1_I3,
data_reg, data_reg, 0xb));
} else {
tcg_out_bundle(s, mII,
tcg_opc_m48(TCG_REG_P0, OPC_NOP_M48, 0),
tcg_opc_i3 (TCG_REG_P0, OPC_MUX1_I3,
data_reg, data_reg, 0xb),
tcg_opc_i29(TCG_REG_P0, opc_sxt_i29[s_bits],
data_reg, data_reg));
}
}
#else
if (GUEST_BASE != 0) {
tcg_out_bundle(s, MmI,
tcg_opc_a1 (TCG_REG_P0, OPC_ADD_A1, TCG_REG_R2,
TCG_GUEST_BASE_REG, addr_reg),
tcg_opc_m1 (TCG_REG_P0, opc_ld_m1[s_bits],
data_reg, TCG_REG_R2),
tcg_opc_i18(TCG_REG_P0, OPC_NOP_I18, 0));
} else {
tcg_out_bundle(s, mmI,
tcg_opc_m48(TCG_REG_P0, OPC_NOP_M48, 0),
tcg_opc_m1 (TCG_REG_P0, opc_ld_m1[s_bits],
data_reg, addr_reg),
tcg_opc_i18(TCG_REG_P0, OPC_NOP_I18, 0));
}
tcg: initial ia64 support A few words about design choices: * On IA64, instructions should be grouped by bundle, and dependencies between instructions declared. A first version of this code tried to schedule instructions automatically, but was very complex and too invasive for the current common TCG code (ops not ending at instruction boundaries, code retranslation breaking already generated code, etc.) It was also not very efficient, as dependencies between TCG ops is not available. Instead the option taken by the current implementation does not try to fill the bundle by scheduling instructions, but by providing ops not available as an ia64 instruction, and by offering 22-bit constant loading for most of the instructions. With both options the bundle are filled at approximately the same level. * Up to 128 registers can be affected to a function on IA64, but TCG limits this number to 64, which is actually more than enough. The register affectation is the following: - r0: used to map a constant argument with value 0 - r1: global pointer - r2, r3: internal use - r4 to r6: not used to avoid saving them - r7: env structure - r8 to r11: free for TCG (call clobbered) - r12: stack pointer - r13: thread pointer - r14 to r31: free for TCG (call clobbered) - r32: reserved (return address) - r33: reserved (PFS) - r33 to r63: free for TCG * The IA64 architecture has only 64-bit registers and no 32-bit instructions (the only exception being cmp4). Therefore 64-bit registers and instructions are used for 32-bit ops. The adopted strategy is the same as the ABI, that is the higher 32 bits are undefined. Most ops (and, or, add, shl, etc.) can directly use the 64-bit registers, while some others have to sign-extend (sar, div, etc.) or zero-extend (shr, divu, etc.) the register first. Signed-off-by: Aurelien Jarno <aurelien@aurel32.net>
2010-03-29 04:12:51 +04:00
if (bswap && s_bits == 1) {
tcg_out_bundle(s, mII,
tcg_opc_m48(TCG_REG_P0, OPC_NOP_M48, 0),
tcg_opc_i12(TCG_REG_P0, OPC_DEP_Z_I12,
data_reg, data_reg, 15, 15),
tcg_opc_i3 (TCG_REG_P0, OPC_MUX1_I3,
data_reg, data_reg, 0xb));
} else if (bswap && s_bits == 2) {
tcg_out_bundle(s, mII,
tcg_opc_m48(TCG_REG_P0, OPC_NOP_M48, 0),
tcg_opc_i12(TCG_REG_P0, OPC_DEP_Z_I12,
data_reg, data_reg, 31, 31),
tcg_opc_i3 (TCG_REG_P0, OPC_MUX1_I3,
data_reg, data_reg, 0xb));
} else if (bswap && s_bits == 3) {
tcg_out_bundle(s, miI,
tcg_opc_m48(TCG_REG_P0, OPC_NOP_M48, 0),
tcg_opc_i18(TCG_REG_P0, OPC_NOP_I18, 0),
tcg_opc_i3 (TCG_REG_P0, OPC_MUX1_I3,
data_reg, data_reg, 0xb));
}
if (s_bits != opc) {
tcg_out_bundle(s, miI,
tcg_opc_m48(TCG_REG_P0, OPC_NOP_M48, 0),
tcg_opc_i18(TCG_REG_P0, OPC_NOP_I18, 0),
tcg_opc_i29(TCG_REG_P0, opc_sxt_i29[s_bits],
data_reg, data_reg));
}
#endif
}
static inline void tcg_out_qemu_st(TCGContext *s, const TCGArg *args, int opc)
{
static uint64_t const opc_st_m4[4] = {
OPC_ST1_M4, OPC_ST2_M4, OPC_ST4_M4, OPC_ST8_M4
};
tcg: initial ia64 support A few words about design choices: * On IA64, instructions should be grouped by bundle, and dependencies between instructions declared. A first version of this code tried to schedule instructions automatically, but was very complex and too invasive for the current common TCG code (ops not ending at instruction boundaries, code retranslation breaking already generated code, etc.) It was also not very efficient, as dependencies between TCG ops is not available. Instead the option taken by the current implementation does not try to fill the bundle by scheduling instructions, but by providing ops not available as an ia64 instruction, and by offering 22-bit constant loading for most of the instructions. With both options the bundle are filled at approximately the same level. * Up to 128 registers can be affected to a function on IA64, but TCG limits this number to 64, which is actually more than enough. The register affectation is the following: - r0: used to map a constant argument with value 0 - r1: global pointer - r2, r3: internal use - r4 to r6: not used to avoid saving them - r7: env structure - r8 to r11: free for TCG (call clobbered) - r12: stack pointer - r13: thread pointer - r14 to r31: free for TCG (call clobbered) - r32: reserved (return address) - r33: reserved (PFS) - r33 to r63: free for TCG * The IA64 architecture has only 64-bit registers and no 32-bit instructions (the only exception being cmp4). Therefore 64-bit registers and instructions are used for 32-bit ops. The adopted strategy is the same as the ABI, that is the higher 32 bits are undefined. Most ops (and, or, add, shl, etc.) can directly use the 64-bit registers, while some others have to sign-extend (sar, div, etc.) or zero-extend (shr, divu, etc.) the register first. Signed-off-by: Aurelien Jarno <aurelien@aurel32.net>
2010-03-29 04:12:51 +04:00
int addr_reg, data_reg, bswap;
#if TARGET_LONG_BITS == 64
uint64_t add_guest_base;
#endif
tcg: initial ia64 support A few words about design choices: * On IA64, instructions should be grouped by bundle, and dependencies between instructions declared. A first version of this code tried to schedule instructions automatically, but was very complex and too invasive for the current common TCG code (ops not ending at instruction boundaries, code retranslation breaking already generated code, etc.) It was also not very efficient, as dependencies between TCG ops is not available. Instead the option taken by the current implementation does not try to fill the bundle by scheduling instructions, but by providing ops not available as an ia64 instruction, and by offering 22-bit constant loading for most of the instructions. With both options the bundle are filled at approximately the same level. * Up to 128 registers can be affected to a function on IA64, but TCG limits this number to 64, which is actually more than enough. The register affectation is the following: - r0: used to map a constant argument with value 0 - r1: global pointer - r2, r3: internal use - r4 to r6: not used to avoid saving them - r7: env structure - r8 to r11: free for TCG (call clobbered) - r12: stack pointer - r13: thread pointer - r14 to r31: free for TCG (call clobbered) - r32: reserved (return address) - r33: reserved (PFS) - r33 to r63: free for TCG * The IA64 architecture has only 64-bit registers and no 32-bit instructions (the only exception being cmp4). Therefore 64-bit registers and instructions are used for 32-bit ops. The adopted strategy is the same as the ABI, that is the higher 32 bits are undefined. Most ops (and, or, add, shl, etc.) can directly use the 64-bit registers, while some others have to sign-extend (sar, div, etc.) or zero-extend (shr, divu, etc.) the register first. Signed-off-by: Aurelien Jarno <aurelien@aurel32.net>
2010-03-29 04:12:51 +04:00
data_reg = *args++;
addr_reg = *args++;
#ifdef TARGET_WORDS_BIGENDIAN
bswap = 1;
#else
bswap = 0;
#endif
#if TARGET_LONG_BITS == 32
if (GUEST_BASE != 0) {
tcg_out_bundle(s, mII,
tcg_opc_m48(TCG_REG_P0, OPC_NOP_M48, 0),
tcg_opc_i29(TCG_REG_P0, OPC_ZXT4_I29,
TCG_REG_R3, addr_reg),
tcg_opc_a1 (TCG_REG_P0, OPC_ADD_A1, TCG_REG_R2,
TCG_GUEST_BASE_REG, TCG_REG_R3));
} else {
tcg_out_bundle(s, miI,
tcg_opc_m48(TCG_REG_P0, OPC_NOP_M48, 0),
tcg_opc_i29(TCG_REG_P0, OPC_ZXT4_I29,
TCG_REG_R2, addr_reg),
tcg_opc_i18(TCG_REG_P0, OPC_NOP_I18, 0));
}
tcg: initial ia64 support A few words about design choices: * On IA64, instructions should be grouped by bundle, and dependencies between instructions declared. A first version of this code tried to schedule instructions automatically, but was very complex and too invasive for the current common TCG code (ops not ending at instruction boundaries, code retranslation breaking already generated code, etc.) It was also not very efficient, as dependencies between TCG ops is not available. Instead the option taken by the current implementation does not try to fill the bundle by scheduling instructions, but by providing ops not available as an ia64 instruction, and by offering 22-bit constant loading for most of the instructions. With both options the bundle are filled at approximately the same level. * Up to 128 registers can be affected to a function on IA64, but TCG limits this number to 64, which is actually more than enough. The register affectation is the following: - r0: used to map a constant argument with value 0 - r1: global pointer - r2, r3: internal use - r4 to r6: not used to avoid saving them - r7: env structure - r8 to r11: free for TCG (call clobbered) - r12: stack pointer - r13: thread pointer - r14 to r31: free for TCG (call clobbered) - r32: reserved (return address) - r33: reserved (PFS) - r33 to r63: free for TCG * The IA64 architecture has only 64-bit registers and no 32-bit instructions (the only exception being cmp4). Therefore 64-bit registers and instructions are used for 32-bit ops. The adopted strategy is the same as the ABI, that is the higher 32 bits are undefined. Most ops (and, or, add, shl, etc.) can directly use the 64-bit registers, while some others have to sign-extend (sar, div, etc.) or zero-extend (shr, divu, etc.) the register first. Signed-off-by: Aurelien Jarno <aurelien@aurel32.net>
