kolibrios-fun/programs/emulator/e80/trunk/z80/op_cb.c
Yogev Ezra b2ba8d7766 Add emulators: 'DosBox' (binary only), 'e80', 'fceu' (binary only).
git-svn-id: svn://kolibrios.org@1814 a494cfbc-eb01-0410-851d-a64ba20cac60
2011-01-30 14:48:24 +00:00

357 lines
18 KiB
C

/*====================================================================/*
opcodes_cb.c -> This file executes the CB PREFIX opcodes.
When you find the CB opcode, it means that you must fetch another
byte from memory and treat it as a new opcode with different
meaning than the single-byte opcodes. This is a common way to extend
the number of opcodes (8 bits of instruction word = just 256 opcodes)
and it's called an OPCODE PREFIX (now we have another 256 new opcodes
by using this trick).
This program is free software; you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation; either version 2 of the License, or
(at your option) any later version.
This program is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with this program; if not, write to the Free Software
Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA.
Copyright (c) 2000 Santiago Romero Iglesias.
Email: sromero@escomposlinux.org
=====================================================================*/
/* 8 clock cycles minimum = CB opcode = 4+4 */
opcode = Z80ReadMem( r_PC );
r_PC++;
switch(opcode)
{
case RLC_B : RLC(r_B); AddCycles( 4+4 ); break;
case RLC_C : RLC(r_C); AddCycles( 4+4 ); break;
case RLC_D : RLC(r_D); AddCycles( 4+4 ); break;
case RLC_E : RLC(r_E); AddCycles( 4+4 ); break;
case RLC_H : RLC(r_H); AddCycles( 4+4 ); break;
case RLC_L : RLC(r_L); AddCycles( 4+4 ); break;
case RLC_xHL : r_meml = Z80ReadMem( r_HL );
RLC(r_meml);
Z80WriteMem( r_HL, r_meml, regs );
AddCycles( 4+4+3+3+1 ); break;
case RLC_A : RLC(r_A); AddCycles( 4+4 ); break;
case RRC_B : RRC(r_B); AddCycles( 4+4 ); break;
case RRC_C : RRC(r_C); AddCycles( 4+4 ); break;
case RRC_D : RRC(r_D); AddCycles( 4+4 ); break;
case RRC_E : RRC(r_E); AddCycles( 4+4 ); break;
case RRC_H : RRC(r_H); AddCycles( 4+4 ); break;
case RRC_L : RRC(r_L); AddCycles( 4+4 ); break;
case RRC_xHL : r_meml = Z80ReadMem( r_HL );
RRC(r_meml);
Z80WriteMem( r_HL, r_meml, regs );
AddCycles( 4+4+3+3+1 ); break;
case RRC_A : RRC(r_A); AddCycles( 4+4 ); break;
case RL_B : RL(r_B); AddCycles( 4+4 ); break;
case RL_C : RL(r_C); AddCycles( 4+4 ); break;
case RL_D : RL(r_D); AddCycles( 4+4 ); break;
case RL_E : RL(r_E); AddCycles( 4+4 ); break;
case RL_H : RL(r_H); AddCycles( 4+4 ); break;
case RL_L : RL(r_L); AddCycles( 4+4 ); break;
case RL_xHL : r_meml = Z80ReadMem( r_HL );
RL(r_meml);
Z80WriteMem( r_HL, r_meml, regs );
AddCycles( 4+4+3+3+1 ); break;
case RL_A : RL(r_A); AddCycles( 4+4 ); break;
