plat/mediatek/common/mtk_smc_handlers.c - filogic/atf - Gitiles

 /*
  * Copyright (c) 2022, MediaTek Inc. All rights reserved.
  *
  * SPDX-License-Identifier: BSD-3-Clause
  */

 #include <assert.h>
 #include <errno.h>
 #if MTK_SIP_KERNEL_BOOT_ENABLE
 #include <cold_boot.h>
 #endif
 #include <common/debug.h>
 #include <common/runtime_svc.h>
 #include <lib/mtk_init/mtk_init.h>
 #include <mtk_sip_svc.h>

 #define SMC_HANDLER_DEBUG(...) VERBOSE(__VA_ARGS__)
 #define SMC_HANDLER_DEBUG_NOT_IMP_MSG "%s[0x%x] smc handler not implemented\n"
 #define SMC_HANDLER_DEBUG_START_MSG "%s[0x%x] smc handler start, smc desc. index:%d\n"
 #define SMC_HANDLER_DEBUG_END_MSG "%s[0x%x] smc handler end\n"

 /*
  * These macros below are used to identify SIP calls from Kernel,
  * Hypervisor, or 2ndBootloader
  */
 #define SIP_FID_ORI_MASK	(0xc000)
 #define SIP_FID_ORI_SHIFT	(14)
 #define SIP_FID_KERNEL		(0x0)
 #define SIP_FID_KERNEL_VIA_GZ	(0x1)
 #define SIP_FID_GZ		(0x2)

 #define GET_SMC_ORI(_fid)	(((_fid) & SIP_FID_ORI_MASK) >> SIP_FID_ORI_SHIFT)
 #define GET_SMC_ORI_NUM(_fid)	((_fid) & ~(SIP_FID_ORI_MASK))

 #define is_from_nsel2(_ori)	(_ori == SIP_FID_GZ)
 #define is_from_bl33(_ori) \
 	((_ori != SIP_FID_GZ) && (is_el1_2nd_bootloader() == 1))
 #define is_from_nsel1(_ori) \
 	(((_ori == SIP_FID_KERNEL) || \
 	 (_ori == SIP_FID_KERNEL_VIA_GZ)) && \
 	 (is_el1_2nd_bootloader() == 0))

 #define is_smc_forbidden(_ori) (_ori == SIP_FID_KERNEL_VIA_GZ)

 #define MASK_32_BIT (0xffffffffU)
 #define SMC_ID_EXPAND_AS_SMC_OPERATION(_smc_id, _smc_num) \
 	case _smc_id##_AARCH32: \
 	{ \
 		x1 = x1 & MASK_32_BIT; \
 		x2 = x2 & MASK_32_BIT; \
 		x3 = x3 & MASK_32_BIT; \
 		x4 = x4 & MASK_32_BIT; \
 	} \
 	/* fallthrough */ \
 	case _smc_id##_AARCH64: \
 	{ \
 		if (_smc_id##_descriptor_index < 0) { \
 			SMC_HANDLER_DEBUG(SMC_HANDLER_DEBUG_NOT_IMP_MSG, #_smc_id, smc_id); \
 			break; \
 		} \
 		if (_smc_id##_descriptor_index >= smc_id_descriptor_max) { \
 			SMC_HANDLER_DEBUG("smc descriptor index[%d] exceed max[%d]\n", \
 					  _smc_id##_descriptor_index, smc_id_descriptor_max); \
 			break; \
 		} \
 		SMC_HANDLER_DEBUG(SMC_HANDLER_DEBUG_START_MSG, #_smc_id, smc_id, \
 				  _smc_id##_descriptor_index); \
 		ret  = smc_handler_pool[_smc_id##_descriptor_index].smc_handler(x1,\
 				x2, x3, x4, handle, &smc_ret); \
 		SMC_HANDLER_DEBUG(SMC_HANDLER_DEBUG_END_MSG, #_smc_id, smc_id); \
 		break; \
 	}

 #define SMC_ID_EXPAND_AS_DESCRIPTOR_INDEX(_smc_id, _smc_num) \
 	short _smc_id##_descriptor_index __section("mtk_plat_ro") = -1;

