Includes/instr_set/opcodes_Grp15.c

/* Copyright 2006-2009, BeatriX
 * File coded by BeatriX
 *
 * This file is part of BeaEngine.
 *
 *    BeaEngine is free software: you can redistribute it and/or modify
 *    it under the terms of the GNU Lesser General Public License as published by
 *    the Free Software Foundation, either version 3 of the License, or
 *    (at your option) any later version.
 *
 *    BeaEngine 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 Lesser General Public License for more details.
 *
 *    You should have received a copy of the GNU Lesser General Public License
 *    along with BeaEngine.  If not, see <http://www.gnu.org/licenses/>. */

/* ====================================================================
 *
 * ==================================================================== */
void __bea_callspec__ G15_(PDISASM pMyDisasm)
{
    GV.REGOPCODE = ((*((UInt8*)(UIntPtr) (GV.EIP_+1))) >> 3) & 0x7;
    if (GV.REGOPCODE == 0) {
        MOD_RM(&(*pMyDisasm).Argument1, pMyDisasm);
        if (GV.MOD_!= 0x3) {
            GV.MemDecoration = Arg1multibytes;
            (*pMyDisasm).Instruction.Category = FPU_INSTRUCTION+STATE_MANAGEMENT;
            #ifndef BEA_LIGHT_DISASSEMBLY
               (void) strcpy ((*pMyDisasm).Instruction.Mnemonic, "fxsave ");
            #endif
            (*pMyDisasm).Argument1.ArgSize = 512;
            (*pMyDisasm).Argument2.ArgType = REGISTER_TYPE+FPU_REG+MMX_REG+SSE_REG;
            (*pMyDisasm).Argument2.ArgSize = 512;
        }
        else {
            FailDecode(pMyDisasm);
        }
    }
    else if (GV.REGOPCODE == 1) {
        MOD_RM(&(*pMyDisasm).Argument2, pMyDisasm);
        if (GV.MOD_!= 0x3) {
            GV.MemDecoration = Arg2multibytes;
            (*pMyDisasm).Instruction.Category = FPU_INSTRUCTION+STATE_MANAGEMENT;
            #ifndef BEA_LIGHT_DISASSEMBLY
               (void) strcpy ((*pMyDisasm).Instruction.Mnemonic, "fxrstor ");
            #endif
            (*pMyDisasm).Argument2.ArgSize = 512;
            (*pMyDisasm).Argument1.ArgType = REGISTER_TYPE+FPU_REG+MMX_REG+SSE_REG;
            (*pMyDisasm).Argument1.ArgSize = 512;
        }
        else {
            FailDecode(pMyDisasm);
        }

    }
    else if (GV.REGOPCODE == 2) {
        MOD_RM(&(*pMyDisasm).Argument2, pMyDisasm);
        if (GV.MOD_!= 0x3) {
            GV.MemDecoration = Arg2dword;
            (*pMyDisasm).Instruction.Category = SSE_INSTRUCTION+STATE_MANAGEMENT;
            #ifndef BEA_LIGHT_DISASSEMBLY
               (void) strcpy ((*pMyDisasm).Instruction.Mnemonic, "ldmxcsr ");
            #endif
            (*pMyDisasm).Argument1.ArgType = REGISTER_TYPE+SPECIAL_REG+REG1;
            (*pMyDisasm).Argument1.ArgSize = 32;
        }
        else {
            FailDecode(pMyDisasm);
        }

    }
    else if (GV.REGOPCODE == 3) {
        MOD_RM(&(*pMyDisasm).Argument1, pMyDisasm);
        if (GV.MOD_!= 0x3) {
            GV.MemDecoration = Arg1dword;
            (*pMyDisasm).Instruction.Category = SSE_INSTRUCTION+STATE_MANAGEMENT;
            #ifndef BEA_LIGHT_DISASSEMBLY
               (void) strcpy ((*pMyDisasm).Instruction.Mnemonic, "stmxcsr ");
            #endif
            (*pMyDisasm).Argument2.ArgType = REGISTER_TYPE+SPECIAL_REG+REG1;
            (*pMyDisasm).Argument2.ArgSize = 32;
        }
        else {
            FailDecode(pMyDisasm);
        }

