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AudioConsole/AudioConsole.X/Source/winc1500/driver/source/nmasic.c

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  1. /**

  2.  *

  3.  * \file

  4.  *

  5.  * \brief This module contains NMC1500 ASIC specific internal APIs.

  6.  *

  7.  * Copyright (c) 2015 - 2017 Atmel Corporation. All rights reserved.

  8.  *

  9.  * \asf_license_start

  10.  *

  11.  * \page License

  12.  *

  13.  * Redistribution and use in source and binary forms, with or without

  14.  * modification, are permitted provided that the following conditions are met:

  15.  *

  16.  * 1. Redistributions of source code must retain the above copyright notice,

  17.  *    this list of conditions and the following disclaimer.

  18.  *

  19.  * 2. Redistributions in binary form must reproduce the above copyright notice,

  20.  *    this list of conditions and the following disclaimer in the documentation

  21.  *    and/or other materials provided with the distribution.

  22.  *

  23.  * 3. The name of Atmel may not be used to endorse or promote products derived

  24.  *    from this software without specific prior written permission.

  25.  *

  26.  * THIS SOFTWARE IS PROVIDED BY ATMEL "AS IS" AND ANY EXPRESS OR IMPLIED

  27.  * WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF

  28.  * MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NON-INFRINGEMENT ARE

  29.  * EXPRESSLY AND SPECIFICALLY DISCLAIMED. IN NO EVENT SHALL ATMEL BE LIABLE FOR

  30.  * ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL

  31.  * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS

  32.  * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)

  33.  * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT,

  34.  * STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN

  35.  * ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE

  36.  * POSSIBILITY OF SUCH DAMAGE.

  37.  *

  38.  * \asf_license_stop

  39.  *

  40.  */

  41. 

  42. #include "common/include/nm_common.h"

  43. #include "driver/source/nmbus.h"

  44. #include "bsp/include/nm_bsp.h"

  45. #include "driver/source/nmasic.h"

  46. #include "driver/include/m2m_types.h"

  47. 

  48. #define NMI_GLB_RESET_0 (NMI_PERIPH_REG_BASE + 0x400)

  49. #define NMI_INTR_REG_BASE (NMI_PERIPH_REG_BASE + 0xa00)

  50. #define NMI_PIN_MUX_0 (NMI_PERIPH_REG_BASE + 0x408)

  51. #define NMI_INTR_ENABLE (NMI_INTR_REG_BASE)

  52. #define GET_UINT32(X, Y) (X[0 + Y] + ((uint32)X[1 + Y] << 8) + ((uint32)X[2 + Y] << 16) + ((uint32)X[3 + Y] << 24))

  53. 

  54. /*SPI and I2C only*/

  55. #define CORT_HOST_COMM (0x10)

  56. #define HOST_CORT_COMM (0x0b)

  57. #define WAKE_CLK_REG (0x1)

  58. #define CLOCKS_EN_REG (0xf)

  59. 

  60. #define TIMEOUT (0xfffffffful)

  61. #define WAKUP_TRAILS_TIMEOUT (4)

  62. 

  63. sint8 chip_apply_conf(uint32 u32Conf)

  64. {

  65. 	sint8  ret   = M2M_SUCCESS;

  66. 	uint32 val32 = u32Conf;

  67. 

  68. #if (defined __ENABLE_PMU__) || (defined CONF_WINC_INT_PMU)

  69. 	val32 |= rHAVE_USE_PMU_BIT;

  70. #endif

  71. #ifdef __ENABLE_SLEEP_CLK_SRC_RTC__

  72. 	val32 |= rHAVE_SLEEP_CLK_SRC_RTC_BIT;

  73. #elif defined __ENABLE_SLEEP_CLK_SRC_XO__

  74. 	val32 |= rHAVE_SLEEP_CLK_SRC_XO_BIT;

  75. #endif

  76. #ifdef __ENABLE_EXT_PA_INV_TX_RX__

  77. 	val32 |= rHAVE_EXT_PA_INV_TX_RX;

  78. #endif

  79. #ifdef __ENABLE_LEGACY_RF_SETTINGS__

  80. 	val32 |= rHAVE_LEGACY_RF_SETTINGS;

  81. #endif

  82. #ifdef __DISABLE_FIRMWARE_LOGS__

  83. 	val32 |= rHAVE_LOGS_DISABLED_BIT;

  84. #endif

  85. #if defined CONF_WINC_XO_XTALGM2_DIS

  86. 	val32 |= rHAVE_XO_XTALGM2_DIS_BIT;

  87. #endif

  88. 