 MTK_SIP_SMC_FROM_BL33_TABLE(SMC_ID_EXPAND_AS_DESCRIPTOR_INDEX);
 MTK_SIP_SMC_FROM_NS_EL1_TABLE(SMC_ID_EXPAND_AS_DESCRIPTOR_INDEX);

 IMPORT_SYM(uintptr_t, __MTK_SMC_POOL_START__, MTK_SMC_POOL_START);
 IMPORT_SYM(uintptr_t, __MTK_SMC_POOL_END_UNALIGNED__, MTK_SMC_POOL_END_UNALIGNED);

 static const struct smc_descriptor *smc_handler_pool;
 static short smc_id_descriptor_max;

 #if !MTK_SIP_KERNEL_BOOT_ENABLE
 /*
  * If there is no SMC request needs to be served in 2nd bootloader,
  * disable the service path inherently.
  */
 bool is_el1_2nd_bootloader(void)
 {
 	return false;
 }
 #endif

 static void print_smc_descriptor(const struct smc_descriptor pool[])
 {
 	const struct smc_descriptor *p_smc_desc;

 	INFO("print smc descriptor pool\n");
 	for (p_smc_desc = &pool[0];
 	     (char *)p_smc_desc < (char *)MTK_SMC_POOL_END_UNALIGNED;
 	     p_smc_desc++) {
 		INFO("descriptor name:%s\n", p_smc_desc->smc_name);
 		INFO("descriptor index:%d\n", *p_smc_desc->smc_descriptor_index);
 		INFO("smc id 32:0x%x, smc id 64:0x%x\n",
 		     p_smc_desc->smc_id_aarch32, p_smc_desc->smc_id_aarch64);
 	}
 }

 static int mtk_smc_handler_init(void)
 {
 	const struct smc_descriptor *iter;
 	short index_cnt;
 	int ret = 0;

 	smc_handler_pool = (const struct smc_descriptor *)MTK_SMC_POOL_START;
 	/* Designate descriptor index point to smc_handler_pool */
 	for (index_cnt = 0, iter = &smc_handler_pool[0];
 	     (char *)iter < (char *)MTK_SMC_POOL_END_UNALIGNED;
 	     iter++, index_cnt++) {
 		if (index_cnt < 0) {
 			SMC_HANDLER_DEBUG("smc handler pool index overflow!\n");
 			ret = -EPERM;
 			assert(0);
 			break;
 		}
 		*(iter->smc_descriptor_index) = index_cnt;
 	}
 	smc_id_descriptor_max = index_cnt;
 	print_smc_descriptor(smc_handler_pool);
 	return ret;
 }
 MTK_EARLY_PLAT_INIT(mtk_smc_handler_init);

 /* This function handles Mediatek defined SiP Calls from Bootloader */
 static uintptr_t mtk_smc_handler_bl33(uint32_t smc_id,
 				      u_register_t x1,
 				      u_register_t x2,
 				      u_register_t x3,
 				      u_register_t x4,
 				      void *cookie,
 				      void *handle,
 				      u_register_t flags)
 {
 	uintptr_t ret = MTK_SIP_E_SUCCESS;
 	struct smccc_res smc_ret = {0};

 	switch (smc_id) {
 		MTK_SIP_SMC_FROM_BL33_TABLE(SMC_ID_EXPAND_AS_SMC_OPERATION);
 	default:
 		INFO("BL33 SMC ID:0x%x not supported\n", smc_id);
 		ret = SMC_UNK;
 		break;
 	}
 	SMC_RET4(handle, ret, smc_ret.a1, smc_ret.a2, smc_ret.a3);
 }

 /* This function handles Mediatek defined SiP Calls from Kernel */
 static uintptr_t mtk_smc_handler_nsel1(uint32_t smc_id,
 				       u_register_t x1,
 				       u_register_t x2,
 				       u_register_t x3,
 				       u_register_t x4,
 				       void *cookie,
 				       void *handle,
 				       u_register_t flags)
 {
 	uintptr_t ret = MTK_SIP_E_SUCCESS;
 	struct smccc_res smc_ret = {0};