case RR_B : RR(r_B); AddCycles( 4+4 ); break;
case RR_C : RR(r_C); AddCycles( 4+4 ); break;
case RR_D : RR(r_D); AddCycles( 4+4 ); break;
case RR_E : RR(r_E); AddCycles( 4+4 ); break;
case RR_H : RR(r_H); AddCycles( 4+4 ); break;
case RR_L : RR(r_L); AddCycles( 4+4 ); break;
case RR_xHL : r_meml = Z80ReadMem( r_HL );
RR(r_meml);
Z80WriteMem( r_HL, r_meml, regs );
AddCycles( 4+4+3+3+1 ); break;
case RR_A : RR(r_A); AddCycles( 4+4 ); break;
case SLA_B : SLA(r_B); AddCycles( 4+4 ); break;
case SLA_C : SLA(r_C); AddCycles( 4+4 ); break;
case SLA_D : SLA(r_D); AddCycles( 4+4 ); break;
case SLA_E : SLA(r_E); AddCycles( 4+4 ); break;
case SLA_H : SLA(r_H); AddCycles( 4+4 ); break;
case SLA_L : SLA(r_L); AddCycles( 4+4 ); break;
case SLA_xHL : r_meml = Z80ReadMem( r_HL );
SLA(r_meml);
Z80WriteMem( r_HL, r_meml, regs );
AddCycles( 4+4+3+3+1 ); break;
case SLA_A : SLA(r_A); AddCycles( 4+4 ); break;
case SRA_B : SRA(r_B); AddCycles( 4+4 ); break;
case SRA_C : SRA(r_C); AddCycles( 4+4 ); break;
case SRA_D : SRA(r_D); AddCycles( 4+4 ); break;
case SRA_E : SRA(r_E); AddCycles( 4+4 ); break;
case SRA_H : SRA(r_H); AddCycles( 4+4 ); break;
case SRA_L : SRA(r_L); AddCycles( 4+4 ); break;
case SRA_xHL : r_meml = Z80ReadMem( r_HL );
SRA(r_meml);
Z80WriteMem( r_HL, r_meml, regs );
AddCycles( 4+4+3+3+1 ); break;
case SRA_A : SRA(r_A); AddCycles( 4+4 ); break;
case SLL_B : SLL(r_B); AddCycles( 4+4 ); break;
case SLL_C : SLL(r_C); AddCycles( 4+4 ); break;
case SLL_D : SLL(r_D); AddCycles( 4+4 ); break;
case SLL_E : SLL(r_E); AddCycles( 4+4 ); break;
case SLL_H : SLL(r_H); AddCycles( 4+4 ); break;
case SLL_L : SLL(r_L); AddCycles( 4+4 ); break;
case SLL_xHL : r_meml = Z80ReadMem( r_HL );
SLL(r_meml);
Z80WriteMem( r_HL, r_meml, regs );
AddCycles( 4+4+3+3+1 ); break;
case SLL_A : SLL(r_A); AddCycles( 4+4 ); break;
case SRL_B : SRL(r_B); AddCycles( 4+4 ); break;
case SRL_C : SRL(r_C); AddCycles( 4+4 ); break;
case SRL_D : SRL(r_D); AddCycles( 4+4 ); break;
case SRL_E : SRL(r_E); AddCycles( 4+4 ); break;
case SRL_H : SRL(r_H); AddCycles( 4+4 ); break;
case SRL_L : SRL(r_L); AddCycles( 4+4 ); break;
case SRL_xHL : r_meml = Z80ReadMem( r_HL );
SRL(r_meml);
Z80WriteMem( r_HL, r_meml, regs );
AddCycles( 4+4+3+3+1 ); break;
case SRL_A : SRL(r_A); AddCycles( 4+4 ); break;
case BIT_0_B : BIT_BIT(0, r_B); AddCycles( 4+4 ); break;
case BIT_0_C : BIT_BIT(0, r_C); AddCycles( 4+4 ); break;
case BIT_0_D : BIT_BIT(0, r_D); AddCycles( 4+4 ); break;
case BIT_0_E : BIT_BIT(0, r_E); AddCycles( 4+4 ); break;
case BIT_0_H : BIT_BIT(0, r_H); AddCycles( 4+4 ); break;
case BIT_0_L : BIT_BIT(0, r_L); AddCycles( 4+4 ); break;
case BIT_0_xHL : BIT_mem_BIT(0, r_HL); AddCycles( 12 ); break;
case BIT_0_A : BIT_BIT(0, r_A); AddCycles( 4+4 ); break;
