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[/] [openrisc/] [trunk/] [rtos/] [freertos-6.1.1/] [Demo/] [lwIP_AVR32_UC3/] [BOARDS/] [EVK1100/] [led.c] - Blame information for rev 583

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/*This file is prepared for Doxygen automatic documentation generation.*/
/*! \file *********************************************************************
 *
 * \brief AT32UC3A EVK1100 board LEDs support package.
 *
 * This file contains definitions and services related to the LED features of
 * the EVK1100 board.
 *
 * - Compiler:           IAR EWAVR32 and GNU GCC for AVR32
 * - Supported devices:  All AVR32 AT32UC3A devices can be used.
 * - AppNote:
 *
 * \author               Atmel Corporation: http://www.atmel.com \n
 *                       Support and FAQ: http://support.atmel.no/
 *
 ******************************************************************************/
 
/* Copyright (c) 2007, Atmel Corporation 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 ATMEL may not be used to endorse or promote products derived
 * from this software without specific prior written permission.
 *
 * THIS SOFTWARE IS PROVIDED BY ATMEL ``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 EXPRESSLY AND
 * SPECIFICALLY DISCLAIMED. IN NO EVENT SHALL ATMEL 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.
 */
 
 
#include <avr32/io.h>
#include "preprocessor.h"
#include "compiler.h"
#include "evk1100.h"
#include "led.h"
 
 
//! Structure describing LED hardware connections.
typedef const struct
{
  struct
  {
    U32 PORT;     //!< LED GPIO port.
    U32 PIN_MASK; //!< Bit-mask of LED pin in GPIO port.
  } GPIO; //!< LED GPIO descriptor.
  struct
  {
    S32 CHANNEL;  //!< LED PWM channel (< 0 if N/A).
    S32 FUNCTION; //!< LED pin PWM function (< 0 if N/A).
  } PWM;  //!< LED PWM descriptor.
} tLED_DESCRIPTOR;
 
 
//! Hardware descriptors of all LEDs.
static tLED_DESCRIPTOR LED_DESCRIPTOR[LED_COUNT] =
{
#define INSERT_LED_DESCRIPTOR(LED_NO, unused)                 \
  {                                                           \
    {LED##LED_NO##_GPIO / 32, 1 << (LED##LED_NO##_GPIO % 32)},\
    {LED##LED_NO##_PWM,       LED##LED_NO##_PWM_FUNCTION    } \
  },
  MREPEAT(LED_COUNT, INSERT_LED_DESCRIPTOR, ~)
#undef INSERT_LED_DESCRIPTOR
};
 
 
//! Saved state of all LEDs.
static volatile U32 LED_State = (1 << LED_COUNT) - 1;
 
 
U32 LED_Read_Display(void)
{
  return LED_State;
}
 
 
void LED_Display(U32 leds)
{
  tLED_DESCRIPTOR *led_descriptor;
  volatile avr32_gpio_port_t *led_gpio_port;
 
  leds &= (1 << LED_COUNT) - 1;
  LED_State = leds;
  for (led_descriptor = &LED_DESCRIPTOR[0];
       led_descriptor < LED_DESCRIPTOR + LED_COUNT;
       led_descriptor++)
  {
    led_gpio_port = &AVR32_GPIO.port[led_descriptor->GPIO.PORT];
    if (leds & 1)
    {
      led_gpio_port->ovrc  = led_descriptor->GPIO.PIN_MASK;
    }
    else
    {
      led_gpio_port->ovrs  = led_descriptor->GPIO.PIN_MASK;
    }
    led_gpio_port->oders = led_descriptor->GPIO.PIN_MASK;
    led_gpio_port->gpers = led_descriptor->GPIO.PIN_MASK;
    leds >>= 1;
  }
}
 