 	switch (smc_id) {
 		MTK_SIP_SMC_FROM_NS_EL1_TABLE(SMC_ID_EXPAND_AS_SMC_OPERATION);
 	default:
 		INFO("NSEL1 SMC ID:0x%x not supported\n", smc_id);
 		ret = SMC_UNK;
 		break;
 	}
 	SMC_RET4(handle, ret, smc_ret.a1, smc_ret.a2, smc_ret.a3);
 }

 static uintptr_t mtk_smc_handler(uint32_t smc_id,
 				 u_register_t x1,
 				 u_register_t x2,
 				 u_register_t x3,
 				 u_register_t x4,
 				 void *cookie,
 				 void *handle,
 				 u_register_t flags)
 {
 	uintptr_t ret = SMC_UNK;
 	uint32_t ns;
 	uint32_t smc_ori;
 	uint32_t smc_num;

 	/* Get SMC Originator bit 14.15 */
 	smc_ori = GET_SMC_ORI(smc_id);
 	/* Get SMC Number. Clean bit 14.15 */
 	smc_num = GET_SMC_ORI_NUM(smc_id);

 	/* Determine which security state this SMC originated from */
 	ns = is_caller_non_secure(flags);

 	if (ns && is_smc_forbidden(smc_ori)) {
 		ERROR("%s: Forbidden SMC call (0x%x)\n", __func__, smc_id);
 		SMC_RET1(handle, ret);
 	}

 	if (!ns) {
 		/* SiP SMC service secure world's call */
 		INFO("Secure SMC ID:0x%x not supported\n", smc_id);
 		SMC_RET1(handle, ret);
 	}
 	if (is_from_bl33(smc_ori)) {
 		/* SiP SMC service secure bootloader's call */
 		return mtk_smc_handler_bl33(smc_num, x1, x2, x3, x4,
 					    cookie, handle, flags);
 	} else if (is_from_nsel1(smc_ori)) {
 		/* SiP SMC service kernel's call */
 		return mtk_smc_handler_nsel1(smc_num, x1, x2, x3, x4,
 					     cookie, handle, flags);
 	}
 	INFO("SMC ID:0x%x not supported\n", smc_id);
 	SMC_RET1(handle, ret);
 }

 /* Define a runtime service descriptor for fast SMC calls */
 DECLARE_RT_SVC(
 	mtk_smc_handler,
 	OEN_SIP_START,
 	OEN_SIP_END,
 	SMC_TYPE_FAST,
 	NULL,
 	mtk_smc_handler
 );
	/*
	* Copyright (c) 2022, MediaTek Inc. All rights reserved.
	*
	* SPDX-License-Identifier: BSD-3-Clause
	*/

	#include <assert.h>
	#include <errno.h>
	#if MTK_SIP_KERNEL_BOOT_ENABLE
	#include <cold_boot.h>
	#endif
	#include <common/debug.h>
	#include <common/runtime_svc.h>
	#include <lib/mtk_init/mtk_init.h>
	#include <mtk_sip_svc.h>

	#define SMC_HANDLER_DEBUG(...) VERBOSE(__VA_ARGS__)
	#define SMC_HANDLER_DEBUG_NOT_IMP_MSG "%s[0x%x] smc handler not implemented\n"
	#define SMC_HANDLER_DEBUG_START_MSG "%s[0x%x] smc handler start, smc desc. index:%d\n"
	#define SMC_HANDLER_DEBUG_END_MSG "%s[0x%x] smc handler end\n"

	/*
	* These macros below are used to identify SIP calls from Kernel,
	* Hypervisor, or 2ndBootloader
	*/
	#define SIP_FID_ORI_MASK (0xc000)
	#define SIP_FID_ORI_SHIFT (14)
	#define SIP_FID_KERNEL (0x0)
	#define SIP_FID_KERNEL_VIA_GZ (0x1)
	#define SIP_FID_GZ (0x2)

	#define GET_SMC_ORI(_fid) (((_fid) & SIP_FID_ORI_MASK) >> SIP_FID_ORI_SHIFT)
	#define GET_SMC_ORI_NUM(_fid) ((_fid) & ~(SIP_FID_ORI_MASK))