    }

    else if (GV.REGOPCODE == 4) {
        MOD_RM(&(*pMyDisasm).Argument1, pMyDisasm);
        if (GV.MOD_!= 0x3) {
            GV.MemDecoration = Arg1multibytes;
            (*pMyDisasm).Instruction.Category = FPU_INSTRUCTION+STATE_MANAGEMENT;
            #ifndef BEA_LIGHT_DISASSEMBLY
               (void) strcpy ((*pMyDisasm).Instruction.Mnemonic, "xsave ");
            #endif
            (*pMyDisasm).Argument1.ArgSize = 512;
            (*pMyDisasm).Argument2.ArgType = REGISTER_TYPE+FPU_REG+MMX_REG+SSE_REG;
            (*pMyDisasm).Argument2.ArgSize = 512;
        }
        else {
            FailDecode(pMyDisasm);
        }
    }

    else if (GV.REGOPCODE == 5) {
        GV.MOD_= ((*((UInt8*)(UIntPtr) (GV.EIP_+1))) >> 6) & 0x3;
        if (GV.MOD_== 0x3) {
            (*pMyDisasm).Instruction.Category = SSE2_INSTRUCTION+CACHEABILITY_CONTROL;
            #ifndef BEA_LIGHT_DISASSEMBLY
               (void) strcpy ((*pMyDisasm).Instruction.Mnemonic, "lfence ");
            #endif
        }
        else {
            MOD_RM(&(*pMyDisasm).Argument2, pMyDisasm);
            GV.MemDecoration = Arg2multibytes;
            (*pMyDisasm).Instruction.Category = FPU_INSTRUCTION+STATE_MANAGEMENT;
            #ifndef BEA_LIGHT_DISASSEMBLY
               (void) strcpy ((*pMyDisasm).Instruction.Mnemonic, "xrstor ");
            #endif
            (*pMyDisasm).Argument2.ArgSize = 512;
            (*pMyDisasm).Argument1.ArgType = REGISTER_TYPE+FPU_REG+MMX_REG+SSE_REG;
            (*pMyDisasm).Argument1.ArgSize = 512;
        }

    }
    else if (GV.REGOPCODE == 6) {
        GV.MOD_= ((*((UInt8*)(UIntPtr) (GV.EIP_+1))) >> 6) & 0x3;
        if (GV.MOD_== 0x3) {
            (*pMyDisasm).Instruction.Category = SSE2_INSTRUCTION+CACHEABILITY_CONTROL;
            #ifndef BEA_LIGHT_DISASSEMBLY
               (void) strcpy ((*pMyDisasm).Instruction.Mnemonic, "mfence ");
            #endif
        }
        else {
            FailDecode(pMyDisasm);
        }
    }
    else if (GV.REGOPCODE == 7) {
        GV.MOD_= ((*((UInt8*)(UIntPtr) (GV.EIP_+1))) >> 6) & 0x3;
        if (GV.MOD_== 0x3) {
            (*pMyDisasm).Instruction.Category = SSE2_INSTRUCTION+CACHEABILITY_CONTROL;
            #ifndef BEA_LIGHT_DISASSEMBLY
               (void) strcpy ((*pMyDisasm).Instruction.Mnemonic, "sfence ");
            #endif
        }
        else {
            GV.OperandSize = 8;
            MOD_RM(&(*pMyDisasm).Argument2, pMyDisasm);
            GV.OperandSize = 32;
            GV.MemDecoration = Arg2byte;
            (*pMyDisasm).Instruction.Category = SSE2_INSTRUCTION+CACHEABILITY_CONTROL;
            #ifndef BEA_LIGHT_DISASSEMBLY
               (void) strcpy ((*pMyDisasm).Instruction.Mnemonic, "clflush ");
            #endif
        }

