/* * Copyright (c) 2008, Google Inc. * All rights reserved. * Copyright (c) 2009-2010, Code Aurora Forum. All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * * Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * * 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. * * Neither the name of Google, Inc. nor the names of its contributors * may be used to endorse or promote products derived from this * software without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS * "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 DISCLAIMED. IN NO EVENT SHALL THE * COPYRIGHT OWNER OR CONTRIBUTORS 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. */ /* TODO: * - style cleanup * - do we need to do *all* of this at boot? */ .text .code 32 #include /* ; LVT Ring Osc counter ; used to determine sense amp settings ; Clobbers registers r0, r4, r5, r6, r7, r9, r10, r11 */ .equ CLK_CTL_BASE, 0xA8600000 .equ A_GLBL_CLK_ENA, 0x0000 .equ A_PRPH_WEB_NS_REG,0x0080 .equ A_MSM_CLK_RINGOSC,0x00D0 .equ A_TCXO_CNT, 0x00D4 .equ A_TCXO_CNT_DONE, 0x00D8 .equ A_RINGOSC_CNT, 0x00DC .equ A_MISC_CLK_CTL, 0x0108 .equ CLK_TEST, 0xA8600114 .equ SPSS_CSR_BASE, 0xAC100000 .equ A_SCRINGOSC, 0x0510 //;; Number of TCXO cycles to count ring oscillations .equ TCXO_CNT_VAL, 0x100 //; Halcyon addresses .equ TCSR_CONF_FUSE_1, 0xAB600060 //; TCSR_CONF_FUSE_1 register .equ TCSR_CONF_FUSE_4, 0xAB60006C //; TCSR_CONF_FUSE_4 register //; SCORPION_L1_ACC (1:0) Fuses bit location .equ L1_ACC_BIT_0, 12 //;12th bit of TCSR_CONF_FUSE_4 .equ L1_ACC_BIT_1, 13 //;13th bit of TCSR_CONF_FUSE_4 //; SCORPION_L2_ACC (2:0) Fuses bit location .equ L2_ACC_BIT_0, 25 //;25th bit of TCSR_CONF_FUSE_1 .equ L2_ACC_BIT_1, 10 //;10th bit of TCSR_CONF_FUSE_4 .equ L2_ACC_BIT_2, 11 //;11th bit of TCSR_CONF_FUSE_4 //; CP15: PVR2F0 values according to SCORPION_L1_ACC (1:0) .equ PVR2F0_00, 0x00000000 .equ PVR2F0_01, 0x04000000 .equ PVR2F0_10, 0x08000000 .equ PVR2F0_11, 0x0C000000 //; CP15: PVR2F1 values according to SCORPION_L1_ACC (1:0) .equ PVR2F1_00, 0x00000008 .equ PVR2F1_01, 0x00000008 .equ PVR2F1_10, 0x00000208 .equ PVR2F1_11, 0x00000208 //; CP15: PVR0F2 values according to SCORPION_L1_ACC (1:0) .equ PVR0F2_00, 0x00000000 .equ PVR0F2_01, 0x00000000 .equ PVR0F2_10, 0x00000200 .equ PVR0F2_11, 0x00000200 //; CP15: PVR0F0 values according to SCORPION_L1_ACC (1:0) .equ PVR0F0_00, 0x7F000000 .equ PVR0F0_01, 0x7F000400 .equ PVR0F0_10, 0x7F000000 .equ PVR0F0_11, 0x7F000400 //; CP15: L2VR3F1 values according to SCORPION_L2_ACC (2:0) .equ L2VR3F1_000, 0x00FFFF60 .equ L2VR3F1_001, 0x00FFFF40 .equ L2VR3F1_010, 0x00FFFC60 .equ L2VR3F1_011, 0x00FFFC40 .equ L2VR3F1_100, 0x00FCFF60 .equ L2VR3F1_101, 0x00FCFF40 .equ L2VR3F1_110, 0x00FCFC60 .equ L2VR3F1_111, 0x00FCFC40 .globl SET_SA