plat/arm/board/juno/aarch64/juno_helpers.S - filogic/atf - Gitiles

 /*
  * Copyright (c) 2013-2017, ARM Limited and Contributors. All rights reserved.
  *
  * SPDX-License-Identifier: BSD-3-Clause
  */

 #include <arch.h>
 #include <asm_macros.S>
 #include <bl_common.h>
 #include <cortex_a53.h>
 #include <cortex_a57.h>
 #include <cortex_a72.h>
 #include <cpu_macros.S>
 #include <css_def.h>
 #include <v2m_def.h>
 #include "../juno_def.h"


 	.globl	plat_reset_handler
 	.globl	plat_arm_calc_core_pos
 #if JUNO_AARCH32_EL3_RUNTIME
 	.globl	plat_get_my_entrypoint
 	.globl	juno_reset_to_aarch32_state
 #endif

 #define JUNO_REVISION(rev)	REV_JUNO_R##rev
 #define JUNO_HANDLER(rev)	plat_reset_handler_juno_r##rev
 #define JUMP_TO_HANDLER_IF_JUNO_R(revision)	\
 	jump_to_handler JUNO_REVISION(revision), JUNO_HANDLER(revision)

 	/* --------------------------------------------------------------------
 	 * Helper macro to jump to the given handler if the board revision
 	 * matches.
 	 * Expects the Juno board revision in x0.
 	 * --------------------------------------------------------------------
 	 */
 	.macro jump_to_handler _revision, _handler
 	cmp	x0, #\_revision
 	b.eq	\_handler
 	.endm

 	/* --------------------------------------------------------------------
 	 * Helper macro that reads the part number of the current CPU and jumps
 	 * to the given label if it matches the CPU MIDR provided.
 	 *
 	 * Clobbers x0.
 	 * --------------------------------------------------------------------
 	 */
 	.macro  jump_if_cpu_midr _cpu_midr, _label
 	mrs	x0, midr_el1
 	ubfx	x0, x0, MIDR_PN_SHIFT, #12
 	cmp     w0, #((\_cpu_midr >> MIDR_PN_SHIFT) & MIDR_PN_MASK)
 	b.eq	\_label
 	.endm

 	/* --------------------------------------------------------------------
 	 * Platform reset handler for Juno R0.
 	 *
 	 * Juno R0 has the following topology:
 	 * - Quad core Cortex-A53 processor cluster;
 	 * - Dual core Cortex-A57 processor cluster.
 	 *
 	 * This handler does the following:
 	 * - Implement workaround for defect id 831273 by enabling an event
 	 *   stream every 65536 cycles.
 	 * - Set the L2 Data RAM latency to 2 (i.e. 3 cycles) for Cortex-A57
 	 * - Set the L2 Tag RAM latency to 2 (i.e. 3 cycles) for Cortex-A57
 	 * --------------------------------------------------------------------
 	 */
 func JUNO_HANDLER(0)
 	/* --------------------------------------------------------------------
 	 * Enable the event stream every 65536 cycles
 	 * --------------------------------------------------------------------
 	 */
 	mov     x0, #(0xf << EVNTI_SHIFT)
 	orr     x0, x0, #EVNTEN_BIT
 	msr     CNTKCTL_EL1, x0

 	/* --------------------------------------------------------------------
 	 * Nothing else to do on Cortex-A53.
 	 * --------------------------------------------------------------------
 	 */
 	jump_if_cpu_midr CORTEX_A53_MIDR, 1f

 	/* --------------------------------------------------------------------
 	 * Cortex-A57 specific settings
 	 * --------------------------------------------------------------------
 	 */
 	mov	x0, #((CORTEX_A57_L2_DATA_RAM_LATENCY_3_CYCLES << CORTEX_A57_L2CTLR_DATA_RAM_LATENCY_SHIFT) |	\
 		      (CORTEX_A57_L2_TAG_RAM_LATENCY_3_CYCLES << CORTEX_A57_L2CTLR_TAG_RAM_LATENCY_SHIFT))
 	msr     CORTEX_A57_L2CTLR_EL1, x0
 1:
 	isb
 	ret
 endfunc JUNO_HANDLER(0)