 
U32 LED_Read_Display_Mask(U32 mask)
{
  return Rd_bits(LED_State, mask);
}
 
 
void LED_Display_Mask(U32 mask, U32 leds)
{
  tLED_DESCRIPTOR *led_descriptor = &LED_DESCRIPTOR[0] - 1;
  volatile avr32_gpio_port_t *led_gpio_port;
  U8 led_shift;
 
  mask &= (1 << LED_COUNT) - 1;
  Wr_bits(LED_State, mask, leds);
  while (mask)
  {
    led_shift = 1 + ctz(mask);
    led_descriptor += led_shift;
    led_gpio_port = &AVR32_GPIO.port[led_descriptor->GPIO.PORT];
    leds >>= led_shift - 1;
    if (leds & 1)
    {
      led_gpio_port->ovrc  = led_descriptor->GPIO.PIN_MASK;
    }
    else
    {
      led_gpio_port->ovrs  = led_descriptor->GPIO.PIN_MASK;
    }
    led_gpio_port->oders = led_descriptor->GPIO.PIN_MASK;
    led_gpio_port->gpers = led_descriptor->GPIO.PIN_MASK;
    leds >>= 1;
    mask >>= led_shift;
  }
}
 
 
Bool LED_Test(U32 leds)
{
  return Tst_bits(LED_State, leds);
}
 
 
void LED_Off(U32 leds)
{
  tLED_DESCRIPTOR *led_descriptor = &LED_DESCRIPTOR[0] - 1;
  volatile avr32_gpio_port_t *led_gpio_port;
  U8 led_shift;
 
  leds &= (1 << LED_COUNT) - 1;
  Clr_bits(LED_State, leds);
  while (leds)
  {
    led_shift = 1 + ctz(leds);
    led_descriptor += led_shift;
    led_gpio_port = &AVR32_GPIO.port[led_descriptor->GPIO.PORT];
    led_gpio_port->ovrs  = led_descriptor->GPIO.PIN_MASK;
    led_gpio_port->oders = led_descriptor->GPIO.PIN_MASK;
    led_gpio_port->gpers = led_descriptor->GPIO.PIN_MASK;
    leds >>= led_shift;
  }
}
 
 
void LED_On(U32 leds)
{
  tLED_DESCRIPTOR *led_descriptor = &LED_DESCRIPTOR[0] - 1;
  volatile avr32_gpio_port_t *led_gpio_port;
  U8 led_shift;
 
  leds &= (1 << LED_COUNT) - 1;
  Set_bits(LED_State, leds);
  while (leds)
  {
    led_shift = 1 + ctz(leds);
    led_descriptor += led_shift;
    led_gpio_port = &AVR32_GPIO.port[led_descriptor->GPIO.PORT];
    led_gpio_port->ovrc  = led_descriptor->GPIO.PIN_MASK;
    led_gpio_port->oders = led_descriptor->GPIO.PIN_MASK;
    led_gpio_port->gpers = led_descriptor->GPIO.PIN_MASK;
    leds >>= led_shift;
  }
}
 
 
void LED_Toggle(U32 leds)
{
  tLED_DESCRIPTOR *led_descriptor = &LED_DESCRIPTOR[0] - 1;
  volatile avr32_gpio_port_t *led_gpio_port;
  U8 led_shift;
 
  leds &= (1 << LED_COUNT) - 1;
  Tgl_bits(LED_State, leds);
  while (leds)
  {
    led_shift = 1 + ctz(leds);
    led_descriptor += led_shift;
    led_gpio_port = &AVR32_GPIO.port[led_descriptor->GPIO.PORT];
    led_gpio_port->ovrt  = led_descriptor->GPIO.PIN_MASK;
    led_gpio_port->oders = led_descriptor->GPIO.PIN_MASK;
    led_gpio_port->gpers = led_descriptor->GPIO.PIN_MASK;
    leds >>= led_shift;
  }
}
 
 
U32 LED_Read_Display_Field(U32 field)
{
  return Rd_bitfield(LED_State, field);
}
 
 
void LED_Display_Field(U32 field, U32 leds)
{
  LED_Display_Mask(field, leds << ctz(field));
}
 
 
U8 LED_Get_Intensity(U32 led)
{
  tLED_DESCRIPTOR *led_descriptor;
 
  // Check that the argument value is valid.
  led = ctz(led);
  led_descriptor = &LED_DESCRIPTOR[led];
  if (led >= LED_COUNT || led_descriptor->PWM.CHANNEL < 0) return 0;
 