2010-03-29 04:12:51 +04:00
if (bswap) {
if (opc == 1) {
tcg_out_bundle(s, mII,
tcg_opc_m48(TCG_REG_P0, OPC_NOP_M48, 0),
tcg_opc_i12(TCG_REG_P0, OPC_DEP_Z_I12,
TCG_REG_R3, data_reg, 15, 15),
tcg_opc_i3 (TCG_REG_P0, OPC_MUX1_I3,
TCG_REG_R3, TCG_REG_R3, 0xb));
data_reg = TCG_REG_R3;
} else if (opc == 2) {
tcg_out_bundle(s, mII,
tcg_opc_m48(TCG_REG_P0, OPC_NOP_M48, 0),
tcg_opc_i12(TCG_REG_P0, OPC_DEP_Z_I12,
TCG_REG_R3, data_reg, 31, 31),
tcg_opc_i3 (TCG_REG_P0, OPC_MUX1_I3,
TCG_REG_R3, TCG_REG_R3, 0xb));
data_reg = TCG_REG_R3;
} else if (opc == 3) {
tcg_out_bundle(s, miI,
tcg_opc_m48(TCG_REG_P0, OPC_NOP_M48, 0),
tcg_opc_i18(TCG_REG_P0, OPC_NOP_I18, 0),
tcg_opc_i3 (TCG_REG_P0, OPC_MUX1_I3,
TCG_REG_R3, data_reg, 0xb));
data_reg = TCG_REG_R3;
}
}
tcg_out_bundle(s, mmI,
tcg_opc_m4 (TCG_REG_P0, opc_st_m4[opc],
data_reg, TCG_REG_R2),
tcg_opc_m48(TCG_REG_P0, OPC_NOP_M48, 0),
tcg_opc_i18(TCG_REG_P0, OPC_NOP_I18, 0));
#else
if (GUEST_BASE != 0) {
add_guest_base = tcg_opc_a1 (TCG_REG_P0, OPC_ADD_A1, TCG_REG_R2,
TCG_GUEST_BASE_REG, addr_reg);
addr_reg = TCG_REG_R2;
} else {
add_guest_base = tcg_opc_m48(TCG_REG_P0, OPC_NOP_M48, 0);
}
tcg: initial ia64 support A few words about design choices: * On IA64, instructions should be grouped by bundle, and dependencies between instructions declared. A first version of this code tried to schedule instructions automatically, but was very complex and too invasive for the current common TCG code (ops not ending at instruction boundaries, code retranslation breaking already generated code, etc.) It was also not very efficient, as dependencies between TCG ops is not available. Instead the option taken by the current implementation does not try to fill the bundle by scheduling instructions, but by providing ops not available as an ia64 instruction, and by offering 22-bit constant loading for most of the instructions. With both options the bundle are filled at approximately the same level. * Up to 128 registers can be affected to a function on IA64, but TCG limits this number to 64, which is actually more than enough. The register affectation is the following: - r0: used to map a constant argument with value 0 - r1: global pointer - r2, r3: internal use - r4 to r6: not used to avoid saving them - r7: env structure - r8 to r11: free for TCG (call clobbered) - r12: stack pointer - r13: thread pointer - r14 to r31: free for TCG (call clobbered) - r32: reserved (return address) - r33: reserved (PFS) - r33 to r63: free for TCG * The IA64 architecture has only 64-bit registers and no 32-bit instructions (the only exception being cmp4). Therefore 64-bit registers and instructions are used for 32-bit ops. The adopted strategy is the same as the ABI, that is the higher 32 bits are undefined. Most ops (and, or, add, shl, etc.) can directly use the 64-bit registers, while some others have to sign-extend (sar, div, etc.) or zero-extend (shr, divu, etc.) the register first. Signed-off-by: Aurelien Jarno <aurelien@aurel32.net>
2010-03-29 04:12:51 +04:00
if (!bswap || opc == 0) {
tcg_out_bundle(s, (GUEST_BASE ? MmI : mmI),
add_guest_base,
tcg: initial ia64 support A few words about design choices: * On IA64, instructions should be grouped by bundle, and dependencies between instructions declared. A first version of this code tried to schedule instructions automatically, but was very complex and too invasive for the current common TCG code (ops not ending at instruction boundaries, code retranslation breaking already generated code, etc.) It was also not very efficient, as dependencies between TCG ops is not available. Instead the option taken by the current implementation does not try to fill the bundle by scheduling instructions, but by providing ops not available as an ia64 instruction, and by offering 22-bit constant loading for most of the instructions. With both options the bundle are filled at approximately the same level. * Up to 128 registers can be affected to a function on IA64, but TCG limits this number to 64, which is actually more than enough. The register affectation is the following: - r0: used to map a constant argument with value 0 - r1: global pointer - r2, r3: internal use - r4 to r6: not used to avoid saving them - r7: env structure - r8 to r11: free for TCG (call clobbered) - r12: stack pointer - r13: thread pointer - r14 to r31: free for TCG (call clobbered) - r32: reserved (return address) - r33: reserved (PFS) - r33 to r63: free for TCG * The IA64 architecture has only 64-bit registers and no 32-bit instructions (the only exception being cmp4). Therefore 64-bit registers and instructions are used for 32-bit ops. The adopted strategy is the same as the ABI, that is the higher 32 bits are undefined. Most ops (and, or, add, shl, etc.) can directly use the 64-bit registers, while some others have to sign-extend (sar, div, etc.) or zero-extend (shr, divu, etc.) the register first. Signed-off-by: Aurelien Jarno <aurelien@aurel32.net>
2010-03-29 04:12:51 +04:00
tcg_opc_m4 (TCG_REG_P0, opc_st_m4[opc],
data_reg, addr_reg),
tcg: initial ia64 support A few words about design choices: * On IA64, instructions should be grouped by bundle, and dependencies between instructions declared. A first version of this code tried to schedule instructions automatically, but was very complex and too invasive for the current common TCG code (ops not ending at instruction boundaries, code retranslation breaking already generated code, etc.) It was also not very efficient, as dependencies between TCG ops is not available. Instead the option taken by the current implementation does not try to fill the bundle by scheduling instructions, but by providing ops not available as an ia64 instruction, and by offering 22-bit constant loading for most of the instructions. With both options the bundle are filled at approximately the same level. * Up to 128 registers can be affected to a function on IA64, but TCG limits this number to 64, which is actually more than enough. The register affectation is the following: - r0: used to map a constant argument with value 0 - r1: global pointer - r2, r3: internal use - r4 to r6: not used to avoid saving them - r7: env structure - r8 to r11: free for TCG (call clobbered) - r12: stack pointer - r13: thread pointer - r14 to r31: free for TCG (call clobbered) - r32: reserved (return address) - r33: reserved (PFS) - r33 to r63: free for TCG * The IA64 architecture has only 64-bit registers and no 32-bit instructions (the only exception being cmp4). Therefore 64-bit registers and instructions are used for 32-bit ops. The adopted strategy is the same as the ABI, that is the higher 32 bits are undefined. Most ops (and, or, add, shl, etc.) can directly use the 64-bit registers, while some others have to sign-extend (sar, div, etc.) or zero-extend (shr, divu, etc.) the register first. Signed-off-by: Aurelien Jarno <aurelien@aurel32.net>
2010-03-29 04:12:51 +04:00
tcg_opc_i18(TCG_REG_P0, OPC_NOP_I18, 0));
} else {
if (opc == 1) {
tcg_out_bundle(s, mII,
add_guest_base,
tcg: initial ia64 support A few words about design choices: * On IA64, instructions should be grouped by bundle, and dependencies between instructions declared. A first version of this code tried to schedule instructions automatically, but was very complex and too invasive for the current common TCG code (ops not ending at instruction boundaries, code retranslation breaking already generated code, etc.) It was also not very efficient, as dependencies between TCG ops is not available. Instead the option taken by the current implementation does not try to fill the bundle by scheduling instructions, but by providing ops not available as an ia64 instruction, and by offering 22-bit constant loading for most of the instructions. With both options the bundle are filled at approximately the same level. * Up to 128 registers can be affected to a function on IA64, but TCG limits this number to 64, which is actually more than enough. The register affectation is the following: - r0: used to map a constant argument with value 0 - r1: global pointer - r2, r3: internal use - r4 to r6: not used to avoid saving them - r7: env structure - r8 to r11: free for TCG (call clobbered) - r12: stack pointer - r13: thread pointer - r14 to r31: free for TCG (call clobbered) - r32: reserved (return address) - r33: reserved (PFS) - r33 to r63: free for TCG * The IA64 architecture has only 64-bit registers and no 32-bit instructions (the only exception being cmp4). Therefore 64-bit registers and instructions are used for 32-bit ops. The adopted strategy is the same as the ABI, that is the higher 32 bits are undefined. Most ops (and, or, add, shl, etc.) can directly use the 64-bit registers, while some others have to sign-extend (sar, div, etc.) or zero-extend (shr, divu, etc.) the register first. Signed-off-by: Aurelien Jarno <aurelien@aurel32.net>
2010-03-29 04:12:51 +04:00
tcg_opc_i12(TCG_REG_P0, OPC_DEP_Z_I12,
TCG_REG_R3, data_reg, 15, 15),
tcg_opc_i3 (TCG_REG_P0, OPC_MUX1_I3,
TCG_REG_R3, TCG_REG_R3, 0xb));
data_reg = TCG_REG_R3;
} else if (opc == 2) {
tcg_out_bundle(s, mII,
add_guest_base,