 	/* --------------------------------------------------------------------
 	 * Platform reset handler for Juno R1.
 	 *
 	 * Juno R1 has the following topology:
 	 * - Quad core Cortex-A53 processor cluster;
 	 * - Dual core Cortex-A57 processor cluster.
 	 *
 	 * This handler does the following:
 	 * - Set the L2 Data RAM latency to 2 (i.e. 3 cycles) for Cortex-A57
 	 *
 	 * Note that:
 	 * - The default value for the L2 Tag RAM latency for Cortex-A57 is
 	 *   suitable.
 	 * - Defect #831273 doesn't affect Juno R1.
 	 * --------------------------------------------------------------------
 	 */
 func JUNO_HANDLER(1)
 	/* --------------------------------------------------------------------
 	 * Nothing to do on Cortex-A53.
 	 * --------------------------------------------------------------------
 	 */
 	jump_if_cpu_midr CORTEX_A57_MIDR, A57
 	ret

 A57:
 	/* --------------------------------------------------------------------
 	 * Cortex-A57 specific settings
 	 * --------------------------------------------------------------------
 	 */
 	mov	x0, #(CORTEX_A57_L2_DATA_RAM_LATENCY_3_CYCLES << CORTEX_A57_L2CTLR_DATA_RAM_LATENCY_SHIFT)
 	msr     CORTEX_A57_L2CTLR_EL1, x0
 	isb
 	ret
 endfunc JUNO_HANDLER(1)

 	/* --------------------------------------------------------------------
 	 * Platform reset handler for Juno R2.
 	 *
 	 * Juno R2 has the following topology:
 	 * - Quad core Cortex-A53 processor cluster;
 	 * - Dual core Cortex-A72 processor cluster.
 	 *
 	 * This handler does the following:
 	 * - Set the L2 Data RAM latency to 2 (i.e. 3 cycles) for Cortex-A72
 	 * - Set the L2 Tag RAM latency to 1 (i.e. 2 cycles) for Cortex-A72
 	 *
 	 * Note that:
 	 * - Defect #831273 doesn't affect Juno R2.
 	 * --------------------------------------------------------------------
 	 */
 func JUNO_HANDLER(2)
 	/* --------------------------------------------------------------------
 	 * Nothing to do on Cortex-A53.
 	 * --------------------------------------------------------------------
 	 */
 	jump_if_cpu_midr CORTEX_A72_MIDR, A72
 	ret

 A72:
 	/* --------------------------------------------------------------------
 	 * Cortex-A72 specific settings
 	 * --------------------------------------------------------------------
 	 */
 	mov	x0, #((CORTEX_A72_L2_DATA_RAM_LATENCY_3_CYCLES << CORTEX_A72_L2CTLR_DATA_RAM_LATENCY_SHIFT) |	\
 		      (CORTEX_A72_L2_TAG_RAM_LATENCY_2_CYCLES << CORTEX_A72_L2CTLR_TAG_RAM_LATENCY_SHIFT))
 	msr     CORTEX_A57_L2CTLR_EL1, x0
 	isb
 	ret
 endfunc JUNO_HANDLER(2)

 	/* --------------------------------------------------------------------
 	 * void plat_reset_handler(void);
 	 *
 	 * Determine the Juno board revision and call the appropriate reset
 	 * handler.
 	 * --------------------------------------------------------------------
 	 */
 func plat_reset_handler
 	/* Read the V2M SYS_ID register */
 	mov_imm	x0, (V2M_SYSREGS_BASE + V2M_SYS_ID)
 	ldr	w1, [x0]
 	/* Extract board revision from the SYS_ID */
 	ubfx	x0, x1, #V2M_SYS_ID_REV_SHIFT, #4

