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/*
 * cpu.c  - This file contains implementation of C function to
 *          instantiate IDT entries. More detailled information can be found
 *          on Intel site and more precisely in the following book :
 *
 *              Pentium Processor family
 *              Developper's Manual
 *
 *              Volume 3 : Architecture and Programming Manual
 *
 * Copyright (C) 1998  Eric Valette (valette@crf.canon.fr)
 *                     Canon Centre Recherche France.
 *
 *  The license and distribution terms for this file may be
 *  found in found in the file LICENSE in this distribution or at
 *  http://www.OARcorp.com/rtems/license.html.
 *
 * $Id: cpu.c,v 1.2 2001-09-27 12:01:22 chris Exp $
 */
 
#include <libcpu/cpu.h>
#include <irq.h>
 
static rtems_raw_irq_connect_data*      raw_irq_table;
static rtems_raw_irq_connect_data       default_raw_irq_entry;
static interrupt_gate_descriptor        default_idt_entry;
static rtems_raw_irq_global_settings*   local_settings;
 
void create_interrupt_gate_descriptor (interrupt_gate_descriptor* idtEntry,
                                       rtems_raw_irq_hdl hdl)
{
    idtEntry->low_offsets_bits  = (((unsigned) hdl) & 0xffff);
    idtEntry->segment_selector  = i386_get_cs();
    idtEntry->fixed_value_bits  = 0;
    idtEntry->gate_type         = 0xe;
    idtEntry->privilege         = 0;
    idtEntry->present           = 1;
    idtEntry->high_offsets_bits = ((((unsigned) hdl) >> 16) & 0xffff);
}
 
rtems_raw_irq_hdl get_hdl_from_vector(rtems_vector_offset index)
{
    rtems_raw_irq_hdl           hdl;
    interrupt_gate_descriptor*  idt_entry_tbl;
    unsigned                    limit;
 
    i386_get_info_from_IDTR (&idt_entry_tbl, &limit);
 
    /* Convert limit into number of entries */
    limit = (limit + 1) / sizeof(interrupt_gate_descriptor);
 
    if(index >= limit) {
        return 0;
    }
 
    * ((unsigned int*) &hdl) = (idt_entry_tbl[index].low_offsets_bits |
                              (idt_entry_tbl[index].high_offsets_bits << 16));
    return hdl;
}
 
int i386_set_idt_entry  (const rtems_raw_irq_connect_data* irq)
{
    interrupt_gate_descriptor*  idt_entry_tbl;
    unsigned                    limit;
    unsigned int                level;
 
 
    i386_get_info_from_IDTR (&idt_entry_tbl, &limit);
 
    /* Convert limit into number of entries */
    limit = (limit + 1) / sizeof(interrupt_gate_descriptor);
 
    if (irq->idtIndex >= limit) {
      return 0;
    }
    /*
     * Check if default handler is actually connected. If not issue an error.
     * You must first get the current handler via i386_get_current_idt_entry
     * and then disconnect it using i386_delete_idt_entry.
     * RATIONALE : to always have the same transition by forcing the user
     * to get the previous handler before accepting to disconnect.
     */
    if (get_hdl_from_vector(irq->idtIndex) != default_raw_irq_entry.hdl) {
      return 0;
    }
 
    _CPU_ISR_Disable(level);
 
    raw_irq_table [irq->idtIndex] = *irq;
    create_interrupt_gate_descriptor (&idt_entry_tbl[irq->idtIndex], irq->hdl);
    irq->on(irq);
 
    _CPU_ISR_Enable(level);
    return 1;
}
 
void _CPU_ISR_install_vector (unsigned vector,
                              void* hdl,
                              void** oldHdl)
{
    interrupt_gate_descriptor*  idt_entry_tbl;
    unsigned                    limit;
    interrupt_gate_descriptor   new;
    unsigned int                level;
 
    i386_get_info_from_IDTR (&idt_entry_tbl, &limit);
 
    /* Convert limit into number of entries */
    limit = (limit + 1) / sizeof(interrupt_gate_descriptor);
 
    if (vector >= limit) {
      return;
    }
    _CPU_ISR_Disable(level)
    * ((unsigned int *) oldHdl) = idt_entry_tbl[vector].low_offsets_bits |
        (idt_entry_tbl[vector].high_offsets_bits << 16);
 
    create_interrupt_gate_descriptor(&new,  hdl);
    idt_entry_tbl[vector] = new;
 