SET_SA: //;-------------------------------------------------------------------- //; Fuse bits used to determine sense amp settings //;-------------------------------------------------------------------- //; Reading L1_ACC LDR r4, = 0x0 //; Read L1_ACC_BIT_0 LDR r1, =TCSR_CONF_FUSE_4 LDR r2, =L1_ACC_BIT_0 LDR r3, [r1] MOV r3, r3, LSR r2 AND r3, r3, #1 ORR r4, r3, r4 //; Read L1_ACC_BIT_1 LDR r1, =TCSR_CONF_FUSE_4 LDR r2, =L1_ACC_BIT_1 LDR r3, [r1] MOV r3, r3, LSR r2 AND r3, r3, #1 MOV r3, r3, LSL #1 ORR r4, r3, r4 l1_ck_0: //; if L1_[1:0] == 00 LDR r5, = 0x0 CMP r4, r5 BNE l1_ck_1 LDR r0, =PVR0F0_00 LDR r1, =PVR0F2_00 LDR r2, =PVR2F0_00 LDR r3, =PVR2F1_00 B WRITE_L1_SA_SETTINGS l1_ck_1: //; if L1_[1:0] == 01 LDR r1, = 0x01 CMP r4, r1 BNE l1_ck_2 LDR r0, =PVR0F0_01 LDR r1, =PVR0F2_01 LDR r2, =PVR2F0_01 LDR r3, =PVR2F1_01 B WRITE_L1_SA_SETTINGS l1_ck_2: //; if L1_[2:0] == 10 LDR r1, = 0x02 CMP r4, r1 BNE l1_ck_3 LDR r0, =PVR0F0_10 LDR r1, =PVR0F2_10 LDR r2, =PVR2F0_10 LDR r3, =PVR2F1_10 B WRITE_L1_SA_SETTINGS l1_ck_3: //; if L1_[2:0] == 11 LDR r1, = 0x03 CMP r4, r1 LDR r0, =PVR0F0_11 LDR r1, =PVR0F2_11 LDR r2, =PVR2F0_11 LDR r3, =PVR2F1_11 B WRITE_L1_SA_SETTINGS WRITE_L1_SA_SETTINGS: //;WCP15_PVR0F0 r0 MCR p15, 0x0, r0, c15, c15, 0x0 //; write R0 to PVR0F0 //;WCP15_PVR0F2 r1 MCR p15, 0x0, r1, c15, c15, 0x2 //; write R1 to PVR0F2 //;WCP15_PVR2F0 r2 MCR p15, 0x2, r2, c15, c15, 0x0 //; write R2 to PVR2F0 // Disable predecode repair cache on certain Scorpion revisions // (Raptor V2 and earlier, or Halcyon V1) MRC p15, 0, r1, c0, c0, 0 //; MIDR BIC r2, r1, #0xf0 //; check for Halcyon V1 LDR r3, =0x511f0000 CMP r2, r3 BNE PVR2F1 DPRC: MRC p15, 0, r1, c15, c15, 2 //; PVR0F2 ORR r1, r1, #0x10 //; enable bit 4 MCR p15, 0, r1, c15, c15, 2 //; disable predecode repair cache PVR2F1: //;WCP15_PVR2F1 r3 MCR p15, 0x2, r3, c15, c15, 0x1 //; write R3 to PVR2F1 //; Reading L2_ACC LDR r4, = 0x0 //; Read L2_ACC_BIT_0 LDR r1, =TCSR_CONF_FUSE_1 LDR r2, =L2_ACC_BIT_0 LDR r3, [r1] MOV r3, r3, LSR r2 AND r3, r3, #1 ORR r4, r3, r4 //; Read L2_ACC_BIT_1 LDR r1, =TCSR_CONF_FUSE_4 LDR r2, =L2_ACC_BIT_1 LDR r3, [r1] MOV r3, r3, LSR r2 AND r3, r3, #1 MOV r3, r3, LSL #1 ORR r4, r3, r4 //; Read L2_ACC_BIT_2 LDR r1, =TCSR_CONF_FUSE_4 LDR r2, =L2_ACC_BIT_2 LDR r3, [r1] MOV r3, r3, LSR r2 AND r3, r3, #1 MOV r3, r3, LSL #2 ORR r4, r3, r4 l2_ck_0: //; if L2_[2:0] == 000 LDR r5, = 0x0 CMP r4, r5 BNE l2_ck_1 LDR r0, =L2VR3F1_000 B WRITE_L2_SA_SETTINGS l2_ck_1: //; if L2_[2:0] == 001 LDR r5, = 0x1 CMP r4, r5 BNE l2_ck_2 LDR r0, =L2VR3F1_001 B WRITE_L2_SA_SETTINGS l2_ck_2: //; if L2_[2:0] == 010 LDR r5, = 0x2 CMP r4, r5 BNE l2_ck_3 LDR r0, =L2VR3F1_010 B WRITE_L2_SA_SETTINGS l2_ck_3: //; if L2_[2:0] == 011 LDR r5, = 0x3 CMP r4, r5 BNE l2_ck_4 LDR