tcg: initial ia64 support A few words about design choices: * On IA64, instructions should be grouped by bundle, and dependencies between instructions declared. A first version of this code tried to schedule instructions automatically, but was very complex and too invasive for the current common TCG code (ops not ending at instruction boundaries, code retranslation breaking already generated code, etc.) It was also not very efficient, as dependencies between TCG ops is not available. Instead the option taken by the current implementation does not try to fill the bundle by scheduling instructions, but by providing ops not available as an ia64 instruction, and by offering 22-bit constant loading for most of the instructions. With both options the bundle are filled at approximately the same level. * Up to 128 registers can be affected to a function on IA64, but TCG limits this number to 64, which is actually more than enough. The register affectation is the following: - r0: used to map a constant argument with value 0 - r1: global pointer - r2, r3: internal use - r4 to r6: not used to avoid saving them - r7: env structure - r8 to r11: free for TCG (call clobbered) - r12: stack pointer - r13: thread pointer - r14 to r31: free for TCG (call clobbered) - r32: reserved (return address) - r33: reserved (PFS) - r33 to r63: free for TCG * The IA64 architecture has only 64-bit registers and no 32-bit instructions (the only exception being cmp4). Therefore 64-bit registers and instructions are used for 32-bit ops. The adopted strategy is the same as the ABI, that is the higher 32 bits are undefined. Most ops (and, or, add, shl, etc.) can directly use the 64-bit registers, while some others have to sign-extend (sar, div, etc.) or zero-extend (shr, divu, etc.) the register first. Signed-off-by: Aurelien Jarno <aurelien@aurel32.net>
2010-03-29 04:12:51 +04:00
tcg_opc_i12(TCG_REG_P0, OPC_DEP_Z_I12,
TCG_REG_R3, data_reg, 31, 31),
tcg_opc_i3 (TCG_REG_P0, OPC_MUX1_I3,
TCG_REG_R3, TCG_REG_R3, 0xb));
data_reg = TCG_REG_R3;
} else if (opc == 3) {
tcg_out_bundle(s, miI,
add_guest_base,
tcg: initial ia64 support A few words about design choices: * On IA64, instructions should be grouped by bundle, and dependencies between instructions declared. A first version of this code tried to schedule instructions automatically, but was very complex and too invasive for the current common TCG code (ops not ending at instruction boundaries, code retranslation breaking already generated code, etc.) It was also not very efficient, as dependencies between TCG ops is not available. Instead the option taken by the current implementation does not try to fill the bundle by scheduling instructions, but by providing ops not available as an ia64 instruction, and by offering 22-bit constant loading for most of the instructions. With both options the bundle are filled at approximately the same level. * Up to 128 registers can be affected to a function on IA64, but TCG limits this number to 64, which is actually more than enough. The register affectation is the following: - r0: used to map a constant argument with value 0 - r1: global pointer - r2, r3: internal use - r4 to r6: not used to avoid saving them - r7: env structure - r8 to r11: free for TCG (call clobbered) - r12: stack pointer - r13: thread pointer - r14 to r31: free for TCG (call clobbered) - r32: reserved (return address) - r33: reserved (PFS) - r33 to r63: free for TCG * The IA64 architecture has only 64-bit registers and no 32-bit instructions (the only exception being cmp4). Therefore 64-bit registers and instructions are used for 32-bit ops. The adopted strategy is the same as the ABI, that is the higher 32 bits are undefined. Most ops (and, or, add, shl, etc.) can directly use the 64-bit registers, while some others have to sign-extend (sar, div, etc.) or zero-extend (shr, divu, etc.) the register first. Signed-off-by: Aurelien Jarno <aurelien@aurel32.net>
2010-03-29 04:12:51 +04:00
tcg_opc_i18(TCG_REG_P0, OPC_NOP_I18, 0),
tcg_opc_i3 (TCG_REG_P0, OPC_MUX1_I3,
TCG_REG_R3, data_reg, 0xb));
data_reg = TCG_REG_R3;
}
tcg_out_bundle(s, miI,
tcg_opc_m4 (TCG_REG_P0, opc_st_m4[opc],
data_reg, addr_reg),
tcg: initial ia64 support A few words about design choices: * On IA64, instructions should be grouped by bundle, and dependencies between instructions declared. A first version of this code tried to schedule instructions automatically, but was very complex and too invasive for the current common TCG code (ops not ending at instruction boundaries, code retranslation breaking already generated code, etc.) It was also not very efficient, as dependencies between TCG ops is not available. Instead the option taken by the current implementation does not try to fill the bundle by scheduling instructions, but by providing ops not available as an ia64 instruction, and by offering 22-bit constant loading for most of the instructions. With both options the bundle are filled at approximately the same level. * Up to 128 registers can be affected to a function on IA64, but TCG limits this number to 64, which is actually more than enough. The register affectation is the following: - r0: used to map a constant argument with value 0 - r1: global pointer - r2, r3: internal use - r4 to r6: not used to avoid saving them - r7: env structure - r8 to r11: free for TCG (call clobbered) - r12: stack pointer - r13: thread pointer - r14 to r31: free for TCG (call clobbered) - r32: reserved (return address) - r33: reserved (PFS) - r33 to r63: free for TCG * The IA64 architecture has only 64-bit registers and no 32-bit instructions (the only exception being cmp4). Therefore 64-bit registers and instructions are used for 32-bit ops. The adopted strategy is the same as the ABI, that is the higher 32 bits are undefined. Most ops (and, or, add, shl, etc.) can directly use the 64-bit registers, while some others have to sign-extend (sar, div, etc.) or zero-extend (shr, divu, etc.) the register first. Signed-off-by: Aurelien Jarno <aurelien@aurel32.net>
2010-03-29 04:12:51 +04:00
tcg_opc_i18(TCG_REG_P0, OPC_NOP_I18, 0),
tcg_opc_i18(TCG_REG_P0, OPC_NOP_I18, 0));
}
#endif
}
#endif
static inline void tcg_out_op(TCGContext *s, TCGOpcode opc,
const TCGArg *args, const int *const_args)
{
switch(opc) {
case INDEX_op_exit_tb:
tcg_out_exit_tb(s, args[0]);
break;
case INDEX_op_br:
tcg_out_br(s, args[0]);
break;
case INDEX_op_call:
tcg_out_call(s, args[0]);
break;
case INDEX_op_goto_tb:
tcg_out_goto_tb(s, args[0]);
break;
case INDEX_op_movi_i32:
tcg_out_movi(s, TCG_TYPE_I32, args[0], args[1]);
break;
case INDEX_op_movi_i64:
tcg_out_movi(s, TCG_TYPE_I64, args[0], args[1]);
break;
case INDEX_op_ld8u_i32:
case INDEX_op_ld8u_i64:
tcg_out_ld_rel(s, OPC_LD1_M1, args[0], args[1], args[2]);
break;
case INDEX_op_ld8s_i32:
case INDEX_op_ld8s_i64:
tcg_out_ld_rel(s, OPC_LD1_M1, args[0], args[1], args[2]);
tcg_out_ext(s, OPC_SXT1_I29, args[0], args[0]);
break;
case INDEX_op_ld16u_i32:
case INDEX_op_ld16u_i64:
tcg_out_ld_rel(s, OPC_LD2_M1, args[0], args[1], args[2]);
break;
case INDEX_op_ld16s_i32:
case INDEX_op_ld16s_i64:
tcg_out_ld_rel(s, OPC_LD2_M1, args[0], args[1], args[2]);
tcg_out_ext(s, OPC_SXT2_I29, args[0], args[0]);
break;
case INDEX_op_ld_i32:
case INDEX_op_ld32u_i64:
tcg_out_ld_rel(s, OPC_LD4_M1, args[0], args[1], args[2]);
break;
case INDEX_op_ld32s_i64:
tcg_out_ld_rel(s, OPC_LD4_M1, args[0], args[1], args[2]);
tcg_out_ext(s, OPC_SXT4_I29, args[0], args[0]);
break;
case INDEX_op_ld_i64:
tcg_out_ld_rel(s, OPC_LD8_M1, args[0], args[1], args[2]);
break;
case INDEX_op_st8_i32:
case INDEX_op_st8_i64:
tcg_out_st_rel(s, OPC_ST1_M4, args[0], args[1], args[2]);
break;
case INDEX_op_st16_i32:
case INDEX_op_st16_i64:
tcg_out_st_rel(s, OPC_ST2_M4, args[0], args[1], args[2]);
break;
case INDEX_op_st_i32:
case INDEX_op_st32_i64:
tcg_out_st_rel(s, OPC_ST4_M4, args[0], args[1], args[2]);
break;
case INDEX_op_st_i64:
tcg_out_st_rel(s, OPC_ST8_M4, args[0], args[1], args[2]);
break;
case INDEX_op_add_i32:
case INDEX_op_add_i64:
tcg_out_alu(s, OPC_ADD_A1, args[0], args[1], const_args[1],
args[2], const_args[2]);
break;
case INDEX_op_sub_i32:
case INDEX_op_sub_i64:
tcg_out_alu(s, OPC_SUB_A1, args[0], args[1], const_args[1],
args[2], const_args[2]);
break;
case INDEX_op_and_i32:
case INDEX_op_and_i64:
tcg_out_alu(s, OPC_AND_A1, args[0], args[1], const_args[1],
args[2], const_args[2]);
break;
case INDEX_op_andc_i32:
case INDEX_op_andc_i64:
tcg_out_alu(s, OPC_ANDCM_A1, args[0], args[1], const_args[1],
args[2], const_args[2]);
break;
case INDEX_op_eqv_i32:
case INDEX_op_eqv_i64:
tcg_out_eqv(s, args[0], args[1], const_args[1],
args[2], const_args[2]);
break;
case INDEX_op_nand_i32:
case INDEX_op_nand_i64:
tcg_out_nand(s, args[0], args[1], const_args[1],
args[2], const_args[2]);
break;
case INDEX_op_nor_i32:
case INDEX_op_nor_i64:
tcg_out_nor(s, args[0], args[1], const_args[1],
args[2], const_args[2]);
break;
case INDEX_op_or_i32:
case INDEX_op_or_i64:
tcg_out_alu(s, OPC_OR_A1, args[0], args[1], const_args[1],
args[2], const_args[2]);
break;
case INDEX_op_orc_i32:
case INDEX_op_orc_i64:
tcg_out_orc(s, args[0], args[1], const_args[1],
args[2], const_args[2]);
break;
case INDEX_op_xor_i32:
case INDEX_op_xor_i64:
tcg_out_alu(s, OPC_XOR_A1, args[0], args[1], const_args[1],
args[2], const_args[2]);
break;
case INDEX_op_mul_i32:
case INDEX_op_mul_i64:
tcg_out_mul(s, args[0], args[1], args[2]);
break;
case INDEX_op_sar_i32:
tcg_out_sar_i32(s, args[0], args[1], args[2], const_args[2]);
break;
case INDEX_op_sar_i64:
tcg_out_sar_i64(s, args[0], args[1], args[2], const_args[2]);
break;
case INDEX_op_shl_i32:
tcg_out_shl_i32(s, args[0], args[1], args[2], const_args[2]);
break;
case INDEX_op_shl_i64:
tcg_out_shl_i64(s, args[0], args[1], args[2], const_args[2]);
break;
case INDEX_op_shr_i32:
tcg_out_shr_i32(s, args[0], args[1], args[2], const_args[2]);
break;
case INDEX_op_shr_i64:
tcg_out_shr_i64(s, args[0], args[1], args[2], const_args[2]);
break;
case INDEX_op_rotl_i32:
tcg_out_rotl_i32(s, args[0], args[1], args[2], const_args[2]);
break;
case INDEX_op_rotl_i64:
tcg_out_rotl_i64(s, args[0], args[1], args[2], const_args[2]);
break;
case INDEX_op_rotr_i32:
tcg_out_rotr_i32(s, args[0], args[1], args[2], const_args[2]);
break;
case INDEX_op_rotr_i64:
tcg_out_rotr_i64(s, args[0], args[1], args[2], const_args[2]);
break;
case INDEX_op_ext8s_i32:
case INDEX_op_ext8s_i64:
tcg_out_ext(s, OPC_SXT1_I29, args[0], args[1]);
break;
case INDEX_op_ext8u_i32:
case INDEX_op_ext8u_i64:
tcg_out_ext(s, OPC_ZXT1_I29, args[0], args[1]);
break;
case INDEX_op_ext16s_i32:
case INDEX_op_ext16s_i64:
tcg_out_ext(s, OPC_SXT2_I29, args[0], args[1]);
break;
case INDEX_op_ext16u_i32:
case INDEX_op_ext16u_i64:
tcg_out_ext(s, OPC_ZXT2_I29, args[0], args[1]);
break;
case INDEX_op_ext32s_i64:
tcg_out_ext(s, OPC_SXT4_I29, args[0], args[1]);
break;
case INDEX_op_ext32u_i64:
tcg_out_ext(s, OPC_ZXT4_I29, args[0], args[1]);
break;
case INDEX_op_bswap16_i32:
case INDEX_op_bswap16_i64:
tcg_out_bswap16(s, args[0], args[1]);
break;
case INDEX_op_bswap32_i32:
case INDEX_op_bswap32_i64:
tcg_out_bswap32(s, args[0], args[1]);
break;
case INDEX_op_bswap64_i64:
tcg_out_bswap64(s, args[0], args[1]);
break;
case INDEX_op_deposit_i32:
case INDEX_op_deposit_i64:
tcg_out_deposit(s, args[0], args[1], args[2], const_args[2],
args[3], args[4]);
break;
tcg: initial ia64 support A few words about design choices: * On IA64, instructions should be grouped by bundle, and dependencies between instructions declared. A first version of this code tried to schedule instructions automatically, but was very complex and too invasive for the current common TCG code (ops not ending at instruction boundaries, code retranslation breaking already generated code, etc.) It was also not very efficient, as dependencies between TCG ops is not available. Instead the option taken by the current implementation does not try to fill the bundle by scheduling instructions, but by providing ops not available as an ia64 instruction, and by offering 22-bit constant loading for most of the instructions. With both options the bundle are filled at approximately the same level. * Up to 128 registers can be affected to a function on IA64, but TCG limits this number to 64, which is actually more than enough. The register affectation is the following: - r0: used to map a constant argument with value 0 - r1: global pointer - r2, r3: internal use - r4 to r6: not used to avoid saving them - r7: env structure - r8 to r11: free for TCG (call clobbered) - r12: stack pointer - r13: thread pointer - r14 to r31: free for TCG (call clobbered) - r32: reserved (return address) - r33: reserved (PFS) - r33 to r63: free for TCG * The IA64 architecture has only 64-bit registers and no 32-bit instructions (the only exception being cmp4). Therefore 64-bit registers and instructions are used for 32-bit ops. The adopted strategy is the same as the ABI, that is the higher 32 bits are undefined. Most ops (and, or, add, shl, etc.) can directly use the 64-bit registers, while some others have to sign-extend (sar, div, etc.) or zero-extend (shr, divu, etc.) the register first. Signed-off-by: Aurelien Jarno <aurelien@aurel32.net>
2010-03-29 04:12:51 +04:00
case INDEX_op_brcond_i32:
tcg_out_brcond(s, args[2], args[0], const_args[0],
args[1], const_args[1], args[3], 1);
break;
case INDEX_op_brcond_i64:
tcg_out_brcond(s, args[2], args[0], const_args[0],
args[1], const_args[1], args[3], 0);
break;
case INDEX_op_setcond_i32:
tcg_out_setcond(s, args[3], args[0], args[1], args[2], 1);
break;
case INDEX_op_setcond_i64:
tcg_out_setcond(s, args[3], args[0], args[1], args[2], 0);
break;
case INDEX_op_movcond_i32:
tcg_out_movcond(s, args[5], args[0], args[1], args[2],
args[3], const_args[3], args[4], const_args[4], 1);
break;
case INDEX_op_movcond_i64:
tcg_out_movcond(s, args[5], args[0], args[1], args[2],
args[3], const_args[3], args[4], const_args[4], 0);
break;
tcg: initial ia64 support A few words about design choices: * On IA64, instructions should be grouped by bundle, and dependencies between instructions declared. A first version of this code tried to schedule instructions automatically, but was very complex and too invasive for the current common TCG code (ops not ending at instruction boundaries, code retranslation breaking already generated code, etc.) It was also not very efficient, as dependencies between TCG ops is not available. Instead the option taken by the current implementation does not try to fill the bundle by scheduling instructions, but by providing ops not available as an ia64 instruction, and by offering 22-bit constant loading for most of the instructions. With both options the bundle are filled at approximately the same level. * Up to 128 registers can be affected to a function on IA64, but TCG limits this number to 64, which is actually more than enough. The register affectation is the following: - r0: used to map a constant argument with value 0 - r1: global pointer - r2, r3: internal use - r4 to r6: not used to avoid saving them - r7: env structure - r8 to r11: free for TCG (call clobbered) - r12: stack pointer - r13: thread pointer - r14 to r31: free for TCG (call clobbered) - r32: reserved (return address) - r33: reserved (PFS) - r33 to r63: free for TCG * The IA64 architecture has only 64-bit registers and no 32-bit instructions (the only exception being cmp4). Therefore 64-bit registers and instructions are used for 32-bit ops. The adopted strategy is the same as the ABI, that is the higher 32 bits are undefined. Most ops (and, or, add, shl, etc.) can directly use the 64-bit registers, while some others have to sign-extend (sar, div, etc.) or zero-extend (shr, divu, etc.) the register first. Signed-off-by: Aurelien Jarno <aurelien@aurel32.net>
2010-03-29 04:12:51 +04:00
case INDEX_op_qemu_ld8u:
tcg_out_qemu_ld(s, args, 0);
break;
case INDEX_op_qemu_ld8s:
tcg_out_qemu_ld(s, args, 0 | 4);
break;
case INDEX_op_qemu_ld16u:
tcg_out_qemu_ld(s, args, 1);
break;
case INDEX_op_qemu_ld16s:
tcg_out_qemu_ld(s, args, 1 | 4);
break;
case INDEX_op_qemu_ld32:
tcg: initial ia64 support A few words about design choices: * On IA64, instructions should be grouped by bundle, and dependencies between instructions declared. A first version of this code tried to schedule instructions automatically, but was very complex and too invasive for the current common TCG code (ops not ending at instruction boundaries, code retranslation breaking already generated code, etc.) It was also not very efficient, as dependencies between TCG ops is not available. Instead the option taken by the current implementation does not try to fill the bundle by scheduling instructions, but by providing ops not available as an ia64 instruction, and by offering 22-bit constant loading for most of the instructions. With both options the bundle are filled at approximately the same level. * Up to 128 registers can be affected to a function on IA64, but TCG limits this number to 64, which is actually more than enough. The register affectation is the following: - r0: used to map a constant argument with value 0 - r1: global pointer - r2, r3: internal use - r4 to r6: not used to avoid saving them - r7: env structure - r8 to r11: free for TCG (call clobbered) - r12: stack pointer - r13: thread pointer - r14 to r31: free for TCG (call clobbered) - r32: reserved (return address) - r33: reserved (PFS) - r33 to r63: free for TCG * The IA64 architecture has only 64-bit registers and no 32-bit instructions (the only exception being cmp4). Therefore 64-bit registers and instructions are used for 32-bit ops. The adopted strategy is the same as the ABI, that is the higher 32 bits are undefined. Most ops (and, or, add, shl, etc.) can directly use the 64-bit registers, while some others have to sign-extend (sar, div, etc.) or zero-extend (shr, divu, etc.) the register first. Signed-off-by: Aurelien Jarno <aurelien@aurel32.net>
2010-03-29 04:12:51 +04:00
case INDEX_op_qemu_ld32u:
tcg_out_qemu_ld(s, args, 2);
break;
case INDEX_op_qemu_ld32s:
tcg_out_qemu_ld(s, args, 2 | 4);
break;
case INDEX_op_qemu_ld64:
tcg_out_qemu_ld(s, args, 3);
break;
case INDEX_op_qemu_st8:
tcg_out_qemu_st(s, args, 0);
break;
case INDEX_op_qemu_st16:
tcg_out_qemu_st(s, args, 1);
break;
case INDEX_op_qemu_st32:
tcg_out_qemu_st(s, args, 2);
break;
case INDEX_op_qemu_st64:
tcg_out_qemu_st(s, args, 3);
break;
default:
tcg_abort();
}
}
static const TCGTargetOpDef ia64_op_defs[] = {
{ INDEX_op_br, { } },
{ INDEX_op_call, { "r" } },
{ INDEX_op_exit_tb, { } },
{ INDEX_op_goto_tb, { } },
{ INDEX_op_mov_i32, { "r", "r" } },
{ INDEX_op_movi_i32, { "r" } },
{ INDEX_op_ld8u_i32, { "r", "r" } },
{ INDEX_op_ld8s_i32, { "r", "r" } },
{ INDEX_op_ld16u_i32, { "r", "r" } },
{ INDEX_op_ld16s_i32, { "r", "r" } },
{ INDEX_op_ld_i32, { "r", "r" } },
{ INDEX_op_st8_i32, { "rZ", "r" } },
{ INDEX_op_st16_i32, { "rZ", "r" } },
{ INDEX_op_st_i32, { "rZ", "r" } },
{ INDEX_op_add_i32, { "r", "rI", "rI" } },
{ INDEX_op_sub_i32, { "r", "rI", "rI" } },
{ INDEX_op_and_i32, { "r", "rI", "rI" } },
{ INDEX_op_andc_i32, { "r", "rI", "rI" } },
{ INDEX_op_eqv_i32, { "r", "rZ", "rZ" } },
{ INDEX_op_nand_i32, { "r", "rZ", "rZ" } },