 	JUMP_TO_HANDLER_IF_JUNO_R(0)
 	JUMP_TO_HANDLER_IF_JUNO_R(1)
 	JUMP_TO_HANDLER_IF_JUNO_R(2)

 	/* Board revision is not supported */
 	no_ret	plat_panic_handler

 endfunc plat_reset_handler

 	/* -----------------------------------------------------
 	 *  void juno_do_reset_to_aarch32_state(void);
 	 *
 	 *  Request warm reset to AArch32 mode.
 	 * -----------------------------------------------------
 	 */
 func juno_do_reset_to_aarch32_state
 	mov	x0, #RMR_EL3_RR_BIT
 	dsb	sy
 	msr	rmr_el3, x0
 	isb
 	wfi
 	b	plat_panic_handler
 endfunc juno_do_reset_to_aarch32_state

 	/* -----------------------------------------------------
 	 *  unsigned int plat_arm_calc_core_pos(u_register_t mpidr)
 	 *  Helper function to calculate the core position.
 	 * -----------------------------------------------------
 	 */
 func plat_arm_calc_core_pos
 	b	css_calc_core_pos_swap_cluster
 endfunc plat_arm_calc_core_pos

 #if JUNO_AARCH32_EL3_RUNTIME
 	/* ---------------------------------------------------------------------
 	 * uintptr_t plat_get_my_entrypoint (void);
 	 *
 	 * Main job of this routine is to distinguish between a cold and a warm
 	 * boot. On JUNO platform, this distinction is based on the contents of
 	 * the Trusted Mailbox. It is initialised to zero by the SCP before the
 	 * AP cores are released from reset. Therefore, a zero mailbox means
 	 * it's a cold reset. If it is a warm boot then a request to reset to
 	 * AArch32 state is issued. This is the only way to reset to AArch32
 	 * in EL3 on Juno. A trampoline located at the high vector address
 	 * has already been prepared by BL1.
 	 *
 	 * This functions returns the contents of the mailbox, i.e.:
 	 *  - 0 for a cold boot;
 	 *  - request warm reset in AArch32 state for warm boot case;
 	 * ---------------------------------------------------------------------
 	 */
 func plat_get_my_entrypoint
 	mov_imm	x0, PLAT_ARM_TRUSTED_MAILBOX_BASE
 	ldr	x0, [x0]
 	cbz	x0, return
 	b	juno_do_reset_to_aarch32_state
 return:
 	ret
 endfunc plat_get_my_entrypoint

 /*
  * Emit a "movw r0, #imm16" which moves the lower
  * 16 bits of `_val` into r0.
  */
 .macro emit_movw _reg_d, _val
 	mov_imm	\_reg_d, (0xe3000000 | \
 			((\_val & 0xfff) | \
 			((\_val & 0xf000) << 4)))
 .endm

 /*
  * Emit a "movt r0, #imm16" which moves the upper
  * 16 bits of `_val` into r0.
  */
 .macro emit_movt _reg_d, _val
 	mov_imm	\_reg_d, (0xe3400000 | \
 			(((\_val & 0x0fff0000) >> 16) | \
 			((\_val & 0xf0000000) >> 12)))
 .endm

 /*
  * This function writes the trampoline code at HI-VEC (0xFFFF0000)
  * address which loads r0 with the entrypoint address for
  * BL32 (a.k.a SP_MIN) when EL3 is in AArch32 mode. A warm reset
  * to AArch32 mode is then requested by writing into RMR_EL3.
  */
 func juno_reset_to_aarch32_state
 	/*
 	 * Invalidate all caches before the warm reset to AArch32 state.
 	 * This is required on the Juno AArch32 boot flow because the L2
 	 * unified cache may contain code and data from when the processor
 	 * was still executing in AArch64 state.  This code only runs on
 	 * the primary core, all other cores are powered down.
 	 */
 	mov	x0, #DCISW
 	bl	dcsw_op_all

 	emit_movw	w0, BL32_BASE
 	emit_movt	w1, BL32_BASE
 	/* opcode "bx r0" to branch using r0 in AArch32 mode */
 	mov_imm	w2, 0xe12fff10