    _CPU_ISR_Enable(level);
}
 
int i386_get_current_idt_entry (rtems_raw_irq_connect_data* irq)
{
    interrupt_gate_descriptor*  idt_entry_tbl;
    unsigned                    limit;
 
    i386_get_info_from_IDTR (&idt_entry_tbl, &limit);
 
    /* Convert limit into number of entries */
    limit = (limit + 1) / sizeof(interrupt_gate_descriptor);
 
    if (irq->idtIndex >= limit) {
      return 0;
    }
    raw_irq_table [irq->idtIndex].hdl = get_hdl_from_vector(irq->idtIndex);
 
    *irq = raw_irq_table [irq->idtIndex];
 
    return 1;
}
 
int i386_delete_idt_entry (const rtems_raw_irq_connect_data* irq)
{
    interrupt_gate_descriptor*  idt_entry_tbl;
    unsigned                    limit;
    unsigned int                level;
 
    i386_get_info_from_IDTR (&idt_entry_tbl, &limit);
 
    /* Convert limit into number of entries */
    limit = (limit + 1) / sizeof(interrupt_gate_descriptor);
 
    if (irq->idtIndex >= limit) {
      return 0;
    }
    /*
     * Check if handler passed is actually connected. If not issue an error.
     * You must first get the current handler via i386_get_current_idt_entry
     * and then disconnect it using i386_delete_idt_entry.
     * RATIONALE : to always have the same transition by forcing the user
     * to get the previous handler before accepting to disconnect.
     */
    if (get_hdl_from_vector(irq->idtIndex) != irq->hdl){
      return 0;
    }
    _CPU_ISR_Disable(level);
 
    idt_entry_tbl[irq->idtIndex] = default_idt_entry;
 
    irq->off(irq);
 
    raw_irq_table[irq->idtIndex] = default_raw_irq_entry;
    raw_irq_table[irq->idtIndex].idtIndex = irq->idtIndex;
 
    _CPU_ISR_Enable(level);
 
    return 1;
}
 
/*
 * Caution this function assumes the IDTR has been already set.
 */
int i386_init_idt (rtems_raw_irq_global_settings* config)
{
    unsigned                    limit;
    unsigned                    i;
    unsigned                    level;
    interrupt_gate_descriptor*  idt_entry_tbl;
 
    i386_get_info_from_IDTR (&idt_entry_tbl, &limit);
 
    /* Convert limit into number of entries */
    limit = (limit + 1) / sizeof(interrupt_gate_descriptor);
 
    if (config->idtSize != limit) {
      return 0;
    }
    /*
     * store various accelarators
     */
    raw_irq_table               = config->rawIrqHdlTbl;
    local_settings              = config;
    default_raw_irq_entry       = config->defaultRawEntry;
 
    _CPU_ISR_Disable(level);
 
    create_interrupt_gate_descriptor (&default_idt_entry, default_raw_irq_entry.hdl);
 
    for (i=0; i < limit; i++) {
      interrupt_gate_descriptor new;
      create_interrupt_gate_descriptor (&new, raw_irq_table[i].hdl);
      idt_entry_tbl[i] = new;
      if (raw_irq_table[i].hdl != default_raw_irq_entry.hdl) {
        raw_irq_table[i].on(&raw_irq_table[i]);
      }
      else {
        raw_irq_table[i].off(&raw_irq_table[i]);
      }
    }
    _CPU_ISR_Enable(level);
 
    return 1;
}
 
int i386_get_idt_config (rtems_raw_irq_global_settings** config)
{
  *config = local_settings;
  return 1;
}
 
/*
 * Caution this function assumes the GDTR has been already set.
 */
int i386_set_gdt_entry (unsigned short segment_selector, unsigned base,
                        unsigned limit)
{
    unsigned                    gdt_limit;
    unsigned short              tmp_segment = 0;
    unsigned int                limit_adjusted;
    segment_descriptors*        gdt_entry_tbl;
 
 
    i386_get_info_from_GDTR (&gdt_entry_tbl, &gdt_limit);
 
