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17#include "smipcie.h"
18
19static void smi_ir_enableInterrupt(struct smi_rc *ir)
20{
21 struct smi_dev *dev = ir->dev;
22
23 smi_write(MSI_INT_ENA_SET, IR_X_INT);
24}
25
26static void smi_ir_disableInterrupt(struct smi_rc *ir)
27{
28 struct smi_dev *dev = ir->dev;
29
30 smi_write(MSI_INT_ENA_CLR, IR_X_INT);
31}
32
33static void smi_ir_clearInterrupt(struct smi_rc *ir)
34{
35 struct smi_dev *dev = ir->dev;
36
37 smi_write(MSI_INT_STATUS_CLR, IR_X_INT);
38}
39
40static void smi_ir_stop(struct smi_rc *ir)
41{
42 struct smi_dev *dev = ir->dev;
43
44 smi_ir_disableInterrupt(ir);
45 smi_clear(IR_Init_Reg, 0x80);
46}
47
48#define BITS_PER_COMMAND 14
49#define GROUPS_PER_BIT 2
50#define IR_RC5_MIN_BIT 36
51#define IR_RC5_MAX_BIT 52
52static u32 smi_decode_rc5(u8 *pData, u8 size)
53{
54 u8 index, current_bit, bit_count;
55 u8 group_array[BITS_PER_COMMAND * GROUPS_PER_BIT + 4];
56 u8 group_index = 0;
57 u32 command = 0xFFFFFFFF;
58
59 group_array[group_index++] = 1;
60
61 for (index = 0; index < size; index++) {
62
63 current_bit = (pData[index] & 0x80) ? 1 : 0;
64 bit_count = pData[index] & 0x7f;
65
66 if ((current_bit == 1) && (bit_count >= 2*IR_RC5_MAX_BIT + 1)) {
67 goto process_code;
68 } else if ((bit_count >= IR_RC5_MIN_BIT) &&
69 (bit_count <= IR_RC5_MAX_BIT)) {
70 group_array[group_index++] = current_bit;
71 } else if ((bit_count > IR_RC5_MAX_BIT) &&
72 (bit_count <= 2*IR_RC5_MAX_BIT)) {
73 group_array[group_index++] = current_bit;
74 group_array[group_index++] = current_bit;
75 } else {
76 goto invalid_timing;
77 }
78 if (group_index >= BITS_PER_COMMAND*GROUPS_PER_BIT)
79 goto process_code;
80
81 if ((group_index == BITS_PER_COMMAND*GROUPS_PER_BIT - 1)
82 && (group_array[group_index-1] == 0)) {
83 group_array[group_index++] = 1;
84 goto process_code;
85 }
86 }
87
88process_code:
89 if (group_index == (BITS_PER_COMMAND*GROUPS_PER_BIT-1))
90 group_array[group_index++] = 1;
91
92 if (group_index == BITS_PER_COMMAND*GROUPS_PER_BIT) {
93 command = 0;
94 for (index = 0; index < (BITS_PER_COMMAND*GROUPS_PER_BIT);
95 index = index + 2) {
96 if ((group_array[index] == 1) &&
97 (group_array[index+1] == 0)) {
98 command |= (1 << (BITS_PER_COMMAND -
99 (index/2) - 1));
100 } else if ((group_array[index] == 0) &&
101 (group_array[index+1] == 1)) {
102
103 } else {
104 command = 0xFFFFFFFF;
105 goto invalid_timing;
106 }
107 }
108 }
109
110invalid_timing:
111 return command;
112}
113
114static void smi_ir_decode(struct work_struct *work)
115{
116 struct smi_rc *ir = container_of(work, struct smi_rc, work);
117 struct smi_dev *dev = ir->dev;
118 struct rc_dev *rc_dev = ir->rc_dev;
119 u32 dwIRControl, dwIRData, dwIRCode, scancode;
120 u8 index, ucIRCount, readLoop, rc5_command, rc5_system, toggle;