r0, =L2VR3F1_011 B WRITE_L2_SA_SETTINGS l2_ck_4: //; if L2_[2:0] == 100 LDR r5, = 0x4 CMP r4, r5 BNE l2_ck_5 LDR r0, =L2VR3F1_100 B WRITE_L2_SA_SETTINGS l2_ck_5: //; if L2_[2:0] == 101 LDR r5, = 0x5 CMP r4, r5 BNE l2_ck_6 LDR r0, =L2VR3F1_101 B WRITE_L2_SA_SETTINGS l2_ck_6: //; if L2_[2:0] == 110 LDR r5, = 0x6 CMP r4, r5 BNE l2_ck_7 LDR r0, =L2VR3F1_110 B WRITE_L2_SA_SETTINGS l2_ck_7: //; if L2_[2:0] == 111 LDR r5, = 0x7 CMP r4, r5 LDR r0, =L2VR3F1_111 B WRITE_L2_SA_SETTINGS WRITE_L2_SA_SETTINGS: //;WCP15_L2VR3F1 r0 MCR p15, 0x3, r0, c15, c15, 0x1 //;write r0 to L2VR3F1 DSB ISB LDR r0, =0 //;make sure the registers we touched LDR r1, =0 //;are cleared when we return LDR r2, =0 LDR r3, =0 LDR r4, =0 LDR r5, =0 //; routine complete BX LR .ltorg .globl __cpu_early_init __cpu_early_init: //; Zero out r0 for use throughout this code. All other GPRs //; (r1-r3) are set throughout this code to help establish //; a consistent startup state for any code that follows. //; Users should add code at the end of this routine to establish //; their own stack address (r13), add translation page tables, enable //; the caches, etc. MOV r0, #0x0 //; Remove hardcoded cache settings. appsbl_handler.s calls Set_SA //; API to dynamically configure cache for slow/nominal/fast parts //; DCIALL to invalidate L2 cache bank (needs to be run 4 times, once per bank) //; This must be done early in code (prior to enabling the caches) MOV r1, #0x2 MCR p15, 0, r1, c9, c0, 6 //; DCIALL bank D ([15:14] == 2'b00) ORR r1, r1, #0x00004000 MCR p15, 0, r1, c9, c0, 6 //; DCIALL bank C ([15:14] == 2'b01) ADD r1, r1, #0x00004000 MCR p15, 0, r1, c9, c0, 6 //; DCIALL bank B ([15:14] == 2'b10) ADD r1, r1, #0x00004000 MCR p15, 0, r1, c9, c0, 6 //; DCIALL bank A ([15:14] == 2'b11) //; Initialize the BPCR - setup Global History Mask (GHRM) to all 1's //; and have all address bits (AM) participate. //; Different settings can be used to improve performance // MOVW r1, #0x01FF .word 0xe30011ff // hardcoded MOVW instruction due to lack of compiler support // MOVT r1, #0x01FF .word 0xe34011ff // hardcoded MOVT instruction due to lack of compiler support MCR p15, 7, r1, c15, c0, 2 //; WCP15_BPCR //; Initialize all I$ Victim Registers to 0 for startup MCR p15, 0, r0, c9, c1, 0 //; WCP15_ICVIC0 r0 MCR p15, 0, r0, c9, c1, 1 //; WCP15_ICVIC1 r0 MCR p15, 0, r0, c9, c1, 2 //; WCP15_ICVIC2 r0 MCR p15, 0, r0, c9, c1, 3 //; WCP15_ICVIC3 r0 MCR p15, 0, r0, c9, c1, 4 //; WCP15_ICVIC4 r0 MCR p15, 0, r0, c9, c1, 5 //; WCP15_ICVIC5 r0 MCR p15, 0, r0, c9, c1, 6 //; WCP15_ICVIC5 r0 MCR p15, 0, r0, c9, c1, 7 //; WCP15_ICVIC7 r0 //; Initialize all I$ Locked Victim Registers (Unlocked Floors) to 0 MCR p15, 1, r0, c9, c1, 0 //; WCP15_ICFLOOR0 r0 MCR p15, 1, r0, c9, c1, 1 //; WCP15_ICFLOOR1 