    if (segment_selector > limit) {
      return 0;
    }
    /*
     * set up limit first
     */
    limit_adjusted = limit;
    if ( limit > 4095 ) {
      gdt_entry_tbl[segment_selector].granularity = 1;
      limit_adjusted /= 4096;
    }
    gdt_entry_tbl[segment_selector].limit_15_0  = limit_adjusted & 0xffff;
    gdt_entry_tbl[segment_selector].limit_19_16 = (limit_adjusted >> 16) & 0xf;
    /*
     * set up base
     */
    gdt_entry_tbl[segment_selector].base_address_15_0  = base & 0xffff;
    gdt_entry_tbl[segment_selector].base_address_23_16 = (base >> 16) & 0xff;
    gdt_entry_tbl[segment_selector].base_address_31_24 = (base >> 24) & 0xff;
    /*
     * set up descriptor type (this may well becomes a parameter if needed)
     */
    gdt_entry_tbl[segment_selector].type                = 2;    /* Data R/W */
    gdt_entry_tbl[segment_selector].descriptor_type     = 1;    /* Code or Data */
    gdt_entry_tbl[segment_selector].privilege           = 0;     /* ring 0 */
    gdt_entry_tbl[segment_selector].present             = 1;    /* not present */
 
    /*
     * Now, reload all segment registers so the limit takes effect.
     */
 
    asm volatile( "movw %%ds,%0 ; movw %0,%%ds
                   movw %%es,%0 ; movw %0,%%es
                   movw %%fs,%0 ; movw %0,%%fs
                   movw %%gs,%0 ; movw %0,%%gs
                   movw %%ss,%0 ; movw %0,%%ss"
                   : "=r" (tmp_segment)
                   : "0"  (tmp_segment)
                  );
 
    return 1;
}

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[/] [openrisc/] [trunk/] [rtos/] [rtems/] [c/] [src/] [lib/] [libcpu/] [i386/] [cpu.c] - Blame information for rev 173

