src/cpus/cpu_m88k_instr_loadstore.c

/*
 *  Copyright (C) 2007  Anders Gavare.  All rights reserved.
 *
 *  Redistribution and use in source and binary forms, with or without
 *  modification, are permitted provided that the following conditions are met:
 *
 *  1. Redistributions of source code must retain the above copyright
 *     notice, this list of conditions and the following disclaimer.
 *  2. Redistributions in binary form must reproduce the above copyright
 *     notice, this list of conditions and the following disclaimer in the
 *     documentation and/or other materials provided with the distribution.
 *  3. The name of the author may not be used to endorse or promote products
 *     derived from this software without specific prior written permission.
 *
 *  THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND
 *  ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
 *  IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
 *  ARE DISCLAIMED.  IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE
 *  FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
 *  DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
 *  OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
 *  HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
 *  LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
 *  OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
 *  SUCH DAMAGE.
 *
 *
 *  $Id: cpu_m88k_instr_loadstore.c,v 1.8 2007/05/27 03:01:28 debug Exp $
 *
 *  M88K load/store instructions; the following args are used:
 *  
 *  arg[0] = pointer to the register to load to or store from (d)
 *  arg[1] = pointer to the base register (s1)
 *  arg[2] = pointer to the offset register (s2), or an uint32_t offset
 *
 *  The GENERIC function always checks for alignment, and supports both big
 *  and little endian byte order.
 *
 *  The quick function is included twice (big/little endian) for each
 *  GENERIC function.
 *
 *
 *  Defines:
 *      LS_LOAD or LS_STORE (only one)
 *      LS_INCLUDE_GENERIC (to generate the generic function)
 *      LS_GENERIC_N is defined as the name of the generic function
 *      LS_N is defined as the name of the fast function
 *      LS_1, LS_2, LS_4, or LS_8 (only one)
 *      LS_SIZE is defined to 1, 2, 4, or 8
 *      LS_SIGNED is defined for signed loads
 *      LS_LE or LS_BE (only one)
 *      LS_SCALED for scaled accesses
 *      LS_USR for usr accesses
 *      LS_REGOFS is defined when arg[2] is a register pointer
 */


#ifdef LS_INCLUDE_GENERIC
void LS_GENERIC_N(struct cpu *cpu, struct m88k_instr_call *ic)
{
#ifdef LS_USR
        const int memory_rw_flags = CACHE_DATA | MEMORY_USER_ACCESS;
#else
        const int memory_rw_flags = CACHE_DATA;
#endif
        uint32_t addr = reg(ic->arg[1]) +
#ifdef LS_REGOFS
#ifdef LS_SCALED
            LS_SIZE *
#endif
            reg(ic->arg[2]);
#else
            ic->arg[2];
#endif
        uint8_t data[LS_SIZE];
        uint64_t x;

        /*  Synchronize the PC:  */
        int low_pc = ((size_t)ic - (size_t)cpu->cd.m88k.cur_ic_page)
            / sizeof(struct m88k_instr_call);
        cpu->pc &= ~((M88K_IC_ENTRIES_PER_PAGE-1)<<M88K_INSTR_ALIGNMENT_SHIFT);
        cpu->pc += (low_pc << M88K_INSTR_ALIGNMENT_SHIFT);

        /*
         *  Update the memory transaction registers:
         */
        cpu->cd.m88k.dmt[1] = 0;

        cpu->cd.m88k.dmt[0] = DMT_VALID;
#ifdef LS_STORE
        cpu->cd.m88k.dmt[0] |= DMT_WRITE;
#else
        {
                int dreg = (((uint32_t *)ic->arg[0]) - &cpu->cd.m88k.r[0]);
                if (dreg < 1 || dreg > 31) {
                        fatal("HUH? dreg = %i in cpu_m88k_instr_loadstore.c."
                            " Internal error.\n", dreg);
                        exit(1);
                }
                cpu->cd.m88k.dmt[0] |= dreg << DMT_DREGSHIFT;
        }
#ifdef LS_SIGNED
        cpu->cd.m88k.dmt[0] |= DMT_SIGNED;
#endif
#endif
        if (cpu->byte_order == EMUL_LITTLE_ENDIAN)
                cpu->cd.m88k.dmt[0] |= DMT_BO;