r0 MCR p15, 1, r0, c9, c1, 2 //; WCP15_ICFLOOR2 r0 MCR p15, 1, r0, c9, c1, 3 //; WCP15_ICFLOOR3 r0 MCR p15, 1, r0, c9, c1, 4 //; WCP15_ICFLOOR4 r0 MCR p15, 1, r0, c9, c1, 5 //; WCP15_ICFLOOR5 r0 MCR p15, 1, r0, c9, c1, 6 //; WCP15_ICFLOOR6 r0 MCR p15, 1, r0, c9, c1, 7 //; WCP15_ICFLOOR7 r0 //; Initialize all D$ Victim Registers to 0 MCR p15, 2, r0, c9, c1, 0 //; WP15_DCVIC0 r0 MCR p15, 2, r0, c9, c1, 1 //; WP15_DCVIC1 r0 MCR p15, 2, r0, c9, c1, 2 //; WP15_DCVIC2 r0 MCR p15, 2, r0, c9, c1, 3 //; WP15_DCVIC3 r0 MCR p15, 2, r0, c9, c1, 4 //; WP15_DCVIC4 r0 MCR p15, 2, r0, c9, c1, 5 //; WP15_DCVIC5 r0 MCR p15, 2, r0, c9, c1, 6 //; WP15_DCVIC6 r0 MCR p15, 2, r0, c9, c1, 7 //; WP15_DCVIC7 r0 //; Initialize all D$ Locked VDCtim Registers (Unlocked Floors) to 0 MCR p15, 3, r0, c9, c1, 0 //; WCP15_DCFLOOR0 r0 MCR p15, 3, r0, c9, c1, 1 //; WCP15_DCFLOOR1 r0 MCR p15, 3, r0, c9, c1, 2 //; WCP15_DCFLOOR2 r0 MCR p15, 3, r0, c9, c1, 3 //; WCP15_DCFLOOR3 r0 MCR p15, 3, r0, c9, c1, 4 //; WCP15_DCFLOOR4 r0 MCR p15, 3, r0, c9, c1, 5 //; WCP15_DCFLOOR5 r0 MCR p15, 3, r0, c9, c1, 6 //; WCP15_DCFLOOR6 r0 MCR p15, 3, r0, c9, c1, 7 //; WCP15_DCFLOOR7 r0 //; Initialize ASID to zero MCR p15, 0, r0, c13, c0, 1 //; WCP15_CONTEXTIDR r0 //; ICIALL to invalidate entire I-Cache MCR p15, 0, r0, c7, c5, 0 //; ICIALLU //; DCIALL to invalidate entire D-Cache MCR p15, 0, r0, c9, c0, 6 //; DCIALL r0 //; Initialize ADFSR to zero MCR p15, 0, r0, c5, c1, 0 //; ADFSR r0 //; Initialize EFSR to zero MCR p15, 7, r0, c15, c0, 1 //; EFSR r0 //; The VBAR (Vector Base Address Register) should be initialized //; early in your code. We are setting it to zero MCR p15, 0, r0, c12, c0, 0 //; WCP15_VBAR r0 //; Ensure the MCR's above have completed their operation before continuing DSB ISB //;------------------------------------------------------------------- //; There are a number of registers that must be set prior to enabling //; the MMU. The DCAR is one of these registers. We are setting //; it to zero (no access) to easily detect improper setup in subsequent //; code sequences //;------------------------------------------------------------------- //; Setup DACR (Domain Access Control Register) to zero MCR p15, 0, r0, c3, c0, 0 //; WCP15_DACR r0 //; Setup DCLKCR to allow normal D-Cache line fills MCR p15, 1, r0, c9, c0, 7 //; WCP15_DCLKCR r0 //; Setup the TLBLKCR //; Victim = 6'b000000; Floor = 6'b000000; //; IASIDCFG = 2'b00 (State-Machine); IALLCFG = 2'b01 (Flash); BNA = 1'b0; MOV r1, #0x02 MCR p15, 0, r1, c10, c1, 3 //; WCP15_TLBLKCR r1 //;Make sure TLBLKCR is complete before continuing ISB //; Invalidate the UTLB MCR p15, 0, r0, c8, c7, 0 //; UTLBIALL //; Make sure UTLB request has been presented to macro before continuing ISB SYSI2: //; setup