  89. 	val32 |= rHAVE_RESERVED1_BIT;

  90. 	do {

  91. 		nm_write_reg(rNMI_GP_REG_1, val32);

  92. 		if (val32 != 0) {

  93. 			uint32 reg = 0;

  94. 			ret        = nm_read_reg_with_ret(rNMI_GP_REG_1, &reg);

  95. 			if (ret == M2M_SUCCESS) {

  96. 				if (reg == val32)

  97. 					break;

  98. 			}

  99. 		} else {

  100. 			break;

  101. 		}

  102. 	} while (1);

  103. 

  104. 	return M2M_SUCCESS;

  105. }

  106. void chip_idle(void)

  107. {

  108. 	uint32 reg = 0;

  109. 	nm_read_reg_with_ret(WAKE_CLK_REG, &reg);

  110. 	if (reg & NBIT1) {

  111. 		reg &= ~NBIT1;

  112. 		nm_write_reg(WAKE_CLK_REG, reg);

  113. 	}

  114. }

  115. 

  116. sint8 enable_interrupts(void)

  117. {

  118. 	uint32 reg = 0;

  119. 	sint8  ret = M2M_SUCCESS;

  120. 	/**

  121. 	interrupt pin mux select

  122. 	**/

  123. 	ret = nm_read_reg_with_ret(NMI_PIN_MUX_0, &reg);

  124. 	if (M2M_SUCCESS != ret)

  125. 		goto ERR1;

  126. 

  127. 	reg |= ((uint32)1 << 8);

  128. 	ret = nm_write_reg(NMI_PIN_MUX_0, reg);

  129. 	if (M2M_SUCCESS != ret)

  130. 		goto ERR1;

  131. 

  132. 	/**

  133. 	interrupt enable

  134. 	**/

  135. 	ret = nm_read_reg_with_ret(NMI_INTR_ENABLE, &reg);

  136. 	if (M2M_SUCCESS != ret)

  137. 		goto ERR1;

  138. 

  139. 	reg |= ((uint32)1 << 16);

  140. 	ret = nm_write_reg(NMI_INTR_ENABLE, reg);

  141. 	if (M2M_SUCCESS != ret)

  142. 		goto ERR1;

  143. ERR1:

  144. 	return ret;

  145. }

  146. 

  147. sint8 cpu_start(void)

  148. {

  149. 	uint32 reg = 0;

  150. 	sint8  ret;

  151. 

  152. 	/**

  153. 	reset regs

  154. 	*/

  155. 	ret = nm_write_reg(BOOTROM_REG, 0);

  156. 	ret += nm_write_reg(NMI_STATE_REG, 0);

  157. 	ret += nm_write_reg(NMI_REV_REG, 0);

  158. 	/**

  159. 	Go...

  160. 	**/

  161. 	ret += nm_read_reg_with_ret(0x1118, &reg);

  162. 	reg |= (1 << 0);

  163. 	ret += nm_write_reg(0x1118, reg);

  164. 	ret += nm_read_reg_with_ret(NMI_GLB_RESET_0, &reg);

  165. 	if ((reg & (1ul << 10)) == (1ul << 10)) {

  166. 		reg &= ~(1ul << 10);

  167. 		ret += nm_write_reg(NMI_GLB_RESET_0, reg);

  168. 	}

  169. 	reg |= (1ul << 10);

  170. 	ret += nm_write_reg(NMI_GLB_RESET_0, reg);

  171. 	nm_bsp_sleep(1);

  172. 	return ret;

  173. }

  174. 

  175. uint32 nmi_get_chipid(void)

  176. {

  177. 	static uint32 chipid = 0;

  178. 

  179. 	if (chipid == 0) {

  180. 		uint32 rfrevid;

  181. 

  182. 		if ((nm_read_reg_with_ret(0x1000, &chipid)) != M2M_SUCCESS) {

  183. 			chipid = 0;

  184. 			return 0;

  185. 		}

  186. 		// if((ret = nm_read_reg_with_ret(0x11fc, &revid)) != M2M_SUCCESS) {

  187. 		//	return 0;

  188. 		//}

  189. 		if ((nm_read_reg_with_ret(0x13f4, &rfrevid)) != M2M_SUCCESS) {

  190. 			chipid = 0;

  191. 			return 0;

  192. 		}

  193. 