#ifndef LS_USR
        if (cpu->cd.m88k.cr[M88K_CR_PSR] & M88K_PSR_MODE)
                cpu->cd.m88k.dmt[0] |= DMT_DAS;         /*  supervisor  */
#endif

        /*  EN bits:  */
#ifdef LS_1
        /*  TODO: Is the EN offset only valid for Big-Endian?  */
        cpu->cd.m88k.dmt[0] |= 1 << DMT_ENSHIFT << (3 - (addr & 3));
#else
#ifdef LS_2
        cpu->cd.m88k.dmt[0] |= 3 << DMT_ENSHIFT << (2 - (addr & 2));
#else
        cpu->cd.m88k.dmt[0] |= 0xf << DMT_ENSHIFT;
#endif
#endif

        cpu->cd.m88k.dma[0] = addr & ~0x3;
        cpu->cd.m88k.dmd[0] = 0;

#ifdef LS_8
        cpu->cd.m88k.dmt[1] = cpu->cd.m88k.dmt[0];
        cpu->cd.m88k.dmt[0] |= DMT_DOUB1;
        cpu->cd.m88k.dma[1] = cpu->cd.m88k.dma[0] + sizeof(uint32_t);
        cpu->cd.m88k.dmd[0] = 0;
#ifdef LS_LOAD
        {
                int dreg = (((uint32_t *)ic->arg[0]) - &cpu->cd.m88k.r[0]);
                dreg ++;
                if (dreg < 1 || dreg > 31) {
                        fatal("HUH? dreg = %i in cpu_m88k_instr_loadstore.c."
                            " Internal error.\n", dreg);
                        exit(1);
                }
                cpu->cd.m88k.dmt[1] &= ~((0x1f) << DMT_DREGSHIFT);
                cpu->cd.m88k.dmt[1] |= dreg << DMT_DREGSHIFT;
        }
#endif
#endif


#ifdef LS_USR
        if (!(cpu->cd.m88k.cr[M88K_CR_PSR] & M88K_PSR_MODE)) {
                /*  Cause a privilege violation exception:  */
                m88k_exception(cpu, M88K_EXCEPTION_PRIVILEGE_VIOLATION, 0);
                return;
        }
#endif

#ifndef LS_1
        /*  Check alignment:  */
        if (addr & (LS_SIZE - 1)) {
#if 0
                /*  Cause an address alignment exception:  */
                m88k_exception(cpu, M88K_EXCEPTION_MISALIGNED_ACCESS, 0);
#else
                fatal("{ m88k dyntrans alignment exception, size = %i,"
                    " addr = %08"PRIx32", pc = %08"PRIx32" }\n", LS_SIZE,
                    (uint32_t) addr, (uint32_t) cpu->pc);

                /*  TODO: Generalize this into a abort_call, or similar:  */
                cpu->running = 0;
                debugger_n_steps_left_before_interaction = 0;
                cpu->cd.m88k.next_ic = &nothing_call;

                if (cpu->delay_slot)
                        cpu->delay_slot |= EXCEPTION_IN_DELAY_SLOT;
#endif
                return;
        }
#endif

#ifdef LS_LOAD
        if (!cpu->memory_rw(cpu, cpu->mem, addr, data, sizeof(data),
            MEM_READ, memory_rw_flags)) {
                /*  Exception.  */
                return;
        }
        x = memory_readmax64(cpu, data, LS_SIZE);
#ifdef LS_8
        if (cpu->byte_order == EMUL_BIG_ENDIAN) {
                reg(ic->arg[0]) = x >> 32;
                reg(ic->arg[0] + 4) = x;
        } else {
                reg(ic->arg[0]) = x;
                reg(ic->arg[0] + 4) = x >> 32;
        }
#else
#ifdef LS_SIGNED
#ifdef LS_1
        x = (int8_t)x;
#endif
#ifdef LS_2
        x = (int16_t)x;
#endif
#ifdef LS_4
        x = (int32_t)x;
#endif
#endif
        reg(ic->arg[0]) = x;
#endif