case BIT_1_B : BIT_BIT(1, r_B); AddCycles( 4+4 ); break;
case BIT_1_C : BIT_BIT(1, r_C); AddCycles( 4+4 ); break;
case BIT_1_D : BIT_BIT(1, r_D); AddCycles( 4+4 ); break;
case BIT_1_E : BIT_BIT(1, r_E); AddCycles( 4+4 ); break;
case BIT_1_H : BIT_BIT(1, r_H); AddCycles( 4+4 ); break;
case BIT_1_L : BIT_BIT(1, r_L); AddCycles( 4+4 ); break;
case BIT_1_xHL : BIT_mem_BIT(1, r_HL); AddCycles( 12 ); break;
case BIT_1_A : BIT_BIT(1, r_A); AddCycles( 4+4 ); break;
case BIT_2_B : BIT_BIT(2, r_B); AddCycles( 4+4 ); break;
case BIT_2_C : BIT_BIT(2, r_C); AddCycles( 4+4 ); break;
case BIT_2_D : BIT_BIT(2, r_D); AddCycles( 4+4 ); break;
case BIT_2_E : BIT_BIT(2, r_E); AddCycles( 4+4 ); break;
case BIT_2_H : BIT_BIT(2, r_H); AddCycles( 4+4 ); break;
case BIT_2_L : BIT_BIT(2, r_L); AddCycles( 4+4 ); break;
case BIT_2_xHL : BIT_mem_BIT(2, r_HL); AddCycles( 12 ); break;
case BIT_2_A : BIT_BIT(2, r_A); AddCycles( 4+4 ); break;
case BIT_3_B : BIT_BIT(3, r_B); AddCycles( 4+4 ); break;
case BIT_3_C : BIT_BIT(3, r_C); AddCycles( 4+4 ); break;
case BIT_3_D : BIT_BIT(3, r_D); AddCycles( 4+4 ); break;
case BIT_3_E : BIT_BIT(3, r_E); AddCycles( 4+4 ); break;
case BIT_3_H : BIT_BIT(3, r_H); AddCycles( 4+4 ); break;
case BIT_3_L : BIT_BIT(3, r_L); AddCycles( 4+4 ); break;
case BIT_3_xHL : BIT_mem_BIT(3, r_HL); AddCycles( 12 ); break;
case BIT_3_A : BIT_BIT(3, r_A); AddCycles( 4+4 ); break;
case BIT_4_B : BIT_BIT(4, r_B); AddCycles( 4+4 ); break;
case BIT_4_C : BIT_BIT(4, r_C); AddCycles( 4+4 ); break;
case BIT_4_D : BIT_BIT(4, r_D); AddCycles( 4+4 ); break;
case BIT_4_E : BIT_BIT(4, r_E); AddCycles( 4+4 ); break;
case BIT_4_H : BIT_BIT(4, r_H); AddCycles( 4+4 ); break;
case BIT_4_L : BIT_BIT(4, r_L); AddCycles( 4+4 ); break;
case BIT_4_xHL : BIT_mem_BIT(4, r_HL); AddCycles( 12 ); break;
case BIT_4_A : BIT_BIT(4, r_A); AddCycles( 4+4 ); break;
case BIT_5_B : BIT_BIT(5, r_B); AddCycles( 4+4 ); break;
case BIT_5_C : BIT_BIT(5, r_C); AddCycles( 4+4 ); break;
case BIT_5_D : BIT_BIT(5, r_D); AddCycles( 4+4 ); break;
case BIT_5_E : BIT_BIT(5, r_E); AddCycles( 4+4 ); break;
case BIT_5_H : BIT_BIT(5, r_H); AddCycles( 4+4 ); break;
case BIT_5_L : BIT_BIT(5, r_L); AddCycles( 4+4 ); break;
case BIT_5_xHL : BIT_mem_BIT(5, r_HL); AddCycles( 12 ); break;
case BIT_5_A : BIT_BIT(5, r_A); AddCycles( 4+4 ); break;
case BIT_6_B : BIT_BIT(6, r_B); AddCycles( 4+4 ); break;
case BIT_6_C : BIT_BIT(6, r_C); AddCycles( 4+4 ); break;
case BIT_6_D : BIT_BIT(6, r_D); AddCycles( 4+4 ); break;
case BIT_6_E : BIT_BIT(6, r_E); AddCycles( 4+4 ); break;
case BIT_6_H : BIT_BIT(6, r_H); AddCycles( 4+4 ); break;
case BIT_6_L : BIT_BIT(6, r_L); AddCycles( 4+4 ); break;
case BIT_6_xHL : BIT_mem_BIT(6, r_HL); AddCycles( 12 ); break;