  194. 		if (chipid == 0x1002a0) {

  195. 			if (rfrevid == 0x1) {              /* 1002A0 */

  196. 			} else /* if (rfrevid == 0x2) */ { /* 1002A1 */

  197. 				chipid = 0x1002a1;

  198. 			}

  199. 		} else if (chipid == 0x1002b0) {

  200. 			if (rfrevid == 3) {        /* 1002B0 */

  201. 			} else if (rfrevid == 4) { /* 1002B1 */

  202. 				chipid = 0x1002b1;

  203. 			} else /* if(rfrevid == 5) */ { /* 1002B2 */

  204. 				chipid = 0x1002b2;

  205. 			}

  206. 		} else if (chipid == 0x1000F0) {

  207. 			if ((nm_read_reg_with_ret(0x3B0000, &chipid)) != M2M_SUCCESS) {

  208. 				chipid = 0;

  209. 				return 0;

  210. 			}

  211. 		} else {

  212. 		}

  213. //#define PROBE_FLASH

  214. #ifdef PROBE_FLASH

  215. 		if (chipid) {

  216. 			UWORD32 flashid;

  217. 

  218. 			flashid = probe_spi_flash();

  219. 			if (flashid == 0x1230ef) {

  220. 				chipid &= ~(0x0f0000);

  221. 				chipid |= 0x050000;

  222. 			}

  223. 			if (flashid == 0xc21320c2) {

  224. 				chipid &= ~(0x0f0000);

  225. 				chipid |= 0x050000;

  226. 			}

  227. 		}

  228. #else

  229. 		/*M2M is by default have SPI flash*/

  230. 		chipid &= ~(0x0f0000);

  231. 		chipid |= 0x050000;

  232. #endif /* PROBE_FLASH */

  233. 	}

  234. 	return chipid;

  235. }

  236. 

  237. uint32 nmi_get_rfrevid(void)

  238. {

  239. 	uint32 rfrevid;

  240. 	if ((nm_read_reg_with_ret(0x13f4, &rfrevid)) != M2M_SUCCESS) {

  241. 		rfrevid = 0;

  242. 		return 0;

  243. 	}

  244. 	return rfrevid;

  245. }

  246. 

  247. void restore_pmu_settings_after_global_reset(void)

  248. {

  249. 	/*

  250. 	 * Must restore PMU register value after

  251. 	 * global reset if PMU toggle is done at

  252. 	 * least once since the last hard reset.

  253. 	 */

  254. 	if (REV(nmi_get_chipid()) >= REV_2B0) {

  255. 		nm_write_reg(0x1e48, 0xb78469ce);

  256. 	}

  257. }

  258. 

  259. void nmi_update_pll(void)

  260. {

  261. 	uint32 pll;

  262. 

  263. 	pll = nm_read_reg(0x1428);

  264. 	pll &= ~0x1ul;

  265. 	nm_write_reg(0x1428, pll);

  266. 	pll |= 0x1ul;

  267. 	nm_write_reg(0x1428, pll);

  268. }

  269. void nmi_set_sys_clk_src_to_xo(void)

  270. {

  271. 	uint32 val32;

  272. 

  273. 	/* Switch system clock source to XO. This will take effect after nmi_update_pll(). */

  274. 	val32 = nm_read_reg(0x141c);

  275. 	val32 |= (1 << 2);

  276. 	nm_write_reg(0x141c, val32);

  277. 

  278. 	/* Do PLL update */

  279. 	nmi_update_pll();

  280. }

  281. sint8 chip_sleep(void)

  282. {

  283. 	uint32 reg;

  284. 	sint8  ret = M2M_SUCCESS;

  285. 

  286. 	while (1) {

  287. 		ret = nm_read_reg_with_ret(CORT_HOST_COMM, &reg);

  288. 		if (ret != M2M_SUCCESS)

  289. 			goto ERR1;

  290. 		if ((reg & NBIT0) == 0)

  291. 			break;

  292. 	}

  293. 