L2CR1 to some default Instruction and data prefetching values //; Users may want specific settings for various performance enhancements //; In Halcyon we do not have broadcasting barriers. So we need to turn // ; on bit 8 of L2CR1; which DBB:( Disable barrier broadcast ) LDR r2, =0x133 MCR p15, 3, r2, c15, c0, 3 //; WCP15_L2CR1 r0 //; Enable Z bit to enable branch prediction (default is off) MRC p15, 0, r2, c1, c0, 0 //; RCP15_SCTLR r2 ORR r2, r2, #0x00000800 MCR p15, 0, r2, c1, c0, 0 //; WCP15_SCTLR r2 //; Make sure Link stack is initialized with branch and links to sequential addresses //; This aids in creating a predictable startup environment BL SEQ1 SEQ1: BL SEQ2 SEQ2: BL SEQ3 SEQ3: BL SEQ4 SEQ4: BL SEQ5 SEQ5: BL SEQ6 SEQ6: BL SEQ7 SEQ7: BL SEQ8 SEQ8: //; REMOVE FOLLOWING THREE INSTRUCTIONS WHEN POWER COLLAPSE IS ENA //;Make sure the DBGOSLSR[LOCK] bit is cleared to allow access to the debug registers //; Writing anything but the "secret code" to the DBGOSLAR clears the DBGOSLSR[LOCK] bit MCR p14, 0, r0, c1, c0, 4 //; WCP14_DBGOSLAR r0 //; Read the DBGPRSR to clear the DBGPRSR[STICKYPD] //; Any read to DBGPRSR clear the STICKYPD bit //; ISB guarantees the read completes before attempting to //; execute a CP14 instruction. MRC p14, 0, r3, c1, c5, 4 //; RCP14_DBGPRSR r3 ISB //; Initialize the Watchpoint Control Registers to zero (optional) //;;; MCR p14, 0, r0, c0, c0, 7 ; WCP14_DBGWCR0 r0 //;;; MCR p14, 0, r0, c0, c1, 7 ; WCP14_DBGWCR1 r0 //;---------------------------------------------------------------------- //; The saved Program Status Registers (SPSRs) should be setup //; prior to any automatic mode switches. The following //; code sets these registers up to a known state. Users will need to //; customize these settings to meet their needs. //;---------------------------------------------------------------------- MOV r2, #0x1f MOV r1, #0xd7 //;ABT mode msr cpsr_c, r1 //;ABT mode msr spsr_cxfs, r2 //;clear the spsr MOV r1, #0xdb //;UND mode msr cpsr_c, r1 //;UND mode msr spsr_cxfs, r2 //;clear the spsr MOV r1, #0xd1 //;FIQ mode msr cpsr_c, r1 //;FIQ mode msr spsr_cxfs, r2 //;clear the spsr MOV r1, #0xd2 //;IRQ mode msr cpsr_c, r1 //;IRQ mode msr spsr_cxfs, r2 //;clear the spsr MOV r1, #0xd6 //;Monitor mode msr cpsr_c, r1 //;Monitor mode msr spsr_cxfs, r2 //;clear the spsr MOV r1, #0xd3 //;SVC mode msr cpsr_c, r1 //;SVC mode msr spsr_cxfs, r2 //;clear the spsr //;---------------------------------------------------------------------- //; Enabling Error reporting is something users may want to do at //; some other point in time. We have chosen some default settings //; that should be reviewed. Most of these registers come up in an //; unpredictable state after