  // Return the duty cycle value if the LED PWM channel is enabled, else 0.
  return (AVR32_PWM.sr & (1 << led_descriptor->PWM.CHANNEL)) ?
           AVR32_PWM.channel[led_descriptor->PWM.CHANNEL].cdty : 0;
}
 
 
void LED_Set_Intensity(U32 leds, U8 intensity)
{
  tLED_DESCRIPTOR *led_descriptor = &LED_DESCRIPTOR[0] - 1;
  volatile avr32_pwm_channel_t *led_pwm_channel;
  volatile avr32_gpio_port_t *led_gpio_port;
  U8 led_shift;
 
  // For each specified LED...
  for (leds &= (1 << LED_COUNT) - 1; leds; leds >>= led_shift)
  {
    // Select the next specified LED and check that it has a PWM channel.
    led_shift = 1 + ctz(leds);
    led_descriptor += led_shift;
    if (led_descriptor->PWM.CHANNEL < 0) continue;
 
    // Initialize or update the LED PWM channel.
    led_pwm_channel = &AVR32_PWM.channel[led_descriptor->PWM.CHANNEL];
    if (!(AVR32_PWM.sr & (1 << led_descriptor->PWM.CHANNEL)))
    {
      led_pwm_channel->cmr = (AVR32_PWM_CPRE_MCK << AVR32_PWM_CPRE_OFFSET) &
                             ~(AVR32_PWM_CALG_MASK |
                               AVR32_PWM_CPOL_MASK |
                               AVR32_PWM_CPD_MASK);
      led_pwm_channel->cprd = 0x000000FF;
      led_pwm_channel->cdty = intensity;
      AVR32_PWM.ena = 1 << led_descriptor->PWM.CHANNEL;
    }
    else
    {
      AVR32_PWM.isr;
      while (!(AVR32_PWM.isr & (1 << led_descriptor->PWM.CHANNEL)));
      led_pwm_channel->cupd = intensity;
    }
 
    // Switch the LED pin to its PWM function.
    led_gpio_port = &AVR32_GPIO.port[led_descriptor->GPIO.PORT];
    if (led_descriptor->PWM.FUNCTION & 0x1)
    {
      led_gpio_port->pmr0s = led_descriptor->GPIO.PIN_MASK;
    }
    else
    {
      led_gpio_port->pmr0c = led_descriptor->GPIO.PIN_MASK;
    }
    if (led_descriptor->PWM.FUNCTION & 0x2)
    {
      led_gpio_port->pmr1s = led_descriptor->GPIO.PIN_MASK;
    }
    else
    {
      led_gpio_port->pmr1c = led_descriptor->GPIO.PIN_MASK;
    }
    led_gpio_port->gperc = led_descriptor->GPIO.PIN_MASK;
  }
}

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[/] [openrisc/] [trunk/] [rtos/] [freertos-6.1.1/] [Demo/] [lwIP_AVR32_UC3/] [BOARDS/] [EVK1100/] [led.c] - Blame information for rev 583