case BIT_6_A : BIT_BIT(6, r_A); AddCycles( 4+4 ); break;
case BIT_7_B : BIT_BIT7(r_B); AddCycles( 4+4 ); break;
case BIT_7_C : BIT_BIT7(r_C); AddCycles( 4+4 ); break;
case BIT_7_D : BIT_BIT7(r_D); AddCycles( 4+4 ); break;
case BIT_7_E : BIT_BIT7(r_E); AddCycles( 4+4 ); break;
case BIT_7_H : BIT_BIT7(r_H); AddCycles( 4+4 ); break;
case BIT_7_L : BIT_BIT7(r_L); AddCycles( 4+4 ); break;
case BIT_7_xHL : BIT_mem_BIT7(r_HL); AddCycles( 12 ); break;
case BIT_7_A : BIT_BIT7(r_A); AddCycles( 4+4 ); break;
case RES_0_B : BIT_RES(0, r_B); AddCycles( 4+4 ); break;
case RES_0_C : BIT_RES(0, r_C); AddCycles( 4+4 ); break;
case RES_0_D : BIT_RES(0, r_D); AddCycles( 4+4 ); break;
case RES_0_E : BIT_RES(0, r_E); AddCycles( 4+4 ); break;
case RES_0_H : BIT_RES(0, r_H); AddCycles( 4+4 ); break;
case RES_0_L : BIT_RES(0, r_L); AddCycles( 4+4 ); break;
case RES_0_xHL : BIT_mem_RES(0, r_HL); AddCycles( 4+4+7 ); break;
case RES_0_A : BIT_RES(0, r_A); AddCycles( 4+4 ); break;
case RES_1_B : BIT_RES(1, r_B); AddCycles( 4+4 ); break;
case RES_1_C : BIT_RES(1, r_C); AddCycles( 4+4 ); break;
case RES_1_D : BIT_RES(1, r_D); AddCycles( 4+4 ); break;
case RES_1_E : BIT_RES(1, r_E); AddCycles( 4+4 ); break;
case RES_1_H : BIT_RES(1, r_H); AddCycles( 4+4 ); break;
case RES_1_L : BIT_RES(1, r_L); AddCycles( 4+4 ); break;
case RES_1_xHL : BIT_mem_RES(1, r_HL); AddCycles( 4+4+7 ); break;
case RES_1_A : BIT_RES(1, r_A); AddCycles( 4+4 ); break;
case RES_2_B : BIT_RES(2, r_B); AddCycles( 4+4 ); break;
case RES_2_C : BIT_RES(2, r_C); AddCycles( 4+4 ); break;
case RES_2_D : BIT_RES(2, r_D); AddCycles( 4+4 ); break;
case RES_2_E : BIT_RES(2, r_E); AddCycles( 4+4 ); break;
case RES_2_H : BIT_RES(2, r_H); AddCycles( 4+4 ); break;
case RES_2_L : BIT_RES(2, r_L); AddCycles( 4+4 ); break;
case RES_2_xHL : BIT_mem_RES(2, r_HL); AddCycles( 4+4+7 ); break;
case RES_2_A : BIT_RES(2, r_A); AddCycles( 4+4 ); break;
case RES_3_B : BIT_RES(3, r_B); AddCycles( 4+4 ); break;
case RES_3_C : BIT_RES(3, r_C); AddCycles( 4+4 ); break;
case RES_3_D : BIT_RES(3, r_D); AddCycles( 4+4 ); break;
case RES_3_E : BIT_RES(3, r_E); AddCycles( 4+4 ); break;
case RES_3_H : BIT_RES(3, r_H); AddCycles( 4+4 ); break;
case RES_3_L : BIT_RES(3, r_L); AddCycles( 4+4 ); break;
case RES_3_xHL : BIT_mem_RES(3, r_HL); AddCycles( 4+4+7 ); break;
case RES_3_A : BIT_RES(3, r_A); AddCycles( 4+4 ); break;
case RES_4_B : BIT_RES(4, r_B); AddCycles( 4+4 ); break;
case RES_4_C : BIT_RES(4, r_C); AddCycles( 4+4 ); break;
case RES_4_D : BIT_RES(4, r_D); AddCycles( 4+4 ); break;
case RES_4_E : BIT_RES(4, r_E); AddCycles( 4+4 ); break;
case RES_4_H : BIT_RES(4, r_H); AddCycles( 4+4 ); break;
case RES_4_L : BIT_RES(4, r_L); AddCycles( 4+4 ); break;