Line No.	Rev	Author	Line
1	30	unneback	`/*`
2			`* cpu.c - This file contains implementation of C function to`
3			`* instantiate IDT entries. More detailled information can be found`
4			`* on Intel site and more precisely in the following book :`
5			`*`
6			`* Pentium Processor family`
7			`* Developper's Manual`
8			`*`
9			`* Volume 3 : Architecture and Programming Manual`
10			`*`
11			`* Copyright (C) 1998 Eric Valette (valette@crf.canon.fr)`
12			`* Canon Centre Recherche France.`
13			`*`
14			`* The license and distribution terms for this file may be`
15			`* found in found in the file LICENSE in this distribution or at`
16			`* http://www.OARcorp.com/rtems/license.html.`
17			`*`
18			`* $Id: cpu.c,v 1.2 2001-09-27 12:01:22 chris Exp $`
19			`*/`
20
21			`#include <libcpu/cpu.h>`
22			`#include <irq.h>`
23
24			`static rtems_raw_irq_connect_data* raw_irq_table;`
25			`static rtems_raw_irq_connect_data default_raw_irq_entry;`
26			`static interrupt_gate_descriptor default_idt_entry;`
27			`static rtems_raw_irq_global_settings* local_settings;`
28
29			`void create_interrupt_gate_descriptor (interrupt_gate_descriptor* idtEntry,`
30			`rtems_raw_irq_hdl hdl)`
31			`{`
32			`idtEntry->low_offsets_bits = (((unsigned) hdl) & 0xffff);`
33			`idtEntry->segment_selector = i386_get_cs();`
34			`idtEntry->fixed_value_bits = 0;`
35			`idtEntry->gate_type = 0xe;`
36			`idtEntry->privilege = 0;`
37			`idtEntry->present = 1;`
38			`idtEntry->high_offsets_bits = ((((unsigned) hdl) >> 16) & 0xffff);`
39			`}`
40
41			`rtems_raw_irq_hdl get_hdl_from_vector(rtems_vector_offset index)`
42			`{`
43			`rtems_raw_irq_hdl hdl;`
44			`interrupt_gate_descriptor* idt_entry_tbl;`
45			`unsigned limit;`
46
47			`i386_get_info_from_IDTR (&idt_entry_tbl, &limit);`
48
49			`/* Convert limit into number of entries */`
50			`limit = (limit + 1) / sizeof(interrupt_gate_descriptor);`
51
52			`if(index >= limit) {`
53			`return 0;`
54			`}`
55
56			`* ((unsigned int*) &hdl) = (idt_entry_tbl[index].low_offsets_bits \|`
57			`(idt_entry_tbl[index].high_offsets_bits << 16));`
58			`return hdl;`
59			`}`
60
61			`int i386_set_idt_entry (const rtems_raw_irq_connect_data* irq)`
62			`{`
63			`interrupt_gate_descriptor* idt_entry_tbl;`
64			`unsigned limit;`
65			`unsigned int level;`
66
67
68			`i386_get_info_from_IDTR (&idt_entry_tbl, &limit);`
69
70			`/* Convert limit into number of entries */`
71			`limit = (limit + 1) / sizeof(interrupt_gate_descriptor);`
72
73			`if (irq->idtIndex >= limit) {`
74			`return 0;`
75			`}`
76			`/*`
77			`* Check if default handler is actually connected. If not issue an error.`
78			`* You must first get the current handler via i386_get_current_idt_entry`
79			`* and then disconnect it using i386_delete_idt_entry.`
80			`* RATIONALE : to always have the same transition by forcing the user`
81			`* to get the previous handler before accepting to disconnect.`
82			`*/`
83			`if (get_hdl_from_vector(irq->idtIndex) != default_raw_irq_entry.hdl) {`
84			`return 0;`
85			`}`
86
87			`_CPU_ISR_Disable(level);`
88
89			`raw_irq_table [irq->idtIndex] = *irq;`
90			`create_interrupt_gate_descriptor (&idt_entry_tbl[irq->idtIndex], irq->hdl);`
91			`irq->on(irq);`
92
93			`_CPU_ISR_Enable(level);`
94			`return 1;`
95			`}`
96
97			`void _CPU_ISR_install_vector (unsigned vector,`
98			`void* hdl,`
99			`void** oldHdl)`
100			`{`
101			`interrupt_gate_descriptor* idt_entry_tbl;`
102			`unsigned limit;`
103			`interrupt_gate_descriptor new;`
104			`unsigned int level;`
105
106			`i386_get_info_from_IDTR (&idt_entry_tbl, &limit);`
107
108			`/* Convert limit into number of entries */`
109			`limit = (limit + 1) / sizeof(interrupt_gate_descriptor);`
110
111			`if (vector >= limit) {`
112			`return;`
113			`}`
114			`_CPU_ISR_Disable(level)`
115			`* ((unsigned int *) oldHdl) = idt_entry_tbl[vector].low_offsets_bits \|`
116			`(idt_entry_tbl[vector].high_offsets_bits << 16);`
117
118			`create_interrupt_gate_descriptor(&new, hdl);`
119			`idt_entry_tbl[vector] = new;`
120
121			`_CPU_ISR_Enable(level);`
122			`}`
123
124			`int i386_get_current_idt_entry (rtems_raw_irq_connect_data* irq)`
125			`{`
126			`interrupt_gate_descriptor* idt_entry_tbl;`
127			`unsigned limit;`
128
129			`i386_get_info_from_IDTR (&idt_entry_tbl, &limit);`
130
131			`/* Convert limit into number of entries */`
132			`limit = (limit + 1) / sizeof(interrupt_gate_descriptor);`
133
134			`if (irq->idtIndex >= limit) {`
135			`return 0;`
136			`}`
137			`raw_irq_table [irq->idtIndex].hdl = get_hdl_from_vector(irq->idtIndex);`
138
139			`*irq = raw_irq_table [irq->idtIndex];`
140
141			`return 1;`
142			`}`