#else   /*  LS_STORE:  */

#ifdef LS_8
        if (cpu->byte_order == EMUL_BIG_ENDIAN)
                x = ((uint64_t)reg(ic->arg[0]) << 32) + reg(ic->arg[0] + 4);
        else
                x = ((uint64_t)reg(ic->arg[0] + 4) << 32) + reg(ic->arg[0]);
        cpu->cd.m88k.dmd[0] = reg(ic->arg[0]);
        cpu->cd.m88k.dmd[1] = reg(ic->arg[0] + 4);
#else
        x = reg(ic->arg[0]);
        cpu->cd.m88k.dmd[0] = x;
#endif
        memory_writemax64(cpu, data, LS_SIZE, x);
        if (!cpu->memory_rw(cpu, cpu->mem, addr, data, sizeof(data),
            MEM_WRITE, memory_rw_flags)) {
                /*  Exception.  */
                return;
        }
#endif
}
#endif  /*  LS_INCLUDE_GENERIC  */


void LS_N(struct cpu *cpu, struct m88k_instr_call *ic)
{
        uint32_t addr = reg(ic->arg[1]) +
#ifdef LS_REGOFS
#ifdef LS_SCALED
            LS_SIZE *
#endif
            reg(ic->arg[2]);
#else
            ic->arg[2];
#endif

#ifdef LS_USR
#ifdef LS_LOAD
        uint8_t *p = cpu->cd.m88k.host_load_usr[addr >> 12];
#else
        uint8_t *p = cpu->cd.m88k.host_store_usr[addr >> 12];
#endif
#else
#ifdef LS_LOAD
        uint8_t *p = cpu->cd.m88k.host_load[addr >> 12];
#else
        uint8_t *p = cpu->cd.m88k.host_store[addr >> 12];
#endif
#endif

        /*
         *  Call the generic function, if things become too complicated:
         *
         *  1)  .usr used in non-supervisor mode
         *  2)  the page pointer is NULL
         *  3)  unaligned access
         */
        if (
#ifdef LS_USR
            !(cpu->cd.m88k.cr[M88K_CR_PSR] & M88K_PSR_MODE) ||
#endif

            p == NULL
#ifndef LS_1
            || addr & (LS_SIZE - 1)
#endif
            ) {
                LS_GENERIC_N(cpu, ic);
                return;
        }

        addr &= 0xfff;

#ifdef LS_LOAD
        /*  Load:  */

#ifdef LS_1
        reg(ic->arg[0]) =
#ifdef LS_SIGNED
            (int8_t)
#endif
            p[addr];
#endif  /*  LS_1  */

#ifdef LS_2
        reg(ic->arg[0]) =
#ifdef LS_SIGNED
            (int16_t)
#endif
#ifdef LS_BE
#ifdef HOST_BIG_ENDIAN
            ( *(uint16_t *)(p + addr) );
#else
            ((p[addr]<<8) + p[addr+1]);
#endif
#else
#ifdef HOST_LITTLE_ENDIAN
            ( *(uint16_t *)(p + addr) );
#else
            (p[addr] + (p[addr+1]<<8));
#endif
#endif
#endif  /*  LS_2  */

#ifdef LS_4
        reg(ic->arg[0]) =
#ifdef LS_SIGNED
            (int32_t)
#else
            (uint32_t)
#endif
#ifdef LS_BE
#ifdef HOST_BIG_ENDIAN
            ( *(uint32_t *)(p + addr) );
#else
            ((p[addr]<<24) + (p[addr+1]<<16) + (p[addr+2]<<8) + p[addr+3]);
#endif
#else
#ifdef HOST_LITTLE_ENDIAN
            ( *(uint32_t *)(p + addr) );
#else
            (p[addr] + (p[addr+1]<<8) + (p[addr+2]<<16) + (p[addr+3]<<24));
#endif
#endif
#endif  /*  LS_4  */

#ifdef LS_8

        /*  Load first word in pair:  */
        reg(ic->arg[0]) =
#ifdef LS_BE
#ifdef HOST_BIG_ENDIAN
            ( *(uint32_t *)(p + addr) );
#else
            ((p[addr]<<24) + (p[addr+1]<<16) + (p[addr+2]<<8) + p[addr+3]);
#endif
#else
#ifdef HOST_LITTLE_ENDIAN
            ( *(uint32_t *)(p + addr + 4) );
#else
            (p[addr+4] + (p[addr+5]<<8) + (p[addr+6]<<16) + (p[addr+7]<<24));
#endif
#endif