  294. 	/* Clear bit 1 */

  295. 	ret = nm_read_reg_with_ret(WAKE_CLK_REG, &reg);

  296. 	if (ret != M2M_SUCCESS)

  297. 		goto ERR1;

  298. 	if (reg & NBIT1) {

  299. 		reg &= ~NBIT1;

  300. 		ret = nm_write_reg(WAKE_CLK_REG, reg);

  301. 		if (ret != M2M_SUCCESS)

  302. 			goto ERR1;

  303. 	}

  304. 

  305. 	ret = nm_read_reg_with_ret(HOST_CORT_COMM, &reg);

  306. 	if (ret != M2M_SUCCESS)

  307. 		goto ERR1;

  308. 	if (reg & NBIT0) {

  309. 		reg &= ~NBIT0;

  310. 		ret = nm_write_reg(HOST_CORT_COMM, reg);

  311. 		if (ret != M2M_SUCCESS)

  312. 			goto ERR1;

  313. 	}

  314. 

  315. ERR1:

  316. 	return ret;

  317. }

  318. sint8 chip_wake(void)

  319. {

  320. 	sint8  ret = M2M_SUCCESS;

  321. 	uint32 reg = 0, clk_status_reg = 0, trials = 0;

  322. 

  323. 	ret = nm_read_reg_with_ret(HOST_CORT_COMM, &reg);

  324. 	if (ret != M2M_SUCCESS)

  325. 		goto _WAKE_EXIT;

  326. 

  327. 	if (!(reg & NBIT0)) {

  328. 		/*USE bit 0 to indicate host wakeup*/

  329. 		ret = nm_write_reg(HOST_CORT_COMM, reg | NBIT0);

  330. 		if (ret != M2M_SUCCESS)

  331. 			goto _WAKE_EXIT;

  332. 	}

  333. 

  334. 	ret = nm_read_reg_with_ret(WAKE_CLK_REG, &reg);

  335. 	if (ret != M2M_SUCCESS)

  336. 		goto _WAKE_EXIT;

  337. 	/* Set bit 1 */

  338. 	if (!(reg & NBIT1)) {

  339. 		ret = nm_write_reg(WAKE_CLK_REG, reg | NBIT1);

  340. 		if (ret != M2M_SUCCESS)

  341. 			goto _WAKE_EXIT;

  342. 	}

  343. 

  344. 	do {

  345. 		ret = nm_read_reg_with_ret(CLOCKS_EN_REG, &clk_status_reg);

  346. 		if (ret != M2M_SUCCESS) {

  347. 			M2M_ERR("Bus error (5).%d %x\n", ret, clk_status_reg);

  348. 			goto _WAKE_EXIT;

  349. 		}

  350. 		if (clk_status_reg & NBIT2) {

  351. 			break;

  352. 		}

  353. 		nm_bsp_sleep(2);

  354. 		trials++;

  355. 		if (trials > WAKUP_TRAILS_TIMEOUT) {

  356. 			M2M_ERR("Failed to wakup the chip\n");

  357. 			ret = M2M_ERR_TIME_OUT;

  358. 			goto _WAKE_EXIT;

  359. 		}

  360. 	} while (1);

  361. 

  362. 	/*workaround sometimes spi fail to read clock regs after reading/writing clockless registers*/

  363. 	nm_bus_reset();

  364. 

  365. _WAKE_EXIT:

  366. 	return ret;

  367. }

  368. sint8 cpu_halt(void)

  369. {

  370. 	sint8  ret;

  371. 	uint32 reg = 0;

  372. 	ret        = nm_read_reg_with_ret(0x1118, &reg);

  373. 	reg |= (1 << 0);

  374. 	ret += nm_write_reg(0x1118, reg);

  375. 	ret += nm_read_reg_with_ret(NMI_GLB_RESET_0, &reg);

  376. 	if ((reg & (1ul << 10)) == (1ul << 10)) {

  377. 		reg &= ~(1ul << 10);

  378. 		ret += nm_write_reg(NMI_GLB_RESET_0, reg);

  379. 		ret += nm_read_reg_with_ret(NMI_GLB_RESET_0, &reg);

  380. 	}

  381. 	return ret;

  382. }

  383. sint8 chip_reset_and_cpu_halt(void)

  384. {

  385. 	sint8 ret = M2M_SUCCESS;

  386. 