{ INDEX_op_nor_i32, { "r", "rZ", "rZ" } },
{ INDEX_op_or_i32, { "r", "rI", "rI" } },
{ INDEX_op_orc_i32, { "r", "rZ", "rZ" } },
{ INDEX_op_xor_i32, { "r", "rI", "rI" } },
{ INDEX_op_mul_i32, { "r", "rZ", "rZ" } },
{ INDEX_op_sar_i32, { "r", "rZ", "ri" } },
{ INDEX_op_shl_i32, { "r", "rZ", "ri" } },
{ INDEX_op_shr_i32, { "r", "rZ", "ri" } },
{ INDEX_op_rotl_i32, { "r", "rZ", "ri" } },
{ INDEX_op_rotr_i32, { "r", "rZ", "ri" } },
{ INDEX_op_ext8s_i32, { "r", "rZ"} },
{ INDEX_op_ext8u_i32, { "r", "rZ"} },
{ INDEX_op_ext16s_i32, { "r", "rZ"} },
{ INDEX_op_ext16u_i32, { "r", "rZ"} },
{ INDEX_op_bswap16_i32, { "r", "rZ" } },
{ INDEX_op_bswap32_i32, { "r", "rZ" } },
{ INDEX_op_brcond_i32, { "rI", "rI" } },
{ INDEX_op_setcond_i32, { "r", "rZ", "rZ" } },
{ INDEX_op_movcond_i32, { "r", "rZ", "rZ", "rI", "rI" } },
tcg: initial ia64 support A few words about design choices: * On IA64, instructions should be grouped by bundle, and dependencies between instructions declared. A first version of this code tried to schedule instructions automatically, but was very complex and too invasive for the current common TCG code (ops not ending at instruction boundaries, code retranslation breaking already generated code, etc.) It was also not very efficient, as dependencies between TCG ops is not available. Instead the option taken by the current implementation does not try to fill the bundle by scheduling instructions, but by providing ops not available as an ia64 instruction, and by offering 22-bit constant loading for most of the instructions. With both options the bundle are filled at approximately the same level. * Up to 128 registers can be affected to a function on IA64, but TCG limits this number to 64, which is actually more than enough. The register affectation is the following: - r0: used to map a constant argument with value 0 - r1: global pointer - r2, r3: internal use - r4 to r6: not used to avoid saving them - r7: env structure - r8 to r11: free for TCG (call clobbered) - r12: stack pointer - r13: thread pointer - r14 to r31: free for TCG (call clobbered) - r32: reserved (return address) - r33: reserved (PFS) - r33 to r63: free for TCG * The IA64 architecture has only 64-bit registers and no 32-bit instructions (the only exception being cmp4). Therefore 64-bit registers and instructions are used for 32-bit ops. The adopted strategy is the same as the ABI, that is the higher 32 bits are undefined. Most ops (and, or, add, shl, etc.) can directly use the 64-bit registers, while some others have to sign-extend (sar, div, etc.) or zero-extend (shr, divu, etc.) the register first. Signed-off-by: Aurelien Jarno <aurelien@aurel32.net>
2010-03-29 04:12:51 +04:00
{ INDEX_op_mov_i64, { "r", "r" } },
{ INDEX_op_movi_i64, { "r" } },
{ INDEX_op_ld8u_i64, { "r", "r" } },
{ INDEX_op_ld8s_i64, { "r", "r" } },
{ INDEX_op_ld16u_i64, { "r", "r" } },
{ INDEX_op_ld16s_i64, { "r", "r" } },
{ INDEX_op_ld32u_i64, { "r", "r" } },
{ INDEX_op_ld32s_i64, { "r", "r" } },
{ INDEX_op_ld_i64, { "r", "r" } },
{ INDEX_op_st8_i64, { "rZ", "r" } },
{ INDEX_op_st16_i64, { "rZ", "r" } },
{ INDEX_op_st32_i64, { "rZ", "r" } },
{ INDEX_op_st_i64, { "rZ", "r" } },
{ INDEX_op_add_i64, { "r", "rI", "rI" } },
{ INDEX_op_sub_i64, { "r", "rI", "rI" } },
{ INDEX_op_and_i64, { "r", "rI", "rI" } },
{ INDEX_op_andc_i64, { "r", "rI", "rI" } },
{ INDEX_op_eqv_i64, { "r", "rZ", "rZ" } },
{ INDEX_op_nand_i64, { "r", "rZ", "rZ" } },
{ INDEX_op_nor_i64, { "r", "rZ", "rZ" } },
{ INDEX_op_or_i64, { "r", "rI", "rI" } },
{ INDEX_op_orc_i64, { "r", "rZ", "rZ" } },
{ INDEX_op_xor_i64, { "r", "rI", "rI" } },
{ INDEX_op_mul_i64, { "r", "rZ", "rZ" } },
{ INDEX_op_sar_i64, { "r", "rZ", "ri" } },
{ INDEX_op_shl_i64, { "r", "rZ", "ri" } },
{ INDEX_op_shr_i64, { "r", "rZ", "ri" } },
{ INDEX_op_rotl_i64, { "r", "rZ", "ri" } },
{ INDEX_op_rotr_i64, { "r", "rZ", "ri" } },
{ INDEX_op_ext8s_i64, { "r", "rZ"} },
{ INDEX_op_ext8u_i64, { "r", "rZ"} },
{ INDEX_op_ext16s_i64, { "r", "rZ"} },
{ INDEX_op_ext16u_i64, { "r", "rZ"} },
{ INDEX_op_ext32s_i64, { "r", "rZ"} },
{ INDEX_op_ext32u_i64, { "r", "rZ"} },
{ INDEX_op_bswap16_i64, { "r", "rZ" } },
{ INDEX_op_bswap32_i64, { "r", "rZ" } },
{ INDEX_op_bswap64_i64, { "r", "rZ" } },
{ INDEX_op_brcond_i64, { "rI", "rI" } },
{ INDEX_op_setcond_i64, { "r", "rZ", "rZ" } },
{ INDEX_op_movcond_i64, { "r", "rZ", "rZ", "rI", "rI" } },
tcg: initial ia64 support A few words about design choices: * On IA64, instructions should be grouped by bundle, and dependencies between instructions declared. A first version of this code tried to schedule instructions automatically, but was very complex and too invasive for the current common TCG code (ops not ending at instruction boundaries, code retranslation breaking already generated code, etc.) It was also not very efficient, as dependencies between TCG ops is not available. Instead the option taken by the current implementation does not try to fill the bundle by scheduling instructions, but by providing ops not available as an ia64 instruction, and by offering 22-bit constant loading for most of the instructions. With both options the bundle are filled at approximately the same level. * Up to 128 registers can be affected to a function on IA64, but TCG limits this number to 64, which is actually more than enough. The register affectation is the following: - r0: used to map a constant argument with value 0 - r1: global pointer - r2, r3: internal use - r4 to r6: not used to avoid saving them - r7: env structure - r8 to r11: free for TCG (call clobbered) - r12: stack pointer - r13: thread pointer - r14 to r31: free for TCG (call clobbered) - r32: reserved (return address) - r33: reserved (PFS) - r33 to r63: free for TCG * The IA64 architecture has only 64-bit registers and no 32-bit instructions (the only exception being cmp4). Therefore 64-bit registers and instructions are used for 32-bit ops. The adopted strategy is the same as the ABI, that is the higher 32 bits are undefined. Most ops (and, or, add, shl, etc.) can directly use the 64-bit registers, while some others have to sign-extend (sar, div, etc.) or zero-extend (shr, divu, etc.) the register first. Signed-off-by: Aurelien Jarno <aurelien@aurel32.net>
2010-03-29 04:12:51 +04:00
{ INDEX_op_deposit_i32, { "r", "rZ", "ri" } },
{ INDEX_op_deposit_i64, { "r", "rZ", "ri" } },
tcg: initial ia64 support A few words about design choices: * On IA64, instructions should be grouped by bundle, and dependencies between instructions declared. A first version of this code tried to schedule instructions automatically, but was very complex and too invasive for the current common TCG code (ops not ending at instruction boundaries, code retranslation breaking already generated code, etc.) It was also not very efficient, as dependencies between TCG ops is not available. Instead the option taken by the current implementation does not try to fill the bundle by scheduling instructions, but by providing ops not available as an ia64 instruction, and by offering 22-bit constant loading for most of the instructions. With both options the bundle are filled at approximately the same level. * Up to 128 registers can be affected to a function on IA64, but TCG limits this number to 64, which is actually more than enough. The register affectation is the following: - r0: used to map a constant argument with value 0 - r1: global pointer - r2, r3: internal use - r4 to r6: not used to avoid saving them - r7: env structure - r8 to r11: free for TCG (call clobbered) - r12: stack pointer - r13: thread pointer - r14 to r31: free for TCG (call clobbered) - r32: reserved (return address) - r33: reserved (PFS) - r33 to r63: free for TCG * The IA64 architecture has only 64-bit registers and no 32-bit instructions (the only exception being cmp4). Therefore 64-bit registers and instructions are used for 32-bit ops. The adopted strategy is the same as the ABI, that is the higher 32 bits are undefined. Most ops (and, or, add, shl, etc.) can directly use the 64-bit registers, while some others have to sign-extend (sar, div, etc.) or zero-extend (shr, divu, etc.) the register first. Signed-off-by: Aurelien Jarno <aurelien@aurel32.net>
2010-03-29 04:12:51 +04:00
{ INDEX_op_qemu_ld8u, { "r", "r" } },
{ INDEX_op_qemu_ld8s, { "r", "r" } },
{ INDEX_op_qemu_ld16u, { "r", "r" } },
{ INDEX_op_qemu_ld16s, { "r", "r" } },
{ INDEX_op_qemu_ld32, { "r", "r" } },
{ INDEX_op_qemu_ld32u, { "r", "r" } },
{ INDEX_op_qemu_ld32s, { "r", "r" } },
{ INDEX_op_qemu_ld64, { "r", "r" } },
{ INDEX_op_qemu_st8, { "SZ", "r" } },
{ INDEX_op_qemu_st16, { "SZ", "r" } },
{ INDEX_op_qemu_st32, { "SZ", "r" } },
{ INDEX_op_qemu_st64, { "SZ", "r" } },
{ -1 },
};
/* Generate global QEMU prologue and epilogue code */
static void tcg_target_qemu_prologue(TCGContext *s)