        /*  Load second word in pair:  */
        reg(ic->arg[0] + 4) =
#ifdef LS_BE
#ifdef HOST_BIG_ENDIAN
            ( *(uint32_t *)(p + addr + 4) );
#else
            ((p[addr+4]<<24) + (p[addr+5]<<16) + (p[addr+6]<<8) + p[addr+7]);
#endif
#else
#ifdef HOST_LITTLE_ENDIAN
            ( *(uint32_t *)(p + addr) );
#else
            (p[addr] + (p[addr+1]<<8) + (p[addr+2]<<16) + (p[addr+3]<<24));
#endif
#endif

#endif  /*  LS_8  */

#else
        /*  Store: */

#ifdef LS_1
        p[addr] = reg(ic->arg[0]);
#endif
#ifdef LS_2
        { uint32_t x = reg(ic->arg[0]);
#ifdef LS_BE
#ifdef HOST_BIG_ENDIAN
        *((uint16_t *)(p+addr)) = x; }
#else
        p[addr] = x >> 8; p[addr+1] = x; }
#endif
#else
#ifdef HOST_LITTLE_ENDIAN
        *((uint16_t *)(p+addr)) = x; }
#else
        p[addr] = x; p[addr+1] = x >> 8; }
#endif
#endif
#endif  /*  LS_2  */
#ifdef LS_4
        { uint32_t x = reg(ic->arg[0]);
#ifdef LS_BE
#ifdef HOST_BIG_ENDIAN
        *((uint32_t *)(p+addr)) = x; }
#else
        p[addr] = x >> 24; p[addr+1] = x >> 16; 
        p[addr+2] = x >> 8; p[addr+3] = x; }
#endif
#else
#ifdef HOST_LITTLE_ENDIAN
        *((uint32_t *)(p+addr)) = x; }
#else
        p[addr] = x; p[addr+1] = x >> 8; 
        p[addr+2] = x >> 16; p[addr+3] = x >> 24; }
#endif
#endif
#endif  /*  LS_4  */
#ifdef LS_8

        /*  First word in pair:  */
        { uint32_t x = reg(ic->arg[0]);
#ifdef LS_BE
#ifdef HOST_BIG_ENDIAN
        *((uint32_t *)(p+addr)) = x; }
#else
        p[addr]   = x >> 24; p[addr+1] = x >> 16;
        p[addr+2] = x >> 8;  p[addr+3] = x; }
#endif
#else
#ifdef HOST_LITTLE_ENDIAN
        *((uint32_t *)(p+addr+4)) = x; }
#else
        p[addr  +4] = x;        p[addr+1+4] = x >> 8;
        p[addr+2+4] = x >> 16;  p[addr+3+4] = x >> 24; }
#endif
#endif

        /*  Second word in pair:  */
        { uint32_t x = reg(ic->arg[0] + 4);
#ifdef LS_BE
#ifdef HOST_BIG_ENDIAN
        *((uint32_t *)(p+addr+4)) = x; }
#else
        p[addr  +4] = x >> 24; p[addr+1+4] = x >> 16;
        p[addr+2+4] = x >> 8;  p[addr+3+4] = x; }
#endif
#else
#ifdef HOST_LITTLE_ENDIAN
        *((uint32_t *)(p+addr)) = x; }
#else
        p[addr  ] = x;        p[addr+1] = x >> 8;
        p[addr+2] = x >> 16;  p[addr+3] = x >> 24; }
#endif
#endif