  387. 	/*Wakeup needed only for I2C interface*/

  388. 	ret = chip_wake();

  389. 	if (ret != M2M_SUCCESS)

  390. 		goto ERR1;

  391. 	/*Reset and CPU halt need for no wait board only*/

  392. 	ret = chip_reset();

  393. 	if (ret != M2M_SUCCESS)

  394. 		goto ERR1;

  395. 	ret = cpu_halt();

  396. 	if (ret != M2M_SUCCESS)

  397. 		goto ERR1;

  398. ERR1:

  399. 	return ret;

  400. }

  401. sint8 chip_reset(void)

  402. {

  403. 	sint8 ret = M2M_SUCCESS;

  404. 	ret       = nm_write_reg(NMI_GLB_RESET_0, 0);

  405. 	nm_bsp_sleep(50);

  406. 	return ret;

  407. }

  408. 

  409. sint8 wait_for_bootrom(uint8 arg)

  410. {

  411. 	sint8  ret = M2M_SUCCESS;

  412. 	uint32 reg = 0, cnt = 0;

  413. 	uint32 u32GpReg1        = 0;

  414. 	uint32 u32DriverVerInfo = M2M_MAKE_VERSION_INFO(M2M_RELEASE_VERSION_MAJOR_NO,

  415. 	                                                M2M_RELEASE_VERSION_MINOR_NO,

  416. 	                                                M2M_RELEASE_VERSION_PATCH_NO,

  417. 	                                                M2M_MIN_REQ_DRV_VERSION_MAJOR_NO,

  418. 	                                                M2M_MIN_REQ_DRV_VERSION_MINOR_NO,

  419. 	                                                M2M_MIN_REQ_DRV_VERSION_PATCH_NO);

  420. 

  421. 	reg = 0;

  422. 	while (1) {

  423. 		reg = nm_read_reg(0x1014); /* wait for efuse loading done */

  424. 		if (reg & 0x80000000) {

  425. 			break;

  426. 		}

  427. 		nm_bsp_sleep(1); /* TODO: Why bus error if this delay is not here. */

  428. 	}

  429. 	reg = nm_read_reg(M2M_WAIT_FOR_HOST_REG);

  430. 	reg &= 0x1;

  431. 

  432. 	/* check if waiting for the host will be skipped or not */

  433. 	if (reg == 0) {

  434. 		reg = 0;

  435. 		while (reg != M2M_FINISH_BOOT_ROM) {

  436. 			nm_bsp_sleep(1);

  437. 			reg = nm_read_reg(BOOTROM_REG);

  438. 

  439. 			if (++cnt > TIMEOUT) {

  440. 				M2M_DBG("failed to load firmware from flash.\n");

  441. 				ret = M2M_ERR_INIT;

  442. 				goto ERR2;

  443. 			}

  444. 		}

  445. 	}

  446. 

  447. 	if (M2M_WIFI_MODE_ATE_HIGH == arg) {

  448. 		nm_write_reg(NMI_REV_REG, M2M_ATE_FW_START_VALUE);

  449. 		nm_write_reg(NMI_STATE_REG, NBIT20);

  450. 	} else if (M2M_WIFI_MODE_ATE_LOW == arg) {

  451. 		nm_write_reg(NMI_REV_REG, M2M_ATE_FW_START_VALUE);

  452. 		nm_write_reg(NMI_STATE_REG, 0);

  453. 	} else if (M2M_WIFI_MODE_ETHERNET == arg) {

  454. 		u32GpReg1 = rHAVE_ETHERNET_MODE_BIT;

  455. 		nm_write_reg(NMI_STATE_REG, u32DriverVerInfo);

  456. 	} else {

  457. 		/*bypass this step*/

  458. 		nm_write_reg(NMI_STATE_REG, u32DriverVerInfo);

  459. 	}

  460. 

  461. 	if (REV(nmi_get_chipid()) >= REV_3A0) {

  462. 		chip_apply_conf(u32GpReg1 | rHAVE_USE_PMU_BIT);

  463. 	} else {

  464. 		chip_apply_conf(u32GpReg1);

  465. 	}

  466. 	M2M_INFO("DriverVerInfo: 0x%08lx\n", u32DriverVerInfo);

  467. 

  468. 	nm_write_reg(BOOTROM_REG, M2M_START_FIRMWARE);

  469. 