Line No.	Rev	Author	Line
1	583	jeremybenn	`/This file is prepared for Doxygen automatic documentation generation./`
2			`/! \file ********************************************************************`
3			`*`
4			`* \brief AT32UC3A EVK1100 board LEDs support package.`
5			`*`
6			`* This file contains definitions and services related to the LED features of`
7			`* the EVK1100 board.`
8			`*`
9			`* - Compiler: IAR EWAVR32 and GNU GCC for AVR32`
10			`* - Supported devices: All AVR32 AT32UC3A devices can be used.`
11			`* - AppNote:`
12			`*`
13			`* \author Atmel Corporation: http://www.atmel.com \n`
14			`* Support and FAQ: http://support.atmel.no/`
15			`*`
16			`******************************************************************************/`
17
18			`/* Copyright (c) 2007, Atmel Corporation All rights reserved.`
19			`*`
20			`* Redistribution and use in source and binary forms, with or without`
21			`* modification, are permitted provided that the following conditions are met:`
22			`*`
23			`* 1. Redistributions of source code must retain the above copyright notice,`
24			`* this list of conditions and the following disclaimer.`
25			`*`
26			`* 2. Redistributions in binary form must reproduce the above copyright notice,`
27			`* this list of conditions and the following disclaimer in the documentation`
28			`* and/or other materials provided with the distribution.`
29			`*`
30			`* 3. The name of ATMEL may not be used to endorse or promote products derived`
31			`* from this software without specific prior written permission.`
32			`*`
33			* THIS SOFTWARE IS PROVIDED BY ATMEL ``AS IS'' AND ANY EXPRESS OR IMPLIED
34			`* WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF`
35			`* MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE EXPRESSLY AND`
36			`* SPECIFICALLY DISCLAIMED. IN NO EVENT SHALL ATMEL BE LIABLE FOR ANY DIRECT,`
37			`* INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES`
38			`* (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;`
39			`* LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND`
40			`* ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT`
41			`* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF`
42			`* THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.`
43			`*/`
44
45
46			`#include <avr32/io.h>`
47			`#include "preprocessor.h"`
48			`#include "compiler.h"`
49			`#include "evk1100.h"`
50			`#include "led.h"`
51
52
53			`//! Structure describing LED hardware connections.`
54			`typedef const struct`
55			`{`
56			`struct`
57			`{`
58			`U32 PORT; //!< LED GPIO port.`
59			`U32 PIN_MASK; //!< Bit-mask of LED pin in GPIO port.`
60			`} GPIO; //!< LED GPIO descriptor.`
61			`struct`
62			`{`
63			`S32 CHANNEL; //!< LED PWM channel (< 0 if N/A).`
64			`S32 FUNCTION; //!< LED pin PWM function (< 0 if N/A).`
65			`} PWM; //!< LED PWM descriptor.`
66			`} tLED_DESCRIPTOR;`
67
68
69			`//! Hardware descriptors of all LEDs.`
70			`static tLED_DESCRIPTOR LED_DESCRIPTOR[LED_COUNT] =`
71			`{`
72			`#define INSERT_LED_DESCRIPTOR(LED_NO, unused) \`
73			`{ \`
74			`{LED##LED_NO##_GPIO / 32, 1 << (LED##LED_NO##_GPIO % 32)},\`
75			`{LED##LED_NO##_PWM, LED##LED_NO##_PWM_FUNCTION } \`
76			`},`
77			`MREPEAT(LED_COUNT, INSERT_LED_DESCRIPTOR, ~)`
78			`#undef INSERT_LED_DESCRIPTOR`
79			`};`
80
81
82			`//! Saved state of all LEDs.`