tcg: initial ia64 support A few words about design choices: * On IA64, instructions should be grouped by bundle, and dependencies between instructions declared. A first version of this code tried to schedule instructions automatically, but was very complex and too invasive for the current common TCG code (ops not ending at instruction boundaries, code retranslation breaking already generated code, etc.) It was also not very efficient, as dependencies between TCG ops is not available. Instead the option taken by the current implementation does not try to fill the bundle by scheduling instructions, but by providing ops not available as an ia64 instruction, and by offering 22-bit constant loading for most of the instructions. With both options the bundle are filled at approximately the same level. * Up to 128 registers can be affected to a function on IA64, but TCG limits this number to 64, which is actually more than enough. The register affectation is the following: - r0: used to map a constant argument with value 0 - r1: global pointer - r2, r3: internal use - r4 to r6: not used to avoid saving them - r7: env structure - r8 to r11: free for TCG (call clobbered) - r12: stack pointer - r13: thread pointer - r14 to r31: free for TCG (call clobbered) - r32: reserved (return address) - r33: reserved (PFS) - r33 to r63: free for TCG * The IA64 architecture has only 64-bit registers and no 32-bit instructions (the only exception being cmp4). Therefore 64-bit registers and instructions are used for 32-bit ops. The adopted strategy is the same as the ABI, that is the higher 32 bits are undefined. Most ops (and, or, add, shl, etc.) can directly use the 64-bit registers, while some others have to sign-extend (sar, div, etc.) or zero-extend (shr, divu, etc.) the register first. Signed-off-by: Aurelien Jarno <aurelien@aurel32.net>
2010-03-29 04:12:51 +04:00
{
int frame_size;
/* reserve some stack space */
frame_size = TCG_STATIC_CALL_ARGS_SIZE +
CPU_TEMP_BUF_NLONGS * sizeof(long);
tcg: initial ia64 support A few words about design choices: * On IA64, instructions should be grouped by bundle, and dependencies between instructions declared. A first version of this code tried to schedule instructions automatically, but was very complex and too invasive for the current common TCG code (ops not ending at instruction boundaries, code retranslation breaking already generated code, etc.) It was also not very efficient, as dependencies between TCG ops is not available. Instead the option taken by the current implementation does not try to fill the bundle by scheduling instructions, but by providing ops not available as an ia64 instruction, and by offering 22-bit constant loading for most of the instructions. With both options the bundle are filled at approximately the same level. * Up to 128 registers can be affected to a function on IA64, but TCG limits this number to 64, which is actually more than enough. The register affectation is the following: - r0: used to map a constant argument with value 0 - r1: global pointer - r2, r3: internal use - r4 to r6: not used to avoid saving them - r7: env structure - r8 to r11: free for TCG (call clobbered) - r12: stack pointer - r13: thread pointer - r14 to r31: free for TCG (call clobbered) - r32: reserved (return address) - r33: reserved (PFS) - r33 to r63: free for TCG * The IA64 architecture has only 64-bit registers and no 32-bit instructions (the only exception being cmp4). Therefore 64-bit registers and instructions are used for 32-bit ops. The adopted strategy is the same as the ABI, that is the higher 32 bits are undefined. Most ops (and, or, add, shl, etc.) can directly use the 64-bit registers, while some others have to sign-extend (sar, div, etc.) or zero-extend (shr, divu, etc.) the register first. Signed-off-by: Aurelien Jarno <aurelien@aurel32.net>
2010-03-29 04:12:51 +04:00
frame_size = (frame_size + TCG_TARGET_STACK_ALIGN - 1) &
~(TCG_TARGET_STACK_ALIGN - 1);
tcg_set_frame(s, TCG_REG_CALL_STACK, TCG_STATIC_CALL_ARGS_SIZE,
CPU_TEMP_BUF_NLONGS * sizeof(long));
tcg: initial ia64 support A few words about design choices: * On IA64, instructions should be grouped by bundle, and dependencies between instructions declared. A first version of this code tried to schedule instructions automatically, but was very complex and too invasive for the current common TCG code (ops not ending at instruction boundaries, code retranslation breaking already generated code, etc.) It was also not very efficient, as dependencies between TCG ops is not available. Instead the option taken by the current implementation does not try to fill the bundle by scheduling instructions, but by providing ops not available as an ia64 instruction, and by offering 22-bit constant loading for most of the instructions. With both options the bundle are filled at approximately the same level. * Up to 128 registers can be affected to a function on IA64, but TCG limits this number to 64, which is actually more than enough. The register affectation is the following: - r0: used to map a constant argument with value 0 - r1: global pointer - r2, r3: internal use - r4 to r6: not used to avoid saving them - r7: env structure - r8 to r11: free for TCG (call clobbered) - r12: stack pointer - r13: thread pointer - r14 to r31: free for TCG (call clobbered) - r32: reserved (return address) - r33: reserved (PFS) - r33 to r63: free for TCG * The IA64 architecture has only 64-bit registers and no 32-bit instructions (the only exception being cmp4). Therefore 64-bit registers and instructions are used for 32-bit ops. The adopted strategy is the same as the ABI, that is the higher 32 bits are undefined. Most ops (and, or, add, shl, etc.) can directly use the 64-bit registers, while some others have to sign-extend (sar, div, etc.) or zero-extend (shr, divu, etc.) the register first. Signed-off-by: Aurelien Jarno <aurelien@aurel32.net>
2010-03-29 04:12:51 +04:00
/* First emit adhoc function descriptor */
*(uint64_t *)(s->code_ptr) = (uint64_t)s->code_ptr + 16; /* entry point */
s->code_ptr += 16; /* skip GP */
/* prologue */
tcg_out_bundle(s, miI,
tcg: initial ia64 support A few words about design choices: * On IA64, instructions should be grouped by bundle, and dependencies between instructions declared. A first version of this code tried to schedule instructions automatically, but was very complex and too invasive for the current common TCG code (ops not ending at instruction boundaries, code retranslation breaking already generated code, etc.) It was also not very efficient, as dependencies between TCG ops is not available. Instead the option taken by the current implementation does not try to fill the bundle by scheduling instructions, but by providing ops not available as an ia64 instruction, and by offering 22-bit constant loading for most of the instructions. With both options the bundle are filled at approximately the same level. * Up to 128 registers can be affected to a function on IA64, but TCG limits this number to 64, which is actually more than enough. The register affectation is the following: - r0: used to map a constant argument with value 0 - r1: global pointer - r2, r3: internal use - r4 to r6: not used to avoid saving them - r7: env structure - r8 to r11: free for TCG (call clobbered) - r12: stack pointer - r13: thread pointer - r14 to r31: free for TCG (call clobbered) - r32: reserved (return address) - r33: reserved (PFS) - r33 to r63: free for TCG * The IA64 architecture has only 64-bit registers and no 32-bit instructions (the only exception being cmp4). Therefore 64-bit registers and instructions are used for 32-bit ops. The adopted strategy is the same as the ABI, that is the higher 32 bits are undefined. Most ops (and, or, add, shl, etc.) can directly use the 64-bit registers, while some others have to sign-extend (sar, div, etc.) or zero-extend (shr, divu, etc.) the register first. Signed-off-by: Aurelien Jarno <aurelien@aurel32.net>
2010-03-29 04:12:51 +04:00
tcg_opc_m34(TCG_REG_P0, OPC_ALLOC_M34,
TCG_REG_R34, 32, 24, 0),
tcg_opc_a4 (TCG_REG_P0, OPC_ADDS_A4,
TCG_AREG0, 0, TCG_REG_R32),
tcg: initial ia64 support A few words about design choices: * On IA64, instructions should be grouped by bundle, and dependencies between instructions declared. A first version of this code tried to schedule instructions automatically, but was very complex and too invasive for the current common TCG code (ops not ending at instruction boundaries, code retranslation breaking already generated code, etc.) It was also not very efficient, as dependencies between TCG ops is not available. Instead the option taken by the current implementation does not try to fill the bundle by scheduling instructions, but by providing ops not available as an ia64 instruction, and by offering 22-bit constant loading for most of the instructions. With both options the bundle are filled at approximately the same level. * Up to 128 registers can be affected to a function on IA64, but TCG limits this number to 64, which is actually more than enough. The register affectation is the following: - r0: used to map a constant argument with value 0 - r1: global pointer - r2, r3: internal use - r4 to r6: not used to avoid saving them - r7: env structure - r8 to r11: free for TCG (call clobbered) - r12: stack pointer - r13: thread pointer - r14 to r31: free for TCG (call clobbered) - r32: reserved (return address) - r33: reserved (PFS) - r33 to r63: free for TCG * The IA64 architecture has only 64-bit registers and no 32-bit instructions (the only exception being cmp4). Therefore 64-bit registers and instructions are used for 32-bit ops. The adopted strategy is the same as the ABI, that is the higher 32 bits are undefined. Most ops (and, or, add, shl, etc.) can directly use the 64-bit registers, while some others have to sign-extend (sar, div, etc.) or zero-extend (shr, divu, etc.) the register first. Signed-off-by: Aurelien Jarno <aurelien@aurel32.net>
2010-03-29 04:12:51 +04:00
tcg_opc_i21(TCG_REG_P0, OPC_MOV_I21,
TCG_REG_B6, TCG_REG_R33, 0));
/* ??? If GUEST_BASE < 0x200000, we could load the register via
an ADDL in the M slot of the next bundle. */
if (GUEST_BASE != 0) {
tcg_out_bundle(s, mlx,