#endif  /*  LS_8  */

#endif  /*  store  */
}

1	/*
2	* Copyright (C) 2007 Anders Gavare. All rights reserved.
3	*
4	* Redistribution and use in source and binary forms, with or without
5	* modification, are permitted provided that the following conditions are met:
6	*
7	* 1. Redistributions of source code must retain the above copyright
8	* notice, this list of conditions and the following disclaimer.
9	* 2. Redistributions in binary form must reproduce the above copyright
10	* notice, this list of conditions and the following disclaimer in the
11	* documentation and/or other materials provided with the distribution.
12	* 3. The name of the author may not be used to endorse or promote products
13	* derived from this software without specific prior written permission.
14	*
15	* THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND
16	* ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
17	* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
18	* ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE
19	* FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
20	* DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
21	* OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
22	* HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
23	* LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
24	* OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
25	* SUCH DAMAGE.
26	*
27	*
28	* $Id: cpu_m88k_instr_loadstore.c,v 1.8 2007/05/27 03:01:28 debug Exp $
29	*
30	* M88K load/store instructions; the following args are used:
31	*
32	* arg[0] = pointer to the register to load to or store from (d)
33	* arg[1] = pointer to the base register (s1)
34	* arg[2] = pointer to the offset register (s2), or an uint32_t offset
35	*
36	* The GENERIC function always checks for alignment, and supports both big
37	* and little endian byte order.
38	*
39	* The quick function is included twice (big/little endian) for each
40	* GENERIC function.
41	*
42	*
43	* Defines:
44	* LS_LOAD or LS_STORE (only one)
45	* LS_INCLUDE_GENERIC (to generate the generic function)
46	* LS_GENERIC_N is defined as the name of the generic function
47	* LS_N is defined as the name of the fast function
48	* LS_1, LS_2, LS_4, or LS_8 (only one)
49	* LS_SIZE is defined to 1, 2, 4, or 8
50	* LS_SIGNED is defined for signed loads
51	* LS_LE or LS_BE (only one)
52	* LS_SCALED for scaled accesses
53	* LS_USR for usr accesses
54	* LS_REGOFS is defined when arg[2] is a register pointer
55	*/
56
57
58	#ifdef LS_INCLUDE_GENERIC
59	void LS_GENERIC_N(struct cpu cpu, struct m88k_instr_call ic)
60	{
61	#ifdef LS_USR
62	const int memory_rw_flags = CACHE_DATA \| MEMORY_USER_ACCESS;
63	#else
64	const int memory_rw_flags = CACHE_DATA;
65	#endif
66	uint32_t addr = reg(ic->arg[1]) +
67	#ifdef LS_REGOFS
68	#ifdef LS_SCALED
69	LS_SIZE *
70	#endif
71	reg(ic->arg[2]);
72	#else
73	ic->arg[2];
74	#endif
75	uint8_t data[LS_SIZE];
76	uint64_t x;
77
78	/* Synchronize the PC: */