143
144			`int i386_delete_idt_entry (const rtems_raw_irq_connect_data* irq)`
145			`{`
146			`interrupt_gate_descriptor* idt_entry_tbl;`
147			`unsigned limit;`
148			`unsigned int level;`
149
150			`i386_get_info_from_IDTR (&idt_entry_tbl, &limit);`
151
152			`/* Convert limit into number of entries */`
153			`limit = (limit + 1) / sizeof(interrupt_gate_descriptor);`
154
155			`if (irq->idtIndex >= limit) {`
156			`return 0;`
157			`}`
158			`/*`
159			`* Check if handler passed is actually connected. If not issue an error.`
160			`* You must first get the current handler via i386_get_current_idt_entry`
161			`* and then disconnect it using i386_delete_idt_entry.`
162			`* RATIONALE : to always have the same transition by forcing the user`
163			`* to get the previous handler before accepting to disconnect.`
164			`*/`
165			`if (get_hdl_from_vector(irq->idtIndex) != irq->hdl){`
166			`return 0;`
167			`}`
168			`_CPU_ISR_Disable(level);`
169
170			`idt_entry_tbl[irq->idtIndex] = default_idt_entry;`
171
172			`irq->off(irq);`
173
174			`raw_irq_table[irq->idtIndex] = default_raw_irq_entry;`
175			`raw_irq_table[irq->idtIndex].idtIndex = irq->idtIndex;`
176
177			`_CPU_ISR_Enable(level);`
178
179			`return 1;`
180			`}`
181
182			`/*`
183			`* Caution this function assumes the IDTR has been already set.`
184			`*/`
185			`int i386_init_idt (rtems_raw_irq_global_settings* config)`
186			`{`
187			`unsigned limit;`
188			`unsigned i;`
189			`unsigned level;`
190			`interrupt_gate_descriptor* idt_entry_tbl;`
191
192			`i386_get_info_from_IDTR (&idt_entry_tbl, &limit);`
193
194			`/* Convert limit into number of entries */`
195			`limit = (limit + 1) / sizeof(interrupt_gate_descriptor);`
196
197			`if (config->idtSize != limit) {`
198			`return 0;`
199			`}`
200			`/*`
201			`* store various accelarators`
202			`*/`
203			`raw_irq_table = config->rawIrqHdlTbl;`
204			`local_settings = config;`
205			`default_raw_irq_entry = config->defaultRawEntry;`
206
207			`_CPU_ISR_Disable(level);`
208
209			`create_interrupt_gate_descriptor (&default_idt_entry, default_raw_irq_entry.hdl);`
210
211			`for (i=0; i < limit; i++) {`
212			`interrupt_gate_descriptor new;`
213			`create_interrupt_gate_descriptor (&new, raw_irq_table[i].hdl);`
214			`idt_entry_tbl[i] = new;`
215			`if (raw_irq_table[i].hdl != default_raw_irq_entry.hdl) {`
216			`raw_irq_table[i].on(&raw_irq_table[i]);`
217			`}`
218			`else {`
219			`raw_irq_table[i].off(&raw_irq_table[i]);`
220			`}`
221			`}`
222			`_CPU_ISR_Enable(level);`
223
224			`return 1;`
225			`}`
226
227			`int i386_get_idt_config (rtems_raw_irq_global_settings** config)`
228			`{`
229			`*config = local_settings;`
230			`return 1;`
231			`}`
232
233			`/*`
234			`* Caution this function assumes the GDTR has been already set.`
235			`*/`
236			`int i386_set_gdt_entry (unsigned short segment_selector, unsigned base,`
237			`unsigned limit)`
238			`{`
239			`unsigned gdt_limit;`
240			`unsigned short tmp_segment = 0;`
241			`unsigned int limit_adjusted;`
242			`segment_descriptors* gdt_entry_tbl;`
243
244
245			`i386_get_info_from_GDTR (&gdt_entry_tbl, &gdt_limit);`
246
247			`if (segment_selector > limit) {`
248			`return 0;`
249			`}`
250			`/*`
251			`* set up limit first`
252			`*/`
253			`limit_adjusted = limit;`
254			`if ( limit > 4095 ) {`
255			`gdt_entry_tbl[segment_selector].granularity = 1;`
256			`limit_adjusted /= 4096;`
257			`}`
258			`gdt_entry_tbl[segment_selector].limit_15_0 = limit_adjusted & 0xffff;`
259			`gdt_entry_tbl[segment_selector].limit_19_16 = (limit_adjusted >> 16) & 0xf;`
260			`/*`
261			`* set up base`
262			`*/`
263			`gdt_entry_tbl[segment_selector].base_address_15_0 = base & 0xffff;`
264			`gdt_entry_tbl[segment_selector].base_address_23_16 = (base >> 16) & 0xff;`
265			`gdt_entry_tbl[segment_selector].base_address_31_24 = (base >> 24) & 0xff;`
266			`/*`
267			`* set up descriptor type (this may well becomes a parameter if needed)`
268			`*/`
269			`gdt_entry_tbl[segment_selector].type = 2; /* Data R/W */`
270			`gdt_entry_tbl[segment_selector].descriptor_type = 1; /* Code or Data */`
271			`gdt_entry_tbl[segment_selector].privilege = 0; /* ring 0 */`
272			`gdt_entry_tbl[segment_selector].present = 1; /* not present */`
273
274			`/*`
275			`* Now, reload all segment registers so the limit takes effect.`
276			`*/`
277
278			`asm volatile( "movw %%ds,%0 ; movw %0,%%ds`
279			`movw %%es,%0 ; movw %0,%%es`
280			`movw %%fs,%0 ; movw %0,%%fs`
281			`movw %%gs,%0 ; movw %0,%%gs`
282			`movw %%ss,%0 ; movw %0,%%ss"`
283			`: "=r" (tmp_segment)`
284			`: "0" (tmp_segment)`
285			`);`
286
287			`return 1;`
288			`}`