  470. #ifdef __ROM_TEST__

  471. 	rom_test();

  472. #endif /* __ROM_TEST__ */

  473. 

  474. ERR2:

  475. 	return ret;

  476. }

  477. 

  478. sint8 wait_for_firmware_start(uint8 arg)

  479. {

  480. 	sint8           ret = M2M_SUCCESS;

  481. 	uint32          reg = 0, cnt = 0;

  482. 	uint32          u32Timeout = TIMEOUT;

  483. 	volatile uint32 regAddress = NMI_STATE_REG;

  484. 	volatile uint32 checkValue = M2M_FINISH_INIT_STATE;

  485. 

  486. 	if ((M2M_WIFI_MODE_ATE_HIGH == arg) || (M2M_WIFI_MODE_ATE_LOW == arg)) {

  487. 		regAddress = NMI_REV_REG;

  488. 		checkValue = M2M_ATE_FW_IS_UP_VALUE;

  489. 	} else {

  490. 		/*bypass this step*/

  491. 	}

  492. 

  493. 	while (checkValue != reg) {

  494. 		nm_bsp_sleep(2); /* TODO: Why bus error if this delay is not here. */

  495. 		M2M_DBG("%x %x %x\n",

  496. 		        (unsigned int)nm_read_reg(0x108c),

  497. 		        (unsigned int)nm_read_reg(0x108c),

  498. 		        (unsigned int)nm_read_reg(0x14A0));

  499. 		reg = nm_read_reg(regAddress);

  500. 		if (++cnt >= u32Timeout) {

  501. 			M2M_DBG("Time out for wait firmware Run\n");

  502. 			ret = M2M_ERR_INIT;

  503. 			goto ERR;

  504. 		}

  505. 	}

  506. 	if (M2M_FINISH_INIT_STATE == checkValue) {

  507. 		nm_write_reg(NMI_STATE_REG, 0);

  508. 	}

  509. ERR:

  510. 	return ret;

  511. }

  512. 

  513. sint8 chip_deinit(void)

  514. {

  515. 	uint32 reg = 0;

  516. 	sint8  ret;

  517. 

  518. 	/**

  519. 	stop the firmware, need a re-download

  520. 	**/

  521. 	ret = nm_read_reg_with_ret(NMI_GLB_RESET_0, &reg);

  522. 	if (ret != M2M_SUCCESS) {

  523. 		M2M_ERR("failed to de-initialize\n");

  524. 		goto ERR1;

  525. 	}

  526. 	reg &= ~(1 << 10);

  527. 	ret = nm_write_reg(NMI_GLB_RESET_0, reg);

  528. 	if (ret != M2M_SUCCESS) {

  529. 		M2M_ERR("failed to de-initialize\n");

  530. 		goto ERR1;

  531. 	}

  532. 

  533. ERR1:

  534. 	return ret;

  535. }

  536. 

  537. #ifdef CONF_PERIPH

  538. 

  539. sint8 set_gpio_dir(uint8 gpio, uint8 dir)

  540. {

  541. 	uint32 val32;

  542. 	sint8  ret;

  543. 

  544. 	ret = nm_read_reg_with_ret(0x20108, &val32);

  545. 	if (ret != M2M_SUCCESS)

  546. 		goto _EXIT;

  547. 

  548. 	if (dir) {

  549. 		val32 |= (1ul << gpio);

  550. 	} else {

  551. 		val32 &= ~(1ul << gpio);

  552. 	}

  553. 

  554. 	ret = nm_write_reg(0x20108, val32);

  555. 

  556. _EXIT:

  557. 	return ret;

  558. }

  559. sint8 set_gpio_val(uint8 gpio, uint8 val)

  560. {

  561. 	uint32 val32;

  562. 	sint8  ret;

  563. 

  564. 	ret = nm_read_reg_with_ret(0x20100, &val32);

  565. 	if (ret != M2M_SUCCESS)

  566. 		goto _EXIT;

  567. 

  568. 	if (val) {

  569. 		val32 |= (1ul << gpio);

  570. 	} else {

  571. 		val32 &= ~(1ul << gpio);

  572. 	}

  573. 

  574. 	ret = nm_write_reg(0x20100, val32);

  575. 

  576. _EXIT:

  577. 	return ret;

  578. }

  579. 