 	/* Write the above opcodes at HI-VECTOR location */
 	mov_imm	x3, HI_VECTOR_BASE
 	str	w0, [x3], #4
 	str	w1, [x3], #4
 	str	w2, [x3]

 	b	juno_do_reset_to_aarch32_state
 endfunc juno_reset_to_aarch32_state

 #endif /* JUNO_AARCH32_EL3_RUNTIME */
	/*
	* Copyright (c) 2013-2017, ARM Limited and Contributors. All rights reserved.
	*
	* SPDX-License-Identifier: BSD-3-Clause
	*/

	#include <arch.h>
	#include <asm_macros.S>
	#include <bl_common.h>
	#include <cortex_a53.h>
	#include <cortex_a57.h>
	#include <cortex_a72.h>
	#include <cpu_macros.S>
	#include <css_def.h>
	#include <v2m_def.h>
	#include "../juno_def.h"


	.globl plat_reset_handler
	.globl plat_arm_calc_core_pos
	#if JUNO_AARCH32_EL3_RUNTIME
	.globl plat_get_my_entrypoint
	.globl juno_reset_to_aarch32_state
	#endif

	#define JUNO_REVISION(rev) REV_JUNO_R##rev
	#define JUNO_HANDLER(rev) plat_reset_handler_juno_r##rev
	#define JUMP_TO_HANDLER_IF_JUNO_R(revision) \
	jump_to_handler JUNO_REVISION(revision), JUNO_HANDLER(revision)

	/* --------------------------------------------------------------------
	* Helper macro to jump to the given handler if the board revision
	* matches.
	* Expects the Juno board revision in x0.
	* --------------------------------------------------------------------
	*/
	.macro jump_to_handler _revision, _handler
	cmp x0, #\_revision
	b.eq \_handler
	.endm

	/* --------------------------------------------------------------------
	* Helper macro that reads the part number of the current CPU and jumps
	* to the given label if it matches the CPU MIDR provided.
	*
	* Clobbers x0.
	* --------------------------------------------------------------------
	*/
	.macro jump_if_cpu_midr _cpu_midr, _label
	mrs x0, midr_el1
	ubfx x0, x0, MIDR_PN_SHIFT, #12
	cmp w0, #((\_cpu_midr >> MIDR_PN_SHIFT) & MIDR_PN_MASK)
	b.eq \_label
	.endm

	/* --------------------------------------------------------------------
	* Platform reset handler for Juno R0.
	*
	* Juno R0 has the following topology:
	* - Quad core Cortex-A53 processor cluster;
	* - Dual core Cortex-A57 processor cluster.
	*
	* This handler does the following:
	* - Implement workaround for defect id 831273 by enabling an event
	* stream every 65536 cycles.
	* - Set the L2 Data RAM latency to 2 (i.e. 3 cycles) for Cortex-A57
	* - Set the L2 Tag RAM latency to 2 (i.e. 3 cycles) for Cortex-A57
	* --------------------------------------------------------------------
	*/
	func JUNO_HANDLER(0)
	/* --------------------------------------------------------------------
	* Enable the event stream every 65536 cycles
	* --------------------------------------------------------------------
	*/
	mov x0, #(0xf << EVNTI_SHIFT)
	orr x0, x0, #EVNTEN_BIT
	msr CNTKCTL_EL1, x0

	/* --------------------------------------------------------------------
	* Nothing else to do on Cortex-A53.
	* --------------------------------------------------------------------
	*/
	jump_if_cpu_midr CORTEX_A53_MIDR, 1f

	/* --------------------------------------------------------------------
	* Cortex-A57 specific settings
	* --------------------------------------------------------------------
	*/
	mov x0, #((CORTEX_A57_L2_DATA_RAM_LATENCY_3_CYCLES << CORTEX_A57_L2CTLR_DATA_RAM_LATENCY_SHIFT) \| \
	(CORTEX_A57_L2_TAG_RAM_LATENCY_3_CYCLES << CORTEX_A57_L2CTLR_TAG_RAM_LATENCY_SHIFT))
	msr CORTEX_A57_L2CTLR_EL1, x0
	1:
	isb
	ret
	endfunc JUNO_HANDLER(0)