79	int low_pc = ((size_t)ic - (size_t)cpu->cd.m88k.cur_ic_page)
80	/ sizeof(struct m88k_instr_call);
81	cpu->pc &= ~((M88K_IC_ENTRIES_PER_PAGE-1)<<M88K_INSTR_ALIGNMENT_SHIFT);
82	cpu->pc += (low_pc << M88K_INSTR_ALIGNMENT_SHIFT);
83
84	/*
85	* Update the memory transaction registers:
86	*/
87	cpu->cd.m88k.dmt[1] = 0;
88
89	cpu->cd.m88k.dmt[0] = DMT_VALID;
90	#ifdef LS_STORE
91	cpu->cd.m88k.dmt[0] \|= DMT_WRITE;
92	#else
93	{
94	int dreg = (((uint32_t *)ic->arg[0]) - &cpu->cd.m88k.r[0]);
95	if (dreg < 1 \|\| dreg > 31) {
96	fatal("HUH? dreg = %i in cpu_m88k_instr_loadstore.c."
97	" Internal error.\n", dreg);
98	exit(1);
99	}
100	cpu->cd.m88k.dmt[0] \|= dreg << DMT_DREGSHIFT;
101	}
102	#ifdef LS_SIGNED
103	cpu->cd.m88k.dmt[0] \|= DMT_SIGNED;
104	#endif
105	#endif
106	if (cpu->byte_order == EMUL_LITTLE_ENDIAN)
107	cpu->cd.m88k.dmt[0] \|= DMT_BO;
108
109	#ifndef LS_USR
110	if (cpu->cd.m88k.cr[M88K_CR_PSR] & M88K_PSR_MODE)
111	cpu->cd.m88k.dmt[0] \|= DMT_DAS; /* supervisor */
112	#endif
113
114	/* EN bits: */
115	#ifdef LS_1
116	/* TODO: Is the EN offset only valid for Big-Endian? */
117	cpu->cd.m88k.dmt[0] \|= 1 << DMT_ENSHIFT << (3 - (addr & 3));
118	#else
119	#ifdef LS_2
120	cpu->cd.m88k.dmt[0] \|= 3 << DMT_ENSHIFT << (2 - (addr & 2));
121	#else
122	cpu->cd.m88k.dmt[0] \|= 0xf << DMT_ENSHIFT;
123	#endif
124	#endif
125
126	cpu->cd.m88k.dma[0] = addr & ~0x3;
127	cpu->cd.m88k.dmd[0] = 0;
128
129	#ifdef LS_8
130	cpu->cd.m88k.dmt[1] = cpu->cd.m88k.dmt[0];
131	cpu->cd.m88k.dmt[0] \|= DMT_DOUB1;
132	cpu->cd.m88k.dma[1] = cpu->cd.m88k.dma[0] + sizeof(uint32_t);
133	cpu->cd.m88k.dmd[0] = 0;
134	#ifdef LS_LOAD
135	{
136	int dreg = (((uint32_t *)ic->arg[0]) - &cpu->cd.m88k.r[0]);
137	dreg ++;
138	if (dreg < 1 \|\| dreg > 31) {
139	fatal("HUH? dreg = %i in cpu_m88k_instr_loadstore.c."
140	" Internal error.\n", dreg);
141	exit(1);
142	}
143	cpu->cd.m88k.dmt[1] &= ~((0x1f) << DMT_DREGSHIFT);
144	cpu->cd.m88k.dmt[1] \|= dreg << DMT_DREGSHIFT;
145	}
146	#endif
147	#endif
148
149
150	#ifdef LS_USR
151	if (!(cpu->cd.m88k.cr[M88K_CR_PSR] & M88K_PSR_MODE)) {
152	/* Cause a privilege violation exception: */
153	m88k_exception(cpu, M88K_EXCEPTION_PRIVILEGE_VIOLATION, 0);
154	return;
155	}
156	#endif
157
158	#ifndef LS_1
159	/* Check alignment: */
160	if (addr & (LS_SIZE - 1)) {
161	#if 0
162	/* Cause an address alignment exception: */
163	m88k_exception(cpu, M88K_EXCEPTION_MISALIGNED_ACCESS, 0);
164	#else
165	fatal("{ m88k dyntrans alignment exception, size = %i,"
166	" addr = %08"PRIx32", pc = %08"PRIx32" }\n", LS_SIZE,
167	(uint32_t) addr, (uint32_t) cpu->pc);
168
169	/* TODO: Generalize this into a abort_call, or similar: */
170	cpu->running = 0;
171	debugger_n_steps_left_before_interaction = 0;
172	cpu->cd.m88k.next_ic = &nothing_call;
173
174	if (cpu->delay_slot)
175	cpu->delay_slot \|= EXCEPTION_IN_DELAY_SLOT;
176	#endif
177	return;
178	}
179	#endif
180
181	#ifdef LS_LOAD
182	if (!cpu->memory_rw(cpu, cpu->mem, addr, data, sizeof(data),