  580. sint8 get_gpio_val(uint8 gpio, uint8 *val)

  581. {

  582. 	uint32 val32;

  583. 	sint8  ret;

  584. 

  585. 	ret = nm_read_reg_with_ret(0x20104, &val32);

  586. 	if (ret != M2M_SUCCESS)

  587. 		goto _EXIT;

  588. 

  589. 	*val = (uint8)((val32 >> gpio) & 0x01);

  590. 

  591. _EXIT:

  592. 	return ret;

  593. }

  594. 

  595. sint8 pullup_ctrl(uint32 pinmask, uint8 enable)

  596. {

  597. 	sint8  s8Ret;

  598. 	uint32 val32;

  599. 	s8Ret = nm_read_reg_with_ret(0x142c, &val32);

  600. 	if (s8Ret != M2M_SUCCESS) {

  601. 		M2M_ERR("[pullup_ctrl]: failed to read\n");

  602. 		goto _EXIT;

  603. 	}

  604. 	if (enable) {

  605. 		val32 &= ~pinmask;

  606. 	} else {

  607. 		val32 |= pinmask;

  608. 	}

  609. 	s8Ret = nm_write_reg(0x142c, val32);

  610. 	if (s8Ret != M2M_SUCCESS) {

  611. 		M2M_ERR("[pullup_ctrl]: failed to write\n");

  612. 		goto _EXIT;

  613. 	}

  614. _EXIT:

  615. 	return s8Ret;

  616. }

  617. #endif /* CONF_PERIPH */

  618. 

  619. sint8 nmi_get_otp_mac_address(uint8 *pu8MacAddr, uint8 *pu8IsValid)

  620. {

  621. 	sint8      ret;

  622. 	uint32     u32RegValue;

  623. 	uint8      mac[6];

  624. 	tstrGpRegs strgp = {0};

  625. 

  626. 	ret = nm_read_reg_with_ret(rNMI_GP_REG_2, &u32RegValue);

  627. 	if (ret != M2M_SUCCESS)

  628. 		goto _EXIT_ERR;

  629. 

  630. 	ret = nm_read_block(u32RegValue | 0x30000, (uint8 *)&strgp, sizeof(tstrGpRegs));

  631. 	if (ret != M2M_SUCCESS)

  632. 		goto _EXIT_ERR;

  633. 	u32RegValue = strgp.u32Mac_efuse_mib;

  634. 

  635. 	if (!EFUSED_MAC(u32RegValue)) {

  636. 		M2M_DBG("Default MAC\n");

  637. 		m2m_memset(pu8MacAddr, 0, 6);

  638. 		goto _EXIT_ERR;

  639. 	}

  640. 

  641. 	M2M_DBG("OTP MAC\n");

  642. 	u32RegValue >>= 16;

  643. 	ret = nm_read_block(u32RegValue | 0x30000, mac, 6);

  644. 	m2m_memcpy(pu8MacAddr, mac, 6);

  645. 	if (pu8IsValid)

  646. 		*pu8IsValid = 1;

  647. 	return ret;

  648. 

  649. _EXIT_ERR:

  650. 	if (pu8IsValid)

  651. 		*pu8IsValid = 0;

  652. 	return ret;

  653. }

  654. 

  655. sint8 nmi_get_mac_address(uint8 *pu8MacAddr)

  656. {

  657. 	sint8      ret;

  658. 	uint32     u32RegValue;

  659. 	uint8      mac[6];

  660. 	tstrGpRegs strgp = {0};

  661. 

  662. 	ret = nm_read_reg_with_ret(rNMI_GP_REG_2, &u32RegValue);

  663. 	if (ret != M2M_SUCCESS)

  664. 		goto _EXIT_ERR;

  665. 

  666. 	ret = nm_read_block(u32RegValue | 0x30000, (uint8 *)&strgp, sizeof(tstrGpRegs));

  667. 	if (ret != M2M_SUCCESS)

  668. 		goto _EXIT_ERR;

  669. 	u32RegValue = strgp.u32Mac_efuse_mib;

  670. 

  671. 	u32RegValue &= 0x0000ffff;

  672. 	ret = nm_read_block(u32RegValue | 0x30000, mac, 6);

  673. 	m2m_memcpy(pu8MacAddr, mac, 6);

  674. 

  675. 	return ret;

  676. 

  677. _EXIT_ERR:

  678. 	return ret;

  679. }