case RES_4_xHL : BIT_mem_RES(4, r_HL); AddCycles( 4+4+7 ); break;
case RES_4_A : BIT_RES(4, r_A); AddCycles( 4+4 ); break;
case RES_5_B : BIT_RES(5, r_B); AddCycles( 4+4 ); break;
case RES_5_C : BIT_RES(5, r_C); AddCycles( 4+4 ); break;
case RES_5_D : BIT_RES(5, r_D); AddCycles( 4+4 ); break;
case RES_5_E : BIT_RES(5, r_E); AddCycles( 4+4 ); break;
case RES_5_H : BIT_RES(5, r_H); AddCycles( 4+4 ); break;
case RES_5_L : BIT_RES(5, r_L); AddCycles( 4+4 ); break;
case RES_5_xHL : BIT_mem_RES(5, r_HL); AddCycles( 4+4+7 ); break;
case RES_5_A : BIT_RES(5, r_A); AddCycles( 4+4 ); break;
case RES_6_B : BIT_RES(6, r_B); AddCycles( 4+4 ); break;
case RES_6_C : BIT_RES(6, r_C); AddCycles( 4+4 ); break;
case RES_6_D : BIT_RES(6, r_D); AddCycles( 4+4 ); break;
case RES_6_E : BIT_RES(6, r_E); AddCycles( 4+4 ); break;
case RES_6_H : BIT_RES(6, r_H); AddCycles( 4+4 ); break;
case RES_6_L : BIT_RES(6, r_L); AddCycles( 4+4 ); break;
case RES_6_xHL : BIT_mem_RES(6, r_HL); AddCycles( 4+4+7 ); break;
case RES_6_A : BIT_RES(6, r_A); AddCycles( 4+4 ); break;
case RES_7_B : BIT_RES(7, r_B); AddCycles( 4+4 ); break;
case RES_7_C : BIT_RES(7, r_C); AddCycles( 4+4 ); break;
case RES_7_D : BIT_RES(7, r_D); AddCycles( 4+4 ); break;
case RES_7_E : BIT_RES(7, r_E); AddCycles( 4+4 ); break;
case RES_7_H : BIT_RES(7, r_H); AddCycles( 4+4 ); break;
case RES_7_L : BIT_RES(7, r_L); AddCycles( 4+4 ); break;
case RES_7_xHL : BIT_mem_RES(7, r_HL); AddCycles( 4+4+7 ); break;
case RES_7_A : BIT_RES(7, r_A); AddCycles( 4+4 ); break;
case SET_0_B : BIT_SET(0, r_B); AddCycles( 4+4 ); break;
case SET_0_C : BIT_SET(0, r_C); AddCycles( 4+4 ); break;
case SET_0_D : BIT_SET(0, r_D); AddCycles( 4+4 ); break;
case SET_0_E : BIT_SET(0, r_E); AddCycles( 4+4 ); break;
case SET_0_H : BIT_SET(0, r_H); AddCycles( 4+4 ); break;
case SET_0_L : BIT_SET(0, r_L); AddCycles( 4+4 ); break;
case SET_0_xHL : BIT_mem_SET(0, r_HL); AddCycles( 4+4+7 ); break;
case SET_0_A : BIT_SET(0, r_A); AddCycles( 4+4 ); break;
case SET_1_B : BIT_SET(1, r_B); AddCycles( 4+4 ); break;
case SET_1_C : BIT_SET(1, r_C); AddCycles( 4+4 ); break;
case SET_1_D : BIT_SET(1, r_D); AddCycles( 4+4 ); break;
case SET_1_E : BIT_SET(1, r_E); AddCycles( 4+4 ); break;
case SET_1_H : BIT_SET(1, r_H); AddCycles( 4+4 ); break;
case SET_1_L : BIT_SET(1, r_L); AddCycles( 4+4 ); break;
case SET_1_xHL : BIT_mem_SET(1, r_HL); AddCycles( 4+4+7 ); break;
case SET_1_A : BIT_SET(1, r_A); AddCycles( 4+4 ); break;
case SET_2_B : BIT_SET(2, r_B); AddCycles( 4+4 ); break;
case SET_2_C : BIT_SET(2, r_C); AddCycles( 4+4 ); break;
case SET_2_D : BIT_SET(2, r_D); AddCycles( 4+4 ); break;
case SET_2_E : BIT_SET(2, r_E); AddCycles( 4+4 ); break;