183	MEM_READ, memory_rw_flags)) {
184	/* Exception. */
185	return;
186	}
187	x = memory_readmax64(cpu, data, LS_SIZE);
188	#ifdef LS_8
189	if (cpu->byte_order == EMUL_BIG_ENDIAN) {
190	reg(ic->arg[0]) = x >> 32;
191	reg(ic->arg[0] + 4) = x;
192	} else {
193	reg(ic->arg[0]) = x;
194	reg(ic->arg[0] + 4) = x >> 32;
195	}
196	#else
197	#ifdef LS_SIGNED
198	#ifdef LS_1
199	x = (int8_t)x;
200	#endif
201	#ifdef LS_2
202	x = (int16_t)x;
203	#endif
204	#ifdef LS_4
205	x = (int32_t)x;
206	#endif
207	#endif
208	reg(ic->arg[0]) = x;
209	#endif
210
211	#else /* LS_STORE: */
212
213	#ifdef LS_8
214	if (cpu->byte_order == EMUL_BIG_ENDIAN)
215	x = ((uint64_t)reg(ic->arg[0]) << 32) + reg(ic->arg[0] + 4);
216	else
217	x = ((uint64_t)reg(ic->arg[0] + 4) << 32) + reg(ic->arg[0]);
218	cpu->cd.m88k.dmd[0] = reg(ic->arg[0]);
219	cpu->cd.m88k.dmd[1] = reg(ic->arg[0] + 4);
220	#else
221	x = reg(ic->arg[0]);
222	cpu->cd.m88k.dmd[0] = x;
223	#endif
224	memory_writemax64(cpu, data, LS_SIZE, x);
225	if (!cpu->memory_rw(cpu, cpu->mem, addr, data, sizeof(data),
226	MEM_WRITE, memory_rw_flags)) {
227	/* Exception. */
228	return;
229	}
230	#endif
231	}
232	#endif /* LS_INCLUDE_GENERIC */
233
234
235	void LS_N(struct cpu cpu, struct m88k_instr_call ic)
236	{
237	uint32_t addr = reg(ic->arg[1]) +
238	#ifdef LS_REGOFS
239	#ifdef LS_SCALED
240	LS_SIZE *
241	#endif
242	reg(ic->arg[2]);
243	#else
244	ic->arg[2];
245	#endif
246
247	#ifdef LS_USR
248	#ifdef LS_LOAD
249	uint8_t *p = cpu->cd.m88k.host_load_usr[addr >> 12];
250	#else
251	uint8_t *p = cpu->cd.m88k.host_store_usr[addr >> 12];
252	#endif
253	#else
254	#ifdef LS_LOAD
255	uint8_t *p = cpu->cd.m88k.host_load[addr >> 12];
256	#else
257	uint8_t *p = cpu->cd.m88k.host_store[addr >> 12];
258	#endif
259	#endif
260
261	/*
262	* Call the generic function, if things become too complicated:
263	*
264	* 1) .usr used in non-supervisor mode
265	* 2) the page pointer is NULL
266	* 3) unaligned access
267	*/
268	if (
269	#ifdef LS_USR
270	!(cpu->cd.m88k.cr[M88K_CR_PSR] & M88K_PSR_MODE) \|\|
271	#endif
272
273	p == NULL
274	#ifndef LS_1
275	\|\| addr & (LS_SIZE - 1)
276	#endif
277	) {
278	LS_GENERIC_N(cpu, ic);
279	return;
280	}
281
282	addr &= 0xfff;
283
284	#ifdef LS_LOAD
285	/* Load: */
286
287	#ifdef LS_1
288	reg(ic->arg[0]) =
289	#ifdef LS_SIGNED
290	(int8_t)
291	#endif
292	p[addr];
293	#endif /* LS_1 */
294
295	#ifdef LS_2
296	reg(ic->arg[0]) =
297	#ifdef LS_SIGNED
298	(int16_t)
299	#endif
300	#ifdef LS_BE
301	#ifdef HOST_BIG_ENDIAN
302	( (uint16_t )(p + addr) );
303	#else
304	((p[addr]<<8) + p[addr+1]);
305	#endif
306	#else
307	#ifdef HOST_LITTLE_ENDIAN
308	( (uint16_t )(p + addr) );
309	#else
310	(p[addr] + (p[addr+1]<<8));
311	#endif
312	#endif
313	#endif /* LS_2 */
314
315	#ifdef LS_4
316	reg(ic->arg[0]) =
317	#ifdef LS_SIGNED
318	(int32_t)
319	#else
320	(uint32_t)
321	#endif
322	#ifdef LS_BE
323	#ifdef HOST_BIG_ENDIAN
324	( (uint32_t )(p + addr) );
325	#else
326	((p[addr]<<24) + (p[addr+1]<<16) + (p[addr+2]<<8) + p[addr+3]);