	/* --------------------------------------------------------------------
	* Platform reset handler for Juno R1.
	*
	* Juno R1 has the following topology:
	* - Quad core Cortex-A53 processor cluster;
	* - Dual core Cortex-A57 processor cluster.
	*
	* This handler does the following:
	* - Set the L2 Data RAM latency to 2 (i.e. 3 cycles) for Cortex-A57
	*
	* Note that:
	* - The default value for the L2 Tag RAM latency for Cortex-A57 is
	* suitable.
	* - Defect #831273 doesn't affect Juno R1.
	* --------------------------------------------------------------------
	*/
	func JUNO_HANDLER(1)
	/* --------------------------------------------------------------------
	* Nothing to do on Cortex-A53.
	* --------------------------------------------------------------------
	*/
	jump_if_cpu_midr CORTEX_A57_MIDR, A57
	ret

	A57:
	/* --------------------------------------------------------------------
	* Cortex-A57 specific settings
	* --------------------------------------------------------------------
	*/
	mov x0, #(CORTEX_A57_L2_DATA_RAM_LATENCY_3_CYCLES << CORTEX_A57_L2CTLR_DATA_RAM_LATENCY_SHIFT)
	msr CORTEX_A57_L2CTLR_EL1, x0
	isb
	ret
	endfunc JUNO_HANDLER(1)

	/* --------------------------------------------------------------------
	* Platform reset handler for Juno R2.
	*
	* Juno R2 has the following topology:
	* - Quad core Cortex-A53 processor cluster;
	* - Dual core Cortex-A72 processor cluster.
	*
	* This handler does the following:
	* - Set the L2 Data RAM latency to 2 (i.e. 3 cycles) for Cortex-A72
	* - Set the L2 Tag RAM latency to 1 (i.e. 2 cycles) for Cortex-A72
	*
	* Note that:
	* - Defect #831273 doesn't affect Juno R2.
	* --------------------------------------------------------------------
	*/
	func JUNO_HANDLER(2)
	/* --------------------------------------------------------------------
	* Nothing to do on Cortex-A53.
	* --------------------------------------------------------------------
	*/
	jump_if_cpu_midr CORTEX_A72_MIDR, A72
	ret

	A72:
	/* --------------------------------------------------------------------
	* Cortex-A72 specific settings
	* --------------------------------------------------------------------
	*/
	mov x0, #((CORTEX_A72_L2_DATA_RAM_LATENCY_3_CYCLES << CORTEX_A72_L2CTLR_DATA_RAM_LATENCY_SHIFT) \| \
	(CORTEX_A72_L2_TAG_RAM_LATENCY_2_CYCLES << CORTEX_A72_L2CTLR_TAG_RAM_LATENCY_SHIFT))
	msr CORTEX_A57_L2CTLR_EL1, x0
	isb
	ret
	endfunc JUNO_HANDLER(2)

	/* --------------------------------------------------------------------
	* void plat_reset_handler(void);
	*
	* Determine the Juno board revision and call the appropriate reset
	* handler.
	* --------------------------------------------------------------------
	*/
	func plat_reset_handler
	/* Read the V2M SYS_ID register */
	mov_imm x0, (V2M_SYSREGS_BASE + V2M_SYS_ID)
	ldr w1, [x0]
	/* Extract board revision from the SYS_ID */
	ubfx x0, x1, #V2M_SYS_ID_REV_SHIFT, #4

	JUMP_TO_HANDLER_IF_JUNO_R(0)
	JUMP_TO_HANDLER_IF_JUNO_R(1)
	JUMP_TO_HANDLER_IF_JUNO_R(2)