    }

    else {
        FailDecode(pMyDisasm);
    }
    GV.EIP_+= GV.DECALAGE_EIP+2;
}
Revision:	984
Committed:	Sun Mar 16 23:35:10 2014 UTC (11 years, 7 months ago) by alloc
Content type:	text/x-csrc
File size:	6509 byte(s)
Log Message:	Daodan: TV code
#	Content
1	/* Copyright 2006-2009, BeatriX
2	* File coded by BeatriX
3	*
4	* This file is part of BeaEngine.
5	*
6	* BeaEngine is free software: you can redistribute it and/or modify
7	* it under the terms of the GNU Lesser General Public License as published by
8	* the Free Software Foundation, either version 3 of the License, or
9	* (at your option) any later version.
10	*
11	* BeaEngine is distributed in the hope that it will be useful,
12	* but WITHOUT ANY WARRANTY; without even the implied warranty of
13	* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
14	* GNU Lesser General Public License for more details.
15	*
16	* You should have received a copy of the GNU Lesser General Public License
17	* along with BeaEngine. If not, see <http://www.gnu.org/licenses/>. */
18
19	/* ====================================================================
20	*
21	* ==================================================================== */
22	void __bea_callspec__ G15_(PDISASM pMyDisasm)
23	{
24	GV.REGOPCODE = ((((UInt8)(UIntPtr) (GV.EIP_+1))) >> 3) & 0x7;
25	if (GV.REGOPCODE == 0) {
26	MOD_RM(&(*pMyDisasm).Argument1, pMyDisasm);
27	if (GV.MOD_!= 0x3) {
28	GV.MemDecoration = Arg1multibytes;
29	(*pMyDisasm).Instruction.Category = FPU_INSTRUCTION+STATE_MANAGEMENT;
30	#ifndef BEA_LIGHT_DISASSEMBLY
31	(void) strcpy ((*pMyDisasm).Instruction.Mnemonic, "fxsave ");
32	#endif
33	(*pMyDisasm).Argument1.ArgSize = 512;
34	(*pMyDisasm).Argument2.ArgType = REGISTER_TYPE+FPU_REG+MMX_REG+SSE_REG;
35	(*pMyDisasm).Argument2.ArgSize = 512;
36	}
37	else {
38	FailDecode(pMyDisasm);
39	}
40	}
41	else if (GV.REGOPCODE == 1) {
42	MOD_RM(&(*pMyDisasm).Argument2, pMyDisasm);
43	if (GV.MOD_!= 0x3) {
44	GV.MemDecoration = Arg2multibytes;
45	(*pMyDisasm).Instruction.Category = FPU_INSTRUCTION+STATE_MANAGEMENT;
46	#ifndef BEA_LIGHT_DISASSEMBLY
47	(void) strcpy ((*pMyDisasm).Instruction.Mnemonic, "fxrstor ");
48	#endif
49	(*pMyDisasm).Argument2.ArgSize = 512;
50	(*pMyDisasm).Argument1.ArgType = REGISTER_TYPE+FPU_REG+MMX_REG+SSE_REG;
51	(*pMyDisasm).Argument1.ArgSize = 512;
52	}
53	else {
54	FailDecode(pMyDisasm);
55	}
56
57	}
58	else if (GV.REGOPCODE == 2) {
59	MOD_RM(&(*pMyDisasm).Argument2, pMyDisasm);
60	if (GV.MOD_!= 0x3) {
61	GV.MemDecoration = Arg2dword;
62	(*pMyDisasm).Instruction.Category = SSE_INSTRUCTION+STATE_MANAGEMENT;
63	#ifndef BEA_LIGHT_DISASSEMBLY
64	(void) strcpy ((*pMyDisasm).Instruction.Mnemonic, "ldmxcsr ");
65	#endif
66	(*pMyDisasm).Argument1.ArgType = REGISTER_TYPE+SPECIAL_REG+REG1;
67	(*pMyDisasm).Argument1.ArgSize = 32;
68	}
69	else {
70	FailDecode(pMyDisasm);
71	}
72
73	}
74	else if (GV.REGOPCODE == 3) {