83			`static volatile U32 LED_State = (1 << LED_COUNT) - 1;`
84
85
86			`U32 LED_Read_Display(void)`
87			`{`
88			`return LED_State;`
89			`}`
90
91
92			`void LED_Display(U32 leds)`
93			`{`
94			`tLED_DESCRIPTOR *led_descriptor;`
95			`volatile avr32_gpio_port_t *led_gpio_port;`
96
97			`leds &= (1 << LED_COUNT) - 1;`
98			`LED_State = leds;`
99			`for (led_descriptor = &LED_DESCRIPTOR[0];`
100			`led_descriptor < LED_DESCRIPTOR + LED_COUNT;`
101			`led_descriptor++)`
102			`{`
103			`led_gpio_port = &AVR32_GPIO.port[led_descriptor->GPIO.PORT];`
104			`if (leds & 1)`
105			`{`
106			`led_gpio_port->ovrc = led_descriptor->GPIO.PIN_MASK;`
107			`}`
108			`else`
109			`{`
110			`led_gpio_port->ovrs = led_descriptor->GPIO.PIN_MASK;`
111			`}`
112			`led_gpio_port->oders = led_descriptor->GPIO.PIN_MASK;`
113			`led_gpio_port->gpers = led_descriptor->GPIO.PIN_MASK;`
114			`leds >>= 1;`
115			`}`
116			`}`
117
118
119			`U32 LED_Read_Display_Mask(U32 mask)`
120			`{`
121			`return Rd_bits(LED_State, mask);`
122			`}`
123
124
125			`void LED_Display_Mask(U32 mask, U32 leds)`
126			`{`
127			`tLED_DESCRIPTOR *led_descriptor = &LED_DESCRIPTOR[0] - 1;`
128			`volatile avr32_gpio_port_t *led_gpio_port;`
129			`U8 led_shift;`
130
131			`mask &= (1 << LED_COUNT) - 1;`
132			`Wr_bits(LED_State, mask, leds);`
133			`while (mask)`
134			`{`
135			`led_shift = 1 + ctz(mask);`
136			`led_descriptor += led_shift;`
137			`led_gpio_port = &AVR32_GPIO.port[led_descriptor->GPIO.PORT];`
138			`leds >>= led_shift - 1;`
139			`if (leds & 1)`
140			`{`
141			`led_gpio_port->ovrc = led_descriptor->GPIO.PIN_MASK;`
142			`}`
143			`else`
144			`{`
145			`led_gpio_port->ovrs = led_descriptor->GPIO.PIN_MASK;`
146			`}`
147			`led_gpio_port->oders = led_descriptor->GPIO.PIN_MASK;`
148			`led_gpio_port->gpers = led_descriptor->GPIO.PIN_MASK;`
149			`leds >>= 1;`
150			`mask >>= led_shift;`
151			`}`
152			`}`
153
154
155			`Bool LED_Test(U32 leds)`
156			`{`
157			`return Tst_bits(LED_State, leds);`
158			`}`
159
160
161			`void LED_Off(U32 leds)`
162			`{`
163			`tLED_DESCRIPTOR *led_descriptor = &LED_DESCRIPTOR[0] - 1;`
164			`volatile avr32_gpio_port_t *led_gpio_port;`
165			`U8 led_shift;`
166
167			`leds &= (1 << LED_COUNT) - 1;`
168			`Clr_bits(LED_State, leds);`
169			`while (leds)`
170			`{`
171			`led_shift = 1 + ctz(leds);`
172			`led_descriptor += led_shift;`
173			`led_gpio_port = &AVR32_GPIO.port[led_descriptor->GPIO.PORT];`
174			`led_gpio_port->ovrs = led_descriptor->GPIO.PIN_MASK;`
175			`led_gpio_port->oders = led_descriptor->GPIO.PIN_MASK;`
176			`led_gpio_port->gpers = led_descriptor->GPIO.PIN_MASK;`
177			`leds >>= led_shift;`
178			`}`
179			`}`
180
181
182			`void LED_On(U32 leds)`
183			`{`
184			`tLED_DESCRIPTOR *led_descriptor = &LED_DESCRIPTOR[0] - 1;`
185			`volatile avr32_gpio_port_t *led_gpio_port;`
186			`U8 led_shift;`
187
188			`leds &= (1 << LED_COUNT) - 1;`
189			`Set_bits(LED_State, leds);`
190			`while (leds)`
191			`{`
192			`led_shift = 1 + ctz(leds);`
193			`led_descriptor += led_shift;`
194			`led_gpio_port = &AVR32_GPIO.port[led_descriptor->GPIO.PORT];`
195			`led_gpio_port->ovrc = led_descriptor->GPIO.PIN_MASK;`
196			`led_gpio_port->oders = led_descriptor->GPIO.PIN_MASK;`
197			`led_gpio_port->gpers = led_descriptor->GPIO.PIN_MASK;`
198			`leds >>= led_shift;`
199			`}`
200			`}`
201
202
203			`void LED_Toggle(U32 leds)`