	#define is_from_nsel2(_ori) (_ori == SIP_FID_GZ)
	#define is_from_bl33(_ori) \
	((_ori != SIP_FID_GZ) && (is_el1_2nd_bootloader() == 1))
	#define is_from_nsel1(_ori) \
	(((_ori == SIP_FID_KERNEL) \|\| \
	(_ori == SIP_FID_KERNEL_VIA_GZ)) && \
	(is_el1_2nd_bootloader() == 0))

	#define is_smc_forbidden(_ori) (_ori == SIP_FID_KERNEL_VIA_GZ)

	#define MASK_32_BIT (0xffffffffU)
	#define SMC_ID_EXPAND_AS_SMC_OPERATION(_smc_id, _smc_num) \
	case _smc_id##_AARCH32: \
	{ \
	x1 = x1 & MASK_32_BIT; \
	x2 = x2 & MASK_32_BIT; \
	x3 = x3 & MASK_32_BIT; \
	x4 = x4 & MASK_32_BIT; \
	} \
	/* fallthrough */ \
	case _smc_id##_AARCH64: \
	{ \
	if (_smc_id##_descriptor_index < 0) { \
	SMC_HANDLER_DEBUG(SMC_HANDLER_DEBUG_NOT_IMP_MSG, #_smc_id, smc_id); \
	break; \
	} \
	if (_smc_id##_descriptor_index >= smc_id_descriptor_max) { \
	SMC_HANDLER_DEBUG("smc descriptor index[%d] exceed max[%d]\n", \
	_smc_id##_descriptor_index, smc_id_descriptor_max); \
	break; \
	} \
	SMC_HANDLER_DEBUG(SMC_HANDLER_DEBUG_START_MSG, #_smc_id, smc_id, \
	_smc_id##_descriptor_index); \
	ret = smc_handler_pool[_smc_id##_descriptor_index].smc_handler(x1,\
	x2, x3, x4, handle, &smc_ret); \
	SMC_HANDLER_DEBUG(SMC_HANDLER_DEBUG_END_MSG, #_smc_id, smc_id); \
	break; \
	}

	#define SMC_ID_EXPAND_AS_DESCRIPTOR_INDEX(_smc_id, _smc_num) \
	short _smc_id##_descriptor_index __section("mtk_plat_ro") = -1;

	MTK_SIP_SMC_FROM_BL33_TABLE(SMC_ID_EXPAND_AS_DESCRIPTOR_INDEX);
	MTK_SIP_SMC_FROM_NS_EL1_TABLE(SMC_ID_EXPAND_AS_DESCRIPTOR_INDEX);

	IMPORT_SYM(uintptr_t, __MTK_SMC_POOL_START__, MTK_SMC_POOL_START);
	IMPORT_SYM(uintptr_t, __MTK_SMC_POOL_END_UNALIGNED__, MTK_SMC_POOL_END_UNALIGNED);

	static const struct smc_descriptor *smc_handler_pool;
	static short smc_id_descriptor_max;

	#if !MTK_SIP_KERNEL_BOOT_ENABLE
	/*
	* If there is no SMC request needs to be served in 2nd bootloader,
	* disable the service path inherently.
	*/
	bool is_el1_2nd_bootloader(void)
	{
	return false;
	}
	#endif

	static void print_smc_descriptor(const struct smc_descriptor pool[])
	{
	const struct smc_descriptor *p_smc_desc;

	INFO("print smc descriptor pool\n");
	for (p_smc_desc = &pool[0];
	(char )p_smc_desc < (char )MTK_SMC_POOL_END_UNALIGNED;
	p_smc_desc++) {
	INFO("descriptor name:%s\n", p_smc_desc->smc_name);
	INFO("descriptor index:%d\n", *p_smc_desc->smc_descriptor_index);
	INFO("smc id 32:0x%x, smc id 64:0x%x\n",
	p_smc_desc->smc_id_aarch32, p_smc_desc->smc_id_aarch64);
	}
	}

	static int mtk_smc_handler_init(void)
	{
	const struct smc_descriptor *iter;
	short index_cnt;
	int ret = 0;

	smc_handler_pool = (const struct smc_descriptor *)MTK_SMC_POOL_START;
	/* Designate descriptor index point to smc_handler_pool */
	for (index_cnt = 0, iter = &smc_handler_pool[0];
	(char )iter < (char )MTK_SMC_POOL_END_UNALIGNED;
	iter++, index_cnt++) {
	if (index_cnt < 0) {
	SMC_HANDLER_DEBUG("smc handler pool index overflow!\n");
	ret = -EPERM;
	assert(0);
	break;
	}
	*(iter->smc_descriptor_index) = index_cnt;
	}
	smc_id_descriptor_max = index_cnt;
	print_smc_descriptor(smc_handler_pool);
	return ret;
	}
	MTK_EARLY_PLAT_INIT(mtk_smc_handler_init);