tcg_opc_m48(TCG_REG_P0, OPC_NOP_M48, 0),
tcg_opc_l2 (GUEST_BASE),
tcg_opc_x2 (TCG_REG_P0, OPC_MOVL_X2,
TCG_GUEST_BASE_REG, GUEST_BASE));
tcg_regset_set_reg(s->reserved_regs, TCG_GUEST_BASE_REG);
}
tcg: initial ia64 support A few words about design choices: * On IA64, instructions should be grouped by bundle, and dependencies between instructions declared. A first version of this code tried to schedule instructions automatically, but was very complex and too invasive for the current common TCG code (ops not ending at instruction boundaries, code retranslation breaking already generated code, etc.) It was also not very efficient, as dependencies between TCG ops is not available. Instead the option taken by the current implementation does not try to fill the bundle by scheduling instructions, but by providing ops not available as an ia64 instruction, and by offering 22-bit constant loading for most of the instructions. With both options the bundle are filled at approximately the same level. * Up to 128 registers can be affected to a function on IA64, but TCG limits this number to 64, which is actually more than enough. The register affectation is the following: - r0: used to map a constant argument with value 0 - r1: global pointer - r2, r3: internal use - r4 to r6: not used to avoid saving them - r7: env structure - r8 to r11: free for TCG (call clobbered) - r12: stack pointer - r13: thread pointer - r14 to r31: free for TCG (call clobbered) - r32: reserved (return address) - r33: reserved (PFS) - r33 to r63: free for TCG * The IA64 architecture has only 64-bit registers and no 32-bit instructions (the only exception being cmp4). Therefore 64-bit registers and instructions are used for 32-bit ops. The adopted strategy is the same as the ABI, that is the higher 32 bits are undefined. Most ops (and, or, add, shl, etc.) can directly use the 64-bit registers, while some others have to sign-extend (sar, div, etc.) or zero-extend (shr, divu, etc.) the register first. Signed-off-by: Aurelien Jarno <aurelien@aurel32.net>
2010-03-29 04:12:51 +04:00
tcg_out_bundle(s, miB,
tcg_opc_a4 (TCG_REG_P0, OPC_ADDS_A4,
TCG_REG_R12, -frame_size, TCG_REG_R12),
tcg_opc_i22(TCG_REG_P0, OPC_MOV_I22,
TCG_REG_R32, TCG_REG_B0),
tcg: initial ia64 support A few words about design choices: * On IA64, instructions should be grouped by bundle, and dependencies between instructions declared. A first version of this code tried to schedule instructions automatically, but was very complex and too invasive for the current common TCG code (ops not ending at instruction boundaries, code retranslation breaking already generated code, etc.) It was also not very efficient, as dependencies between TCG ops is not available. Instead the option taken by the current implementation does not try to fill the bundle by scheduling instructions, but by providing ops not available as an ia64 instruction, and by offering 22-bit constant loading for most of the instructions. With both options the bundle are filled at approximately the same level. * Up to 128 registers can be affected to a function on IA64, but TCG limits this number to 64, which is actually more than enough. The register affectation is the following: - r0: used to map a constant argument with value 0 - r1: global pointer - r2, r3: internal use - r4 to r6: not used to avoid saving them - r7: env structure - r8 to r11: free for TCG (call clobbered) - r12: stack pointer - r13: thread pointer - r14 to r31: free for TCG (call clobbered) - r32: reserved (return address) - r33: reserved (PFS) - r33 to r63: free for TCG * The IA64 architecture has only 64-bit registers and no 32-bit instructions (the only exception being cmp4). Therefore 64-bit registers and instructions are used for 32-bit ops. The adopted strategy is the same as the ABI, that is the higher 32 bits are undefined. Most ops (and, or, add, shl, etc.) can directly use the 64-bit registers, while some others have to sign-extend (sar, div, etc.) or zero-extend (shr, divu, etc.) the register first. Signed-off-by: Aurelien Jarno <aurelien@aurel32.net>
2010-03-29 04:12:51 +04:00
tcg_opc_b4 (TCG_REG_P0, OPC_BR_SPTK_MANY_B4, TCG_REG_B6));
/* epilogue */
tb_ret_addr = s->code_ptr;
tcg_out_bundle(s, miI,
tcg_opc_m48(TCG_REG_P0, OPC_NOP_M48, 0),
tcg_opc_i21(TCG_REG_P0, OPC_MOV_I21,
TCG_REG_B0, TCG_REG_R32, 0),
tcg_opc_a4 (TCG_REG_P0, OPC_ADDS_A4,
TCG_REG_R12, frame_size, TCG_REG_R12));
tcg_out_bundle(s, miB,
tcg_opc_m48(TCG_REG_P0, OPC_NOP_M48, 0),
tcg_opc_i26(TCG_REG_P0, OPC_MOV_I_I26,
TCG_REG_PFS, TCG_REG_R34),
tcg: initial ia64 support A few words about design choices: * On IA64, instructions should be grouped by bundle, and dependencies between instructions declared. A first version of this code tried to schedule instructions automatically, but was very complex and too invasive for the current common TCG code (ops not ending at instruction boundaries, code retranslation breaking already generated code, etc.) It was also not very efficient, as dependencies between TCG ops is not available. Instead the option taken by the current implementation does not try to fill the bundle by scheduling instructions, but by providing ops not available as an ia64 instruction, and by offering 22-bit constant loading for most of the instructions. With both options the bundle are filled at approximately the same level. * Up to 128 registers can be affected to a function on IA64, but TCG limits this number to 64, which is actually more than enough. The register affectation is the following: - r0: used to map a constant argument with value 0 - r1: global pointer - r2, r3: internal use - r4 to r6: not used to avoid saving them - r7: env structure - r8 to r11: free for TCG (call clobbered) - r12: stack pointer - r13: thread pointer - r14 to r31: free for TCG (call clobbered) - r32: reserved (return address) - r33: reserved (PFS) - r33 to r63: free for TCG * The IA64 architecture has only 64-bit registers and no 32-bit instructions (the only exception being cmp4). Therefore 64-bit registers and instructions are used for 32-bit ops. The adopted strategy is the same as the ABI, that is the higher 32 bits are undefined. Most ops (and, or, add, shl, etc.) can directly use the 64-bit registers, while some others have to sign-extend (sar, div, etc.) or zero-extend (shr, divu, etc.) the register first. Signed-off-by: Aurelien Jarno <aurelien@aurel32.net>
2010-03-29 04:12:51 +04:00
tcg_opc_b4 (TCG_REG_P0, OPC_BR_RET_SPTK_MANY_B4,
TCG_REG_B0));
}
static void tcg_target_init(TCGContext *s)
tcg: initial ia64 support A few words about design choices: * On IA64, instructions should be grouped by bundle, and dependencies between instructions declared. A first version of this code tried to schedule instructions automatically, but was very complex and too invasive for the current common TCG code (ops not ending at instruction boundaries, code retranslation breaking already generated code, etc.) It was also not very efficient, as dependencies between TCG ops is not available. Instead the option taken by the current implementation does not try to fill the bundle by scheduling instructions, but by providing ops not available as an ia64 instruction, and by offering 22-bit constant loading for most of the instructions. With both options the bundle are filled at approximately the same level. * Up to 128 registers can be affected to a function on IA64, but TCG limits this number to 64, which is actually more than enough. The register affectation is the following: - r0: used to map a constant argument with value 0 - r1: global pointer - r2, r3: internal use - r4 to r6: not used to avoid saving them - r7: env structure - r8 to r11: free for TCG (call clobbered) - r12: stack pointer - r13: thread pointer - r14 to r31: free for TCG (call clobbered) - r32: reserved (return address) - r33: reserved (PFS) - r33 to r63: free for TCG * The IA64 architecture has only 64-bit registers and no 32-bit instructions (the only exception being cmp4). Therefore 64-bit registers and instructions are used for 32-bit ops. The adopted strategy is the same as the ABI, that is the higher 32 bits are undefined. Most ops (and, or, add, shl, etc.) can directly use the 64-bit registers, while some others have to sign-extend (sar, div, etc.) or zero-extend (shr, divu, etc.) the register first. Signed-off-by: Aurelien Jarno <aurelien@aurel32.net>
2010-03-29 04:12:51 +04:00
{
tcg_regset_set(tcg_target_available_regs[TCG_TYPE_I32],
0xffffffffffffffffull);
tcg_regset_set(tcg_target_available_regs[TCG_TYPE_I64],
0xffffffffffffffffull);
tcg_regset_clear(tcg_target_call_clobber_regs);
tcg_regset_set_reg(tcg_target_call_clobber_regs, TCG_REG_R8);
tcg_regset_set_reg(tcg_target_call_clobber_regs, TCG_REG_R9);
tcg_regset_set_reg(tcg_target_call_clobber_regs, TCG_REG_R10);
tcg_regset_set_reg(tcg_target_call_clobber_regs, TCG_REG_R11);
tcg_regset_set_reg(tcg_target_call_clobber_regs, TCG_REG_R14);
tcg_regset_set_reg(tcg_target_call_clobber_regs, TCG_REG_R15);
tcg_regset_set_reg(tcg_target_call_clobber_regs, TCG_REG_R16);
tcg_regset_set_reg(tcg_target_call_clobber_regs, TCG_REG_R17);
tcg_regset_set_reg(tcg_target_call_clobber_regs, TCG_REG_R18);
tcg_regset_set_reg(tcg_target_call_clobber_regs, TCG_REG_R19);
tcg_regset_set_reg(tcg_target_call_clobber_regs, TCG_REG_R20);
tcg_regset_set_reg(tcg_target_call_clobber_regs, TCG_REG_R21);
tcg_regset_set_reg(tcg_target_call_clobber_regs, TCG_REG_R22);
tcg_regset_set_reg(tcg_target_call_clobber_regs, TCG_REG_R23);