case SET_2_H : BIT_SET(2, r_H); AddCycles( 4+4 ); break;
case SET_2_L : BIT_SET(2, r_L); AddCycles( 4+4 ); break;
case SET_2_xHL : BIT_mem_SET(2, r_HL); AddCycles( 4+4+7 ); break;
case SET_2_A : BIT_SET(2, r_A); AddCycles( 4+4 ); break;
case SET_3_B : BIT_SET(3, r_B); AddCycles( 4+4 ); break;
case SET_3_C : BIT_SET(3, r_C); AddCycles( 4+4 ); break;
case SET_3_D : BIT_SET(3, r_D); AddCycles( 4+4 ); break;
case SET_3_E : BIT_SET(3, r_E); AddCycles( 4+4 ); break;
case SET_3_H : BIT_SET(3, r_H); AddCycles( 4+4 ); break;
case SET_3_L : BIT_SET(3, r_L); AddCycles( 4+4 ); break;
case SET_3_xHL : BIT_mem_SET(3, r_HL); AddCycles( 4+4+7 ); break;
case SET_3_A : BIT_SET(3, r_A); AddCycles( 4+4 ); break;
case SET_4_B : BIT_SET(4, r_B); AddCycles( 4+4 ); break;
case SET_4_C : BIT_SET(4, r_C); AddCycles( 4+4 ); break;
case SET_4_D : BIT_SET(4, r_D); AddCycles( 4+4 ); break;
case SET_4_E : BIT_SET(4, r_E); AddCycles( 4+4 ); break;
case SET_4_H : BIT_SET(4, r_H); AddCycles( 4+4 ); break;
case SET_4_L : BIT_SET(4, r_L); AddCycles( 4+4 ); break;
case SET_4_xHL : BIT_mem_SET(4, r_HL); AddCycles( 4+4+7 ); break;
case SET_4_A : BIT_SET(4, r_A); AddCycles( 4+4 ); break;
case SET_5_B : BIT_SET(5, r_B); AddCycles( 4+4 ); break;
case SET_5_C : BIT_SET(5, r_C); AddCycles( 4+4 ); break;
case SET_5_D : BIT_SET(5, r_D); AddCycles( 4+4 ); break;
case SET_5_E : BIT_SET(5, r_E); AddCycles( 4+4 ); break;
case SET_5_H : BIT_SET(5, r_H); AddCycles( 4+4 ); break;
case SET_5_L : BIT_SET(5, r_L); AddCycles( 4+4 ); break;
case SET_5_xHL : BIT_mem_SET(5, r_HL); AddCycles( 4+4+7 ); break;
case SET_5_A : BIT_SET(5, r_A); AddCycles( 4+4 ); break;
case SET_6_B : BIT_SET(6, r_B); AddCycles( 4+4 ); break;
case SET_6_C : BIT_SET(6, r_C); AddCycles( 4+4 ); break;
case SET_6_D : BIT_SET(6, r_D); AddCycles( 4+4 ); break;
case SET_6_E : BIT_SET(6, r_E); AddCycles( 4+4 ); break;
case SET_6_H : BIT_SET(6, r_H); AddCycles( 4+4 ); break;
case SET_6_L : BIT_SET(6, r_L); AddCycles( 4+4 ); break;
case SET_6_xHL : BIT_mem_SET(6, r_HL); AddCycles( 4+4+7 ); break;
case SET_6_A : BIT_SET(6, r_A); AddCycles( 4+4 ); break;
case SET_7_B : BIT_SET(7, r_B); AddCycles( 4+4 ); break;
case SET_7_C : BIT_SET(7, r_C); AddCycles( 4+4 ); break;
case SET_7_D : BIT_SET(7, r_D); AddCycles( 4+4 ); break;
case SET_7_E : BIT_SET(7, r_E); AddCycles( 4+4 ); break;
case SET_7_H : BIT_SET(7, r_H); AddCycles( 4+4 ); break;
case SET_7_L : BIT_SET(7, r_L); AddCycles( 4+4 ); break;
case SET_7_xHL : BIT_mem_SET(7, r_HL); AddCycles( 4+4+7 ); break;
case SET_7_A : BIT_SET(7, r_A); AddCycles( 4+4 ); break;
default:
// exit(1);
///!!! if( regs->DecodingErrors )
///!!! printf("z80 core: Unknown instruction: CB %02Xh at PC=%04Xh.\n",
///!!! Z80ReadMem(r_PC-1), r_PC-2 );
break;
}