reset. //;---------------------------------------------------------------------- //;Start of error and control setting //; setup L2CR0 with various L2/TCM control settings //; enable out of order bus attributes and error reporting //; this register comes up unpredictable after reset // MOVW r1, #0x0F0F .word 0xe3001f0f // hardcoded MOVW instruction due to lack of compiler support // MOVT r1, #0xC005 .word 0xe34c1005 // hardcoded MOVW instruction due to lack of compiler support MCR p15, 3, r1, c15, c0, 1 //; WCP15_L2CR0 r1 //; setup L2CPUCR //; MOV r2, #0xFF //; Enable I and D cache parity //;L2CPUCR[7:5] = 3~Rh7 ~V enable parity error reporting for modified, //;tag, and data parity errors MOV r2, #0xe0 MCR p15, 3, r2, c15, c0, 2 //; WCP15_L2CPUCR r2 //; setup SPCR //; enable all error reporting (reset value is unpredicatble for most bits) MOV r3, #0x0F MCR p15, 0, r3, c9, c7, 0 //; WCP15_SPCR r3 //; setup DMACHCRs (reset value unpredictable) //; control setting and enable all error reporting MOV r1, #0x0F //; DMACHCR0 = 0000000F MOV r2, #0x00 //; channel 0 MCR p15, 0, r2, c11, c0, 0 //; WCP15_DMASELR r2 MCR p15, 0, r1, c11, c0, 2 //; WCP15_DMACHCR r1 //; DMACHCR1 = 0000000F MOV r2, #0x01 //; channel 1 MCR p15, 0, r2, c11, c0, 0 //; WCP15_DMASELR r2 MCR p15, 0, r1, c11, c0, 2 //; WCP15_DMACHCR r1 //; DMACHCR2 = 0000000F MOV r2, #0x02 //; channel 2 MCR p15, 0, r2, c11, c0, 0 //; WCP15_DMASELR r2 MCR p15, 0, r1, c11, c0, 2 //; WCP15_DMACHCR r1 //; DMACHCR3 = 0000000F MOV r2, #0x03 //; channel 3 MCR p15, 0, r2, c11, c0, 0 //; WCP15_DMASELR r2 MCR p15, 0, r1, c11, c0, 2 //; WCP15_DMACHCR r1 //; Set ACTLR (reset unpredictable) //; Set AVIVT control, error reporting, etc. //; MOV r3, #0x07 //; Enable I and D cache parity //;ACTLR[2:0] = 3'h7 - enable parity error reporting from L2/I$/D$) //;ACTLR[5:4] = 2'h3 - enable parity //;ACTLR[19:18] =2'h3 - always generate and check parity(when MMU disabled). //;Value to be written #0xC0037 // MOVW r3, #0x0037 .word 0xe3003037 // hardcoded MOVW instruction due to lack of compiler support // MOVT r3, #0x000C .word 0xe340300c // hardcoded MOVW instruction due to lack of compiler support MCR p15, 0, r3, c1, c0, 1 //; WCP15_ACTLR r3 //;End of error and control setting //;---------------------------------------------------------------------- //; Unlock ETM and read StickyPD to halt the ETM clocks from running. //; This is required for power saving whether the ETM is used or not. //;---------------------------------------------------------------------- //;Clear ETMOSLSR[LOCK] bit MOV r1, #0x00000000 MCR p14, 1, r1, c1, c0, 4 //; WCP14_ETMOSLAR r1 //;Clear ETMPDSR[STICKYPD] bit MRC p14, 1, r2, c1, c5, 4 //; RCP14_ETMPDSR r2 /* #ifdef APPSBL_ETM_ENABLE ;---------------------------------------------------------------------- ; Optionally