	/* Board revision is not supported */
	no_ret plat_panic_handler

	endfunc plat_reset_handler

	/* -----------------------------------------------------
	* void juno_do_reset_to_aarch32_state(void);
	*
	* Request warm reset to AArch32 mode.
	* -----------------------------------------------------
	*/
	func juno_do_reset_to_aarch32_state
	mov x0, #RMR_EL3_RR_BIT
	dsb sy
	msr rmr_el3, x0
	isb
	wfi
	b plat_panic_handler
	endfunc juno_do_reset_to_aarch32_state

	/* -----------------------------------------------------
	* unsigned int plat_arm_calc_core_pos(u_register_t mpidr)
	* Helper function to calculate the core position.
	* -----------------------------------------------------
	*/
	func plat_arm_calc_core_pos
	b css_calc_core_pos_swap_cluster
	endfunc plat_arm_calc_core_pos

	#if JUNO_AARCH32_EL3_RUNTIME
	/* ---------------------------------------------------------------------
	* uintptr_t plat_get_my_entrypoint (void);
	*
	* Main job of this routine is to distinguish between a cold and a warm
	* boot. On JUNO platform, this distinction is based on the contents of
	* the Trusted Mailbox. It is initialised to zero by the SCP before the
	* AP cores are released from reset. Therefore, a zero mailbox means
	* it's a cold reset. If it is a warm boot then a request to reset to
	* AArch32 state is issued. This is the only way to reset to AArch32
	* in EL3 on Juno. A trampoline located at the high vector address
	* has already been prepared by BL1.
	*
	* This functions returns the contents of the mailbox, i.e.:
	* - 0 for a cold boot;
	* - request warm reset in AArch32 state for warm boot case;
	* ---------------------------------------------------------------------
	*/
	func plat_get_my_entrypoint
	mov_imm x0, PLAT_ARM_TRUSTED_MAILBOX_BASE
	ldr x0, [x0]
	cbz x0, return
	b juno_do_reset_to_aarch32_state
	return:
	ret
	endfunc plat_get_my_entrypoint

	/*
	* Emit a "movw r0, #imm16" which moves the lower
	* 16 bits of `_val` into r0.
	*/
	.macro emit_movw _reg_d, _val
	mov_imm \_reg_d, (0xe3000000 \| \
	((\_val & 0xfff) \| \
	((\_val & 0xf000) << 4)))
	.endm

	/*
	* Emit a "movt r0, #imm16" which moves the upper
	* 16 bits of `_val` into r0.
	*/
	.macro emit_movt _reg_d, _val
	mov_imm \_reg_d, (0xe3400000 \| \
	(((\_val & 0x0fff0000) >> 16) \| \
	((\_val & 0xf0000000) >> 12)))
	.endm

	/*
	* This function writes the trampoline code at HI-VEC (0xFFFF0000)
	* address which loads r0 with the entrypoint address for
	* BL32 (a.k.a SP_MIN) when EL3 is in AArch32 mode. A warm reset
	* to AArch32 mode is then requested by writing into RMR_EL3.
	*/
	func juno_reset_to_aarch32_state
	/*
	* Invalidate all caches before the warm reset to AArch32 state.
	* This is required on the Juno AArch32 boot flow because the L2
	* unified cache may contain code and data from when the processor
	* was still executing in AArch64 state. This code only runs on
	* the primary core, all other cores are powered down.
	*/
	mov x0, #DCISW
	bl dcsw_op_all

	emit_movw w0, BL32_BASE
	emit_movt w1, BL32_BASE
	/* opcode "bx r0" to branch using r0 in AArch32 mode */
	mov_imm w2, 0xe12fff10

	/* Write the above opcodes at HI-VECTOR location */
	mov_imm x3, HI_VECTOR_BASE
	str w0, [x3], #4
	str w1, [x3], #4
	str w2, [x3]

	b juno_do_reset_to_aarch32_state
	endfunc juno_reset_to_aarch32_state

	#endif /* JUNO_AARCH32_EL3_RUNTIME */