75	MOD_RM(&(*pMyDisasm).Argument1, pMyDisasm);
76	if (GV.MOD_!= 0x3) {
77	GV.MemDecoration = Arg1dword;
78	(*pMyDisasm).Instruction.Category = SSE_INSTRUCTION+STATE_MANAGEMENT;
79	#ifndef BEA_LIGHT_DISASSEMBLY
80	(void) strcpy ((*pMyDisasm).Instruction.Mnemonic, "stmxcsr ");
81	#endif
82	(*pMyDisasm).Argument2.ArgType = REGISTER_TYPE+SPECIAL_REG+REG1;
83	(*pMyDisasm).Argument2.ArgSize = 32;
84	}
85	else {
86	FailDecode(pMyDisasm);
87	}
88
89	}
90
91	else if (GV.REGOPCODE == 4) {
92	MOD_RM(&(*pMyDisasm).Argument1, pMyDisasm);
93	if (GV.MOD_!= 0x3) {
94	GV.MemDecoration = Arg1multibytes;
95	(*pMyDisasm).Instruction.Category = FPU_INSTRUCTION+STATE_MANAGEMENT;
96	#ifndef BEA_LIGHT_DISASSEMBLY
97	(void) strcpy ((*pMyDisasm).Instruction.Mnemonic, "xsave ");
98	#endif
99	(*pMyDisasm).Argument1.ArgSize = 512;
100	(*pMyDisasm).Argument2.ArgType = REGISTER_TYPE+FPU_REG+MMX_REG+SSE_REG;
101	(*pMyDisasm).Argument2.ArgSize = 512;
102	}
103	else {
104	FailDecode(pMyDisasm);
105	}
106	}
107
108	else if (GV.REGOPCODE == 5) {
109	GV.MOD_= ((((UInt8)(UIntPtr) (GV.EIP_+1))) >> 6) & 0x3;
110	if (GV.MOD_== 0x3) {
111	(*pMyDisasm).Instruction.Category = SSE2_INSTRUCTION+CACHEABILITY_CONTROL;
112	#ifndef BEA_LIGHT_DISASSEMBLY
113	(void) strcpy ((*pMyDisasm).Instruction.Mnemonic, "lfence ");
114	#endif
115	}
116	else {
117	MOD_RM(&(*pMyDisasm).Argument2, pMyDisasm);
118	GV.MemDecoration = Arg2multibytes;
119	(*pMyDisasm).Instruction.Category = FPU_INSTRUCTION+STATE_MANAGEMENT;
120	#ifndef BEA_LIGHT_DISASSEMBLY
121	(void) strcpy ((*pMyDisasm).Instruction.Mnemonic, "xrstor ");
122	#endif
123	(*pMyDisasm).Argument2.ArgSize = 512;
124	(*pMyDisasm).Argument1.ArgType = REGISTER_TYPE+FPU_REG+MMX_REG+SSE_REG;
125	(*pMyDisasm).Argument1.ArgSize = 512;
126	}
127
128	}
129	else if (GV.REGOPCODE == 6) {
130	GV.MOD_= ((((UInt8)(UIntPtr) (GV.EIP_+1))) >> 6) & 0x3;
131	if (GV.MOD_== 0x3) {
132	(*pMyDisasm).Instruction.Category = SSE2_INSTRUCTION+CACHEABILITY_CONTROL;
133	#ifndef BEA_LIGHT_DISASSEMBLY
134	(void) strcpy ((*pMyDisasm).Instruction.Mnemonic, "mfence ");
135	#endif
136	}
137	else {
138	FailDecode(pMyDisasm);
139	}
140	}
141	else if (GV.REGOPCODE == 7) {
142	GV.MOD_= ((((UInt8)(UIntPtr) (GV.EIP_+1))) >> 6) & 0x3;
143	if (GV.MOD_== 0x3) {
144	(*pMyDisasm).Instruction.Category = SSE2_INSTRUCTION+CACHEABILITY_CONTROL;
145	#ifndef BEA_LIGHT_DISASSEMBLY
146	(void) strcpy ((*pMyDisasm).Instruction.Mnemonic, "sfence ");
147	#endif
148	}
149	else {
150	GV.OperandSize = 8;
151	MOD_RM(&(*pMyDisasm).Argument2, pMyDisasm);
152	GV.OperandSize = 32;
153	GV.MemDecoration = Arg2byte;
154	(*pMyDisasm).Instruction.Category = SSE2_INSTRUCTION+CACHEABILITY_CONTROL;
155	#ifndef BEA_LIGHT_DISASSEMBLY
156	(void) strcpy ((*pMyDisasm).Instruction.Mnemonic, "clflush ");
157	#endif
158	}
159
160	}
161
162	else {
163	FailDecode(pMyDisasm);
164	}
165	GV.EIP_+= GV.DECALAGE_EIP+2;
166	}