tcg_regset_set_reg(tcg_target_call_clobber_regs, TCG_REG_R24);
tcg_regset_set_reg(tcg_target_call_clobber_regs, TCG_REG_R25);
tcg_regset_set_reg(tcg_target_call_clobber_regs, TCG_REG_R26);
tcg_regset_set_reg(tcg_target_call_clobber_regs, TCG_REG_R27);
tcg_regset_set_reg(tcg_target_call_clobber_regs, TCG_REG_R28);
tcg_regset_set_reg(tcg_target_call_clobber_regs, TCG_REG_R29);
tcg_regset_set_reg(tcg_target_call_clobber_regs, TCG_REG_R30);
tcg_regset_set_reg(tcg_target_call_clobber_regs, TCG_REG_R31);
tcg_regset_set_reg(tcg_target_call_clobber_regs, TCG_REG_R56);
tcg_regset_set_reg(tcg_target_call_clobber_regs, TCG_REG_R57);
tcg_regset_set_reg(tcg_target_call_clobber_regs, TCG_REG_R58);
tcg_regset_set_reg(tcg_target_call_clobber_regs, TCG_REG_R59);
tcg_regset_set_reg(tcg_target_call_clobber_regs, TCG_REG_R60);
tcg_regset_set_reg(tcg_target_call_clobber_regs, TCG_REG_R61);
tcg_regset_set_reg(tcg_target_call_clobber_regs, TCG_REG_R62);
tcg_regset_set_reg(tcg_target_call_clobber_regs, TCG_REG_R63);
tcg_regset_clear(s->reserved_regs);
tcg: initial ia64 support A few words about design choices: * On IA64, instructions should be grouped by bundle, and dependencies between instructions declared. A first version of this code tried to schedule instructions automatically, but was very complex and too invasive for the current common TCG code (ops not ending at instruction boundaries, code retranslation breaking already generated code, etc.) It was also not very efficient, as dependencies between TCG ops is not available. Instead the option taken by the current implementation does not try to fill the bundle by scheduling instructions, but by providing ops not available as an ia64 instruction, and by offering 22-bit constant loading for most of the instructions. With both options the bundle are filled at approximately the same level. * Up to 128 registers can be affected to a function on IA64, but TCG limits this number to 64, which is actually more than enough. The register affectation is the following: - r0: used to map a constant argument with value 0 - r1: global pointer - r2, r3: internal use - r4 to r6: not used to avoid saving them - r7: env structure - r8 to r11: free for TCG (call clobbered) - r12: stack pointer - r13: thread pointer - r14 to r31: free for TCG (call clobbered) - r32: reserved (return address) - r33: reserved (PFS) - r33 to r63: free for TCG * The IA64 architecture has only 64-bit registers and no 32-bit instructions (the only exception being cmp4). Therefore 64-bit registers and instructions are used for 32-bit ops. The adopted strategy is the same as the ABI, that is the higher 32 bits are undefined. Most ops (and, or, add, shl, etc.) can directly use the 64-bit registers, while some others have to sign-extend (sar, div, etc.) or zero-extend (shr, divu, etc.) the register first. Signed-off-by: Aurelien Jarno <aurelien@aurel32.net>
2010-03-29 04:12:51 +04:00
tcg_regset_set_reg(s->reserved_regs, TCG_REG_R0); /* zero register */
tcg_regset_set_reg(s->reserved_regs, TCG_REG_R1); /* global pointer */
tcg_regset_set_reg(s->reserved_regs, TCG_REG_R2); /* internal use */
tcg_regset_set_reg(s->reserved_regs, TCG_REG_R3); /* internal use */
tcg_regset_set_reg(s->reserved_regs, TCG_REG_R12); /* stack pointer */
tcg_regset_set_reg(s->reserved_regs, TCG_REG_R13); /* thread pointer */
tcg: initial ia64 support A few words about design choices: * On IA64, instructions should be grouped by bundle, and dependencies between instructions declared. A first version of this code tried to schedule instructions automatically, but was very complex and too invasive for the current common TCG code (ops not ending at instruction boundaries, code retranslation breaking already generated code, etc.) It was also not very efficient, as dependencies between TCG ops is not available. Instead the option taken by the current implementation does not try to fill the bundle by scheduling instructions, but by providing ops not available as an ia64 instruction, and by offering 22-bit constant loading for most of the instructions. With both options the bundle are filled at approximately the same level. * Up to 128 registers can be affected to a function on IA64, but TCG limits this number to 64, which is actually more than enough. The register affectation is the following: - r0: used to map a constant argument with value 0 - r1: global pointer - r2, r3: internal use - r4 to r6: not used to avoid saving them - r7: env structure - r8 to r11: free for TCG (call clobbered) - r12: stack pointer - r13: thread pointer - r14 to r31: free for TCG (call clobbered) - r32: reserved (return address) - r33: reserved (PFS) - r33 to r63: free for TCG * The IA64 architecture has only 64-bit registers and no 32-bit instructions (the only exception being cmp4). Therefore 64-bit registers and instructions are used for 32-bit ops. The adopted strategy is the same as the ABI, that is the higher 32 bits are undefined. Most ops (and, or, add, shl, etc.) can directly use the 64-bit registers, while some others have to sign-extend (sar, div, etc.) or zero-extend (shr, divu, etc.) the register first. Signed-off-by: Aurelien Jarno <aurelien@aurel32.net>
2010-03-29 04:12:51 +04:00
tcg_regset_set_reg(s->reserved_regs, TCG_REG_R32); /* return address */
tcg_regset_set_reg(s->reserved_regs, TCG_REG_R34); /* PFS */
tcg: initial ia64 support A few words about design choices: * On IA64, instructions should be grouped by bundle, and dependencies between instructions declared. A first version of this code tried to schedule instructions automatically, but was very complex and too invasive for the current common TCG code (ops not ending at instruction boundaries, code retranslation breaking already generated code, etc.) It was also not very efficient, as dependencies between TCG ops is not available. Instead the option taken by the current implementation does not try to fill the bundle by scheduling instructions, but by providing ops not available as an ia64 instruction, and by offering 22-bit constant loading for most of the instructions. With both options the bundle are filled at approximately the same level. * Up to 128 registers can be affected to a function on IA64, but TCG limits this number to 64, which is actually more than enough. The register affectation is the following: - r0: used to map a constant argument with value 0 - r1: global pointer - r2, r3: internal use - r4 to r6: not used to avoid saving them - r7: env structure - r8 to r11: free for TCG (call clobbered) - r12: stack pointer - r13: thread pointer - r14 to r31: free for TCG (call clobbered) - r32: reserved (return address) - r33: reserved (PFS) - r33 to r63: free for TCG * The IA64 architecture has only 64-bit registers and no 32-bit instructions (the only exception being cmp4). Therefore 64-bit registers and instructions are used for 32-bit ops. The adopted strategy is the same as the ABI, that is the higher 32 bits are undefined. Most ops (and, or, add, shl, etc.) can directly use the 64-bit registers, while some others have to sign-extend (sar, div, etc.) or zero-extend (shr, divu, etc.) the register first. Signed-off-by: Aurelien Jarno <aurelien@aurel32.net>
2010-03-29 04:12:51 +04:00
/* The following 3 are not in use, are call-saved, but *not* saved
by the prologue. Therefore we cannot use them without modifying
the prologue. There doesn't seem to be any good reason to use
these as opposed to the windowed registers. */
tcg_regset_set_reg(s->reserved_regs, TCG_REG_R4);
tcg_regset_set_reg(s->reserved_regs, TCG_REG_R5);
tcg_regset_set_reg(s->reserved_regs, TCG_REG_R6);
tcg: initial ia64 support A few words about design choices: * On IA64, instructions should be grouped by bundle, and dependencies between instructions declared. A first version of this code tried to schedule instructions automatically, but was very complex and too invasive for the current common TCG code (ops not ending at instruction boundaries, code retranslation breaking already generated code, etc.) It was also not very efficient, as dependencies between TCG ops is not available. Instead the option taken by the current implementation does not try to fill the bundle by scheduling instructions, but by providing ops not available as an ia64 instruction, and by offering 22-bit constant loading for most of the instructions. With both options the bundle are filled at approximately the same level. * Up to 128 registers can be affected to a function on IA64, but TCG limits this number to 64, which is actually more than enough. The register affectation is the following: - r0: used to map a constant argument with value 0 - r1: global pointer - r2, r3: internal use - r4 to r6: not used to avoid saving them - r7: env structure - r8 to r11: free for TCG (call clobbered) - r12: stack pointer - r13: thread pointer - r14 to r31: free for TCG (call clobbered) - r32: reserved (return address) - r33: reserved (PFS) - r33 to r63: free for TCG * The IA64 architecture has only 64-bit registers and no 32-bit instructions (the only exception being cmp4). Therefore 64-bit registers and instructions are used for 32-bit ops. The adopted strategy is the same as the ABI, that is the higher 32 bits are undefined. Most ops (and, or, add, shl, etc.) can directly use the 64-bit registers, while some others have to sign-extend (sar, div, etc.) or zero-extend (shr, divu, etc.) the register first. Signed-off-by: Aurelien Jarno <aurelien@aurel32.net>
2010-03-29 04:12:51 +04:00
tcg_add_target_add_op_defs(ia64_op_defs);
}