121
122 dwIRControl = smi_read(IR_Init_Reg);
123 if (dwIRControl & rbIRVld) {
124 ucIRCount = (u8) smi_read(IR_Data_Cnt);
125
126 if (ucIRCount < 4)
127 goto end_ir_decode;
128
129 readLoop = ucIRCount/4;
130 if (ucIRCount % 4)
131 readLoop += 1;
132 for (index = 0; index < readLoop; index++) {
133 dwIRData = smi_read(IR_DATA_BUFFER_BASE + (index*4));
134
135 ir->irData[index*4 + 0] = (u8)(dwIRData);
136 ir->irData[index*4 + 1] = (u8)(dwIRData >> 8);
137 ir->irData[index*4 + 2] = (u8)(dwIRData >> 16);
138 ir->irData[index*4 + 3] = (u8)(dwIRData >> 24);
139 }
140 dwIRCode = smi_decode_rc5(ir->irData, ucIRCount);
141
142 if (dwIRCode != 0xFFFFFFFF) {
143 rc5_command = dwIRCode & 0x3F;
144 rc5_system = (dwIRCode & 0x7C0) >> 6;
145 toggle = (dwIRCode & 0x800) ? 1 : 0;
146 scancode = rc5_system << 8 | rc5_command;
147 rc_keydown(rc_dev, RC_PROTO_RC5, scancode, toggle);
148 }
149 }
150end_ir_decode:
151 smi_set(IR_Init_Reg, 0x04);
152 smi_ir_enableInterrupt(ir);
153}
154
155
156int smi_ir_irq(struct smi_rc *ir, u32 int_status)
157{
158 int handled = 0;
159
160 if (int_status & IR_X_INT) {
161 smi_ir_disableInterrupt(ir);
162 smi_ir_clearInterrupt(ir);
163 schedule_work(&ir->work);
164 handled = 1;
165 }
166 return handled;
167}
168
169void smi_ir_start(struct smi_rc *ir)
170{
171 struct smi_dev *dev = ir->dev;
172
173 smi_write(IR_Idle_Cnt_Low, 0x00140070);
174 msleep(20);
175 smi_set(IR_Init_Reg, 0x90);
176
177 smi_ir_enableInterrupt(ir);
178}
179
180int smi_ir_init(struct smi_dev *dev)
181{
182 int ret;
183 struct rc_dev *rc_dev;
184 struct smi_rc *ir = &dev->ir;
185
186 rc_dev = rc_allocate_device(RC_DRIVER_SCANCODE);
187 if (!rc_dev)
188 return -ENOMEM;
189
190
191 snprintf(ir->device_name, sizeof(ir->device_name), "IR (%s)",
192 dev->info->name);
193 snprintf(ir->input_phys, sizeof(ir->input_phys), "pci-%s/ir0",
194 pci_name(dev->pci_dev));
195
196 rc_dev->driver_name = "SMI_PCIe";
197 rc_dev->input_phys = ir->input_phys;
198 rc_dev->device_name = ir->device_name;
199 rc_dev->input_id.bustype = BUS_PCI;
200 rc_dev->input_id.version = 1;
201 rc_dev->input_id.vendor = dev->pci_dev->subsystem_vendor;
202 rc_dev->input_id.product = dev->pci_dev->subsystem_device;
203 rc_dev->dev.parent = &dev->pci_dev->dev;
204
205 rc_dev->map_name = dev->info->rc_map;
206
207 ir->rc_dev = rc_dev;
208 ir->dev = dev;
209
210 INIT_WORK(&ir->work, smi_ir_decode);
211 smi_ir_disableInterrupt(ir);
212
213 ret = rc_register_device(rc_dev);
214 if (ret)
215 goto ir_err;
216
217 return 0;
218ir_err:
219 rc_free_device(rc_dev);
220 return ret;
221}
222
223void smi_ir_exit(struct smi_dev *dev)
224{
225 struct smi_rc *ir = &dev->ir;
226 struct rc_dev *rc_dev = ir->rc_dev;
227
228 smi_ir_stop(ir);
229 rc_unregister_device(rc_dev);
230 ir->rc_dev = NULL;
231}
232