Enable the ETM (Embedded Trace Macro) which is used for debug ;---------------------------------------------------------------------- ; enable ETM clock if disabled MRC p15, 7, r1, c15, c0, 5 ; RCP15_CPMR r1 ORR r1, r1, #0x00000008 MCR p15, 7, r1, c15, c0, 5 ; WCP15_CPMR r1 ISB ; set trigger event to counter1 being zero MOV r3, #0x00000040 MCR p14, 1, r3, c0, c2, 0 ; WCP14_ETMTRIGGER r3 ; clear ETMSR MOV r2, #0x00000000 MCR p14, 1, r2, c0, c4, 0 ; WCP14_ETMSR r2 ; clear trace enable single address comparator usage MCR p14, 1, r2, c0, c7, 0 ; WCP14_ETMTECR2 r2 ; set trace enable to always MOV r2, #0x0000006F MCR p14, 1, r2, c0, c8, 0 ; WCP14_ETMTEEVR r2 ; clear trace enable address range comparator usage and exclude nothing MOV r2, #0x01000000 MCR p14, 1, r2, c0, c9, 0 ; WCP14_ETMTECR1 r2 ; set view data to always MOV r2, #0x0000006F MCR p14, 1, r2, c0, c12, 0 ; WCP14_ETMVDEVR r2 ; clear view data single address comparator usage MOV r2, #0x00000000 MCR p14, 1, r2, c0, c13, 0 ; WCP14_ETMVDCR1 r2 ; clear view data address range comparator usage and exclude nothing MOV r2, #0x00010000 MCR p14, 1, r2, c0, c15, 0 ; WCP14_ETMVDCR3 r2 ; set counter1 to 194 MOV r2, #0x000000C2 MCR p14, 1, r2, c0, c0, 5 ; WCP14_ETMCNTRLDVR1 r2 ; set counter1 to never reload MOV r2, #0x0000406F MCR p14, 1, r2, c0, c8, 5 ; WCP14_ETMCNTRLDEVR1 r2 ; set counter1 to decrement every cycle MOV r2, #0x0000006F MCR p14, 1, r2, c0, c4, 5 ; WCP14_ETMCNTENR1 r2 ; Set trace synchronization frequency 1024 bytes MOV r2, #0x00000400 MCR p14, 1, r2, c0, c8, 7 ; WCP14_ETMSYNCFR r2 ; Program etm control register ; - Set the CPU to ETM clock ratio to 1:1 ; - Set the ETM to perform data address tracing MOV r2, #0x00002008 MCR p14, 1, r2, c0, c0, 0 ; WCP14_ETMCR r2 ISB #endif *//* APPSBL_ETM_ENABLE */ /* #ifdef APPSBL_VFP_ENABLE ;---------------------------------------------------------------------- ; Perform the following operations if you intend to make use of ; the VFP/Neon unit. Note that the FMXR instruction requires a CPU ID ; indicating the VFP unit is present (i.e.Cortex-A8). . ; Some tools will require full double precision floating point support ; which will become available in Scorpion pass 2 ;---------------------------------------------------------------------- ; allow full access to CP 10 and 11 space for VFP/NEON use MRC p15, 0, r1, c1, c0, 2 ; Read CP Access Control Register ORR r1, r1, #0x00F00000 ; enable full access for p10,11 MCR p15, 0, r1, c1, c0, 2 ; Write CPACR ;make sure the CPACR is complete before continuing ISB ; Enable VFP itself (certain OSes may want to dynamically set/clear ; the enable bit based on the application being executed MOV r1, #0x40000000 FMXR FPEXC, r1 #endif *//* APPSBL_VFP_ENABLE */ BX LR .ltorg