	/* This function handles Mediatek defined SiP Calls from Bootloader */
	static uintptr_t mtk_smc_handler_bl33(uint32_t smc_id,
	u_register_t x1,
	u_register_t x2,
	u_register_t x3,
	u_register_t x4,
	void *cookie,
	void *handle,
	u_register_t flags)
	{
	uintptr_t ret = MTK_SIP_E_SUCCESS;
	struct smccc_res smc_ret = {0};

	switch (smc_id) {
	MTK_SIP_SMC_FROM_BL33_TABLE(SMC_ID_EXPAND_AS_SMC_OPERATION);
	default:
	INFO("BL33 SMC ID:0x%x not supported\n", smc_id);
	ret = SMC_UNK;
	break;
	}
	SMC_RET4(handle, ret, smc_ret.a1, smc_ret.a2, smc_ret.a3);
	}

	/* This function handles Mediatek defined SiP Calls from Kernel */
	static uintptr_t mtk_smc_handler_nsel1(uint32_t smc_id,
	u_register_t x1,
	u_register_t x2,
	u_register_t x3,
	u_register_t x4,
	void *cookie,
	void *handle,
	u_register_t flags)
	{
	uintptr_t ret = MTK_SIP_E_SUCCESS;
	struct smccc_res smc_ret = {0};

	switch (smc_id) {
	MTK_SIP_SMC_FROM_NS_EL1_TABLE(SMC_ID_EXPAND_AS_SMC_OPERATION);
	default:
	INFO("NSEL1 SMC ID:0x%x not supported\n", smc_id);
	ret = SMC_UNK;
	break;
	}
	SMC_RET4(handle, ret, smc_ret.a1, smc_ret.a2, smc_ret.a3);
	}

	static uintptr_t mtk_smc_handler(uint32_t smc_id,
	u_register_t x1,
	u_register_t x2,
	u_register_t x3,
	u_register_t x4,
	void *cookie,
	void *handle,
	u_register_t flags)
	{
	uintptr_t ret = SMC_UNK;
	uint32_t ns;
	uint32_t smc_ori;
	uint32_t smc_num;

	/* Get SMC Originator bit 14.15 */
	smc_ori = GET_SMC_ORI(smc_id);
	/* Get SMC Number. Clean bit 14.15 */
	smc_num = GET_SMC_ORI_NUM(smc_id);

	/* Determine which security state this SMC originated from */
	ns = is_caller_non_secure(flags);

	if (ns && is_smc_forbidden(smc_ori)) {
	ERROR("%s: Forbidden SMC call (0x%x)\n", __func__, smc_id);
	SMC_RET1(handle, ret);
	}

	if (!ns) {
	/* SiP SMC service secure world's call */
	INFO("Secure SMC ID:0x%x not supported\n", smc_id);
	SMC_RET1(handle, ret);
	}
	if (is_from_bl33(smc_ori)) {
	/* SiP SMC service secure bootloader's call */
	return mtk_smc_handler_bl33(smc_num, x1, x2, x3, x4,
	cookie, handle, flags);
	} else if (is_from_nsel1(smc_ori)) {
	/* SiP SMC service kernel's call */
	return mtk_smc_handler_nsel1(smc_num, x1, x2, x3, x4,
	cookie, handle, flags);
	}
	INFO("SMC ID:0x%x not supported\n", smc_id);
	SMC_RET1(handle, ret);
	}

	/* Define a runtime service descriptor for fast SMC calls */
	DECLARE_RT_SVC(
	mtk_smc_handler,
	OEN_SIP_START,
	OEN_SIP_END,
	SMC_TYPE_FAST,
	NULL,
	mtk_smc_handler
	);