327	#endif
328	#else
329	#ifdef HOST_LITTLE_ENDIAN
330	( (uint32_t )(p + addr) );
331	#else
332	(p[addr] + (p[addr+1]<<8) + (p[addr+2]<<16) + (p[addr+3]<<24));
333	#endif
334	#endif
335	#endif /* LS_4 */
336
337	#ifdef LS_8
338
339	/* Load first word in pair: */
340	reg(ic->arg[0]) =
341	#ifdef LS_BE
342	#ifdef HOST_BIG_ENDIAN
343	( (uint32_t )(p + addr) );
344	#else
345	((p[addr]<<24) + (p[addr+1]<<16) + (p[addr+2]<<8) + p[addr+3]);
346	#endif
347	#else
348	#ifdef HOST_LITTLE_ENDIAN
349	( (uint32_t )(p + addr + 4) );
350	#else
351	(p[addr+4] + (p[addr+5]<<8) + (p[addr+6]<<16) + (p[addr+7]<<24));
352	#endif
353	#endif
354
355	/* Load second word in pair: */
356	reg(ic->arg[0] + 4) =
357	#ifdef LS_BE
358	#ifdef HOST_BIG_ENDIAN
359	( (uint32_t )(p + addr + 4) );
360	#else
361	((p[addr+4]<<24) + (p[addr+5]<<16) + (p[addr+6]<<8) + p[addr+7]);
362	#endif
363	#else
364	#ifdef HOST_LITTLE_ENDIAN
365	( (uint32_t )(p + addr) );
366	#else
367	(p[addr] + (p[addr+1]<<8) + (p[addr+2]<<16) + (p[addr+3]<<24));
368	#endif
369	#endif
370
371	#endif /* LS_8 */
372
373	#else
374	/* Store: */
375
376	#ifdef LS_1
377	p[addr] = reg(ic->arg[0]);
378	#endif
379	#ifdef LS_2
380	{ uint32_t x = reg(ic->arg[0]);
381	#ifdef LS_BE
382	#ifdef HOST_BIG_ENDIAN
383	((uint16_t )(p+addr)) = x; }
384	#else
385	p[addr] = x >> 8; p[addr+1] = x; }
386	#endif
387	#else
388	#ifdef HOST_LITTLE_ENDIAN
389	((uint16_t )(p+addr)) = x; }
390	#else
391	p[addr] = x; p[addr+1] = x >> 8; }
392	#endif
393	#endif
394	#endif /* LS_2 */
395	#ifdef LS_4
396	{ uint32_t x = reg(ic->arg[0]);
397	#ifdef LS_BE
398	#ifdef HOST_BIG_ENDIAN
399	((uint32_t )(p+addr)) = x; }
400	#else
401	p[addr] = x >> 24; p[addr+1] = x >> 16;
402	p[addr+2] = x >> 8; p[addr+3] = x; }
403	#endif
404	#else
405	#ifdef HOST_LITTLE_ENDIAN
406	((uint32_t )(p+addr)) = x; }
407	#else
408	p[addr] = x; p[addr+1] = x >> 8;
409	p[addr+2] = x >> 16; p[addr+3] = x >> 24; }
410	#endif
411	#endif
412	#endif /* LS_4 */
413	#ifdef LS_8
414
415	/* First word in pair: */
416	{ uint32_t x = reg(ic->arg[0]);
417	#ifdef LS_BE
418	#ifdef HOST_BIG_ENDIAN
419	((uint32_t )(p+addr)) = x; }
420	#else
421	p[addr] = x >> 24; p[addr+1] = x >> 16;
422	p[addr+2] = x >> 8; p[addr+3] = x; }
423	#endif
424	#else
425	#ifdef HOST_LITTLE_ENDIAN
426	((uint32_t )(p+addr+4)) = x; }
427	#else
428	p[addr +4] = x; p[addr+1+4] = x >> 8;
429	p[addr+2+4] = x >> 16; p[addr+3+4] = x >> 24; }
430	#endif
431	#endif
432
433	/* Second word in pair: */
434	{ uint32_t x = reg(ic->arg[0] + 4);
435	#ifdef LS_BE
436	#ifdef HOST_BIG_ENDIAN
437	((uint32_t )(p+addr+4)) = x; }
438	#else
439	p[addr +4] = x >> 24; p[addr+1+4] = x >> 16;
440	p[addr+2+4] = x >> 8; p[addr+3+4] = x; }
441	#endif
442	#else
443	#ifdef HOST_LITTLE_ENDIAN
444	((uint32_t )(p+addr)) = x; }
445	#else
446	p[addr ] = x; p[addr+1] = x >> 8;
447	p[addr+2] = x >> 16; p[addr+3] = x >> 24; }
448	#endif
449	#endif
450
451	#endif /* LS_8 */
452
453	#endif /* store */
454	}
455