204			`{`
205			`tLED_DESCRIPTOR *led_descriptor = &LED_DESCRIPTOR[0] - 1;`
206			`volatile avr32_gpio_port_t *led_gpio_port;`
207			`U8 led_shift;`
208
209			`leds &= (1 << LED_COUNT) - 1;`
210			`Tgl_bits(LED_State, leds);`
211			`while (leds)`
212			`{`
213			`led_shift = 1 + ctz(leds);`
214			`led_descriptor += led_shift;`
215			`led_gpio_port = &AVR32_GPIO.port[led_descriptor->GPIO.PORT];`
216			`led_gpio_port->ovrt = led_descriptor->GPIO.PIN_MASK;`
217			`led_gpio_port->oders = led_descriptor->GPIO.PIN_MASK;`
218			`led_gpio_port->gpers = led_descriptor->GPIO.PIN_MASK;`
219			`leds >>= led_shift;`
220			`}`
221			`}`
222
223
224			`U32 LED_Read_Display_Field(U32 field)`
225			`{`
226			`return Rd_bitfield(LED_State, field);`
227			`}`
228
229
230			`void LED_Display_Field(U32 field, U32 leds)`
231			`{`
232			`LED_Display_Mask(field, leds << ctz(field));`
233			`}`
234
235
236			`U8 LED_Get_Intensity(U32 led)`
237			`{`
238			`tLED_DESCRIPTOR *led_descriptor;`
239
240			`// Check that the argument value is valid.`
241			`led = ctz(led);`
242			`led_descriptor = &LED_DESCRIPTOR[led];`
243			`if (led >= LED_COUNT \|\| led_descriptor->PWM.CHANNEL < 0) return 0;`
244
245			`// Return the duty cycle value if the LED PWM channel is enabled, else 0.`
246			`return (AVR32_PWM.sr & (1 << led_descriptor->PWM.CHANNEL)) ?`
247			`AVR32_PWM.channel[led_descriptor->PWM.CHANNEL].cdty : 0;`
248			`}`
249
250
251			`void LED_Set_Intensity(U32 leds, U8 intensity)`
252			`{`
253			`tLED_DESCRIPTOR *led_descriptor = &LED_DESCRIPTOR[0] - 1;`
254			`volatile avr32_pwm_channel_t *led_pwm_channel;`
255			`volatile avr32_gpio_port_t *led_gpio_port;`
256			`U8 led_shift;`
257
258			`// For each specified LED...`
259			`for (leds &= (1 << LED_COUNT) - 1; leds; leds >>= led_shift)`
260			`{`
261			`// Select the next specified LED and check that it has a PWM channel.`
262			`led_shift = 1 + ctz(leds);`
263			`led_descriptor += led_shift;`
264			`if (led_descriptor->PWM.CHANNEL < 0) continue;`
265
266			`// Initialize or update the LED PWM channel.`
267			`led_pwm_channel = &AVR32_PWM.channel[led_descriptor->PWM.CHANNEL];`
268			`if (!(AVR32_PWM.sr & (1 << led_descriptor->PWM.CHANNEL)))`
269			`{`
270			`led_pwm_channel->cmr = (AVR32_PWM_CPRE_MCK << AVR32_PWM_CPRE_OFFSET) &`
271			`~(AVR32_PWM_CALG_MASK \|`
272			`AVR32_PWM_CPOL_MASK \|`
273			`AVR32_PWM_CPD_MASK);`
274			`led_pwm_channel->cprd = 0x000000FF;`
275			`led_pwm_channel->cdty = intensity;`
276			`AVR32_PWM.ena = 1 << led_descriptor->PWM.CHANNEL;`
277			`}`
278			`else`
279			`{`
280			`AVR32_PWM.isr;`
281			`while (!(AVR32_PWM.isr & (1 << led_descriptor->PWM.CHANNEL)));`
282			`led_pwm_channel->cupd = intensity;`
283			`}`
284
285			`// Switch the LED pin to its PWM function.`
286			`led_gpio_port = &AVR32_GPIO.port[led_descriptor->GPIO.PORT];`
287			`if (led_descriptor->PWM.FUNCTION & 0x1)`
288			`{`
289			`led_gpio_port->pmr0s = led_descriptor->GPIO.PIN_MASK;`
290			`}`
291			`else`
292			`{`
293			`led_gpio_port->pmr0c = led_descriptor->GPIO.PIN_MASK;`
294			`}`
295			`if (led_descriptor->PWM.FUNCTION & 0x2)`
296			`{`
297			`led_gpio_port->pmr1s = led_descriptor->GPIO.PIN_MASK;`
298			`}`
299			`else`
300			`{`
301			`led_gpio_port->pmr1c = led_descriptor->GPIO.PIN_MASK;`
302			`}`
303			`led_gpio_port->gperc = led_descriptor->GPIO.PIN_MASK;`
304			`}`
305			`}`